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infinityofspace
/
python_codestyles-random-500

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xet
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code
stringlengths
87
55.2k
code_codestyle
int64
0
349
style_context
stringlengths
135
49.1k
style_context_codestyle
int64
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from typing import TYPE_CHECKING from ...utils import ( OptionalDependencyNotAvailable, _LazyModule, is_flax_available, is_tf_available, is_tokenizers_available, is_torch_available, ) lowercase__ :int = { "configuration_blenderbot": [ "BLENDERBOT_PRETRAINED_CONFIG_ARCHIVE_MAP", "BlenderbotConfig", "BlenderbotOnnxConfig", ], "tokenization_blenderbot": ["BlenderbotTokenizer"], } try: if not is_tokenizers_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: lowercase__ :Optional[int] = ["BlenderbotTokenizerFast"] try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: lowercase__ :List[str] = [ "BLENDERBOT_PRETRAINED_MODEL_ARCHIVE_LIST", "BlenderbotForCausalLM", "BlenderbotForConditionalGeneration", "BlenderbotModel", "BlenderbotPreTrainedModel", ] try: if not is_tf_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: lowercase__ :Any = [ "TFBlenderbotForConditionalGeneration", "TFBlenderbotModel", "TFBlenderbotPreTrainedModel", ] try: if not is_flax_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: lowercase__ :Union[str, Any] = [ "FlaxBlenderbotForConditionalGeneration", "FlaxBlenderbotModel", "FlaxBlenderbotPreTrainedModel", ] if TYPE_CHECKING: from .configuration_blenderbot import ( BLENDERBOT_PRETRAINED_CONFIG_ARCHIVE_MAP, BlenderbotConfig, BlenderbotOnnxConfig, ) from .tokenization_blenderbot import BlenderbotTokenizer try: if not is_tokenizers_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .tokenization_blenderbot_fast import BlenderbotTokenizerFast try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_blenderbot import ( BLENDERBOT_PRETRAINED_MODEL_ARCHIVE_LIST, BlenderbotForCausalLM, BlenderbotForConditionalGeneration, BlenderbotModel, BlenderbotPreTrainedModel, ) try: if not is_tf_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_tf_blenderbot import ( TFBlenderbotForConditionalGeneration, TFBlenderbotModel, TFBlenderbotPreTrainedModel, ) try: if not is_flax_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_flax_blenderbot import ( FlaxBlenderbotForConditionalGeneration, FlaxBlenderbotModel, FlaxBlenderbotPreTrainedModel, ) else: import sys lowercase__ :Union[str, Any] = _LazyModule(__name__, globals()["__file__"], _import_structure, module_spec=__spec__)
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import argparse import json import os import torch from torch import nn from transformers import NllbMoeConfig, NllbMoeModel from transformers.modeling_utils import dtype_byte_size from transformers.utils import WEIGHTS_INDEX_NAME, WEIGHTS_NAME def lowercase_ (A : List[str] ): snake_case__ : Tuple = [ 'encoder.version', 'decoder.version', 'model.encoder.version', 'model.decoder.version', 'decoder.output_projection.weight', '_float_tensor', 'encoder.embed_positions._float_tensor', 'decoder.embed_positions._float_tensor', ] for k in ignore_keys: state_dict.pop(A , A ) def lowercase_ (A : str ): snake_case__ , snake_case__ : Union[str, Any] = emb.weight.shape snake_case__ : str = nn.Linear(A , A , bias=A ) snake_case__ : str = emb.weight.data return lin_layer def lowercase_ (A : Optional[int] , A : Union[str, Any]=None ): snake_case__ : Any = {} for old_key in state_dict.keys(): snake_case__ : Tuple = old_key if "moe_layer.experts." in key: if expert_idx is not None: snake_case__ : int = key.replace('moe_layer.experts.0' , F'''ffn.experts.expert_{expert_idx}''' ) else: snake_case__ : Any = key.replace('moe_layer.experts.' , 'ffn.experts.expert_' ) if "gate" in key: snake_case__ : Dict = key.replace('.moe_layer.gate.wg' , '.ffn.router.classifier' ) if "fc2" and "experts" not in key: snake_case__ : str = key.replace('.fc2.' , '.ffn.fc2.' ) if "fc1" and "experts" not in key: snake_case__ : str = key.replace('.fc1.' , '.ffn.fc1.' ) if ".encoder_attn." in key: snake_case__ : Tuple = key.replace('.encoder_attn.' , '.cross_attention.' ) if "encoder_attn_layer_norm" in key: snake_case__ : Tuple = key.replace('encoder_attn_layer_norm' , 'cross_attention_layer_norm' ) if "final_layer_norm" in key: snake_case__ : Optional[int] = key.replace('final_layer_norm' , 'ff_layer_norm' ) snake_case__ : Dict = state_dict[old_key] return new_dict def lowercase_ (A : List[Any] , A : Tuple , A : List[Any] , A : List[str] , A : str = WEIGHTS_NAME ): snake_case__ : Dict = [] snake_case__ : str = 0 os.makedirs(A , exist_ok=A ) for expert in range(A ): snake_case__ : Tuple = switch_checkpoint_path + F'''-rank-{expert}.pt''' if os.path.isfile(A ): snake_case__ : Optional[Any] = torch.load(A )['model'] remove_ignore_keys_(A ) snake_case__ : Optional[Any] = rename_fairseq_keys(A , A ) snake_case__ : Dict = os.path.join( A , weights_name.replace('.bin' , F'''-{len(A )+1:05d}-of-???.bin''' ) ) torch.save(A , A ) sharded_state_dicts.append(expert_state.keys() ) total_size += sum([value.numel() for key, value in expert_state.items()] ) * dtype_byte_size( expert_state[list(A )[0]].dtype ) # Add the last block snake_case__ : Tuple = os.path.join(A , weights_name.replace('.bin' , F'''-{len(A )+1:05d}-of-???.bin''' ) ) snake_case__ : Union[str, Any] = torch.load(switch_checkpoint_path + '-shared.pt' )['model'] remove_ignore_keys_(A ) snake_case__ : str = rename_fairseq_keys(A , A ) snake_case__ : Any = shared_weights['decoder.embed_tokens.weight'] sharded_state_dicts.append(shared_weights.keys() ) # If we only have the shared weights (dummy model/experts saved on the same file) if len(A ) == 1: snake_case__ : Any = os.path.join(A , A ) torch.save(A , A ) return {weights_name: sharded_state_dicts[0]}, None else: torch.save(A , A ) # Otherwise, let's build the index snake_case__ : Tuple = {} for idx, shard in enumerate(A ): snake_case__ : Optional[int] = weights_name.replace('.bin' , F'''-{idx+1:05d}-of-{len(A ):05d}.bin''' ) snake_case__ : List[Any] = os.path.join(A , weights_name.replace('.bin' , F'''-{idx+1:05d}-of-???.bin''' ) ) os.rename(A , os.path.join(A , A ) ) for key in shard: snake_case__ : Any = shard_file # Add the metadata snake_case__ : int = {'total_size': total_size} snake_case__ : Dict = {'metadata': metadata, 'weight_map': weight_map} with open(os.path.join(A , A ) , 'w' , encoding='utf-8' ) as f: snake_case__ : Any = json.dumps(A , indent=2 , sort_keys=A ) + '\n' f.write(A ) return metadata, index if __name__ == "__main__": a_ :int = argparse.ArgumentParser() # Required parameters parser.add_argument( "--nllb_moe_checkpoint_path", default="/home/arthur_huggingface_co/fairseq/weights/checkpoints/model_moe_54b/checkpoint_2_300000", type=str, required=False, help="Path to a directory containing a folder per layer. Follows the original Google format.", ) parser.add_argument("--dtype", default="float32", type=str, required=False, help="dtype of the saved model") parser.add_argument( "--pytorch_dump_folder_path", default="/home/arthur_huggingface_co/fairseq/weights/checkpoints/hf-converted-moe-54b", type=str, required=False, help="Path to the output pytorch model.", ) a_ :Optional[Any] = parser.parse_args() a_ , a_ :Optional[Any] = shard_on_the_fly( args.nllb_moe_checkpoint_path, args.pytorch_dump_folder_path, 128, args.dtype, ) a_ :List[str] = NllbMoeConfig.from_pretrained( "facebook/nllb-200-3.3B", encoder_sparse_step=4, decoder_sparse_step=4, num_experts=128 ) config.save_pretrained(args.pytorch_dump_folder_path) a_ :int = NllbMoeModel.from_pretrained(args.pytorch_dump_folder_path) print("Done") model.save_pretrained(args.pytorch_dump_folder_path)
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"""simple docstring""" from collections import OrderedDict from typing import Mapping from packaging import version from ...configuration_utils import PretrainedConfig from ...onnx import OnnxConfig from ...utils import logging SCREAMING_SNAKE_CASE : Union[str, Any] = logging.get_logger(__name__) SCREAMING_SNAKE_CASE : Optional[int] = { """sail/poolformer_s12""": """https://huggingface.co/sail/poolformer_s12/resolve/main/config.json""", # See all PoolFormer models at https://huggingface.co/models?filter=poolformer } class _UpperCAmelCase ( __snake_case ): '''simple docstring''' lowerCamelCase__ ='poolformer' def __init__(self , a_=3 , a_=16 , a_=16 , a_=3 , a_=4.0 , a_=[2, 2, 6, 2] , a_=[64, 1_28, 3_20, 5_12] , a_=[7, 3, 3, 3] , a_=[4, 2, 2, 2] , a_=[2, 1, 1, 1] , a_=4 , a_=0.0 , a_="gelu" , a_=True , a_=1E-5 , a_=0.02 , **a_ , ): '''simple docstring''' __snake_case : int = num_channels __snake_case : Union[str, Any] = patch_size __snake_case : Optional[int] = stride __snake_case : List[Any] = padding __snake_case : Optional[Any] = pool_size __snake_case : List[Any] = hidden_sizes __snake_case : Union[str, Any] = mlp_ratio __snake_case : List[Any] = depths __snake_case : Dict = patch_sizes __snake_case : str = strides __snake_case : Dict = num_encoder_blocks __snake_case : List[str] = drop_path_rate __snake_case : int = hidden_act __snake_case : List[str] = use_layer_scale __snake_case : List[str] = layer_scale_init_value __snake_case : List[Any] = initializer_range super().__init__(**a_ ) class _UpperCAmelCase ( __snake_case ): '''simple docstring''' lowerCamelCase__ =version.parse('1.11' ) @property def SCREAMING_SNAKE_CASE (self ): '''simple docstring''' return OrderedDict( [ ('''pixel_values''', {0: '''batch''', 1: '''num_channels''', 2: '''height''', 3: '''width'''}), ] ) @property def SCREAMING_SNAKE_CASE (self ): '''simple docstring''' return 2E-3
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from typing import TYPE_CHECKING from ...utils import ( OptionalDependencyNotAvailable, _LazyModule, is_sentencepiece_available, is_tokenizers_available, is_torch_available, ) a_ :Optional[Any] = {"configuration_reformer": ["REFORMER_PRETRAINED_CONFIG_ARCHIVE_MAP", "ReformerConfig"]} try: if not is_sentencepiece_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: a_ :str = ["ReformerTokenizer"] try: if not is_tokenizers_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: a_ :int = ["ReformerTokenizerFast"] try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: a_ :List[str] = [ "REFORMER_PRETRAINED_MODEL_ARCHIVE_LIST", "ReformerAttention", "ReformerForMaskedLM", "ReformerForQuestionAnswering", "ReformerForSequenceClassification", "ReformerLayer", "ReformerModel", "ReformerModelWithLMHead", "ReformerPreTrainedModel", ] if TYPE_CHECKING: from .configuration_reformer import REFORMER_PRETRAINED_CONFIG_ARCHIVE_MAP, ReformerConfig try: if not is_sentencepiece_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .tokenization_reformer import ReformerTokenizer try: if not is_tokenizers_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .tokenization_reformer_fast import ReformerTokenizerFast try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_reformer import ( REFORMER_PRETRAINED_MODEL_ARCHIVE_LIST, ReformerAttention, ReformerForMaskedLM, ReformerForQuestionAnswering, ReformerForSequenceClassification, ReformerLayer, ReformerModel, ReformerModelWithLMHead, ReformerPreTrainedModel, ) else: import sys a_ :Optional[Any] = _LazyModule(__name__, globals()["__file__"], _import_structure, module_spec=__spec__)
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0
import re def UpperCamelCase( __UpperCamelCase : str ): if len(re.findall('''[ATCG]''' ,__UpperCamelCase ) ) != len(__UpperCamelCase ): raise ValueError('''Invalid Strand''' ) return dna.translate(dna.maketrans('''ATCG''' ,'''TAGC''' ) ) if __name__ == "__main__": import doctest doctest.testmod()
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import itertools import random import unittest import numpy as np from transformers import BatchFeature, SpeechTaFeatureExtractor from transformers.testing_utils import require_torch from transformers.utils.import_utils import is_torch_available from ...test_sequence_feature_extraction_common import SequenceFeatureExtractionTestMixin if is_torch_available(): import torch a_ :Any = random.Random() def lowercase_ (A : int , A : Union[str, Any]=1.0 , A : List[str]=None , A : Any=None ): if rng is None: snake_case__ : List[str] = global_rng snake_case__ : int = [] for batch_idx in range(shape[0] ): values.append([] ) for _ in range(shape[1] ): values[-1].append(rng.random() * scale ) return values @require_torch class snake_case__ ( unittest.TestCase ): """simple docstring""" def __init__( self : Optional[Any], _snake_case : List[str], _snake_case : Tuple=7, _snake_case : Union[str, Any]=4_0_0, _snake_case : Any=2_0_0_0, _snake_case : Dict=1, _snake_case : Optional[Any]=0.0, _snake_case : List[Any]=1_6_0_0_0, _snake_case : List[Any]=True, _snake_case : List[Any]=8_0, _snake_case : Dict=1_6, _snake_case : str=6_4, _snake_case : Tuple="hann_window", _snake_case : Union[str, Any]=8_0, _snake_case : Optional[Any]=7_6_0_0, _snake_case : str=1e-10, _snake_case : Any=True, ) ->Union[str, Any]: snake_case__ : Optional[int] = parent snake_case__ : Optional[Any] = batch_size snake_case__ : List[Any] = min_seq_length snake_case__ : List[Any] = max_seq_length snake_case__ : Any = (self.max_seq_length - self.min_seq_length) // (self.batch_size - 1) snake_case__ : Tuple = feature_size snake_case__ : List[Any] = padding_value snake_case__ : Any = sampling_rate snake_case__ : Dict = do_normalize snake_case__ : Union[str, Any] = num_mel_bins snake_case__ : Any = hop_length snake_case__ : Any = win_length snake_case__ : Any = win_function snake_case__ : Optional[int] = fmin snake_case__ : int = fmax snake_case__ : Union[str, Any] = mel_floor snake_case__ : Union[str, Any] = return_attention_mask def lowercase_ ( self : Optional[int] ) ->List[str]: return { "feature_size": self.feature_size, "padding_value": self.padding_value, "sampling_rate": self.sampling_rate, "do_normalize": self.do_normalize, "num_mel_bins": self.num_mel_bins, "hop_length": self.hop_length, "win_length": self.win_length, "win_function": self.win_function, "fmin": self.fmin, "fmax": self.fmax, "mel_floor": self.mel_floor, "return_attention_mask": self.return_attention_mask, } def lowercase_ ( self : Any, _snake_case : Optional[Any]=False, _snake_case : List[str]=False ) ->Union[str, Any]: def _flatten(_snake_case : List[str] ): return list(itertools.chain(*_snake_case ) ) if equal_length: snake_case__ : Any = floats_list((self.batch_size, self.max_seq_length) ) else: # make sure that inputs increase in size snake_case__ : int = [ _flatten(floats_list((x, self.feature_size) ) ) for x in range(self.min_seq_length, self.max_seq_length, self.seq_length_diff ) ] if numpify: snake_case__ : Any = [np.asarray(_snake_case ) for x in speech_inputs] return speech_inputs def lowercase_ ( self : Union[str, Any], _snake_case : str=False, _snake_case : Dict=False ) ->List[str]: if equal_length: snake_case__ : Optional[Any] = [floats_list((self.max_seq_length, self.num_mel_bins) ) for _ in range(self.batch_size )] else: # make sure that inputs increase in size snake_case__ : List[str] = [ floats_list((x, self.num_mel_bins) ) for x in range(self.min_seq_length, self.max_seq_length, self.seq_length_diff ) ] if numpify: snake_case__ : int = [np.asarray(_snake_case ) for x in speech_inputs] return speech_inputs @require_torch class snake_case__ ( lowerCAmelCase_ , unittest.TestCase ): """simple docstring""" _SCREAMING_SNAKE_CASE = SpeechTaFeatureExtractor def lowercase_ ( self : int ) ->Union[str, Any]: snake_case__ : List[str] = SpeechTaFeatureExtractionTester(self ) def lowercase_ ( self : Any, _snake_case : Dict ) ->Any: self.assertTrue(np.all(np.mean(_snake_case, axis=0 ) < 1e-3 ) ) self.assertTrue(np.all(np.abs(np.var(_snake_case, axis=0 ) - 1 ) < 1e-3 ) ) def lowercase_ ( self : List[Any] ) ->Union[str, Any]: # Tests that all call wrap to encode_plus and batch_encode_plus snake_case__ : Optional[Any] = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) # create three inputs of length 800, 1000, and 1200 snake_case__ : int = [floats_list((1, x) )[0] for x in range(8_0_0, 1_4_0_0, 2_0_0 )] snake_case__ : Tuple = [np.asarray(_snake_case ) for speech_input in speech_inputs] # Test not batched input snake_case__ : str = feat_extract(speech_inputs[0], return_tensors='np' ).input_values snake_case__ : List[str] = feat_extract(np_speech_inputs[0], return_tensors='np' ).input_values self.assertTrue(np.allclose(_snake_case, _snake_case, atol=1e-3 ) ) # Test batched snake_case__ : Any = feat_extract(_snake_case, return_tensors='np' ).input_values snake_case__ : Union[str, Any] = feat_extract(_snake_case, return_tensors='np' ).input_values for enc_seq_a, enc_seq_a in zip(_snake_case, _snake_case ): self.assertTrue(np.allclose(_snake_case, _snake_case, atol=1e-3 ) ) def lowercase_ ( self : int ) ->Optional[int]: snake_case__ : List[Any] = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) snake_case__ : Tuple = [floats_list((1, x) )[0] for x in range(8_0_0, 1_4_0_0, 2_0_0 )] snake_case__ : int = ['longest', 'max_length', 'do_not_pad'] snake_case__ : List[str] = [None, 1_6_0_0, None] for max_length, padding in zip(_snake_case, _snake_case ): snake_case__ : Optional[int] = feat_extract(_snake_case, padding=_snake_case, max_length=_snake_case, return_tensors='np' ) snake_case__ : Optional[int] = processed.input_values self._check_zero_mean_unit_variance(input_values[0][:8_0_0] ) self.assertTrue(input_values[0][8_0_0:].sum() < 1e-6 ) self._check_zero_mean_unit_variance(input_values[1][:1_0_0_0] ) self.assertTrue(input_values[0][1_0_0_0:].sum() < 1e-6 ) self._check_zero_mean_unit_variance(input_values[2][:1_2_0_0] ) def lowercase_ ( self : Union[str, Any] ) ->Optional[Any]: snake_case__ : Optional[Any] = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) snake_case__ : Tuple = range(8_0_0, 1_4_0_0, 2_0_0 ) snake_case__ : Optional[Any] = [floats_list((1, x) )[0] for x in lengths] snake_case__ : Union[str, Any] = ['longest', 'max_length', 'do_not_pad'] snake_case__ : str = [None, 1_6_0_0, None] for max_length, padding in zip(_snake_case, _snake_case ): snake_case__ : List[str] = feat_extract(_snake_case, max_length=_snake_case, padding=_snake_case ) snake_case__ : Tuple = processed.input_values self._check_zero_mean_unit_variance(input_values[0][:8_0_0] ) self._check_zero_mean_unit_variance(input_values[1][:1_0_0_0] ) self._check_zero_mean_unit_variance(input_values[2][:1_2_0_0] ) def lowercase_ ( self : List[Any] ) ->Optional[Any]: snake_case__ : Any = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) snake_case__ : str = [floats_list((1, x) )[0] for x in range(8_0_0, 1_4_0_0, 2_0_0 )] snake_case__ : Optional[Any] = feat_extract( _snake_case, truncation=_snake_case, max_length=1_0_0_0, padding='max_length', return_tensors='np' ) snake_case__ : int = processed.input_values self._check_zero_mean_unit_variance(input_values[0, :8_0_0] ) self._check_zero_mean_unit_variance(input_values[1] ) self._check_zero_mean_unit_variance(input_values[2] ) def lowercase_ ( self : int ) ->Union[str, Any]: snake_case__ : str = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) snake_case__ : Dict = [floats_list((1, x) )[0] for x in range(8_0_0, 1_4_0_0, 2_0_0 )] snake_case__ : str = feat_extract( _snake_case, truncation=_snake_case, max_length=1_0_0_0, padding='longest', return_tensors='np' ) snake_case__ : Dict = processed.input_values self._check_zero_mean_unit_variance(input_values[0, :8_0_0] ) self._check_zero_mean_unit_variance(input_values[1, :1_0_0_0] ) self._check_zero_mean_unit_variance(input_values[2] ) # make sure that if max_length < longest -> then pad to max_length self.assertTrue(input_values.shape == (3, 1_0_0_0) ) snake_case__ : Tuple = [floats_list((1, x) )[0] for x in range(8_0_0, 1_4_0_0, 2_0_0 )] snake_case__ : List[str] = feat_extract( _snake_case, truncation=_snake_case, max_length=2_0_0_0, padding='longest', return_tensors='np' ) snake_case__ : Optional[Any] = processed.input_values self._check_zero_mean_unit_variance(input_values[0, :8_0_0] ) self._check_zero_mean_unit_variance(input_values[1, :1_0_0_0] ) self._check_zero_mean_unit_variance(input_values[2] ) # make sure that if max_length > longest -> then pad to longest self.assertTrue(input_values.shape == (3, 1_2_0_0) ) def lowercase_ ( self : List[str] ) ->Dict: snake_case__ : Dict = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) snake_case__ : List[Any] = np.random.rand(1_0_0 ).astype(np.floataa ) snake_case__ : int = np_speech_inputs.tolist() for inputs in [py_speech_inputs, np_speech_inputs]: snake_case__ : int = feature_extractor.pad([{'input_values': inputs}], return_tensors='np' ) self.assertTrue(np_processed.input_values.dtype == np.floataa ) snake_case__ : Optional[int] = feature_extractor.pad([{'input_values': inputs}], return_tensors='pt' ) self.assertTrue(pt_processed.input_values.dtype == torch.floataa ) def lowercase_ ( self : Optional[int] ) ->Optional[Any]: # Tests that all call wrap to encode_plus and batch_encode_plus snake_case__ : str = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) # create three inputs of length 800, 1000, and 1200 snake_case__ : List[Any] = [floats_list((1, x) )[0] for x in range(8_0_0, 1_4_0_0, 2_0_0 )] snake_case__ : Dict = [np.asarray(_snake_case ) for speech_input in speech_inputs] # Test feature size snake_case__ : Optional[int] = feature_extractor(audio_target=_snake_case, padding=_snake_case, return_tensors='np' ).input_values self.assertTrue(input_values.ndim == 3 ) self.assertTrue(input_values.shape[-1] == feature_extractor.num_mel_bins ) # Test not batched input snake_case__ : Dict = feature_extractor(speech_inputs[0], return_tensors='np' ).input_values snake_case__ : Any = feature_extractor(np_speech_inputs[0], return_tensors='np' ).input_values self.assertTrue(np.allclose(_snake_case, _snake_case, atol=1e-3 ) ) # Test batched snake_case__ : Dict = feature_extractor(_snake_case, return_tensors='np' ).input_values snake_case__ : Dict = feature_extractor(_snake_case, return_tensors='np' ).input_values for enc_seq_a, enc_seq_a in zip(_snake_case, _snake_case ): self.assertTrue(np.allclose(_snake_case, _snake_case, atol=1e-3 ) ) # Test 2-D numpy arrays are batched. snake_case__ : Optional[Any] = [floats_list((1, x) )[0] for x in (8_0_0, 8_0_0, 8_0_0)] snake_case__ : int = np.asarray(_snake_case ) snake_case__ : Union[str, Any] = feature_extractor(_snake_case, return_tensors='np' ).input_values snake_case__ : Union[str, Any] = feature_extractor(_snake_case, return_tensors='np' ).input_values for enc_seq_a, enc_seq_a in zip(_snake_case, _snake_case ): self.assertTrue(np.allclose(_snake_case, _snake_case, atol=1e-3 ) ) def lowercase_ ( self : Union[str, Any] ) ->str: snake_case__ : int = self.feat_extract_tester.prepare_inputs_for_target() snake_case__ : List[str] = self.feature_extraction_class(**self.feat_extract_dict ) snake_case__ : Optional[Any] = feat_extract.model_input_names[0] snake_case__ : Tuple = BatchFeature({input_name: speech_inputs} ) self.assertTrue(all(len(_snake_case ) == len(_snake_case ) for x, y in zip(_snake_case, processed_features[input_name] ) ) ) snake_case__ : int = self.feat_extract_tester.prepare_inputs_for_target(equal_length=_snake_case ) snake_case__ : Union[str, Any] = BatchFeature({input_name: speech_inputs}, tensor_type='np' ) snake_case__ : Dict = processed_features[input_name] if len(batch_features_input.shape ) < 3: snake_case__ : List[str] = batch_features_input[:, :, None] self.assertTrue( batch_features_input.shape == (self.feat_extract_tester.batch_size, len(speech_inputs[0] ), self.feat_extract_tester.num_mel_bins) ) @require_torch def lowercase_ ( self : List[str] ) ->Any: snake_case__ : int = self.feat_extract_tester.prepare_inputs_for_target(equal_length=_snake_case ) snake_case__ : Optional[Any] = self.feature_extraction_class(**self.feat_extract_dict ) snake_case__ : Tuple = feat_extract.model_input_names[0] snake_case__ : List[Any] = BatchFeature({input_name: speech_inputs}, tensor_type='pt' ) snake_case__ : Tuple = processed_features[input_name] if len(batch_features_input.shape ) < 3: snake_case__ : Any = batch_features_input[:, :, None] self.assertTrue( batch_features_input.shape == (self.feat_extract_tester.batch_size, len(speech_inputs[0] ), self.feat_extract_tester.num_mel_bins) ) @require_torch def lowercase_ ( self : Optional[int] ) ->Tuple: snake_case__ : Dict = self.feature_extraction_class(**self.feat_extract_dict ) snake_case__ : Union[str, Any] = self.feat_extract_tester.prepare_inputs_for_target() snake_case__ : Optional[Any] = feat_extract.model_input_names[0] snake_case__ : List[str] = BatchFeature({input_name: speech_inputs} ) snake_case__ : int = feat_extract.num_mel_bins # hack! snake_case__ : Tuple = feat_extract.pad(_snake_case, padding='longest', return_tensors='np' )[input_name] snake_case__ : Union[str, Any] = feat_extract.pad(_snake_case, padding='longest', return_tensors='pt' )[input_name] self.assertTrue(abs(input_np.astype(np.floataa ).sum() - input_pt.numpy().astype(np.floataa ).sum() ) < 1e-2 ) def lowercase_ ( self : int ) ->Any: snake_case__ : Any = self.feat_extract_dict snake_case__ : List[Any] = True snake_case__ : Union[str, Any] = self.feature_extraction_class(**_snake_case ) snake_case__ : Any = self.feat_extract_tester.prepare_inputs_for_target() snake_case__ : List[Any] = [len(_snake_case ) for x in speech_inputs] snake_case__ : Union[str, Any] = feat_extract.model_input_names[0] snake_case__ : Optional[int] = BatchFeature({input_name: speech_inputs} ) snake_case__ : List[str] = feat_extract.num_mel_bins # hack! snake_case__ : str = feat_extract.pad(_snake_case, padding='longest', return_tensors='np' ) self.assertIn('attention_mask', _snake_case ) self.assertListEqual(list(processed.attention_mask.shape ), list(processed[input_name].shape[:2] ) ) self.assertListEqual(processed.attention_mask.sum(-1 ).tolist(), _snake_case ) def lowercase_ ( self : Optional[int] ) ->str: snake_case__ : int = self.feat_extract_dict snake_case__ : List[str] = True snake_case__ : Tuple = self.feature_extraction_class(**_snake_case ) snake_case__ : List[str] = self.feat_extract_tester.prepare_inputs_for_target() snake_case__ : str = [len(_snake_case ) for x in speech_inputs] snake_case__ : Optional[Any] = feat_extract.model_input_names[0] snake_case__ : Optional[int] = BatchFeature({input_name: speech_inputs} ) snake_case__ : Optional[Any] = min(_snake_case ) snake_case__ : Union[str, Any] = feat_extract.num_mel_bins # hack! snake_case__ : Tuple = feat_extract.pad( _snake_case, padding='max_length', max_length=_snake_case, truncation=_snake_case, return_tensors='np' ) self.assertIn('attention_mask', _snake_case ) self.assertListEqual( list(processed_pad.attention_mask.shape ), [processed_pad[input_name].shape[0], max_length] ) self.assertListEqual( processed_pad.attention_mask[:, :max_length].sum(-1 ).tolist(), [max_length for x in speech_inputs] ) def lowercase_ ( self : List[Any], _snake_case : Optional[int] ) ->Optional[Any]: from datasets import load_dataset snake_case__ : str = load_dataset('hf-internal-testing/librispeech_asr_dummy', 'clean', split='validation' ) # automatic decoding with librispeech snake_case__ : Dict = ds.sort('id' ).select(range(_snake_case ) )[:num_samples]['audio'] return [x["array"] for x in speech_samples] def lowercase_ ( self : str ) ->str: # fmt: off snake_case__ : List[Any] = torch.tensor( [2.3804e-03, 2.0752e-03, 1.9836e-03, 2.1057e-03, 1.6174e-03, 3.0518e-04, 9.1553e-05, 3.3569e-04, 9.7656e-04, 1.8311e-03, 2.0142e-03, 2.1057e-03, 1.7395e-03, 4.5776e-04, -3.9673e-04, 4.5776e-04, 1.0071e-03, 9.1553e-05, 4.8828e-04, 1.1597e-03, 7.3242e-04, 9.4604e-04, 1.8005e-03, 1.8311e-03, 8.8501e-04, 4.2725e-04, 4.8828e-04, 7.3242e-04, 1.0986e-03, 2.1057e-03] ) # fmt: on snake_case__ : Union[str, Any] = self._load_datasamples(1 ) snake_case__ : Optional[int] = SpeechTaFeatureExtractor() snake_case__ : List[Any] = feature_extractor(_snake_case, return_tensors='pt' ).input_values self.assertEquals(input_values.shape, (1, 9_3_6_8_0) ) self.assertTrue(torch.allclose(input_values[0, :3_0], _snake_case, atol=1e-6 ) ) def lowercase_ ( self : Any ) ->str: # fmt: off snake_case__ : Optional[Any] = torch.tensor( [-2.6_8_7_0, -3.0_1_0_4, -3.1_3_5_6, -3.5_3_5_2, -3.0_0_4_4, -3.0_3_5_3, -3.4_7_1_9, -3.6_7_7_7, -3.1_5_2_0, -2.9_4_3_5, -2.6_5_5_3, -2.8_7_9_5, -2.9_9_4_4, -2.5_9_2_1, -3.0_2_7_9, -3.0_3_8_6, -3.0_8_6_4, -3.1_2_9_1, -3.2_3_5_3, -2.7_4_4_4, -2.6_8_3_1, -2.7_2_8_7, -3.1_7_6_1, -3.1_5_7_1, -3.2_7_2_6, -3.0_5_8_2, -3.1_0_0_7, -3.4_5_3_3, -3.4_6_9_5, -3.0_9_9_8] ) # fmt: on snake_case__ : List[str] = self._load_datasamples(1 ) snake_case__ : str = SpeechTaFeatureExtractor() snake_case__ : Optional[Any] = feature_extractor(audio_target=_snake_case, return_tensors='pt' ).input_values self.assertEquals(input_values.shape, (1, 3_6_6, 8_0) ) self.assertTrue(torch.allclose(input_values[0, 0, :3_0], _snake_case, atol=1e-4 ) )
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'''simple docstring''' import inspect import tempfile import unittest from huggingface_hub import hf_hub_download from transformers import is_torch_available from transformers.testing_utils import is_flaky, require_torch, slow, torch_device from ...test_configuration_common import ConfigTester from ...test_modeling_common import ModelTesterMixin, floats_tensor, ids_tensor from ...test_pipeline_mixin import PipelineTesterMixin lowerCAmelCase__ = 1e-4 if is_torch_available(): import torch from transformers import AutoformerConfig, AutoformerForPrediction, AutoformerModel from transformers.models.autoformer.modeling_autoformer import AutoformerDecoder, AutoformerEncoder @require_torch class lowercase_ : """simple docstring""" def __init__( self : Any ,lowercase__ : Optional[Any] ,lowercase__ : List[str]=1_6 ,lowercase__ : List[Any]=1_3 ,lowercase__ : str=7 ,lowercase__ : int=1_4 ,lowercase__ : Dict=1_0 ,lowercase__ : Any=1_9 ,lowercase__ : Optional[Any]=5 ,lowercase__ : Tuple=4 ,lowercase__ : int=True ,lowercase__ : Any=1_6 ,lowercase__ : Tuple=2 ,lowercase__ : str=4 ,lowercase__ : str=4 ,lowercase__ : Dict="gelu" ,lowercase__ : str=0.1 ,lowercase__ : Tuple=0.1 ,lowercase__ : List[Any]=[1, 2, 3, 4, 5] ,lowercase__ : Optional[int]=2_5 ,lowercase__ : str=5 ,): __lowercase = d_model __lowercase = parent __lowercase = batch_size __lowercase = prediction_length __lowercase = context_length __lowercase = cardinality __lowercase = num_time_features __lowercase = lags_sequence __lowercase = embedding_dimension __lowercase = is_training __lowercase = hidden_size __lowercase = num_hidden_layers __lowercase = num_attention_heads __lowercase = intermediate_size __lowercase = hidden_act __lowercase = hidden_dropout_prob __lowercase = attention_probs_dropout_prob __lowercase = context_length __lowercase = prediction_length + label_length __lowercase = label_length __lowercase = moving_average __lowercase = autocorrelation_factor def SCREAMING_SNAKE_CASE ( self : Tuple ): return AutoformerConfig( d_model=self.d_model ,encoder_layers=self.num_hidden_layers ,decoder_layers=self.num_hidden_layers ,encoder_attention_heads=self.num_attention_heads ,decoder_attention_heads=self.num_attention_heads ,encoder_ffn_dim=self.intermediate_size ,decoder_ffn_dim=self.intermediate_size ,dropout=self.hidden_dropout_prob ,attention_dropout=self.attention_probs_dropout_prob ,prediction_length=self.prediction_length ,context_length=self.context_length ,label_length=self.label_length ,lags_sequence=self.lags_sequence ,num_time_features=self.num_time_features ,num_static_categorical_features=1 ,cardinality=[self.cardinality] ,embedding_dimension=[self.embedding_dimension] ,moving_average=self.moving_average ,) def SCREAMING_SNAKE_CASE ( self : Dict ,lowercase__ : List[str] ): __lowercase = config.context_length + max(config.lags_sequence ) __lowercase = ids_tensor([self.batch_size, 1] ,config.cardinality[0] ) __lowercase = floats_tensor([self.batch_size, _past_length, config.num_time_features] ) __lowercase = floats_tensor([self.batch_size, _past_length] ) __lowercase = floats_tensor([self.batch_size, _past_length] ) > 0.5 # decoder inputs __lowercase = floats_tensor([self.batch_size, config.prediction_length, config.num_time_features] ) __lowercase = floats_tensor([self.batch_size, config.prediction_length] ) __lowercase = { '''past_values''': past_values, '''static_categorical_features''': static_categorical_features, '''past_time_features''': past_time_features, '''past_observed_mask''': past_observed_mask, '''future_time_features''': future_time_features, '''future_values''': future_values, } return inputs_dict def SCREAMING_SNAKE_CASE ( self : Optional[Any] ): __lowercase = self.get_config() __lowercase = self.prepare_autoformer_inputs_dict(lowercase__ ) return config, inputs_dict def SCREAMING_SNAKE_CASE ( self : Union[str, Any] ): __lowercase , __lowercase = self.prepare_config_and_inputs() return config, inputs_dict def SCREAMING_SNAKE_CASE ( self : Any ,lowercase__ : int ,lowercase__ : Any ): __lowercase = AutoformerModel(config=lowercase__ ).to(lowercase__ ).eval() __lowercase = model(**lowercase__ ) __lowercase = outputs.encoder_last_hidden_state __lowercase = outputs.last_hidden_state with tempfile.TemporaryDirectory() as tmpdirname: __lowercase = model.get_encoder() encoder.save_pretrained(lowercase__ ) __lowercase = AutoformerEncoder.from_pretrained(lowercase__ ).to(lowercase__ ) __lowercase , __lowercase , __lowercase , __lowercase , __lowercase = model.create_network_inputs(**lowercase__ ) __lowercase , __lowercase = model.decomposition_layer(transformer_inputs[:, : config.context_length, ...] ) __lowercase = torch.cat( (transformer_inputs[:, : config.context_length, ...], feature[:, : config.context_length, ...]) ,dim=-1 ,) __lowercase = encoder(inputs_embeds=lowercase__ )[0] self.parent.assertTrue((encoder_last_hidden_state_a - encoder_last_hidden_state).abs().max().item() < 1e-3 ) __lowercase = ( torch.mean(transformer_inputs[:, : config.context_length, ...] ,dim=1 ) .unsqueeze(1 ) .repeat(1 ,config.prediction_length ,1 ) ) __lowercase = torch.zeros( [transformer_inputs.shape[0], config.prediction_length, transformer_inputs.shape[2]] ,device=enc_input.device ,) __lowercase = torch.cat( ( torch.cat((seasonal_input[:, -config.label_length :, ...], zeros) ,dim=1 ), feature[:, config.context_length - config.label_length :, ...], ) ,dim=-1 ,) __lowercase = torch.cat( ( torch.cat((trend_input[:, -config.label_length :, ...], mean) ,dim=1 ), feature[:, config.context_length - config.label_length :, ...], ) ,dim=-1 ,) with tempfile.TemporaryDirectory() as tmpdirname: __lowercase = model.get_decoder() decoder.save_pretrained(lowercase__ ) __lowercase = AutoformerDecoder.from_pretrained(lowercase__ ).to(lowercase__ ) __lowercase = decoder( trend=lowercase__ ,inputs_embeds=lowercase__ ,encoder_hidden_states=lowercase__ ,)[0] self.parent.assertTrue((last_hidden_state_a - last_hidden_state).abs().max().item() < 1e-3 ) @require_torch class lowercase_ (lowerCamelCase__ , lowerCamelCase__ , unittest.TestCase ): """simple docstring""" SCREAMING_SNAKE_CASE : Union[str, Any] = (AutoformerModel, AutoformerForPrediction) if is_torch_available() else () SCREAMING_SNAKE_CASE : Any = (AutoformerForPrediction,) if is_torch_available() else () SCREAMING_SNAKE_CASE : List[Any] = {'feature-extraction': AutoformerModel} if is_torch_available() else {} SCREAMING_SNAKE_CASE : Union[str, Any] = False SCREAMING_SNAKE_CASE : int = False SCREAMING_SNAKE_CASE : str = False SCREAMING_SNAKE_CASE : Optional[int] = False SCREAMING_SNAKE_CASE : Optional[Any] = False SCREAMING_SNAKE_CASE : List[Any] = False def SCREAMING_SNAKE_CASE ( self : Optional[Any] ): __lowercase = AutoformerModelTester(self ) __lowercase = ConfigTester(self ,config_class=lowercase__ ,has_text_modality=lowercase__ ) def SCREAMING_SNAKE_CASE ( self : Tuple ): self.config_tester.run_common_tests() def SCREAMING_SNAKE_CASE ( self : List[Any] ): __lowercase , __lowercase = self.model_tester.prepare_config_and_inputs() for model_class in self.all_model_classes: __lowercase = model_class(lowercase__ ) with tempfile.TemporaryDirectory() as tmpdirname: model.save_pretrained(lowercase__ ) __lowercase , __lowercase = model_class.from_pretrained(lowercase__ ,output_loading_info=lowercase__ ) self.assertEqual(info['''missing_keys'''] ,[] ) def SCREAMING_SNAKE_CASE ( self : Dict ): __lowercase = self.model_tester.prepare_config_and_inputs_for_common() self.model_tester.check_encoder_decoder_model_standalone(*lowercase__ ) @unittest.skip(reason='''Model has no tokens embeddings''' ) def SCREAMING_SNAKE_CASE ( self : List[str] ): pass def SCREAMING_SNAKE_CASE ( self : List[str] ): __lowercase = inspect.signature(getattr(lowercase__ ,'''forward''' ) ) # The main input is the name of the argument after `self` __lowercase = list(model_signature.parameters.keys() )[1] self.assertEqual(AutoformerModel.main_input_name ,lowercase__ ) def SCREAMING_SNAKE_CASE ( self : List[Any] ): __lowercase , __lowercase = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: __lowercase = model_class(lowercase__ ) __lowercase = inspect.signature(model.forward ) # signature.parameters is an OrderedDict => so arg_names order is deterministic __lowercase = [*signature.parameters.keys()] __lowercase = [ '''past_values''', '''past_time_features''', '''past_observed_mask''', '''static_categorical_features''', '''static_real_features''', '''future_values''', '''future_time_features''', ] if model.__class__.__name__ in ["AutoformerForPrediction"]: expected_arg_names.append('''future_observed_mask''' ) expected_arg_names.extend( [ '''decoder_attention_mask''', '''head_mask''', '''decoder_head_mask''', '''cross_attn_head_mask''', '''encoder_outputs''', '''past_key_values''', '''output_hidden_states''', '''output_attentions''', '''use_cache''', '''return_dict''', ] ) self.assertListEqual(arg_names[: len(lowercase__ )] ,lowercase__ ) def SCREAMING_SNAKE_CASE ( self : Optional[Any] ): __lowercase , __lowercase = self.model_tester.prepare_config_and_inputs_for_common() __lowercase = True __lowercase = getattr(self.model_tester ,'''seq_length''' ,lowercase__ ) __lowercase = getattr(self.model_tester ,'''decoder_seq_length''' ,lowercase__ ) __lowercase = getattr(self.model_tester ,'''encoder_seq_length''' ,lowercase__ ) __lowercase = getattr(self.model_tester ,'''d_model''' ,lowercase__ ) __lowercase = getattr(self.model_tester ,'''num_attention_heads''' ,lowercase__ ) __lowercase = d_model // num_attention_heads for model_class in self.all_model_classes: __lowercase = True __lowercase = False __lowercase = True __lowercase = model_class(lowercase__ ) model.to(lowercase__ ) model.eval() with torch.no_grad(): __lowercase = model(**self._prepare_for_class(lowercase__ ,lowercase__ ) ) __lowercase = outputs.encoder_attentions if config.is_encoder_decoder else outputs.attentions self.assertEqual(len(lowercase__ ) ,self.model_tester.num_hidden_layers ) # check that output_attentions also work using config del inputs_dict["output_attentions"] __lowercase = True __lowercase = model_class(lowercase__ ) model.to(lowercase__ ) model.eval() with torch.no_grad(): __lowercase = model(**self._prepare_for_class(lowercase__ ,lowercase__ ) ) __lowercase = outputs.encoder_attentions self.assertEqual(len(lowercase__ ) ,self.model_tester.num_hidden_layers ) self.assertListEqual( list(attentions[0].shape[-3:] ) ,[self.model_tester.num_attention_heads, encoder_seq_length, dim] ,) __lowercase = len(lowercase__ ) __lowercase = 7 if "last_hidden_state" in outputs: correct_outlen += 1 if "trend" in outputs: correct_outlen += 1 if "past_key_values" in outputs: correct_outlen += 1 # past_key_values have been returned if "loss" in outputs: correct_outlen += 1 if "params" in outputs: correct_outlen += 1 self.assertEqual(lowercase__ ,lowercase__ ) # decoder attentions __lowercase = outputs.decoder_attentions self.assertIsInstance(lowercase__ ,(list, tuple) ) self.assertEqual(len(lowercase__ ) ,self.model_tester.num_hidden_layers ) self.assertListEqual( list(decoder_attentions[0].shape[-3:] ) ,[self.model_tester.num_attention_heads, decoder_seq_length, dim] ,) # cross attentions __lowercase = outputs.cross_attentions self.assertIsInstance(lowercase__ ,(list, tuple) ) self.assertEqual(len(lowercase__ ) ,self.model_tester.num_hidden_layers ) self.assertListEqual( list(cross_attentions[0].shape[-3:] ) ,[self.model_tester.num_attention_heads, decoder_seq_length, dim] ,) # Check attention is always last and order is fine __lowercase = True __lowercase = True __lowercase = model_class(lowercase__ ) model.to(lowercase__ ) model.eval() with torch.no_grad(): __lowercase = model(**self._prepare_for_class(lowercase__ ,lowercase__ ) ) self.assertEqual(out_len + 2 ,len(lowercase__ ) ) __lowercase = outputs.encoder_attentions if config.is_encoder_decoder else outputs.attentions self.assertEqual(len(lowercase__ ) ,self.model_tester.num_hidden_layers ) self.assertListEqual( list(self_attentions[0].shape[-3:] ) ,[self.model_tester.num_attention_heads, encoder_seq_length, dim] ,) @is_flaky() def SCREAMING_SNAKE_CASE ( self : Union[str, Any] ): super().test_retain_grad_hidden_states_attentions() def _A ( A__="train-batch.pt" ): """simple docstring""" __lowercase = hf_hub_download(repo_id='''hf-internal-testing/tourism-monthly-batch''' , filename=A__ , repo_type='''dataset''' ) __lowercase = torch.load(A__ , map_location=A__ ) return batch @require_torch @slow class lowercase_ (unittest.TestCase ): """simple docstring""" def SCREAMING_SNAKE_CASE ( self : Any ): __lowercase = AutoformerModel.from_pretrained('''huggingface/autoformer-tourism-monthly''' ).to(lowercase__ ) __lowercase = prepare_batch() with torch.no_grad(): __lowercase = model( past_values=batch['''past_values'''] ,past_time_features=batch['''past_time_features'''] ,past_observed_mask=batch['''past_observed_mask'''] ,static_categorical_features=batch['''static_categorical_features'''] ,future_values=batch['''future_values'''] ,future_time_features=batch['''future_time_features'''] ,)[0] __lowercase = torch.Size( (6_4, model.config.prediction_length + model.config.label_length, model.config.feature_size) ) self.assertEqual(output.shape ,lowercase__ ) __lowercase = torch.tensor( [[0.3_5_9_3, -1.3_3_9_8, 0.6_3_3_0], [0.2_2_7_9, 1.5_3_9_6, -0.1_7_9_2], [0.0_4_5_0, 1.3_2_2_5, -0.2_3_3_5]] ,device=lowercase__ ) self.assertTrue(torch.allclose(output[0, :3, :3] ,lowercase__ ,atol=lowercase__ ) ) def SCREAMING_SNAKE_CASE ( self : Union[str, Any] ): __lowercase = AutoformerForPrediction.from_pretrained('''huggingface/autoformer-tourism-monthly''' ).to(lowercase__ ) __lowercase = prepare_batch('''val-batch.pt''' ) with torch.no_grad(): __lowercase = model( past_values=batch['''past_values'''] ,past_time_features=batch['''past_time_features'''] ,past_observed_mask=batch['''past_observed_mask'''] ,static_categorical_features=batch['''static_categorical_features'''] ,).encoder_last_hidden_state __lowercase = torch.Size((6_4, model.config.context_length, model.config.d_model) ) self.assertEqual(output.shape ,lowercase__ ) __lowercase = torch.tensor( [[-0.0_7_3_4, -0.9_0_3_6, 0.8_3_5_8], [4.7_1_8_6, 2.4_1_1_3, 1.9_5_8_1], [1.7_9_5_3, 2.3_5_5_8, 1.2_9_7_0]] ,device=lowercase__ ) self.assertTrue(torch.allclose(output[0, :3, :3] ,lowercase__ ,atol=lowercase__ ) ) def SCREAMING_SNAKE_CASE ( self : str ): __lowercase = AutoformerForPrediction.from_pretrained('''huggingface/autoformer-tourism-monthly''' ).to(lowercase__ ) __lowercase = prepare_batch('''val-batch.pt''' ) with torch.no_grad(): __lowercase = model.generate( static_categorical_features=batch['''static_categorical_features'''] ,past_time_features=batch['''past_time_features'''] ,past_values=batch['''past_values'''] ,future_time_features=batch['''future_time_features'''] ,past_observed_mask=batch['''past_observed_mask'''] ,) __lowercase = torch.Size((6_4, model.config.num_parallel_samples, model.config.prediction_length) ) self.assertEqual(outputs.sequences.shape ,lowercase__ ) __lowercase = torch.tensor([3_1_3_0.6_7_6_3, 4_0_5_6.5_2_9_3, 7_0_5_3.0_7_8_6] ,device=lowercase__ ) __lowercase = outputs.sequences.mean(dim=1 ) self.assertTrue(torch.allclose(mean_prediction[0, -3:] ,lowercase__ ,rtol=1e-1 ) )
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# Copyright 2023 The HuggingFace Inc. team. All rights reserved. # # Licensed under the Apache License, Version 2.0 (the "License"); # you may not use this file except in compliance with the License. # You may obtain a copy of the License at # # http://www.apache.org/licenses/LICENSE-2.0 # # Unless required by applicable law or agreed to in writing, software # distributed under the License is distributed on an "AS IS" BASIS, # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. # See the License for the specific language governing permissions and # limitations under the License. from ..models.auto import AutoModelForSeqaSeqLM, AutoTokenizer from .base import PipelineTool class snake_case__ ( lowerCAmelCase_ ): """simple docstring""" _SCREAMING_SNAKE_CASE = """philschmid/bart-large-cnn-samsum""" _SCREAMING_SNAKE_CASE = ( """This is a tool that summarizes an English text. It takes an input `text` containing the text to summarize, """ """and returns a summary of the text.""" ) _SCREAMING_SNAKE_CASE = """summarizer""" _SCREAMING_SNAKE_CASE = AutoTokenizer _SCREAMING_SNAKE_CASE = AutoModelForSeqaSeqLM _SCREAMING_SNAKE_CASE = ["""text"""] _SCREAMING_SNAKE_CASE = ["""text"""] def lowercase_ ( self : Optional[Any], _snake_case : str ) ->Any: return self.pre_processor(_snake_case, return_tensors='pt', truncation=_snake_case ) def lowercase_ ( self : int, _snake_case : List[Any] ) ->Any: return self.model.generate(**_snake_case )[0] def lowercase_ ( self : int, _snake_case : int ) ->str: return self.pre_processor.decode(_snake_case, skip_special_tokens=_snake_case, clean_up_tokenization_spaces=_snake_case )
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"""simple docstring""" from typing import TYPE_CHECKING from ...utils import ( OptionalDependencyNotAvailable, _LazyModule, is_flax_available, is_tf_available, is_tokenizers_available, is_torch_available, is_vision_available, ) a : Optional[Any] = { '''configuration_clip''': [ '''CLIP_PRETRAINED_CONFIG_ARCHIVE_MAP''', '''CLIPConfig''', '''CLIPOnnxConfig''', '''CLIPTextConfig''', '''CLIPVisionConfig''', ], '''processing_clip''': ['''CLIPProcessor'''], '''tokenization_clip''': ['''CLIPTokenizer'''], } try: if not is_tokenizers_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: a : Any = ['''CLIPTokenizerFast'''] try: if not is_vision_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: a : Any = ['''CLIPFeatureExtractor'''] a : List[Any] = ['''CLIPImageProcessor'''] try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: a : Any = [ '''CLIP_PRETRAINED_MODEL_ARCHIVE_LIST''', '''CLIPModel''', '''CLIPPreTrainedModel''', '''CLIPTextModel''', '''CLIPTextModelWithProjection''', '''CLIPVisionModel''', '''CLIPVisionModelWithProjection''', ] try: if not is_tf_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: a : Any = [ '''TF_CLIP_PRETRAINED_MODEL_ARCHIVE_LIST''', '''TFCLIPModel''', '''TFCLIPPreTrainedModel''', '''TFCLIPTextModel''', '''TFCLIPVisionModel''', ] try: if not is_flax_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: a : Tuple = [ '''FlaxCLIPModel''', '''FlaxCLIPPreTrainedModel''', '''FlaxCLIPTextModel''', '''FlaxCLIPTextPreTrainedModel''', '''FlaxCLIPVisionModel''', '''FlaxCLIPVisionPreTrainedModel''', ] if TYPE_CHECKING: from .configuration_clip import ( CLIP_PRETRAINED_CONFIG_ARCHIVE_MAP, CLIPConfig, CLIPOnnxConfig, CLIPTextConfig, CLIPVisionConfig, ) from .processing_clip import CLIPProcessor from .tokenization_clip import CLIPTokenizer try: if not is_tokenizers_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .tokenization_clip_fast import CLIPTokenizerFast try: if not is_vision_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .feature_extraction_clip import CLIPFeatureExtractor from .image_processing_clip import CLIPImageProcessor try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_clip import ( CLIP_PRETRAINED_MODEL_ARCHIVE_LIST, CLIPModel, CLIPPreTrainedModel, CLIPTextModel, CLIPTextModelWithProjection, CLIPVisionModel, CLIPVisionModelWithProjection, ) try: if not is_tf_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_tf_clip import ( TF_CLIP_PRETRAINED_MODEL_ARCHIVE_LIST, TFCLIPModel, TFCLIPPreTrainedModel, TFCLIPTextModel, TFCLIPVisionModel, ) try: if not is_flax_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_flax_clip import ( FlaxCLIPModel, FlaxCLIPPreTrainedModel, FlaxCLIPTextModel, FlaxCLIPTextPreTrainedModel, FlaxCLIPVisionModel, FlaxCLIPVisionPreTrainedModel, ) else: import sys a : Tuple = _LazyModule(__name__, globals()['''__file__'''], _import_structure, module_spec=__spec__)
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import argparse import torch from transformers import LxmertConfig, LxmertForPreTraining, load_tf_weights_in_lxmert from transformers.utils import logging logging.set_verbosity_info() def lowercase_ (A : str , A : List[Any] , A : Any ): # Initialise PyTorch model snake_case__ : List[Any] = LxmertConfig.from_json_file(A ) print(F'''Building PyTorch model from configuration: {config}''' ) snake_case__ : List[str] = LxmertForPreTraining(A ) # Load weights from tf checkpoint load_tf_weights_in_lxmert(A , A , A ) # Save pytorch-model print(F'''Save PyTorch model to {pytorch_dump_path}''' ) torch.save(model.state_dict() , A ) if __name__ == "__main__": a_ :Union[str, Any] = argparse.ArgumentParser() # Required parameters parser.add_argument( "--tf_checkpoint_path", default=None, type=str, required=True, help="Path to the TensorFlow checkpoint path." ) parser.add_argument( "--config_file", default=None, type=str, required=True, help="The config json file corresponding to the pre-trained model. \nThis specifies the model architecture.", ) parser.add_argument( "--pytorch_dump_path", default=None, type=str, required=True, help="Path to the output PyTorch model." ) a_ :Optional[int] = parser.parse_args() convert_tf_checkpoint_to_pytorch(args.tf_checkpoint_path, args.config_file, args.pytorch_dump_path)
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"""simple docstring""" def __SCREAMING_SNAKE_CASE ( ): return 1 def __SCREAMING_SNAKE_CASE ( A_ ): return 0 if x < 0 else two_pence(x - 2 ) + one_pence() def __SCREAMING_SNAKE_CASE ( A_ ): return 0 if x < 0 else five_pence(x - 5 ) + two_pence(A_ ) def __SCREAMING_SNAKE_CASE ( A_ ): return 0 if x < 0 else ten_pence(x - 10 ) + five_pence(A_ ) def __SCREAMING_SNAKE_CASE ( A_ ): return 0 if x < 0 else twenty_pence(x - 20 ) + ten_pence(A_ ) def __SCREAMING_SNAKE_CASE ( A_ ): return 0 if x < 0 else fifty_pence(x - 50 ) + twenty_pence(A_ ) def __SCREAMING_SNAKE_CASE ( A_ ): return 0 if x < 0 else one_pound(x - 1_00 ) + fifty_pence(A_ ) def __SCREAMING_SNAKE_CASE ( A_ ): return 0 if x < 0 else two_pound(x - 2_00 ) + one_pound(A_ ) def __SCREAMING_SNAKE_CASE ( A_ = 2_00 ): return two_pound(A_ ) if __name__ == "__main__": print(solution(int(input().strip())))
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import argparse import fairseq import torch from torch import nn from transformers import ( MBartaaTokenizer, MBartConfig, MBartForCausalLM, SpeechEncoderDecoderConfig, SpeechEncoderDecoderModel, WavaVecaConfig, WavaVecaFeatureExtractor, WavaVecaModel, logging, ) logging.set_verbosity_info() a_ :Tuple = logging.get_logger(__name__) a_ :List[Any] = { "post_extract_proj": "feature_projection.projection", "encoder.pos_conv.0": "encoder.pos_conv_embed.conv", "self_attn.k_proj": "encoder.layers.*.attention.k_proj", "self_attn.v_proj": "encoder.layers.*.attention.v_proj", "self_attn.q_proj": "encoder.layers.*.attention.q_proj", "self_attn.out_proj": "encoder.layers.*.attention.out_proj", "self_attn_layer_norm": "encoder.layers.*.layer_norm", "fc1": "encoder.layers.*.feed_forward.intermediate_dense", "fc2": "encoder.layers.*.feed_forward.output_dense", "final_layer_norm": "encoder.layers.*.final_layer_norm", "encoder.layer_norm": "encoder.layer_norm", "w2v_model.layer_norm": "feature_projection.layer_norm", "quantizer.weight_proj": "quantizer.weight_proj", "quantizer.vars": "quantizer.codevectors", "project_q": "project_q", "final_proj": "project_hid", "w2v_encoder.proj": "lm_head", "mask_emb": "masked_spec_embed", } a_ :Optional[int] = [ "lm_head", "quantizer.weight_proj", "quantizer.codevectors", "project_q", "project_hid", ] def lowercase_ (A : Union[str, Any] , A : str , A : Dict , A : Optional[Any] , A : Optional[Any] ): for attribute in key.split('.' ): snake_case__ : Any = getattr(A , A ) if weight_type is not None: snake_case__ : Optional[Any] = getattr(A , A ).shape else: snake_case__ : Optional[int] = hf_pointer.shape assert hf_shape == value.shape, ( F'''Shape of hf {key + "." + weight_type if weight_type is not None else ""} is {hf_shape}, but should be''' F''' {value.shape} for {full_name}''' ) if weight_type == "weight": snake_case__ : Tuple = value elif weight_type == "weight_g": snake_case__ : Tuple = value elif weight_type == "weight_v": snake_case__ : List[Any] = value elif weight_type == "bias": snake_case__ : List[Any] = value else: snake_case__ : Optional[Any] = value logger.info(F'''{key + "." + weight_type if weight_type is not None else ""} was initialized from {full_name}.''' ) def lowercase_ (A : str , A : Any ): snake_case__ : Union[str, Any] = [] snake_case__ : Union[str, Any] = fairseq_model.state_dict() snake_case__ : Union[str, Any] = hf_model.feature_extractor snake_case__ : Any = hf_model.adapter for name, value in fairseq_dict.items(): snake_case__ : Any = False if "conv_layers" in name: load_conv_layer( A , A , A , A , hf_model.config.feat_extract_norm == 'group' , ) snake_case__ : List[Any] = True elif any(x in name for x in ['adaptor', 'w2v_encoder.proj.', 'w2v_proj_ln.'] ): load_adapter(A , A , A , A ) snake_case__ : Optional[Any] = True else: for key, mapped_key in MAPPING.items(): if key in name or key.split('w2v_model.' )[-1] == name.split('.' )[0]: snake_case__ : Tuple = True if "*" in mapped_key: snake_case__ : List[Any] = name.split(A )[0].split('.' )[-2] snake_case__ : Optional[int] = mapped_key.replace('*' , A ) if "weight_g" in name: snake_case__ : Optional[int] = 'weight_g' elif "weight_v" in name: snake_case__ : Optional[Any] = 'weight_v' elif "bias" in name: snake_case__ : Union[str, Any] = 'bias' elif "weight" in name: snake_case__ : Optional[int] = 'weight' else: snake_case__ : Tuple = None set_recursively(A , A , A , A , A ) continue if not is_used: unused_weights.append(A ) logger.warning(F'''Unused weights: {unused_weights}''' ) def lowercase_ (A : Union[str, Any] , A : Any , A : str , A : str , A : int ): snake_case__ : str = full_name.split('conv_layers.' )[-1] snake_case__ : Optional[int] = name.split('.' ) snake_case__ : Tuple = int(items[0] ) snake_case__ : Any = int(items[1] ) if type_id == 0: if "bias" in name: assert value.shape == feature_extractor.conv_layers[layer_id].conv.bias.data.shape, ( F'''{full_name} has size {value.shape}, but''' F''' {feature_extractor.conv_layers[layer_id].conv.bias.data.shape} was found.''' ) snake_case__ : Union[str, Any] = value logger.info(F'''Feat extract conv layer {layer_id} was initialized from {full_name}.''' ) elif "weight" in name: assert value.shape == feature_extractor.conv_layers[layer_id].conv.weight.data.shape, ( F'''{full_name} has size {value.shape}, but''' F''' {feature_extractor.conv_layers[layer_id].conv.weight.data.shape} was found.''' ) snake_case__ : Union[str, Any] = value logger.info(F'''Feat extract conv layer {layer_id} was initialized from {full_name}.''' ) elif (type_id == 2 and not use_group_norm) or (type_id == 2 and layer_id == 0 and use_group_norm): if "bias" in name: assert value.shape == feature_extractor.conv_layers[layer_id].layer_norm.bias.data.shape, ( F'''{full_name} has size {value.shape}, but {feature_extractor[layer_id].layer_norm.bias.data.shape} was''' " found." ) snake_case__ : Optional[int] = value logger.info(F'''Feat extract layer norm weight of layer {layer_id} was initialized from {full_name}.''' ) elif "weight" in name: assert value.shape == feature_extractor.conv_layers[layer_id].layer_norm.weight.data.shape, ( F'''{full_name} has size {value.shape}, but''' F''' {feature_extractor[layer_id].layer_norm.weight.data.shape} was found.''' ) snake_case__ : Optional[Any] = value logger.info(F'''Feat extract layer norm weight of layer {layer_id} was initialized from {full_name}.''' ) else: unused_weights.append(A ) def lowercase_ (A : Optional[Any] , A : Any , A : Tuple , A : Any ): snake_case__ : List[str] = full_name.split('adaptor.' )[-1] snake_case__ : Tuple = name.split('.' ) if items[1].isdigit(): snake_case__ : Optional[int] = int(items[1] ) else: snake_case__ : Any = None if "adaptor" not in full_name: if "proj_ln" in full_name: # has to be layer norm if "bias" in name: assert ( value.shape == adapter.proj_layer_norm.bias.data.shape ), F'''{full_name} has size {value.shape}, but {adapter.proj_layer_norm.bias.data.shape} was found.''' snake_case__ : List[Any] = value logger.info(F'''Adapter proj layer norm bias was initialized from {full_name}.''' ) if "weight" in name: assert ( value.shape == adapter.proj_layer_norm.weight.data.shape ), F'''{full_name} has size {value.shape}, but {adapter.proj_layer_norm.weight.data.shape} was found.''' snake_case__ : int = value else: # has to be projection layer if "bias" in name: assert ( value.shape == adapter.proj.bias.data.shape ), F'''{full_name} has size {value.shape}, but {adapter.proj.bias.data.shape} was found.''' snake_case__ : str = value logger.info(F'''Adapter proj layer bias was initialized from {full_name}.''' ) if "weight" in name: assert ( value.shape == adapter.proj.weight.data.shape ), F'''{full_name} has size {value.shape}, but {adapter.proj.weight.data.shape} was found.''' snake_case__ : Dict = value logger.info(F'''Adapter proj layer weight was initialized from {full_name}.''' ) elif isinstance(A , A ): if "bias" in name: assert ( value.shape == adapter.layers[layer_id].conv.bias.data.shape ), F'''{full_name} has size {value.shape}, but {adapter.layers[layer_id].conv.bias.data.shape} was found.''' snake_case__ : List[str] = value logger.info(F'''Adapter layer {layer_id} bias was initialized from {full_name}.''' ) elif "weight" in name: assert ( value.shape == adapter.layers[layer_id].conv.weight.data.shape ), F'''{full_name} has size {value.shape}, but {adapter.layers[layer_id].conv.weight.data.shape} was found.''' snake_case__ : List[str] = value logger.info(F'''Adapter layer {layer_id} bias was initialized from {full_name}.''' ) else: unused_weights.append(A ) def lowercase_ (A : int ): snake_case__ , snake_case__ : Union[str, Any] = emb.weight.shape snake_case__ : int = nn.Linear(A , A , bias=A ) snake_case__ : Optional[Any] = emb.weight.data return lin_layer @torch.no_grad() def lowercase_ (A : Tuple , A : Tuple , A : Any , A : Optional[Any] , A : int , A : Optional[Any] , A : Union[str, Any] , A : Union[str, Any] , A : Optional[Any] , A : List[Any] , A : Union[str, Any] , ): snake_case__ : Optional[Any] = WavaVecaConfig.from_pretrained( A , add_adapter=A , adapter_stride=A , adapter_kernel_size=A , use_auth_token=A , output_hidden_size=A , ) snake_case__ : Dict = MBartConfig.from_pretrained(A ) # load model snake_case__ , snake_case__ , snake_case__ : Any = fairseq.checkpoint_utils.load_model_ensemble_and_task( [checkpoint_path] , arg_overrides={ 'config_yaml': config_yaml_path, 'data': '/'.join(dict_path.split('/' )[:-1] ), 'w2v_path': checkpoint_path, 'load_pretrained_decoder_from': None, } , ) snake_case__ : List[Any] = model[0].eval() # load feature extractor snake_case__ : str = WavaVecaFeatureExtractor.from_pretrained(A , use_auth_token=A ) # set weights for wav2vec2 encoder snake_case__ : List[str] = WavaVecaModel(A ) recursively_load_weights_wavaveca(model.encoder , A ) # load decoder weights snake_case__ : Any = MBartForCausalLM(A ) snake_case__ , snake_case__ : int = hf_decoder.model.decoder.load_state_dict(model.decoder.state_dict() , strict=A ) logger.warning(F'''The following keys are missing when loading the decoder weights: {missing_keys}''' ) logger.warning(F'''The following keys are unexpected when loading the decoder weights: {unexpected_keys}''' ) snake_case__ : Union[str, Any] = SpeechEncoderDecoderModel(encoder=A , decoder=A ) snake_case__ : str = False snake_case__ : int = MBartaaTokenizer(A ) tokenizer.save_pretrained(A ) snake_case__ : Any = hf_wavavec.config.to_dict() snake_case__ : Tuple = tokenizer.pad_token_id snake_case__ : Union[str, Any] = tokenizer.bos_token_id snake_case__ : Dict = tokenizer.eos_token_id snake_case__ : Optional[int] = 'mbart50' snake_case__ : Union[str, Any] = 'wav2vec2' snake_case__ : List[str] = tokenizer.eos_token_id snake_case__ : Union[str, Any] = 2_5_0_0_0_4 snake_case__ : int = tokenizer.eos_token_id snake_case__ : Union[str, Any] = SpeechEncoderDecoderConfig.from_dict(A ) hf_wavavec.save_pretrained(A ) feature_extractor.save_pretrained(A ) if __name__ == "__main__": a_ :str = argparse.ArgumentParser() parser.add_argument("--pytorch_dump_folder_path", default=None, type=str, help="Path to the output PyTorch model.") parser.add_argument("--checkpoint_path", default=None, type=str, help="Path to fairseq checkpoint") parser.add_argument("--dict_path", default=None, type=str, help="Path to dict of fine-tuned model") parser.add_argument("--config_yaml_path", default=None, type=str, help="Path to yaml file of fine-tuned model") parser.add_argument( "--encoder_config_path", default="facebook/wav2vec2-xls-r-1b", type=str, help="Path to hf encoder wav2vec2 checkpoint config", ) parser.add_argument( "--decoder_config_path", default="facebook/mbart-large-50-one-to-many-mmt", type=str, help="Path to hf decoder checkpoint config", ) parser.add_argument("--add_adapter", default=True, type=bool, help="whethere to add model adapter layers") parser.add_argument("--adapter_stride", default=2, type=int, help="stride of adapter layers") parser.add_argument("--adapter_kernel_size", default=3, type=int, help="kernel size of adapter layers") parser.add_argument("--encoder_output_dim", default=1_024, type=int, help="encoder output dim") parser.add_argument("--start_token_id", default=250_004, type=int, help="`decoder_start_token_id` of model config") a_ :Union[str, Any] = parser.parse_args() convert_wavaveca_checkpoint( args.checkpoint_path, args.pytorch_dump_folder_path, args.dict_path, args.config_yaml_path, encoder_config_path=args.encoder_config_path, decoder_config_path=args.decoder_config_path, add_adapter=args.add_adapter, adapter_kernel_size=args.adapter_kernel_size, adapter_stride=args.adapter_stride, decoder_start_token_id=args.start_token_id, encoder_output_dim=args.encoder_output_dim, )
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import datasets import faiss import numpy as np import streamlit as st import torch from elasticsearch import Elasticsearch from elia_utils import ( embed_questions_for_retrieval, make_qa_sas_model, qa_sas_generate, query_es_index, query_qa_dense_index, ) import transformers from transformers import AutoModel, AutoModelForSeqaSeqLM, AutoTokenizer __lowerCAmelCase : Any = 'bart' __lowerCAmelCase : List[str] = True @st.cache(allow_output_mutation=A ) def __magic_name__ ( ): '''simple docstring''' if LOAD_DENSE_INDEX: a = AutoTokenizer.from_pretrained("yjernite/retribert-base-uncased" ) a = AutoModel.from_pretrained("yjernite/retribert-base-uncased" ).to("cuda:0" ) a = qar_model.eval() else: a , a = (None, None) if MODEL_TYPE == "bart": a = AutoTokenizer.from_pretrained("yjernite/bart_eli5" ) a = AutoModelForSeqaSeqLM.from_pretrained("yjernite/bart_eli5" ).to("cuda:0" ) a = torch.load("seq2seq_models/eli5_bart_model_blm_2.pth" ) sas_model.load_state_dict(save_dict["model"] ) a = sas_model.eval() else: a , a = make_qa_sas_model( model_name="t5-small", from_file="seq2seq_models/eli5_t5_model_1024_4.pth", device="cuda:0" ) return (qar_tokenizer, qar_model, sas_tokenizer, sas_model) @st.cache(allow_output_mutation=A ) def __magic_name__ ( ): '''simple docstring''' if LOAD_DENSE_INDEX: a = faiss.StandardGpuResources() a = datasets.load_dataset(path="wiki_snippets", name="wiki40b_en_100_0" )["train"] a = np.memmap( "wiki40b_passages_reps_32_l-8_h-768_b-512-512.dat", dtype="float32", mode="r", shape=(wikiaab_passages.num_rows, 128), ) a = faiss.IndexFlatIP(128 ) a = faiss.index_cpu_to_gpu(A, 1, A ) wikiaab_gpu_index_flat.add(A ) # TODO fix for larger GPU else: a , a = (None, None) a = Elasticsearch([{"host": "localhost", "port": "9200"}] ) return (wikiaab_passages, wikiaab_gpu_index_flat, es_client) @st.cache(allow_output_mutation=A ) def __magic_name__ ( ): '''simple docstring''' a = datasets.load_dataset("eli5", name="LFQA_reddit" ) a = elia["train_eli5"] a = np.memmap( "eli5_questions_reps.dat", dtype="float32", mode="r", shape=(elia_train.num_rows, 128) ) a = faiss.IndexFlatIP(128 ) eli5_train_q_index.add(A ) return (elia_train, eli5_train_q_index) __lowerCAmelCase , __lowerCAmelCase , __lowerCAmelCase : int = load_indexes() __lowerCAmelCase , __lowerCAmelCase , __lowerCAmelCase , __lowerCAmelCase : Any = load_models() __lowerCAmelCase , __lowerCAmelCase : List[Any] = load_train_data() def __magic_name__ ( A : Optional[int], A : Any=10 ): '''simple docstring''' a = embed_questions_for_retrieval([question], A, A ) a , a = eli5_train_q_index.search(A, A ) a = [elia_train[int(A )] for i in I[0]] return nn_examples def __magic_name__ ( A : Tuple, A : Optional[Any]="wiki40b", A : Union[str, Any]="dense", A : Dict=10 ): '''simple docstring''' if source == "none": a , a = (" <P> ".join(["" for _ in range(11 )] ).strip(), []) else: if method == "dense": a , a = query_qa_dense_index( A, A, A, A, A, A ) else: a , a = query_es_index( A, A, index_name="english_wiki40b_snippets_100w", n_results=A, ) a = [ (res["article_title"], res["section_title"].strip(), res["score"], res["passage_text"]) for res in hit_lst ] a = "question: {} context: {}".format(A, A ) return question_doc, support_list @st.cache( hash_funcs={ torch.Tensor: (lambda A : None), transformers.models.bart.tokenization_bart.BartTokenizer: (lambda A : None), } ) def __magic_name__ ( A : Optional[Any], A : int, A : str, A : Any=64, A : List[str]=256, A : Union[str, Any]=False, A : Optional[Any]=2, A : Tuple=0.95, A : List[str]=0.8 ): '''simple docstring''' with torch.no_grad(): a = qa_sas_generate( A, A, A, num_answers=1, num_beams=A, min_len=A, max_len=A, do_sample=A, temp=A, top_p=A, top_k=A, max_input_length=1024, device="cuda:0", )[0] return (answer, support_list) st.title('Long Form Question Answering with ELI5') # Start sidebar __lowerCAmelCase : Tuple = '<img src=\'https://huggingface.co/front/assets/huggingface_logo.svg\'>' __lowerCAmelCase : Optional[Any] = '\n<html>\n <head>\n <style>\n .img-container {\n padding-left: 90px;\n padding-right: 90px;\n padding-top: 50px;\n padding-bottom: 50px;\n background-color: #f0f3f9;\n }\n </style>\n </head>\n <body>\n <span class="img-container"> <!-- Inline parent element -->\n %s\n </span>\n </body>\n</html>\n' % ( header_html, ) st.sidebar.markdown( header_full, unsafe_allow_html=True, ) # Long Form QA with ELI5 and Wikipedia __lowerCAmelCase : List[str] = '\nThis demo presents a model trained to [provide long-form answers to open-domain questions](https://yjernite.github.io/lfqa.html).\nFirst, a document retriever fetches a set of relevant Wikipedia passages given the question from the [Wiki40b](https://research.google/pubs/pub49029/) dataset,\na pre-processed fixed snapshot of Wikipedia.\n' st.sidebar.markdown(description, unsafe_allow_html=True) __lowerCAmelCase : Any = [ 'Answer the question', 'View the retrieved document only', 'View the most similar ELI5 question and answer', 'Show me everything, please!', ] __lowerCAmelCase : Optional[int] = st.sidebar.checkbox('Demo options') if demo_options: __lowerCAmelCase : List[Any] = st.sidebar.selectbox( '', action_list, index=3, ) __lowerCAmelCase : Optional[Any] = action_list.index(action_st) __lowerCAmelCase : Optional[int] = st.sidebar.selectbox( '', ['Show full text of passages', 'Show passage section titles'], index=0, ) __lowerCAmelCase : Optional[int] = show_type == 'Show full text of passages' else: __lowerCAmelCase : Union[str, Any] = 3 __lowerCAmelCase : List[Any] = True __lowerCAmelCase : List[str] = st.sidebar.checkbox('Retrieval options') if retrieval_options: __lowerCAmelCase : Tuple = '\n ### Information retriever options\n\n The **sparse** retriever uses ElasticSearch, while the **dense** retriever uses max-inner-product search between a question and passage embedding\n trained using the [ELI5](https://arxiv.org/abs/1907.09190) questions-answer pairs.\n The answer is then generated by sequence to sequence model which takes the question and retrieved document as input.\n ' st.sidebar.markdown(retriever_info) __lowerCAmelCase : List[str] = st.sidebar.selectbox('Which Wikipedia format should the model use?', ['wiki40b', 'none']) __lowerCAmelCase : Optional[Any] = st.sidebar.selectbox('Which Wikipedia indexer should the model use?', ['dense', 'sparse', 'mixed']) else: __lowerCAmelCase : int = 'wiki40b' __lowerCAmelCase : str = 'dense' __lowerCAmelCase : List[str] = 'beam' __lowerCAmelCase : Optional[Any] = 2 __lowerCAmelCase : Optional[int] = 64 __lowerCAmelCase : List[str] = 256 __lowerCAmelCase : List[Any] = None __lowerCAmelCase : Optional[Any] = None __lowerCAmelCase : str = st.sidebar.checkbox('Generation options') if generate_options: __lowerCAmelCase : Optional[int] = '\n ### Answer generation options\n\n The sequence-to-sequence model was initialized with [BART](https://huggingface.co/facebook/bart-large)\n weights and fine-tuned on the ELI5 QA pairs and retrieved documents. You can use the model for greedy decoding with\n **beam** search, or **sample** from the decoder\'s output probabilities.\n ' st.sidebar.markdown(generate_info) __lowerCAmelCase : Optional[Any] = st.sidebar.selectbox('Would you like to use beam search or sample an answer?', ['beam', 'sampled']) __lowerCAmelCase : List[Any] = st.sidebar.slider( 'Minimum generation length', min_value=8, max_value=256, value=64, step=8, format=None, key=None ) __lowerCAmelCase : Dict = st.sidebar.slider( 'Maximum generation length', min_value=64, max_value=512, value=256, step=16, format=None, key=None ) if sampled == "beam": __lowerCAmelCase : Dict = st.sidebar.slider('Beam size', min_value=1, max_value=8, value=2, step=None, format=None, key=None) else: __lowerCAmelCase : Optional[Any] = st.sidebar.slider( 'Nucleus sampling p', min_value=0.1, max_value=1.0, value=0.9_5, step=0.0_1, format=None, key=None ) __lowerCAmelCase : Optional[int] = st.sidebar.slider( 'Temperature', min_value=0.1, max_value=1.0, value=0.7, step=0.0_1, format=None, key=None ) __lowerCAmelCase : Tuple = None # start main text __lowerCAmelCase : List[str] = [ '<MY QUESTION>', 'How do people make chocolate?', 'Why do we get a fever when we are sick?', 'How can different animals perceive different colors?', 'What is natural language processing?', 'What\'s the best way to treat a sunburn?', 'What exactly are vitamins ?', 'How does nuclear energy provide electricity?', 'What\'s the difference between viruses and bacteria?', 'Why are flutes classified as woodwinds when most of them are made out of metal ?', 'Why do people like drinking coffee even though it tastes so bad?', 'What happens when wine ages? How does it make the wine taste better?', 'If an animal is an herbivore, where does it get the protein that it needs to survive if it only eats grass?', 'How can we set a date to the beginning or end of an artistic period? Doesn\'t the change happen gradually?', 'How does New Zealand have so many large bird predators?', ] __lowerCAmelCase : List[Any] = st.selectbox( 'What would you like to ask? ---- select <MY QUESTION> to enter a new query', questions_list, index=1, ) if question_s == "<MY QUESTION>": __lowerCAmelCase : Optional[Any] = st.text_input('Enter your question here:', '') else: __lowerCAmelCase : Union[str, Any] = question_s if st.button('Show me!'): if action in [0, 1, 3]: if index_type == "mixed": __lowerCAmelCase , __lowerCAmelCase : int = make_support(question, source=wiki_source, method='dense', n_results=10) __lowerCAmelCase , __lowerCAmelCase : Union[str, Any] = make_support(question, source=wiki_source, method='sparse', n_results=10) __lowerCAmelCase : int = [] for res_d, res_s in zip(support_list_dense, support_list_sparse): if tuple(res_d) not in support_list: support_list += [tuple(res_d)] if tuple(res_s) not in support_list: support_list += [tuple(res_s)] __lowerCAmelCase : List[str] = support_list[:10] __lowerCAmelCase : List[str] = '<P> ' + ' <P> '.join([res[-1] for res in support_list]) else: __lowerCAmelCase , __lowerCAmelCase : Any = make_support(question, source=wiki_source, method=index_type, n_results=10) if action in [0, 3]: __lowerCAmelCase , __lowerCAmelCase : Any = answer_question( question_doc, sas_model, sas_tokenizer, min_len=min_len, max_len=int(max_len), sampling=(sampled == 'sampled'), n_beams=n_beams, top_p=top_p, temp=temp, ) st.markdown('### The model generated answer is:') st.write(answer) if action in [0, 1, 3] and wiki_source != "none": st.markdown('--- \n ### The model is drawing information from the following Wikipedia passages:') for i, res in enumerate(support_list): __lowerCAmelCase : Union[str, Any] = 'https://en.wikipedia.org/wiki/{}'.format(res[0].replace(' ', '_')) __lowerCAmelCase : Tuple = res[1].strip() if sec_titles == "": __lowerCAmelCase : Any = '[{}]({})'.format(res[0], wiki_url) else: __lowerCAmelCase : Tuple = sec_titles.split(' & ') __lowerCAmelCase : Any = ' & '.join( ['[{}]({}#{})'.format(sec.strip(), wiki_url, sec.strip().replace(' ', '_')) for sec in sec_list] ) st.markdown( '{0:02d} - **Article**: {1:<18} <br> _Section_: {2}'.format(i + 1, res[0], sections), unsafe_allow_html=True, ) if show_passages: st.write( '> <span style="font-family:arial; font-size:10pt;">' + res[-1] + '</span>', unsafe_allow_html=True ) if action in [2, 3]: __lowerCAmelCase : int = find_nearest_training(question) __lowerCAmelCase : List[Any] = nn_train_list[0] st.markdown( '--- \n ### The most similar question in the ELI5 training set was: \n\n {}'.format(train_exple['title']) ) __lowerCAmelCase : str = [ '{}. {}'.format(i + 1, ' \n'.join([line.strip() for line in ans.split('\n') if line.strip() != ''])) for i, (ans, sc) in enumerate(zip(train_exple['answers']['text'], train_exple['answers']['score'])) if i == 0 or sc > 2 ] st.markdown('##### Its answers were: \n\n {}'.format('\n'.join(answers_st))) __lowerCAmelCase : Dict = '\n---\n\n**Disclaimer**\n\n*The intent of this app is to provide some (hopefully entertaining) insights into the behavior of a current LFQA system.\nEvaluating biases of such a model and ensuring factual generations are still very much open research problems.\nTherefore, until some significant progress is achieved, we caution against using the generated answers for practical purposes.*\n' st.sidebar.markdown(disclaimer, unsafe_allow_html=True)
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from collections import OrderedDict from typing import TYPE_CHECKING, Any, Mapping, Optional, Union from ...configuration_utils import PretrainedConfig from ...onnx import OnnxConfig from ...utils import logging if TYPE_CHECKING: from ... import FeatureExtractionMixin, PreTrainedTokenizerBase, TensorType a_ :Tuple = logging.get_logger(__name__) a_ :Union[str, Any] = { "microsoft/deberta-v2-xlarge": "https://huggingface.co/microsoft/deberta-v2-xlarge/resolve/main/config.json", "microsoft/deberta-v2-xxlarge": "https://huggingface.co/microsoft/deberta-v2-xxlarge/resolve/main/config.json", "microsoft/deberta-v2-xlarge-mnli": ( "https://huggingface.co/microsoft/deberta-v2-xlarge-mnli/resolve/main/config.json" ), "microsoft/deberta-v2-xxlarge-mnli": ( "https://huggingface.co/microsoft/deberta-v2-xxlarge-mnli/resolve/main/config.json" ), } class snake_case__ ( lowerCAmelCase_ ): """simple docstring""" _SCREAMING_SNAKE_CASE = """deberta-v2""" def __init__( self : Union[str, Any], _snake_case : Dict=1_2_8_1_0_0, _snake_case : Any=1_5_3_6, _snake_case : Tuple=2_4, _snake_case : int=2_4, _snake_case : Optional[int]=6_1_4_4, _snake_case : Optional[int]="gelu", _snake_case : Optional[int]=0.1, _snake_case : List[str]=0.1, _snake_case : str=5_1_2, _snake_case : Optional[int]=0, _snake_case : Optional[int]=0.0_2, _snake_case : Dict=1e-7, _snake_case : int=False, _snake_case : Any=-1, _snake_case : List[str]=0, _snake_case : Tuple=True, _snake_case : Any=None, _snake_case : Union[str, Any]=0, _snake_case : Tuple="gelu", **_snake_case : Union[str, Any], ) ->Optional[int]: super().__init__(**_snake_case ) snake_case__ : Dict = hidden_size snake_case__ : Optional[int] = num_hidden_layers snake_case__ : Any = num_attention_heads snake_case__ : List[Any] = intermediate_size snake_case__ : List[Any] = hidden_act snake_case__ : Union[str, Any] = hidden_dropout_prob snake_case__ : Dict = attention_probs_dropout_prob snake_case__ : List[str] = max_position_embeddings snake_case__ : List[str] = type_vocab_size snake_case__ : Optional[Any] = initializer_range snake_case__ : Optional[int] = relative_attention snake_case__ : Tuple = max_relative_positions snake_case__ : Union[str, Any] = pad_token_id snake_case__ : Optional[int] = position_biased_input # Backwards compatibility if type(_snake_case ) == str: snake_case__ : int = [x.strip() for x in pos_att_type.lower().split('|' )] snake_case__ : List[str] = pos_att_type snake_case__ : Union[str, Any] = vocab_size snake_case__ : Optional[int] = layer_norm_eps snake_case__ : Optional[int] = kwargs.get('pooler_hidden_size', _snake_case ) snake_case__ : int = pooler_dropout snake_case__ : str = pooler_hidden_act class snake_case__ ( lowerCAmelCase_ ): """simple docstring""" @property def lowercase_ ( self : Optional[int] ) ->Mapping[str, Mapping[int, str]]: if self.task == "multiple-choice": snake_case__ : List[Any] = {0: 'batch', 1: 'choice', 2: 'sequence'} else: snake_case__ : int = {0: 'batch', 1: 'sequence'} if self._config.type_vocab_size > 0: return OrderedDict( [('input_ids', dynamic_axis), ('attention_mask', dynamic_axis), ('token_type_ids', dynamic_axis)] ) else: return OrderedDict([('input_ids', dynamic_axis), ('attention_mask', dynamic_axis)] ) @property def lowercase_ ( self : Dict ) ->int: return 1_2 def lowercase_ ( self : Tuple, _snake_case : Union["PreTrainedTokenizerBase", "FeatureExtractionMixin"], _snake_case : int = -1, _snake_case : int = -1, _snake_case : int = -1, _snake_case : bool = False, _snake_case : Optional["TensorType"] = None, _snake_case : int = 3, _snake_case : int = 4_0, _snake_case : int = 4_0, _snake_case : "PreTrainedTokenizerBase" = None, ) ->Mapping[str, Any]: snake_case__ : Union[str, Any] = super().generate_dummy_inputs(preprocessor=_snake_case, framework=_snake_case ) if self._config.type_vocab_size == 0 and "token_type_ids" in dummy_inputs: del dummy_inputs["token_type_ids"] return dummy_inputs
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"""simple docstring""" import unittest from transformers import BigBirdTokenizer, BigBirdTokenizerFast from transformers.testing_utils import get_tests_dir, require_sentencepiece, require_tokenizers, require_torch, slow from transformers.utils import cached_property from ...test_tokenization_common import TokenizerTesterMixin lowerCAmelCase__ = '''▁''' lowerCAmelCase__ = get_tests_dir('''fixtures/test_sentencepiece.model''') @require_sentencepiece @require_tokenizers class SCREAMING_SNAKE_CASE__ ( lowercase , unittest.TestCase ): """simple docstring""" a : str =BigBirdTokenizer a : Union[str, Any] =BigBirdTokenizerFast a : Tuple =True a : Any =True def lowercase__ ( self ): """simple docstring""" super().setUp() lowerCAmelCase : str = self.tokenizer_class(snake_case__ , keep_accents=snake_case__ ) tokenizer.save_pretrained(self.tmpdirname ) def lowercase__ ( self ): """simple docstring""" lowerCAmelCase : str = "<s>" lowerCAmelCase : Optional[int] = 1 self.assertEqual(self.get_tokenizer()._convert_token_to_id(snake_case__ ) , snake_case__ ) self.assertEqual(self.get_tokenizer()._convert_id_to_token(snake_case__ ) , snake_case__ ) def lowercase__ ( self ): """simple docstring""" lowerCAmelCase : Dict = list(self.get_tokenizer().get_vocab().keys() ) self.assertEqual(vocab_keys[0] , "<unk>" ) self.assertEqual(vocab_keys[1] , "<s>" ) self.assertEqual(vocab_keys[-1] , "[MASK]" ) self.assertEqual(len(snake_case__ ) , 1_004 ) def lowercase__ ( self ): """simple docstring""" self.assertEqual(self.get_tokenizer().vocab_size , 1_000 ) def lowercase__ ( self ): """simple docstring""" if not self.test_rust_tokenizer: return lowerCAmelCase : Tuple = self.get_tokenizer() lowerCAmelCase : Optional[int] = self.get_rust_tokenizer() lowerCAmelCase : Tuple = "I was born in 92000, and this is falsé." lowerCAmelCase : Optional[int] = tokenizer.tokenize(snake_case__ ) lowerCAmelCase : int = rust_tokenizer.tokenize(snake_case__ ) self.assertListEqual(snake_case__ , snake_case__ ) lowerCAmelCase : Tuple = tokenizer.encode(snake_case__ , add_special_tokens=snake_case__ ) lowerCAmelCase : int = rust_tokenizer.encode(snake_case__ , add_special_tokens=snake_case__ ) self.assertListEqual(snake_case__ , snake_case__ ) lowerCAmelCase : List[Any] = self.get_rust_tokenizer() lowerCAmelCase : Tuple = tokenizer.encode(snake_case__ ) lowerCAmelCase : List[Any] = rust_tokenizer.encode(snake_case__ ) self.assertListEqual(snake_case__ , snake_case__ ) def lowercase__ ( self ): """simple docstring""" lowerCAmelCase : Any = BigBirdTokenizer(snake_case__ , keep_accents=snake_case__ ) lowerCAmelCase : Union[str, Any] = tokenizer.tokenize("This is a test" ) self.assertListEqual(snake_case__ , ["▁This", "▁is", "▁a", "▁t", "est"] ) self.assertListEqual( tokenizer.convert_tokens_to_ids(snake_case__ ) , [285, 46, 10, 170, 382] , ) lowerCAmelCase : Any = tokenizer.tokenize("I was born in 92000, and this is falsé." ) self.assertListEqual( snake_case__ , [ SPIECE_UNDERLINE + "I", SPIECE_UNDERLINE + "was", SPIECE_UNDERLINE + "b", "or", "n", SPIECE_UNDERLINE + "in", SPIECE_UNDERLINE + "", "9", "2", "0", "0", "0", ",", SPIECE_UNDERLINE + "and", SPIECE_UNDERLINE + "this", SPIECE_UNDERLINE + "is", SPIECE_UNDERLINE + "f", "al", "s", "é", ".", ] , ) lowerCAmelCase : str = tokenizer.convert_tokens_to_ids(snake_case__ ) self.assertListEqual( snake_case__ , [8, 21, 84, 55, 24, 19, 7, 0, 602, 347, 347, 347, 3, 12, 66, 46, 72, 80, 6, 0, 4] , ) lowerCAmelCase : List[str] = tokenizer.convert_ids_to_tokens(snake_case__ ) self.assertListEqual( snake_case__ , [ SPIECE_UNDERLINE + "I", SPIECE_UNDERLINE + "was", SPIECE_UNDERLINE + "b", "or", "n", SPIECE_UNDERLINE + "in", SPIECE_UNDERLINE + "", "<unk>", "2", "0", "0", "0", ",", SPIECE_UNDERLINE + "and", SPIECE_UNDERLINE + "this", SPIECE_UNDERLINE + "is", SPIECE_UNDERLINE + "f", "al", "s", "<unk>", ".", ] , ) @cached_property def lowercase__ ( self ): """simple docstring""" return BigBirdTokenizer.from_pretrained("google/bigbird-roberta-base" ) @slow def lowercase__ ( self ): """simple docstring""" lowerCAmelCase : List[Any] = "Hello World!" lowerCAmelCase : Any = [65, 18_536, 2_260, 101, 66] self.assertListEqual(snake_case__ , self.big_tokenizer.encode(snake_case__ ) ) @slow def lowercase__ ( self ): """simple docstring""" lowerCAmelCase : Union[str, Any] = ( "This is a very long text with a lot of weird characters, such as: . , ~ ? ( ) \" [ ] ! : - . Also we will" " add words that should not exsist and be tokenized to <unk>, such as saoneuhaoesuth" ) # fmt: off lowerCAmelCase : List[str] = [65, 871, 419, 358, 946, 991, 2_521, 452, 358, 1_357, 387, 7_751, 3_536, 112, 985, 456, 126, 865, 938, 5_400, 5_734, 458, 1_368, 467, 786, 2_462, 5_246, 1_159, 633, 865, 4_519, 457, 582, 852, 2_557, 427, 916, 508, 405, 34_324, 497, 391, 408, 11_342, 1_244, 385, 100, 938, 985, 456, 574, 362, 12_597, 3_200, 3_129, 1_172, 66] # noqa: E231 # fmt: on self.assertListEqual(snake_case__ , self.big_tokenizer.encode(snake_case__ ) ) @require_torch @slow def lowercase__ ( self ): """simple docstring""" import torch from transformers import BigBirdConfig, BigBirdModel # Build sequence lowerCAmelCase : Dict = list(self.big_tokenizer.get_vocab().keys() )[:10] lowerCAmelCase : int = " ".join(snake_case__ ) lowerCAmelCase : Dict = self.big_tokenizer.encode_plus(snake_case__ , return_tensors="pt" , return_token_type_ids=snake_case__ ) lowerCAmelCase : Any = self.big_tokenizer.batch_encode_plus( [sequence + " " + sequence] , return_tensors="pt" , return_token_type_ids=snake_case__ ) lowerCAmelCase : str = BigBirdConfig(attention_type="original_full" ) lowerCAmelCase : Any = BigBirdModel(snake_case__ ) assert model.get_input_embeddings().weight.shape[0] >= self.big_tokenizer.vocab_size with torch.no_grad(): model(**snake_case__ ) model(**snake_case__ ) @slow def lowercase__ ( self ): """simple docstring""" lowerCAmelCase : List[str] = BigBirdTokenizer.from_pretrained("google/bigbird-roberta-base" ) lowerCAmelCase : Union[str, Any] = tokenizer.decode(tokenizer("Paris is the [MASK]." ).input_ids ) self.assertTrue(decoded_text == "[CLS] Paris is the[MASK].[SEP]" ) @slow def lowercase__ ( self ): """simple docstring""" lowerCAmelCase : Any = {"input_ids": [[65, 39_286, 458, 36_335, 2_001, 456, 13_073, 13_266, 455, 113, 7_746, 1_741, 11_157, 391, 13_073, 13_266, 455, 113, 3_967, 35_412, 113, 4_936, 109, 3_870, 2_377, 113, 30_084, 45_720, 458, 134, 17_496, 112, 503, 11_672, 113, 118, 112, 5_665, 13_347, 38_687, 112, 1_496, 31_389, 112, 3_268, 47_264, 134, 962, 112, 16_377, 8_035, 23_130, 430, 12_169, 15_518, 28_592, 458, 146, 41_697, 109, 391, 12_169, 15_518, 16_689, 458, 146, 41_358, 109, 452, 726, 4_034, 111, 763, 35_412, 5_082, 388, 1_903, 111, 9_051, 391, 2_870, 48_918, 1_900, 1_123, 550, 998, 112, 9_586, 15_985, 455, 391, 410, 22_955, 37_636, 114, 66], [65, 448, 17_496, 419, 3_663, 385, 763, 113, 27_533, 2_870, 3_283, 13_043, 1_639, 24_713, 523, 656, 24_013, 18_550, 2_521, 517, 27_014, 21_244, 420, 1_212, 1_465, 391, 927, 4_833, 388, 578, 11_786, 114, 66, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0], [65, 484, 2_169, 7_687, 21_932, 18_146, 726, 363, 17_032, 3_391, 114, 66, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0]], "attention_mask": [[1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1], [1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0], [1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0]]} # noqa: E501 # fmt: on self.tokenizer_integration_test_util( expected_encoding=snake_case__ , model_name="google/bigbird-roberta-base" , revision="215c99f1600e06f83acce68422f2035b2b5c3510" , )
108
import argparse import json import pickle from pathlib import Path import requests import torch from huggingface_hub import hf_hub_download from PIL import Image from transformers import MaskFormerConfig, MaskFormerForInstanceSegmentation, MaskFormerImageProcessor, SwinConfig from transformers.utils import logging logging.set_verbosity_info() a_ :str = logging.get_logger(__name__) def lowercase_ (A : str ): snake_case__ : Tuple = SwinConfig.from_pretrained( 'microsoft/swin-tiny-patch4-window7-224' , out_features=['stage1', 'stage2', 'stage3', 'stage4'] ) snake_case__ : List[Any] = MaskFormerConfig(backbone_config=A ) snake_case__ : Union[str, Any] = 'huggingface/label-files' if "ade20k-full" in model_name: # this should be ok snake_case__ : Dict = 8_4_7 snake_case__ : List[str] = 'maskformer-ade20k-full-id2label.json' elif "ade" in model_name: # this should be ok snake_case__ : Union[str, Any] = 1_5_0 snake_case__ : Any = 'ade20k-id2label.json' elif "coco-stuff" in model_name: # this should be ok snake_case__ : List[str] = 1_7_1 snake_case__ : Union[str, Any] = 'maskformer-coco-stuff-id2label.json' elif "coco" in model_name: # TODO snake_case__ : Dict = 1_3_3 snake_case__ : str = 'coco-panoptic-id2label.json' elif "cityscapes" in model_name: # this should be ok snake_case__ : List[str] = 1_9 snake_case__ : Union[str, Any] = 'cityscapes-id2label.json' elif "vistas" in model_name: # this should be ok snake_case__ : Tuple = 6_5 snake_case__ : List[str] = 'mapillary-vistas-id2label.json' snake_case__ : Dict = json.load(open(hf_hub_download(A , A , repo_type='dataset' ) , 'r' ) ) snake_case__ : List[str] = {int(A ): v for k, v in idalabel.items()} return config def lowercase_ (A : Any ): snake_case__ : Optional[int] = [] # stem # fmt: off rename_keys.append(('backbone.patch_embed.proj.weight', 'model.pixel_level_module.encoder.model.embeddings.patch_embeddings.projection.weight') ) rename_keys.append(('backbone.patch_embed.proj.bias', 'model.pixel_level_module.encoder.model.embeddings.patch_embeddings.projection.bias') ) rename_keys.append(('backbone.patch_embed.norm.weight', 'model.pixel_level_module.encoder.model.embeddings.norm.weight') ) rename_keys.append(('backbone.patch_embed.norm.bias', 'model.pixel_level_module.encoder.model.embeddings.norm.bias') ) # stages for i in range(len(config.backbone_config.depths ) ): for j in range(config.backbone_config.depths[i] ): rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.norm1.weight''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.layernorm_before.weight''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.norm1.bias''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.layernorm_before.bias''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.attn.relative_position_bias_table''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.attention.self.relative_position_bias_table''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.attn.relative_position_index''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.attention.self.relative_position_index''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.attn.proj.weight''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.attention.output.dense.weight''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.attn.proj.bias''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.attention.output.dense.bias''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.norm2.weight''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.layernorm_after.weight''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.norm2.bias''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.layernorm_after.bias''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.mlp.fc1.weight''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.intermediate.dense.weight''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.mlp.fc1.bias''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.intermediate.dense.bias''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.mlp.fc2.weight''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.output.dense.weight''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.mlp.fc2.bias''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.output.dense.bias''') ) if i < 3: rename_keys.append((F'''backbone.layers.{i}.downsample.reduction.weight''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.downsample.reduction.weight''') ) rename_keys.append((F'''backbone.layers.{i}.downsample.norm.weight''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.downsample.norm.weight''') ) rename_keys.append((F'''backbone.layers.{i}.downsample.norm.bias''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.downsample.norm.bias''') ) rename_keys.append((F'''backbone.norm{i}.weight''', F'''model.pixel_level_module.encoder.hidden_states_norms.{i}.weight''') ) rename_keys.append((F'''backbone.norm{i}.bias''', F'''model.pixel_level_module.encoder.hidden_states_norms.{i}.bias''') ) # FPN rename_keys.append(('sem_seg_head.layer_4.weight', 'model.pixel_level_module.decoder.fpn.stem.0.weight') ) rename_keys.append(('sem_seg_head.layer_4.norm.weight', 'model.pixel_level_module.decoder.fpn.stem.1.weight') ) rename_keys.append(('sem_seg_head.layer_4.norm.bias', 'model.pixel_level_module.decoder.fpn.stem.1.bias') ) for source_index, target_index in zip(range(3 , 0 , -1 ) , range(0 , 3 ) ): rename_keys.append((F'''sem_seg_head.adapter_{source_index}.weight''', F'''model.pixel_level_module.decoder.fpn.layers.{target_index}.proj.0.weight''') ) rename_keys.append((F'''sem_seg_head.adapter_{source_index}.norm.weight''', F'''model.pixel_level_module.decoder.fpn.layers.{target_index}.proj.1.weight''') ) rename_keys.append((F'''sem_seg_head.adapter_{source_index}.norm.bias''', F'''model.pixel_level_module.decoder.fpn.layers.{target_index}.proj.1.bias''') ) rename_keys.append((F'''sem_seg_head.layer_{source_index}.weight''', F'''model.pixel_level_module.decoder.fpn.layers.{target_index}.block.0.weight''') ) rename_keys.append((F'''sem_seg_head.layer_{source_index}.norm.weight''', F'''model.pixel_level_module.decoder.fpn.layers.{target_index}.block.1.weight''') ) rename_keys.append((F'''sem_seg_head.layer_{source_index}.norm.bias''', F'''model.pixel_level_module.decoder.fpn.layers.{target_index}.block.1.bias''') ) rename_keys.append(('sem_seg_head.mask_features.weight', 'model.pixel_level_module.decoder.mask_projection.weight') ) rename_keys.append(('sem_seg_head.mask_features.bias', 'model.pixel_level_module.decoder.mask_projection.bias') ) # Transformer decoder for idx in range(config.decoder_config.decoder_layers ): # self-attention out projection rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.self_attn.out_proj.weight''', F'''model.transformer_module.decoder.layers.{idx}.self_attn.out_proj.weight''') ) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.self_attn.out_proj.bias''', F'''model.transformer_module.decoder.layers.{idx}.self_attn.out_proj.bias''') ) # cross-attention out projection rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.multihead_attn.out_proj.weight''', F'''model.transformer_module.decoder.layers.{idx}.encoder_attn.out_proj.weight''') ) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.multihead_attn.out_proj.bias''', F'''model.transformer_module.decoder.layers.{idx}.encoder_attn.out_proj.bias''') ) # MLP 1 rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.linear1.weight''', F'''model.transformer_module.decoder.layers.{idx}.fc1.weight''') ) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.linear1.bias''', F'''model.transformer_module.decoder.layers.{idx}.fc1.bias''') ) # MLP 2 rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.linear2.weight''', F'''model.transformer_module.decoder.layers.{idx}.fc2.weight''') ) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.linear2.bias''', F'''model.transformer_module.decoder.layers.{idx}.fc2.bias''') ) # layernorm 1 (self-attention layernorm) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.norm1.weight''', F'''model.transformer_module.decoder.layers.{idx}.self_attn_layer_norm.weight''') ) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.norm1.bias''', F'''model.transformer_module.decoder.layers.{idx}.self_attn_layer_norm.bias''') ) # layernorm 2 (cross-attention layernorm) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.norm2.weight''', F'''model.transformer_module.decoder.layers.{idx}.encoder_attn_layer_norm.weight''') ) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.norm2.bias''', F'''model.transformer_module.decoder.layers.{idx}.encoder_attn_layer_norm.bias''') ) # layernorm 3 (final layernorm) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.norm3.weight''', F'''model.transformer_module.decoder.layers.{idx}.final_layer_norm.weight''') ) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.norm3.bias''', F'''model.transformer_module.decoder.layers.{idx}.final_layer_norm.bias''') ) rename_keys.append(('sem_seg_head.predictor.transformer.decoder.norm.weight', 'model.transformer_module.decoder.layernorm.weight') ) rename_keys.append(('sem_seg_head.predictor.transformer.decoder.norm.bias', 'model.transformer_module.decoder.layernorm.bias') ) # heads on top rename_keys.append(('sem_seg_head.predictor.query_embed.weight', 'model.transformer_module.queries_embedder.weight') ) rename_keys.append(('sem_seg_head.predictor.input_proj.weight', 'model.transformer_module.input_projection.weight') ) rename_keys.append(('sem_seg_head.predictor.input_proj.bias', 'model.transformer_module.input_projection.bias') ) rename_keys.append(('sem_seg_head.predictor.class_embed.weight', 'class_predictor.weight') ) rename_keys.append(('sem_seg_head.predictor.class_embed.bias', 'class_predictor.bias') ) for i in range(3 ): rename_keys.append((F'''sem_seg_head.predictor.mask_embed.layers.{i}.weight''', F'''mask_embedder.{i}.0.weight''') ) rename_keys.append((F'''sem_seg_head.predictor.mask_embed.layers.{i}.bias''', F'''mask_embedder.{i}.0.bias''') ) # fmt: on return rename_keys def lowercase_ (A : Tuple , A : Tuple , A : Optional[Any] ): snake_case__ : Optional[int] = dct.pop(A ) snake_case__ : Union[str, Any] = val def lowercase_ (A : Optional[Any] , A : Tuple ): snake_case__ : Optional[int] = [int(backbone_config.embed_dim * 2**i ) for i in range(len(backbone_config.depths ) )] for i in range(len(backbone_config.depths ) ): snake_case__ : Optional[int] = num_features[i] for j in range(backbone_config.depths[i] ): # fmt: off # read in weights + bias of input projection layer (in original implementation, this is a single matrix + bias) snake_case__ : int = state_dict.pop(F'''backbone.layers.{i}.blocks.{j}.attn.qkv.weight''' ) snake_case__ : Tuple = state_dict.pop(F'''backbone.layers.{i}.blocks.{j}.attn.qkv.bias''' ) # next, add query, keys and values (in that order) to the state dict snake_case__ : str = in_proj_weight[:dim, :] snake_case__ : int = in_proj_bias[: dim] snake_case__ : List[Any] = in_proj_weight[ dim : dim * 2, : ] snake_case__ : List[str] = in_proj_bias[ dim : dim * 2 ] snake_case__ : List[Any] = in_proj_weight[ -dim :, : ] snake_case__ : Dict = in_proj_bias[-dim :] # fmt: on def lowercase_ (A : List[str] , A : List[Any] ): # fmt: off snake_case__ : str = config.decoder_config.hidden_size for idx in range(config.decoder_config.decoder_layers ): # read in weights + bias of self-attention input projection layer (in the original implementation, this is a single matrix + bias) snake_case__ : List[Any] = state_dict.pop(F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.self_attn.in_proj_weight''' ) snake_case__ : int = state_dict.pop(F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.self_attn.in_proj_bias''' ) # next, add query, keys and values (in that order) to the state dict snake_case__ : Any = in_proj_weight[: hidden_size, :] snake_case__ : Tuple = in_proj_bias[:config.hidden_size] snake_case__ : List[str] = in_proj_weight[hidden_size : hidden_size * 2, :] snake_case__ : Dict = in_proj_bias[hidden_size : hidden_size * 2] snake_case__ : Any = in_proj_weight[-hidden_size :, :] snake_case__ : int = in_proj_bias[-hidden_size :] # read in weights + bias of cross-attention input projection layer (in the original implementation, this is a single matrix + bias) snake_case__ : List[Any] = state_dict.pop(F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.multihead_attn.in_proj_weight''' ) snake_case__ : List[str] = state_dict.pop(F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.multihead_attn.in_proj_bias''' ) # next, add query, keys and values (in that order) to the state dict snake_case__ : Optional[int] = in_proj_weight[: hidden_size, :] snake_case__ : Optional[Any] = in_proj_bias[:config.hidden_size] snake_case__ : int = in_proj_weight[hidden_size : hidden_size * 2, :] snake_case__ : List[str] = in_proj_bias[hidden_size : hidden_size * 2] snake_case__ : List[str] = in_proj_weight[-hidden_size :, :] snake_case__ : str = in_proj_bias[-hidden_size :] # fmt: on def lowercase_ (): snake_case__ : Any = 'http://images.cocodataset.org/val2017/000000039769.jpg' snake_case__ : int = Image.open(requests.get(A , stream=A ).raw ) return im @torch.no_grad() def lowercase_ (A : str , A : str , A : str , A : bool = False ): snake_case__ : Optional[int] = get_maskformer_config(A ) # load original state_dict with open(A , 'rb' ) as f: snake_case__ : List[Any] = pickle.load(A ) snake_case__ : Optional[int] = data['model'] # for name, param in state_dict.items(): # print(name, param.shape) # rename keys snake_case__ : List[str] = create_rename_keys(A ) for src, dest in rename_keys: rename_key(A , A , A ) read_in_swin_q_k_v(A , config.backbone_config ) read_in_decoder_q_k_v(A , A ) # update to torch tensors for key, value in state_dict.items(): snake_case__ : int = torch.from_numpy(A ) # load 🤗 model snake_case__ : str = MaskFormerForInstanceSegmentation(A ) model.eval() for name, param in model.named_parameters(): print(A , param.shape ) snake_case__ , snake_case__ : Union[str, Any] = model.load_state_dict(A , strict=A ) assert missing_keys == [ "model.pixel_level_module.encoder.model.layernorm.weight", "model.pixel_level_module.encoder.model.layernorm.bias", ] assert len(A ) == 0, F'''Unexpected keys: {unexpected_keys}''' # verify results snake_case__ : Optional[Any] = prepare_img() if "vistas" in model_name: snake_case__ : int = 6_5 elif "cityscapes" in model_name: snake_case__ : Dict = 6_5_5_3_5 else: snake_case__ : Tuple = 2_5_5 snake_case__ : Optional[int] = True if 'ade' in model_name else False snake_case__ : Dict = MaskFormerImageProcessor(ignore_index=A , reduce_labels=A ) snake_case__ : Any = image_processor(A , return_tensors='pt' ) snake_case__ : Any = model(**A ) print('Logits:' , outputs.class_queries_logits[0, :3, :3] ) if model_name == "maskformer-swin-tiny-ade": snake_case__ : Tuple = torch.tensor( [[3.6353, -4.4770, -2.6065], [0.5081, -4.2394, -3.5343], [2.1909, -5.0353, -1.9323]] ) assert torch.allclose(outputs.class_queries_logits[0, :3, :3] , A , atol=1e-4 ) print('Looks ok!' ) if pytorch_dump_folder_path is not None: print(F'''Saving model and image processor to {pytorch_dump_folder_path}''' ) Path(A ).mkdir(exist_ok=A ) model.save_pretrained(A ) image_processor.save_pretrained(A ) if push_to_hub: print('Pushing model and image processor to the hub...' ) model.push_to_hub(F'''nielsr/{model_name}''' ) image_processor.push_to_hub(F'''nielsr/{model_name}''' ) if __name__ == "__main__": a_ :Optional[int] = argparse.ArgumentParser() # Required parameters parser.add_argument( "--model_name", default="maskformer-swin-tiny-ade", type=str, help=("Name of the MaskFormer model you'd like to convert",), ) parser.add_argument( "--checkpoint_path", default="/Users/nielsrogge/Documents/MaskFormer_checkpoints/MaskFormer-Swin-tiny-ADE20k/model.pkl", type=str, help="Path to the original state dict (.pth file).", ) parser.add_argument( "--pytorch_dump_folder_path", default=None, type=str, help="Path to the output PyTorch model directory." ) parser.add_argument( "--push_to_hub", action="store_true", help="Whether or not to push the converted model to the 🤗 hub." ) a_ :Dict = parser.parse_args() convert_maskformer_checkpoint( args.model_name, args.checkpoint_path, args.pytorch_dump_folder_path, args.push_to_hub )
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"""simple docstring""" from math import pow, sqrt def _snake_case ( *UpperCamelCase : float ): UpperCAmelCase : str = len(UpperCamelCase ) > 0 and all(value > 0.0 for value in values ) return result def _snake_case ( UpperCamelCase : float , UpperCamelCase : float ): return ( round(sqrt(molar_mass_a / molar_mass_a ) , 6 ) if validate(UpperCamelCase , UpperCamelCase ) else ValueError("""Input Error: Molar mass values must greater than 0.""" ) ) def _snake_case ( UpperCamelCase : float , UpperCamelCase : float , UpperCamelCase : float ): return ( round(effusion_rate * sqrt(molar_mass_a / molar_mass_a ) , 6 ) if validate(UpperCamelCase , UpperCamelCase , UpperCamelCase ) else ValueError( """Input Error: Molar mass and effusion rate values must greater than 0.""" ) ) def _snake_case ( UpperCamelCase : float , UpperCamelCase : float , UpperCamelCase : float ): return ( round(effusion_rate / sqrt(molar_mass_a / molar_mass_a ) , 6 ) if validate(UpperCamelCase , UpperCamelCase , UpperCamelCase ) else ValueError( """Input Error: Molar mass and effusion rate values must greater than 0.""" ) ) def _snake_case ( UpperCamelCase : float , UpperCamelCase : float , UpperCamelCase : float ): return ( round(molar_mass / pow(effusion_rate_a / effusion_rate_a , 2 ) , 6 ) if validate(UpperCamelCase , UpperCamelCase , UpperCamelCase ) else ValueError( """Input Error: Molar mass and effusion rate values must greater than 0.""" ) ) def _snake_case ( UpperCamelCase : float , UpperCamelCase : float , UpperCamelCase : float ): return ( round(pow(effusion_rate_a / effusion_rate_a , 2 ) / molar_mass , 6 ) if validate(UpperCamelCase , UpperCamelCase , UpperCamelCase ) else ValueError( """Input Error: Molar mass and effusion rate values must greater than 0.""" ) )
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import unittest from transformers import is_torch_available from transformers.testing_utils import require_torch, slow, torch_device from ...generation.test_utils import GenerationTesterMixin from ...test_configuration_common import ConfigTester from ...test_modeling_common import ModelTesterMixin, ids_tensor from ...test_pipeline_mixin import PipelineTesterMixin if is_torch_available(): import torch from transformers import ( OPENAI_GPT_PRETRAINED_MODEL_ARCHIVE_LIST, OpenAIGPTConfig, OpenAIGPTDoubleHeadsModel, OpenAIGPTForSequenceClassification, OpenAIGPTLMHeadModel, OpenAIGPTModel, ) class snake_case__ : """simple docstring""" def __init__( self : List[str], _snake_case : Any, _snake_case : int=1_3, _snake_case : Optional[int]=7, _snake_case : int=True, _snake_case : Optional[Any]=True, _snake_case : Optional[Any]=True, _snake_case : Union[str, Any]=9_9, _snake_case : Optional[Any]=3_2, _snake_case : Tuple=5, _snake_case : str=4, _snake_case : Any=3_7, _snake_case : int="gelu", _snake_case : Optional[Any]=0.1, _snake_case : str=0.1, _snake_case : str=5_1_2, _snake_case : Dict=1_6, _snake_case : str=2, _snake_case : Union[str, Any]=0.0_2, _snake_case : Optional[int]=3, _snake_case : Union[str, Any]=4, _snake_case : Tuple=None, ) ->Optional[Any]: snake_case__ : Optional[int] = parent snake_case__ : List[Any] = batch_size snake_case__ : Tuple = seq_length snake_case__ : str = is_training snake_case__ : Optional[int] = use_token_type_ids snake_case__ : Any = use_labels snake_case__ : Dict = vocab_size snake_case__ : str = hidden_size snake_case__ : Union[str, Any] = num_hidden_layers snake_case__ : List[str] = num_attention_heads snake_case__ : Union[str, Any] = intermediate_size snake_case__ : List[Any] = hidden_act snake_case__ : int = hidden_dropout_prob snake_case__ : str = attention_probs_dropout_prob snake_case__ : Any = max_position_embeddings snake_case__ : Union[str, Any] = type_vocab_size snake_case__ : Optional[Any] = type_sequence_label_size snake_case__ : Optional[int] = initializer_range snake_case__ : Optional[int] = num_labels snake_case__ : str = num_choices snake_case__ : int = scope snake_case__ : List[str] = self.vocab_size - 1 def lowercase_ ( self : Union[str, Any] ) ->Tuple: snake_case__ : List[str] = ids_tensor([self.batch_size, self.seq_length], self.vocab_size ) snake_case__ : List[str] = None if self.use_token_type_ids: snake_case__ : Optional[Any] = ids_tensor([self.batch_size, self.seq_length], self.type_vocab_size ) snake_case__ : Tuple = None snake_case__ : str = None snake_case__ : List[Any] = None if self.use_labels: snake_case__ : Dict = ids_tensor([self.batch_size], self.type_sequence_label_size ) snake_case__ : int = ids_tensor([self.batch_size, self.seq_length], self.num_labels ) snake_case__ : List[str] = ids_tensor([self.batch_size], self.num_choices ) snake_case__ : Union[str, Any] = OpenAIGPTConfig( vocab_size=self.vocab_size, n_embd=self.hidden_size, n_layer=self.num_hidden_layers, n_head=self.num_attention_heads, n_positions=self.max_position_embeddings, pad_token_id=self.pad_token_id, ) snake_case__ : List[str] = ids_tensor([self.num_hidden_layers, self.num_attention_heads], 2 ) return ( config, input_ids, head_mask, token_type_ids, sequence_labels, token_labels, choice_labels, ) def lowercase_ ( self : Any, _snake_case : List[str], _snake_case : Any, _snake_case : List[Any], _snake_case : Tuple, *_snake_case : Optional[Any] ) ->Tuple: snake_case__ : Union[str, Any] = OpenAIGPTModel(config=_snake_case ) model.to(_snake_case ) model.eval() snake_case__ : Optional[Any] = model(_snake_case, token_type_ids=_snake_case, head_mask=_snake_case ) snake_case__ : Union[str, Any] = model(_snake_case, token_type_ids=_snake_case ) snake_case__ : Optional[Any] = model(_snake_case ) self.parent.assertEqual(result.last_hidden_state.shape, (self.batch_size, self.seq_length, self.hidden_size) ) def lowercase_ ( self : Optional[int], _snake_case : Optional[Any], _snake_case : Union[str, Any], _snake_case : Optional[int], _snake_case : List[Any], *_snake_case : Dict ) ->Optional[int]: snake_case__ : Optional[Any] = OpenAIGPTLMHeadModel(_snake_case ) model.to(_snake_case ) model.eval() snake_case__ : Tuple = model(_snake_case, token_type_ids=_snake_case, labels=_snake_case ) self.parent.assertEqual(result.loss.shape, () ) self.parent.assertEqual(result.logits.shape, (self.batch_size, self.seq_length, self.vocab_size) ) def lowercase_ ( self : int, _snake_case : Tuple, _snake_case : List[str], _snake_case : List[Any], _snake_case : List[Any], *_snake_case : List[Any] ) ->Optional[int]: snake_case__ : List[str] = OpenAIGPTDoubleHeadsModel(_snake_case ) model.to(_snake_case ) model.eval() snake_case__ : Optional[Any] = model(_snake_case, token_type_ids=_snake_case, labels=_snake_case ) self.parent.assertEqual(result.loss.shape, () ) self.parent.assertEqual(result.logits.shape, (self.batch_size, self.seq_length, self.vocab_size) ) def lowercase_ ( self : Optional[int], _snake_case : Tuple, _snake_case : Dict, _snake_case : List[str], _snake_case : Optional[Any], *_snake_case : Union[str, Any] ) ->str: snake_case__ : List[str] = self.num_labels snake_case__ : Dict = OpenAIGPTForSequenceClassification(_snake_case ) model.to(_snake_case ) model.eval() snake_case__ : List[str] = ids_tensor([self.batch_size], self.type_sequence_label_size ) snake_case__ : List[str] = model(_snake_case, token_type_ids=_snake_case, labels=_snake_case ) self.parent.assertEqual(result.logits.shape, (self.batch_size, self.num_labels) ) def lowercase_ ( self : Dict ) ->int: snake_case__ : List[Any] = self.prepare_config_and_inputs() ( ( snake_case__ ) , ( snake_case__ ) , ( snake_case__ ) , ( snake_case__ ) , ( snake_case__ ) , ( snake_case__ ) , ( snake_case__ ) , ) : Optional[Any] = config_and_inputs snake_case__ : str = { 'input_ids': input_ids, 'token_type_ids': token_type_ids, 'head_mask': head_mask, } return config, inputs_dict @require_torch class snake_case__ ( lowerCAmelCase_ , lowerCAmelCase_ , lowerCAmelCase_ , unittest.TestCase ): """simple docstring""" _SCREAMING_SNAKE_CASE = ( (OpenAIGPTModel, OpenAIGPTLMHeadModel, OpenAIGPTDoubleHeadsModel, OpenAIGPTForSequenceClassification) if is_torch_available() else () ) _SCREAMING_SNAKE_CASE = ( (OpenAIGPTLMHeadModel,) if is_torch_available() else () ) # TODO (PVP): Add Double HeadsModel when generate() function is changed accordingly _SCREAMING_SNAKE_CASE = ( { """feature-extraction""": OpenAIGPTModel, """text-classification""": OpenAIGPTForSequenceClassification, """text-generation""": OpenAIGPTLMHeadModel, """zero-shot""": OpenAIGPTForSequenceClassification, } if is_torch_available() else {} ) def lowercase_ ( self : Optional[int], _snake_case : Union[str, Any], _snake_case : int, _snake_case : Tuple, _snake_case : Tuple, _snake_case : List[str] ) ->Optional[Any]: if pipeline_test_casse_name == "ZeroShotClassificationPipelineTests": # Get `tokenizer does not have a padding token` error for both fast/slow tokenizers. # `OpenAIGPTConfig` was never used in pipeline tests, either because of a missing checkpoint or because a # tiny config could not be created. return True return False def lowercase_ ( self : Optional[Any], _snake_case : Union[str, Any], _snake_case : List[str], _snake_case : Any=False ) ->Tuple: snake_case__ : Optional[int] = super()._prepare_for_class(_snake_case, _snake_case, return_labels=_snake_case ) if return_labels: if model_class.__name__ == "OpenAIGPTDoubleHeadsModel": snake_case__ : Union[str, Any] = torch.zeros( (self.model_tester.batch_size, self.model_tester.num_choices, self.model_tester.seq_length), dtype=torch.long, device=_snake_case, ) snake_case__ : List[Any] = inputs_dict['labels'] snake_case__ : List[Any] = inputs_dict['labels'] snake_case__ : Any = torch.zeros( (self.model_tester.batch_size, self.model_tester.num_choices), dtype=torch.long, device=_snake_case, ) snake_case__ : Tuple = torch.zeros( self.model_tester.batch_size, dtype=torch.long, device=_snake_case ) return inputs_dict def lowercase_ ( self : Union[str, Any] ) ->List[str]: snake_case__ : List[str] = OpenAIGPTModelTester(self ) snake_case__ : Any = ConfigTester(self, config_class=_snake_case, n_embd=3_7 ) def lowercase_ ( self : Optional[int] ) ->str: self.config_tester.run_common_tests() def lowercase_ ( self : int ) ->Tuple: snake_case__ : str = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_openai_gpt_model(*_snake_case ) def lowercase_ ( self : Tuple ) ->List[str]: snake_case__ : Optional[int] = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_lm_head_model(*_snake_case ) def lowercase_ ( self : Dict ) ->int: snake_case__ : Optional[Any] = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_double_lm_head_model(*_snake_case ) def lowercase_ ( self : int ) ->str: snake_case__ : List[Any] = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_openai_gpt_for_sequence_classification(*_snake_case ) @slow def lowercase_ ( self : Optional[Any] ) ->str: for model_name in OPENAI_GPT_PRETRAINED_MODEL_ARCHIVE_LIST[:1]: snake_case__ : Optional[int] = OpenAIGPTModel.from_pretrained(_snake_case ) self.assertIsNotNone(_snake_case ) @require_torch class snake_case__ ( unittest.TestCase ): """simple docstring""" @slow def lowercase_ ( self : Tuple ) ->Optional[int]: snake_case__ : Union[str, Any] = OpenAIGPTLMHeadModel.from_pretrained('openai-gpt' ) model.to(_snake_case ) snake_case__ : Tuple = torch.tensor([[4_8_1, 4_7_3_5, 5_4_4]], dtype=torch.long, device=_snake_case ) # the president is snake_case__ : int = [ 4_8_1, 4_7_3_5, 5_4_4, 2_4_6, 9_6_3, 8_7_0, 7_6_2, 2_3_9, 2_4_4, 4_0_4_7_7, 2_4_4, 2_4_9, 7_1_9, 8_8_1, 4_8_7, 5_4_4, 2_4_0, 2_4_4, 6_0_3, 4_8_1, ] # the president is a very good man. " \n " i\'m sure he is, " said the snake_case__ : Optional[int] = model.generate(_snake_case, do_sample=_snake_case ) self.assertListEqual(output_ids[0].tolist(), _snake_case )
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from __future__ import absolute_import, division, print_function, unicode_literals from torch import nn from torch.nn import CrossEntropyLoss, MSELoss from transformers import RobertaConfig from transformers.file_utils import add_start_docstrings, add_start_docstrings_to_model_forward from transformers.models.roberta.modeling_roberta import ( ROBERTA_INPUTS_DOCSTRING, ROBERTA_START_DOCSTRING, RobertaEmbeddings, ) from .modeling_highway_bert import BertPreTrainedModel, DeeBertModel, HighwayException, entropy @add_start_docstrings( """The RoBERTa Model transformer with early exiting (DeeRoBERTa). """ , lowerCAmelCase_ , ) class __lowerCAmelCase ( lowerCAmelCase_): _lowercase : Union[str, Any] = RobertaConfig _lowercase : Tuple = """roberta""" def __init__( self , lowerCAmelCase__ ) -> List[Any]: '''simple docstring''' super().__init__(_snake_case ) a__ : Union[str, Any] =RobertaEmbeddings(_snake_case ) self.init_weights() @add_start_docstrings( """RoBERTa Model (with early exiting - DeeRoBERTa) with a classifier on top, also takes care of multi-layer training. """ , lowerCAmelCase_ , ) class __lowerCAmelCase ( lowerCAmelCase_): _lowercase : Optional[int] = RobertaConfig _lowercase : List[Any] = """roberta""" def __init__( self , lowerCAmelCase__ ) -> str: '''simple docstring''' super().__init__(_snake_case ) a__ : Dict =config.num_labels a__ : Tuple =config.num_hidden_layers a__ : Optional[int] =DeeRobertaModel(_snake_case ) a__ : Any =nn.Dropout(config.hidden_dropout_prob ) a__ : str =nn.Linear(config.hidden_size , self.config.num_labels ) @add_start_docstrings_to_model_forward(_snake_case ) def _lowercase ( self , lowerCAmelCase__=None , lowerCAmelCase__=None , lowerCAmelCase__=None , lowerCAmelCase__=None , lowerCAmelCase__=None , lowerCAmelCase__=None , lowerCAmelCase__=None , lowerCAmelCase__=-1 , lowerCAmelCase__=False , ) -> List[str]: '''simple docstring''' a__ : Optional[Any] =self.num_layers try: a__ : Union[str, Any] =self.roberta( _snake_case , attention_mask=_snake_case , token_type_ids=_snake_case , position_ids=_snake_case , head_mask=_snake_case , inputs_embeds=_snake_case , ) a__ : List[str] =outputs[1] a__ : int =self.dropout(_snake_case ) a__ : Union[str, Any] =self.classifier(_snake_case ) a__ : Tuple =(logits,) + outputs[2:] # add hidden states and attention if they are here except HighwayException as e: a__ : str =e.message a__ : Any =e.exit_layer a__ : Any =outputs[0] if not self.training: a__ : Optional[int] =entropy(_snake_case ) a__ : Dict =[] a__ : Any =[] if labels is not None: if self.num_labels == 1: # We are doing regression a__ : List[str] =MSELoss() a__ : Optional[Any] =loss_fct(logits.view(-1 ) , labels.view(-1 ) ) else: a__ : str =CrossEntropyLoss() a__ : List[Any] =loss_fct(logits.view(-1 , self.num_labels ) , labels.view(-1 ) ) # work with highway exits a__ : Optional[int] =[] for highway_exit in outputs[-1]: a__ : List[Any] =highway_exit[0] if not self.training: highway_logits_all.append(_snake_case ) highway_entropy.append(highway_exit[2] ) if self.num_labels == 1: # We are doing regression a__ : str =MSELoss() a__ : List[str] =loss_fct(highway_logits.view(-1 ) , labels.view(-1 ) ) else: a__ : int =CrossEntropyLoss() a__ : Any =loss_fct(highway_logits.view(-1 , self.num_labels ) , labels.view(-1 ) ) highway_losses.append(_snake_case ) if train_highway: a__ : Optional[Any] =(sum(highway_losses[:-1] ),) + outputs # exclude the final highway, of course else: a__ : Optional[int] =(loss,) + outputs if not self.training: a__ : Optional[int] =outputs + ((original_entropy, highway_entropy), exit_layer) if output_layer >= 0: a__ : str =( (outputs[0],) + (highway_logits_all[output_layer],) + outputs[2:] ) # use the highway of the last layer return outputs # (loss), logits, (hidden_states), (attentions), entropy
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import os import unittest from transformers.models.transfo_xl.tokenization_transfo_xl import VOCAB_FILES_NAMES, TransfoXLTokenizer from ...test_tokenization_common import TokenizerTesterMixin class snake_case__ ( lowerCAmelCase_ , unittest.TestCase ): """simple docstring""" _SCREAMING_SNAKE_CASE = TransfoXLTokenizer _SCREAMING_SNAKE_CASE = False _SCREAMING_SNAKE_CASE = False def lowercase_ ( self : Optional[int] ) ->Any: super().setUp() snake_case__ : Tuple = [ '<unk>', '[CLS]', '[SEP]', 'want', 'unwanted', 'wa', 'un', 'running', ',', 'low', 'l', ] snake_case__ : Any = os.path.join(self.tmpdirname, VOCAB_FILES_NAMES['vocab_file'] ) with open(self.vocab_file, 'w', encoding='utf-8' ) as vocab_writer: vocab_writer.write(''.join([x + '\n' for x in vocab_tokens] ) ) def lowercase_ ( self : Union[str, Any], **_snake_case : List[Any] ) ->Dict: snake_case__ : str = True return TransfoXLTokenizer.from_pretrained(self.tmpdirname, **_snake_case ) def lowercase_ ( self : Optional[Any], _snake_case : str ) ->Dict: snake_case__ : List[Any] = '<unk> UNwanted , running' snake_case__ : List[Any] = '<unk> unwanted, running' return input_text, output_text def lowercase_ ( self : List[Any] ) ->Tuple: snake_case__ : Dict = TransfoXLTokenizer(vocab_file=self.vocab_file, lower_case=_snake_case ) snake_case__ : str = tokenizer.tokenize('<unk> UNwanted , running' ) self.assertListEqual(_snake_case, ['<unk>', 'unwanted', ',', 'running'] ) self.assertListEqual(tokenizer.convert_tokens_to_ids(_snake_case ), [0, 4, 8, 7] ) def lowercase_ ( self : List[str] ) ->List[Any]: snake_case__ : str = TransfoXLTokenizer(lower_case=_snake_case ) self.assertListEqual( tokenizer.tokenize(' \tHeLLo ! how \n Are yoU ? ' ), ['hello', '!', 'how', 'are', 'you', '?'] ) def lowercase_ ( self : Optional[int] ) ->Optional[Any]: snake_case__ : Optional[int] = TransfoXLTokenizer(lower_case=_snake_case ) self.assertListEqual( tokenizer.tokenize(' \tHeLLo ! how \n Are yoU ? ' ), ['HeLLo', '!', 'how', 'Are', 'yoU', '?'] ) def lowercase_ ( self : Optional[int] ) ->Union[str, Any]: snake_case__ : List[Any] = TransfoXLTokenizer(lower_case=_snake_case ) snake_case__ : Dict = 'Hello (bracket) and side-scrolled [and] Henry\'s $5,000 with 3.34 m. What\'s up!?' snake_case__ : List[Any] = [ 'Hello', '(', 'bracket', ')', 'and', 'side', '@-@', 'scrolled', '[', 'and', ']', 'Henry', '\'s', '$', '5', '@,@', '000', 'with', '3', '@.@', '34', 'm', '.', 'What', '\'s', 'up', '!', '?', ] self.assertListEqual(tokenizer.tokenize(_snake_case ), _snake_case ) self.assertEqual(tokenizer.convert_tokens_to_string(_snake_case ), _snake_case ) def lowercase_ ( self : Dict ) ->Any: snake_case__ : Dict = self.get_tokenizer() snake_case__ : Optional[Any] = len(_snake_case ) tokenizer.add_tokens(['new1', 'new2'] ) tokenizer.move_added_token('new1', 1 ) # Check that moved token is not copied (duplicate) self.assertEqual(len(_snake_case ), original_len + 2 ) # Check that token is moved to specified id self.assertEqual(tokenizer.encode('new1' ), [1] ) self.assertEqual(tokenizer.decode([1] ), 'new1' )
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def a ( snake_case__: List[str] ): '''simple docstring''' lowercase_ = len(snake_case__ ) for i in range(length - 1 ): lowercase_ = i for k in range(i + 1 , snake_case__ ): if collection[k] < collection[least]: lowercase_ = k if least != i: lowercase_ = (collection[i], collection[least]) return collection if __name__ == "__main__": __a = input('Enter numbers separated by a comma:\n').strip() __a = [int(item) for item in user_input.split(',')] print(selection_sort(unsorted))
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from ...configuration_utils import PretrainedConfig from ...utils import logging a_ :Optional[int] = logging.get_logger(__name__) a_ :Dict = {"openai-gpt": "https://huggingface.co/openai-gpt/resolve/main/config.json"} class snake_case__ ( lowerCAmelCase_ ): """simple docstring""" _SCREAMING_SNAKE_CASE = """openai-gpt""" _SCREAMING_SNAKE_CASE = { """max_position_embeddings""": """n_positions""", """hidden_size""": """n_embd""", """num_attention_heads""": """n_head""", """num_hidden_layers""": """n_layer""", } def __init__( self : Optional[int], _snake_case : Dict=4_0_4_7_8, _snake_case : str=5_1_2, _snake_case : int=7_6_8, _snake_case : Tuple=1_2, _snake_case : Any=1_2, _snake_case : str="gelu", _snake_case : List[str]=0.1, _snake_case : Any=0.1, _snake_case : Dict=0.1, _snake_case : int=1e-5, _snake_case : Optional[Any]=0.0_2, _snake_case : List[Any]="cls_index", _snake_case : Any=True, _snake_case : Any=None, _snake_case : int=True, _snake_case : Optional[Any]=0.1, **_snake_case : List[Any], ) ->Optional[int]: snake_case__ : int = vocab_size snake_case__ : Dict = n_positions snake_case__ : str = n_embd snake_case__ : str = n_layer snake_case__ : List[Any] = n_head snake_case__ : List[Any] = afn snake_case__ : Optional[Any] = resid_pdrop snake_case__ : List[str] = embd_pdrop snake_case__ : List[Any] = attn_pdrop snake_case__ : Optional[int] = layer_norm_epsilon snake_case__ : str = initializer_range snake_case__ : List[str] = summary_type snake_case__ : Optional[int] = summary_use_proj snake_case__ : List[str] = summary_activation snake_case__ : Optional[Any] = summary_first_dropout snake_case__ : int = summary_proj_to_labels super().__init__(**_snake_case )
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"""simple docstring""" import unittest import numpy as np from transformers.testing_utils import require_torch, require_vision from transformers.utils import is_torch_available, is_vision_available from ...test_image_processing_common import ImageProcessingSavingTestMixin, prepare_image_inputs if is_torch_available(): import torch if is_vision_available(): from PIL import Image from transformers import MobileNetVaImageProcessor class __lowerCAmelCase ( unittest.TestCase ): '''simple docstring''' def __init__( self , _a , _a=7 , _a=3 , _a=18 , _a=30 , _a=400 , _a=True , _a=None , _a=True , _a=None , ): __a = size if size is not None else {'shortest_edge': 20} __a = crop_size if crop_size is not None else {'height': 18, 'width': 18} __a = parent __a = batch_size __a = num_channels __a = image_size __a = min_resolution __a = max_resolution __a = do_resize __a = size __a = do_center_crop __a = crop_size def __UpperCAmelCase ( self ): return { "do_resize": self.do_resize, "size": self.size, "do_center_crop": self.do_center_crop, "crop_size": self.crop_size, } @require_torch @require_vision class __lowerCAmelCase ( lowerCAmelCase_ , unittest.TestCase ): '''simple docstring''' __UpperCAmelCase : Optional[Any] = MobileNetVaImageProcessor if is_vision_available() else None def __UpperCAmelCase ( self ): __a = MobileNetVaImageProcessingTester(self ) @property def __UpperCAmelCase ( self ): return self.image_processor_tester.prepare_image_processor_dict() def __UpperCAmelCase ( self ): __a = self.image_processing_class(**self.image_processor_dict ) self.assertTrue(hasattr(_snake_case , '''do_resize''' ) ) self.assertTrue(hasattr(_snake_case , '''size''' ) ) self.assertTrue(hasattr(_snake_case , '''do_center_crop''' ) ) self.assertTrue(hasattr(_snake_case , '''crop_size''' ) ) def __UpperCAmelCase ( self ): __a = self.image_processing_class.from_dict(self.image_processor_dict ) self.assertEqual(image_processor.size , {'''shortest_edge''': 20} ) self.assertEqual(image_processor.crop_size , {'''height''': 18, '''width''': 18} ) __a = self.image_processing_class.from_dict(self.image_processor_dict , size=42 , crop_size=84 ) self.assertEqual(image_processor.size , {'''shortest_edge''': 42} ) self.assertEqual(image_processor.crop_size , {'''height''': 84, '''width''': 84} ) def __UpperCAmelCase ( self ): pass def __UpperCAmelCase ( self ): # Initialize image_processing __a = self.image_processing_class(**self.image_processor_dict ) # create random PIL images __a = prepare_image_inputs(self.image_processor_tester , equal_resolution=_snake_case ) for image in image_inputs: self.assertIsInstance(_snake_case , Image.Image ) # Test not batched input __a = image_processing(image_inputs[0] , return_tensors='''pt''' ).pixel_values self.assertEqual( encoded_images.shape , ( 1, self.image_processor_tester.num_channels, self.image_processor_tester.crop_size['''height'''], self.image_processor_tester.crop_size['''width'''], ) , ) # Test batched __a = image_processing(_snake_case , return_tensors='''pt''' ).pixel_values self.assertEqual( encoded_images.shape , ( self.image_processor_tester.batch_size, self.image_processor_tester.num_channels, self.image_processor_tester.crop_size['''height'''], self.image_processor_tester.crop_size['''width'''], ) , ) def __UpperCAmelCase ( self ): # Initialize image_processing __a = self.image_processing_class(**self.image_processor_dict ) # create random numpy tensors __a = prepare_image_inputs(self.image_processor_tester , equal_resolution=_snake_case , numpify=_snake_case ) for image in image_inputs: self.assertIsInstance(_snake_case , np.ndarray ) # Test not batched input __a = image_processing(image_inputs[0] , return_tensors='''pt''' ).pixel_values self.assertEqual( encoded_images.shape , ( 1, self.image_processor_tester.num_channels, self.image_processor_tester.crop_size['''height'''], self.image_processor_tester.crop_size['''width'''], ) , ) # Test batched __a = image_processing(_snake_case , return_tensors='''pt''' ).pixel_values self.assertEqual( encoded_images.shape , ( self.image_processor_tester.batch_size, self.image_processor_tester.num_channels, self.image_processor_tester.crop_size['''height'''], self.image_processor_tester.crop_size['''width'''], ) , ) def __UpperCAmelCase ( self ): # Initialize image_processing __a = self.image_processing_class(**self.image_processor_dict ) # create random PyTorch tensors __a = prepare_image_inputs(self.image_processor_tester , equal_resolution=_snake_case , torchify=_snake_case ) for image in image_inputs: self.assertIsInstance(_snake_case , torch.Tensor ) # Test not batched input __a = image_processing(image_inputs[0] , return_tensors='''pt''' ).pixel_values self.assertEqual( encoded_images.shape , ( 1, self.image_processor_tester.num_channels, self.image_processor_tester.crop_size['''height'''], self.image_processor_tester.crop_size['''width'''], ) , ) # Test batched __a = image_processing(_snake_case , return_tensors='''pt''' ).pixel_values self.assertEqual( encoded_images.shape , ( self.image_processor_tester.batch_size, self.image_processor_tester.num_channels, self.image_processor_tester.crop_size['''height'''], self.image_processor_tester.crop_size['''width'''], ) , )
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import argparse import logging import os from datetime import datetime import numpy as np import torch from torch import nn from torch.utils.data import DataLoader, RandomSampler, TensorDataset from tqdm import tqdm from transformers import GPTaLMHeadModel a_ :Optional[Any] = logging.getLogger(__name__) def lowercase_ (A : List[Any] , A : List[Any] ): # save results if os.path.exists(A ): if os.path.exists(os.path.join(A , 'config.json' ) ) and os.path.isfile( os.path.join(A , 'config.json' ) ): os.remove(os.path.join(A , 'config.json' ) ) if os.path.exists(os.path.join(A , 'pytorch_model.bin' ) ) and os.path.isfile( os.path.join(A , 'pytorch_model.bin' ) ): os.remove(os.path.join(A , 'pytorch_model.bin' ) ) else: os.makedirs(A ) model.save_pretrained(A ) def lowercase_ (A : Any , A : Optional[Any]=False ): snake_case__ : str = 2 if unlogit: snake_case__ : Dict = torch.pow(A , A ) snake_case__ : Any = p * torch.log(A ) snake_case__ : Tuple = 0 return -plogp.sum(dim=-1 ) def lowercase_ (A : List[str] ): logger.info('lv, h >\t' + '\t'.join(F'''{x + 1}''' for x in range(len(A ) ) ) ) for row in range(len(A ) ): if tensor.dtype != torch.long: logger.info(F'''layer {row + 1}:\t''' + '\t'.join(F'''{x:.5f}''' for x in tensor[row].cpu().data ) ) else: logger.info(F'''layer {row + 1}:\t''' + '\t'.join(F'''{x:d}''' for x in tensor[row].cpu().data ) ) def lowercase_ (A : Tuple , A : Optional[Any] , A : str , A : int=True , A : Optional[int]=True , A : Any=None , A : int=False ): snake_case__ , snake_case__ : Optional[Any] = model.config.num_hidden_layers, model.config.num_attention_heads snake_case__ : int = torch.zeros(A , A ).to(args.device ) snake_case__ : Any = torch.zeros(A , A ).to(args.device ) if head_mask is None: snake_case__ : Dict = torch.ones(A , A ).to(args.device ) head_mask.requires_grad_(requires_grad=A ) # If actually pruned attention multi-head, set head mask to None to avoid shape mismatch if actually_pruned: snake_case__ : Optional[int] = None snake_case__ : List[Any] = 0.0 snake_case__ : str = 0.0 for step, inputs in enumerate(tqdm(A , desc='Iteration' , disable=args.local_rank not in [-1, 0] ) ): snake_case__ : Union[str, Any] = tuple(t.to(args.device ) for t in inputs ) ((snake_case__) , ) : Optional[Any] = inputs # Do a forward pass (not with torch.no_grad() since we need gradients for importance score - see below) snake_case__ : Union[str, Any] = model(A , labels=A , head_mask=A ) # (loss), lm_logits, presents, (all hidden_states), (attentions) snake_case__ , snake_case__ , snake_case__ : Dict = ( outputs[0], outputs[1], outputs[-1], ) # Loss and logits are the first, attention the last loss.backward() # Backpropagate to populate the gradients in the head mask total_loss += loss.detach().cpu().numpy() if compute_entropy: for layer, attn in enumerate(A ): snake_case__ : Optional[Any] = entropy(attn.detach() , A ) attn_entropy[layer] += masked_entropy.sum(-1 ).sum(0 ).sum(0 ).detach() if compute_importance: head_importance += head_mask.grad.abs().detach() tot_tokens += torch.ones_like(A ).float().detach().sum().data # Normalize attn_entropy /= tot_tokens head_importance /= tot_tokens # Layerwise importance normalization if not args.dont_normalize_importance_by_layer: snake_case__ : Union[str, Any] = 2 snake_case__ : List[Any] = torch.pow(torch.pow(A , A ).sum(-1 ) , 1 / exponent ) head_importance /= norm_by_layer.unsqueeze(-1 ) + 1e-20 if not args.dont_normalize_global_importance: snake_case__ : Tuple = (head_importance - head_importance.min()) / (head_importance.max() - head_importance.min()) # Print matrices if compute_entropy: logger.info('Attention entropies' ) print_ad_tensor(A ) if compute_importance: logger.info('Head importance scores' ) print_ad_tensor(A ) logger.info('Head ranked by importance scores' ) snake_case__ : Tuple = torch.zeros(head_importance.numel() , dtype=torch.long , device=args.device ) snake_case__ : Union[str, Any] = torch.arange( head_importance.numel() , device=args.device ) snake_case__ : str = head_ranks.view_as(A ) print_ad_tensor(A ) return attn_entropy, head_importance, total_loss def lowercase_ (A : Optional[int] , A : Dict , A : Optional[int] ): snake_case__ , snake_case__ , snake_case__ : Any = compute_heads_importance(A , A , A , compute_entropy=A ) snake_case__ : Tuple = 1 / loss # instead of downsteam score use the LM loss logger.info('Pruning: original score: %f, threshold: %f' , A , original_score * args.masking_threshold ) snake_case__ : Optional[Any] = torch.ones_like(A ) snake_case__ : Union[str, Any] = max(1 , int(new_head_mask.numel() * args.masking_amount ) ) snake_case__ : Dict = original_score while current_score >= original_score * args.masking_threshold: snake_case__ : int = new_head_mask.clone().detach() # save current head mask # heads from least important to most - keep only not-masked heads snake_case__ : List[Any] = float('Inf' ) snake_case__ : Union[str, Any] = head_importance.view(-1 ).sort()[1] if len(A ) <= num_to_mask: print('BREAK BY num_to_mask' ) break # mask heads snake_case__ : int = current_heads_to_mask[:num_to_mask] logger.info('Heads to mask: %s' , str(current_heads_to_mask.tolist() ) ) snake_case__ : int = new_head_mask.view(-1 ) snake_case__ : int = 0.0 snake_case__ : Union[str, Any] = new_head_mask.view_as(A ) snake_case__ : List[str] = new_head_mask.clone().detach() print_ad_tensor(A ) # Compute metric and head importance again snake_case__ , snake_case__ , snake_case__ : Any = compute_heads_importance( A , A , A , compute_entropy=A , head_mask=A ) snake_case__ : Dict = 1 / loss logger.info( 'Masking: current score: %f, remaining heads %d (%.1f percents)' , A , new_head_mask.sum() , new_head_mask.sum() / new_head_mask.numel() * 1_0_0 , ) logger.info('Final head mask' ) print_ad_tensor(A ) np.save(os.path.join(args.output_dir , 'head_mask.npy' ) , head_mask.detach().cpu().numpy() ) return head_mask def lowercase_ (A : List[str] , A : Tuple , A : Optional[Any] , A : int ): snake_case__ : Any = datetime.now() snake_case__ , snake_case__ , snake_case__ : str = compute_heads_importance( A , A , A , compute_entropy=A , compute_importance=A , head_mask=A ) snake_case__ : Tuple = 1 / loss snake_case__ : Dict = datetime.now() - before_time snake_case__ : Union[str, Any] = sum(p.numel() for p in model.parameters() ) snake_case__ : Optional[Any] = { layer: (1 - head_mask[layer].long()).nonzero().squeeze().tolist() for layer in range(len(A ) ) } for k, v in heads_to_prune.items(): if isinstance(A , A ): snake_case__ : Any = [ v, ] assert sum(len(A ) for h in heads_to_prune.values() ) == (1 - head_mask.long()).sum().item() model.prune_heads(A ) snake_case__ : Dict = sum(p.numel() for p in model.parameters() ) snake_case__ : Tuple = datetime.now() snake_case__ , snake_case__ , snake_case__ : Dict = compute_heads_importance( A , A , A , compute_entropy=A , compute_importance=A , head_mask=A , actually_pruned=A , ) snake_case__ : Any = 1 / loss snake_case__ : int = datetime.now() - before_time logger.info( 'Pruning: original num of params: %.2e, after pruning %.2e (%.1f percents)' , A , A , pruned_num_params / original_num_params * 1_0_0 , ) logger.info('Pruning: score with masking: %f score with pruning: %f' , A , A ) logger.info('Pruning: speed ratio (original timing / new timing): %f percents' , original_time / new_time * 1_0_0 ) save_model(A , args.output_dir ) def lowercase_ (): snake_case__ : str = argparse.ArgumentParser() # Required parameters parser.add_argument( '--data_dir' , default=A , type=A , required=A , help='The input data dir. Should contain the .tsv files (or other data files) for the task.' , ) parser.add_argument( '--model_name_or_path' , default=A , type=A , required=A , help='Path to pretrained model or model identifier from huggingface.co/models' , ) parser.add_argument( '--output_dir' , default=A , type=A , required=A , help='The output directory where the model predictions and checkpoints will be written.' , ) # Other parameters parser.add_argument( '--config_name' , default='' , type=A , help='Pretrained config name or path if not the same as model_name_or_path' , ) parser.add_argument( '--tokenizer_name' , default='' , type=A , help='Pretrained tokenizer name or path if not the same as model_name_or_path' , ) parser.add_argument( '--cache_dir' , default=A , type=A , help='Where do you want to store the pre-trained models downloaded from s3' , ) parser.add_argument( '--data_subset' , type=A , default=-1 , help='If > 0: limit the data to a subset of data_subset instances.' ) parser.add_argument( '--overwrite_output_dir' , action='store_true' , help='Whether to overwrite data in output directory' ) parser.add_argument( '--overwrite_cache' , action='store_true' , help='Overwrite the cached training and evaluation sets' ) parser.add_argument( '--dont_normalize_importance_by_layer' , action='store_true' , help='Don\'t normalize importance score by layers' ) parser.add_argument( '--dont_normalize_global_importance' , action='store_true' , help='Don\'t normalize all importance scores between 0 and 1' , ) parser.add_argument( '--try_masking' , action='store_true' , help='Whether to try to mask head until a threshold of accuracy.' ) parser.add_argument( '--masking_threshold' , default=0.9 , type=A , help='masking threshold in term of metrics (stop masking when metric < threshold * original metric value).' , ) parser.add_argument( '--masking_amount' , default=0.1 , type=A , help='Amount to heads to masking at each masking step.' ) parser.add_argument('--metric_name' , default='acc' , type=A , help='Metric to use for head masking.' ) parser.add_argument( '--max_seq_length' , default=1_2_8 , type=A , help=( 'The maximum total input sequence length after WordPiece tokenization. \n' 'Sequences longer than this will be truncated, sequences shorter padded.' ) , ) parser.add_argument('--batch_size' , default=1 , type=A , help='Batch size.' ) parser.add_argument('--seed' , type=A , default=4_2 ) parser.add_argument('--local_rank' , type=A , default=-1 , help='local_rank for distributed training on gpus' ) parser.add_argument('--no_cuda' , action='store_true' , help='Whether not to use CUDA when available' ) parser.add_argument('--server_ip' , type=A , default='' , help='Can be used for distant debugging.' ) parser.add_argument('--server_port' , type=A , default='' , help='Can be used for distant debugging.' ) snake_case__ : Optional[int] = parser.parse_args() if args.server_ip and args.server_port: # Distant debugging - see https://code.visualstudio.com/docs/python/debugging#_attach-to-a-local-script import ptvsd print('Waiting for debugger attach' ) ptvsd.enable_attach(address=(args.server_ip, args.server_port) , redirect_output=A ) ptvsd.wait_for_attach() # Setup devices and distributed training if args.local_rank == -1 or args.no_cuda: snake_case__ : List[Any] = torch.device('cuda' if torch.cuda.is_available() and not args.no_cuda else 'cpu' ) snake_case__ : Optional[Any] = 0 if args.no_cuda else torch.cuda.device_count() else: torch.cuda.set_device(args.local_rank ) snake_case__ : int = torch.device('cuda' , args.local_rank ) snake_case__ : List[str] = 1 torch.distributed.init_process_group(backend='nccl' ) # Initializes the distributed backend # Setup logging logging.basicConfig(level=logging.INFO if args.local_rank in [-1, 0] else logging.WARN ) logger.info('device: {} n_gpu: {}, distributed: {}'.format(args.device , args.n_gpu , bool(args.local_rank != -1 ) ) ) snake_case__ : Any = GPTaLMHeadModel.from_pretrained(args.model_name_or_path ) # Distributed and parallel training model.to(args.device ) if args.local_rank != -1: snake_case__ : List[str] = nn.parallel.DistributedDataParallel( A , device_ids=[args.local_rank] , output_device=args.local_rank , find_unused_parameters=A ) elif args.n_gpu > 1: snake_case__ : Optional[int] = nn.DataParallel(A ) # Print/save training arguments os.makedirs(args.output_dir , exist_ok=A ) torch.save(A , os.path.join(args.output_dir , 'run_args.bin' ) ) logger.info('Training/evaluation parameters %s' , A ) # Prepare dataset snake_case__ : Optional[Any] = np.concatenate( [ np.loadtxt(args.data_dir , dtype=np.intaa ), ] ) snake_case__ : List[str] = (torch.from_numpy(A ),) snake_case__ : int = TensorDataset(*A ) snake_case__ : Union[str, Any] = RandomSampler(A ) snake_case__ : Any = DataLoader(A , sampler=A , batch_size=args.batch_size ) # Compute head entropy and importance score compute_heads_importance(A , A , A ) # Try head masking (set heads to zero until the score goes under a threshole) # and head pruning (remove masked heads and see the effect on the network) if args.try_masking and args.masking_threshold > 0.0 and args.masking_threshold < 1.0: snake_case__ : Dict = mask_heads(A , A , A ) prune_heads(A , A , A , A ) if __name__ == "__main__": main()
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0
'''simple docstring''' import baseaa import io import json import os from copy import deepcopy from ..optimizer import AcceleratedOptimizer from ..scheduler import AcceleratedScheduler class A : '''simple docstring''' def __init__(self , _UpperCAmelCase ) -> Optional[int]: if isinstance(_snake_case , _snake_case ): # Don't modify user's data should they want to reuse it (e.g. in tests), because once we # modified it, it will not be accepted here again, since `auto` values would have been overridden __UpperCamelCase : Optional[Any] = deepcopy(_snake_case ) elif os.path.exists(_snake_case ): with io.open(_snake_case , "r" , encoding="utf-8" ) as f: __UpperCamelCase : Optional[int] = json.load(_snake_case ) else: try: __UpperCamelCase : Dict = baseaa.urlsafe_baadecode(_snake_case ).decode("utf-8" ) __UpperCamelCase : Optional[Any] = json.loads(_snake_case ) except (UnicodeDecodeError, AttributeError, ValueError): raise ValueError( f"Expected a string path to an existing deepspeed config, or a dictionary, or a base64 encoded string. Received: {config_file_or_dict}" ) __UpperCamelCase : List[Any] = config self.set_stage_and_offload() def a_ (self ) -> Optional[int]: # zero stage - this is done as early as possible, before model is created, to allow # ``is_deepspeed_zero3_enabled`` query and getting to the early deepspeed config object # during ``zero.Init()`` which needs to know the dtype, and some other hparams. __UpperCamelCase : Dict = self.get_value("zero_optimization.stage" , -1 ) # offload __UpperCamelCase : Optional[int] = False if self.is_zeroa() or self.is_zeroa(): __UpperCamelCase : int = set(["cpu", "nvme"] ) __UpperCamelCase : Any = set( [ self.get_value("zero_optimization.offload_optimizer.device" ), self.get_value("zero_optimization.offload_param.device" ), ] ) if len(offload_devices & offload_devices_valid ) > 0: __UpperCamelCase : Tuple = True def a_ (self , _UpperCAmelCase ) -> Optional[int]: __UpperCamelCase : int = self.config # find the config node of interest if it exists __UpperCamelCase : Optional[Any] = ds_key_long.split("." ) __UpperCamelCase : Any = nodes.pop() for node in nodes: __UpperCamelCase : Optional[Any] = config.get(_snake_case ) if config is None: return None, ds_key return config, ds_key def a_ (self , _UpperCAmelCase , _UpperCAmelCase=None ) -> Any: __UpperCamelCase : Dict = self.find_config_node(_snake_case ) if config is None: return default return config.get(_snake_case , _snake_case ) def a_ (self , _UpperCAmelCase , _UpperCAmelCase=False ) -> Tuple: __UpperCamelCase : Any = self.config # find the config node of interest if it exists __UpperCamelCase : List[str] = ds_key_long.split("." ) for node in nodes: __UpperCamelCase : Any = config __UpperCamelCase : Optional[Any] = config.get(_snake_case ) if config is None: if must_exist: raise ValueError(f"Can\'t find {ds_key_long} entry in the config: {self.config}" ) else: return # if found remove it if parent_config is not None: parent_config.pop(_snake_case ) def a_ (self , _UpperCAmelCase ) -> Tuple: __UpperCamelCase : Any = self.get_value(_snake_case ) return False if value is None else bool(_snake_case ) def a_ (self , _UpperCAmelCase ) -> Union[str, Any]: __UpperCamelCase : Any = self.get_value(_snake_case ) return False if value is None else not bool(_snake_case ) def a_ (self ) -> int: return self._stage == 2 def a_ (self ) -> List[Any]: return self._stage == 3 def a_ (self ) -> List[str]: return self._offload class A : '''simple docstring''' def __init__(self , _UpperCAmelCase ) -> Union[str, Any]: __UpperCamelCase : Tuple = engine def a_ (self , _UpperCAmelCase , **_UpperCAmelCase ) -> Union[str, Any]: # runs backpropagation and handles mixed precision self.engine.backward(_snake_case , **_snake_case ) # Deepspeed's `engine.step` performs the following operations: # - gradient accumulation check # - gradient clipping # - optimizer step # - zero grad # - checking overflow # - lr_scheduler step (only if engine.lr_scheduler is not None) self.engine.step() # and this plugin overrides the above calls with no-ops when Accelerate runs under # Deepspeed, but allows normal functionality for non-Deepspeed cases thus enabling a simple # training loop that works transparently under many training regimes. class A ( lowerCAmelCase_ ): '''simple docstring''' def __init__(self , _UpperCAmelCase ) -> Union[str, Any]: super().__init__(_snake_case , device_placement=_snake_case , scaler=_snake_case ) __UpperCamelCase : Optional[Any] = hasattr(self.optimizer , "overflow" ) def a_ (self , _UpperCAmelCase=None ) -> Optional[int]: pass # `accelerator.backward(loss)` is doing that automatically. Therefore, its implementation is not needed def a_ (self ) -> Dict: pass # `accelerator.backward(loss)` is doing that automatically. Therefore, its implementation is not needed @property def a_ (self ) -> Any: if self.__has_overflow__: return self.optimizer.overflow return False class A ( lowerCAmelCase_ ): '''simple docstring''' def __init__(self , _UpperCAmelCase , _UpperCAmelCase ) -> List[Any]: super().__init__(_snake_case , _snake_case ) def a_ (self ) -> Optional[int]: pass # `accelerator.backward(loss)` is doing that automatically. Therefore, its implementation is not needed class A : '''simple docstring''' def __init__(self , _UpperCAmelCase , _UpperCAmelCase=0.001 , _UpperCAmelCase=0 , **_UpperCAmelCase ) -> Union[str, Any]: __UpperCamelCase : Optional[int] = params __UpperCamelCase : Optional[Any] = lr __UpperCamelCase : Optional[int] = weight_decay __UpperCamelCase : int = kwargs class A : '''simple docstring''' def __init__(self , _UpperCAmelCase , _UpperCAmelCase=None , _UpperCAmelCase=0 , **_UpperCAmelCase ) -> List[Any]: __UpperCamelCase : Union[str, Any] = optimizer __UpperCamelCase : Union[str, Any] = total_num_steps __UpperCamelCase : Union[str, Any] = warmup_num_steps __UpperCamelCase : Optional[int] = kwargs
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import argparse import json from collections import OrderedDict from pathlib import Path import requests import torch from huggingface_hub import hf_hub_download from PIL import Image from transformers import ( SegformerConfig, SegformerForImageClassification, SegformerForSemanticSegmentation, SegformerImageProcessor, ) from transformers.utils import logging logging.set_verbosity_info() a_ :Dict = logging.get_logger(__name__) def lowercase_ (A : Optional[Any] , A : Any=False ): snake_case__ : List[Any] = OrderedDict() for key, value in state_dict.items(): if encoder_only and not key.startswith('head' ): snake_case__ : str = 'segformer.encoder.' + key if key.startswith('backbone' ): snake_case__ : str = key.replace('backbone' , 'segformer.encoder' ) if "patch_embed" in key: # replace for example patch_embed1 by patch_embeddings.0 snake_case__ : Optional[int] = key[key.find('patch_embed' ) + len('patch_embed' )] snake_case__ : int = key.replace(F'''patch_embed{idx}''' , F'''patch_embeddings.{int(A )-1}''' ) if "norm" in key: snake_case__ : Optional[int] = key.replace('norm' , 'layer_norm' ) if "segformer.encoder.layer_norm" in key: # replace for example layer_norm1 by layer_norm.0 snake_case__ : Tuple = key[key.find('segformer.encoder.layer_norm' ) + len('segformer.encoder.layer_norm' )] snake_case__ : Union[str, Any] = key.replace(F'''layer_norm{idx}''' , F'''layer_norm.{int(A )-1}''' ) if "layer_norm1" in key: snake_case__ : List[Any] = key.replace('layer_norm1' , 'layer_norm_1' ) if "layer_norm2" in key: snake_case__ : List[Any] = key.replace('layer_norm2' , 'layer_norm_2' ) if "block" in key: # replace for example block1 by block.0 snake_case__ : List[Any] = key[key.find('block' ) + len('block' )] snake_case__ : List[Any] = key.replace(F'''block{idx}''' , F'''block.{int(A )-1}''' ) if "attn.q" in key: snake_case__ : int = key.replace('attn.q' , 'attention.self.query' ) if "attn.proj" in key: snake_case__ : str = key.replace('attn.proj' , 'attention.output.dense' ) if "attn" in key: snake_case__ : Optional[int] = key.replace('attn' , 'attention.self' ) if "fc1" in key: snake_case__ : str = key.replace('fc1' , 'dense1' ) if "fc2" in key: snake_case__ : Dict = key.replace('fc2' , 'dense2' ) if "linear_pred" in key: snake_case__ : Union[str, Any] = key.replace('linear_pred' , 'classifier' ) if "linear_fuse" in key: snake_case__ : List[str] = key.replace('linear_fuse.conv' , 'linear_fuse' ) snake_case__ : List[Any] = key.replace('linear_fuse.bn' , 'batch_norm' ) if "linear_c" in key: # replace for example linear_c4 by linear_c.3 snake_case__ : Optional[int] = key[key.find('linear_c' ) + len('linear_c' )] snake_case__ : Tuple = key.replace(F'''linear_c{idx}''' , F'''linear_c.{int(A )-1}''' ) if key.startswith('head' ): snake_case__ : Tuple = key.replace('head' , 'classifier' ) snake_case__ : Optional[int] = value return new_state_dict def lowercase_ (A : Tuple , A : Optional[int] ): # for each of the encoder blocks: for i in range(config.num_encoder_blocks ): for j in range(config.depths[i] ): # read in weights + bias of keys and values (which is a single matrix in the original implementation) snake_case__ : List[str] = state_dict.pop(F'''segformer.encoder.block.{i}.{j}.attention.self.kv.weight''' ) snake_case__ : Optional[Any] = state_dict.pop(F'''segformer.encoder.block.{i}.{j}.attention.self.kv.bias''' ) # next, add keys and values (in that order) to the state dict snake_case__ : str = kv_weight[ : config.hidden_sizes[i], : ] snake_case__ : Dict = kv_bias[: config.hidden_sizes[i]] snake_case__ : List[str] = kv_weight[ config.hidden_sizes[i] :, : ] snake_case__ : List[Any] = kv_bias[ config.hidden_sizes[i] : ] def lowercase_ (): snake_case__ : Union[str, Any] = 'http://images.cocodataset.org/val2017/000000039769.jpg' snake_case__ : Dict = Image.open(requests.get(A , stream=A ).raw ) return image @torch.no_grad() def lowercase_ (A : Any , A : Union[str, Any] , A : Optional[Any] ): snake_case__ : List[str] = SegformerConfig() snake_case__ : Dict = False # set attributes based on model_name snake_case__ : Optional[int] = 'huggingface/label-files' if "segformer" in model_name: snake_case__ : str = model_name[len('segformer.' ) : len('segformer.' ) + 2] if "ade" in model_name: snake_case__ : Optional[int] = 1_5_0 snake_case__ : int = 'ade20k-id2label.json' snake_case__ : List[Any] = (1, 1_5_0, 1_2_8, 1_2_8) elif "city" in model_name: snake_case__ : str = 1_9 snake_case__ : List[str] = 'cityscapes-id2label.json' snake_case__ : Optional[Any] = (1, 1_9, 1_2_8, 1_2_8) else: raise ValueError(F'''Model {model_name} not supported''' ) elif "mit" in model_name: snake_case__ : str = True snake_case__ : Union[str, Any] = model_name[4:6] snake_case__ : Optional[Any] = 1_0_0_0 snake_case__ : Optional[int] = 'imagenet-1k-id2label.json' snake_case__ : List[Any] = (1, 1_0_0_0) else: raise ValueError(F'''Model {model_name} not supported''' ) # set config attributes snake_case__ : str = json.load(open(hf_hub_download(A , A , repo_type='dataset' ) , 'r' ) ) snake_case__ : List[Any] = {int(A ): v for k, v in idalabel.items()} snake_case__ : Union[str, Any] = idalabel snake_case__ : Tuple = {v: k for k, v in idalabel.items()} if size == "b0": pass elif size == "b1": snake_case__ : List[Any] = [6_4, 1_2_8, 3_2_0, 5_1_2] snake_case__ : Tuple = 2_5_6 elif size == "b2": snake_case__ : List[str] = [6_4, 1_2_8, 3_2_0, 5_1_2] snake_case__ : int = 7_6_8 snake_case__ : List[Any] = [3, 4, 6, 3] elif size == "b3": snake_case__ : Optional[Any] = [6_4, 1_2_8, 3_2_0, 5_1_2] snake_case__ : int = 7_6_8 snake_case__ : Optional[Any] = [3, 4, 1_8, 3] elif size == "b4": snake_case__ : str = [6_4, 1_2_8, 3_2_0, 5_1_2] snake_case__ : Optional[Any] = 7_6_8 snake_case__ : Union[str, Any] = [3, 8, 2_7, 3] elif size == "b5": snake_case__ : List[str] = [6_4, 1_2_8, 3_2_0, 5_1_2] snake_case__ : Optional[Any] = 7_6_8 snake_case__ : Any = [3, 6, 4_0, 3] else: raise ValueError(F'''Size {size} not supported''' ) # load image processor (only resize + normalize) snake_case__ : Dict = SegformerImageProcessor( image_scale=(5_1_2, 5_1_2) , keep_ratio=A , align=A , do_random_crop=A ) # prepare image snake_case__ : List[str] = prepare_img() snake_case__ : Dict = image_processor(images=A , return_tensors='pt' ).pixel_values logger.info(F'''Converting model {model_name}...''' ) # load original state dict if encoder_only: snake_case__ : Tuple = torch.load(A , map_location=torch.device('cpu' ) ) else: snake_case__ : int = torch.load(A , map_location=torch.device('cpu' ) )['state_dict'] # rename keys snake_case__ : List[Any] = rename_keys(A , encoder_only=A ) if not encoder_only: del state_dict["decode_head.conv_seg.weight"] del state_dict["decode_head.conv_seg.bias"] # key and value matrices need special treatment read_in_k_v(A , A ) # create HuggingFace model and load state dict if encoder_only: snake_case__ : str = False snake_case__ : List[Any] = SegformerForImageClassification(A ) else: snake_case__ : Dict = SegformerForSemanticSegmentation(A ) model.load_state_dict(A ) model.eval() # forward pass snake_case__ : int = model(A ) snake_case__ : Any = outputs.logits # set expected_slice based on model name # ADE20k checkpoints if model_name == "segformer.b0.512x512.ade.160k": snake_case__ : Dict = torch.tensor( [ [[-4.6310, -5.5232, -6.2356], [-5.1921, -6.1444, -6.5996], [-5.4424, -6.2790, -6.7574]], [[-12.1391, -13.3122, -13.9554], [-12.8732, -13.9352, -14.3563], [-12.9438, -13.8226, -14.2513]], [[-12.5134, -13.4686, -14.4915], [-12.8669, -14.4343, -14.7758], [-13.2523, -14.5819, -15.0694]], ] ) elif model_name == "segformer.b1.512x512.ade.160k": snake_case__ : Optional[int] = torch.tensor( [ [[-7.5820, -8.7231, -8.3215], [-8.0600, -10.3529, -10.0304], [-7.5208, -9.4103, -9.6239]], [[-12.6918, -13.8994, -13.7137], [-13.3196, -15.7523, -15.4789], [-12.9343, -14.8757, -14.9689]], [[-11.1911, -11.9421, -11.3243], [-11.3342, -13.6839, -13.3581], [-10.3909, -12.1832, -12.4858]], ] ) elif model_name == "segformer.b2.512x512.ade.160k": snake_case__ : List[Any] = torch.tensor( [ [[-11.8173, -14.3850, -16.3128], [-14.5648, -16.5804, -18.6568], [-14.7223, -15.7387, -18.4218]], [[-15.7290, -17.9171, -19.4423], [-18.3105, -19.9448, -21.4661], [-17.9296, -18.6497, -20.7910]], [[-15.0783, -17.0336, -18.2789], [-16.8771, -18.6870, -20.1612], [-16.2454, -17.1426, -19.5055]], ] ) elif model_name == "segformer.b3.512x512.ade.160k": snake_case__ : Union[str, Any] = torch.tensor( [ [[-9.0878, -10.2081, -10.1891], [-9.3144, -10.7941, -10.9843], [-9.2294, -10.3855, -10.5704]], [[-12.2316, -13.9068, -13.6102], [-12.9161, -14.3702, -14.3235], [-12.5233, -13.7174, -13.7932]], [[-14.6275, -15.2490, -14.9727], [-14.3400, -15.9687, -16.2827], [-14.1484, -15.4033, -15.8937]], ] ) elif model_name == "segformer.b4.512x512.ade.160k": snake_case__ : Dict = torch.tensor( [ [[-12.3144, -13.2447, -14.0802], [-13.3614, -14.5816, -15.6117], [-13.3340, -14.4433, -16.2219]], [[-19.2781, -20.4128, -20.7506], [-20.6153, -21.6566, -22.0998], [-19.9800, -21.0430, -22.1494]], [[-18.8739, -19.7804, -21.1834], [-20.1233, -21.6765, -23.2944], [-20.0315, -21.2641, -23.6944]], ] ) elif model_name == "segformer.b5.640x640.ade.160k": snake_case__ : List[Any] = torch.tensor( [ [[-9.5524, -12.0835, -11.7348], [-10.5229, -13.6446, -14.5662], [-9.5842, -12.8851, -13.9414]], [[-15.3432, -17.5323, -17.0818], [-16.3330, -18.9255, -19.2101], [-15.1340, -17.7848, -18.3971]], [[-12.6072, -14.9486, -14.6631], [-13.7629, -17.0907, -17.7745], [-12.7899, -16.1695, -17.1671]], ] ) # Cityscapes checkpoints elif model_name == "segformer.b0.1024x1024.city.160k": snake_case__ : str = torch.tensor( [ [[-11.9295, -13.4057, -14.8106], [-13.3431, -14.8179, -15.3781], [-14.2836, -15.5942, -16.1588]], [[-11.4906, -12.8067, -13.6564], [-13.1189, -14.0500, -14.1543], [-13.8748, -14.5136, -14.8789]], [[0.5374, 0.1067, -0.4742], [0.1141, -0.2255, -0.7099], [-0.3000, -0.5924, -1.3105]], ] ) elif model_name == "segformer.b0.512x1024.city.160k": snake_case__ : Tuple = torch.tensor( [ [[-7.8217, -9.8767, -10.1717], [-9.4438, -10.9058, -11.4047], [-9.7939, -12.3495, -12.1079]], [[-7.1514, -9.5336, -10.0860], [-9.7776, -11.6822, -11.8439], [-10.1411, -12.7655, -12.8972]], [[0.3021, 0.0805, -0.2310], [-0.0328, -0.1605, -0.2714], [-0.1408, -0.5477, -0.6976]], ] ) elif model_name == "segformer.b0.640x1280.city.160k": snake_case__ : Any = torch.tensor( [ [ [-1.1_372e01, -1.2_787e01, -1.3_477e01], [-1.2_536e01, -1.4_194e01, -1.4_409e01], [-1.3_217e01, -1.4_888e01, -1.5_327e01], ], [ [-1.4_791e01, -1.7_122e01, -1.8_277e01], [-1.7_163e01, -1.9_192e01, -1.9_533e01], [-1.7_897e01, -1.9_991e01, -2.0_315e01], ], [ [7.6_723e-01, 4.1_921e-01, -7.7_878e-02], [4.7_772e-01, 9.5_557e-03, -2.8_082e-01], [3.6_032e-01, -2.4_826e-01, -5.1_168e-01], ], ] ) elif model_name == "segformer.b0.768x768.city.160k": snake_case__ : Optional[int] = torch.tensor( [ [[-9.4959, -11.3087, -11.7479], [-11.0025, -12.6540, -12.3319], [-11.4064, -13.0487, -12.9905]], [[-9.8905, -11.3084, -12.0854], [-11.1726, -12.7698, -12.9583], [-11.5985, -13.3278, -14.1774]], [[0.2213, 0.0192, -0.2466], [-0.1731, -0.4213, -0.4874], [-0.3126, -0.6541, -1.1389]], ] ) elif model_name == "segformer.b1.1024x1024.city.160k": snake_case__ : Union[str, Any] = torch.tensor( [ [[-13.5748, -13.9111, -12.6500], [-14.3500, -15.3683, -14.2328], [-14.7532, -16.0424, -15.6087]], [[-17.1651, -15.8725, -12.9653], [-17.2580, -17.3718, -14.8223], [-16.6058, -16.8783, -16.7452]], [[-3.6456, -3.0209, -1.4203], [-3.0797, -3.1959, -2.0000], [-1.8757, -1.9217, -1.6997]], ] ) elif model_name == "segformer.b2.1024x1024.city.160k": snake_case__ : List[str] = torch.tensor( [ [[-16.0976, -16.4856, -17.3962], [-16.6234, -19.0342, -19.7685], [-16.0900, -18.0661, -19.1180]], [[-18.4750, -18.8488, -19.5074], [-19.4030, -22.1570, -22.5977], [-19.1191, -20.8486, -22.3783]], [[-4.5178, -5.5037, -6.5109], [-5.0884, -7.2174, -8.0334], [-4.4156, -5.8117, -7.2970]], ] ) elif model_name == "segformer.b3.1024x1024.city.160k": snake_case__ : List[Any] = torch.tensor( [ [[-14.2081, -14.4732, -14.1977], [-14.5867, -16.4423, -16.6356], [-13.4441, -14.9685, -16.8696]], [[-14.4576, -14.7073, -15.0451], [-15.0816, -17.6237, -17.9873], [-14.4213, -16.0199, -18.5992]], [[-4.7349, -4.9588, -5.0966], [-4.3210, -6.9325, -7.2591], [-3.4312, -4.7484, -7.1917]], ] ) elif model_name == "segformer.b4.1024x1024.city.160k": snake_case__ : str = torch.tensor( [ [[-11.7737, -11.9526, -11.3273], [-13.6692, -14.4574, -13.8878], [-13.8937, -14.6924, -15.9345]], [[-14.6706, -14.5330, -14.1306], [-16.1502, -16.8180, -16.4269], [-16.8338, -17.8939, -20.1746]], [[1.0491, 0.8289, 1.0310], [1.1044, 0.5219, 0.8055], [1.0899, 0.6926, 0.5590]], ] ) elif model_name == "segformer.b5.1024x1024.city.160k": snake_case__ : List[str] = torch.tensor( [ [[-12.5641, -13.4777, -13.0684], [-13.9587, -15.8983, -16.6557], [-13.3109, -15.7350, -16.3141]], [[-14.7074, -15.4352, -14.5944], [-16.6353, -18.1663, -18.6120], [-15.1702, -18.0329, -18.1547]], [[-1.7990, -2.0951, -1.7784], [-2.6397, -3.8245, -3.9686], [-1.5264, -2.8126, -2.9316]], ] ) else: snake_case__ : Tuple = logits.argmax(-1 ).item() print('Predicted class:' , model.config.idalabel[predicted_class_idx] ) # verify logits if not encoder_only: assert logits.shape == expected_shape assert torch.allclose(logits[0, :3, :3, :3] , A , atol=1e-2 ) # finally, save model and image processor logger.info(F'''Saving PyTorch model and image processor to {pytorch_dump_folder_path}...''' ) Path(A ).mkdir(exist_ok=A ) model.save_pretrained(A ) image_processor.save_pretrained(A ) if __name__ == "__main__": a_ :Optional[int] = argparse.ArgumentParser() parser.add_argument( "--model_name", default="segformer.b0.512x512.ade.160k", type=str, help="Name of the model you'd like to convert.", ) parser.add_argument( "--checkpoint_path", default=None, type=str, help="Path to the original PyTorch checkpoint (.pth file)." ) parser.add_argument( "--pytorch_dump_folder_path", default=None, type=str, help="Path to the folder to output PyTorch model." ) a_ :Union[str, Any] = parser.parse_args() convert_segformer_checkpoint(args.model_name, args.checkpoint_path, args.pytorch_dump_folder_path)
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import argparse import json from collections import OrderedDict from pathlib import Path import requests import torch from huggingface_hub import hf_hub_download from PIL import Image from transformers import PoolFormerConfig, PoolFormerForImageClassification, PoolFormerImageProcessor from transformers.utils import logging logging.set_verbosity_info() _snake_case = logging.get_logger(__name__) def lowerCAmelCase_ ( snake_case_,snake_case_,snake_case_,snake_case_ ): _A : str = original_name.split(""".""" )[0] _A : List[str] = key.split(""".""" ) _A : Tuple = int(key_list[key_list.index(snake_case_ ) - 2] ) _A : Dict = int(key_list[key_list.index(snake_case_ ) - 1] ) _A : Any = orig_block_num - offset _A : Dict = key.replace(f'''{orig_block_num}.{layer_num}.{original_name}''',f'''block.{new_block_num}.{layer_num}.{new_name}''' ) return key def lowerCAmelCase_ ( snake_case_ ): _A : Dict = OrderedDict() _A : int = 0, 0 for key, value in state_dict.items(): if key.startswith("""network""" ): _A : str = key.replace("""network""","""poolformer.encoder""" ) if "proj" in key: # Works for the first embedding as well as the internal embedding layers if key.endswith("""bias""" ) and "patch_embed" not in key: patch_emb_offset += 1 _A : Dict = key[: key.find("""proj""" )] _A : int = key.replace(snake_case_,f'''patch_embeddings.{total_embed_found}.''' ) _A : Dict = key.replace("""proj""","""projection""" ) if key.endswith("""bias""" ): total_embed_found += 1 if "patch_embeddings" in key: _A : Dict = 'poolformer.encoder.' + key if "mlp.fc1" in key: _A : Dict = replace_key_with_offset(snake_case_,snake_case_,"""mlp.fc1""","""output.conv1""" ) if "mlp.fc2" in key: _A : List[Any] = replace_key_with_offset(snake_case_,snake_case_,"""mlp.fc2""","""output.conv2""" ) if "norm1" in key: _A : List[str] = replace_key_with_offset(snake_case_,snake_case_,"""norm1""","""before_norm""" ) if "norm2" in key: _A : Dict = replace_key_with_offset(snake_case_,snake_case_,"""norm2""","""after_norm""" ) if "layer_scale_1" in key: _A : Optional[Any] = replace_key_with_offset(snake_case_,snake_case_,"""layer_scale_1""","""layer_scale_1""" ) if "layer_scale_2" in key: _A : Tuple = replace_key_with_offset(snake_case_,snake_case_,"""layer_scale_2""","""layer_scale_2""" ) if "head" in key: _A : Union[str, Any] = key.replace("""head""","""classifier""" ) _A : int = value return new_state_dict def lowerCAmelCase_ ( ): _A : Dict = 'http://images.cocodataset.org/val2017/000000039769.jpg' _A : List[str] = Image.open(requests.get(snake_case_,stream=snake_case_ ).raw ) return image @torch.no_grad() def lowerCAmelCase_ ( snake_case_,snake_case_,snake_case_ ): _A : Any = PoolFormerConfig() # set attributes based on model_name _A : str = 'huggingface/label-files' _A : List[Any] = model_name[-3:] _A : Optional[int] = 1000 _A : Tuple = 'imagenet-1k-id2label.json' _A : Union[str, Any] = (1, 1000) # set config attributes _A : Optional[int] = json.load(open(hf_hub_download(snake_case_,snake_case_,repo_type="""dataset""" ),"""r""" ) ) _A : Any = {int(snake_case_ ): v for k, v in idalabel.items()} _A : int = idalabel _A : List[str] = {v: k for k, v in idalabel.items()} if size == "s12": _A : str = [2, 2, 6, 2] _A : Optional[int] = [64, 128, 320, 512] _A : Union[str, Any] = 4.0 _A : str = 0.9 elif size == "s24": _A : List[str] = [4, 4, 12, 4] _A : Any = [64, 128, 320, 512] _A : List[str] = 4.0 _A : Any = 0.9 elif size == "s36": _A : int = [6, 6, 18, 6] _A : int = [64, 128, 320, 512] _A : Dict = 4.0 _A : Dict = 1e-6 _A : Any = 0.9 elif size == "m36": _A : int = [6, 6, 18, 6] _A : Dict = [96, 192, 384, 768] _A : Tuple = 4.0 _A : Union[str, Any] = 1e-6 _A : str = 0.95 elif size == "m48": _A : Union[str, Any] = [8, 8, 24, 8] _A : Optional[int] = [96, 192, 384, 768] _A : Optional[Any] = 4.0 _A : int = 1e-6 _A : Optional[Any] = 0.95 else: raise ValueError(f'''Size {size} not supported''' ) # load image processor _A : List[Any] = PoolFormerImageProcessor(crop_pct=snake_case_ ) # Prepare image _A : Optional[Any] = prepare_img() _A : Optional[Any] = image_processor(images=snake_case_,return_tensors="""pt""" ).pixel_values logger.info(f'''Converting model {model_name}...''' ) # load original state dict _A : Optional[Any] = torch.load(snake_case_,map_location=torch.device("""cpu""" ) ) # rename keys _A : Union[str, Any] = rename_keys(snake_case_ ) # create HuggingFace model and load state dict _A : str = PoolFormerForImageClassification(snake_case_ ) model.load_state_dict(snake_case_ ) model.eval() # Define image processor _A : Union[str, Any] = PoolFormerImageProcessor(crop_pct=snake_case_ ) _A : Any = image_processor(images=prepare_img(),return_tensors="""pt""" ).pixel_values # forward pass _A : List[Any] = model(snake_case_ ) _A : List[Any] = outputs.logits # define expected logit slices for different models if size == "s12": _A : List[Any] = torch.tensor([-0.30_45, -0.67_58, -0.48_69] ) elif size == "s24": _A : Optional[int] = torch.tensor([0.44_02, -0.13_74, -0.80_45] ) elif size == "s36": _A : Optional[Any] = torch.tensor([-0.60_80, -0.51_33, -0.58_98] ) elif size == "m36": _A : Any = torch.tensor([0.39_52, 0.22_63, -1.26_68] ) elif size == "m48": _A : Optional[int] = torch.tensor([0.11_67, -0.06_56, -0.34_23] ) else: raise ValueError(f'''Size {size} not supported''' ) # verify logits assert logits.shape == expected_shape assert torch.allclose(logits[0, :3],snake_case_,atol=1e-2 ) # finally, save model and image processor logger.info(f'''Saving PyTorch model and image processor to {pytorch_dump_folder_path}...''' ) Path(snake_case_ ).mkdir(exist_ok=snake_case_ ) model.save_pretrained(snake_case_ ) print(f'''Saving image processor to {pytorch_dump_folder_path}''' ) image_processor.save_pretrained(snake_case_ ) if __name__ == "__main__": _snake_case = argparse.ArgumentParser() parser.add_argument( "--model_name", default="poolformer_s12", type=str, help="Name of the model you'd like to convert.", ) parser.add_argument( "--checkpoint_path", default=None, type=str, help="Path to the original PyTorch checkpoint (.pth file)." ) parser.add_argument( "--pytorch_dump_folder_path", default=None, type=str, help="Path to the folder to output PyTorch model." ) _snake_case = parser.parse_args() convert_poolformer_checkpoint(args.model_name, args.checkpoint_path, args.pytorch_dump_folder_path)
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import argparse import json import os import fairseq import torch from fairseq.data import Dictionary from transformers import ( WavaVecaConfig, WavaVecaCTCTokenizer, WavaVecaFeatureExtractor, WavaVecaForCTC, WavaVecaForPreTraining, WavaVecaProcessor, logging, ) from transformers.models.wavaveca.modeling_wavaveca import WavaVecaForSequenceClassification logging.set_verbosity_info() a_ :List[Any] = logging.get_logger(__name__) a_ :List[Any] = { "post_extract_proj": "feature_projection.projection", "encoder.pos_conv.0": "encoder.pos_conv_embed.conv", "self_attn.k_proj": "encoder.layers.*.attention.k_proj", "self_attn.v_proj": "encoder.layers.*.attention.v_proj", "self_attn.q_proj": "encoder.layers.*.attention.q_proj", "self_attn.out_proj": "encoder.layers.*.attention.out_proj", "self_attn_layer_norm": "encoder.layers.*.layer_norm", "fc1": "encoder.layers.*.feed_forward.intermediate_dense", "fc2": "encoder.layers.*.feed_forward.output_dense", "final_layer_norm": "encoder.layers.*.final_layer_norm", "encoder.layer_norm": "encoder.layer_norm", "adapter_layer": "encoder.layers.*.adapter_layer", "w2v_model.layer_norm": "feature_projection.layer_norm", "quantizer.weight_proj": "quantizer.weight_proj", "quantizer.vars": "quantizer.codevectors", "project_q": "project_q", "final_proj": "project_hid", "w2v_encoder.proj": "lm_head", "mask_emb": "masked_spec_embed", "pooling_layer.linear": "projector", "pooling_layer.projection": "classifier", } a_ :List[Any] = [ "lm_head", "quantizer.weight_proj", "quantizer.codevectors", "project_q", "project_hid", "projector", "classifier", ] def lowercase_ (A : Dict ): snake_case__ : Optional[Any] = {} with open(A , 'r' ) as file: for line_number, line in enumerate(A ): snake_case__ : Dict = line.strip() if line: snake_case__ : int = line.split() snake_case__ : List[str] = line_number snake_case__ : Dict = words[0] snake_case__ : Optional[Any] = value return result def lowercase_ (A : int , A : int , A : Optional[int] , A : Optional[Any] , A : Tuple ): for attribute in key.split('.' ): snake_case__ : Optional[int] = getattr(A , A ) snake_case__ : Union[str, Any] = None for param_key in PARAM_MAPPING.keys(): if full_name.endswith(A ): snake_case__ : List[str] = PARAM_MAPPING[full_name.split('.' )[-1]] snake_case__ : Dict = 'param' if weight_type is not None and weight_type != "param": snake_case__ : Union[str, Any] = getattr(A , A ).shape elif weight_type is not None and weight_type == "param": snake_case__ : Optional[int] = hf_pointer for attribute in hf_param_name.split('.' ): snake_case__ : Optional[Any] = getattr(A , A ) snake_case__ : Dict = shape_pointer.shape # let's reduce dimension snake_case__ : List[Any] = value[0] else: snake_case__ : Union[str, Any] = hf_pointer.shape if hf_shape != value.shape: raise ValueError( F'''Shape of hf {key + "." + weight_type if weight_type is not None else ""} is {hf_shape}, but should be''' F''' {value.shape} for {full_name}''' ) if weight_type == "weight": snake_case__ : Any = value elif weight_type == "weight_g": snake_case__ : List[Any] = value elif weight_type == "weight_v": snake_case__ : Any = value elif weight_type == "bias": snake_case__ : List[Any] = value elif weight_type == "param": for attribute in hf_param_name.split('.' ): snake_case__ : int = getattr(A , A ) snake_case__ : Optional[int] = value else: snake_case__ : Optional[Any] = value logger.info(F'''{key + "." + weight_type if weight_type is not None else ""} was initialized from {full_name}.''' ) def lowercase_ (A : Tuple , A : List[Any] , A : int , A : str , A : Tuple ): snake_case__ : Optional[int] = None for param_key in PARAM_MAPPING.keys(): if full_name.endswith(A ): snake_case__ : List[str] = PARAM_MAPPING[full_name.split('.' )[-1]] snake_case__ : str = 'param' if weight_type is not None and weight_type != "param": snake_case__ : int = '.'.join([key, weight_type] ) elif weight_type is not None and weight_type == "param": snake_case__ : Any = '.'.join([key, hf_param_name] ) else: snake_case__ : Dict = key snake_case__ : List[str] = value if 'lm_head' in full_key else value[0] a_ :List[str] = { "W_a": "linear_1.weight", "W_b": "linear_2.weight", "b_a": "linear_1.bias", "b_b": "linear_2.bias", "ln_W": "norm.weight", "ln_b": "norm.bias", } def lowercase_ (A : str , A : Optional[Any] , A : Optional[Any]=None , A : List[str]=None ): snake_case__ : Optional[int] = False for key, mapped_key in MAPPING.items(): snake_case__ : Tuple = 'wav2vec2.' + mapped_key if mapped_key not in TOP_LEVEL_KEYS else mapped_key if key in name or key.split('w2v_model.' )[-1] == name.split('.' )[0]: snake_case__ : Optional[int] = True if "*" in mapped_key: snake_case__ : List[Any] = name.split(A )[0].split('.' )[-2] snake_case__ : Union[str, Any] = mapped_key.replace('*' , A ) if "weight_g" in name: snake_case__ : Tuple = 'weight_g' elif "weight_v" in name: snake_case__ : List[str] = 'weight_v' elif "bias" in name: snake_case__ : Dict = 'bias' elif "weight" in name: # TODO: don't match quantizer.weight_proj snake_case__ : Optional[int] = 'weight' else: snake_case__ : str = None if hf_dict is not None: rename_dict(A , A , A , A , A ) else: set_recursively(A , A , A , A , A ) return is_used return is_used def lowercase_ (A : Optional[Any] , A : Dict , A : Optional[int] ): snake_case__ : Dict = [] snake_case__ : Tuple = fairseq_model.state_dict() snake_case__ : str = hf_model.wavaveca.feature_extractor for name, value in fairseq_dict.items(): snake_case__ : str = False if "conv_layers" in name: load_conv_layer( A , A , A , A , hf_model.config.feat_extract_norm == 'group' , ) snake_case__ : Any = True else: snake_case__ : Dict = load_wavaveca_layer(A , A , A ) if not is_used: unused_weights.append(A ) logger.warning(F'''Unused weights: {unused_weights}''' ) def lowercase_ (A : Dict , A : Optional[Any] , A : Tuple , A : str , A : List[str] ): snake_case__ : List[Any] = full_name.split('conv_layers.' )[-1] snake_case__ : List[str] = name.split('.' ) snake_case__ : List[Any] = int(items[0] ) snake_case__ : str = int(items[1] ) if type_id == 0: if "bias" in name: if value.shape != feature_extractor.conv_layers[layer_id].conv.bias.data.shape: raise ValueError( F'''{full_name} has size {value.shape}, but''' F''' {feature_extractor.conv_layers[layer_id].conv.bias.data.shape} was found.''' ) snake_case__ : Any = value logger.info(F'''Feat extract conv layer {layer_id} was initialized from {full_name}.''' ) elif "weight" in name: if value.shape != feature_extractor.conv_layers[layer_id].conv.weight.data.shape: raise ValueError( F'''{full_name} has size {value.shape}, but''' F''' {feature_extractor.conv_layers[layer_id].conv.weight.data.shape} was found.''' ) snake_case__ : str = value logger.info(F'''Feat extract conv layer {layer_id} was initialized from {full_name}.''' ) elif (type_id == 2 and not use_group_norm) or (type_id == 2 and layer_id == 0 and use_group_norm): if "bias" in name: if value.shape != feature_extractor.conv_layers[layer_id].layer_norm.bias.data.shape: raise ValueError( F'''{full_name} has size {value.shape}, but''' F''' {feature_extractor.conv_layers[layer_id].layer_norm.bias.data.shape} was found.''' ) snake_case__ : str = value logger.info(F'''Feat extract layer norm weight of layer {layer_id} was initialized from {full_name}.''' ) elif "weight" in name: if value.shape != feature_extractor.conv_layers[layer_id].layer_norm.weight.data.shape: raise ValueError( F'''{full_name} has size {value.shape}, but''' F''' {feature_extractor.conv_layers[layer_id].layer_norm.weight.data.shape} was found.''' ) snake_case__ : int = value logger.info(F'''Feat extract layer norm weight of layer {layer_id} was initialized from {full_name}.''' ) else: unused_weights.append(A ) @torch.no_grad() def lowercase_ (A : Union[str, Any] , A : str , A : Tuple=None , A : List[str]=None , A : Any=True , A : Optional[int]=False ): if config_path is not None: snake_case__ : List[Any] = WavaVecaConfig.from_pretrained(A ) else: snake_case__ : List[Any] = WavaVecaConfig() if is_seq_class: snake_case__ : Dict = read_txt_into_dict(A ) snake_case__ : Any = idalabel snake_case__ : Union[str, Any] = WavaVecaForSequenceClassification(A ) snake_case__ : Any = WavaVecaFeatureExtractor( feature_size=1 , sampling_rate=1_6_0_0_0 , padding_value=0 , do_normalize=A , return_attention_mask=A , ) feature_extractor.save_pretrained(A ) elif is_finetuned: if dict_path: snake_case__ : str = Dictionary.load(A ) # important change bos & pad token id since CTC symbol is <pad> and # not <s> as in fairseq snake_case__ : List[str] = target_dict.pad_index snake_case__ : Optional[int] = target_dict.bos_index snake_case__ : Optional[int] = target_dict.eos_index snake_case__ : List[Any] = len(target_dict.symbols ) snake_case__ : str = os.path.join(A , 'vocab.json' ) if not os.path.isdir(A ): logger.error('--pytorch_dump_folder_path ({}) should be a directory'.format(A ) ) return os.makedirs(A , exist_ok=A ) snake_case__ : Optional[Any] = target_dict.indices # fairseq has the <pad> and <s> switched snake_case__ : Optional[Any] = 0 snake_case__ : Union[str, Any] = 1 with open(A , 'w' , encoding='utf-8' ) as vocab_handle: json.dump(A , A ) snake_case__ : List[Any] = WavaVecaCTCTokenizer( A , unk_token=target_dict.unk_word , pad_token=target_dict.pad_word , bos_token=target_dict.bos_word , eos_token=target_dict.eos_word , word_delimiter_token='|' , do_lower_case=A , ) snake_case__ : str = True if config.feat_extract_norm == 'layer' else False snake_case__ : Optional[Any] = WavaVecaFeatureExtractor( feature_size=1 , sampling_rate=1_6_0_0_0 , padding_value=0 , do_normalize=A , return_attention_mask=A , ) snake_case__ : Union[str, Any] = WavaVecaProcessor(feature_extractor=A , tokenizer=A ) processor.save_pretrained(A ) snake_case__ : str = WavaVecaForCTC(A ) else: snake_case__ : int = WavaVecaForPreTraining(A ) if is_finetuned or is_seq_class: snake_case__ , snake_case__ , snake_case__ : str = fairseq.checkpoint_utils.load_model_ensemble_and_task( [checkpoint_path] , arg_overrides={'data': '/'.join(dict_path.split('/' )[:-1] )} ) else: snake_case__ : Tuple = argparse.Namespace(task='audio_pretraining' ) snake_case__ : str = fairseq.tasks.setup_task(A ) snake_case__ , snake_case__ , snake_case__ : Any = fairseq.checkpoint_utils.load_model_ensemble_and_task([checkpoint_path] , task=A ) snake_case__ : List[Any] = model[0].eval() recursively_load_weights(A , A , not is_finetuned ) hf_wavavec.save_pretrained(A ) if __name__ == "__main__": a_ :List[Any] = argparse.ArgumentParser() parser.add_argument("--pytorch_dump_folder_path", default=None, type=str, help="Path to the output PyTorch model.") parser.add_argument("--checkpoint_path", default=None, type=str, help="Path to fairseq checkpoint") parser.add_argument("--dict_path", default=None, type=str, help="Path to dict of fine-tuned model") parser.add_argument("--config_path", default=None, type=str, help="Path to hf config.json of model to convert") parser.add_argument( "--not_finetuned", action="store_true", help="Whether the model to convert is a fine-tuned model or not" ) parser.add_argument( "--is_seq_class", action="store_true", help="Whether the model to convert is a fine-tuned sequence classification model or not", ) a_ :str = parser.parse_args() a_ :Tuple = not args.not_finetuned and not args.is_seq_class convert_wavaveca_checkpoint( args.checkpoint_path, args.pytorch_dump_folder_path, args.config_path, args.dict_path, is_finetuned, args.is_seq_class, )
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import datasets UpperCAmelCase__ = "\\n@InProceedings{conneau2018xnli,\n author = \"Conneau, Alexis\n and Rinott, Ruty\n and Lample, Guillaume\n and Williams, Adina\n and Bowman, Samuel R.\n and Schwenk, Holger\n and Stoyanov, Veselin\",\n title = \"XNLI: Evaluating Cross-lingual Sentence Representations\",\n booktitle = \"Proceedings of the 2018 Conference on Empirical Methods\n in Natural Language Processing\",\n year = \"2018\",\n publisher = \"Association for Computational Linguistics\",\n location = \"Brussels, Belgium\",\n}\n" UpperCAmelCase__ = "\\nXNLI is a subset of a few thousand examples from MNLI which has been translated\ninto a 14 different languages (some low-ish resource). As with MNLI, the goal is\nto predict textual entailment (does sentence A imply/contradict/neither sentence\nB) and is a classification task (given two sentences, predict one of three\nlabels).\n" UpperCAmelCase__ = "\nComputes XNLI score which is just simple accuracy.\nArgs:\n predictions: Predicted labels.\n references: Ground truth labels.\nReturns:\n 'accuracy': accuracy\nExamples:\n\n >>> predictions = [0, 1]\n >>> references = [0, 1]\n >>> xnli_metric = datasets.load_metric(\"xnli\")\n >>> results = xnli_metric.compute(predictions=predictions, references=references)\n >>> print(results)\n {'accuracy': 1.0}\n" def A ( _UpperCAmelCase : Any , _UpperCAmelCase : Union[str, Any] ) -> Any: '''simple docstring''' return (preds == labels).mean() @datasets.utils.file_utils.add_start_docstrings(_DESCRIPTION , _KWARGS_DESCRIPTION ) class __lowerCAmelCase ( datasets.Metric ): def _lowerCamelCase ( self : List[str]) -> int: """simple docstring""" return datasets.MetricInfo( description=_DESCRIPTION , citation=_CITATION , inputs_description=_KWARGS_DESCRIPTION , features=datasets.Features( { 'predictions': datasets.Value('int64' if self.config_name != 'sts-b' else 'float32'), 'references': datasets.Value('int64' if self.config_name != 'sts-b' else 'float32'), }) , codebase_urls=[] , reference_urls=[] , format='numpy' , ) def _lowerCamelCase ( self : List[str] , A : Dict , A : Optional[Any]) -> List[str]: """simple docstring""" return {"accuracy": simple_accuracy(_snake_case , _snake_case)}
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from typing import Dict, List from nltk.translate import gleu_score import datasets from datasets import MetricInfo a_ :Any = "\\n@misc{wu2016googles,\n title={Google's Neural Machine Translation System: Bridging the Gap between Human and Machine Translation},\n author={Yonghui Wu and Mike Schuster and Zhifeng Chen and Quoc V. Le and Mohammad Norouzi and Wolfgang Macherey\n and Maxim Krikun and Yuan Cao and Qin Gao and Klaus Macherey and Jeff Klingner and Apurva Shah and Melvin\n Johnson and Xiaobing Liu and Łukasz Kaiser and Stephan Gouws and Yoshikiyo Kato and Taku Kudo and Hideto\n Kazawa and Keith Stevens and George Kurian and Nishant Patil and Wei Wang and Cliff Young and\n Jason Smith and Jason Riesa and Alex Rudnick and Oriol Vinyals and Greg Corrado and Macduff Hughes\n and Jeffrey Dean},\n year={2016},\n eprint={1609.08144},\n archivePrefix={arXiv},\n primaryClass={cs.CL}\n}\n" a_ :List[str] = "\\nThe BLEU score has some undesirable properties when used for single\nsentences, as it was designed to be a corpus measure. We therefore\nuse a slightly different score for our RL experiments which we call\nthe 'GLEU score'. For the GLEU score, we record all sub-sequences of\n1, 2, 3 or 4 tokens in output and target sequence (n-grams). We then\ncompute a recall, which is the ratio of the number of matching n-grams\nto the number of total n-grams in the target (ground truth) sequence,\nand a precision, which is the ratio of the number of matching n-grams\nto the number of total n-grams in the generated output sequence. Then\nGLEU score is simply the minimum of recall and precision. This GLEU\nscore's range is always between 0 (no matches) and 1 (all match) and\nit is symmetrical when switching output and target. According to\nour experiments, GLEU score correlates quite well with the BLEU\nmetric on a corpus level but does not have its drawbacks for our per\nsentence reward objective.\n" a_ :List[str] = "\\nComputes corpus-level Google BLEU (GLEU) score of translated segments against one or more references.\nInstead of averaging the sentence level GLEU scores (i.e. macro-average precision), Wu et al. (2016) sum up the matching\ntokens and the max of hypothesis and reference tokens for each sentence, then compute using the aggregate values.\n\nArgs:\n predictions (list of str): list of translations to score.\n Each translation should be tokenized into a list of tokens.\n references (list of list of str): list of lists of references for each translation.\n Each reference should be tokenized into a list of tokens.\n min_len (int): The minimum order of n-gram this function should extract. Defaults to 1.\n max_len (int): The maximum order of n-gram this function should extract. Defaults to 4.\n\nReturns:\n 'google_bleu': google_bleu score\n\nExamples:\n Example 1:\n >>> hyp1 = ['It', 'is', 'a', 'guide', 'to', 'action', 'which',\n ... 'ensures', 'that', 'the', 'rubber', 'duck', 'always',\n ... 'disobeys', 'the', 'commands', 'of', 'the', 'cat']\n >>> ref1a = ['It', 'is', 'the', 'guiding', 'principle', 'which',\n ... 'guarantees', 'the', 'rubber', 'duck', 'forces', 'never',\n ... 'being', 'under', 'the', 'command', 'of', 'the', 'cat']\n\n >>> hyp2 = ['he', 'read', 'the', 'book', 'because', 'he', 'was',\n ... 'interested', 'in', 'world', 'history']\n >>> ref2a = ['he', 'was', 'interested', 'in', 'world', 'history',\n ... 'because', 'he', 'read', 'the', 'book']\n\n >>> list_of_references = [[ref1a], [ref2a]]\n >>> hypotheses = [hyp1, hyp2]\n >>> google_bleu = datasets.load_metric(\"google_bleu\")\n >>> results = google_bleu.compute(predictions=hypotheses, references=list_of_references)\n >>> print(round(results[\"google_bleu\"], 2))\n 0.44\n\n Example 2:\n >>> hyp1 = ['It', 'is', 'a', 'guide', 'to', 'action', 'which',\n ... 'ensures', 'that', 'the', 'rubber', 'duck', 'always',\n ... 'disobeys', 'the', 'commands', 'of', 'the', 'cat']\n >>> ref1a = ['It', 'is', 'the', 'guiding', 'principle', 'which',\n ... 'guarantees', 'the', 'rubber', 'duck', 'forces', 'never',\n ... 'being', 'under', 'the', 'command', 'of', 'the', 'cat']\n >>> ref1b = ['It', 'is', 'a', 'guide', 'to', 'action', 'that',\n ... 'ensures', 'that', 'the', 'rubber', 'duck', 'will', 'never',\n ... 'heed', 'the', 'cat', 'commands']\n >>> ref1c = ['It', 'is', 'the', 'practical', 'guide', 'for', 'the',\n ... 'rubber', 'duck', 'army', 'never', 'to', 'heed', 'the', 'directions',\n ... 'of', 'the', 'cat']\n\n >>> hyp2 = ['he', 'read', 'the', 'book', 'because', 'he', 'was',\n ... 'interested', 'in', 'world', 'history']\n >>> ref2a = ['he', 'was', 'interested', 'in', 'world', 'history',\n ... 'because', 'he', 'read', 'the', 'book']\n\n >>> list_of_references = [[ref1a, ref1b, ref1c], [ref2a]]\n >>> hypotheses = [hyp1, hyp2]\n >>> google_bleu = datasets.load_metric(\"google_bleu\")\n >>> results = google_bleu.compute(predictions=hypotheses, references=list_of_references)\n >>> print(round(results[\"google_bleu\"], 2))\n 0.61\n\n Example 3:\n >>> hyp1 = ['It', 'is', 'a', 'guide', 'to', 'action', 'which',\n ... 'ensures', 'that', 'the', 'rubber', 'duck', 'always',\n ... 'disobeys', 'the', 'commands', 'of', 'the', 'cat']\n >>> ref1a = ['It', 'is', 'the', 'guiding', 'principle', 'which',\n ... 'guarantees', 'the', 'rubber', 'duck', 'forces', 'never',\n ... 'being', 'under', 'the', 'command', 'of', 'the', 'cat']\n >>> ref1b = ['It', 'is', 'a', 'guide', 'to', 'action', 'that',\n ... 'ensures', 'that', 'the', 'rubber', 'duck', 'will', 'never',\n ... 'heed', 'the', 'cat', 'commands']\n >>> ref1c = ['It', 'is', 'the', 'practical', 'guide', 'for', 'the',\n ... 'rubber', 'duck', 'army', 'never', 'to', 'heed', 'the', 'directions',\n ... 'of', 'the', 'cat']\n\n >>> hyp2 = ['he', 'read', 'the', 'book', 'because', 'he', 'was',\n ... 'interested', 'in', 'world', 'history']\n >>> ref2a = ['he', 'was', 'interested', 'in', 'world', 'history',\n ... 'because', 'he', 'read', 'the', 'book']\n\n >>> list_of_references = [[ref1a, ref1b, ref1c], [ref2a]]\n >>> hypotheses = [hyp1, hyp2]\n >>> google_bleu = datasets.load_metric(\"google_bleu\")\n >>> results = google_bleu.compute(predictions=hypotheses, references=list_of_references, min_len=2)\n >>> print(round(results[\"google_bleu\"], 2))\n 0.53\n\n Example 4:\n >>> hyp1 = ['It', 'is', 'a', 'guide', 'to', 'action', 'which',\n ... 'ensures', 'that', 'the', 'rubber', 'duck', 'always',\n ... 'disobeys', 'the', 'commands', 'of', 'the', 'cat']\n >>> ref1a = ['It', 'is', 'the', 'guiding', 'principle', 'which',\n ... 'guarantees', 'the', 'rubber', 'duck', 'forces', 'never',\n ... 'being', 'under', 'the', 'command', 'of', 'the', 'cat']\n >>> ref1b = ['It', 'is', 'a', 'guide', 'to', 'action', 'that',\n ... 'ensures', 'that', 'the', 'rubber', 'duck', 'will', 'never',\n ... 'heed', 'the', 'cat', 'commands']\n >>> ref1c = ['It', 'is', 'the', 'practical', 'guide', 'for', 'the',\n ... 'rubber', 'duck', 'army', 'never', 'to', 'heed', 'the', 'directions',\n ... 'of', 'the', 'cat']\n\n >>> hyp2 = ['he', 'read', 'the', 'book', 'because', 'he', 'was',\n ... 'interested', 'in', 'world', 'history']\n >>> ref2a = ['he', 'was', 'interested', 'in', 'world', 'history',\n ... 'because', 'he', 'read', 'the', 'book']\n\n >>> list_of_references = [[ref1a, ref1b, ref1c], [ref2a]]\n >>> hypotheses = [hyp1, hyp2]\n >>> google_bleu = datasets.load_metric(\"google_bleu\")\n >>> results = google_bleu.compute(predictions=hypotheses,references=list_of_references, min_len=2, max_len=6)\n >>> print(round(results[\"google_bleu\"], 2))\n 0.4\n" @datasets.utils.file_utils.add_start_docstrings(_DESCRIPTION , _KWARGS_DESCRIPTION ) class snake_case__ ( datasets.Metric ): """simple docstring""" def lowercase_ ( self : str ) ->MetricInfo: return datasets.MetricInfo( description=_DESCRIPTION, citation=_CITATION, inputs_description=_KWARGS_DESCRIPTION, features=datasets.Features( { 'predictions': datasets.Sequence(datasets.Value('string', id='token' ), id='sequence' ), 'references': datasets.Sequence( datasets.Sequence(datasets.Value('string', id='token' ), id='sequence' ), id='references' ), } ), ) def lowercase_ ( self : str, _snake_case : List[List[List[str]]], _snake_case : List[List[str]], _snake_case : int = 1, _snake_case : int = 4, ) ->Dict[str, float]: return { "google_bleu": gleu_score.corpus_gleu( list_of_references=_snake_case, hypotheses=_snake_case, min_len=_snake_case, max_len=_snake_case ) }
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from collections import OrderedDict from typing import Mapping from ...configuration_utils import PretrainedConfig from ...onnx import OnnxConfig from ...utils import logging lowercase = logging.get_logger(__name__) lowercase = { "facebook/data2vec-text-base": "https://huggingface.co/data2vec/resolve/main/config.json", } class UpperCamelCase_ ( lowerCAmelCase_ ): '''simple docstring''' lowerCAmelCase = '''data2vec-text''' def __init__( self , a=3_05_22 , a=7_68 , a=12 , a=12 , a=30_72 , a="gelu" , a=0.1 , a=0.1 , a=5_12 , a=2 , a=0.02 , a=1E-12 , a=1 , a=0 , a=2 , a="absolute" , a=True , a=None , **a , ) -> int: super().__init__(pad_token_id=_snake_case , bos_token_id=_snake_case , eos_token_id=_snake_case , **_snake_case ) snake_case_ = vocab_size snake_case_ = hidden_size snake_case_ = num_hidden_layers snake_case_ = num_attention_heads snake_case_ = hidden_act snake_case_ = intermediate_size snake_case_ = hidden_dropout_prob snake_case_ = attention_probs_dropout_prob snake_case_ = max_position_embeddings snake_case_ = type_vocab_size snake_case_ = initializer_range snake_case_ = layer_norm_eps snake_case_ = position_embedding_type snake_case_ = use_cache snake_case_ = classifier_dropout class UpperCamelCase_ ( lowerCAmelCase_ ): '''simple docstring''' @property def _UpperCamelCase ( self ) -> Mapping[str, Mapping[int, str]]: if self.task == "multiple-choice": snake_case_ = {0: 'batch', 1: 'choice', 2: 'sequence'} else: snake_case_ = {0: 'batch', 1: 'sequence'} return OrderedDict( [ ('input_ids', dynamic_axis), ('attention_mask', dynamic_axis), ] )
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from math import factorial def lowercase_ (A : int , A : int , A : float ): if successes > trials: raise ValueError('successes must be lower or equal to trials' ) if trials < 0 or successes < 0: raise ValueError('the function is defined for non-negative integers' ) if not isinstance(A , A ) or not isinstance(A , A ): raise ValueError('the function is defined for non-negative integers' ) if not 0 < prob < 1: raise ValueError('prob has to be in range of 1 - 0' ) snake_case__ : List[Any] = (prob**successes) * ((1 - prob) ** (trials - successes)) # Calculate the binomial coefficient: n! / k!(n-k)! snake_case__ : List[str] = float(factorial(A ) ) coefficient /= factorial(A ) * factorial(trials - successes ) return probability * coefficient if __name__ == "__main__": from doctest import testmod testmod() print("Probability of 2 successes out of 4 trails") print("with probability of 0.75 is:", end=" ") print(binomial_distribution(2, 4, 0.75))
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"""simple docstring""" def lowercase (SCREAMING_SNAKE_CASE_ : int = 2_00_00_00 ) -> List[Any]: SCREAMING_SNAKE_CASE = [0 for i in range(n + 1 )] SCREAMING_SNAKE_CASE = 1 SCREAMING_SNAKE_CASE = 1 for i in range(2 , int(n**0.5 ) + 1 ): if primality_list[i] == 0: for j in range(i * i , n + 1 , SCREAMING_SNAKE_CASE_ ): SCREAMING_SNAKE_CASE = 1 SCREAMING_SNAKE_CASE = 0 for i in range(SCREAMING_SNAKE_CASE_ ): if primality_list[i] == 0: sum_of_primes += i return sum_of_primes if __name__ == "__main__": print(f'''{solution() = }''')
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from collections import UserDict from typing import Union import numpy as np import requests from ..utils import ( add_end_docstrings, logging, ) from .audio_classification import ffmpeg_read from .base import PIPELINE_INIT_ARGS, Pipeline a_ :List[Any] = logging.get_logger(__name__) @add_end_docstrings(lowerCAmelCase_ ) class snake_case__ ( lowerCAmelCase_ ): """simple docstring""" def __init__( self : Optional[Any], **_snake_case : str ) ->Dict: super().__init__(**_snake_case ) if self.framework != "pt": raise ValueError(F'''The {self.__class__} is only available in PyTorch.''' ) # No specific FOR_XXX available yet def __call__( self : Union[str, Any], _snake_case : Union[np.ndarray, bytes, str], **_snake_case : Tuple ) ->Dict: return super().__call__(_snake_case, **_snake_case ) def lowercase_ ( self : Tuple, **_snake_case : Any ) ->Union[str, Any]: snake_case__ : str = {} if "candidate_labels" in kwargs: snake_case__ : str = kwargs['candidate_labels'] if "hypothesis_template" in kwargs: snake_case__ : str = kwargs['hypothesis_template'] return preprocess_params, {}, {} def lowercase_ ( self : Dict, _snake_case : str, _snake_case : Optional[int]=None, _snake_case : List[str]="This is a sound of {}." ) ->int: if isinstance(_snake_case, _snake_case ): if audio.startswith('http://' ) or audio.startswith('https://' ): # We need to actually check for a real protocol, otherwise it's impossible to use a local file # like http_huggingface_co.png snake_case__ : List[Any] = requests.get(_snake_case ).content else: with open(_snake_case, 'rb' ) as f: snake_case__ : Union[str, Any] = f.read() if isinstance(_snake_case, _snake_case ): snake_case__ : List[Any] = ffmpeg_read(_snake_case, self.feature_extractor.sampling_rate ) if not isinstance(_snake_case, np.ndarray ): raise ValueError('We expect a numpy ndarray as input' ) if len(audio.shape ) != 1: raise ValueError('We expect a single channel audio input for ZeroShotAudioClassificationPipeline' ) snake_case__ : Tuple = self.feature_extractor( [audio], sampling_rate=self.feature_extractor.sampling_rate, return_tensors='pt' ) snake_case__ : int = candidate_labels snake_case__ : int = [hypothesis_template.format(_snake_case ) for x in candidate_labels] snake_case__ : Optional[int] = self.tokenizer(_snake_case, return_tensors=self.framework, padding=_snake_case ) snake_case__ : List[Any] = [text_inputs] return inputs def lowercase_ ( self : Optional[int], _snake_case : Optional[Any] ) ->int: snake_case__ : Optional[int] = model_inputs.pop('candidate_labels' ) snake_case__ : str = model_inputs.pop('text_inputs' ) if isinstance(text_inputs[0], _snake_case ): snake_case__ : Optional[Any] = text_inputs[0] else: # Batching case. snake_case__ : int = text_inputs[0][0] snake_case__ : Any = self.model(**_snake_case, **_snake_case ) snake_case__ : List[Any] = { 'candidate_labels': candidate_labels, 'logits': outputs.logits_per_audio, } return model_outputs def lowercase_ ( self : Union[str, Any], _snake_case : str ) ->List[str]: snake_case__ : int = model_outputs.pop('candidate_labels' ) snake_case__ : List[Any] = model_outputs['logits'][0] if self.framework == "pt": snake_case__ : Tuple = logits.softmax(dim=0 ) snake_case__ : Union[str, Any] = probs.tolist() else: raise ValueError('`tf` framework not supported.' ) snake_case__ : Union[str, Any] = [ {'score': score, 'label': candidate_label} for score, candidate_label in sorted(zip(_snake_case, _snake_case ), key=lambda _snake_case : -x[0] ) ] return result
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'''simple docstring''' import cva import numpy as np class _lowercase : '''simple docstring''' def __init__( self : Tuple , SCREAMING_SNAKE_CASE__ : float , SCREAMING_SNAKE_CASE__ : int ) -> List[Any]: if k in (0.0_4, 0.0_6): __lowerCAmelCase = k __lowerCAmelCase = window_size else: raise ValueError("""invalid k value""" ) def __str__( self : Optional[int] ) -> str: return str(self.k ) def a ( self : Optional[int] , SCREAMING_SNAKE_CASE__ : str ) -> tuple[cva.Mat, list[list[int]]]: __lowerCAmelCase = cva.imread(_snake_case , 0 ) __lowerCAmelCase = img.shape __lowerCAmelCase = [] __lowerCAmelCase = img.copy() __lowerCAmelCase = cva.cvtColor(_snake_case , cva.COLOR_GRAY2RGB ) __lowerCAmelCase = np.gradient(_snake_case ) __lowerCAmelCase = dx**2 __lowerCAmelCase = dy**2 __lowerCAmelCase = dx * dy __lowerCAmelCase = 0.0_4 __lowerCAmelCase = self.window_size // 2 for y in range(_snake_case , h - offset ): for x in range(_snake_case , w - offset ): __lowerCAmelCase = ixx[ y - offset : y + offset + 1, x - offset : x + offset + 1 ].sum() __lowerCAmelCase = iyy[ y - offset : y + offset + 1, x - offset : x + offset + 1 ].sum() __lowerCAmelCase = ixy[ y - offset : y + offset + 1, x - offset : x + offset + 1 ].sum() __lowerCAmelCase = (wxx * wyy) - (wxy**2) __lowerCAmelCase = wxx + wyy __lowerCAmelCase = det - k * (trace**2) # Can change the value if r > 0.5: corner_list.append([x, y, r] ) color_img.itemset((y, x, 0) , 0 ) color_img.itemset((y, x, 1) , 0 ) color_img.itemset((y, x, 2) , 2_55 ) return color_img, corner_list if __name__ == "__main__": _A : Dict = HarrisCorner(0.0_4, 3) _A : List[Any] = edge_detect.detect('''path_to_image''') cva.imwrite('''detect.png''', color_img)
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import collections import inspect import unittest from transformers import SwinvaConfig from transformers.testing_utils import require_torch, require_vision, slow, torch_device from transformers.utils import cached_property, is_torch_available, is_vision_available from ...test_configuration_common import ConfigTester from ...test_modeling_common import ModelTesterMixin, _config_zero_init, floats_tensor, ids_tensor from ...test_pipeline_mixin import PipelineTesterMixin if is_torch_available(): import torch from torch import nn from transformers import SwinvaForImageClassification, SwinvaForMaskedImageModeling, SwinvaModel from transformers.models.swinva.modeling_swinva import SWINV2_PRETRAINED_MODEL_ARCHIVE_LIST if is_vision_available(): from PIL import Image from transformers import AutoImageProcessor class snake_case__ : """simple docstring""" def __init__( self : Tuple, _snake_case : Any, _snake_case : int=1_3, _snake_case : Optional[int]=3_2, _snake_case : Tuple=2, _snake_case : Any=3, _snake_case : Tuple=1_6, _snake_case : Tuple=[1, 2, 1], _snake_case : Dict=[2, 2, 4], _snake_case : str=2, _snake_case : Union[str, Any]=2.0, _snake_case : Dict=True, _snake_case : Dict=0.0, _snake_case : str=0.0, _snake_case : str=0.1, _snake_case : List[str]="gelu", _snake_case : int=False, _snake_case : Optional[Any]=True, _snake_case : List[Any]=0.0_2, _snake_case : Union[str, Any]=1e-5, _snake_case : Union[str, Any]=True, _snake_case : List[Any]=None, _snake_case : Any=True, _snake_case : List[Any]=1_0, _snake_case : str=8, ) ->Union[str, Any]: snake_case__ : Any = parent snake_case__ : Tuple = batch_size snake_case__ : Tuple = image_size snake_case__ : Any = patch_size snake_case__ : Optional[int] = num_channels snake_case__ : Tuple = embed_dim snake_case__ : Any = depths snake_case__ : Any = num_heads snake_case__ : List[str] = window_size snake_case__ : Dict = mlp_ratio snake_case__ : Optional[int] = qkv_bias snake_case__ : Optional[Any] = hidden_dropout_prob snake_case__ : List[str] = attention_probs_dropout_prob snake_case__ : Union[str, Any] = drop_path_rate snake_case__ : str = hidden_act snake_case__ : Union[str, Any] = use_absolute_embeddings snake_case__ : Union[str, Any] = patch_norm snake_case__ : Any = layer_norm_eps snake_case__ : Tuple = initializer_range snake_case__ : Dict = is_training snake_case__ : Any = scope snake_case__ : Optional[Any] = use_labels snake_case__ : str = type_sequence_label_size snake_case__ : List[Any] = encoder_stride def lowercase_ ( self : Tuple ) ->str: snake_case__ : Tuple = floats_tensor([self.batch_size, self.num_channels, self.image_size, self.image_size] ) snake_case__ : List[Any] = None if self.use_labels: snake_case__ : Optional[Any] = ids_tensor([self.batch_size], self.type_sequence_label_size ) snake_case__ : Any = self.get_config() return config, pixel_values, labels def lowercase_ ( self : Optional[int] ) ->Optional[int]: return SwinvaConfig( image_size=self.image_size, patch_size=self.patch_size, num_channels=self.num_channels, embed_dim=self.embed_dim, depths=self.depths, num_heads=self.num_heads, window_size=self.window_size, mlp_ratio=self.mlp_ratio, qkv_bias=self.qkv_bias, hidden_dropout_prob=self.hidden_dropout_prob, attention_probs_dropout_prob=self.attention_probs_dropout_prob, drop_path_rate=self.drop_path_rate, hidden_act=self.hidden_act, use_absolute_embeddings=self.use_absolute_embeddings, path_norm=self.patch_norm, layer_norm_eps=self.layer_norm_eps, initializer_range=self.initializer_range, encoder_stride=self.encoder_stride, ) def lowercase_ ( self : Optional[int], _snake_case : str, _snake_case : List[str], _snake_case : int ) ->Dict: snake_case__ : List[Any] = SwinvaModel(config=_snake_case ) model.to(_snake_case ) model.eval() snake_case__ : Optional[int] = model(_snake_case ) snake_case__ : List[Any] = ((config.image_size // config.patch_size) ** 2) // (4 ** (len(config.depths ) - 1)) snake_case__ : List[Any] = int(config.embed_dim * 2 ** (len(config.depths ) - 1) ) self.parent.assertEqual(result.last_hidden_state.shape, (self.batch_size, expected_seq_len, expected_dim) ) def lowercase_ ( self : Optional[Any], _snake_case : Any, _snake_case : List[str], _snake_case : Dict ) ->List[Any]: snake_case__ : List[str] = SwinvaForMaskedImageModeling(config=_snake_case ) model.to(_snake_case ) model.eval() snake_case__ : Union[str, Any] = model(_snake_case ) self.parent.assertEqual( result.logits.shape, (self.batch_size, self.num_channels, self.image_size, self.image_size) ) # test greyscale images snake_case__ : Optional[Any] = 1 snake_case__ : Optional[int] = SwinvaForMaskedImageModeling(_snake_case ) model.to(_snake_case ) model.eval() snake_case__ : Tuple = floats_tensor([self.batch_size, 1, self.image_size, self.image_size] ) snake_case__ : Any = model(_snake_case ) self.parent.assertEqual(result.logits.shape, (self.batch_size, 1, self.image_size, self.image_size) ) def lowercase_ ( self : List[str], _snake_case : int, _snake_case : List[Any], _snake_case : Optional[int] ) ->Any: snake_case__ : Tuple = self.type_sequence_label_size snake_case__ : int = SwinvaForImageClassification(_snake_case ) model.to(_snake_case ) model.eval() snake_case__ : Tuple = model(_snake_case, labels=_snake_case ) self.parent.assertEqual(result.logits.shape, (self.batch_size, self.type_sequence_label_size) ) def lowercase_ ( self : Any ) ->Dict: snake_case__ : str = self.prepare_config_and_inputs() snake_case__ , snake_case__ , snake_case__ : List[str] = config_and_inputs snake_case__ : Union[str, Any] = {'pixel_values': pixel_values} return config, inputs_dict @require_torch class snake_case__ ( lowerCAmelCase_ , lowerCAmelCase_ , unittest.TestCase ): """simple docstring""" _SCREAMING_SNAKE_CASE = ( (SwinvaModel, SwinvaForImageClassification, SwinvaForMaskedImageModeling) if is_torch_available() else () ) _SCREAMING_SNAKE_CASE = ( {"""feature-extraction""": SwinvaModel, """image-classification""": SwinvaForImageClassification} if is_torch_available() else {} ) _SCREAMING_SNAKE_CASE = False _SCREAMING_SNAKE_CASE = False _SCREAMING_SNAKE_CASE = False _SCREAMING_SNAKE_CASE = False def lowercase_ ( self : Union[str, Any] ) ->Dict: snake_case__ : Optional[int] = SwinvaModelTester(self ) snake_case__ : int = ConfigTester(self, config_class=_snake_case, embed_dim=3_7 ) def lowercase_ ( self : Tuple ) ->int: self.config_tester.create_and_test_config_to_json_string() self.config_tester.create_and_test_config_to_json_file() self.config_tester.create_and_test_config_from_and_save_pretrained() self.config_tester.create_and_test_config_with_num_labels() self.config_tester.check_config_can_be_init_without_params() self.config_tester.check_config_arguments_init() def lowercase_ ( self : Any ) ->str: snake_case__ : int = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_model(*_snake_case ) @unittest.skip(reason='Got `CUDA error: misaligned address` with PyTorch 2.0.0.' ) def lowercase_ ( self : Any ) ->Union[str, Any]: pass @unittest.skip(reason='Swinv2 does not use inputs_embeds' ) def lowercase_ ( self : str ) ->Union[str, Any]: pass def lowercase_ ( self : Optional[Any] ) ->Union[str, Any]: snake_case__ , snake_case__ : Optional[int] = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: snake_case__ : Union[str, Any] = model_class(_snake_case ) self.assertIsInstance(model.get_input_embeddings(), (nn.Module) ) snake_case__ : Union[str, Any] = model.get_output_embeddings() self.assertTrue(x is None or isinstance(_snake_case, nn.Linear ) ) def lowercase_ ( self : List[str] ) ->Optional[int]: snake_case__ , snake_case__ : Any = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: snake_case__ : Any = model_class(_snake_case ) snake_case__ : Dict = inspect.signature(model.forward ) # signature.parameters is an OrderedDict => so arg_names order is deterministic snake_case__ : Optional[Any] = [*signature.parameters.keys()] snake_case__ : List[Any] = ['pixel_values'] self.assertListEqual(arg_names[:1], _snake_case ) def lowercase_ ( self : str ) ->Union[str, Any]: snake_case__ , snake_case__ : Any = self.model_tester.prepare_config_and_inputs_for_common() snake_case__ : int = True for model_class in self.all_model_classes: snake_case__ : str = True snake_case__ : Union[str, Any] = False snake_case__ : Tuple = True snake_case__ : int = model_class(_snake_case ) model.to(_snake_case ) model.eval() with torch.no_grad(): snake_case__ : Optional[int] = model(**self._prepare_for_class(_snake_case, _snake_case ) ) snake_case__ : List[str] = outputs.attentions snake_case__ : List[Any] = len(self.model_tester.depths ) self.assertEqual(len(_snake_case ), _snake_case ) # check that output_attentions also work using config del inputs_dict["output_attentions"] snake_case__ : str = True snake_case__ : Tuple = config.window_size**2 snake_case__ : Optional[int] = model_class(_snake_case ) model.to(_snake_case ) model.eval() with torch.no_grad(): snake_case__ : str = model(**self._prepare_for_class(_snake_case, _snake_case ) ) snake_case__ : Tuple = outputs.attentions self.assertEqual(len(_snake_case ), _snake_case ) self.assertListEqual( list(attentions[0].shape[-3:] ), [self.model_tester.num_heads[0], window_size_squared, window_size_squared], ) snake_case__ : Optional[Any] = len(_snake_case ) # Check attention is always last and order is fine snake_case__ : Optional[int] = True snake_case__ : Dict = True snake_case__ : List[Any] = model_class(_snake_case ) model.to(_snake_case ) model.eval() with torch.no_grad(): snake_case__ : Optional[int] = model(**self._prepare_for_class(_snake_case, _snake_case ) ) if hasattr(self.model_tester, 'num_hidden_states_types' ): snake_case__ : str = self.model_tester.num_hidden_states_types else: # also another +1 for reshaped_hidden_states snake_case__ : Dict = 2 self.assertEqual(out_len + added_hidden_states, len(_snake_case ) ) snake_case__ : Any = outputs.attentions self.assertEqual(len(_snake_case ), _snake_case ) self.assertListEqual( list(self_attentions[0].shape[-3:] ), [self.model_tester.num_heads[0], window_size_squared, window_size_squared], ) def lowercase_ ( self : Dict, _snake_case : Tuple, _snake_case : Any, _snake_case : int, _snake_case : Optional[int] ) ->str: snake_case__ : Dict = model_class(_snake_case ) model.to(_snake_case ) model.eval() with torch.no_grad(): snake_case__ : List[Any] = model(**self._prepare_for_class(_snake_case, _snake_case ) ) snake_case__ : Dict = outputs.hidden_states snake_case__ : int = getattr( self.model_tester, 'expected_num_hidden_layers', len(self.model_tester.depths ) + 1 ) self.assertEqual(len(_snake_case ), _snake_case ) # Swinv2 has a different seq_length snake_case__ : int = ( config.patch_size if isinstance(config.patch_size, collections.abc.Iterable ) else (config.patch_size, config.patch_size) ) snake_case__ : Optional[Any] = (image_size[1] // patch_size[1]) * (image_size[0] // patch_size[0]) self.assertListEqual( list(hidden_states[0].shape[-2:] ), [num_patches, self.model_tester.embed_dim], ) snake_case__ : Union[str, Any] = outputs.reshaped_hidden_states self.assertEqual(len(_snake_case ), _snake_case ) snake_case__ , snake_case__ , snake_case__ , snake_case__ : str = reshaped_hidden_states[0].shape snake_case__ : Any = ( reshaped_hidden_states[0].view(_snake_case, _snake_case, height * width ).permute(0, 2, 1 ) ) self.assertListEqual( list(reshaped_hidden_states.shape[-2:] ), [num_patches, self.model_tester.embed_dim], ) def lowercase_ ( self : str ) ->List[Any]: snake_case__ , snake_case__ : Any = self.model_tester.prepare_config_and_inputs_for_common() snake_case__ : List[Any] = ( self.model_tester.image_size if isinstance(self.model_tester.image_size, collections.abc.Iterable ) else (self.model_tester.image_size, self.model_tester.image_size) ) for model_class in self.all_model_classes: snake_case__ : Optional[int] = True self.check_hidden_states_output(_snake_case, _snake_case, _snake_case, _snake_case ) # check that output_hidden_states also work using config del inputs_dict["output_hidden_states"] snake_case__ : Dict = True self.check_hidden_states_output(_snake_case, _snake_case, _snake_case, _snake_case ) def lowercase_ ( self : List[str] ) ->str: snake_case__ , snake_case__ : Optional[Any] = self.model_tester.prepare_config_and_inputs_for_common() snake_case__ : List[str] = 3 snake_case__ : Union[str, Any] = ( self.model_tester.image_size if isinstance(self.model_tester.image_size, collections.abc.Iterable ) else (self.model_tester.image_size, self.model_tester.image_size) ) snake_case__ : str = ( config.patch_size if isinstance(config.patch_size, collections.abc.Iterable ) else (config.patch_size, config.patch_size) ) snake_case__ : Tuple = image_size[0] + patch_size[0] - (image_size[0] % patch_size[0]) snake_case__ : Optional[Any] = image_size[1] + patch_size[1] - (image_size[1] % patch_size[1]) for model_class in self.all_model_classes: snake_case__ : int = True self.check_hidden_states_output(_snake_case, _snake_case, _snake_case, (padded_height, padded_width) ) # check that output_hidden_states also work using config del inputs_dict["output_hidden_states"] snake_case__ : List[str] = True self.check_hidden_states_output(_snake_case, _snake_case, _snake_case, (padded_height, padded_width) ) def lowercase_ ( self : List[str] ) ->Optional[int]: snake_case__ : Any = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_for_masked_image_modeling(*_snake_case ) def lowercase_ ( self : List[Any] ) ->str: snake_case__ : Any = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_for_image_classification(*_snake_case ) @slow def lowercase_ ( self : str ) ->Union[str, Any]: for model_name in SWINV2_PRETRAINED_MODEL_ARCHIVE_LIST[:1]: snake_case__ : Dict = SwinvaModel.from_pretrained(_snake_case ) self.assertIsNotNone(_snake_case ) def lowercase_ ( self : Optional[int] ) ->List[str]: snake_case__ , snake_case__ : Any = self.model_tester.prepare_config_and_inputs_for_common() snake_case__ : List[Any] = _config_zero_init(_snake_case ) for model_class in self.all_model_classes: snake_case__ : List[str] = model_class(config=_snake_case ) for name, param in model.named_parameters(): if "embeddings" not in name and "logit_scale" not in name and param.requires_grad: self.assertIn( ((param.data.mean() * 1e9).round() / 1e9).item(), [0.0, 1.0], msg=F'''Parameter {name} of model {model_class} seems not properly initialized''', ) @require_vision @require_torch class snake_case__ ( unittest.TestCase ): """simple docstring""" @cached_property def lowercase_ ( self : Union[str, Any] ) ->List[str]: return ( AutoImageProcessor.from_pretrained('microsoft/swinv2-tiny-patch4-window8-256' ) if is_vision_available() else None ) @slow def lowercase_ ( self : int ) ->List[Any]: snake_case__ : Any = SwinvaForImageClassification.from_pretrained('microsoft/swinv2-tiny-patch4-window8-256' ).to( _snake_case ) snake_case__ : int = self.default_image_processor snake_case__ : Union[str, Any] = Image.open('./tests/fixtures/tests_samples/COCO/000000039769.png' ) snake_case__ : Optional[Any] = image_processor(images=_snake_case, return_tensors='pt' ).to(_snake_case ) # forward pass with torch.no_grad(): snake_case__ : List[str] = model(**_snake_case ) # verify the logits snake_case__ : int = torch.Size((1, 1_0_0_0) ) self.assertEqual(outputs.logits.shape, _snake_case ) snake_case__ : Optional[int] = torch.tensor([-0.3_9_4_7, -0.4_3_0_6, 0.0_0_2_6] ).to(_snake_case ) self.assertTrue(torch.allclose(outputs.logits[0, :3], _snake_case, atol=1e-4 ) )
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"""simple docstring""" import argparse import json from pathlib import Path import requests import torch from huggingface_hub import hf_hub_download from PIL import Image from transformers import ( BertTokenizer, ViltConfig, ViltForImageAndTextRetrieval, ViltForImagesAndTextClassification, ViltForMaskedLM, ViltForQuestionAnswering, ViltImageProcessor, ViltProcessor, ) from transformers.utils import logging logging.set_verbosity_info() UpperCAmelCase = logging.get_logger(__name__) def lowercase ( a__ : Dict , a__ : int=False , a__ : int=False , a__ : int=False ) -> Tuple: _UpperCamelCase = [] for i in range(config.num_hidden_layers ): # encoder layers: output projection, 2 feedforward neural networks and 2 layernorms rename_keys.append((F'''transformer.blocks.{i}.norm1.weight''', F'''vilt.encoder.layer.{i}.layernorm_before.weight''') ) rename_keys.append((F'''transformer.blocks.{i}.norm1.bias''', F'''vilt.encoder.layer.{i}.layernorm_before.bias''') ) rename_keys.append( (F'''transformer.blocks.{i}.attn.proj.weight''', F'''vilt.encoder.layer.{i}.attention.output.dense.weight''') ) rename_keys.append( (F'''transformer.blocks.{i}.attn.proj.bias''', F'''vilt.encoder.layer.{i}.attention.output.dense.bias''') ) rename_keys.append((F'''transformer.blocks.{i}.norm2.weight''', F'''vilt.encoder.layer.{i}.layernorm_after.weight''') ) rename_keys.append((F'''transformer.blocks.{i}.norm2.bias''', F'''vilt.encoder.layer.{i}.layernorm_after.bias''') ) rename_keys.append( (F'''transformer.blocks.{i}.mlp.fc1.weight''', F'''vilt.encoder.layer.{i}.intermediate.dense.weight''') ) rename_keys.append((F'''transformer.blocks.{i}.mlp.fc1.bias''', F'''vilt.encoder.layer.{i}.intermediate.dense.bias''') ) rename_keys.append((F'''transformer.blocks.{i}.mlp.fc2.weight''', F'''vilt.encoder.layer.{i}.output.dense.weight''') ) rename_keys.append((F'''transformer.blocks.{i}.mlp.fc2.bias''', F'''vilt.encoder.layer.{i}.output.dense.bias''') ) # embeddings rename_keys.extend( [ # text embeddings ('''text_embeddings.word_embeddings.weight''', '''vilt.embeddings.text_embeddings.word_embeddings.weight'''), ( '''text_embeddings.position_embeddings.weight''', '''vilt.embeddings.text_embeddings.position_embeddings.weight''', ), ('''text_embeddings.position_ids''', '''vilt.embeddings.text_embeddings.position_ids'''), ( '''text_embeddings.token_type_embeddings.weight''', '''vilt.embeddings.text_embeddings.token_type_embeddings.weight''', ), ('''text_embeddings.LayerNorm.weight''', '''vilt.embeddings.text_embeddings.LayerNorm.weight'''), ('''text_embeddings.LayerNorm.bias''', '''vilt.embeddings.text_embeddings.LayerNorm.bias'''), # patch embeddings ('''transformer.cls_token''', '''vilt.embeddings.cls_token'''), ('''transformer.patch_embed.proj.weight''', '''vilt.embeddings.patch_embeddings.projection.weight'''), ('''transformer.patch_embed.proj.bias''', '''vilt.embeddings.patch_embeddings.projection.bias'''), ('''transformer.pos_embed''', '''vilt.embeddings.position_embeddings'''), # token type embeddings ('''token_type_embeddings.weight''', '''vilt.embeddings.token_type_embeddings.weight'''), ] ) # final layernorm + pooler rename_keys.extend( [ ('''transformer.norm.weight''', '''vilt.layernorm.weight'''), ('''transformer.norm.bias''', '''vilt.layernorm.bias'''), ('''pooler.dense.weight''', '''vilt.pooler.dense.weight'''), ('''pooler.dense.bias''', '''vilt.pooler.dense.bias'''), ] ) # classifier head(s) if vqa_model: # classification head rename_keys.extend( [ ('''vqa_classifier.0.weight''', '''classifier.0.weight'''), ('''vqa_classifier.0.bias''', '''classifier.0.bias'''), ('''vqa_classifier.1.weight''', '''classifier.1.weight'''), ('''vqa_classifier.1.bias''', '''classifier.1.bias'''), ('''vqa_classifier.3.weight''', '''classifier.3.weight'''), ('''vqa_classifier.3.bias''', '''classifier.3.bias'''), ] ) elif nlvr_model: # classification head rename_keys.extend( [ ('''nlvr2_classifier.0.weight''', '''classifier.0.weight'''), ('''nlvr2_classifier.0.bias''', '''classifier.0.bias'''), ('''nlvr2_classifier.1.weight''', '''classifier.1.weight'''), ('''nlvr2_classifier.1.bias''', '''classifier.1.bias'''), ('''nlvr2_classifier.3.weight''', '''classifier.3.weight'''), ('''nlvr2_classifier.3.bias''', '''classifier.3.bias'''), ] ) else: pass return rename_keys def lowercase ( a__ : List[str] , a__ : List[Any] ) -> List[str]: for i in range(config.num_hidden_layers ): _UpperCamelCase = 'vilt.' # read in weights + bias of input projection layer (in timm, this is a single matrix + bias) _UpperCamelCase = state_dict.pop(F'''transformer.blocks.{i}.attn.qkv.weight''' ) _UpperCamelCase = state_dict.pop(F'''transformer.blocks.{i}.attn.qkv.bias''' ) # next, add query, keys and values (in that order) to the state dict _UpperCamelCase = in_proj_weight[ : config.hidden_size, : ] _UpperCamelCase = in_proj_bias[: config.hidden_size] _UpperCamelCase = in_proj_weight[ config.hidden_size : config.hidden_size * 2, : ] _UpperCamelCase = in_proj_bias[ config.hidden_size : config.hidden_size * 2 ] _UpperCamelCase = in_proj_weight[ -config.hidden_size :, : ] _UpperCamelCase = in_proj_bias[-config.hidden_size :] def lowercase ( a__ : int ) -> Any: _UpperCamelCase = ['head.weight', 'head.bias'] for k in ignore_keys: state_dict.pop(a__ , a__ ) def lowercase ( a__ : int , a__ : List[Any] , a__ : List[str] ) -> Dict: _UpperCamelCase = dct.pop(a__ ) _UpperCamelCase = val @torch.no_grad() def lowercase ( a__ : int , a__ : Union[str, Any] ) -> Any: _UpperCamelCase = ViltConfig(image_size=384 , patch_size=32 , tie_word_embeddings=a__ ) _UpperCamelCase = False _UpperCamelCase = False _UpperCamelCase = False _UpperCamelCase = False if "vqa" in checkpoint_url: _UpperCamelCase = True _UpperCamelCase = 3129 _UpperCamelCase = 'huggingface/label-files' _UpperCamelCase = 'vqa2-id2label.json' _UpperCamelCase = json.load(open(hf_hub_download(a__ , a__ , repo_type='''dataset''' ) , '''r''' ) ) _UpperCamelCase = {int(a__ ): v for k, v in idalabel.items()} _UpperCamelCase = idalabel _UpperCamelCase = {v: k for k, v in idalabel.items()} _UpperCamelCase = ViltForQuestionAnswering(a__ ) elif "nlvr" in checkpoint_url: _UpperCamelCase = True _UpperCamelCase = 2 _UpperCamelCase = {0: 'False', 1: 'True'} _UpperCamelCase = {v: k for k, v in config.idalabel.items()} _UpperCamelCase = 3 _UpperCamelCase = ViltForImagesAndTextClassification(a__ ) elif "irtr" in checkpoint_url: _UpperCamelCase = True _UpperCamelCase = ViltForImageAndTextRetrieval(a__ ) elif "mlm_itm" in checkpoint_url: _UpperCamelCase = True _UpperCamelCase = ViltForMaskedLM(a__ ) else: raise ValueError('''Unknown model type''' ) # load state_dict of original model, remove and rename some keys _UpperCamelCase = torch.hub.load_state_dict_from_url(a__ , map_location='''cpu''' )['state_dict'] _UpperCamelCase = create_rename_keys(a__ , a__ , a__ , a__ ) for src, dest in rename_keys: rename_key(a__ , a__ , a__ ) read_in_q_k_v(a__ , a__ ) if mlm_model or irtr_model: _UpperCamelCase = ['itm_score.fc.weight', 'itm_score.fc.bias'] for k in ignore_keys: state_dict.pop(a__ , a__ ) # load state dict into HuggingFace model model.eval() if mlm_model: _UpperCamelCase = model.load_state_dict(a__ , strict=a__ ) assert missing_keys == ["mlm_score.decoder.bias"] else: model.load_state_dict(a__ ) # Define processor _UpperCamelCase = ViltImageProcessor(size=384 ) _UpperCamelCase = BertTokenizer.from_pretrained('''bert-base-uncased''' ) _UpperCamelCase = ViltProcessor(a__ , a__ ) # Forward pass on example inputs (image + text) if nlvr_model: _UpperCamelCase = Image.open(requests.get('''https://lil.nlp.cornell.edu/nlvr/exs/ex0_0.jpg''' , stream=a__ ).raw ) _UpperCamelCase = Image.open(requests.get('''https://lil.nlp.cornell.edu/nlvr/exs/ex0_0.jpg''' , stream=a__ ).raw ) _UpperCamelCase = ( 'The left image contains twice the number of dogs as the right image, and at least two dogs in total are' ' standing.' ) _UpperCamelCase = processor(a__ , a__ , return_tensors='''pt''' ) _UpperCamelCase = processor(a__ , a__ , return_tensors='''pt''' ) _UpperCamelCase = model( input_ids=encoding_a.input_ids , pixel_values=encoding_a.pixel_values , pixel_values_a=encoding_a.pixel_values , ) else: _UpperCamelCase = Image.open(requests.get('''http://images.cocodataset.org/val2017/000000039769.jpg''' , stream=a__ ).raw ) if mlm_model: _UpperCamelCase = 'a bunch of [MASK] laying on a [MASK].' else: _UpperCamelCase = 'How many cats are there?' _UpperCamelCase = processor(a__ , a__ , return_tensors='''pt''' ) _UpperCamelCase = model(**a__ ) # Verify outputs if mlm_model: _UpperCamelCase = torch.Size([1, 11, 30522] ) _UpperCamelCase = torch.tensor([-12.5061, -12.5123, -12.5174] ) assert outputs.logits.shape == expected_shape assert torch.allclose(outputs.logits[0, 0, :3] , a__ , atol=1e-4 ) # verify masked token prediction equals "cats" _UpperCamelCase = outputs.logits[0, 4, :].argmax(-1 ).item() assert tokenizer.decode([predicted_id] ) == "cats" elif vqa_model: _UpperCamelCase = torch.Size([1, 3129] ) _UpperCamelCase = torch.tensor([-15.9495, -18.1472, -10.3041] ) assert torch.allclose(outputs.logits[0, :3] , a__ , atol=1e-4 ) assert outputs.logits.shape == expected_shape assert torch.allclose(outputs.logits[0, 0, :3] , a__ , atol=1e-4 ) # verify vqa prediction equals "2" _UpperCamelCase = outputs.logits.argmax(-1 ).item() assert model.config.idalabel[predicted_idx] == "2" elif nlvr_model: _UpperCamelCase = torch.Size([1, 2] ) _UpperCamelCase = torch.tensor([-2.8721, 2.1291] ) assert torch.allclose(outputs.logits[0, :3] , a__ , atol=1e-4 ) assert outputs.logits.shape == expected_shape Path(a__ ).mkdir(exist_ok=a__ ) print(F'''Saving model and processor to {pytorch_dump_folder_path}''' ) model.save_pretrained(a__ ) processor.save_pretrained(a__ ) if __name__ == "__main__": UpperCAmelCase = argparse.ArgumentParser() # Required parameters parser.add_argument( """--checkpoint_url""", default="""https://github.com/dandelin/ViLT/releases/download/200k/vilt_200k_mlm_itm.ckpt""", type=str, help="""URL of the checkpoint you'd like to convert.""", ) parser.add_argument( """--pytorch_dump_folder_path""", default=None, type=str, help="""Path to the output PyTorch model directory.""" ) UpperCAmelCase = parser.parse_args() convert_vilt_checkpoint(args.checkpoint_url, args.pytorch_dump_folder_path)
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import unittest import numpy as np from transformers.testing_utils import require_torch, require_vision from transformers.utils import is_torch_available, is_vision_available from ...test_image_processing_common import ImageProcessingSavingTestMixin, prepare_image_inputs if is_torch_available(): import torch if is_vision_available(): from PIL import Image from transformers import PoolFormerImageProcessor class snake_case__ ( unittest.TestCase ): """simple docstring""" def __init__( self : Optional[int], _snake_case : List[Any], _snake_case : str=7, _snake_case : Tuple=3, _snake_case : List[str]=3_0, _snake_case : Tuple=4_0_0, _snake_case : Any=True, _snake_case : List[Any]=None, _snake_case : int=0.9, _snake_case : Optional[Any]=None, _snake_case : str=True, _snake_case : Union[str, Any]=[0.5, 0.5, 0.5], _snake_case : Union[str, Any]=[0.5, 0.5, 0.5], ) ->List[Any]: snake_case__ : int = size if size is not None else {'shortest_edge': 3_0} snake_case__ : Tuple = crop_size if crop_size is not None else {'height': 3_0, 'width': 3_0} snake_case__ : Union[str, Any] = parent snake_case__ : Dict = batch_size snake_case__ : int = num_channels snake_case__ : Tuple = min_resolution snake_case__ : Any = max_resolution snake_case__ : List[Any] = do_resize_and_center_crop snake_case__ : str = size snake_case__ : str = crop_pct snake_case__ : List[str] = crop_size snake_case__ : Optional[int] = do_normalize snake_case__ : Tuple = image_mean snake_case__ : Tuple = image_std def lowercase_ ( self : Optional[int] ) ->int: return { "size": self.size, "do_resize_and_center_crop": self.do_resize_and_center_crop, "crop_pct": self.crop_pct, "crop_size": self.crop_size, "do_normalize": self.do_normalize, "image_mean": self.image_mean, "image_std": self.image_std, } @require_torch @require_vision class snake_case__ ( lowerCAmelCase_ , unittest.TestCase ): """simple docstring""" _SCREAMING_SNAKE_CASE = PoolFormerImageProcessor if is_vision_available() else None def lowercase_ ( self : Union[str, Any] ) ->Dict: snake_case__ : Union[str, Any] = PoolFormerImageProcessingTester(self ) @property def lowercase_ ( self : int ) ->Dict: return self.image_processor_tester.prepare_image_processor_dict() def lowercase_ ( self : Union[str, Any] ) ->Optional[int]: snake_case__ : List[str] = self.image_processing_class(**self.image_processor_dict ) self.assertTrue(hasattr(_snake_case, 'do_resize_and_center_crop' ) ) self.assertTrue(hasattr(_snake_case, 'size' ) ) self.assertTrue(hasattr(_snake_case, 'crop_pct' ) ) self.assertTrue(hasattr(_snake_case, 'do_normalize' ) ) self.assertTrue(hasattr(_snake_case, 'image_mean' ) ) self.assertTrue(hasattr(_snake_case, 'image_std' ) ) def lowercase_ ( self : List[str] ) ->List[str]: snake_case__ : Union[str, Any] = self.image_processing_class.from_dict(self.image_processor_dict ) self.assertEqual(image_processor.size, {'shortest_edge': 3_0} ) self.assertEqual(image_processor.crop_size, {'height': 3_0, 'width': 3_0} ) snake_case__ : int = self.image_processing_class.from_dict(self.image_processor_dict, size=4_2, crop_size=8_4 ) self.assertEqual(image_processor.size, {'shortest_edge': 4_2} ) self.assertEqual(image_processor.crop_size, {'height': 8_4, 'width': 8_4} ) def lowercase_ ( self : List[Any] ) ->List[Any]: pass def lowercase_ ( self : List[str] ) ->str: # Initialize image_processing snake_case__ : Union[str, Any] = self.image_processing_class(**self.image_processor_dict ) # create random PIL images snake_case__ : List[str] = prepare_image_inputs(self.image_processor_tester, equal_resolution=_snake_case ) for image in image_inputs: self.assertIsInstance(_snake_case, Image.Image ) # Test not batched input snake_case__ : Optional[int] = image_processing(image_inputs[0], return_tensors='pt' ).pixel_values self.assertEqual( encoded_images.shape, ( 1, self.image_processor_tester.num_channels, self.image_processor_tester.crop_size['height'], self.image_processor_tester.crop_size['width'], ), ) # Test batched snake_case__ : str = image_processing(_snake_case, return_tensors='pt' ).pixel_values self.assertEqual( encoded_images.shape, ( self.image_processor_tester.batch_size, self.image_processor_tester.num_channels, self.image_processor_tester.crop_size['height'], self.image_processor_tester.crop_size['width'], ), ) def lowercase_ ( self : int ) ->List[Any]: # Initialize image_processing snake_case__ : Optional[int] = self.image_processing_class(**self.image_processor_dict ) # create random numpy tensors snake_case__ : Dict = prepare_image_inputs(self.image_processor_tester, equal_resolution=_snake_case, numpify=_snake_case ) for image in image_inputs: self.assertIsInstance(_snake_case, np.ndarray ) # Test not batched input snake_case__ : Dict = image_processing(image_inputs[0], return_tensors='pt' ).pixel_values self.assertEqual( encoded_images.shape, ( 1, self.image_processor_tester.num_channels, self.image_processor_tester.crop_size['height'], self.image_processor_tester.crop_size['width'], ), ) # Test batched snake_case__ : List[Any] = image_processing(_snake_case, return_tensors='pt' ).pixel_values self.assertEqual( encoded_images.shape, ( self.image_processor_tester.batch_size, self.image_processor_tester.num_channels, self.image_processor_tester.crop_size['height'], self.image_processor_tester.crop_size['width'], ), ) def lowercase_ ( self : List[str] ) ->List[str]: # Initialize image_processing snake_case__ : Tuple = self.image_processing_class(**self.image_processor_dict ) # create random PyTorch tensors snake_case__ : List[str] = prepare_image_inputs(self.image_processor_tester, equal_resolution=_snake_case, torchify=_snake_case ) for image in image_inputs: self.assertIsInstance(_snake_case, torch.Tensor ) # Test not batched input snake_case__ : Tuple = image_processing(image_inputs[0], return_tensors='pt' ).pixel_values self.assertEqual( encoded_images.shape, ( 1, self.image_processor_tester.num_channels, self.image_processor_tester.crop_size['height'], self.image_processor_tester.crop_size['width'], ), ) # Test batched snake_case__ : Optional[Any] = image_processing(_snake_case, return_tensors='pt' ).pixel_values self.assertEqual( encoded_images.shape, ( self.image_processor_tester.batch_size, self.image_processor_tester.num_channels, self.image_processor_tester.crop_size['height'], self.image_processor_tester.crop_size['width'], ), )
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import itertools import random import unittest import numpy as np from transformers import BatchFeature, SpeechTaFeatureExtractor from transformers.testing_utils import require_torch from transformers.utils.import_utils import is_torch_available from ...test_sequence_feature_extraction_common import SequenceFeatureExtractionTestMixin if is_torch_available(): import torch _a = random.Random() def _a ( SCREAMING_SNAKE_CASE : int , SCREAMING_SNAKE_CASE : Union[str, Any]=1.0 , SCREAMING_SNAKE_CASE : List[str]=None , SCREAMING_SNAKE_CASE : Any=None ) -> Any: """simple docstring""" if rng is None: __lowerCAmelCase: List[str] = global_rng __lowerCAmelCase: int = [] for batch_idx in range(shape[0] ): values.append([] ) for _ in range(shape[1] ): values[-1].append(rng.random() * scale ) return values @require_torch class A_ ( unittest.TestCase ): def __init__( self : Optional[Any] , UpperCAmelCase : List[str] , UpperCAmelCase : Tuple=7 , UpperCAmelCase : Union[str, Any]=4_0_0 , UpperCAmelCase : Any=2_0_0_0 , UpperCAmelCase : Dict=1 , UpperCAmelCase : Optional[Any]=0.0 , UpperCAmelCase : List[Any]=1_6_0_0_0 , UpperCAmelCase : List[Any]=True , UpperCAmelCase : List[Any]=8_0 , UpperCAmelCase : Dict=1_6 , UpperCAmelCase : str=6_4 , UpperCAmelCase : Tuple="hann_window" , UpperCAmelCase : Union[str, Any]=8_0 , UpperCAmelCase : Optional[Any]=7_6_0_0 , UpperCAmelCase : str=1E-10 , UpperCAmelCase : Any=True , ) -> Union[str, Any]: __lowerCAmelCase: Optional[int] = parent __lowerCAmelCase: Optional[Any] = batch_size __lowerCAmelCase: List[Any] = min_seq_length __lowerCAmelCase: List[Any] = max_seq_length __lowerCAmelCase: Any = (self.max_seq_length - self.min_seq_length) // (self.batch_size - 1) __lowerCAmelCase: Tuple = feature_size __lowerCAmelCase: List[Any] = padding_value __lowerCAmelCase: Any = sampling_rate __lowerCAmelCase: Dict = do_normalize __lowerCAmelCase: Union[str, Any] = num_mel_bins __lowerCAmelCase: Any = hop_length __lowerCAmelCase: Any = win_length __lowerCAmelCase: Any = win_function __lowerCAmelCase: Optional[int] = fmin __lowerCAmelCase: int = fmax __lowerCAmelCase: Union[str, Any] = mel_floor __lowerCAmelCase: Union[str, Any] = return_attention_mask def UpperCAmelCase ( self : Optional[int] ) -> List[str]: return { "feature_size": self.feature_size, "padding_value": self.padding_value, "sampling_rate": self.sampling_rate, "do_normalize": self.do_normalize, "num_mel_bins": self.num_mel_bins, "hop_length": self.hop_length, "win_length": self.win_length, "win_function": self.win_function, "fmin": self.fmin, "fmax": self.fmax, "mel_floor": self.mel_floor, "return_attention_mask": self.return_attention_mask, } def UpperCAmelCase ( self : Any , UpperCAmelCase : Optional[Any]=False , UpperCAmelCase : List[str]=False ) -> Union[str, Any]: def _flatten(UpperCAmelCase : List[str] ): return list(itertools.chain(*_snake_case ) ) if equal_length: __lowerCAmelCase: Any = floats_list((self.batch_size, self.max_seq_length) ) else: # make sure that inputs increase in size __lowerCAmelCase: int = [ _flatten(floats_list((x, self.feature_size) ) ) for x in range(self.min_seq_length , self.max_seq_length , self.seq_length_diff ) ] if numpify: __lowerCAmelCase: Any = [np.asarray(_snake_case ) for x in speech_inputs] return speech_inputs def UpperCAmelCase ( self : Union[str, Any] , UpperCAmelCase : str=False , UpperCAmelCase : Dict=False ) -> List[str]: if equal_length: __lowerCAmelCase: Optional[Any] = [floats_list((self.max_seq_length, self.num_mel_bins) ) for _ in range(self.batch_size )] else: # make sure that inputs increase in size __lowerCAmelCase: List[str] = [ floats_list((x, self.num_mel_bins) ) for x in range(self.min_seq_length , self.max_seq_length , self.seq_length_diff ) ] if numpify: __lowerCAmelCase: int = [np.asarray(_snake_case ) for x in speech_inputs] return speech_inputs @require_torch class A_ ( lowerCAmelCase_ , unittest.TestCase ): _lowercase : int = SpeechTaFeatureExtractor def UpperCAmelCase ( self : int ) -> Union[str, Any]: __lowerCAmelCase: List[str] = SpeechTaFeatureExtractionTester(self ) def UpperCAmelCase ( self : Any , UpperCAmelCase : Dict ) -> Any: self.assertTrue(np.all(np.mean(_snake_case , axis=0 ) < 1E-3 ) ) self.assertTrue(np.all(np.abs(np.var(_snake_case , axis=0 ) - 1 ) < 1E-3 ) ) def UpperCAmelCase ( self : List[Any] ) -> Union[str, Any]: # Tests that all call wrap to encode_plus and batch_encode_plus __lowerCAmelCase: Optional[Any] = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) # create three inputs of length 800, 1000, and 1200 __lowerCAmelCase: int = [floats_list((1, x) )[0] for x in range(8_0_0 , 1_4_0_0 , 2_0_0 )] __lowerCAmelCase: Tuple = [np.asarray(_snake_case ) for speech_input in speech_inputs] # Test not batched input __lowerCAmelCase: str = feat_extract(speech_inputs[0] , return_tensors='np' ).input_values __lowerCAmelCase: List[str] = feat_extract(np_speech_inputs[0] , return_tensors='np' ).input_values self.assertTrue(np.allclose(_snake_case , _snake_case , atol=1E-3 ) ) # Test batched __lowerCAmelCase: Any = feat_extract(_snake_case , return_tensors='np' ).input_values __lowerCAmelCase: Union[str, Any] = feat_extract(_snake_case , return_tensors='np' ).input_values for enc_seq_a, enc_seq_a in zip(_snake_case , _snake_case ): self.assertTrue(np.allclose(_snake_case , _snake_case , atol=1E-3 ) ) def UpperCAmelCase ( self : int ) -> Optional[int]: __lowerCAmelCase: List[Any] = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) __lowerCAmelCase: Tuple = [floats_list((1, x) )[0] for x in range(8_0_0 , 1_4_0_0 , 2_0_0 )] __lowerCAmelCase: int = ['longest', 'max_length', 'do_not_pad'] __lowerCAmelCase: List[str] = [None, 1_6_0_0, None] for max_length, padding in zip(_snake_case , _snake_case ): __lowerCAmelCase: Optional[int] = feat_extract(_snake_case , padding=_snake_case , max_length=_snake_case , return_tensors='np' ) __lowerCAmelCase: Optional[int] = processed.input_values self._check_zero_mean_unit_variance(input_values[0][:8_0_0] ) self.assertTrue(input_values[0][8_0_0:].sum() < 1E-6 ) self._check_zero_mean_unit_variance(input_values[1][:1_0_0_0] ) self.assertTrue(input_values[0][1_0_0_0:].sum() < 1E-6 ) self._check_zero_mean_unit_variance(input_values[2][:1_2_0_0] ) def UpperCAmelCase ( self : Union[str, Any] ) -> Optional[Any]: __lowerCAmelCase: Optional[Any] = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) __lowerCAmelCase: Tuple = range(8_0_0 , 1_4_0_0 , 2_0_0 ) __lowerCAmelCase: Optional[Any] = [floats_list((1, x) )[0] for x in lengths] __lowerCAmelCase: Union[str, Any] = ['longest', 'max_length', 'do_not_pad'] __lowerCAmelCase: str = [None, 1_6_0_0, None] for max_length, padding in zip(_snake_case , _snake_case ): __lowerCAmelCase: List[str] = feat_extract(_snake_case , max_length=_snake_case , padding=_snake_case ) __lowerCAmelCase: Tuple = processed.input_values self._check_zero_mean_unit_variance(input_values[0][:8_0_0] ) self._check_zero_mean_unit_variance(input_values[1][:1_0_0_0] ) self._check_zero_mean_unit_variance(input_values[2][:1_2_0_0] ) def UpperCAmelCase ( self : List[Any] ) -> Optional[Any]: __lowerCAmelCase: Any = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) __lowerCAmelCase: str = [floats_list((1, x) )[0] for x in range(8_0_0 , 1_4_0_0 , 2_0_0 )] __lowerCAmelCase: Optional[Any] = feat_extract( _snake_case , truncation=_snake_case , max_length=1_0_0_0 , padding='max_length' , return_tensors='np' ) __lowerCAmelCase: int = processed.input_values self._check_zero_mean_unit_variance(input_values[0, :8_0_0] ) self._check_zero_mean_unit_variance(input_values[1] ) self._check_zero_mean_unit_variance(input_values[2] ) def UpperCAmelCase ( self : int ) -> Union[str, Any]: __lowerCAmelCase: str = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) __lowerCAmelCase: Dict = [floats_list((1, x) )[0] for x in range(8_0_0 , 1_4_0_0 , 2_0_0 )] __lowerCAmelCase: str = feat_extract( _snake_case , truncation=_snake_case , max_length=1_0_0_0 , padding='longest' , return_tensors='np' ) __lowerCAmelCase: Dict = processed.input_values self._check_zero_mean_unit_variance(input_values[0, :8_0_0] ) self._check_zero_mean_unit_variance(input_values[1, :1_0_0_0] ) self._check_zero_mean_unit_variance(input_values[2] ) # make sure that if max_length < longest -> then pad to max_length self.assertTrue(input_values.shape == (3, 1_0_0_0) ) __lowerCAmelCase: Tuple = [floats_list((1, x) )[0] for x in range(8_0_0 , 1_4_0_0 , 2_0_0 )] __lowerCAmelCase: List[str] = feat_extract( _snake_case , truncation=_snake_case , max_length=2_0_0_0 , padding='longest' , return_tensors='np' ) __lowerCAmelCase: Optional[Any] = processed.input_values self._check_zero_mean_unit_variance(input_values[0, :8_0_0] ) self._check_zero_mean_unit_variance(input_values[1, :1_0_0_0] ) self._check_zero_mean_unit_variance(input_values[2] ) # make sure that if max_length > longest -> then pad to longest self.assertTrue(input_values.shape == (3, 1_2_0_0) ) def UpperCAmelCase ( self : List[str] ) -> Dict: __lowerCAmelCase: Dict = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) __lowerCAmelCase: List[Any] = np.random.rand(1_0_0 ).astype(np.floataa ) __lowerCAmelCase: int = np_speech_inputs.tolist() for inputs in [py_speech_inputs, np_speech_inputs]: __lowerCAmelCase: int = feature_extractor.pad([{'input_values': inputs}] , return_tensors='np' ) self.assertTrue(np_processed.input_values.dtype == np.floataa ) __lowerCAmelCase: Optional[int] = feature_extractor.pad([{'input_values': inputs}] , return_tensors='pt' ) self.assertTrue(pt_processed.input_values.dtype == torch.floataa ) def UpperCAmelCase ( self : Optional[int] ) -> Optional[Any]: # Tests that all call wrap to encode_plus and batch_encode_plus __lowerCAmelCase: str = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) # create three inputs of length 800, 1000, and 1200 __lowerCAmelCase: List[Any] = [floats_list((1, x) )[0] for x in range(8_0_0 , 1_4_0_0 , 2_0_0 )] __lowerCAmelCase: Dict = [np.asarray(_snake_case ) for speech_input in speech_inputs] # Test feature size __lowerCAmelCase: Optional[int] = feature_extractor(audio_target=_snake_case , padding=_snake_case , return_tensors='np' ).input_values self.assertTrue(input_values.ndim == 3 ) self.assertTrue(input_values.shape[-1] == feature_extractor.num_mel_bins ) # Test not batched input __lowerCAmelCase: Dict = feature_extractor(speech_inputs[0] , return_tensors='np' ).input_values __lowerCAmelCase: Any = feature_extractor(np_speech_inputs[0] , return_tensors='np' ).input_values self.assertTrue(np.allclose(_snake_case , _snake_case , atol=1E-3 ) ) # Test batched __lowerCAmelCase: Dict = feature_extractor(_snake_case , return_tensors='np' ).input_values __lowerCAmelCase: Dict = feature_extractor(_snake_case , return_tensors='np' ).input_values for enc_seq_a, enc_seq_a in zip(_snake_case , _snake_case ): self.assertTrue(np.allclose(_snake_case , _snake_case , atol=1E-3 ) ) # Test 2-D numpy arrays are batched. __lowerCAmelCase: Optional[Any] = [floats_list((1, x) )[0] for x in (8_0_0, 8_0_0, 8_0_0)] __lowerCAmelCase: int = np.asarray(_snake_case ) __lowerCAmelCase: Union[str, Any] = feature_extractor(_snake_case , return_tensors='np' ).input_values __lowerCAmelCase: Union[str, Any] = feature_extractor(_snake_case , return_tensors='np' ).input_values for enc_seq_a, enc_seq_a in zip(_snake_case , _snake_case ): self.assertTrue(np.allclose(_snake_case , _snake_case , atol=1E-3 ) ) def UpperCAmelCase ( self : Union[str, Any] ) -> str: __lowerCAmelCase: int = self.feat_extract_tester.prepare_inputs_for_target() __lowerCAmelCase: List[str] = self.feature_extraction_class(**self.feat_extract_dict ) __lowerCAmelCase: Optional[Any] = feat_extract.model_input_names[0] __lowerCAmelCase: Tuple = BatchFeature({input_name: speech_inputs} ) self.assertTrue(all(len(_snake_case ) == len(_snake_case ) for x, y in zip(_snake_case , processed_features[input_name] ) ) ) __lowerCAmelCase: int = self.feat_extract_tester.prepare_inputs_for_target(equal_length=_snake_case ) __lowerCAmelCase: Union[str, Any] = BatchFeature({input_name: speech_inputs} , tensor_type='np' ) __lowerCAmelCase: Dict = processed_features[input_name] if len(batch_features_input.shape ) < 3: __lowerCAmelCase: List[str] = batch_features_input[:, :, None] self.assertTrue( batch_features_input.shape == (self.feat_extract_tester.batch_size, len(speech_inputs[0] ), self.feat_extract_tester.num_mel_bins) ) @require_torch def UpperCAmelCase ( self : List[str] ) -> Any: __lowerCAmelCase: int = self.feat_extract_tester.prepare_inputs_for_target(equal_length=_snake_case ) __lowerCAmelCase: Optional[Any] = self.feature_extraction_class(**self.feat_extract_dict ) __lowerCAmelCase: Tuple = feat_extract.model_input_names[0] __lowerCAmelCase: List[Any] = BatchFeature({input_name: speech_inputs} , tensor_type='pt' ) __lowerCAmelCase: Tuple = processed_features[input_name] if len(batch_features_input.shape ) < 3: __lowerCAmelCase: Any = batch_features_input[:, :, None] self.assertTrue( batch_features_input.shape == (self.feat_extract_tester.batch_size, len(speech_inputs[0] ), self.feat_extract_tester.num_mel_bins) ) @require_torch def UpperCAmelCase ( self : Optional[int] ) -> Tuple: __lowerCAmelCase: Dict = self.feature_extraction_class(**self.feat_extract_dict ) __lowerCAmelCase: Union[str, Any] = self.feat_extract_tester.prepare_inputs_for_target() __lowerCAmelCase: Optional[Any] = feat_extract.model_input_names[0] __lowerCAmelCase: List[str] = BatchFeature({input_name: speech_inputs} ) __lowerCAmelCase: int = feat_extract.num_mel_bins # hack! __lowerCAmelCase: Tuple = feat_extract.pad(_snake_case , padding='longest' , return_tensors='np' )[input_name] __lowerCAmelCase: Union[str, Any] = feat_extract.pad(_snake_case , padding='longest' , return_tensors='pt' )[input_name] self.assertTrue(abs(input_np.astype(np.floataa ).sum() - input_pt.numpy().astype(np.floataa ).sum() ) < 1E-2 ) def UpperCAmelCase ( self : int ) -> Any: __lowerCAmelCase: Any = self.feat_extract_dict __lowerCAmelCase: List[Any] = True __lowerCAmelCase: Union[str, Any] = self.feature_extraction_class(**_snake_case ) __lowerCAmelCase: Any = self.feat_extract_tester.prepare_inputs_for_target() __lowerCAmelCase: List[Any] = [len(_snake_case ) for x in speech_inputs] __lowerCAmelCase: Union[str, Any] = feat_extract.model_input_names[0] __lowerCAmelCase: Optional[int] = BatchFeature({input_name: speech_inputs} ) __lowerCAmelCase: List[str] = feat_extract.num_mel_bins # hack! __lowerCAmelCase: str = feat_extract.pad(_snake_case , padding='longest' , return_tensors='np' ) self.assertIn('attention_mask' , _snake_case ) self.assertListEqual(list(processed.attention_mask.shape ) , list(processed[input_name].shape[:2] ) ) self.assertListEqual(processed.attention_mask.sum(-1 ).tolist() , _snake_case ) def UpperCAmelCase ( self : Optional[int] ) -> str: __lowerCAmelCase: int = self.feat_extract_dict __lowerCAmelCase: List[str] = True __lowerCAmelCase: Tuple = self.feature_extraction_class(**_snake_case ) __lowerCAmelCase: List[str] = self.feat_extract_tester.prepare_inputs_for_target() __lowerCAmelCase: str = [len(_snake_case ) for x in speech_inputs] __lowerCAmelCase: Optional[Any] = feat_extract.model_input_names[0] __lowerCAmelCase: Optional[int] = BatchFeature({input_name: speech_inputs} ) __lowerCAmelCase: Optional[Any] = min(_snake_case ) __lowerCAmelCase: Union[str, Any] = feat_extract.num_mel_bins # hack! __lowerCAmelCase: Tuple = feat_extract.pad( _snake_case , padding='max_length' , max_length=_snake_case , truncation=_snake_case , return_tensors='np' ) self.assertIn('attention_mask' , _snake_case ) self.assertListEqual( list(processed_pad.attention_mask.shape ) , [processed_pad[input_name].shape[0], max_length] ) self.assertListEqual( processed_pad.attention_mask[:, :max_length].sum(-1 ).tolist() , [max_length for x in speech_inputs] ) def UpperCAmelCase ( self : List[Any] , UpperCAmelCase : Optional[int] ) -> Optional[Any]: from datasets import load_dataset __lowerCAmelCase: str = load_dataset('hf-internal-testing/librispeech_asr_dummy' , 'clean' , split='validation' ) # automatic decoding with librispeech __lowerCAmelCase: Dict = ds.sort('id' ).select(range(_snake_case ) )[:num_samples]['audio'] return [x["array"] for x in speech_samples] def UpperCAmelCase ( self : str ) -> str: # fmt: off __lowerCAmelCase: List[Any] = torch.tensor( [2.38_04E-03, 2.07_52E-03, 1.98_36E-03, 2.10_57E-03, 1.61_74E-03, 3.05_18E-04, 9.15_53E-05, 3.35_69E-04, 9.76_56E-04, 1.83_11E-03, 2.01_42E-03, 2.10_57E-03, 1.73_95E-03, 4.57_76E-04, -3.96_73E-04, 4.57_76E-04, 1.00_71E-03, 9.15_53E-05, 4.88_28E-04, 1.15_97E-03, 7.32_42E-04, 9.46_04E-04, 1.80_05E-03, 1.83_11E-03, 8.85_01E-04, 4.27_25E-04, 4.88_28E-04, 7.32_42E-04, 1.09_86E-03, 2.10_57E-03] ) # fmt: on __lowerCAmelCase: Union[str, Any] = self._load_datasamples(1 ) __lowerCAmelCase: Optional[int] = SpeechTaFeatureExtractor() __lowerCAmelCase: List[Any] = feature_extractor(_snake_case , return_tensors='pt' ).input_values self.assertEquals(input_values.shape , (1, 9_3_6_8_0) ) self.assertTrue(torch.allclose(input_values[0, :3_0] , _snake_case , atol=1E-6 ) ) def UpperCAmelCase ( self : Any ) -> str: # fmt: off __lowerCAmelCase: Optional[Any] = torch.tensor( [-2.6870, -3.0104, -3.1356, -3.5352, -3.0044, -3.0353, -3.4719, -3.6777, -3.1520, -2.9435, -2.6553, -2.8795, -2.9944, -2.5921, -3.0279, -3.0386, -3.0864, -3.1291, -3.2353, -2.7444, -2.6831, -2.7287, -3.1761, -3.1571, -3.2726, -3.0582, -3.1007, -3.4533, -3.4695, -3.0998] ) # fmt: on __lowerCAmelCase: List[str] = self._load_datasamples(1 ) __lowerCAmelCase: str = SpeechTaFeatureExtractor() __lowerCAmelCase: Optional[Any] = feature_extractor(audio_target=_snake_case , return_tensors='pt' ).input_values self.assertEquals(input_values.shape , (1, 3_6_6, 8_0) ) self.assertTrue(torch.allclose(input_values[0, 0, :3_0] , _snake_case , atol=1E-4 ) )
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from collections import deque from .hash_table import HashTable class snake_case__ ( lowerCAmelCase_ ): """simple docstring""" def __init__( self : Optional[Any], *_snake_case : Optional[Any], **_snake_case : List[Any] ) ->Optional[int]: super().__init__(*_snake_case, **_snake_case ) def lowercase_ ( self : Optional[Any], _snake_case : Tuple, _snake_case : Dict ) ->Dict: snake_case__ : int = deque([] ) if self.values[key] is None else self.values[key] self.values[key].appendleft(_snake_case ) snake_case__ : Dict = self.values[key] def lowercase_ ( self : Any ) ->Optional[Any]: return ( sum(self.charge_factor - len(_snake_case ) for slot in self.values ) / self.size_table * self.charge_factor ) def lowercase_ ( self : Union[str, Any], _snake_case : str, _snake_case : Optional[int]=None ) ->Optional[Any]: if not ( len(self.values[key] ) == self.charge_factor and self.values.count(_snake_case ) == 0 ): return key return super()._collision_resolution(_snake_case, _snake_case )
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import sys from typing import Tuple import numpy as np import torch from PIL import Image from torch import nn from transformers.image_utils import PILImageResampling from utils import img_tensorize class __lowerCAmelCase : def __init__( self , lowerCAmelCase__ , lowerCAmelCase__=sys.maxsize ) -> Any: '''simple docstring''' a__ : Any ='bilinear' a__ : Optional[int] =max_size a__ : Union[str, Any] =short_edge_length def __call__( self , lowerCAmelCase__ ) -> List[Any]: '''simple docstring''' a__ : List[str] =[] for img in imgs: a__ : Union[str, Any] =img.shape[:2] # later: provide list and randomly choose index for resize a__ : Dict =np.random.randint(self.short_edge_length[0] , self.short_edge_length[1] + 1 ) if size == 0: return img a__ : Any =size * 1.0 / min(_snake_case , _snake_case ) if h < w: a__ : str =size, scale * w else: a__ : Optional[int] =scale * h, size if max(_snake_case , _snake_case ) > self.max_size: a__ : Union[str, Any] =self.max_size * 1.0 / max(_snake_case , _snake_case ) a__ : Optional[int] =newh * scale a__ : Dict =neww * scale a__ : List[str] =int(neww + 0.5 ) a__ : Dict =int(newh + 0.5 ) if img.dtype == np.uinta: a__ : str =Image.fromarray(_snake_case ) a__ : List[Any] =pil_image.resize((neww, newh) , PILImageResampling.BILINEAR ) a__ : List[Any] =np.asarray(_snake_case ) else: a__ : Dict =img.permute(2 , 0 , 1 ).unsqueeze(0 ) # 3, 0, 1) # hw(c) -> nchw a__ : int =nn.functional.interpolate( _snake_case , (newh, neww) , mode=self.interp_method , align_corners=_snake_case ).squeeze(0 ) img_augs.append(_snake_case ) return img_augs class __lowerCAmelCase : def __init__( self , lowerCAmelCase__ ) -> Union[str, Any]: '''simple docstring''' a__ : Optional[int] =ResizeShortestEdge([cfg.INPUT.MIN_SIZE_TEST, cfg.INPUT.MIN_SIZE_TEST] , cfg.INPUT.MAX_SIZE_TEST ) a__ : Optional[Any] =cfg.INPUT.FORMAT a__ : Optional[Any] =cfg.SIZE_DIVISIBILITY a__ : int =cfg.PAD_VALUE a__ : Optional[int] =cfg.INPUT.MAX_SIZE_TEST a__ : Optional[int] =cfg.MODEL.DEVICE a__ : List[str] =torch.tensor(cfg.MODEL.PIXEL_STD ).to(self.device ).view(len(cfg.MODEL.PIXEL_STD ) , 1 , 1 ) a__ : Dict =torch.tensor(cfg.MODEL.PIXEL_MEAN ).to(self.device ).view(len(cfg.MODEL.PIXEL_STD ) , 1 , 1 ) a__ : Any =lambda lowerCAmelCase__ : (x - self.pixel_mean) / self.pixel_std def _lowercase ( self , lowerCAmelCase__ ) -> List[Any]: '''simple docstring''' a__ : str =tuple(max(_snake_case ) for s in zip(*[img.shape for img in images] ) ) a__ : Any =[im.shape[-2:] for im in images] a__ : Any =[ nn.functional.pad( _snake_case , [0, max_size[-1] - size[1], 0, max_size[-2] - size[0]] , value=self.pad_value , ) for size, im in zip(_snake_case , _snake_case ) ] return torch.stack(_snake_case ), torch.tensor(_snake_case ) def __call__( self , lowerCAmelCase__ , lowerCAmelCase__=False ) -> int: '''simple docstring''' with torch.no_grad(): if not isinstance(_snake_case , _snake_case ): a__ : Optional[Any] =[images] if single_image: assert len(_snake_case ) == 1 for i in range(len(_snake_case ) ): if isinstance(images[i] , torch.Tensor ): images.insert(_snake_case , images.pop(_snake_case ).to(self.device ).float() ) elif not isinstance(images[i] , torch.Tensor ): images.insert( _snake_case , torch.as_tensor(img_tensorize(images.pop(_snake_case ) , input_format=self.input_format ) ) .to(self.device ) .float() , ) # resize smallest edge a__ : Union[str, Any] =torch.tensor([im.shape[:2] for im in images] ) a__ : str =self.aug(_snake_case ) # transpose images and convert to torch tensors # images = [torch.as_tensor(i.astype("float32")).permute(2, 0, 1).to(self.device) for i in images] # now normalize before pad to avoid useless arithmetic a__ : str =[self.normalizer(_snake_case ) for x in images] # now pad them to do the following operations a__ : List[str] =self.pad(_snake_case ) # Normalize if self.size_divisibility > 0: raise NotImplementedError() # pad a__ : Tuple =torch.true_divide(_snake_case , _snake_case ) if single_image: return images[0], sizes[0], scales_yx[0] else: return images, sizes, scales_yx def _A ( SCREAMING_SNAKE_CASE : List[str] , SCREAMING_SNAKE_CASE : Any ): """simple docstring""" boxes[:, 0::2] *= scale_yx[:, 1] boxes[:, 1::2] *= scale_yx[:, 0] return boxes def _A ( SCREAMING_SNAKE_CASE : List[str] , SCREAMING_SNAKE_CASE : Tuple[int, int] ): """simple docstring""" assert torch.isfinite(SCREAMING_SNAKE_CASE ).all(), "Box tensor contains infinite or NaN!" a__ : Dict =box_size tensor[:, 0].clamp_(min=0 , max=SCREAMING_SNAKE_CASE ) tensor[:, 1].clamp_(min=0 , max=SCREAMING_SNAKE_CASE ) tensor[:, 2].clamp_(min=0 , max=SCREAMING_SNAKE_CASE ) tensor[:, 3].clamp_(min=0 , max=SCREAMING_SNAKE_CASE )
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def lowercase_ (A : Union[str, Any] , A : List[str] , A : int , A : Optional[int] ): global f # a global dp table for knapsack if f[i][j] < 0: if j < wt[i - 1]: snake_case__ : Union[str, Any] = mf_knapsack(i - 1 , A , A , A ) else: snake_case__ : Any = max( mf_knapsack(i - 1 , A , A , A ) , mf_knapsack(i - 1 , A , A , j - wt[i - 1] ) + val[i - 1] , ) snake_case__ : Optional[int] = val return f[i][j] def lowercase_ (A : Optional[int] , A : Union[str, Any] , A : str , A : Dict ): snake_case__ : int = [[0] * (w + 1) for _ in range(n + 1 )] for i in range(1 , n + 1 ): for w_ in range(1 , w + 1 ): if wt[i - 1] <= w_: snake_case__ : Union[str, Any] = max(val[i - 1] + dp[i - 1][w_ - wt[i - 1]] , dp[i - 1][w_] ) else: snake_case__ : str = dp[i - 1][w_] return dp[n][w_], dp def lowercase_ (A : int , A : list , A : list ): if not (isinstance(A , (list, tuple) ) and isinstance(A , (list, tuple) )): raise ValueError( 'Both the weights and values vectors must be either lists or tuples' ) snake_case__ : Dict = len(A ) if num_items != len(A ): snake_case__ : str = ( 'The number of weights must be the same as the number of values.\n' F'''But got {num_items} weights and {len(A )} values''' ) raise ValueError(A ) for i in range(A ): if not isinstance(wt[i] , A ): snake_case__ : Optional[int] = ( 'All weights must be integers but got weight of ' F'''type {type(wt[i] )} at index {i}''' ) raise TypeError(A ) snake_case__ , snake_case__ : Optional[int] = knapsack(A , A , A , A ) snake_case__ : set = set() _construct_solution(A , A , A , A , A ) return optimal_val, example_optional_set def lowercase_ (A : list , A : list , A : int , A : int , A : set ): # for the current item i at a maximum weight j to be part of an optimal subset, # the optimal value at (i, j) must be greater than the optimal value at (i-1, j). # where i - 1 means considering only the previous items at the given maximum weight if i > 0 and j > 0: if dp[i - 1][j] == dp[i][j]: _construct_solution(A , A , i - 1 , A , A ) else: optimal_set.add(A ) _construct_solution(A , A , i - 1 , j - wt[i - 1] , A ) if __name__ == "__main__": a_ :Any = [3, 2, 4, 4] a_ :List[Any] = [4, 3, 2, 3] a_ :Union[str, Any] = 4 a_ :List[str] = 6 a_ :Union[str, Any] = [[0] * (w + 1)] + [[0] + [-1] * (w + 1) for _ in range(n + 1)] a_ , a_ :List[Any] = knapsack(w, wt, val, n) print(optimal_solution) print(mf_knapsack(n, wt, val, w)) # switched the n and w # testing the dynamic programming problem with example # the optimal subset for the above example are items 3 and 4 a_ , a_ :Any = knapsack_with_example_solution(w, wt, val) assert optimal_solution == 8 assert optimal_subset == {3, 4} print("optimal_value = ", optimal_solution) print("An optimal subset corresponding to the optimal value", optimal_subset)
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from __future__ import annotations def a ( snake_case__: list[float] ): '''simple docstring''' if len(snake_case__ ) < 2: raise ValueError('''Monogons and Digons are not polygons in the Euclidean space''' ) if any(i <= 0 for i in nums ): raise ValueError('''All values must be greater than 0''' ) lowercase_ = nums.copy() copy_nums.sort() return copy_nums[-1] < sum(copy_nums[:-1] ) if __name__ == "__main__": import doctest doctest.testmod()
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from typing import TYPE_CHECKING from ...utils import OptionalDependencyNotAvailable, _LazyModule, is_flax_available, is_torch_available a_ :int = { "configuration_longt5": ["LONGT5_PRETRAINED_CONFIG_ARCHIVE_MAP", "LongT5Config", "LongT5OnnxConfig"], } try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: a_ :List[str] = [ "LONGT5_PRETRAINED_MODEL_ARCHIVE_LIST", "LongT5EncoderModel", "LongT5ForConditionalGeneration", "LongT5Model", "LongT5PreTrainedModel", ] try: if not is_flax_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: a_ :int = [ "FlaxLongT5ForConditionalGeneration", "FlaxLongT5Model", "FlaxLongT5PreTrainedModel", ] if TYPE_CHECKING: from .configuration_longta import LONGT5_PRETRAINED_CONFIG_ARCHIVE_MAP, LongTaConfig, LongTaOnnxConfig try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_longta import ( LONGT5_PRETRAINED_MODEL_ARCHIVE_LIST, LongTaEncoderModel, LongTaForConditionalGeneration, LongTaModel, LongTaPreTrainedModel, ) try: if not is_flax_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_flax_longta import ( FlaxLongTaForConditionalGeneration, FlaxLongTaModel, FlaxLongTaPreTrainedModel, ) else: import sys a_ :Optional[int] = _LazyModule(__name__, globals()["__file__"], _import_structure, module_spec=__spec__)
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"""simple docstring""" import argparse import json import os import fairseq import torch from fairseq.data import Dictionary from transformers import ( WavaVecaConfig, WavaVecaCTCTokenizer, WavaVecaFeatureExtractor, WavaVecaForCTC, WavaVecaForPreTraining, WavaVecaProcessor, logging, ) from transformers.models.wavaveca.modeling_wavaveca import WavaVecaForSequenceClassification logging.set_verbosity_info() lowercase_ = logging.get_logger(__name__) lowercase_ = { "post_extract_proj": "feature_projection.projection", "encoder.pos_conv.0": "encoder.pos_conv_embed.conv", "self_attn.k_proj": "encoder.layers.*.attention.k_proj", "self_attn.v_proj": "encoder.layers.*.attention.v_proj", "self_attn.q_proj": "encoder.layers.*.attention.q_proj", "self_attn.out_proj": "encoder.layers.*.attention.out_proj", "self_attn_layer_norm": "encoder.layers.*.layer_norm", "fc1": "encoder.layers.*.feed_forward.intermediate_dense", "fc2": "encoder.layers.*.feed_forward.output_dense", "final_layer_norm": "encoder.layers.*.final_layer_norm", "encoder.layer_norm": "encoder.layer_norm", "adapter_layer": "encoder.layers.*.adapter_layer", "w2v_model.layer_norm": "feature_projection.layer_norm", "quantizer.weight_proj": "quantizer.weight_proj", "quantizer.vars": "quantizer.codevectors", "project_q": "project_q", "final_proj": "project_hid", "w2v_encoder.proj": "lm_head", "mask_emb": "masked_spec_embed", "pooling_layer.linear": "projector", "pooling_layer.projection": "classifier", } lowercase_ = [ "lm_head", "quantizer.weight_proj", "quantizer.codevectors", "project_q", "project_hid", "projector", "classifier", ] def lowercase ( lowerCAmelCase__ : Dict ) -> Optional[Any]: __a = {} with open(lowerCAmelCase__ , '''r''' ) as file: for line_number, line in enumerate(lowerCAmelCase__ ): __a = line.strip() if line: __a = line.split() __a = line_number __a = words[0] __a = value return result def lowercase ( lowerCAmelCase__ : int , lowerCAmelCase__ : int , lowerCAmelCase__ : Optional[int] , lowerCAmelCase__ : Optional[Any] , lowerCAmelCase__ : Tuple ) -> Tuple: for attribute in key.split('''.''' ): __a = getattr(lowerCAmelCase__ , lowerCAmelCase__ ) __a = None for param_key in PARAM_MAPPING.keys(): if full_name.endswith(lowerCAmelCase__ ): __a = PARAM_MAPPING[full_name.split('''.''' )[-1]] __a = 'param' if weight_type is not None and weight_type != "param": __a = getattr(lowerCAmelCase__ , lowerCAmelCase__ ).shape elif weight_type is not None and weight_type == "param": __a = hf_pointer for attribute in hf_param_name.split('''.''' ): __a = getattr(lowerCAmelCase__ , lowerCAmelCase__ ) __a = shape_pointer.shape # let's reduce dimension __a = value[0] else: __a = hf_pointer.shape if hf_shape != value.shape: raise ValueError( f'''Shape of hf {key + '.' + weight_type if weight_type is not None else ''} is {hf_shape}, but should be''' f''' {value.shape} for {full_name}''' ) if weight_type == "weight": __a = value elif weight_type == "weight_g": __a = value elif weight_type == "weight_v": __a = value elif weight_type == "bias": __a = value elif weight_type == "param": for attribute in hf_param_name.split('''.''' ): __a = getattr(lowerCAmelCase__ , lowerCAmelCase__ ) __a = value else: __a = value logger.info(f'''{key + '.' + weight_type if weight_type is not None else ''} was initialized from {full_name}.''' ) def lowercase ( lowerCAmelCase__ : Tuple , lowerCAmelCase__ : List[Any] , lowerCAmelCase__ : int , lowerCAmelCase__ : str , lowerCAmelCase__ : Tuple ) -> int: __a = None for param_key in PARAM_MAPPING.keys(): if full_name.endswith(lowerCAmelCase__ ): __a = PARAM_MAPPING[full_name.split('''.''' )[-1]] __a = 'param' if weight_type is not None and weight_type != "param": __a = '.'.join([key, weight_type] ) elif weight_type is not None and weight_type == "param": __a = '.'.join([key, hf_param_name] ) else: __a = key __a = value if 'lm_head' in full_key else value[0] lowercase_ = { "W_a": "linear_1.weight", "W_b": "linear_2.weight", "b_a": "linear_1.bias", "b_b": "linear_2.bias", "ln_W": "norm.weight", "ln_b": "norm.bias", } def lowercase ( lowerCAmelCase__ : str , lowerCAmelCase__ : Optional[Any] , lowerCAmelCase__ : Optional[Any]=None , lowerCAmelCase__ : List[str]=None ) -> Any: __a = False for key, mapped_key in MAPPING.items(): __a = 'wav2vec2.' + mapped_key if mapped_key not in TOP_LEVEL_KEYS else mapped_key if key in name or key.split('''w2v_model.''' )[-1] == name.split('''.''' )[0]: __a = True if "*" in mapped_key: __a = name.split(lowerCAmelCase__ )[0].split('''.''' )[-2] __a = mapped_key.replace('''*''' , lowerCAmelCase__ ) if "weight_g" in name: __a = 'weight_g' elif "weight_v" in name: __a = 'weight_v' elif "bias" in name: __a = 'bias' elif "weight" in name: # TODO: don't match quantizer.weight_proj __a = 'weight' else: __a = None if hf_dict is not None: rename_dict(lowerCAmelCase__ , lowerCAmelCase__ , lowerCAmelCase__ , lowerCAmelCase__ , lowerCAmelCase__ ) else: set_recursively(lowerCAmelCase__ , lowerCAmelCase__ , lowerCAmelCase__ , lowerCAmelCase__ , lowerCAmelCase__ ) return is_used return is_used def lowercase ( lowerCAmelCase__ : Optional[Any] , lowerCAmelCase__ : Dict , lowerCAmelCase__ : Optional[int] ) -> str: __a = [] __a = fairseq_model.state_dict() __a = hf_model.wavaveca.feature_extractor for name, value in fairseq_dict.items(): __a = False if "conv_layers" in name: load_conv_layer( lowerCAmelCase__ , lowerCAmelCase__ , lowerCAmelCase__ , lowerCAmelCase__ , hf_model.config.feat_extract_norm == '''group''' , ) __a = True else: __a = load_wavaveca_layer(lowerCAmelCase__ , lowerCAmelCase__ , lowerCAmelCase__ ) if not is_used: unused_weights.append(lowerCAmelCase__ ) logger.warning(f'''Unused weights: {unused_weights}''' ) def lowercase ( lowerCAmelCase__ : Dict , lowerCAmelCase__ : Optional[Any] , lowerCAmelCase__ : Tuple , lowerCAmelCase__ : str , lowerCAmelCase__ : List[str] ) -> List[str]: __a = full_name.split('''conv_layers.''' )[-1] __a = name.split('''.''' ) __a = int(items[0] ) __a = int(items[1] ) if type_id == 0: if "bias" in name: if value.shape != feature_extractor.conv_layers[layer_id].conv.bias.data.shape: raise ValueError( f'''{full_name} has size {value.shape}, but''' f''' {feature_extractor.conv_layers[layer_id].conv.bias.data.shape} was found.''' ) __a = value logger.info(f'''Feat extract conv layer {layer_id} was initialized from {full_name}.''' ) elif "weight" in name: if value.shape != feature_extractor.conv_layers[layer_id].conv.weight.data.shape: raise ValueError( f'''{full_name} has size {value.shape}, but''' f''' {feature_extractor.conv_layers[layer_id].conv.weight.data.shape} was found.''' ) __a = value logger.info(f'''Feat extract conv layer {layer_id} was initialized from {full_name}.''' ) elif (type_id == 2 and not use_group_norm) or (type_id == 2 and layer_id == 0 and use_group_norm): if "bias" in name: if value.shape != feature_extractor.conv_layers[layer_id].layer_norm.bias.data.shape: raise ValueError( f'''{full_name} has size {value.shape}, but''' f''' {feature_extractor.conv_layers[layer_id].layer_norm.bias.data.shape} was found.''' ) __a = value logger.info(f'''Feat extract layer norm weight of layer {layer_id} was initialized from {full_name}.''' ) elif "weight" in name: if value.shape != feature_extractor.conv_layers[layer_id].layer_norm.weight.data.shape: raise ValueError( f'''{full_name} has size {value.shape}, but''' f''' {feature_extractor.conv_layers[layer_id].layer_norm.weight.data.shape} was found.''' ) __a = value logger.info(f'''Feat extract layer norm weight of layer {layer_id} was initialized from {full_name}.''' ) else: unused_weights.append(lowerCAmelCase__ ) @torch.no_grad() def lowercase ( lowerCAmelCase__ : Union[str, Any] , lowerCAmelCase__ : str , lowerCAmelCase__ : Tuple=None , lowerCAmelCase__ : List[str]=None , lowerCAmelCase__ : Any=True , lowerCAmelCase__ : Optional[int]=False ) -> Dict: if config_path is not None: __a = WavaVecaConfig.from_pretrained(lowerCAmelCase__ ) else: __a = WavaVecaConfig() if is_seq_class: __a = read_txt_into_dict(lowerCAmelCase__ ) __a = idalabel __a = WavaVecaForSequenceClassification(lowerCAmelCase__ ) __a = WavaVecaFeatureExtractor( feature_size=1 , sampling_rate=16000 , padding_value=0 , do_normalize=lowerCAmelCase__ , return_attention_mask=lowerCAmelCase__ , ) feature_extractor.save_pretrained(lowerCAmelCase__ ) elif is_finetuned: if dict_path: __a = Dictionary.load(lowerCAmelCase__ ) # important change bos & pad token id since CTC symbol is <pad> and # not <s> as in fairseq __a = target_dict.pad_index __a = target_dict.bos_index __a = target_dict.eos_index __a = len(target_dict.symbols ) __a = os.path.join(lowerCAmelCase__ , '''vocab.json''' ) if not os.path.isdir(lowerCAmelCase__ ): logger.error('''--pytorch_dump_folder_path ({}) should be a directory'''.format(lowerCAmelCase__ ) ) return os.makedirs(lowerCAmelCase__ , exist_ok=lowerCAmelCase__ ) __a = target_dict.indices # fairseq has the <pad> and <s> switched __a = 0 __a = 1 with open(lowerCAmelCase__ , '''w''' , encoding='''utf-8''' ) as vocab_handle: json.dump(lowerCAmelCase__ , lowerCAmelCase__ ) __a = WavaVecaCTCTokenizer( lowerCAmelCase__ , unk_token=target_dict.unk_word , pad_token=target_dict.pad_word , bos_token=target_dict.bos_word , eos_token=target_dict.eos_word , word_delimiter_token='''|''' , do_lower_case=lowerCAmelCase__ , ) __a = True if config.feat_extract_norm == 'layer' else False __a = WavaVecaFeatureExtractor( feature_size=1 , sampling_rate=16000 , padding_value=0 , do_normalize=lowerCAmelCase__ , return_attention_mask=lowerCAmelCase__ , ) __a = WavaVecaProcessor(feature_extractor=lowerCAmelCase__ , tokenizer=lowerCAmelCase__ ) processor.save_pretrained(lowerCAmelCase__ ) __a = WavaVecaForCTC(lowerCAmelCase__ ) else: __a = WavaVecaForPreTraining(lowerCAmelCase__ ) if is_finetuned or is_seq_class: __a = fairseq.checkpoint_utils.load_model_ensemble_and_task( [checkpoint_path] , arg_overrides={'''data''': '''/'''.join(dict_path.split('''/''' )[:-1] )} ) else: __a = argparse.Namespace(task='''audio_pretraining''' ) __a = fairseq.tasks.setup_task(lowerCAmelCase__ ) __a = fairseq.checkpoint_utils.load_model_ensemble_and_task([checkpoint_path] , task=lowerCAmelCase__ ) __a = model[0].eval() recursively_load_weights(lowerCAmelCase__ , lowerCAmelCase__ , not is_finetuned ) hf_wavavec.save_pretrained(lowerCAmelCase__ ) if __name__ == "__main__": lowercase_ = argparse.ArgumentParser() parser.add_argument("--pytorch_dump_folder_path", default=None, type=str, help="Path to the output PyTorch model.") parser.add_argument("--checkpoint_path", default=None, type=str, help="Path to fairseq checkpoint") parser.add_argument("--dict_path", default=None, type=str, help="Path to dict of fine-tuned model") parser.add_argument("--config_path", default=None, type=str, help="Path to hf config.json of model to convert") parser.add_argument( "--not_finetuned", action="store_true", help="Whether the model to convert is a fine-tuned model or not" ) parser.add_argument( "--is_seq_class", action="store_true", help="Whether the model to convert is a fine-tuned sequence classification model or not", ) lowercase_ = parser.parse_args() lowercase_ = not args.not_finetuned and not args.is_seq_class convert_wavaveca_checkpoint( args.checkpoint_path, args.pytorch_dump_folder_path, args.config_path, args.dict_path, is_finetuned, args.is_seq_class, )
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import argparse import json import os import torch from torch import nn from transformers import NllbMoeConfig, NllbMoeModel from transformers.modeling_utils import dtype_byte_size from transformers.utils import WEIGHTS_INDEX_NAME, WEIGHTS_NAME def lowercase_ (A : List[str] ): snake_case__ : Tuple = [ 'encoder.version', 'decoder.version', 'model.encoder.version', 'model.decoder.version', 'decoder.output_projection.weight', '_float_tensor', 'encoder.embed_positions._float_tensor', 'decoder.embed_positions._float_tensor', ] for k in ignore_keys: state_dict.pop(A , A ) def lowercase_ (A : str ): snake_case__ , snake_case__ : Union[str, Any] = emb.weight.shape snake_case__ : str = nn.Linear(A , A , bias=A ) snake_case__ : str = emb.weight.data return lin_layer def lowercase_ (A : Optional[int] , A : Union[str, Any]=None ): snake_case__ : Any = {} for old_key in state_dict.keys(): snake_case__ : Tuple = old_key if "moe_layer.experts." in key: if expert_idx is not None: snake_case__ : int = key.replace('moe_layer.experts.0' , F'''ffn.experts.expert_{expert_idx}''' ) else: snake_case__ : Any = key.replace('moe_layer.experts.' , 'ffn.experts.expert_' ) if "gate" in key: snake_case__ : Dict = key.replace('.moe_layer.gate.wg' , '.ffn.router.classifier' ) if "fc2" and "experts" not in key: snake_case__ : str = key.replace('.fc2.' , '.ffn.fc2.' ) if "fc1" and "experts" not in key: snake_case__ : str = key.replace('.fc1.' , '.ffn.fc1.' ) if ".encoder_attn." in key: snake_case__ : Tuple = key.replace('.encoder_attn.' , '.cross_attention.' ) if "encoder_attn_layer_norm" in key: snake_case__ : Tuple = key.replace('encoder_attn_layer_norm' , 'cross_attention_layer_norm' ) if "final_layer_norm" in key: snake_case__ : Optional[int] = key.replace('final_layer_norm' , 'ff_layer_norm' ) snake_case__ : Dict = state_dict[old_key] return new_dict def lowercase_ (A : List[Any] , A : Tuple , A : List[Any] , A : List[str] , A : str = WEIGHTS_NAME ): snake_case__ : Dict = [] snake_case__ : str = 0 os.makedirs(A , exist_ok=A ) for expert in range(A ): snake_case__ : Tuple = switch_checkpoint_path + F'''-rank-{expert}.pt''' if os.path.isfile(A ): snake_case__ : Optional[Any] = torch.load(A )['model'] remove_ignore_keys_(A ) snake_case__ : Optional[Any] = rename_fairseq_keys(A , A ) snake_case__ : Dict = os.path.join( A , weights_name.replace('.bin' , F'''-{len(A )+1:05d}-of-???.bin''' ) ) torch.save(A , A ) sharded_state_dicts.append(expert_state.keys() ) total_size += sum([value.numel() for key, value in expert_state.items()] ) * dtype_byte_size( expert_state[list(A )[0]].dtype ) # Add the last block snake_case__ : Tuple = os.path.join(A , weights_name.replace('.bin' , F'''-{len(A )+1:05d}-of-???.bin''' ) ) snake_case__ : Union[str, Any] = torch.load(switch_checkpoint_path + '-shared.pt' )['model'] remove_ignore_keys_(A ) snake_case__ : str = rename_fairseq_keys(A , A ) snake_case__ : Any = shared_weights['decoder.embed_tokens.weight'] sharded_state_dicts.append(shared_weights.keys() ) # If we only have the shared weights (dummy model/experts saved on the same file) if len(A ) == 1: snake_case__ : Any = os.path.join(A , A ) torch.save(A , A ) return {weights_name: sharded_state_dicts[0]}, None else: torch.save(A , A ) # Otherwise, let's build the index snake_case__ : Tuple = {} for idx, shard in enumerate(A ): snake_case__ : Optional[int] = weights_name.replace('.bin' , F'''-{idx+1:05d}-of-{len(A ):05d}.bin''' ) snake_case__ : List[Any] = os.path.join(A , weights_name.replace('.bin' , F'''-{idx+1:05d}-of-???.bin''' ) ) os.rename(A , os.path.join(A , A ) ) for key in shard: snake_case__ : Any = shard_file # Add the metadata snake_case__ : int = {'total_size': total_size} snake_case__ : Dict = {'metadata': metadata, 'weight_map': weight_map} with open(os.path.join(A , A ) , 'w' , encoding='utf-8' ) as f: snake_case__ : Any = json.dumps(A , indent=2 , sort_keys=A ) + '\n' f.write(A ) return metadata, index if __name__ == "__main__": a_ :int = argparse.ArgumentParser() # Required parameters parser.add_argument( "--nllb_moe_checkpoint_path", default="/home/arthur_huggingface_co/fairseq/weights/checkpoints/model_moe_54b/checkpoint_2_300000", type=str, required=False, help="Path to a directory containing a folder per layer. Follows the original Google format.", ) parser.add_argument("--dtype", default="float32", type=str, required=False, help="dtype of the saved model") parser.add_argument( "--pytorch_dump_folder_path", default="/home/arthur_huggingface_co/fairseq/weights/checkpoints/hf-converted-moe-54b", type=str, required=False, help="Path to the output pytorch model.", ) a_ :Optional[Any] = parser.parse_args() a_ , a_ :Optional[Any] = shard_on_the_fly( args.nllb_moe_checkpoint_path, args.pytorch_dump_folder_path, 128, args.dtype, ) a_ :List[str] = NllbMoeConfig.from_pretrained( "facebook/nllb-200-3.3B", encoder_sparse_step=4, decoder_sparse_step=4, num_experts=128 ) config.save_pretrained(args.pytorch_dump_folder_path) a_ :int = NllbMoeModel.from_pretrained(args.pytorch_dump_folder_path) print("Done") model.save_pretrained(args.pytorch_dump_folder_path)
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'''simple docstring''' import json from typing import List, Optional, Tuple from tokenizers import pre_tokenizers, processors from ...tokenization_utils_base import AddedToken, BatchEncoding from ...tokenization_utils_fast import PreTrainedTokenizerFast from ...utils import logging from .tokenization_bart import BartTokenizer _lowerCAmelCase = logging.get_logger(__name__) _lowerCAmelCase = {"vocab_file": "vocab.json", "merges_file": "merges.txt", "tokenizer_file": "tokenizer.json"} # See all BART models at https://huggingface.co/models?filter=bart _lowerCAmelCase = { "vocab_file": { "facebook/bart-base": "https://huggingface.co/facebook/bart-base/resolve/main/vocab.json", "facebook/bart-large": "https://huggingface.co/facebook/bart-large/resolve/main/vocab.json", "facebook/bart-large-mnli": "https://huggingface.co/facebook/bart-large-mnli/resolve/main/vocab.json", "facebook/bart-large-cnn": "https://huggingface.co/facebook/bart-large-cnn/resolve/main/vocab.json", "facebook/bart-large-xsum": "https://huggingface.co/facebook/bart-large-xsum/resolve/main/vocab.json", "yjernite/bart_eli5": "https://huggingface.co/yjernite/bart_eli5/resolve/main/vocab.json", }, "merges_file": { "facebook/bart-base": "https://huggingface.co/facebook/bart-base/resolve/main/merges.txt", "facebook/bart-large": "https://huggingface.co/facebook/bart-large/resolve/main/merges.txt", "facebook/bart-large-mnli": "https://huggingface.co/facebook/bart-large-mnli/resolve/main/merges.txt", "facebook/bart-large-cnn": "https://huggingface.co/facebook/bart-large-cnn/resolve/main/merges.txt", "facebook/bart-large-xsum": "https://huggingface.co/facebook/bart-large-xsum/resolve/main/merges.txt", "yjernite/bart_eli5": "https://huggingface.co/yjernite/bart_eli5/resolve/main/merges.txt", }, "tokenizer_file": { "facebook/bart-base": "https://huggingface.co/facebook/bart-base/resolve/main/tokenizer.json", "facebook/bart-large": "https://huggingface.co/facebook/bart-large/resolve/main/tokenizer.json", "facebook/bart-large-mnli": "https://huggingface.co/facebook/bart-large-mnli/resolve/main/tokenizer.json", "facebook/bart-large-cnn": "https://huggingface.co/facebook/bart-large-cnn/resolve/main/tokenizer.json", "facebook/bart-large-xsum": "https://huggingface.co/facebook/bart-large-xsum/resolve/main/tokenizer.json", "yjernite/bart_eli5": "https://huggingface.co/yjernite/bart_eli5/resolve/main/tokenizer.json", }, } _lowerCAmelCase = { "facebook/bart-base": 1024, "facebook/bart-large": 1024, "facebook/bart-large-mnli": 1024, "facebook/bart-large-cnn": 1024, "facebook/bart-large-xsum": 1024, "yjernite/bart_eli5": 1024, } class A ( lowerCAmelCase_ ): '''simple docstring''' A = VOCAB_FILES_NAMES A = PRETRAINED_VOCAB_FILES_MAP A = PRETRAINED_POSITIONAL_EMBEDDINGS_SIZES A = ["input_ids", "attention_mask"] A = BartTokenizer def __init__(self , _UpperCAmelCase=None , _UpperCAmelCase=None , _UpperCAmelCase=None , _UpperCAmelCase="replace" , _UpperCAmelCase="<s>" , _UpperCAmelCase="</s>" , _UpperCAmelCase="</s>" , _UpperCAmelCase="<s>" , _UpperCAmelCase="<unk>" , _UpperCAmelCase="<pad>" , _UpperCAmelCase="<mask>" , _UpperCAmelCase=False , _UpperCAmelCase=True , **_UpperCAmelCase , ) -> int: super().__init__( _snake_case , _snake_case , tokenizer_file=_snake_case , errors=_snake_case , bos_token=_snake_case , eos_token=_snake_case , sep_token=_snake_case , cls_token=_snake_case , unk_token=_snake_case , pad_token=_snake_case , mask_token=_snake_case , add_prefix_space=_snake_case , trim_offsets=_snake_case , **_snake_case , ) __UpperCamelCase : str = json.loads(self.backend_tokenizer.pre_tokenizer.__getstate__() ) if pre_tok_state.get("add_prefix_space" , _snake_case ) != add_prefix_space: __UpperCamelCase : Tuple = getattr(_snake_case , pre_tok_state.pop("type" ) ) __UpperCamelCase : List[Any] = add_prefix_space __UpperCamelCase : str = pre_tok_class(**_snake_case ) __UpperCamelCase : int = add_prefix_space # the pre_tokenizer is already updated in the GPT2TokenizerFast `__init__` __UpperCamelCase : Any = 'post_processor' __UpperCamelCase : List[Any] = getattr(self.backend_tokenizer , _snake_case , _snake_case ) if tokenizer_component_instance: __UpperCamelCase : Union[str, Any] = json.loads(tokenizer_component_instance.__getstate__() ) # The lists 'sep' and 'cls' must be cased in tuples for the object `post_processor_class` if "sep" in state: __UpperCamelCase : Tuple = tuple(state["sep"] ) if "cls" in state: __UpperCamelCase : Optional[Any] = tuple(state["cls"] ) __UpperCamelCase : int = False if state.get("add_prefix_space" , _snake_case ) != add_prefix_space: __UpperCamelCase : int = add_prefix_space __UpperCamelCase : Tuple = True if state.get("trim_offsets" , _snake_case ) != trim_offsets: __UpperCamelCase : Optional[Any] = trim_offsets __UpperCamelCase : Tuple = True if changes_to_apply: __UpperCamelCase : Union[str, Any] = getattr(_snake_case , state.pop("type" ) ) __UpperCamelCase : List[str] = component_class(**_snake_case ) setattr(self.backend_tokenizer , _snake_case , _snake_case ) @property def a_ (self ) -> str: if self._mask_token is None: if self.verbose: logger.error("Using mask_token, but it is not set yet." ) return None return str(self._mask_token ) @mask_token.setter def a_ (self , _UpperCAmelCase ) -> Dict: __UpperCamelCase : List[str] = AddedToken(_snake_case , lstrip=_snake_case , rstrip=_snake_case ) if isinstance(_snake_case , _snake_case ) else value __UpperCamelCase : Union[str, Any] = value def a_ (self , *_UpperCAmelCase , **_UpperCAmelCase ) -> BatchEncoding: __UpperCamelCase : str = kwargs.get("is_split_into_words" , _snake_case ) if is_split_into_words and not self.add_prefix_space: raise ValueError( f"You need to instantiate {self.__class__.__name__} with add_prefix_space=True " "to use it with pretokenized inputs." ) return super()._batch_encode_plus(*_snake_case , **_snake_case ) def a_ (self , *_UpperCAmelCase , **_UpperCAmelCase ) -> BatchEncoding: __UpperCamelCase : List[str] = kwargs.get("is_split_into_words" , _snake_case ) if is_split_into_words and not self.add_prefix_space: raise ValueError( f"You need to instantiate {self.__class__.__name__} with add_prefix_space=True " "to use it with pretokenized inputs." ) return super()._encode_plus(*_snake_case , **_snake_case ) def a_ (self , _UpperCAmelCase , _UpperCAmelCase = None ) -> Tuple[str]: __UpperCamelCase : Dict = self._tokenizer.model.save(_snake_case , name=_snake_case ) return tuple(_snake_case ) def a_ (self , _UpperCAmelCase , _UpperCAmelCase=None ) -> Dict: __UpperCamelCase : Tuple = [self.bos_token_id] + token_ids_a + [self.eos_token_id] if token_ids_a is None: return output return output + [self.eos_token_id] + token_ids_a + [self.eos_token_id] def a_ (self , _UpperCAmelCase , _UpperCAmelCase = None ) -> List[int]: __UpperCamelCase : Any = [self.sep_token_id] __UpperCamelCase : Optional[Any] = [self.cls_token_id] if token_ids_a is None: return len(cls + token_ids_a + sep ) * [0] return len(cls + token_ids_a + sep + sep + token_ids_a + sep ) * [0]
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from typing import TYPE_CHECKING from ...utils import ( OptionalDependencyNotAvailable, _LazyModule, is_sentencepiece_available, is_tokenizers_available, is_torch_available, ) a_ :Optional[Any] = {"configuration_reformer": ["REFORMER_PRETRAINED_CONFIG_ARCHIVE_MAP", "ReformerConfig"]} try: if not is_sentencepiece_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: a_ :str = ["ReformerTokenizer"] try: if not is_tokenizers_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: a_ :int = ["ReformerTokenizerFast"] try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: a_ :List[str] = [ "REFORMER_PRETRAINED_MODEL_ARCHIVE_LIST", "ReformerAttention", "ReformerForMaskedLM", "ReformerForQuestionAnswering", "ReformerForSequenceClassification", "ReformerLayer", "ReformerModel", "ReformerModelWithLMHead", "ReformerPreTrainedModel", ] if TYPE_CHECKING: from .configuration_reformer import REFORMER_PRETRAINED_CONFIG_ARCHIVE_MAP, ReformerConfig try: if not is_sentencepiece_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .tokenization_reformer import ReformerTokenizer try: if not is_tokenizers_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .tokenization_reformer_fast import ReformerTokenizerFast try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_reformer import ( REFORMER_PRETRAINED_MODEL_ARCHIVE_LIST, ReformerAttention, ReformerForMaskedLM, ReformerForQuestionAnswering, ReformerForSequenceClassification, ReformerLayer, ReformerModel, ReformerModelWithLMHead, ReformerPreTrainedModel, ) else: import sys a_ :Optional[Any] = _LazyModule(__name__, globals()["__file__"], _import_structure, module_spec=__spec__)
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import shutil import tempfile import unittest import numpy as np import pytest from transformers.testing_utils import require_vision from transformers.utils import is_vision_available if is_vision_available(): from PIL import Image from transformers import AutoProcessor, BlipaProcessor, BlipImageProcessor, GPTaTokenizer, PreTrainedTokenizerFast @require_vision class lowercase ( unittest.TestCase ): def a__ ( self ) -> Tuple: _A : List[Any] = tempfile.mkdtemp() _A : str = BlipImageProcessor() _A : Any = GPTaTokenizer.from_pretrained("""hf-internal-testing/tiny-random-GPT2Model""" ) _A : int = BlipaProcessor(_snake_case , _snake_case ) processor.save_pretrained(self.tmpdirname ) def a__ ( self , **_a ) -> Dict: return AutoProcessor.from_pretrained(self.tmpdirname , **_snake_case ).tokenizer def a__ ( self , **_a ) -> str: return AutoProcessor.from_pretrained(self.tmpdirname , **_snake_case ).image_processor def a__ ( self ) -> List[str]: shutil.rmtree(self.tmpdirname ) def a__ ( self ) -> Any: _A : str = [np.random.randint(255 , size=(3, 30, 400) , dtype=np.uinta )] _A : Optional[int] = [Image.fromarray(np.moveaxis(_snake_case , 0 , -1 ) ) for x in image_inputs] return image_inputs def a__ ( self ) -> Optional[Any]: _A : Union[str, Any] = BlipaProcessor(tokenizer=self.get_tokenizer() , image_processor=self.get_image_processor() ) processor.save_pretrained(self.tmpdirname ) _A : Optional[Any] = self.get_tokenizer(bos_token="""(BOS)""" , eos_token="""(EOS)""" ) _A : int = self.get_image_processor(do_normalize=_snake_case , padding_value=1.0 ) _A : Optional[int] = BlipaProcessor.from_pretrained( self.tmpdirname , bos_token="""(BOS)""" , eos_token="""(EOS)""" , do_normalize=_snake_case , padding_value=1.0 ) self.assertEqual(processor.tokenizer.get_vocab() , tokenizer_add_kwargs.get_vocab() ) self.assertIsInstance(processor.tokenizer , _snake_case ) self.assertEqual(processor.image_processor.to_json_string() , image_processor_add_kwargs.to_json_string() ) self.assertIsInstance(processor.image_processor , _snake_case ) def a__ ( self ) -> List[Any]: _A : Optional[Any] = self.get_image_processor() _A : List[Any] = self.get_tokenizer() _A : Union[str, Any] = BlipaProcessor(tokenizer=_snake_case , image_processor=_snake_case ) _A : Tuple = self.prepare_image_inputs() _A : Optional[Any] = image_processor(_snake_case , return_tensors="""np""" ) _A : Tuple = processor(images=_snake_case , return_tensors="""np""" ) for key in input_feat_extract.keys(): self.assertAlmostEqual(input_feat_extract[key].sum() , input_processor[key].sum() , delta=1e-2 ) def a__ ( self ) -> Union[str, Any]: _A : str = self.get_image_processor() _A : List[Any] = self.get_tokenizer() _A : int = BlipaProcessor(tokenizer=_snake_case , image_processor=_snake_case ) _A : List[Any] = 'lower newer' _A : str = processor(text=_snake_case ) _A : Dict = tokenizer(_snake_case , return_token_type_ids=_snake_case ) for key in encoded_tok.keys(): self.assertListEqual(encoded_tok[key] , encoded_processor[key] ) def a__ ( self ) -> List[Any]: _A : Tuple = self.get_image_processor() _A : Optional[int] = self.get_tokenizer() _A : Optional[Any] = BlipaProcessor(tokenizer=_snake_case , image_processor=_snake_case ) _A : Dict = 'lower newer' _A : Dict = self.prepare_image_inputs() _A : Union[str, Any] = processor(text=_snake_case , images=_snake_case ) self.assertListEqual(list(inputs.keys() ) , ["""pixel_values""", """input_ids""", """attention_mask"""] ) # test if it raises when no input is passed with pytest.raises(_snake_case ): processor() def a__ ( self ) -> Optional[int]: _A : Optional[int] = self.get_image_processor() _A : int = self.get_tokenizer() _A : List[Any] = BlipaProcessor(tokenizer=_snake_case , image_processor=_snake_case ) _A : Optional[Any] = [[1, 4, 5, 8, 1, 0, 8], [3, 4, 3, 1, 1, 8, 9]] _A : Union[str, Any] = processor.batch_decode(_snake_case ) _A : List[str] = tokenizer.batch_decode(_snake_case ) self.assertListEqual(_snake_case , _snake_case ) def a__ ( self ) -> Optional[int]: _A : Dict = self.get_image_processor() _A : List[Any] = self.get_tokenizer() _A : Optional[int] = BlipaProcessor(tokenizer=_snake_case , image_processor=_snake_case ) _A : Tuple = 'lower newer' _A : Optional[int] = self.prepare_image_inputs() _A : str = processor(text=_snake_case , images=_snake_case ) # For now the processor supports only ['pixel_values', 'input_ids', 'attention_mask'] self.assertListEqual(list(inputs.keys() ) , ["""pixel_values""", """input_ids""", """attention_mask"""] )
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import itertools import random import unittest import numpy as np from transformers import BatchFeature, SpeechTaFeatureExtractor from transformers.testing_utils import require_torch from transformers.utils.import_utils import is_torch_available from ...test_sequence_feature_extraction_common import SequenceFeatureExtractionTestMixin if is_torch_available(): import torch a_ :Any = random.Random() def lowercase_ (A : int , A : Union[str, Any]=1.0 , A : List[str]=None , A : Any=None ): if rng is None: snake_case__ : List[str] = global_rng snake_case__ : int = [] for batch_idx in range(shape[0] ): values.append([] ) for _ in range(shape[1] ): values[-1].append(rng.random() * scale ) return values @require_torch class snake_case__ ( unittest.TestCase ): """simple docstring""" def __init__( self : Optional[Any], _snake_case : List[str], _snake_case : Tuple=7, _snake_case : Union[str, Any]=4_0_0, _snake_case : Any=2_0_0_0, _snake_case : Dict=1, _snake_case : Optional[Any]=0.0, _snake_case : List[Any]=1_6_0_0_0, _snake_case : List[Any]=True, _snake_case : List[Any]=8_0, _snake_case : Dict=1_6, _snake_case : str=6_4, _snake_case : Tuple="hann_window", _snake_case : Union[str, Any]=8_0, _snake_case : Optional[Any]=7_6_0_0, _snake_case : str=1e-10, _snake_case : Any=True, ) ->Union[str, Any]: snake_case__ : Optional[int] = parent snake_case__ : Optional[Any] = batch_size snake_case__ : List[Any] = min_seq_length snake_case__ : List[Any] = max_seq_length snake_case__ : Any = (self.max_seq_length - self.min_seq_length) // (self.batch_size - 1) snake_case__ : Tuple = feature_size snake_case__ : List[Any] = padding_value snake_case__ : Any = sampling_rate snake_case__ : Dict = do_normalize snake_case__ : Union[str, Any] = num_mel_bins snake_case__ : Any = hop_length snake_case__ : Any = win_length snake_case__ : Any = win_function snake_case__ : Optional[int] = fmin snake_case__ : int = fmax snake_case__ : Union[str, Any] = mel_floor snake_case__ : Union[str, Any] = return_attention_mask def lowercase_ ( self : Optional[int] ) ->List[str]: return { "feature_size": self.feature_size, "padding_value": self.padding_value, "sampling_rate": self.sampling_rate, "do_normalize": self.do_normalize, "num_mel_bins": self.num_mel_bins, "hop_length": self.hop_length, "win_length": self.win_length, "win_function": self.win_function, "fmin": self.fmin, "fmax": self.fmax, "mel_floor": self.mel_floor, "return_attention_mask": self.return_attention_mask, } def lowercase_ ( self : Any, _snake_case : Optional[Any]=False, _snake_case : List[str]=False ) ->Union[str, Any]: def _flatten(_snake_case : List[str] ): return list(itertools.chain(*_snake_case ) ) if equal_length: snake_case__ : Any = floats_list((self.batch_size, self.max_seq_length) ) else: # make sure that inputs increase in size snake_case__ : int = [ _flatten(floats_list((x, self.feature_size) ) ) for x in range(self.min_seq_length, self.max_seq_length, self.seq_length_diff ) ] if numpify: snake_case__ : Any = [np.asarray(_snake_case ) for x in speech_inputs] return speech_inputs def lowercase_ ( self : Union[str, Any], _snake_case : str=False, _snake_case : Dict=False ) ->List[str]: if equal_length: snake_case__ : Optional[Any] = [floats_list((self.max_seq_length, self.num_mel_bins) ) for _ in range(self.batch_size )] else: # make sure that inputs increase in size snake_case__ : List[str] = [ floats_list((x, self.num_mel_bins) ) for x in range(self.min_seq_length, self.max_seq_length, self.seq_length_diff ) ] if numpify: snake_case__ : int = [np.asarray(_snake_case ) for x in speech_inputs] return speech_inputs @require_torch class snake_case__ ( lowerCAmelCase_ , unittest.TestCase ): """simple docstring""" _SCREAMING_SNAKE_CASE = SpeechTaFeatureExtractor def lowercase_ ( self : int ) ->Union[str, Any]: snake_case__ : List[str] = SpeechTaFeatureExtractionTester(self ) def lowercase_ ( self : Any, _snake_case : Dict ) ->Any: self.assertTrue(np.all(np.mean(_snake_case, axis=0 ) < 1e-3 ) ) self.assertTrue(np.all(np.abs(np.var(_snake_case, axis=0 ) - 1 ) < 1e-3 ) ) def lowercase_ ( self : List[Any] ) ->Union[str, Any]: # Tests that all call wrap to encode_plus and batch_encode_plus snake_case__ : Optional[Any] = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) # create three inputs of length 800, 1000, and 1200 snake_case__ : int = [floats_list((1, x) )[0] for x in range(8_0_0, 1_4_0_0, 2_0_0 )] snake_case__ : Tuple = [np.asarray(_snake_case ) for speech_input in speech_inputs] # Test not batched input snake_case__ : str = feat_extract(speech_inputs[0], return_tensors='np' ).input_values snake_case__ : List[str] = feat_extract(np_speech_inputs[0], return_tensors='np' ).input_values self.assertTrue(np.allclose(_snake_case, _snake_case, atol=1e-3 ) ) # Test batched snake_case__ : Any = feat_extract(_snake_case, return_tensors='np' ).input_values snake_case__ : Union[str, Any] = feat_extract(_snake_case, return_tensors='np' ).input_values for enc_seq_a, enc_seq_a in zip(_snake_case, _snake_case ): self.assertTrue(np.allclose(_snake_case, _snake_case, atol=1e-3 ) ) def lowercase_ ( self : int ) ->Optional[int]: snake_case__ : List[Any] = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) snake_case__ : Tuple = [floats_list((1, x) )[0] for x in range(8_0_0, 1_4_0_0, 2_0_0 )] snake_case__ : int = ['longest', 'max_length', 'do_not_pad'] snake_case__ : List[str] = [None, 1_6_0_0, None] for max_length, padding in zip(_snake_case, _snake_case ): snake_case__ : Optional[int] = feat_extract(_snake_case, padding=_snake_case, max_length=_snake_case, return_tensors='np' ) snake_case__ : Optional[int] = processed.input_values self._check_zero_mean_unit_variance(input_values[0][:8_0_0] ) self.assertTrue(input_values[0][8_0_0:].sum() < 1e-6 ) self._check_zero_mean_unit_variance(input_values[1][:1_0_0_0] ) self.assertTrue(input_values[0][1_0_0_0:].sum() < 1e-6 ) self._check_zero_mean_unit_variance(input_values[2][:1_2_0_0] ) def lowercase_ ( self : Union[str, Any] ) ->Optional[Any]: snake_case__ : Optional[Any] = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) snake_case__ : Tuple = range(8_0_0, 1_4_0_0, 2_0_0 ) snake_case__ : Optional[Any] = [floats_list((1, x) )[0] for x in lengths] snake_case__ : Union[str, Any] = ['longest', 'max_length', 'do_not_pad'] snake_case__ : str = [None, 1_6_0_0, None] for max_length, padding in zip(_snake_case, _snake_case ): snake_case__ : List[str] = feat_extract(_snake_case, max_length=_snake_case, padding=_snake_case ) snake_case__ : Tuple = processed.input_values self._check_zero_mean_unit_variance(input_values[0][:8_0_0] ) self._check_zero_mean_unit_variance(input_values[1][:1_0_0_0] ) self._check_zero_mean_unit_variance(input_values[2][:1_2_0_0] ) def lowercase_ ( self : List[Any] ) ->Optional[Any]: snake_case__ : Any = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) snake_case__ : str = [floats_list((1, x) )[0] for x in range(8_0_0, 1_4_0_0, 2_0_0 )] snake_case__ : Optional[Any] = feat_extract( _snake_case, truncation=_snake_case, max_length=1_0_0_0, padding='max_length', return_tensors='np' ) snake_case__ : int = processed.input_values self._check_zero_mean_unit_variance(input_values[0, :8_0_0] ) self._check_zero_mean_unit_variance(input_values[1] ) self._check_zero_mean_unit_variance(input_values[2] ) def lowercase_ ( self : int ) ->Union[str, Any]: snake_case__ : str = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) snake_case__ : Dict = [floats_list((1, x) )[0] for x in range(8_0_0, 1_4_0_0, 2_0_0 )] snake_case__ : str = feat_extract( _snake_case, truncation=_snake_case, max_length=1_0_0_0, padding='longest', return_tensors='np' ) snake_case__ : Dict = processed.input_values self._check_zero_mean_unit_variance(input_values[0, :8_0_0] ) self._check_zero_mean_unit_variance(input_values[1, :1_0_0_0] ) self._check_zero_mean_unit_variance(input_values[2] ) # make sure that if max_length < longest -> then pad to max_length self.assertTrue(input_values.shape == (3, 1_0_0_0) ) snake_case__ : Tuple = [floats_list((1, x) )[0] for x in range(8_0_0, 1_4_0_0, 2_0_0 )] snake_case__ : List[str] = feat_extract( _snake_case, truncation=_snake_case, max_length=2_0_0_0, padding='longest', return_tensors='np' ) snake_case__ : Optional[Any] = processed.input_values self._check_zero_mean_unit_variance(input_values[0, :8_0_0] ) self._check_zero_mean_unit_variance(input_values[1, :1_0_0_0] ) self._check_zero_mean_unit_variance(input_values[2] ) # make sure that if max_length > longest -> then pad to longest self.assertTrue(input_values.shape == (3, 1_2_0_0) ) def lowercase_ ( self : List[str] ) ->Dict: snake_case__ : Dict = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) snake_case__ : List[Any] = np.random.rand(1_0_0 ).astype(np.floataa ) snake_case__ : int = np_speech_inputs.tolist() for inputs in [py_speech_inputs, np_speech_inputs]: snake_case__ : int = feature_extractor.pad([{'input_values': inputs}], return_tensors='np' ) self.assertTrue(np_processed.input_values.dtype == np.floataa ) snake_case__ : Optional[int] = feature_extractor.pad([{'input_values': inputs}], return_tensors='pt' ) self.assertTrue(pt_processed.input_values.dtype == torch.floataa ) def lowercase_ ( self : Optional[int] ) ->Optional[Any]: # Tests that all call wrap to encode_plus and batch_encode_plus snake_case__ : str = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) # create three inputs of length 800, 1000, and 1200 snake_case__ : List[Any] = [floats_list((1, x) )[0] for x in range(8_0_0, 1_4_0_0, 2_0_0 )] snake_case__ : Dict = [np.asarray(_snake_case ) for speech_input in speech_inputs] # Test feature size snake_case__ : Optional[int] = feature_extractor(audio_target=_snake_case, padding=_snake_case, return_tensors='np' ).input_values self.assertTrue(input_values.ndim == 3 ) self.assertTrue(input_values.shape[-1] == feature_extractor.num_mel_bins ) # Test not batched input snake_case__ : Dict = feature_extractor(speech_inputs[0], return_tensors='np' ).input_values snake_case__ : Any = feature_extractor(np_speech_inputs[0], return_tensors='np' ).input_values self.assertTrue(np.allclose(_snake_case, _snake_case, atol=1e-3 ) ) # Test batched snake_case__ : Dict = feature_extractor(_snake_case, return_tensors='np' ).input_values snake_case__ : Dict = feature_extractor(_snake_case, return_tensors='np' ).input_values for enc_seq_a, enc_seq_a in zip(_snake_case, _snake_case ): self.assertTrue(np.allclose(_snake_case, _snake_case, atol=1e-3 ) ) # Test 2-D numpy arrays are batched. snake_case__ : Optional[Any] = [floats_list((1, x) )[0] for x in (8_0_0, 8_0_0, 8_0_0)] snake_case__ : int = np.asarray(_snake_case ) snake_case__ : Union[str, Any] = feature_extractor(_snake_case, return_tensors='np' ).input_values snake_case__ : Union[str, Any] = feature_extractor(_snake_case, return_tensors='np' ).input_values for enc_seq_a, enc_seq_a in zip(_snake_case, _snake_case ): self.assertTrue(np.allclose(_snake_case, _snake_case, atol=1e-3 ) ) def lowercase_ ( self : Union[str, Any] ) ->str: snake_case__ : int = self.feat_extract_tester.prepare_inputs_for_target() snake_case__ : List[str] = self.feature_extraction_class(**self.feat_extract_dict ) snake_case__ : Optional[Any] = feat_extract.model_input_names[0] snake_case__ : Tuple = BatchFeature({input_name: speech_inputs} ) self.assertTrue(all(len(_snake_case ) == len(_snake_case ) for x, y in zip(_snake_case, processed_features[input_name] ) ) ) snake_case__ : int = self.feat_extract_tester.prepare_inputs_for_target(equal_length=_snake_case ) snake_case__ : Union[str, Any] = BatchFeature({input_name: speech_inputs}, tensor_type='np' ) snake_case__ : Dict = processed_features[input_name] if len(batch_features_input.shape ) < 3: snake_case__ : List[str] = batch_features_input[:, :, None] self.assertTrue( batch_features_input.shape == (self.feat_extract_tester.batch_size, len(speech_inputs[0] ), self.feat_extract_tester.num_mel_bins) ) @require_torch def lowercase_ ( self : List[str] ) ->Any: snake_case__ : int = self.feat_extract_tester.prepare_inputs_for_target(equal_length=_snake_case ) snake_case__ : Optional[Any] = self.feature_extraction_class(**self.feat_extract_dict ) snake_case__ : Tuple = feat_extract.model_input_names[0] snake_case__ : List[Any] = BatchFeature({input_name: speech_inputs}, tensor_type='pt' ) snake_case__ : Tuple = processed_features[input_name] if len(batch_features_input.shape ) < 3: snake_case__ : Any = batch_features_input[:, :, None] self.assertTrue( batch_features_input.shape == (self.feat_extract_tester.batch_size, len(speech_inputs[0] ), self.feat_extract_tester.num_mel_bins) ) @require_torch def lowercase_ ( self : Optional[int] ) ->Tuple: snake_case__ : Dict = self.feature_extraction_class(**self.feat_extract_dict ) snake_case__ : Union[str, Any] = self.feat_extract_tester.prepare_inputs_for_target() snake_case__ : Optional[Any] = feat_extract.model_input_names[0] snake_case__ : List[str] = BatchFeature({input_name: speech_inputs} ) snake_case__ : int = feat_extract.num_mel_bins # hack! snake_case__ : Tuple = feat_extract.pad(_snake_case, padding='longest', return_tensors='np' )[input_name] snake_case__ : Union[str, Any] = feat_extract.pad(_snake_case, padding='longest', return_tensors='pt' )[input_name] self.assertTrue(abs(input_np.astype(np.floataa ).sum() - input_pt.numpy().astype(np.floataa ).sum() ) < 1e-2 ) def lowercase_ ( self : int ) ->Any: snake_case__ : Any = self.feat_extract_dict snake_case__ : List[Any] = True snake_case__ : Union[str, Any] = self.feature_extraction_class(**_snake_case ) snake_case__ : Any = self.feat_extract_tester.prepare_inputs_for_target() snake_case__ : List[Any] = [len(_snake_case ) for x in speech_inputs] snake_case__ : Union[str, Any] = feat_extract.model_input_names[0] snake_case__ : Optional[int] = BatchFeature({input_name: speech_inputs} ) snake_case__ : List[str] = feat_extract.num_mel_bins # hack! snake_case__ : str = feat_extract.pad(_snake_case, padding='longest', return_tensors='np' ) self.assertIn('attention_mask', _snake_case ) self.assertListEqual(list(processed.attention_mask.shape ), list(processed[input_name].shape[:2] ) ) self.assertListEqual(processed.attention_mask.sum(-1 ).tolist(), _snake_case ) def lowercase_ ( self : Optional[int] ) ->str: snake_case__ : int = self.feat_extract_dict snake_case__ : List[str] = True snake_case__ : Tuple = self.feature_extraction_class(**_snake_case ) snake_case__ : List[str] = self.feat_extract_tester.prepare_inputs_for_target() snake_case__ : str = [len(_snake_case ) for x in speech_inputs] snake_case__ : Optional[Any] = feat_extract.model_input_names[0] snake_case__ : Optional[int] = BatchFeature({input_name: speech_inputs} ) snake_case__ : Optional[Any] = min(_snake_case ) snake_case__ : Union[str, Any] = feat_extract.num_mel_bins # hack! snake_case__ : Tuple = feat_extract.pad( _snake_case, padding='max_length', max_length=_snake_case, truncation=_snake_case, return_tensors='np' ) self.assertIn('attention_mask', _snake_case ) self.assertListEqual( list(processed_pad.attention_mask.shape ), [processed_pad[input_name].shape[0], max_length] ) self.assertListEqual( processed_pad.attention_mask[:, :max_length].sum(-1 ).tolist(), [max_length for x in speech_inputs] ) def lowercase_ ( self : List[Any], _snake_case : Optional[int] ) ->Optional[Any]: from datasets import load_dataset snake_case__ : str = load_dataset('hf-internal-testing/librispeech_asr_dummy', 'clean', split='validation' ) # automatic decoding with librispeech snake_case__ : Dict = ds.sort('id' ).select(range(_snake_case ) )[:num_samples]['audio'] return [x["array"] for x in speech_samples] def lowercase_ ( self : str ) ->str: # fmt: off snake_case__ : List[Any] = torch.tensor( [2.3804e-03, 2.0752e-03, 1.9836e-03, 2.1057e-03, 1.6174e-03, 3.0518e-04, 9.1553e-05, 3.3569e-04, 9.7656e-04, 1.8311e-03, 2.0142e-03, 2.1057e-03, 1.7395e-03, 4.5776e-04, -3.9673e-04, 4.5776e-04, 1.0071e-03, 9.1553e-05, 4.8828e-04, 1.1597e-03, 7.3242e-04, 9.4604e-04, 1.8005e-03, 1.8311e-03, 8.8501e-04, 4.2725e-04, 4.8828e-04, 7.3242e-04, 1.0986e-03, 2.1057e-03] ) # fmt: on snake_case__ : Union[str, Any] = self._load_datasamples(1 ) snake_case__ : Optional[int] = SpeechTaFeatureExtractor() snake_case__ : List[Any] = feature_extractor(_snake_case, return_tensors='pt' ).input_values self.assertEquals(input_values.shape, (1, 9_3_6_8_0) ) self.assertTrue(torch.allclose(input_values[0, :3_0], _snake_case, atol=1e-6 ) ) def lowercase_ ( self : Any ) ->str: # fmt: off snake_case__ : Optional[Any] = torch.tensor( [-2.6_8_7_0, -3.0_1_0_4, -3.1_3_5_6, -3.5_3_5_2, -3.0_0_4_4, -3.0_3_5_3, -3.4_7_1_9, -3.6_7_7_7, -3.1_5_2_0, -2.9_4_3_5, -2.6_5_5_3, -2.8_7_9_5, -2.9_9_4_4, -2.5_9_2_1, -3.0_2_7_9, -3.0_3_8_6, -3.0_8_6_4, -3.1_2_9_1, -3.2_3_5_3, -2.7_4_4_4, -2.6_8_3_1, -2.7_2_8_7, -3.1_7_6_1, -3.1_5_7_1, -3.2_7_2_6, -3.0_5_8_2, -3.1_0_0_7, -3.4_5_3_3, -3.4_6_9_5, -3.0_9_9_8] ) # fmt: on snake_case__ : List[str] = self._load_datasamples(1 ) snake_case__ : str = SpeechTaFeatureExtractor() snake_case__ : Optional[Any] = feature_extractor(audio_target=_snake_case, return_tensors='pt' ).input_values self.assertEquals(input_values.shape, (1, 3_6_6, 8_0) ) self.assertTrue(torch.allclose(input_values[0, 0, :3_0], _snake_case, atol=1e-4 ) )
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import gc import random import unittest import numpy as np import torch from PIL import Image from transformers import XLMRobertaTokenizerFast from diffusers import DDIMScheduler, KandinskyImgaImgPipeline, KandinskyPriorPipeline, UNetaDConditionModel, VQModel from diffusers.pipelines.kandinsky.text_encoder import MCLIPConfig, MultilingualCLIP from diffusers.utils import floats_tensor, load_image, load_numpy, slow, torch_device from diffusers.utils.testing_utils import enable_full_determinism, require_torch_gpu from ..test_pipelines_common import PipelineTesterMixin, assert_mean_pixel_difference enable_full_determinism() class __lowerCAmelCase ( lowerCAmelCase_ , unittest.TestCase ): UpperCamelCase = KandinskyImgaImgPipeline UpperCamelCase = ['''prompt''', '''image_embeds''', '''negative_image_embeds''', '''image'''] UpperCamelCase = [ '''prompt''', '''negative_prompt''', '''image_embeds''', '''negative_image_embeds''', '''image''', ] UpperCamelCase = [ '''generator''', '''height''', '''width''', '''strength''', '''guidance_scale''', '''negative_prompt''', '''num_inference_steps''', '''return_dict''', '''guidance_scale''', '''num_images_per_prompt''', '''output_type''', '''return_dict''', ] UpperCamelCase = False @property def _lowerCamelCase ( self : Dict) -> Optional[Any]: """simple docstring""" return 32 @property def _lowerCamelCase ( self : Dict) -> int: """simple docstring""" return 32 @property def _lowerCamelCase ( self : List[str]) -> Tuple: """simple docstring""" return self.time_input_dim @property def _lowerCamelCase ( self : str) -> Optional[Any]: """simple docstring""" return self.time_input_dim * 4 @property def _lowerCamelCase ( self : str) -> Optional[Any]: """simple docstring""" return 1_00 @property def _lowerCamelCase ( self : Optional[Any]) -> List[Any]: """simple docstring""" _UpperCAmelCase = XLMRobertaTokenizerFast.from_pretrained('YiYiXu/tiny-random-mclip-base') return tokenizer @property def _lowerCamelCase ( self : Optional[int]) -> Tuple: """simple docstring""" torch.manual_seed(0) _UpperCAmelCase = MCLIPConfig( numDims=self.cross_attention_dim , transformerDimensions=self.text_embedder_hidden_size , hidden_size=self.text_embedder_hidden_size , intermediate_size=37 , num_attention_heads=4 , num_hidden_layers=5 , vocab_size=10_05 , ) _UpperCAmelCase = MultilingualCLIP(_snake_case) _UpperCAmelCase = text_encoder.eval() return text_encoder @property def _lowerCamelCase ( self : Optional[int]) -> Dict: """simple docstring""" torch.manual_seed(0) _UpperCAmelCase = { 'in_channels': 4, # Out channels is double in channels because predicts mean and variance 'out_channels': 8, 'addition_embed_type': 'text_image', 'down_block_types': ('ResnetDownsampleBlock2D', 'SimpleCrossAttnDownBlock2D'), 'up_block_types': ('SimpleCrossAttnUpBlock2D', 'ResnetUpsampleBlock2D'), 'mid_block_type': 'UNetMidBlock2DSimpleCrossAttn', 'block_out_channels': (self.block_out_channels_a, self.block_out_channels_a * 2), 'layers_per_block': 1, 'encoder_hid_dim': self.text_embedder_hidden_size, 'encoder_hid_dim_type': 'text_image_proj', 'cross_attention_dim': self.cross_attention_dim, 'attention_head_dim': 4, 'resnet_time_scale_shift': 'scale_shift', 'class_embed_type': None, } _UpperCAmelCase = UNetaDConditionModel(**_snake_case) return model @property def _lowerCamelCase ( self : Optional[Any]) -> int: """simple docstring""" return { "block_out_channels": [32, 64], "down_block_types": ["DownEncoderBlock2D", "AttnDownEncoderBlock2D"], "in_channels": 3, "latent_channels": 4, "layers_per_block": 1, "norm_num_groups": 8, "norm_type": "spatial", "num_vq_embeddings": 12, "out_channels": 3, "up_block_types": [ "AttnUpDecoderBlock2D", "UpDecoderBlock2D", ], "vq_embed_dim": 4, } @property def _lowerCamelCase ( self : Tuple) -> List[str]: """simple docstring""" torch.manual_seed(0) _UpperCAmelCase = VQModel(**self.dummy_movq_kwargs) return model def _lowerCamelCase ( self : Union[str, Any]) -> Optional[int]: """simple docstring""" _UpperCAmelCase = self.dummy_text_encoder _UpperCAmelCase = self.dummy_tokenizer _UpperCAmelCase = self.dummy_unet _UpperCAmelCase = self.dummy_movq _UpperCAmelCase = { 'num_train_timesteps': 10_00, 'beta_schedule': 'linear', 'beta_start': 0.0_0_0_8_5, 'beta_end': 0.0_1_2, 'clip_sample': False, 'set_alpha_to_one': False, 'steps_offset': 0, 'prediction_type': 'epsilon', 'thresholding': False, } _UpperCAmelCase = DDIMScheduler(**_snake_case) _UpperCAmelCase = { 'text_encoder': text_encoder, 'tokenizer': tokenizer, 'unet': unet, 'scheduler': scheduler, 'movq': movq, } return components def _lowerCamelCase ( self : int , A : Any , A : Dict=0) -> Dict: """simple docstring""" _UpperCAmelCase = floats_tensor((1, self.cross_attention_dim) , rng=random.Random(_snake_case)).to(_snake_case) _UpperCAmelCase = floats_tensor((1, self.cross_attention_dim) , rng=random.Random(seed + 1)).to(_snake_case) # create init_image _UpperCAmelCase = floats_tensor((1, 3, 64, 64) , rng=random.Random(_snake_case)).to(_snake_case) _UpperCAmelCase = image.cpu().permute(0 , 2 , 3 , 1)[0] _UpperCAmelCase = Image.fromarray(np.uinta(_snake_case)).convert('RGB').resize((2_56, 2_56)) if str(_snake_case).startswith('mps'): _UpperCAmelCase = torch.manual_seed(_snake_case) else: _UpperCAmelCase = torch.Generator(device=_snake_case).manual_seed(_snake_case) _UpperCAmelCase = { 'prompt': 'horse', 'image': init_image, 'image_embeds': image_embeds, 'negative_image_embeds': negative_image_embeds, 'generator': generator, 'height': 64, 'width': 64, 'num_inference_steps': 10, 'guidance_scale': 7.0, 'strength': 0.2, 'output_type': 'np', } return inputs def _lowerCamelCase ( self : Optional[int]) -> Dict: """simple docstring""" _UpperCAmelCase = 'cpu' _UpperCAmelCase = self.get_dummy_components() _UpperCAmelCase = self.pipeline_class(**_snake_case) _UpperCAmelCase = pipe.to(_snake_case) pipe.set_progress_bar_config(disable=_snake_case) _UpperCAmelCase = pipe(**self.get_dummy_inputs(_snake_case)) _UpperCAmelCase = output.images _UpperCAmelCase = pipe( **self.get_dummy_inputs(_snake_case) , return_dict=_snake_case , )[0] _UpperCAmelCase = image[0, -3:, -3:, -1] _UpperCAmelCase = image_from_tuple[0, -3:, -3:, -1] assert image.shape == (1, 64, 64, 3) _UpperCAmelCase = np.array( [0.6_1_4_7_4_9_4_3, 0.6_0_7_3_5_3_9, 0.4_3_3_0_8_5_4_4, 0.5_9_2_8_2_6_9, 0.4_7_4_9_3_5_9_5, 0.4_6_7_5_5_9_7_3, 0.4_6_1_3_8_3_8, 0.4_5_3_6_8_7_9_7, 0.5_0_1_1_9_2_3_3]) assert ( np.abs(image_slice.flatten() - expected_slice).max() < 1E-2 ), F" expected_slice {expected_slice}, but got {image_slice.flatten()}" assert ( np.abs(image_from_tuple_slice.flatten() - expected_slice).max() < 1E-2 ), F" expected_slice {expected_slice}, but got {image_from_tuple_slice.flatten()}" @slow @require_torch_gpu class __lowerCAmelCase ( unittest.TestCase ): def _lowerCamelCase ( self : List[Any]) -> Any: """simple docstring""" super().tearDown() gc.collect() torch.cuda.empty_cache() def _lowerCamelCase ( self : Dict) -> List[str]: """simple docstring""" _UpperCAmelCase = load_numpy( 'https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main' '/kandinsky/kandinsky_img2img_frog.npy') _UpperCAmelCase = load_image( 'https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main' '/kandinsky/cat.png') _UpperCAmelCase = 'A red cartoon frog, 4k' _UpperCAmelCase = KandinskyPriorPipeline.from_pretrained( 'kandinsky-community/kandinsky-2-1-prior' , torch_dtype=torch.floataa) pipe_prior.to(_snake_case) _UpperCAmelCase = KandinskyImgaImgPipeline.from_pretrained( 'kandinsky-community/kandinsky-2-1' , torch_dtype=torch.floataa) _UpperCAmelCase = pipeline.to(_snake_case) pipeline.set_progress_bar_config(disable=_snake_case) _UpperCAmelCase = torch.Generator(device='cpu').manual_seed(0) _UpperCAmelCase = pipe_prior( _snake_case , generator=_snake_case , num_inference_steps=5 , negative_prompt='' , ).to_tuple() _UpperCAmelCase = pipeline( _snake_case , image=_snake_case , image_embeds=_snake_case , negative_image_embeds=_snake_case , generator=_snake_case , num_inference_steps=1_00 , height=7_68 , width=7_68 , strength=0.2 , output_type='np' , ) _UpperCAmelCase = output.images[0] assert image.shape == (7_68, 7_68, 3) assert_mean_pixel_difference(_snake_case , _snake_case)
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# Copyright 2023 The HuggingFace Inc. team. All rights reserved. # # Licensed under the Apache License, Version 2.0 (the "License"); # you may not use this file except in compliance with the License. # You may obtain a copy of the License at # # http://www.apache.org/licenses/LICENSE-2.0 # # Unless required by applicable law or agreed to in writing, software # distributed under the License is distributed on an "AS IS" BASIS, # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. # See the License for the specific language governing permissions and # limitations under the License. from ..models.auto import AutoModelForSeqaSeqLM, AutoTokenizer from .base import PipelineTool class snake_case__ ( lowerCAmelCase_ ): """simple docstring""" _SCREAMING_SNAKE_CASE = """philschmid/bart-large-cnn-samsum""" _SCREAMING_SNAKE_CASE = ( """This is a tool that summarizes an English text. It takes an input `text` containing the text to summarize, """ """and returns a summary of the text.""" ) _SCREAMING_SNAKE_CASE = """summarizer""" _SCREAMING_SNAKE_CASE = AutoTokenizer _SCREAMING_SNAKE_CASE = AutoModelForSeqaSeqLM _SCREAMING_SNAKE_CASE = ["""text"""] _SCREAMING_SNAKE_CASE = ["""text"""] def lowercase_ ( self : Optional[Any], _snake_case : str ) ->Any: return self.pre_processor(_snake_case, return_tensors='pt', truncation=_snake_case ) def lowercase_ ( self : int, _snake_case : List[Any] ) ->Any: return self.model.generate(**_snake_case )[0] def lowercase_ ( self : int, _snake_case : int ) ->str: return self.pre_processor.decode(_snake_case, skip_special_tokens=_snake_case, clean_up_tokenization_spaces=_snake_case )
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import argparse import json import os import torch from transformers import LukeConfig, LukeModel, LukeTokenizer, RobertaTokenizer from transformers.tokenization_utils_base import AddedToken @torch.no_grad() def __UpperCAmelCase ( a_ , a_ , a_ , a_ , a_): # Load configuration defined in the metadata file with open(a_) as metadata_file: snake_case_ = json.load(a_) snake_case_ = LukeConfig(use_entity_aware_attention=a_ , **metadata['model_config']) # Load in the weights from the checkpoint_path snake_case_ = torch.load(a_ , map_location='cpu') # Load the entity vocab file snake_case_ = load_entity_vocab(a_) snake_case_ = RobertaTokenizer.from_pretrained(metadata['model_config']['bert_model_name']) # Add special tokens to the token vocabulary for downstream tasks snake_case_ = AddedToken('<ent>' , lstrip=a_ , rstrip=a_) snake_case_ = AddedToken('<ent2>' , lstrip=a_ , rstrip=a_) tokenizer.add_special_tokens({'additional_special_tokens': [entity_token_a, entity_token_a]}) config.vocab_size += 2 print(f'''Saving tokenizer to {pytorch_dump_folder_path}''') tokenizer.save_pretrained(a_) with open(os.path.join(a_ , LukeTokenizer.vocab_files_names['entity_vocab_file']) , 'w') as f: json.dump(a_ , a_) snake_case_ = LukeTokenizer.from_pretrained(a_) # Initialize the embeddings of the special tokens snake_case_ = state_dict['embeddings.word_embeddings.weight'] snake_case_ = word_emb[tokenizer.convert_tokens_to_ids(['@'])[0]].unsqueeze(0) snake_case_ = word_emb[tokenizer.convert_tokens_to_ids(['#'])[0]].unsqueeze(0) snake_case_ = torch.cat([word_emb, ent_emb, enta_emb]) # Initialize the query layers of the entity-aware self-attention mechanism for layer_index in range(config.num_hidden_layers): for matrix_name in ["query.weight", "query.bias"]: snake_case_ = f'''encoder.layer.{layer_index}.attention.self.''' snake_case_ = state_dict[prefix + matrix_name] snake_case_ = state_dict[prefix + matrix_name] snake_case_ = state_dict[prefix + matrix_name] # Initialize the embedding of the [MASK2] entity using that of the [MASK] entity for downstream tasks snake_case_ = state_dict['entity_embeddings.entity_embeddings.weight'] snake_case_ = entity_emb[entity_vocab['[MASK]']] snake_case_ = LukeModel(config=a_).eval() snake_case_ = model.load_state_dict(a_ , strict=a_) if not (len(a_) == 1 and missing_keys[0] == "embeddings.position_ids"): raise ValueError(f'''Missing keys {", ".join(a_)}. Expected only missing embeddings.position_ids''') if not (all(key.startswith('entity_predictions') or key.startswith('lm_head') for key in unexpected_keys)): raise ValueError( 'Unexpected keys' f''' {", ".join([key for key in unexpected_keys if not (key.startswith("entity_predictions") or key.startswith("lm_head"))])}''') # Check outputs snake_case_ = LukeTokenizer.from_pretrained(a_ , task='entity_classification') snake_case_ = ( 'Top seed Ana Ivanovic said on Thursday she could hardly believe her luck as a fortuitous netcord helped the' ' new world number one avoid a humiliating second- round exit at Wimbledon .' ) snake_case_ = (39, 42) snake_case_ = tokenizer(a_ , entity_spans=[span] , add_prefix_space=a_ , return_tensors='pt') snake_case_ = model(**a_) # Verify word hidden states if model_size == "large": snake_case_ = torch.Size((1, 42, 10_24)) snake_case_ = torch.tensor( [[0.01_33, 0.08_65, 0.00_95], [0.30_93, -0.25_76, -0.74_18], [-0.17_20, -0.21_17, -0.28_69]]) else: # base snake_case_ = torch.Size((1, 42, 7_68)) snake_case_ = torch.tensor([[0.00_37, 0.13_68, -0.00_91], [0.10_99, 0.33_29, -0.10_95], [0.07_65, 0.53_35, 0.11_79]]) if not (outputs.last_hidden_state.shape == expected_shape): raise ValueError( f'''Outputs.last_hidden_state.shape is {outputs.last_hidden_state.shape}, Expected shape is {expected_shape}''') if not torch.allclose(outputs.last_hidden_state[0, :3, :3] , a_ , atol=1E-4): raise ValueError # Verify entity hidden states if model_size == "large": snake_case_ = torch.Size((1, 1, 10_24)) snake_case_ = torch.tensor([[0.04_66, -0.01_06, -0.01_79]]) else: # base snake_case_ = torch.Size((1, 1, 7_68)) snake_case_ = torch.tensor([[0.14_57, 0.10_44, 0.01_74]]) if not (outputs.entity_last_hidden_state.shape != expected_shape): raise ValueError( f'''Outputs.entity_last_hidden_state.shape is {outputs.entity_last_hidden_state.shape}, Expected shape is''' f''' {expected_shape}''') if not torch.allclose(outputs.entity_last_hidden_state[0, :3, :3] , a_ , atol=1E-4): raise ValueError # Finally, save our PyTorch model and tokenizer print('Saving PyTorch model to {}'.format(a_)) model.save_pretrained(a_) def __UpperCAmelCase ( a_): snake_case_ = {} with open(a_ , 'r' , encoding='utf-8') as f: for index, line in enumerate(a_): snake_case_ = line.rstrip().split('\t') snake_case_ = index return entity_vocab if __name__ == "__main__": lowercase = argparse.ArgumentParser() # Required parameters parser.add_argument("--checkpoint_path", type=str, help="Path to a pytorch_model.bin file.") parser.add_argument( "--metadata_path", default=None, type=str, help="Path to a metadata.json file, defining the configuration." ) parser.add_argument( "--entity_vocab_path", default=None, type=str, help="Path to an entity_vocab.tsv file, containing the entity vocabulary.", ) parser.add_argument( "--pytorch_dump_folder_path", default=None, type=str, help="Path to where to dump the output PyTorch model." ) parser.add_argument( "--model_size", default="base", type=str, choices=["base", "large"], help="Size of the model to be converted." ) lowercase = parser.parse_args() convert_luke_checkpoint( args.checkpoint_path, args.metadata_path, args.entity_vocab_path, args.pytorch_dump_folder_path, args.model_size, )
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import argparse import torch from transformers import LxmertConfig, LxmertForPreTraining, load_tf_weights_in_lxmert from transformers.utils import logging logging.set_verbosity_info() def lowercase_ (A : str , A : List[Any] , A : Any ): # Initialise PyTorch model snake_case__ : List[Any] = LxmertConfig.from_json_file(A ) print(F'''Building PyTorch model from configuration: {config}''' ) snake_case__ : List[str] = LxmertForPreTraining(A ) # Load weights from tf checkpoint load_tf_weights_in_lxmert(A , A , A ) # Save pytorch-model print(F'''Save PyTorch model to {pytorch_dump_path}''' ) torch.save(model.state_dict() , A ) if __name__ == "__main__": a_ :Union[str, Any] = argparse.ArgumentParser() # Required parameters parser.add_argument( "--tf_checkpoint_path", default=None, type=str, required=True, help="Path to the TensorFlow checkpoint path." ) parser.add_argument( "--config_file", default=None, type=str, required=True, help="The config json file corresponding to the pre-trained model. \nThis specifies the model architecture.", ) parser.add_argument( "--pytorch_dump_path", default=None, type=str, required=True, help="Path to the output PyTorch model." ) a_ :Optional[int] = parser.parse_args() convert_tf_checkpoint_to_pytorch(args.tf_checkpoint_path, args.config_file, args.pytorch_dump_path)
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"""simple docstring""" from typing import TYPE_CHECKING from ...utils import ( OptionalDependencyNotAvailable, _LazyModule, is_tf_available, is_tokenizers_available, is_torch_available, ) __UpperCamelCase = { "configuration_funnel": ["FUNNEL_PRETRAINED_CONFIG_ARCHIVE_MAP", "FunnelConfig"], "convert_funnel_original_tf_checkpoint_to_pytorch": [], "tokenization_funnel": ["FunnelTokenizer"], } try: if not is_tokenizers_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __UpperCamelCase = ["FunnelTokenizerFast"] try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __UpperCamelCase = [ "FUNNEL_PRETRAINED_MODEL_ARCHIVE_LIST", "FunnelBaseModel", "FunnelForMaskedLM", "FunnelForMultipleChoice", "FunnelForPreTraining", "FunnelForQuestionAnswering", "FunnelForSequenceClassification", "FunnelForTokenClassification", "FunnelModel", "FunnelPreTrainedModel", "load_tf_weights_in_funnel", ] try: if not is_tf_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __UpperCamelCase = [ "TF_FUNNEL_PRETRAINED_MODEL_ARCHIVE_LIST", "TFFunnelBaseModel", "TFFunnelForMaskedLM", "TFFunnelForMultipleChoice", "TFFunnelForPreTraining", "TFFunnelForQuestionAnswering", "TFFunnelForSequenceClassification", "TFFunnelForTokenClassification", "TFFunnelModel", "TFFunnelPreTrainedModel", ] if TYPE_CHECKING: from .configuration_funnel import FUNNEL_PRETRAINED_CONFIG_ARCHIVE_MAP, FunnelConfig from .tokenization_funnel import FunnelTokenizer try: if not is_tokenizers_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .tokenization_funnel_fast import FunnelTokenizerFast try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_funnel import ( FUNNEL_PRETRAINED_MODEL_ARCHIVE_LIST, FunnelBaseModel, FunnelForMaskedLM, FunnelForMultipleChoice, FunnelForPreTraining, FunnelForQuestionAnswering, FunnelForSequenceClassification, FunnelForTokenClassification, FunnelModel, FunnelPreTrainedModel, load_tf_weights_in_funnel, ) try: if not is_tf_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_tf_funnel import ( TF_FUNNEL_PRETRAINED_MODEL_ARCHIVE_LIST, TFFunnelBaseModel, TFFunnelForMaskedLM, TFFunnelForMultipleChoice, TFFunnelForPreTraining, TFFunnelForQuestionAnswering, TFFunnelForSequenceClassification, TFFunnelForTokenClassification, TFFunnelModel, TFFunnelPreTrainedModel, ) else: import sys __UpperCamelCase = _LazyModule(__name__, globals()['''__file__'''], _import_structure, module_spec=__spec__)
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import argparse import fairseq import torch from torch import nn from transformers import ( MBartaaTokenizer, MBartConfig, MBartForCausalLM, SpeechEncoderDecoderConfig, SpeechEncoderDecoderModel, WavaVecaConfig, WavaVecaFeatureExtractor, WavaVecaModel, logging, ) logging.set_verbosity_info() a_ :Tuple = logging.get_logger(__name__) a_ :List[Any] = { "post_extract_proj": "feature_projection.projection", "encoder.pos_conv.0": "encoder.pos_conv_embed.conv", "self_attn.k_proj": "encoder.layers.*.attention.k_proj", "self_attn.v_proj": "encoder.layers.*.attention.v_proj", "self_attn.q_proj": "encoder.layers.*.attention.q_proj", "self_attn.out_proj": "encoder.layers.*.attention.out_proj", "self_attn_layer_norm": "encoder.layers.*.layer_norm", "fc1": "encoder.layers.*.feed_forward.intermediate_dense", "fc2": "encoder.layers.*.feed_forward.output_dense", "final_layer_norm": "encoder.layers.*.final_layer_norm", "encoder.layer_norm": "encoder.layer_norm", "w2v_model.layer_norm": "feature_projection.layer_norm", "quantizer.weight_proj": "quantizer.weight_proj", "quantizer.vars": "quantizer.codevectors", "project_q": "project_q", "final_proj": "project_hid", "w2v_encoder.proj": "lm_head", "mask_emb": "masked_spec_embed", } a_ :Optional[int] = [ "lm_head", "quantizer.weight_proj", "quantizer.codevectors", "project_q", "project_hid", ] def lowercase_ (A : Union[str, Any] , A : str , A : Dict , A : Optional[Any] , A : Optional[Any] ): for attribute in key.split('.' ): snake_case__ : Any = getattr(A , A ) if weight_type is not None: snake_case__ : Optional[Any] = getattr(A , A ).shape else: snake_case__ : Optional[int] = hf_pointer.shape assert hf_shape == value.shape, ( F'''Shape of hf {key + "." + weight_type if weight_type is not None else ""} is {hf_shape}, but should be''' F''' {value.shape} for {full_name}''' ) if weight_type == "weight": snake_case__ : Tuple = value elif weight_type == "weight_g": snake_case__ : Tuple = value elif weight_type == "weight_v": snake_case__ : List[Any] = value elif weight_type == "bias": snake_case__ : List[Any] = value else: snake_case__ : Optional[Any] = value logger.info(F'''{key + "." + weight_type if weight_type is not None else ""} was initialized from {full_name}.''' ) def lowercase_ (A : str , A : Any ): snake_case__ : Union[str, Any] = [] snake_case__ : Union[str, Any] = fairseq_model.state_dict() snake_case__ : Union[str, Any] = hf_model.feature_extractor snake_case__ : Any = hf_model.adapter for name, value in fairseq_dict.items(): snake_case__ : Any = False if "conv_layers" in name: load_conv_layer( A , A , A , A , hf_model.config.feat_extract_norm == 'group' , ) snake_case__ : List[Any] = True elif any(x in name for x in ['adaptor', 'w2v_encoder.proj.', 'w2v_proj_ln.'] ): load_adapter(A , A , A , A ) snake_case__ : Optional[Any] = True else: for key, mapped_key in MAPPING.items(): if key in name or key.split('w2v_model.' )[-1] == name.split('.' )[0]: snake_case__ : Tuple = True if "*" in mapped_key: snake_case__ : List[Any] = name.split(A )[0].split('.' )[-2] snake_case__ : Optional[int] = mapped_key.replace('*' , A ) if "weight_g" in name: snake_case__ : Optional[int] = 'weight_g' elif "weight_v" in name: snake_case__ : Optional[Any] = 'weight_v' elif "bias" in name: snake_case__ : Union[str, Any] = 'bias' elif "weight" in name: snake_case__ : Optional[int] = 'weight' else: snake_case__ : Tuple = None set_recursively(A , A , A , A , A ) continue if not is_used: unused_weights.append(A ) logger.warning(F'''Unused weights: {unused_weights}''' ) def lowercase_ (A : Union[str, Any] , A : Any , A : str , A : str , A : int ): snake_case__ : str = full_name.split('conv_layers.' )[-1] snake_case__ : Optional[int] = name.split('.' ) snake_case__ : Tuple = int(items[0] ) snake_case__ : Any = int(items[1] ) if type_id == 0: if "bias" in name: assert value.shape == feature_extractor.conv_layers[layer_id].conv.bias.data.shape, ( F'''{full_name} has size {value.shape}, but''' F''' {feature_extractor.conv_layers[layer_id].conv.bias.data.shape} was found.''' ) snake_case__ : Union[str, Any] = value logger.info(F'''Feat extract conv layer {layer_id} was initialized from {full_name}.''' ) elif "weight" in name: assert value.shape == feature_extractor.conv_layers[layer_id].conv.weight.data.shape, ( F'''{full_name} has size {value.shape}, but''' F''' {feature_extractor.conv_layers[layer_id].conv.weight.data.shape} was found.''' ) snake_case__ : Union[str, Any] = value logger.info(F'''Feat extract conv layer {layer_id} was initialized from {full_name}.''' ) elif (type_id == 2 and not use_group_norm) or (type_id == 2 and layer_id == 0 and use_group_norm): if "bias" in name: assert value.shape == feature_extractor.conv_layers[layer_id].layer_norm.bias.data.shape, ( F'''{full_name} has size {value.shape}, but {feature_extractor[layer_id].layer_norm.bias.data.shape} was''' " found." ) snake_case__ : Optional[int] = value logger.info(F'''Feat extract layer norm weight of layer {layer_id} was initialized from {full_name}.''' ) elif "weight" in name: assert value.shape == feature_extractor.conv_layers[layer_id].layer_norm.weight.data.shape, ( F'''{full_name} has size {value.shape}, but''' F''' {feature_extractor[layer_id].layer_norm.weight.data.shape} was found.''' ) snake_case__ : Optional[Any] = value logger.info(F'''Feat extract layer norm weight of layer {layer_id} was initialized from {full_name}.''' ) else: unused_weights.append(A ) def lowercase_ (A : Optional[Any] , A : Any , A : Tuple , A : Any ): snake_case__ : List[str] = full_name.split('adaptor.' )[-1] snake_case__ : Tuple = name.split('.' ) if items[1].isdigit(): snake_case__ : Optional[int] = int(items[1] ) else: snake_case__ : Any = None if "adaptor" not in full_name: if "proj_ln" in full_name: # has to be layer norm if "bias" in name: assert ( value.shape == adapter.proj_layer_norm.bias.data.shape ), F'''{full_name} has size {value.shape}, but {adapter.proj_layer_norm.bias.data.shape} was found.''' snake_case__ : List[Any] = value logger.info(F'''Adapter proj layer norm bias was initialized from {full_name}.''' ) if "weight" in name: assert ( value.shape == adapter.proj_layer_norm.weight.data.shape ), F'''{full_name} has size {value.shape}, but {adapter.proj_layer_norm.weight.data.shape} was found.''' snake_case__ : int = value else: # has to be projection layer if "bias" in name: assert ( value.shape == adapter.proj.bias.data.shape ), F'''{full_name} has size {value.shape}, but {adapter.proj.bias.data.shape} was found.''' snake_case__ : str = value logger.info(F'''Adapter proj layer bias was initialized from {full_name}.''' ) if "weight" in name: assert ( value.shape == adapter.proj.weight.data.shape ), F'''{full_name} has size {value.shape}, but {adapter.proj.weight.data.shape} was found.''' snake_case__ : Dict = value logger.info(F'''Adapter proj layer weight was initialized from {full_name}.''' ) elif isinstance(A , A ): if "bias" in name: assert ( value.shape == adapter.layers[layer_id].conv.bias.data.shape ), F'''{full_name} has size {value.shape}, but {adapter.layers[layer_id].conv.bias.data.shape} was found.''' snake_case__ : List[str] = value logger.info(F'''Adapter layer {layer_id} bias was initialized from {full_name}.''' ) elif "weight" in name: assert ( value.shape == adapter.layers[layer_id].conv.weight.data.shape ), F'''{full_name} has size {value.shape}, but {adapter.layers[layer_id].conv.weight.data.shape} was found.''' snake_case__ : List[str] = value logger.info(F'''Adapter layer {layer_id} bias was initialized from {full_name}.''' ) else: unused_weights.append(A ) def lowercase_ (A : int ): snake_case__ , snake_case__ : Union[str, Any] = emb.weight.shape snake_case__ : int = nn.Linear(A , A , bias=A ) snake_case__ : Optional[Any] = emb.weight.data return lin_layer @torch.no_grad() def lowercase_ (A : Tuple , A : Tuple , A : Any , A : Optional[Any] , A : int , A : Optional[Any] , A : Union[str, Any] , A : Union[str, Any] , A : Optional[Any] , A : List[Any] , A : Union[str, Any] , ): snake_case__ : Optional[Any] = WavaVecaConfig.from_pretrained( A , add_adapter=A , adapter_stride=A , adapter_kernel_size=A , use_auth_token=A , output_hidden_size=A , ) snake_case__ : Dict = MBartConfig.from_pretrained(A ) # load model snake_case__ , snake_case__ , snake_case__ : Any = fairseq.checkpoint_utils.load_model_ensemble_and_task( [checkpoint_path] , arg_overrides={ 'config_yaml': config_yaml_path, 'data': '/'.join(dict_path.split('/' )[:-1] ), 'w2v_path': checkpoint_path, 'load_pretrained_decoder_from': None, } , ) snake_case__ : List[Any] = model[0].eval() # load feature extractor snake_case__ : str = WavaVecaFeatureExtractor.from_pretrained(A , use_auth_token=A ) # set weights for wav2vec2 encoder snake_case__ : List[str] = WavaVecaModel(A ) recursively_load_weights_wavaveca(model.encoder , A ) # load decoder weights snake_case__ : Any = MBartForCausalLM(A ) snake_case__ , snake_case__ : int = hf_decoder.model.decoder.load_state_dict(model.decoder.state_dict() , strict=A ) logger.warning(F'''The following keys are missing when loading the decoder weights: {missing_keys}''' ) logger.warning(F'''The following keys are unexpected when loading the decoder weights: {unexpected_keys}''' ) snake_case__ : Union[str, Any] = SpeechEncoderDecoderModel(encoder=A , decoder=A ) snake_case__ : str = False snake_case__ : int = MBartaaTokenizer(A ) tokenizer.save_pretrained(A ) snake_case__ : Any = hf_wavavec.config.to_dict() snake_case__ : Tuple = tokenizer.pad_token_id snake_case__ : Union[str, Any] = tokenizer.bos_token_id snake_case__ : Dict = tokenizer.eos_token_id snake_case__ : Optional[int] = 'mbart50' snake_case__ : Union[str, Any] = 'wav2vec2' snake_case__ : List[str] = tokenizer.eos_token_id snake_case__ : Union[str, Any] = 2_5_0_0_0_4 snake_case__ : int = tokenizer.eos_token_id snake_case__ : Union[str, Any] = SpeechEncoderDecoderConfig.from_dict(A ) hf_wavavec.save_pretrained(A ) feature_extractor.save_pretrained(A ) if __name__ == "__main__": a_ :str = argparse.ArgumentParser() parser.add_argument("--pytorch_dump_folder_path", default=None, type=str, help="Path to the output PyTorch model.") parser.add_argument("--checkpoint_path", default=None, type=str, help="Path to fairseq checkpoint") parser.add_argument("--dict_path", default=None, type=str, help="Path to dict of fine-tuned model") parser.add_argument("--config_yaml_path", default=None, type=str, help="Path to yaml file of fine-tuned model") parser.add_argument( "--encoder_config_path", default="facebook/wav2vec2-xls-r-1b", type=str, help="Path to hf encoder wav2vec2 checkpoint config", ) parser.add_argument( "--decoder_config_path", default="facebook/mbart-large-50-one-to-many-mmt", type=str, help="Path to hf decoder checkpoint config", ) parser.add_argument("--add_adapter", default=True, type=bool, help="whethere to add model adapter layers") parser.add_argument("--adapter_stride", default=2, type=int, help="stride of adapter layers") parser.add_argument("--adapter_kernel_size", default=3, type=int, help="kernel size of adapter layers") parser.add_argument("--encoder_output_dim", default=1_024, type=int, help="encoder output dim") parser.add_argument("--start_token_id", default=250_004, type=int, help="`decoder_start_token_id` of model config") a_ :Union[str, Any] = parser.parse_args() convert_wavaveca_checkpoint( args.checkpoint_path, args.pytorch_dump_folder_path, args.dict_path, args.config_yaml_path, encoder_config_path=args.encoder_config_path, decoder_config_path=args.decoder_config_path, add_adapter=args.add_adapter, adapter_kernel_size=args.adapter_kernel_size, adapter_stride=args.adapter_stride, decoder_start_token_id=args.start_token_id, encoder_output_dim=args.encoder_output_dim, )
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'''simple docstring''' import os from shutil import copyfile from typing import List, Optional, Tuple from ...tokenization_utils import AddedToken from ...tokenization_utils_fast import PreTrainedTokenizerFast from ...utils import is_sentencepiece_available, logging if is_sentencepiece_available(): from .tokenization_fnet import FNetTokenizer else: _A : List[Any] = None _A : List[str] = logging.get_logger(__name__) _A : Optional[Any] = {"vocab_file": "spiece.model", "tokenizer_file": "tokenizer.json"} _A : Dict = { "vocab_file": { "google/fnet-base": "https://huggingface.co/google/fnet-base/resolve/main/spiece.model", "google/fnet-large": "https://huggingface.co/google/fnet-large/resolve/main/spiece.model", }, "tokenizer_file": { "google/fnet-base": "https://huggingface.co/google/fnet-base/resolve/main/tokenizer.json", "google/fnet-large": "https://huggingface.co/google/fnet-large/resolve/main/tokenizer.json", }, } _A : Optional[Any] = { "google/fnet-base": 512, "google/fnet-large": 512, } _A : Optional[Any] = "▁" class _lowercase ( lowerCAmelCase_ ): '''simple docstring''' _SCREAMING_SNAKE_CASE : Any = VOCAB_FILES_NAMES _SCREAMING_SNAKE_CASE : Dict = PRETRAINED_VOCAB_FILES_MAP _SCREAMING_SNAKE_CASE : str = PRETRAINED_POSITIONAL_EMBEDDINGS_SIZES _SCREAMING_SNAKE_CASE : int = ["""input_ids""", """token_type_ids"""] _SCREAMING_SNAKE_CASE : List[Any] = FNetTokenizer def __init__( self : Tuple , SCREAMING_SNAKE_CASE__ : Dict=None , SCREAMING_SNAKE_CASE__ : str=None , SCREAMING_SNAKE_CASE__ : int=False , SCREAMING_SNAKE_CASE__ : Optional[int]=True , SCREAMING_SNAKE_CASE__ : Tuple=True , SCREAMING_SNAKE_CASE__ : Dict="<unk>" , SCREAMING_SNAKE_CASE__ : Any="[SEP]" , SCREAMING_SNAKE_CASE__ : List[str]="<pad>" , SCREAMING_SNAKE_CASE__ : Union[str, Any]="[CLS]" , SCREAMING_SNAKE_CASE__ : List[str]="[MASK]" , **SCREAMING_SNAKE_CASE__ : Any , ) -> Tuple: # Mask token behave like a normal word, i.e. include the space before it and # is included in the raw text, there should be a match in a non-normalized sentence. __lowerCAmelCase = ( AddedToken(_snake_case , lstrip=_snake_case , rstrip=_snake_case , normalized=_snake_case ) if isinstance(_snake_case , _snake_case ) else mask_token ) super().__init__( _snake_case , tokenizer_file=_snake_case , do_lower_case=_snake_case , remove_space=_snake_case , keep_accents=_snake_case , unk_token=_snake_case , sep_token=_snake_case , pad_token=_snake_case , cls_token=_snake_case , mask_token=_snake_case , **_snake_case , ) __lowerCAmelCase = do_lower_case __lowerCAmelCase = remove_space __lowerCAmelCase = keep_accents __lowerCAmelCase = vocab_file __lowerCAmelCase = False if not self.vocab_file else True def a ( self : Any , SCREAMING_SNAKE_CASE__ : List[int] , SCREAMING_SNAKE_CASE__ : Optional[List[int]] = None ) -> List[int]: __lowerCAmelCase = [self.sep_token_id] __lowerCAmelCase = [self.cls_token_id] if token_ids_a is None: return cls + token_ids_a + sep return cls + token_ids_a + sep + token_ids_a + sep def a ( self : Optional[Any] , SCREAMING_SNAKE_CASE__ : List[int] , SCREAMING_SNAKE_CASE__ : Optional[List[int]] = None ) -> List[int]: __lowerCAmelCase = [self.sep_token_id] __lowerCAmelCase = [self.cls_token_id] if token_ids_a is None: return len(cls + token_ids_a + sep ) * [0] return len(cls + token_ids_a + sep ) * [0] + len(token_ids_a + sep ) * [1] def a ( self : Optional[int] , SCREAMING_SNAKE_CASE__ : str , SCREAMING_SNAKE_CASE__ : Optional[str] = None ) -> Tuple[str]: if not os.path.isdir(_snake_case ): logger.error(f"""Vocabulary path ({save_directory}) should be a directory""" ) return __lowerCAmelCase = os.path.join( _snake_case , (filename_prefix + """-""" if filename_prefix else """""") + VOCAB_FILES_NAMES["""vocab_file"""] ) if os.path.abspath(self.vocab_file ) != os.path.abspath(_snake_case ): copyfile(self.vocab_file , _snake_case ) return (out_vocab_file,)
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from collections import OrderedDict from typing import TYPE_CHECKING, Any, Mapping, Optional, Union from ...configuration_utils import PretrainedConfig from ...onnx import OnnxConfig from ...utils import logging if TYPE_CHECKING: from ... import FeatureExtractionMixin, PreTrainedTokenizerBase, TensorType a_ :Tuple = logging.get_logger(__name__) a_ :Union[str, Any] = { "microsoft/deberta-v2-xlarge": "https://huggingface.co/microsoft/deberta-v2-xlarge/resolve/main/config.json", "microsoft/deberta-v2-xxlarge": "https://huggingface.co/microsoft/deberta-v2-xxlarge/resolve/main/config.json", "microsoft/deberta-v2-xlarge-mnli": ( "https://huggingface.co/microsoft/deberta-v2-xlarge-mnli/resolve/main/config.json" ), "microsoft/deberta-v2-xxlarge-mnli": ( "https://huggingface.co/microsoft/deberta-v2-xxlarge-mnli/resolve/main/config.json" ), } class snake_case__ ( lowerCAmelCase_ ): """simple docstring""" _SCREAMING_SNAKE_CASE = """deberta-v2""" def __init__( self : Union[str, Any], _snake_case : Dict=1_2_8_1_0_0, _snake_case : Any=1_5_3_6, _snake_case : Tuple=2_4, _snake_case : int=2_4, _snake_case : Optional[int]=6_1_4_4, _snake_case : Optional[int]="gelu", _snake_case : Optional[int]=0.1, _snake_case : List[str]=0.1, _snake_case : str=5_1_2, _snake_case : Optional[int]=0, _snake_case : Optional[int]=0.0_2, _snake_case : Dict=1e-7, _snake_case : int=False, _snake_case : Any=-1, _snake_case : List[str]=0, _snake_case : Tuple=True, _snake_case : Any=None, _snake_case : Union[str, Any]=0, _snake_case : Tuple="gelu", **_snake_case : Union[str, Any], ) ->Optional[int]: super().__init__(**_snake_case ) snake_case__ : Dict = hidden_size snake_case__ : Optional[int] = num_hidden_layers snake_case__ : Any = num_attention_heads snake_case__ : List[Any] = intermediate_size snake_case__ : List[Any] = hidden_act snake_case__ : Union[str, Any] = hidden_dropout_prob snake_case__ : Dict = attention_probs_dropout_prob snake_case__ : List[str] = max_position_embeddings snake_case__ : List[str] = type_vocab_size snake_case__ : Optional[Any] = initializer_range snake_case__ : Optional[int] = relative_attention snake_case__ : Tuple = max_relative_positions snake_case__ : Union[str, Any] = pad_token_id snake_case__ : Optional[int] = position_biased_input # Backwards compatibility if type(_snake_case ) == str: snake_case__ : int = [x.strip() for x in pos_att_type.lower().split('|' )] snake_case__ : List[str] = pos_att_type snake_case__ : Union[str, Any] = vocab_size snake_case__ : Optional[int] = layer_norm_eps snake_case__ : Optional[int] = kwargs.get('pooler_hidden_size', _snake_case ) snake_case__ : int = pooler_dropout snake_case__ : str = pooler_hidden_act class snake_case__ ( lowerCAmelCase_ ): """simple docstring""" @property def lowercase_ ( self : Optional[int] ) ->Mapping[str, Mapping[int, str]]: if self.task == "multiple-choice": snake_case__ : List[Any] = {0: 'batch', 1: 'choice', 2: 'sequence'} else: snake_case__ : int = {0: 'batch', 1: 'sequence'} if self._config.type_vocab_size > 0: return OrderedDict( [('input_ids', dynamic_axis), ('attention_mask', dynamic_axis), ('token_type_ids', dynamic_axis)] ) else: return OrderedDict([('input_ids', dynamic_axis), ('attention_mask', dynamic_axis)] ) @property def lowercase_ ( self : Dict ) ->int: return 1_2 def lowercase_ ( self : Tuple, _snake_case : Union["PreTrainedTokenizerBase", "FeatureExtractionMixin"], _snake_case : int = -1, _snake_case : int = -1, _snake_case : int = -1, _snake_case : bool = False, _snake_case : Optional["TensorType"] = None, _snake_case : int = 3, _snake_case : int = 4_0, _snake_case : int = 4_0, _snake_case : "PreTrainedTokenizerBase" = None, ) ->Mapping[str, Any]: snake_case__ : Union[str, Any] = super().generate_dummy_inputs(preprocessor=_snake_case, framework=_snake_case ) if self._config.type_vocab_size == 0 and "token_type_ids" in dummy_inputs: del dummy_inputs["token_type_ids"] return dummy_inputs
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"""simple docstring""" import os import unittest from transformers.models.transfo_xl.tokenization_transfo_xl import VOCAB_FILES_NAMES, TransfoXLTokenizer from ...test_tokenization_common import TokenizerTesterMixin class UpperCAmelCase_ ( lowerCAmelCase_ , unittest.TestCase): snake_case__ = TransfoXLTokenizer snake_case__ = False snake_case__ = False def _UpperCamelCase ( self : Optional[int] ) -> Any: super().setUp() _UpperCamelCase = [ '<unk>', '[CLS]', '[SEP]', 'want', 'unwanted', 'wa', 'un', 'running', ',', 'low', 'l', ] _UpperCamelCase = os.path.join(self.tmpdirname , VOCAB_FILES_NAMES['''vocab_file'''] ) with open(self.vocab_file , '''w''' , encoding='''utf-8''' ) as vocab_writer: vocab_writer.write(''''''.join([x + '''\n''' for x in vocab_tokens] ) ) def _UpperCamelCase ( self : Union[str, Any] , **__UpperCamelCase : List[Any] ) -> Dict: _UpperCamelCase = True return TransfoXLTokenizer.from_pretrained(self.tmpdirname , **_snake_case ) def _UpperCamelCase ( self : Optional[Any] , __UpperCamelCase : str ) -> Dict: _UpperCamelCase = '<unk> UNwanted , running' _UpperCamelCase = '<unk> unwanted, running' return input_text, output_text def _UpperCamelCase ( self : List[Any] ) -> Tuple: _UpperCamelCase = TransfoXLTokenizer(vocab_file=self.vocab_file , lower_case=_snake_case ) _UpperCamelCase = tokenizer.tokenize('''<unk> UNwanted , running''' ) self.assertListEqual(_snake_case , ['''<unk>''', '''unwanted''', ''',''', '''running'''] ) self.assertListEqual(tokenizer.convert_tokens_to_ids(_snake_case ) , [0, 4, 8, 7] ) def _UpperCamelCase ( self : List[str] ) -> List[Any]: _UpperCamelCase = TransfoXLTokenizer(lower_case=_snake_case ) self.assertListEqual( tokenizer.tokenize(''' \tHeLLo ! how \n Are yoU ? ''' ) , ['''hello''', '''!''', '''how''', '''are''', '''you''', '''?'''] ) def _UpperCamelCase ( self : Optional[int] ) -> Optional[Any]: _UpperCamelCase = TransfoXLTokenizer(lower_case=_snake_case ) self.assertListEqual( tokenizer.tokenize(''' \tHeLLo ! how \n Are yoU ? ''' ) , ['''HeLLo''', '''!''', '''how''', '''Are''', '''yoU''', '''?'''] ) def _UpperCamelCase ( self : Optional[int] ) -> Union[str, Any]: _UpperCamelCase = TransfoXLTokenizer(lower_case=_snake_case ) _UpperCamelCase = 'Hello (bracket) and side-scrolled [and] Henry\'s $5,000 with 3.34 m. What\'s up!?' _UpperCamelCase = [ 'Hello', '(', 'bracket', ')', 'and', 'side', '@-@', 'scrolled', '[', 'and', ']', 'Henry', '\'s', '$', '5', '@,@', '000', 'with', '3', '@.@', '34', 'm', '.', 'What', '\'s', 'up', '!', '?', ] self.assertListEqual(tokenizer.tokenize(_snake_case ) , _snake_case ) self.assertEqual(tokenizer.convert_tokens_to_string(_snake_case ) , _snake_case ) def _UpperCamelCase ( self : Dict ) -> Any: _UpperCamelCase = self.get_tokenizer() _UpperCamelCase = len(_snake_case ) tokenizer.add_tokens(['''new1''', '''new2'''] ) tokenizer.move_added_token('''new1''' , 1 ) # Check that moved token is not copied (duplicate) self.assertEqual(len(_snake_case ) , original_len + 2 ) # Check that token is moved to specified id self.assertEqual(tokenizer.encode('''new1''' ) , [1] ) self.assertEqual(tokenizer.decode([1] ) , '''new1''' )
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import argparse import json import pickle from pathlib import Path import requests import torch from huggingface_hub import hf_hub_download from PIL import Image from transformers import MaskFormerConfig, MaskFormerForInstanceSegmentation, MaskFormerImageProcessor, SwinConfig from transformers.utils import logging logging.set_verbosity_info() a_ :str = logging.get_logger(__name__) def lowercase_ (A : str ): snake_case__ : Tuple = SwinConfig.from_pretrained( 'microsoft/swin-tiny-patch4-window7-224' , out_features=['stage1', 'stage2', 'stage3', 'stage4'] ) snake_case__ : List[Any] = MaskFormerConfig(backbone_config=A ) snake_case__ : Union[str, Any] = 'huggingface/label-files' if "ade20k-full" in model_name: # this should be ok snake_case__ : Dict = 8_4_7 snake_case__ : List[str] = 'maskformer-ade20k-full-id2label.json' elif "ade" in model_name: # this should be ok snake_case__ : Union[str, Any] = 1_5_0 snake_case__ : Any = 'ade20k-id2label.json' elif "coco-stuff" in model_name: # this should be ok snake_case__ : List[str] = 1_7_1 snake_case__ : Union[str, Any] = 'maskformer-coco-stuff-id2label.json' elif "coco" in model_name: # TODO snake_case__ : Dict = 1_3_3 snake_case__ : str = 'coco-panoptic-id2label.json' elif "cityscapes" in model_name: # this should be ok snake_case__ : List[str] = 1_9 snake_case__ : Union[str, Any] = 'cityscapes-id2label.json' elif "vistas" in model_name: # this should be ok snake_case__ : Tuple = 6_5 snake_case__ : List[str] = 'mapillary-vistas-id2label.json' snake_case__ : Dict = json.load(open(hf_hub_download(A , A , repo_type='dataset' ) , 'r' ) ) snake_case__ : List[str] = {int(A ): v for k, v in idalabel.items()} return config def lowercase_ (A : Any ): snake_case__ : Optional[int] = [] # stem # fmt: off rename_keys.append(('backbone.patch_embed.proj.weight', 'model.pixel_level_module.encoder.model.embeddings.patch_embeddings.projection.weight') ) rename_keys.append(('backbone.patch_embed.proj.bias', 'model.pixel_level_module.encoder.model.embeddings.patch_embeddings.projection.bias') ) rename_keys.append(('backbone.patch_embed.norm.weight', 'model.pixel_level_module.encoder.model.embeddings.norm.weight') ) rename_keys.append(('backbone.patch_embed.norm.bias', 'model.pixel_level_module.encoder.model.embeddings.norm.bias') ) # stages for i in range(len(config.backbone_config.depths ) ): for j in range(config.backbone_config.depths[i] ): rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.norm1.weight''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.layernorm_before.weight''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.norm1.bias''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.layernorm_before.bias''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.attn.relative_position_bias_table''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.attention.self.relative_position_bias_table''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.attn.relative_position_index''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.attention.self.relative_position_index''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.attn.proj.weight''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.attention.output.dense.weight''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.attn.proj.bias''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.attention.output.dense.bias''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.norm2.weight''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.layernorm_after.weight''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.norm2.bias''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.layernorm_after.bias''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.mlp.fc1.weight''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.intermediate.dense.weight''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.mlp.fc1.bias''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.intermediate.dense.bias''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.mlp.fc2.weight''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.output.dense.weight''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.mlp.fc2.bias''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.output.dense.bias''') ) if i < 3: rename_keys.append((F'''backbone.layers.{i}.downsample.reduction.weight''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.downsample.reduction.weight''') ) rename_keys.append((F'''backbone.layers.{i}.downsample.norm.weight''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.downsample.norm.weight''') ) rename_keys.append((F'''backbone.layers.{i}.downsample.norm.bias''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.downsample.norm.bias''') ) rename_keys.append((F'''backbone.norm{i}.weight''', F'''model.pixel_level_module.encoder.hidden_states_norms.{i}.weight''') ) rename_keys.append((F'''backbone.norm{i}.bias''', F'''model.pixel_level_module.encoder.hidden_states_norms.{i}.bias''') ) # FPN rename_keys.append(('sem_seg_head.layer_4.weight', 'model.pixel_level_module.decoder.fpn.stem.0.weight') ) rename_keys.append(('sem_seg_head.layer_4.norm.weight', 'model.pixel_level_module.decoder.fpn.stem.1.weight') ) rename_keys.append(('sem_seg_head.layer_4.norm.bias', 'model.pixel_level_module.decoder.fpn.stem.1.bias') ) for source_index, target_index in zip(range(3 , 0 , -1 ) , range(0 , 3 ) ): rename_keys.append((F'''sem_seg_head.adapter_{source_index}.weight''', F'''model.pixel_level_module.decoder.fpn.layers.{target_index}.proj.0.weight''') ) rename_keys.append((F'''sem_seg_head.adapter_{source_index}.norm.weight''', F'''model.pixel_level_module.decoder.fpn.layers.{target_index}.proj.1.weight''') ) rename_keys.append((F'''sem_seg_head.adapter_{source_index}.norm.bias''', F'''model.pixel_level_module.decoder.fpn.layers.{target_index}.proj.1.bias''') ) rename_keys.append((F'''sem_seg_head.layer_{source_index}.weight''', F'''model.pixel_level_module.decoder.fpn.layers.{target_index}.block.0.weight''') ) rename_keys.append((F'''sem_seg_head.layer_{source_index}.norm.weight''', F'''model.pixel_level_module.decoder.fpn.layers.{target_index}.block.1.weight''') ) rename_keys.append((F'''sem_seg_head.layer_{source_index}.norm.bias''', F'''model.pixel_level_module.decoder.fpn.layers.{target_index}.block.1.bias''') ) rename_keys.append(('sem_seg_head.mask_features.weight', 'model.pixel_level_module.decoder.mask_projection.weight') ) rename_keys.append(('sem_seg_head.mask_features.bias', 'model.pixel_level_module.decoder.mask_projection.bias') ) # Transformer decoder for idx in range(config.decoder_config.decoder_layers ): # self-attention out projection rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.self_attn.out_proj.weight''', F'''model.transformer_module.decoder.layers.{idx}.self_attn.out_proj.weight''') ) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.self_attn.out_proj.bias''', F'''model.transformer_module.decoder.layers.{idx}.self_attn.out_proj.bias''') ) # cross-attention out projection rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.multihead_attn.out_proj.weight''', F'''model.transformer_module.decoder.layers.{idx}.encoder_attn.out_proj.weight''') ) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.multihead_attn.out_proj.bias''', F'''model.transformer_module.decoder.layers.{idx}.encoder_attn.out_proj.bias''') ) # MLP 1 rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.linear1.weight''', F'''model.transformer_module.decoder.layers.{idx}.fc1.weight''') ) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.linear1.bias''', F'''model.transformer_module.decoder.layers.{idx}.fc1.bias''') ) # MLP 2 rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.linear2.weight''', F'''model.transformer_module.decoder.layers.{idx}.fc2.weight''') ) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.linear2.bias''', F'''model.transformer_module.decoder.layers.{idx}.fc2.bias''') ) # layernorm 1 (self-attention layernorm) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.norm1.weight''', F'''model.transformer_module.decoder.layers.{idx}.self_attn_layer_norm.weight''') ) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.norm1.bias''', F'''model.transformer_module.decoder.layers.{idx}.self_attn_layer_norm.bias''') ) # layernorm 2 (cross-attention layernorm) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.norm2.weight''', F'''model.transformer_module.decoder.layers.{idx}.encoder_attn_layer_norm.weight''') ) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.norm2.bias''', F'''model.transformer_module.decoder.layers.{idx}.encoder_attn_layer_norm.bias''') ) # layernorm 3 (final layernorm) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.norm3.weight''', F'''model.transformer_module.decoder.layers.{idx}.final_layer_norm.weight''') ) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.norm3.bias''', F'''model.transformer_module.decoder.layers.{idx}.final_layer_norm.bias''') ) rename_keys.append(('sem_seg_head.predictor.transformer.decoder.norm.weight', 'model.transformer_module.decoder.layernorm.weight') ) rename_keys.append(('sem_seg_head.predictor.transformer.decoder.norm.bias', 'model.transformer_module.decoder.layernorm.bias') ) # heads on top rename_keys.append(('sem_seg_head.predictor.query_embed.weight', 'model.transformer_module.queries_embedder.weight') ) rename_keys.append(('sem_seg_head.predictor.input_proj.weight', 'model.transformer_module.input_projection.weight') ) rename_keys.append(('sem_seg_head.predictor.input_proj.bias', 'model.transformer_module.input_projection.bias') ) rename_keys.append(('sem_seg_head.predictor.class_embed.weight', 'class_predictor.weight') ) rename_keys.append(('sem_seg_head.predictor.class_embed.bias', 'class_predictor.bias') ) for i in range(3 ): rename_keys.append((F'''sem_seg_head.predictor.mask_embed.layers.{i}.weight''', F'''mask_embedder.{i}.0.weight''') ) rename_keys.append((F'''sem_seg_head.predictor.mask_embed.layers.{i}.bias''', F'''mask_embedder.{i}.0.bias''') ) # fmt: on return rename_keys def lowercase_ (A : Tuple , A : Tuple , A : Optional[Any] ): snake_case__ : Optional[int] = dct.pop(A ) snake_case__ : Union[str, Any] = val def lowercase_ (A : Optional[Any] , A : Tuple ): snake_case__ : Optional[int] = [int(backbone_config.embed_dim * 2**i ) for i in range(len(backbone_config.depths ) )] for i in range(len(backbone_config.depths ) ): snake_case__ : Optional[int] = num_features[i] for j in range(backbone_config.depths[i] ): # fmt: off # read in weights + bias of input projection layer (in original implementation, this is a single matrix + bias) snake_case__ : int = state_dict.pop(F'''backbone.layers.{i}.blocks.{j}.attn.qkv.weight''' ) snake_case__ : Tuple = state_dict.pop(F'''backbone.layers.{i}.blocks.{j}.attn.qkv.bias''' ) # next, add query, keys and values (in that order) to the state dict snake_case__ : str = in_proj_weight[:dim, :] snake_case__ : int = in_proj_bias[: dim] snake_case__ : List[Any] = in_proj_weight[ dim : dim * 2, : ] snake_case__ : List[str] = in_proj_bias[ dim : dim * 2 ] snake_case__ : List[Any] = in_proj_weight[ -dim :, : ] snake_case__ : Dict = in_proj_bias[-dim :] # fmt: on def lowercase_ (A : List[str] , A : List[Any] ): # fmt: off snake_case__ : str = config.decoder_config.hidden_size for idx in range(config.decoder_config.decoder_layers ): # read in weights + bias of self-attention input projection layer (in the original implementation, this is a single matrix + bias) snake_case__ : List[Any] = state_dict.pop(F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.self_attn.in_proj_weight''' ) snake_case__ : int = state_dict.pop(F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.self_attn.in_proj_bias''' ) # next, add query, keys and values (in that order) to the state dict snake_case__ : Any = in_proj_weight[: hidden_size, :] snake_case__ : Tuple = in_proj_bias[:config.hidden_size] snake_case__ : List[str] = in_proj_weight[hidden_size : hidden_size * 2, :] snake_case__ : Dict = in_proj_bias[hidden_size : hidden_size * 2] snake_case__ : Any = in_proj_weight[-hidden_size :, :] snake_case__ : int = in_proj_bias[-hidden_size :] # read in weights + bias of cross-attention input projection layer (in the original implementation, this is a single matrix + bias) snake_case__ : List[Any] = state_dict.pop(F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.multihead_attn.in_proj_weight''' ) snake_case__ : List[str] = state_dict.pop(F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.multihead_attn.in_proj_bias''' ) # next, add query, keys and values (in that order) to the state dict snake_case__ : Optional[int] = in_proj_weight[: hidden_size, :] snake_case__ : Optional[Any] = in_proj_bias[:config.hidden_size] snake_case__ : int = in_proj_weight[hidden_size : hidden_size * 2, :] snake_case__ : List[str] = in_proj_bias[hidden_size : hidden_size * 2] snake_case__ : List[str] = in_proj_weight[-hidden_size :, :] snake_case__ : str = in_proj_bias[-hidden_size :] # fmt: on def lowercase_ (): snake_case__ : Any = 'http://images.cocodataset.org/val2017/000000039769.jpg' snake_case__ : int = Image.open(requests.get(A , stream=A ).raw ) return im @torch.no_grad() def lowercase_ (A : str , A : str , A : str , A : bool = False ): snake_case__ : Optional[int] = get_maskformer_config(A ) # load original state_dict with open(A , 'rb' ) as f: snake_case__ : List[Any] = pickle.load(A ) snake_case__ : Optional[int] = data['model'] # for name, param in state_dict.items(): # print(name, param.shape) # rename keys snake_case__ : List[str] = create_rename_keys(A ) for src, dest in rename_keys: rename_key(A , A , A ) read_in_swin_q_k_v(A , config.backbone_config ) read_in_decoder_q_k_v(A , A ) # update to torch tensors for key, value in state_dict.items(): snake_case__ : int = torch.from_numpy(A ) # load 🤗 model snake_case__ : str = MaskFormerForInstanceSegmentation(A ) model.eval() for name, param in model.named_parameters(): print(A , param.shape ) snake_case__ , snake_case__ : Union[str, Any] = model.load_state_dict(A , strict=A ) assert missing_keys == [ "model.pixel_level_module.encoder.model.layernorm.weight", "model.pixel_level_module.encoder.model.layernorm.bias", ] assert len(A ) == 0, F'''Unexpected keys: {unexpected_keys}''' # verify results snake_case__ : Optional[Any] = prepare_img() if "vistas" in model_name: snake_case__ : int = 6_5 elif "cityscapes" in model_name: snake_case__ : Dict = 6_5_5_3_5 else: snake_case__ : Tuple = 2_5_5 snake_case__ : Optional[int] = True if 'ade' in model_name else False snake_case__ : Dict = MaskFormerImageProcessor(ignore_index=A , reduce_labels=A ) snake_case__ : Any = image_processor(A , return_tensors='pt' ) snake_case__ : Any = model(**A ) print('Logits:' , outputs.class_queries_logits[0, :3, :3] ) if model_name == "maskformer-swin-tiny-ade": snake_case__ : Tuple = torch.tensor( [[3.6353, -4.4770, -2.6065], [0.5081, -4.2394, -3.5343], [2.1909, -5.0353, -1.9323]] ) assert torch.allclose(outputs.class_queries_logits[0, :3, :3] , A , atol=1e-4 ) print('Looks ok!' ) if pytorch_dump_folder_path is not None: print(F'''Saving model and image processor to {pytorch_dump_folder_path}''' ) Path(A ).mkdir(exist_ok=A ) model.save_pretrained(A ) image_processor.save_pretrained(A ) if push_to_hub: print('Pushing model and image processor to the hub...' ) model.push_to_hub(F'''nielsr/{model_name}''' ) image_processor.push_to_hub(F'''nielsr/{model_name}''' ) if __name__ == "__main__": a_ :Optional[int] = argparse.ArgumentParser() # Required parameters parser.add_argument( "--model_name", default="maskformer-swin-tiny-ade", type=str, help=("Name of the MaskFormer model you'd like to convert",), ) parser.add_argument( "--checkpoint_path", default="/Users/nielsrogge/Documents/MaskFormer_checkpoints/MaskFormer-Swin-tiny-ADE20k/model.pkl", type=str, help="Path to the original state dict (.pth file).", ) parser.add_argument( "--pytorch_dump_folder_path", default=None, type=str, help="Path to the output PyTorch model directory." ) parser.add_argument( "--push_to_hub", action="store_true", help="Whether or not to push the converted model to the 🤗 hub." ) a_ :Dict = parser.parse_args() convert_maskformer_checkpoint( args.model_name, args.checkpoint_path, args.pytorch_dump_folder_path, args.push_to_hub )
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from __future__ import annotations _a = 1_0 def _a ( SCREAMING_SNAKE_CASE : list[int] ) -> Any: """simple docstring""" __lowerCAmelCase: Any = 1 __lowerCAmelCase: Optional[int] = max(SCREAMING_SNAKE_CASE ) while placement <= max_digit: # declare and initialize empty buckets __lowerCAmelCase: list[list] = [[] for _ in range(SCREAMING_SNAKE_CASE )] # split list_of_ints between the buckets for i in list_of_ints: __lowerCAmelCase: Dict = int((i / placement) % RADIX ) buckets[tmp].append(SCREAMING_SNAKE_CASE ) # put each buckets' contents into list_of_ints __lowerCAmelCase: str = 0 for b in range(SCREAMING_SNAKE_CASE ): for i in buckets[b]: __lowerCAmelCase: str = i a += 1 # move to next placement *= RADIX return list_of_ints if __name__ == "__main__": import doctest doctest.testmod()
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import unittest from transformers import is_torch_available from transformers.testing_utils import require_torch, slow, torch_device from ...generation.test_utils import GenerationTesterMixin from ...test_configuration_common import ConfigTester from ...test_modeling_common import ModelTesterMixin, ids_tensor from ...test_pipeline_mixin import PipelineTesterMixin if is_torch_available(): import torch from transformers import ( OPENAI_GPT_PRETRAINED_MODEL_ARCHIVE_LIST, OpenAIGPTConfig, OpenAIGPTDoubleHeadsModel, OpenAIGPTForSequenceClassification, OpenAIGPTLMHeadModel, OpenAIGPTModel, ) class snake_case__ : """simple docstring""" def __init__( self : List[str], _snake_case : Any, _snake_case : int=1_3, _snake_case : Optional[int]=7, _snake_case : int=True, _snake_case : Optional[Any]=True, _snake_case : Optional[Any]=True, _snake_case : Union[str, Any]=9_9, _snake_case : Optional[Any]=3_2, _snake_case : Tuple=5, _snake_case : str=4, _snake_case : Any=3_7, _snake_case : int="gelu", _snake_case : Optional[Any]=0.1, _snake_case : str=0.1, _snake_case : str=5_1_2, _snake_case : Dict=1_6, _snake_case : str=2, _snake_case : Union[str, Any]=0.0_2, _snake_case : Optional[int]=3, _snake_case : Union[str, Any]=4, _snake_case : Tuple=None, ) ->Optional[Any]: snake_case__ : Optional[int] = parent snake_case__ : List[Any] = batch_size snake_case__ : Tuple = seq_length snake_case__ : str = is_training snake_case__ : Optional[int] = use_token_type_ids snake_case__ : Any = use_labels snake_case__ : Dict = vocab_size snake_case__ : str = hidden_size snake_case__ : Union[str, Any] = num_hidden_layers snake_case__ : List[str] = num_attention_heads snake_case__ : Union[str, Any] = intermediate_size snake_case__ : List[Any] = hidden_act snake_case__ : int = hidden_dropout_prob snake_case__ : str = attention_probs_dropout_prob snake_case__ : Any = max_position_embeddings snake_case__ : Union[str, Any] = type_vocab_size snake_case__ : Optional[Any] = type_sequence_label_size snake_case__ : Optional[int] = initializer_range snake_case__ : Optional[int] = num_labels snake_case__ : str = num_choices snake_case__ : int = scope snake_case__ : List[str] = self.vocab_size - 1 def lowercase_ ( self : Union[str, Any] ) ->Tuple: snake_case__ : List[str] = ids_tensor([self.batch_size, self.seq_length], self.vocab_size ) snake_case__ : List[str] = None if self.use_token_type_ids: snake_case__ : Optional[Any] = ids_tensor([self.batch_size, self.seq_length], self.type_vocab_size ) snake_case__ : Tuple = None snake_case__ : str = None snake_case__ : List[Any] = None if self.use_labels: snake_case__ : Dict = ids_tensor([self.batch_size], self.type_sequence_label_size ) snake_case__ : int = ids_tensor([self.batch_size, self.seq_length], self.num_labels ) snake_case__ : List[str] = ids_tensor([self.batch_size], self.num_choices ) snake_case__ : Union[str, Any] = OpenAIGPTConfig( vocab_size=self.vocab_size, n_embd=self.hidden_size, n_layer=self.num_hidden_layers, n_head=self.num_attention_heads, n_positions=self.max_position_embeddings, pad_token_id=self.pad_token_id, ) snake_case__ : List[str] = ids_tensor([self.num_hidden_layers, self.num_attention_heads], 2 ) return ( config, input_ids, head_mask, token_type_ids, sequence_labels, token_labels, choice_labels, ) def lowercase_ ( self : Any, _snake_case : List[str], _snake_case : Any, _snake_case : List[Any], _snake_case : Tuple, *_snake_case : Optional[Any] ) ->Tuple: snake_case__ : Union[str, Any] = OpenAIGPTModel(config=_snake_case ) model.to(_snake_case ) model.eval() snake_case__ : Optional[Any] = model(_snake_case, token_type_ids=_snake_case, head_mask=_snake_case ) snake_case__ : Union[str, Any] = model(_snake_case, token_type_ids=_snake_case ) snake_case__ : Optional[Any] = model(_snake_case ) self.parent.assertEqual(result.last_hidden_state.shape, (self.batch_size, self.seq_length, self.hidden_size) ) def lowercase_ ( self : Optional[int], _snake_case : Optional[Any], _snake_case : Union[str, Any], _snake_case : Optional[int], _snake_case : List[Any], *_snake_case : Dict ) ->Optional[int]: snake_case__ : Optional[Any] = OpenAIGPTLMHeadModel(_snake_case ) model.to(_snake_case ) model.eval() snake_case__ : Tuple = model(_snake_case, token_type_ids=_snake_case, labels=_snake_case ) self.parent.assertEqual(result.loss.shape, () ) self.parent.assertEqual(result.logits.shape, (self.batch_size, self.seq_length, self.vocab_size) ) def lowercase_ ( self : int, _snake_case : Tuple, _snake_case : List[str], _snake_case : List[Any], _snake_case : List[Any], *_snake_case : List[Any] ) ->Optional[int]: snake_case__ : List[str] = OpenAIGPTDoubleHeadsModel(_snake_case ) model.to(_snake_case ) model.eval() snake_case__ : Optional[Any] = model(_snake_case, token_type_ids=_snake_case, labels=_snake_case ) self.parent.assertEqual(result.loss.shape, () ) self.parent.assertEqual(result.logits.shape, (self.batch_size, self.seq_length, self.vocab_size) ) def lowercase_ ( self : Optional[int], _snake_case : Tuple, _snake_case : Dict, _snake_case : List[str], _snake_case : Optional[Any], *_snake_case : Union[str, Any] ) ->str: snake_case__ : List[str] = self.num_labels snake_case__ : Dict = OpenAIGPTForSequenceClassification(_snake_case ) model.to(_snake_case ) model.eval() snake_case__ : List[str] = ids_tensor([self.batch_size], self.type_sequence_label_size ) snake_case__ : List[str] = model(_snake_case, token_type_ids=_snake_case, labels=_snake_case ) self.parent.assertEqual(result.logits.shape, (self.batch_size, self.num_labels) ) def lowercase_ ( self : Dict ) ->int: snake_case__ : List[Any] = self.prepare_config_and_inputs() ( ( snake_case__ ) , ( snake_case__ ) , ( snake_case__ ) , ( snake_case__ ) , ( snake_case__ ) , ( snake_case__ ) , ( snake_case__ ) , ) : Optional[Any] = config_and_inputs snake_case__ : str = { 'input_ids': input_ids, 'token_type_ids': token_type_ids, 'head_mask': head_mask, } return config, inputs_dict @require_torch class snake_case__ ( lowerCAmelCase_ , lowerCAmelCase_ , lowerCAmelCase_ , unittest.TestCase ): """simple docstring""" _SCREAMING_SNAKE_CASE = ( (OpenAIGPTModel, OpenAIGPTLMHeadModel, OpenAIGPTDoubleHeadsModel, OpenAIGPTForSequenceClassification) if is_torch_available() else () ) _SCREAMING_SNAKE_CASE = ( (OpenAIGPTLMHeadModel,) if is_torch_available() else () ) # TODO (PVP): Add Double HeadsModel when generate() function is changed accordingly _SCREAMING_SNAKE_CASE = ( { """feature-extraction""": OpenAIGPTModel, """text-classification""": OpenAIGPTForSequenceClassification, """text-generation""": OpenAIGPTLMHeadModel, """zero-shot""": OpenAIGPTForSequenceClassification, } if is_torch_available() else {} ) def lowercase_ ( self : Optional[int], _snake_case : Union[str, Any], _snake_case : int, _snake_case : Tuple, _snake_case : Tuple, _snake_case : List[str] ) ->Optional[Any]: if pipeline_test_casse_name == "ZeroShotClassificationPipelineTests": # Get `tokenizer does not have a padding token` error for both fast/slow tokenizers. # `OpenAIGPTConfig` was never used in pipeline tests, either because of a missing checkpoint or because a # tiny config could not be created. return True return False def lowercase_ ( self : Optional[Any], _snake_case : Union[str, Any], _snake_case : List[str], _snake_case : Any=False ) ->Tuple: snake_case__ : Optional[int] = super()._prepare_for_class(_snake_case, _snake_case, return_labels=_snake_case ) if return_labels: if model_class.__name__ == "OpenAIGPTDoubleHeadsModel": snake_case__ : Union[str, Any] = torch.zeros( (self.model_tester.batch_size, self.model_tester.num_choices, self.model_tester.seq_length), dtype=torch.long, device=_snake_case, ) snake_case__ : List[Any] = inputs_dict['labels'] snake_case__ : List[Any] = inputs_dict['labels'] snake_case__ : Any = torch.zeros( (self.model_tester.batch_size, self.model_tester.num_choices), dtype=torch.long, device=_snake_case, ) snake_case__ : Tuple = torch.zeros( self.model_tester.batch_size, dtype=torch.long, device=_snake_case ) return inputs_dict def lowercase_ ( self : Union[str, Any] ) ->List[str]: snake_case__ : List[str] = OpenAIGPTModelTester(self ) snake_case__ : Any = ConfigTester(self, config_class=_snake_case, n_embd=3_7 ) def lowercase_ ( self : Optional[int] ) ->str: self.config_tester.run_common_tests() def lowercase_ ( self : int ) ->Tuple: snake_case__ : str = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_openai_gpt_model(*_snake_case ) def lowercase_ ( self : Tuple ) ->List[str]: snake_case__ : Optional[int] = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_lm_head_model(*_snake_case ) def lowercase_ ( self : Dict ) ->int: snake_case__ : Optional[Any] = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_double_lm_head_model(*_snake_case ) def lowercase_ ( self : int ) ->str: snake_case__ : List[Any] = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_openai_gpt_for_sequence_classification(*_snake_case ) @slow def lowercase_ ( self : Optional[Any] ) ->str: for model_name in OPENAI_GPT_PRETRAINED_MODEL_ARCHIVE_LIST[:1]: snake_case__ : Optional[int] = OpenAIGPTModel.from_pretrained(_snake_case ) self.assertIsNotNone(_snake_case ) @require_torch class snake_case__ ( unittest.TestCase ): """simple docstring""" @slow def lowercase_ ( self : Tuple ) ->Optional[int]: snake_case__ : Union[str, Any] = OpenAIGPTLMHeadModel.from_pretrained('openai-gpt' ) model.to(_snake_case ) snake_case__ : Tuple = torch.tensor([[4_8_1, 4_7_3_5, 5_4_4]], dtype=torch.long, device=_snake_case ) # the president is snake_case__ : int = [ 4_8_1, 4_7_3_5, 5_4_4, 2_4_6, 9_6_3, 8_7_0, 7_6_2, 2_3_9, 2_4_4, 4_0_4_7_7, 2_4_4, 2_4_9, 7_1_9, 8_8_1, 4_8_7, 5_4_4, 2_4_0, 2_4_4, 6_0_3, 4_8_1, ] # the president is a very good man. " \n " i\'m sure he is, " said the snake_case__ : Optional[int] = model.generate(_snake_case, do_sample=_snake_case ) self.assertListEqual(output_ids[0].tolist(), _snake_case )
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from ..utils import DummyObject, requires_backends class __lowerCAmelCase ( metaclass=lowerCAmelCase_): _lowercase : Tuple = ["""torch""", """torchsde"""] def __init__( self , *lowerCAmelCase__ , **lowerCAmelCase__ ) -> Optional[Any]: '''simple docstring''' requires_backends(self , ["torch", "torchsde"] ) @classmethod def _lowercase ( cls , *lowerCAmelCase__ , **lowerCAmelCase__ ) -> Union[str, Any]: '''simple docstring''' requires_backends(cls , ["torch", "torchsde"] ) @classmethod def _lowercase ( cls , *lowerCAmelCase__ , **lowerCAmelCase__ ) -> Optional[Any]: '''simple docstring''' requires_backends(cls , ["torch", "torchsde"] )
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import os import unittest from transformers.models.transfo_xl.tokenization_transfo_xl import VOCAB_FILES_NAMES, TransfoXLTokenizer from ...test_tokenization_common import TokenizerTesterMixin class snake_case__ ( lowerCAmelCase_ , unittest.TestCase ): """simple docstring""" _SCREAMING_SNAKE_CASE = TransfoXLTokenizer _SCREAMING_SNAKE_CASE = False _SCREAMING_SNAKE_CASE = False def lowercase_ ( self : Optional[int] ) ->Any: super().setUp() snake_case__ : Tuple = [ '<unk>', '[CLS]', '[SEP]', 'want', 'unwanted', 'wa', 'un', 'running', ',', 'low', 'l', ] snake_case__ : Any = os.path.join(self.tmpdirname, VOCAB_FILES_NAMES['vocab_file'] ) with open(self.vocab_file, 'w', encoding='utf-8' ) as vocab_writer: vocab_writer.write(''.join([x + '\n' for x in vocab_tokens] ) ) def lowercase_ ( self : Union[str, Any], **_snake_case : List[Any] ) ->Dict: snake_case__ : str = True return TransfoXLTokenizer.from_pretrained(self.tmpdirname, **_snake_case ) def lowercase_ ( self : Optional[Any], _snake_case : str ) ->Dict: snake_case__ : List[Any] = '<unk> UNwanted , running' snake_case__ : List[Any] = '<unk> unwanted, running' return input_text, output_text def lowercase_ ( self : List[Any] ) ->Tuple: snake_case__ : Dict = TransfoXLTokenizer(vocab_file=self.vocab_file, lower_case=_snake_case ) snake_case__ : str = tokenizer.tokenize('<unk> UNwanted , running' ) self.assertListEqual(_snake_case, ['<unk>', 'unwanted', ',', 'running'] ) self.assertListEqual(tokenizer.convert_tokens_to_ids(_snake_case ), [0, 4, 8, 7] ) def lowercase_ ( self : List[str] ) ->List[Any]: snake_case__ : str = TransfoXLTokenizer(lower_case=_snake_case ) self.assertListEqual( tokenizer.tokenize(' \tHeLLo ! how \n Are yoU ? ' ), ['hello', '!', 'how', 'are', 'you', '?'] ) def lowercase_ ( self : Optional[int] ) ->Optional[Any]: snake_case__ : Optional[int] = TransfoXLTokenizer(lower_case=_snake_case ) self.assertListEqual( tokenizer.tokenize(' \tHeLLo ! how \n Are yoU ? ' ), ['HeLLo', '!', 'how', 'Are', 'yoU', '?'] ) def lowercase_ ( self : Optional[int] ) ->Union[str, Any]: snake_case__ : List[Any] = TransfoXLTokenizer(lower_case=_snake_case ) snake_case__ : Dict = 'Hello (bracket) and side-scrolled [and] Henry\'s $5,000 with 3.34 m. What\'s up!?' snake_case__ : List[Any] = [ 'Hello', '(', 'bracket', ')', 'and', 'side', '@-@', 'scrolled', '[', 'and', ']', 'Henry', '\'s', '$', '5', '@,@', '000', 'with', '3', '@.@', '34', 'm', '.', 'What', '\'s', 'up', '!', '?', ] self.assertListEqual(tokenizer.tokenize(_snake_case ), _snake_case ) self.assertEqual(tokenizer.convert_tokens_to_string(_snake_case ), _snake_case ) def lowercase_ ( self : Dict ) ->Any: snake_case__ : Dict = self.get_tokenizer() snake_case__ : Optional[Any] = len(_snake_case ) tokenizer.add_tokens(['new1', 'new2'] ) tokenizer.move_added_token('new1', 1 ) # Check that moved token is not copied (duplicate) self.assertEqual(len(_snake_case ), original_len + 2 ) # Check that token is moved to specified id self.assertEqual(tokenizer.encode('new1' ), [1] ) self.assertEqual(tokenizer.decode([1] ), 'new1' )
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import unittest from parameterized import parameterized from transformers import AutoTokenizer, GPTNeoXConfig, is_torch_available, set_seed from transformers.testing_utils import require_torch, slow, torch_device from ...generation.test_utils import GenerationTesterMixin from ...test_configuration_common import ConfigTester from ...test_modeling_common import ModelTesterMixin, ids_tensor, random_attention_mask from ...test_pipeline_mixin import PipelineTesterMixin if is_torch_available(): import torch from transformers import ( GPTNeoXForCausalLM, GPTNeoXForQuestionAnswering, GPTNeoXForSequenceClassification, GPTNeoXForTokenClassification, GPTNeoXModel, ) class lowercase__: """simple docstring""" def __init__( self : int , SCREAMING_SNAKE_CASE_ : str , SCREAMING_SNAKE_CASE_ : List[str]=1_3 , SCREAMING_SNAKE_CASE_ : Union[str, Any]=7 , SCREAMING_SNAKE_CASE_ : Tuple=True , SCREAMING_SNAKE_CASE_ : str=True , SCREAMING_SNAKE_CASE_ : List[Any]=True , SCREAMING_SNAKE_CASE_ : List[Any]=True , SCREAMING_SNAKE_CASE_ : List[Any]=9_9 , SCREAMING_SNAKE_CASE_ : Any=6_4 , SCREAMING_SNAKE_CASE_ : Optional[Any]=5 , SCREAMING_SNAKE_CASE_ : Any=4 , SCREAMING_SNAKE_CASE_ : Optional[int]=3_7 , SCREAMING_SNAKE_CASE_ : Tuple="gelu" , SCREAMING_SNAKE_CASE_ : Any=0.1 , SCREAMING_SNAKE_CASE_ : Optional[Any]=0.1 , SCREAMING_SNAKE_CASE_ : Any=5_1_2 , SCREAMING_SNAKE_CASE_ : Optional[Any]=1_6 , SCREAMING_SNAKE_CASE_ : List[str]=2 , SCREAMING_SNAKE_CASE_ : Dict=0.02 , SCREAMING_SNAKE_CASE_ : Dict=3 , SCREAMING_SNAKE_CASE_ : int=4 , SCREAMING_SNAKE_CASE_ : Optional[int]=None , ) -> Any: lowercase_ = parent lowercase_ = batch_size lowercase_ = seq_length lowercase_ = is_training lowercase_ = use_input_mask lowercase_ = use_token_type_ids lowercase_ = use_labels lowercase_ = vocab_size lowercase_ = hidden_size lowercase_ = num_hidden_layers lowercase_ = num_attention_heads lowercase_ = intermediate_size lowercase_ = hidden_act lowercase_ = hidden_dropout_prob lowercase_ = attention_probs_dropout_prob lowercase_ = max_position_embeddings lowercase_ = type_vocab_size lowercase_ = type_sequence_label_size lowercase_ = initializer_range lowercase_ = num_labels lowercase_ = num_choices lowercase_ = scope lowercase_ = vocab_size - 1 def _lowercase ( self : int ) -> int: lowercase_ = ids_tensor([self.batch_size, self.seq_length] , self.vocab_size ) lowercase_ = None if self.use_input_mask: lowercase_ = random_attention_mask([self.batch_size, self.seq_length] ) lowercase_ = None if self.use_labels: lowercase_ = ids_tensor([self.batch_size, self.seq_length] , self.num_labels ) lowercase_ = self.get_config() return config, input_ids, input_mask, token_labels def _lowercase ( self : Optional[int] ) -> Optional[Any]: return GPTNeoXConfig( vocab_size=self.vocab_size , hidden_size=self.hidden_size , num_hidden_layers=self.num_hidden_layers , num_attention_heads=self.num_attention_heads , intermediate_size=self.intermediate_size , hidden_act=self.hidden_act , hidden_dropout_prob=self.hidden_dropout_prob , attention_probs_dropout_prob=self.attention_probs_dropout_prob , max_position_embeddings=self.max_position_embeddings , type_vocab_size=self.type_vocab_size , is_decoder=_snake_case , initializer_range=self.initializer_range , pad_token_id=self.pad_token_id , ) def _lowercase ( self : Optional[Any] ) -> Optional[Any]: lowercase_ = self.prepare_config_and_inputs() lowercase_ = True return config, input_ids, input_mask, token_labels def _lowercase ( self : Any , SCREAMING_SNAKE_CASE_ : List[str] , SCREAMING_SNAKE_CASE_ : Optional[Any] , SCREAMING_SNAKE_CASE_ : Optional[Any] ) -> List[str]: lowercase_ = GPTNeoXModel(config=_snake_case ) model.to(_snake_case ) model.eval() lowercase_ = model(_snake_case , attention_mask=_snake_case ) lowercase_ = model(_snake_case ) self.parent.assertEqual(result.last_hidden_state.shape , (self.batch_size, self.seq_length, self.hidden_size) ) def _lowercase ( self : Union[str, Any] , SCREAMING_SNAKE_CASE_ : Optional[Any] , SCREAMING_SNAKE_CASE_ : Tuple , SCREAMING_SNAKE_CASE_ : List[str] ) -> Optional[Any]: lowercase_ = True lowercase_ = GPTNeoXModel(_snake_case ) model.to(_snake_case ) model.eval() lowercase_ = model(_snake_case , attention_mask=_snake_case ) self.parent.assertEqual(result.last_hidden_state.shape , (self.batch_size, self.seq_length, self.hidden_size) ) def _lowercase ( self : int , SCREAMING_SNAKE_CASE_ : int , SCREAMING_SNAKE_CASE_ : List[Any] , SCREAMING_SNAKE_CASE_ : List[str] , SCREAMING_SNAKE_CASE_ : List[str] ) -> Tuple: lowercase_ = GPTNeoXForCausalLM(config=_snake_case ) model.to(_snake_case ) model.eval() lowercase_ = model(_snake_case , attention_mask=_snake_case , labels=_snake_case ) self.parent.assertEqual(result.logits.shape , (self.batch_size, self.seq_length, self.vocab_size) ) def _lowercase ( self : Optional[int] , SCREAMING_SNAKE_CASE_ : List[str] , SCREAMING_SNAKE_CASE_ : Union[str, Any] , SCREAMING_SNAKE_CASE_ : Optional[Any] , SCREAMING_SNAKE_CASE_ : Any ) -> List[str]: lowercase_ = self.num_labels lowercase_ = GPTNeoXForQuestionAnswering(_snake_case ) model.to(_snake_case ) model.eval() lowercase_ = model(_snake_case , attention_mask=_snake_case ) self.parent.assertEqual(result.start_logits.shape , (self.batch_size, self.seq_length) ) self.parent.assertEqual(result.end_logits.shape , (self.batch_size, self.seq_length) ) def _lowercase ( self : Any , SCREAMING_SNAKE_CASE_ : Any , SCREAMING_SNAKE_CASE_ : Dict , SCREAMING_SNAKE_CASE_ : Optional[Any] , SCREAMING_SNAKE_CASE_ : str ) -> Union[str, Any]: lowercase_ = self.num_labels lowercase_ = GPTNeoXForSequenceClassification(_snake_case ) model.to(_snake_case ) model.eval() lowercase_ = ids_tensor([self.batch_size] , self.type_sequence_label_size ) lowercase_ = model(_snake_case , attention_mask=_snake_case , labels=_snake_case ) self.parent.assertEqual(result.logits.shape , (self.batch_size, self.num_labels) ) def _lowercase ( self : Dict , SCREAMING_SNAKE_CASE_ : str , SCREAMING_SNAKE_CASE_ : Optional[Any] , SCREAMING_SNAKE_CASE_ : Optional[int] , SCREAMING_SNAKE_CASE_ : List[Any] ) -> str: lowercase_ = self.num_labels lowercase_ = GPTNeoXForTokenClassification(_snake_case ) model.to(_snake_case ) model.eval() lowercase_ = model(_snake_case , attention_mask=_snake_case , labels=_snake_case ) self.parent.assertEqual(result.logits.shape , (self.batch_size, self.seq_length, self.num_labels) ) def _lowercase ( self : Any , SCREAMING_SNAKE_CASE_ : List[str] , SCREAMING_SNAKE_CASE_ : str , SCREAMING_SNAKE_CASE_ : int ) -> str: lowercase_ = True lowercase_ = GPTNeoXForCausalLM(config=_snake_case ) model.to(_snake_case ) model.eval() # first forward pass lowercase_ = model(_snake_case , attention_mask=_snake_case , use_cache=_snake_case ) lowercase_ = outputs.past_key_values # create hypothetical multiple next token and extent to next_input_ids lowercase_ = ids_tensor((self.batch_size, 3) , config.vocab_size ) lowercase_ = ids_tensor((self.batch_size, 3) , vocab_size=2 ) # append to next input_ids and lowercase_ = torch.cat([input_ids, next_tokens] , dim=-1 ) lowercase_ = torch.cat([input_mask, next_mask] , dim=-1 ) lowercase_ = model(_snake_case , attention_mask=_snake_case , output_hidden_states=_snake_case ) lowercase_ = output_from_no_past['hidden_states'][0] lowercase_ = model( _snake_case , attention_mask=_snake_case , past_key_values=_snake_case , output_hidden_states=_snake_case , )['hidden_states'][0] # select random slice lowercase_ = ids_tensor((1,) , output_from_past.shape[-1] ).item() lowercase_ = output_from_no_past[:, -3:, random_slice_idx].detach() lowercase_ = output_from_past[:, :, random_slice_idx].detach() self.parent.assertTrue(output_from_past_slice.shape[1] == next_tokens.shape[1] ) # test that outputs are equal for slice self.parent.assertTrue(torch.allclose(_snake_case , _snake_case , atol=1e-3 ) ) def _lowercase ( self : str ) -> Union[str, Any]: lowercase_ = self.prepare_config_and_inputs() lowercase_ = config_and_inputs lowercase_ = {'input_ids': input_ids, 'attention_mask': input_mask} return config, inputs_dict @require_torch class lowercase__( lowerCAmelCase_ , lowerCAmelCase_ , lowerCAmelCase_ , unittest.TestCase ): """simple docstring""" a :int = ( ( GPTNeoXModel, GPTNeoXForCausalLM, GPTNeoXForQuestionAnswering, GPTNeoXForSequenceClassification, GPTNeoXForTokenClassification, ) if is_torch_available() else () ) a :str = (GPTNeoXForCausalLM,) if is_torch_available() else () a :Dict = ( { 'feature-extraction': GPTNeoXModel, 'question-answering': GPTNeoXForQuestionAnswering, 'text-classification': GPTNeoXForSequenceClassification, 'text-generation': GPTNeoXForCausalLM, 'token-classification': GPTNeoXForTokenClassification, 'zero-shot': GPTNeoXForSequenceClassification, } if is_torch_available() else {} ) a :Any = False a :int = False a :Any = False a :Dict = False def _lowercase ( self : Optional[int] ) -> List[Any]: lowercase_ = GPTNeoXModelTester(self ) lowercase_ = ConfigTester(self , config_class=_snake_case , hidden_size=6_4 , num_attention_heads=8 ) def _lowercase ( self : List[str] ) -> Any: self.config_tester.run_common_tests() def _lowercase ( self : Union[str, Any] ) -> List[str]: lowercase_ = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_model(_snake_case , _snake_case , _snake_case ) def _lowercase ( self : Tuple ) -> int: lowercase_ = self.model_tester.prepare_config_and_inputs_for_decoder() self.model_tester.create_and_check_model_as_decoder(_snake_case , _snake_case , _snake_case ) def _lowercase ( self : Optional[Any] ) -> str: # This regression test was failing with PyTorch < 1.3 lowercase_ = self.model_tester.prepare_config_and_inputs_for_decoder() lowercase_ = None self.model_tester.create_and_check_model_as_decoder(_snake_case , _snake_case , _snake_case ) def _lowercase ( self : Union[str, Any] ) -> Tuple: lowercase_ = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_decoder_model_past_large_inputs(_snake_case , _snake_case , _snake_case ) def _lowercase ( self : Any ) -> List[Any]: lowercase_ = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_for_causal_lm(*_snake_case ) def _lowercase ( self : Tuple ) -> List[str]: lowercase_ = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_for_question_answering(*_snake_case ) def _lowercase ( self : Tuple ) -> Dict: lowercase_ = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_for_sequence_classification(*_snake_case ) def _lowercase ( self : List[str] ) -> int: lowercase_ = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_for_token_classification(*_snake_case ) @unittest.skip(reason='''Feed forward chunking is not implemented''' ) def _lowercase ( self : Any ) -> List[str]: pass @parameterized.expand([('''linear''',), ('''dynamic''',)] ) def _lowercase ( self : List[str] , SCREAMING_SNAKE_CASE_ : Tuple ) -> List[Any]: lowercase_ = self.model_tester.prepare_config_and_inputs_for_common() lowercase_ = ids_tensor([1, 1_0] , config.vocab_size ) lowercase_ = ids_tensor([1, int(config.max_position_embeddings * 1.5 )] , config.vocab_size ) set_seed(4_2 ) # Fixed seed at init time so the two models get the same random weights lowercase_ = GPTNeoXModel(_snake_case ) original_model.to(_snake_case ) original_model.eval() lowercase_ = original_model(_snake_case ).last_hidden_state lowercase_ = original_model(_snake_case ).last_hidden_state set_seed(4_2 ) # Fixed seed at init time so the two models get the same random weights lowercase_ = {'type': scaling_type, 'factor': 1_0.0} lowercase_ = GPTNeoXModel(_snake_case ) scaled_model.to(_snake_case ) scaled_model.eval() lowercase_ = scaled_model(_snake_case ).last_hidden_state lowercase_ = scaled_model(_snake_case ).last_hidden_state # Dynamic scaling does not change the RoPE embeddings until it receives an input longer than the original # maximum sequence length, so the outputs for the short input should match. if scaling_type == "dynamic": self.assertTrue(torch.allclose(_snake_case , _snake_case , atol=1e-5 ) ) else: self.assertFalse(torch.allclose(_snake_case , _snake_case , atol=1e-5 ) ) # The output should be different for long inputs self.assertFalse(torch.allclose(_snake_case , _snake_case , atol=1e-5 ) ) @require_torch class lowercase__( unittest.TestCase ): """simple docstring""" @slow def _lowercase ( self : List[Any] ) -> Union[str, Any]: lowercase_ = AutoTokenizer.from_pretrained('''EleutherAI/pythia-410m-deduped''' ) for checkpointing in [True, False]: lowercase_ = GPTNeoXForCausalLM.from_pretrained('''EleutherAI/pythia-410m-deduped''' ) if checkpointing: model.gradient_checkpointing_enable() else: model.gradient_checkpointing_disable() model.to(_snake_case ) lowercase_ = tokenizer('''My favorite food is''' , return_tensors='''pt''' ).to(_snake_case ) # The hub repo. is updated on 2023-04-04, resulting in poor outputs. # See: https://github.com/huggingface/transformers/pull/24193 lowercase_ = 'My favorite food is a good old-fashioned, old-fashioned, old-fashioned.\n\nI\'m not sure' lowercase_ = model.generate(**_snake_case , do_sample=_snake_case , max_new_tokens=2_0 ) lowercase_ = tokenizer.batch_decode(_snake_case )[0] self.assertEqual(_snake_case , _snake_case )
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from ...configuration_utils import PretrainedConfig from ...utils import logging a_ :Optional[int] = logging.get_logger(__name__) a_ :Dict = {"openai-gpt": "https://huggingface.co/openai-gpt/resolve/main/config.json"} class snake_case__ ( lowerCAmelCase_ ): """simple docstring""" _SCREAMING_SNAKE_CASE = """openai-gpt""" _SCREAMING_SNAKE_CASE = { """max_position_embeddings""": """n_positions""", """hidden_size""": """n_embd""", """num_attention_heads""": """n_head""", """num_hidden_layers""": """n_layer""", } def __init__( self : Optional[int], _snake_case : Dict=4_0_4_7_8, _snake_case : str=5_1_2, _snake_case : int=7_6_8, _snake_case : Tuple=1_2, _snake_case : Any=1_2, _snake_case : str="gelu", _snake_case : List[str]=0.1, _snake_case : Any=0.1, _snake_case : Dict=0.1, _snake_case : int=1e-5, _snake_case : Optional[Any]=0.0_2, _snake_case : List[Any]="cls_index", _snake_case : Any=True, _snake_case : Any=None, _snake_case : int=True, _snake_case : Optional[Any]=0.1, **_snake_case : List[Any], ) ->Optional[int]: snake_case__ : int = vocab_size snake_case__ : Dict = n_positions snake_case__ : str = n_embd snake_case__ : str = n_layer snake_case__ : List[Any] = n_head snake_case__ : List[Any] = afn snake_case__ : Optional[Any] = resid_pdrop snake_case__ : List[str] = embd_pdrop snake_case__ : List[Any] = attn_pdrop snake_case__ : Optional[int] = layer_norm_epsilon snake_case__ : str = initializer_range snake_case__ : List[str] = summary_type snake_case__ : Optional[int] = summary_use_proj snake_case__ : List[str] = summary_activation snake_case__ : Optional[Any] = summary_first_dropout snake_case__ : int = summary_proj_to_labels super().__init__(**_snake_case )
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"""simple docstring""" import math import time from typing import Dict, List, Optional from torch.utils.data import Dataset from transformers import SeqaSeqTrainer, is_torch_tpu_available from transformers.trainer_utils import PredictionOutput, speed_metrics if is_torch_tpu_available(check_device=False): import torch_xla.core.xla_model as xm import torch_xla.debug.metrics as met class __lowerCAmelCase ( lowerCAmelCase_ ): '''simple docstring''' def __init__( self , *_a , _a=None , _a=None , **_a ): super().__init__(*_snake_case , **_snake_case ) __a = eval_examples __a = post_process_function def __UpperCAmelCase ( self , _a = None , _a=None , _a = None , _a = "eval" , **_a , ): __a = gen_kwargs.copy() __a = ( gen_kwargs['max_length'] if gen_kwargs.get('''max_length''' ) is not None else self.args.generation_max_length ) __a = ( gen_kwargs['num_beams'] if gen_kwargs.get('''num_beams''' ) is not None else self.args.generation_num_beams ) __a = gen_kwargs __a = self.eval_dataset if eval_dataset is None else eval_dataset __a = self.get_eval_dataloader(_snake_case ) __a = self.eval_examples if eval_examples is None else eval_examples # Temporarily disable metric computation, we will do it in the loop here. __a = self.compute_metrics __a = None __a = time.time() __a = self.prediction_loop if self.args.use_legacy_prediction_loop else self.evaluation_loop try: __a = eval_loop( _snake_case , description='''Evaluation''' , prediction_loss_only=True if compute_metrics is None else None , ignore_keys=_snake_case , metric_key_prefix=_snake_case , ) finally: __a = compute_metrics __a = self.args.eval_batch_size * self.args.world_size if f'''{metric_key_prefix}_jit_compilation_time''' in output.metrics: start_time += output.metrics[f'''{metric_key_prefix}_jit_compilation_time'''] output.metrics.update( speed_metrics( _snake_case , _snake_case , num_samples=output.num_samples , num_steps=math.ceil(output.num_samples / total_batch_size ) , ) ) if self.post_process_function is not None and self.compute_metrics is not None and self.args.should_save: # Only the main node write the results by default __a = self.post_process_function(_snake_case , _snake_case , _snake_case ) __a = self.compute_metrics(_snake_case ) # Prefix all keys with metric_key_prefix + '_' for key in list(metrics.keys() ): if not key.startswith(f'''{metric_key_prefix}_''' ): __a = metrics.pop(_snake_case ) metrics.update(output.metrics ) else: __a = output.metrics if self.args.should_log: # Only the main node log the results by default self.log(_snake_case ) if self.args.tpu_metrics_debug or self.args.debug: # tpu-comment: Logging debug metrics for PyTorch/XLA (compile, execute times, ops, etc.) xm.master_print(met.metrics_report() ) __a = self.callback_handler.on_evaluate(self.args , self.state , self.control , _snake_case ) return metrics def __UpperCAmelCase ( self , _a , _a , _a=None , _a = "test" , **_a ): __a = gen_kwargs.copy() __a = self.get_test_dataloader(_snake_case ) # Temporarily disable metric computation, we will do it in the loop here. __a = self.compute_metrics __a = None __a = time.time() __a = self.prediction_loop if self.args.use_legacy_prediction_loop else self.evaluation_loop try: __a = eval_loop( _snake_case , description='''Prediction''' , prediction_loss_only=True if compute_metrics is None else None , ignore_keys=_snake_case , metric_key_prefix=_snake_case , ) finally: __a = compute_metrics __a = self.args.eval_batch_size * self.args.world_size if f'''{metric_key_prefix}_jit_compilation_time''' in output.metrics: start_time += output.metrics[f'''{metric_key_prefix}_jit_compilation_time'''] output.metrics.update( speed_metrics( _snake_case , _snake_case , num_samples=output.num_samples , num_steps=math.ceil(output.num_samples / total_batch_size ) , ) ) if self.post_process_function is None or self.compute_metrics is None: return output __a = self.post_process_function(_snake_case , _snake_case , _snake_case , '''predict''' ) __a = self.compute_metrics(_snake_case ) # Prefix all keys with metric_key_prefix + '_' for key in list(metrics.keys() ): if not key.startswith(f'''{metric_key_prefix}_''' ): __a = metrics.pop(_snake_case ) metrics.update(output.metrics ) return PredictionOutput(predictions=predictions.predictions , label_ids=predictions.label_ids , metrics=_snake_case )
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import argparse import logging import os from datetime import datetime import numpy as np import torch from torch import nn from torch.utils.data import DataLoader, RandomSampler, TensorDataset from tqdm import tqdm from transformers import GPTaLMHeadModel a_ :Optional[Any] = logging.getLogger(__name__) def lowercase_ (A : List[Any] , A : List[Any] ): # save results if os.path.exists(A ): if os.path.exists(os.path.join(A , 'config.json' ) ) and os.path.isfile( os.path.join(A , 'config.json' ) ): os.remove(os.path.join(A , 'config.json' ) ) if os.path.exists(os.path.join(A , 'pytorch_model.bin' ) ) and os.path.isfile( os.path.join(A , 'pytorch_model.bin' ) ): os.remove(os.path.join(A , 'pytorch_model.bin' ) ) else: os.makedirs(A ) model.save_pretrained(A ) def lowercase_ (A : Any , A : Optional[Any]=False ): snake_case__ : str = 2 if unlogit: snake_case__ : Dict = torch.pow(A , A ) snake_case__ : Any = p * torch.log(A ) snake_case__ : Tuple = 0 return -plogp.sum(dim=-1 ) def lowercase_ (A : List[str] ): logger.info('lv, h >\t' + '\t'.join(F'''{x + 1}''' for x in range(len(A ) ) ) ) for row in range(len(A ) ): if tensor.dtype != torch.long: logger.info(F'''layer {row + 1}:\t''' + '\t'.join(F'''{x:.5f}''' for x in tensor[row].cpu().data ) ) else: logger.info(F'''layer {row + 1}:\t''' + '\t'.join(F'''{x:d}''' for x in tensor[row].cpu().data ) ) def lowercase_ (A : Tuple , A : Optional[Any] , A : str , A : int=True , A : Optional[int]=True , A : Any=None , A : int=False ): snake_case__ , snake_case__ : Optional[Any] = model.config.num_hidden_layers, model.config.num_attention_heads snake_case__ : int = torch.zeros(A , A ).to(args.device ) snake_case__ : Any = torch.zeros(A , A ).to(args.device ) if head_mask is None: snake_case__ : Dict = torch.ones(A , A ).to(args.device ) head_mask.requires_grad_(requires_grad=A ) # If actually pruned attention multi-head, set head mask to None to avoid shape mismatch if actually_pruned: snake_case__ : Optional[int] = None snake_case__ : List[Any] = 0.0 snake_case__ : str = 0.0 for step, inputs in enumerate(tqdm(A , desc='Iteration' , disable=args.local_rank not in [-1, 0] ) ): snake_case__ : Union[str, Any] = tuple(t.to(args.device ) for t in inputs ) ((snake_case__) , ) : Optional[Any] = inputs # Do a forward pass (not with torch.no_grad() since we need gradients for importance score - see below) snake_case__ : Union[str, Any] = model(A , labels=A , head_mask=A ) # (loss), lm_logits, presents, (all hidden_states), (attentions) snake_case__ , snake_case__ , snake_case__ : Dict = ( outputs[0], outputs[1], outputs[-1], ) # Loss and logits are the first, attention the last loss.backward() # Backpropagate to populate the gradients in the head mask total_loss += loss.detach().cpu().numpy() if compute_entropy: for layer, attn in enumerate(A ): snake_case__ : Optional[Any] = entropy(attn.detach() , A ) attn_entropy[layer] += masked_entropy.sum(-1 ).sum(0 ).sum(0 ).detach() if compute_importance: head_importance += head_mask.grad.abs().detach() tot_tokens += torch.ones_like(A ).float().detach().sum().data # Normalize attn_entropy /= tot_tokens head_importance /= tot_tokens # Layerwise importance normalization if not args.dont_normalize_importance_by_layer: snake_case__ : Union[str, Any] = 2 snake_case__ : List[Any] = torch.pow(torch.pow(A , A ).sum(-1 ) , 1 / exponent ) head_importance /= norm_by_layer.unsqueeze(-1 ) + 1e-20 if not args.dont_normalize_global_importance: snake_case__ : Tuple = (head_importance - head_importance.min()) / (head_importance.max() - head_importance.min()) # Print matrices if compute_entropy: logger.info('Attention entropies' ) print_ad_tensor(A ) if compute_importance: logger.info('Head importance scores' ) print_ad_tensor(A ) logger.info('Head ranked by importance scores' ) snake_case__ : Tuple = torch.zeros(head_importance.numel() , dtype=torch.long , device=args.device ) snake_case__ : Union[str, Any] = torch.arange( head_importance.numel() , device=args.device ) snake_case__ : str = head_ranks.view_as(A ) print_ad_tensor(A ) return attn_entropy, head_importance, total_loss def lowercase_ (A : Optional[int] , A : Dict , A : Optional[int] ): snake_case__ , snake_case__ , snake_case__ : Any = compute_heads_importance(A , A , A , compute_entropy=A ) snake_case__ : Tuple = 1 / loss # instead of downsteam score use the LM loss logger.info('Pruning: original score: %f, threshold: %f' , A , original_score * args.masking_threshold ) snake_case__ : Optional[Any] = torch.ones_like(A ) snake_case__ : Union[str, Any] = max(1 , int(new_head_mask.numel() * args.masking_amount ) ) snake_case__ : Dict = original_score while current_score >= original_score * args.masking_threshold: snake_case__ : int = new_head_mask.clone().detach() # save current head mask # heads from least important to most - keep only not-masked heads snake_case__ : List[Any] = float('Inf' ) snake_case__ : Union[str, Any] = head_importance.view(-1 ).sort()[1] if len(A ) <= num_to_mask: print('BREAK BY num_to_mask' ) break # mask heads snake_case__ : int = current_heads_to_mask[:num_to_mask] logger.info('Heads to mask: %s' , str(current_heads_to_mask.tolist() ) ) snake_case__ : int = new_head_mask.view(-1 ) snake_case__ : int = 0.0 snake_case__ : Union[str, Any] = new_head_mask.view_as(A ) snake_case__ : List[str] = new_head_mask.clone().detach() print_ad_tensor(A ) # Compute metric and head importance again snake_case__ , snake_case__ , snake_case__ : Any = compute_heads_importance( A , A , A , compute_entropy=A , head_mask=A ) snake_case__ : Dict = 1 / loss logger.info( 'Masking: current score: %f, remaining heads %d (%.1f percents)' , A , new_head_mask.sum() , new_head_mask.sum() / new_head_mask.numel() * 1_0_0 , ) logger.info('Final head mask' ) print_ad_tensor(A ) np.save(os.path.join(args.output_dir , 'head_mask.npy' ) , head_mask.detach().cpu().numpy() ) return head_mask def lowercase_ (A : List[str] , A : Tuple , A : Optional[Any] , A : int ): snake_case__ : Any = datetime.now() snake_case__ , snake_case__ , snake_case__ : str = compute_heads_importance( A , A , A , compute_entropy=A , compute_importance=A , head_mask=A ) snake_case__ : Tuple = 1 / loss snake_case__ : Dict = datetime.now() - before_time snake_case__ : Union[str, Any] = sum(p.numel() for p in model.parameters() ) snake_case__ : Optional[Any] = { layer: (1 - head_mask[layer].long()).nonzero().squeeze().tolist() for layer in range(len(A ) ) } for k, v in heads_to_prune.items(): if isinstance(A , A ): snake_case__ : Any = [ v, ] assert sum(len(A ) for h in heads_to_prune.values() ) == (1 - head_mask.long()).sum().item() model.prune_heads(A ) snake_case__ : Dict = sum(p.numel() for p in model.parameters() ) snake_case__ : Tuple = datetime.now() snake_case__ , snake_case__ , snake_case__ : Dict = compute_heads_importance( A , A , A , compute_entropy=A , compute_importance=A , head_mask=A , actually_pruned=A , ) snake_case__ : Any = 1 / loss snake_case__ : int = datetime.now() - before_time logger.info( 'Pruning: original num of params: %.2e, after pruning %.2e (%.1f percents)' , A , A , pruned_num_params / original_num_params * 1_0_0 , ) logger.info('Pruning: score with masking: %f score with pruning: %f' , A , A ) logger.info('Pruning: speed ratio (original timing / new timing): %f percents' , original_time / new_time * 1_0_0 ) save_model(A , args.output_dir ) def lowercase_ (): snake_case__ : str = argparse.ArgumentParser() # Required parameters parser.add_argument( '--data_dir' , default=A , type=A , required=A , help='The input data dir. Should contain the .tsv files (or other data files) for the task.' , ) parser.add_argument( '--model_name_or_path' , default=A , type=A , required=A , help='Path to pretrained model or model identifier from huggingface.co/models' , ) parser.add_argument( '--output_dir' , default=A , type=A , required=A , help='The output directory where the model predictions and checkpoints will be written.' , ) # Other parameters parser.add_argument( '--config_name' , default='' , type=A , help='Pretrained config name or path if not the same as model_name_or_path' , ) parser.add_argument( '--tokenizer_name' , default='' , type=A , help='Pretrained tokenizer name or path if not the same as model_name_or_path' , ) parser.add_argument( '--cache_dir' , default=A , type=A , help='Where do you want to store the pre-trained models downloaded from s3' , ) parser.add_argument( '--data_subset' , type=A , default=-1 , help='If > 0: limit the data to a subset of data_subset instances.' ) parser.add_argument( '--overwrite_output_dir' , action='store_true' , help='Whether to overwrite data in output directory' ) parser.add_argument( '--overwrite_cache' , action='store_true' , help='Overwrite the cached training and evaluation sets' ) parser.add_argument( '--dont_normalize_importance_by_layer' , action='store_true' , help='Don\'t normalize importance score by layers' ) parser.add_argument( '--dont_normalize_global_importance' , action='store_true' , help='Don\'t normalize all importance scores between 0 and 1' , ) parser.add_argument( '--try_masking' , action='store_true' , help='Whether to try to mask head until a threshold of accuracy.' ) parser.add_argument( '--masking_threshold' , default=0.9 , type=A , help='masking threshold in term of metrics (stop masking when metric < threshold * original metric value).' , ) parser.add_argument( '--masking_amount' , default=0.1 , type=A , help='Amount to heads to masking at each masking step.' ) parser.add_argument('--metric_name' , default='acc' , type=A , help='Metric to use for head masking.' ) parser.add_argument( '--max_seq_length' , default=1_2_8 , type=A , help=( 'The maximum total input sequence length after WordPiece tokenization. \n' 'Sequences longer than this will be truncated, sequences shorter padded.' ) , ) parser.add_argument('--batch_size' , default=1 , type=A , help='Batch size.' ) parser.add_argument('--seed' , type=A , default=4_2 ) parser.add_argument('--local_rank' , type=A , default=-1 , help='local_rank for distributed training on gpus' ) parser.add_argument('--no_cuda' , action='store_true' , help='Whether not to use CUDA when available' ) parser.add_argument('--server_ip' , type=A , default='' , help='Can be used for distant debugging.' ) parser.add_argument('--server_port' , type=A , default='' , help='Can be used for distant debugging.' ) snake_case__ : Optional[int] = parser.parse_args() if args.server_ip and args.server_port: # Distant debugging - see https://code.visualstudio.com/docs/python/debugging#_attach-to-a-local-script import ptvsd print('Waiting for debugger attach' ) ptvsd.enable_attach(address=(args.server_ip, args.server_port) , redirect_output=A ) ptvsd.wait_for_attach() # Setup devices and distributed training if args.local_rank == -1 or args.no_cuda: snake_case__ : List[Any] = torch.device('cuda' if torch.cuda.is_available() and not args.no_cuda else 'cpu' ) snake_case__ : Optional[Any] = 0 if args.no_cuda else torch.cuda.device_count() else: torch.cuda.set_device(args.local_rank ) snake_case__ : int = torch.device('cuda' , args.local_rank ) snake_case__ : List[str] = 1 torch.distributed.init_process_group(backend='nccl' ) # Initializes the distributed backend # Setup logging logging.basicConfig(level=logging.INFO if args.local_rank in [-1, 0] else logging.WARN ) logger.info('device: {} n_gpu: {}, distributed: {}'.format(args.device , args.n_gpu , bool(args.local_rank != -1 ) ) ) snake_case__ : Any = GPTaLMHeadModel.from_pretrained(args.model_name_or_path ) # Distributed and parallel training model.to(args.device ) if args.local_rank != -1: snake_case__ : List[str] = nn.parallel.DistributedDataParallel( A , device_ids=[args.local_rank] , output_device=args.local_rank , find_unused_parameters=A ) elif args.n_gpu > 1: snake_case__ : Optional[int] = nn.DataParallel(A ) # Print/save training arguments os.makedirs(args.output_dir , exist_ok=A ) torch.save(A , os.path.join(args.output_dir , 'run_args.bin' ) ) logger.info('Training/evaluation parameters %s' , A ) # Prepare dataset snake_case__ : Optional[Any] = np.concatenate( [ np.loadtxt(args.data_dir , dtype=np.intaa ), ] ) snake_case__ : List[str] = (torch.from_numpy(A ),) snake_case__ : int = TensorDataset(*A ) snake_case__ : Union[str, Any] = RandomSampler(A ) snake_case__ : Any = DataLoader(A , sampler=A , batch_size=args.batch_size ) # Compute head entropy and importance score compute_heads_importance(A , A , A ) # Try head masking (set heads to zero until the score goes under a threshole) # and head pruning (remove masked heads and see the effect on the network) if args.try_masking and args.masking_threshold > 0.0 and args.masking_threshold < 1.0: snake_case__ : Dict = mask_heads(A , A , A ) prune_heads(A , A , A , A ) if __name__ == "__main__": main()
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'''simple docstring''' from ..utils import DummyObject, requires_backends class A ( metaclass=lowerCAmelCase_ ): '''simple docstring''' A = ["torch"] def __init__(self , *_UpperCAmelCase , **_UpperCAmelCase ) -> Optional[int]: requires_backends(self , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> List[str]: requires_backends(cls , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> List[str]: requires_backends(cls , ["torch"] ) class A ( metaclass=lowerCAmelCase_ ): '''simple docstring''' A = ["torch"] def __init__(self , *_UpperCAmelCase , **_UpperCAmelCase ) -> Optional[int]: requires_backends(self , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Optional[Any]: requires_backends(cls , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Any: requires_backends(cls , ["torch"] ) class A ( metaclass=lowerCAmelCase_ ): '''simple docstring''' A = ["torch"] def __init__(self , *_UpperCAmelCase , **_UpperCAmelCase ) -> List[Any]: requires_backends(self , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Union[str, Any]: requires_backends(cls , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Union[str, Any]: requires_backends(cls , ["torch"] ) class A ( metaclass=lowerCAmelCase_ ): '''simple docstring''' A = ["torch"] def __init__(self , *_UpperCAmelCase , **_UpperCAmelCase ) -> Any: requires_backends(self , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Union[str, Any]: requires_backends(cls , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Union[str, Any]: requires_backends(cls , ["torch"] ) class A ( metaclass=lowerCAmelCase_ ): '''simple docstring''' A = ["torch"] def __init__(self , *_UpperCAmelCase , **_UpperCAmelCase ) -> int: requires_backends(self , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Optional[Any]: requires_backends(cls , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Optional[int]: requires_backends(cls , ["torch"] ) class A ( metaclass=lowerCAmelCase_ ): '''simple docstring''' A = ["torch"] def __init__(self , *_UpperCAmelCase , **_UpperCAmelCase ) -> List[Any]: requires_backends(self , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Union[str, Any]: requires_backends(cls , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> List[Any]: requires_backends(cls , ["torch"] ) class A ( metaclass=lowerCAmelCase_ ): '''simple docstring''' A = ["torch"] def __init__(self , *_UpperCAmelCase , **_UpperCAmelCase ) -> List[str]: requires_backends(self , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> List[Any]: requires_backends(cls , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> List[str]: requires_backends(cls , ["torch"] ) class A ( metaclass=lowerCAmelCase_ ): '''simple docstring''' A = ["torch"] def __init__(self , *_UpperCAmelCase , **_UpperCAmelCase ) -> str: requires_backends(self , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Optional[int]: requires_backends(cls , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> int: requires_backends(cls , ["torch"] ) class A ( metaclass=lowerCAmelCase_ ): '''simple docstring''' A = ["torch"] def __init__(self , *_UpperCAmelCase , **_UpperCAmelCase ) -> List[Any]: requires_backends(self , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Union[str, Any]: requires_backends(cls , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Optional[Any]: requires_backends(cls , ["torch"] ) class A ( metaclass=lowerCAmelCase_ ): '''simple docstring''' A = ["torch"] def __init__(self , *_UpperCAmelCase , **_UpperCAmelCase ) -> Optional[int]: requires_backends(self , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> List[Any]: requires_backends(cls , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Union[str, Any]: requires_backends(cls , ["torch"] ) class A ( metaclass=lowerCAmelCase_ ): '''simple docstring''' A = ["torch"] def __init__(self , *_UpperCAmelCase , **_UpperCAmelCase ) -> Dict: requires_backends(self , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> str: requires_backends(cls , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Dict: requires_backends(cls , ["torch"] ) def __lowerCAmelCase ( *snake_case__ , **snake_case__ ): requires_backends(snake_case__ , ["torch"] ) def __lowerCAmelCase ( *snake_case__ , **snake_case__ ): requires_backends(snake_case__ , ["torch"] ) def __lowerCAmelCase ( *snake_case__ , **snake_case__ ): requires_backends(snake_case__ , ["torch"] ) def __lowerCAmelCase ( *snake_case__ , **snake_case__ ): requires_backends(snake_case__ , ["torch"] ) def __lowerCAmelCase ( *snake_case__ , **snake_case__ ): requires_backends(snake_case__ , ["torch"] ) def __lowerCAmelCase ( *snake_case__ , **snake_case__ ): requires_backends(snake_case__ , ["torch"] ) def __lowerCAmelCase ( *snake_case__ , **snake_case__ ): requires_backends(snake_case__ , ["torch"] ) class A ( metaclass=lowerCAmelCase_ ): '''simple docstring''' A = ["torch"] def __init__(self , *_UpperCAmelCase , **_UpperCAmelCase ) -> Optional[Any]: requires_backends(self , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> str: requires_backends(cls , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Dict: requires_backends(cls , ["torch"] ) class A ( metaclass=lowerCAmelCase_ ): '''simple docstring''' A = ["torch"] def __init__(self , *_UpperCAmelCase , **_UpperCAmelCase ) -> Any: requires_backends(self , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Optional[Any]: requires_backends(cls , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Tuple: requires_backends(cls , ["torch"] ) class A ( metaclass=lowerCAmelCase_ ): '''simple docstring''' A = ["torch"] def __init__(self , *_UpperCAmelCase , **_UpperCAmelCase ) -> str: requires_backends(self , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Any: requires_backends(cls , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Tuple: requires_backends(cls , ["torch"] ) class A ( metaclass=lowerCAmelCase_ ): '''simple docstring''' A = ["torch"] def __init__(self , *_UpperCAmelCase , **_UpperCAmelCase ) -> List[Any]: requires_backends(self , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Optional[Any]: requires_backends(cls , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Any: requires_backends(cls , ["torch"] ) class A ( metaclass=lowerCAmelCase_ ): '''simple docstring''' A = ["torch"] def __init__(self , *_UpperCAmelCase , **_UpperCAmelCase ) -> Optional[int]: requires_backends(self , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> List[str]: requires_backends(cls , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Optional[Any]: requires_backends(cls , ["torch"] ) class A ( metaclass=lowerCAmelCase_ ): '''simple docstring''' A = ["torch"] def __init__(self , *_UpperCAmelCase , **_UpperCAmelCase ) -> List[str]: requires_backends(self , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Optional[Any]: requires_backends(cls , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> List[str]: requires_backends(cls , ["torch"] ) class A ( metaclass=lowerCAmelCase_ ): '''simple docstring''' A = ["torch"] def __init__(self , *_UpperCAmelCase , **_UpperCAmelCase ) -> List[Any]: requires_backends(self , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> int: requires_backends(cls , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> int: requires_backends(cls , ["torch"] ) class A ( metaclass=lowerCAmelCase_ ): '''simple docstring''' A = ["torch"] def __init__(self , *_UpperCAmelCase , **_UpperCAmelCase ) -> Optional[int]: requires_backends(self , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Dict: requires_backends(cls , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> str: requires_backends(cls , ["torch"] ) class A ( metaclass=lowerCAmelCase_ ): '''simple docstring''' A = ["torch"] def __init__(self , *_UpperCAmelCase , **_UpperCAmelCase ) -> Dict: requires_backends(self , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> int: requires_backends(cls , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Union[str, Any]: requires_backends(cls , ["torch"] ) class A ( metaclass=lowerCAmelCase_ ): '''simple docstring''' A = ["torch"] def __init__(self , *_UpperCAmelCase , **_UpperCAmelCase ) -> Optional[int]: requires_backends(self , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> int: requires_backends(cls , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Optional[Any]: requires_backends(cls , ["torch"] ) class A ( metaclass=lowerCAmelCase_ ): '''simple docstring''' A = ["torch"] def __init__(self , *_UpperCAmelCase , **_UpperCAmelCase ) -> Optional[Any]: requires_backends(self , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> int: requires_backends(cls , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> str: requires_backends(cls , ["torch"] ) class A ( metaclass=lowerCAmelCase_ ): '''simple docstring''' A = ["torch"] def __init__(self , *_UpperCAmelCase , **_UpperCAmelCase ) -> List[Any]: requires_backends(self , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> List[str]: requires_backends(cls , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> List[str]: requires_backends(cls , ["torch"] ) class A ( metaclass=lowerCAmelCase_ ): '''simple docstring''' A = ["torch"] def __init__(self , *_UpperCAmelCase , **_UpperCAmelCase ) -> int: requires_backends(self , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Optional[Any]: requires_backends(cls , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> str: requires_backends(cls , ["torch"] ) class A ( metaclass=lowerCAmelCase_ ): '''simple docstring''' A = ["torch"] def __init__(self , *_UpperCAmelCase , **_UpperCAmelCase ) -> Tuple: requires_backends(self , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Tuple: requires_backends(cls , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> List[str]: requires_backends(cls , ["torch"] ) class A ( metaclass=lowerCAmelCase_ ): '''simple docstring''' A = ["torch"] def __init__(self , *_UpperCAmelCase , **_UpperCAmelCase ) -> List[str]: requires_backends(self , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> int: requires_backends(cls , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Dict: requires_backends(cls , ["torch"] ) class A ( metaclass=lowerCAmelCase_ ): '''simple docstring''' A = ["torch"] def __init__(self , *_UpperCAmelCase , **_UpperCAmelCase ) -> Optional[Any]: requires_backends(self , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Tuple: requires_backends(cls , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Union[str, Any]: requires_backends(cls , ["torch"] ) class A ( metaclass=lowerCAmelCase_ ): '''simple docstring''' A = ["torch"] def __init__(self , *_UpperCAmelCase , **_UpperCAmelCase ) -> Dict: requires_backends(self , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Optional[int]: requires_backends(cls , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> int: requires_backends(cls , ["torch"] ) class A ( metaclass=lowerCAmelCase_ ): '''simple docstring''' A = ["torch"] def __init__(self , *_UpperCAmelCase , **_UpperCAmelCase ) -> List[Any]: requires_backends(self , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Dict: requires_backends(cls , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Tuple: requires_backends(cls , ["torch"] ) class A ( metaclass=lowerCAmelCase_ ): '''simple docstring''' A = ["torch"] def __init__(self , *_UpperCAmelCase , **_UpperCAmelCase ) -> Optional[Any]: requires_backends(self , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> int: requires_backends(cls , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Tuple: requires_backends(cls , ["torch"] ) class A ( metaclass=lowerCAmelCase_ ): '''simple docstring''' A = ["torch"] def __init__(self , *_UpperCAmelCase , **_UpperCAmelCase ) -> Dict: requires_backends(self , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Tuple: requires_backends(cls , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> List[Any]: requires_backends(cls , ["torch"] ) class A ( metaclass=lowerCAmelCase_ ): '''simple docstring''' A = ["torch"] def __init__(self , *_UpperCAmelCase , **_UpperCAmelCase ) -> str: requires_backends(self , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> List[str]: requires_backends(cls , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Any: requires_backends(cls , ["torch"] ) class A ( metaclass=lowerCAmelCase_ ): '''simple docstring''' A = ["torch"] def __init__(self , *_UpperCAmelCase , **_UpperCAmelCase ) -> int: requires_backends(self , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Optional[Any]: requires_backends(cls , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Tuple: requires_backends(cls , ["torch"] ) class A ( metaclass=lowerCAmelCase_ ): '''simple docstring''' A = ["torch"] def __init__(self , *_UpperCAmelCase , **_UpperCAmelCase ) -> Optional[Any]: requires_backends(self , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Dict: requires_backends(cls , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> List[Any]: requires_backends(cls , ["torch"] ) class A ( metaclass=lowerCAmelCase_ ): '''simple docstring''' A = ["torch"] def __init__(self , *_UpperCAmelCase , **_UpperCAmelCase ) -> List[str]: requires_backends(self , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Dict: requires_backends(cls , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Union[str, Any]: requires_backends(cls , ["torch"] ) class A ( metaclass=lowerCAmelCase_ ): '''simple docstring''' A = ["torch"] def __init__(self , *_UpperCAmelCase , **_UpperCAmelCase ) -> Dict: requires_backends(self , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Dict: requires_backends(cls , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> List[str]: requires_backends(cls , ["torch"] ) class A ( metaclass=lowerCAmelCase_ ): '''simple docstring''' A = ["torch"] def __init__(self , *_UpperCAmelCase , **_UpperCAmelCase ) -> Optional[int]: requires_backends(self , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Dict: requires_backends(cls , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Dict: requires_backends(cls , ["torch"] ) class A ( metaclass=lowerCAmelCase_ ): '''simple docstring''' A = ["torch"] def __init__(self , *_UpperCAmelCase , **_UpperCAmelCase ) -> str: requires_backends(self , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> List[Any]: requires_backends(cls , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> List[str]: requires_backends(cls , ["torch"] ) class A ( metaclass=lowerCAmelCase_ ): '''simple docstring''' A = ["torch"] def __init__(self , *_UpperCAmelCase , **_UpperCAmelCase ) -> str: requires_backends(self , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> List[str]: requires_backends(cls , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> List[Any]: requires_backends(cls , ["torch"] ) class A ( metaclass=lowerCAmelCase_ ): '''simple docstring''' A = ["torch"] def __init__(self , *_UpperCAmelCase , **_UpperCAmelCase ) -> Optional[Any]: requires_backends(self , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Any: requires_backends(cls , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Union[str, Any]: requires_backends(cls , ["torch"] ) class A ( metaclass=lowerCAmelCase_ ): '''simple docstring''' A = ["torch"] def __init__(self , *_UpperCAmelCase , **_UpperCAmelCase ) -> List[Any]: requires_backends(self , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Tuple: requires_backends(cls , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Union[str, Any]: requires_backends(cls , ["torch"] ) class A ( metaclass=lowerCAmelCase_ ): '''simple docstring''' A = ["torch"] def __init__(self , *_UpperCAmelCase , **_UpperCAmelCase ) -> List[Any]: requires_backends(self , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Tuple: requires_backends(cls , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> str: requires_backends(cls , ["torch"] ) class A ( metaclass=lowerCAmelCase_ ): '''simple docstring''' A = ["torch"] def __init__(self , *_UpperCAmelCase , **_UpperCAmelCase ) -> Optional[Any]: requires_backends(self , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> str: requires_backends(cls , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Optional[int]: requires_backends(cls , ["torch"] ) class A ( metaclass=lowerCAmelCase_ ): '''simple docstring''' A = ["torch"] def __init__(self , *_UpperCAmelCase , **_UpperCAmelCase ) -> Optional[Any]: requires_backends(self , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> int: requires_backends(cls , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Tuple: requires_backends(cls , ["torch"] ) class A ( metaclass=lowerCAmelCase_ ): '''simple docstring''' A = ["torch"] def __init__(self , *_UpperCAmelCase , **_UpperCAmelCase ) -> List[Any]: requires_backends(self , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Optional[int]: requires_backends(cls , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Dict: requires_backends(cls , ["torch"] ) class A ( metaclass=lowerCAmelCase_ ): '''simple docstring''' A = ["torch"] def __init__(self , *_UpperCAmelCase , **_UpperCAmelCase ) -> List[str]: requires_backends(self , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Optional[Any]: requires_backends(cls , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Any: requires_backends(cls , ["torch"] ) class A ( metaclass=lowerCAmelCase_ ): '''simple docstring''' A = ["torch"] def __init__(self , *_UpperCAmelCase , **_UpperCAmelCase ) -> str: requires_backends(self , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> str: requires_backends(cls , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Union[str, Any]: requires_backends(cls , ["torch"] ) class A ( metaclass=lowerCAmelCase_ ): '''simple docstring''' A = ["torch"] def __init__(self , *_UpperCAmelCase , **_UpperCAmelCase ) -> Dict: requires_backends(self , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Optional[int]: requires_backends(cls , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Optional[int]: requires_backends(cls , ["torch"] ) class A ( metaclass=lowerCAmelCase_ ): '''simple docstring''' A = ["torch"] def __init__(self , *_UpperCAmelCase , **_UpperCAmelCase ) -> Union[str, Any]: requires_backends(self , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> str: requires_backends(cls , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> int: requires_backends(cls , ["torch"] ) class A ( metaclass=lowerCAmelCase_ ): '''simple docstring''' A = ["torch"] def __init__(self , *_UpperCAmelCase , **_UpperCAmelCase ) -> Dict: requires_backends(self , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Tuple: requires_backends(cls , ["torch"] ) @classmethod def a_ (cls , *_UpperCAmelCase , **_UpperCAmelCase ) -> Union[str, Any]: requires_backends(cls , ["torch"] )
298
import argparse import json from collections import OrderedDict from pathlib import Path import requests import torch from huggingface_hub import hf_hub_download from PIL import Image from transformers import ( SegformerConfig, SegformerForImageClassification, SegformerForSemanticSegmentation, SegformerImageProcessor, ) from transformers.utils import logging logging.set_verbosity_info() a_ :Dict = logging.get_logger(__name__) def lowercase_ (A : Optional[Any] , A : Any=False ): snake_case__ : List[Any] = OrderedDict() for key, value in state_dict.items(): if encoder_only and not key.startswith('head' ): snake_case__ : str = 'segformer.encoder.' + key if key.startswith('backbone' ): snake_case__ : str = key.replace('backbone' , 'segformer.encoder' ) if "patch_embed" in key: # replace for example patch_embed1 by patch_embeddings.0 snake_case__ : Optional[int] = key[key.find('patch_embed' ) + len('patch_embed' )] snake_case__ : int = key.replace(F'''patch_embed{idx}''' , F'''patch_embeddings.{int(A )-1}''' ) if "norm" in key: snake_case__ : Optional[int] = key.replace('norm' , 'layer_norm' ) if "segformer.encoder.layer_norm" in key: # replace for example layer_norm1 by layer_norm.0 snake_case__ : Tuple = key[key.find('segformer.encoder.layer_norm' ) + len('segformer.encoder.layer_norm' )] snake_case__ : Union[str, Any] = key.replace(F'''layer_norm{idx}''' , F'''layer_norm.{int(A )-1}''' ) if "layer_norm1" in key: snake_case__ : List[Any] = key.replace('layer_norm1' , 'layer_norm_1' ) if "layer_norm2" in key: snake_case__ : List[Any] = key.replace('layer_norm2' , 'layer_norm_2' ) if "block" in key: # replace for example block1 by block.0 snake_case__ : List[Any] = key[key.find('block' ) + len('block' )] snake_case__ : List[Any] = key.replace(F'''block{idx}''' , F'''block.{int(A )-1}''' ) if "attn.q" in key: snake_case__ : int = key.replace('attn.q' , 'attention.self.query' ) if "attn.proj" in key: snake_case__ : str = key.replace('attn.proj' , 'attention.output.dense' ) if "attn" in key: snake_case__ : Optional[int] = key.replace('attn' , 'attention.self' ) if "fc1" in key: snake_case__ : str = key.replace('fc1' , 'dense1' ) if "fc2" in key: snake_case__ : Dict = key.replace('fc2' , 'dense2' ) if "linear_pred" in key: snake_case__ : Union[str, Any] = key.replace('linear_pred' , 'classifier' ) if "linear_fuse" in key: snake_case__ : List[str] = key.replace('linear_fuse.conv' , 'linear_fuse' ) snake_case__ : List[Any] = key.replace('linear_fuse.bn' , 'batch_norm' ) if "linear_c" in key: # replace for example linear_c4 by linear_c.3 snake_case__ : Optional[int] = key[key.find('linear_c' ) + len('linear_c' )] snake_case__ : Tuple = key.replace(F'''linear_c{idx}''' , F'''linear_c.{int(A )-1}''' ) if key.startswith('head' ): snake_case__ : Tuple = key.replace('head' , 'classifier' ) snake_case__ : Optional[int] = value return new_state_dict def lowercase_ (A : Tuple , A : Optional[int] ): # for each of the encoder blocks: for i in range(config.num_encoder_blocks ): for j in range(config.depths[i] ): # read in weights + bias of keys and values (which is a single matrix in the original implementation) snake_case__ : List[str] = state_dict.pop(F'''segformer.encoder.block.{i}.{j}.attention.self.kv.weight''' ) snake_case__ : Optional[Any] = state_dict.pop(F'''segformer.encoder.block.{i}.{j}.attention.self.kv.bias''' ) # next, add keys and values (in that order) to the state dict snake_case__ : str = kv_weight[ : config.hidden_sizes[i], : ] snake_case__ : Dict = kv_bias[: config.hidden_sizes[i]] snake_case__ : List[str] = kv_weight[ config.hidden_sizes[i] :, : ] snake_case__ : List[Any] = kv_bias[ config.hidden_sizes[i] : ] def lowercase_ (): snake_case__ : Union[str, Any] = 'http://images.cocodataset.org/val2017/000000039769.jpg' snake_case__ : Dict = Image.open(requests.get(A , stream=A ).raw ) return image @torch.no_grad() def lowercase_ (A : Any , A : Union[str, Any] , A : Optional[Any] ): snake_case__ : List[str] = SegformerConfig() snake_case__ : Dict = False # set attributes based on model_name snake_case__ : Optional[int] = 'huggingface/label-files' if "segformer" in model_name: snake_case__ : str = model_name[len('segformer.' ) : len('segformer.' ) + 2] if "ade" in model_name: snake_case__ : Optional[int] = 1_5_0 snake_case__ : int = 'ade20k-id2label.json' snake_case__ : List[Any] = (1, 1_5_0, 1_2_8, 1_2_8) elif "city" in model_name: snake_case__ : str = 1_9 snake_case__ : List[str] = 'cityscapes-id2label.json' snake_case__ : Optional[Any] = (1, 1_9, 1_2_8, 1_2_8) else: raise ValueError(F'''Model {model_name} not supported''' ) elif "mit" in model_name: snake_case__ : str = True snake_case__ : Union[str, Any] = model_name[4:6] snake_case__ : Optional[Any] = 1_0_0_0 snake_case__ : Optional[int] = 'imagenet-1k-id2label.json' snake_case__ : List[Any] = (1, 1_0_0_0) else: raise ValueError(F'''Model {model_name} not supported''' ) # set config attributes snake_case__ : str = json.load(open(hf_hub_download(A , A , repo_type='dataset' ) , 'r' ) ) snake_case__ : List[Any] = {int(A ): v for k, v in idalabel.items()} snake_case__ : Union[str, Any] = idalabel snake_case__ : Tuple = {v: k for k, v in idalabel.items()} if size == "b0": pass elif size == "b1": snake_case__ : List[Any] = [6_4, 1_2_8, 3_2_0, 5_1_2] snake_case__ : Tuple = 2_5_6 elif size == "b2": snake_case__ : List[str] = [6_4, 1_2_8, 3_2_0, 5_1_2] snake_case__ : int = 7_6_8 snake_case__ : List[Any] = [3, 4, 6, 3] elif size == "b3": snake_case__ : Optional[Any] = [6_4, 1_2_8, 3_2_0, 5_1_2] snake_case__ : int = 7_6_8 snake_case__ : Optional[Any] = [3, 4, 1_8, 3] elif size == "b4": snake_case__ : str = [6_4, 1_2_8, 3_2_0, 5_1_2] snake_case__ : Optional[Any] = 7_6_8 snake_case__ : Union[str, Any] = [3, 8, 2_7, 3] elif size == "b5": snake_case__ : List[str] = [6_4, 1_2_8, 3_2_0, 5_1_2] snake_case__ : Optional[Any] = 7_6_8 snake_case__ : Any = [3, 6, 4_0, 3] else: raise ValueError(F'''Size {size} not supported''' ) # load image processor (only resize + normalize) snake_case__ : Dict = SegformerImageProcessor( image_scale=(5_1_2, 5_1_2) , keep_ratio=A , align=A , do_random_crop=A ) # prepare image snake_case__ : List[str] = prepare_img() snake_case__ : Dict = image_processor(images=A , return_tensors='pt' ).pixel_values logger.info(F'''Converting model {model_name}...''' ) # load original state dict if encoder_only: snake_case__ : Tuple = torch.load(A , map_location=torch.device('cpu' ) ) else: snake_case__ : int = torch.load(A , map_location=torch.device('cpu' ) )['state_dict'] # rename keys snake_case__ : List[Any] = rename_keys(A , encoder_only=A ) if not encoder_only: del state_dict["decode_head.conv_seg.weight"] del state_dict["decode_head.conv_seg.bias"] # key and value matrices need special treatment read_in_k_v(A , A ) # create HuggingFace model and load state dict if encoder_only: snake_case__ : str = False snake_case__ : List[Any] = SegformerForImageClassification(A ) else: snake_case__ : Dict = SegformerForSemanticSegmentation(A ) model.load_state_dict(A ) model.eval() # forward pass snake_case__ : int = model(A ) snake_case__ : Any = outputs.logits # set expected_slice based on model name # ADE20k checkpoints if model_name == "segformer.b0.512x512.ade.160k": snake_case__ : Dict = torch.tensor( [ [[-4.6310, -5.5232, -6.2356], [-5.1921, -6.1444, -6.5996], [-5.4424, -6.2790, -6.7574]], [[-12.1391, -13.3122, -13.9554], [-12.8732, -13.9352, -14.3563], [-12.9438, -13.8226, -14.2513]], [[-12.5134, -13.4686, -14.4915], [-12.8669, -14.4343, -14.7758], [-13.2523, -14.5819, -15.0694]], ] ) elif model_name == "segformer.b1.512x512.ade.160k": snake_case__ : Optional[int] = torch.tensor( [ [[-7.5820, -8.7231, -8.3215], [-8.0600, -10.3529, -10.0304], [-7.5208, -9.4103, -9.6239]], [[-12.6918, -13.8994, -13.7137], [-13.3196, -15.7523, -15.4789], [-12.9343, -14.8757, -14.9689]], [[-11.1911, -11.9421, -11.3243], [-11.3342, -13.6839, -13.3581], [-10.3909, -12.1832, -12.4858]], ] ) elif model_name == "segformer.b2.512x512.ade.160k": snake_case__ : List[Any] = torch.tensor( [ [[-11.8173, -14.3850, -16.3128], [-14.5648, -16.5804, -18.6568], [-14.7223, -15.7387, -18.4218]], [[-15.7290, -17.9171, -19.4423], [-18.3105, -19.9448, -21.4661], [-17.9296, -18.6497, -20.7910]], [[-15.0783, -17.0336, -18.2789], [-16.8771, -18.6870, -20.1612], [-16.2454, -17.1426, -19.5055]], ] ) elif model_name == "segformer.b3.512x512.ade.160k": snake_case__ : Union[str, Any] = torch.tensor( [ [[-9.0878, -10.2081, -10.1891], [-9.3144, -10.7941, -10.9843], [-9.2294, -10.3855, -10.5704]], [[-12.2316, -13.9068, -13.6102], [-12.9161, -14.3702, -14.3235], [-12.5233, -13.7174, -13.7932]], [[-14.6275, -15.2490, -14.9727], [-14.3400, -15.9687, -16.2827], [-14.1484, -15.4033, -15.8937]], ] ) elif model_name == "segformer.b4.512x512.ade.160k": snake_case__ : Dict = torch.tensor( [ [[-12.3144, -13.2447, -14.0802], [-13.3614, -14.5816, -15.6117], [-13.3340, -14.4433, -16.2219]], [[-19.2781, -20.4128, -20.7506], [-20.6153, -21.6566, -22.0998], [-19.9800, -21.0430, -22.1494]], [[-18.8739, -19.7804, -21.1834], [-20.1233, -21.6765, -23.2944], [-20.0315, -21.2641, -23.6944]], ] ) elif model_name == "segformer.b5.640x640.ade.160k": snake_case__ : List[Any] = torch.tensor( [ [[-9.5524, -12.0835, -11.7348], [-10.5229, -13.6446, -14.5662], [-9.5842, -12.8851, -13.9414]], [[-15.3432, -17.5323, -17.0818], [-16.3330, -18.9255, -19.2101], [-15.1340, -17.7848, -18.3971]], [[-12.6072, -14.9486, -14.6631], [-13.7629, -17.0907, -17.7745], [-12.7899, -16.1695, -17.1671]], ] ) # Cityscapes checkpoints elif model_name == "segformer.b0.1024x1024.city.160k": snake_case__ : str = torch.tensor( [ [[-11.9295, -13.4057, -14.8106], [-13.3431, -14.8179, -15.3781], [-14.2836, -15.5942, -16.1588]], [[-11.4906, -12.8067, -13.6564], [-13.1189, -14.0500, -14.1543], [-13.8748, -14.5136, -14.8789]], [[0.5374, 0.1067, -0.4742], [0.1141, -0.2255, -0.7099], [-0.3000, -0.5924, -1.3105]], ] ) elif model_name == "segformer.b0.512x1024.city.160k": snake_case__ : Tuple = torch.tensor( [ [[-7.8217, -9.8767, -10.1717], [-9.4438, -10.9058, -11.4047], [-9.7939, -12.3495, -12.1079]], [[-7.1514, -9.5336, -10.0860], [-9.7776, -11.6822, -11.8439], [-10.1411, -12.7655, -12.8972]], [[0.3021, 0.0805, -0.2310], [-0.0328, -0.1605, -0.2714], [-0.1408, -0.5477, -0.6976]], ] ) elif model_name == "segformer.b0.640x1280.city.160k": snake_case__ : Any = torch.tensor( [ [ [-1.1_372e01, -1.2_787e01, -1.3_477e01], [-1.2_536e01, -1.4_194e01, -1.4_409e01], [-1.3_217e01, -1.4_888e01, -1.5_327e01], ], [ [-1.4_791e01, -1.7_122e01, -1.8_277e01], [-1.7_163e01, -1.9_192e01, -1.9_533e01], [-1.7_897e01, -1.9_991e01, -2.0_315e01], ], [ [7.6_723e-01, 4.1_921e-01, -7.7_878e-02], [4.7_772e-01, 9.5_557e-03, -2.8_082e-01], [3.6_032e-01, -2.4_826e-01, -5.1_168e-01], ], ] ) elif model_name == "segformer.b0.768x768.city.160k": snake_case__ : Optional[int] = torch.tensor( [ [[-9.4959, -11.3087, -11.7479], [-11.0025, -12.6540, -12.3319], [-11.4064, -13.0487, -12.9905]], [[-9.8905, -11.3084, -12.0854], [-11.1726, -12.7698, -12.9583], [-11.5985, -13.3278, -14.1774]], [[0.2213, 0.0192, -0.2466], [-0.1731, -0.4213, -0.4874], [-0.3126, -0.6541, -1.1389]], ] ) elif model_name == "segformer.b1.1024x1024.city.160k": snake_case__ : Union[str, Any] = torch.tensor( [ [[-13.5748, -13.9111, -12.6500], [-14.3500, -15.3683, -14.2328], [-14.7532, -16.0424, -15.6087]], [[-17.1651, -15.8725, -12.9653], [-17.2580, -17.3718, -14.8223], [-16.6058, -16.8783, -16.7452]], [[-3.6456, -3.0209, -1.4203], [-3.0797, -3.1959, -2.0000], [-1.8757, -1.9217, -1.6997]], ] ) elif model_name == "segformer.b2.1024x1024.city.160k": snake_case__ : List[str] = torch.tensor( [ [[-16.0976, -16.4856, -17.3962], [-16.6234, -19.0342, -19.7685], [-16.0900, -18.0661, -19.1180]], [[-18.4750, -18.8488, -19.5074], [-19.4030, -22.1570, -22.5977], [-19.1191, -20.8486, -22.3783]], [[-4.5178, -5.5037, -6.5109], [-5.0884, -7.2174, -8.0334], [-4.4156, -5.8117, -7.2970]], ] ) elif model_name == "segformer.b3.1024x1024.city.160k": snake_case__ : List[Any] = torch.tensor( [ [[-14.2081, -14.4732, -14.1977], [-14.5867, -16.4423, -16.6356], [-13.4441, -14.9685, -16.8696]], [[-14.4576, -14.7073, -15.0451], [-15.0816, -17.6237, -17.9873], [-14.4213, -16.0199, -18.5992]], [[-4.7349, -4.9588, -5.0966], [-4.3210, -6.9325, -7.2591], [-3.4312, -4.7484, -7.1917]], ] ) elif model_name == "segformer.b4.1024x1024.city.160k": snake_case__ : str = torch.tensor( [ [[-11.7737, -11.9526, -11.3273], [-13.6692, -14.4574, -13.8878], [-13.8937, -14.6924, -15.9345]], [[-14.6706, -14.5330, -14.1306], [-16.1502, -16.8180, -16.4269], [-16.8338, -17.8939, -20.1746]], [[1.0491, 0.8289, 1.0310], [1.1044, 0.5219, 0.8055], [1.0899, 0.6926, 0.5590]], ] ) elif model_name == "segformer.b5.1024x1024.city.160k": snake_case__ : List[str] = torch.tensor( [ [[-12.5641, -13.4777, -13.0684], [-13.9587, -15.8983, -16.6557], [-13.3109, -15.7350, -16.3141]], [[-14.7074, -15.4352, -14.5944], [-16.6353, -18.1663, -18.6120], [-15.1702, -18.0329, -18.1547]], [[-1.7990, -2.0951, -1.7784], [-2.6397, -3.8245, -3.9686], [-1.5264, -2.8126, -2.9316]], ] ) else: snake_case__ : Tuple = logits.argmax(-1 ).item() print('Predicted class:' , model.config.idalabel[predicted_class_idx] ) # verify logits if not encoder_only: assert logits.shape == expected_shape assert torch.allclose(logits[0, :3, :3, :3] , A , atol=1e-2 ) # finally, save model and image processor logger.info(F'''Saving PyTorch model and image processor to {pytorch_dump_folder_path}...''' ) Path(A ).mkdir(exist_ok=A ) model.save_pretrained(A ) image_processor.save_pretrained(A ) if __name__ == "__main__": a_ :Optional[int] = argparse.ArgumentParser() parser.add_argument( "--model_name", default="segformer.b0.512x512.ade.160k", type=str, help="Name of the model you'd like to convert.", ) parser.add_argument( "--checkpoint_path", default=None, type=str, help="Path to the original PyTorch checkpoint (.pth file)." ) parser.add_argument( "--pytorch_dump_folder_path", default=None, type=str, help="Path to the folder to output PyTorch model." ) a_ :Union[str, Any] = parser.parse_args() convert_segformer_checkpoint(args.model_name, args.checkpoint_path, args.pytorch_dump_folder_path)
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0
_snake_case = { "a": "AAAAA", "b": "AAAAB", "c": "AAABA", "d": "AAABB", "e": "AABAA", "f": "AABAB", "g": "AABBA", "h": "AABBB", "i": "ABAAA", "j": "BBBAA", "k": "ABAAB", "l": "ABABA", "m": "ABABB", "n": "ABBAA", "o": "ABBAB", "p": "ABBBA", "q": "ABBBB", "r": "BAAAA", "s": "BAAAB", "t": "BAABA", "u": "BAABB", "v": "BBBAB", "w": "BABAA", "x": "BABAB", "y": "BABBA", "z": "BABBB", " ": " ", } _snake_case = {value: key for key, value in encode_dict.items()} def lowerCAmelCase_ ( snake_case_ ): _A : List[Any] = '' for letter in word.lower(): if letter.isalpha() or letter == " ": encoded += encode_dict[letter] else: raise Exception("""encode() accepts only letters of the alphabet and spaces""" ) return encoded def lowerCAmelCase_ ( snake_case_ ): if set(snake_case_ ) - {"A", "B", " "} != set(): raise Exception("""decode() accepts only \'A\', \'B\' and spaces""" ) _A : str = '' for word in coded.split(): while len(snake_case_ ) != 0: decoded += decode_dict[word[:5]] _A : List[str] = word[5:] decoded += " " return decoded.strip() if __name__ == "__main__": from doctest import testmod testmod()
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import argparse import json import os import fairseq import torch from fairseq.data import Dictionary from transformers import ( WavaVecaConfig, WavaVecaCTCTokenizer, WavaVecaFeatureExtractor, WavaVecaForCTC, WavaVecaForPreTraining, WavaVecaProcessor, logging, ) from transformers.models.wavaveca.modeling_wavaveca import WavaVecaForSequenceClassification logging.set_verbosity_info() a_ :List[Any] = logging.get_logger(__name__) a_ :List[Any] = { "post_extract_proj": "feature_projection.projection", "encoder.pos_conv.0": "encoder.pos_conv_embed.conv", "self_attn.k_proj": "encoder.layers.*.attention.k_proj", "self_attn.v_proj": "encoder.layers.*.attention.v_proj", "self_attn.q_proj": "encoder.layers.*.attention.q_proj", "self_attn.out_proj": "encoder.layers.*.attention.out_proj", "self_attn_layer_norm": "encoder.layers.*.layer_norm", "fc1": "encoder.layers.*.feed_forward.intermediate_dense", "fc2": "encoder.layers.*.feed_forward.output_dense", "final_layer_norm": "encoder.layers.*.final_layer_norm", "encoder.layer_norm": "encoder.layer_norm", "adapter_layer": "encoder.layers.*.adapter_layer", "w2v_model.layer_norm": "feature_projection.layer_norm", "quantizer.weight_proj": "quantizer.weight_proj", "quantizer.vars": "quantizer.codevectors", "project_q": "project_q", "final_proj": "project_hid", "w2v_encoder.proj": "lm_head", "mask_emb": "masked_spec_embed", "pooling_layer.linear": "projector", "pooling_layer.projection": "classifier", } a_ :List[Any] = [ "lm_head", "quantizer.weight_proj", "quantizer.codevectors", "project_q", "project_hid", "projector", "classifier", ] def lowercase_ (A : Dict ): snake_case__ : Optional[Any] = {} with open(A , 'r' ) as file: for line_number, line in enumerate(A ): snake_case__ : Dict = line.strip() if line: snake_case__ : int = line.split() snake_case__ : List[str] = line_number snake_case__ : Dict = words[0] snake_case__ : Optional[Any] = value return result def lowercase_ (A : int , A : int , A : Optional[int] , A : Optional[Any] , A : Tuple ): for attribute in key.split('.' ): snake_case__ : Optional[int] = getattr(A , A ) snake_case__ : Union[str, Any] = None for param_key in PARAM_MAPPING.keys(): if full_name.endswith(A ): snake_case__ : List[str] = PARAM_MAPPING[full_name.split('.' )[-1]] snake_case__ : Dict = 'param' if weight_type is not None and weight_type != "param": snake_case__ : Union[str, Any] = getattr(A , A ).shape elif weight_type is not None and weight_type == "param": snake_case__ : Optional[int] = hf_pointer for attribute in hf_param_name.split('.' ): snake_case__ : Optional[Any] = getattr(A , A ) snake_case__ : Dict = shape_pointer.shape # let's reduce dimension snake_case__ : List[Any] = value[0] else: snake_case__ : Union[str, Any] = hf_pointer.shape if hf_shape != value.shape: raise ValueError( F'''Shape of hf {key + "." + weight_type if weight_type is not None else ""} is {hf_shape}, but should be''' F''' {value.shape} for {full_name}''' ) if weight_type == "weight": snake_case__ : Any = value elif weight_type == "weight_g": snake_case__ : List[Any] = value elif weight_type == "weight_v": snake_case__ : Any = value elif weight_type == "bias": snake_case__ : List[Any] = value elif weight_type == "param": for attribute in hf_param_name.split('.' ): snake_case__ : int = getattr(A , A ) snake_case__ : Optional[int] = value else: snake_case__ : Optional[Any] = value logger.info(F'''{key + "." + weight_type if weight_type is not None else ""} was initialized from {full_name}.''' ) def lowercase_ (A : Tuple , A : List[Any] , A : int , A : str , A : Tuple ): snake_case__ : Optional[int] = None for param_key in PARAM_MAPPING.keys(): if full_name.endswith(A ): snake_case__ : List[str] = PARAM_MAPPING[full_name.split('.' )[-1]] snake_case__ : str = 'param' if weight_type is not None and weight_type != "param": snake_case__ : int = '.'.join([key, weight_type] ) elif weight_type is not None and weight_type == "param": snake_case__ : Any = '.'.join([key, hf_param_name] ) else: snake_case__ : Dict = key snake_case__ : List[str] = value if 'lm_head' in full_key else value[0] a_ :List[str] = { "W_a": "linear_1.weight", "W_b": "linear_2.weight", "b_a": "linear_1.bias", "b_b": "linear_2.bias", "ln_W": "norm.weight", "ln_b": "norm.bias", } def lowercase_ (A : str , A : Optional[Any] , A : Optional[Any]=None , A : List[str]=None ): snake_case__ : Optional[int] = False for key, mapped_key in MAPPING.items(): snake_case__ : Tuple = 'wav2vec2.' + mapped_key if mapped_key not in TOP_LEVEL_KEYS else mapped_key if key in name or key.split('w2v_model.' )[-1] == name.split('.' )[0]: snake_case__ : Optional[int] = True if "*" in mapped_key: snake_case__ : List[Any] = name.split(A )[0].split('.' )[-2] snake_case__ : Union[str, Any] = mapped_key.replace('*' , A ) if "weight_g" in name: snake_case__ : Tuple = 'weight_g' elif "weight_v" in name: snake_case__ : List[str] = 'weight_v' elif "bias" in name: snake_case__ : Dict = 'bias' elif "weight" in name: # TODO: don't match quantizer.weight_proj snake_case__ : Optional[int] = 'weight' else: snake_case__ : str = None if hf_dict is not None: rename_dict(A , A , A , A , A ) else: set_recursively(A , A , A , A , A ) return is_used return is_used def lowercase_ (A : Optional[Any] , A : Dict , A : Optional[int] ): snake_case__ : Dict = [] snake_case__ : Tuple = fairseq_model.state_dict() snake_case__ : str = hf_model.wavaveca.feature_extractor for name, value in fairseq_dict.items(): snake_case__ : str = False if "conv_layers" in name: load_conv_layer( A , A , A , A , hf_model.config.feat_extract_norm == 'group' , ) snake_case__ : Any = True else: snake_case__ : Dict = load_wavaveca_layer(A , A , A ) if not is_used: unused_weights.append(A ) logger.warning(F'''Unused weights: {unused_weights}''' ) def lowercase_ (A : Dict , A : Optional[Any] , A : Tuple , A : str , A : List[str] ): snake_case__ : List[Any] = full_name.split('conv_layers.' )[-1] snake_case__ : List[str] = name.split('.' ) snake_case__ : List[Any] = int(items[0] ) snake_case__ : str = int(items[1] ) if type_id == 0: if "bias" in name: if value.shape != feature_extractor.conv_layers[layer_id].conv.bias.data.shape: raise ValueError( F'''{full_name} has size {value.shape}, but''' F''' {feature_extractor.conv_layers[layer_id].conv.bias.data.shape} was found.''' ) snake_case__ : Any = value logger.info(F'''Feat extract conv layer {layer_id} was initialized from {full_name}.''' ) elif "weight" in name: if value.shape != feature_extractor.conv_layers[layer_id].conv.weight.data.shape: raise ValueError( F'''{full_name} has size {value.shape}, but''' F''' {feature_extractor.conv_layers[layer_id].conv.weight.data.shape} was found.''' ) snake_case__ : str = value logger.info(F'''Feat extract conv layer {layer_id} was initialized from {full_name}.''' ) elif (type_id == 2 and not use_group_norm) or (type_id == 2 and layer_id == 0 and use_group_norm): if "bias" in name: if value.shape != feature_extractor.conv_layers[layer_id].layer_norm.bias.data.shape: raise ValueError( F'''{full_name} has size {value.shape}, but''' F''' {feature_extractor.conv_layers[layer_id].layer_norm.bias.data.shape} was found.''' ) snake_case__ : str = value logger.info(F'''Feat extract layer norm weight of layer {layer_id} was initialized from {full_name}.''' ) elif "weight" in name: if value.shape != feature_extractor.conv_layers[layer_id].layer_norm.weight.data.shape: raise ValueError( F'''{full_name} has size {value.shape}, but''' F''' {feature_extractor.conv_layers[layer_id].layer_norm.weight.data.shape} was found.''' ) snake_case__ : int = value logger.info(F'''Feat extract layer norm weight of layer {layer_id} was initialized from {full_name}.''' ) else: unused_weights.append(A ) @torch.no_grad() def lowercase_ (A : Union[str, Any] , A : str , A : Tuple=None , A : List[str]=None , A : Any=True , A : Optional[int]=False ): if config_path is not None: snake_case__ : List[Any] = WavaVecaConfig.from_pretrained(A ) else: snake_case__ : List[Any] = WavaVecaConfig() if is_seq_class: snake_case__ : Dict = read_txt_into_dict(A ) snake_case__ : Any = idalabel snake_case__ : Union[str, Any] = WavaVecaForSequenceClassification(A ) snake_case__ : Any = WavaVecaFeatureExtractor( feature_size=1 , sampling_rate=1_6_0_0_0 , padding_value=0 , do_normalize=A , return_attention_mask=A , ) feature_extractor.save_pretrained(A ) elif is_finetuned: if dict_path: snake_case__ : str = Dictionary.load(A ) # important change bos & pad token id since CTC symbol is <pad> and # not <s> as in fairseq snake_case__ : List[str] = target_dict.pad_index snake_case__ : Optional[int] = target_dict.bos_index snake_case__ : Optional[int] = target_dict.eos_index snake_case__ : List[Any] = len(target_dict.symbols ) snake_case__ : str = os.path.join(A , 'vocab.json' ) if not os.path.isdir(A ): logger.error('--pytorch_dump_folder_path ({}) should be a directory'.format(A ) ) return os.makedirs(A , exist_ok=A ) snake_case__ : Optional[Any] = target_dict.indices # fairseq has the <pad> and <s> switched snake_case__ : Optional[Any] = 0 snake_case__ : Union[str, Any] = 1 with open(A , 'w' , encoding='utf-8' ) as vocab_handle: json.dump(A , A ) snake_case__ : List[Any] = WavaVecaCTCTokenizer( A , unk_token=target_dict.unk_word , pad_token=target_dict.pad_word , bos_token=target_dict.bos_word , eos_token=target_dict.eos_word , word_delimiter_token='|' , do_lower_case=A , ) snake_case__ : str = True if config.feat_extract_norm == 'layer' else False snake_case__ : Optional[Any] = WavaVecaFeatureExtractor( feature_size=1 , sampling_rate=1_6_0_0_0 , padding_value=0 , do_normalize=A , return_attention_mask=A , ) snake_case__ : Union[str, Any] = WavaVecaProcessor(feature_extractor=A , tokenizer=A ) processor.save_pretrained(A ) snake_case__ : str = WavaVecaForCTC(A ) else: snake_case__ : int = WavaVecaForPreTraining(A ) if is_finetuned or is_seq_class: snake_case__ , snake_case__ , snake_case__ : str = fairseq.checkpoint_utils.load_model_ensemble_and_task( [checkpoint_path] , arg_overrides={'data': '/'.join(dict_path.split('/' )[:-1] )} ) else: snake_case__ : Tuple = argparse.Namespace(task='audio_pretraining' ) snake_case__ : str = fairseq.tasks.setup_task(A ) snake_case__ , snake_case__ , snake_case__ : Any = fairseq.checkpoint_utils.load_model_ensemble_and_task([checkpoint_path] , task=A ) snake_case__ : List[Any] = model[0].eval() recursively_load_weights(A , A , not is_finetuned ) hf_wavavec.save_pretrained(A ) if __name__ == "__main__": a_ :List[Any] = argparse.ArgumentParser() parser.add_argument("--pytorch_dump_folder_path", default=None, type=str, help="Path to the output PyTorch model.") parser.add_argument("--checkpoint_path", default=None, type=str, help="Path to fairseq checkpoint") parser.add_argument("--dict_path", default=None, type=str, help="Path to dict of fine-tuned model") parser.add_argument("--config_path", default=None, type=str, help="Path to hf config.json of model to convert") parser.add_argument( "--not_finetuned", action="store_true", help="Whether the model to convert is a fine-tuned model or not" ) parser.add_argument( "--is_seq_class", action="store_true", help="Whether the model to convert is a fine-tuned sequence classification model or not", ) a_ :str = parser.parse_args() a_ :Tuple = not args.not_finetuned and not args.is_seq_class convert_wavaveca_checkpoint( args.checkpoint_path, args.pytorch_dump_folder_path, args.config_path, args.dict_path, is_finetuned, args.is_seq_class, )
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import argparse import json from collections import OrderedDict from pathlib import Path import requests import torch from huggingface_hub import hf_hub_download from PIL import Image from transformers import ( SegformerConfig, SegformerForImageClassification, SegformerForSemanticSegmentation, SegformerImageProcessor, ) from transformers.utils import logging logging.set_verbosity_info() UpperCAmelCase__ = logging.get_logger(__name__) def A ( _UpperCAmelCase : Optional[Any] , _UpperCAmelCase : Any=False ) -> str: '''simple docstring''' _UpperCAmelCase = OrderedDict() for key, value in state_dict.items(): if encoder_only and not key.startswith('head' ): _UpperCAmelCase = 'segformer.encoder.' + key if key.startswith('backbone' ): _UpperCAmelCase = key.replace('backbone' , 'segformer.encoder' ) if "patch_embed" in key: # replace for example patch_embed1 by patch_embeddings.0 _UpperCAmelCase = key[key.find('patch_embed' ) + len('patch_embed' )] _UpperCAmelCase = key.replace(F"patch_embed{idx}" , F"patch_embeddings.{int(_UpperCAmelCase )-1}" ) if "norm" in key: _UpperCAmelCase = key.replace('norm' , 'layer_norm' ) if "segformer.encoder.layer_norm" in key: # replace for example layer_norm1 by layer_norm.0 _UpperCAmelCase = key[key.find('segformer.encoder.layer_norm' ) + len('segformer.encoder.layer_norm' )] _UpperCAmelCase = key.replace(F"layer_norm{idx}" , F"layer_norm.{int(_UpperCAmelCase )-1}" ) if "layer_norm1" in key: _UpperCAmelCase = key.replace('layer_norm1' , 'layer_norm_1' ) if "layer_norm2" in key: _UpperCAmelCase = key.replace('layer_norm2' , 'layer_norm_2' ) if "block" in key: # replace for example block1 by block.0 _UpperCAmelCase = key[key.find('block' ) + len('block' )] _UpperCAmelCase = key.replace(F"block{idx}" , F"block.{int(_UpperCAmelCase )-1}" ) if "attn.q" in key: _UpperCAmelCase = key.replace('attn.q' , 'attention.self.query' ) if "attn.proj" in key: _UpperCAmelCase = key.replace('attn.proj' , 'attention.output.dense' ) if "attn" in key: _UpperCAmelCase = key.replace('attn' , 'attention.self' ) if "fc1" in key: _UpperCAmelCase = key.replace('fc1' , 'dense1' ) if "fc2" in key: _UpperCAmelCase = key.replace('fc2' , 'dense2' ) if "linear_pred" in key: _UpperCAmelCase = key.replace('linear_pred' , 'classifier' ) if "linear_fuse" in key: _UpperCAmelCase = key.replace('linear_fuse.conv' , 'linear_fuse' ) _UpperCAmelCase = key.replace('linear_fuse.bn' , 'batch_norm' ) if "linear_c" in key: # replace for example linear_c4 by linear_c.3 _UpperCAmelCase = key[key.find('linear_c' ) + len('linear_c' )] _UpperCAmelCase = key.replace(F"linear_c{idx}" , F"linear_c.{int(_UpperCAmelCase )-1}" ) if key.startswith('head' ): _UpperCAmelCase = key.replace('head' , 'classifier' ) _UpperCAmelCase = value return new_state_dict def A ( _UpperCAmelCase : Tuple , _UpperCAmelCase : Optional[int] ) -> Optional[Any]: '''simple docstring''' # for each of the encoder blocks: for i in range(config.num_encoder_blocks ): for j in range(config.depths[i] ): # read in weights + bias of keys and values (which is a single matrix in the original implementation) _UpperCAmelCase = state_dict.pop(F"segformer.encoder.block.{i}.{j}.attention.self.kv.weight" ) _UpperCAmelCase = state_dict.pop(F"segformer.encoder.block.{i}.{j}.attention.self.kv.bias" ) # next, add keys and values (in that order) to the state dict _UpperCAmelCase = kv_weight[ : config.hidden_sizes[i], : ] _UpperCAmelCase = kv_bias[: config.hidden_sizes[i]] _UpperCAmelCase = kv_weight[ config.hidden_sizes[i] :, : ] _UpperCAmelCase = kv_bias[ config.hidden_sizes[i] : ] def A ( ) -> Tuple: '''simple docstring''' _UpperCAmelCase = 'http://images.cocodataset.org/val2017/000000039769.jpg' _UpperCAmelCase = Image.open(requests.get(_UpperCAmelCase , stream=_UpperCAmelCase ).raw ) return image @torch.no_grad() def A ( _UpperCAmelCase : Any , _UpperCAmelCase : Union[str, Any] , _UpperCAmelCase : Optional[Any] ) -> int: '''simple docstring''' _UpperCAmelCase = SegformerConfig() _UpperCAmelCase = False # set attributes based on model_name _UpperCAmelCase = 'huggingface/label-files' if "segformer" in model_name: _UpperCAmelCase = model_name[len('segformer.' ) : len('segformer.' ) + 2] if "ade" in model_name: _UpperCAmelCase = 150 _UpperCAmelCase = 'ade20k-id2label.json' _UpperCAmelCase = (1, 150, 128, 128) elif "city" in model_name: _UpperCAmelCase = 19 _UpperCAmelCase = 'cityscapes-id2label.json' _UpperCAmelCase = (1, 19, 128, 128) else: raise ValueError(F"Model {model_name} not supported" ) elif "mit" in model_name: _UpperCAmelCase = True _UpperCAmelCase = model_name[4:6] _UpperCAmelCase = 1_000 _UpperCAmelCase = 'imagenet-1k-id2label.json' _UpperCAmelCase = (1, 1_000) else: raise ValueError(F"Model {model_name} not supported" ) # set config attributes _UpperCAmelCase = json.load(open(hf_hub_download(_UpperCAmelCase , _UpperCAmelCase , repo_type='dataset' ) , 'r' ) ) _UpperCAmelCase = {int(_UpperCAmelCase ): v for k, v in idalabel.items()} _UpperCAmelCase = idalabel _UpperCAmelCase = {v: k for k, v in idalabel.items()} if size == "b0": pass elif size == "b1": _UpperCAmelCase = [64, 128, 320, 512] _UpperCAmelCase = 256 elif size == "b2": _UpperCAmelCase = [64, 128, 320, 512] _UpperCAmelCase = 768 _UpperCAmelCase = [3, 4, 6, 3] elif size == "b3": _UpperCAmelCase = [64, 128, 320, 512] _UpperCAmelCase = 768 _UpperCAmelCase = [3, 4, 18, 3] elif size == "b4": _UpperCAmelCase = [64, 128, 320, 512] _UpperCAmelCase = 768 _UpperCAmelCase = [3, 8, 27, 3] elif size == "b5": _UpperCAmelCase = [64, 128, 320, 512] _UpperCAmelCase = 768 _UpperCAmelCase = [3, 6, 40, 3] else: raise ValueError(F"Size {size} not supported" ) # load image processor (only resize + normalize) _UpperCAmelCase = SegformerImageProcessor( image_scale=(512, 512) , keep_ratio=_UpperCAmelCase , align=_UpperCAmelCase , do_random_crop=_UpperCAmelCase ) # prepare image _UpperCAmelCase = prepare_img() _UpperCAmelCase = image_processor(images=_UpperCAmelCase , return_tensors='pt' ).pixel_values logger.info(F"Converting model {model_name}..." ) # load original state dict if encoder_only: _UpperCAmelCase = torch.load(_UpperCAmelCase , map_location=torch.device('cpu' ) ) else: _UpperCAmelCase = torch.load(_UpperCAmelCase , map_location=torch.device('cpu' ) )['state_dict'] # rename keys _UpperCAmelCase = rename_keys(_UpperCAmelCase , encoder_only=_UpperCAmelCase ) if not encoder_only: del state_dict["decode_head.conv_seg.weight"] del state_dict["decode_head.conv_seg.bias"] # key and value matrices need special treatment read_in_k_v(_UpperCAmelCase , _UpperCAmelCase ) # create HuggingFace model and load state dict if encoder_only: _UpperCAmelCase = False _UpperCAmelCase = SegformerForImageClassification(_UpperCAmelCase ) else: _UpperCAmelCase = SegformerForSemanticSegmentation(_UpperCAmelCase ) model.load_state_dict(_UpperCAmelCase ) model.eval() # forward pass _UpperCAmelCase = model(_UpperCAmelCase ) _UpperCAmelCase = outputs.logits # set expected_slice based on model name # ADE20k checkpoints if model_name == "segformer.b0.512x512.ade.160k": _UpperCAmelCase = torch.tensor( [ [[-4.6310, -5.5232, -6.2356], [-5.1921, -6.1444, -6.5996], [-5.4424, -6.2790, -6.7574]], [[-12.1391, -13.3122, -13.9554], [-12.8732, -13.9352, -14.3563], [-12.9438, -13.8226, -14.2513]], [[-12.5134, -13.4686, -14.4915], [-12.8669, -14.4343, -14.7758], [-13.2523, -14.5819, -15.0694]], ] ) elif model_name == "segformer.b1.512x512.ade.160k": _UpperCAmelCase = torch.tensor( [ [[-7.5820, -8.7231, -8.3215], [-8.0600, -10.3529, -10.0304], [-7.5208, -9.4103, -9.6239]], [[-12.6918, -13.8994, -13.7137], [-13.3196, -15.7523, -15.4789], [-12.9343, -14.8757, -14.9689]], [[-11.1911, -11.9421, -11.3243], [-11.3342, -13.6839, -13.3581], [-10.3909, -12.1832, -12.4858]], ] ) elif model_name == "segformer.b2.512x512.ade.160k": _UpperCAmelCase = torch.tensor( [ [[-11.8173, -14.3850, -16.3128], [-14.5648, -16.5804, -18.6568], [-14.7223, -15.7387, -18.4218]], [[-15.7290, -17.9171, -19.4423], [-18.3105, -19.9448, -21.4661], [-17.9296, -18.6497, -20.7910]], [[-15.0783, -17.0336, -18.2789], [-16.8771, -18.6870, -20.1612], [-16.2454, -17.1426, -19.5055]], ] ) elif model_name == "segformer.b3.512x512.ade.160k": _UpperCAmelCase = torch.tensor( [ [[-9.0878, -10.2081, -10.1891], [-9.3144, -10.7941, -10.9843], [-9.2294, -10.3855, -10.5704]], [[-12.2316, -13.9068, -13.6102], [-12.9161, -14.3702, -14.3235], [-12.5233, -13.7174, -13.7932]], [[-14.6275, -15.2490, -14.9727], [-14.3400, -15.9687, -16.2827], [-14.1484, -15.4033, -15.8937]], ] ) elif model_name == "segformer.b4.512x512.ade.160k": _UpperCAmelCase = torch.tensor( [ [[-12.3144, -13.2447, -14.0802], [-13.3614, -14.5816, -15.6117], [-13.3340, -14.4433, -16.2219]], [[-19.2781, -20.4128, -20.7506], [-20.6153, -21.6566, -22.0998], [-19.9800, -21.0430, -22.1494]], [[-18.8739, -19.7804, -21.1834], [-20.1233, -21.6765, -23.2944], [-20.0315, -21.2641, -23.6944]], ] ) elif model_name == "segformer.b5.640x640.ade.160k": _UpperCAmelCase = torch.tensor( [ [[-9.5524, -12.0835, -11.7348], [-10.5229, -13.6446, -14.5662], [-9.5842, -12.8851, -13.9414]], [[-15.3432, -17.5323, -17.0818], [-16.3330, -18.9255, -19.2101], [-15.1340, -17.7848, -18.3971]], [[-12.6072, -14.9486, -14.6631], [-13.7629, -17.0907, -17.7745], [-12.7899, -16.1695, -17.1671]], ] ) # Cityscapes checkpoints elif model_name == "segformer.b0.1024x1024.city.160k": _UpperCAmelCase = torch.tensor( [ [[-11.9295, -13.4057, -14.8106], [-13.3431, -14.8179, -15.3781], [-14.2836, -15.5942, -16.1588]], [[-11.4906, -12.8067, -13.6564], [-13.1189, -14.0500, -14.1543], [-13.8748, -14.5136, -14.8789]], [[0.5374, 0.1067, -0.4742], [0.1141, -0.2255, -0.7099], [-0.3000, -0.5924, -1.3105]], ] ) elif model_name == "segformer.b0.512x1024.city.160k": _UpperCAmelCase = torch.tensor( [ [[-7.8217, -9.8767, -10.1717], [-9.4438, -10.9058, -11.4047], [-9.7939, -12.3495, -12.1079]], [[-7.1514, -9.5336, -10.0860], [-9.7776, -11.6822, -11.8439], [-10.1411, -12.7655, -12.8972]], [[0.3021, 0.0805, -0.2310], [-0.0328, -0.1605, -0.2714], [-0.1408, -0.5477, -0.6976]], ] ) elif model_name == "segformer.b0.640x1280.city.160k": _UpperCAmelCase = torch.tensor( [ [ [-1.13_72E01, -1.27_87E01, -1.34_77E01], [-1.25_36E01, -1.41_94E01, -1.44_09E01], [-1.32_17E01, -1.48_88E01, -1.53_27E01], ], [ [-1.47_91E01, -1.71_22E01, -1.82_77E01], [-1.71_63E01, -1.91_92E01, -1.95_33E01], [-1.78_97E01, -1.99_91E01, -2.03_15E01], ], [ [7.67_23E-01, 4.19_21E-01, -7.78_78E-02], [4.77_72E-01, 9.55_57E-03, -2.80_82E-01], [3.60_32E-01, -2.48_26E-01, -5.11_68E-01], ], ] ) elif model_name == "segformer.b0.768x768.city.160k": _UpperCAmelCase = torch.tensor( [ [[-9.4959, -11.3087, -11.7479], [-11.0025, -12.6540, -12.3319], [-11.4064, -13.0487, -12.9905]], [[-9.8905, -11.3084, -12.0854], [-11.1726, -12.7698, -12.9583], [-11.5985, -13.3278, -14.1774]], [[0.2213, 0.0192, -0.2466], [-0.1731, -0.4213, -0.4874], [-0.3126, -0.6541, -1.1389]], ] ) elif model_name == "segformer.b1.1024x1024.city.160k": _UpperCAmelCase = torch.tensor( [ [[-13.5748, -13.9111, -12.6500], [-14.3500, -15.3683, -14.2328], [-14.7532, -16.0424, -15.6087]], [[-17.1651, -15.8725, -12.9653], [-17.2580, -17.3718, -14.8223], [-16.6058, -16.8783, -16.7452]], [[-3.6456, -3.0209, -1.4203], [-3.0797, -3.1959, -2.0000], [-1.8757, -1.9217, -1.6997]], ] ) elif model_name == "segformer.b2.1024x1024.city.160k": _UpperCAmelCase = torch.tensor( [ [[-16.0976, -16.4856, -17.3962], [-16.6234, -19.0342, -19.7685], [-16.0900, -18.0661, -19.1180]], [[-18.4750, -18.8488, -19.5074], [-19.4030, -22.1570, -22.5977], [-19.1191, -20.8486, -22.3783]], [[-4.5178, -5.5037, -6.5109], [-5.0884, -7.2174, -8.0334], [-4.4156, -5.8117, -7.2970]], ] ) elif model_name == "segformer.b3.1024x1024.city.160k": _UpperCAmelCase = torch.tensor( [ [[-14.2081, -14.4732, -14.1977], [-14.5867, -16.4423, -16.6356], [-13.4441, -14.9685, -16.8696]], [[-14.4576, -14.7073, -15.0451], [-15.0816, -17.6237, -17.9873], [-14.4213, -16.0199, -18.5992]], [[-4.7349, -4.9588, -5.0966], [-4.3210, -6.9325, -7.2591], [-3.4312, -4.7484, -7.1917]], ] ) elif model_name == "segformer.b4.1024x1024.city.160k": _UpperCAmelCase = torch.tensor( [ [[-11.7737, -11.9526, -11.3273], [-13.6692, -14.4574, -13.8878], [-13.8937, -14.6924, -15.9345]], [[-14.6706, -14.5330, -14.1306], [-16.1502, -16.8180, -16.4269], [-16.8338, -17.8939, -20.1746]], [[1.0491, 0.8289, 1.0310], [1.1044, 0.5219, 0.8055], [1.0899, 0.6926, 0.5590]], ] ) elif model_name == "segformer.b5.1024x1024.city.160k": _UpperCAmelCase = torch.tensor( [ [[-12.5641, -13.4777, -13.0684], [-13.9587, -15.8983, -16.6557], [-13.3109, -15.7350, -16.3141]], [[-14.7074, -15.4352, -14.5944], [-16.6353, -18.1663, -18.6120], [-15.1702, -18.0329, -18.1547]], [[-1.7990, -2.0951, -1.7784], [-2.6397, -3.8245, -3.9686], [-1.5264, -2.8126, -2.9316]], ] ) else: _UpperCAmelCase = logits.argmax(-1 ).item() print('Predicted class:' , model.config.idalabel[predicted_class_idx] ) # verify logits if not encoder_only: assert logits.shape == expected_shape assert torch.allclose(logits[0, :3, :3, :3] , _UpperCAmelCase , atol=1E-2 ) # finally, save model and image processor logger.info(F"Saving PyTorch model and image processor to {pytorch_dump_folder_path}..." ) Path(_UpperCAmelCase ).mkdir(exist_ok=_UpperCAmelCase ) model.save_pretrained(_UpperCAmelCase ) image_processor.save_pretrained(_UpperCAmelCase ) if __name__ == "__main__": UpperCAmelCase__ = argparse.ArgumentParser() parser.add_argument( "--model_name", default="segformer.b0.512x512.ade.160k", type=str, help="Name of the model you'd like to convert.", ) parser.add_argument( "--checkpoint_path", default=None, type=str, help="Path to the original PyTorch checkpoint (.pth file)." ) parser.add_argument( "--pytorch_dump_folder_path", default=None, type=str, help="Path to the folder to output PyTorch model." ) UpperCAmelCase__ = parser.parse_args() convert_segformer_checkpoint(args.model_name, args.checkpoint_path, args.pytorch_dump_folder_path)
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from typing import Dict, List from nltk.translate import gleu_score import datasets from datasets import MetricInfo a_ :Any = "\\n@misc{wu2016googles,\n title={Google's Neural Machine Translation System: Bridging the Gap between Human and Machine Translation},\n author={Yonghui Wu and Mike Schuster and Zhifeng Chen and Quoc V. Le and Mohammad Norouzi and Wolfgang Macherey\n and Maxim Krikun and Yuan Cao and Qin Gao and Klaus Macherey and Jeff Klingner and Apurva Shah and Melvin\n Johnson and Xiaobing Liu and Łukasz Kaiser and Stephan Gouws and Yoshikiyo Kato and Taku Kudo and Hideto\n Kazawa and Keith Stevens and George Kurian and Nishant Patil and Wei Wang and Cliff Young and\n Jason Smith and Jason Riesa and Alex Rudnick and Oriol Vinyals and Greg Corrado and Macduff Hughes\n and Jeffrey Dean},\n year={2016},\n eprint={1609.08144},\n archivePrefix={arXiv},\n primaryClass={cs.CL}\n}\n" a_ :List[str] = "\\nThe BLEU score has some undesirable properties when used for single\nsentences, as it was designed to be a corpus measure. We therefore\nuse a slightly different score for our RL experiments which we call\nthe 'GLEU score'. For the GLEU score, we record all sub-sequences of\n1, 2, 3 or 4 tokens in output and target sequence (n-grams). We then\ncompute a recall, which is the ratio of the number of matching n-grams\nto the number of total n-grams in the target (ground truth) sequence,\nand a precision, which is the ratio of the number of matching n-grams\nto the number of total n-grams in the generated output sequence. Then\nGLEU score is simply the minimum of recall and precision. This GLEU\nscore's range is always between 0 (no matches) and 1 (all match) and\nit is symmetrical when switching output and target. According to\nour experiments, GLEU score correlates quite well with the BLEU\nmetric on a corpus level but does not have its drawbacks for our per\nsentence reward objective.\n" a_ :List[str] = "\\nComputes corpus-level Google BLEU (GLEU) score of translated segments against one or more references.\nInstead of averaging the sentence level GLEU scores (i.e. macro-average precision), Wu et al. (2016) sum up the matching\ntokens and the max of hypothesis and reference tokens for each sentence, then compute using the aggregate values.\n\nArgs:\n predictions (list of str): list of translations to score.\n Each translation should be tokenized into a list of tokens.\n references (list of list of str): list of lists of references for each translation.\n Each reference should be tokenized into a list of tokens.\n min_len (int): The minimum order of n-gram this function should extract. Defaults to 1.\n max_len (int): The maximum order of n-gram this function should extract. Defaults to 4.\n\nReturns:\n 'google_bleu': google_bleu score\n\nExamples:\n Example 1:\n >>> hyp1 = ['It', 'is', 'a', 'guide', 'to', 'action', 'which',\n ... 'ensures', 'that', 'the', 'rubber', 'duck', 'always',\n ... 'disobeys', 'the', 'commands', 'of', 'the', 'cat']\n >>> ref1a = ['It', 'is', 'the', 'guiding', 'principle', 'which',\n ... 'guarantees', 'the', 'rubber', 'duck', 'forces', 'never',\n ... 'being', 'under', 'the', 'command', 'of', 'the', 'cat']\n\n >>> hyp2 = ['he', 'read', 'the', 'book', 'because', 'he', 'was',\n ... 'interested', 'in', 'world', 'history']\n >>> ref2a = ['he', 'was', 'interested', 'in', 'world', 'history',\n ... 'because', 'he', 'read', 'the', 'book']\n\n >>> list_of_references = [[ref1a], [ref2a]]\n >>> hypotheses = [hyp1, hyp2]\n >>> google_bleu = datasets.load_metric(\"google_bleu\")\n >>> results = google_bleu.compute(predictions=hypotheses, references=list_of_references)\n >>> print(round(results[\"google_bleu\"], 2))\n 0.44\n\n Example 2:\n >>> hyp1 = ['It', 'is', 'a', 'guide', 'to', 'action', 'which',\n ... 'ensures', 'that', 'the', 'rubber', 'duck', 'always',\n ... 'disobeys', 'the', 'commands', 'of', 'the', 'cat']\n >>> ref1a = ['It', 'is', 'the', 'guiding', 'principle', 'which',\n ... 'guarantees', 'the', 'rubber', 'duck', 'forces', 'never',\n ... 'being', 'under', 'the', 'command', 'of', 'the', 'cat']\n >>> ref1b = ['It', 'is', 'a', 'guide', 'to', 'action', 'that',\n ... 'ensures', 'that', 'the', 'rubber', 'duck', 'will', 'never',\n ... 'heed', 'the', 'cat', 'commands']\n >>> ref1c = ['It', 'is', 'the', 'practical', 'guide', 'for', 'the',\n ... 'rubber', 'duck', 'army', 'never', 'to', 'heed', 'the', 'directions',\n ... 'of', 'the', 'cat']\n\n >>> hyp2 = ['he', 'read', 'the', 'book', 'because', 'he', 'was',\n ... 'interested', 'in', 'world', 'history']\n >>> ref2a = ['he', 'was', 'interested', 'in', 'world', 'history',\n ... 'because', 'he', 'read', 'the', 'book']\n\n >>> list_of_references = [[ref1a, ref1b, ref1c], [ref2a]]\n >>> hypotheses = [hyp1, hyp2]\n >>> google_bleu = datasets.load_metric(\"google_bleu\")\n >>> results = google_bleu.compute(predictions=hypotheses, references=list_of_references)\n >>> print(round(results[\"google_bleu\"], 2))\n 0.61\n\n Example 3:\n >>> hyp1 = ['It', 'is', 'a', 'guide', 'to', 'action', 'which',\n ... 'ensures', 'that', 'the', 'rubber', 'duck', 'always',\n ... 'disobeys', 'the', 'commands', 'of', 'the', 'cat']\n >>> ref1a = ['It', 'is', 'the', 'guiding', 'principle', 'which',\n ... 'guarantees', 'the', 'rubber', 'duck', 'forces', 'never',\n ... 'being', 'under', 'the', 'command', 'of', 'the', 'cat']\n >>> ref1b = ['It', 'is', 'a', 'guide', 'to', 'action', 'that',\n ... 'ensures', 'that', 'the', 'rubber', 'duck', 'will', 'never',\n ... 'heed', 'the', 'cat', 'commands']\n >>> ref1c = ['It', 'is', 'the', 'practical', 'guide', 'for', 'the',\n ... 'rubber', 'duck', 'army', 'never', 'to', 'heed', 'the', 'directions',\n ... 'of', 'the', 'cat']\n\n >>> hyp2 = ['he', 'read', 'the', 'book', 'because', 'he', 'was',\n ... 'interested', 'in', 'world', 'history']\n >>> ref2a = ['he', 'was', 'interested', 'in', 'world', 'history',\n ... 'because', 'he', 'read', 'the', 'book']\n\n >>> list_of_references = [[ref1a, ref1b, ref1c], [ref2a]]\n >>> hypotheses = [hyp1, hyp2]\n >>> google_bleu = datasets.load_metric(\"google_bleu\")\n >>> results = google_bleu.compute(predictions=hypotheses, references=list_of_references, min_len=2)\n >>> print(round(results[\"google_bleu\"], 2))\n 0.53\n\n Example 4:\n >>> hyp1 = ['It', 'is', 'a', 'guide', 'to', 'action', 'which',\n ... 'ensures', 'that', 'the', 'rubber', 'duck', 'always',\n ... 'disobeys', 'the', 'commands', 'of', 'the', 'cat']\n >>> ref1a = ['It', 'is', 'the', 'guiding', 'principle', 'which',\n ... 'guarantees', 'the', 'rubber', 'duck', 'forces', 'never',\n ... 'being', 'under', 'the', 'command', 'of', 'the', 'cat']\n >>> ref1b = ['It', 'is', 'a', 'guide', 'to', 'action', 'that',\n ... 'ensures', 'that', 'the', 'rubber', 'duck', 'will', 'never',\n ... 'heed', 'the', 'cat', 'commands']\n >>> ref1c = ['It', 'is', 'the', 'practical', 'guide', 'for', 'the',\n ... 'rubber', 'duck', 'army', 'never', 'to', 'heed', 'the', 'directions',\n ... 'of', 'the', 'cat']\n\n >>> hyp2 = ['he', 'read', 'the', 'book', 'because', 'he', 'was',\n ... 'interested', 'in', 'world', 'history']\n >>> ref2a = ['he', 'was', 'interested', 'in', 'world', 'history',\n ... 'because', 'he', 'read', 'the', 'book']\n\n >>> list_of_references = [[ref1a, ref1b, ref1c], [ref2a]]\n >>> hypotheses = [hyp1, hyp2]\n >>> google_bleu = datasets.load_metric(\"google_bleu\")\n >>> results = google_bleu.compute(predictions=hypotheses,references=list_of_references, min_len=2, max_len=6)\n >>> print(round(results[\"google_bleu\"], 2))\n 0.4\n" @datasets.utils.file_utils.add_start_docstrings(_DESCRIPTION , _KWARGS_DESCRIPTION ) class snake_case__ ( datasets.Metric ): """simple docstring""" def lowercase_ ( self : str ) ->MetricInfo: return datasets.MetricInfo( description=_DESCRIPTION, citation=_CITATION, inputs_description=_KWARGS_DESCRIPTION, features=datasets.Features( { 'predictions': datasets.Sequence(datasets.Value('string', id='token' ), id='sequence' ), 'references': datasets.Sequence( datasets.Sequence(datasets.Value('string', id='token' ), id='sequence' ), id='references' ), } ), ) def lowercase_ ( self : str, _snake_case : List[List[List[str]]], _snake_case : List[List[str]], _snake_case : int = 1, _snake_case : int = 4, ) ->Dict[str, float]: return { "google_bleu": gleu_score.corpus_gleu( list_of_references=_snake_case, hypotheses=_snake_case, min_len=_snake_case, max_len=_snake_case ) }
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import unittest import numpy as np from transformers.testing_utils import require_torch, require_vision from transformers.utils import is_torch_available, is_vision_available from ...test_image_processing_common import ImageProcessingSavingTestMixin, prepare_image_inputs if is_torch_available(): import torch if is_vision_available(): from PIL import Image from transformers import LevitImageProcessor class UpperCamelCase_ ( unittest.TestCase ): '''simple docstring''' def __init__( self , a , a=7 , a=3 , a=18 , a=30 , a=4_00 , a=True , a=None , a=True , a=None , a=True , a=[0.5, 0.5, 0.5] , a=[0.5, 0.5, 0.5] , ) -> str: snake_case_ = size if size is not None else {'shortest_edge': 18} snake_case_ = crop_size if crop_size is not None else {'height': 18, 'width': 18} snake_case_ = parent snake_case_ = batch_size snake_case_ = num_channels snake_case_ = image_size snake_case_ = min_resolution snake_case_ = max_resolution snake_case_ = do_resize snake_case_ = size snake_case_ = do_center_crop snake_case_ = crop_size snake_case_ = do_normalize snake_case_ = image_mean snake_case_ = image_std def _UpperCamelCase ( self ) -> List[str]: return { "image_mean": self.image_mean, "image_std": self.image_std, "do_normalize": self.do_normalize, "do_resize": self.do_resize, "do_center_crop": self.do_center_crop, "size": self.size, "crop_size": self.crop_size, } @require_torch @require_vision class UpperCamelCase_ ( lowerCAmelCase_ , unittest.TestCase ): '''simple docstring''' lowerCAmelCase = LevitImageProcessor if is_vision_available() else None def _UpperCamelCase ( self ) -> Any: snake_case_ = LevitImageProcessingTester(self ) @property def _UpperCamelCase ( self ) -> Dict: return self.image_processor_tester.prepare_image_processor_dict() def _UpperCamelCase ( self ) -> List[str]: snake_case_ = self.image_processing_class(**self.image_processor_dict ) self.assertTrue(hasattr(_snake_case , 'image_mean' ) ) self.assertTrue(hasattr(_snake_case , 'image_std' ) ) self.assertTrue(hasattr(_snake_case , 'do_normalize' ) ) self.assertTrue(hasattr(_snake_case , 'do_resize' ) ) self.assertTrue(hasattr(_snake_case , 'do_center_crop' ) ) self.assertTrue(hasattr(_snake_case , 'size' ) ) def _UpperCamelCase ( self ) -> str: snake_case_ = self.image_processing_class.from_dict(self.image_processor_dict ) self.assertEqual(image_processor.size , {'shortest_edge': 18} ) self.assertEqual(image_processor.crop_size , {'height': 18, 'width': 18} ) snake_case_ = self.image_processing_class.from_dict(self.image_processor_dict , size=42 , crop_size=84 ) self.assertEqual(image_processor.size , {'shortest_edge': 42} ) self.assertEqual(image_processor.crop_size , {'height': 84, 'width': 84} ) def _UpperCamelCase ( self ) -> Optional[int]: pass def _UpperCamelCase ( self ) -> Optional[Any]: # Initialize image_processing snake_case_ = self.image_processing_class(**self.image_processor_dict ) # create random PIL images snake_case_ = prepare_image_inputs(self.image_processor_tester , equal_resolution=_snake_case ) for image in image_inputs: self.assertIsInstance(_snake_case , Image.Image ) # Test not batched input snake_case_ = image_processing(image_inputs[0] , return_tensors='pt' ).pixel_values self.assertEqual( encoded_images.shape , ( 1, self.image_processor_tester.num_channels, self.image_processor_tester.crop_size['height'], self.image_processor_tester.crop_size['width'], ) , ) # Test batched snake_case_ = image_processing(_snake_case , return_tensors='pt' ).pixel_values self.assertEqual( encoded_images.shape , ( self.image_processor_tester.batch_size, self.image_processor_tester.num_channels, self.image_processor_tester.crop_size['height'], self.image_processor_tester.crop_size['width'], ) , ) def _UpperCamelCase ( self ) -> Tuple: # Initialize image_processing snake_case_ = self.image_processing_class(**self.image_processor_dict ) # create random numpy tensors snake_case_ = prepare_image_inputs(self.image_processor_tester , equal_resolution=_snake_case , numpify=_snake_case ) for image in image_inputs: self.assertIsInstance(_snake_case , np.ndarray ) # Test not batched input snake_case_ = image_processing(image_inputs[0] , return_tensors='pt' ).pixel_values self.assertEqual( encoded_images.shape , ( 1, self.image_processor_tester.num_channels, self.image_processor_tester.crop_size['height'], self.image_processor_tester.crop_size['width'], ) , ) # Test batched snake_case_ = image_processing(_snake_case , return_tensors='pt' ).pixel_values self.assertEqual( encoded_images.shape , ( self.image_processor_tester.batch_size, self.image_processor_tester.num_channels, self.image_processor_tester.crop_size['height'], self.image_processor_tester.crop_size['width'], ) , ) def _UpperCamelCase ( self ) -> List[Any]: # Initialize image_processing snake_case_ = self.image_processing_class(**self.image_processor_dict ) # create random PyTorch tensors snake_case_ = prepare_image_inputs(self.image_processor_tester , equal_resolution=_snake_case , torchify=_snake_case ) for image in image_inputs: self.assertIsInstance(_snake_case , torch.Tensor ) # Test not batched input snake_case_ = image_processing(image_inputs[0] , return_tensors='pt' ).pixel_values self.assertEqual( encoded_images.shape , ( 1, self.image_processor_tester.num_channels, self.image_processor_tester.crop_size['height'], self.image_processor_tester.crop_size['width'], ) , ) # Test batched snake_case_ = image_processing(_snake_case , return_tensors='pt' ).pixel_values self.assertEqual( encoded_images.shape , ( self.image_processor_tester.batch_size, self.image_processor_tester.num_channels, self.image_processor_tester.crop_size['height'], self.image_processor_tester.crop_size['width'], ) , )
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from math import factorial def lowercase_ (A : int , A : int , A : float ): if successes > trials: raise ValueError('successes must be lower or equal to trials' ) if trials < 0 or successes < 0: raise ValueError('the function is defined for non-negative integers' ) if not isinstance(A , A ) or not isinstance(A , A ): raise ValueError('the function is defined for non-negative integers' ) if not 0 < prob < 1: raise ValueError('prob has to be in range of 1 - 0' ) snake_case__ : List[Any] = (prob**successes) * ((1 - prob) ** (trials - successes)) # Calculate the binomial coefficient: n! / k!(n-k)! snake_case__ : List[str] = float(factorial(A ) ) coefficient /= factorial(A ) * factorial(trials - successes ) return probability * coefficient if __name__ == "__main__": from doctest import testmod testmod() print("Probability of 2 successes out of 4 trails") print("with probability of 0.75 is:", end=" ") print(binomial_distribution(2, 4, 0.75))
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"""simple docstring""" import json import os import tempfile from unittest.mock import patch import torch from torch.utils.data import DataLoader, TensorDataset from accelerate import DistributedType, infer_auto_device_map, init_empty_weights from accelerate.accelerator import Accelerator from accelerate.state import GradientState, PartialState from accelerate.test_utils import require_bnb, require_multi_gpu, slow from accelerate.test_utils.testing import AccelerateTestCase, require_cuda from accelerate.utils import patch_environment def lowercase () -> Optional[int]: SCREAMING_SNAKE_CASE = torch.nn.Linear(2 , 4 ) SCREAMING_SNAKE_CASE = torch.optim.AdamW(model.parameters() , lr=1.0 ) SCREAMING_SNAKE_CASE = torch.optim.lr_scheduler.OneCycleLR(SCREAMING_SNAKE_CASE_ , max_lr=0.01 , steps_per_epoch=2 , epochs=1 ) SCREAMING_SNAKE_CASE = DataLoader(TensorDataset(torch.tensor([1, 2, 3] ) ) ) SCREAMING_SNAKE_CASE = DataLoader(TensorDataset(torch.tensor([4, 5, 6] ) ) ) return model, optimizer, scheduler, train_dl, valid_dl def lowercase (SCREAMING_SNAKE_CASE_ : Optional[Any] ) -> int: return (model.weight.abs().sum() + model.bias.abs().sum()).item() def lowercase (SCREAMING_SNAKE_CASE_ : str ) -> List[str]: SCREAMING_SNAKE_CASE = torch.nn.Linear(*tuple(model.weight.T.shape ) ).state_dict() model.load_state_dict(SCREAMING_SNAKE_CASE_ ) class lowerCAmelCase ( lowerCAmelCase_ ): '''simple docstring''' @require_cuda def __A ( self ) -> Optional[int]: SCREAMING_SNAKE_CASE = Accelerator() assert PartialState._shared_state["_cpu"] is False assert PartialState._shared_state["device"].type == "cuda" with self.assertRaises(_snake_case ): SCREAMING_SNAKE_CASE = Accelerator(cpu=_snake_case ) def __A ( self ) -> Dict: SCREAMING_SNAKE_CASE = Accelerator() SCREAMING_SNAKE_CASE = GradientState() assert state.num_steps == 1 SCREAMING_SNAKE_CASE = 4 assert state.num_steps == 4 assert state.sync_gradients is True SCREAMING_SNAKE_CASE = False assert state.sync_gradients is False GradientState._reset_state() def __A ( self ) -> Optional[Any]: SCREAMING_SNAKE_CASE = Accelerator() SCREAMING_SNAKE_CASE = create_components() ( SCREAMING_SNAKE_CASE ) = accelerator.prepare(_snake_case , _snake_case , _snake_case , _snake_case , _snake_case ) self.assertTrue(prepared_model in accelerator._models ) self.assertTrue(prepared_optimizer in accelerator._optimizers ) self.assertTrue(prepared_scheduler in accelerator._schedulers ) self.assertTrue(prepared_train_dl in accelerator._dataloaders ) self.assertTrue(prepared_valid_dl in accelerator._dataloaders ) def __A ( self ) -> int: SCREAMING_SNAKE_CASE = Accelerator() SCREAMING_SNAKE_CASE = create_components() accelerator.prepare(_snake_case , _snake_case , _snake_case , _snake_case , _snake_case ) accelerator.free_memory() self.assertTrue(len(accelerator._models ) == 0 ) self.assertTrue(len(accelerator._optimizers ) == 0 ) self.assertTrue(len(accelerator._schedulers ) == 0 ) self.assertTrue(len(accelerator._dataloaders ) == 0 ) def __A ( self ) -> List[Any]: PartialState._reset_state() # Mock torch.cuda.set_device to avoid an exception as the device doesn't exist def noop(*lowerCAmelCase__ , **lowerCAmelCase__ ): pass with patch('torch.cuda.set_device' , _snake_case ), patch_environment(ACCELERATE_TORCH_DEVICE='cuda:64' ): SCREAMING_SNAKE_CASE = Accelerator() self.assertEqual(str(accelerator.state.device ) , 'cuda:64' ) def __A ( self ) -> List[Any]: SCREAMING_SNAKE_CASE = Accelerator() SCREAMING_SNAKE_CASE = create_components() accelerator.prepare(_snake_case , _snake_case , _snake_case , _snake_case , _snake_case ) SCREAMING_SNAKE_CASE = get_signature(_snake_case ) with tempfile.TemporaryDirectory() as tmpdirname: accelerator.save_state(_snake_case ) # make sure random weights don't match load_random_weights(_snake_case ) self.assertTrue(abs(model_signature - get_signature(_snake_case ) ) > 1e-3 ) # make sure loaded weights match accelerator.load_state(_snake_case ) self.assertTrue(abs(model_signature - get_signature(_snake_case ) ) < 1e-3 ) def __A ( self ) -> int: SCREAMING_SNAKE_CASE = Accelerator() SCREAMING_SNAKE_CASE = create_components() accelerator.prepare(_snake_case , _snake_case , _snake_case , _snake_case , _snake_case ) SCREAMING_SNAKE_CASE = get_signature(_snake_case ) # saving hook def save_config(lowerCAmelCase__ , lowerCAmelCase__ , lowerCAmelCase__ ): SCREAMING_SNAKE_CASE = {'class_name': models[0].__class__.__name__} with open(os.path.join(_snake_case , 'data.json' ) , 'w' ) as f: json.dump(_snake_case , _snake_case ) # loading hook def load_config(lowerCAmelCase__ , lowerCAmelCase__ ): with open(os.path.join(_snake_case , 'data.json' ) , 'r' ) as f: SCREAMING_SNAKE_CASE = json.load(_snake_case ) SCREAMING_SNAKE_CASE = config['class_name'] SCREAMING_SNAKE_CASE = accelerator.register_save_state_pre_hook(_snake_case ) SCREAMING_SNAKE_CASE = accelerator.register_load_state_pre_hook(_snake_case ) with tempfile.TemporaryDirectory() as tmpdirname: accelerator.save_state(_snake_case ) # make sure random weights don't match with hooks load_random_weights(_snake_case ) self.assertTrue(abs(model_signature - get_signature(_snake_case ) ) > 1e-3 ) # random class name to verify correct one is loaded SCREAMING_SNAKE_CASE = 'random' # make sure loaded weights match with hooks accelerator.load_state(_snake_case ) self.assertTrue(abs(model_signature - get_signature(_snake_case ) ) < 1e-3 ) # mode.class_name is loaded from config self.assertTrue(model.class_name == model.__class__.__name__ ) # remove hooks save_hook.remove() load_hook.remove() with tempfile.TemporaryDirectory() as tmpdirname: accelerator.save_state(_snake_case ) # make sure random weights don't match with hooks removed load_random_weights(_snake_case ) self.assertTrue(abs(model_signature - get_signature(_snake_case ) ) > 1e-3 ) # random class name to verify correct one is loaded SCREAMING_SNAKE_CASE = 'random' # make sure loaded weights match with hooks removed accelerator.load_state(_snake_case ) self.assertTrue(abs(model_signature - get_signature(_snake_case ) ) < 1e-3 ) # mode.class_name is NOT loaded from config self.assertTrue(model.class_name != model.__class__.__name__ ) def __A ( self ) -> Any: SCREAMING_SNAKE_CASE = Accelerator() SCREAMING_SNAKE_CASE = create_components() SCREAMING_SNAKE_CASE = None # This should work SCREAMING_SNAKE_CASE = accelerator.prepare( _snake_case , _snake_case , _snake_case , _snake_case , _snake_case , _snake_case ) self.assertTrue(dummy_obj is None ) def __A ( self ) -> Optional[int]: SCREAMING_SNAKE_CASE = Accelerator() SCREAMING_SNAKE_CASE = create_components() SCREAMING_SNAKE_CASE = [1, 2, 3] # This should work SCREAMING_SNAKE_CASE = accelerator.prepare( _snake_case , _snake_case , _snake_case , _snake_case , _snake_case , _snake_case ) self.assertEqual( getattr(_snake_case , '_is_accelerate_prepared' , _snake_case ) , _snake_case , 'Dummy object should have `_is_accelerate_prepared` set to `True`' , ) self.assertEqual( getattr(_snake_case , '_is_accelerate_prepared' , _snake_case ) , _snake_case , 'Model is missing `_is_accelerator_prepared` or is set to `False`' , ) self.assertEqual( getattr(_snake_case , '_is_accelerate_prepared' , _snake_case ) , _snake_case , 'Optimizer is missing `_is_accelerator_prepared` or is set to `False`' , ) self.assertEqual( getattr(_snake_case , '_is_accelerate_prepared' , _snake_case ) , _snake_case , 'Scheduler is missing `_is_accelerator_prepared` or is set to `False`' , ) self.assertEqual( getattr(_snake_case , '_is_accelerate_prepared' , _snake_case ) , _snake_case , 'Train Dataloader is missing `_is_accelerator_prepared` or is set to `False`' , ) self.assertEqual( getattr(_snake_case , '_is_accelerate_prepared' , _snake_case ) , _snake_case , 'Valid Dataloader is missing `_is_accelerator_prepared` or is set to `False`' , ) @slow @require_bnb def __A ( self ) -> Any: from transformers import AutoModelForCausalLM SCREAMING_SNAKE_CASE = AutoModelForCausalLM.from_pretrained( 'EleutherAI/gpt-neo-125m' , load_in_abit=_snake_case , device_map={'': 0} , ) SCREAMING_SNAKE_CASE = Accelerator() # This should work SCREAMING_SNAKE_CASE = accelerator.prepare(_snake_case ) @slow @require_bnb def __A ( self ) -> str: from transformers import AutoModelForCausalLM SCREAMING_SNAKE_CASE = Accelerator() with init_empty_weights(): SCREAMING_SNAKE_CASE = AutoModelForCausalLM.from_pretrained( 'EleutherAI/gpt-neo-125m' , ) model.tie_weights() SCREAMING_SNAKE_CASE = infer_auto_device_map(_snake_case ) SCREAMING_SNAKE_CASE = 'cpu' SCREAMING_SNAKE_CASE = AutoModelForCausalLM.from_pretrained( 'EleutherAI/gpt-neo-125m' , device_map=_snake_case , load_in_abit=_snake_case , llm_inta_enable_fpaa_cpu_offload=_snake_case ) # This should not work and get value error with self.assertRaises(_snake_case ): SCREAMING_SNAKE_CASE = accelerator.prepare(_snake_case ) @slow @require_bnb @require_multi_gpu def __A ( self ) -> Optional[Any]: from transformers import AutoModelForCausalLM SCREAMING_SNAKE_CASE = {'distributed_type': DistributedType.MULTI_GPU} with init_empty_weights(): SCREAMING_SNAKE_CASE = AutoModelForCausalLM.from_pretrained( 'EleutherAI/gpt-neo-125m' , ) model.tie_weights() SCREAMING_SNAKE_CASE = infer_auto_device_map(_snake_case ) SCREAMING_SNAKE_CASE = 1 SCREAMING_SNAKE_CASE = AutoModelForCausalLM.from_pretrained( 'EleutherAI/gpt-neo-125m' , load_in_abit=_snake_case , device_map=_snake_case , ) SCREAMING_SNAKE_CASE = Accelerator() # This should not work and get value error with self.assertRaises(_snake_case ): SCREAMING_SNAKE_CASE = accelerator.prepare(_snake_case ) PartialState._reset_state() @slow @require_bnb @require_multi_gpu def __A ( self ) -> Tuple: from transformers import AutoModelForCausalLM with init_empty_weights(): SCREAMING_SNAKE_CASE = AutoModelForCausalLM.from_pretrained( 'EleutherAI/gpt-neo-125m' , ) SCREAMING_SNAKE_CASE = infer_auto_device_map(_snake_case ) SCREAMING_SNAKE_CASE = 1 SCREAMING_SNAKE_CASE = AutoModelForCausalLM.from_pretrained( 'EleutherAI/gpt-neo-125m' , load_in_abit=_snake_case , device_map=_snake_case , ) SCREAMING_SNAKE_CASE = Accelerator() # This should work SCREAMING_SNAKE_CASE = accelerator.prepare(_snake_case ) @require_cuda def __A ( self ) -> List[Any]: SCREAMING_SNAKE_CASE = torch.nn.Linear(10 , 10 ) SCREAMING_SNAKE_CASE = torch.optim.SGD(model.parameters() , lr=0.01 ) SCREAMING_SNAKE_CASE = Accelerator(cpu=_snake_case ) SCREAMING_SNAKE_CASE = accelerator.prepare(_snake_case )
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from collections import UserDict from typing import Union import numpy as np import requests from ..utils import ( add_end_docstrings, logging, ) from .audio_classification import ffmpeg_read from .base import PIPELINE_INIT_ARGS, Pipeline a_ :List[Any] = logging.get_logger(__name__) @add_end_docstrings(lowerCAmelCase_ ) class snake_case__ ( lowerCAmelCase_ ): """simple docstring""" def __init__( self : Optional[Any], **_snake_case : str ) ->Dict: super().__init__(**_snake_case ) if self.framework != "pt": raise ValueError(F'''The {self.__class__} is only available in PyTorch.''' ) # No specific FOR_XXX available yet def __call__( self : Union[str, Any], _snake_case : Union[np.ndarray, bytes, str], **_snake_case : Tuple ) ->Dict: return super().__call__(_snake_case, **_snake_case ) def lowercase_ ( self : Tuple, **_snake_case : Any ) ->Union[str, Any]: snake_case__ : str = {} if "candidate_labels" in kwargs: snake_case__ : str = kwargs['candidate_labels'] if "hypothesis_template" in kwargs: snake_case__ : str = kwargs['hypothesis_template'] return preprocess_params, {}, {} def lowercase_ ( self : Dict, _snake_case : str, _snake_case : Optional[int]=None, _snake_case : List[str]="This is a sound of {}." ) ->int: if isinstance(_snake_case, _snake_case ): if audio.startswith('http://' ) or audio.startswith('https://' ): # We need to actually check for a real protocol, otherwise it's impossible to use a local file # like http_huggingface_co.png snake_case__ : List[Any] = requests.get(_snake_case ).content else: with open(_snake_case, 'rb' ) as f: snake_case__ : Union[str, Any] = f.read() if isinstance(_snake_case, _snake_case ): snake_case__ : List[Any] = ffmpeg_read(_snake_case, self.feature_extractor.sampling_rate ) if not isinstance(_snake_case, np.ndarray ): raise ValueError('We expect a numpy ndarray as input' ) if len(audio.shape ) != 1: raise ValueError('We expect a single channel audio input for ZeroShotAudioClassificationPipeline' ) snake_case__ : Tuple = self.feature_extractor( [audio], sampling_rate=self.feature_extractor.sampling_rate, return_tensors='pt' ) snake_case__ : int = candidate_labels snake_case__ : int = [hypothesis_template.format(_snake_case ) for x in candidate_labels] snake_case__ : Optional[int] = self.tokenizer(_snake_case, return_tensors=self.framework, padding=_snake_case ) snake_case__ : List[Any] = [text_inputs] return inputs def lowercase_ ( self : Optional[int], _snake_case : Optional[Any] ) ->int: snake_case__ : Optional[int] = model_inputs.pop('candidate_labels' ) snake_case__ : str = model_inputs.pop('text_inputs' ) if isinstance(text_inputs[0], _snake_case ): snake_case__ : Optional[Any] = text_inputs[0] else: # Batching case. snake_case__ : int = text_inputs[0][0] snake_case__ : Any = self.model(**_snake_case, **_snake_case ) snake_case__ : List[Any] = { 'candidate_labels': candidate_labels, 'logits': outputs.logits_per_audio, } return model_outputs def lowercase_ ( self : Union[str, Any], _snake_case : str ) ->List[str]: snake_case__ : int = model_outputs.pop('candidate_labels' ) snake_case__ : List[Any] = model_outputs['logits'][0] if self.framework == "pt": snake_case__ : Tuple = logits.softmax(dim=0 ) snake_case__ : Union[str, Any] = probs.tolist() else: raise ValueError('`tf` framework not supported.' ) snake_case__ : Union[str, Any] = [ {'score': score, 'label': candidate_label} for score, candidate_label in sorted(zip(_snake_case, _snake_case ), key=lambda _snake_case : -x[0] ) ] return result
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'''simple docstring''' import unittest from transformers import MODEL_FOR_ZERO_SHOT_OBJECT_DETECTION_MAPPING, is_vision_available, pipeline from transformers.testing_utils import ( is_pipeline_test, nested_simplify, require_tf, require_torch, require_vision, slow, ) from .test_pipelines_common import ANY if is_vision_available(): from PIL import Image else: class _lowercase : '''simple docstring''' @staticmethod def a ( *SCREAMING_SNAKE_CASE__ : Optional[Any] , **SCREAMING_SNAKE_CASE__ : int ) -> Optional[int]: pass @is_pipeline_test @require_vision @require_torch class _lowercase ( unittest.TestCase ): '''simple docstring''' _SCREAMING_SNAKE_CASE : Dict = MODEL_FOR_ZERO_SHOT_OBJECT_DETECTION_MAPPING def a ( self : Optional[int] , SCREAMING_SNAKE_CASE__ : Dict , SCREAMING_SNAKE_CASE__ : Dict , SCREAMING_SNAKE_CASE__ : Any ) -> Dict: __lowerCAmelCase = pipeline( """zero-shot-object-detection""" , model="""hf-internal-testing/tiny-random-owlvit-object-detection""" ) __lowerCAmelCase = [ { 'image': './tests/fixtures/tests_samples/COCO/000000039769.png', 'candidate_labels': ['cat', 'remote', 'couch'], } ] return object_detector, examples def a ( self : Union[str, Any] , SCREAMING_SNAKE_CASE__ : Optional[int] , SCREAMING_SNAKE_CASE__ : Optional[int] ) -> Any: __lowerCAmelCase = object_detector(examples[0] , threshold=0.0 ) __lowerCAmelCase = len(_snake_case ) self.assertGreater(_snake_case , 0 ) self.assertEqual( _snake_case , [ { """score""": ANY(_snake_case ), """label""": ANY(_snake_case ), """box""": {"""xmin""": ANY(_snake_case ), """ymin""": ANY(_snake_case ), """xmax""": ANY(_snake_case ), """ymax""": ANY(_snake_case )}, } for i in range(_snake_case ) ] , ) @require_tf @unittest.skip("""Zero Shot Object Detection not implemented in TF""" ) def a ( self : int ) -> Optional[int]: pass @require_torch def a ( self : Any ) -> Tuple: __lowerCAmelCase = pipeline( """zero-shot-object-detection""" , model="""hf-internal-testing/tiny-random-owlvit-object-detection""" ) __lowerCAmelCase = object_detector( """./tests/fixtures/tests_samples/COCO/000000039769.png""" , candidate_labels=["""cat""", """remote""", """couch"""] , threshold=0.6_4 , ) self.assertEqual( nested_simplify(_snake_case , decimals=4 ) , [ {"""score""": 0.7_2_3_5, """label""": """cat""", """box""": {"""xmin""": 2_04, """ymin""": 1_67, """xmax""": 2_32, """ymax""": 1_90}}, {"""score""": 0.7_2_1_8, """label""": """remote""", """box""": {"""xmin""": 2_04, """ymin""": 1_67, """xmax""": 2_32, """ymax""": 1_90}}, {"""score""": 0.7_1_8_4, """label""": """couch""", """box""": {"""xmin""": 2_04, """ymin""": 1_67, """xmax""": 2_32, """ymax""": 1_90}}, {"""score""": 0.6_7_4_8, """label""": """remote""", """box""": {"""xmin""": 5_71, """ymin""": 83, """xmax""": 5_98, """ymax""": 1_03}}, {"""score""": 0.6_6_5_6, """label""": """cat""", """box""": {"""xmin""": 5_71, """ymin""": 83, """xmax""": 5_98, """ymax""": 1_03}}, {"""score""": 0.6_6_1_4, """label""": """couch""", """box""": {"""xmin""": 5_71, """ymin""": 83, """xmax""": 5_98, """ymax""": 1_03}}, {"""score""": 0.6_4_5_6, """label""": """remote""", """box""": {"""xmin""": 4_94, """ymin""": 1_05, """xmax""": 5_21, """ymax""": 1_27}}, {"""score""": 0.6_4_2, """label""": """remote""", """box""": {"""xmin""": 67, """ymin""": 2_74, """xmax""": 93, """ymax""": 2_97}}, {"""score""": 0.6_4_1_9, """label""": """cat""", """box""": {"""xmin""": 4_94, """ymin""": 1_05, """xmax""": 5_21, """ymax""": 1_27}}, ] , ) __lowerCAmelCase = object_detector( [ { """image""": """./tests/fixtures/tests_samples/COCO/000000039769.png""", """candidate_labels""": ["""cat""", """remote""", """couch"""], } ] , threshold=0.6_4 , ) self.assertEqual( nested_simplify(_snake_case , decimals=4 ) , [ [ {"""score""": 0.7_2_3_5, """label""": """cat""", """box""": {"""xmin""": 2_04, """ymin""": 1_67, """xmax""": 2_32, """ymax""": 1_90}}, {"""score""": 0.7_2_1_8, """label""": """remote""", """box""": {"""xmin""": 2_04, """ymin""": 1_67, """xmax""": 2_32, """ymax""": 1_90}}, {"""score""": 0.7_1_8_4, """label""": """couch""", """box""": {"""xmin""": 2_04, """ymin""": 1_67, """xmax""": 2_32, """ymax""": 1_90}}, {"""score""": 0.6_7_4_8, """label""": """remote""", """box""": {"""xmin""": 5_71, """ymin""": 83, """xmax""": 5_98, """ymax""": 1_03}}, {"""score""": 0.6_6_5_6, """label""": """cat""", """box""": {"""xmin""": 5_71, """ymin""": 83, """xmax""": 5_98, """ymax""": 1_03}}, {"""score""": 0.6_6_1_4, """label""": """couch""", """box""": {"""xmin""": 5_71, """ymin""": 83, """xmax""": 5_98, """ymax""": 1_03}}, {"""score""": 0.6_4_5_6, """label""": """remote""", """box""": {"""xmin""": 4_94, """ymin""": 1_05, """xmax""": 5_21, """ymax""": 1_27}}, {"""score""": 0.6_4_2, """label""": """remote""", """box""": {"""xmin""": 67, """ymin""": 2_74, """xmax""": 93, """ymax""": 2_97}}, {"""score""": 0.6_4_1_9, """label""": """cat""", """box""": {"""xmin""": 4_94, """ymin""": 1_05, """xmax""": 5_21, """ymax""": 1_27}}, ] ] , ) @require_torch @slow def a ( self : List[Any] ) -> Dict: __lowerCAmelCase = pipeline("""zero-shot-object-detection""" ) __lowerCAmelCase = object_detector( """http://images.cocodataset.org/val2017/000000039769.jpg""" , candidate_labels=["""cat""", """remote""", """couch"""] , ) self.assertEqual( nested_simplify(_snake_case , decimals=4 ) , [ {"""score""": 0.2_8_6_8, """label""": """cat""", """box""": {"""xmin""": 3_24, """ymin""": 20, """xmax""": 6_40, """ymax""": 3_73}}, {"""score""": 0.2_7_7, """label""": """remote""", """box""": {"""xmin""": 40, """ymin""": 72, """xmax""": 1_77, """ymax""": 1_15}}, {"""score""": 0.2_5_3_7, """label""": """cat""", """box""": {"""xmin""": 1, """ymin""": 55, """xmax""": 3_15, """ymax""": 4_72}}, {"""score""": 0.1_4_7_4, """label""": """remote""", """box""": {"""xmin""": 3_35, """ymin""": 74, """xmax""": 3_71, """ymax""": 1_87}}, {"""score""": 0.1_2_0_8, """label""": """couch""", """box""": {"""xmin""": 4, """ymin""": 0, """xmax""": 6_42, """ymax""": 4_76}}, ] , ) __lowerCAmelCase = object_detector( [ { """image""": """http://images.cocodataset.org/val2017/000000039769.jpg""", """candidate_labels""": ["""cat""", """remote""", """couch"""], }, { """image""": """http://images.cocodataset.org/val2017/000000039769.jpg""", """candidate_labels""": ["""cat""", """remote""", """couch"""], }, ] , ) self.assertEqual( nested_simplify(_snake_case , decimals=4 ) , [ [ {"""score""": 0.2_8_6_8, """label""": """cat""", """box""": {"""xmin""": 3_24, """ymin""": 20, """xmax""": 6_40, """ymax""": 3_73}}, {"""score""": 0.2_7_7, """label""": """remote""", """box""": {"""xmin""": 40, """ymin""": 72, """xmax""": 1_77, """ymax""": 1_15}}, {"""score""": 0.2_5_3_7, """label""": """cat""", """box""": {"""xmin""": 1, """ymin""": 55, """xmax""": 3_15, """ymax""": 4_72}}, {"""score""": 0.1_4_7_4, """label""": """remote""", """box""": {"""xmin""": 3_35, """ymin""": 74, """xmax""": 3_71, """ymax""": 1_87}}, {"""score""": 0.1_2_0_8, """label""": """couch""", """box""": {"""xmin""": 4, """ymin""": 0, """xmax""": 6_42, """ymax""": 4_76}}, ], [ {"""score""": 0.2_8_6_8, """label""": """cat""", """box""": {"""xmin""": 3_24, """ymin""": 20, """xmax""": 6_40, """ymax""": 3_73}}, {"""score""": 0.2_7_7, """label""": """remote""", """box""": {"""xmin""": 40, """ymin""": 72, """xmax""": 1_77, """ymax""": 1_15}}, {"""score""": 0.2_5_3_7, """label""": """cat""", """box""": {"""xmin""": 1, """ymin""": 55, """xmax""": 3_15, """ymax""": 4_72}}, {"""score""": 0.1_4_7_4, """label""": """remote""", """box""": {"""xmin""": 3_35, """ymin""": 74, """xmax""": 3_71, """ymax""": 1_87}}, {"""score""": 0.1_2_0_8, """label""": """couch""", """box""": {"""xmin""": 4, """ymin""": 0, """xmax""": 6_42, """ymax""": 4_76}}, ], ] , ) @require_tf @unittest.skip("""Zero Shot Object Detection not implemented in TF""" ) def a ( self : List[str] ) -> Any: pass @require_torch @slow def a ( self : Optional[int] ) -> Tuple: __lowerCAmelCase = 0.2 __lowerCAmelCase = pipeline("""zero-shot-object-detection""" ) __lowerCAmelCase = object_detector( """http://images.cocodataset.org/val2017/000000039769.jpg""" , candidate_labels=["""cat""", """remote""", """couch"""] , threshold=_snake_case , ) self.assertEqual( nested_simplify(_snake_case , decimals=4 ) , [ {"""score""": 0.2_8_6_8, """label""": """cat""", """box""": {"""xmin""": 3_24, """ymin""": 20, """xmax""": 6_40, """ymax""": 3_73}}, {"""score""": 0.2_7_7, """label""": """remote""", """box""": {"""xmin""": 40, """ymin""": 72, """xmax""": 1_77, """ymax""": 1_15}}, {"""score""": 0.2_5_3_7, """label""": """cat""", """box""": {"""xmin""": 1, """ymin""": 55, """xmax""": 3_15, """ymax""": 4_72}}, ] , ) @require_torch @slow def a ( self : List[Any] ) -> str: __lowerCAmelCase = 2 __lowerCAmelCase = pipeline("""zero-shot-object-detection""" ) __lowerCAmelCase = object_detector( """http://images.cocodataset.org/val2017/000000039769.jpg""" , candidate_labels=["""cat""", """remote""", """couch"""] , top_k=_snake_case , ) self.assertEqual( nested_simplify(_snake_case , decimals=4 ) , [ {"""score""": 0.2_8_6_8, """label""": """cat""", """box""": {"""xmin""": 3_24, """ymin""": 20, """xmax""": 6_40, """ymax""": 3_73}}, {"""score""": 0.2_7_7, """label""": """remote""", """box""": {"""xmin""": 40, """ymin""": 72, """xmax""": 1_77, """ymax""": 1_15}}, ] , )
229
import collections import inspect import unittest from transformers import SwinvaConfig from transformers.testing_utils import require_torch, require_vision, slow, torch_device from transformers.utils import cached_property, is_torch_available, is_vision_available from ...test_configuration_common import ConfigTester from ...test_modeling_common import ModelTesterMixin, _config_zero_init, floats_tensor, ids_tensor from ...test_pipeline_mixin import PipelineTesterMixin if is_torch_available(): import torch from torch import nn from transformers import SwinvaForImageClassification, SwinvaForMaskedImageModeling, SwinvaModel from transformers.models.swinva.modeling_swinva import SWINV2_PRETRAINED_MODEL_ARCHIVE_LIST if is_vision_available(): from PIL import Image from transformers import AutoImageProcessor class snake_case__ : """simple docstring""" def __init__( self : Tuple, _snake_case : Any, _snake_case : int=1_3, _snake_case : Optional[int]=3_2, _snake_case : Tuple=2, _snake_case : Any=3, _snake_case : Tuple=1_6, _snake_case : Tuple=[1, 2, 1], _snake_case : Dict=[2, 2, 4], _snake_case : str=2, _snake_case : Union[str, Any]=2.0, _snake_case : Dict=True, _snake_case : Dict=0.0, _snake_case : str=0.0, _snake_case : str=0.1, _snake_case : List[str]="gelu", _snake_case : int=False, _snake_case : Optional[Any]=True, _snake_case : List[Any]=0.0_2, _snake_case : Union[str, Any]=1e-5, _snake_case : Union[str, Any]=True, _snake_case : List[Any]=None, _snake_case : Any=True, _snake_case : List[Any]=1_0, _snake_case : str=8, ) ->Union[str, Any]: snake_case__ : Any = parent snake_case__ : Tuple = batch_size snake_case__ : Tuple = image_size snake_case__ : Any = patch_size snake_case__ : Optional[int] = num_channels snake_case__ : Tuple = embed_dim snake_case__ : Any = depths snake_case__ : Any = num_heads snake_case__ : List[str] = window_size snake_case__ : Dict = mlp_ratio snake_case__ : Optional[int] = qkv_bias snake_case__ : Optional[Any] = hidden_dropout_prob snake_case__ : List[str] = attention_probs_dropout_prob snake_case__ : Union[str, Any] = drop_path_rate snake_case__ : str = hidden_act snake_case__ : Union[str, Any] = use_absolute_embeddings snake_case__ : Union[str, Any] = patch_norm snake_case__ : Any = layer_norm_eps snake_case__ : Tuple = initializer_range snake_case__ : Dict = is_training snake_case__ : Any = scope snake_case__ : Optional[Any] = use_labels snake_case__ : str = type_sequence_label_size snake_case__ : List[Any] = encoder_stride def lowercase_ ( self : Tuple ) ->str: snake_case__ : Tuple = floats_tensor([self.batch_size, self.num_channels, self.image_size, self.image_size] ) snake_case__ : List[Any] = None if self.use_labels: snake_case__ : Optional[Any] = ids_tensor([self.batch_size], self.type_sequence_label_size ) snake_case__ : Any = self.get_config() return config, pixel_values, labels def lowercase_ ( self : Optional[int] ) ->Optional[int]: return SwinvaConfig( image_size=self.image_size, patch_size=self.patch_size, num_channels=self.num_channels, embed_dim=self.embed_dim, depths=self.depths, num_heads=self.num_heads, window_size=self.window_size, mlp_ratio=self.mlp_ratio, qkv_bias=self.qkv_bias, hidden_dropout_prob=self.hidden_dropout_prob, attention_probs_dropout_prob=self.attention_probs_dropout_prob, drop_path_rate=self.drop_path_rate, hidden_act=self.hidden_act, use_absolute_embeddings=self.use_absolute_embeddings, path_norm=self.patch_norm, layer_norm_eps=self.layer_norm_eps, initializer_range=self.initializer_range, encoder_stride=self.encoder_stride, ) def lowercase_ ( self : Optional[int], _snake_case : str, _snake_case : List[str], _snake_case : int ) ->Dict: snake_case__ : List[Any] = SwinvaModel(config=_snake_case ) model.to(_snake_case ) model.eval() snake_case__ : Optional[int] = model(_snake_case ) snake_case__ : List[Any] = ((config.image_size // config.patch_size) ** 2) // (4 ** (len(config.depths ) - 1)) snake_case__ : List[Any] = int(config.embed_dim * 2 ** (len(config.depths ) - 1) ) self.parent.assertEqual(result.last_hidden_state.shape, (self.batch_size, expected_seq_len, expected_dim) ) def lowercase_ ( self : Optional[Any], _snake_case : Any, _snake_case : List[str], _snake_case : Dict ) ->List[Any]: snake_case__ : List[str] = SwinvaForMaskedImageModeling(config=_snake_case ) model.to(_snake_case ) model.eval() snake_case__ : Union[str, Any] = model(_snake_case ) self.parent.assertEqual( result.logits.shape, (self.batch_size, self.num_channels, self.image_size, self.image_size) ) # test greyscale images snake_case__ : Optional[Any] = 1 snake_case__ : Optional[int] = SwinvaForMaskedImageModeling(_snake_case ) model.to(_snake_case ) model.eval() snake_case__ : Tuple = floats_tensor([self.batch_size, 1, self.image_size, self.image_size] ) snake_case__ : Any = model(_snake_case ) self.parent.assertEqual(result.logits.shape, (self.batch_size, 1, self.image_size, self.image_size) ) def lowercase_ ( self : List[str], _snake_case : int, _snake_case : List[Any], _snake_case : Optional[int] ) ->Any: snake_case__ : Tuple = self.type_sequence_label_size snake_case__ : int = SwinvaForImageClassification(_snake_case ) model.to(_snake_case ) model.eval() snake_case__ : Tuple = model(_snake_case, labels=_snake_case ) self.parent.assertEqual(result.logits.shape, (self.batch_size, self.type_sequence_label_size) ) def lowercase_ ( self : Any ) ->Dict: snake_case__ : str = self.prepare_config_and_inputs() snake_case__ , snake_case__ , snake_case__ : List[str] = config_and_inputs snake_case__ : Union[str, Any] = {'pixel_values': pixel_values} return config, inputs_dict @require_torch class snake_case__ ( lowerCAmelCase_ , lowerCAmelCase_ , unittest.TestCase ): """simple docstring""" _SCREAMING_SNAKE_CASE = ( (SwinvaModel, SwinvaForImageClassification, SwinvaForMaskedImageModeling) if is_torch_available() else () ) _SCREAMING_SNAKE_CASE = ( {"""feature-extraction""": SwinvaModel, """image-classification""": SwinvaForImageClassification} if is_torch_available() else {} ) _SCREAMING_SNAKE_CASE = False _SCREAMING_SNAKE_CASE = False _SCREAMING_SNAKE_CASE = False _SCREAMING_SNAKE_CASE = False def lowercase_ ( self : Union[str, Any] ) ->Dict: snake_case__ : Optional[int] = SwinvaModelTester(self ) snake_case__ : int = ConfigTester(self, config_class=_snake_case, embed_dim=3_7 ) def lowercase_ ( self : Tuple ) ->int: self.config_tester.create_and_test_config_to_json_string() self.config_tester.create_and_test_config_to_json_file() self.config_tester.create_and_test_config_from_and_save_pretrained() self.config_tester.create_and_test_config_with_num_labels() self.config_tester.check_config_can_be_init_without_params() self.config_tester.check_config_arguments_init() def lowercase_ ( self : Any ) ->str: snake_case__ : int = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_model(*_snake_case ) @unittest.skip(reason='Got `CUDA error: misaligned address` with PyTorch 2.0.0.' ) def lowercase_ ( self : Any ) ->Union[str, Any]: pass @unittest.skip(reason='Swinv2 does not use inputs_embeds' ) def lowercase_ ( self : str ) ->Union[str, Any]: pass def lowercase_ ( self : Optional[Any] ) ->Union[str, Any]: snake_case__ , snake_case__ : Optional[int] = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: snake_case__ : Union[str, Any] = model_class(_snake_case ) self.assertIsInstance(model.get_input_embeddings(), (nn.Module) ) snake_case__ : Union[str, Any] = model.get_output_embeddings() self.assertTrue(x is None or isinstance(_snake_case, nn.Linear ) ) def lowercase_ ( self : List[str] ) ->Optional[int]: snake_case__ , snake_case__ : Any = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: snake_case__ : Any = model_class(_snake_case ) snake_case__ : Dict = inspect.signature(model.forward ) # signature.parameters is an OrderedDict => so arg_names order is deterministic snake_case__ : Optional[Any] = [*signature.parameters.keys()] snake_case__ : List[Any] = ['pixel_values'] self.assertListEqual(arg_names[:1], _snake_case ) def lowercase_ ( self : str ) ->Union[str, Any]: snake_case__ , snake_case__ : Any = self.model_tester.prepare_config_and_inputs_for_common() snake_case__ : int = True for model_class in self.all_model_classes: snake_case__ : str = True snake_case__ : Union[str, Any] = False snake_case__ : Tuple = True snake_case__ : int = model_class(_snake_case ) model.to(_snake_case ) model.eval() with torch.no_grad(): snake_case__ : Optional[int] = model(**self._prepare_for_class(_snake_case, _snake_case ) ) snake_case__ : List[str] = outputs.attentions snake_case__ : List[Any] = len(self.model_tester.depths ) self.assertEqual(len(_snake_case ), _snake_case ) # check that output_attentions also work using config del inputs_dict["output_attentions"] snake_case__ : str = True snake_case__ : Tuple = config.window_size**2 snake_case__ : Optional[int] = model_class(_snake_case ) model.to(_snake_case ) model.eval() with torch.no_grad(): snake_case__ : str = model(**self._prepare_for_class(_snake_case, _snake_case ) ) snake_case__ : Tuple = outputs.attentions self.assertEqual(len(_snake_case ), _snake_case ) self.assertListEqual( list(attentions[0].shape[-3:] ), [self.model_tester.num_heads[0], window_size_squared, window_size_squared], ) snake_case__ : Optional[Any] = len(_snake_case ) # Check attention is always last and order is fine snake_case__ : Optional[int] = True snake_case__ : Dict = True snake_case__ : List[Any] = model_class(_snake_case ) model.to(_snake_case ) model.eval() with torch.no_grad(): snake_case__ : Optional[int] = model(**self._prepare_for_class(_snake_case, _snake_case ) ) if hasattr(self.model_tester, 'num_hidden_states_types' ): snake_case__ : str = self.model_tester.num_hidden_states_types else: # also another +1 for reshaped_hidden_states snake_case__ : Dict = 2 self.assertEqual(out_len + added_hidden_states, len(_snake_case ) ) snake_case__ : Any = outputs.attentions self.assertEqual(len(_snake_case ), _snake_case ) self.assertListEqual( list(self_attentions[0].shape[-3:] ), [self.model_tester.num_heads[0], window_size_squared, window_size_squared], ) def lowercase_ ( self : Dict, _snake_case : Tuple, _snake_case : Any, _snake_case : int, _snake_case : Optional[int] ) ->str: snake_case__ : Dict = model_class(_snake_case ) model.to(_snake_case ) model.eval() with torch.no_grad(): snake_case__ : List[Any] = model(**self._prepare_for_class(_snake_case, _snake_case ) ) snake_case__ : Dict = outputs.hidden_states snake_case__ : int = getattr( self.model_tester, 'expected_num_hidden_layers', len(self.model_tester.depths ) + 1 ) self.assertEqual(len(_snake_case ), _snake_case ) # Swinv2 has a different seq_length snake_case__ : int = ( config.patch_size if isinstance(config.patch_size, collections.abc.Iterable ) else (config.patch_size, config.patch_size) ) snake_case__ : Optional[Any] = (image_size[1] // patch_size[1]) * (image_size[0] // patch_size[0]) self.assertListEqual( list(hidden_states[0].shape[-2:] ), [num_patches, self.model_tester.embed_dim], ) snake_case__ : Union[str, Any] = outputs.reshaped_hidden_states self.assertEqual(len(_snake_case ), _snake_case ) snake_case__ , snake_case__ , snake_case__ , snake_case__ : str = reshaped_hidden_states[0].shape snake_case__ : Any = ( reshaped_hidden_states[0].view(_snake_case, _snake_case, height * width ).permute(0, 2, 1 ) ) self.assertListEqual( list(reshaped_hidden_states.shape[-2:] ), [num_patches, self.model_tester.embed_dim], ) def lowercase_ ( self : str ) ->List[Any]: snake_case__ , snake_case__ : Any = self.model_tester.prepare_config_and_inputs_for_common() snake_case__ : List[Any] = ( self.model_tester.image_size if isinstance(self.model_tester.image_size, collections.abc.Iterable ) else (self.model_tester.image_size, self.model_tester.image_size) ) for model_class in self.all_model_classes: snake_case__ : Optional[int] = True self.check_hidden_states_output(_snake_case, _snake_case, _snake_case, _snake_case ) # check that output_hidden_states also work using config del inputs_dict["output_hidden_states"] snake_case__ : Dict = True self.check_hidden_states_output(_snake_case, _snake_case, _snake_case, _snake_case ) def lowercase_ ( self : List[str] ) ->str: snake_case__ , snake_case__ : Optional[Any] = self.model_tester.prepare_config_and_inputs_for_common() snake_case__ : List[str] = 3 snake_case__ : Union[str, Any] = ( self.model_tester.image_size if isinstance(self.model_tester.image_size, collections.abc.Iterable ) else (self.model_tester.image_size, self.model_tester.image_size) ) snake_case__ : str = ( config.patch_size if isinstance(config.patch_size, collections.abc.Iterable ) else (config.patch_size, config.patch_size) ) snake_case__ : Tuple = image_size[0] + patch_size[0] - (image_size[0] % patch_size[0]) snake_case__ : Optional[Any] = image_size[1] + patch_size[1] - (image_size[1] % patch_size[1]) for model_class in self.all_model_classes: snake_case__ : int = True self.check_hidden_states_output(_snake_case, _snake_case, _snake_case, (padded_height, padded_width) ) # check that output_hidden_states also work using config del inputs_dict["output_hidden_states"] snake_case__ : List[str] = True self.check_hidden_states_output(_snake_case, _snake_case, _snake_case, (padded_height, padded_width) ) def lowercase_ ( self : List[str] ) ->Optional[int]: snake_case__ : Any = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_for_masked_image_modeling(*_snake_case ) def lowercase_ ( self : List[Any] ) ->str: snake_case__ : Any = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_for_image_classification(*_snake_case ) @slow def lowercase_ ( self : str ) ->Union[str, Any]: for model_name in SWINV2_PRETRAINED_MODEL_ARCHIVE_LIST[:1]: snake_case__ : Dict = SwinvaModel.from_pretrained(_snake_case ) self.assertIsNotNone(_snake_case ) def lowercase_ ( self : Optional[int] ) ->List[str]: snake_case__ , snake_case__ : Any = self.model_tester.prepare_config_and_inputs_for_common() snake_case__ : List[Any] = _config_zero_init(_snake_case ) for model_class in self.all_model_classes: snake_case__ : List[str] = model_class(config=_snake_case ) for name, param in model.named_parameters(): if "embeddings" not in name and "logit_scale" not in name and param.requires_grad: self.assertIn( ((param.data.mean() * 1e9).round() / 1e9).item(), [0.0, 1.0], msg=F'''Parameter {name} of model {model_class} seems not properly initialized''', ) @require_vision @require_torch class snake_case__ ( unittest.TestCase ): """simple docstring""" @cached_property def lowercase_ ( self : Union[str, Any] ) ->List[str]: return ( AutoImageProcessor.from_pretrained('microsoft/swinv2-tiny-patch4-window8-256' ) if is_vision_available() else None ) @slow def lowercase_ ( self : int ) ->List[Any]: snake_case__ : Any = SwinvaForImageClassification.from_pretrained('microsoft/swinv2-tiny-patch4-window8-256' ).to( _snake_case ) snake_case__ : int = self.default_image_processor snake_case__ : Union[str, Any] = Image.open('./tests/fixtures/tests_samples/COCO/000000039769.png' ) snake_case__ : Optional[Any] = image_processor(images=_snake_case, return_tensors='pt' ).to(_snake_case ) # forward pass with torch.no_grad(): snake_case__ : List[str] = model(**_snake_case ) # verify the logits snake_case__ : int = torch.Size((1, 1_0_0_0) ) self.assertEqual(outputs.logits.shape, _snake_case ) snake_case__ : Optional[int] = torch.tensor([-0.3_9_4_7, -0.4_3_0_6, 0.0_0_2_6] ).to(_snake_case ) self.assertTrue(torch.allclose(outputs.logits[0, :3], _snake_case, atol=1e-4 ) )
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"""simple docstring""" import argparse import json import pickle from pathlib import Path import requests import torch from huggingface_hub import hf_hub_download from PIL import Image from transformers import MaskFormerConfig, MaskFormerForInstanceSegmentation, MaskFormerImageProcessor, SwinConfig from transformers.utils import logging logging.set_verbosity_info() UpperCAmelCase = logging.get_logger(__name__) def lowercase ( a__ : str ) -> List[Any]: _UpperCamelCase = SwinConfig.from_pretrained( '''microsoft/swin-tiny-patch4-window7-224''' , out_features=['''stage1''', '''stage2''', '''stage3''', '''stage4'''] ) _UpperCamelCase = MaskFormerConfig(backbone_config=a__ ) _UpperCamelCase = 'huggingface/label-files' if "ade20k-full" in model_name: # this should be ok _UpperCamelCase = 847 _UpperCamelCase = 'maskformer-ade20k-full-id2label.json' elif "ade" in model_name: # this should be ok _UpperCamelCase = 150 _UpperCamelCase = 'ade20k-id2label.json' elif "coco-stuff" in model_name: # this should be ok _UpperCamelCase = 171 _UpperCamelCase = 'maskformer-coco-stuff-id2label.json' elif "coco" in model_name: # TODO _UpperCamelCase = 133 _UpperCamelCase = 'coco-panoptic-id2label.json' elif "cityscapes" in model_name: # this should be ok _UpperCamelCase = 19 _UpperCamelCase = 'cityscapes-id2label.json' elif "vistas" in model_name: # this should be ok _UpperCamelCase = 65 _UpperCamelCase = 'mapillary-vistas-id2label.json' _UpperCamelCase = json.load(open(hf_hub_download(a__ , a__ , repo_type='''dataset''' ) , '''r''' ) ) _UpperCamelCase = {int(a__ ): v for k, v in idalabel.items()} return config def lowercase ( a__ : Any ) -> List[Any]: _UpperCamelCase = [] # stem # fmt: off rename_keys.append(('''backbone.patch_embed.proj.weight''', '''model.pixel_level_module.encoder.model.embeddings.patch_embeddings.projection.weight''') ) rename_keys.append(('''backbone.patch_embed.proj.bias''', '''model.pixel_level_module.encoder.model.embeddings.patch_embeddings.projection.bias''') ) rename_keys.append(('''backbone.patch_embed.norm.weight''', '''model.pixel_level_module.encoder.model.embeddings.norm.weight''') ) rename_keys.append(('''backbone.patch_embed.norm.bias''', '''model.pixel_level_module.encoder.model.embeddings.norm.bias''') ) # stages for i in range(len(config.backbone_config.depths ) ): for j in range(config.backbone_config.depths[i] ): rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.norm1.weight''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.layernorm_before.weight''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.norm1.bias''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.layernorm_before.bias''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.attn.relative_position_bias_table''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.attention.self.relative_position_bias_table''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.attn.relative_position_index''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.attention.self.relative_position_index''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.attn.proj.weight''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.attention.output.dense.weight''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.attn.proj.bias''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.attention.output.dense.bias''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.norm2.weight''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.layernorm_after.weight''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.norm2.bias''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.layernorm_after.bias''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.mlp.fc1.weight''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.intermediate.dense.weight''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.mlp.fc1.bias''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.intermediate.dense.bias''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.mlp.fc2.weight''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.output.dense.weight''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.mlp.fc2.bias''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.output.dense.bias''') ) if i < 3: rename_keys.append((F'''backbone.layers.{i}.downsample.reduction.weight''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.downsample.reduction.weight''') ) rename_keys.append((F'''backbone.layers.{i}.downsample.norm.weight''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.downsample.norm.weight''') ) rename_keys.append((F'''backbone.layers.{i}.downsample.norm.bias''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.downsample.norm.bias''') ) rename_keys.append((F'''backbone.norm{i}.weight''', F'''model.pixel_level_module.encoder.hidden_states_norms.{i}.weight''') ) rename_keys.append((F'''backbone.norm{i}.bias''', F'''model.pixel_level_module.encoder.hidden_states_norms.{i}.bias''') ) # FPN rename_keys.append(('''sem_seg_head.layer_4.weight''', '''model.pixel_level_module.decoder.fpn.stem.0.weight''') ) rename_keys.append(('''sem_seg_head.layer_4.norm.weight''', '''model.pixel_level_module.decoder.fpn.stem.1.weight''') ) rename_keys.append(('''sem_seg_head.layer_4.norm.bias''', '''model.pixel_level_module.decoder.fpn.stem.1.bias''') ) for source_index, target_index in zip(range(3 , 0 , -1 ) , range(0 , 3 ) ): rename_keys.append((F'''sem_seg_head.adapter_{source_index}.weight''', F'''model.pixel_level_module.decoder.fpn.layers.{target_index}.proj.0.weight''') ) rename_keys.append((F'''sem_seg_head.adapter_{source_index}.norm.weight''', F'''model.pixel_level_module.decoder.fpn.layers.{target_index}.proj.1.weight''') ) rename_keys.append((F'''sem_seg_head.adapter_{source_index}.norm.bias''', F'''model.pixel_level_module.decoder.fpn.layers.{target_index}.proj.1.bias''') ) rename_keys.append((F'''sem_seg_head.layer_{source_index}.weight''', F'''model.pixel_level_module.decoder.fpn.layers.{target_index}.block.0.weight''') ) rename_keys.append((F'''sem_seg_head.layer_{source_index}.norm.weight''', F'''model.pixel_level_module.decoder.fpn.layers.{target_index}.block.1.weight''') ) rename_keys.append((F'''sem_seg_head.layer_{source_index}.norm.bias''', F'''model.pixel_level_module.decoder.fpn.layers.{target_index}.block.1.bias''') ) rename_keys.append(('''sem_seg_head.mask_features.weight''', '''model.pixel_level_module.decoder.mask_projection.weight''') ) rename_keys.append(('''sem_seg_head.mask_features.bias''', '''model.pixel_level_module.decoder.mask_projection.bias''') ) # Transformer decoder for idx in range(config.decoder_config.decoder_layers ): # self-attention out projection rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.self_attn.out_proj.weight''', F'''model.transformer_module.decoder.layers.{idx}.self_attn.out_proj.weight''') ) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.self_attn.out_proj.bias''', F'''model.transformer_module.decoder.layers.{idx}.self_attn.out_proj.bias''') ) # cross-attention out projection rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.multihead_attn.out_proj.weight''', F'''model.transformer_module.decoder.layers.{idx}.encoder_attn.out_proj.weight''') ) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.multihead_attn.out_proj.bias''', F'''model.transformer_module.decoder.layers.{idx}.encoder_attn.out_proj.bias''') ) # MLP 1 rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.linear1.weight''', F'''model.transformer_module.decoder.layers.{idx}.fc1.weight''') ) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.linear1.bias''', F'''model.transformer_module.decoder.layers.{idx}.fc1.bias''') ) # MLP 2 rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.linear2.weight''', F'''model.transformer_module.decoder.layers.{idx}.fc2.weight''') ) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.linear2.bias''', F'''model.transformer_module.decoder.layers.{idx}.fc2.bias''') ) # layernorm 1 (self-attention layernorm) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.norm1.weight''', F'''model.transformer_module.decoder.layers.{idx}.self_attn_layer_norm.weight''') ) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.norm1.bias''', F'''model.transformer_module.decoder.layers.{idx}.self_attn_layer_norm.bias''') ) # layernorm 2 (cross-attention layernorm) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.norm2.weight''', F'''model.transformer_module.decoder.layers.{idx}.encoder_attn_layer_norm.weight''') ) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.norm2.bias''', F'''model.transformer_module.decoder.layers.{idx}.encoder_attn_layer_norm.bias''') ) # layernorm 3 (final layernorm) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.norm3.weight''', F'''model.transformer_module.decoder.layers.{idx}.final_layer_norm.weight''') ) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.norm3.bias''', F'''model.transformer_module.decoder.layers.{idx}.final_layer_norm.bias''') ) rename_keys.append(('''sem_seg_head.predictor.transformer.decoder.norm.weight''', '''model.transformer_module.decoder.layernorm.weight''') ) rename_keys.append(('''sem_seg_head.predictor.transformer.decoder.norm.bias''', '''model.transformer_module.decoder.layernorm.bias''') ) # heads on top rename_keys.append(('''sem_seg_head.predictor.query_embed.weight''', '''model.transformer_module.queries_embedder.weight''') ) rename_keys.append(('''sem_seg_head.predictor.input_proj.weight''', '''model.transformer_module.input_projection.weight''') ) rename_keys.append(('''sem_seg_head.predictor.input_proj.bias''', '''model.transformer_module.input_projection.bias''') ) rename_keys.append(('''sem_seg_head.predictor.class_embed.weight''', '''class_predictor.weight''') ) rename_keys.append(('''sem_seg_head.predictor.class_embed.bias''', '''class_predictor.bias''') ) for i in range(3 ): rename_keys.append((F'''sem_seg_head.predictor.mask_embed.layers.{i}.weight''', F'''mask_embedder.{i}.0.weight''') ) rename_keys.append((F'''sem_seg_head.predictor.mask_embed.layers.{i}.bias''', F'''mask_embedder.{i}.0.bias''') ) # fmt: on return rename_keys def lowercase ( a__ : Tuple , a__ : Tuple , a__ : Optional[Any] ) -> Any: _UpperCamelCase = dct.pop(a__ ) _UpperCamelCase = val def lowercase ( a__ : Optional[Any] , a__ : Tuple ) -> Union[str, Any]: _UpperCamelCase = [int(backbone_config.embed_dim * 2**i ) for i in range(len(backbone_config.depths ) )] for i in range(len(backbone_config.depths ) ): _UpperCamelCase = num_features[i] for j in range(backbone_config.depths[i] ): # fmt: off # read in weights + bias of input projection layer (in original implementation, this is a single matrix + bias) _UpperCamelCase = state_dict.pop(F'''backbone.layers.{i}.blocks.{j}.attn.qkv.weight''' ) _UpperCamelCase = state_dict.pop(F'''backbone.layers.{i}.blocks.{j}.attn.qkv.bias''' ) # next, add query, keys and values (in that order) to the state dict _UpperCamelCase = in_proj_weight[:dim, :] _UpperCamelCase = in_proj_bias[: dim] _UpperCamelCase = in_proj_weight[ dim : dim * 2, : ] _UpperCamelCase = in_proj_bias[ dim : dim * 2 ] _UpperCamelCase = in_proj_weight[ -dim :, : ] _UpperCamelCase = in_proj_bias[-dim :] # fmt: on def lowercase ( a__ : List[str] , a__ : List[Any] ) -> Union[str, Any]: # fmt: off _UpperCamelCase = config.decoder_config.hidden_size for idx in range(config.decoder_config.decoder_layers ): # read in weights + bias of self-attention input projection layer (in the original implementation, this is a single matrix + bias) _UpperCamelCase = state_dict.pop(F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.self_attn.in_proj_weight''' ) _UpperCamelCase = state_dict.pop(F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.self_attn.in_proj_bias''' ) # next, add query, keys and values (in that order) to the state dict _UpperCamelCase = in_proj_weight[: hidden_size, :] _UpperCamelCase = in_proj_bias[:config.hidden_size] _UpperCamelCase = in_proj_weight[hidden_size : hidden_size * 2, :] _UpperCamelCase = in_proj_bias[hidden_size : hidden_size * 2] _UpperCamelCase = in_proj_weight[-hidden_size :, :] _UpperCamelCase = in_proj_bias[-hidden_size :] # read in weights + bias of cross-attention input projection layer (in the original implementation, this is a single matrix + bias) _UpperCamelCase = state_dict.pop(F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.multihead_attn.in_proj_weight''' ) _UpperCamelCase = state_dict.pop(F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.multihead_attn.in_proj_bias''' ) # next, add query, keys and values (in that order) to the state dict _UpperCamelCase = in_proj_weight[: hidden_size, :] _UpperCamelCase = in_proj_bias[:config.hidden_size] _UpperCamelCase = in_proj_weight[hidden_size : hidden_size * 2, :] _UpperCamelCase = in_proj_bias[hidden_size : hidden_size * 2] _UpperCamelCase = in_proj_weight[-hidden_size :, :] _UpperCamelCase = in_proj_bias[-hidden_size :] # fmt: on def lowercase ( ) -> Tuple: _UpperCamelCase = 'http://images.cocodataset.org/val2017/000000039769.jpg' _UpperCamelCase = Image.open(requests.get(a__ , stream=a__ ).raw ) return im @torch.no_grad() def lowercase ( a__ : str , a__ : str , a__ : str , a__ : bool = False ) -> List[Any]: _UpperCamelCase = get_maskformer_config(a__ ) # load original state_dict with open(a__ , '''rb''' ) as f: _UpperCamelCase = pickle.load(a__ ) _UpperCamelCase = data['model'] # for name, param in state_dict.items(): # print(name, param.shape) # rename keys _UpperCamelCase = create_rename_keys(a__ ) for src, dest in rename_keys: rename_key(a__ , a__ , a__ ) read_in_swin_q_k_v(a__ , config.backbone_config ) read_in_decoder_q_k_v(a__ , a__ ) # update to torch tensors for key, value in state_dict.items(): _UpperCamelCase = torch.from_numpy(a__ ) # load 🤗 model _UpperCamelCase = MaskFormerForInstanceSegmentation(a__ ) model.eval() for name, param in model.named_parameters(): print(a__ , param.shape ) _UpperCamelCase = model.load_state_dict(a__ , strict=a__ ) assert missing_keys == [ "model.pixel_level_module.encoder.model.layernorm.weight", "model.pixel_level_module.encoder.model.layernorm.bias", ] assert len(a__ ) == 0, F'''Unexpected keys: {unexpected_keys}''' # verify results _UpperCamelCase = prepare_img() if "vistas" in model_name: _UpperCamelCase = 65 elif "cityscapes" in model_name: _UpperCamelCase = 65535 else: _UpperCamelCase = 255 _UpperCamelCase = True if 'ade' in model_name else False _UpperCamelCase = MaskFormerImageProcessor(ignore_index=a__ , reduce_labels=a__ ) _UpperCamelCase = image_processor(a__ , return_tensors='''pt''' ) _UpperCamelCase = model(**a__ ) print('''Logits:''' , outputs.class_queries_logits[0, :3, :3] ) if model_name == "maskformer-swin-tiny-ade": _UpperCamelCase = torch.tensor( [[3.6353, -4.4770, -2.6065], [0.5081, -4.2394, -3.5343], [2.1909, -5.0353, -1.9323]] ) assert torch.allclose(outputs.class_queries_logits[0, :3, :3] , a__ , atol=1e-4 ) print('''Looks ok!''' ) if pytorch_dump_folder_path is not None: print(F'''Saving model and image processor to {pytorch_dump_folder_path}''' ) Path(a__ ).mkdir(exist_ok=a__ ) model.save_pretrained(a__ ) image_processor.save_pretrained(a__ ) if push_to_hub: print('''Pushing model and image processor to the hub...''' ) model.push_to_hub(F'''nielsr/{model_name}''' ) image_processor.push_to_hub(F'''nielsr/{model_name}''' ) if __name__ == "__main__": UpperCAmelCase = argparse.ArgumentParser() # Required parameters parser.add_argument( """--model_name""", default="""maskformer-swin-tiny-ade""", type=str, help=("""Name of the MaskFormer model you'd like to convert""",), ) parser.add_argument( """--checkpoint_path""", default="""/Users/nielsrogge/Documents/MaskFormer_checkpoints/MaskFormer-Swin-tiny-ADE20k/model.pkl""", type=str, help="""Path to the original state dict (.pth file).""", ) parser.add_argument( """--pytorch_dump_folder_path""", default=None, type=str, help="""Path to the output PyTorch model directory.""" ) parser.add_argument( """--push_to_hub""", action="""store_true""", help="""Whether or not to push the converted model to the 🤗 hub.""" ) UpperCAmelCase = parser.parse_args() convert_maskformer_checkpoint( args.model_name, args.checkpoint_path, args.pytorch_dump_folder_path, args.push_to_hub )
256
import unittest import numpy as np from transformers.testing_utils import require_torch, require_vision from transformers.utils import is_torch_available, is_vision_available from ...test_image_processing_common import ImageProcessingSavingTestMixin, prepare_image_inputs if is_torch_available(): import torch if is_vision_available(): from PIL import Image from transformers import PoolFormerImageProcessor class snake_case__ ( unittest.TestCase ): """simple docstring""" def __init__( self : Optional[int], _snake_case : List[Any], _snake_case : str=7, _snake_case : Tuple=3, _snake_case : List[str]=3_0, _snake_case : Tuple=4_0_0, _snake_case : Any=True, _snake_case : List[Any]=None, _snake_case : int=0.9, _snake_case : Optional[Any]=None, _snake_case : str=True, _snake_case : Union[str, Any]=[0.5, 0.5, 0.5], _snake_case : Union[str, Any]=[0.5, 0.5, 0.5], ) ->List[Any]: snake_case__ : int = size if size is not None else {'shortest_edge': 3_0} snake_case__ : Tuple = crop_size if crop_size is not None else {'height': 3_0, 'width': 3_0} snake_case__ : Union[str, Any] = parent snake_case__ : Dict = batch_size snake_case__ : int = num_channels snake_case__ : Tuple = min_resolution snake_case__ : Any = max_resolution snake_case__ : List[Any] = do_resize_and_center_crop snake_case__ : str = size snake_case__ : str = crop_pct snake_case__ : List[str] = crop_size snake_case__ : Optional[int] = do_normalize snake_case__ : Tuple = image_mean snake_case__ : Tuple = image_std def lowercase_ ( self : Optional[int] ) ->int: return { "size": self.size, "do_resize_and_center_crop": self.do_resize_and_center_crop, "crop_pct": self.crop_pct, "crop_size": self.crop_size, "do_normalize": self.do_normalize, "image_mean": self.image_mean, "image_std": self.image_std, } @require_torch @require_vision class snake_case__ ( lowerCAmelCase_ , unittest.TestCase ): """simple docstring""" _SCREAMING_SNAKE_CASE = PoolFormerImageProcessor if is_vision_available() else None def lowercase_ ( self : Union[str, Any] ) ->Dict: snake_case__ : Union[str, Any] = PoolFormerImageProcessingTester(self ) @property def lowercase_ ( self : int ) ->Dict: return self.image_processor_tester.prepare_image_processor_dict() def lowercase_ ( self : Union[str, Any] ) ->Optional[int]: snake_case__ : List[str] = self.image_processing_class(**self.image_processor_dict ) self.assertTrue(hasattr(_snake_case, 'do_resize_and_center_crop' ) ) self.assertTrue(hasattr(_snake_case, 'size' ) ) self.assertTrue(hasattr(_snake_case, 'crop_pct' ) ) self.assertTrue(hasattr(_snake_case, 'do_normalize' ) ) self.assertTrue(hasattr(_snake_case, 'image_mean' ) ) self.assertTrue(hasattr(_snake_case, 'image_std' ) ) def lowercase_ ( self : List[str] ) ->List[str]: snake_case__ : Union[str, Any] = self.image_processing_class.from_dict(self.image_processor_dict ) self.assertEqual(image_processor.size, {'shortest_edge': 3_0} ) self.assertEqual(image_processor.crop_size, {'height': 3_0, 'width': 3_0} ) snake_case__ : int = self.image_processing_class.from_dict(self.image_processor_dict, size=4_2, crop_size=8_4 ) self.assertEqual(image_processor.size, {'shortest_edge': 4_2} ) self.assertEqual(image_processor.crop_size, {'height': 8_4, 'width': 8_4} ) def lowercase_ ( self : List[Any] ) ->List[Any]: pass def lowercase_ ( self : List[str] ) ->str: # Initialize image_processing snake_case__ : Union[str, Any] = self.image_processing_class(**self.image_processor_dict ) # create random PIL images snake_case__ : List[str] = prepare_image_inputs(self.image_processor_tester, equal_resolution=_snake_case ) for image in image_inputs: self.assertIsInstance(_snake_case, Image.Image ) # Test not batched input snake_case__ : Optional[int] = image_processing(image_inputs[0], return_tensors='pt' ).pixel_values self.assertEqual( encoded_images.shape, ( 1, self.image_processor_tester.num_channels, self.image_processor_tester.crop_size['height'], self.image_processor_tester.crop_size['width'], ), ) # Test batched snake_case__ : str = image_processing(_snake_case, return_tensors='pt' ).pixel_values self.assertEqual( encoded_images.shape, ( self.image_processor_tester.batch_size, self.image_processor_tester.num_channels, self.image_processor_tester.crop_size['height'], self.image_processor_tester.crop_size['width'], ), ) def lowercase_ ( self : int ) ->List[Any]: # Initialize image_processing snake_case__ : Optional[int] = self.image_processing_class(**self.image_processor_dict ) # create random numpy tensors snake_case__ : Dict = prepare_image_inputs(self.image_processor_tester, equal_resolution=_snake_case, numpify=_snake_case ) for image in image_inputs: self.assertIsInstance(_snake_case, np.ndarray ) # Test not batched input snake_case__ : Dict = image_processing(image_inputs[0], return_tensors='pt' ).pixel_values self.assertEqual( encoded_images.shape, ( 1, self.image_processor_tester.num_channels, self.image_processor_tester.crop_size['height'], self.image_processor_tester.crop_size['width'], ), ) # Test batched snake_case__ : List[Any] = image_processing(_snake_case, return_tensors='pt' ).pixel_values self.assertEqual( encoded_images.shape, ( self.image_processor_tester.batch_size, self.image_processor_tester.num_channels, self.image_processor_tester.crop_size['height'], self.image_processor_tester.crop_size['width'], ), ) def lowercase_ ( self : List[str] ) ->List[str]: # Initialize image_processing snake_case__ : Tuple = self.image_processing_class(**self.image_processor_dict ) # create random PyTorch tensors snake_case__ : List[str] = prepare_image_inputs(self.image_processor_tester, equal_resolution=_snake_case, torchify=_snake_case ) for image in image_inputs: self.assertIsInstance(_snake_case, torch.Tensor ) # Test not batched input snake_case__ : Tuple = image_processing(image_inputs[0], return_tensors='pt' ).pixel_values self.assertEqual( encoded_images.shape, ( 1, self.image_processor_tester.num_channels, self.image_processor_tester.crop_size['height'], self.image_processor_tester.crop_size['width'], ), ) # Test batched snake_case__ : Optional[Any] = image_processing(_snake_case, return_tensors='pt' ).pixel_values self.assertEqual( encoded_images.shape, ( self.image_processor_tester.batch_size, self.image_processor_tester.num_channels, self.image_processor_tester.crop_size['height'], self.image_processor_tester.crop_size['width'], ), )
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import gc import random import unittest import numpy as np import torch from PIL import Image from transformers import XLMRobertaTokenizerFast from diffusers import DDIMScheduler, KandinskyInpaintPipeline, KandinskyPriorPipeline, UNetaDConditionModel, VQModel from diffusers.pipelines.kandinsky.text_encoder import MCLIPConfig, MultilingualCLIP from diffusers.utils import floats_tensor, load_image, load_numpy, slow, torch_device from diffusers.utils.testing_utils import enable_full_determinism, require_torch_gpu from ..test_pipelines_common import PipelineTesterMixin, assert_mean_pixel_difference enable_full_determinism() class A_ ( lowerCAmelCase_ , unittest.TestCase ): _lowercase : Optional[Any] = KandinskyInpaintPipeline _lowercase : str = ['prompt', 'image_embeds', 'negative_image_embeds', 'image', 'mask_image'] _lowercase : str = [ 'prompt', 'negative_prompt', 'image_embeds', 'negative_image_embeds', 'image', 'mask_image', ] _lowercase : List[Any] = [ 'generator', 'height', 'width', 'latents', 'guidance_scale', 'negative_prompt', 'num_inference_steps', 'return_dict', 'guidance_scale', 'num_images_per_prompt', 'output_type', 'return_dict', ] _lowercase : str = False @property def UpperCAmelCase ( self : Optional[int] ) -> Optional[Any]: return 3_2 @property def UpperCAmelCase ( self : Dict ) -> Tuple: return 3_2 @property def UpperCAmelCase ( self : List[str] ) -> int: return self.time_input_dim @property def UpperCAmelCase ( self : List[str] ) -> Optional[int]: return self.time_input_dim * 4 @property def UpperCAmelCase ( self : str ) -> List[Any]: return 1_0_0 @property def UpperCAmelCase ( self : Union[str, Any] ) -> Tuple: __lowerCAmelCase: List[Any] = XLMRobertaTokenizerFast.from_pretrained('YiYiXu/tiny-random-mclip-base' ) return tokenizer @property def UpperCAmelCase ( self : List[Any] ) -> str: torch.manual_seed(0 ) __lowerCAmelCase: Tuple = MCLIPConfig( numDims=self.cross_attention_dim , transformerDimensions=self.text_embedder_hidden_size , hidden_size=self.text_embedder_hidden_size , intermediate_size=3_7 , num_attention_heads=4 , num_hidden_layers=5 , vocab_size=1_0_0_5 , ) __lowerCAmelCase: Dict = MultilingualCLIP(_snake_case ) __lowerCAmelCase: Any = text_encoder.eval() return text_encoder @property def UpperCAmelCase ( self : Optional[Any] ) -> Union[str, Any]: torch.manual_seed(0 ) __lowerCAmelCase: Union[str, Any] = { 'in_channels': 9, # Out channels is double in channels because predicts mean and variance 'out_channels': 8, 'addition_embed_type': 'text_image', 'down_block_types': ('ResnetDownsampleBlock2D', 'SimpleCrossAttnDownBlock2D'), 'up_block_types': ('SimpleCrossAttnUpBlock2D', 'ResnetUpsampleBlock2D'), 'mid_block_type': 'UNetMidBlock2DSimpleCrossAttn', 'block_out_channels': (self.block_out_channels_a, self.block_out_channels_a * 2), 'layers_per_block': 1, 'encoder_hid_dim': self.text_embedder_hidden_size, 'encoder_hid_dim_type': 'text_image_proj', 'cross_attention_dim': self.cross_attention_dim, 'attention_head_dim': 4, 'resnet_time_scale_shift': 'scale_shift', 'class_embed_type': None, } __lowerCAmelCase: Optional[int] = UNetaDConditionModel(**_snake_case ) return model @property def UpperCAmelCase ( self : Any ) -> Tuple: return { "block_out_channels": [3_2, 6_4], "down_block_types": ["DownEncoderBlock2D", "AttnDownEncoderBlock2D"], "in_channels": 3, "latent_channels": 4, "layers_per_block": 1, "norm_num_groups": 8, "norm_type": "spatial", "num_vq_embeddings": 1_2, "out_channels": 3, "up_block_types": [ "AttnUpDecoderBlock2D", "UpDecoderBlock2D", ], "vq_embed_dim": 4, } @property def UpperCAmelCase ( self : str ) -> Dict: torch.manual_seed(0 ) __lowerCAmelCase: List[str] = VQModel(**self.dummy_movq_kwargs ) return model def UpperCAmelCase ( self : str ) -> List[Any]: __lowerCAmelCase: str = self.dummy_text_encoder __lowerCAmelCase: Optional[Any] = self.dummy_tokenizer __lowerCAmelCase: List[Any] = self.dummy_unet __lowerCAmelCase: Optional[int] = self.dummy_movq __lowerCAmelCase: Optional[Any] = DDIMScheduler( num_train_timesteps=1_0_0_0 , beta_schedule='linear' , beta_start=0.00085 , beta_end=0.012 , clip_sample=_snake_case , set_alpha_to_one=_snake_case , steps_offset=1 , prediction_type='epsilon' , thresholding=_snake_case , ) __lowerCAmelCase: Union[str, Any] = { 'text_encoder': text_encoder, 'tokenizer': tokenizer, 'unet': unet, 'scheduler': scheduler, 'movq': movq, } return components def UpperCAmelCase ( self : str , UpperCAmelCase : Any , UpperCAmelCase : Tuple=0 ) -> str: __lowerCAmelCase: List[str] = floats_tensor((1, self.cross_attention_dim) , rng=random.Random(_snake_case ) ).to(_snake_case ) __lowerCAmelCase: List[str] = floats_tensor((1, self.cross_attention_dim) , rng=random.Random(seed + 1 ) ).to(_snake_case ) # create init_image __lowerCAmelCase: Any = floats_tensor((1, 3, 6_4, 6_4) , rng=random.Random(_snake_case ) ).to(_snake_case ) __lowerCAmelCase: int = image.cpu().permute(0 , 2 , 3 , 1 )[0] __lowerCAmelCase: Dict = Image.fromarray(np.uinta(_snake_case ) ).convert('RGB' ).resize((2_5_6, 2_5_6) ) # create mask __lowerCAmelCase: Optional[Any] = np.ones((6_4, 6_4) , dtype=np.floataa ) __lowerCAmelCase: Optional[Any] = 0 if str(_snake_case ).startswith('mps' ): __lowerCAmelCase: Any = torch.manual_seed(_snake_case ) else: __lowerCAmelCase: int = torch.Generator(device=_snake_case ).manual_seed(_snake_case ) __lowerCAmelCase: int = { 'prompt': 'horse', 'image': init_image, 'mask_image': mask, 'image_embeds': image_embeds, 'negative_image_embeds': negative_image_embeds, 'generator': generator, 'height': 6_4, 'width': 6_4, 'num_inference_steps': 2, 'guidance_scale': 4.0, 'output_type': 'np', } return inputs def UpperCAmelCase ( self : List[str] ) -> Any: __lowerCAmelCase: Any = 'cpu' __lowerCAmelCase: str = self.get_dummy_components() __lowerCAmelCase: Any = self.pipeline_class(**_snake_case ) __lowerCAmelCase: Any = pipe.to(_snake_case ) pipe.set_progress_bar_config(disable=_snake_case ) __lowerCAmelCase: Optional[int] = pipe(**self.get_dummy_inputs(_snake_case ) ) __lowerCAmelCase: int = output.images __lowerCAmelCase: str = pipe( **self.get_dummy_inputs(_snake_case ) , return_dict=_snake_case , )[0] __lowerCAmelCase: Optional[Any] = image[0, -3:, -3:, -1] __lowerCAmelCase: Union[str, Any] = image_from_tuple[0, -3:, -3:, -1] print(F'''image.shape {image.shape}''' ) assert image.shape == (1, 6_4, 6_4, 3) __lowerCAmelCase: Any = np.array( [0.8326919, 0.73790467, 0.20918581, 0.9309612, 0.5511791, 0.43713328, 0.5513321, 0.49922934, 0.59497786] ) assert ( np.abs(image_slice.flatten() - expected_slice ).max() < 1E-2 ), F''' expected_slice {expected_slice}, but got {image_slice.flatten()}''' assert ( np.abs(image_from_tuple_slice.flatten() - expected_slice ).max() < 1E-2 ), F''' expected_slice {expected_slice}, but got {image_from_tuple_slice.flatten()}''' def UpperCAmelCase ( self : Dict ) -> Optional[int]: super().test_inference_batch_single_identical(expected_max_diff=3E-3 ) @slow @require_torch_gpu class A_ ( unittest.TestCase ): def UpperCAmelCase ( self : int ) -> Dict: # clean up the VRAM after each test super().tearDown() gc.collect() torch.cuda.empty_cache() def UpperCAmelCase ( self : Any ) -> Tuple: __lowerCAmelCase: Optional[Any] = load_numpy( 'https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main' '/kandinsky/kandinsky_inpaint_cat_with_hat_fp16.npy' ) __lowerCAmelCase: Optional[Any] = load_image( 'https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main' '/kandinsky/cat.png' ) __lowerCAmelCase: Dict = np.ones((7_6_8, 7_6_8) , dtype=np.floataa ) __lowerCAmelCase: Union[str, Any] = 0 __lowerCAmelCase: Optional[Any] = 'a hat' __lowerCAmelCase: Optional[int] = KandinskyPriorPipeline.from_pretrained( 'kandinsky-community/kandinsky-2-1-prior' , torch_dtype=torch.floataa ) pipe_prior.to(_snake_case ) __lowerCAmelCase: List[str] = KandinskyInpaintPipeline.from_pretrained( 'kandinsky-community/kandinsky-2-1-inpaint' , torch_dtype=torch.floataa ) __lowerCAmelCase: Any = pipeline.to(_snake_case ) pipeline.set_progress_bar_config(disable=_snake_case ) __lowerCAmelCase: Dict = torch.Generator(device='cpu' ).manual_seed(0 ) __lowerCAmelCase: List[Any] = pipe_prior( _snake_case , generator=_snake_case , num_inference_steps=5 , negative_prompt='' , ).to_tuple() __lowerCAmelCase: Dict = pipeline( _snake_case , image=_snake_case , mask_image=_snake_case , image_embeds=_snake_case , negative_image_embeds=_snake_case , generator=_snake_case , num_inference_steps=1_0_0 , height=7_6_8 , width=7_6_8 , output_type='np' , ) __lowerCAmelCase: List[Any] = output.images[0] assert image.shape == (7_6_8, 7_6_8, 3) assert_mean_pixel_difference(_snake_case , _snake_case )
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from collections import deque from .hash_table import HashTable class snake_case__ ( lowerCAmelCase_ ): """simple docstring""" def __init__( self : Optional[Any], *_snake_case : Optional[Any], **_snake_case : List[Any] ) ->Optional[int]: super().__init__(*_snake_case, **_snake_case ) def lowercase_ ( self : Optional[Any], _snake_case : Tuple, _snake_case : Dict ) ->Dict: snake_case__ : int = deque([] ) if self.values[key] is None else self.values[key] self.values[key].appendleft(_snake_case ) snake_case__ : Dict = self.values[key] def lowercase_ ( self : Any ) ->Optional[Any]: return ( sum(self.charge_factor - len(_snake_case ) for slot in self.values ) / self.size_table * self.charge_factor ) def lowercase_ ( self : Union[str, Any], _snake_case : str, _snake_case : Optional[int]=None ) ->Optional[Any]: if not ( len(self.values[key] ) == self.charge_factor and self.values.count(_snake_case ) == 0 ): return key return super()._collision_resolution(_snake_case, _snake_case )
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from dataclasses import dataclass from typing import Optional, Tuple, Union import flax import jax.numpy as jnp from jax import random from ..configuration_utils import ConfigMixin, register_to_config from ..utils import BaseOutput from .scheduling_utils_flax import FlaxSchedulerMixin @flax.struct.dataclass class __lowerCAmelCase : _lowercase : List[Any] = None _lowercase : List[str] = None _lowercase : Tuple = None # sigma(t_i) @classmethod def _lowercase ( cls ) -> Optional[Any]: '''simple docstring''' return cls() @dataclass class __lowerCAmelCase ( lowerCAmelCase_): _lowercase : Optional[int] = 42 _lowercase : Union[str, Any] = 42 _lowercase : List[str] = 42 class __lowerCAmelCase ( lowerCAmelCase_ , lowerCAmelCase_): @property def _lowercase ( self ) -> List[str]: '''simple docstring''' return True @register_to_config def __init__( self , lowerCAmelCase__ = 0.02 , lowerCAmelCase__ = 1_0_0 , lowerCAmelCase__ = 1.0_07 , lowerCAmelCase__ = 8_0 , lowerCAmelCase__ = 0.05 , lowerCAmelCase__ = 5_0 , ) -> List[Any]: '''simple docstring''' pass def _lowercase ( self ) -> str: '''simple docstring''' return KarrasVeSchedulerState.create() def _lowercase ( self , lowerCAmelCase__ , lowerCAmelCase__ , lowerCAmelCase__ = () ) -> KarrasVeSchedulerState: '''simple docstring''' a__ : Tuple =jnp.arange(0 , _snake_case )[::-1].copy() a__ : List[str] =[ ( self.config.sigma_max**2 * (self.config.sigma_min**2 / self.config.sigma_max**2) ** (i / (num_inference_steps - 1)) ) for i in timesteps ] return state.replace( num_inference_steps=_snake_case , schedule=jnp.array(_snake_case , dtype=jnp.floataa ) , timesteps=_snake_case , ) def _lowercase ( self , lowerCAmelCase__ , lowerCAmelCase__ , lowerCAmelCase__ , lowerCAmelCase__ , ) -> Tuple[jnp.ndarray, float]: '''simple docstring''' if self.config.s_min <= sigma <= self.config.s_max: a__ : Optional[int] =min(self.config.s_churn / state.num_inference_steps , 2**0.5 - 1 ) else: a__ : Any =0 # sample eps ~ N(0, S_noise^2 * I) a__ : List[Any] =random.split(_snake_case , num=1 ) a__ : List[str] =self.config.s_noise * random.normal(key=_snake_case , shape=sample.shape ) a__ : Optional[Any] =sigma + gamma * sigma a__ : Optional[Any] =sample + ((sigma_hat**2 - sigma**2) ** 0.5 * eps) return sample_hat, sigma_hat def _lowercase ( self , lowerCAmelCase__ , lowerCAmelCase__ , lowerCAmelCase__ , lowerCAmelCase__ , lowerCAmelCase__ , lowerCAmelCase__ = True , ) -> Union[FlaxKarrasVeOutput, Tuple]: '''simple docstring''' a__ : int =sample_hat + sigma_hat * model_output a__ : List[str] =(sample_hat - pred_original_sample) / sigma_hat a__ : int =sample_hat + (sigma_prev - sigma_hat) * derivative if not return_dict: return (sample_prev, derivative, state) return FlaxKarrasVeOutput(prev_sample=_snake_case , derivative=_snake_case , state=_snake_case ) def _lowercase ( self , lowerCAmelCase__ , lowerCAmelCase__ , lowerCAmelCase__ , lowerCAmelCase__ , lowerCAmelCase__ , lowerCAmelCase__ , lowerCAmelCase__ , lowerCAmelCase__ = True , ) -> Union[FlaxKarrasVeOutput, Tuple]: '''simple docstring''' a__ : Optional[Any] =sample_prev + sigma_prev * model_output a__ : str =(sample_prev - pred_original_sample) / sigma_prev a__ : int =sample_hat + (sigma_prev - sigma_hat) * (0.5 * derivative + 0.5 * derivative_corr) if not return_dict: return (sample_prev, derivative, state) return FlaxKarrasVeOutput(prev_sample=_snake_case , derivative=_snake_case , state=_snake_case ) def _lowercase ( self , lowerCAmelCase__ , lowerCAmelCase__ , lowerCAmelCase__ , lowerCAmelCase__ ) -> Union[str, Any]: '''simple docstring''' raise NotImplementedError()
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def lowercase_ (A : Union[str, Any] , A : List[str] , A : int , A : Optional[int] ): global f # a global dp table for knapsack if f[i][j] < 0: if j < wt[i - 1]: snake_case__ : Union[str, Any] = mf_knapsack(i - 1 , A , A , A ) else: snake_case__ : Any = max( mf_knapsack(i - 1 , A , A , A ) , mf_knapsack(i - 1 , A , A , j - wt[i - 1] ) + val[i - 1] , ) snake_case__ : Optional[int] = val return f[i][j] def lowercase_ (A : Optional[int] , A : Union[str, Any] , A : str , A : Dict ): snake_case__ : int = [[0] * (w + 1) for _ in range(n + 1 )] for i in range(1 , n + 1 ): for w_ in range(1 , w + 1 ): if wt[i - 1] <= w_: snake_case__ : Union[str, Any] = max(val[i - 1] + dp[i - 1][w_ - wt[i - 1]] , dp[i - 1][w_] ) else: snake_case__ : str = dp[i - 1][w_] return dp[n][w_], dp def lowercase_ (A : int , A : list , A : list ): if not (isinstance(A , (list, tuple) ) and isinstance(A , (list, tuple) )): raise ValueError( 'Both the weights and values vectors must be either lists or tuples' ) snake_case__ : Dict = len(A ) if num_items != len(A ): snake_case__ : str = ( 'The number of weights must be the same as the number of values.\n' F'''But got {num_items} weights and {len(A )} values''' ) raise ValueError(A ) for i in range(A ): if not isinstance(wt[i] , A ): snake_case__ : Optional[int] = ( 'All weights must be integers but got weight of ' F'''type {type(wt[i] )} at index {i}''' ) raise TypeError(A ) snake_case__ , snake_case__ : Optional[int] = knapsack(A , A , A , A ) snake_case__ : set = set() _construct_solution(A , A , A , A , A ) return optimal_val, example_optional_set def lowercase_ (A : list , A : list , A : int , A : int , A : set ): # for the current item i at a maximum weight j to be part of an optimal subset, # the optimal value at (i, j) must be greater than the optimal value at (i-1, j). # where i - 1 means considering only the previous items at the given maximum weight if i > 0 and j > 0: if dp[i - 1][j] == dp[i][j]: _construct_solution(A , A , i - 1 , A , A ) else: optimal_set.add(A ) _construct_solution(A , A , i - 1 , j - wt[i - 1] , A ) if __name__ == "__main__": a_ :Any = [3, 2, 4, 4] a_ :List[Any] = [4, 3, 2, 3] a_ :Union[str, Any] = 4 a_ :List[str] = 6 a_ :Union[str, Any] = [[0] * (w + 1)] + [[0] + [-1] * (w + 1) for _ in range(n + 1)] a_ , a_ :List[Any] = knapsack(w, wt, val, n) print(optimal_solution) print(mf_knapsack(n, wt, val, w)) # switched the n and w # testing the dynamic programming problem with example # the optimal subset for the above example are items 3 and 4 a_ , a_ :Any = knapsack_with_example_solution(w, wt, val) assert optimal_solution == 8 assert optimal_subset == {3, 4} print("optimal_value = ", optimal_solution) print("An optimal subset corresponding to the optimal value", optimal_subset)
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import math def a ( snake_case__: int ): '''simple docstring''' assert isinstance(snake_case__ , snake_case__ ) and ( number >= 0 ), "'number' must been an int and positive" if 1 < number < 4: # 2 and 3 are primes return True elif number < 2 or not number % 2: # Negatives, 0, 1 and all even numbers are not primes return False lowercase_ = range(3 , int(math.sqrt(snake_case__ ) + 1 ) , 2 ) return not any(not number % i for i in odd_numbers ) def a ( snake_case__: Any , snake_case__: Optional[Any]=1 , **snake_case__: Any ): '''simple docstring''' lowercase_ = factor * value lowercase_ = value while not is_prime(snake_case__ ): value += 1 if not ("desc" in kwargs and kwargs["desc"] is True) else -1 if value == first_value_val: return next_prime(value + 1 , **snake_case__ ) return value
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from typing import TYPE_CHECKING from ...utils import OptionalDependencyNotAvailable, _LazyModule, is_flax_available, is_torch_available a_ :int = { "configuration_longt5": ["LONGT5_PRETRAINED_CONFIG_ARCHIVE_MAP", "LongT5Config", "LongT5OnnxConfig"], } try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: a_ :List[str] = [ "LONGT5_PRETRAINED_MODEL_ARCHIVE_LIST", "LongT5EncoderModel", "LongT5ForConditionalGeneration", "LongT5Model", "LongT5PreTrainedModel", ] try: if not is_flax_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: a_ :int = [ "FlaxLongT5ForConditionalGeneration", "FlaxLongT5Model", "FlaxLongT5PreTrainedModel", ] if TYPE_CHECKING: from .configuration_longta import LONGT5_PRETRAINED_CONFIG_ARCHIVE_MAP, LongTaConfig, LongTaOnnxConfig try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_longta import ( LONGT5_PRETRAINED_MODEL_ARCHIVE_LIST, LongTaEncoderModel, LongTaForConditionalGeneration, LongTaModel, LongTaPreTrainedModel, ) try: if not is_flax_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_flax_longta import ( FlaxLongTaForConditionalGeneration, FlaxLongTaModel, FlaxLongTaPreTrainedModel, ) else: import sys a_ :Optional[int] = _LazyModule(__name__, globals()["__file__"], _import_structure, module_spec=__spec__)
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"""simple docstring""" def lowercase ( lowerCAmelCase__ : int , lowerCAmelCase__ : int ) -> str: while b: __a = b, a % b return a def lowercase ( lowerCAmelCase__ : int , lowerCAmelCase__ : int ) -> List[str]: return a if b == 0 else euclidean_gcd_recursive(lowerCAmelCase__ , a % b ) def lowercase ( ) -> Optional[Any]: print(f'''euclidean_gcd(3, 5) = {euclidean_gcd(3 , 5 )}''' ) print(f'''euclidean_gcd(5, 3) = {euclidean_gcd(5 , 3 )}''' ) print(f'''euclidean_gcd(1, 3) = {euclidean_gcd(1 , 3 )}''' ) print(f'''euclidean_gcd(3, 6) = {euclidean_gcd(3 , 6 )}''' ) print(f'''euclidean_gcd(6, 3) = {euclidean_gcd(6 , 3 )}''' ) print(f'''euclidean_gcd_recursive(3, 5) = {euclidean_gcd_recursive(3 , 5 )}''' ) print(f'''euclidean_gcd_recursive(5, 3) = {euclidean_gcd_recursive(5 , 3 )}''' ) print(f'''euclidean_gcd_recursive(1, 3) = {euclidean_gcd_recursive(1 , 3 )}''' ) print(f'''euclidean_gcd_recursive(3, 6) = {euclidean_gcd_recursive(3 , 6 )}''' ) print(f'''euclidean_gcd_recursive(6, 3) = {euclidean_gcd_recursive(6 , 3 )}''' ) if __name__ == "__main__": main()
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import argparse import json import os import torch from torch import nn from transformers import NllbMoeConfig, NllbMoeModel from transformers.modeling_utils import dtype_byte_size from transformers.utils import WEIGHTS_INDEX_NAME, WEIGHTS_NAME def lowercase_ (A : List[str] ): snake_case__ : Tuple = [ 'encoder.version', 'decoder.version', 'model.encoder.version', 'model.decoder.version', 'decoder.output_projection.weight', '_float_tensor', 'encoder.embed_positions._float_tensor', 'decoder.embed_positions._float_tensor', ] for k in ignore_keys: state_dict.pop(A , A ) def lowercase_ (A : str ): snake_case__ , snake_case__ : Union[str, Any] = emb.weight.shape snake_case__ : str = nn.Linear(A , A , bias=A ) snake_case__ : str = emb.weight.data return lin_layer def lowercase_ (A : Optional[int] , A : Union[str, Any]=None ): snake_case__ : Any = {} for old_key in state_dict.keys(): snake_case__ : Tuple = old_key if "moe_layer.experts." in key: if expert_idx is not None: snake_case__ : int = key.replace('moe_layer.experts.0' , F'''ffn.experts.expert_{expert_idx}''' ) else: snake_case__ : Any = key.replace('moe_layer.experts.' , 'ffn.experts.expert_' ) if "gate" in key: snake_case__ : Dict = key.replace('.moe_layer.gate.wg' , '.ffn.router.classifier' ) if "fc2" and "experts" not in key: snake_case__ : str = key.replace('.fc2.' , '.ffn.fc2.' ) if "fc1" and "experts" not in key: snake_case__ : str = key.replace('.fc1.' , '.ffn.fc1.' ) if ".encoder_attn." in key: snake_case__ : Tuple = key.replace('.encoder_attn.' , '.cross_attention.' ) if "encoder_attn_layer_norm" in key: snake_case__ : Tuple = key.replace('encoder_attn_layer_norm' , 'cross_attention_layer_norm' ) if "final_layer_norm" in key: snake_case__ : Optional[int] = key.replace('final_layer_norm' , 'ff_layer_norm' ) snake_case__ : Dict = state_dict[old_key] return new_dict def lowercase_ (A : List[Any] , A : Tuple , A : List[Any] , A : List[str] , A : str = WEIGHTS_NAME ): snake_case__ : Dict = [] snake_case__ : str = 0 os.makedirs(A , exist_ok=A ) for expert in range(A ): snake_case__ : Tuple = switch_checkpoint_path + F'''-rank-{expert}.pt''' if os.path.isfile(A ): snake_case__ : Optional[Any] = torch.load(A )['model'] remove_ignore_keys_(A ) snake_case__ : Optional[Any] = rename_fairseq_keys(A , A ) snake_case__ : Dict = os.path.join( A , weights_name.replace('.bin' , F'''-{len(A )+1:05d}-of-???.bin''' ) ) torch.save(A , A ) sharded_state_dicts.append(expert_state.keys() ) total_size += sum([value.numel() for key, value in expert_state.items()] ) * dtype_byte_size( expert_state[list(A )[0]].dtype ) # Add the last block snake_case__ : Tuple = os.path.join(A , weights_name.replace('.bin' , F'''-{len(A )+1:05d}-of-???.bin''' ) ) snake_case__ : Union[str, Any] = torch.load(switch_checkpoint_path + '-shared.pt' )['model'] remove_ignore_keys_(A ) snake_case__ : str = rename_fairseq_keys(A , A ) snake_case__ : Any = shared_weights['decoder.embed_tokens.weight'] sharded_state_dicts.append(shared_weights.keys() ) # If we only have the shared weights (dummy model/experts saved on the same file) if len(A ) == 1: snake_case__ : Any = os.path.join(A , A ) torch.save(A , A ) return {weights_name: sharded_state_dicts[0]}, None else: torch.save(A , A ) # Otherwise, let's build the index snake_case__ : Tuple = {} for idx, shard in enumerate(A ): snake_case__ : Optional[int] = weights_name.replace('.bin' , F'''-{idx+1:05d}-of-{len(A ):05d}.bin''' ) snake_case__ : List[Any] = os.path.join(A , weights_name.replace('.bin' , F'''-{idx+1:05d}-of-???.bin''' ) ) os.rename(A , os.path.join(A , A ) ) for key in shard: snake_case__ : Any = shard_file # Add the metadata snake_case__ : int = {'total_size': total_size} snake_case__ : Dict = {'metadata': metadata, 'weight_map': weight_map} with open(os.path.join(A , A ) , 'w' , encoding='utf-8' ) as f: snake_case__ : Any = json.dumps(A , indent=2 , sort_keys=A ) + '\n' f.write(A ) return metadata, index if __name__ == "__main__": a_ :int = argparse.ArgumentParser() # Required parameters parser.add_argument( "--nllb_moe_checkpoint_path", default="/home/arthur_huggingface_co/fairseq/weights/checkpoints/model_moe_54b/checkpoint_2_300000", type=str, required=False, help="Path to a directory containing a folder per layer. Follows the original Google format.", ) parser.add_argument("--dtype", default="float32", type=str, required=False, help="dtype of the saved model") parser.add_argument( "--pytorch_dump_folder_path", default="/home/arthur_huggingface_co/fairseq/weights/checkpoints/hf-converted-moe-54b", type=str, required=False, help="Path to the output pytorch model.", ) a_ :Optional[Any] = parser.parse_args() a_ , a_ :Optional[Any] = shard_on_the_fly( args.nllb_moe_checkpoint_path, args.pytorch_dump_folder_path, 128, args.dtype, ) a_ :List[str] = NllbMoeConfig.from_pretrained( "facebook/nllb-200-3.3B", encoder_sparse_step=4, decoder_sparse_step=4, num_experts=128 ) config.save_pretrained(args.pytorch_dump_folder_path) a_ :int = NllbMoeModel.from_pretrained(args.pytorch_dump_folder_path) print("Done") model.save_pretrained(args.pytorch_dump_folder_path)
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'''simple docstring''' import argparse import json import os import fairseq import torch from fairseq.data import Dictionary from transformers import ( UniSpeechConfig, UniSpeechForCTC, UniSpeechForPreTraining, WavaVecaFeatureExtractor, WavaVecaPhonemeCTCTokenizer, WavaVecaProcessor, logging, ) logging.set_verbosity_info() _lowerCAmelCase = logging.get_logger(__name__) _lowerCAmelCase = { "post_extract_proj": "feature_projection.projection", "encoder.pos_conv.0": "encoder.pos_conv_embed.conv", "self_attn.k_proj": "encoder.layers.*.attention.k_proj", "self_attn.v_proj": "encoder.layers.*.attention.v_proj", "self_attn.q_proj": "encoder.layers.*.attention.q_proj", "self_attn.out_proj": "encoder.layers.*.attention.out_proj", "self_attn_layer_norm": "encoder.layers.*.layer_norm", "fc1": "encoder.layers.*.feed_forward.intermediate_dense", "fc2": "encoder.layers.*.feed_forward.output_dense", "final_layer_norm": "encoder.layers.*.final_layer_norm", "encoder.layer_norm": "encoder.layer_norm", "w2v_model.layer_norm": "feature_projection.layer_norm", "quantizer.weight_proj": "quantizer.weight_proj", "quantizer.vars": "quantizer.codevectors", "project_q": "project_q", "final_proj": "project_hid", "w2v_encoder.proj": "ctc_proj", "mask_emb": "masked_spec_embed", } _lowerCAmelCase = [ "ctc_proj", "quantizer.weight_proj", "quantizer.codevectors", "project_q", "project_hid", ] def __lowerCAmelCase ( snake_case__ , snake_case__ , snake_case__ , snake_case__ , snake_case__ , snake_case__ ): for attribute in key.split("." ): if is_finetuned: if attribute in ["quantizer", "project_q", "project_hid"]: # those layers are only relevant for pretraining and should be dropped return if attribute == "ctc_proj": # we should rename `ctc_proj` to `lm_head` for fine-tuned phoneme models __UpperCamelCase : Optional[Any] = 'lm_head' __UpperCamelCase : int = getattr(snake_case__ , snake_case__ ) if weight_type is not None: __UpperCamelCase : Tuple = getattr(snake_case__ , snake_case__ ).shape else: __UpperCamelCase : List[Any] = hf_pointer.shape assert hf_shape == value.shape, ( F"Shape of hf {key + '.' + weight_type if weight_type is not None else ''} is {hf_shape}, but should be" F" {value.shape} for {full_name}" ) if weight_type == "weight": __UpperCamelCase : Any = value elif weight_type == "weight_g": __UpperCamelCase : Union[str, Any] = value elif weight_type == "weight_v": __UpperCamelCase : Optional[Any] = value elif weight_type == "bias": __UpperCamelCase : Dict = value else: __UpperCamelCase : Optional[Any] = value logger.info(F"{key + '.' + weight_type if weight_type is not None else ''} was initialized from {full_name}." ) def __lowerCAmelCase ( snake_case__ , snake_case__ , snake_case__ ): __UpperCamelCase : Optional[int] = [] __UpperCamelCase : Optional[Any] = fairseq_model.state_dict() __UpperCamelCase : Tuple = hf_model.unispeech.feature_extractor for name, value in fairseq_dict.items(): __UpperCamelCase : Dict = False if "conv_layers" in name: load_conv_layer( snake_case__ , snake_case__ , snake_case__ , snake_case__ , hf_model.config.feat_extract_norm == "group" , ) __UpperCamelCase : Tuple = True else: for key, mapped_key in MAPPING.items(): __UpperCamelCase : List[Any] = 'unispeech.' + mapped_key if mapped_key not in TOP_LEVEL_KEYS else mapped_key if key in name or key.split("w2v_model." )[-1] == name.split("." )[0]: __UpperCamelCase : Optional[int] = True if "*" in mapped_key: __UpperCamelCase : int = name.split(snake_case__ )[0].split("." )[-2] __UpperCamelCase : List[str] = mapped_key.replace("*" , snake_case__ ) if "weight_g" in name: __UpperCamelCase : Any = 'weight_g' elif "weight_v" in name: __UpperCamelCase : List[Any] = 'weight_v' elif "bias" in name: __UpperCamelCase : int = 'bias' elif "weight" in name: # TODO: don't match quantizer.weight_proj __UpperCamelCase : Any = 'weight' else: __UpperCamelCase : Union[str, Any] = None set_recursively(snake_case__ , snake_case__ , snake_case__ , snake_case__ , snake_case__ , snake_case__ ) continue if not is_used: unused_weights.append(snake_case__ ) logger.warning(F"Unused weights: {unused_weights}" ) def __lowerCAmelCase ( snake_case__ , snake_case__ , snake_case__ , snake_case__ , snake_case__ ): __UpperCamelCase : Optional[int] = full_name.split("conv_layers." )[-1] __UpperCamelCase : str = name.split("." ) __UpperCamelCase : Union[str, Any] = int(items[0] ) __UpperCamelCase : Optional[Any] = int(items[1] ) if type_id == 0: if "bias" in name: assert value.shape == feature_extractor.conv_layers[layer_id].conv.bias.data.shape, ( F"{full_name} has size {value.shape}, but" F" {feature_extractor.conv_layers[layer_id].conv.bias.data.shape} was found." ) __UpperCamelCase : int = value logger.info(F"Feat extract conv layer {layer_id} was initialized from {full_name}." ) elif "weight" in name: assert value.shape == feature_extractor.conv_layers[layer_id].conv.weight.data.shape, ( F"{full_name} has size {value.shape}, but" F" {feature_extractor.conv_layers[layer_id].conv.weight.data.shape} was found." ) __UpperCamelCase : List[str] = value logger.info(F"Feat extract conv layer {layer_id} was initialized from {full_name}." ) elif (type_id == 2 and not use_group_norm) or (type_id == 2 and layer_id == 0 and use_group_norm): if "bias" in name: assert value.shape == feature_extractor.conv_layers[layer_id].layer_norm.bias.data.shape, ( F"{full_name} has size {value.shape}, but {feature_extractor[layer_id].layer_norm.bias.data.shape} was" " found." ) __UpperCamelCase : List[Any] = value logger.info(F"Feat extract layer norm weight of layer {layer_id} was initialized from {full_name}." ) elif "weight" in name: assert value.shape == feature_extractor.conv_layers[layer_id].layer_norm.weight.data.shape, ( F"{full_name} has size {value.shape}, but" F" {feature_extractor[layer_id].layer_norm.weight.data.shape} was found." ) __UpperCamelCase : str = value logger.info(F"Feat extract layer norm weight of layer {layer_id} was initialized from {full_name}." ) else: unused_weights.append(snake_case__ ) @torch.no_grad() def __lowerCAmelCase ( snake_case__ , snake_case__ , snake_case__=None , snake_case__=None , snake_case__=True ): if config_path is not None: __UpperCamelCase : Tuple = UniSpeechConfig.from_pretrained(snake_case__ ) else: __UpperCamelCase : Tuple = UniSpeechConfig() if is_finetuned: if dict_path: __UpperCamelCase : Tuple = Dictionary.load_from_json(snake_case__ ) # important change bos & pad token id since CTC symbol is <pad> and # not <s> as in fairseq __UpperCamelCase : Any = target_dict.pad_index __UpperCamelCase : List[str] = target_dict.bos_index __UpperCamelCase : List[Any] = target_dict.eos_index __UpperCamelCase : Optional[Any] = len(target_dict.symbols ) __UpperCamelCase : List[Any] = os.path.join(snake_case__ , "vocab.json" ) if not os.path.isdir(snake_case__ ): logger.error("--pytorch_dump_folder_path ({}) should be a directory".format(snake_case__ ) ) return os.makedirs(snake_case__ , exist_ok=snake_case__ ) __UpperCamelCase : List[Any] = target_dict.indices # fairseq has the <pad> and <s> switched __UpperCamelCase : Optional[Any] = 42 __UpperCamelCase : Tuple = 43 with open(snake_case__ , "w" , encoding="utf-8" ) as vocab_handle: json.dump(snake_case__ , snake_case__ ) __UpperCamelCase : Tuple = WavaVecaPhonemeCTCTokenizer( snake_case__ , unk_token=target_dict.unk_word , pad_token=target_dict.pad_word , bos_token=target_dict.bos_word , eos_token=target_dict.eos_word , word_delimiter_token="|" , do_lower_case=snake_case__ , ) __UpperCamelCase : int = True if config.feat_extract_norm == 'layer' else False __UpperCamelCase : Union[str, Any] = WavaVecaFeatureExtractor( feature_size=1 , sampling_rate=16_000 , padding_value=0 , do_normalize=snake_case__ , return_attention_mask=snake_case__ , ) __UpperCamelCase : Union[str, Any] = WavaVecaProcessor(feature_extractor=snake_case__ , tokenizer=snake_case__ ) processor.save_pretrained(snake_case__ ) __UpperCamelCase : int = UniSpeechForCTC(snake_case__ ) else: __UpperCamelCase : Optional[int] = UniSpeechForPreTraining(snake_case__ ) if is_finetuned: __UpperCamelCase : str = fairseq.checkpoint_utils.load_model_ensemble_and_task( [checkpoint_path] , arg_overrides={"data": "/".join(dict_path.split("/" )[:-1] ), "w2v_path": checkpoint_path} ) else: __UpperCamelCase : Tuple = fairseq.checkpoint_utils.load_model_ensemble_and_task([checkpoint_path] ) __UpperCamelCase : Tuple = model[0].eval() recursively_load_weights(snake_case__ , snake_case__ , snake_case__ ) hf_unispeech.save_pretrained(snake_case__ ) if __name__ == "__main__": _lowerCAmelCase = argparse.ArgumentParser() parser.add_argument('''--pytorch_dump_folder_path''', default=None, type=str, help='''Path to the output PyTorch model.''') parser.add_argument('''--checkpoint_path''', default=None, type=str, help='''Path to fairseq checkpoint''') parser.add_argument('''--dict_path''', default=None, type=str, help='''Path to dict of fine-tuned model''') parser.add_argument('''--config_path''', default=None, type=str, help='''Path to hf config.json of model to convert''') parser.add_argument( '''--not_finetuned''', action='''store_true''', help='''Whether the model to convert is a fine-tuned model or not''' ) _lowerCAmelCase = parser.parse_args() convert_unispeech_checkpoint( args.checkpoint_path, args.pytorch_dump_folder_path, args.config_path, args.dict_path, not args.not_finetuned )
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from typing import TYPE_CHECKING from ...utils import ( OptionalDependencyNotAvailable, _LazyModule, is_sentencepiece_available, is_tokenizers_available, is_torch_available, ) a_ :Optional[Any] = {"configuration_reformer": ["REFORMER_PRETRAINED_CONFIG_ARCHIVE_MAP", "ReformerConfig"]} try: if not is_sentencepiece_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: a_ :str = ["ReformerTokenizer"] try: if not is_tokenizers_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: a_ :int = ["ReformerTokenizerFast"] try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: a_ :List[str] = [ "REFORMER_PRETRAINED_MODEL_ARCHIVE_LIST", "ReformerAttention", "ReformerForMaskedLM", "ReformerForQuestionAnswering", "ReformerForSequenceClassification", "ReformerLayer", "ReformerModel", "ReformerModelWithLMHead", "ReformerPreTrainedModel", ] if TYPE_CHECKING: from .configuration_reformer import REFORMER_PRETRAINED_CONFIG_ARCHIVE_MAP, ReformerConfig try: if not is_sentencepiece_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .tokenization_reformer import ReformerTokenizer try: if not is_tokenizers_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .tokenization_reformer_fast import ReformerTokenizerFast try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_reformer import ( REFORMER_PRETRAINED_MODEL_ARCHIVE_LIST, ReformerAttention, ReformerForMaskedLM, ReformerForQuestionAnswering, ReformerForSequenceClassification, ReformerLayer, ReformerModel, ReformerModelWithLMHead, ReformerPreTrainedModel, ) else: import sys a_ :Optional[Any] = _LazyModule(__name__, globals()["__file__"], _import_structure, module_spec=__spec__)
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import inspect from typing import Callable, List, Optional, Union import torch from transformers import ( CLIPImageProcessor, CLIPTextModel, CLIPTokenizer, WhisperForConditionalGeneration, WhisperProcessor, ) from diffusers import ( AutoencoderKL, DDIMScheduler, DiffusionPipeline, LMSDiscreteScheduler, PNDMScheduler, UNetaDConditionModel, ) from diffusers.pipelines.stable_diffusion.pipeline_stable_diffusion import StableDiffusionPipelineOutput from diffusers.pipelines.stable_diffusion.safety_checker import StableDiffusionSafetyChecker from diffusers.utils import logging _snake_case = logging.get_logger(__name__) # pylint: disable=invalid-name class lowercase ( lowerCAmelCase_ ): def __init__( self , _a , _a , _a , _a , _a , _a , _a , _a , _a , ) -> Optional[int]: super().__init__() if safety_checker is None: logger.warning( F'''You have disabled the safety checker for {self.__class__} by passing `safety_checker=None`. Ensure''' """ that you abide to the conditions of the Stable Diffusion license and do not expose unfiltered""" """ results in services or applications open to the public. Both the diffusers team and Hugging Face""" """ strongly recommend to keep the safety filter enabled in all public facing circumstances, disabling""" """ it only for use-cases that involve analyzing network behavior or auditing its results. For more""" """ information, please have a look at https://github.com/huggingface/diffusers/pull/254 .""" ) self.register_modules( speech_model=_snake_case , speech_processor=_snake_case , vae=_snake_case , text_encoder=_snake_case , tokenizer=_snake_case , unet=_snake_case , scheduler=_snake_case , feature_extractor=_snake_case , ) def a__ ( self , _a = "auto" ) -> Union[str, Any]: if slice_size == "auto": _A : Any = self.unet.config.attention_head_dim // 2 self.unet.set_attention_slice(_snake_case ) def a__ ( self ) -> Any: self.enable_attention_slicing(_snake_case ) @torch.no_grad() def __call__( self , _a , _a=1_6000 , _a = 512 , _a = 512 , _a = 50 , _a = 7.5 , _a = None , _a = 1 , _a = 0.0 , _a = None , _a = None , _a = "pil" , _a = True , _a = None , _a = 1 , **_a , ) -> int: _A : Optional[int] = self.speech_processor.feature_extractor( _snake_case , return_tensors="""pt""" , sampling_rate=_snake_case ).input_features.to(self.device ) _A : Dict = self.speech_model.generate(_snake_case , max_length=48_0000 ) _A : Optional[int] = self.speech_processor.tokenizer.batch_decode(_snake_case , skip_special_tokens=_snake_case , normalize=_snake_case )[ 0 ] if isinstance(_snake_case , _snake_case ): _A : Union[str, Any] = 1 elif isinstance(_snake_case , _snake_case ): _A : int = len(_snake_case ) else: raise ValueError(F'''`prompt` has to be of type `str` or `list` but is {type(_snake_case )}''' ) if height % 8 != 0 or width % 8 != 0: raise ValueError(F'''`height` and `width` have to be divisible by 8 but are {height} and {width}.''' ) if (callback_steps is None) or ( callback_steps is not None and (not isinstance(_snake_case , _snake_case ) or callback_steps <= 0) ): raise ValueError( F'''`callback_steps` has to be a positive integer but is {callback_steps} of type''' F''' {type(_snake_case )}.''' ) # get prompt text embeddings _A : Dict = self.tokenizer( _snake_case , padding="""max_length""" , max_length=self.tokenizer.model_max_length , return_tensors="""pt""" , ) _A : Dict = text_inputs.input_ids if text_input_ids.shape[-1] > self.tokenizer.model_max_length: _A : List[Any] = self.tokenizer.batch_decode(text_input_ids[:, self.tokenizer.model_max_length :] ) logger.warning( """The following part of your input was truncated because CLIP can only handle sequences up to""" F''' {self.tokenizer.model_max_length} tokens: {removed_text}''' ) _A : Union[str, Any] = text_input_ids[:, : self.tokenizer.model_max_length] _A : Optional[Any] = self.text_encoder(text_input_ids.to(self.device ) )[0] # duplicate text embeddings for each generation per prompt, using mps friendly method _A : Optional[int] = text_embeddings.shape _A : Optional[int] = text_embeddings.repeat(1 , _snake_case , 1 ) _A : str = text_embeddings.view(bs_embed * num_images_per_prompt , _snake_case , -1 ) # here `guidance_scale` is defined analog to the guidance weight `w` of equation (2) # of the Imagen paper: https://arxiv.org/pdf/2205.11487.pdf . `guidance_scale = 1` # corresponds to doing no classifier free guidance. _A : Optional[Any] = guidance_scale > 1.0 # get unconditional embeddings for classifier free guidance if do_classifier_free_guidance: _A : List[str] if negative_prompt is None: _A : Optional[Any] = [''] * batch_size elif type(_snake_case ) is not type(_snake_case ): raise TypeError( F'''`negative_prompt` should be the same type to `prompt`, but got {type(_snake_case )} !=''' F''' {type(_snake_case )}.''' ) elif isinstance(_snake_case , _snake_case ): _A : int = [negative_prompt] elif batch_size != len(_snake_case ): raise ValueError( F'''`negative_prompt`: {negative_prompt} has batch size {len(_snake_case )}, but `prompt`:''' F''' {prompt} has batch size {batch_size}. Please make sure that passed `negative_prompt` matches''' """ the batch size of `prompt`.""" ) else: _A : Tuple = negative_prompt _A : Dict = text_input_ids.shape[-1] _A : int = self.tokenizer( _snake_case , padding="""max_length""" , max_length=_snake_case , truncation=_snake_case , return_tensors="""pt""" , ) _A : Optional[int] = self.text_encoder(uncond_input.input_ids.to(self.device ) )[0] # duplicate unconditional embeddings for each generation per prompt, using mps friendly method _A : List[Any] = uncond_embeddings.shape[1] _A : str = uncond_embeddings.repeat(1 , _snake_case , 1 ) _A : Union[str, Any] = uncond_embeddings.view(batch_size * num_images_per_prompt , _snake_case , -1 ) # For classifier free guidance, we need to do two forward passes. # Here we concatenate the unconditional and text embeddings into a single batch # to avoid doing two forward passes _A : Tuple = torch.cat([uncond_embeddings, text_embeddings] ) # get the initial random noise unless the user supplied it # Unlike in other pipelines, latents need to be generated in the target device # for 1-to-1 results reproducibility with the CompVis implementation. # However this currently doesn't work in `mps`. _A : str = (batch_size * num_images_per_prompt, self.unet.config.in_channels, height // 8, width // 8) _A : str = text_embeddings.dtype if latents is None: if self.device.type == "mps": # randn does not exist on mps _A : Dict = torch.randn(_snake_case , generator=_snake_case , device="""cpu""" , dtype=_snake_case ).to( self.device ) else: _A : str = torch.randn(_snake_case , generator=_snake_case , device=self.device , dtype=_snake_case ) else: if latents.shape != latents_shape: raise ValueError(F'''Unexpected latents shape, got {latents.shape}, expected {latents_shape}''' ) _A : int = latents.to(self.device ) # set timesteps self.scheduler.set_timesteps(_snake_case ) # Some schedulers like PNDM have timesteps as arrays # It's more optimized to move all timesteps to correct device beforehand _A : Any = self.scheduler.timesteps.to(self.device ) # scale the initial noise by the standard deviation required by the scheduler _A : Any = latents * self.scheduler.init_noise_sigma # prepare extra kwargs for the scheduler step, since not all schedulers have the same signature # eta (η) is only used with the DDIMScheduler, it will be ignored for other schedulers. # eta corresponds to η in DDIM paper: https://arxiv.org/abs/2010.02502 # and should be between [0, 1] _A : List[str] = 'eta' in set(inspect.signature(self.scheduler.step ).parameters.keys() ) _A : Any = {} if accepts_eta: _A : Optional[int] = eta for i, t in enumerate(self.progress_bar(_snake_case ) ): # expand the latents if we are doing classifier free guidance _A : List[Any] = torch.cat([latents] * 2 ) if do_classifier_free_guidance else latents _A : Tuple = self.scheduler.scale_model_input(_snake_case , _snake_case ) # predict the noise residual _A : str = self.unet(_snake_case , _snake_case , encoder_hidden_states=_snake_case ).sample # perform guidance if do_classifier_free_guidance: _A : List[str] = noise_pred.chunk(2 ) _A : Optional[int] = noise_pred_uncond + guidance_scale * (noise_pred_text - noise_pred_uncond) # compute the previous noisy sample x_t -> x_t-1 _A : Union[str, Any] = self.scheduler.step(_snake_case , _snake_case , _snake_case , **_snake_case ).prev_sample # call the callback, if provided if callback is not None and i % callback_steps == 0: callback(_snake_case , _snake_case , _snake_case ) _A : Optional[int] = 1 / 0.18215 * latents _A : Tuple = self.vae.decode(_snake_case ).sample _A : Tuple = (image / 2 + 0.5).clamp(0 , 1 ) # we always cast to float32 as this does not cause significant overhead and is compatible with bfloat16 _A : int = image.cpu().permute(0 , 2 , 3 , 1 ).float().numpy() if output_type == "pil": _A : str = self.numpy_to_pil(_snake_case ) if not return_dict: return image return StableDiffusionPipelineOutput(images=_snake_case , nsfw_content_detected=_snake_case )
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import itertools import random import unittest import numpy as np from transformers import BatchFeature, SpeechTaFeatureExtractor from transformers.testing_utils import require_torch from transformers.utils.import_utils import is_torch_available from ...test_sequence_feature_extraction_common import SequenceFeatureExtractionTestMixin if is_torch_available(): import torch a_ :Any = random.Random() def lowercase_ (A : int , A : Union[str, Any]=1.0 , A : List[str]=None , A : Any=None ): if rng is None: snake_case__ : List[str] = global_rng snake_case__ : int = [] for batch_idx in range(shape[0] ): values.append([] ) for _ in range(shape[1] ): values[-1].append(rng.random() * scale ) return values @require_torch class snake_case__ ( unittest.TestCase ): """simple docstring""" def __init__( self : Optional[Any], _snake_case : List[str], _snake_case : Tuple=7, _snake_case : Union[str, Any]=4_0_0, _snake_case : Any=2_0_0_0, _snake_case : Dict=1, _snake_case : Optional[Any]=0.0, _snake_case : List[Any]=1_6_0_0_0, _snake_case : List[Any]=True, _snake_case : List[Any]=8_0, _snake_case : Dict=1_6, _snake_case : str=6_4, _snake_case : Tuple="hann_window", _snake_case : Union[str, Any]=8_0, _snake_case : Optional[Any]=7_6_0_0, _snake_case : str=1e-10, _snake_case : Any=True, ) ->Union[str, Any]: snake_case__ : Optional[int] = parent snake_case__ : Optional[Any] = batch_size snake_case__ : List[Any] = min_seq_length snake_case__ : List[Any] = max_seq_length snake_case__ : Any = (self.max_seq_length - self.min_seq_length) // (self.batch_size - 1) snake_case__ : Tuple = feature_size snake_case__ : List[Any] = padding_value snake_case__ : Any = sampling_rate snake_case__ : Dict = do_normalize snake_case__ : Union[str, Any] = num_mel_bins snake_case__ : Any = hop_length snake_case__ : Any = win_length snake_case__ : Any = win_function snake_case__ : Optional[int] = fmin snake_case__ : int = fmax snake_case__ : Union[str, Any] = mel_floor snake_case__ : Union[str, Any] = return_attention_mask def lowercase_ ( self : Optional[int] ) ->List[str]: return { "feature_size": self.feature_size, "padding_value": self.padding_value, "sampling_rate": self.sampling_rate, "do_normalize": self.do_normalize, "num_mel_bins": self.num_mel_bins, "hop_length": self.hop_length, "win_length": self.win_length, "win_function": self.win_function, "fmin": self.fmin, "fmax": self.fmax, "mel_floor": self.mel_floor, "return_attention_mask": self.return_attention_mask, } def lowercase_ ( self : Any, _snake_case : Optional[Any]=False, _snake_case : List[str]=False ) ->Union[str, Any]: def _flatten(_snake_case : List[str] ): return list(itertools.chain(*_snake_case ) ) if equal_length: snake_case__ : Any = floats_list((self.batch_size, self.max_seq_length) ) else: # make sure that inputs increase in size snake_case__ : int = [ _flatten(floats_list((x, self.feature_size) ) ) for x in range(self.min_seq_length, self.max_seq_length, self.seq_length_diff ) ] if numpify: snake_case__ : Any = [np.asarray(_snake_case ) for x in speech_inputs] return speech_inputs def lowercase_ ( self : Union[str, Any], _snake_case : str=False, _snake_case : Dict=False ) ->List[str]: if equal_length: snake_case__ : Optional[Any] = [floats_list((self.max_seq_length, self.num_mel_bins) ) for _ in range(self.batch_size )] else: # make sure that inputs increase in size snake_case__ : List[str] = [ floats_list((x, self.num_mel_bins) ) for x in range(self.min_seq_length, self.max_seq_length, self.seq_length_diff ) ] if numpify: snake_case__ : int = [np.asarray(_snake_case ) for x in speech_inputs] return speech_inputs @require_torch class snake_case__ ( lowerCAmelCase_ , unittest.TestCase ): """simple docstring""" _SCREAMING_SNAKE_CASE = SpeechTaFeatureExtractor def lowercase_ ( self : int ) ->Union[str, Any]: snake_case__ : List[str] = SpeechTaFeatureExtractionTester(self ) def lowercase_ ( self : Any, _snake_case : Dict ) ->Any: self.assertTrue(np.all(np.mean(_snake_case, axis=0 ) < 1e-3 ) ) self.assertTrue(np.all(np.abs(np.var(_snake_case, axis=0 ) - 1 ) < 1e-3 ) ) def lowercase_ ( self : List[Any] ) ->Union[str, Any]: # Tests that all call wrap to encode_plus and batch_encode_plus snake_case__ : Optional[Any] = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) # create three inputs of length 800, 1000, and 1200 snake_case__ : int = [floats_list((1, x) )[0] for x in range(8_0_0, 1_4_0_0, 2_0_0 )] snake_case__ : Tuple = [np.asarray(_snake_case ) for speech_input in speech_inputs] # Test not batched input snake_case__ : str = feat_extract(speech_inputs[0], return_tensors='np' ).input_values snake_case__ : List[str] = feat_extract(np_speech_inputs[0], return_tensors='np' ).input_values self.assertTrue(np.allclose(_snake_case, _snake_case, atol=1e-3 ) ) # Test batched snake_case__ : Any = feat_extract(_snake_case, return_tensors='np' ).input_values snake_case__ : Union[str, Any] = feat_extract(_snake_case, return_tensors='np' ).input_values for enc_seq_a, enc_seq_a in zip(_snake_case, _snake_case ): self.assertTrue(np.allclose(_snake_case, _snake_case, atol=1e-3 ) ) def lowercase_ ( self : int ) ->Optional[int]: snake_case__ : List[Any] = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) snake_case__ : Tuple = [floats_list((1, x) )[0] for x in range(8_0_0, 1_4_0_0, 2_0_0 )] snake_case__ : int = ['longest', 'max_length', 'do_not_pad'] snake_case__ : List[str] = [None, 1_6_0_0, None] for max_length, padding in zip(_snake_case, _snake_case ): snake_case__ : Optional[int] = feat_extract(_snake_case, padding=_snake_case, max_length=_snake_case, return_tensors='np' ) snake_case__ : Optional[int] = processed.input_values self._check_zero_mean_unit_variance(input_values[0][:8_0_0] ) self.assertTrue(input_values[0][8_0_0:].sum() < 1e-6 ) self._check_zero_mean_unit_variance(input_values[1][:1_0_0_0] ) self.assertTrue(input_values[0][1_0_0_0:].sum() < 1e-6 ) self._check_zero_mean_unit_variance(input_values[2][:1_2_0_0] ) def lowercase_ ( self : Union[str, Any] ) ->Optional[Any]: snake_case__ : Optional[Any] = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) snake_case__ : Tuple = range(8_0_0, 1_4_0_0, 2_0_0 ) snake_case__ : Optional[Any] = [floats_list((1, x) )[0] for x in lengths] snake_case__ : Union[str, Any] = ['longest', 'max_length', 'do_not_pad'] snake_case__ : str = [None, 1_6_0_0, None] for max_length, padding in zip(_snake_case, _snake_case ): snake_case__ : List[str] = feat_extract(_snake_case, max_length=_snake_case, padding=_snake_case ) snake_case__ : Tuple = processed.input_values self._check_zero_mean_unit_variance(input_values[0][:8_0_0] ) self._check_zero_mean_unit_variance(input_values[1][:1_0_0_0] ) self._check_zero_mean_unit_variance(input_values[2][:1_2_0_0] ) def lowercase_ ( self : List[Any] ) ->Optional[Any]: snake_case__ : Any = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) snake_case__ : str = [floats_list((1, x) )[0] for x in range(8_0_0, 1_4_0_0, 2_0_0 )] snake_case__ : Optional[Any] = feat_extract( _snake_case, truncation=_snake_case, max_length=1_0_0_0, padding='max_length', return_tensors='np' ) snake_case__ : int = processed.input_values self._check_zero_mean_unit_variance(input_values[0, :8_0_0] ) self._check_zero_mean_unit_variance(input_values[1] ) self._check_zero_mean_unit_variance(input_values[2] ) def lowercase_ ( self : int ) ->Union[str, Any]: snake_case__ : str = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) snake_case__ : Dict = [floats_list((1, x) )[0] for x in range(8_0_0, 1_4_0_0, 2_0_0 )] snake_case__ : str = feat_extract( _snake_case, truncation=_snake_case, max_length=1_0_0_0, padding='longest', return_tensors='np' ) snake_case__ : Dict = processed.input_values self._check_zero_mean_unit_variance(input_values[0, :8_0_0] ) self._check_zero_mean_unit_variance(input_values[1, :1_0_0_0] ) self._check_zero_mean_unit_variance(input_values[2] ) # make sure that if max_length < longest -> then pad to max_length self.assertTrue(input_values.shape == (3, 1_0_0_0) ) snake_case__ : Tuple = [floats_list((1, x) )[0] for x in range(8_0_0, 1_4_0_0, 2_0_0 )] snake_case__ : List[str] = feat_extract( _snake_case, truncation=_snake_case, max_length=2_0_0_0, padding='longest', return_tensors='np' ) snake_case__ : Optional[Any] = processed.input_values self._check_zero_mean_unit_variance(input_values[0, :8_0_0] ) self._check_zero_mean_unit_variance(input_values[1, :1_0_0_0] ) self._check_zero_mean_unit_variance(input_values[2] ) # make sure that if max_length > longest -> then pad to longest self.assertTrue(input_values.shape == (3, 1_2_0_0) ) def lowercase_ ( self : List[str] ) ->Dict: snake_case__ : Dict = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) snake_case__ : List[Any] = np.random.rand(1_0_0 ).astype(np.floataa ) snake_case__ : int = np_speech_inputs.tolist() for inputs in [py_speech_inputs, np_speech_inputs]: snake_case__ : int = feature_extractor.pad([{'input_values': inputs}], return_tensors='np' ) self.assertTrue(np_processed.input_values.dtype == np.floataa ) snake_case__ : Optional[int] = feature_extractor.pad([{'input_values': inputs}], return_tensors='pt' ) self.assertTrue(pt_processed.input_values.dtype == torch.floataa ) def lowercase_ ( self : Optional[int] ) ->Optional[Any]: # Tests that all call wrap to encode_plus and batch_encode_plus snake_case__ : str = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) # create three inputs of length 800, 1000, and 1200 snake_case__ : List[Any] = [floats_list((1, x) )[0] for x in range(8_0_0, 1_4_0_0, 2_0_0 )] snake_case__ : Dict = [np.asarray(_snake_case ) for speech_input in speech_inputs] # Test feature size snake_case__ : Optional[int] = feature_extractor(audio_target=_snake_case, padding=_snake_case, return_tensors='np' ).input_values self.assertTrue(input_values.ndim == 3 ) self.assertTrue(input_values.shape[-1] == feature_extractor.num_mel_bins ) # Test not batched input snake_case__ : Dict = feature_extractor(speech_inputs[0], return_tensors='np' ).input_values snake_case__ : Any = feature_extractor(np_speech_inputs[0], return_tensors='np' ).input_values self.assertTrue(np.allclose(_snake_case, _snake_case, atol=1e-3 ) ) # Test batched snake_case__ : Dict = feature_extractor(_snake_case, return_tensors='np' ).input_values snake_case__ : Dict = feature_extractor(_snake_case, return_tensors='np' ).input_values for enc_seq_a, enc_seq_a in zip(_snake_case, _snake_case ): self.assertTrue(np.allclose(_snake_case, _snake_case, atol=1e-3 ) ) # Test 2-D numpy arrays are batched. snake_case__ : Optional[Any] = [floats_list((1, x) )[0] for x in (8_0_0, 8_0_0, 8_0_0)] snake_case__ : int = np.asarray(_snake_case ) snake_case__ : Union[str, Any] = feature_extractor(_snake_case, return_tensors='np' ).input_values snake_case__ : Union[str, Any] = feature_extractor(_snake_case, return_tensors='np' ).input_values for enc_seq_a, enc_seq_a in zip(_snake_case, _snake_case ): self.assertTrue(np.allclose(_snake_case, _snake_case, atol=1e-3 ) ) def lowercase_ ( self : Union[str, Any] ) ->str: snake_case__ : int = self.feat_extract_tester.prepare_inputs_for_target() snake_case__ : List[str] = self.feature_extraction_class(**self.feat_extract_dict ) snake_case__ : Optional[Any] = feat_extract.model_input_names[0] snake_case__ : Tuple = BatchFeature({input_name: speech_inputs} ) self.assertTrue(all(len(_snake_case ) == len(_snake_case ) for x, y in zip(_snake_case, processed_features[input_name] ) ) ) snake_case__ : int = self.feat_extract_tester.prepare_inputs_for_target(equal_length=_snake_case ) snake_case__ : Union[str, Any] = BatchFeature({input_name: speech_inputs}, tensor_type='np' ) snake_case__ : Dict = processed_features[input_name] if len(batch_features_input.shape ) < 3: snake_case__ : List[str] = batch_features_input[:, :, None] self.assertTrue( batch_features_input.shape == (self.feat_extract_tester.batch_size, len(speech_inputs[0] ), self.feat_extract_tester.num_mel_bins) ) @require_torch def lowercase_ ( self : List[str] ) ->Any: snake_case__ : int = self.feat_extract_tester.prepare_inputs_for_target(equal_length=_snake_case ) snake_case__ : Optional[Any] = self.feature_extraction_class(**self.feat_extract_dict ) snake_case__ : Tuple = feat_extract.model_input_names[0] snake_case__ : List[Any] = BatchFeature({input_name: speech_inputs}, tensor_type='pt' ) snake_case__ : Tuple = processed_features[input_name] if len(batch_features_input.shape ) < 3: snake_case__ : Any = batch_features_input[:, :, None] self.assertTrue( batch_features_input.shape == (self.feat_extract_tester.batch_size, len(speech_inputs[0] ), self.feat_extract_tester.num_mel_bins) ) @require_torch def lowercase_ ( self : Optional[int] ) ->Tuple: snake_case__ : Dict = self.feature_extraction_class(**self.feat_extract_dict ) snake_case__ : Union[str, Any] = self.feat_extract_tester.prepare_inputs_for_target() snake_case__ : Optional[Any] = feat_extract.model_input_names[0] snake_case__ : List[str] = BatchFeature({input_name: speech_inputs} ) snake_case__ : int = feat_extract.num_mel_bins # hack! snake_case__ : Tuple = feat_extract.pad(_snake_case, padding='longest', return_tensors='np' )[input_name] snake_case__ : Union[str, Any] = feat_extract.pad(_snake_case, padding='longest', return_tensors='pt' )[input_name] self.assertTrue(abs(input_np.astype(np.floataa ).sum() - input_pt.numpy().astype(np.floataa ).sum() ) < 1e-2 ) def lowercase_ ( self : int ) ->Any: snake_case__ : Any = self.feat_extract_dict snake_case__ : List[Any] = True snake_case__ : Union[str, Any] = self.feature_extraction_class(**_snake_case ) snake_case__ : Any = self.feat_extract_tester.prepare_inputs_for_target() snake_case__ : List[Any] = [len(_snake_case ) for x in speech_inputs] snake_case__ : Union[str, Any] = feat_extract.model_input_names[0] snake_case__ : Optional[int] = BatchFeature({input_name: speech_inputs} ) snake_case__ : List[str] = feat_extract.num_mel_bins # hack! snake_case__ : str = feat_extract.pad(_snake_case, padding='longest', return_tensors='np' ) self.assertIn('attention_mask', _snake_case ) self.assertListEqual(list(processed.attention_mask.shape ), list(processed[input_name].shape[:2] ) ) self.assertListEqual(processed.attention_mask.sum(-1 ).tolist(), _snake_case ) def lowercase_ ( self : Optional[int] ) ->str: snake_case__ : int = self.feat_extract_dict snake_case__ : List[str] = True snake_case__ : Tuple = self.feature_extraction_class(**_snake_case ) snake_case__ : List[str] = self.feat_extract_tester.prepare_inputs_for_target() snake_case__ : str = [len(_snake_case ) for x in speech_inputs] snake_case__ : Optional[Any] = feat_extract.model_input_names[0] snake_case__ : Optional[int] = BatchFeature({input_name: speech_inputs} ) snake_case__ : Optional[Any] = min(_snake_case ) snake_case__ : Union[str, Any] = feat_extract.num_mel_bins # hack! snake_case__ : Tuple = feat_extract.pad( _snake_case, padding='max_length', max_length=_snake_case, truncation=_snake_case, return_tensors='np' ) self.assertIn('attention_mask', _snake_case ) self.assertListEqual( list(processed_pad.attention_mask.shape ), [processed_pad[input_name].shape[0], max_length] ) self.assertListEqual( processed_pad.attention_mask[:, :max_length].sum(-1 ).tolist(), [max_length for x in speech_inputs] ) def lowercase_ ( self : List[Any], _snake_case : Optional[int] ) ->Optional[Any]: from datasets import load_dataset snake_case__ : str = load_dataset('hf-internal-testing/librispeech_asr_dummy', 'clean', split='validation' ) # automatic decoding with librispeech snake_case__ : Dict = ds.sort('id' ).select(range(_snake_case ) )[:num_samples]['audio'] return [x["array"] for x in speech_samples] def lowercase_ ( self : str ) ->str: # fmt: off snake_case__ : List[Any] = torch.tensor( [2.3804e-03, 2.0752e-03, 1.9836e-03, 2.1057e-03, 1.6174e-03, 3.0518e-04, 9.1553e-05, 3.3569e-04, 9.7656e-04, 1.8311e-03, 2.0142e-03, 2.1057e-03, 1.7395e-03, 4.5776e-04, -3.9673e-04, 4.5776e-04, 1.0071e-03, 9.1553e-05, 4.8828e-04, 1.1597e-03, 7.3242e-04, 9.4604e-04, 1.8005e-03, 1.8311e-03, 8.8501e-04, 4.2725e-04, 4.8828e-04, 7.3242e-04, 1.0986e-03, 2.1057e-03] ) # fmt: on snake_case__ : Union[str, Any] = self._load_datasamples(1 ) snake_case__ : Optional[int] = SpeechTaFeatureExtractor() snake_case__ : List[Any] = feature_extractor(_snake_case, return_tensors='pt' ).input_values self.assertEquals(input_values.shape, (1, 9_3_6_8_0) ) self.assertTrue(torch.allclose(input_values[0, :3_0], _snake_case, atol=1e-6 ) ) def lowercase_ ( self : Any ) ->str: # fmt: off snake_case__ : Optional[Any] = torch.tensor( [-2.6_8_7_0, -3.0_1_0_4, -3.1_3_5_6, -3.5_3_5_2, -3.0_0_4_4, -3.0_3_5_3, -3.4_7_1_9, -3.6_7_7_7, -3.1_5_2_0, -2.9_4_3_5, -2.6_5_5_3, -2.8_7_9_5, -2.9_9_4_4, -2.5_9_2_1, -3.0_2_7_9, -3.0_3_8_6, -3.0_8_6_4, -3.1_2_9_1, -3.2_3_5_3, -2.7_4_4_4, -2.6_8_3_1, -2.7_2_8_7, -3.1_7_6_1, -3.1_5_7_1, -3.2_7_2_6, -3.0_5_8_2, -3.1_0_0_7, -3.4_5_3_3, -3.4_6_9_5, -3.0_9_9_8] ) # fmt: on snake_case__ : List[str] = self._load_datasamples(1 ) snake_case__ : str = SpeechTaFeatureExtractor() snake_case__ : Optional[Any] = feature_extractor(audio_target=_snake_case, return_tensors='pt' ).input_values self.assertEquals(input_values.shape, (1, 3_6_6, 8_0) ) self.assertTrue(torch.allclose(input_values[0, 0, :3_0], _snake_case, atol=1e-4 ) )
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import dataclasses import json import warnings from dataclasses import dataclass, field from time import time from typing import List from ..utils import logging UpperCAmelCase__ = logging.get_logger(__name__) def A ( _UpperCAmelCase : Tuple=None , _UpperCAmelCase : Tuple=None ) -> Dict: '''simple docstring''' return field(default_factory=lambda: default , metadata=_UpperCAmelCase ) @dataclass class __lowerCAmelCase : UpperCamelCase = list_field( default=[] , metadata={ '''help''': ( '''Model checkpoints to be provided to the AutoModel classes. Leave blank to benchmark the base version''' ''' of all available models''' ) } , ) UpperCamelCase = list_field( default=[8] , metadata={'''help''': '''List of batch sizes for which memory and time performance will be evaluated'''} ) UpperCamelCase = list_field( default=[8, 3_2, 1_2_8, 5_1_2] , metadata={'''help''': '''List of sequence lengths for which memory and time performance will be evaluated'''} , ) UpperCamelCase = field( default=lowerCAmelCase_ , metadata={'''help''': '''Whether to benchmark inference of model. Inference can be disabled via --no-inference.'''} , ) UpperCamelCase = field( default=lowerCAmelCase_ , metadata={'''help''': '''Whether to run on available cuda devices. Cuda can be disabled via --no-cuda.'''} , ) UpperCamelCase = field( default=lowerCAmelCase_ , metadata={'''help''': '''Whether to run on available tpu devices. TPU can be disabled via --no-tpu.'''} ) UpperCamelCase = field(default=lowerCAmelCase_ , metadata={'''help''': '''Use FP16 to accelerate inference.'''} ) UpperCamelCase = field(default=lowerCAmelCase_ , metadata={'''help''': '''Benchmark training of model'''} ) UpperCamelCase = field(default=lowerCAmelCase_ , metadata={'''help''': '''Verbose memory tracing'''} ) UpperCamelCase = field( default=lowerCAmelCase_ , metadata={'''help''': '''Whether to perform speed measurements. Speed measurements can be disabled via --no-speed.'''} , ) UpperCamelCase = field( default=lowerCAmelCase_ , metadata={ '''help''': '''Whether to perform memory measurements. Memory measurements can be disabled via --no-memory''' } , ) UpperCamelCase = field(default=lowerCAmelCase_ , metadata={'''help''': '''Trace memory line by line'''} ) UpperCamelCase = field(default=lowerCAmelCase_ , metadata={'''help''': '''Save result to a CSV file'''} ) UpperCamelCase = field(default=lowerCAmelCase_ , metadata={'''help''': '''Save all print statements in a log file'''} ) UpperCamelCase = field(default=lowerCAmelCase_ , metadata={'''help''': '''Whether to print environment information'''} ) UpperCamelCase = field( default=lowerCAmelCase_ , metadata={ '''help''': ( '''Whether to use multiprocessing for memory and speed measurement. It is highly recommended to use''' ''' multiprocessing for accurate CPU and GPU memory measurements. This option should only be disabled''' ''' for debugging / testing and on TPU.''' ) } , ) UpperCamelCase = field( default=f'''inference_time_{round(time() )}.csv''' , metadata={'''help''': '''CSV filename used if saving time results to csv.'''} , ) UpperCamelCase = field( default=f'''inference_memory_{round(time() )}.csv''' , metadata={'''help''': '''CSV filename used if saving memory results to csv.'''} , ) UpperCamelCase = field( default=f'''train_time_{round(time() )}.csv''' , metadata={'''help''': '''CSV filename used if saving time results to csv for training.'''} , ) UpperCamelCase = field( default=f'''train_memory_{round(time() )}.csv''' , metadata={'''help''': '''CSV filename used if saving memory results to csv for training.'''} , ) UpperCamelCase = field( default=f'''env_info_{round(time() )}.csv''' , metadata={'''help''': '''CSV filename used if saving environment information.'''} , ) UpperCamelCase = field( default=f'''log_{round(time() )}.csv''' , metadata={'''help''': '''Log filename used if print statements are saved in log.'''} , ) UpperCamelCase = field(default=3 , metadata={'''help''': '''Times an experiment will be run.'''} ) UpperCamelCase = field( default=lowerCAmelCase_ , metadata={ '''help''': ( '''Instead of loading the model as defined in `config.architectures` if exists, just load the pretrain''' ''' model weights.''' ) } , ) def _lowerCamelCase ( self : Optional[Any]) -> List[str]: """simple docstring""" warnings.warn( F"The class {self.__class__} is deprecated. Hugging Face Benchmarking utils" ' are deprecated in general and it is advised to use external Benchmarking libraries ' ' to benchmark Transformer models.' , _snake_case , ) def _lowerCamelCase ( self : Tuple) -> int: """simple docstring""" return json.dumps(dataclasses.asdict(self) , indent=2) @property def _lowerCamelCase ( self : Optional[Any]) -> List[str]: """simple docstring""" if len(self.models) <= 0: raise ValueError( 'Please make sure you provide at least one model name / model identifier, *e.g.* `--models' ' bert-base-cased` or `args.models = [\'bert-base-cased\'].') return self.models @property def _lowerCamelCase ( self : Union[str, Any]) -> Tuple: """simple docstring""" if not self.multi_process: return False elif self.is_tpu: logger.info('Multiprocessing is currently not possible on TPU.') return False else: return True
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# Copyright 2023 The HuggingFace Inc. team. All rights reserved. # # Licensed under the Apache License, Version 2.0 (the "License"); # you may not use this file except in compliance with the License. # You may obtain a copy of the License at # # http://www.apache.org/licenses/LICENSE-2.0 # # Unless required by applicable law or agreed to in writing, software # distributed under the License is distributed on an "AS IS" BASIS, # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. # See the License for the specific language governing permissions and # limitations under the License. from ..models.auto import AutoModelForSeqaSeqLM, AutoTokenizer from .base import PipelineTool class snake_case__ ( lowerCAmelCase_ ): """simple docstring""" _SCREAMING_SNAKE_CASE = """philschmid/bart-large-cnn-samsum""" _SCREAMING_SNAKE_CASE = ( """This is a tool that summarizes an English text. It takes an input `text` containing the text to summarize, """ """and returns a summary of the text.""" ) _SCREAMING_SNAKE_CASE = """summarizer""" _SCREAMING_SNAKE_CASE = AutoTokenizer _SCREAMING_SNAKE_CASE = AutoModelForSeqaSeqLM _SCREAMING_SNAKE_CASE = ["""text"""] _SCREAMING_SNAKE_CASE = ["""text"""] def lowercase_ ( self : Optional[Any], _snake_case : str ) ->Any: return self.pre_processor(_snake_case, return_tensors='pt', truncation=_snake_case ) def lowercase_ ( self : int, _snake_case : List[Any] ) ->Any: return self.model.generate(**_snake_case )[0] def lowercase_ ( self : int, _snake_case : int ) ->str: return self.pre_processor.decode(_snake_case, skip_special_tokens=_snake_case, clean_up_tokenization_spaces=_snake_case )
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# Copyright 2023 The HuggingFace Inc. team. All rights reserved. # # Licensed under the Apache License, Version 2.0 (the "License"); # you may not use this file except in compliance with the License. # You may obtain a copy of the License at # # http://www.apache.org/licenses/LICENSE-2.0 # # Unless required by applicable law or agreed to in writing, software # distributed under the License is distributed on an "AS IS" BASIS, # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. # See the License for the specific language governing permissions and # limitations under the License. from ..models.auto import AutoModelForSeqaSeqLM, AutoTokenizer from .base import PipelineTool class UpperCamelCase_ ( lowerCAmelCase_ ): '''simple docstring''' lowerCAmelCase = '''philschmid/bart-large-cnn-samsum''' lowerCAmelCase = ( '''This is a tool that summarizes an English text. It takes an input `text` containing the text to summarize, ''' '''and returns a summary of the text.''' ) lowerCAmelCase = '''summarizer''' lowerCAmelCase = AutoTokenizer lowerCAmelCase = AutoModelForSeqaSeqLM lowerCAmelCase = ['''text'''] lowerCAmelCase = ['''text'''] def _UpperCamelCase ( self , a ) -> Any: return self.pre_processor(_snake_case , return_tensors='pt' , truncation=_snake_case ) def _UpperCamelCase ( self , a ) -> Any: return self.model.generate(**_snake_case )[0] def _UpperCamelCase ( self , a ) -> str: return self.pre_processor.decode(_snake_case , skip_special_tokens=_snake_case , clean_up_tokenization_spaces=_snake_case )
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import argparse import torch from transformers import LxmertConfig, LxmertForPreTraining, load_tf_weights_in_lxmert from transformers.utils import logging logging.set_verbosity_info() def lowercase_ (A : str , A : List[Any] , A : Any ): # Initialise PyTorch model snake_case__ : List[Any] = LxmertConfig.from_json_file(A ) print(F'''Building PyTorch model from configuration: {config}''' ) snake_case__ : List[str] = LxmertForPreTraining(A ) # Load weights from tf checkpoint load_tf_weights_in_lxmert(A , A , A ) # Save pytorch-model print(F'''Save PyTorch model to {pytorch_dump_path}''' ) torch.save(model.state_dict() , A ) if __name__ == "__main__": a_ :Union[str, Any] = argparse.ArgumentParser() # Required parameters parser.add_argument( "--tf_checkpoint_path", default=None, type=str, required=True, help="Path to the TensorFlow checkpoint path." ) parser.add_argument( "--config_file", default=None, type=str, required=True, help="The config json file corresponding to the pre-trained model. \nThis specifies the model architecture.", ) parser.add_argument( "--pytorch_dump_path", default=None, type=str, required=True, help="Path to the output PyTorch model." ) a_ :Optional[int] = parser.parse_args() convert_tf_checkpoint_to_pytorch(args.tf_checkpoint_path, args.config_file, args.pytorch_dump_path)
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"""simple docstring""" from typing import List from ...configuration_utils import PretrainedConfig from ...utils import logging __UpperCamelCase = logging.get_logger(__name__) __UpperCamelCase = { "snap-research/efficientformer-l1-300": ( "https://huggingface.co/snap-research/efficientformer-l1-300/resolve/main/config.json" ), } class lowerCAmelCase ( lowerCAmelCase_ ): '''simple docstring''' SCREAMING_SNAKE_CASE_ : Tuple = """efficientformer""" def __init__( self , lowerCAmelCase__ = [3, 2, 6, 4] , lowerCAmelCase__ = [48, 96, 224, 448] , lowerCAmelCase__ = [True, True, True, True] , lowerCAmelCase__ = 448 , lowerCAmelCase__ = 32 , lowerCAmelCase__ = 4 , lowerCAmelCase__ = 7 , lowerCAmelCase__ = 5 , lowerCAmelCase__ = 8 , lowerCAmelCase__ = 4 , lowerCAmelCase__ = 0.0 , lowerCAmelCase__ = 16 , lowerCAmelCase__ = 3 , lowerCAmelCase__ = 3 , lowerCAmelCase__ = 3 , lowerCAmelCase__ = 2 , lowerCAmelCase__ = 1 , lowerCAmelCase__ = 0.0 , lowerCAmelCase__ = 1 , lowerCAmelCase__ = True , lowerCAmelCase__ = True , lowerCAmelCase__ = 1e-5 , lowerCAmelCase__ = "gelu" , lowerCAmelCase__ = 0.02 , lowerCAmelCase__ = 1e-12 , lowerCAmelCase__ = 224 , lowerCAmelCase__ = 1e-05 , **lowerCAmelCase__ , ) -> None: super().__init__(**_snake_case ) SCREAMING_SNAKE_CASE = hidden_act SCREAMING_SNAKE_CASE = hidden_dropout_prob SCREAMING_SNAKE_CASE = hidden_sizes SCREAMING_SNAKE_CASE = num_hidden_layers SCREAMING_SNAKE_CASE = num_attention_heads SCREAMING_SNAKE_CASE = initializer_range SCREAMING_SNAKE_CASE = layer_norm_eps SCREAMING_SNAKE_CASE = patch_size SCREAMING_SNAKE_CASE = num_channels SCREAMING_SNAKE_CASE = depths SCREAMING_SNAKE_CASE = mlp_expansion_ratio SCREAMING_SNAKE_CASE = downsamples SCREAMING_SNAKE_CASE = dim SCREAMING_SNAKE_CASE = key_dim SCREAMING_SNAKE_CASE = attention_ratio SCREAMING_SNAKE_CASE = resolution SCREAMING_SNAKE_CASE = pool_size SCREAMING_SNAKE_CASE = downsample_patch_size SCREAMING_SNAKE_CASE = downsample_stride SCREAMING_SNAKE_CASE = downsample_pad SCREAMING_SNAKE_CASE = drop_path_rate SCREAMING_SNAKE_CASE = num_metaad_blocks SCREAMING_SNAKE_CASE = distillation SCREAMING_SNAKE_CASE = use_layer_scale SCREAMING_SNAKE_CASE = layer_scale_init_value SCREAMING_SNAKE_CASE = image_size SCREAMING_SNAKE_CASE = batch_norm_eps
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import argparse import fairseq import torch from torch import nn from transformers import ( MBartaaTokenizer, MBartConfig, MBartForCausalLM, SpeechEncoderDecoderConfig, SpeechEncoderDecoderModel, WavaVecaConfig, WavaVecaFeatureExtractor, WavaVecaModel, logging, ) logging.set_verbosity_info() a_ :Tuple = logging.get_logger(__name__) a_ :List[Any] = { "post_extract_proj": "feature_projection.projection", "encoder.pos_conv.0": "encoder.pos_conv_embed.conv", "self_attn.k_proj": "encoder.layers.*.attention.k_proj", "self_attn.v_proj": "encoder.layers.*.attention.v_proj", "self_attn.q_proj": "encoder.layers.*.attention.q_proj", "self_attn.out_proj": "encoder.layers.*.attention.out_proj", "self_attn_layer_norm": "encoder.layers.*.layer_norm", "fc1": "encoder.layers.*.feed_forward.intermediate_dense", "fc2": "encoder.layers.*.feed_forward.output_dense", "final_layer_norm": "encoder.layers.*.final_layer_norm", "encoder.layer_norm": "encoder.layer_norm", "w2v_model.layer_norm": "feature_projection.layer_norm", "quantizer.weight_proj": "quantizer.weight_proj", "quantizer.vars": "quantizer.codevectors", "project_q": "project_q", "final_proj": "project_hid", "w2v_encoder.proj": "lm_head", "mask_emb": "masked_spec_embed", } a_ :Optional[int] = [ "lm_head", "quantizer.weight_proj", "quantizer.codevectors", "project_q", "project_hid", ] def lowercase_ (A : Union[str, Any] , A : str , A : Dict , A : Optional[Any] , A : Optional[Any] ): for attribute in key.split('.' ): snake_case__ : Any = getattr(A , A ) if weight_type is not None: snake_case__ : Optional[Any] = getattr(A , A ).shape else: snake_case__ : Optional[int] = hf_pointer.shape assert hf_shape == value.shape, ( F'''Shape of hf {key + "." + weight_type if weight_type is not None else ""} is {hf_shape}, but should be''' F''' {value.shape} for {full_name}''' ) if weight_type == "weight": snake_case__ : Tuple = value elif weight_type == "weight_g": snake_case__ : Tuple = value elif weight_type == "weight_v": snake_case__ : List[Any] = value elif weight_type == "bias": snake_case__ : List[Any] = value else: snake_case__ : Optional[Any] = value logger.info(F'''{key + "." + weight_type if weight_type is not None else ""} was initialized from {full_name}.''' ) def lowercase_ (A : str , A : Any ): snake_case__ : Union[str, Any] = [] snake_case__ : Union[str, Any] = fairseq_model.state_dict() snake_case__ : Union[str, Any] = hf_model.feature_extractor snake_case__ : Any = hf_model.adapter for name, value in fairseq_dict.items(): snake_case__ : Any = False if "conv_layers" in name: load_conv_layer( A , A , A , A , hf_model.config.feat_extract_norm == 'group' , ) snake_case__ : List[Any] = True elif any(x in name for x in ['adaptor', 'w2v_encoder.proj.', 'w2v_proj_ln.'] ): load_adapter(A , A , A , A ) snake_case__ : Optional[Any] = True else: for key, mapped_key in MAPPING.items(): if key in name or key.split('w2v_model.' )[-1] == name.split('.' )[0]: snake_case__ : Tuple = True if "*" in mapped_key: snake_case__ : List[Any] = name.split(A )[0].split('.' )[-2] snake_case__ : Optional[int] = mapped_key.replace('*' , A ) if "weight_g" in name: snake_case__ : Optional[int] = 'weight_g' elif "weight_v" in name: snake_case__ : Optional[Any] = 'weight_v' elif "bias" in name: snake_case__ : Union[str, Any] = 'bias' elif "weight" in name: snake_case__ : Optional[int] = 'weight' else: snake_case__ : Tuple = None set_recursively(A , A , A , A , A ) continue if not is_used: unused_weights.append(A ) logger.warning(F'''Unused weights: {unused_weights}''' ) def lowercase_ (A : Union[str, Any] , A : Any , A : str , A : str , A : int ): snake_case__ : str = full_name.split('conv_layers.' )[-1] snake_case__ : Optional[int] = name.split('.' ) snake_case__ : Tuple = int(items[0] ) snake_case__ : Any = int(items[1] ) if type_id == 0: if "bias" in name: assert value.shape == feature_extractor.conv_layers[layer_id].conv.bias.data.shape, ( F'''{full_name} has size {value.shape}, but''' F''' {feature_extractor.conv_layers[layer_id].conv.bias.data.shape} was found.''' ) snake_case__ : Union[str, Any] = value logger.info(F'''Feat extract conv layer {layer_id} was initialized from {full_name}.''' ) elif "weight" in name: assert value.shape == feature_extractor.conv_layers[layer_id].conv.weight.data.shape, ( F'''{full_name} has size {value.shape}, but''' F''' {feature_extractor.conv_layers[layer_id].conv.weight.data.shape} was found.''' ) snake_case__ : Union[str, Any] = value logger.info(F'''Feat extract conv layer {layer_id} was initialized from {full_name}.''' ) elif (type_id == 2 and not use_group_norm) or (type_id == 2 and layer_id == 0 and use_group_norm): if "bias" in name: assert value.shape == feature_extractor.conv_layers[layer_id].layer_norm.bias.data.shape, ( F'''{full_name} has size {value.shape}, but {feature_extractor[layer_id].layer_norm.bias.data.shape} was''' " found." ) snake_case__ : Optional[int] = value logger.info(F'''Feat extract layer norm weight of layer {layer_id} was initialized from {full_name}.''' ) elif "weight" in name: assert value.shape == feature_extractor.conv_layers[layer_id].layer_norm.weight.data.shape, ( F'''{full_name} has size {value.shape}, but''' F''' {feature_extractor[layer_id].layer_norm.weight.data.shape} was found.''' ) snake_case__ : Optional[Any] = value logger.info(F'''Feat extract layer norm weight of layer {layer_id} was initialized from {full_name}.''' ) else: unused_weights.append(A ) def lowercase_ (A : Optional[Any] , A : Any , A : Tuple , A : Any ): snake_case__ : List[str] = full_name.split('adaptor.' )[-1] snake_case__ : Tuple = name.split('.' ) if items[1].isdigit(): snake_case__ : Optional[int] = int(items[1] ) else: snake_case__ : Any = None if "adaptor" not in full_name: if "proj_ln" in full_name: # has to be layer norm if "bias" in name: assert ( value.shape == adapter.proj_layer_norm.bias.data.shape ), F'''{full_name} has size {value.shape}, but {adapter.proj_layer_norm.bias.data.shape} was found.''' snake_case__ : List[Any] = value logger.info(F'''Adapter proj layer norm bias was initialized from {full_name}.''' ) if "weight" in name: assert ( value.shape == adapter.proj_layer_norm.weight.data.shape ), F'''{full_name} has size {value.shape}, but {adapter.proj_layer_norm.weight.data.shape} was found.''' snake_case__ : int = value else: # has to be projection layer if "bias" in name: assert ( value.shape == adapter.proj.bias.data.shape ), F'''{full_name} has size {value.shape}, but {adapter.proj.bias.data.shape} was found.''' snake_case__ : str = value logger.info(F'''Adapter proj layer bias was initialized from {full_name}.''' ) if "weight" in name: assert ( value.shape == adapter.proj.weight.data.shape ), F'''{full_name} has size {value.shape}, but {adapter.proj.weight.data.shape} was found.''' snake_case__ : Dict = value logger.info(F'''Adapter proj layer weight was initialized from {full_name}.''' ) elif isinstance(A , A ): if "bias" in name: assert ( value.shape == adapter.layers[layer_id].conv.bias.data.shape ), F'''{full_name} has size {value.shape}, but {adapter.layers[layer_id].conv.bias.data.shape} was found.''' snake_case__ : List[str] = value logger.info(F'''Adapter layer {layer_id} bias was initialized from {full_name}.''' ) elif "weight" in name: assert ( value.shape == adapter.layers[layer_id].conv.weight.data.shape ), F'''{full_name} has size {value.shape}, but {adapter.layers[layer_id].conv.weight.data.shape} was found.''' snake_case__ : List[str] = value logger.info(F'''Adapter layer {layer_id} bias was initialized from {full_name}.''' ) else: unused_weights.append(A ) def lowercase_ (A : int ): snake_case__ , snake_case__ : Union[str, Any] = emb.weight.shape snake_case__ : int = nn.Linear(A , A , bias=A ) snake_case__ : Optional[Any] = emb.weight.data return lin_layer @torch.no_grad() def lowercase_ (A : Tuple , A : Tuple , A : Any , A : Optional[Any] , A : int , A : Optional[Any] , A : Union[str, Any] , A : Union[str, Any] , A : Optional[Any] , A : List[Any] , A : Union[str, Any] , ): snake_case__ : Optional[Any] = WavaVecaConfig.from_pretrained( A , add_adapter=A , adapter_stride=A , adapter_kernel_size=A , use_auth_token=A , output_hidden_size=A , ) snake_case__ : Dict = MBartConfig.from_pretrained(A ) # load model snake_case__ , snake_case__ , snake_case__ : Any = fairseq.checkpoint_utils.load_model_ensemble_and_task( [checkpoint_path] , arg_overrides={ 'config_yaml': config_yaml_path, 'data': '/'.join(dict_path.split('/' )[:-1] ), 'w2v_path': checkpoint_path, 'load_pretrained_decoder_from': None, } , ) snake_case__ : List[Any] = model[0].eval() # load feature extractor snake_case__ : str = WavaVecaFeatureExtractor.from_pretrained(A , use_auth_token=A ) # set weights for wav2vec2 encoder snake_case__ : List[str] = WavaVecaModel(A ) recursively_load_weights_wavaveca(model.encoder , A ) # load decoder weights snake_case__ : Any = MBartForCausalLM(A ) snake_case__ , snake_case__ : int = hf_decoder.model.decoder.load_state_dict(model.decoder.state_dict() , strict=A ) logger.warning(F'''The following keys are missing when loading the decoder weights: {missing_keys}''' ) logger.warning(F'''The following keys are unexpected when loading the decoder weights: {unexpected_keys}''' ) snake_case__ : Union[str, Any] = SpeechEncoderDecoderModel(encoder=A , decoder=A ) snake_case__ : str = False snake_case__ : int = MBartaaTokenizer(A ) tokenizer.save_pretrained(A ) snake_case__ : Any = hf_wavavec.config.to_dict() snake_case__ : Tuple = tokenizer.pad_token_id snake_case__ : Union[str, Any] = tokenizer.bos_token_id snake_case__ : Dict = tokenizer.eos_token_id snake_case__ : Optional[int] = 'mbart50' snake_case__ : Union[str, Any] = 'wav2vec2' snake_case__ : List[str] = tokenizer.eos_token_id snake_case__ : Union[str, Any] = 2_5_0_0_0_4 snake_case__ : int = tokenizer.eos_token_id snake_case__ : Union[str, Any] = SpeechEncoderDecoderConfig.from_dict(A ) hf_wavavec.save_pretrained(A ) feature_extractor.save_pretrained(A ) if __name__ == "__main__": a_ :str = argparse.ArgumentParser() parser.add_argument("--pytorch_dump_folder_path", default=None, type=str, help="Path to the output PyTorch model.") parser.add_argument("--checkpoint_path", default=None, type=str, help="Path to fairseq checkpoint") parser.add_argument("--dict_path", default=None, type=str, help="Path to dict of fine-tuned model") parser.add_argument("--config_yaml_path", default=None, type=str, help="Path to yaml file of fine-tuned model") parser.add_argument( "--encoder_config_path", default="facebook/wav2vec2-xls-r-1b", type=str, help="Path to hf encoder wav2vec2 checkpoint config", ) parser.add_argument( "--decoder_config_path", default="facebook/mbart-large-50-one-to-many-mmt", type=str, help="Path to hf decoder checkpoint config", ) parser.add_argument("--add_adapter", default=True, type=bool, help="whethere to add model adapter layers") parser.add_argument("--adapter_stride", default=2, type=int, help="stride of adapter layers") parser.add_argument("--adapter_kernel_size", default=3, type=int, help="kernel size of adapter layers") parser.add_argument("--encoder_output_dim", default=1_024, type=int, help="encoder output dim") parser.add_argument("--start_token_id", default=250_004, type=int, help="`decoder_start_token_id` of model config") a_ :Union[str, Any] = parser.parse_args() convert_wavaveca_checkpoint( args.checkpoint_path, args.pytorch_dump_folder_path, args.dict_path, args.config_yaml_path, encoder_config_path=args.encoder_config_path, decoder_config_path=args.decoder_config_path, add_adapter=args.add_adapter, adapter_kernel_size=args.adapter_kernel_size, adapter_stride=args.adapter_stride, decoder_start_token_id=args.start_token_id, encoder_output_dim=args.encoder_output_dim, )
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'''simple docstring''' from typing import TYPE_CHECKING from ...utils import OptionalDependencyNotAvailable, _LazyModule, is_flax_available, is_torch_available _A : int = { "configuration_longt5": ["LONGT5_PRETRAINED_CONFIG_ARCHIVE_MAP", "LongT5Config", "LongT5OnnxConfig"], } try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: _A : List[str] = [ "LONGT5_PRETRAINED_MODEL_ARCHIVE_LIST", "LongT5EncoderModel", "LongT5ForConditionalGeneration", "LongT5Model", "LongT5PreTrainedModel", ] try: if not is_flax_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: _A : int = [ "FlaxLongT5ForConditionalGeneration", "FlaxLongT5Model", "FlaxLongT5PreTrainedModel", ] if TYPE_CHECKING: from .configuration_longta import LONGT5_PRETRAINED_CONFIG_ARCHIVE_MAP, LongTaConfig, LongTaOnnxConfig try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_longta import ( LONGT5_PRETRAINED_MODEL_ARCHIVE_LIST, LongTaEncoderModel, LongTaForConditionalGeneration, LongTaModel, LongTaPreTrainedModel, ) try: if not is_flax_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_flax_longta import ( FlaxLongTaForConditionalGeneration, FlaxLongTaModel, FlaxLongTaPreTrainedModel, ) else: import sys _A : Optional[int] = _LazyModule(__name__, globals()['''__file__'''], _import_structure, module_spec=__spec__)
229
from collections import OrderedDict from typing import TYPE_CHECKING, Any, Mapping, Optional, Union from ...configuration_utils import PretrainedConfig from ...onnx import OnnxConfig from ...utils import logging if TYPE_CHECKING: from ... import FeatureExtractionMixin, PreTrainedTokenizerBase, TensorType a_ :Tuple = logging.get_logger(__name__) a_ :Union[str, Any] = { "microsoft/deberta-v2-xlarge": "https://huggingface.co/microsoft/deberta-v2-xlarge/resolve/main/config.json", "microsoft/deberta-v2-xxlarge": "https://huggingface.co/microsoft/deberta-v2-xxlarge/resolve/main/config.json", "microsoft/deberta-v2-xlarge-mnli": ( "https://huggingface.co/microsoft/deberta-v2-xlarge-mnli/resolve/main/config.json" ), "microsoft/deberta-v2-xxlarge-mnli": ( "https://huggingface.co/microsoft/deberta-v2-xxlarge-mnli/resolve/main/config.json" ), } class snake_case__ ( lowerCAmelCase_ ): """simple docstring""" _SCREAMING_SNAKE_CASE = """deberta-v2""" def __init__( self : Union[str, Any], _snake_case : Dict=1_2_8_1_0_0, _snake_case : Any=1_5_3_6, _snake_case : Tuple=2_4, _snake_case : int=2_4, _snake_case : Optional[int]=6_1_4_4, _snake_case : Optional[int]="gelu", _snake_case : Optional[int]=0.1, _snake_case : List[str]=0.1, _snake_case : str=5_1_2, _snake_case : Optional[int]=0, _snake_case : Optional[int]=0.0_2, _snake_case : Dict=1e-7, _snake_case : int=False, _snake_case : Any=-1, _snake_case : List[str]=0, _snake_case : Tuple=True, _snake_case : Any=None, _snake_case : Union[str, Any]=0, _snake_case : Tuple="gelu", **_snake_case : Union[str, Any], ) ->Optional[int]: super().__init__(**_snake_case ) snake_case__ : Dict = hidden_size snake_case__ : Optional[int] = num_hidden_layers snake_case__ : Any = num_attention_heads snake_case__ : List[Any] = intermediate_size snake_case__ : List[Any] = hidden_act snake_case__ : Union[str, Any] = hidden_dropout_prob snake_case__ : Dict = attention_probs_dropout_prob snake_case__ : List[str] = max_position_embeddings snake_case__ : List[str] = type_vocab_size snake_case__ : Optional[Any] = initializer_range snake_case__ : Optional[int] = relative_attention snake_case__ : Tuple = max_relative_positions snake_case__ : Union[str, Any] = pad_token_id snake_case__ : Optional[int] = position_biased_input # Backwards compatibility if type(_snake_case ) == str: snake_case__ : int = [x.strip() for x in pos_att_type.lower().split('|' )] snake_case__ : List[str] = pos_att_type snake_case__ : Union[str, Any] = vocab_size snake_case__ : Optional[int] = layer_norm_eps snake_case__ : Optional[int] = kwargs.get('pooler_hidden_size', _snake_case ) snake_case__ : int = pooler_dropout snake_case__ : str = pooler_hidden_act class snake_case__ ( lowerCAmelCase_ ): """simple docstring""" @property def lowercase_ ( self : Optional[int] ) ->Mapping[str, Mapping[int, str]]: if self.task == "multiple-choice": snake_case__ : List[Any] = {0: 'batch', 1: 'choice', 2: 'sequence'} else: snake_case__ : int = {0: 'batch', 1: 'sequence'} if self._config.type_vocab_size > 0: return OrderedDict( [('input_ids', dynamic_axis), ('attention_mask', dynamic_axis), ('token_type_ids', dynamic_axis)] ) else: return OrderedDict([('input_ids', dynamic_axis), ('attention_mask', dynamic_axis)] ) @property def lowercase_ ( self : Dict ) ->int: return 1_2 def lowercase_ ( self : Tuple, _snake_case : Union["PreTrainedTokenizerBase", "FeatureExtractionMixin"], _snake_case : int = -1, _snake_case : int = -1, _snake_case : int = -1, _snake_case : bool = False, _snake_case : Optional["TensorType"] = None, _snake_case : int = 3, _snake_case : int = 4_0, _snake_case : int = 4_0, _snake_case : "PreTrainedTokenizerBase" = None, ) ->Mapping[str, Any]: snake_case__ : Union[str, Any] = super().generate_dummy_inputs(preprocessor=_snake_case, framework=_snake_case ) if self._config.type_vocab_size == 0 and "token_type_ids" in dummy_inputs: del dummy_inputs["token_type_ids"] return dummy_inputs
277
0
"""simple docstring""" import requests UpperCAmelCase = "YOUR API KEY" def lowercase ( a__ : str , a__ : str = giphy_api_key ) -> Optional[Any]: _UpperCamelCase = '+'.join(query.split() ) _UpperCamelCase = F'''https://api.giphy.com/v1/gifs/search?q={formatted_query}&api_key={api_key}''' _UpperCamelCase = requests.get(a__ ).json()['data'] return [gif["url"] for gif in gifs] if __name__ == "__main__": print("""\n""".join(get_gifs("""space ship""")))
256
import argparse import json import pickle from pathlib import Path import requests import torch from huggingface_hub import hf_hub_download from PIL import Image from transformers import MaskFormerConfig, MaskFormerForInstanceSegmentation, MaskFormerImageProcessor, SwinConfig from transformers.utils import logging logging.set_verbosity_info() a_ :str = logging.get_logger(__name__) def lowercase_ (A : str ): snake_case__ : Tuple = SwinConfig.from_pretrained( 'microsoft/swin-tiny-patch4-window7-224' , out_features=['stage1', 'stage2', 'stage3', 'stage4'] ) snake_case__ : List[Any] = MaskFormerConfig(backbone_config=A ) snake_case__ : Union[str, Any] = 'huggingface/label-files' if "ade20k-full" in model_name: # this should be ok snake_case__ : Dict = 8_4_7 snake_case__ : List[str] = 'maskformer-ade20k-full-id2label.json' elif "ade" in model_name: # this should be ok snake_case__ : Union[str, Any] = 1_5_0 snake_case__ : Any = 'ade20k-id2label.json' elif "coco-stuff" in model_name: # this should be ok snake_case__ : List[str] = 1_7_1 snake_case__ : Union[str, Any] = 'maskformer-coco-stuff-id2label.json' elif "coco" in model_name: # TODO snake_case__ : Dict = 1_3_3 snake_case__ : str = 'coco-panoptic-id2label.json' elif "cityscapes" in model_name: # this should be ok snake_case__ : List[str] = 1_9 snake_case__ : Union[str, Any] = 'cityscapes-id2label.json' elif "vistas" in model_name: # this should be ok snake_case__ : Tuple = 6_5 snake_case__ : List[str] = 'mapillary-vistas-id2label.json' snake_case__ : Dict = json.load(open(hf_hub_download(A , A , repo_type='dataset' ) , 'r' ) ) snake_case__ : List[str] = {int(A ): v for k, v in idalabel.items()} return config def lowercase_ (A : Any ): snake_case__ : Optional[int] = [] # stem # fmt: off rename_keys.append(('backbone.patch_embed.proj.weight', 'model.pixel_level_module.encoder.model.embeddings.patch_embeddings.projection.weight') ) rename_keys.append(('backbone.patch_embed.proj.bias', 'model.pixel_level_module.encoder.model.embeddings.patch_embeddings.projection.bias') ) rename_keys.append(('backbone.patch_embed.norm.weight', 'model.pixel_level_module.encoder.model.embeddings.norm.weight') ) rename_keys.append(('backbone.patch_embed.norm.bias', 'model.pixel_level_module.encoder.model.embeddings.norm.bias') ) # stages for i in range(len(config.backbone_config.depths ) ): for j in range(config.backbone_config.depths[i] ): rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.norm1.weight''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.layernorm_before.weight''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.norm1.bias''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.layernorm_before.bias''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.attn.relative_position_bias_table''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.attention.self.relative_position_bias_table''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.attn.relative_position_index''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.attention.self.relative_position_index''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.attn.proj.weight''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.attention.output.dense.weight''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.attn.proj.bias''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.attention.output.dense.bias''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.norm2.weight''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.layernorm_after.weight''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.norm2.bias''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.layernorm_after.bias''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.mlp.fc1.weight''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.intermediate.dense.weight''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.mlp.fc1.bias''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.intermediate.dense.bias''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.mlp.fc2.weight''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.output.dense.weight''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.mlp.fc2.bias''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.output.dense.bias''') ) if i < 3: rename_keys.append((F'''backbone.layers.{i}.downsample.reduction.weight''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.downsample.reduction.weight''') ) rename_keys.append((F'''backbone.layers.{i}.downsample.norm.weight''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.downsample.norm.weight''') ) rename_keys.append((F'''backbone.layers.{i}.downsample.norm.bias''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.downsample.norm.bias''') ) rename_keys.append((F'''backbone.norm{i}.weight''', F'''model.pixel_level_module.encoder.hidden_states_norms.{i}.weight''') ) rename_keys.append((F'''backbone.norm{i}.bias''', F'''model.pixel_level_module.encoder.hidden_states_norms.{i}.bias''') ) # FPN rename_keys.append(('sem_seg_head.layer_4.weight', 'model.pixel_level_module.decoder.fpn.stem.0.weight') ) rename_keys.append(('sem_seg_head.layer_4.norm.weight', 'model.pixel_level_module.decoder.fpn.stem.1.weight') ) rename_keys.append(('sem_seg_head.layer_4.norm.bias', 'model.pixel_level_module.decoder.fpn.stem.1.bias') ) for source_index, target_index in zip(range(3 , 0 , -1 ) , range(0 , 3 ) ): rename_keys.append((F'''sem_seg_head.adapter_{source_index}.weight''', F'''model.pixel_level_module.decoder.fpn.layers.{target_index}.proj.0.weight''') ) rename_keys.append((F'''sem_seg_head.adapter_{source_index}.norm.weight''', F'''model.pixel_level_module.decoder.fpn.layers.{target_index}.proj.1.weight''') ) rename_keys.append((F'''sem_seg_head.adapter_{source_index}.norm.bias''', F'''model.pixel_level_module.decoder.fpn.layers.{target_index}.proj.1.bias''') ) rename_keys.append((F'''sem_seg_head.layer_{source_index}.weight''', F'''model.pixel_level_module.decoder.fpn.layers.{target_index}.block.0.weight''') ) rename_keys.append((F'''sem_seg_head.layer_{source_index}.norm.weight''', F'''model.pixel_level_module.decoder.fpn.layers.{target_index}.block.1.weight''') ) rename_keys.append((F'''sem_seg_head.layer_{source_index}.norm.bias''', F'''model.pixel_level_module.decoder.fpn.layers.{target_index}.block.1.bias''') ) rename_keys.append(('sem_seg_head.mask_features.weight', 'model.pixel_level_module.decoder.mask_projection.weight') ) rename_keys.append(('sem_seg_head.mask_features.bias', 'model.pixel_level_module.decoder.mask_projection.bias') ) # Transformer decoder for idx in range(config.decoder_config.decoder_layers ): # self-attention out projection rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.self_attn.out_proj.weight''', F'''model.transformer_module.decoder.layers.{idx}.self_attn.out_proj.weight''') ) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.self_attn.out_proj.bias''', F'''model.transformer_module.decoder.layers.{idx}.self_attn.out_proj.bias''') ) # cross-attention out projection rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.multihead_attn.out_proj.weight''', F'''model.transformer_module.decoder.layers.{idx}.encoder_attn.out_proj.weight''') ) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.multihead_attn.out_proj.bias''', F'''model.transformer_module.decoder.layers.{idx}.encoder_attn.out_proj.bias''') ) # MLP 1 rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.linear1.weight''', F'''model.transformer_module.decoder.layers.{idx}.fc1.weight''') ) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.linear1.bias''', F'''model.transformer_module.decoder.layers.{idx}.fc1.bias''') ) # MLP 2 rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.linear2.weight''', F'''model.transformer_module.decoder.layers.{idx}.fc2.weight''') ) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.linear2.bias''', F'''model.transformer_module.decoder.layers.{idx}.fc2.bias''') ) # layernorm 1 (self-attention layernorm) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.norm1.weight''', F'''model.transformer_module.decoder.layers.{idx}.self_attn_layer_norm.weight''') ) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.norm1.bias''', F'''model.transformer_module.decoder.layers.{idx}.self_attn_layer_norm.bias''') ) # layernorm 2 (cross-attention layernorm) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.norm2.weight''', F'''model.transformer_module.decoder.layers.{idx}.encoder_attn_layer_norm.weight''') ) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.norm2.bias''', F'''model.transformer_module.decoder.layers.{idx}.encoder_attn_layer_norm.bias''') ) # layernorm 3 (final layernorm) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.norm3.weight''', F'''model.transformer_module.decoder.layers.{idx}.final_layer_norm.weight''') ) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.norm3.bias''', F'''model.transformer_module.decoder.layers.{idx}.final_layer_norm.bias''') ) rename_keys.append(('sem_seg_head.predictor.transformer.decoder.norm.weight', 'model.transformer_module.decoder.layernorm.weight') ) rename_keys.append(('sem_seg_head.predictor.transformer.decoder.norm.bias', 'model.transformer_module.decoder.layernorm.bias') ) # heads on top rename_keys.append(('sem_seg_head.predictor.query_embed.weight', 'model.transformer_module.queries_embedder.weight') ) rename_keys.append(('sem_seg_head.predictor.input_proj.weight', 'model.transformer_module.input_projection.weight') ) rename_keys.append(('sem_seg_head.predictor.input_proj.bias', 'model.transformer_module.input_projection.bias') ) rename_keys.append(('sem_seg_head.predictor.class_embed.weight', 'class_predictor.weight') ) rename_keys.append(('sem_seg_head.predictor.class_embed.bias', 'class_predictor.bias') ) for i in range(3 ): rename_keys.append((F'''sem_seg_head.predictor.mask_embed.layers.{i}.weight''', F'''mask_embedder.{i}.0.weight''') ) rename_keys.append((F'''sem_seg_head.predictor.mask_embed.layers.{i}.bias''', F'''mask_embedder.{i}.0.bias''') ) # fmt: on return rename_keys def lowercase_ (A : Tuple , A : Tuple , A : Optional[Any] ): snake_case__ : Optional[int] = dct.pop(A ) snake_case__ : Union[str, Any] = val def lowercase_ (A : Optional[Any] , A : Tuple ): snake_case__ : Optional[int] = [int(backbone_config.embed_dim * 2**i ) for i in range(len(backbone_config.depths ) )] for i in range(len(backbone_config.depths ) ): snake_case__ : Optional[int] = num_features[i] for j in range(backbone_config.depths[i] ): # fmt: off # read in weights + bias of input projection layer (in original implementation, this is a single matrix + bias) snake_case__ : int = state_dict.pop(F'''backbone.layers.{i}.blocks.{j}.attn.qkv.weight''' ) snake_case__ : Tuple = state_dict.pop(F'''backbone.layers.{i}.blocks.{j}.attn.qkv.bias''' ) # next, add query, keys and values (in that order) to the state dict snake_case__ : str = in_proj_weight[:dim, :] snake_case__ : int = in_proj_bias[: dim] snake_case__ : List[Any] = in_proj_weight[ dim : dim * 2, : ] snake_case__ : List[str] = in_proj_bias[ dim : dim * 2 ] snake_case__ : List[Any] = in_proj_weight[ -dim :, : ] snake_case__ : Dict = in_proj_bias[-dim :] # fmt: on def lowercase_ (A : List[str] , A : List[Any] ): # fmt: off snake_case__ : str = config.decoder_config.hidden_size for idx in range(config.decoder_config.decoder_layers ): # read in weights + bias of self-attention input projection layer (in the original implementation, this is a single matrix + bias) snake_case__ : List[Any] = state_dict.pop(F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.self_attn.in_proj_weight''' ) snake_case__ : int = state_dict.pop(F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.self_attn.in_proj_bias''' ) # next, add query, keys and values (in that order) to the state dict snake_case__ : Any = in_proj_weight[: hidden_size, :] snake_case__ : Tuple = in_proj_bias[:config.hidden_size] snake_case__ : List[str] = in_proj_weight[hidden_size : hidden_size * 2, :] snake_case__ : Dict = in_proj_bias[hidden_size : hidden_size * 2] snake_case__ : Any = in_proj_weight[-hidden_size :, :] snake_case__ : int = in_proj_bias[-hidden_size :] # read in weights + bias of cross-attention input projection layer (in the original implementation, this is a single matrix + bias) snake_case__ : List[Any] = state_dict.pop(F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.multihead_attn.in_proj_weight''' ) snake_case__ : List[str] = state_dict.pop(F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.multihead_attn.in_proj_bias''' ) # next, add query, keys and values (in that order) to the state dict snake_case__ : Optional[int] = in_proj_weight[: hidden_size, :] snake_case__ : Optional[Any] = in_proj_bias[:config.hidden_size] snake_case__ : int = in_proj_weight[hidden_size : hidden_size * 2, :] snake_case__ : List[str] = in_proj_bias[hidden_size : hidden_size * 2] snake_case__ : List[str] = in_proj_weight[-hidden_size :, :] snake_case__ : str = in_proj_bias[-hidden_size :] # fmt: on def lowercase_ (): snake_case__ : Any = 'http://images.cocodataset.org/val2017/000000039769.jpg' snake_case__ : int = Image.open(requests.get(A , stream=A ).raw ) return im @torch.no_grad() def lowercase_ (A : str , A : str , A : str , A : bool = False ): snake_case__ : Optional[int] = get_maskformer_config(A ) # load original state_dict with open(A , 'rb' ) as f: snake_case__ : List[Any] = pickle.load(A ) snake_case__ : Optional[int] = data['model'] # for name, param in state_dict.items(): # print(name, param.shape) # rename keys snake_case__ : List[str] = create_rename_keys(A ) for src, dest in rename_keys: rename_key(A , A , A ) read_in_swin_q_k_v(A , config.backbone_config ) read_in_decoder_q_k_v(A , A ) # update to torch tensors for key, value in state_dict.items(): snake_case__ : int = torch.from_numpy(A ) # load 🤗 model snake_case__ : str = MaskFormerForInstanceSegmentation(A ) model.eval() for name, param in model.named_parameters(): print(A , param.shape ) snake_case__ , snake_case__ : Union[str, Any] = model.load_state_dict(A , strict=A ) assert missing_keys == [ "model.pixel_level_module.encoder.model.layernorm.weight", "model.pixel_level_module.encoder.model.layernorm.bias", ] assert len(A ) == 0, F'''Unexpected keys: {unexpected_keys}''' # verify results snake_case__ : Optional[Any] = prepare_img() if "vistas" in model_name: snake_case__ : int = 6_5 elif "cityscapes" in model_name: snake_case__ : Dict = 6_5_5_3_5 else: snake_case__ : Tuple = 2_5_5 snake_case__ : Optional[int] = True if 'ade' in model_name else False snake_case__ : Dict = MaskFormerImageProcessor(ignore_index=A , reduce_labels=A ) snake_case__ : Any = image_processor(A , return_tensors='pt' ) snake_case__ : Any = model(**A ) print('Logits:' , outputs.class_queries_logits[0, :3, :3] ) if model_name == "maskformer-swin-tiny-ade": snake_case__ : Tuple = torch.tensor( [[3.6353, -4.4770, -2.6065], [0.5081, -4.2394, -3.5343], [2.1909, -5.0353, -1.9323]] ) assert torch.allclose(outputs.class_queries_logits[0, :3, :3] , A , atol=1e-4 ) print('Looks ok!' ) if pytorch_dump_folder_path is not None: print(F'''Saving model and image processor to {pytorch_dump_folder_path}''' ) Path(A ).mkdir(exist_ok=A ) model.save_pretrained(A ) image_processor.save_pretrained(A ) if push_to_hub: print('Pushing model and image processor to the hub...' ) model.push_to_hub(F'''nielsr/{model_name}''' ) image_processor.push_to_hub(F'''nielsr/{model_name}''' ) if __name__ == "__main__": a_ :Optional[int] = argparse.ArgumentParser() # Required parameters parser.add_argument( "--model_name", default="maskformer-swin-tiny-ade", type=str, help=("Name of the MaskFormer model you'd like to convert",), ) parser.add_argument( "--checkpoint_path", default="/Users/nielsrogge/Documents/MaskFormer_checkpoints/MaskFormer-Swin-tiny-ADE20k/model.pkl", type=str, help="Path to the original state dict (.pth file).", ) parser.add_argument( "--pytorch_dump_folder_path", default=None, type=str, help="Path to the output PyTorch model directory." ) parser.add_argument( "--push_to_hub", action="store_true", help="Whether or not to push the converted model to the 🤗 hub." ) a_ :Dict = parser.parse_args() convert_maskformer_checkpoint( args.model_name, args.checkpoint_path, args.pytorch_dump_folder_path, args.push_to_hub )
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from timeit import timeit def _a ( SCREAMING_SNAKE_CASE : int ) -> Optional[Any]: """simple docstring""" if number < 0: raise ValueError('the value of input must not be negative' ) __lowerCAmelCase: Dict = 0 while number: number &= number - 1 result += 1 return result def _a ( SCREAMING_SNAKE_CASE : int ) -> Optional[Any]: """simple docstring""" if number < 0: raise ValueError('the value of input must not be negative' ) __lowerCAmelCase: List[str] = 0 while number: if number % 2 == 1: result += 1 number >>= 1 return result def _a ( ) -> str: """simple docstring""" def do_benchmark(SCREAMING_SNAKE_CASE : int ) -> None: __lowerCAmelCase: Dict = 'import __main__ as z' print(f'''Benchmark when {number = }:''' ) print(f'''{get_set_bits_count_using_modulo_operator(SCREAMING_SNAKE_CASE ) = }''' ) __lowerCAmelCase: int = timeit('z.get_set_bits_count_using_modulo_operator(25)' , setup=SCREAMING_SNAKE_CASE ) print(f'''timeit() runs in {timing} seconds''' ) print(f'''{get_set_bits_count_using_brian_kernighans_algorithm(SCREAMING_SNAKE_CASE ) = }''' ) __lowerCAmelCase: Tuple = timeit( 'z.get_set_bits_count_using_brian_kernighans_algorithm(25)' , setup=SCREAMING_SNAKE_CASE , ) print(f'''timeit() runs in {timing} seconds''' ) for number in (25, 37, 58, 0): do_benchmark(SCREAMING_SNAKE_CASE ) print() if __name__ == "__main__": import doctest doctest.testmod() benchmark()
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import unittest from transformers import is_torch_available from transformers.testing_utils import require_torch, slow, torch_device from ...generation.test_utils import GenerationTesterMixin from ...test_configuration_common import ConfigTester from ...test_modeling_common import ModelTesterMixin, ids_tensor from ...test_pipeline_mixin import PipelineTesterMixin if is_torch_available(): import torch from transformers import ( OPENAI_GPT_PRETRAINED_MODEL_ARCHIVE_LIST, OpenAIGPTConfig, OpenAIGPTDoubleHeadsModel, OpenAIGPTForSequenceClassification, OpenAIGPTLMHeadModel, OpenAIGPTModel, ) class snake_case__ : """simple docstring""" def __init__( self : List[str], _snake_case : Any, _snake_case : int=1_3, _snake_case : Optional[int]=7, _snake_case : int=True, _snake_case : Optional[Any]=True, _snake_case : Optional[Any]=True, _snake_case : Union[str, Any]=9_9, _snake_case : Optional[Any]=3_2, _snake_case : Tuple=5, _snake_case : str=4, _snake_case : Any=3_7, _snake_case : int="gelu", _snake_case : Optional[Any]=0.1, _snake_case : str=0.1, _snake_case : str=5_1_2, _snake_case : Dict=1_6, _snake_case : str=2, _snake_case : Union[str, Any]=0.0_2, _snake_case : Optional[int]=3, _snake_case : Union[str, Any]=4, _snake_case : Tuple=None, ) ->Optional[Any]: snake_case__ : Optional[int] = parent snake_case__ : List[Any] = batch_size snake_case__ : Tuple = seq_length snake_case__ : str = is_training snake_case__ : Optional[int] = use_token_type_ids snake_case__ : Any = use_labels snake_case__ : Dict = vocab_size snake_case__ : str = hidden_size snake_case__ : Union[str, Any] = num_hidden_layers snake_case__ : List[str] = num_attention_heads snake_case__ : Union[str, Any] = intermediate_size snake_case__ : List[Any] = hidden_act snake_case__ : int = hidden_dropout_prob snake_case__ : str = attention_probs_dropout_prob snake_case__ : Any = max_position_embeddings snake_case__ : Union[str, Any] = type_vocab_size snake_case__ : Optional[Any] = type_sequence_label_size snake_case__ : Optional[int] = initializer_range snake_case__ : Optional[int] = num_labels snake_case__ : str = num_choices snake_case__ : int = scope snake_case__ : List[str] = self.vocab_size - 1 def lowercase_ ( self : Union[str, Any] ) ->Tuple: snake_case__ : List[str] = ids_tensor([self.batch_size, self.seq_length], self.vocab_size ) snake_case__ : List[str] = None if self.use_token_type_ids: snake_case__ : Optional[Any] = ids_tensor([self.batch_size, self.seq_length], self.type_vocab_size ) snake_case__ : Tuple = None snake_case__ : str = None snake_case__ : List[Any] = None if self.use_labels: snake_case__ : Dict = ids_tensor([self.batch_size], self.type_sequence_label_size ) snake_case__ : int = ids_tensor([self.batch_size, self.seq_length], self.num_labels ) snake_case__ : List[str] = ids_tensor([self.batch_size], self.num_choices ) snake_case__ : Union[str, Any] = OpenAIGPTConfig( vocab_size=self.vocab_size, n_embd=self.hidden_size, n_layer=self.num_hidden_layers, n_head=self.num_attention_heads, n_positions=self.max_position_embeddings, pad_token_id=self.pad_token_id, ) snake_case__ : List[str] = ids_tensor([self.num_hidden_layers, self.num_attention_heads], 2 ) return ( config, input_ids, head_mask, token_type_ids, sequence_labels, token_labels, choice_labels, ) def lowercase_ ( self : Any, _snake_case : List[str], _snake_case : Any, _snake_case : List[Any], _snake_case : Tuple, *_snake_case : Optional[Any] ) ->Tuple: snake_case__ : Union[str, Any] = OpenAIGPTModel(config=_snake_case ) model.to(_snake_case ) model.eval() snake_case__ : Optional[Any] = model(_snake_case, token_type_ids=_snake_case, head_mask=_snake_case ) snake_case__ : Union[str, Any] = model(_snake_case, token_type_ids=_snake_case ) snake_case__ : Optional[Any] = model(_snake_case ) self.parent.assertEqual(result.last_hidden_state.shape, (self.batch_size, self.seq_length, self.hidden_size) ) def lowercase_ ( self : Optional[int], _snake_case : Optional[Any], _snake_case : Union[str, Any], _snake_case : Optional[int], _snake_case : List[Any], *_snake_case : Dict ) ->Optional[int]: snake_case__ : Optional[Any] = OpenAIGPTLMHeadModel(_snake_case ) model.to(_snake_case ) model.eval() snake_case__ : Tuple = model(_snake_case, token_type_ids=_snake_case, labels=_snake_case ) self.parent.assertEqual(result.loss.shape, () ) self.parent.assertEqual(result.logits.shape, (self.batch_size, self.seq_length, self.vocab_size) ) def lowercase_ ( self : int, _snake_case : Tuple, _snake_case : List[str], _snake_case : List[Any], _snake_case : List[Any], *_snake_case : List[Any] ) ->Optional[int]: snake_case__ : List[str] = OpenAIGPTDoubleHeadsModel(_snake_case ) model.to(_snake_case ) model.eval() snake_case__ : Optional[Any] = model(_snake_case, token_type_ids=_snake_case, labels=_snake_case ) self.parent.assertEqual(result.loss.shape, () ) self.parent.assertEqual(result.logits.shape, (self.batch_size, self.seq_length, self.vocab_size) ) def lowercase_ ( self : Optional[int], _snake_case : Tuple, _snake_case : Dict, _snake_case : List[str], _snake_case : Optional[Any], *_snake_case : Union[str, Any] ) ->str: snake_case__ : List[str] = self.num_labels snake_case__ : Dict = OpenAIGPTForSequenceClassification(_snake_case ) model.to(_snake_case ) model.eval() snake_case__ : List[str] = ids_tensor([self.batch_size], self.type_sequence_label_size ) snake_case__ : List[str] = model(_snake_case, token_type_ids=_snake_case, labels=_snake_case ) self.parent.assertEqual(result.logits.shape, (self.batch_size, self.num_labels) ) def lowercase_ ( self : Dict ) ->int: snake_case__ : List[Any] = self.prepare_config_and_inputs() ( ( snake_case__ ) , ( snake_case__ ) , ( snake_case__ ) , ( snake_case__ ) , ( snake_case__ ) , ( snake_case__ ) , ( snake_case__ ) , ) : Optional[Any] = config_and_inputs snake_case__ : str = { 'input_ids': input_ids, 'token_type_ids': token_type_ids, 'head_mask': head_mask, } return config, inputs_dict @require_torch class snake_case__ ( lowerCAmelCase_ , lowerCAmelCase_ , lowerCAmelCase_ , unittest.TestCase ): """simple docstring""" _SCREAMING_SNAKE_CASE = ( (OpenAIGPTModel, OpenAIGPTLMHeadModel, OpenAIGPTDoubleHeadsModel, OpenAIGPTForSequenceClassification) if is_torch_available() else () ) _SCREAMING_SNAKE_CASE = ( (OpenAIGPTLMHeadModel,) if is_torch_available() else () ) # TODO (PVP): Add Double HeadsModel when generate() function is changed accordingly _SCREAMING_SNAKE_CASE = ( { """feature-extraction""": OpenAIGPTModel, """text-classification""": OpenAIGPTForSequenceClassification, """text-generation""": OpenAIGPTLMHeadModel, """zero-shot""": OpenAIGPTForSequenceClassification, } if is_torch_available() else {} ) def lowercase_ ( self : Optional[int], _snake_case : Union[str, Any], _snake_case : int, _snake_case : Tuple, _snake_case : Tuple, _snake_case : List[str] ) ->Optional[Any]: if pipeline_test_casse_name == "ZeroShotClassificationPipelineTests": # Get `tokenizer does not have a padding token` error for both fast/slow tokenizers. # `OpenAIGPTConfig` was never used in pipeline tests, either because of a missing checkpoint or because a # tiny config could not be created. return True return False def lowercase_ ( self : Optional[Any], _snake_case : Union[str, Any], _snake_case : List[str], _snake_case : Any=False ) ->Tuple: snake_case__ : Optional[int] = super()._prepare_for_class(_snake_case, _snake_case, return_labels=_snake_case ) if return_labels: if model_class.__name__ == "OpenAIGPTDoubleHeadsModel": snake_case__ : Union[str, Any] = torch.zeros( (self.model_tester.batch_size, self.model_tester.num_choices, self.model_tester.seq_length), dtype=torch.long, device=_snake_case, ) snake_case__ : List[Any] = inputs_dict['labels'] snake_case__ : List[Any] = inputs_dict['labels'] snake_case__ : Any = torch.zeros( (self.model_tester.batch_size, self.model_tester.num_choices), dtype=torch.long, device=_snake_case, ) snake_case__ : Tuple = torch.zeros( self.model_tester.batch_size, dtype=torch.long, device=_snake_case ) return inputs_dict def lowercase_ ( self : Union[str, Any] ) ->List[str]: snake_case__ : List[str] = OpenAIGPTModelTester(self ) snake_case__ : Any = ConfigTester(self, config_class=_snake_case, n_embd=3_7 ) def lowercase_ ( self : Optional[int] ) ->str: self.config_tester.run_common_tests() def lowercase_ ( self : int ) ->Tuple: snake_case__ : str = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_openai_gpt_model(*_snake_case ) def lowercase_ ( self : Tuple ) ->List[str]: snake_case__ : Optional[int] = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_lm_head_model(*_snake_case ) def lowercase_ ( self : Dict ) ->int: snake_case__ : Optional[Any] = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_double_lm_head_model(*_snake_case ) def lowercase_ ( self : int ) ->str: snake_case__ : List[Any] = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_openai_gpt_for_sequence_classification(*_snake_case ) @slow def lowercase_ ( self : Optional[Any] ) ->str: for model_name in OPENAI_GPT_PRETRAINED_MODEL_ARCHIVE_LIST[:1]: snake_case__ : Optional[int] = OpenAIGPTModel.from_pretrained(_snake_case ) self.assertIsNotNone(_snake_case ) @require_torch class snake_case__ ( unittest.TestCase ): """simple docstring""" @slow def lowercase_ ( self : Tuple ) ->Optional[int]: snake_case__ : Union[str, Any] = OpenAIGPTLMHeadModel.from_pretrained('openai-gpt' ) model.to(_snake_case ) snake_case__ : Tuple = torch.tensor([[4_8_1, 4_7_3_5, 5_4_4]], dtype=torch.long, device=_snake_case ) # the president is snake_case__ : int = [ 4_8_1, 4_7_3_5, 5_4_4, 2_4_6, 9_6_3, 8_7_0, 7_6_2, 2_3_9, 2_4_4, 4_0_4_7_7, 2_4_4, 2_4_9, 7_1_9, 8_8_1, 4_8_7, 5_4_4, 2_4_0, 2_4_4, 6_0_3, 4_8_1, ] # the president is a very good man. " \n " i\'m sure he is, " said the snake_case__ : Optional[int] = model.generate(_snake_case, do_sample=_snake_case ) self.assertListEqual(output_ids[0].tolist(), _snake_case )
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import collections import inspect import unittest from transformers import SwinvaConfig from transformers.testing_utils import require_torch, require_vision, slow, torch_device from transformers.utils import cached_property, is_torch_available, is_vision_available from ...test_configuration_common import ConfigTester from ...test_modeling_common import ModelTesterMixin, _config_zero_init, floats_tensor, ids_tensor from ...test_pipeline_mixin import PipelineTesterMixin if is_torch_available(): import torch from torch import nn from transformers import SwinvaForImageClassification, SwinvaForMaskedImageModeling, SwinvaModel from transformers.models.swinva.modeling_swinva import SWINV2_PRETRAINED_MODEL_ARCHIVE_LIST if is_vision_available(): from PIL import Image from transformers import AutoImageProcessor class __lowerCAmelCase : def __init__( self , lowerCAmelCase__ , lowerCAmelCase__=1_3 , lowerCAmelCase__=3_2 , lowerCAmelCase__=2 , lowerCAmelCase__=3 , lowerCAmelCase__=1_6 , lowerCAmelCase__=[1, 2, 1] , lowerCAmelCase__=[2, 2, 4] , lowerCAmelCase__=2 , lowerCAmelCase__=2.0 , lowerCAmelCase__=True , lowerCAmelCase__=0.0 , lowerCAmelCase__=0.0 , lowerCAmelCase__=0.1 , lowerCAmelCase__="gelu" , lowerCAmelCase__=False , lowerCAmelCase__=True , lowerCAmelCase__=0.02 , lowerCAmelCase__=1E-5 , lowerCAmelCase__=True , lowerCAmelCase__=None , lowerCAmelCase__=True , lowerCAmelCase__=1_0 , lowerCAmelCase__=8 , ) -> Union[str, Any]: '''simple docstring''' a__ : Any =parent a__ : Tuple =batch_size a__ : Tuple =image_size a__ : Any =patch_size a__ : Optional[int] =num_channels a__ : Tuple =embed_dim a__ : Any =depths a__ : Any =num_heads a__ : List[str] =window_size a__ : Dict =mlp_ratio a__ : Optional[int] =qkv_bias a__ : Optional[Any] =hidden_dropout_prob a__ : List[str] =attention_probs_dropout_prob a__ : Union[str, Any] =drop_path_rate a__ : str =hidden_act a__ : Union[str, Any] =use_absolute_embeddings a__ : Union[str, Any] =patch_norm a__ : Any =layer_norm_eps a__ : Tuple =initializer_range a__ : Dict =is_training a__ : Any =scope a__ : Optional[Any] =use_labels a__ : str =type_sequence_label_size a__ : List[Any] =encoder_stride def _lowercase ( self ) -> str: '''simple docstring''' a__ : Tuple =floats_tensor([self.batch_size, self.num_channels, self.image_size, self.image_size] ) a__ : List[Any] =None if self.use_labels: a__ : Optional[Any] =ids_tensor([self.batch_size] , self.type_sequence_label_size ) a__ : Any =self.get_config() return config, pixel_values, labels def _lowercase ( self ) -> Optional[int]: '''simple docstring''' return SwinvaConfig( image_size=self.image_size , patch_size=self.patch_size , num_channels=self.num_channels , embed_dim=self.embed_dim , depths=self.depths , num_heads=self.num_heads , window_size=self.window_size , mlp_ratio=self.mlp_ratio , qkv_bias=self.qkv_bias , hidden_dropout_prob=self.hidden_dropout_prob , attention_probs_dropout_prob=self.attention_probs_dropout_prob , drop_path_rate=self.drop_path_rate , hidden_act=self.hidden_act , use_absolute_embeddings=self.use_absolute_embeddings , path_norm=self.patch_norm , layer_norm_eps=self.layer_norm_eps , initializer_range=self.initializer_range , encoder_stride=self.encoder_stride , ) def _lowercase ( self , lowerCAmelCase__ , lowerCAmelCase__ , lowerCAmelCase__ ) -> Dict: '''simple docstring''' a__ : List[Any] =SwinvaModel(config=_snake_case ) model.to(_snake_case ) model.eval() a__ : Optional[int] =model(_snake_case ) a__ : List[Any] =((config.image_size // config.patch_size) ** 2) // (4 ** (len(config.depths ) - 1)) a__ : List[Any] =int(config.embed_dim * 2 ** (len(config.depths ) - 1) ) self.parent.assertEqual(result.last_hidden_state.shape , (self.batch_size, expected_seq_len, expected_dim) ) def _lowercase ( self , lowerCAmelCase__ , lowerCAmelCase__ , lowerCAmelCase__ ) -> List[Any]: '''simple docstring''' a__ : List[str] =SwinvaForMaskedImageModeling(config=_snake_case ) model.to(_snake_case ) model.eval() a__ : Union[str, Any] =model(_snake_case ) self.parent.assertEqual( result.logits.shape , (self.batch_size, self.num_channels, self.image_size, self.image_size) ) # test greyscale images a__ : Optional[Any] =1 a__ : Optional[int] =SwinvaForMaskedImageModeling(_snake_case ) model.to(_snake_case ) model.eval() a__ : Tuple =floats_tensor([self.batch_size, 1, self.image_size, self.image_size] ) a__ : Any =model(_snake_case ) self.parent.assertEqual(result.logits.shape , (self.batch_size, 1, self.image_size, self.image_size) ) def _lowercase ( self , lowerCAmelCase__ , lowerCAmelCase__ , lowerCAmelCase__ ) -> Any: '''simple docstring''' a__ : Tuple =self.type_sequence_label_size a__ : int =SwinvaForImageClassification(_snake_case ) model.to(_snake_case ) model.eval() a__ : Tuple =model(_snake_case , labels=_snake_case ) self.parent.assertEqual(result.logits.shape , (self.batch_size, self.type_sequence_label_size) ) def _lowercase ( self ) -> Dict: '''simple docstring''' a__ : str =self.prepare_config_and_inputs() a__ : List[str] =config_and_inputs a__ : Union[str, Any] ={'pixel_values': pixel_values} return config, inputs_dict @require_torch class __lowerCAmelCase ( lowerCAmelCase_ , lowerCAmelCase_ , unittest.TestCase): _lowercase : Union[str, Any] = ( (SwinvaModel, SwinvaForImageClassification, SwinvaForMaskedImageModeling) if is_torch_available() else () ) _lowercase : Optional[Any] = ( {"""feature-extraction""": SwinvaModel, """image-classification""": SwinvaForImageClassification} if is_torch_available() else {} ) _lowercase : int = False _lowercase : List[str] = False _lowercase : List[Any] = False _lowercase : int = False def _lowercase ( self ) -> Dict: '''simple docstring''' a__ : Optional[int] =SwinvaModelTester(self ) a__ : int =ConfigTester(self , config_class=_snake_case , embed_dim=3_7 ) def _lowercase ( self ) -> int: '''simple docstring''' self.config_tester.create_and_test_config_to_json_string() self.config_tester.create_and_test_config_to_json_file() self.config_tester.create_and_test_config_from_and_save_pretrained() self.config_tester.create_and_test_config_with_num_labels() self.config_tester.check_config_can_be_init_without_params() self.config_tester.check_config_arguments_init() def _lowercase ( self ) -> str: '''simple docstring''' a__ : int =self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_model(*_snake_case ) @unittest.skip(reason="Got `CUDA error: misaligned address` with PyTorch 2.0.0." ) def _lowercase ( self ) -> Union[str, Any]: '''simple docstring''' pass @unittest.skip(reason="Swinv2 does not use inputs_embeds" ) def _lowercase ( self ) -> Union[str, Any]: '''simple docstring''' pass def _lowercase ( self ) -> Union[str, Any]: '''simple docstring''' a__ : Optional[int] =self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: a__ : Union[str, Any] =model_class(_snake_case ) self.assertIsInstance(model.get_input_embeddings() , (nn.Module) ) a__ : Union[str, Any] =model.get_output_embeddings() self.assertTrue(x is None or isinstance(_snake_case , nn.Linear ) ) def _lowercase ( self ) -> Optional[int]: '''simple docstring''' a__ : Any =self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: a__ : Any =model_class(_snake_case ) a__ : Dict =inspect.signature(model.forward ) # signature.parameters is an OrderedDict => so arg_names order is deterministic a__ : Optional[Any] =[*signature.parameters.keys()] a__ : List[Any] =['pixel_values'] self.assertListEqual(arg_names[:1] , _snake_case ) def _lowercase ( self ) -> Union[str, Any]: '''simple docstring''' a__ : Any =self.model_tester.prepare_config_and_inputs_for_common() a__ : int =True for model_class in self.all_model_classes: a__ : str =True a__ : Union[str, Any] =False a__ : Tuple =True a__ : int =model_class(_snake_case ) model.to(_snake_case ) model.eval() with torch.no_grad(): a__ : Optional[int] =model(**self._prepare_for_class(_snake_case , _snake_case ) ) a__ : List[str] =outputs.attentions a__ : List[Any] =len(self.model_tester.depths ) self.assertEqual(len(_snake_case ) , _snake_case ) # check that output_attentions also work using config del inputs_dict["output_attentions"] a__ : str =True a__ : Tuple =config.window_size**2 a__ : Optional[int] =model_class(_snake_case ) model.to(_snake_case ) model.eval() with torch.no_grad(): a__ : str =model(**self._prepare_for_class(_snake_case , _snake_case ) ) a__ : Tuple =outputs.attentions self.assertEqual(len(_snake_case ) , _snake_case ) self.assertListEqual( list(attentions[0].shape[-3:] ) , [self.model_tester.num_heads[0], window_size_squared, window_size_squared] , ) a__ : Optional[Any] =len(_snake_case ) # Check attention is always last and order is fine a__ : Optional[int] =True a__ : Dict =True a__ : List[Any] =model_class(_snake_case ) model.to(_snake_case ) model.eval() with torch.no_grad(): a__ : Optional[int] =model(**self._prepare_for_class(_snake_case , _snake_case ) ) if hasattr(self.model_tester , "num_hidden_states_types" ): a__ : str =self.model_tester.num_hidden_states_types else: # also another +1 for reshaped_hidden_states a__ : Dict =2 self.assertEqual(out_len + added_hidden_states , len(_snake_case ) ) a__ : Any =outputs.attentions self.assertEqual(len(_snake_case ) , _snake_case ) self.assertListEqual( list(self_attentions[0].shape[-3:] ) , [self.model_tester.num_heads[0], window_size_squared, window_size_squared] , ) def _lowercase ( self , lowerCAmelCase__ , lowerCAmelCase__ , lowerCAmelCase__ , lowerCAmelCase__ ) -> str: '''simple docstring''' a__ : Dict =model_class(_snake_case ) model.to(_snake_case ) model.eval() with torch.no_grad(): a__ : List[Any] =model(**self._prepare_for_class(_snake_case , _snake_case ) ) a__ : Dict =outputs.hidden_states a__ : int =getattr( self.model_tester , "expected_num_hidden_layers" , len(self.model_tester.depths ) + 1 ) self.assertEqual(len(_snake_case ) , _snake_case ) # Swinv2 has a different seq_length a__ : int =( config.patch_size if isinstance(config.patch_size , collections.abc.Iterable ) else (config.patch_size, config.patch_size) ) a__ : Optional[Any] =(image_size[1] // patch_size[1]) * (image_size[0] // patch_size[0]) self.assertListEqual( list(hidden_states[0].shape[-2:] ) , [num_patches, self.model_tester.embed_dim] , ) a__ : Union[str, Any] =outputs.reshaped_hidden_states self.assertEqual(len(_snake_case ) , _snake_case ) a__ : str =reshaped_hidden_states[0].shape a__ : Any =( reshaped_hidden_states[0].view(_snake_case , _snake_case , height * width ).permute(0 , 2 , 1 ) ) self.assertListEqual( list(reshaped_hidden_states.shape[-2:] ) , [num_patches, self.model_tester.embed_dim] , ) def _lowercase ( self ) -> List[Any]: '''simple docstring''' a__ : Any =self.model_tester.prepare_config_and_inputs_for_common() a__ : List[Any] =( self.model_tester.image_size if isinstance(self.model_tester.image_size , collections.abc.Iterable ) else (self.model_tester.image_size, self.model_tester.image_size) ) for model_class in self.all_model_classes: a__ : Optional[int] =True self.check_hidden_states_output(_snake_case , _snake_case , _snake_case , _snake_case ) # check that output_hidden_states also work using config del inputs_dict["output_hidden_states"] a__ : Dict =True self.check_hidden_states_output(_snake_case , _snake_case , _snake_case , _snake_case ) def _lowercase ( self ) -> str: '''simple docstring''' a__ : Optional[Any] =self.model_tester.prepare_config_and_inputs_for_common() a__ : List[str] =3 a__ : Union[str, Any] =( self.model_tester.image_size if isinstance(self.model_tester.image_size , collections.abc.Iterable ) else (self.model_tester.image_size, self.model_tester.image_size) ) a__ : str =( config.patch_size if isinstance(config.patch_size , collections.abc.Iterable ) else (config.patch_size, config.patch_size) ) a__ : Tuple =image_size[0] + patch_size[0] - (image_size[0] % patch_size[0]) a__ : Optional[Any] =image_size[1] + patch_size[1] - (image_size[1] % patch_size[1]) for model_class in self.all_model_classes: a__ : int =True self.check_hidden_states_output(_snake_case , _snake_case , _snake_case , (padded_height, padded_width) ) # check that output_hidden_states also work using config del inputs_dict["output_hidden_states"] a__ : List[str] =True self.check_hidden_states_output(_snake_case , _snake_case , _snake_case , (padded_height, padded_width) ) def _lowercase ( self ) -> Optional[int]: '''simple docstring''' a__ : Any =self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_for_masked_image_modeling(*_snake_case ) def _lowercase ( self ) -> str: '''simple docstring''' a__ : Any =self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_for_image_classification(*_snake_case ) @slow def _lowercase ( self ) -> Union[str, Any]: '''simple docstring''' for model_name in SWINV2_PRETRAINED_MODEL_ARCHIVE_LIST[:1]: a__ : Dict =SwinvaModel.from_pretrained(_snake_case ) self.assertIsNotNone(_snake_case ) def _lowercase ( self ) -> List[str]: '''simple docstring''' a__ : Any =self.model_tester.prepare_config_and_inputs_for_common() a__ : List[Any] =_config_zero_init(_snake_case ) for model_class in self.all_model_classes: a__ : List[str] =model_class(config=_snake_case ) for name, param in model.named_parameters(): if "embeddings" not in name and "logit_scale" not in name and param.requires_grad: self.assertIn( ((param.data.mean() * 1E9).round() / 1E9).item() , [0.0, 1.0] , msg=F'''Parameter {name} of model {model_class} seems not properly initialized''' , ) @require_vision @require_torch class __lowerCAmelCase ( unittest.TestCase): @cached_property def _lowercase ( self ) -> List[str]: '''simple docstring''' return ( AutoImageProcessor.from_pretrained("microsoft/swinv2-tiny-patch4-window8-256" ) if is_vision_available() else None ) @slow def _lowercase ( self ) -> List[Any]: '''simple docstring''' a__ : Any =SwinvaForImageClassification.from_pretrained("microsoft/swinv2-tiny-patch4-window8-256" ).to( _snake_case ) a__ : int =self.default_image_processor a__ : Union[str, Any] =Image.open("./tests/fixtures/tests_samples/COCO/000000039769.png" ) a__ : Optional[Any] =image_processor(images=_snake_case , return_tensors="pt" ).to(_snake_case ) # forward pass with torch.no_grad(): a__ : List[str] =model(**_snake_case ) # verify the logits a__ : int =torch.Size((1, 1_0_0_0) ) self.assertEqual(outputs.logits.shape , _snake_case ) a__ : Optional[int] =torch.tensor([-0.39_47, -0.43_06, 0.00_26] ).to(_snake_case ) self.assertTrue(torch.allclose(outputs.logits[0, :3] , _snake_case , atol=1E-4 ) )
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import os import unittest from transformers.models.transfo_xl.tokenization_transfo_xl import VOCAB_FILES_NAMES, TransfoXLTokenizer from ...test_tokenization_common import TokenizerTesterMixin class snake_case__ ( lowerCAmelCase_ , unittest.TestCase ): """simple docstring""" _SCREAMING_SNAKE_CASE = TransfoXLTokenizer _SCREAMING_SNAKE_CASE = False _SCREAMING_SNAKE_CASE = False def lowercase_ ( self : Optional[int] ) ->Any: super().setUp() snake_case__ : Tuple = [ '<unk>', '[CLS]', '[SEP]', 'want', 'unwanted', 'wa', 'un', 'running', ',', 'low', 'l', ] snake_case__ : Any = os.path.join(self.tmpdirname, VOCAB_FILES_NAMES['vocab_file'] ) with open(self.vocab_file, 'w', encoding='utf-8' ) as vocab_writer: vocab_writer.write(''.join([x + '\n' for x in vocab_tokens] ) ) def lowercase_ ( self : Union[str, Any], **_snake_case : List[Any] ) ->Dict: snake_case__ : str = True return TransfoXLTokenizer.from_pretrained(self.tmpdirname, **_snake_case ) def lowercase_ ( self : Optional[Any], _snake_case : str ) ->Dict: snake_case__ : List[Any] = '<unk> UNwanted , running' snake_case__ : List[Any] = '<unk> unwanted, running' return input_text, output_text def lowercase_ ( self : List[Any] ) ->Tuple: snake_case__ : Dict = TransfoXLTokenizer(vocab_file=self.vocab_file, lower_case=_snake_case ) snake_case__ : str = tokenizer.tokenize('<unk> UNwanted , running' ) self.assertListEqual(_snake_case, ['<unk>', 'unwanted', ',', 'running'] ) self.assertListEqual(tokenizer.convert_tokens_to_ids(_snake_case ), [0, 4, 8, 7] ) def lowercase_ ( self : List[str] ) ->List[Any]: snake_case__ : str = TransfoXLTokenizer(lower_case=_snake_case ) self.assertListEqual( tokenizer.tokenize(' \tHeLLo ! how \n Are yoU ? ' ), ['hello', '!', 'how', 'are', 'you', '?'] ) def lowercase_ ( self : Optional[int] ) ->Optional[Any]: snake_case__ : Optional[int] = TransfoXLTokenizer(lower_case=_snake_case ) self.assertListEqual( tokenizer.tokenize(' \tHeLLo ! how \n Are yoU ? ' ), ['HeLLo', '!', 'how', 'Are', 'yoU', '?'] ) def lowercase_ ( self : Optional[int] ) ->Union[str, Any]: snake_case__ : List[Any] = TransfoXLTokenizer(lower_case=_snake_case ) snake_case__ : Dict = 'Hello (bracket) and side-scrolled [and] Henry\'s $5,000 with 3.34 m. What\'s up!?' snake_case__ : List[Any] = [ 'Hello', '(', 'bracket', ')', 'and', 'side', '@-@', 'scrolled', '[', 'and', ']', 'Henry', '\'s', '$', '5', '@,@', '000', 'with', '3', '@.@', '34', 'm', '.', 'What', '\'s', 'up', '!', '?', ] self.assertListEqual(tokenizer.tokenize(_snake_case ), _snake_case ) self.assertEqual(tokenizer.convert_tokens_to_string(_snake_case ), _snake_case ) def lowercase_ ( self : Dict ) ->Any: snake_case__ : Dict = self.get_tokenizer() snake_case__ : Optional[Any] = len(_snake_case ) tokenizer.add_tokens(['new1', 'new2'] ) tokenizer.move_added_token('new1', 1 ) # Check that moved token is not copied (duplicate) self.assertEqual(len(_snake_case ), original_len + 2 ) # Check that token is moved to specified id self.assertEqual(tokenizer.encode('new1' ), [1] ) self.assertEqual(tokenizer.decode([1] ), 'new1' )
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from math import factorial, pi def a ( snake_case__: float , snake_case__: int = 30 ): '''simple docstring''' if not isinstance(snake_case__ , (int, float) ): raise ValueError('''maclaurin_sin() requires either an int or float for theta''' ) if not isinstance(snake_case__ , snake_case__ ) or accuracy <= 0: raise ValueError('''maclaurin_sin() requires a positive int for accuracy''' ) lowercase_ = float(snake_case__ ) lowercase_ = theta // (2 * pi) theta -= 2 * div * pi return sum( (-1) ** r * theta ** (2 * r + 1) / factorial(2 * r + 1 ) for r in range(snake_case__ ) ) def a ( snake_case__: float , snake_case__: int = 30 ): '''simple docstring''' if not isinstance(snake_case__ , (int, float) ): raise ValueError('''maclaurin_cos() requires either an int or float for theta''' ) if not isinstance(snake_case__ , snake_case__ ) or accuracy <= 0: raise ValueError('''maclaurin_cos() requires a positive int for accuracy''' ) lowercase_ = float(snake_case__ ) lowercase_ = theta // (2 * pi) theta -= 2 * div * pi return sum((-1) ** r * theta ** (2 * r) / factorial(2 * r ) for r in range(snake_case__ ) ) if __name__ == "__main__": import doctest doctest.testmod() print(maclaurin_sin(1_0)) print(maclaurin_sin(-1_0)) print(maclaurin_sin(1_0, 1_5)) print(maclaurin_sin(-1_0, 1_5)) print(maclaurin_cos(5)) print(maclaurin_cos(-5)) print(maclaurin_cos(1_0, 1_5)) print(maclaurin_cos(-1_0, 1_5))
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from ...configuration_utils import PretrainedConfig from ...utils import logging a_ :Optional[int] = logging.get_logger(__name__) a_ :Dict = {"openai-gpt": "https://huggingface.co/openai-gpt/resolve/main/config.json"} class snake_case__ ( lowerCAmelCase_ ): """simple docstring""" _SCREAMING_SNAKE_CASE = """openai-gpt""" _SCREAMING_SNAKE_CASE = { """max_position_embeddings""": """n_positions""", """hidden_size""": """n_embd""", """num_attention_heads""": """n_head""", """num_hidden_layers""": """n_layer""", } def __init__( self : Optional[int], _snake_case : Dict=4_0_4_7_8, _snake_case : str=5_1_2, _snake_case : int=7_6_8, _snake_case : Tuple=1_2, _snake_case : Any=1_2, _snake_case : str="gelu", _snake_case : List[str]=0.1, _snake_case : Any=0.1, _snake_case : Dict=0.1, _snake_case : int=1e-5, _snake_case : Optional[Any]=0.0_2, _snake_case : List[Any]="cls_index", _snake_case : Any=True, _snake_case : Any=None, _snake_case : int=True, _snake_case : Optional[Any]=0.1, **_snake_case : List[Any], ) ->Optional[int]: snake_case__ : int = vocab_size snake_case__ : Dict = n_positions snake_case__ : str = n_embd snake_case__ : str = n_layer snake_case__ : List[Any] = n_head snake_case__ : List[Any] = afn snake_case__ : Optional[Any] = resid_pdrop snake_case__ : List[str] = embd_pdrop snake_case__ : List[Any] = attn_pdrop snake_case__ : Optional[int] = layer_norm_epsilon snake_case__ : str = initializer_range snake_case__ : List[str] = summary_type snake_case__ : Optional[int] = summary_use_proj snake_case__ : List[str] = summary_activation snake_case__ : Optional[Any] = summary_first_dropout snake_case__ : int = summary_proj_to_labels super().__init__(**_snake_case )
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"""simple docstring""" from __future__ import annotations class __lowerCAmelCase : '''simple docstring''' def __init__( self , _a=None ): __a = data __a = None def __repr__( self ): __a = [] __a = self while temp: string_rep.append(f'''{temp.data}''' ) __a = temp.next return "->".join(_snake_case ) def lowercase ( lowerCAmelCase__ : list ) -> Optional[Any]: if not elements_list: raise Exception('''The Elements List is empty''' ) __a = Node(elements_list[0] ) for i in range(1 , len(lowerCAmelCase__ ) ): __a = Node(elements_list[i] ) __a = current.next return head def lowercase ( lowerCAmelCase__ : Node ) -> Any: if head_node is not None and isinstance(lowerCAmelCase__ , lowerCAmelCase__ ): print_reverse(head_node.next ) print(head_node.data ) def lowercase ( ) -> Tuple: from doctest import testmod testmod() __a = make_linked_list([14, 52, 14, 12, 43] ) print('''Linked List:''' ) print(lowerCAmelCase__ ) print('''Elements in Reverse:''' ) print_reverse(lowerCAmelCase__ ) if __name__ == "__main__": main()
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import argparse import logging import os from datetime import datetime import numpy as np import torch from torch import nn from torch.utils.data import DataLoader, RandomSampler, TensorDataset from tqdm import tqdm from transformers import GPTaLMHeadModel a_ :Optional[Any] = logging.getLogger(__name__) def lowercase_ (A : List[Any] , A : List[Any] ): # save results if os.path.exists(A ): if os.path.exists(os.path.join(A , 'config.json' ) ) and os.path.isfile( os.path.join(A , 'config.json' ) ): os.remove(os.path.join(A , 'config.json' ) ) if os.path.exists(os.path.join(A , 'pytorch_model.bin' ) ) and os.path.isfile( os.path.join(A , 'pytorch_model.bin' ) ): os.remove(os.path.join(A , 'pytorch_model.bin' ) ) else: os.makedirs(A ) model.save_pretrained(A ) def lowercase_ (A : Any , A : Optional[Any]=False ): snake_case__ : str = 2 if unlogit: snake_case__ : Dict = torch.pow(A , A ) snake_case__ : Any = p * torch.log(A ) snake_case__ : Tuple = 0 return -plogp.sum(dim=-1 ) def lowercase_ (A : List[str] ): logger.info('lv, h >\t' + '\t'.join(F'''{x + 1}''' for x in range(len(A ) ) ) ) for row in range(len(A ) ): if tensor.dtype != torch.long: logger.info(F'''layer {row + 1}:\t''' + '\t'.join(F'''{x:.5f}''' for x in tensor[row].cpu().data ) ) else: logger.info(F'''layer {row + 1}:\t''' + '\t'.join(F'''{x:d}''' for x in tensor[row].cpu().data ) ) def lowercase_ (A : Tuple , A : Optional[Any] , A : str , A : int=True , A : Optional[int]=True , A : Any=None , A : int=False ): snake_case__ , snake_case__ : Optional[Any] = model.config.num_hidden_layers, model.config.num_attention_heads snake_case__ : int = torch.zeros(A , A ).to(args.device ) snake_case__ : Any = torch.zeros(A , A ).to(args.device ) if head_mask is None: snake_case__ : Dict = torch.ones(A , A ).to(args.device ) head_mask.requires_grad_(requires_grad=A ) # If actually pruned attention multi-head, set head mask to None to avoid shape mismatch if actually_pruned: snake_case__ : Optional[int] = None snake_case__ : List[Any] = 0.0 snake_case__ : str = 0.0 for step, inputs in enumerate(tqdm(A , desc='Iteration' , disable=args.local_rank not in [-1, 0] ) ): snake_case__ : Union[str, Any] = tuple(t.to(args.device ) for t in inputs ) ((snake_case__) , ) : Optional[Any] = inputs # Do a forward pass (not with torch.no_grad() since we need gradients for importance score - see below) snake_case__ : Union[str, Any] = model(A , labels=A , head_mask=A ) # (loss), lm_logits, presents, (all hidden_states), (attentions) snake_case__ , snake_case__ , snake_case__ : Dict = ( outputs[0], outputs[1], outputs[-1], ) # Loss and logits are the first, attention the last loss.backward() # Backpropagate to populate the gradients in the head mask total_loss += loss.detach().cpu().numpy() if compute_entropy: for layer, attn in enumerate(A ): snake_case__ : Optional[Any] = entropy(attn.detach() , A ) attn_entropy[layer] += masked_entropy.sum(-1 ).sum(0 ).sum(0 ).detach() if compute_importance: head_importance += head_mask.grad.abs().detach() tot_tokens += torch.ones_like(A ).float().detach().sum().data # Normalize attn_entropy /= tot_tokens head_importance /= tot_tokens # Layerwise importance normalization if not args.dont_normalize_importance_by_layer: snake_case__ : Union[str, Any] = 2 snake_case__ : List[Any] = torch.pow(torch.pow(A , A ).sum(-1 ) , 1 / exponent ) head_importance /= norm_by_layer.unsqueeze(-1 ) + 1e-20 if not args.dont_normalize_global_importance: snake_case__ : Tuple = (head_importance - head_importance.min()) / (head_importance.max() - head_importance.min()) # Print matrices if compute_entropy: logger.info('Attention entropies' ) print_ad_tensor(A ) if compute_importance: logger.info('Head importance scores' ) print_ad_tensor(A ) logger.info('Head ranked by importance scores' ) snake_case__ : Tuple = torch.zeros(head_importance.numel() , dtype=torch.long , device=args.device ) snake_case__ : Union[str, Any] = torch.arange( head_importance.numel() , device=args.device ) snake_case__ : str = head_ranks.view_as(A ) print_ad_tensor(A ) return attn_entropy, head_importance, total_loss def lowercase_ (A : Optional[int] , A : Dict , A : Optional[int] ): snake_case__ , snake_case__ , snake_case__ : Any = compute_heads_importance(A , A , A , compute_entropy=A ) snake_case__ : Tuple = 1 / loss # instead of downsteam score use the LM loss logger.info('Pruning: original score: %f, threshold: %f' , A , original_score * args.masking_threshold ) snake_case__ : Optional[Any] = torch.ones_like(A ) snake_case__ : Union[str, Any] = max(1 , int(new_head_mask.numel() * args.masking_amount ) ) snake_case__ : Dict = original_score while current_score >= original_score * args.masking_threshold: snake_case__ : int = new_head_mask.clone().detach() # save current head mask # heads from least important to most - keep only not-masked heads snake_case__ : List[Any] = float('Inf' ) snake_case__ : Union[str, Any] = head_importance.view(-1 ).sort()[1] if len(A ) <= num_to_mask: print('BREAK BY num_to_mask' ) break # mask heads snake_case__ : int = current_heads_to_mask[:num_to_mask] logger.info('Heads to mask: %s' , str(current_heads_to_mask.tolist() ) ) snake_case__ : int = new_head_mask.view(-1 ) snake_case__ : int = 0.0 snake_case__ : Union[str, Any] = new_head_mask.view_as(A ) snake_case__ : List[str] = new_head_mask.clone().detach() print_ad_tensor(A ) # Compute metric and head importance again snake_case__ , snake_case__ , snake_case__ : Any = compute_heads_importance( A , A , A , compute_entropy=A , head_mask=A ) snake_case__ : Dict = 1 / loss logger.info( 'Masking: current score: %f, remaining heads %d (%.1f percents)' , A , new_head_mask.sum() , new_head_mask.sum() / new_head_mask.numel() * 1_0_0 , ) logger.info('Final head mask' ) print_ad_tensor(A ) np.save(os.path.join(args.output_dir , 'head_mask.npy' ) , head_mask.detach().cpu().numpy() ) return head_mask def lowercase_ (A : List[str] , A : Tuple , A : Optional[Any] , A : int ): snake_case__ : Any = datetime.now() snake_case__ , snake_case__ , snake_case__ : str = compute_heads_importance( A , A , A , compute_entropy=A , compute_importance=A , head_mask=A ) snake_case__ : Tuple = 1 / loss snake_case__ : Dict = datetime.now() - before_time snake_case__ : Union[str, Any] = sum(p.numel() for p in model.parameters() ) snake_case__ : Optional[Any] = { layer: (1 - head_mask[layer].long()).nonzero().squeeze().tolist() for layer in range(len(A ) ) } for k, v in heads_to_prune.items(): if isinstance(A , A ): snake_case__ : Any = [ v, ] assert sum(len(A ) for h in heads_to_prune.values() ) == (1 - head_mask.long()).sum().item() model.prune_heads(A ) snake_case__ : Dict = sum(p.numel() for p in model.parameters() ) snake_case__ : Tuple = datetime.now() snake_case__ , snake_case__ , snake_case__ : Dict = compute_heads_importance( A , A , A , compute_entropy=A , compute_importance=A , head_mask=A , actually_pruned=A , ) snake_case__ : Any = 1 / loss snake_case__ : int = datetime.now() - before_time logger.info( 'Pruning: original num of params: %.2e, after pruning %.2e (%.1f percents)' , A , A , pruned_num_params / original_num_params * 1_0_0 , ) logger.info('Pruning: score with masking: %f score with pruning: %f' , A , A ) logger.info('Pruning: speed ratio (original timing / new timing): %f percents' , original_time / new_time * 1_0_0 ) save_model(A , args.output_dir ) def lowercase_ (): snake_case__ : str = argparse.ArgumentParser() # Required parameters parser.add_argument( '--data_dir' , default=A , type=A , required=A , help='The input data dir. Should contain the .tsv files (or other data files) for the task.' , ) parser.add_argument( '--model_name_or_path' , default=A , type=A , required=A , help='Path to pretrained model or model identifier from huggingface.co/models' , ) parser.add_argument( '--output_dir' , default=A , type=A , required=A , help='The output directory where the model predictions and checkpoints will be written.' , ) # Other parameters parser.add_argument( '--config_name' , default='' , type=A , help='Pretrained config name or path if not the same as model_name_or_path' , ) parser.add_argument( '--tokenizer_name' , default='' , type=A , help='Pretrained tokenizer name or path if not the same as model_name_or_path' , ) parser.add_argument( '--cache_dir' , default=A , type=A , help='Where do you want to store the pre-trained models downloaded from s3' , ) parser.add_argument( '--data_subset' , type=A , default=-1 , help='If > 0: limit the data to a subset of data_subset instances.' ) parser.add_argument( '--overwrite_output_dir' , action='store_true' , help='Whether to overwrite data in output directory' ) parser.add_argument( '--overwrite_cache' , action='store_true' , help='Overwrite the cached training and evaluation sets' ) parser.add_argument( '--dont_normalize_importance_by_layer' , action='store_true' , help='Don\'t normalize importance score by layers' ) parser.add_argument( '--dont_normalize_global_importance' , action='store_true' , help='Don\'t normalize all importance scores between 0 and 1' , ) parser.add_argument( '--try_masking' , action='store_true' , help='Whether to try to mask head until a threshold of accuracy.' ) parser.add_argument( '--masking_threshold' , default=0.9 , type=A , help='masking threshold in term of metrics (stop masking when metric < threshold * original metric value).' , ) parser.add_argument( '--masking_amount' , default=0.1 , type=A , help='Amount to heads to masking at each masking step.' ) parser.add_argument('--metric_name' , default='acc' , type=A , help='Metric to use for head masking.' ) parser.add_argument( '--max_seq_length' , default=1_2_8 , type=A , help=( 'The maximum total input sequence length after WordPiece tokenization. \n' 'Sequences longer than this will be truncated, sequences shorter padded.' ) , ) parser.add_argument('--batch_size' , default=1 , type=A , help='Batch size.' ) parser.add_argument('--seed' , type=A , default=4_2 ) parser.add_argument('--local_rank' , type=A , default=-1 , help='local_rank for distributed training on gpus' ) parser.add_argument('--no_cuda' , action='store_true' , help='Whether not to use CUDA when available' ) parser.add_argument('--server_ip' , type=A , default='' , help='Can be used for distant debugging.' ) parser.add_argument('--server_port' , type=A , default='' , help='Can be used for distant debugging.' ) snake_case__ : Optional[int] = parser.parse_args() if args.server_ip and args.server_port: # Distant debugging - see https://code.visualstudio.com/docs/python/debugging#_attach-to-a-local-script import ptvsd print('Waiting for debugger attach' ) ptvsd.enable_attach(address=(args.server_ip, args.server_port) , redirect_output=A ) ptvsd.wait_for_attach() # Setup devices and distributed training if args.local_rank == -1 or args.no_cuda: snake_case__ : List[Any] = torch.device('cuda' if torch.cuda.is_available() and not args.no_cuda else 'cpu' ) snake_case__ : Optional[Any] = 0 if args.no_cuda else torch.cuda.device_count() else: torch.cuda.set_device(args.local_rank ) snake_case__ : int = torch.device('cuda' , args.local_rank ) snake_case__ : List[str] = 1 torch.distributed.init_process_group(backend='nccl' ) # Initializes the distributed backend # Setup logging logging.basicConfig(level=logging.INFO if args.local_rank in [-1, 0] else logging.WARN ) logger.info('device: {} n_gpu: {}, distributed: {}'.format(args.device , args.n_gpu , bool(args.local_rank != -1 ) ) ) snake_case__ : Any = GPTaLMHeadModel.from_pretrained(args.model_name_or_path ) # Distributed and parallel training model.to(args.device ) if args.local_rank != -1: snake_case__ : List[str] = nn.parallel.DistributedDataParallel( A , device_ids=[args.local_rank] , output_device=args.local_rank , find_unused_parameters=A ) elif args.n_gpu > 1: snake_case__ : Optional[int] = nn.DataParallel(A ) # Print/save training arguments os.makedirs(args.output_dir , exist_ok=A ) torch.save(A , os.path.join(args.output_dir , 'run_args.bin' ) ) logger.info('Training/evaluation parameters %s' , A ) # Prepare dataset snake_case__ : Optional[Any] = np.concatenate( [ np.loadtxt(args.data_dir , dtype=np.intaa ), ] ) snake_case__ : List[str] = (torch.from_numpy(A ),) snake_case__ : int = TensorDataset(*A ) snake_case__ : Union[str, Any] = RandomSampler(A ) snake_case__ : Any = DataLoader(A , sampler=A , batch_size=args.batch_size ) # Compute head entropy and importance score compute_heads_importance(A , A , A ) # Try head masking (set heads to zero until the score goes under a threshole) # and head pruning (remove masked heads and see the effect on the network) if args.try_masking and args.masking_threshold > 0.0 and args.masking_threshold < 1.0: snake_case__ : Dict = mask_heads(A , A , A ) prune_heads(A , A , A , A ) if __name__ == "__main__": main()
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0
'''simple docstring''' import socket def __lowerCAmelCase ( ): __UpperCamelCase : Optional[Any] = socket.socket(socket.AF_INET , socket.SOCK_STREAM ) __UpperCamelCase : Dict = socket.gethostname() __UpperCamelCase : List[str] = 12_312 sock.connect((host, port) ) sock.send(b"Hello server!" ) with open("Received_file" , "wb" ) as out_file: print("File opened" ) print("Receiving data..." ) while True: __UpperCamelCase : Tuple = sock.recv(1_024 ) if not data: break out_file.write(snake_case__ ) print("Successfully received the file" ) sock.close() print("Connection closed" ) if __name__ == "__main__": main()
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import argparse import json from collections import OrderedDict from pathlib import Path import requests import torch from huggingface_hub import hf_hub_download from PIL import Image from transformers import ( SegformerConfig, SegformerForImageClassification, SegformerForSemanticSegmentation, SegformerImageProcessor, ) from transformers.utils import logging logging.set_verbosity_info() a_ :Dict = logging.get_logger(__name__) def lowercase_ (A : Optional[Any] , A : Any=False ): snake_case__ : List[Any] = OrderedDict() for key, value in state_dict.items(): if encoder_only and not key.startswith('head' ): snake_case__ : str = 'segformer.encoder.' + key if key.startswith('backbone' ): snake_case__ : str = key.replace('backbone' , 'segformer.encoder' ) if "patch_embed" in key: # replace for example patch_embed1 by patch_embeddings.0 snake_case__ : Optional[int] = key[key.find('patch_embed' ) + len('patch_embed' )] snake_case__ : int = key.replace(F'''patch_embed{idx}''' , F'''patch_embeddings.{int(A )-1}''' ) if "norm" in key: snake_case__ : Optional[int] = key.replace('norm' , 'layer_norm' ) if "segformer.encoder.layer_norm" in key: # replace for example layer_norm1 by layer_norm.0 snake_case__ : Tuple = key[key.find('segformer.encoder.layer_norm' ) + len('segformer.encoder.layer_norm' )] snake_case__ : Union[str, Any] = key.replace(F'''layer_norm{idx}''' , F'''layer_norm.{int(A )-1}''' ) if "layer_norm1" in key: snake_case__ : List[Any] = key.replace('layer_norm1' , 'layer_norm_1' ) if "layer_norm2" in key: snake_case__ : List[Any] = key.replace('layer_norm2' , 'layer_norm_2' ) if "block" in key: # replace for example block1 by block.0 snake_case__ : List[Any] = key[key.find('block' ) + len('block' )] snake_case__ : List[Any] = key.replace(F'''block{idx}''' , F'''block.{int(A )-1}''' ) if "attn.q" in key: snake_case__ : int = key.replace('attn.q' , 'attention.self.query' ) if "attn.proj" in key: snake_case__ : str = key.replace('attn.proj' , 'attention.output.dense' ) if "attn" in key: snake_case__ : Optional[int] = key.replace('attn' , 'attention.self' ) if "fc1" in key: snake_case__ : str = key.replace('fc1' , 'dense1' ) if "fc2" in key: snake_case__ : Dict = key.replace('fc2' , 'dense2' ) if "linear_pred" in key: snake_case__ : Union[str, Any] = key.replace('linear_pred' , 'classifier' ) if "linear_fuse" in key: snake_case__ : List[str] = key.replace('linear_fuse.conv' , 'linear_fuse' ) snake_case__ : List[Any] = key.replace('linear_fuse.bn' , 'batch_norm' ) if "linear_c" in key: # replace for example linear_c4 by linear_c.3 snake_case__ : Optional[int] = key[key.find('linear_c' ) + len('linear_c' )] snake_case__ : Tuple = key.replace(F'''linear_c{idx}''' , F'''linear_c.{int(A )-1}''' ) if key.startswith('head' ): snake_case__ : Tuple = key.replace('head' , 'classifier' ) snake_case__ : Optional[int] = value return new_state_dict def lowercase_ (A : Tuple , A : Optional[int] ): # for each of the encoder blocks: for i in range(config.num_encoder_blocks ): for j in range(config.depths[i] ): # read in weights + bias of keys and values (which is a single matrix in the original implementation) snake_case__ : List[str] = state_dict.pop(F'''segformer.encoder.block.{i}.{j}.attention.self.kv.weight''' ) snake_case__ : Optional[Any] = state_dict.pop(F'''segformer.encoder.block.{i}.{j}.attention.self.kv.bias''' ) # next, add keys and values (in that order) to the state dict snake_case__ : str = kv_weight[ : config.hidden_sizes[i], : ] snake_case__ : Dict = kv_bias[: config.hidden_sizes[i]] snake_case__ : List[str] = kv_weight[ config.hidden_sizes[i] :, : ] snake_case__ : List[Any] = kv_bias[ config.hidden_sizes[i] : ] def lowercase_ (): snake_case__ : Union[str, Any] = 'http://images.cocodataset.org/val2017/000000039769.jpg' snake_case__ : Dict = Image.open(requests.get(A , stream=A ).raw ) return image @torch.no_grad() def lowercase_ (A : Any , A : Union[str, Any] , A : Optional[Any] ): snake_case__ : List[str] = SegformerConfig() snake_case__ : Dict = False # set attributes based on model_name snake_case__ : Optional[int] = 'huggingface/label-files' if "segformer" in model_name: snake_case__ : str = model_name[len('segformer.' ) : len('segformer.' ) + 2] if "ade" in model_name: snake_case__ : Optional[int] = 1_5_0 snake_case__ : int = 'ade20k-id2label.json' snake_case__ : List[Any] = (1, 1_5_0, 1_2_8, 1_2_8) elif "city" in model_name: snake_case__ : str = 1_9 snake_case__ : List[str] = 'cityscapes-id2label.json' snake_case__ : Optional[Any] = (1, 1_9, 1_2_8, 1_2_8) else: raise ValueError(F'''Model {model_name} not supported''' ) elif "mit" in model_name: snake_case__ : str = True snake_case__ : Union[str, Any] = model_name[4:6] snake_case__ : Optional[Any] = 1_0_0_0 snake_case__ : Optional[int] = 'imagenet-1k-id2label.json' snake_case__ : List[Any] = (1, 1_0_0_0) else: raise ValueError(F'''Model {model_name} not supported''' ) # set config attributes snake_case__ : str = json.load(open(hf_hub_download(A , A , repo_type='dataset' ) , 'r' ) ) snake_case__ : List[Any] = {int(A ): v for k, v in idalabel.items()} snake_case__ : Union[str, Any] = idalabel snake_case__ : Tuple = {v: k for k, v in idalabel.items()} if size == "b0": pass elif size == "b1": snake_case__ : List[Any] = [6_4, 1_2_8, 3_2_0, 5_1_2] snake_case__ : Tuple = 2_5_6 elif size == "b2": snake_case__ : List[str] = [6_4, 1_2_8, 3_2_0, 5_1_2] snake_case__ : int = 7_6_8 snake_case__ : List[Any] = [3, 4, 6, 3] elif size == "b3": snake_case__ : Optional[Any] = [6_4, 1_2_8, 3_2_0, 5_1_2] snake_case__ : int = 7_6_8 snake_case__ : Optional[Any] = [3, 4, 1_8, 3] elif size == "b4": snake_case__ : str = [6_4, 1_2_8, 3_2_0, 5_1_2] snake_case__ : Optional[Any] = 7_6_8 snake_case__ : Union[str, Any] = [3, 8, 2_7, 3] elif size == "b5": snake_case__ : List[str] = [6_4, 1_2_8, 3_2_0, 5_1_2] snake_case__ : Optional[Any] = 7_6_8 snake_case__ : Any = [3, 6, 4_0, 3] else: raise ValueError(F'''Size {size} not supported''' ) # load image processor (only resize + normalize) snake_case__ : Dict = SegformerImageProcessor( image_scale=(5_1_2, 5_1_2) , keep_ratio=A , align=A , do_random_crop=A ) # prepare image snake_case__ : List[str] = prepare_img() snake_case__ : Dict = image_processor(images=A , return_tensors='pt' ).pixel_values logger.info(F'''Converting model {model_name}...''' ) # load original state dict if encoder_only: snake_case__ : Tuple = torch.load(A , map_location=torch.device('cpu' ) ) else: snake_case__ : int = torch.load(A , map_location=torch.device('cpu' ) )['state_dict'] # rename keys snake_case__ : List[Any] = rename_keys(A , encoder_only=A ) if not encoder_only: del state_dict["decode_head.conv_seg.weight"] del state_dict["decode_head.conv_seg.bias"] # key and value matrices need special treatment read_in_k_v(A , A ) # create HuggingFace model and load state dict if encoder_only: snake_case__ : str = False snake_case__ : List[Any] = SegformerForImageClassification(A ) else: snake_case__ : Dict = SegformerForSemanticSegmentation(A ) model.load_state_dict(A ) model.eval() # forward pass snake_case__ : int = model(A ) snake_case__ : Any = outputs.logits # set expected_slice based on model name # ADE20k checkpoints if model_name == "segformer.b0.512x512.ade.160k": snake_case__ : Dict = torch.tensor( [ [[-4.6310, -5.5232, -6.2356], [-5.1921, -6.1444, -6.5996], [-5.4424, -6.2790, -6.7574]], [[-12.1391, -13.3122, -13.9554], [-12.8732, -13.9352, -14.3563], [-12.9438, -13.8226, -14.2513]], [[-12.5134, -13.4686, -14.4915], [-12.8669, -14.4343, -14.7758], [-13.2523, -14.5819, -15.0694]], ] ) elif model_name == "segformer.b1.512x512.ade.160k": snake_case__ : Optional[int] = torch.tensor( [ [[-7.5820, -8.7231, -8.3215], [-8.0600, -10.3529, -10.0304], [-7.5208, -9.4103, -9.6239]], [[-12.6918, -13.8994, -13.7137], [-13.3196, -15.7523, -15.4789], [-12.9343, -14.8757, -14.9689]], [[-11.1911, -11.9421, -11.3243], [-11.3342, -13.6839, -13.3581], [-10.3909, -12.1832, -12.4858]], ] ) elif model_name == "segformer.b2.512x512.ade.160k": snake_case__ : List[Any] = torch.tensor( [ [[-11.8173, -14.3850, -16.3128], [-14.5648, -16.5804, -18.6568], [-14.7223, -15.7387, -18.4218]], [[-15.7290, -17.9171, -19.4423], [-18.3105, -19.9448, -21.4661], [-17.9296, -18.6497, -20.7910]], [[-15.0783, -17.0336, -18.2789], [-16.8771, -18.6870, -20.1612], [-16.2454, -17.1426, -19.5055]], ] ) elif model_name == "segformer.b3.512x512.ade.160k": snake_case__ : Union[str, Any] = torch.tensor( [ [[-9.0878, -10.2081, -10.1891], [-9.3144, -10.7941, -10.9843], [-9.2294, -10.3855, -10.5704]], [[-12.2316, -13.9068, -13.6102], [-12.9161, -14.3702, -14.3235], [-12.5233, -13.7174, -13.7932]], [[-14.6275, -15.2490, -14.9727], [-14.3400, -15.9687, -16.2827], [-14.1484, -15.4033, -15.8937]], ] ) elif model_name == "segformer.b4.512x512.ade.160k": snake_case__ : Dict = torch.tensor( [ [[-12.3144, -13.2447, -14.0802], [-13.3614, -14.5816, -15.6117], [-13.3340, -14.4433, -16.2219]], [[-19.2781, -20.4128, -20.7506], [-20.6153, -21.6566, -22.0998], [-19.9800, -21.0430, -22.1494]], [[-18.8739, -19.7804, -21.1834], [-20.1233, -21.6765, -23.2944], [-20.0315, -21.2641, -23.6944]], ] ) elif model_name == "segformer.b5.640x640.ade.160k": snake_case__ : List[Any] = torch.tensor( [ [[-9.5524, -12.0835, -11.7348], [-10.5229, -13.6446, -14.5662], [-9.5842, -12.8851, -13.9414]], [[-15.3432, -17.5323, -17.0818], [-16.3330, -18.9255, -19.2101], [-15.1340, -17.7848, -18.3971]], [[-12.6072, -14.9486, -14.6631], [-13.7629, -17.0907, -17.7745], [-12.7899, -16.1695, -17.1671]], ] ) # Cityscapes checkpoints elif model_name == "segformer.b0.1024x1024.city.160k": snake_case__ : str = torch.tensor( [ [[-11.9295, -13.4057, -14.8106], [-13.3431, -14.8179, -15.3781], [-14.2836, -15.5942, -16.1588]], [[-11.4906, -12.8067, -13.6564], [-13.1189, -14.0500, -14.1543], [-13.8748, -14.5136, -14.8789]], [[0.5374, 0.1067, -0.4742], [0.1141, -0.2255, -0.7099], [-0.3000, -0.5924, -1.3105]], ] ) elif model_name == "segformer.b0.512x1024.city.160k": snake_case__ : Tuple = torch.tensor( [ [[-7.8217, -9.8767, -10.1717], [-9.4438, -10.9058, -11.4047], [-9.7939, -12.3495, -12.1079]], [[-7.1514, -9.5336, -10.0860], [-9.7776, -11.6822, -11.8439], [-10.1411, -12.7655, -12.8972]], [[0.3021, 0.0805, -0.2310], [-0.0328, -0.1605, -0.2714], [-0.1408, -0.5477, -0.6976]], ] ) elif model_name == "segformer.b0.640x1280.city.160k": snake_case__ : Any = torch.tensor( [ [ [-1.1_372e01, -1.2_787e01, -1.3_477e01], [-1.2_536e01, -1.4_194e01, -1.4_409e01], [-1.3_217e01, -1.4_888e01, -1.5_327e01], ], [ [-1.4_791e01, -1.7_122e01, -1.8_277e01], [-1.7_163e01, -1.9_192e01, -1.9_533e01], [-1.7_897e01, -1.9_991e01, -2.0_315e01], ], [ [7.6_723e-01, 4.1_921e-01, -7.7_878e-02], [4.7_772e-01, 9.5_557e-03, -2.8_082e-01], [3.6_032e-01, -2.4_826e-01, -5.1_168e-01], ], ] ) elif model_name == "segformer.b0.768x768.city.160k": snake_case__ : Optional[int] = torch.tensor( [ [[-9.4959, -11.3087, -11.7479], [-11.0025, -12.6540, -12.3319], [-11.4064, -13.0487, -12.9905]], [[-9.8905, -11.3084, -12.0854], [-11.1726, -12.7698, -12.9583], [-11.5985, -13.3278, -14.1774]], [[0.2213, 0.0192, -0.2466], [-0.1731, -0.4213, -0.4874], [-0.3126, -0.6541, -1.1389]], ] ) elif model_name == "segformer.b1.1024x1024.city.160k": snake_case__ : Union[str, Any] = torch.tensor( [ [[-13.5748, -13.9111, -12.6500], [-14.3500, -15.3683, -14.2328], [-14.7532, -16.0424, -15.6087]], [[-17.1651, -15.8725, -12.9653], [-17.2580, -17.3718, -14.8223], [-16.6058, -16.8783, -16.7452]], [[-3.6456, -3.0209, -1.4203], [-3.0797, -3.1959, -2.0000], [-1.8757, -1.9217, -1.6997]], ] ) elif model_name == "segformer.b2.1024x1024.city.160k": snake_case__ : List[str] = torch.tensor( [ [[-16.0976, -16.4856, -17.3962], [-16.6234, -19.0342, -19.7685], [-16.0900, -18.0661, -19.1180]], [[-18.4750, -18.8488, -19.5074], [-19.4030, -22.1570, -22.5977], [-19.1191, -20.8486, -22.3783]], [[-4.5178, -5.5037, -6.5109], [-5.0884, -7.2174, -8.0334], [-4.4156, -5.8117, -7.2970]], ] ) elif model_name == "segformer.b3.1024x1024.city.160k": snake_case__ : List[Any] = torch.tensor( [ [[-14.2081, -14.4732, -14.1977], [-14.5867, -16.4423, -16.6356], [-13.4441, -14.9685, -16.8696]], [[-14.4576, -14.7073, -15.0451], [-15.0816, -17.6237, -17.9873], [-14.4213, -16.0199, -18.5992]], [[-4.7349, -4.9588, -5.0966], [-4.3210, -6.9325, -7.2591], [-3.4312, -4.7484, -7.1917]], ] ) elif model_name == "segformer.b4.1024x1024.city.160k": snake_case__ : str = torch.tensor( [ [[-11.7737, -11.9526, -11.3273], [-13.6692, -14.4574, -13.8878], [-13.8937, -14.6924, -15.9345]], [[-14.6706, -14.5330, -14.1306], [-16.1502, -16.8180, -16.4269], [-16.8338, -17.8939, -20.1746]], [[1.0491, 0.8289, 1.0310], [1.1044, 0.5219, 0.8055], [1.0899, 0.6926, 0.5590]], ] ) elif model_name == "segformer.b5.1024x1024.city.160k": snake_case__ : List[str] = torch.tensor( [ [[-12.5641, -13.4777, -13.0684], [-13.9587, -15.8983, -16.6557], [-13.3109, -15.7350, -16.3141]], [[-14.7074, -15.4352, -14.5944], [-16.6353, -18.1663, -18.6120], [-15.1702, -18.0329, -18.1547]], [[-1.7990, -2.0951, -1.7784], [-2.6397, -3.8245, -3.9686], [-1.5264, -2.8126, -2.9316]], ] ) else: snake_case__ : Tuple = logits.argmax(-1 ).item() print('Predicted class:' , model.config.idalabel[predicted_class_idx] ) # verify logits if not encoder_only: assert logits.shape == expected_shape assert torch.allclose(logits[0, :3, :3, :3] , A , atol=1e-2 ) # finally, save model and image processor logger.info(F'''Saving PyTorch model and image processor to {pytorch_dump_folder_path}...''' ) Path(A ).mkdir(exist_ok=A ) model.save_pretrained(A ) image_processor.save_pretrained(A ) if __name__ == "__main__": a_ :Optional[int] = argparse.ArgumentParser() parser.add_argument( "--model_name", default="segformer.b0.512x512.ade.160k", type=str, help="Name of the model you'd like to convert.", ) parser.add_argument( "--checkpoint_path", default=None, type=str, help="Path to the original PyTorch checkpoint (.pth file)." ) parser.add_argument( "--pytorch_dump_folder_path", default=None, type=str, help="Path to the folder to output PyTorch model." ) a_ :Union[str, Any] = parser.parse_args() convert_segformer_checkpoint(args.model_name, args.checkpoint_path, args.pytorch_dump_folder_path)
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from typing import TYPE_CHECKING from ...utils import ( OptionalDependencyNotAvailable, _LazyModule, is_sentencepiece_available, is_tokenizers_available, is_torch_available, ) _snake_case = {"configuration_reformer": ["REFORMER_PRETRAINED_CONFIG_ARCHIVE_MAP", "ReformerConfig"]} try: if not is_sentencepiece_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: _snake_case = ["ReformerTokenizer"] try: if not is_tokenizers_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: _snake_case = ["ReformerTokenizerFast"] try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: _snake_case = [ "REFORMER_PRETRAINED_MODEL_ARCHIVE_LIST", "ReformerAttention", "ReformerForMaskedLM", "ReformerForQuestionAnswering", "ReformerForSequenceClassification", "ReformerLayer", "ReformerModel", "ReformerModelWithLMHead", "ReformerPreTrainedModel", ] if TYPE_CHECKING: from .configuration_reformer import REFORMER_PRETRAINED_CONFIG_ARCHIVE_MAP, ReformerConfig try: if not is_sentencepiece_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .tokenization_reformer import ReformerTokenizer try: if not is_tokenizers_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .tokenization_reformer_fast import ReformerTokenizerFast try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_reformer import ( REFORMER_PRETRAINED_MODEL_ARCHIVE_LIST, ReformerAttention, ReformerForMaskedLM, ReformerForQuestionAnswering, ReformerForSequenceClassification, ReformerLayer, ReformerModel, ReformerModelWithLMHead, ReformerPreTrainedModel, ) else: import sys _snake_case = _LazyModule(__name__, globals()["__file__"], _import_structure, module_spec=__spec__)
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import argparse import json import os import fairseq import torch from fairseq.data import Dictionary from transformers import ( WavaVecaConfig, WavaVecaCTCTokenizer, WavaVecaFeatureExtractor, WavaVecaForCTC, WavaVecaForPreTraining, WavaVecaProcessor, logging, ) from transformers.models.wavaveca.modeling_wavaveca import WavaVecaForSequenceClassification logging.set_verbosity_info() a_ :List[Any] = logging.get_logger(__name__) a_ :List[Any] = { "post_extract_proj": "feature_projection.projection", "encoder.pos_conv.0": "encoder.pos_conv_embed.conv", "self_attn.k_proj": "encoder.layers.*.attention.k_proj", "self_attn.v_proj": "encoder.layers.*.attention.v_proj", "self_attn.q_proj": "encoder.layers.*.attention.q_proj", "self_attn.out_proj": "encoder.layers.*.attention.out_proj", "self_attn_layer_norm": "encoder.layers.*.layer_norm", "fc1": "encoder.layers.*.feed_forward.intermediate_dense", "fc2": "encoder.layers.*.feed_forward.output_dense", "final_layer_norm": "encoder.layers.*.final_layer_norm", "encoder.layer_norm": "encoder.layer_norm", "adapter_layer": "encoder.layers.*.adapter_layer", "w2v_model.layer_norm": "feature_projection.layer_norm", "quantizer.weight_proj": "quantizer.weight_proj", "quantizer.vars": "quantizer.codevectors", "project_q": "project_q", "final_proj": "project_hid", "w2v_encoder.proj": "lm_head", "mask_emb": "masked_spec_embed", "pooling_layer.linear": "projector", "pooling_layer.projection": "classifier", } a_ :List[Any] = [ "lm_head", "quantizer.weight_proj", "quantizer.codevectors", "project_q", "project_hid", "projector", "classifier", ] def lowercase_ (A : Dict ): snake_case__ : Optional[Any] = {} with open(A , 'r' ) as file: for line_number, line in enumerate(A ): snake_case__ : Dict = line.strip() if line: snake_case__ : int = line.split() snake_case__ : List[str] = line_number snake_case__ : Dict = words[0] snake_case__ : Optional[Any] = value return result def lowercase_ (A : int , A : int , A : Optional[int] , A : Optional[Any] , A : Tuple ): for attribute in key.split('.' ): snake_case__ : Optional[int] = getattr(A , A ) snake_case__ : Union[str, Any] = None for param_key in PARAM_MAPPING.keys(): if full_name.endswith(A ): snake_case__ : List[str] = PARAM_MAPPING[full_name.split('.' )[-1]] snake_case__ : Dict = 'param' if weight_type is not None and weight_type != "param": snake_case__ : Union[str, Any] = getattr(A , A ).shape elif weight_type is not None and weight_type == "param": snake_case__ : Optional[int] = hf_pointer for attribute in hf_param_name.split('.' ): snake_case__ : Optional[Any] = getattr(A , A ) snake_case__ : Dict = shape_pointer.shape # let's reduce dimension snake_case__ : List[Any] = value[0] else: snake_case__ : Union[str, Any] = hf_pointer.shape if hf_shape != value.shape: raise ValueError( F'''Shape of hf {key + "." + weight_type if weight_type is not None else ""} is {hf_shape}, but should be''' F''' {value.shape} for {full_name}''' ) if weight_type == "weight": snake_case__ : Any = value elif weight_type == "weight_g": snake_case__ : List[Any] = value elif weight_type == "weight_v": snake_case__ : Any = value elif weight_type == "bias": snake_case__ : List[Any] = value elif weight_type == "param": for attribute in hf_param_name.split('.' ): snake_case__ : int = getattr(A , A ) snake_case__ : Optional[int] = value else: snake_case__ : Optional[Any] = value logger.info(F'''{key + "." + weight_type if weight_type is not None else ""} was initialized from {full_name}.''' ) def lowercase_ (A : Tuple , A : List[Any] , A : int , A : str , A : Tuple ): snake_case__ : Optional[int] = None for param_key in PARAM_MAPPING.keys(): if full_name.endswith(A ): snake_case__ : List[str] = PARAM_MAPPING[full_name.split('.' )[-1]] snake_case__ : str = 'param' if weight_type is not None and weight_type != "param": snake_case__ : int = '.'.join([key, weight_type] ) elif weight_type is not None and weight_type == "param": snake_case__ : Any = '.'.join([key, hf_param_name] ) else: snake_case__ : Dict = key snake_case__ : List[str] = value if 'lm_head' in full_key else value[0] a_ :List[str] = { "W_a": "linear_1.weight", "W_b": "linear_2.weight", "b_a": "linear_1.bias", "b_b": "linear_2.bias", "ln_W": "norm.weight", "ln_b": "norm.bias", } def lowercase_ (A : str , A : Optional[Any] , A : Optional[Any]=None , A : List[str]=None ): snake_case__ : Optional[int] = False for key, mapped_key in MAPPING.items(): snake_case__ : Tuple = 'wav2vec2.' + mapped_key if mapped_key not in TOP_LEVEL_KEYS else mapped_key if key in name or key.split('w2v_model.' )[-1] == name.split('.' )[0]: snake_case__ : Optional[int] = True if "*" in mapped_key: snake_case__ : List[Any] = name.split(A )[0].split('.' )[-2] snake_case__ : Union[str, Any] = mapped_key.replace('*' , A ) if "weight_g" in name: snake_case__ : Tuple = 'weight_g' elif "weight_v" in name: snake_case__ : List[str] = 'weight_v' elif "bias" in name: snake_case__ : Dict = 'bias' elif "weight" in name: # TODO: don't match quantizer.weight_proj snake_case__ : Optional[int] = 'weight' else: snake_case__ : str = None if hf_dict is not None: rename_dict(A , A , A , A , A ) else: set_recursively(A , A , A , A , A ) return is_used return is_used def lowercase_ (A : Optional[Any] , A : Dict , A : Optional[int] ): snake_case__ : Dict = [] snake_case__ : Tuple = fairseq_model.state_dict() snake_case__ : str = hf_model.wavaveca.feature_extractor for name, value in fairseq_dict.items(): snake_case__ : str = False if "conv_layers" in name: load_conv_layer( A , A , A , A , hf_model.config.feat_extract_norm == 'group' , ) snake_case__ : Any = True else: snake_case__ : Dict = load_wavaveca_layer(A , A , A ) if not is_used: unused_weights.append(A ) logger.warning(F'''Unused weights: {unused_weights}''' ) def lowercase_ (A : Dict , A : Optional[Any] , A : Tuple , A : str , A : List[str] ): snake_case__ : List[Any] = full_name.split('conv_layers.' )[-1] snake_case__ : List[str] = name.split('.' ) snake_case__ : List[Any] = int(items[0] ) snake_case__ : str = int(items[1] ) if type_id == 0: if "bias" in name: if value.shape != feature_extractor.conv_layers[layer_id].conv.bias.data.shape: raise ValueError( F'''{full_name} has size {value.shape}, but''' F''' {feature_extractor.conv_layers[layer_id].conv.bias.data.shape} was found.''' ) snake_case__ : Any = value logger.info(F'''Feat extract conv layer {layer_id} was initialized from {full_name}.''' ) elif "weight" in name: if value.shape != feature_extractor.conv_layers[layer_id].conv.weight.data.shape: raise ValueError( F'''{full_name} has size {value.shape}, but''' F''' {feature_extractor.conv_layers[layer_id].conv.weight.data.shape} was found.''' ) snake_case__ : str = value logger.info(F'''Feat extract conv layer {layer_id} was initialized from {full_name}.''' ) elif (type_id == 2 and not use_group_norm) or (type_id == 2 and layer_id == 0 and use_group_norm): if "bias" in name: if value.shape != feature_extractor.conv_layers[layer_id].layer_norm.bias.data.shape: raise ValueError( F'''{full_name} has size {value.shape}, but''' F''' {feature_extractor.conv_layers[layer_id].layer_norm.bias.data.shape} was found.''' ) snake_case__ : str = value logger.info(F'''Feat extract layer norm weight of layer {layer_id} was initialized from {full_name}.''' ) elif "weight" in name: if value.shape != feature_extractor.conv_layers[layer_id].layer_norm.weight.data.shape: raise ValueError( F'''{full_name} has size {value.shape}, but''' F''' {feature_extractor.conv_layers[layer_id].layer_norm.weight.data.shape} was found.''' ) snake_case__ : int = value logger.info(F'''Feat extract layer norm weight of layer {layer_id} was initialized from {full_name}.''' ) else: unused_weights.append(A ) @torch.no_grad() def lowercase_ (A : Union[str, Any] , A : str , A : Tuple=None , A : List[str]=None , A : Any=True , A : Optional[int]=False ): if config_path is not None: snake_case__ : List[Any] = WavaVecaConfig.from_pretrained(A ) else: snake_case__ : List[Any] = WavaVecaConfig() if is_seq_class: snake_case__ : Dict = read_txt_into_dict(A ) snake_case__ : Any = idalabel snake_case__ : Union[str, Any] = WavaVecaForSequenceClassification(A ) snake_case__ : Any = WavaVecaFeatureExtractor( feature_size=1 , sampling_rate=1_6_0_0_0 , padding_value=0 , do_normalize=A , return_attention_mask=A , ) feature_extractor.save_pretrained(A ) elif is_finetuned: if dict_path: snake_case__ : str = Dictionary.load(A ) # important change bos & pad token id since CTC symbol is <pad> and # not <s> as in fairseq snake_case__ : List[str] = target_dict.pad_index snake_case__ : Optional[int] = target_dict.bos_index snake_case__ : Optional[int] = target_dict.eos_index snake_case__ : List[Any] = len(target_dict.symbols ) snake_case__ : str = os.path.join(A , 'vocab.json' ) if not os.path.isdir(A ): logger.error('--pytorch_dump_folder_path ({}) should be a directory'.format(A ) ) return os.makedirs(A , exist_ok=A ) snake_case__ : Optional[Any] = target_dict.indices # fairseq has the <pad> and <s> switched snake_case__ : Optional[Any] = 0 snake_case__ : Union[str, Any] = 1 with open(A , 'w' , encoding='utf-8' ) as vocab_handle: json.dump(A , A ) snake_case__ : List[Any] = WavaVecaCTCTokenizer( A , unk_token=target_dict.unk_word , pad_token=target_dict.pad_word , bos_token=target_dict.bos_word , eos_token=target_dict.eos_word , word_delimiter_token='|' , do_lower_case=A , ) snake_case__ : str = True if config.feat_extract_norm == 'layer' else False snake_case__ : Optional[Any] = WavaVecaFeatureExtractor( feature_size=1 , sampling_rate=1_6_0_0_0 , padding_value=0 , do_normalize=A , return_attention_mask=A , ) snake_case__ : Union[str, Any] = WavaVecaProcessor(feature_extractor=A , tokenizer=A ) processor.save_pretrained(A ) snake_case__ : str = WavaVecaForCTC(A ) else: snake_case__ : int = WavaVecaForPreTraining(A ) if is_finetuned or is_seq_class: snake_case__ , snake_case__ , snake_case__ : str = fairseq.checkpoint_utils.load_model_ensemble_and_task( [checkpoint_path] , arg_overrides={'data': '/'.join(dict_path.split('/' )[:-1] )} ) else: snake_case__ : Tuple = argparse.Namespace(task='audio_pretraining' ) snake_case__ : str = fairseq.tasks.setup_task(A ) snake_case__ , snake_case__ , snake_case__ : Any = fairseq.checkpoint_utils.load_model_ensemble_and_task([checkpoint_path] , task=A ) snake_case__ : List[Any] = model[0].eval() recursively_load_weights(A , A , not is_finetuned ) hf_wavavec.save_pretrained(A ) if __name__ == "__main__": a_ :List[Any] = argparse.ArgumentParser() parser.add_argument("--pytorch_dump_folder_path", default=None, type=str, help="Path to the output PyTorch model.") parser.add_argument("--checkpoint_path", default=None, type=str, help="Path to fairseq checkpoint") parser.add_argument("--dict_path", default=None, type=str, help="Path to dict of fine-tuned model") parser.add_argument("--config_path", default=None, type=str, help="Path to hf config.json of model to convert") parser.add_argument( "--not_finetuned", action="store_true", help="Whether the model to convert is a fine-tuned model or not" ) parser.add_argument( "--is_seq_class", action="store_true", help="Whether the model to convert is a fine-tuned sequence classification model or not", ) a_ :str = parser.parse_args() a_ :Tuple = not args.not_finetuned and not args.is_seq_class convert_wavaveca_checkpoint( args.checkpoint_path, args.pytorch_dump_folder_path, args.config_path, args.dict_path, is_finetuned, args.is_seq_class, )
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import os import re import warnings from shutil import copyfile from typing import TYPE_CHECKING, Any, Dict, List, Optional, Tuple import sentencepiece as spm from ...tokenization_utils import PreTrainedTokenizer if TYPE_CHECKING: from ...tokenization_utils_base import TextInput from ...utils import logging UpperCAmelCase__ = logging.get_logger(__name__) UpperCAmelCase__ = {"vocab_file": "spiece.model"} UpperCAmelCase__ = { "vocab_file": { "t5-small": "https://huggingface.co/t5-small/resolve/main/spiece.model", "t5-base": "https://huggingface.co/t5-base/resolve/main/spiece.model", "t5-large": "https://huggingface.co/t5-large/resolve/main/spiece.model", "t5-3b": "https://huggingface.co/t5-3b/resolve/main/spiece.model", "t5-11b": "https://huggingface.co/t5-11b/resolve/main/spiece.model", } } # TODO(PVP) - this should be removed in Transformers v5 UpperCAmelCase__ = { "t5-small": 512, "t5-base": 512, "t5-large": 512, "t5-3b": 512, "t5-11b": 512, } UpperCAmelCase__ = "▁" class __lowerCAmelCase ( lowerCAmelCase_ ): UpperCamelCase = VOCAB_FILES_NAMES UpperCamelCase = PRETRAINED_VOCAB_FILES_MAP UpperCamelCase = PRETRAINED_POSITIONAL_EMBEDDINGS_SIZES UpperCamelCase = ['''input_ids''', '''attention_mask'''] def __init__( self : Dict , A : List[Any] , A : str="</s>" , A : List[Any]="<unk>" , A : Union[str, Any]="<pad>" , A : List[Any]=1_00 , A : str=None , A : Optional[Dict[str, Any]] = None , A : Optional[Any]=True , **A : List[str] , ) -> None: """simple docstring""" if extra_ids > 0 and additional_special_tokens is None: _UpperCAmelCase = [F"<extra_id_{i}>" for i in range(_snake_case)] elif extra_ids > 0 and additional_special_tokens is not None: # Check that we have the right number of extra_id special tokens _UpperCAmelCase = len(set(filter(lambda A: bool('extra_id' in str(_snake_case)) , _snake_case))) if extra_tokens != extra_ids: raise ValueError( F"Both extra_ids ({extra_ids}) and additional_special_tokens ({additional_special_tokens}) are" ' provided to T5Tokenizer. In this case the additional_special_tokens must include the extra_ids' ' tokens') if legacy: logger.warning_once( F"You are using the legacy behaviour of the {self.__class__}. This means that tokens that come after special tokens will not be properly handled. We recommend you to" ' read the related pull request available at https://github.com/huggingface/transformers/pull/24565') _UpperCAmelCase = legacy _UpperCAmelCase = {} if sp_model_kwargs is None else sp_model_kwargs super().__init__( eos_token=_snake_case , unk_token=_snake_case , pad_token=_snake_case , extra_ids=_snake_case , additional_special_tokens=_snake_case , sp_model_kwargs=self.sp_model_kwargs , legacy=_snake_case , **_snake_case , ) _UpperCAmelCase = vocab_file _UpperCAmelCase = extra_ids _UpperCAmelCase = spm.SentencePieceProcessor(**self.sp_model_kwargs) self.sp_model.Load(_snake_case) @staticmethod def _lowerCamelCase ( A : Optional[int] , A : Optional[int] , A : List[Any]) -> Tuple: """simple docstring""" if pretrained_model_name_or_path in TaTokenizer.max_model_input_sizes: _UpperCAmelCase = TaTokenizer.max_model_input_sizes[pretrained_model_name_or_path] if init_max_model_length is not None and init_max_model_length != max_model_length: return init_max_model_length elif init_max_model_length is None: warnings.warn( 'This tokenizer was incorrectly instantiated with a model max length of' F" {deprecated_max_model_length} which will be corrected in Transformers v5.\nFor now, this" ' behavior is kept to avoid breaking backwards compatibility when padding/encoding with' ' `truncation is True`.\n- Be aware that you SHOULD NOT rely on' F" {pretrained_model_name_or_path} automatically truncating your input to" F" {deprecated_max_model_length} when padding/encoding.\n- If you want to encode/pad to sequences" F" longer than {deprecated_max_model_length} you can either instantiate this tokenizer with" ' `model_max_length` or pass `max_length` when encoding/padding.\n- To avoid this warning, please' ' instantiate this tokenizer with `model_max_length` set to your preferred value.' , _snake_case , ) return max_model_length @property def _lowerCamelCase ( self : Optional[Any]) -> Tuple: """simple docstring""" return self.sp_model.get_piece_size() + self._extra_ids def _lowerCamelCase ( self : Optional[Any]) -> List[Any]: """simple docstring""" _UpperCAmelCase = {self.convert_ids_to_tokens(_snake_case): i for i in range(self.vocab_size)} vocab.update(self.added_tokens_encoder) return vocab def _lowerCamelCase ( self : List[Any] , A : List[int] , A : Optional[List[int]] = None , A : bool = False) -> List[int]: """simple docstring""" if already_has_special_tokens: return super().get_special_tokens_mask( token_ids_a=_snake_case , token_ids_a=_snake_case , already_has_special_tokens=_snake_case) # normal case: some special tokens if token_ids_a is None: return ([0] * len(_snake_case)) + [1] return ([0] * len(_snake_case)) + [1] + ([0] * len(_snake_case)) + [1] def _lowerCamelCase ( self : Tuple) -> Union[str, Any]: """simple docstring""" return list( set(filter(lambda A: bool(re.search(R'<extra_id_\d+>' , _snake_case)) is not None , self.additional_special_tokens))) def _lowerCamelCase ( self : Any) -> str: """simple docstring""" return [self._convert_token_to_id(_snake_case) for token in self.get_sentinel_tokens()] def _lowerCamelCase ( self : Dict , A : List[int]) -> List[int]: """simple docstring""" if len(_snake_case) > 0 and token_ids[-1] == self.eos_token_id: warnings.warn( F"This sequence already has {self.eos_token}. In future versions this behavior may lead to duplicated" ' eos tokens being added.') return token_ids else: return token_ids + [self.eos_token_id] def _lowerCamelCase ( self : Optional[Any] , A : List[int] , A : Optional[List[int]] = None) -> List[int]: """simple docstring""" _UpperCAmelCase = [self.eos_token_id] if token_ids_a is None: return len(token_ids_a + eos) * [0] return len(token_ids_a + eos + token_ids_a + eos) * [0] def _lowerCamelCase ( self : int , A : List[int] , A : Optional[List[int]] = None) -> List[int]: """simple docstring""" _UpperCAmelCase = self._add_eos_if_not_present(_snake_case) if token_ids_a is None: return token_ids_a else: _UpperCAmelCase = self._add_eos_if_not_present(_snake_case) return token_ids_a + token_ids_a def __getstate__( self : Optional[Any]) -> Union[str, Any]: """simple docstring""" _UpperCAmelCase = self.__dict__.copy() _UpperCAmelCase = None return state def __setstate__( self : Optional[int] , A : Optional[int]) -> Dict: """simple docstring""" _UpperCAmelCase = d # for backward compatibility if not hasattr(self , 'sp_model_kwargs'): _UpperCAmelCase = {} _UpperCAmelCase = spm.SentencePieceProcessor(**self.sp_model_kwargs) self.sp_model.Load(self.vocab_file) def _lowerCamelCase ( self : Tuple , A : "TextInput" , **A : Union[str, Any]) -> List[str]: """simple docstring""" if not self.legacy: _UpperCAmelCase = SPIECE_UNDERLINE + text.replace(_snake_case , ' ') return super().tokenize(_snake_case , **_snake_case) def _lowerCamelCase ( self : int , A : Optional[Any] , **A : Optional[Any]) -> int: """simple docstring""" if not self.legacy: _UpperCAmelCase = text.startswith(_snake_case) if is_first: _UpperCAmelCase = text[1:] _UpperCAmelCase = self.sp_model.encode(_snake_case , out_type=_snake_case) if not self.legacy and not is_first and not text.startswith(' ') and tokens[0].startswith(_snake_case): _UpperCAmelCase = ([tokens[0][1:]] if len(tokens[0]) > 1 else []) + tokens[1:] return tokens def _lowerCamelCase ( self : Union[str, Any] , A : List[Any]) -> int: """simple docstring""" if token.startswith('<extra_id_'): _UpperCAmelCase = re.match(R'<extra_id_(\d+)>' , _snake_case) _UpperCAmelCase = int(match.group(1)) return self.vocab_size - num - 1 return self.sp_model.piece_to_id(_snake_case) def _lowerCamelCase ( self : int , A : int) -> int: """simple docstring""" if index < self.sp_model.get_piece_size(): _UpperCAmelCase = self.sp_model.IdToPiece(_snake_case) else: _UpperCAmelCase = F"<extra_id_{self.vocab_size - 1 - index}>" return token def _lowerCamelCase ( self : Optional[Any] , A : Union[str, Any]) -> Optional[int]: """simple docstring""" _UpperCAmelCase = [] _UpperCAmelCase = '' _UpperCAmelCase = False for token in tokens: # make sure that special tokens are not decoded using sentencepiece model if token in self.all_special_tokens: if not prev_is_special: out_string += " " out_string += self.sp_model.decode(_snake_case) + token _UpperCAmelCase = True _UpperCAmelCase = [] else: current_sub_tokens.append(_snake_case) _UpperCAmelCase = False out_string += self.sp_model.decode(_snake_case) return out_string.strip() def _lowerCamelCase ( self : int , A : str , A : Optional[str] = None) -> Tuple[str]: """simple docstring""" if not os.path.isdir(_snake_case): logger.error(F"Vocabulary path ({save_directory}) should be a directory") return _UpperCAmelCase = os.path.join( _snake_case , (filename_prefix + '-' if filename_prefix else '') + VOCAB_FILES_NAMES['vocab_file']) if os.path.abspath(self.vocab_file) != os.path.abspath(_snake_case) and os.path.isfile(self.vocab_file): copyfile(self.vocab_file , _snake_case) elif not os.path.isfile(self.vocab_file): with open(_snake_case , 'wb') as fi: _UpperCAmelCase = self.sp_model.serialized_model_proto() fi.write(_snake_case) return (out_vocab_file,)
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from typing import Dict, List from nltk.translate import gleu_score import datasets from datasets import MetricInfo a_ :Any = "\\n@misc{wu2016googles,\n title={Google's Neural Machine Translation System: Bridging the Gap between Human and Machine Translation},\n author={Yonghui Wu and Mike Schuster and Zhifeng Chen and Quoc V. Le and Mohammad Norouzi and Wolfgang Macherey\n and Maxim Krikun and Yuan Cao and Qin Gao and Klaus Macherey and Jeff Klingner and Apurva Shah and Melvin\n Johnson and Xiaobing Liu and Łukasz Kaiser and Stephan Gouws and Yoshikiyo Kato and Taku Kudo and Hideto\n Kazawa and Keith Stevens and George Kurian and Nishant Patil and Wei Wang and Cliff Young and\n Jason Smith and Jason Riesa and Alex Rudnick and Oriol Vinyals and Greg Corrado and Macduff Hughes\n and Jeffrey Dean},\n year={2016},\n eprint={1609.08144},\n archivePrefix={arXiv},\n primaryClass={cs.CL}\n}\n" a_ :List[str] = "\\nThe BLEU score has some undesirable properties when used for single\nsentences, as it was designed to be a corpus measure. We therefore\nuse a slightly different score for our RL experiments which we call\nthe 'GLEU score'. For the GLEU score, we record all sub-sequences of\n1, 2, 3 or 4 tokens in output and target sequence (n-grams). We then\ncompute a recall, which is the ratio of the number of matching n-grams\nto the number of total n-grams in the target (ground truth) sequence,\nand a precision, which is the ratio of the number of matching n-grams\nto the number of total n-grams in the generated output sequence. Then\nGLEU score is simply the minimum of recall and precision. This GLEU\nscore's range is always between 0 (no matches) and 1 (all match) and\nit is symmetrical when switching output and target. According to\nour experiments, GLEU score correlates quite well with the BLEU\nmetric on a corpus level but does not have its drawbacks for our per\nsentence reward objective.\n" a_ :List[str] = "\\nComputes corpus-level Google BLEU (GLEU) score of translated segments against one or more references.\nInstead of averaging the sentence level GLEU scores (i.e. macro-average precision), Wu et al. (2016) sum up the matching\ntokens and the max of hypothesis and reference tokens for each sentence, then compute using the aggregate values.\n\nArgs:\n predictions (list of str): list of translations to score.\n Each translation should be tokenized into a list of tokens.\n references (list of list of str): list of lists of references for each translation.\n Each reference should be tokenized into a list of tokens.\n min_len (int): The minimum order of n-gram this function should extract. Defaults to 1.\n max_len (int): The maximum order of n-gram this function should extract. Defaults to 4.\n\nReturns:\n 'google_bleu': google_bleu score\n\nExamples:\n Example 1:\n >>> hyp1 = ['It', 'is', 'a', 'guide', 'to', 'action', 'which',\n ... 'ensures', 'that', 'the', 'rubber', 'duck', 'always',\n ... 'disobeys', 'the', 'commands', 'of', 'the', 'cat']\n >>> ref1a = ['It', 'is', 'the', 'guiding', 'principle', 'which',\n ... 'guarantees', 'the', 'rubber', 'duck', 'forces', 'never',\n ... 'being', 'under', 'the', 'command', 'of', 'the', 'cat']\n\n >>> hyp2 = ['he', 'read', 'the', 'book', 'because', 'he', 'was',\n ... 'interested', 'in', 'world', 'history']\n >>> ref2a = ['he', 'was', 'interested', 'in', 'world', 'history',\n ... 'because', 'he', 'read', 'the', 'book']\n\n >>> list_of_references = [[ref1a], [ref2a]]\n >>> hypotheses = [hyp1, hyp2]\n >>> google_bleu = datasets.load_metric(\"google_bleu\")\n >>> results = google_bleu.compute(predictions=hypotheses, references=list_of_references)\n >>> print(round(results[\"google_bleu\"], 2))\n 0.44\n\n Example 2:\n >>> hyp1 = ['It', 'is', 'a', 'guide', 'to', 'action', 'which',\n ... 'ensures', 'that', 'the', 'rubber', 'duck', 'always',\n ... 'disobeys', 'the', 'commands', 'of', 'the', 'cat']\n >>> ref1a = ['It', 'is', 'the', 'guiding', 'principle', 'which',\n ... 'guarantees', 'the', 'rubber', 'duck', 'forces', 'never',\n ... 'being', 'under', 'the', 'command', 'of', 'the', 'cat']\n >>> ref1b = ['It', 'is', 'a', 'guide', 'to', 'action', 'that',\n ... 'ensures', 'that', 'the', 'rubber', 'duck', 'will', 'never',\n ... 'heed', 'the', 'cat', 'commands']\n >>> ref1c = ['It', 'is', 'the', 'practical', 'guide', 'for', 'the',\n ... 'rubber', 'duck', 'army', 'never', 'to', 'heed', 'the', 'directions',\n ... 'of', 'the', 'cat']\n\n >>> hyp2 = ['he', 'read', 'the', 'book', 'because', 'he', 'was',\n ... 'interested', 'in', 'world', 'history']\n >>> ref2a = ['he', 'was', 'interested', 'in', 'world', 'history',\n ... 'because', 'he', 'read', 'the', 'book']\n\n >>> list_of_references = [[ref1a, ref1b, ref1c], [ref2a]]\n >>> hypotheses = [hyp1, hyp2]\n >>> google_bleu = datasets.load_metric(\"google_bleu\")\n >>> results = google_bleu.compute(predictions=hypotheses, references=list_of_references)\n >>> print(round(results[\"google_bleu\"], 2))\n 0.61\n\n Example 3:\n >>> hyp1 = ['It', 'is', 'a', 'guide', 'to', 'action', 'which',\n ... 'ensures', 'that', 'the', 'rubber', 'duck', 'always',\n ... 'disobeys', 'the', 'commands', 'of', 'the', 'cat']\n >>> ref1a = ['It', 'is', 'the', 'guiding', 'principle', 'which',\n ... 'guarantees', 'the', 'rubber', 'duck', 'forces', 'never',\n ... 'being', 'under', 'the', 'command', 'of', 'the', 'cat']\n >>> ref1b = ['It', 'is', 'a', 'guide', 'to', 'action', 'that',\n ... 'ensures', 'that', 'the', 'rubber', 'duck', 'will', 'never',\n ... 'heed', 'the', 'cat', 'commands']\n >>> ref1c = ['It', 'is', 'the', 'practical', 'guide', 'for', 'the',\n ... 'rubber', 'duck', 'army', 'never', 'to', 'heed', 'the', 'directions',\n ... 'of', 'the', 'cat']\n\n >>> hyp2 = ['he', 'read', 'the', 'book', 'because', 'he', 'was',\n ... 'interested', 'in', 'world', 'history']\n >>> ref2a = ['he', 'was', 'interested', 'in', 'world', 'history',\n ... 'because', 'he', 'read', 'the', 'book']\n\n >>> list_of_references = [[ref1a, ref1b, ref1c], [ref2a]]\n >>> hypotheses = [hyp1, hyp2]\n >>> google_bleu = datasets.load_metric(\"google_bleu\")\n >>> results = google_bleu.compute(predictions=hypotheses, references=list_of_references, min_len=2)\n >>> print(round(results[\"google_bleu\"], 2))\n 0.53\n\n Example 4:\n >>> hyp1 = ['It', 'is', 'a', 'guide', 'to', 'action', 'which',\n ... 'ensures', 'that', 'the', 'rubber', 'duck', 'always',\n ... 'disobeys', 'the', 'commands', 'of', 'the', 'cat']\n >>> ref1a = ['It', 'is', 'the', 'guiding', 'principle', 'which',\n ... 'guarantees', 'the', 'rubber', 'duck', 'forces', 'never',\n ... 'being', 'under', 'the', 'command', 'of', 'the', 'cat']\n >>> ref1b = ['It', 'is', 'a', 'guide', 'to', 'action', 'that',\n ... 'ensures', 'that', 'the', 'rubber', 'duck', 'will', 'never',\n ... 'heed', 'the', 'cat', 'commands']\n >>> ref1c = ['It', 'is', 'the', 'practical', 'guide', 'for', 'the',\n ... 'rubber', 'duck', 'army', 'never', 'to', 'heed', 'the', 'directions',\n ... 'of', 'the', 'cat']\n\n >>> hyp2 = ['he', 'read', 'the', 'book', 'because', 'he', 'was',\n ... 'interested', 'in', 'world', 'history']\n >>> ref2a = ['he', 'was', 'interested', 'in', 'world', 'history',\n ... 'because', 'he', 'read', 'the', 'book']\n\n >>> list_of_references = [[ref1a, ref1b, ref1c], [ref2a]]\n >>> hypotheses = [hyp1, hyp2]\n >>> google_bleu = datasets.load_metric(\"google_bleu\")\n >>> results = google_bleu.compute(predictions=hypotheses,references=list_of_references, min_len=2, max_len=6)\n >>> print(round(results[\"google_bleu\"], 2))\n 0.4\n" @datasets.utils.file_utils.add_start_docstrings(_DESCRIPTION , _KWARGS_DESCRIPTION ) class snake_case__ ( datasets.Metric ): """simple docstring""" def lowercase_ ( self : str ) ->MetricInfo: return datasets.MetricInfo( description=_DESCRIPTION, citation=_CITATION, inputs_description=_KWARGS_DESCRIPTION, features=datasets.Features( { 'predictions': datasets.Sequence(datasets.Value('string', id='token' ), id='sequence' ), 'references': datasets.Sequence( datasets.Sequence(datasets.Value('string', id='token' ), id='sequence' ), id='references' ), } ), ) def lowercase_ ( self : str, _snake_case : List[List[List[str]]], _snake_case : List[List[str]], _snake_case : int = 1, _snake_case : int = 4, ) ->Dict[str, float]: return { "google_bleu": gleu_score.corpus_gleu( list_of_references=_snake_case, hypotheses=_snake_case, min_len=_snake_case, max_len=_snake_case ) }
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from __future__ import annotations import typing from collections.abc import Iterable import numpy as np lowercase = typing.Union[Iterable[float], Iterable[int], np.ndarray] # noqa: UP007 lowercase = typing.Union[np.floataa, int, float] # noqa: UP007 def __UpperCAmelCase ( a_ , a_): return np.sqrt(np.sum((np.asarray(a_) - np.asarray(a_)) ** 2)) def __UpperCAmelCase ( a_ , a_): return sum((va - va) ** 2 for va, va in zip(a_ , a_)) ** (1 / 2) if __name__ == "__main__": def __UpperCAmelCase ( ): from timeit import timeit print('Without Numpy') print( timeit( 'euclidean_distance_no_np([1, 2, 3], [4, 5, 6])' , number=1_00_00 , globals=globals() , )) print('With Numpy') print( timeit( 'euclidean_distance([1, 2, 3], [4, 5, 6])' , number=1_00_00 , globals=globals() , )) benchmark()
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from math import factorial def lowercase_ (A : int , A : int , A : float ): if successes > trials: raise ValueError('successes must be lower or equal to trials' ) if trials < 0 or successes < 0: raise ValueError('the function is defined for non-negative integers' ) if not isinstance(A , A ) or not isinstance(A , A ): raise ValueError('the function is defined for non-negative integers' ) if not 0 < prob < 1: raise ValueError('prob has to be in range of 1 - 0' ) snake_case__ : List[Any] = (prob**successes) * ((1 - prob) ** (trials - successes)) # Calculate the binomial coefficient: n! / k!(n-k)! snake_case__ : List[str] = float(factorial(A ) ) coefficient /= factorial(A ) * factorial(trials - successes ) return probability * coefficient if __name__ == "__main__": from doctest import testmod testmod() print("Probability of 2 successes out of 4 trails") print("with probability of 0.75 is:", end=" ") print(binomial_distribution(2, 4, 0.75))
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"""simple docstring""" import os import random import sys from . import cryptomath_module as cryptomath from . import rabin_miller __UpperCamelCase = 3 def lowercase (SCREAMING_SNAKE_CASE_ : int ) -> Dict: print('Generating primitive root of p' ) while True: SCREAMING_SNAKE_CASE = random.randrange(3 , SCREAMING_SNAKE_CASE_ ) if pow(SCREAMING_SNAKE_CASE_ , 2 , SCREAMING_SNAKE_CASE_ ) == 1: continue if pow(SCREAMING_SNAKE_CASE_ , SCREAMING_SNAKE_CASE_ , SCREAMING_SNAKE_CASE_ ) == 1: continue return g def lowercase (SCREAMING_SNAKE_CASE_ : int ) -> List[Any]: print('Generating prime p...' ) SCREAMING_SNAKE_CASE = rabin_miller.generate_large_prime(SCREAMING_SNAKE_CASE_ ) # select large prime number. SCREAMING_SNAKE_CASE = primitive_root(SCREAMING_SNAKE_CASE_ ) # one primitive root on modulo p. SCREAMING_SNAKE_CASE = random.randrange(3 , SCREAMING_SNAKE_CASE_ ) # private_key -> have to be greater than 2 for safety. SCREAMING_SNAKE_CASE = cryptomath.find_mod_inverse(pow(SCREAMING_SNAKE_CASE_ , SCREAMING_SNAKE_CASE_ , SCREAMING_SNAKE_CASE_ ) , SCREAMING_SNAKE_CASE_ ) SCREAMING_SNAKE_CASE = (key_size, e_a, e_a, p) SCREAMING_SNAKE_CASE = (key_size, d) return public_key, private_key def lowercase (SCREAMING_SNAKE_CASE_ : str , SCREAMING_SNAKE_CASE_ : int ) -> List[str]: if os.path.exists(F'{name}_pubkey.txt' ) or os.path.exists(F'{name}_privkey.txt' ): print('\nWARNING:' ) print( F'"{name}_pubkey.txt" or "{name}_privkey.txt" already exists. \n' 'Use a different name or delete these files and re-run this program.' ) sys.exit() SCREAMING_SNAKE_CASE = generate_key(SCREAMING_SNAKE_CASE_ ) print(F'\nWriting public key to file {name}_pubkey.txt...' ) with open(F'{name}_pubkey.txt' , 'w' ) as fo: fo.write(F'{public_key[0]},{public_key[1]},{public_key[2]},{public_key[3]}' ) print(F'Writing private key to file {name}_privkey.txt...' ) with open(F'{name}_privkey.txt' , 'w' ) as fo: fo.write(F'{private_key[0]},{private_key[1]}' ) def lowercase () -> List[str]: print('Making key files...' ) make_key_files('elgamal' , 20_48 ) print('Key files generation successful' ) if __name__ == "__main__": main()
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from collections import UserDict from typing import Union import numpy as np import requests from ..utils import ( add_end_docstrings, logging, ) from .audio_classification import ffmpeg_read from .base import PIPELINE_INIT_ARGS, Pipeline a_ :List[Any] = logging.get_logger(__name__) @add_end_docstrings(lowerCAmelCase_ ) class snake_case__ ( lowerCAmelCase_ ): """simple docstring""" def __init__( self : Optional[Any], **_snake_case : str ) ->Dict: super().__init__(**_snake_case ) if self.framework != "pt": raise ValueError(F'''The {self.__class__} is only available in PyTorch.''' ) # No specific FOR_XXX available yet def __call__( self : Union[str, Any], _snake_case : Union[np.ndarray, bytes, str], **_snake_case : Tuple ) ->Dict: return super().__call__(_snake_case, **_snake_case ) def lowercase_ ( self : Tuple, **_snake_case : Any ) ->Union[str, Any]: snake_case__ : str = {} if "candidate_labels" in kwargs: snake_case__ : str = kwargs['candidate_labels'] if "hypothesis_template" in kwargs: snake_case__ : str = kwargs['hypothesis_template'] return preprocess_params, {}, {} def lowercase_ ( self : Dict, _snake_case : str, _snake_case : Optional[int]=None, _snake_case : List[str]="This is a sound of {}." ) ->int: if isinstance(_snake_case, _snake_case ): if audio.startswith('http://' ) or audio.startswith('https://' ): # We need to actually check for a real protocol, otherwise it's impossible to use a local file # like http_huggingface_co.png snake_case__ : List[Any] = requests.get(_snake_case ).content else: with open(_snake_case, 'rb' ) as f: snake_case__ : Union[str, Any] = f.read() if isinstance(_snake_case, _snake_case ): snake_case__ : List[Any] = ffmpeg_read(_snake_case, self.feature_extractor.sampling_rate ) if not isinstance(_snake_case, np.ndarray ): raise ValueError('We expect a numpy ndarray as input' ) if len(audio.shape ) != 1: raise ValueError('We expect a single channel audio input for ZeroShotAudioClassificationPipeline' ) snake_case__ : Tuple = self.feature_extractor( [audio], sampling_rate=self.feature_extractor.sampling_rate, return_tensors='pt' ) snake_case__ : int = candidate_labels snake_case__ : int = [hypothesis_template.format(_snake_case ) for x in candidate_labels] snake_case__ : Optional[int] = self.tokenizer(_snake_case, return_tensors=self.framework, padding=_snake_case ) snake_case__ : List[Any] = [text_inputs] return inputs def lowercase_ ( self : Optional[int], _snake_case : Optional[Any] ) ->int: snake_case__ : Optional[int] = model_inputs.pop('candidate_labels' ) snake_case__ : str = model_inputs.pop('text_inputs' ) if isinstance(text_inputs[0], _snake_case ): snake_case__ : Optional[Any] = text_inputs[0] else: # Batching case. snake_case__ : int = text_inputs[0][0] snake_case__ : Any = self.model(**_snake_case, **_snake_case ) snake_case__ : List[Any] = { 'candidate_labels': candidate_labels, 'logits': outputs.logits_per_audio, } return model_outputs def lowercase_ ( self : Union[str, Any], _snake_case : str ) ->List[str]: snake_case__ : int = model_outputs.pop('candidate_labels' ) snake_case__ : List[Any] = model_outputs['logits'][0] if self.framework == "pt": snake_case__ : Tuple = logits.softmax(dim=0 ) snake_case__ : Union[str, Any] = probs.tolist() else: raise ValueError('`tf` framework not supported.' ) snake_case__ : Union[str, Any] = [ {'score': score, 'label': candidate_label} for score, candidate_label in sorted(zip(_snake_case, _snake_case ), key=lambda _snake_case : -x[0] ) ] return result
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'''simple docstring''' from manim import * class _lowercase ( lowerCAmelCase_ ): '''simple docstring''' def a ( self : int ) -> Any: __lowerCAmelCase = Rectangle(height=0.5 , width=0.5 ) __lowerCAmelCase = Rectangle(height=0.4_6 , width=0.4_6 ).set_stroke(width=0 ) __lowerCAmelCase = [mem.copy() for i in range(6 )] __lowerCAmelCase = [mem.copy() for i in range(6 )] __lowerCAmelCase = VGroup(*_snake_case ).arrange(_snake_case , buff=0 ) __lowerCAmelCase = VGroup(*_snake_case ).arrange(_snake_case , buff=0 ) __lowerCAmelCase = VGroup(_snake_case , _snake_case ).arrange(_snake_case , buff=0 ) __lowerCAmelCase = Text("""CPU""" , font_size=24 ) __lowerCAmelCase = Group(_snake_case , _snake_case ).arrange(_snake_case , buff=0.5 , aligned_edge=_snake_case ) cpu.move_to([-2.5, -0.5, 0] ) self.add(_snake_case ) __lowerCAmelCase = [mem.copy() for i in range(1 )] __lowerCAmelCase = VGroup(*_snake_case ).arrange(_snake_case , buff=0 ) __lowerCAmelCase = Text("""GPU""" , font_size=24 ) __lowerCAmelCase = Group(_snake_case , _snake_case ).arrange(_snake_case , buff=0.5 , aligned_edge=_snake_case ) gpu.align_to(_snake_case , _snake_case ) gpu.set_x(gpu.get_x() - 1 ) self.add(_snake_case ) __lowerCAmelCase = [mem.copy() for i in range(6 )] __lowerCAmelCase = VGroup(*_snake_case ).arrange(_snake_case , buff=0 ) __lowerCAmelCase = Text("""Model""" , font_size=24 ) __lowerCAmelCase = Group(_snake_case , _snake_case ).arrange(_snake_case , buff=0.5 , aligned_edge=_snake_case ) model.move_to([3, -1.0, 0] ) self.play( Create(_snake_case , run_time=1 ) , Create(_snake_case , run_time=1 ) , Create(_snake_case , run_time=1 ) , ) __lowerCAmelCase = MarkupText( f"""First, an empty model skeleton is loaded\ninto <span fgcolor=\'{YELLOW}\'>memory</span> without using much RAM.""" , font_size=24 , ) __lowerCAmelCase = Square(side_length=2.2 ) key.move_to([-5, 2, 0] ) __lowerCAmelCase = MarkupText( f"""<b>Key:</b>\n\n<span fgcolor=\'{YELLOW}\'>●</span> Empty Model""" , font_size=18 , ) key_text.move_to([-5, 2.4, 0] ) step_a.move_to([2, 2, 0] ) self.play(Write(_snake_case , run_time=2.5 ) , Write(_snake_case ) , Write(_snake_case ) ) self.add(_snake_case ) __lowerCAmelCase = [] __lowerCAmelCase = [] __lowerCAmelCase = [] for i, rect in enumerate(_snake_case ): __lowerCAmelCase = Rectangle(height=0.4_6 , width=0.4_6 ).set_stroke(width=0.0 ).set_fill(_snake_case , opacity=0.7 ) cpu_target.move_to(_snake_case ) cpu_target.generate_target() __lowerCAmelCase = 0.4_6 / 4 __lowerCAmelCase = 0.4_6 / 3 if i == 0: cpu_target.target.next_to(cpu_left_col_base[0].get_corner(DOWN + LEFT ) , buff=0.0_2 , direction=_snake_case ) cpu_target.target.set_x(cpu_target.target.get_x() + 0.1 ) elif i == 3: cpu_target.target.next_to(cpu_targs[0].target , direction=_snake_case , buff=0.0 ) else: cpu_target.target.next_to(cpu_targs[i - 1].target , direction=_snake_case , buff=0.0 ) cpu_targs.append(_snake_case ) first_animations.append(rect.animate(run_time=0.5 ).set_stroke(_snake_case ) ) second_animations.append(MoveToTarget(_snake_case , run_time=1.5 ) ) self.play(*_snake_case ) self.play(*_snake_case ) self.wait()
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import collections import inspect import unittest from transformers import SwinvaConfig from transformers.testing_utils import require_torch, require_vision, slow, torch_device from transformers.utils import cached_property, is_torch_available, is_vision_available from ...test_configuration_common import ConfigTester from ...test_modeling_common import ModelTesterMixin, _config_zero_init, floats_tensor, ids_tensor from ...test_pipeline_mixin import PipelineTesterMixin if is_torch_available(): import torch from torch import nn from transformers import SwinvaForImageClassification, SwinvaForMaskedImageModeling, SwinvaModel from transformers.models.swinva.modeling_swinva import SWINV2_PRETRAINED_MODEL_ARCHIVE_LIST if is_vision_available(): from PIL import Image from transformers import AutoImageProcessor class snake_case__ : """simple docstring""" def __init__( self : Tuple, _snake_case : Any, _snake_case : int=1_3, _snake_case : Optional[int]=3_2, _snake_case : Tuple=2, _snake_case : Any=3, _snake_case : Tuple=1_6, _snake_case : Tuple=[1, 2, 1], _snake_case : Dict=[2, 2, 4], _snake_case : str=2, _snake_case : Union[str, Any]=2.0, _snake_case : Dict=True, _snake_case : Dict=0.0, _snake_case : str=0.0, _snake_case : str=0.1, _snake_case : List[str]="gelu", _snake_case : int=False, _snake_case : Optional[Any]=True, _snake_case : List[Any]=0.0_2, _snake_case : Union[str, Any]=1e-5, _snake_case : Union[str, Any]=True, _snake_case : List[Any]=None, _snake_case : Any=True, _snake_case : List[Any]=1_0, _snake_case : str=8, ) ->Union[str, Any]: snake_case__ : Any = parent snake_case__ : Tuple = batch_size snake_case__ : Tuple = image_size snake_case__ : Any = patch_size snake_case__ : Optional[int] = num_channels snake_case__ : Tuple = embed_dim snake_case__ : Any = depths snake_case__ : Any = num_heads snake_case__ : List[str] = window_size snake_case__ : Dict = mlp_ratio snake_case__ : Optional[int] = qkv_bias snake_case__ : Optional[Any] = hidden_dropout_prob snake_case__ : List[str] = attention_probs_dropout_prob snake_case__ : Union[str, Any] = drop_path_rate snake_case__ : str = hidden_act snake_case__ : Union[str, Any] = use_absolute_embeddings snake_case__ : Union[str, Any] = patch_norm snake_case__ : Any = layer_norm_eps snake_case__ : Tuple = initializer_range snake_case__ : Dict = is_training snake_case__ : Any = scope snake_case__ : Optional[Any] = use_labels snake_case__ : str = type_sequence_label_size snake_case__ : List[Any] = encoder_stride def lowercase_ ( self : Tuple ) ->str: snake_case__ : Tuple = floats_tensor([self.batch_size, self.num_channels, self.image_size, self.image_size] ) snake_case__ : List[Any] = None if self.use_labels: snake_case__ : Optional[Any] = ids_tensor([self.batch_size], self.type_sequence_label_size ) snake_case__ : Any = self.get_config() return config, pixel_values, labels def lowercase_ ( self : Optional[int] ) ->Optional[int]: return SwinvaConfig( image_size=self.image_size, patch_size=self.patch_size, num_channels=self.num_channels, embed_dim=self.embed_dim, depths=self.depths, num_heads=self.num_heads, window_size=self.window_size, mlp_ratio=self.mlp_ratio, qkv_bias=self.qkv_bias, hidden_dropout_prob=self.hidden_dropout_prob, attention_probs_dropout_prob=self.attention_probs_dropout_prob, drop_path_rate=self.drop_path_rate, hidden_act=self.hidden_act, use_absolute_embeddings=self.use_absolute_embeddings, path_norm=self.patch_norm, layer_norm_eps=self.layer_norm_eps, initializer_range=self.initializer_range, encoder_stride=self.encoder_stride, ) def lowercase_ ( self : Optional[int], _snake_case : str, _snake_case : List[str], _snake_case : int ) ->Dict: snake_case__ : List[Any] = SwinvaModel(config=_snake_case ) model.to(_snake_case ) model.eval() snake_case__ : Optional[int] = model(_snake_case ) snake_case__ : List[Any] = ((config.image_size // config.patch_size) ** 2) // (4 ** (len(config.depths ) - 1)) snake_case__ : List[Any] = int(config.embed_dim * 2 ** (len(config.depths ) - 1) ) self.parent.assertEqual(result.last_hidden_state.shape, (self.batch_size, expected_seq_len, expected_dim) ) def lowercase_ ( self : Optional[Any], _snake_case : Any, _snake_case : List[str], _snake_case : Dict ) ->List[Any]: snake_case__ : List[str] = SwinvaForMaskedImageModeling(config=_snake_case ) model.to(_snake_case ) model.eval() snake_case__ : Union[str, Any] = model(_snake_case ) self.parent.assertEqual( result.logits.shape, (self.batch_size, self.num_channels, self.image_size, self.image_size) ) # test greyscale images snake_case__ : Optional[Any] = 1 snake_case__ : Optional[int] = SwinvaForMaskedImageModeling(_snake_case ) model.to(_snake_case ) model.eval() snake_case__ : Tuple = floats_tensor([self.batch_size, 1, self.image_size, self.image_size] ) snake_case__ : Any = model(_snake_case ) self.parent.assertEqual(result.logits.shape, (self.batch_size, 1, self.image_size, self.image_size) ) def lowercase_ ( self : List[str], _snake_case : int, _snake_case : List[Any], _snake_case : Optional[int] ) ->Any: snake_case__ : Tuple = self.type_sequence_label_size snake_case__ : int = SwinvaForImageClassification(_snake_case ) model.to(_snake_case ) model.eval() snake_case__ : Tuple = model(_snake_case, labels=_snake_case ) self.parent.assertEqual(result.logits.shape, (self.batch_size, self.type_sequence_label_size) ) def lowercase_ ( self : Any ) ->Dict: snake_case__ : str = self.prepare_config_and_inputs() snake_case__ , snake_case__ , snake_case__ : List[str] = config_and_inputs snake_case__ : Union[str, Any] = {'pixel_values': pixel_values} return config, inputs_dict @require_torch class snake_case__ ( lowerCAmelCase_ , lowerCAmelCase_ , unittest.TestCase ): """simple docstring""" _SCREAMING_SNAKE_CASE = ( (SwinvaModel, SwinvaForImageClassification, SwinvaForMaskedImageModeling) if is_torch_available() else () ) _SCREAMING_SNAKE_CASE = ( {"""feature-extraction""": SwinvaModel, """image-classification""": SwinvaForImageClassification} if is_torch_available() else {} ) _SCREAMING_SNAKE_CASE = False _SCREAMING_SNAKE_CASE = False _SCREAMING_SNAKE_CASE = False _SCREAMING_SNAKE_CASE = False def lowercase_ ( self : Union[str, Any] ) ->Dict: snake_case__ : Optional[int] = SwinvaModelTester(self ) snake_case__ : int = ConfigTester(self, config_class=_snake_case, embed_dim=3_7 ) def lowercase_ ( self : Tuple ) ->int: self.config_tester.create_and_test_config_to_json_string() self.config_tester.create_and_test_config_to_json_file() self.config_tester.create_and_test_config_from_and_save_pretrained() self.config_tester.create_and_test_config_with_num_labels() self.config_tester.check_config_can_be_init_without_params() self.config_tester.check_config_arguments_init() def lowercase_ ( self : Any ) ->str: snake_case__ : int = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_model(*_snake_case ) @unittest.skip(reason='Got `CUDA error: misaligned address` with PyTorch 2.0.0.' ) def lowercase_ ( self : Any ) ->Union[str, Any]: pass @unittest.skip(reason='Swinv2 does not use inputs_embeds' ) def lowercase_ ( self : str ) ->Union[str, Any]: pass def lowercase_ ( self : Optional[Any] ) ->Union[str, Any]: snake_case__ , snake_case__ : Optional[int] = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: snake_case__ : Union[str, Any] = model_class(_snake_case ) self.assertIsInstance(model.get_input_embeddings(), (nn.Module) ) snake_case__ : Union[str, Any] = model.get_output_embeddings() self.assertTrue(x is None or isinstance(_snake_case, nn.Linear ) ) def lowercase_ ( self : List[str] ) ->Optional[int]: snake_case__ , snake_case__ : Any = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: snake_case__ : Any = model_class(_snake_case ) snake_case__ : Dict = inspect.signature(model.forward ) # signature.parameters is an OrderedDict => so arg_names order is deterministic snake_case__ : Optional[Any] = [*signature.parameters.keys()] snake_case__ : List[Any] = ['pixel_values'] self.assertListEqual(arg_names[:1], _snake_case ) def lowercase_ ( self : str ) ->Union[str, Any]: snake_case__ , snake_case__ : Any = self.model_tester.prepare_config_and_inputs_for_common() snake_case__ : int = True for model_class in self.all_model_classes: snake_case__ : str = True snake_case__ : Union[str, Any] = False snake_case__ : Tuple = True snake_case__ : int = model_class(_snake_case ) model.to(_snake_case ) model.eval() with torch.no_grad(): snake_case__ : Optional[int] = model(**self._prepare_for_class(_snake_case, _snake_case ) ) snake_case__ : List[str] = outputs.attentions snake_case__ : List[Any] = len(self.model_tester.depths ) self.assertEqual(len(_snake_case ), _snake_case ) # check that output_attentions also work using config del inputs_dict["output_attentions"] snake_case__ : str = True snake_case__ : Tuple = config.window_size**2 snake_case__ : Optional[int] = model_class(_snake_case ) model.to(_snake_case ) model.eval() with torch.no_grad(): snake_case__ : str = model(**self._prepare_for_class(_snake_case, _snake_case ) ) snake_case__ : Tuple = outputs.attentions self.assertEqual(len(_snake_case ), _snake_case ) self.assertListEqual( list(attentions[0].shape[-3:] ), [self.model_tester.num_heads[0], window_size_squared, window_size_squared], ) snake_case__ : Optional[Any] = len(_snake_case ) # Check attention is always last and order is fine snake_case__ : Optional[int] = True snake_case__ : Dict = True snake_case__ : List[Any] = model_class(_snake_case ) model.to(_snake_case ) model.eval() with torch.no_grad(): snake_case__ : Optional[int] = model(**self._prepare_for_class(_snake_case, _snake_case ) ) if hasattr(self.model_tester, 'num_hidden_states_types' ): snake_case__ : str = self.model_tester.num_hidden_states_types else: # also another +1 for reshaped_hidden_states snake_case__ : Dict = 2 self.assertEqual(out_len + added_hidden_states, len(_snake_case ) ) snake_case__ : Any = outputs.attentions self.assertEqual(len(_snake_case ), _snake_case ) self.assertListEqual( list(self_attentions[0].shape[-3:] ), [self.model_tester.num_heads[0], window_size_squared, window_size_squared], ) def lowercase_ ( self : Dict, _snake_case : Tuple, _snake_case : Any, _snake_case : int, _snake_case : Optional[int] ) ->str: snake_case__ : Dict = model_class(_snake_case ) model.to(_snake_case ) model.eval() with torch.no_grad(): snake_case__ : List[Any] = model(**self._prepare_for_class(_snake_case, _snake_case ) ) snake_case__ : Dict = outputs.hidden_states snake_case__ : int = getattr( self.model_tester, 'expected_num_hidden_layers', len(self.model_tester.depths ) + 1 ) self.assertEqual(len(_snake_case ), _snake_case ) # Swinv2 has a different seq_length snake_case__ : int = ( config.patch_size if isinstance(config.patch_size, collections.abc.Iterable ) else (config.patch_size, config.patch_size) ) snake_case__ : Optional[Any] = (image_size[1] // patch_size[1]) * (image_size[0] // patch_size[0]) self.assertListEqual( list(hidden_states[0].shape[-2:] ), [num_patches, self.model_tester.embed_dim], ) snake_case__ : Union[str, Any] = outputs.reshaped_hidden_states self.assertEqual(len(_snake_case ), _snake_case ) snake_case__ , snake_case__ , snake_case__ , snake_case__ : str = reshaped_hidden_states[0].shape snake_case__ : Any = ( reshaped_hidden_states[0].view(_snake_case, _snake_case, height * width ).permute(0, 2, 1 ) ) self.assertListEqual( list(reshaped_hidden_states.shape[-2:] ), [num_patches, self.model_tester.embed_dim], ) def lowercase_ ( self : str ) ->List[Any]: snake_case__ , snake_case__ : Any = self.model_tester.prepare_config_and_inputs_for_common() snake_case__ : List[Any] = ( self.model_tester.image_size if isinstance(self.model_tester.image_size, collections.abc.Iterable ) else (self.model_tester.image_size, self.model_tester.image_size) ) for model_class in self.all_model_classes: snake_case__ : Optional[int] = True self.check_hidden_states_output(_snake_case, _snake_case, _snake_case, _snake_case ) # check that output_hidden_states also work using config del inputs_dict["output_hidden_states"] snake_case__ : Dict = True self.check_hidden_states_output(_snake_case, _snake_case, _snake_case, _snake_case ) def lowercase_ ( self : List[str] ) ->str: snake_case__ , snake_case__ : Optional[Any] = self.model_tester.prepare_config_and_inputs_for_common() snake_case__ : List[str] = 3 snake_case__ : Union[str, Any] = ( self.model_tester.image_size if isinstance(self.model_tester.image_size, collections.abc.Iterable ) else (self.model_tester.image_size, self.model_tester.image_size) ) snake_case__ : str = ( config.patch_size if isinstance(config.patch_size, collections.abc.Iterable ) else (config.patch_size, config.patch_size) ) snake_case__ : Tuple = image_size[0] + patch_size[0] - (image_size[0] % patch_size[0]) snake_case__ : Optional[Any] = image_size[1] + patch_size[1] - (image_size[1] % patch_size[1]) for model_class in self.all_model_classes: snake_case__ : int = True self.check_hidden_states_output(_snake_case, _snake_case, _snake_case, (padded_height, padded_width) ) # check that output_hidden_states also work using config del inputs_dict["output_hidden_states"] snake_case__ : List[str] = True self.check_hidden_states_output(_snake_case, _snake_case, _snake_case, (padded_height, padded_width) ) def lowercase_ ( self : List[str] ) ->Optional[int]: snake_case__ : Any = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_for_masked_image_modeling(*_snake_case ) def lowercase_ ( self : List[Any] ) ->str: snake_case__ : Any = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_for_image_classification(*_snake_case ) @slow def lowercase_ ( self : str ) ->Union[str, Any]: for model_name in SWINV2_PRETRAINED_MODEL_ARCHIVE_LIST[:1]: snake_case__ : Dict = SwinvaModel.from_pretrained(_snake_case ) self.assertIsNotNone(_snake_case ) def lowercase_ ( self : Optional[int] ) ->List[str]: snake_case__ , snake_case__ : Any = self.model_tester.prepare_config_and_inputs_for_common() snake_case__ : List[Any] = _config_zero_init(_snake_case ) for model_class in self.all_model_classes: snake_case__ : List[str] = model_class(config=_snake_case ) for name, param in model.named_parameters(): if "embeddings" not in name and "logit_scale" not in name and param.requires_grad: self.assertIn( ((param.data.mean() * 1e9).round() / 1e9).item(), [0.0, 1.0], msg=F'''Parameter {name} of model {model_class} seems not properly initialized''', ) @require_vision @require_torch class snake_case__ ( unittest.TestCase ): """simple docstring""" @cached_property def lowercase_ ( self : Union[str, Any] ) ->List[str]: return ( AutoImageProcessor.from_pretrained('microsoft/swinv2-tiny-patch4-window8-256' ) if is_vision_available() else None ) @slow def lowercase_ ( self : int ) ->List[Any]: snake_case__ : Any = SwinvaForImageClassification.from_pretrained('microsoft/swinv2-tiny-patch4-window8-256' ).to( _snake_case ) snake_case__ : int = self.default_image_processor snake_case__ : Union[str, Any] = Image.open('./tests/fixtures/tests_samples/COCO/000000039769.png' ) snake_case__ : Optional[Any] = image_processor(images=_snake_case, return_tensors='pt' ).to(_snake_case ) # forward pass with torch.no_grad(): snake_case__ : List[str] = model(**_snake_case ) # verify the logits snake_case__ : int = torch.Size((1, 1_0_0_0) ) self.assertEqual(outputs.logits.shape, _snake_case ) snake_case__ : Optional[int] = torch.tensor([-0.3_9_4_7, -0.4_3_0_6, 0.0_0_2_6] ).to(_snake_case ) self.assertTrue(torch.allclose(outputs.logits[0, :3], _snake_case, atol=1e-4 ) )
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"""simple docstring""" from __future__ import annotations from typing import Any def lowercase ( a__ : list[Any] ) -> int: create_state_space_tree(a__ , [] , 0 ) def lowercase ( a__ : list[Any] , a__ : list[Any] , a__ : int ) -> List[Any]: if index == len(a__ ): print(a__ ) return create_state_space_tree(a__ , a__ , index + 1 ) current_subsequence.append(sequence[index] ) create_state_space_tree(a__ , a__ , index + 1 ) current_subsequence.pop() if __name__ == "__main__": UpperCAmelCase = [3, 1, 2, 4] generate_all_subsequences(seq) seq.clear() seq.extend(["""A""", """B""", """C"""]) generate_all_subsequences(seq)
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import unittest import numpy as np from transformers.testing_utils import require_torch, require_vision from transformers.utils import is_torch_available, is_vision_available from ...test_image_processing_common import ImageProcessingSavingTestMixin, prepare_image_inputs if is_torch_available(): import torch if is_vision_available(): from PIL import Image from transformers import PoolFormerImageProcessor class snake_case__ ( unittest.TestCase ): """simple docstring""" def __init__( self : Optional[int], _snake_case : List[Any], _snake_case : str=7, _snake_case : Tuple=3, _snake_case : List[str]=3_0, _snake_case : Tuple=4_0_0, _snake_case : Any=True, _snake_case : List[Any]=None, _snake_case : int=0.9, _snake_case : Optional[Any]=None, _snake_case : str=True, _snake_case : Union[str, Any]=[0.5, 0.5, 0.5], _snake_case : Union[str, Any]=[0.5, 0.5, 0.5], ) ->List[Any]: snake_case__ : int = size if size is not None else {'shortest_edge': 3_0} snake_case__ : Tuple = crop_size if crop_size is not None else {'height': 3_0, 'width': 3_0} snake_case__ : Union[str, Any] = parent snake_case__ : Dict = batch_size snake_case__ : int = num_channels snake_case__ : Tuple = min_resolution snake_case__ : Any = max_resolution snake_case__ : List[Any] = do_resize_and_center_crop snake_case__ : str = size snake_case__ : str = crop_pct snake_case__ : List[str] = crop_size snake_case__ : Optional[int] = do_normalize snake_case__ : Tuple = image_mean snake_case__ : Tuple = image_std def lowercase_ ( self : Optional[int] ) ->int: return { "size": self.size, "do_resize_and_center_crop": self.do_resize_and_center_crop, "crop_pct": self.crop_pct, "crop_size": self.crop_size, "do_normalize": self.do_normalize, "image_mean": self.image_mean, "image_std": self.image_std, } @require_torch @require_vision class snake_case__ ( lowerCAmelCase_ , unittest.TestCase ): """simple docstring""" _SCREAMING_SNAKE_CASE = PoolFormerImageProcessor if is_vision_available() else None def lowercase_ ( self : Union[str, Any] ) ->Dict: snake_case__ : Union[str, Any] = PoolFormerImageProcessingTester(self ) @property def lowercase_ ( self : int ) ->Dict: return self.image_processor_tester.prepare_image_processor_dict() def lowercase_ ( self : Union[str, Any] ) ->Optional[int]: snake_case__ : List[str] = self.image_processing_class(**self.image_processor_dict ) self.assertTrue(hasattr(_snake_case, 'do_resize_and_center_crop' ) ) self.assertTrue(hasattr(_snake_case, 'size' ) ) self.assertTrue(hasattr(_snake_case, 'crop_pct' ) ) self.assertTrue(hasattr(_snake_case, 'do_normalize' ) ) self.assertTrue(hasattr(_snake_case, 'image_mean' ) ) self.assertTrue(hasattr(_snake_case, 'image_std' ) ) def lowercase_ ( self : List[str] ) ->List[str]: snake_case__ : Union[str, Any] = self.image_processing_class.from_dict(self.image_processor_dict ) self.assertEqual(image_processor.size, {'shortest_edge': 3_0} ) self.assertEqual(image_processor.crop_size, {'height': 3_0, 'width': 3_0} ) snake_case__ : int = self.image_processing_class.from_dict(self.image_processor_dict, size=4_2, crop_size=8_4 ) self.assertEqual(image_processor.size, {'shortest_edge': 4_2} ) self.assertEqual(image_processor.crop_size, {'height': 8_4, 'width': 8_4} ) def lowercase_ ( self : List[Any] ) ->List[Any]: pass def lowercase_ ( self : List[str] ) ->str: # Initialize image_processing snake_case__ : Union[str, Any] = self.image_processing_class(**self.image_processor_dict ) # create random PIL images snake_case__ : List[str] = prepare_image_inputs(self.image_processor_tester, equal_resolution=_snake_case ) for image in image_inputs: self.assertIsInstance(_snake_case, Image.Image ) # Test not batched input snake_case__ : Optional[int] = image_processing(image_inputs[0], return_tensors='pt' ).pixel_values self.assertEqual( encoded_images.shape, ( 1, self.image_processor_tester.num_channels, self.image_processor_tester.crop_size['height'], self.image_processor_tester.crop_size['width'], ), ) # Test batched snake_case__ : str = image_processing(_snake_case, return_tensors='pt' ).pixel_values self.assertEqual( encoded_images.shape, ( self.image_processor_tester.batch_size, self.image_processor_tester.num_channels, self.image_processor_tester.crop_size['height'], self.image_processor_tester.crop_size['width'], ), ) def lowercase_ ( self : int ) ->List[Any]: # Initialize image_processing snake_case__ : Optional[int] = self.image_processing_class(**self.image_processor_dict ) # create random numpy tensors snake_case__ : Dict = prepare_image_inputs(self.image_processor_tester, equal_resolution=_snake_case, numpify=_snake_case ) for image in image_inputs: self.assertIsInstance(_snake_case, np.ndarray ) # Test not batched input snake_case__ : Dict = image_processing(image_inputs[0], return_tensors='pt' ).pixel_values self.assertEqual( encoded_images.shape, ( 1, self.image_processor_tester.num_channels, self.image_processor_tester.crop_size['height'], self.image_processor_tester.crop_size['width'], ), ) # Test batched snake_case__ : List[Any] = image_processing(_snake_case, return_tensors='pt' ).pixel_values self.assertEqual( encoded_images.shape, ( self.image_processor_tester.batch_size, self.image_processor_tester.num_channels, self.image_processor_tester.crop_size['height'], self.image_processor_tester.crop_size['width'], ), ) def lowercase_ ( self : List[str] ) ->List[str]: # Initialize image_processing snake_case__ : Tuple = self.image_processing_class(**self.image_processor_dict ) # create random PyTorch tensors snake_case__ : List[str] = prepare_image_inputs(self.image_processor_tester, equal_resolution=_snake_case, torchify=_snake_case ) for image in image_inputs: self.assertIsInstance(_snake_case, torch.Tensor ) # Test not batched input snake_case__ : Tuple = image_processing(image_inputs[0], return_tensors='pt' ).pixel_values self.assertEqual( encoded_images.shape, ( 1, self.image_processor_tester.num_channels, self.image_processor_tester.crop_size['height'], self.image_processor_tester.crop_size['width'], ), ) # Test batched snake_case__ : Optional[Any] = image_processing(_snake_case, return_tensors='pt' ).pixel_values self.assertEqual( encoded_images.shape, ( self.image_processor_tester.batch_size, self.image_processor_tester.num_channels, self.image_processor_tester.crop_size['height'], self.image_processor_tester.crop_size['width'], ), )
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from typing import Optional, Tuple, Union import torch from einops import rearrange, reduce from diffusers import DDIMScheduler, DDPMScheduler, DiffusionPipeline, ImagePipelineOutput, UNetaDConditionModel from diffusers.schedulers.scheduling_ddim import DDIMSchedulerOutput from diffusers.schedulers.scheduling_ddpm import DDPMSchedulerOutput _a = 8 def _a ( SCREAMING_SNAKE_CASE : Optional[int] , SCREAMING_SNAKE_CASE : Optional[int]=BITS ) -> int: """simple docstring""" __lowerCAmelCase: Optional[Any] = x.device __lowerCAmelCase: List[Any] = (x * 2_55).int().clamp(0 , 2_55 ) __lowerCAmelCase: Any = 2 ** torch.arange(bits - 1 , -1 , -1 , device=SCREAMING_SNAKE_CASE ) __lowerCAmelCase: Tuple = rearrange(SCREAMING_SNAKE_CASE , 'd -> d 1 1' ) __lowerCAmelCase: Tuple = rearrange(SCREAMING_SNAKE_CASE , 'b c h w -> b c 1 h w' ) __lowerCAmelCase: Dict = ((x & mask) != 0).float() __lowerCAmelCase: Dict = rearrange(SCREAMING_SNAKE_CASE , 'b c d h w -> b (c d) h w' ) __lowerCAmelCase: str = bits * 2 - 1 return bits def _a ( SCREAMING_SNAKE_CASE : Optional[Any] , SCREAMING_SNAKE_CASE : int=BITS ) -> List[str]: """simple docstring""" __lowerCAmelCase: str = x.device __lowerCAmelCase: int = (x > 0).int() __lowerCAmelCase: Tuple = 2 ** torch.arange(bits - 1 , -1 , -1 , device=SCREAMING_SNAKE_CASE , dtype=torch.intaa ) __lowerCAmelCase: Union[str, Any] = rearrange(SCREAMING_SNAKE_CASE , 'd -> d 1 1' ) __lowerCAmelCase: int = rearrange(SCREAMING_SNAKE_CASE , 'b (c d) h w -> b c d h w' , d=8 ) __lowerCAmelCase: List[Any] = reduce(x * mask , 'b c d h w -> b c h w' , 'sum' ) return (dec / 2_55).clamp(0.0 , 1.0 ) def _a ( self : List[str] , SCREAMING_SNAKE_CASE : torch.FloatTensor , SCREAMING_SNAKE_CASE : int , SCREAMING_SNAKE_CASE : torch.FloatTensor , SCREAMING_SNAKE_CASE : float = 0.0 , SCREAMING_SNAKE_CASE : bool = True , SCREAMING_SNAKE_CASE : Optional[Any]=None , SCREAMING_SNAKE_CASE : bool = True , ) -> Dict: """simple docstring""" if self.num_inference_steps is None: raise ValueError( 'Number of inference steps is \'None\', you need to run \'set_timesteps\' after creating the scheduler' ) # See formulas (12) and (16) of DDIM paper https://arxiv.org/pdf/2010.02502.pdf # Ideally, read DDIM paper in-detail understanding # Notation (<variable name> -> <name in paper> # - pred_noise_t -> e_theta(x_t, t) # - pred_original_sample -> f_theta(x_t, t) or x_0 # - std_dev_t -> sigma_t # - eta -> η # - pred_sample_direction -> "direction pointing to x_t" # - pred_prev_sample -> "x_t-1" # 1. get previous step value (=t-1) __lowerCAmelCase: List[Any] = timestep - self.config.num_train_timesteps // self.num_inference_steps # 2. compute alphas, betas __lowerCAmelCase: List[Any] = self.alphas_cumprod[timestep] __lowerCAmelCase: Dict = self.alphas_cumprod[prev_timestep] if prev_timestep >= 0 else self.final_alpha_cumprod __lowerCAmelCase: int = 1 - alpha_prod_t # 3. compute predicted original sample from predicted noise also called # "predicted x_0" of formula (12) from https://arxiv.org/pdf/2010.02502.pdf __lowerCAmelCase: Dict = (sample - beta_prod_t ** 0.5 * model_output) / alpha_prod_t ** 0.5 # 4. Clip "predicted x_0" __lowerCAmelCase: Union[str, Any] = self.bit_scale if self.config.clip_sample: __lowerCAmelCase: List[Any] = torch.clamp(SCREAMING_SNAKE_CASE , -scale , SCREAMING_SNAKE_CASE ) # 5. compute variance: "sigma_t(η)" -> see formula (16) # σ_t = sqrt((1 − α_t−1)/(1 − α_t)) * sqrt(1 − α_t/α_t−1) __lowerCAmelCase: int = self._get_variance(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ) __lowerCAmelCase: int = eta * variance ** 0.5 if use_clipped_model_output: # the model_output is always re-derived from the clipped x_0 in Glide __lowerCAmelCase: Optional[Any] = (sample - alpha_prod_t ** 0.5 * pred_original_sample) / beta_prod_t ** 0.5 # 6. compute "direction pointing to x_t" of formula (12) from https://arxiv.org/pdf/2010.02502.pdf __lowerCAmelCase: Tuple = (1 - alpha_prod_t_prev - std_dev_t**2) ** 0.5 * model_output # 7. compute x_t without "random noise" of formula (12) from https://arxiv.org/pdf/2010.02502.pdf __lowerCAmelCase: Tuple = alpha_prod_t_prev ** 0.5 * pred_original_sample + pred_sample_direction if eta > 0: # randn_like does not support generator https://github.com/pytorch/pytorch/issues/27072 __lowerCAmelCase: Union[str, Any] = model_output.device if torch.is_tensor(SCREAMING_SNAKE_CASE ) else 'cpu' __lowerCAmelCase: Any = torch.randn(model_output.shape , dtype=model_output.dtype , generator=SCREAMING_SNAKE_CASE ).to(SCREAMING_SNAKE_CASE ) __lowerCAmelCase: Optional[Any] = self._get_variance(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ) ** 0.5 * eta * noise __lowerCAmelCase: int = prev_sample + variance if not return_dict: return (prev_sample,) return DDIMSchedulerOutput(prev_sample=SCREAMING_SNAKE_CASE , pred_original_sample=SCREAMING_SNAKE_CASE ) def _a ( self : List[str] , SCREAMING_SNAKE_CASE : torch.FloatTensor , SCREAMING_SNAKE_CASE : int , SCREAMING_SNAKE_CASE : torch.FloatTensor , SCREAMING_SNAKE_CASE : Tuple="epsilon" , SCREAMING_SNAKE_CASE : Union[str, Any]=None , SCREAMING_SNAKE_CASE : bool = True , ) -> Union[str, Any]: """simple docstring""" __lowerCAmelCase: List[Any] = timestep if model_output.shape[1] == sample.shape[1] * 2 and self.variance_type in ["learned", "learned_range"]: __lowerCAmelCase: Optional[Any] = torch.split(SCREAMING_SNAKE_CASE , sample.shape[1] , dim=1 ) else: __lowerCAmelCase: Tuple = None # 1. compute alphas, betas __lowerCAmelCase: Optional[int] = self.alphas_cumprod[t] __lowerCAmelCase: int = self.alphas_cumprod[t - 1] if t > 0 else self.one __lowerCAmelCase: List[str] = 1 - alpha_prod_t __lowerCAmelCase: List[str] = 1 - alpha_prod_t_prev # 2. compute predicted original sample from predicted noise also called # "predicted x_0" of formula (15) from https://arxiv.org/pdf/2006.11239.pdf if prediction_type == "epsilon": __lowerCAmelCase: int = (sample - beta_prod_t ** 0.5 * model_output) / alpha_prod_t ** 0.5 elif prediction_type == "sample": __lowerCAmelCase: Dict = model_output else: raise ValueError(f'''Unsupported prediction_type {prediction_type}.''' ) # 3. Clip "predicted x_0" __lowerCAmelCase: List[str] = self.bit_scale if self.config.clip_sample: __lowerCAmelCase: Union[str, Any] = torch.clamp(SCREAMING_SNAKE_CASE , -scale , SCREAMING_SNAKE_CASE ) # 4. Compute coefficients for pred_original_sample x_0 and current sample x_t # See formula (7) from https://arxiv.org/pdf/2006.11239.pdf __lowerCAmelCase: Union[str, Any] = (alpha_prod_t_prev ** 0.5 * self.betas[t]) / beta_prod_t __lowerCAmelCase: str = self.alphas[t] ** 0.5 * beta_prod_t_prev / beta_prod_t # 5. Compute predicted previous sample µ_t # See formula (7) from https://arxiv.org/pdf/2006.11239.pdf __lowerCAmelCase: Optional[int] = pred_original_sample_coeff * pred_original_sample + current_sample_coeff * sample # 6. Add noise __lowerCAmelCase: Tuple = 0 if t > 0: __lowerCAmelCase: Optional[Any] = torch.randn( model_output.size() , dtype=model_output.dtype , layout=model_output.layout , generator=SCREAMING_SNAKE_CASE ).to(model_output.device ) __lowerCAmelCase: str = (self._get_variance(SCREAMING_SNAKE_CASE , predicted_variance=SCREAMING_SNAKE_CASE ) ** 0.5) * noise __lowerCAmelCase: Any = pred_prev_sample + variance if not return_dict: return (pred_prev_sample,) return DDPMSchedulerOutput(prev_sample=SCREAMING_SNAKE_CASE , pred_original_sample=SCREAMING_SNAKE_CASE ) class A_ ( lowerCAmelCase_ ): def __init__( self : Union[str, Any] , UpperCAmelCase : UNetaDConditionModel , UpperCAmelCase : Union[DDIMScheduler, DDPMScheduler] , UpperCAmelCase : Optional[float] = 1.0 , ) -> int: super().__init__() __lowerCAmelCase: Optional[int] = bit_scale __lowerCAmelCase: int = ( ddim_bit_scheduler_step if isinstance(_snake_case , _snake_case ) else ddpm_bit_scheduler_step ) self.register_modules(unet=_snake_case , scheduler=_snake_case ) @torch.no_grad() def __call__( self : List[str] , UpperCAmelCase : Optional[int] = 2_5_6 , UpperCAmelCase : Optional[int] = 2_5_6 , UpperCAmelCase : Optional[int] = 5_0 , UpperCAmelCase : Optional[torch.Generator] = None , UpperCAmelCase : Optional[int] = 1 , UpperCAmelCase : Optional[str] = "pil" , UpperCAmelCase : bool = True , **UpperCAmelCase : Tuple , ) -> Union[Tuple, ImagePipelineOutput]: __lowerCAmelCase: int = torch.randn( (batch_size, self.unet.config.in_channels, height, width) , generator=_snake_case , ) __lowerCAmelCase: Tuple = decimal_to_bits(_snake_case ) * self.bit_scale __lowerCAmelCase: Optional[Any] = latents.to(self.device ) self.scheduler.set_timesteps(_snake_case ) for t in self.progress_bar(self.scheduler.timesteps ): # predict the noise residual __lowerCAmelCase: Union[str, Any] = self.unet(_snake_case , _snake_case ).sample # compute the previous noisy sample x_t -> x_t-1 __lowerCAmelCase: int = self.scheduler.step(_snake_case , _snake_case , _snake_case ).prev_sample __lowerCAmelCase: Optional[int] = bits_to_decimal(_snake_case ) if output_type == "pil": __lowerCAmelCase: Any = self.numpy_to_pil(_snake_case ) if not return_dict: return (image,) return ImagePipelineOutput(images=_snake_case )
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from collections import deque from .hash_table import HashTable class snake_case__ ( lowerCAmelCase_ ): """simple docstring""" def __init__( self : Optional[Any], *_snake_case : Optional[Any], **_snake_case : List[Any] ) ->Optional[int]: super().__init__(*_snake_case, **_snake_case ) def lowercase_ ( self : Optional[Any], _snake_case : Tuple, _snake_case : Dict ) ->Dict: snake_case__ : int = deque([] ) if self.values[key] is None else self.values[key] self.values[key].appendleft(_snake_case ) snake_case__ : Dict = self.values[key] def lowercase_ ( self : Any ) ->Optional[Any]: return ( sum(self.charge_factor - len(_snake_case ) for slot in self.values ) / self.size_table * self.charge_factor ) def lowercase_ ( self : Union[str, Any], _snake_case : str, _snake_case : Optional[int]=None ) ->Optional[Any]: if not ( len(self.values[key] ) == self.charge_factor and self.values.count(_snake_case ) == 0 ): return key return super()._collision_resolution(_snake_case, _snake_case )
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import argparse import json import os import torch from torch import nn from transformers import NllbMoeConfig, NllbMoeModel from transformers.modeling_utils import dtype_byte_size from transformers.utils import WEIGHTS_INDEX_NAME, WEIGHTS_NAME def _A ( SCREAMING_SNAKE_CASE : List[str] ): """simple docstring""" a__ : Tuple =[ 'encoder.version', 'decoder.version', 'model.encoder.version', 'model.decoder.version', 'decoder.output_projection.weight', '_float_tensor', 'encoder.embed_positions._float_tensor', 'decoder.embed_positions._float_tensor', ] for k in ignore_keys: state_dict.pop(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ) def _A ( SCREAMING_SNAKE_CASE : str ): """simple docstring""" a__ : Union[str, Any] =emb.weight.shape a__ : str =nn.Linear(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , bias=SCREAMING_SNAKE_CASE ) a__ : str =emb.weight.data return lin_layer def _A ( SCREAMING_SNAKE_CASE : Optional[int] , SCREAMING_SNAKE_CASE : Union[str, Any]=None ): """simple docstring""" a__ : Any ={} for old_key in state_dict.keys(): a__ : Tuple =old_key if "moe_layer.experts." in key: if expert_idx is not None: a__ : int =key.replace("moe_layer.experts.0" , f'''ffn.experts.expert_{expert_idx}''' ) else: a__ : Any =key.replace("moe_layer.experts." , "ffn.experts.expert_" ) if "gate" in key: a__ : Dict =key.replace(".moe_layer.gate.wg" , ".ffn.router.classifier" ) if "fc2" and "experts" not in key: a__ : str =key.replace(".fc2." , ".ffn.fc2." ) if "fc1" and "experts" not in key: a__ : str =key.replace(".fc1." , ".ffn.fc1." ) if ".encoder_attn." in key: a__ : Tuple =key.replace(".encoder_attn." , ".cross_attention." ) if "encoder_attn_layer_norm" in key: a__ : Tuple =key.replace("encoder_attn_layer_norm" , "cross_attention_layer_norm" ) if "final_layer_norm" in key: a__ : Optional[int] =key.replace("final_layer_norm" , "ff_layer_norm" ) a__ : Dict =state_dict[old_key] return new_dict def _A ( SCREAMING_SNAKE_CASE : List[Any] , SCREAMING_SNAKE_CASE : Tuple , SCREAMING_SNAKE_CASE : List[Any] , SCREAMING_SNAKE_CASE : List[str] , SCREAMING_SNAKE_CASE : str = WEIGHTS_NAME ): """simple docstring""" a__ : Dict =[] a__ : str =0 os.makedirs(SCREAMING_SNAKE_CASE , exist_ok=SCREAMING_SNAKE_CASE ) for expert in range(SCREAMING_SNAKE_CASE ): a__ : Tuple =switch_checkpoint_path + f'''-rank-{expert}.pt''' if os.path.isfile(SCREAMING_SNAKE_CASE ): a__ : Optional[Any] =torch.load(SCREAMING_SNAKE_CASE )['model'] remove_ignore_keys_(SCREAMING_SNAKE_CASE ) a__ : Optional[Any] =rename_fairseq_keys(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ) a__ : Dict =os.path.join( SCREAMING_SNAKE_CASE , weights_name.replace(".bin" , f'''-{len(SCREAMING_SNAKE_CASE )+1:05d}-of-???.bin''' ) ) torch.save(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ) sharded_state_dicts.append(expert_state.keys() ) total_size += sum([value.numel() for key, value in expert_state.items()] ) * dtype_byte_size( expert_state[list(SCREAMING_SNAKE_CASE )[0]].dtype ) # Add the last block a__ : Tuple =os.path.join(SCREAMING_SNAKE_CASE , weights_name.replace(".bin" , f'''-{len(SCREAMING_SNAKE_CASE )+1:05d}-of-???.bin''' ) ) a__ : Union[str, Any] =torch.load(switch_checkpoint_path + "-shared.pt" )['model'] remove_ignore_keys_(SCREAMING_SNAKE_CASE ) a__ : str =rename_fairseq_keys(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ) a__ : Any =shared_weights['decoder.embed_tokens.weight'] sharded_state_dicts.append(shared_weights.keys() ) # If we only have the shared weights (dummy model/experts saved on the same file) if len(SCREAMING_SNAKE_CASE ) == 1: a__ : Any =os.path.join(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ) torch.save(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ) return {weights_name: sharded_state_dicts[0]}, None else: torch.save(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ) # Otherwise, let's build the index a__ : Tuple ={} for idx, shard in enumerate(SCREAMING_SNAKE_CASE ): a__ : Optional[int] =weights_name.replace(".bin" , f'''-{idx+1:05d}-of-{len(SCREAMING_SNAKE_CASE ):05d}.bin''' ) a__ : List[Any] =os.path.join(SCREAMING_SNAKE_CASE , weights_name.replace(".bin" , f'''-{idx+1:05d}-of-???.bin''' ) ) os.rename(SCREAMING_SNAKE_CASE , os.path.join(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ) ) for key in shard: a__ : Any =shard_file # Add the metadata a__ : int ={'total_size': total_size} a__ : Dict ={'metadata': metadata, 'weight_map': weight_map} with open(os.path.join(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ) , "w" , encoding="utf-8" ) as f: a__ : Any =json.dumps(SCREAMING_SNAKE_CASE , indent=2 , sort_keys=SCREAMING_SNAKE_CASE ) + '\n' f.write(SCREAMING_SNAKE_CASE ) return metadata, index if __name__ == "__main__": UpperCAmelCase : int = argparse.ArgumentParser() # Required parameters parser.add_argument( """--nllb_moe_checkpoint_path""", default="""/home/arthur_huggingface_co/fairseq/weights/checkpoints/model_moe_54b/checkpoint_2_300000""", type=str, required=False, help="""Path to a directory containing a folder per layer. Follows the original Google format.""", ) parser.add_argument("""--dtype""", default="""float32""", type=str, required=False, help="""dtype of the saved model""") parser.add_argument( """--pytorch_dump_folder_path""", default="""/home/arthur_huggingface_co/fairseq/weights/checkpoints/hf-converted-moe-54b""", type=str, required=False, help="""Path to the output pytorch model.""", ) UpperCAmelCase : Optional[Any] = parser.parse_args() UpperCAmelCase : Optional[Any] = shard_on_the_fly( args.nllb_moe_checkpoint_path, args.pytorch_dump_folder_path, 128, args.dtype, ) UpperCAmelCase : List[str] = NllbMoeConfig.from_pretrained( """facebook/nllb-200-3.3B""", encoder_sparse_step=4, decoder_sparse_step=4, num_experts=128 ) config.save_pretrained(args.pytorch_dump_folder_path) UpperCAmelCase : int = NllbMoeModel.from_pretrained(args.pytorch_dump_folder_path) print("""Done""") model.save_pretrained(args.pytorch_dump_folder_path)
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def lowercase_ (A : Union[str, Any] , A : List[str] , A : int , A : Optional[int] ): global f # a global dp table for knapsack if f[i][j] < 0: if j < wt[i - 1]: snake_case__ : Union[str, Any] = mf_knapsack(i - 1 , A , A , A ) else: snake_case__ : Any = max( mf_knapsack(i - 1 , A , A , A ) , mf_knapsack(i - 1 , A , A , j - wt[i - 1] ) + val[i - 1] , ) snake_case__ : Optional[int] = val return f[i][j] def lowercase_ (A : Optional[int] , A : Union[str, Any] , A : str , A : Dict ): snake_case__ : int = [[0] * (w + 1) for _ in range(n + 1 )] for i in range(1 , n + 1 ): for w_ in range(1 , w + 1 ): if wt[i - 1] <= w_: snake_case__ : Union[str, Any] = max(val[i - 1] + dp[i - 1][w_ - wt[i - 1]] , dp[i - 1][w_] ) else: snake_case__ : str = dp[i - 1][w_] return dp[n][w_], dp def lowercase_ (A : int , A : list , A : list ): if not (isinstance(A , (list, tuple) ) and isinstance(A , (list, tuple) )): raise ValueError( 'Both the weights and values vectors must be either lists or tuples' ) snake_case__ : Dict = len(A ) if num_items != len(A ): snake_case__ : str = ( 'The number of weights must be the same as the number of values.\n' F'''But got {num_items} weights and {len(A )} values''' ) raise ValueError(A ) for i in range(A ): if not isinstance(wt[i] , A ): snake_case__ : Optional[int] = ( 'All weights must be integers but got weight of ' F'''type {type(wt[i] )} at index {i}''' ) raise TypeError(A ) snake_case__ , snake_case__ : Optional[int] = knapsack(A , A , A , A ) snake_case__ : set = set() _construct_solution(A , A , A , A , A ) return optimal_val, example_optional_set def lowercase_ (A : list , A : list , A : int , A : int , A : set ): # for the current item i at a maximum weight j to be part of an optimal subset, # the optimal value at (i, j) must be greater than the optimal value at (i-1, j). # where i - 1 means considering only the previous items at the given maximum weight if i > 0 and j > 0: if dp[i - 1][j] == dp[i][j]: _construct_solution(A , A , i - 1 , A , A ) else: optimal_set.add(A ) _construct_solution(A , A , i - 1 , j - wt[i - 1] , A ) if __name__ == "__main__": a_ :Any = [3, 2, 4, 4] a_ :List[Any] = [4, 3, 2, 3] a_ :Union[str, Any] = 4 a_ :List[str] = 6 a_ :Union[str, Any] = [[0] * (w + 1)] + [[0] + [-1] * (w + 1) for _ in range(n + 1)] a_ , a_ :List[Any] = knapsack(w, wt, val, n) print(optimal_solution) print(mf_knapsack(n, wt, val, w)) # switched the n and w # testing the dynamic programming problem with example # the optimal subset for the above example are items 3 and 4 a_ , a_ :Any = knapsack_with_example_solution(w, wt, val) assert optimal_solution == 8 assert optimal_subset == {3, 4} print("optimal_value = ", optimal_solution) print("An optimal subset corresponding to the optimal value", optimal_subset)
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from collections import OrderedDict from typing import TYPE_CHECKING, Any, Mapping, Optional, Union from ...configuration_utils import PretrainedConfig from ...onnx import OnnxConfig from ...utils import logging if TYPE_CHECKING: from ... import FeatureExtractionMixin, PreTrainedTokenizerBase, TensorType __a = logging.get_logger(__name__) __a = { "microsoft/deberta-v2-xlarge": "https://huggingface.co/microsoft/deberta-v2-xlarge/resolve/main/config.json", "microsoft/deberta-v2-xxlarge": "https://huggingface.co/microsoft/deberta-v2-xxlarge/resolve/main/config.json", "microsoft/deberta-v2-xlarge-mnli": ( "https://huggingface.co/microsoft/deberta-v2-xlarge-mnli/resolve/main/config.json" ), "microsoft/deberta-v2-xxlarge-mnli": ( "https://huggingface.co/microsoft/deberta-v2-xxlarge-mnli/resolve/main/config.json" ), } class lowercase__( lowerCAmelCase_ ): """simple docstring""" a :Any = 'deberta-v2' def __init__( self : Union[str, Any] , SCREAMING_SNAKE_CASE_ : Dict=1_2_8_1_0_0 , SCREAMING_SNAKE_CASE_ : Any=1_5_3_6 , SCREAMING_SNAKE_CASE_ : Tuple=2_4 , SCREAMING_SNAKE_CASE_ : int=2_4 , SCREAMING_SNAKE_CASE_ : Optional[int]=6_1_4_4 , SCREAMING_SNAKE_CASE_ : Optional[int]="gelu" , SCREAMING_SNAKE_CASE_ : Optional[int]=0.1 , SCREAMING_SNAKE_CASE_ : List[str]=0.1 , SCREAMING_SNAKE_CASE_ : str=5_1_2 , SCREAMING_SNAKE_CASE_ : Optional[int]=0 , SCREAMING_SNAKE_CASE_ : Optional[int]=0.02 , SCREAMING_SNAKE_CASE_ : Dict=1e-7 , SCREAMING_SNAKE_CASE_ : int=False , SCREAMING_SNAKE_CASE_ : Any=-1 , SCREAMING_SNAKE_CASE_ : List[str]=0 , SCREAMING_SNAKE_CASE_ : Tuple=True , SCREAMING_SNAKE_CASE_ : Any=None , SCREAMING_SNAKE_CASE_ : Union[str, Any]=0 , SCREAMING_SNAKE_CASE_ : Tuple="gelu" , **SCREAMING_SNAKE_CASE_ : Union[str, Any] , ) -> Optional[int]: super().__init__(**_snake_case ) lowercase_ = hidden_size lowercase_ = num_hidden_layers lowercase_ = num_attention_heads lowercase_ = intermediate_size lowercase_ = hidden_act lowercase_ = hidden_dropout_prob lowercase_ = attention_probs_dropout_prob lowercase_ = max_position_embeddings lowercase_ = type_vocab_size lowercase_ = initializer_range lowercase_ = relative_attention lowercase_ = max_relative_positions lowercase_ = pad_token_id lowercase_ = position_biased_input # Backwards compatibility if type(_snake_case ) == str: lowercase_ = [x.strip() for x in pos_att_type.lower().split('''|''' )] lowercase_ = pos_att_type lowercase_ = vocab_size lowercase_ = layer_norm_eps lowercase_ = kwargs.get('''pooler_hidden_size''' , _snake_case ) lowercase_ = pooler_dropout lowercase_ = pooler_hidden_act class lowercase__( lowerCAmelCase_ ): """simple docstring""" @property def _lowercase ( self : Optional[int] ) -> Mapping[str, Mapping[int, str]]: if self.task == "multiple-choice": lowercase_ = {0: 'batch', 1: 'choice', 2: 'sequence'} else: lowercase_ = {0: 'batch', 1: 'sequence'} if self._config.type_vocab_size > 0: return OrderedDict( [('''input_ids''', dynamic_axis), ('''attention_mask''', dynamic_axis), ('''token_type_ids''', dynamic_axis)] ) else: return OrderedDict([('''input_ids''', dynamic_axis), ('''attention_mask''', dynamic_axis)] ) @property def _lowercase ( self : Dict ) -> int: return 1_2 def _lowercase ( self : Tuple , SCREAMING_SNAKE_CASE_ : Union["PreTrainedTokenizerBase", "FeatureExtractionMixin"] , SCREAMING_SNAKE_CASE_ : int = -1 , SCREAMING_SNAKE_CASE_ : int = -1 , SCREAMING_SNAKE_CASE_ : int = -1 , SCREAMING_SNAKE_CASE_ : bool = False , SCREAMING_SNAKE_CASE_ : Optional["TensorType"] = None , SCREAMING_SNAKE_CASE_ : int = 3 , SCREAMING_SNAKE_CASE_ : int = 4_0 , SCREAMING_SNAKE_CASE_ : int = 4_0 , SCREAMING_SNAKE_CASE_ : "PreTrainedTokenizerBase" = None , ) -> Mapping[str, Any]: lowercase_ = super().generate_dummy_inputs(preprocessor=_snake_case , framework=_snake_case ) if self._config.type_vocab_size == 0 and "token_type_ids" in dummy_inputs: del dummy_inputs["token_type_ids"] return dummy_inputs
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from typing import TYPE_CHECKING from ...utils import OptionalDependencyNotAvailable, _LazyModule, is_flax_available, is_torch_available a_ :int = { "configuration_longt5": ["LONGT5_PRETRAINED_CONFIG_ARCHIVE_MAP", "LongT5Config", "LongT5OnnxConfig"], } try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: a_ :List[str] = [ "LONGT5_PRETRAINED_MODEL_ARCHIVE_LIST", "LongT5EncoderModel", "LongT5ForConditionalGeneration", "LongT5Model", "LongT5PreTrainedModel", ] try: if not is_flax_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: a_ :int = [ "FlaxLongT5ForConditionalGeneration", "FlaxLongT5Model", "FlaxLongT5PreTrainedModel", ] if TYPE_CHECKING: from .configuration_longta import LONGT5_PRETRAINED_CONFIG_ARCHIVE_MAP, LongTaConfig, LongTaOnnxConfig try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_longta import ( LONGT5_PRETRAINED_MODEL_ARCHIVE_LIST, LongTaEncoderModel, LongTaForConditionalGeneration, LongTaModel, LongTaPreTrainedModel, ) try: if not is_flax_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_flax_longta import ( FlaxLongTaForConditionalGeneration, FlaxLongTaModel, FlaxLongTaPreTrainedModel, ) else: import sys a_ :Optional[int] = _LazyModule(__name__, globals()["__file__"], _import_structure, module_spec=__spec__)
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"""simple docstring""" import warnings from functools import wraps from typing import Callable def lowercase ( lowerCAmelCase__ : Callable ) -> Tuple: @wraps(lowerCAmelCase__ ) def _inner_fn(*lowerCAmelCase__ : Optional[Any] , **lowerCAmelCase__ : str ): warnings.warn( (f'''\'{fn.__name__}\' is experimental and might be subject to breaking changes in the future.''') , lowerCAmelCase__ , ) return fn(*lowerCAmelCase__ , **lowerCAmelCase__ ) return _inner_fn
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import argparse import json import os import torch from torch import nn from transformers import NllbMoeConfig, NllbMoeModel from transformers.modeling_utils import dtype_byte_size from transformers.utils import WEIGHTS_INDEX_NAME, WEIGHTS_NAME def lowercase_ (A : List[str] ): snake_case__ : Tuple = [ 'encoder.version', 'decoder.version', 'model.encoder.version', 'model.decoder.version', 'decoder.output_projection.weight', '_float_tensor', 'encoder.embed_positions._float_tensor', 'decoder.embed_positions._float_tensor', ] for k in ignore_keys: state_dict.pop(A , A ) def lowercase_ (A : str ): snake_case__ , snake_case__ : Union[str, Any] = emb.weight.shape snake_case__ : str = nn.Linear(A , A , bias=A ) snake_case__ : str = emb.weight.data return lin_layer def lowercase_ (A : Optional[int] , A : Union[str, Any]=None ): snake_case__ : Any = {} for old_key in state_dict.keys(): snake_case__ : Tuple = old_key if "moe_layer.experts." in key: if expert_idx is not None: snake_case__ : int = key.replace('moe_layer.experts.0' , F'''ffn.experts.expert_{expert_idx}''' ) else: snake_case__ : Any = key.replace('moe_layer.experts.' , 'ffn.experts.expert_' ) if "gate" in key: snake_case__ : Dict = key.replace('.moe_layer.gate.wg' , '.ffn.router.classifier' ) if "fc2" and "experts" not in key: snake_case__ : str = key.replace('.fc2.' , '.ffn.fc2.' ) if "fc1" and "experts" not in key: snake_case__ : str = key.replace('.fc1.' , '.ffn.fc1.' ) if ".encoder_attn." in key: snake_case__ : Tuple = key.replace('.encoder_attn.' , '.cross_attention.' ) if "encoder_attn_layer_norm" in key: snake_case__ : Tuple = key.replace('encoder_attn_layer_norm' , 'cross_attention_layer_norm' ) if "final_layer_norm" in key: snake_case__ : Optional[int] = key.replace('final_layer_norm' , 'ff_layer_norm' ) snake_case__ : Dict = state_dict[old_key] return new_dict def lowercase_ (A : List[Any] , A : Tuple , A : List[Any] , A : List[str] , A : str = WEIGHTS_NAME ): snake_case__ : Dict = [] snake_case__ : str = 0 os.makedirs(A , exist_ok=A ) for expert in range(A ): snake_case__ : Tuple = switch_checkpoint_path + F'''-rank-{expert}.pt''' if os.path.isfile(A ): snake_case__ : Optional[Any] = torch.load(A )['model'] remove_ignore_keys_(A ) snake_case__ : Optional[Any] = rename_fairseq_keys(A , A ) snake_case__ : Dict = os.path.join( A , weights_name.replace('.bin' , F'''-{len(A )+1:05d}-of-???.bin''' ) ) torch.save(A , A ) sharded_state_dicts.append(expert_state.keys() ) total_size += sum([value.numel() for key, value in expert_state.items()] ) * dtype_byte_size( expert_state[list(A )[0]].dtype ) # Add the last block snake_case__ : Tuple = os.path.join(A , weights_name.replace('.bin' , F'''-{len(A )+1:05d}-of-???.bin''' ) ) snake_case__ : Union[str, Any] = torch.load(switch_checkpoint_path + '-shared.pt' )['model'] remove_ignore_keys_(A ) snake_case__ : str = rename_fairseq_keys(A , A ) snake_case__ : Any = shared_weights['decoder.embed_tokens.weight'] sharded_state_dicts.append(shared_weights.keys() ) # If we only have the shared weights (dummy model/experts saved on the same file) if len(A ) == 1: snake_case__ : Any = os.path.join(A , A ) torch.save(A , A ) return {weights_name: sharded_state_dicts[0]}, None else: torch.save(A , A ) # Otherwise, let's build the index snake_case__ : Tuple = {} for idx, shard in enumerate(A ): snake_case__ : Optional[int] = weights_name.replace('.bin' , F'''-{idx+1:05d}-of-{len(A ):05d}.bin''' ) snake_case__ : List[Any] = os.path.join(A , weights_name.replace('.bin' , F'''-{idx+1:05d}-of-???.bin''' ) ) os.rename(A , os.path.join(A , A ) ) for key in shard: snake_case__ : Any = shard_file # Add the metadata snake_case__ : int = {'total_size': total_size} snake_case__ : Dict = {'metadata': metadata, 'weight_map': weight_map} with open(os.path.join(A , A ) , 'w' , encoding='utf-8' ) as f: snake_case__ : Any = json.dumps(A , indent=2 , sort_keys=A ) + '\n' f.write(A ) return metadata, index if __name__ == "__main__": a_ :int = argparse.ArgumentParser() # Required parameters parser.add_argument( "--nllb_moe_checkpoint_path", default="/home/arthur_huggingface_co/fairseq/weights/checkpoints/model_moe_54b/checkpoint_2_300000", type=str, required=False, help="Path to a directory containing a folder per layer. Follows the original Google format.", ) parser.add_argument("--dtype", default="float32", type=str, required=False, help="dtype of the saved model") parser.add_argument( "--pytorch_dump_folder_path", default="/home/arthur_huggingface_co/fairseq/weights/checkpoints/hf-converted-moe-54b", type=str, required=False, help="Path to the output pytorch model.", ) a_ :Optional[Any] = parser.parse_args() a_ , a_ :Optional[Any] = shard_on_the_fly( args.nllb_moe_checkpoint_path, args.pytorch_dump_folder_path, 128, args.dtype, ) a_ :List[str] = NllbMoeConfig.from_pretrained( "facebook/nllb-200-3.3B", encoder_sparse_step=4, decoder_sparse_step=4, num_experts=128 ) config.save_pretrained(args.pytorch_dump_folder_path) a_ :int = NllbMoeModel.from_pretrained(args.pytorch_dump_folder_path) print("Done") model.save_pretrained(args.pytorch_dump_folder_path)
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'''simple docstring''' # Copyright 2023 The HuggingFace Team. All rights reserved. # # Licensed under the Apache License, Version 2.0 (the "License"); # you may not use this file except in compliance with the License. # You may obtain a copy of the License at # # http://www.apache.org/licenses/LICENSE-2.0 # # Unless required by applicable law or agreed to in writing, software # distributed under the License is distributed on an "AS IS" BASIS, # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. # See the License for the specific language governing permissions and # limitations under the License. from typing import TYPE_CHECKING # rely on isort to merge the imports from ...utils import OptionalDependencyNotAvailable, _LazyModule, is_tokenizers_available, is_torch_available _lowerCAmelCase = {"configuration_mra": ["MRA_PRETRAINED_CONFIG_ARCHIVE_MAP", "MraConfig"]} try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: _lowerCAmelCase = [ "MRA_PRETRAINED_MODEL_ARCHIVE_LIST", "MraForMaskedLM", "MraForMultipleChoice", "MraForQuestionAnswering", "MraForSequenceClassification", "MraForTokenClassification", "MraLayer", "MraModel", "MraPreTrainedModel", ] if TYPE_CHECKING: from .configuration_mra import MRA_PRETRAINED_CONFIG_ARCHIVE_MAP, MraConfig try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_mra import ( MRA_PRETRAINED_MODEL_ARCHIVE_LIST, MraForMaskedLM, MraForMultipleChoice, MraForQuestionAnswering, MraForSequenceClassification, MraForTokenClassification, MraLayer, MraModel, MraPreTrainedModel, ) else: import sys _lowerCAmelCase = _LazyModule(__name__, globals()['''__file__'''], _import_structure)
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from typing import TYPE_CHECKING from ...utils import ( OptionalDependencyNotAvailable, _LazyModule, is_sentencepiece_available, is_tokenizers_available, is_torch_available, ) a_ :Optional[Any] = {"configuration_reformer": ["REFORMER_PRETRAINED_CONFIG_ARCHIVE_MAP", "ReformerConfig"]} try: if not is_sentencepiece_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: a_ :str = ["ReformerTokenizer"] try: if not is_tokenizers_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: a_ :int = ["ReformerTokenizerFast"] try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: a_ :List[str] = [ "REFORMER_PRETRAINED_MODEL_ARCHIVE_LIST", "ReformerAttention", "ReformerForMaskedLM", "ReformerForQuestionAnswering", "ReformerForSequenceClassification", "ReformerLayer", "ReformerModel", "ReformerModelWithLMHead", "ReformerPreTrainedModel", ] if TYPE_CHECKING: from .configuration_reformer import REFORMER_PRETRAINED_CONFIG_ARCHIVE_MAP, ReformerConfig try: if not is_sentencepiece_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .tokenization_reformer import ReformerTokenizer try: if not is_tokenizers_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .tokenization_reformer_fast import ReformerTokenizerFast try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_reformer import ( REFORMER_PRETRAINED_MODEL_ARCHIVE_LIST, ReformerAttention, ReformerForMaskedLM, ReformerForQuestionAnswering, ReformerForSequenceClassification, ReformerLayer, ReformerModel, ReformerModelWithLMHead, ReformerPreTrainedModel, ) else: import sys a_ :Optional[Any] = _LazyModule(__name__, globals()["__file__"], _import_structure, module_spec=__spec__)
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from math import sqrt def lowerCAmelCase_ ( snake_case_ ): assert isinstance(snake_case_,snake_case_ ) and ( number >= 0 ), "'number' must been an int and positive" _A : Optional[Any] = True # 0 and 1 are none primes. if number <= 1: _A : Tuple = False for divisor in range(2,int(round(sqrt(snake_case_ ) ) ) + 1 ): # if 'number' divisible by 'divisor' then sets 'status' # of false and break up the loop. if number % divisor == 0: _A : Optional[Any] = False break # precondition assert isinstance(snake_case_,snake_case_ ), "'status' must been from type bool" return status def lowerCAmelCase_ ( snake_case_ ): assert isinstance(snake_case_,snake_case_ ) and (n > 2), "'N' must been an int and > 2" # beginList: contains all natural numbers from 2 up to N _A : Optional[Any] = list(range(2,n + 1 ) ) _A : List[Any] = [] # this list will be returns. # actual sieve of erathostenes for i in range(len(snake_case_ ) ): for j in range(i + 1,len(snake_case_ ) ): if (begin_list[i] != 0) and (begin_list[j] % begin_list[i] == 0): _A : int = 0 # filters actual prime numbers. _A : Union[str, Any] = [x for x in begin_list if x != 0] # precondition assert isinstance(snake_case_,snake_case_ ), "'ans' must been from type list" return ans def lowerCAmelCase_ ( snake_case_ ): assert isinstance(snake_case_,snake_case_ ) and (n > 2), "'N' must been an int and > 2" _A : int = [] # iterates over all numbers between 2 up to N+1 # if a number is prime then appends to list 'ans' for number in range(2,n + 1 ): if is_prime(snake_case_ ): ans.append(snake_case_ ) # precondition assert isinstance(snake_case_,snake_case_ ), "'ans' must been from type list" return ans def lowerCAmelCase_ ( snake_case_ ): assert isinstance(snake_case_,snake_case_ ) and number >= 0, "'number' must been an int and >= 0" _A : Optional[int] = [] # this list will be returns of the function. # potential prime number factors. _A : List[Any] = 2 _A : Dict = number if number == 0 or number == 1: ans.append(snake_case_ ) # if 'number' not prime then builds the prime factorization of 'number' elif not is_prime(snake_case_ ): while quotient != 1: if is_prime(snake_case_ ) and (quotient % factor == 0): ans.append(snake_case_ ) quotient /= factor else: factor += 1 else: ans.append(snake_case_ ) # precondition assert isinstance(snake_case_,snake_case_ ), "'ans' must been from type list" return ans def lowerCAmelCase_ ( snake_case_ ): assert isinstance(snake_case_,snake_case_ ) and ( number >= 0 ), "'number' bust been an int and >= 0" _A : Union[str, Any] = 0 # prime factorization of 'number' _A : Tuple = prime_factorization(snake_case_ ) _A : Tuple = max(snake_case_ ) # precondition assert isinstance(snake_case_,snake_case_ ), "'ans' must been from type int" return ans def lowerCAmelCase_ ( snake_case_ ): assert isinstance(snake_case_,snake_case_ ) and ( number >= 0 ), "'number' bust been an int and >= 0" _A : Tuple = 0 # prime factorization of 'number' _A : Union[str, Any] = prime_factorization(snake_case_ ) _A : Union[str, Any] = min(snake_case_ ) # precondition assert isinstance(snake_case_,snake_case_ ), "'ans' must been from type int" return ans def lowerCAmelCase_ ( snake_case_ ): assert isinstance(snake_case_,snake_case_ ), "'number' must been an int" assert isinstance(number % 2 == 0,snake_case_ ), "compare bust been from type bool" return number % 2 == 0 def lowerCAmelCase_ ( snake_case_ ): assert isinstance(snake_case_,snake_case_ ), "'number' must been an int" assert isinstance(number % 2 != 0,snake_case_ ), "compare bust been from type bool" return number % 2 != 0 def lowerCAmelCase_ ( snake_case_ ): assert ( isinstance(snake_case_,snake_case_ ) and (number > 2) and is_even(snake_case_ ) ), "'number' must been an int, even and > 2" _A : Dict = [] # this list will returned # creates a list of prime numbers between 2 up to 'number' _A : Union[str, Any] = get_prime_numbers(snake_case_ ) _A : Union[str, Any] = len(snake_case_ ) # run variable for while-loops. _A : Dict = 0 _A : Union[str, Any] = None # exit variable. for break up the loops _A : str = True while i < len_pn and loop: _A : Union[str, Any] = i + 1 while j < len_pn and loop: if prime_numbers[i] + prime_numbers[j] == number: _A : List[Any] = False ans.append(prime_numbers[i] ) ans.append(prime_numbers[j] ) j += 1 i += 1 # precondition assert ( isinstance(snake_case_,snake_case_ ) and (len(snake_case_ ) == 2) and (ans[0] + ans[1] == number) and is_prime(ans[0] ) and is_prime(ans[1] ) ), "'ans' must contains two primes. And sum of elements must been eq 'number'" return ans def lowerCAmelCase_ ( snake_case_,snake_case_ ): assert ( isinstance(snake_case_,snake_case_ ) and isinstance(snake_case_,snake_case_ ) and (numbera >= 0) and (numbera >= 0) ), "'number1' and 'number2' must been positive integer." _A : Optional[Any] = 0 while numbera != 0: _A : List[Any] = numbera % numbera _A : List[Any] = numbera _A : Dict = rest # precondition assert isinstance(snake_case_,snake_case_ ) and ( numbera >= 0 ), "'number' must been from type int and positive" return numbera def lowerCAmelCase_ ( snake_case_,snake_case_ ): assert ( isinstance(snake_case_,snake_case_ ) and isinstance(snake_case_,snake_case_ ) and (numbera >= 1) and (numbera >= 1) ), "'number1' and 'number2' must been positive integer." _A : Optional[int] = 1 # actual answer that will be return. # for kgV (x,1) if numbera > 1 and numbera > 1: # builds the prime factorization of 'number1' and 'number2' _A : Tuple = prime_factorization(snake_case_ ) _A : Dict = prime_factorization(snake_case_ ) elif numbera == 1 or numbera == 1: _A : Optional[Any] = [] _A : List[str] = [] _A : Union[str, Any] = max(snake_case_,snake_case_ ) _A : Tuple = 0 _A : Tuple = 0 _A : Optional[int] = [] # captured numbers int both 'primeFac1' and 'primeFac2' # iterates through primeFac1 for n in prime_fac_a: if n not in done: if n in prime_fac_a: _A : int = prime_fac_a.count(snake_case_ ) _A : Union[str, Any] = prime_fac_a.count(snake_case_ ) for _ in range(max(snake_case_,snake_case_ ) ): ans *= n else: _A : Union[str, Any] = prime_fac_a.count(snake_case_ ) for _ in range(snake_case_ ): ans *= n done.append(snake_case_ ) # iterates through primeFac2 for n in prime_fac_a: if n not in done: _A : int = prime_fac_a.count(snake_case_ ) for _ in range(snake_case_ ): ans *= n done.append(snake_case_ ) # precondition assert isinstance(snake_case_,snake_case_ ) and ( ans >= 0 ), "'ans' must been from type int and positive" return ans def lowerCAmelCase_ ( snake_case_ ): assert isinstance(snake_case_,snake_case_ ) and (n >= 0), "'number' must been a positive int" _A : Union[str, Any] = 0 _A : Optional[int] = 2 # this variable holds the answer while index < n: index += 1 ans += 1 # counts to the next number # if ans not prime then # runs to the next prime number. while not is_prime(snake_case_ ): ans += 1 # precondition assert isinstance(snake_case_,snake_case_ ) and is_prime( snake_case_ ), "'ans' must been a prime number and from type int" return ans def lowerCAmelCase_ ( snake_case_,snake_case_ ): assert ( is_prime(snake_case_ ) and is_prime(snake_case_ ) and (p_number_a < p_number_a) ), "The arguments must been prime numbers and 'pNumber1' < 'pNumber2'" _A : str = p_number_a + 1 # jump to the next number _A : Tuple = [] # this list will be returns. # if number is not prime then # fetch the next prime number. while not is_prime(snake_case_ ): number += 1 while number < p_number_a: ans.append(snake_case_ ) number += 1 # fetch the next prime number. while not is_prime(snake_case_ ): number += 1 # precondition assert ( isinstance(snake_case_,snake_case_ ) and ans[0] != p_number_a and ans[len(snake_case_ ) - 1] != p_number_a ), "'ans' must been a list without the arguments" # 'ans' contains not 'pNumber1' and 'pNumber2' ! return ans def lowerCAmelCase_ ( snake_case_ ): assert isinstance(snake_case_,snake_case_ ) and (n >= 1), "'n' must been int and >= 1" _A : Optional[int] = [] # will be returned. for divisor in range(1,n + 1 ): if n % divisor == 0: ans.append(snake_case_ ) # precondition assert ans[0] == 1 and ans[len(snake_case_ ) - 1] == n, "Error in function getDivisiors(...)" return ans def lowerCAmelCase_ ( snake_case_ ): assert isinstance(snake_case_,snake_case_ ) and ( number > 1 ), "'number' must been an int and >= 1" _A : Optional[Any] = get_divisors(snake_case_ ) # precondition assert ( isinstance(snake_case_,snake_case_ ) and (divisors[0] == 1) and (divisors[len(snake_case_ ) - 1] == number) ), "Error in help-function getDivisiors(...)" # summed all divisors up to 'number' (exclusive), hence [:-1] return sum(divisors[:-1] ) == number def lowerCAmelCase_ ( snake_case_,snake_case_ ): assert ( isinstance(snake_case_,snake_case_ ) and isinstance(snake_case_,snake_case_ ) and (denominator != 0) ), "The arguments must been from type int and 'denominator' != 0" # build the greatest common divisor of numerator and denominator. _A : Union[str, Any] = gcd(abs(snake_case_ ),abs(snake_case_ ) ) # precondition assert ( isinstance(snake_case_,snake_case_ ) and (numerator % gcd_of_fraction == 0) and (denominator % gcd_of_fraction == 0) ), "Error in function gcd(...,...)" return (numerator // gcd_of_fraction, denominator // gcd_of_fraction) def lowerCAmelCase_ ( snake_case_ ): assert isinstance(snake_case_,snake_case_ ) and (n >= 0), "'n' must been a int and >= 0" _A : List[Any] = 1 # this will be return. for factor in range(1,n + 1 ): ans *= factor return ans def lowerCAmelCase_ ( snake_case_ ): assert isinstance(snake_case_,snake_case_ ) and (n >= 0), "'n' must been an int and >= 0" _A : Any = 0 _A : Tuple = 1 _A : Dict = 1 # this will be return for _ in range(n - 1 ): _A : Optional[int] = ans ans += fiba _A : Optional[int] = tmp return ans
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import itertools import random import unittest import numpy as np from transformers import BatchFeature, SpeechTaFeatureExtractor from transformers.testing_utils import require_torch from transformers.utils.import_utils import is_torch_available from ...test_sequence_feature_extraction_common import SequenceFeatureExtractionTestMixin if is_torch_available(): import torch a_ :Any = random.Random() def lowercase_ (A : int , A : Union[str, Any]=1.0 , A : List[str]=None , A : Any=None ): if rng is None: snake_case__ : List[str] = global_rng snake_case__ : int = [] for batch_idx in range(shape[0] ): values.append([] ) for _ in range(shape[1] ): values[-1].append(rng.random() * scale ) return values @require_torch class snake_case__ ( unittest.TestCase ): """simple docstring""" def __init__( self : Optional[Any], _snake_case : List[str], _snake_case : Tuple=7, _snake_case : Union[str, Any]=4_0_0, _snake_case : Any=2_0_0_0, _snake_case : Dict=1, _snake_case : Optional[Any]=0.0, _snake_case : List[Any]=1_6_0_0_0, _snake_case : List[Any]=True, _snake_case : List[Any]=8_0, _snake_case : Dict=1_6, _snake_case : str=6_4, _snake_case : Tuple="hann_window", _snake_case : Union[str, Any]=8_0, _snake_case : Optional[Any]=7_6_0_0, _snake_case : str=1e-10, _snake_case : Any=True, ) ->Union[str, Any]: snake_case__ : Optional[int] = parent snake_case__ : Optional[Any] = batch_size snake_case__ : List[Any] = min_seq_length snake_case__ : List[Any] = max_seq_length snake_case__ : Any = (self.max_seq_length - self.min_seq_length) // (self.batch_size - 1) snake_case__ : Tuple = feature_size snake_case__ : List[Any] = padding_value snake_case__ : Any = sampling_rate snake_case__ : Dict = do_normalize snake_case__ : Union[str, Any] = num_mel_bins snake_case__ : Any = hop_length snake_case__ : Any = win_length snake_case__ : Any = win_function snake_case__ : Optional[int] = fmin snake_case__ : int = fmax snake_case__ : Union[str, Any] = mel_floor snake_case__ : Union[str, Any] = return_attention_mask def lowercase_ ( self : Optional[int] ) ->List[str]: return { "feature_size": self.feature_size, "padding_value": self.padding_value, "sampling_rate": self.sampling_rate, "do_normalize": self.do_normalize, "num_mel_bins": self.num_mel_bins, "hop_length": self.hop_length, "win_length": self.win_length, "win_function": self.win_function, "fmin": self.fmin, "fmax": self.fmax, "mel_floor": self.mel_floor, "return_attention_mask": self.return_attention_mask, } def lowercase_ ( self : Any, _snake_case : Optional[Any]=False, _snake_case : List[str]=False ) ->Union[str, Any]: def _flatten(_snake_case : List[str] ): return list(itertools.chain(*_snake_case ) ) if equal_length: snake_case__ : Any = floats_list((self.batch_size, self.max_seq_length) ) else: # make sure that inputs increase in size snake_case__ : int = [ _flatten(floats_list((x, self.feature_size) ) ) for x in range(self.min_seq_length, self.max_seq_length, self.seq_length_diff ) ] if numpify: snake_case__ : Any = [np.asarray(_snake_case ) for x in speech_inputs] return speech_inputs def lowercase_ ( self : Union[str, Any], _snake_case : str=False, _snake_case : Dict=False ) ->List[str]: if equal_length: snake_case__ : Optional[Any] = [floats_list((self.max_seq_length, self.num_mel_bins) ) for _ in range(self.batch_size )] else: # make sure that inputs increase in size snake_case__ : List[str] = [ floats_list((x, self.num_mel_bins) ) for x in range(self.min_seq_length, self.max_seq_length, self.seq_length_diff ) ] if numpify: snake_case__ : int = [np.asarray(_snake_case ) for x in speech_inputs] return speech_inputs @require_torch class snake_case__ ( lowerCAmelCase_ , unittest.TestCase ): """simple docstring""" _SCREAMING_SNAKE_CASE = SpeechTaFeatureExtractor def lowercase_ ( self : int ) ->Union[str, Any]: snake_case__ : List[str] = SpeechTaFeatureExtractionTester(self ) def lowercase_ ( self : Any, _snake_case : Dict ) ->Any: self.assertTrue(np.all(np.mean(_snake_case, axis=0 ) < 1e-3 ) ) self.assertTrue(np.all(np.abs(np.var(_snake_case, axis=0 ) - 1 ) < 1e-3 ) ) def lowercase_ ( self : List[Any] ) ->Union[str, Any]: # Tests that all call wrap to encode_plus and batch_encode_plus snake_case__ : Optional[Any] = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) # create three inputs of length 800, 1000, and 1200 snake_case__ : int = [floats_list((1, x) )[0] for x in range(8_0_0, 1_4_0_0, 2_0_0 )] snake_case__ : Tuple = [np.asarray(_snake_case ) for speech_input in speech_inputs] # Test not batched input snake_case__ : str = feat_extract(speech_inputs[0], return_tensors='np' ).input_values snake_case__ : List[str] = feat_extract(np_speech_inputs[0], return_tensors='np' ).input_values self.assertTrue(np.allclose(_snake_case, _snake_case, atol=1e-3 ) ) # Test batched snake_case__ : Any = feat_extract(_snake_case, return_tensors='np' ).input_values snake_case__ : Union[str, Any] = feat_extract(_snake_case, return_tensors='np' ).input_values for enc_seq_a, enc_seq_a in zip(_snake_case, _snake_case ): self.assertTrue(np.allclose(_snake_case, _snake_case, atol=1e-3 ) ) def lowercase_ ( self : int ) ->Optional[int]: snake_case__ : List[Any] = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) snake_case__ : Tuple = [floats_list((1, x) )[0] for x in range(8_0_0, 1_4_0_0, 2_0_0 )] snake_case__ : int = ['longest', 'max_length', 'do_not_pad'] snake_case__ : List[str] = [None, 1_6_0_0, None] for max_length, padding in zip(_snake_case, _snake_case ): snake_case__ : Optional[int] = feat_extract(_snake_case, padding=_snake_case, max_length=_snake_case, return_tensors='np' ) snake_case__ : Optional[int] = processed.input_values self._check_zero_mean_unit_variance(input_values[0][:8_0_0] ) self.assertTrue(input_values[0][8_0_0:].sum() < 1e-6 ) self._check_zero_mean_unit_variance(input_values[1][:1_0_0_0] ) self.assertTrue(input_values[0][1_0_0_0:].sum() < 1e-6 ) self._check_zero_mean_unit_variance(input_values[2][:1_2_0_0] ) def lowercase_ ( self : Union[str, Any] ) ->Optional[Any]: snake_case__ : Optional[Any] = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) snake_case__ : Tuple = range(8_0_0, 1_4_0_0, 2_0_0 ) snake_case__ : Optional[Any] = [floats_list((1, x) )[0] for x in lengths] snake_case__ : Union[str, Any] = ['longest', 'max_length', 'do_not_pad'] snake_case__ : str = [None, 1_6_0_0, None] for max_length, padding in zip(_snake_case, _snake_case ): snake_case__ : List[str] = feat_extract(_snake_case, max_length=_snake_case, padding=_snake_case ) snake_case__ : Tuple = processed.input_values self._check_zero_mean_unit_variance(input_values[0][:8_0_0] ) self._check_zero_mean_unit_variance(input_values[1][:1_0_0_0] ) self._check_zero_mean_unit_variance(input_values[2][:1_2_0_0] ) def lowercase_ ( self : List[Any] ) ->Optional[Any]: snake_case__ : Any = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) snake_case__ : str = [floats_list((1, x) )[0] for x in range(8_0_0, 1_4_0_0, 2_0_0 )] snake_case__ : Optional[Any] = feat_extract( _snake_case, truncation=_snake_case, max_length=1_0_0_0, padding='max_length', return_tensors='np' ) snake_case__ : int = processed.input_values self._check_zero_mean_unit_variance(input_values[0, :8_0_0] ) self._check_zero_mean_unit_variance(input_values[1] ) self._check_zero_mean_unit_variance(input_values[2] ) def lowercase_ ( self : int ) ->Union[str, Any]: snake_case__ : str = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) snake_case__ : Dict = [floats_list((1, x) )[0] for x in range(8_0_0, 1_4_0_0, 2_0_0 )] snake_case__ : str = feat_extract( _snake_case, truncation=_snake_case, max_length=1_0_0_0, padding='longest', return_tensors='np' ) snake_case__ : Dict = processed.input_values self._check_zero_mean_unit_variance(input_values[0, :8_0_0] ) self._check_zero_mean_unit_variance(input_values[1, :1_0_0_0] ) self._check_zero_mean_unit_variance(input_values[2] ) # make sure that if max_length < longest -> then pad to max_length self.assertTrue(input_values.shape == (3, 1_0_0_0) ) snake_case__ : Tuple = [floats_list((1, x) )[0] for x in range(8_0_0, 1_4_0_0, 2_0_0 )] snake_case__ : List[str] = feat_extract( _snake_case, truncation=_snake_case, max_length=2_0_0_0, padding='longest', return_tensors='np' ) snake_case__ : Optional[Any] = processed.input_values self._check_zero_mean_unit_variance(input_values[0, :8_0_0] ) self._check_zero_mean_unit_variance(input_values[1, :1_0_0_0] ) self._check_zero_mean_unit_variance(input_values[2] ) # make sure that if max_length > longest -> then pad to longest self.assertTrue(input_values.shape == (3, 1_2_0_0) ) def lowercase_ ( self : List[str] ) ->Dict: snake_case__ : Dict = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) snake_case__ : List[Any] = np.random.rand(1_0_0 ).astype(np.floataa ) snake_case__ : int = np_speech_inputs.tolist() for inputs in [py_speech_inputs, np_speech_inputs]: snake_case__ : int = feature_extractor.pad([{'input_values': inputs}], return_tensors='np' ) self.assertTrue(np_processed.input_values.dtype == np.floataa ) snake_case__ : Optional[int] = feature_extractor.pad([{'input_values': inputs}], return_tensors='pt' ) self.assertTrue(pt_processed.input_values.dtype == torch.floataa ) def lowercase_ ( self : Optional[int] ) ->Optional[Any]: # Tests that all call wrap to encode_plus and batch_encode_plus snake_case__ : str = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) # create three inputs of length 800, 1000, and 1200 snake_case__ : List[Any] = [floats_list((1, x) )[0] for x in range(8_0_0, 1_4_0_0, 2_0_0 )] snake_case__ : Dict = [np.asarray(_snake_case ) for speech_input in speech_inputs] # Test feature size snake_case__ : Optional[int] = feature_extractor(audio_target=_snake_case, padding=_snake_case, return_tensors='np' ).input_values self.assertTrue(input_values.ndim == 3 ) self.assertTrue(input_values.shape[-1] == feature_extractor.num_mel_bins ) # Test not batched input snake_case__ : Dict = feature_extractor(speech_inputs[0], return_tensors='np' ).input_values snake_case__ : Any = feature_extractor(np_speech_inputs[0], return_tensors='np' ).input_values self.assertTrue(np.allclose(_snake_case, _snake_case, atol=1e-3 ) ) # Test batched snake_case__ : Dict = feature_extractor(_snake_case, return_tensors='np' ).input_values snake_case__ : Dict = feature_extractor(_snake_case, return_tensors='np' ).input_values for enc_seq_a, enc_seq_a in zip(_snake_case, _snake_case ): self.assertTrue(np.allclose(_snake_case, _snake_case, atol=1e-3 ) ) # Test 2-D numpy arrays are batched. snake_case__ : Optional[Any] = [floats_list((1, x) )[0] for x in (8_0_0, 8_0_0, 8_0_0)] snake_case__ : int = np.asarray(_snake_case ) snake_case__ : Union[str, Any] = feature_extractor(_snake_case, return_tensors='np' ).input_values snake_case__ : Union[str, Any] = feature_extractor(_snake_case, return_tensors='np' ).input_values for enc_seq_a, enc_seq_a in zip(_snake_case, _snake_case ): self.assertTrue(np.allclose(_snake_case, _snake_case, atol=1e-3 ) ) def lowercase_ ( self : Union[str, Any] ) ->str: snake_case__ : int = self.feat_extract_tester.prepare_inputs_for_target() snake_case__ : List[str] = self.feature_extraction_class(**self.feat_extract_dict ) snake_case__ : Optional[Any] = feat_extract.model_input_names[0] snake_case__ : Tuple = BatchFeature({input_name: speech_inputs} ) self.assertTrue(all(len(_snake_case ) == len(_snake_case ) for x, y in zip(_snake_case, processed_features[input_name] ) ) ) snake_case__ : int = self.feat_extract_tester.prepare_inputs_for_target(equal_length=_snake_case ) snake_case__ : Union[str, Any] = BatchFeature({input_name: speech_inputs}, tensor_type='np' ) snake_case__ : Dict = processed_features[input_name] if len(batch_features_input.shape ) < 3: snake_case__ : List[str] = batch_features_input[:, :, None] self.assertTrue( batch_features_input.shape == (self.feat_extract_tester.batch_size, len(speech_inputs[0] ), self.feat_extract_tester.num_mel_bins) ) @require_torch def lowercase_ ( self : List[str] ) ->Any: snake_case__ : int = self.feat_extract_tester.prepare_inputs_for_target(equal_length=_snake_case ) snake_case__ : Optional[Any] = self.feature_extraction_class(**self.feat_extract_dict ) snake_case__ : Tuple = feat_extract.model_input_names[0] snake_case__ : List[Any] = BatchFeature({input_name: speech_inputs}, tensor_type='pt' ) snake_case__ : Tuple = processed_features[input_name] if len(batch_features_input.shape ) < 3: snake_case__ : Any = batch_features_input[:, :, None] self.assertTrue( batch_features_input.shape == (self.feat_extract_tester.batch_size, len(speech_inputs[0] ), self.feat_extract_tester.num_mel_bins) ) @require_torch def lowercase_ ( self : Optional[int] ) ->Tuple: snake_case__ : Dict = self.feature_extraction_class(**self.feat_extract_dict ) snake_case__ : Union[str, Any] = self.feat_extract_tester.prepare_inputs_for_target() snake_case__ : Optional[Any] = feat_extract.model_input_names[0] snake_case__ : List[str] = BatchFeature({input_name: speech_inputs} ) snake_case__ : int = feat_extract.num_mel_bins # hack! snake_case__ : Tuple = feat_extract.pad(_snake_case, padding='longest', return_tensors='np' )[input_name] snake_case__ : Union[str, Any] = feat_extract.pad(_snake_case, padding='longest', return_tensors='pt' )[input_name] self.assertTrue(abs(input_np.astype(np.floataa ).sum() - input_pt.numpy().astype(np.floataa ).sum() ) < 1e-2 ) def lowercase_ ( self : int ) ->Any: snake_case__ : Any = self.feat_extract_dict snake_case__ : List[Any] = True snake_case__ : Union[str, Any] = self.feature_extraction_class(**_snake_case ) snake_case__ : Any = self.feat_extract_tester.prepare_inputs_for_target() snake_case__ : List[Any] = [len(_snake_case ) for x in speech_inputs] snake_case__ : Union[str, Any] = feat_extract.model_input_names[0] snake_case__ : Optional[int] = BatchFeature({input_name: speech_inputs} ) snake_case__ : List[str] = feat_extract.num_mel_bins # hack! snake_case__ : str = feat_extract.pad(_snake_case, padding='longest', return_tensors='np' ) self.assertIn('attention_mask', _snake_case ) self.assertListEqual(list(processed.attention_mask.shape ), list(processed[input_name].shape[:2] ) ) self.assertListEqual(processed.attention_mask.sum(-1 ).tolist(), _snake_case ) def lowercase_ ( self : Optional[int] ) ->str: snake_case__ : int = self.feat_extract_dict snake_case__ : List[str] = True snake_case__ : Tuple = self.feature_extraction_class(**_snake_case ) snake_case__ : List[str] = self.feat_extract_tester.prepare_inputs_for_target() snake_case__ : str = [len(_snake_case ) for x in speech_inputs] snake_case__ : Optional[Any] = feat_extract.model_input_names[0] snake_case__ : Optional[int] = BatchFeature({input_name: speech_inputs} ) snake_case__ : Optional[Any] = min(_snake_case ) snake_case__ : Union[str, Any] = feat_extract.num_mel_bins # hack! snake_case__ : Tuple = feat_extract.pad( _snake_case, padding='max_length', max_length=_snake_case, truncation=_snake_case, return_tensors='np' ) self.assertIn('attention_mask', _snake_case ) self.assertListEqual( list(processed_pad.attention_mask.shape ), [processed_pad[input_name].shape[0], max_length] ) self.assertListEqual( processed_pad.attention_mask[:, :max_length].sum(-1 ).tolist(), [max_length for x in speech_inputs] ) def lowercase_ ( self : List[Any], _snake_case : Optional[int] ) ->Optional[Any]: from datasets import load_dataset snake_case__ : str = load_dataset('hf-internal-testing/librispeech_asr_dummy', 'clean', split='validation' ) # automatic decoding with librispeech snake_case__ : Dict = ds.sort('id' ).select(range(_snake_case ) )[:num_samples]['audio'] return [x["array"] for x in speech_samples] def lowercase_ ( self : str ) ->str: # fmt: off snake_case__ : List[Any] = torch.tensor( [2.3804e-03, 2.0752e-03, 1.9836e-03, 2.1057e-03, 1.6174e-03, 3.0518e-04, 9.1553e-05, 3.3569e-04, 9.7656e-04, 1.8311e-03, 2.0142e-03, 2.1057e-03, 1.7395e-03, 4.5776e-04, -3.9673e-04, 4.5776e-04, 1.0071e-03, 9.1553e-05, 4.8828e-04, 1.1597e-03, 7.3242e-04, 9.4604e-04, 1.8005e-03, 1.8311e-03, 8.8501e-04, 4.2725e-04, 4.8828e-04, 7.3242e-04, 1.0986e-03, 2.1057e-03] ) # fmt: on snake_case__ : Union[str, Any] = self._load_datasamples(1 ) snake_case__ : Optional[int] = SpeechTaFeatureExtractor() snake_case__ : List[Any] = feature_extractor(_snake_case, return_tensors='pt' ).input_values self.assertEquals(input_values.shape, (1, 9_3_6_8_0) ) self.assertTrue(torch.allclose(input_values[0, :3_0], _snake_case, atol=1e-6 ) ) def lowercase_ ( self : Any ) ->str: # fmt: off snake_case__ : Optional[Any] = torch.tensor( [-2.6_8_7_0, -3.0_1_0_4, -3.1_3_5_6, -3.5_3_5_2, -3.0_0_4_4, -3.0_3_5_3, -3.4_7_1_9, -3.6_7_7_7, -3.1_5_2_0, -2.9_4_3_5, -2.6_5_5_3, -2.8_7_9_5, -2.9_9_4_4, -2.5_9_2_1, -3.0_2_7_9, -3.0_3_8_6, -3.0_8_6_4, -3.1_2_9_1, -3.2_3_5_3, -2.7_4_4_4, -2.6_8_3_1, -2.7_2_8_7, -3.1_7_6_1, -3.1_5_7_1, -3.2_7_2_6, -3.0_5_8_2, -3.1_0_0_7, -3.4_5_3_3, -3.4_6_9_5, -3.0_9_9_8] ) # fmt: on snake_case__ : List[str] = self._load_datasamples(1 ) snake_case__ : str = SpeechTaFeatureExtractor() snake_case__ : Optional[Any] = feature_extractor(audio_target=_snake_case, return_tensors='pt' ).input_values self.assertEquals(input_values.shape, (1, 3_6_6, 8_0) ) self.assertTrue(torch.allclose(input_values[0, 0, :3_0], _snake_case, atol=1e-4 ) )
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0
import copy import os import tempfile from unittest import TestCase from unittest.mock import patch import numpy as np import pyarrow as pa import pyarrow.parquet as pq import pytest from datasets.arrow_writer import ArrowWriter, OptimizedTypedSequence, ParquetWriter, TypedSequence from datasets.features import ArrayaD, ClassLabel, Features, Image, Value from datasets.features.features import ArrayaDExtensionType, cast_to_python_objects from datasets.keyhash import DuplicatedKeysError, InvalidKeyError from .utils import require_pil class __lowerCAmelCase ( lowerCAmelCase_ ): def _lowerCamelCase ( self : List[Any]) -> str: """simple docstring""" _UpperCAmelCase = pa.array(TypedSequence([1, 2, 3])) self.assertEqual(arr.type , pa.intaa()) def _lowerCamelCase ( self : Dict) -> str: """simple docstring""" with self.assertRaises(_snake_case): _UpperCAmelCase = pa.array(TypedSequence([1, 2, 3]) , type=pa.intaa()) def _lowerCamelCase ( self : List[Any]) -> Dict: """simple docstring""" with self.assertRaises(_snake_case): _UpperCAmelCase = pa.array(TypedSequence([1, 2, 3] , try_type=Value('bool') , type=Value('int64'))) def _lowerCamelCase ( self : int) -> Optional[int]: """simple docstring""" _UpperCAmelCase = pa.array(TypedSequence([1, 2, 3] , type=Value('int32'))) self.assertEqual(arr.type , pa.intaa()) def _lowerCamelCase ( self : List[str]) -> Optional[Any]: """simple docstring""" with self.assertRaises((TypeError, pa.lib.ArrowInvalid)): _UpperCAmelCase = pa.array(TypedSequence(['foo', 'bar'] , type=Value('int64'))) def _lowerCamelCase ( self : Tuple) -> Any: """simple docstring""" _UpperCAmelCase = pa.array(TypedSequence([1, 2, 3] , try_type=Value('int32'))) self.assertEqual(arr.type , pa.intaa()) def _lowerCamelCase ( self : Optional[int]) -> List[str]: """simple docstring""" _UpperCAmelCase = pa.array(TypedSequence(['foo', 'bar'] , try_type=Value('int64'))) self.assertEqual(arr.type , pa.string()) def _lowerCamelCase ( self : str) -> List[Any]: """simple docstring""" _UpperCAmelCase = pa.array(TypedSequence([[[1, 2, 3]]] , type=ArrayaD((1, 3) , 'int64'))) self.assertEqual(arr.type , ArrayaDExtensionType((1, 3) , 'int64')) def _lowerCamelCase ( self : Any) -> List[Any]: """simple docstring""" with self.assertRaises((TypeError, pa.lib.ArrowInvalid)): _UpperCAmelCase = pa.array(TypedSequence(['foo', 'bar'] , type=ArrayaD((1, 3) , 'int64'))) def _lowerCamelCase ( self : Union[str, Any]) -> Tuple: """simple docstring""" _UpperCAmelCase = pa.array(TypedSequence([[[1, 2, 3]]] , try_type=ArrayaD((1, 3) , 'int64'))) self.assertEqual(arr.type , ArrayaDExtensionType((1, 3) , 'int64')) def _lowerCamelCase ( self : int) -> Union[str, Any]: """simple docstring""" _UpperCAmelCase = pa.array(TypedSequence(['foo', 'bar'] , try_type=ArrayaD((1, 3) , 'int64'))) self.assertEqual(arr.type , pa.string()) @require_pil def _lowerCamelCase ( self : Any) -> Optional[int]: """simple docstring""" import PIL.Image _UpperCAmelCase = PIL.Image.fromarray(np.arange(10 , dtype=np.uinta).reshape(2 , 5)) with patch( 'datasets.arrow_writer.cast_to_python_objects' , side_effect=_snake_case) as mock_cast_to_python_objects: _UpperCAmelCase = pa.array(TypedSequence([{'path': None, 'bytes': B'image_bytes'}, pil_image] , type=Image())) _UpperCAmelCase = mock_cast_to_python_objects.call_args_list[-1] self.assertIn('optimize_list_casting' , _snake_case) self.assertFalse(kwargs['optimize_list_casting']) def A ( _UpperCAmelCase : Dict , _UpperCAmelCase : int ) -> Dict: '''simple docstring''' _UpperCAmelCase = pa.BufferReader(_UpperCAmelCase ) if isinstance(_UpperCAmelCase , pa.Buffer ) else pa.memory_map(_UpperCAmelCase ) _UpperCAmelCase = pa.ipc.open_stream(_UpperCAmelCase ) _UpperCAmelCase = f.read_all() assert len(pa_table.to_batches() ) == expected_num_chunks assert pa_table.to_pydict() == {"col_1": ["foo", "bar"], "col_2": [1, 2]} del pa_table @pytest.mark.parametrize('writer_batch_size' , [None, 1, 10] ) @pytest.mark.parametrize( 'fields' , [None, {'col_1': pa.string(), 'col_2': pa.intaa()}, {'col_1': pa.string(), 'col_2': pa.intaa()}] ) def A ( _UpperCAmelCase : List[str] , _UpperCAmelCase : List[str] ) -> List[Any]: '''simple docstring''' _UpperCAmelCase = pa.BufferOutputStream() _UpperCAmelCase = pa.schema(_UpperCAmelCase ) if fields else None with ArrowWriter(stream=_UpperCAmelCase , schema=_UpperCAmelCase , writer_batch_size=_UpperCAmelCase ) as writer: writer.write({'col_1': 'foo', 'col_2': 1} ) writer.write({'col_1': 'bar', 'col_2': 2} ) _UpperCAmelCase = writer.finalize() assert num_examples == 2 assert num_bytes > 0 if not fields: _UpperCAmelCase = {'col_1': pa.string(), 'col_2': pa.intaa()} assert writer._schema == pa.schema(_UpperCAmelCase , metadata=writer._schema.metadata ) _check_output(output.getvalue() , expected_num_chunks=num_examples if writer_batch_size == 1 else 1 ) def A ( ) -> Optional[int]: '''simple docstring''' _UpperCAmelCase = pa.BufferOutputStream() _UpperCAmelCase = Features({'labels': ClassLabel(names=['neg', 'pos'] )} ) with ArrowWriter(stream=_UpperCAmelCase , features=_UpperCAmelCase ) as writer: writer.write({'labels': 0} ) writer.write({'labels': 1} ) _UpperCAmelCase = writer.finalize() assert num_examples == 2 assert num_bytes > 0 assert writer._schema == features.arrow_schema assert writer._schema.metadata == features.arrow_schema.metadata _UpperCAmelCase = pa.BufferReader(output.getvalue() ) _UpperCAmelCase = pa.ipc.open_stream(_UpperCAmelCase ) _UpperCAmelCase = f.read_all() _UpperCAmelCase = pa_table.schema assert pa_table.num_rows == 2 assert schema == features.arrow_schema assert schema.metadata == features.arrow_schema.metadata assert features == Features.from_arrow_schema(_UpperCAmelCase ) @pytest.mark.parametrize('writer_batch_size' , [None, 1, 10] ) def A ( _UpperCAmelCase : int ) -> Dict: '''simple docstring''' _UpperCAmelCase = pa.BufferOutputStream() with ArrowWriter( stream=_UpperCAmelCase , writer_batch_size=_UpperCAmelCase , hash_salt='split_name' , check_duplicates=_UpperCAmelCase , ) as writer: with pytest.raises(_UpperCAmelCase ): writer.write({'col_1': 'foo', 'col_2': 1} , key=[1, 2] ) _UpperCAmelCase = writer.finalize() @pytest.mark.parametrize('writer_batch_size' , [None, 2, 10] ) def A ( _UpperCAmelCase : Optional[int] ) -> List[Any]: '''simple docstring''' _UpperCAmelCase = pa.BufferOutputStream() with ArrowWriter( stream=_UpperCAmelCase , writer_batch_size=_UpperCAmelCase , hash_salt='split_name' , check_duplicates=_UpperCAmelCase , ) as writer: with pytest.raises(_UpperCAmelCase ): writer.write({'col_1': 'foo', 'col_2': 1} , key=10 ) writer.write({'col_1': 'bar', 'col_2': 2} , key=10 ) _UpperCAmelCase = writer.finalize() @pytest.mark.parametrize('writer_batch_size' , [None, 2, 10] ) def A ( _UpperCAmelCase : List[Any] ) -> Optional[int]: '''simple docstring''' _UpperCAmelCase = pa.BufferOutputStream() with ArrowWriter( stream=_UpperCAmelCase , writer_batch_size=_UpperCAmelCase , hash_salt='split_name' , check_duplicates=_UpperCAmelCase , ) as writer: writer.write({'col_1': 'foo', 'col_2': 1} , key=1 ) writer.write({'col_1': 'bar', 'col_2': 2} , key=2 ) _UpperCAmelCase = writer.finalize() assert num_examples == 2 assert num_bytes > 0 _check_output(output.getvalue() , expected_num_chunks=num_examples if writer_batch_size == 1 else 1 ) @pytest.mark.parametrize('writer_batch_size' , [None, 1, 10] ) @pytest.mark.parametrize( 'fields' , [None, {'col_1': pa.string(), 'col_2': pa.intaa()}, {'col_1': pa.string(), 'col_2': pa.intaa()}] ) def A ( _UpperCAmelCase : Dict , _UpperCAmelCase : Any ) -> List[Any]: '''simple docstring''' _UpperCAmelCase = pa.BufferOutputStream() _UpperCAmelCase = pa.schema(_UpperCAmelCase ) if fields else None with ArrowWriter(stream=_UpperCAmelCase , schema=_UpperCAmelCase , writer_batch_size=_UpperCAmelCase ) as writer: writer.write_batch({'col_1': ['foo', 'bar'], 'col_2': [1, 2]} ) writer.write_batch({'col_1': [], 'col_2': []} ) _UpperCAmelCase = writer.finalize() assert num_examples == 2 assert num_bytes > 0 if not fields: _UpperCAmelCase = {'col_1': pa.string(), 'col_2': pa.intaa()} assert writer._schema == pa.schema(_UpperCAmelCase , metadata=writer._schema.metadata ) _check_output(output.getvalue() , expected_num_chunks=num_examples if writer_batch_size == 1 else 1 ) @pytest.mark.parametrize('writer_batch_size' , [None, 1, 10] ) @pytest.mark.parametrize( 'fields' , [None, {'col_1': pa.string(), 'col_2': pa.intaa()}, {'col_1': pa.string(), 'col_2': pa.intaa()}] ) def A ( _UpperCAmelCase : Tuple , _UpperCAmelCase : str ) -> Any: '''simple docstring''' _UpperCAmelCase = pa.BufferOutputStream() _UpperCAmelCase = pa.schema(_UpperCAmelCase ) if fields else None with ArrowWriter(stream=_UpperCAmelCase , schema=_UpperCAmelCase , writer_batch_size=_UpperCAmelCase ) as writer: writer.write_table(pa.Table.from_pydict({'col_1': ['foo', 'bar'], 'col_2': [1, 2]} ) ) _UpperCAmelCase = writer.finalize() assert num_examples == 2 assert num_bytes > 0 if not fields: _UpperCAmelCase = {'col_1': pa.string(), 'col_2': pa.intaa()} assert writer._schema == pa.schema(_UpperCAmelCase , metadata=writer._schema.metadata ) _check_output(output.getvalue() , expected_num_chunks=num_examples if writer_batch_size == 1 else 1 ) @pytest.mark.parametrize('writer_batch_size' , [None, 1, 10] ) @pytest.mark.parametrize( 'fields' , [None, {'col_1': pa.string(), 'col_2': pa.intaa()}, {'col_1': pa.string(), 'col_2': pa.intaa()}] ) def A ( _UpperCAmelCase : List[str] , _UpperCAmelCase : Union[str, Any] ) -> Tuple: '''simple docstring''' _UpperCAmelCase = pa.BufferOutputStream() _UpperCAmelCase = pa.schema(_UpperCAmelCase ) if fields else None with ArrowWriter(stream=_UpperCAmelCase , schema=_UpperCAmelCase , writer_batch_size=_UpperCAmelCase ) as writer: writer.write_row(pa.Table.from_pydict({'col_1': ['foo'], 'col_2': [1]} ) ) writer.write_row(pa.Table.from_pydict({'col_1': ['bar'], 'col_2': [2]} ) ) _UpperCAmelCase = writer.finalize() assert num_examples == 2 assert num_bytes > 0 if not fields: _UpperCAmelCase = {'col_1': pa.string(), 'col_2': pa.intaa()} assert writer._schema == pa.schema(_UpperCAmelCase , metadata=writer._schema.metadata ) _check_output(output.getvalue() , expected_num_chunks=num_examples if writer_batch_size == 1 else 1 ) def A ( ) -> int: '''simple docstring''' with tempfile.TemporaryDirectory() as tmp_dir: _UpperCAmelCase = {'col_1': pa.string(), 'col_2': pa.intaa()} _UpperCAmelCase = os.path.join(_UpperCAmelCase , 'test.arrow' ) with ArrowWriter(path=_UpperCAmelCase , schema=pa.schema(_UpperCAmelCase ) ) as writer: writer.write_batch({'col_1': ['foo', 'bar'], 'col_2': [1, 2]} ) _UpperCAmelCase = writer.finalize() assert num_examples == 2 assert num_bytes > 0 assert writer._schema == pa.schema(_UpperCAmelCase , metadata=writer._schema.metadata ) _check_output(_UpperCAmelCase , 1 ) def A ( _UpperCAmelCase : Union[str, Any] ) -> Dict: '''simple docstring''' if pa.types.is_list(_UpperCAmelCase ): return get_base_dtype(arr_type.value_type ) else: return arr_type def A ( _UpperCAmelCase : List[Any] , _UpperCAmelCase : Union[str, Any] ) -> Union[str, Any]: '''simple docstring''' if isinstance(lst[0] , _UpperCAmelCase ): change_first_primitive_element_in_list(lst[0] , _UpperCAmelCase ) else: _UpperCAmelCase = value @pytest.mark.parametrize('optimized_int_type, expected_dtype' , [(None, pa.intaa()), (Value('int32' ), pa.intaa())] ) @pytest.mark.parametrize('sequence' , [[1, 2, 3], [[1, 2, 3]], [[[1, 2, 3]]]] ) def A ( _UpperCAmelCase : Tuple , _UpperCAmelCase : List[str] , _UpperCAmelCase : List[Any] ) -> Union[str, Any]: '''simple docstring''' _UpperCAmelCase = pa.array(TypedSequence(_UpperCAmelCase , optimized_int_type=_UpperCAmelCase ) ) assert get_base_dtype(arr.type ) == expected_dtype @pytest.mark.parametrize( 'col, expected_dtype' , [ ('attention_mask', pa.inta()), ('special_tokens_mask', pa.inta()), ('token_type_ids', pa.inta()), ('input_ids', pa.intaa()), ('other', pa.intaa()), ] , ) @pytest.mark.parametrize('sequence' , [[1, 2, 3], [[1, 2, 3]], [[[1, 2, 3]]]] ) def A ( _UpperCAmelCase : List[Any] , _UpperCAmelCase : Union[str, Any] , _UpperCAmelCase : str ) -> Optional[Any]: '''simple docstring''' # in range _UpperCAmelCase = pa.array(OptimizedTypedSequence(_UpperCAmelCase , col=_UpperCAmelCase ) ) assert get_base_dtype(arr.type ) == expected_dtype # not in range if col != "other": # avoids errors due to in-place modifications _UpperCAmelCase = copy.deepcopy(_UpperCAmelCase ) _UpperCAmelCase = np.iinfo(expected_dtype.to_pandas_dtype() ).max + 1 change_first_primitive_element_in_list(_UpperCAmelCase , _UpperCAmelCase ) _UpperCAmelCase = pa.array(OptimizedTypedSequence(_UpperCAmelCase , col=_UpperCAmelCase ) ) assert get_base_dtype(arr.type ) == pa.intaa() @pytest.mark.parametrize('raise_exception' , [False, True] ) def A ( _UpperCAmelCase : Union[str, Any] , _UpperCAmelCase : List[str] ) -> Optional[Any]: '''simple docstring''' _UpperCAmelCase = str(tmp_path / 'dataset-train.arrow' ) try: with ArrowWriter(path=_UpperCAmelCase ) as writer: if raise_exception: raise pa.lib.ArrowInvalid() else: writer.stream.close() except pa.lib.ArrowInvalid: pass finally: assert writer.stream.closed def A ( _UpperCAmelCase : int ) -> Tuple: '''simple docstring''' _UpperCAmelCase = 'mock://dataset-train.arrow' with ArrowWriter(path=_UpperCAmelCase , storage_options=mockfs.storage_options ) as writer: assert isinstance(writer._fs , type(_UpperCAmelCase ) ) assert writer._fs.storage_options == mockfs.storage_options writer.write({'col_1': 'foo', 'col_2': 1} ) writer.write({'col_1': 'bar', 'col_2': 2} ) _UpperCAmelCase = writer.finalize() assert num_examples == 2 assert num_bytes > 0 assert mockfs.exists(_UpperCAmelCase ) def A ( ) -> Any: '''simple docstring''' _UpperCAmelCase = pa.BufferOutputStream() with ParquetWriter(stream=_UpperCAmelCase ) as writer: writer.write({'col_1': 'foo', 'col_2': 1} ) writer.write({'col_1': 'bar', 'col_2': 2} ) _UpperCAmelCase = writer.finalize() assert num_examples == 2 assert num_bytes > 0 _UpperCAmelCase = pa.BufferReader(output.getvalue() ) _UpperCAmelCase = pq.read_table(_UpperCAmelCase ) assert pa_table.to_pydict() == {"col_1": ["foo", "bar"], "col_2": [1, 2]} @require_pil @pytest.mark.parametrize('embed_local_files' , [False, True] ) def A ( _UpperCAmelCase : List[Any] , _UpperCAmelCase : Optional[Any] ) -> List[Any]: '''simple docstring''' import PIL.Image _UpperCAmelCase = str(tmp_path / 'test_image_rgb.jpg' ) PIL.Image.fromarray(np.zeros((5, 5) , dtype=np.uinta ) ).save(_UpperCAmelCase , format='png' ) _UpperCAmelCase = pa.BufferOutputStream() with ParquetWriter( stream=_UpperCAmelCase , features=Features({'image': Image()} ) , embed_local_files=_UpperCAmelCase ) as writer: writer.write({'image': image_path} ) writer.finalize() _UpperCAmelCase = pa.BufferReader(output.getvalue() ) _UpperCAmelCase = pq.read_table(_UpperCAmelCase ) _UpperCAmelCase = pa_table.to_pydict() if embed_local_files: assert isinstance(out['image'][0]['path'] , _UpperCAmelCase ) with open(_UpperCAmelCase , 'rb' ) as f: assert out["image"][0]["bytes"] == f.read() else: assert out["image"][0]["path"] == image_path assert out["image"][0]["bytes"] is None def A ( ) -> Dict: '''simple docstring''' _UpperCAmelCase = pa.schema([pa.field('col_1' , pa.string() , nullable=_UpperCAmelCase )] ) _UpperCAmelCase = pa.BufferOutputStream() with ArrowWriter(stream=_UpperCAmelCase ) as writer: writer._build_writer(inferred_schema=_UpperCAmelCase ) assert writer._schema == pa.schema([pa.field('col_1' , pa.string() )] )
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# Copyright 2023 The HuggingFace Inc. team. All rights reserved. # # Licensed under the Apache License, Version 2.0 (the "License"); # you may not use this file except in compliance with the License. # You may obtain a copy of the License at # # http://www.apache.org/licenses/LICENSE-2.0 # # Unless required by applicable law or agreed to in writing, software # distributed under the License is distributed on an "AS IS" BASIS, # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. # See the License for the specific language governing permissions and # limitations under the License. from ..models.auto import AutoModelForSeqaSeqLM, AutoTokenizer from .base import PipelineTool class snake_case__ ( lowerCAmelCase_ ): """simple docstring""" _SCREAMING_SNAKE_CASE = """philschmid/bart-large-cnn-samsum""" _SCREAMING_SNAKE_CASE = ( """This is a tool that summarizes an English text. It takes an input `text` containing the text to summarize, """ """and returns a summary of the text.""" ) _SCREAMING_SNAKE_CASE = """summarizer""" _SCREAMING_SNAKE_CASE = AutoTokenizer _SCREAMING_SNAKE_CASE = AutoModelForSeqaSeqLM _SCREAMING_SNAKE_CASE = ["""text"""] _SCREAMING_SNAKE_CASE = ["""text"""] def lowercase_ ( self : Optional[Any], _snake_case : str ) ->Any: return self.pre_processor(_snake_case, return_tensors='pt', truncation=_snake_case ) def lowercase_ ( self : int, _snake_case : List[Any] ) ->Any: return self.model.generate(**_snake_case )[0] def lowercase_ ( self : int, _snake_case : int ) ->str: return self.pre_processor.decode(_snake_case, skip_special_tokens=_snake_case, clean_up_tokenization_spaces=_snake_case )
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# We ignore warnings about stepping the scheduler since we step it ourselves during gradient accumulation import warnings from .state import AcceleratorState, GradientState warnings.filterwarnings("ignore", category=UserWarning, module="torch.optim.lr_scheduler") class UpperCamelCase_ : '''simple docstring''' def __init__( self , a , a , a = True , a = False ) -> int: snake_case_ = scheduler snake_case_ = optimizers if isinstance(_snake_case , (list, tuple) ) else [optimizers] snake_case_ = split_batches snake_case_ = step_with_optimizer snake_case_ = GradientState() def _UpperCamelCase ( self , *a , **a ) -> Tuple: if not self.step_with_optimizer: # No link between scheduler and optimizer -> just step self.scheduler.step(*_snake_case , **_snake_case ) return # Otherwise, first make sure the optimizer was stepped. if not self.gradient_state.sync_gradients: if self.gradient_state.adjust_scheduler: self.scheduler._step_count += 1 return for opt in self.optimizers: if opt.step_was_skipped: return if self.split_batches: # Split batches -> the training dataloader batch size is not changed so one step per training step self.scheduler.step(*_snake_case , **_snake_case ) else: # Otherwise the training dataloader batch size was multiplied by `num_processes`, so we need to do # num_processes steps per training step snake_case_ = AcceleratorState().num_processes for _ in range(_snake_case ): # Special case when using OneCycle and `drop_last` was not used if hasattr(self.scheduler , 'total_steps' ): if self.scheduler._step_count <= self.scheduler.total_steps: self.scheduler.step(*_snake_case , **_snake_case ) else: self.scheduler.step(*_snake_case , **_snake_case ) def _UpperCamelCase ( self ) -> List[str]: return self.scheduler.get_last_lr() def _UpperCamelCase ( self ) -> int: return self.scheduler.state_dict() def _UpperCamelCase ( self , a ) -> Optional[int]: self.scheduler.load_state_dict(_snake_case ) def _UpperCamelCase ( self ) -> Union[str, Any]: return self.scheduler.get_lr() def _UpperCamelCase ( self , *a , **a ) -> Optional[Any]: return self.scheduler.print_lr(*_snake_case , **_snake_case )
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import argparse import torch from transformers import LxmertConfig, LxmertForPreTraining, load_tf_weights_in_lxmert from transformers.utils import logging logging.set_verbosity_info() def lowercase_ (A : str , A : List[Any] , A : Any ): # Initialise PyTorch model snake_case__ : List[Any] = LxmertConfig.from_json_file(A ) print(F'''Building PyTorch model from configuration: {config}''' ) snake_case__ : List[str] = LxmertForPreTraining(A ) # Load weights from tf checkpoint load_tf_weights_in_lxmert(A , A , A ) # Save pytorch-model print(F'''Save PyTorch model to {pytorch_dump_path}''' ) torch.save(model.state_dict() , A ) if __name__ == "__main__": a_ :Union[str, Any] = argparse.ArgumentParser() # Required parameters parser.add_argument( "--tf_checkpoint_path", default=None, type=str, required=True, help="Path to the TensorFlow checkpoint path." ) parser.add_argument( "--config_file", default=None, type=str, required=True, help="The config json file corresponding to the pre-trained model. \nThis specifies the model architecture.", ) parser.add_argument( "--pytorch_dump_path", default=None, type=str, required=True, help="Path to the output PyTorch model." ) a_ :Optional[int] = parser.parse_args() convert_tf_checkpoint_to_pytorch(args.tf_checkpoint_path, args.config_file, args.pytorch_dump_path)
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"""simple docstring""" __UpperCamelCase = 8.3_144_598 def lowercase (SCREAMING_SNAKE_CASE_ : float , SCREAMING_SNAKE_CASE_ : float ) -> List[str]: if temperature < 0: raise Exception('Temperature cannot be less than 0 K' ) if molar_mass <= 0: raise Exception('Molar mass cannot be less than or equal to 0 kg/mol' ) else: return (3 * UNIVERSAL_GAS_CONSTANT * temperature / molar_mass) ** 0.5 if __name__ == "__main__": import doctest # run doctest doctest.testmod() # example __UpperCamelCase = 300 __UpperCamelCase = 28 __UpperCamelCase = rms_speed_of_molecule(temperature, molar_mass) print(f'''Vrms of Nitrogen gas at 300 K is {vrms} m/s''')
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import argparse import fairseq import torch from torch import nn from transformers import ( MBartaaTokenizer, MBartConfig, MBartForCausalLM, SpeechEncoderDecoderConfig, SpeechEncoderDecoderModel, WavaVecaConfig, WavaVecaFeatureExtractor, WavaVecaModel, logging, ) logging.set_verbosity_info() a_ :Tuple = logging.get_logger(__name__) a_ :List[Any] = { "post_extract_proj": "feature_projection.projection", "encoder.pos_conv.0": "encoder.pos_conv_embed.conv", "self_attn.k_proj": "encoder.layers.*.attention.k_proj", "self_attn.v_proj": "encoder.layers.*.attention.v_proj", "self_attn.q_proj": "encoder.layers.*.attention.q_proj", "self_attn.out_proj": "encoder.layers.*.attention.out_proj", "self_attn_layer_norm": "encoder.layers.*.layer_norm", "fc1": "encoder.layers.*.feed_forward.intermediate_dense", "fc2": "encoder.layers.*.feed_forward.output_dense", "final_layer_norm": "encoder.layers.*.final_layer_norm", "encoder.layer_norm": "encoder.layer_norm", "w2v_model.layer_norm": "feature_projection.layer_norm", "quantizer.weight_proj": "quantizer.weight_proj", "quantizer.vars": "quantizer.codevectors", "project_q": "project_q", "final_proj": "project_hid", "w2v_encoder.proj": "lm_head", "mask_emb": "masked_spec_embed", } a_ :Optional[int] = [ "lm_head", "quantizer.weight_proj", "quantizer.codevectors", "project_q", "project_hid", ] def lowercase_ (A : Union[str, Any] , A : str , A : Dict , A : Optional[Any] , A : Optional[Any] ): for attribute in key.split('.' ): snake_case__ : Any = getattr(A , A ) if weight_type is not None: snake_case__ : Optional[Any] = getattr(A , A ).shape else: snake_case__ : Optional[int] = hf_pointer.shape assert hf_shape == value.shape, ( F'''Shape of hf {key + "." + weight_type if weight_type is not None else ""} is {hf_shape}, but should be''' F''' {value.shape} for {full_name}''' ) if weight_type == "weight": snake_case__ : Tuple = value elif weight_type == "weight_g": snake_case__ : Tuple = value elif weight_type == "weight_v": snake_case__ : List[Any] = value elif weight_type == "bias": snake_case__ : List[Any] = value else: snake_case__ : Optional[Any] = value logger.info(F'''{key + "." + weight_type if weight_type is not None else ""} was initialized from {full_name}.''' ) def lowercase_ (A : str , A : Any ): snake_case__ : Union[str, Any] = [] snake_case__ : Union[str, Any] = fairseq_model.state_dict() snake_case__ : Union[str, Any] = hf_model.feature_extractor snake_case__ : Any = hf_model.adapter for name, value in fairseq_dict.items(): snake_case__ : Any = False if "conv_layers" in name: load_conv_layer( A , A , A , A , hf_model.config.feat_extract_norm == 'group' , ) snake_case__ : List[Any] = True elif any(x in name for x in ['adaptor', 'w2v_encoder.proj.', 'w2v_proj_ln.'] ): load_adapter(A , A , A , A ) snake_case__ : Optional[Any] = True else: for key, mapped_key in MAPPING.items(): if key in name or key.split('w2v_model.' )[-1] == name.split('.' )[0]: snake_case__ : Tuple = True if "*" in mapped_key: snake_case__ : List[Any] = name.split(A )[0].split('.' )[-2] snake_case__ : Optional[int] = mapped_key.replace('*' , A ) if "weight_g" in name: snake_case__ : Optional[int] = 'weight_g' elif "weight_v" in name: snake_case__ : Optional[Any] = 'weight_v' elif "bias" in name: snake_case__ : Union[str, Any] = 'bias' elif "weight" in name: snake_case__ : Optional[int] = 'weight' else: snake_case__ : Tuple = None set_recursively(A , A , A , A , A ) continue if not is_used: unused_weights.append(A ) logger.warning(F'''Unused weights: {unused_weights}''' ) def lowercase_ (A : Union[str, Any] , A : Any , A : str , A : str , A : int ): snake_case__ : str = full_name.split('conv_layers.' )[-1] snake_case__ : Optional[int] = name.split('.' ) snake_case__ : Tuple = int(items[0] ) snake_case__ : Any = int(items[1] ) if type_id == 0: if "bias" in name: assert value.shape == feature_extractor.conv_layers[layer_id].conv.bias.data.shape, ( F'''{full_name} has size {value.shape}, but''' F''' {feature_extractor.conv_layers[layer_id].conv.bias.data.shape} was found.''' ) snake_case__ : Union[str, Any] = value logger.info(F'''Feat extract conv layer {layer_id} was initialized from {full_name}.''' ) elif "weight" in name: assert value.shape == feature_extractor.conv_layers[layer_id].conv.weight.data.shape, ( F'''{full_name} has size {value.shape}, but''' F''' {feature_extractor.conv_layers[layer_id].conv.weight.data.shape} was found.''' ) snake_case__ : Union[str, Any] = value logger.info(F'''Feat extract conv layer {layer_id} was initialized from {full_name}.''' ) elif (type_id == 2 and not use_group_norm) or (type_id == 2 and layer_id == 0 and use_group_norm): if "bias" in name: assert value.shape == feature_extractor.conv_layers[layer_id].layer_norm.bias.data.shape, ( F'''{full_name} has size {value.shape}, but {feature_extractor[layer_id].layer_norm.bias.data.shape} was''' " found." ) snake_case__ : Optional[int] = value logger.info(F'''Feat extract layer norm weight of layer {layer_id} was initialized from {full_name}.''' ) elif "weight" in name: assert value.shape == feature_extractor.conv_layers[layer_id].layer_norm.weight.data.shape, ( F'''{full_name} has size {value.shape}, but''' F''' {feature_extractor[layer_id].layer_norm.weight.data.shape} was found.''' ) snake_case__ : Optional[Any] = value logger.info(F'''Feat extract layer norm weight of layer {layer_id} was initialized from {full_name}.''' ) else: unused_weights.append(A ) def lowercase_ (A : Optional[Any] , A : Any , A : Tuple , A : Any ): snake_case__ : List[str] = full_name.split('adaptor.' )[-1] snake_case__ : Tuple = name.split('.' ) if items[1].isdigit(): snake_case__ : Optional[int] = int(items[1] ) else: snake_case__ : Any = None if "adaptor" not in full_name: if "proj_ln" in full_name: # has to be layer norm if "bias" in name: assert ( value.shape == adapter.proj_layer_norm.bias.data.shape ), F'''{full_name} has size {value.shape}, but {adapter.proj_layer_norm.bias.data.shape} was found.''' snake_case__ : List[Any] = value logger.info(F'''Adapter proj layer norm bias was initialized from {full_name}.''' ) if "weight" in name: assert ( value.shape == adapter.proj_layer_norm.weight.data.shape ), F'''{full_name} has size {value.shape}, but {adapter.proj_layer_norm.weight.data.shape} was found.''' snake_case__ : int = value else: # has to be projection layer if "bias" in name: assert ( value.shape == adapter.proj.bias.data.shape ), F'''{full_name} has size {value.shape}, but {adapter.proj.bias.data.shape} was found.''' snake_case__ : str = value logger.info(F'''Adapter proj layer bias was initialized from {full_name}.''' ) if "weight" in name: assert ( value.shape == adapter.proj.weight.data.shape ), F'''{full_name} has size {value.shape}, but {adapter.proj.weight.data.shape} was found.''' snake_case__ : Dict = value logger.info(F'''Adapter proj layer weight was initialized from {full_name}.''' ) elif isinstance(A , A ): if "bias" in name: assert ( value.shape == adapter.layers[layer_id].conv.bias.data.shape ), F'''{full_name} has size {value.shape}, but {adapter.layers[layer_id].conv.bias.data.shape} was found.''' snake_case__ : List[str] = value logger.info(F'''Adapter layer {layer_id} bias was initialized from {full_name}.''' ) elif "weight" in name: assert ( value.shape == adapter.layers[layer_id].conv.weight.data.shape ), F'''{full_name} has size {value.shape}, but {adapter.layers[layer_id].conv.weight.data.shape} was found.''' snake_case__ : List[str] = value logger.info(F'''Adapter layer {layer_id} bias was initialized from {full_name}.''' ) else: unused_weights.append(A ) def lowercase_ (A : int ): snake_case__ , snake_case__ : Union[str, Any] = emb.weight.shape snake_case__ : int = nn.Linear(A , A , bias=A ) snake_case__ : Optional[Any] = emb.weight.data return lin_layer @torch.no_grad() def lowercase_ (A : Tuple , A : Tuple , A : Any , A : Optional[Any] , A : int , A : Optional[Any] , A : Union[str, Any] , A : Union[str, Any] , A : Optional[Any] , A : List[Any] , A : Union[str, Any] , ): snake_case__ : Optional[Any] = WavaVecaConfig.from_pretrained( A , add_adapter=A , adapter_stride=A , adapter_kernel_size=A , use_auth_token=A , output_hidden_size=A , ) snake_case__ : Dict = MBartConfig.from_pretrained(A ) # load model snake_case__ , snake_case__ , snake_case__ : Any = fairseq.checkpoint_utils.load_model_ensemble_and_task( [checkpoint_path] , arg_overrides={ 'config_yaml': config_yaml_path, 'data': '/'.join(dict_path.split('/' )[:-1] ), 'w2v_path': checkpoint_path, 'load_pretrained_decoder_from': None, } , ) snake_case__ : List[Any] = model[0].eval() # load feature extractor snake_case__ : str = WavaVecaFeatureExtractor.from_pretrained(A , use_auth_token=A ) # set weights for wav2vec2 encoder snake_case__ : List[str] = WavaVecaModel(A ) recursively_load_weights_wavaveca(model.encoder , A ) # load decoder weights snake_case__ : Any = MBartForCausalLM(A ) snake_case__ , snake_case__ : int = hf_decoder.model.decoder.load_state_dict(model.decoder.state_dict() , strict=A ) logger.warning(F'''The following keys are missing when loading the decoder weights: {missing_keys}''' ) logger.warning(F'''The following keys are unexpected when loading the decoder weights: {unexpected_keys}''' ) snake_case__ : Union[str, Any] = SpeechEncoderDecoderModel(encoder=A , decoder=A ) snake_case__ : str = False snake_case__ : int = MBartaaTokenizer(A ) tokenizer.save_pretrained(A ) snake_case__ : Any = hf_wavavec.config.to_dict() snake_case__ : Tuple = tokenizer.pad_token_id snake_case__ : Union[str, Any] = tokenizer.bos_token_id snake_case__ : Dict = tokenizer.eos_token_id snake_case__ : Optional[int] = 'mbart50' snake_case__ : Union[str, Any] = 'wav2vec2' snake_case__ : List[str] = tokenizer.eos_token_id snake_case__ : Union[str, Any] = 2_5_0_0_0_4 snake_case__ : int = tokenizer.eos_token_id snake_case__ : Union[str, Any] = SpeechEncoderDecoderConfig.from_dict(A ) hf_wavavec.save_pretrained(A ) feature_extractor.save_pretrained(A ) if __name__ == "__main__": a_ :str = argparse.ArgumentParser() parser.add_argument("--pytorch_dump_folder_path", default=None, type=str, help="Path to the output PyTorch model.") parser.add_argument("--checkpoint_path", default=None, type=str, help="Path to fairseq checkpoint") parser.add_argument("--dict_path", default=None, type=str, help="Path to dict of fine-tuned model") parser.add_argument("--config_yaml_path", default=None, type=str, help="Path to yaml file of fine-tuned model") parser.add_argument( "--encoder_config_path", default="facebook/wav2vec2-xls-r-1b", type=str, help="Path to hf encoder wav2vec2 checkpoint config", ) parser.add_argument( "--decoder_config_path", default="facebook/mbart-large-50-one-to-many-mmt", type=str, help="Path to hf decoder checkpoint config", ) parser.add_argument("--add_adapter", default=True, type=bool, help="whethere to add model adapter layers") parser.add_argument("--adapter_stride", default=2, type=int, help="stride of adapter layers") parser.add_argument("--adapter_kernel_size", default=3, type=int, help="kernel size of adapter layers") parser.add_argument("--encoder_output_dim", default=1_024, type=int, help="encoder output dim") parser.add_argument("--start_token_id", default=250_004, type=int, help="`decoder_start_token_id` of model config") a_ :Union[str, Any] = parser.parse_args() convert_wavaveca_checkpoint( args.checkpoint_path, args.pytorch_dump_folder_path, args.dict_path, args.config_yaml_path, encoder_config_path=args.encoder_config_path, decoder_config_path=args.decoder_config_path, add_adapter=args.add_adapter, adapter_kernel_size=args.adapter_kernel_size, adapter_stride=args.adapter_stride, decoder_start_token_id=args.start_token_id, encoder_output_dim=args.encoder_output_dim, )
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'''simple docstring''' from typing import TYPE_CHECKING from ...utils import OptionalDependencyNotAvailable, _LazyModule, is_tokenizers_available, is_torch_available _A : Union[str, Any] = { "configuration_squeezebert": [ "SQUEEZEBERT_PRETRAINED_CONFIG_ARCHIVE_MAP", "SqueezeBertConfig", "SqueezeBertOnnxConfig", ], "tokenization_squeezebert": ["SqueezeBertTokenizer"], } try: if not is_tokenizers_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: _A : Union[str, Any] = ["SqueezeBertTokenizerFast"] try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: _A : List[str] = [ "SQUEEZEBERT_PRETRAINED_MODEL_ARCHIVE_LIST", "SqueezeBertForMaskedLM", "SqueezeBertForMultipleChoice", "SqueezeBertForQuestionAnswering", "SqueezeBertForSequenceClassification", "SqueezeBertForTokenClassification", "SqueezeBertModel", "SqueezeBertModule", "SqueezeBertPreTrainedModel", ] if TYPE_CHECKING: from .configuration_squeezebert import ( SQUEEZEBERT_PRETRAINED_CONFIG_ARCHIVE_MAP, SqueezeBertConfig, SqueezeBertOnnxConfig, ) from .tokenization_squeezebert import SqueezeBertTokenizer try: if not is_tokenizers_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .tokenization_squeezebert_fast import SqueezeBertTokenizerFast try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_squeezebert import ( SQUEEZEBERT_PRETRAINED_MODEL_ARCHIVE_LIST, SqueezeBertForMaskedLM, SqueezeBertForMultipleChoice, SqueezeBertForQuestionAnswering, SqueezeBertForSequenceClassification, SqueezeBertForTokenClassification, SqueezeBertModel, SqueezeBertModule, SqueezeBertPreTrainedModel, ) else: import sys _A : Dict = _LazyModule(__name__, globals()['''__file__'''], _import_structure, module_spec=__spec__)
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from collections import OrderedDict from typing import TYPE_CHECKING, Any, Mapping, Optional, Union from ...configuration_utils import PretrainedConfig from ...onnx import OnnxConfig from ...utils import logging if TYPE_CHECKING: from ... import FeatureExtractionMixin, PreTrainedTokenizerBase, TensorType a_ :Tuple = logging.get_logger(__name__) a_ :Union[str, Any] = { "microsoft/deberta-v2-xlarge": "https://huggingface.co/microsoft/deberta-v2-xlarge/resolve/main/config.json", "microsoft/deberta-v2-xxlarge": "https://huggingface.co/microsoft/deberta-v2-xxlarge/resolve/main/config.json", "microsoft/deberta-v2-xlarge-mnli": ( "https://huggingface.co/microsoft/deberta-v2-xlarge-mnli/resolve/main/config.json" ), "microsoft/deberta-v2-xxlarge-mnli": ( "https://huggingface.co/microsoft/deberta-v2-xxlarge-mnli/resolve/main/config.json" ), } class snake_case__ ( lowerCAmelCase_ ): """simple docstring""" _SCREAMING_SNAKE_CASE = """deberta-v2""" def __init__( self : Union[str, Any], _snake_case : Dict=1_2_8_1_0_0, _snake_case : Any=1_5_3_6, _snake_case : Tuple=2_4, _snake_case : int=2_4, _snake_case : Optional[int]=6_1_4_4, _snake_case : Optional[int]="gelu", _snake_case : Optional[int]=0.1, _snake_case : List[str]=0.1, _snake_case : str=5_1_2, _snake_case : Optional[int]=0, _snake_case : Optional[int]=0.0_2, _snake_case : Dict=1e-7, _snake_case : int=False, _snake_case : Any=-1, _snake_case : List[str]=0, _snake_case : Tuple=True, _snake_case : Any=None, _snake_case : Union[str, Any]=0, _snake_case : Tuple="gelu", **_snake_case : Union[str, Any], ) ->Optional[int]: super().__init__(**_snake_case ) snake_case__ : Dict = hidden_size snake_case__ : Optional[int] = num_hidden_layers snake_case__ : Any = num_attention_heads snake_case__ : List[Any] = intermediate_size snake_case__ : List[Any] = hidden_act snake_case__ : Union[str, Any] = hidden_dropout_prob snake_case__ : Dict = attention_probs_dropout_prob snake_case__ : List[str] = max_position_embeddings snake_case__ : List[str] = type_vocab_size snake_case__ : Optional[Any] = initializer_range snake_case__ : Optional[int] = relative_attention snake_case__ : Tuple = max_relative_positions snake_case__ : Union[str, Any] = pad_token_id snake_case__ : Optional[int] = position_biased_input # Backwards compatibility if type(_snake_case ) == str: snake_case__ : int = [x.strip() for x in pos_att_type.lower().split('|' )] snake_case__ : List[str] = pos_att_type snake_case__ : Union[str, Any] = vocab_size snake_case__ : Optional[int] = layer_norm_eps snake_case__ : Optional[int] = kwargs.get('pooler_hidden_size', _snake_case ) snake_case__ : int = pooler_dropout snake_case__ : str = pooler_hidden_act class snake_case__ ( lowerCAmelCase_ ): """simple docstring""" @property def lowercase_ ( self : Optional[int] ) ->Mapping[str, Mapping[int, str]]: if self.task == "multiple-choice": snake_case__ : List[Any] = {0: 'batch', 1: 'choice', 2: 'sequence'} else: snake_case__ : int = {0: 'batch', 1: 'sequence'} if self._config.type_vocab_size > 0: return OrderedDict( [('input_ids', dynamic_axis), ('attention_mask', dynamic_axis), ('token_type_ids', dynamic_axis)] ) else: return OrderedDict([('input_ids', dynamic_axis), ('attention_mask', dynamic_axis)] ) @property def lowercase_ ( self : Dict ) ->int: return 1_2 def lowercase_ ( self : Tuple, _snake_case : Union["PreTrainedTokenizerBase", "FeatureExtractionMixin"], _snake_case : int = -1, _snake_case : int = -1, _snake_case : int = -1, _snake_case : bool = False, _snake_case : Optional["TensorType"] = None, _snake_case : int = 3, _snake_case : int = 4_0, _snake_case : int = 4_0, _snake_case : "PreTrainedTokenizerBase" = None, ) ->Mapping[str, Any]: snake_case__ : Union[str, Any] = super().generate_dummy_inputs(preprocessor=_snake_case, framework=_snake_case ) if self._config.type_vocab_size == 0 and "token_type_ids" in dummy_inputs: del dummy_inputs["token_type_ids"] return dummy_inputs
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0
"""simple docstring""" from typing import Dict import numpy as np import torch from . import residue_constants as rc from .tensor_utils import tensor_tree_map, tree_map def lowercase ( a__ : Dict[str, torch.Tensor] ) -> List[Any]: _UpperCamelCase = [] _UpperCamelCase = [] _UpperCamelCase = [] for rt in rc.restypes: _UpperCamelCase = rc.restype_name_to_atomaa_names[rc.restype_atoa[rt]] restype_atomaa_to_atomaa_list.append([(rc.atom_order[name] if name else 0) for name in atom_names] ) _UpperCamelCase = {name: i for i, name in enumerate(a__ )} restype_atomaa_to_atomaa_list.append( [(atom_name_to_idxaa[name] if name in atom_name_to_idxaa else 0) for name in rc.atom_types] ) restype_atomaa_mask_list.append([(1.0 if name else 0.0) for name in atom_names] ) # Add dummy mapping for restype 'UNK' restype_atomaa_to_atomaa_list.append([0] * 14 ) restype_atomaa_to_atomaa_list.append([0] * 37 ) restype_atomaa_mask_list.append([0.0] * 14 ) _UpperCamelCase = torch.tensor( a__ , dtype=torch.intaa , device=protein['''aatype'''].device , ) _UpperCamelCase = torch.tensor( a__ , dtype=torch.intaa , device=protein['''aatype'''].device , ) _UpperCamelCase = torch.tensor( a__ , dtype=torch.floataa , device=protein['''aatype'''].device , ) _UpperCamelCase = protein['aatype'].to(torch.long ) # create the mapping for (residx, atom14) --> atom37, i.e. an array # with shape (num_res, 14) containing the atom37 indices for this protein _UpperCamelCase = restype_atomaa_to_atomaa[protein_aatype] _UpperCamelCase = restype_atomaa_mask[protein_aatype] _UpperCamelCase = residx_atomaa_mask _UpperCamelCase = residx_atomaa_to_atomaa.long() # create the gather indices for mapping back _UpperCamelCase = restype_atomaa_to_atomaa[protein_aatype] _UpperCamelCase = residx_atomaa_to_atomaa.long() # create the corresponding mask _UpperCamelCase = torch.zeros([21, 37] , dtype=torch.floataa , device=protein['''aatype'''].device ) for restype, restype_letter in enumerate(rc.restypes ): _UpperCamelCase = rc.restype_atoa[restype_letter] _UpperCamelCase = rc.residue_atoms[restype_name] for atom_name in atom_names: _UpperCamelCase = rc.atom_order[atom_name] _UpperCamelCase = 1 _UpperCamelCase = restype_atomaa_mask[protein_aatype] _UpperCamelCase = residx_atomaa_mask return protein def lowercase ( a__ : Dict[str, torch.Tensor] ) -> Any: _UpperCamelCase = tree_map(lambda a__ : torch.tensor(a__ , device=batch['''aatype'''].device ) , a__ , np.ndarray ) _UpperCamelCase = tensor_tree_map(lambda a__ : np.array(a__ ) , make_atomaa_masks(a__ ) ) return out
256
import argparse import json import pickle from pathlib import Path import requests import torch from huggingface_hub import hf_hub_download from PIL import Image from transformers import MaskFormerConfig, MaskFormerForInstanceSegmentation, MaskFormerImageProcessor, SwinConfig from transformers.utils import logging logging.set_verbosity_info() a_ :str = logging.get_logger(__name__) def lowercase_ (A : str ): snake_case__ : Tuple = SwinConfig.from_pretrained( 'microsoft/swin-tiny-patch4-window7-224' , out_features=['stage1', 'stage2', 'stage3', 'stage4'] ) snake_case__ : List[Any] = MaskFormerConfig(backbone_config=A ) snake_case__ : Union[str, Any] = 'huggingface/label-files' if "ade20k-full" in model_name: # this should be ok snake_case__ : Dict = 8_4_7 snake_case__ : List[str] = 'maskformer-ade20k-full-id2label.json' elif "ade" in model_name: # this should be ok snake_case__ : Union[str, Any] = 1_5_0 snake_case__ : Any = 'ade20k-id2label.json' elif "coco-stuff" in model_name: # this should be ok snake_case__ : List[str] = 1_7_1 snake_case__ : Union[str, Any] = 'maskformer-coco-stuff-id2label.json' elif "coco" in model_name: # TODO snake_case__ : Dict = 1_3_3 snake_case__ : str = 'coco-panoptic-id2label.json' elif "cityscapes" in model_name: # this should be ok snake_case__ : List[str] = 1_9 snake_case__ : Union[str, Any] = 'cityscapes-id2label.json' elif "vistas" in model_name: # this should be ok snake_case__ : Tuple = 6_5 snake_case__ : List[str] = 'mapillary-vistas-id2label.json' snake_case__ : Dict = json.load(open(hf_hub_download(A , A , repo_type='dataset' ) , 'r' ) ) snake_case__ : List[str] = {int(A ): v for k, v in idalabel.items()} return config def lowercase_ (A : Any ): snake_case__ : Optional[int] = [] # stem # fmt: off rename_keys.append(('backbone.patch_embed.proj.weight', 'model.pixel_level_module.encoder.model.embeddings.patch_embeddings.projection.weight') ) rename_keys.append(('backbone.patch_embed.proj.bias', 'model.pixel_level_module.encoder.model.embeddings.patch_embeddings.projection.bias') ) rename_keys.append(('backbone.patch_embed.norm.weight', 'model.pixel_level_module.encoder.model.embeddings.norm.weight') ) rename_keys.append(('backbone.patch_embed.norm.bias', 'model.pixel_level_module.encoder.model.embeddings.norm.bias') ) # stages for i in range(len(config.backbone_config.depths ) ): for j in range(config.backbone_config.depths[i] ): rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.norm1.weight''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.layernorm_before.weight''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.norm1.bias''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.layernorm_before.bias''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.attn.relative_position_bias_table''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.attention.self.relative_position_bias_table''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.attn.relative_position_index''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.attention.self.relative_position_index''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.attn.proj.weight''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.attention.output.dense.weight''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.attn.proj.bias''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.attention.output.dense.bias''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.norm2.weight''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.layernorm_after.weight''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.norm2.bias''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.layernorm_after.bias''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.mlp.fc1.weight''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.intermediate.dense.weight''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.mlp.fc1.bias''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.intermediate.dense.bias''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.mlp.fc2.weight''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.output.dense.weight''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.mlp.fc2.bias''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.output.dense.bias''') ) if i < 3: rename_keys.append((F'''backbone.layers.{i}.downsample.reduction.weight''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.downsample.reduction.weight''') ) rename_keys.append((F'''backbone.layers.{i}.downsample.norm.weight''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.downsample.norm.weight''') ) rename_keys.append((F'''backbone.layers.{i}.downsample.norm.bias''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.downsample.norm.bias''') ) rename_keys.append((F'''backbone.norm{i}.weight''', F'''model.pixel_level_module.encoder.hidden_states_norms.{i}.weight''') ) rename_keys.append((F'''backbone.norm{i}.bias''', F'''model.pixel_level_module.encoder.hidden_states_norms.{i}.bias''') ) # FPN rename_keys.append(('sem_seg_head.layer_4.weight', 'model.pixel_level_module.decoder.fpn.stem.0.weight') ) rename_keys.append(('sem_seg_head.layer_4.norm.weight', 'model.pixel_level_module.decoder.fpn.stem.1.weight') ) rename_keys.append(('sem_seg_head.layer_4.norm.bias', 'model.pixel_level_module.decoder.fpn.stem.1.bias') ) for source_index, target_index in zip(range(3 , 0 , -1 ) , range(0 , 3 ) ): rename_keys.append((F'''sem_seg_head.adapter_{source_index}.weight''', F'''model.pixel_level_module.decoder.fpn.layers.{target_index}.proj.0.weight''') ) rename_keys.append((F'''sem_seg_head.adapter_{source_index}.norm.weight''', F'''model.pixel_level_module.decoder.fpn.layers.{target_index}.proj.1.weight''') ) rename_keys.append((F'''sem_seg_head.adapter_{source_index}.norm.bias''', F'''model.pixel_level_module.decoder.fpn.layers.{target_index}.proj.1.bias''') ) rename_keys.append((F'''sem_seg_head.layer_{source_index}.weight''', F'''model.pixel_level_module.decoder.fpn.layers.{target_index}.block.0.weight''') ) rename_keys.append((F'''sem_seg_head.layer_{source_index}.norm.weight''', F'''model.pixel_level_module.decoder.fpn.layers.{target_index}.block.1.weight''') ) rename_keys.append((F'''sem_seg_head.layer_{source_index}.norm.bias''', F'''model.pixel_level_module.decoder.fpn.layers.{target_index}.block.1.bias''') ) rename_keys.append(('sem_seg_head.mask_features.weight', 'model.pixel_level_module.decoder.mask_projection.weight') ) rename_keys.append(('sem_seg_head.mask_features.bias', 'model.pixel_level_module.decoder.mask_projection.bias') ) # Transformer decoder for idx in range(config.decoder_config.decoder_layers ): # self-attention out projection rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.self_attn.out_proj.weight''', F'''model.transformer_module.decoder.layers.{idx}.self_attn.out_proj.weight''') ) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.self_attn.out_proj.bias''', F'''model.transformer_module.decoder.layers.{idx}.self_attn.out_proj.bias''') ) # cross-attention out projection rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.multihead_attn.out_proj.weight''', F'''model.transformer_module.decoder.layers.{idx}.encoder_attn.out_proj.weight''') ) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.multihead_attn.out_proj.bias''', F'''model.transformer_module.decoder.layers.{idx}.encoder_attn.out_proj.bias''') ) # MLP 1 rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.linear1.weight''', F'''model.transformer_module.decoder.layers.{idx}.fc1.weight''') ) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.linear1.bias''', F'''model.transformer_module.decoder.layers.{idx}.fc1.bias''') ) # MLP 2 rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.linear2.weight''', F'''model.transformer_module.decoder.layers.{idx}.fc2.weight''') ) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.linear2.bias''', F'''model.transformer_module.decoder.layers.{idx}.fc2.bias''') ) # layernorm 1 (self-attention layernorm) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.norm1.weight''', F'''model.transformer_module.decoder.layers.{idx}.self_attn_layer_norm.weight''') ) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.norm1.bias''', F'''model.transformer_module.decoder.layers.{idx}.self_attn_layer_norm.bias''') ) # layernorm 2 (cross-attention layernorm) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.norm2.weight''', F'''model.transformer_module.decoder.layers.{idx}.encoder_attn_layer_norm.weight''') ) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.norm2.bias''', F'''model.transformer_module.decoder.layers.{idx}.encoder_attn_layer_norm.bias''') ) # layernorm 3 (final layernorm) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.norm3.weight''', F'''model.transformer_module.decoder.layers.{idx}.final_layer_norm.weight''') ) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.norm3.bias''', F'''model.transformer_module.decoder.layers.{idx}.final_layer_norm.bias''') ) rename_keys.append(('sem_seg_head.predictor.transformer.decoder.norm.weight', 'model.transformer_module.decoder.layernorm.weight') ) rename_keys.append(('sem_seg_head.predictor.transformer.decoder.norm.bias', 'model.transformer_module.decoder.layernorm.bias') ) # heads on top rename_keys.append(('sem_seg_head.predictor.query_embed.weight', 'model.transformer_module.queries_embedder.weight') ) rename_keys.append(('sem_seg_head.predictor.input_proj.weight', 'model.transformer_module.input_projection.weight') ) rename_keys.append(('sem_seg_head.predictor.input_proj.bias', 'model.transformer_module.input_projection.bias') ) rename_keys.append(('sem_seg_head.predictor.class_embed.weight', 'class_predictor.weight') ) rename_keys.append(('sem_seg_head.predictor.class_embed.bias', 'class_predictor.bias') ) for i in range(3 ): rename_keys.append((F'''sem_seg_head.predictor.mask_embed.layers.{i}.weight''', F'''mask_embedder.{i}.0.weight''') ) rename_keys.append((F'''sem_seg_head.predictor.mask_embed.layers.{i}.bias''', F'''mask_embedder.{i}.0.bias''') ) # fmt: on return rename_keys def lowercase_ (A : Tuple , A : Tuple , A : Optional[Any] ): snake_case__ : Optional[int] = dct.pop(A ) snake_case__ : Union[str, Any] = val def lowercase_ (A : Optional[Any] , A : Tuple ): snake_case__ : Optional[int] = [int(backbone_config.embed_dim * 2**i ) for i in range(len(backbone_config.depths ) )] for i in range(len(backbone_config.depths ) ): snake_case__ : Optional[int] = num_features[i] for j in range(backbone_config.depths[i] ): # fmt: off # read in weights + bias of input projection layer (in original implementation, this is a single matrix + bias) snake_case__ : int = state_dict.pop(F'''backbone.layers.{i}.blocks.{j}.attn.qkv.weight''' ) snake_case__ : Tuple = state_dict.pop(F'''backbone.layers.{i}.blocks.{j}.attn.qkv.bias''' ) # next, add query, keys and values (in that order) to the state dict snake_case__ : str = in_proj_weight[:dim, :] snake_case__ : int = in_proj_bias[: dim] snake_case__ : List[Any] = in_proj_weight[ dim : dim * 2, : ] snake_case__ : List[str] = in_proj_bias[ dim : dim * 2 ] snake_case__ : List[Any] = in_proj_weight[ -dim :, : ] snake_case__ : Dict = in_proj_bias[-dim :] # fmt: on def lowercase_ (A : List[str] , A : List[Any] ): # fmt: off snake_case__ : str = config.decoder_config.hidden_size for idx in range(config.decoder_config.decoder_layers ): # read in weights + bias of self-attention input projection layer (in the original implementation, this is a single matrix + bias) snake_case__ : List[Any] = state_dict.pop(F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.self_attn.in_proj_weight''' ) snake_case__ : int = state_dict.pop(F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.self_attn.in_proj_bias''' ) # next, add query, keys and values (in that order) to the state dict snake_case__ : Any = in_proj_weight[: hidden_size, :] snake_case__ : Tuple = in_proj_bias[:config.hidden_size] snake_case__ : List[str] = in_proj_weight[hidden_size : hidden_size * 2, :] snake_case__ : Dict = in_proj_bias[hidden_size : hidden_size * 2] snake_case__ : Any = in_proj_weight[-hidden_size :, :] snake_case__ : int = in_proj_bias[-hidden_size :] # read in weights + bias of cross-attention input projection layer (in the original implementation, this is a single matrix + bias) snake_case__ : List[Any] = state_dict.pop(F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.multihead_attn.in_proj_weight''' ) snake_case__ : List[str] = state_dict.pop(F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.multihead_attn.in_proj_bias''' ) # next, add query, keys and values (in that order) to the state dict snake_case__ : Optional[int] = in_proj_weight[: hidden_size, :] snake_case__ : Optional[Any] = in_proj_bias[:config.hidden_size] snake_case__ : int = in_proj_weight[hidden_size : hidden_size * 2, :] snake_case__ : List[str] = in_proj_bias[hidden_size : hidden_size * 2] snake_case__ : List[str] = in_proj_weight[-hidden_size :, :] snake_case__ : str = in_proj_bias[-hidden_size :] # fmt: on def lowercase_ (): snake_case__ : Any = 'http://images.cocodataset.org/val2017/000000039769.jpg' snake_case__ : int = Image.open(requests.get(A , stream=A ).raw ) return im @torch.no_grad() def lowercase_ (A : str , A : str , A : str , A : bool = False ): snake_case__ : Optional[int] = get_maskformer_config(A ) # load original state_dict with open(A , 'rb' ) as f: snake_case__ : List[Any] = pickle.load(A ) snake_case__ : Optional[int] = data['model'] # for name, param in state_dict.items(): # print(name, param.shape) # rename keys snake_case__ : List[str] = create_rename_keys(A ) for src, dest in rename_keys: rename_key(A , A , A ) read_in_swin_q_k_v(A , config.backbone_config ) read_in_decoder_q_k_v(A , A ) # update to torch tensors for key, value in state_dict.items(): snake_case__ : int = torch.from_numpy(A ) # load 🤗 model snake_case__ : str = MaskFormerForInstanceSegmentation(A ) model.eval() for name, param in model.named_parameters(): print(A , param.shape ) snake_case__ , snake_case__ : Union[str, Any] = model.load_state_dict(A , strict=A ) assert missing_keys == [ "model.pixel_level_module.encoder.model.layernorm.weight", "model.pixel_level_module.encoder.model.layernorm.bias", ] assert len(A ) == 0, F'''Unexpected keys: {unexpected_keys}''' # verify results snake_case__ : Optional[Any] = prepare_img() if "vistas" in model_name: snake_case__ : int = 6_5 elif "cityscapes" in model_name: snake_case__ : Dict = 6_5_5_3_5 else: snake_case__ : Tuple = 2_5_5 snake_case__ : Optional[int] = True if 'ade' in model_name else False snake_case__ : Dict = MaskFormerImageProcessor(ignore_index=A , reduce_labels=A ) snake_case__ : Any = image_processor(A , return_tensors='pt' ) snake_case__ : Any = model(**A ) print('Logits:' , outputs.class_queries_logits[0, :3, :3] ) if model_name == "maskformer-swin-tiny-ade": snake_case__ : Tuple = torch.tensor( [[3.6353, -4.4770, -2.6065], [0.5081, -4.2394, -3.5343], [2.1909, -5.0353, -1.9323]] ) assert torch.allclose(outputs.class_queries_logits[0, :3, :3] , A , atol=1e-4 ) print('Looks ok!' ) if pytorch_dump_folder_path is not None: print(F'''Saving model and image processor to {pytorch_dump_folder_path}''' ) Path(A ).mkdir(exist_ok=A ) model.save_pretrained(A ) image_processor.save_pretrained(A ) if push_to_hub: print('Pushing model and image processor to the hub...' ) model.push_to_hub(F'''nielsr/{model_name}''' ) image_processor.push_to_hub(F'''nielsr/{model_name}''' ) if __name__ == "__main__": a_ :Optional[int] = argparse.ArgumentParser() # Required parameters parser.add_argument( "--model_name", default="maskformer-swin-tiny-ade", type=str, help=("Name of the MaskFormer model you'd like to convert",), ) parser.add_argument( "--checkpoint_path", default="/Users/nielsrogge/Documents/MaskFormer_checkpoints/MaskFormer-Swin-tiny-ADE20k/model.pkl", type=str, help="Path to the original state dict (.pth file).", ) parser.add_argument( "--pytorch_dump_folder_path", default=None, type=str, help="Path to the output PyTorch model directory." ) parser.add_argument( "--push_to_hub", action="store_true", help="Whether or not to push the converted model to the 🤗 hub." ) a_ :Dict = parser.parse_args() convert_maskformer_checkpoint( args.model_name, args.checkpoint_path, args.pytorch_dump_folder_path, args.push_to_hub )
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from __future__ import annotations from math import ceil, floor, sqrt def _a ( SCREAMING_SNAKE_CASE : int = 2_00_00_00 ) -> Optional[int]: """simple docstring""" __lowerCAmelCase: list[int] = [0] __lowerCAmelCase: int for idx in range(1 , ceil(sqrt(target * 2 ) * 1.1 ) ): triangle_numbers.append(triangle_numbers[-1] + idx ) # we want this to be as close as possible to target __lowerCAmelCase: int = 0 # the area corresponding to the grid that gives the product closest to target __lowerCAmelCase: int = 0 # an estimate of b, using the quadratic formula __lowerCAmelCase: float # the largest integer less than b_estimate __lowerCAmelCase: int # the largest integer less than b_estimate __lowerCAmelCase: int # the triangle number corresponding to b_floor __lowerCAmelCase: int # the triangle number corresponding to b_ceil __lowerCAmelCase: int for idx_a, triangle_a in enumerate(triangle_numbers[1:] , 1 ): __lowerCAmelCase: Dict = (-1 + sqrt(1 + 8 * target / triangle_a )) / 2 __lowerCAmelCase: Optional[Any] = floor(SCREAMING_SNAKE_CASE ) __lowerCAmelCase: List[Any] = ceil(SCREAMING_SNAKE_CASE ) __lowerCAmelCase: Union[str, Any] = triangle_numbers[b_floor] __lowerCAmelCase: Any = triangle_numbers[b_ceil] if abs(target - triangle_b_first_guess * triangle_a ) < abs( target - best_product ): __lowerCAmelCase: List[str] = triangle_b_first_guess * triangle_a __lowerCAmelCase: Dict = idx_a * b_floor if abs(target - triangle_b_second_guess * triangle_a ) < abs( target - best_product ): __lowerCAmelCase: int = triangle_b_second_guess * triangle_a __lowerCAmelCase: List[Any] = idx_a * b_ceil return area if __name__ == "__main__": print(f"{solution() = }")
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import unittest from transformers import is_torch_available from transformers.testing_utils import require_torch, slow, torch_device from ...generation.test_utils import GenerationTesterMixin from ...test_configuration_common import ConfigTester from ...test_modeling_common import ModelTesterMixin, ids_tensor from ...test_pipeline_mixin import PipelineTesterMixin if is_torch_available(): import torch from transformers import ( OPENAI_GPT_PRETRAINED_MODEL_ARCHIVE_LIST, OpenAIGPTConfig, OpenAIGPTDoubleHeadsModel, OpenAIGPTForSequenceClassification, OpenAIGPTLMHeadModel, OpenAIGPTModel, ) class snake_case__ : """simple docstring""" def __init__( self : List[str], _snake_case : Any, _snake_case : int=1_3, _snake_case : Optional[int]=7, _snake_case : int=True, _snake_case : Optional[Any]=True, _snake_case : Optional[Any]=True, _snake_case : Union[str, Any]=9_9, _snake_case : Optional[Any]=3_2, _snake_case : Tuple=5, _snake_case : str=4, _snake_case : Any=3_7, _snake_case : int="gelu", _snake_case : Optional[Any]=0.1, _snake_case : str=0.1, _snake_case : str=5_1_2, _snake_case : Dict=1_6, _snake_case : str=2, _snake_case : Union[str, Any]=0.0_2, _snake_case : Optional[int]=3, _snake_case : Union[str, Any]=4, _snake_case : Tuple=None, ) ->Optional[Any]: snake_case__ : Optional[int] = parent snake_case__ : List[Any] = batch_size snake_case__ : Tuple = seq_length snake_case__ : str = is_training snake_case__ : Optional[int] = use_token_type_ids snake_case__ : Any = use_labels snake_case__ : Dict = vocab_size snake_case__ : str = hidden_size snake_case__ : Union[str, Any] = num_hidden_layers snake_case__ : List[str] = num_attention_heads snake_case__ : Union[str, Any] = intermediate_size snake_case__ : List[Any] = hidden_act snake_case__ : int = hidden_dropout_prob snake_case__ : str = attention_probs_dropout_prob snake_case__ : Any = max_position_embeddings snake_case__ : Union[str, Any] = type_vocab_size snake_case__ : Optional[Any] = type_sequence_label_size snake_case__ : Optional[int] = initializer_range snake_case__ : Optional[int] = num_labels snake_case__ : str = num_choices snake_case__ : int = scope snake_case__ : List[str] = self.vocab_size - 1 def lowercase_ ( self : Union[str, Any] ) ->Tuple: snake_case__ : List[str] = ids_tensor([self.batch_size, self.seq_length], self.vocab_size ) snake_case__ : List[str] = None if self.use_token_type_ids: snake_case__ : Optional[Any] = ids_tensor([self.batch_size, self.seq_length], self.type_vocab_size ) snake_case__ : Tuple = None snake_case__ : str = None snake_case__ : List[Any] = None if self.use_labels: snake_case__ : Dict = ids_tensor([self.batch_size], self.type_sequence_label_size ) snake_case__ : int = ids_tensor([self.batch_size, self.seq_length], self.num_labels ) snake_case__ : List[str] = ids_tensor([self.batch_size], self.num_choices ) snake_case__ : Union[str, Any] = OpenAIGPTConfig( vocab_size=self.vocab_size, n_embd=self.hidden_size, n_layer=self.num_hidden_layers, n_head=self.num_attention_heads, n_positions=self.max_position_embeddings, pad_token_id=self.pad_token_id, ) snake_case__ : List[str] = ids_tensor([self.num_hidden_layers, self.num_attention_heads], 2 ) return ( config, input_ids, head_mask, token_type_ids, sequence_labels, token_labels, choice_labels, ) def lowercase_ ( self : Any, _snake_case : List[str], _snake_case : Any, _snake_case : List[Any], _snake_case : Tuple, *_snake_case : Optional[Any] ) ->Tuple: snake_case__ : Union[str, Any] = OpenAIGPTModel(config=_snake_case ) model.to(_snake_case ) model.eval() snake_case__ : Optional[Any] = model(_snake_case, token_type_ids=_snake_case, head_mask=_snake_case ) snake_case__ : Union[str, Any] = model(_snake_case, token_type_ids=_snake_case ) snake_case__ : Optional[Any] = model(_snake_case ) self.parent.assertEqual(result.last_hidden_state.shape, (self.batch_size, self.seq_length, self.hidden_size) ) def lowercase_ ( self : Optional[int], _snake_case : Optional[Any], _snake_case : Union[str, Any], _snake_case : Optional[int], _snake_case : List[Any], *_snake_case : Dict ) ->Optional[int]: snake_case__ : Optional[Any] = OpenAIGPTLMHeadModel(_snake_case ) model.to(_snake_case ) model.eval() snake_case__ : Tuple = model(_snake_case, token_type_ids=_snake_case, labels=_snake_case ) self.parent.assertEqual(result.loss.shape, () ) self.parent.assertEqual(result.logits.shape, (self.batch_size, self.seq_length, self.vocab_size) ) def lowercase_ ( self : int, _snake_case : Tuple, _snake_case : List[str], _snake_case : List[Any], _snake_case : List[Any], *_snake_case : List[Any] ) ->Optional[int]: snake_case__ : List[str] = OpenAIGPTDoubleHeadsModel(_snake_case ) model.to(_snake_case ) model.eval() snake_case__ : Optional[Any] = model(_snake_case, token_type_ids=_snake_case, labels=_snake_case ) self.parent.assertEqual(result.loss.shape, () ) self.parent.assertEqual(result.logits.shape, (self.batch_size, self.seq_length, self.vocab_size) ) def lowercase_ ( self : Optional[int], _snake_case : Tuple, _snake_case : Dict, _snake_case : List[str], _snake_case : Optional[Any], *_snake_case : Union[str, Any] ) ->str: snake_case__ : List[str] = self.num_labels snake_case__ : Dict = OpenAIGPTForSequenceClassification(_snake_case ) model.to(_snake_case ) model.eval() snake_case__ : List[str] = ids_tensor([self.batch_size], self.type_sequence_label_size ) snake_case__ : List[str] = model(_snake_case, token_type_ids=_snake_case, labels=_snake_case ) self.parent.assertEqual(result.logits.shape, (self.batch_size, self.num_labels) ) def lowercase_ ( self : Dict ) ->int: snake_case__ : List[Any] = self.prepare_config_and_inputs() ( ( snake_case__ ) , ( snake_case__ ) , ( snake_case__ ) , ( snake_case__ ) , ( snake_case__ ) , ( snake_case__ ) , ( snake_case__ ) , ) : Optional[Any] = config_and_inputs snake_case__ : str = { 'input_ids': input_ids, 'token_type_ids': token_type_ids, 'head_mask': head_mask, } return config, inputs_dict @require_torch class snake_case__ ( lowerCAmelCase_ , lowerCAmelCase_ , lowerCAmelCase_ , unittest.TestCase ): """simple docstring""" _SCREAMING_SNAKE_CASE = ( (OpenAIGPTModel, OpenAIGPTLMHeadModel, OpenAIGPTDoubleHeadsModel, OpenAIGPTForSequenceClassification) if is_torch_available() else () ) _SCREAMING_SNAKE_CASE = ( (OpenAIGPTLMHeadModel,) if is_torch_available() else () ) # TODO (PVP): Add Double HeadsModel when generate() function is changed accordingly _SCREAMING_SNAKE_CASE = ( { """feature-extraction""": OpenAIGPTModel, """text-classification""": OpenAIGPTForSequenceClassification, """text-generation""": OpenAIGPTLMHeadModel, """zero-shot""": OpenAIGPTForSequenceClassification, } if is_torch_available() else {} ) def lowercase_ ( self : Optional[int], _snake_case : Union[str, Any], _snake_case : int, _snake_case : Tuple, _snake_case : Tuple, _snake_case : List[str] ) ->Optional[Any]: if pipeline_test_casse_name == "ZeroShotClassificationPipelineTests": # Get `tokenizer does not have a padding token` error for both fast/slow tokenizers. # `OpenAIGPTConfig` was never used in pipeline tests, either because of a missing checkpoint or because a # tiny config could not be created. return True return False def lowercase_ ( self : Optional[Any], _snake_case : Union[str, Any], _snake_case : List[str], _snake_case : Any=False ) ->Tuple: snake_case__ : Optional[int] = super()._prepare_for_class(_snake_case, _snake_case, return_labels=_snake_case ) if return_labels: if model_class.__name__ == "OpenAIGPTDoubleHeadsModel": snake_case__ : Union[str, Any] = torch.zeros( (self.model_tester.batch_size, self.model_tester.num_choices, self.model_tester.seq_length), dtype=torch.long, device=_snake_case, ) snake_case__ : List[Any] = inputs_dict['labels'] snake_case__ : List[Any] = inputs_dict['labels'] snake_case__ : Any = torch.zeros( (self.model_tester.batch_size, self.model_tester.num_choices), dtype=torch.long, device=_snake_case, ) snake_case__ : Tuple = torch.zeros( self.model_tester.batch_size, dtype=torch.long, device=_snake_case ) return inputs_dict def lowercase_ ( self : Union[str, Any] ) ->List[str]: snake_case__ : List[str] = OpenAIGPTModelTester(self ) snake_case__ : Any = ConfigTester(self, config_class=_snake_case, n_embd=3_7 ) def lowercase_ ( self : Optional[int] ) ->str: self.config_tester.run_common_tests() def lowercase_ ( self : int ) ->Tuple: snake_case__ : str = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_openai_gpt_model(*_snake_case ) def lowercase_ ( self : Tuple ) ->List[str]: snake_case__ : Optional[int] = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_lm_head_model(*_snake_case ) def lowercase_ ( self : Dict ) ->int: snake_case__ : Optional[Any] = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_double_lm_head_model(*_snake_case ) def lowercase_ ( self : int ) ->str: snake_case__ : List[Any] = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_openai_gpt_for_sequence_classification(*_snake_case ) @slow def lowercase_ ( self : Optional[Any] ) ->str: for model_name in OPENAI_GPT_PRETRAINED_MODEL_ARCHIVE_LIST[:1]: snake_case__ : Optional[int] = OpenAIGPTModel.from_pretrained(_snake_case ) self.assertIsNotNone(_snake_case ) @require_torch class snake_case__ ( unittest.TestCase ): """simple docstring""" @slow def lowercase_ ( self : Tuple ) ->Optional[int]: snake_case__ : Union[str, Any] = OpenAIGPTLMHeadModel.from_pretrained('openai-gpt' ) model.to(_snake_case ) snake_case__ : Tuple = torch.tensor([[4_8_1, 4_7_3_5, 5_4_4]], dtype=torch.long, device=_snake_case ) # the president is snake_case__ : int = [ 4_8_1, 4_7_3_5, 5_4_4, 2_4_6, 9_6_3, 8_7_0, 7_6_2, 2_3_9, 2_4_4, 4_0_4_7_7, 2_4_4, 2_4_9, 7_1_9, 8_8_1, 4_8_7, 5_4_4, 2_4_0, 2_4_4, 6_0_3, 4_8_1, ] # the president is a very good man. " \n " i\'m sure he is, " said the snake_case__ : Optional[int] = model.generate(_snake_case, do_sample=_snake_case ) self.assertListEqual(output_ids[0].tolist(), _snake_case )
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from __future__ import annotations import unittest from transformers import BlenderbotSmallConfig, BlenderbotSmallTokenizer, is_tf_available from transformers.testing_utils import require_tf, require_tokenizers, slow from transformers.utils import cached_property from ...test_configuration_common import ConfigTester from ...test_modeling_tf_common import TFModelTesterMixin, ids_tensor from ...test_pipeline_mixin import PipelineTesterMixin if is_tf_available(): import tensorflow as tf from transformers import TFAutoModelForSeqaSeqLM, TFBlenderbotSmallForConditionalGeneration, TFBlenderbotSmallModel @require_tf class __lowerCAmelCase : _lowercase : str = BlenderbotSmallConfig _lowercase : Optional[int] = {} _lowercase : int = """gelu""" def __init__( self , lowerCAmelCase__ , lowerCAmelCase__=1_3 , lowerCAmelCase__=7 , lowerCAmelCase__=True , lowerCAmelCase__=False , lowerCAmelCase__=9_9 , lowerCAmelCase__=3_2 , lowerCAmelCase__=2 , lowerCAmelCase__=4 , lowerCAmelCase__=3_7 , lowerCAmelCase__=0.1 , lowerCAmelCase__=0.1 , lowerCAmelCase__=2_0 , lowerCAmelCase__=2 , lowerCAmelCase__=1 , lowerCAmelCase__=0 , ) -> str: '''simple docstring''' a__ : List[str] =parent a__ : Union[str, Any] =batch_size a__ : Optional[Any] =seq_length a__ : str =is_training a__ : Any =use_labels a__ : Optional[Any] =vocab_size a__ : List[Any] =hidden_size a__ : List[str] =num_hidden_layers a__ : List[str] =num_attention_heads a__ : Tuple =intermediate_size a__ : Optional[int] =hidden_dropout_prob a__ : List[Any] =attention_probs_dropout_prob a__ : int =max_position_embeddings a__ : Optional[Any] =eos_token_id a__ : List[Any] =pad_token_id a__ : Any =bos_token_id def _lowercase ( self ) -> Optional[int]: '''simple docstring''' a__ : int =ids_tensor([self.batch_size, self.seq_length - 1] , self.vocab_size ) a__ : int =tf.expand_dims(tf.constant([self.eos_token_id] * self.batch_size ) , 1 ) a__ : List[str] =tf.concat([input_ids, eos_tensor] , axis=1 ) a__ : Any =ids_tensor([self.batch_size, self.seq_length] , self.vocab_size ) a__ : Dict =self.config_cls( vocab_size=self.vocab_size , d_model=self.hidden_size , encoder_layers=self.num_hidden_layers , decoder_layers=self.num_hidden_layers , encoder_attention_heads=self.num_attention_heads , decoder_attention_heads=self.num_attention_heads , encoder_ffn_dim=self.intermediate_size , decoder_ffn_dim=self.intermediate_size , dropout=self.hidden_dropout_prob , attention_dropout=self.attention_probs_dropout_prob , max_position_embeddings=self.max_position_embeddings , eos_token_ids=[2] , bos_token_id=self.bos_token_id , pad_token_id=self.pad_token_id , decoder_start_token_id=self.pad_token_id , **self.config_updates , ) a__ : str =prepare_blenderbot_small_inputs_dict(_snake_case , _snake_case , _snake_case ) return config, inputs_dict def _lowercase ( self , lowerCAmelCase__ , lowerCAmelCase__ ) -> Tuple: '''simple docstring''' a__ : str =TFBlenderbotSmallModel(config=_snake_case ).get_decoder() a__ : List[str] =inputs_dict['input_ids'] a__ : Tuple =input_ids[:1, :] a__ : str =inputs_dict['attention_mask'][:1, :] a__ : Optional[Any] =inputs_dict['head_mask'] a__ : Union[str, Any] =1 # first forward pass a__ : Dict =model(_snake_case , attention_mask=_snake_case , head_mask=_snake_case , use_cache=_snake_case ) a__ : List[Any] =outputs.to_tuple() # create hypothetical next token and extent to next_input_ids a__ : Optional[int] =ids_tensor((self.batch_size, 3) , config.vocab_size ) a__ : Any =tf.cast(ids_tensor((self.batch_size, 3) , 2 ) , tf.inta ) # append to next input_ids and a__ : int =tf.concat([input_ids, next_tokens] , axis=-1 ) a__ : List[str] =tf.concat([attention_mask, next_attn_mask] , axis=-1 ) a__ : Tuple =model(_snake_case , attention_mask=_snake_case )[0] a__ : int =model(_snake_case , attention_mask=_snake_case , past_key_values=_snake_case )[0] self.parent.assertEqual(next_tokens.shape[1] , output_from_past.shape[1] ) # select random slice a__ : List[str] =int(ids_tensor((1,) , output_from_past.shape[-1] ) ) a__ : Tuple =output_from_no_past[:, -3:, random_slice_idx] a__ : List[Any] =output_from_past[:, :, random_slice_idx] # test that outputs are equal for slice tf.debugging.assert_near(_snake_case , _snake_case , rtol=1E-3 ) def _A ( SCREAMING_SNAKE_CASE : Dict , SCREAMING_SNAKE_CASE : Any , SCREAMING_SNAKE_CASE : Optional[int] , SCREAMING_SNAKE_CASE : Dict=None , SCREAMING_SNAKE_CASE : int=None , SCREAMING_SNAKE_CASE : List[str]=None , SCREAMING_SNAKE_CASE : Union[str, Any]=None , SCREAMING_SNAKE_CASE : Optional[Any]=None , ): """simple docstring""" if attention_mask is None: a__ : Union[str, Any] =tf.cast(tf.math.not_equal(SCREAMING_SNAKE_CASE , config.pad_token_id ) , tf.inta ) if decoder_attention_mask is None: a__ : List[str] =tf.concat( [ tf.ones(decoder_input_ids[:, :1].shape , dtype=tf.inta ), tf.cast(tf.math.not_equal(decoder_input_ids[:, 1:] , config.pad_token_id ) , tf.inta ), ] , axis=-1 , ) if head_mask is None: a__ : Tuple =tf.ones((config.encoder_layers, config.encoder_attention_heads) ) if decoder_head_mask is None: a__ : int =tf.ones((config.decoder_layers, config.decoder_attention_heads) ) if cross_attn_head_mask is None: a__ : Any =tf.ones((config.decoder_layers, config.decoder_attention_heads) ) return { "input_ids": input_ids, "decoder_input_ids": decoder_input_ids, "attention_mask": attention_mask, "decoder_attention_mask": decoder_attention_mask, "head_mask": head_mask, "decoder_head_mask": decoder_head_mask, "cross_attn_head_mask": cross_attn_head_mask, } @require_tf class __lowerCAmelCase ( lowerCAmelCase_ , lowerCAmelCase_ , unittest.TestCase): _lowercase : List[str] = ( (TFBlenderbotSmallForConditionalGeneration, TFBlenderbotSmallModel) if is_tf_available() else () ) _lowercase : Optional[Any] = (TFBlenderbotSmallForConditionalGeneration,) if is_tf_available() else () _lowercase : Dict = ( { """conversational""": TFBlenderbotSmallForConditionalGeneration, """feature-extraction""": TFBlenderbotSmallModel, """summarization""": TFBlenderbotSmallForConditionalGeneration, """text2text-generation""": TFBlenderbotSmallForConditionalGeneration, """translation""": TFBlenderbotSmallForConditionalGeneration, } if is_tf_available() else {} ) _lowercase : Tuple = True _lowercase : List[str] = False _lowercase : List[Any] = False def _lowercase ( self ) -> List[str]: '''simple docstring''' a__ : Optional[int] =TFBlenderbotSmallModelTester(self ) a__ : List[Any] =ConfigTester(self , config_class=_snake_case ) def _lowercase ( self ) -> Any: '''simple docstring''' self.config_tester.run_common_tests() def _lowercase ( self ) -> Optional[Any]: '''simple docstring''' a__ : List[Any] =self.model_tester.prepare_config_and_inputs_for_common() self.model_tester.check_decoder_model_past_large_inputs(*_snake_case ) @require_tokenizers @require_tf class __lowerCAmelCase ( unittest.TestCase): _lowercase : Dict = [ """Social anxiety\nWow, I am never shy. Do you have anxiety?\nYes. I end up sweating and blushing and feel like """ """ i'm going to throw up.\nand why is that?""" ] _lowercase : int = """facebook/blenderbot_small-90M""" @cached_property def _lowercase ( self ) -> List[Any]: '''simple docstring''' return BlenderbotSmallTokenizer.from_pretrained("facebook/blenderbot-90M" ) @cached_property def _lowercase ( self ) -> List[str]: '''simple docstring''' a__ : Tuple =TFAutoModelForSeqaSeqLM.from_pretrained(self.model_name ) return model @slow def _lowercase ( self ) -> Optional[int]: '''simple docstring''' a__ : Any =self.tokenizer(self.src_text , return_tensors="tf" ) a__ : List[str] =self.model.generate( model_inputs.input_ids , attention_mask=model_inputs.attention_mask , num_beams=2 , use_cache=_snake_case , ) a__ : List[str] =self.tokenizer.batch_decode(generated_ids.numpy() , skip_special_tokens=_snake_case )[0] assert generated_words in ( "i don't know. i just feel like i'm going to throw up. it's not fun.", "i'm not sure. i just feel like i've been feeling like i have to be in a certain place", "i'm not sure. i just feel like i've been in a bad situation.", )
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import os import unittest from transformers.models.transfo_xl.tokenization_transfo_xl import VOCAB_FILES_NAMES, TransfoXLTokenizer from ...test_tokenization_common import TokenizerTesterMixin class snake_case__ ( lowerCAmelCase_ , unittest.TestCase ): """simple docstring""" _SCREAMING_SNAKE_CASE = TransfoXLTokenizer _SCREAMING_SNAKE_CASE = False _SCREAMING_SNAKE_CASE = False def lowercase_ ( self : Optional[int] ) ->Any: super().setUp() snake_case__ : Tuple = [ '<unk>', '[CLS]', '[SEP]', 'want', 'unwanted', 'wa', 'un', 'running', ',', 'low', 'l', ] snake_case__ : Any = os.path.join(self.tmpdirname, VOCAB_FILES_NAMES['vocab_file'] ) with open(self.vocab_file, 'w', encoding='utf-8' ) as vocab_writer: vocab_writer.write(''.join([x + '\n' for x in vocab_tokens] ) ) def lowercase_ ( self : Union[str, Any], **_snake_case : List[Any] ) ->Dict: snake_case__ : str = True return TransfoXLTokenizer.from_pretrained(self.tmpdirname, **_snake_case ) def lowercase_ ( self : Optional[Any], _snake_case : str ) ->Dict: snake_case__ : List[Any] = '<unk> UNwanted , running' snake_case__ : List[Any] = '<unk> unwanted, running' return input_text, output_text def lowercase_ ( self : List[Any] ) ->Tuple: snake_case__ : Dict = TransfoXLTokenizer(vocab_file=self.vocab_file, lower_case=_snake_case ) snake_case__ : str = tokenizer.tokenize('<unk> UNwanted , running' ) self.assertListEqual(_snake_case, ['<unk>', 'unwanted', ',', 'running'] ) self.assertListEqual(tokenizer.convert_tokens_to_ids(_snake_case ), [0, 4, 8, 7] ) def lowercase_ ( self : List[str] ) ->List[Any]: snake_case__ : str = TransfoXLTokenizer(lower_case=_snake_case ) self.assertListEqual( tokenizer.tokenize(' \tHeLLo ! how \n Are yoU ? ' ), ['hello', '!', 'how', 'are', 'you', '?'] ) def lowercase_ ( self : Optional[int] ) ->Optional[Any]: snake_case__ : Optional[int] = TransfoXLTokenizer(lower_case=_snake_case ) self.assertListEqual( tokenizer.tokenize(' \tHeLLo ! how \n Are yoU ? ' ), ['HeLLo', '!', 'how', 'Are', 'yoU', '?'] ) def lowercase_ ( self : Optional[int] ) ->Union[str, Any]: snake_case__ : List[Any] = TransfoXLTokenizer(lower_case=_snake_case ) snake_case__ : Dict = 'Hello (bracket) and side-scrolled [and] Henry\'s $5,000 with 3.34 m. What\'s up!?' snake_case__ : List[Any] = [ 'Hello', '(', 'bracket', ')', 'and', 'side', '@-@', 'scrolled', '[', 'and', ']', 'Henry', '\'s', '$', '5', '@,@', '000', 'with', '3', '@.@', '34', 'm', '.', 'What', '\'s', 'up', '!', '?', ] self.assertListEqual(tokenizer.tokenize(_snake_case ), _snake_case ) self.assertEqual(tokenizer.convert_tokens_to_string(_snake_case ), _snake_case ) def lowercase_ ( self : Dict ) ->Any: snake_case__ : Dict = self.get_tokenizer() snake_case__ : Optional[Any] = len(_snake_case ) tokenizer.add_tokens(['new1', 'new2'] ) tokenizer.move_added_token('new1', 1 ) # Check that moved token is not copied (duplicate) self.assertEqual(len(_snake_case ), original_len + 2 ) # Check that token is moved to specified id self.assertEqual(tokenizer.encode('new1' ), [1] ) self.assertEqual(tokenizer.decode([1] ), 'new1' )
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import gc import unittest import numpy as np import torch from transformers import CLIPTextConfig, CLIPTextModel, CLIPTokenizer from diffusers import ( AutoencoderKL, DDIMScheduler, EulerAncestralDiscreteScheduler, LMSDiscreteScheduler, PNDMScheduler, StableDiffusionPanoramaPipeline, UNetaDConditionModel, ) from diffusers.utils import slow, torch_device from diffusers.utils.testing_utils import enable_full_determinism, require_torch_gpu, skip_mps from ..pipeline_params import TEXT_TO_IMAGE_BATCH_PARAMS, TEXT_TO_IMAGE_IMAGE_PARAMS, TEXT_TO_IMAGE_PARAMS from ..test_pipelines_common import PipelineLatentTesterMixin, PipelineTesterMixin enable_full_determinism() @skip_mps class lowercase__( lowerCAmelCase_ , lowerCAmelCase_ , unittest.TestCase ): """simple docstring""" a :int = StableDiffusionPanoramaPipeline a :List[str] = TEXT_TO_IMAGE_PARAMS a :Dict = TEXT_TO_IMAGE_BATCH_PARAMS a :Any = TEXT_TO_IMAGE_IMAGE_PARAMS a :List[Any] = TEXT_TO_IMAGE_IMAGE_PARAMS def _lowercase ( self : Union[str, Any] ) -> Any: torch.manual_seed(0 ) lowercase_ = UNetaDConditionModel( block_out_channels=(3_2, 6_4) , layers_per_block=1 , sample_size=3_2 , in_channels=4 , out_channels=4 , down_block_types=('''DownBlock2D''', '''CrossAttnDownBlock2D''') , up_block_types=('''CrossAttnUpBlock2D''', '''UpBlock2D''') , cross_attention_dim=3_2 , ) lowercase_ = DDIMScheduler() torch.manual_seed(0 ) lowercase_ = AutoencoderKL( block_out_channels=[3_2, 6_4] , in_channels=3 , out_channels=3 , down_block_types=['''DownEncoderBlock2D''', '''DownEncoderBlock2D'''] , up_block_types=['''UpDecoderBlock2D''', '''UpDecoderBlock2D'''] , latent_channels=4 , ) torch.manual_seed(0 ) lowercase_ = CLIPTextConfig( bos_token_id=0 , eos_token_id=2 , hidden_size=3_2 , intermediate_size=3_7 , layer_norm_eps=1e-05 , num_attention_heads=4 , num_hidden_layers=5 , pad_token_id=1 , vocab_size=1_0_0_0 , ) lowercase_ = CLIPTextModel(_snake_case ) lowercase_ = CLIPTokenizer.from_pretrained('''hf-internal-testing/tiny-random-clip''' ) lowercase_ = { 'unet': unet, 'scheduler': scheduler, 'vae': vae, 'text_encoder': text_encoder, 'tokenizer': tokenizer, 'safety_checker': None, 'feature_extractor': None, } return components def _lowercase ( self : Optional[Any] , SCREAMING_SNAKE_CASE_ : List[Any] , SCREAMING_SNAKE_CASE_ : Tuple=0 ) -> Union[str, Any]: lowercase_ = torch.manual_seed(_snake_case ) lowercase_ = { 'prompt': 'a photo of the dolomites', 'generator': generator, # Setting height and width to None to prevent OOMs on CPU. 'height': None, 'width': None, 'num_inference_steps': 1, 'guidance_scale': 6.0, 'output_type': 'numpy', } return inputs def _lowercase ( self : Optional[Any] ) -> str: lowercase_ = 'cpu' # ensure determinism for the device-dependent torch.Generator lowercase_ = self.get_dummy_components() lowercase_ = StableDiffusionPanoramaPipeline(**_snake_case ) lowercase_ = sd_pipe.to(_snake_case ) sd_pipe.set_progress_bar_config(disable=_snake_case ) lowercase_ = self.get_dummy_inputs(_snake_case ) lowercase_ = sd_pipe(**_snake_case ).images lowercase_ = image[0, -3:, -3:, -1] assert image.shape == (1, 6_4, 6_4, 3) lowercase_ = np.array([0.61_86, 0.53_74, 0.49_15, 0.41_35, 0.41_14, 0.45_63, 0.51_28, 0.49_77, 0.47_57] ) assert np.abs(image_slice.flatten() - expected_slice ).max() < 1e-2 def _lowercase ( self : Tuple ) -> Any: super().test_inference_batch_consistent(batch_sizes=[1, 2] ) def _lowercase ( self : Optional[Any] ) -> Any: super().test_inference_batch_single_identical(batch_size=2 , expected_max_diff=3.25e-3 ) def _lowercase ( self : str ) -> List[str]: lowercase_ = 'cpu' # ensure determinism for the device-dependent torch.Generator lowercase_ = self.get_dummy_components() lowercase_ = StableDiffusionPanoramaPipeline(**_snake_case ) lowercase_ = sd_pipe.to(_snake_case ) sd_pipe.set_progress_bar_config(disable=_snake_case ) lowercase_ = self.get_dummy_inputs(_snake_case ) lowercase_ = 'french fries' lowercase_ = sd_pipe(**_snake_case , negative_prompt=_snake_case ) lowercase_ = output.images lowercase_ = image[0, -3:, -3:, -1] assert image.shape == (1, 6_4, 6_4, 3) lowercase_ = np.array([0.61_87, 0.53_75, 0.49_15, 0.41_36, 0.41_14, 0.45_63, 0.51_28, 0.49_76, 0.47_57] ) assert np.abs(image_slice.flatten() - expected_slice ).max() < 1e-2 def _lowercase ( self : Optional[Any] ) -> Optional[Any]: lowercase_ = 'cpu' # ensure determinism for the device-dependent torch.Generator lowercase_ = self.get_dummy_components() lowercase_ = StableDiffusionPanoramaPipeline(**_snake_case ) lowercase_ = sd_pipe.to(_snake_case ) sd_pipe.set_progress_bar_config(disable=_snake_case ) lowercase_ = self.get_dummy_inputs(_snake_case ) lowercase_ = sd_pipe(**_snake_case , view_batch_size=2 ) lowercase_ = output.images lowercase_ = image[0, -3:, -3:, -1] assert image.shape == (1, 6_4, 6_4, 3) lowercase_ = np.array([0.61_87, 0.53_75, 0.49_15, 0.41_36, 0.41_14, 0.45_63, 0.51_28, 0.49_76, 0.47_57] ) assert np.abs(image_slice.flatten() - expected_slice ).max() < 1e-2 def _lowercase ( self : Dict ) -> Any: lowercase_ = 'cpu' # ensure determinism for the device-dependent torch.Generator lowercase_ = self.get_dummy_components() lowercase_ = EulerAncestralDiscreteScheduler( beta_start=0.0_00_85 , beta_end=0.0_12 , beta_schedule='''scaled_linear''' ) lowercase_ = StableDiffusionPanoramaPipeline(**_snake_case ) lowercase_ = sd_pipe.to(_snake_case ) sd_pipe.set_progress_bar_config(disable=_snake_case ) lowercase_ = self.get_dummy_inputs(_snake_case ) lowercase_ = sd_pipe(**_snake_case ).images lowercase_ = image[0, -3:, -3:, -1] assert image.shape == (1, 6_4, 6_4, 3) lowercase_ = np.array([0.40_24, 0.65_10, 0.49_01, 0.53_78, 0.58_13, 0.56_22, 0.47_95, 0.44_67, 0.49_52] ) assert np.abs(image_slice.flatten() - expected_slice ).max() < 1e-2 def _lowercase ( self : Union[str, Any] ) -> Any: lowercase_ = 'cpu' # ensure determinism for the device-dependent torch.Generator lowercase_ = self.get_dummy_components() lowercase_ = PNDMScheduler( beta_start=0.0_00_85 , beta_end=0.0_12 , beta_schedule='''scaled_linear''' , skip_prk_steps=_snake_case ) lowercase_ = StableDiffusionPanoramaPipeline(**_snake_case ) lowercase_ = sd_pipe.to(_snake_case ) sd_pipe.set_progress_bar_config(disable=_snake_case ) lowercase_ = self.get_dummy_inputs(_snake_case ) lowercase_ = sd_pipe(**_snake_case ).images lowercase_ = image[0, -3:, -3:, -1] assert image.shape == (1, 6_4, 6_4, 3) lowercase_ = np.array([0.63_91, 0.62_91, 0.48_61, 0.51_34, 0.55_52, 0.45_78, 0.50_32, 0.50_23, 0.45_39] ) assert np.abs(image_slice.flatten() - expected_slice ).max() < 1e-2 @slow @require_torch_gpu class lowercase__( unittest.TestCase ): """simple docstring""" def _lowercase ( self : Dict ) -> List[Any]: super().tearDown() gc.collect() torch.cuda.empty_cache() def _lowercase ( self : Optional[Any] , SCREAMING_SNAKE_CASE_ : Any=0 ) -> Any: lowercase_ = torch.manual_seed(_snake_case ) lowercase_ = { 'prompt': 'a photo of the dolomites', 'generator': generator, 'num_inference_steps': 3, 'guidance_scale': 7.5, 'output_type': 'numpy', } return inputs def _lowercase ( self : Any ) -> Optional[Any]: lowercase_ = 'stabilityai/stable-diffusion-2-base' lowercase_ = DDIMScheduler.from_pretrained(_snake_case , subfolder='''scheduler''' ) lowercase_ = StableDiffusionPanoramaPipeline.from_pretrained(_snake_case , scheduler=_snake_case , safety_checker=_snake_case ) pipe.to(_snake_case ) pipe.set_progress_bar_config(disable=_snake_case ) pipe.enable_attention_slicing() lowercase_ = self.get_inputs() lowercase_ = pipe(**_snake_case ).images lowercase_ = image[0, -3:, -3:, -1].flatten() assert image.shape == (1, 5_1_2, 2_0_4_8, 3) lowercase_ = np.array( [ 0.36_96_83_92, 0.27_02_53_72, 0.32_44_67_66, 0.28_37_93_87, 0.36_36_32_74, 0.30_73_33_47, 0.27_10_00_27, 0.27_05_41_25, 0.25_53_60_96, ] ) assert np.abs(expected_slice - image_slice ).max() < 1e-2 def _lowercase ( self : Optional[Any] ) -> str: lowercase_ = StableDiffusionPanoramaPipeline.from_pretrained( '''stabilityai/stable-diffusion-2-base''' , safety_checker=_snake_case ) lowercase_ = LMSDiscreteScheduler.from_config(pipe.scheduler.config ) pipe.to(_snake_case ) pipe.set_progress_bar_config(disable=_snake_case ) pipe.enable_attention_slicing() lowercase_ = self.get_inputs() lowercase_ = pipe(**_snake_case ).images lowercase_ = image[0, -3:, -3:, -1].flatten() assert image.shape == (1, 5_1_2, 2_0_4_8, 3) lowercase_ = np.array( [ [ 0.0, 0.0, 0.0, 0.0, 0.0, 0.0, 0.0, 0.0, 0.0, ] ] ) assert np.abs(expected_slice - image_slice ).max() < 1e-3 def _lowercase ( self : int ) -> Any: lowercase_ = 0 def callback_fn(SCREAMING_SNAKE_CASE_ : int , SCREAMING_SNAKE_CASE_ : int , SCREAMING_SNAKE_CASE_ : torch.FloatTensor ) -> None: lowercase_ = True nonlocal number_of_steps number_of_steps += 1 if step == 1: lowercase_ = latents.detach().cpu().numpy() assert latents.shape == (1, 4, 6_4, 2_5_6) lowercase_ = latents[0, -3:, -3:, -1] lowercase_ = np.array( [ 0.18_68_18_69, 0.33_90_78_16, 0.5_36_12_76, 0.14_43_28_65, -0.02_85_66_11, -0.73_94_11_23, 0.23_39_79_87, 0.47_32_26_82, -0.37_82_31_64, ] ) assert np.abs(latents_slice.flatten() - expected_slice ).max() < 5e-2 elif step == 2: lowercase_ = latents.detach().cpu().numpy() assert latents.shape == (1, 4, 6_4, 2_5_6) lowercase_ = latents[0, -3:, -3:, -1] lowercase_ = np.array( [ 0.18_53_96_45, 0.33_98_72_48, 0.5_37_85_59, 0.14_43_71_42, -0.02_45_52_61, -0.7_33_83_17, 0.23_99_07_55, 0.47_35_62_72, -0.3_78_65_05, ] ) assert np.abs(latents_slice.flatten() - expected_slice ).max() < 5e-2 lowercase_ = False lowercase_ = 'stabilityai/stable-diffusion-2-base' lowercase_ = DDIMScheduler.from_pretrained(_snake_case , subfolder='''scheduler''' ) lowercase_ = StableDiffusionPanoramaPipeline.from_pretrained(_snake_case , scheduler=_snake_case , safety_checker=_snake_case ) lowercase_ = pipe.to(_snake_case ) pipe.set_progress_bar_config(disable=_snake_case ) pipe.enable_attention_slicing() lowercase_ = self.get_inputs() pipe(**_snake_case , callback=_snake_case , callback_steps=1 ) assert callback_fn.has_been_called assert number_of_steps == 3 def _lowercase ( self : Optional[Any] ) -> Optional[int]: torch.cuda.empty_cache() torch.cuda.reset_max_memory_allocated() torch.cuda.reset_peak_memory_stats() lowercase_ = 'stabilityai/stable-diffusion-2-base' lowercase_ = DDIMScheduler.from_pretrained(_snake_case , subfolder='''scheduler''' ) lowercase_ = StableDiffusionPanoramaPipeline.from_pretrained(_snake_case , scheduler=_snake_case , safety_checker=_snake_case ) lowercase_ = pipe.to(_snake_case ) pipe.set_progress_bar_config(disable=_snake_case ) pipe.enable_attention_slicing(1 ) pipe.enable_sequential_cpu_offload() lowercase_ = self.get_inputs() lowercase_ = pipe(**_snake_case ) lowercase_ = torch.cuda.max_memory_allocated() # make sure that less than 5.2 GB is allocated assert mem_bytes < 5.5 * 1_0**9
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from ...configuration_utils import PretrainedConfig from ...utils import logging a_ :Optional[int] = logging.get_logger(__name__) a_ :Dict = {"openai-gpt": "https://huggingface.co/openai-gpt/resolve/main/config.json"} class snake_case__ ( lowerCAmelCase_ ): """simple docstring""" _SCREAMING_SNAKE_CASE = """openai-gpt""" _SCREAMING_SNAKE_CASE = { """max_position_embeddings""": """n_positions""", """hidden_size""": """n_embd""", """num_attention_heads""": """n_head""", """num_hidden_layers""": """n_layer""", } def __init__( self : Optional[int], _snake_case : Dict=4_0_4_7_8, _snake_case : str=5_1_2, _snake_case : int=7_6_8, _snake_case : Tuple=1_2, _snake_case : Any=1_2, _snake_case : str="gelu", _snake_case : List[str]=0.1, _snake_case : Any=0.1, _snake_case : Dict=0.1, _snake_case : int=1e-5, _snake_case : Optional[Any]=0.0_2, _snake_case : List[Any]="cls_index", _snake_case : Any=True, _snake_case : Any=None, _snake_case : int=True, _snake_case : Optional[Any]=0.1, **_snake_case : List[Any], ) ->Optional[int]: snake_case__ : int = vocab_size snake_case__ : Dict = n_positions snake_case__ : str = n_embd snake_case__ : str = n_layer snake_case__ : List[Any] = n_head snake_case__ : List[Any] = afn snake_case__ : Optional[Any] = resid_pdrop snake_case__ : List[str] = embd_pdrop snake_case__ : List[Any] = attn_pdrop snake_case__ : Optional[int] = layer_norm_epsilon snake_case__ : str = initializer_range snake_case__ : List[str] = summary_type snake_case__ : Optional[int] = summary_use_proj snake_case__ : List[str] = summary_activation snake_case__ : Optional[Any] = summary_first_dropout snake_case__ : int = summary_proj_to_labels super().__init__(**_snake_case )
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0
"""simple docstring""" from collections import OrderedDict from typing import List, Mapping from packaging import version from ...configuration_utils import PretrainedConfig from ...onnx import OnnxConfig from ...utils import logging lowercase_ = logging.get_logger(__name__) lowercase_ = { "google/efficientnet-b7": "https://huggingface.co/google/efficientnet-b7/resolve/main/config.json", } class __lowerCAmelCase ( lowerCAmelCase_ ): '''simple docstring''' __UpperCAmelCase : List[str] = 'efficientnet' def __init__( self , _a = 3 , _a = 600 , _a = 2.0 , _a = 3.1 , _a = 8 , _a = [3, 3, 5, 3, 5, 5, 3] , _a = [32, 16, 24, 40, 80, 112, 192] , _a = [16, 24, 40, 80, 112, 192, 320] , _a = [] , _a = [1, 2, 2, 2, 1, 2, 1] , _a = [1, 2, 2, 3, 3, 4, 1] , _a = [1, 6, 6, 6, 6, 6, 6] , _a = 0.25 , _a = "swish" , _a = 2_560 , _a = "mean" , _a = 0.02 , _a = 0.001 , _a = 0.99 , _a = 0.5 , _a = 0.2 , **_a , ): super().__init__(**_snake_case ) __a = num_channels __a = image_size __a = width_coefficient __a = depth_coefficient __a = depth_divisor __a = kernel_sizes __a = in_channels __a = out_channels __a = depthwise_padding __a = strides __a = num_block_repeats __a = expand_ratios __a = squeeze_expansion_ratio __a = hidden_act __a = hidden_dim __a = pooling_type __a = initializer_range __a = batch_norm_eps __a = batch_norm_momentum __a = dropout_rate __a = drop_connect_rate __a = sum(_snake_case ) * 4 class __lowerCAmelCase ( lowerCAmelCase_ ): '''simple docstring''' __UpperCAmelCase : Union[str, Any] = version.parse('1.11' ) @property def __UpperCAmelCase ( self ): return OrderedDict( [ ('''pixel_values''', {0: '''batch''', 1: '''num_channels''', 2: '''height''', 3: '''width'''}), ] ) @property def __UpperCAmelCase ( self ): return 1E-5
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import argparse import logging import os from datetime import datetime import numpy as np import torch from torch import nn from torch.utils.data import DataLoader, RandomSampler, TensorDataset from tqdm import tqdm from transformers import GPTaLMHeadModel a_ :Optional[Any] = logging.getLogger(__name__) def lowercase_ (A : List[Any] , A : List[Any] ): # save results if os.path.exists(A ): if os.path.exists(os.path.join(A , 'config.json' ) ) and os.path.isfile( os.path.join(A , 'config.json' ) ): os.remove(os.path.join(A , 'config.json' ) ) if os.path.exists(os.path.join(A , 'pytorch_model.bin' ) ) and os.path.isfile( os.path.join(A , 'pytorch_model.bin' ) ): os.remove(os.path.join(A , 'pytorch_model.bin' ) ) else: os.makedirs(A ) model.save_pretrained(A ) def lowercase_ (A : Any , A : Optional[Any]=False ): snake_case__ : str = 2 if unlogit: snake_case__ : Dict = torch.pow(A , A ) snake_case__ : Any = p * torch.log(A ) snake_case__ : Tuple = 0 return -plogp.sum(dim=-1 ) def lowercase_ (A : List[str] ): logger.info('lv, h >\t' + '\t'.join(F'''{x + 1}''' for x in range(len(A ) ) ) ) for row in range(len(A ) ): if tensor.dtype != torch.long: logger.info(F'''layer {row + 1}:\t''' + '\t'.join(F'''{x:.5f}''' for x in tensor[row].cpu().data ) ) else: logger.info(F'''layer {row + 1}:\t''' + '\t'.join(F'''{x:d}''' for x in tensor[row].cpu().data ) ) def lowercase_ (A : Tuple , A : Optional[Any] , A : str , A : int=True , A : Optional[int]=True , A : Any=None , A : int=False ): snake_case__ , snake_case__ : Optional[Any] = model.config.num_hidden_layers, model.config.num_attention_heads snake_case__ : int = torch.zeros(A , A ).to(args.device ) snake_case__ : Any = torch.zeros(A , A ).to(args.device ) if head_mask is None: snake_case__ : Dict = torch.ones(A , A ).to(args.device ) head_mask.requires_grad_(requires_grad=A ) # If actually pruned attention multi-head, set head mask to None to avoid shape mismatch if actually_pruned: snake_case__ : Optional[int] = None snake_case__ : List[Any] = 0.0 snake_case__ : str = 0.0 for step, inputs in enumerate(tqdm(A , desc='Iteration' , disable=args.local_rank not in [-1, 0] ) ): snake_case__ : Union[str, Any] = tuple(t.to(args.device ) for t in inputs ) ((snake_case__) , ) : Optional[Any] = inputs # Do a forward pass (not with torch.no_grad() since we need gradients for importance score - see below) snake_case__ : Union[str, Any] = model(A , labels=A , head_mask=A ) # (loss), lm_logits, presents, (all hidden_states), (attentions) snake_case__ , snake_case__ , snake_case__ : Dict = ( outputs[0], outputs[1], outputs[-1], ) # Loss and logits are the first, attention the last loss.backward() # Backpropagate to populate the gradients in the head mask total_loss += loss.detach().cpu().numpy() if compute_entropy: for layer, attn in enumerate(A ): snake_case__ : Optional[Any] = entropy(attn.detach() , A ) attn_entropy[layer] += masked_entropy.sum(-1 ).sum(0 ).sum(0 ).detach() if compute_importance: head_importance += head_mask.grad.abs().detach() tot_tokens += torch.ones_like(A ).float().detach().sum().data # Normalize attn_entropy /= tot_tokens head_importance /= tot_tokens # Layerwise importance normalization if not args.dont_normalize_importance_by_layer: snake_case__ : Union[str, Any] = 2 snake_case__ : List[Any] = torch.pow(torch.pow(A , A ).sum(-1 ) , 1 / exponent ) head_importance /= norm_by_layer.unsqueeze(-1 ) + 1e-20 if not args.dont_normalize_global_importance: snake_case__ : Tuple = (head_importance - head_importance.min()) / (head_importance.max() - head_importance.min()) # Print matrices if compute_entropy: logger.info('Attention entropies' ) print_ad_tensor(A ) if compute_importance: logger.info('Head importance scores' ) print_ad_tensor(A ) logger.info('Head ranked by importance scores' ) snake_case__ : Tuple = torch.zeros(head_importance.numel() , dtype=torch.long , device=args.device ) snake_case__ : Union[str, Any] = torch.arange( head_importance.numel() , device=args.device ) snake_case__ : str = head_ranks.view_as(A ) print_ad_tensor(A ) return attn_entropy, head_importance, total_loss def lowercase_ (A : Optional[int] , A : Dict , A : Optional[int] ): snake_case__ , snake_case__ , snake_case__ : Any = compute_heads_importance(A , A , A , compute_entropy=A ) snake_case__ : Tuple = 1 / loss # instead of downsteam score use the LM loss logger.info('Pruning: original score: %f, threshold: %f' , A , original_score * args.masking_threshold ) snake_case__ : Optional[Any] = torch.ones_like(A ) snake_case__ : Union[str, Any] = max(1 , int(new_head_mask.numel() * args.masking_amount ) ) snake_case__ : Dict = original_score while current_score >= original_score * args.masking_threshold: snake_case__ : int = new_head_mask.clone().detach() # save current head mask # heads from least important to most - keep only not-masked heads snake_case__ : List[Any] = float('Inf' ) snake_case__ : Union[str, Any] = head_importance.view(-1 ).sort()[1] if len(A ) <= num_to_mask: print('BREAK BY num_to_mask' ) break # mask heads snake_case__ : int = current_heads_to_mask[:num_to_mask] logger.info('Heads to mask: %s' , str(current_heads_to_mask.tolist() ) ) snake_case__ : int = new_head_mask.view(-1 ) snake_case__ : int = 0.0 snake_case__ : Union[str, Any] = new_head_mask.view_as(A ) snake_case__ : List[str] = new_head_mask.clone().detach() print_ad_tensor(A ) # Compute metric and head importance again snake_case__ , snake_case__ , snake_case__ : Any = compute_heads_importance( A , A , A , compute_entropy=A , head_mask=A ) snake_case__ : Dict = 1 / loss logger.info( 'Masking: current score: %f, remaining heads %d (%.1f percents)' , A , new_head_mask.sum() , new_head_mask.sum() / new_head_mask.numel() * 1_0_0 , ) logger.info('Final head mask' ) print_ad_tensor(A ) np.save(os.path.join(args.output_dir , 'head_mask.npy' ) , head_mask.detach().cpu().numpy() ) return head_mask def lowercase_ (A : List[str] , A : Tuple , A : Optional[Any] , A : int ): snake_case__ : Any = datetime.now() snake_case__ , snake_case__ , snake_case__ : str = compute_heads_importance( A , A , A , compute_entropy=A , compute_importance=A , head_mask=A ) snake_case__ : Tuple = 1 / loss snake_case__ : Dict = datetime.now() - before_time snake_case__ : Union[str, Any] = sum(p.numel() for p in model.parameters() ) snake_case__ : Optional[Any] = { layer: (1 - head_mask[layer].long()).nonzero().squeeze().tolist() for layer in range(len(A ) ) } for k, v in heads_to_prune.items(): if isinstance(A , A ): snake_case__ : Any = [ v, ] assert sum(len(A ) for h in heads_to_prune.values() ) == (1 - head_mask.long()).sum().item() model.prune_heads(A ) snake_case__ : Dict = sum(p.numel() for p in model.parameters() ) snake_case__ : Tuple = datetime.now() snake_case__ , snake_case__ , snake_case__ : Dict = compute_heads_importance( A , A , A , compute_entropy=A , compute_importance=A , head_mask=A , actually_pruned=A , ) snake_case__ : Any = 1 / loss snake_case__ : int = datetime.now() - before_time logger.info( 'Pruning: original num of params: %.2e, after pruning %.2e (%.1f percents)' , A , A , pruned_num_params / original_num_params * 1_0_0 , ) logger.info('Pruning: score with masking: %f score with pruning: %f' , A , A ) logger.info('Pruning: speed ratio (original timing / new timing): %f percents' , original_time / new_time * 1_0_0 ) save_model(A , args.output_dir ) def lowercase_ (): snake_case__ : str = argparse.ArgumentParser() # Required parameters parser.add_argument( '--data_dir' , default=A , type=A , required=A , help='The input data dir. Should contain the .tsv files (or other data files) for the task.' , ) parser.add_argument( '--model_name_or_path' , default=A , type=A , required=A , help='Path to pretrained model or model identifier from huggingface.co/models' , ) parser.add_argument( '--output_dir' , default=A , type=A , required=A , help='The output directory where the model predictions and checkpoints will be written.' , ) # Other parameters parser.add_argument( '--config_name' , default='' , type=A , help='Pretrained config name or path if not the same as model_name_or_path' , ) parser.add_argument( '--tokenizer_name' , default='' , type=A , help='Pretrained tokenizer name or path if not the same as model_name_or_path' , ) parser.add_argument( '--cache_dir' , default=A , type=A , help='Where do you want to store the pre-trained models downloaded from s3' , ) parser.add_argument( '--data_subset' , type=A , default=-1 , help='If > 0: limit the data to a subset of data_subset instances.' ) parser.add_argument( '--overwrite_output_dir' , action='store_true' , help='Whether to overwrite data in output directory' ) parser.add_argument( '--overwrite_cache' , action='store_true' , help='Overwrite the cached training and evaluation sets' ) parser.add_argument( '--dont_normalize_importance_by_layer' , action='store_true' , help='Don\'t normalize importance score by layers' ) parser.add_argument( '--dont_normalize_global_importance' , action='store_true' , help='Don\'t normalize all importance scores between 0 and 1' , ) parser.add_argument( '--try_masking' , action='store_true' , help='Whether to try to mask head until a threshold of accuracy.' ) parser.add_argument( '--masking_threshold' , default=0.9 , type=A , help='masking threshold in term of metrics (stop masking when metric < threshold * original metric value).' , ) parser.add_argument( '--masking_amount' , default=0.1 , type=A , help='Amount to heads to masking at each masking step.' ) parser.add_argument('--metric_name' , default='acc' , type=A , help='Metric to use for head masking.' ) parser.add_argument( '--max_seq_length' , default=1_2_8 , type=A , help=( 'The maximum total input sequence length after WordPiece tokenization. \n' 'Sequences longer than this will be truncated, sequences shorter padded.' ) , ) parser.add_argument('--batch_size' , default=1 , type=A , help='Batch size.' ) parser.add_argument('--seed' , type=A , default=4_2 ) parser.add_argument('--local_rank' , type=A , default=-1 , help='local_rank for distributed training on gpus' ) parser.add_argument('--no_cuda' , action='store_true' , help='Whether not to use CUDA when available' ) parser.add_argument('--server_ip' , type=A , default='' , help='Can be used for distant debugging.' ) parser.add_argument('--server_port' , type=A , default='' , help='Can be used for distant debugging.' ) snake_case__ : Optional[int] = parser.parse_args() if args.server_ip and args.server_port: # Distant debugging - see https://code.visualstudio.com/docs/python/debugging#_attach-to-a-local-script import ptvsd print('Waiting for debugger attach' ) ptvsd.enable_attach(address=(args.server_ip, args.server_port) , redirect_output=A ) ptvsd.wait_for_attach() # Setup devices and distributed training if args.local_rank == -1 or args.no_cuda: snake_case__ : List[Any] = torch.device('cuda' if torch.cuda.is_available() and not args.no_cuda else 'cpu' ) snake_case__ : Optional[Any] = 0 if args.no_cuda else torch.cuda.device_count() else: torch.cuda.set_device(args.local_rank ) snake_case__ : int = torch.device('cuda' , args.local_rank ) snake_case__ : List[str] = 1 torch.distributed.init_process_group(backend='nccl' ) # Initializes the distributed backend # Setup logging logging.basicConfig(level=logging.INFO if args.local_rank in [-1, 0] else logging.WARN ) logger.info('device: {} n_gpu: {}, distributed: {}'.format(args.device , args.n_gpu , bool(args.local_rank != -1 ) ) ) snake_case__ : Any = GPTaLMHeadModel.from_pretrained(args.model_name_or_path ) # Distributed and parallel training model.to(args.device ) if args.local_rank != -1: snake_case__ : List[str] = nn.parallel.DistributedDataParallel( A , device_ids=[args.local_rank] , output_device=args.local_rank , find_unused_parameters=A ) elif args.n_gpu > 1: snake_case__ : Optional[int] = nn.DataParallel(A ) # Print/save training arguments os.makedirs(args.output_dir , exist_ok=A ) torch.save(A , os.path.join(args.output_dir , 'run_args.bin' ) ) logger.info('Training/evaluation parameters %s' , A ) # Prepare dataset snake_case__ : Optional[Any] = np.concatenate( [ np.loadtxt(args.data_dir , dtype=np.intaa ), ] ) snake_case__ : List[str] = (torch.from_numpy(A ),) snake_case__ : int = TensorDataset(*A ) snake_case__ : Union[str, Any] = RandomSampler(A ) snake_case__ : Any = DataLoader(A , sampler=A , batch_size=args.batch_size ) # Compute head entropy and importance score compute_heads_importance(A , A , A ) # Try head masking (set heads to zero until the score goes under a threshole) # and head pruning (remove masked heads and see the effect on the network) if args.try_masking and args.masking_threshold > 0.0 and args.masking_threshold < 1.0: snake_case__ : Dict = mask_heads(A , A , A ) prune_heads(A , A , A , A ) if __name__ == "__main__": main()
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0
'''simple docstring''' def __lowerCAmelCase ( snake_case__ ): __UpperCamelCase : int = len(snake_case__ ) for i in range(snake_case__ ): for j in range(i + 1 , snake_case__ ): if numbers[j] < numbers[i]: __UpperCamelCase : Dict = numbers[j], numbers[i] return numbers if __name__ == "__main__": _lowerCAmelCase = input('''Enter numbers separated by a comma:\n''').strip() _lowerCAmelCase = [int(item) for item in user_input.split(''',''')] print(exchange_sort(unsorted))
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import argparse import json from collections import OrderedDict from pathlib import Path import requests import torch from huggingface_hub import hf_hub_download from PIL import Image from transformers import ( SegformerConfig, SegformerForImageClassification, SegformerForSemanticSegmentation, SegformerImageProcessor, ) from transformers.utils import logging logging.set_verbosity_info() a_ :Dict = logging.get_logger(__name__) def lowercase_ (A : Optional[Any] , A : Any=False ): snake_case__ : List[Any] = OrderedDict() for key, value in state_dict.items(): if encoder_only and not key.startswith('head' ): snake_case__ : str = 'segformer.encoder.' + key if key.startswith('backbone' ): snake_case__ : str = key.replace('backbone' , 'segformer.encoder' ) if "patch_embed" in key: # replace for example patch_embed1 by patch_embeddings.0 snake_case__ : Optional[int] = key[key.find('patch_embed' ) + len('patch_embed' )] snake_case__ : int = key.replace(F'''patch_embed{idx}''' , F'''patch_embeddings.{int(A )-1}''' ) if "norm" in key: snake_case__ : Optional[int] = key.replace('norm' , 'layer_norm' ) if "segformer.encoder.layer_norm" in key: # replace for example layer_norm1 by layer_norm.0 snake_case__ : Tuple = key[key.find('segformer.encoder.layer_norm' ) + len('segformer.encoder.layer_norm' )] snake_case__ : Union[str, Any] = key.replace(F'''layer_norm{idx}''' , F'''layer_norm.{int(A )-1}''' ) if "layer_norm1" in key: snake_case__ : List[Any] = key.replace('layer_norm1' , 'layer_norm_1' ) if "layer_norm2" in key: snake_case__ : List[Any] = key.replace('layer_norm2' , 'layer_norm_2' ) if "block" in key: # replace for example block1 by block.0 snake_case__ : List[Any] = key[key.find('block' ) + len('block' )] snake_case__ : List[Any] = key.replace(F'''block{idx}''' , F'''block.{int(A )-1}''' ) if "attn.q" in key: snake_case__ : int = key.replace('attn.q' , 'attention.self.query' ) if "attn.proj" in key: snake_case__ : str = key.replace('attn.proj' , 'attention.output.dense' ) if "attn" in key: snake_case__ : Optional[int] = key.replace('attn' , 'attention.self' ) if "fc1" in key: snake_case__ : str = key.replace('fc1' , 'dense1' ) if "fc2" in key: snake_case__ : Dict = key.replace('fc2' , 'dense2' ) if "linear_pred" in key: snake_case__ : Union[str, Any] = key.replace('linear_pred' , 'classifier' ) if "linear_fuse" in key: snake_case__ : List[str] = key.replace('linear_fuse.conv' , 'linear_fuse' ) snake_case__ : List[Any] = key.replace('linear_fuse.bn' , 'batch_norm' ) if "linear_c" in key: # replace for example linear_c4 by linear_c.3 snake_case__ : Optional[int] = key[key.find('linear_c' ) + len('linear_c' )] snake_case__ : Tuple = key.replace(F'''linear_c{idx}''' , F'''linear_c.{int(A )-1}''' ) if key.startswith('head' ): snake_case__ : Tuple = key.replace('head' , 'classifier' ) snake_case__ : Optional[int] = value return new_state_dict def lowercase_ (A : Tuple , A : Optional[int] ): # for each of the encoder blocks: for i in range(config.num_encoder_blocks ): for j in range(config.depths[i] ): # read in weights + bias of keys and values (which is a single matrix in the original implementation) snake_case__ : List[str] = state_dict.pop(F'''segformer.encoder.block.{i}.{j}.attention.self.kv.weight''' ) snake_case__ : Optional[Any] = state_dict.pop(F'''segformer.encoder.block.{i}.{j}.attention.self.kv.bias''' ) # next, add keys and values (in that order) to the state dict snake_case__ : str = kv_weight[ : config.hidden_sizes[i], : ] snake_case__ : Dict = kv_bias[: config.hidden_sizes[i]] snake_case__ : List[str] = kv_weight[ config.hidden_sizes[i] :, : ] snake_case__ : List[Any] = kv_bias[ config.hidden_sizes[i] : ] def lowercase_ (): snake_case__ : Union[str, Any] = 'http://images.cocodataset.org/val2017/000000039769.jpg' snake_case__ : Dict = Image.open(requests.get(A , stream=A ).raw ) return image @torch.no_grad() def lowercase_ (A : Any , A : Union[str, Any] , A : Optional[Any] ): snake_case__ : List[str] = SegformerConfig() snake_case__ : Dict = False # set attributes based on model_name snake_case__ : Optional[int] = 'huggingface/label-files' if "segformer" in model_name: snake_case__ : str = model_name[len('segformer.' ) : len('segformer.' ) + 2] if "ade" in model_name: snake_case__ : Optional[int] = 1_5_0 snake_case__ : int = 'ade20k-id2label.json' snake_case__ : List[Any] = (1, 1_5_0, 1_2_8, 1_2_8) elif "city" in model_name: snake_case__ : str = 1_9 snake_case__ : List[str] = 'cityscapes-id2label.json' snake_case__ : Optional[Any] = (1, 1_9, 1_2_8, 1_2_8) else: raise ValueError(F'''Model {model_name} not supported''' ) elif "mit" in model_name: snake_case__ : str = True snake_case__ : Union[str, Any] = model_name[4:6] snake_case__ : Optional[Any] = 1_0_0_0 snake_case__ : Optional[int] = 'imagenet-1k-id2label.json' snake_case__ : List[Any] = (1, 1_0_0_0) else: raise ValueError(F'''Model {model_name} not supported''' ) # set config attributes snake_case__ : str = json.load(open(hf_hub_download(A , A , repo_type='dataset' ) , 'r' ) ) snake_case__ : List[Any] = {int(A ): v for k, v in idalabel.items()} snake_case__ : Union[str, Any] = idalabel snake_case__ : Tuple = {v: k for k, v in idalabel.items()} if size == "b0": pass elif size == "b1": snake_case__ : List[Any] = [6_4, 1_2_8, 3_2_0, 5_1_2] snake_case__ : Tuple = 2_5_6 elif size == "b2": snake_case__ : List[str] = [6_4, 1_2_8, 3_2_0, 5_1_2] snake_case__ : int = 7_6_8 snake_case__ : List[Any] = [3, 4, 6, 3] elif size == "b3": snake_case__ : Optional[Any] = [6_4, 1_2_8, 3_2_0, 5_1_2] snake_case__ : int = 7_6_8 snake_case__ : Optional[Any] = [3, 4, 1_8, 3] elif size == "b4": snake_case__ : str = [6_4, 1_2_8, 3_2_0, 5_1_2] snake_case__ : Optional[Any] = 7_6_8 snake_case__ : Union[str, Any] = [3, 8, 2_7, 3] elif size == "b5": snake_case__ : List[str] = [6_4, 1_2_8, 3_2_0, 5_1_2] snake_case__ : Optional[Any] = 7_6_8 snake_case__ : Any = [3, 6, 4_0, 3] else: raise ValueError(F'''Size {size} not supported''' ) # load image processor (only resize + normalize) snake_case__ : Dict = SegformerImageProcessor( image_scale=(5_1_2, 5_1_2) , keep_ratio=A , align=A , do_random_crop=A ) # prepare image snake_case__ : List[str] = prepare_img() snake_case__ : Dict = image_processor(images=A , return_tensors='pt' ).pixel_values logger.info(F'''Converting model {model_name}...''' ) # load original state dict if encoder_only: snake_case__ : Tuple = torch.load(A , map_location=torch.device('cpu' ) ) else: snake_case__ : int = torch.load(A , map_location=torch.device('cpu' ) )['state_dict'] # rename keys snake_case__ : List[Any] = rename_keys(A , encoder_only=A ) if not encoder_only: del state_dict["decode_head.conv_seg.weight"] del state_dict["decode_head.conv_seg.bias"] # key and value matrices need special treatment read_in_k_v(A , A ) # create HuggingFace model and load state dict if encoder_only: snake_case__ : str = False snake_case__ : List[Any] = SegformerForImageClassification(A ) else: snake_case__ : Dict = SegformerForSemanticSegmentation(A ) model.load_state_dict(A ) model.eval() # forward pass snake_case__ : int = model(A ) snake_case__ : Any = outputs.logits # set expected_slice based on model name # ADE20k checkpoints if model_name == "segformer.b0.512x512.ade.160k": snake_case__ : Dict = torch.tensor( [ [[-4.6310, -5.5232, -6.2356], [-5.1921, -6.1444, -6.5996], [-5.4424, -6.2790, -6.7574]], [[-12.1391, -13.3122, -13.9554], [-12.8732, -13.9352, -14.3563], [-12.9438, -13.8226, -14.2513]], [[-12.5134, -13.4686, -14.4915], [-12.8669, -14.4343, -14.7758], [-13.2523, -14.5819, -15.0694]], ] ) elif model_name == "segformer.b1.512x512.ade.160k": snake_case__ : Optional[int] = torch.tensor( [ [[-7.5820, -8.7231, -8.3215], [-8.0600, -10.3529, -10.0304], [-7.5208, -9.4103, -9.6239]], [[-12.6918, -13.8994, -13.7137], [-13.3196, -15.7523, -15.4789], [-12.9343, -14.8757, -14.9689]], [[-11.1911, -11.9421, -11.3243], [-11.3342, -13.6839, -13.3581], [-10.3909, -12.1832, -12.4858]], ] ) elif model_name == "segformer.b2.512x512.ade.160k": snake_case__ : List[Any] = torch.tensor( [ [[-11.8173, -14.3850, -16.3128], [-14.5648, -16.5804, -18.6568], [-14.7223, -15.7387, -18.4218]], [[-15.7290, -17.9171, -19.4423], [-18.3105, -19.9448, -21.4661], [-17.9296, -18.6497, -20.7910]], [[-15.0783, -17.0336, -18.2789], [-16.8771, -18.6870, -20.1612], [-16.2454, -17.1426, -19.5055]], ] ) elif model_name == "segformer.b3.512x512.ade.160k": snake_case__ : Union[str, Any] = torch.tensor( [ [[-9.0878, -10.2081, -10.1891], [-9.3144, -10.7941, -10.9843], [-9.2294, -10.3855, -10.5704]], [[-12.2316, -13.9068, -13.6102], [-12.9161, -14.3702, -14.3235], [-12.5233, -13.7174, -13.7932]], [[-14.6275, -15.2490, -14.9727], [-14.3400, -15.9687, -16.2827], [-14.1484, -15.4033, -15.8937]], ] ) elif model_name == "segformer.b4.512x512.ade.160k": snake_case__ : Dict = torch.tensor( [ [[-12.3144, -13.2447, -14.0802], [-13.3614, -14.5816, -15.6117], [-13.3340, -14.4433, -16.2219]], [[-19.2781, -20.4128, -20.7506], [-20.6153, -21.6566, -22.0998], [-19.9800, -21.0430, -22.1494]], [[-18.8739, -19.7804, -21.1834], [-20.1233, -21.6765, -23.2944], [-20.0315, -21.2641, -23.6944]], ] ) elif model_name == "segformer.b5.640x640.ade.160k": snake_case__ : List[Any] = torch.tensor( [ [[-9.5524, -12.0835, -11.7348], [-10.5229, -13.6446, -14.5662], [-9.5842, -12.8851, -13.9414]], [[-15.3432, -17.5323, -17.0818], [-16.3330, -18.9255, -19.2101], [-15.1340, -17.7848, -18.3971]], [[-12.6072, -14.9486, -14.6631], [-13.7629, -17.0907, -17.7745], [-12.7899, -16.1695, -17.1671]], ] ) # Cityscapes checkpoints elif model_name == "segformer.b0.1024x1024.city.160k": snake_case__ : str = torch.tensor( [ [[-11.9295, -13.4057, -14.8106], [-13.3431, -14.8179, -15.3781], [-14.2836, -15.5942, -16.1588]], [[-11.4906, -12.8067, -13.6564], [-13.1189, -14.0500, -14.1543], [-13.8748, -14.5136, -14.8789]], [[0.5374, 0.1067, -0.4742], [0.1141, -0.2255, -0.7099], [-0.3000, -0.5924, -1.3105]], ] ) elif model_name == "segformer.b0.512x1024.city.160k": snake_case__ : Tuple = torch.tensor( [ [[-7.8217, -9.8767, -10.1717], [-9.4438, -10.9058, -11.4047], [-9.7939, -12.3495, -12.1079]], [[-7.1514, -9.5336, -10.0860], [-9.7776, -11.6822, -11.8439], [-10.1411, -12.7655, -12.8972]], [[0.3021, 0.0805, -0.2310], [-0.0328, -0.1605, -0.2714], [-0.1408, -0.5477, -0.6976]], ] ) elif model_name == "segformer.b0.640x1280.city.160k": snake_case__ : Any = torch.tensor( [ [ [-1.1_372e01, -1.2_787e01, -1.3_477e01], [-1.2_536e01, -1.4_194e01, -1.4_409e01], [-1.3_217e01, -1.4_888e01, -1.5_327e01], ], [ [-1.4_791e01, -1.7_122e01, -1.8_277e01], [-1.7_163e01, -1.9_192e01, -1.9_533e01], [-1.7_897e01, -1.9_991e01, -2.0_315e01], ], [ [7.6_723e-01, 4.1_921e-01, -7.7_878e-02], [4.7_772e-01, 9.5_557e-03, -2.8_082e-01], [3.6_032e-01, -2.4_826e-01, -5.1_168e-01], ], ] ) elif model_name == "segformer.b0.768x768.city.160k": snake_case__ : Optional[int] = torch.tensor( [ [[-9.4959, -11.3087, -11.7479], [-11.0025, -12.6540, -12.3319], [-11.4064, -13.0487, -12.9905]], [[-9.8905, -11.3084, -12.0854], [-11.1726, -12.7698, -12.9583], [-11.5985, -13.3278, -14.1774]], [[0.2213, 0.0192, -0.2466], [-0.1731, -0.4213, -0.4874], [-0.3126, -0.6541, -1.1389]], ] ) elif model_name == "segformer.b1.1024x1024.city.160k": snake_case__ : Union[str, Any] = torch.tensor( [ [[-13.5748, -13.9111, -12.6500], [-14.3500, -15.3683, -14.2328], [-14.7532, -16.0424, -15.6087]], [[-17.1651, -15.8725, -12.9653], [-17.2580, -17.3718, -14.8223], [-16.6058, -16.8783, -16.7452]], [[-3.6456, -3.0209, -1.4203], [-3.0797, -3.1959, -2.0000], [-1.8757, -1.9217, -1.6997]], ] ) elif model_name == "segformer.b2.1024x1024.city.160k": snake_case__ : List[str] = torch.tensor( [ [[-16.0976, -16.4856, -17.3962], [-16.6234, -19.0342, -19.7685], [-16.0900, -18.0661, -19.1180]], [[-18.4750, -18.8488, -19.5074], [-19.4030, -22.1570, -22.5977], [-19.1191, -20.8486, -22.3783]], [[-4.5178, -5.5037, -6.5109], [-5.0884, -7.2174, -8.0334], [-4.4156, -5.8117, -7.2970]], ] ) elif model_name == "segformer.b3.1024x1024.city.160k": snake_case__ : List[Any] = torch.tensor( [ [[-14.2081, -14.4732, -14.1977], [-14.5867, -16.4423, -16.6356], [-13.4441, -14.9685, -16.8696]], [[-14.4576, -14.7073, -15.0451], [-15.0816, -17.6237, -17.9873], [-14.4213, -16.0199, -18.5992]], [[-4.7349, -4.9588, -5.0966], [-4.3210, -6.9325, -7.2591], [-3.4312, -4.7484, -7.1917]], ] ) elif model_name == "segformer.b4.1024x1024.city.160k": snake_case__ : str = torch.tensor( [ [[-11.7737, -11.9526, -11.3273], [-13.6692, -14.4574, -13.8878], [-13.8937, -14.6924, -15.9345]], [[-14.6706, -14.5330, -14.1306], [-16.1502, -16.8180, -16.4269], [-16.8338, -17.8939, -20.1746]], [[1.0491, 0.8289, 1.0310], [1.1044, 0.5219, 0.8055], [1.0899, 0.6926, 0.5590]], ] ) elif model_name == "segformer.b5.1024x1024.city.160k": snake_case__ : List[str] = torch.tensor( [ [[-12.5641, -13.4777, -13.0684], [-13.9587, -15.8983, -16.6557], [-13.3109, -15.7350, -16.3141]], [[-14.7074, -15.4352, -14.5944], [-16.6353, -18.1663, -18.6120], [-15.1702, -18.0329, -18.1547]], [[-1.7990, -2.0951, -1.7784], [-2.6397, -3.8245, -3.9686], [-1.5264, -2.8126, -2.9316]], ] ) else: snake_case__ : Tuple = logits.argmax(-1 ).item() print('Predicted class:' , model.config.idalabel[predicted_class_idx] ) # verify logits if not encoder_only: assert logits.shape == expected_shape assert torch.allclose(logits[0, :3, :3, :3] , A , atol=1e-2 ) # finally, save model and image processor logger.info(F'''Saving PyTorch model and image processor to {pytorch_dump_folder_path}...''' ) Path(A ).mkdir(exist_ok=A ) model.save_pretrained(A ) image_processor.save_pretrained(A ) if __name__ == "__main__": a_ :Optional[int] = argparse.ArgumentParser() parser.add_argument( "--model_name", default="segformer.b0.512x512.ade.160k", type=str, help="Name of the model you'd like to convert.", ) parser.add_argument( "--checkpoint_path", default=None, type=str, help="Path to the original PyTorch checkpoint (.pth file)." ) parser.add_argument( "--pytorch_dump_folder_path", default=None, type=str, help="Path to the folder to output PyTorch model." ) a_ :Union[str, Any] = parser.parse_args() convert_segformer_checkpoint(args.model_name, args.checkpoint_path, args.pytorch_dump_folder_path)
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import logging import os import sys import warnings from dataclasses import dataclass, field from random import randint from typing import Optional import datasets import evaluate import numpy as np from datasets import DatasetDict, load_dataset import transformers from transformers import ( AutoConfig, AutoFeatureExtractor, AutoModelForAudioClassification, HfArgumentParser, Trainer, TrainingArguments, set_seed, ) from transformers.trainer_utils import get_last_checkpoint from transformers.utils import check_min_version, send_example_telemetry from transformers.utils.versions import require_version _snake_case = logging.getLogger(__name__) # Will error if the minimal version of Transformers is not installed. Remove at your own risks. check_min_version("4.31.0") require_version("datasets>=1.14.0", "To fix: pip install -r examples/pytorch/audio-classification/requirements.txt") def lowerCAmelCase_ ( snake_case_,snake_case_,snake_case_ = 16000 ): _A : Optional[int] = int(round(sample_rate * max_length ) ) if len(snake_case_ ) <= sample_length: return wav _A : Any = randint(0,len(snake_case_ ) - sample_length - 1 ) return wav[random_offset : random_offset + sample_length] @dataclass class lowercase : _a = field(default=lowerCAmelCase_,metadata={"help": "Name of a dataset from the datasets package"} ) _a = field( default=lowerCAmelCase_,metadata={"help": "The configuration name of the dataset to use (via the datasets library)."} ) _a = field( default=lowerCAmelCase_,metadata={"help": "A file containing the training audio paths and labels."} ) _a = field( default=lowerCAmelCase_,metadata={"help": "A file containing the validation audio paths and labels."} ) _a = field( default="train",metadata={ "help": "The name of the training data set split to use (via the datasets library). Defaults to 'train'" },) _a = field( default="validation",metadata={ "help": ( "The name of the training data set split to use (via the datasets library). Defaults to 'validation'" ) },) _a = field( default="audio",metadata={"help": "The name of the dataset column containing the audio data. Defaults to 'audio'"},) _a = field( default="label",metadata={"help": "The name of the dataset column containing the labels. Defaults to 'label'"} ) _a = field( default=lowerCAmelCase_,metadata={ "help": ( "For debugging purposes or quicker training, truncate the number of training examples to this " "value if set." ) },) _a = field( default=lowerCAmelCase_,metadata={ "help": ( "For debugging purposes or quicker training, truncate the number of evaluation examples to this " "value if set." ) },) _a = field( default=2_0,metadata={"help": "Audio clips will be randomly cut to this length during training if the value is set."},) @dataclass class lowercase : _a = field( default="facebook/wav2vec2-base",metadata={"help": "Path to pretrained model or model identifier from huggingface.co/models"},) _a = field( default=lowerCAmelCase_,metadata={"help": "Pretrained config name or path if not the same as model_name"} ) _a = field( default=lowerCAmelCase_,metadata={"help": "Where do you want to store the pretrained models downloaded from the Hub"} ) _a = field( default="main",metadata={"help": "The specific model version to use (can be a branch name, tag name or commit id)."},) _a = field( default=lowerCAmelCase_,metadata={"help": "Name or path of preprocessor config."} ) _a = field( default=lowerCAmelCase_,metadata={"help": "Whether to freeze the feature encoder layers of the model."} ) _a = field( default=lowerCAmelCase_,metadata={"help": "Whether to generate an attention mask in the feature extractor."} ) _a = field( default=lowerCAmelCase_,metadata={ "help": ( "Will use the token generated when running `huggingface-cli login` (necessary to use this script " "with private models)." ) },) _a = field( default=lowerCAmelCase_,metadata={"help": "Whether to freeze the feature extractor layers of the model."} ) _a = field( default=lowerCAmelCase_,metadata={"help": "Will enable to load a pretrained model whose head dimensions are different."},) def a__ ( self ) -> str: if not self.freeze_feature_extractor and self.freeze_feature_encoder: warnings.warn( """The argument `--freeze_feature_extractor` is deprecated and """ """will be removed in a future version. Use `--freeze_feature_encoder`""" """instead. Setting `freeze_feature_encoder==True`.""" , _snake_case , ) if self.freeze_feature_extractor and not self.freeze_feature_encoder: raise ValueError( """The argument `--freeze_feature_extractor` is deprecated and """ """should not be used in combination with `--freeze_feature_encoder`.""" """Only make use of `--freeze_feature_encoder`.""" ) def lowerCAmelCase_ ( ): # See all possible arguments in src/transformers/training_args.py # or by passing the --help flag to this script. # We now keep distinct sets of args, for a cleaner separation of concerns. _A : Optional[int] = HfArgumentParser((ModelArguments, DataTrainingArguments, TrainingArguments) ) if len(sys.argv ) == 2 and sys.argv[1].endswith(""".json""" ): # If we pass only one argument to the script and it's the path to a json file, # let's parse it to get our arguments. _A : Dict = parser.parse_json_file(json_file=os.path.abspath(sys.argv[1] ) ) else: _A : str = parser.parse_args_into_dataclasses() # Sending telemetry. Tracking the example usage helps us better allocate resources to maintain them. The # information sent is the one passed as arguments along with your Python/PyTorch versions. send_example_telemetry("""run_audio_classification""",snake_case_,snake_case_ ) # Setup logging logging.basicConfig( format="""%(asctime)s - %(levelname)s - %(name)s - %(message)s""",datefmt="""%m/%d/%Y %H:%M:%S""",handlers=[logging.StreamHandler(sys.stdout )],) if training_args.should_log: # The default of training_args.log_level is passive, so we set log level at info here to have that default. transformers.utils.logging.set_verbosity_info() _A : Optional[Any] = training_args.get_process_log_level() logger.setLevel(snake_case_ ) transformers.utils.logging.set_verbosity(snake_case_ ) transformers.utils.logging.enable_default_handler() transformers.utils.logging.enable_explicit_format() # Log on each process the small summary: logger.warning( f'''Process rank: {training_args.local_rank}, device: {training_args.device}, n_gpu: {training_args.n_gpu} ''' + f'''distributed training: {bool(training_args.local_rank != -1 )}, 16-bits training: {training_args.fpaa}''' ) logger.info(f'''Training/evaluation parameters {training_args}''' ) # Set seed before initializing model. set_seed(training_args.seed ) # Detecting last checkpoint. _A : Dict = None if os.path.isdir(training_args.output_dir ) and training_args.do_train and not training_args.overwrite_output_dir: _A : Optional[int] = get_last_checkpoint(training_args.output_dir ) if last_checkpoint is None and len(os.listdir(training_args.output_dir ) ) > 0: raise ValueError( f'''Output directory ({training_args.output_dir}) already exists and is not empty. ''' """Use --overwrite_output_dir to train from scratch.""" ) elif last_checkpoint is not None and training_args.resume_from_checkpoint is None: logger.info( f'''Checkpoint detected, resuming training at {last_checkpoint}. To avoid this behavior, change ''' """the `--output_dir` or add `--overwrite_output_dir` to train from scratch.""" ) # Initialize our dataset and prepare it for the audio classification task. _A : Dict = DatasetDict() _A : Tuple = load_dataset( data_args.dataset_name,data_args.dataset_config_name,split=data_args.train_split_name,use_auth_token=True if model_args.use_auth_token else None,) _A : Optional[int] = load_dataset( data_args.dataset_name,data_args.dataset_config_name,split=data_args.eval_split_name,use_auth_token=True if model_args.use_auth_token else None,) if data_args.audio_column_name not in raw_datasets["train"].column_names: raise ValueError( f'''--audio_column_name {data_args.audio_column_name} not found in dataset \'{data_args.dataset_name}\'. ''' """Make sure to set `--audio_column_name` to the correct audio column - one of """ f'''{", ".join(raw_datasets["train"].column_names )}.''' ) if data_args.label_column_name not in raw_datasets["train"].column_names: raise ValueError( f'''--label_column_name {data_args.label_column_name} not found in dataset \'{data_args.dataset_name}\'. ''' """Make sure to set `--label_column_name` to the correct text column - one of """ f'''{", ".join(raw_datasets["train"].column_names )}.''' ) # Setting `return_attention_mask=True` is the way to get a correctly masked mean-pooling over # transformer outputs in the classifier, but it doesn't always lead to better accuracy _A : Optional[Any] = AutoFeatureExtractor.from_pretrained( model_args.feature_extractor_name or model_args.model_name_or_path,return_attention_mask=model_args.attention_mask,cache_dir=model_args.cache_dir,revision=model_args.model_revision,use_auth_token=True if model_args.use_auth_token else None,) # `datasets` takes care of automatically loading and resampling the audio, # so we just need to set the correct target sampling rate. _A : List[str] = raw_datasets.cast_column( data_args.audio_column_name,datasets.features.Audio(sampling_rate=feature_extractor.sampling_rate ) ) _A : Union[str, Any] = feature_extractor.model_input_names[0] def train_transforms(snake_case_ ): _A : Optional[Any] = [] for audio in batch[data_args.audio_column_name]: _A : List[Any] = random_subsample( audio["""array"""],max_length=data_args.max_length_seconds,sample_rate=feature_extractor.sampling_rate ) subsampled_wavs.append(snake_case_ ) _A : Optional[int] = feature_extractor(snake_case_,sampling_rate=feature_extractor.sampling_rate ) _A : Optional[int] = {model_input_name: inputs.get(snake_case_ )} _A : Any = list(batch[data_args.label_column_name] ) return output_batch def val_transforms(snake_case_ ): _A : Optional[Any] = [audio['array'] for audio in batch[data_args.audio_column_name]] _A : Union[str, Any] = feature_extractor(snake_case_,sampling_rate=feature_extractor.sampling_rate ) _A : List[str] = {model_input_name: inputs.get(snake_case_ )} _A : List[str] = list(batch[data_args.label_column_name] ) return output_batch # Prepare label mappings. # We'll include these in the model's config to get human readable labels in the Inference API. _A : Dict = raw_datasets['train'].features[data_args.label_column_name].names _A : Tuple = {}, {} for i, label in enumerate(snake_case_ ): _A : Tuple = str(snake_case_ ) _A : List[str] = label # Load the accuracy metric from the datasets package _A : Union[str, Any] = evaluate.load("""accuracy""" ) # Define our compute_metrics function. It takes an `EvalPrediction` object (a namedtuple with # `predictions` and `label_ids` fields) and has to return a dictionary string to float. def compute_metrics(snake_case_ ): _A : Tuple = np.argmax(eval_pred.predictions,axis=1 ) return metric.compute(predictions=snake_case_,references=eval_pred.label_ids ) _A : List[str] = AutoConfig.from_pretrained( model_args.config_name or model_args.model_name_or_path,num_labels=len(snake_case_ ),labelaid=snake_case_,idalabel=snake_case_,finetuning_task="""audio-classification""",cache_dir=model_args.cache_dir,revision=model_args.model_revision,use_auth_token=True if model_args.use_auth_token else None,) _A : Any = AutoModelForAudioClassification.from_pretrained( model_args.model_name_or_path,from_tf=bool(""".ckpt""" in model_args.model_name_or_path ),config=snake_case_,cache_dir=model_args.cache_dir,revision=model_args.model_revision,use_auth_token=True if model_args.use_auth_token else None,ignore_mismatched_sizes=model_args.ignore_mismatched_sizes,) # freeze the convolutional waveform encoder if model_args.freeze_feature_encoder: model.freeze_feature_encoder() if training_args.do_train: if data_args.max_train_samples is not None: _A : Dict = ( raw_datasets['train'].shuffle(seed=training_args.seed ).select(range(data_args.max_train_samples ) ) ) # Set the training transforms raw_datasets["train"].set_transform(snake_case_,output_all_columns=snake_case_ ) if training_args.do_eval: if data_args.max_eval_samples is not None: _A : List[Any] = ( raw_datasets['eval'].shuffle(seed=training_args.seed ).select(range(data_args.max_eval_samples ) ) ) # Set the validation transforms raw_datasets["eval"].set_transform(snake_case_,output_all_columns=snake_case_ ) # Initialize our trainer _A : Dict = Trainer( model=snake_case_,args=snake_case_,train_dataset=raw_datasets["""train"""] if training_args.do_train else None,eval_dataset=raw_datasets["""eval"""] if training_args.do_eval else None,compute_metrics=snake_case_,tokenizer=snake_case_,) # Training if training_args.do_train: _A : Tuple = None if training_args.resume_from_checkpoint is not None: _A : Any = training_args.resume_from_checkpoint elif last_checkpoint is not None: _A : Optional[Any] = last_checkpoint _A : int = trainer.train(resume_from_checkpoint=snake_case_ ) trainer.save_model() trainer.log_metrics("""train""",train_result.metrics ) trainer.save_metrics("""train""",train_result.metrics ) trainer.save_state() # Evaluation if training_args.do_eval: _A : int = trainer.evaluate() trainer.log_metrics("""eval""",snake_case_ ) trainer.save_metrics("""eval""",snake_case_ ) # Write model card and (optionally) push to hub _A : Any = { 'finetuned_from': model_args.model_name_or_path, 'tasks': 'audio-classification', 'dataset': data_args.dataset_name, 'tags': ['audio-classification'], } if training_args.push_to_hub: trainer.push_to_hub(**snake_case_ ) else: trainer.create_model_card(**snake_case_ ) if __name__ == "__main__": main()
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import argparse import json import os import fairseq import torch from fairseq.data import Dictionary from transformers import ( WavaVecaConfig, WavaVecaCTCTokenizer, WavaVecaFeatureExtractor, WavaVecaForCTC, WavaVecaForPreTraining, WavaVecaProcessor, logging, ) from transformers.models.wavaveca.modeling_wavaveca import WavaVecaForSequenceClassification logging.set_verbosity_info() a_ :List[Any] = logging.get_logger(__name__) a_ :List[Any] = { "post_extract_proj": "feature_projection.projection", "encoder.pos_conv.0": "encoder.pos_conv_embed.conv", "self_attn.k_proj": "encoder.layers.*.attention.k_proj", "self_attn.v_proj": "encoder.layers.*.attention.v_proj", "self_attn.q_proj": "encoder.layers.*.attention.q_proj", "self_attn.out_proj": "encoder.layers.*.attention.out_proj", "self_attn_layer_norm": "encoder.layers.*.layer_norm", "fc1": "encoder.layers.*.feed_forward.intermediate_dense", "fc2": "encoder.layers.*.feed_forward.output_dense", "final_layer_norm": "encoder.layers.*.final_layer_norm", "encoder.layer_norm": "encoder.layer_norm", "adapter_layer": "encoder.layers.*.adapter_layer", "w2v_model.layer_norm": "feature_projection.layer_norm", "quantizer.weight_proj": "quantizer.weight_proj", "quantizer.vars": "quantizer.codevectors", "project_q": "project_q", "final_proj": "project_hid", "w2v_encoder.proj": "lm_head", "mask_emb": "masked_spec_embed", "pooling_layer.linear": "projector", "pooling_layer.projection": "classifier", } a_ :List[Any] = [ "lm_head", "quantizer.weight_proj", "quantizer.codevectors", "project_q", "project_hid", "projector", "classifier", ] def lowercase_ (A : Dict ): snake_case__ : Optional[Any] = {} with open(A , 'r' ) as file: for line_number, line in enumerate(A ): snake_case__ : Dict = line.strip() if line: snake_case__ : int = line.split() snake_case__ : List[str] = line_number snake_case__ : Dict = words[0] snake_case__ : Optional[Any] = value return result def lowercase_ (A : int , A : int , A : Optional[int] , A : Optional[Any] , A : Tuple ): for attribute in key.split('.' ): snake_case__ : Optional[int] = getattr(A , A ) snake_case__ : Union[str, Any] = None for param_key in PARAM_MAPPING.keys(): if full_name.endswith(A ): snake_case__ : List[str] = PARAM_MAPPING[full_name.split('.' )[-1]] snake_case__ : Dict = 'param' if weight_type is not None and weight_type != "param": snake_case__ : Union[str, Any] = getattr(A , A ).shape elif weight_type is not None and weight_type == "param": snake_case__ : Optional[int] = hf_pointer for attribute in hf_param_name.split('.' ): snake_case__ : Optional[Any] = getattr(A , A ) snake_case__ : Dict = shape_pointer.shape # let's reduce dimension snake_case__ : List[Any] = value[0] else: snake_case__ : Union[str, Any] = hf_pointer.shape if hf_shape != value.shape: raise ValueError( F'''Shape of hf {key + "." + weight_type if weight_type is not None else ""} is {hf_shape}, but should be''' F''' {value.shape} for {full_name}''' ) if weight_type == "weight": snake_case__ : Any = value elif weight_type == "weight_g": snake_case__ : List[Any] = value elif weight_type == "weight_v": snake_case__ : Any = value elif weight_type == "bias": snake_case__ : List[Any] = value elif weight_type == "param": for attribute in hf_param_name.split('.' ): snake_case__ : int = getattr(A , A ) snake_case__ : Optional[int] = value else: snake_case__ : Optional[Any] = value logger.info(F'''{key + "." + weight_type if weight_type is not None else ""} was initialized from {full_name}.''' ) def lowercase_ (A : Tuple , A : List[Any] , A : int , A : str , A : Tuple ): snake_case__ : Optional[int] = None for param_key in PARAM_MAPPING.keys(): if full_name.endswith(A ): snake_case__ : List[str] = PARAM_MAPPING[full_name.split('.' )[-1]] snake_case__ : str = 'param' if weight_type is not None and weight_type != "param": snake_case__ : int = '.'.join([key, weight_type] ) elif weight_type is not None and weight_type == "param": snake_case__ : Any = '.'.join([key, hf_param_name] ) else: snake_case__ : Dict = key snake_case__ : List[str] = value if 'lm_head' in full_key else value[0] a_ :List[str] = { "W_a": "linear_1.weight", "W_b": "linear_2.weight", "b_a": "linear_1.bias", "b_b": "linear_2.bias", "ln_W": "norm.weight", "ln_b": "norm.bias", } def lowercase_ (A : str , A : Optional[Any] , A : Optional[Any]=None , A : List[str]=None ): snake_case__ : Optional[int] = False for key, mapped_key in MAPPING.items(): snake_case__ : Tuple = 'wav2vec2.' + mapped_key if mapped_key not in TOP_LEVEL_KEYS else mapped_key if key in name or key.split('w2v_model.' )[-1] == name.split('.' )[0]: snake_case__ : Optional[int] = True if "*" in mapped_key: snake_case__ : List[Any] = name.split(A )[0].split('.' )[-2] snake_case__ : Union[str, Any] = mapped_key.replace('*' , A ) if "weight_g" in name: snake_case__ : Tuple = 'weight_g' elif "weight_v" in name: snake_case__ : List[str] = 'weight_v' elif "bias" in name: snake_case__ : Dict = 'bias' elif "weight" in name: # TODO: don't match quantizer.weight_proj snake_case__ : Optional[int] = 'weight' else: snake_case__ : str = None if hf_dict is not None: rename_dict(A , A , A , A , A ) else: set_recursively(A , A , A , A , A ) return is_used return is_used def lowercase_ (A : Optional[Any] , A : Dict , A : Optional[int] ): snake_case__ : Dict = [] snake_case__ : Tuple = fairseq_model.state_dict() snake_case__ : str = hf_model.wavaveca.feature_extractor for name, value in fairseq_dict.items(): snake_case__ : str = False if "conv_layers" in name: load_conv_layer( A , A , A , A , hf_model.config.feat_extract_norm == 'group' , ) snake_case__ : Any = True else: snake_case__ : Dict = load_wavaveca_layer(A , A , A ) if not is_used: unused_weights.append(A ) logger.warning(F'''Unused weights: {unused_weights}''' ) def lowercase_ (A : Dict , A : Optional[Any] , A : Tuple , A : str , A : List[str] ): snake_case__ : List[Any] = full_name.split('conv_layers.' )[-1] snake_case__ : List[str] = name.split('.' ) snake_case__ : List[Any] = int(items[0] ) snake_case__ : str = int(items[1] ) if type_id == 0: if "bias" in name: if value.shape != feature_extractor.conv_layers[layer_id].conv.bias.data.shape: raise ValueError( F'''{full_name} has size {value.shape}, but''' F''' {feature_extractor.conv_layers[layer_id].conv.bias.data.shape} was found.''' ) snake_case__ : Any = value logger.info(F'''Feat extract conv layer {layer_id} was initialized from {full_name}.''' ) elif "weight" in name: if value.shape != feature_extractor.conv_layers[layer_id].conv.weight.data.shape: raise ValueError( F'''{full_name} has size {value.shape}, but''' F''' {feature_extractor.conv_layers[layer_id].conv.weight.data.shape} was found.''' ) snake_case__ : str = value logger.info(F'''Feat extract conv layer {layer_id} was initialized from {full_name}.''' ) elif (type_id == 2 and not use_group_norm) or (type_id == 2 and layer_id == 0 and use_group_norm): if "bias" in name: if value.shape != feature_extractor.conv_layers[layer_id].layer_norm.bias.data.shape: raise ValueError( F'''{full_name} has size {value.shape}, but''' F''' {feature_extractor.conv_layers[layer_id].layer_norm.bias.data.shape} was found.''' ) snake_case__ : str = value logger.info(F'''Feat extract layer norm weight of layer {layer_id} was initialized from {full_name}.''' ) elif "weight" in name: if value.shape != feature_extractor.conv_layers[layer_id].layer_norm.weight.data.shape: raise ValueError( F'''{full_name} has size {value.shape}, but''' F''' {feature_extractor.conv_layers[layer_id].layer_norm.weight.data.shape} was found.''' ) snake_case__ : int = value logger.info(F'''Feat extract layer norm weight of layer {layer_id} was initialized from {full_name}.''' ) else: unused_weights.append(A ) @torch.no_grad() def lowercase_ (A : Union[str, Any] , A : str , A : Tuple=None , A : List[str]=None , A : Any=True , A : Optional[int]=False ): if config_path is not None: snake_case__ : List[Any] = WavaVecaConfig.from_pretrained(A ) else: snake_case__ : List[Any] = WavaVecaConfig() if is_seq_class: snake_case__ : Dict = read_txt_into_dict(A ) snake_case__ : Any = idalabel snake_case__ : Union[str, Any] = WavaVecaForSequenceClassification(A ) snake_case__ : Any = WavaVecaFeatureExtractor( feature_size=1 , sampling_rate=1_6_0_0_0 , padding_value=0 , do_normalize=A , return_attention_mask=A , ) feature_extractor.save_pretrained(A ) elif is_finetuned: if dict_path: snake_case__ : str = Dictionary.load(A ) # important change bos & pad token id since CTC symbol is <pad> and # not <s> as in fairseq snake_case__ : List[str] = target_dict.pad_index snake_case__ : Optional[int] = target_dict.bos_index snake_case__ : Optional[int] = target_dict.eos_index snake_case__ : List[Any] = len(target_dict.symbols ) snake_case__ : str = os.path.join(A , 'vocab.json' ) if not os.path.isdir(A ): logger.error('--pytorch_dump_folder_path ({}) should be a directory'.format(A ) ) return os.makedirs(A , exist_ok=A ) snake_case__ : Optional[Any] = target_dict.indices # fairseq has the <pad> and <s> switched snake_case__ : Optional[Any] = 0 snake_case__ : Union[str, Any] = 1 with open(A , 'w' , encoding='utf-8' ) as vocab_handle: json.dump(A , A ) snake_case__ : List[Any] = WavaVecaCTCTokenizer( A , unk_token=target_dict.unk_word , pad_token=target_dict.pad_word , bos_token=target_dict.bos_word , eos_token=target_dict.eos_word , word_delimiter_token='|' , do_lower_case=A , ) snake_case__ : str = True if config.feat_extract_norm == 'layer' else False snake_case__ : Optional[Any] = WavaVecaFeatureExtractor( feature_size=1 , sampling_rate=1_6_0_0_0 , padding_value=0 , do_normalize=A , return_attention_mask=A , ) snake_case__ : Union[str, Any] = WavaVecaProcessor(feature_extractor=A , tokenizer=A ) processor.save_pretrained(A ) snake_case__ : str = WavaVecaForCTC(A ) else: snake_case__ : int = WavaVecaForPreTraining(A ) if is_finetuned or is_seq_class: snake_case__ , snake_case__ , snake_case__ : str = fairseq.checkpoint_utils.load_model_ensemble_and_task( [checkpoint_path] , arg_overrides={'data': '/'.join(dict_path.split('/' )[:-1] )} ) else: snake_case__ : Tuple = argparse.Namespace(task='audio_pretraining' ) snake_case__ : str = fairseq.tasks.setup_task(A ) snake_case__ , snake_case__ , snake_case__ : Any = fairseq.checkpoint_utils.load_model_ensemble_and_task([checkpoint_path] , task=A ) snake_case__ : List[Any] = model[0].eval() recursively_load_weights(A , A , not is_finetuned ) hf_wavavec.save_pretrained(A ) if __name__ == "__main__": a_ :List[Any] = argparse.ArgumentParser() parser.add_argument("--pytorch_dump_folder_path", default=None, type=str, help="Path to the output PyTorch model.") parser.add_argument("--checkpoint_path", default=None, type=str, help="Path to fairseq checkpoint") parser.add_argument("--dict_path", default=None, type=str, help="Path to dict of fine-tuned model") parser.add_argument("--config_path", default=None, type=str, help="Path to hf config.json of model to convert") parser.add_argument( "--not_finetuned", action="store_true", help="Whether the model to convert is a fine-tuned model or not" ) parser.add_argument( "--is_seq_class", action="store_true", help="Whether the model to convert is a fine-tuned sequence classification model or not", ) a_ :str = parser.parse_args() a_ :Tuple = not args.not_finetuned and not args.is_seq_class convert_wavaveca_checkpoint( args.checkpoint_path, args.pytorch_dump_folder_path, args.config_path, args.dict_path, is_finetuned, args.is_seq_class, )
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from math import factorial, radians def A ( _UpperCAmelCase : float , _UpperCAmelCase : int = 18 , _UpperCAmelCase : int = 10 ) -> str: '''simple docstring''' _UpperCAmelCase = angle_in_degrees - ((angle_in_degrees // 360.0) * 360.0) # Converting from degrees to radians _UpperCAmelCase = radians(_UpperCAmelCase ) _UpperCAmelCase = angle_in_radians _UpperCAmelCase = 3 _UpperCAmelCase = -1 for _ in range(_UpperCAmelCase ): result += (b * (angle_in_radians**a)) / factorial(_UpperCAmelCase ) _UpperCAmelCase = -b # One positive term and the next will be negative and so on... a += 2 # Increased by 2 for every term. return round(_UpperCAmelCase , _UpperCAmelCase ) if __name__ == "__main__": __import__("doctest").testmod()
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from typing import Dict, List from nltk.translate import gleu_score import datasets from datasets import MetricInfo a_ :Any = "\\n@misc{wu2016googles,\n title={Google's Neural Machine Translation System: Bridging the Gap between Human and Machine Translation},\n author={Yonghui Wu and Mike Schuster and Zhifeng Chen and Quoc V. Le and Mohammad Norouzi and Wolfgang Macherey\n and Maxim Krikun and Yuan Cao and Qin Gao and Klaus Macherey and Jeff Klingner and Apurva Shah and Melvin\n Johnson and Xiaobing Liu and Łukasz Kaiser and Stephan Gouws and Yoshikiyo Kato and Taku Kudo and Hideto\n Kazawa and Keith Stevens and George Kurian and Nishant Patil and Wei Wang and Cliff Young and\n Jason Smith and Jason Riesa and Alex Rudnick and Oriol Vinyals and Greg Corrado and Macduff Hughes\n and Jeffrey Dean},\n year={2016},\n eprint={1609.08144},\n archivePrefix={arXiv},\n primaryClass={cs.CL}\n}\n" a_ :List[str] = "\\nThe BLEU score has some undesirable properties when used for single\nsentences, as it was designed to be a corpus measure. We therefore\nuse a slightly different score for our RL experiments which we call\nthe 'GLEU score'. For the GLEU score, we record all sub-sequences of\n1, 2, 3 or 4 tokens in output and target sequence (n-grams). We then\ncompute a recall, which is the ratio of the number of matching n-grams\nto the number of total n-grams in the target (ground truth) sequence,\nand a precision, which is the ratio of the number of matching n-grams\nto the number of total n-grams in the generated output sequence. Then\nGLEU score is simply the minimum of recall and precision. This GLEU\nscore's range is always between 0 (no matches) and 1 (all match) and\nit is symmetrical when switching output and target. According to\nour experiments, GLEU score correlates quite well with the BLEU\nmetric on a corpus level but does not have its drawbacks for our per\nsentence reward objective.\n" a_ :List[str] = "\\nComputes corpus-level Google BLEU (GLEU) score of translated segments against one or more references.\nInstead of averaging the sentence level GLEU scores (i.e. macro-average precision), Wu et al. (2016) sum up the matching\ntokens and the max of hypothesis and reference tokens for each sentence, then compute using the aggregate values.\n\nArgs:\n predictions (list of str): list of translations to score.\n Each translation should be tokenized into a list of tokens.\n references (list of list of str): list of lists of references for each translation.\n Each reference should be tokenized into a list of tokens.\n min_len (int): The minimum order of n-gram this function should extract. Defaults to 1.\n max_len (int): The maximum order of n-gram this function should extract. Defaults to 4.\n\nReturns:\n 'google_bleu': google_bleu score\n\nExamples:\n Example 1:\n >>> hyp1 = ['It', 'is', 'a', 'guide', 'to', 'action', 'which',\n ... 'ensures', 'that', 'the', 'rubber', 'duck', 'always',\n ... 'disobeys', 'the', 'commands', 'of', 'the', 'cat']\n >>> ref1a = ['It', 'is', 'the', 'guiding', 'principle', 'which',\n ... 'guarantees', 'the', 'rubber', 'duck', 'forces', 'never',\n ... 'being', 'under', 'the', 'command', 'of', 'the', 'cat']\n\n >>> hyp2 = ['he', 'read', 'the', 'book', 'because', 'he', 'was',\n ... 'interested', 'in', 'world', 'history']\n >>> ref2a = ['he', 'was', 'interested', 'in', 'world', 'history',\n ... 'because', 'he', 'read', 'the', 'book']\n\n >>> list_of_references = [[ref1a], [ref2a]]\n >>> hypotheses = [hyp1, hyp2]\n >>> google_bleu = datasets.load_metric(\"google_bleu\")\n >>> results = google_bleu.compute(predictions=hypotheses, references=list_of_references)\n >>> print(round(results[\"google_bleu\"], 2))\n 0.44\n\n Example 2:\n >>> hyp1 = ['It', 'is', 'a', 'guide', 'to', 'action', 'which',\n ... 'ensures', 'that', 'the', 'rubber', 'duck', 'always',\n ... 'disobeys', 'the', 'commands', 'of', 'the', 'cat']\n >>> ref1a = ['It', 'is', 'the', 'guiding', 'principle', 'which',\n ... 'guarantees', 'the', 'rubber', 'duck', 'forces', 'never',\n ... 'being', 'under', 'the', 'command', 'of', 'the', 'cat']\n >>> ref1b = ['It', 'is', 'a', 'guide', 'to', 'action', 'that',\n ... 'ensures', 'that', 'the', 'rubber', 'duck', 'will', 'never',\n ... 'heed', 'the', 'cat', 'commands']\n >>> ref1c = ['It', 'is', 'the', 'practical', 'guide', 'for', 'the',\n ... 'rubber', 'duck', 'army', 'never', 'to', 'heed', 'the', 'directions',\n ... 'of', 'the', 'cat']\n\n >>> hyp2 = ['he', 'read', 'the', 'book', 'because', 'he', 'was',\n ... 'interested', 'in', 'world', 'history']\n >>> ref2a = ['he', 'was', 'interested', 'in', 'world', 'history',\n ... 'because', 'he', 'read', 'the', 'book']\n\n >>> list_of_references = [[ref1a, ref1b, ref1c], [ref2a]]\n >>> hypotheses = [hyp1, hyp2]\n >>> google_bleu = datasets.load_metric(\"google_bleu\")\n >>> results = google_bleu.compute(predictions=hypotheses, references=list_of_references)\n >>> print(round(results[\"google_bleu\"], 2))\n 0.61\n\n Example 3:\n >>> hyp1 = ['It', 'is', 'a', 'guide', 'to', 'action', 'which',\n ... 'ensures', 'that', 'the', 'rubber', 'duck', 'always',\n ... 'disobeys', 'the', 'commands', 'of', 'the', 'cat']\n >>> ref1a = ['It', 'is', 'the', 'guiding', 'principle', 'which',\n ... 'guarantees', 'the', 'rubber', 'duck', 'forces', 'never',\n ... 'being', 'under', 'the', 'command', 'of', 'the', 'cat']\n >>> ref1b = ['It', 'is', 'a', 'guide', 'to', 'action', 'that',\n ... 'ensures', 'that', 'the', 'rubber', 'duck', 'will', 'never',\n ... 'heed', 'the', 'cat', 'commands']\n >>> ref1c = ['It', 'is', 'the', 'practical', 'guide', 'for', 'the',\n ... 'rubber', 'duck', 'army', 'never', 'to', 'heed', 'the', 'directions',\n ... 'of', 'the', 'cat']\n\n >>> hyp2 = ['he', 'read', 'the', 'book', 'because', 'he', 'was',\n ... 'interested', 'in', 'world', 'history']\n >>> ref2a = ['he', 'was', 'interested', 'in', 'world', 'history',\n ... 'because', 'he', 'read', 'the', 'book']\n\n >>> list_of_references = [[ref1a, ref1b, ref1c], [ref2a]]\n >>> hypotheses = [hyp1, hyp2]\n >>> google_bleu = datasets.load_metric(\"google_bleu\")\n >>> results = google_bleu.compute(predictions=hypotheses, references=list_of_references, min_len=2)\n >>> print(round(results[\"google_bleu\"], 2))\n 0.53\n\n Example 4:\n >>> hyp1 = ['It', 'is', 'a', 'guide', 'to', 'action', 'which',\n ... 'ensures', 'that', 'the', 'rubber', 'duck', 'always',\n ... 'disobeys', 'the', 'commands', 'of', 'the', 'cat']\n >>> ref1a = ['It', 'is', 'the', 'guiding', 'principle', 'which',\n ... 'guarantees', 'the', 'rubber', 'duck', 'forces', 'never',\n ... 'being', 'under', 'the', 'command', 'of', 'the', 'cat']\n >>> ref1b = ['It', 'is', 'a', 'guide', 'to', 'action', 'that',\n ... 'ensures', 'that', 'the', 'rubber', 'duck', 'will', 'never',\n ... 'heed', 'the', 'cat', 'commands']\n >>> ref1c = ['It', 'is', 'the', 'practical', 'guide', 'for', 'the',\n ... 'rubber', 'duck', 'army', 'never', 'to', 'heed', 'the', 'directions',\n ... 'of', 'the', 'cat']\n\n >>> hyp2 = ['he', 'read', 'the', 'book', 'because', 'he', 'was',\n ... 'interested', 'in', 'world', 'history']\n >>> ref2a = ['he', 'was', 'interested', 'in', 'world', 'history',\n ... 'because', 'he', 'read', 'the', 'book']\n\n >>> list_of_references = [[ref1a, ref1b, ref1c], [ref2a]]\n >>> hypotheses = [hyp1, hyp2]\n >>> google_bleu = datasets.load_metric(\"google_bleu\")\n >>> results = google_bleu.compute(predictions=hypotheses,references=list_of_references, min_len=2, max_len=6)\n >>> print(round(results[\"google_bleu\"], 2))\n 0.4\n" @datasets.utils.file_utils.add_start_docstrings(_DESCRIPTION , _KWARGS_DESCRIPTION ) class snake_case__ ( datasets.Metric ): """simple docstring""" def lowercase_ ( self : str ) ->MetricInfo: return datasets.MetricInfo( description=_DESCRIPTION, citation=_CITATION, inputs_description=_KWARGS_DESCRIPTION, features=datasets.Features( { 'predictions': datasets.Sequence(datasets.Value('string', id='token' ), id='sequence' ), 'references': datasets.Sequence( datasets.Sequence(datasets.Value('string', id='token' ), id='sequence' ), id='references' ), } ), ) def lowercase_ ( self : str, _snake_case : List[List[List[str]]], _snake_case : List[List[str]], _snake_case : int = 1, _snake_case : int = 4, ) ->Dict[str, float]: return { "google_bleu": gleu_score.corpus_gleu( list_of_references=_snake_case, hypotheses=_snake_case, min_len=_snake_case, max_len=_snake_case ) }
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from math import factorial def __UpperCAmelCase ( a_ , a_ , a_): if successes > trials: raise ValueError('successes must be lower or equal to trials') if trials < 0 or successes < 0: raise ValueError('the function is defined for non-negative integers') if not isinstance(a_ , a_) or not isinstance(a_ , a_): raise ValueError('the function is defined for non-negative integers') if not 0 < prob < 1: raise ValueError('prob has to be in range of 1 - 0') snake_case_ = (prob**successes) * ((1 - prob) ** (trials - successes)) # Calculate the binomial coefficient: n! / k!(n-k)! snake_case_ = float(factorial(a_)) coefficient /= factorial(a_) * factorial(trials - successes) return probability * coefficient if __name__ == "__main__": from doctest import testmod testmod() print("Probability of 2 successes out of 4 trails") print("with probability of 0.75 is:", end=" ") print(binomial_distribution(2, 4, 0.75))
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from math import factorial def lowercase_ (A : int , A : int , A : float ): if successes > trials: raise ValueError('successes must be lower or equal to trials' ) if trials < 0 or successes < 0: raise ValueError('the function is defined for non-negative integers' ) if not isinstance(A , A ) or not isinstance(A , A ): raise ValueError('the function is defined for non-negative integers' ) if not 0 < prob < 1: raise ValueError('prob has to be in range of 1 - 0' ) snake_case__ : List[Any] = (prob**successes) * ((1 - prob) ** (trials - successes)) # Calculate the binomial coefficient: n! / k!(n-k)! snake_case__ : List[str] = float(factorial(A ) ) coefficient /= factorial(A ) * factorial(trials - successes ) return probability * coefficient if __name__ == "__main__": from doctest import testmod testmod() print("Probability of 2 successes out of 4 trails") print("with probability of 0.75 is:", end=" ") print(binomial_distribution(2, 4, 0.75))
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"""simple docstring""" import os import unittest from transformers import BertTokenizerFast from transformers.models.bert.tokenization_bert import ( VOCAB_FILES_NAMES, BasicTokenizer, BertTokenizer, WordpieceTokenizer, _is_control, _is_punctuation, _is_whitespace, ) from transformers.testing_utils import require_tokenizers, slow from ...test_tokenization_common import TokenizerTesterMixin, filter_non_english @require_tokenizers class lowerCAmelCase ( lowerCAmelCase_ , unittest.TestCase ): '''simple docstring''' SCREAMING_SNAKE_CASE_ : Any = BertTokenizer SCREAMING_SNAKE_CASE_ : Optional[int] = BertTokenizerFast SCREAMING_SNAKE_CASE_ : Optional[Any] = True SCREAMING_SNAKE_CASE_ : Tuple = True SCREAMING_SNAKE_CASE_ : int = filter_non_english def __A ( self ) -> Any: super().setUp() SCREAMING_SNAKE_CASE = [ '[UNK]', '[CLS]', '[SEP]', '[PAD]', '[MASK]', 'want', '##want', '##ed', 'wa', 'un', 'runn', '##ing', ',', 'low', 'lowest', ] SCREAMING_SNAKE_CASE = os.path.join(self.tmpdirname , VOCAB_FILES_NAMES['vocab_file'] ) with open(self.vocab_file , 'w' , encoding='utf-8' ) as vocab_writer: vocab_writer.write(''.join([x + '\n' for x in vocab_tokens] ) ) def __A ( self , lowerCAmelCase__ ) -> str: SCREAMING_SNAKE_CASE = 'UNwant\u00E9d,running' SCREAMING_SNAKE_CASE = 'unwanted, running' return input_text, output_text def __A ( self ) -> Dict: SCREAMING_SNAKE_CASE = self.tokenizer_class(self.vocab_file ) SCREAMING_SNAKE_CASE = tokenizer.tokenize('UNwant\u00E9d,running' ) self.assertListEqual(_snake_case , ['un', '##want', '##ed', ',', 'runn', '##ing'] ) self.assertListEqual(tokenizer.convert_tokens_to_ids(_snake_case ) , [9, 6, 7, 12, 10, 11] ) def __A ( self ) -> List[str]: if not self.test_rust_tokenizer: return SCREAMING_SNAKE_CASE = self.get_tokenizer() SCREAMING_SNAKE_CASE = self.get_rust_tokenizer() SCREAMING_SNAKE_CASE = 'UNwant\u00E9d,running' SCREAMING_SNAKE_CASE = tokenizer.tokenize(_snake_case ) SCREAMING_SNAKE_CASE = rust_tokenizer.tokenize(_snake_case ) self.assertListEqual(_snake_case , _snake_case ) SCREAMING_SNAKE_CASE = tokenizer.encode(_snake_case , add_special_tokens=_snake_case ) SCREAMING_SNAKE_CASE = rust_tokenizer.encode(_snake_case , add_special_tokens=_snake_case ) self.assertListEqual(_snake_case , _snake_case ) SCREAMING_SNAKE_CASE = self.get_rust_tokenizer() SCREAMING_SNAKE_CASE = tokenizer.encode(_snake_case ) SCREAMING_SNAKE_CASE = rust_tokenizer.encode(_snake_case ) self.assertListEqual(_snake_case , _snake_case ) # With lower casing SCREAMING_SNAKE_CASE = self.get_tokenizer(do_lower_case=_snake_case ) SCREAMING_SNAKE_CASE = self.get_rust_tokenizer(do_lower_case=_snake_case ) SCREAMING_SNAKE_CASE = 'UNwant\u00E9d,running' SCREAMING_SNAKE_CASE = tokenizer.tokenize(_snake_case ) SCREAMING_SNAKE_CASE = rust_tokenizer.tokenize(_snake_case ) self.assertListEqual(_snake_case , _snake_case ) SCREAMING_SNAKE_CASE = tokenizer.encode(_snake_case , add_special_tokens=_snake_case ) SCREAMING_SNAKE_CASE = rust_tokenizer.encode(_snake_case , add_special_tokens=_snake_case ) self.assertListEqual(_snake_case , _snake_case ) SCREAMING_SNAKE_CASE = self.get_rust_tokenizer() SCREAMING_SNAKE_CASE = tokenizer.encode(_snake_case ) SCREAMING_SNAKE_CASE = rust_tokenizer.encode(_snake_case ) self.assertListEqual(_snake_case , _snake_case ) def __A ( self ) -> Any: SCREAMING_SNAKE_CASE = BasicTokenizer() self.assertListEqual(tokenizer.tokenize('ah\u535A\u63A8zz' ) , ['ah', '\u535A', '\u63A8', 'zz'] ) def __A ( self ) -> Any: SCREAMING_SNAKE_CASE = BasicTokenizer(do_lower_case=_snake_case ) self.assertListEqual( tokenizer.tokenize(' \tHeLLo!how \n Are yoU? ' ) , ['hello', '!', 'how', 'are', 'you', '?'] ) self.assertListEqual(tokenizer.tokenize('H\u00E9llo' ) , ['hello'] ) def __A ( self ) -> Any: SCREAMING_SNAKE_CASE = BasicTokenizer(do_lower_case=_snake_case , strip_accents=_snake_case ) self.assertListEqual( tokenizer.tokenize(' \tHäLLo!how \n Are yoU? ' ) , ['hällo', '!', 'how', 'are', 'you', '?'] ) self.assertListEqual(tokenizer.tokenize('H\u00E9llo' ) , ['h\u00E9llo'] ) def __A ( self ) -> str: SCREAMING_SNAKE_CASE = BasicTokenizer(do_lower_case=_snake_case , strip_accents=_snake_case ) self.assertListEqual( tokenizer.tokenize(' \tHäLLo!how \n Are yoU? ' ) , ['hallo', '!', 'how', 'are', 'you', '?'] ) self.assertListEqual(tokenizer.tokenize('H\u00E9llo' ) , ['hello'] ) def __A ( self ) -> List[str]: SCREAMING_SNAKE_CASE = BasicTokenizer(do_lower_case=_snake_case ) self.assertListEqual( tokenizer.tokenize(' \tHäLLo!how \n Are yoU? ' ) , ['hallo', '!', 'how', 'are', 'you', '?'] ) self.assertListEqual(tokenizer.tokenize('H\u00E9llo' ) , ['hello'] ) def __A ( self ) -> Optional[Any]: SCREAMING_SNAKE_CASE = BasicTokenizer(do_lower_case=_snake_case ) self.assertListEqual( tokenizer.tokenize(' \tHeLLo!how \n Are yoU? ' ) , ['HeLLo', '!', 'how', 'Are', 'yoU', '?'] ) def __A ( self ) -> Optional[int]: SCREAMING_SNAKE_CASE = BasicTokenizer(do_lower_case=_snake_case , strip_accents=_snake_case ) self.assertListEqual( tokenizer.tokenize(' \tHäLLo!how \n Are yoU? ' ) , ['HäLLo', '!', 'how', 'Are', 'yoU', '?'] ) def __A ( self ) -> List[Any]: SCREAMING_SNAKE_CASE = BasicTokenizer(do_lower_case=_snake_case , strip_accents=_snake_case ) self.assertListEqual( tokenizer.tokenize(' \tHäLLo!how \n Are yoU? ' ) , ['HaLLo', '!', 'how', 'Are', 'yoU', '?'] ) def __A ( self ) -> Optional[Any]: SCREAMING_SNAKE_CASE = BasicTokenizer(do_lower_case=_snake_case , never_split=['[UNK]'] ) self.assertListEqual( tokenizer.tokenize(' \tHeLLo!how \n Are yoU? [UNK]' ) , ['HeLLo', '!', 'how', 'Are', 'yoU', '?', '[UNK]'] ) def __A ( self ) -> Union[str, Any]: SCREAMING_SNAKE_CASE = BasicTokenizer() SCREAMING_SNAKE_CASE = 'a\n\'ll !!to?\'d of, can\'t.' SCREAMING_SNAKE_CASE = ['a', '\'', 'll', '!', '!', 'to', '?', '\'', 'd', 'of', ',', 'can', '\'', 't', '.'] self.assertListEqual(tokenizer.tokenize(_snake_case ) , _snake_case ) def __A ( self ) -> List[Any]: SCREAMING_SNAKE_CASE = ['[UNK]', '[CLS]', '[SEP]', 'want', '##want', '##ed', 'wa', 'un', 'runn', '##ing'] SCREAMING_SNAKE_CASE = {} for i, token in enumerate(_snake_case ): SCREAMING_SNAKE_CASE = i SCREAMING_SNAKE_CASE = WordpieceTokenizer(vocab=_snake_case , unk_token='[UNK]' ) self.assertListEqual(tokenizer.tokenize('' ) , [] ) self.assertListEqual(tokenizer.tokenize('unwanted running' ) , ['un', '##want', '##ed', 'runn', '##ing'] ) self.assertListEqual(tokenizer.tokenize('unwantedX running' ) , ['[UNK]', 'runn', '##ing'] ) def __A ( self ) -> Any: self.assertTrue(_is_whitespace(' ' ) ) self.assertTrue(_is_whitespace('\t' ) ) self.assertTrue(_is_whitespace('\r' ) ) self.assertTrue(_is_whitespace('\n' ) ) self.assertTrue(_is_whitespace('\u00A0' ) ) self.assertFalse(_is_whitespace('A' ) ) self.assertFalse(_is_whitespace('-' ) ) def __A ( self ) -> Optional[int]: self.assertTrue(_is_control('\u0005' ) ) self.assertFalse(_is_control('A' ) ) self.assertFalse(_is_control(' ' ) ) self.assertFalse(_is_control('\t' ) ) self.assertFalse(_is_control('\r' ) ) def __A ( self ) -> Tuple: self.assertTrue(_is_punctuation('-' ) ) self.assertTrue(_is_punctuation('$' ) ) self.assertTrue(_is_punctuation('`' ) ) self.assertTrue(_is_punctuation('.' ) ) self.assertFalse(_is_punctuation('A' ) ) self.assertFalse(_is_punctuation(' ' ) ) def __A ( self ) -> Any: SCREAMING_SNAKE_CASE = self.get_tokenizer() SCREAMING_SNAKE_CASE = self.get_rust_tokenizer() # Example taken from the issue https://github.com/huggingface/tokenizers/issues/340 self.assertListEqual([tokenizer.tokenize(_snake_case ) for t in ['Test', '\xad', 'test']] , [['[UNK]'], [], ['[UNK]']] ) self.assertListEqual( [rust_tokenizer.tokenize(_snake_case ) for t in ['Test', '\xad', 'test']] , [['[UNK]'], [], ['[UNK]']] ) @slow def __A ( self ) -> Any: SCREAMING_SNAKE_CASE = self.tokenizer_class.from_pretrained('bert-base-uncased' ) SCREAMING_SNAKE_CASE = tokenizer.encode('sequence builders' , add_special_tokens=_snake_case ) SCREAMING_SNAKE_CASE = tokenizer.encode('multi-sequence build' , add_special_tokens=_snake_case ) SCREAMING_SNAKE_CASE = tokenizer.build_inputs_with_special_tokens(_snake_case ) SCREAMING_SNAKE_CASE = tokenizer.build_inputs_with_special_tokens(_snake_case , _snake_case ) assert encoded_sentence == [101] + text + [102] assert encoded_pair == [101] + text + [102] + text_a + [102] def __A ( self ) -> List[Any]: for tokenizer, pretrained_name, kwargs in self.tokenizers_list: with self.subTest(F'{tokenizer.__class__.__name__} ({pretrained_name})' ): SCREAMING_SNAKE_CASE = self.rust_tokenizer_class.from_pretrained(_snake_case , **_snake_case ) SCREAMING_SNAKE_CASE = F'A, naïve {tokenizer_r.mask_token} AllenNLP sentence.' SCREAMING_SNAKE_CASE = tokenizer_r.encode_plus( _snake_case , return_attention_mask=_snake_case , return_token_type_ids=_snake_case , return_offsets_mapping=_snake_case , add_special_tokens=_snake_case , ) SCREAMING_SNAKE_CASE = tokenizer_r.do_lower_case if hasattr(_snake_case , 'do_lower_case' ) else False SCREAMING_SNAKE_CASE = ( [ ((0, 0), tokenizer_r.cls_token), ((0, 1), 'A'), ((1, 2), ','), ((3, 5), 'na'), ((5, 6), '##ï'), ((6, 8), '##ve'), ((9, 15), tokenizer_r.mask_token), ((16, 21), 'Allen'), ((21, 23), '##NL'), ((23, 24), '##P'), ((25, 33), 'sentence'), ((33, 34), '.'), ((0, 0), tokenizer_r.sep_token), ] if not do_lower_case else [ ((0, 0), tokenizer_r.cls_token), ((0, 1), 'a'), ((1, 2), ','), ((3, 8), 'naive'), ((9, 15), tokenizer_r.mask_token), ((16, 21), 'allen'), ((21, 23), '##nl'), ((23, 24), '##p'), ((25, 33), 'sentence'), ((33, 34), '.'), ((0, 0), tokenizer_r.sep_token), ] ) self.assertEqual( [e[1] for e in expected_results] , tokenizer_r.convert_ids_to_tokens(tokens['input_ids'] ) ) self.assertEqual([e[0] for e in expected_results] , tokens['offset_mapping'] ) def __A ( self ) -> Optional[Any]: SCREAMING_SNAKE_CASE = ['的', '人', '有'] SCREAMING_SNAKE_CASE = ''.join(_snake_case ) for tokenizer, pretrained_name, kwargs in self.tokenizers_list: with self.subTest(F'{tokenizer.__class__.__name__} ({pretrained_name})' ): SCREAMING_SNAKE_CASE = True SCREAMING_SNAKE_CASE = self.tokenizer_class.from_pretrained(_snake_case , **_snake_case ) SCREAMING_SNAKE_CASE = self.rust_tokenizer_class.from_pretrained(_snake_case , **_snake_case ) SCREAMING_SNAKE_CASE = tokenizer_p.encode(_snake_case , add_special_tokens=_snake_case ) SCREAMING_SNAKE_CASE = tokenizer_r.encode(_snake_case , add_special_tokens=_snake_case ) SCREAMING_SNAKE_CASE = tokenizer_r.convert_ids_to_tokens(_snake_case ) SCREAMING_SNAKE_CASE = tokenizer_p.convert_ids_to_tokens(_snake_case ) # it is expected that each Chinese character is not preceded by "##" self.assertListEqual(_snake_case , _snake_case ) self.assertListEqual(_snake_case , _snake_case ) SCREAMING_SNAKE_CASE = False SCREAMING_SNAKE_CASE = self.rust_tokenizer_class.from_pretrained(_snake_case , **_snake_case ) SCREAMING_SNAKE_CASE = self.tokenizer_class.from_pretrained(_snake_case , **_snake_case ) SCREAMING_SNAKE_CASE = tokenizer_r.encode(_snake_case , add_special_tokens=_snake_case ) SCREAMING_SNAKE_CASE = tokenizer_p.encode(_snake_case , add_special_tokens=_snake_case ) SCREAMING_SNAKE_CASE = tokenizer_r.convert_ids_to_tokens(_snake_case ) SCREAMING_SNAKE_CASE = tokenizer_p.convert_ids_to_tokens(_snake_case ) # it is expected that only the first Chinese character is not preceded by "##". SCREAMING_SNAKE_CASE = [ F'##{token}' if idx != 0 else token for idx, token in enumerate(_snake_case ) ] self.assertListEqual(_snake_case , _snake_case ) self.assertListEqual(_snake_case , _snake_case )
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from collections import UserDict from typing import Union import numpy as np import requests from ..utils import ( add_end_docstrings, logging, ) from .audio_classification import ffmpeg_read from .base import PIPELINE_INIT_ARGS, Pipeline a_ :List[Any] = logging.get_logger(__name__) @add_end_docstrings(lowerCAmelCase_ ) class snake_case__ ( lowerCAmelCase_ ): """simple docstring""" def __init__( self : Optional[Any], **_snake_case : str ) ->Dict: super().__init__(**_snake_case ) if self.framework != "pt": raise ValueError(F'''The {self.__class__} is only available in PyTorch.''' ) # No specific FOR_XXX available yet def __call__( self : Union[str, Any], _snake_case : Union[np.ndarray, bytes, str], **_snake_case : Tuple ) ->Dict: return super().__call__(_snake_case, **_snake_case ) def lowercase_ ( self : Tuple, **_snake_case : Any ) ->Union[str, Any]: snake_case__ : str = {} if "candidate_labels" in kwargs: snake_case__ : str = kwargs['candidate_labels'] if "hypothesis_template" in kwargs: snake_case__ : str = kwargs['hypothesis_template'] return preprocess_params, {}, {} def lowercase_ ( self : Dict, _snake_case : str, _snake_case : Optional[int]=None, _snake_case : List[str]="This is a sound of {}." ) ->int: if isinstance(_snake_case, _snake_case ): if audio.startswith('http://' ) or audio.startswith('https://' ): # We need to actually check for a real protocol, otherwise it's impossible to use a local file # like http_huggingface_co.png snake_case__ : List[Any] = requests.get(_snake_case ).content else: with open(_snake_case, 'rb' ) as f: snake_case__ : Union[str, Any] = f.read() if isinstance(_snake_case, _snake_case ): snake_case__ : List[Any] = ffmpeg_read(_snake_case, self.feature_extractor.sampling_rate ) if not isinstance(_snake_case, np.ndarray ): raise ValueError('We expect a numpy ndarray as input' ) if len(audio.shape ) != 1: raise ValueError('We expect a single channel audio input for ZeroShotAudioClassificationPipeline' ) snake_case__ : Tuple = self.feature_extractor( [audio], sampling_rate=self.feature_extractor.sampling_rate, return_tensors='pt' ) snake_case__ : int = candidate_labels snake_case__ : int = [hypothesis_template.format(_snake_case ) for x in candidate_labels] snake_case__ : Optional[int] = self.tokenizer(_snake_case, return_tensors=self.framework, padding=_snake_case ) snake_case__ : List[Any] = [text_inputs] return inputs def lowercase_ ( self : Optional[int], _snake_case : Optional[Any] ) ->int: snake_case__ : Optional[int] = model_inputs.pop('candidate_labels' ) snake_case__ : str = model_inputs.pop('text_inputs' ) if isinstance(text_inputs[0], _snake_case ): snake_case__ : Optional[Any] = text_inputs[0] else: # Batching case. snake_case__ : int = text_inputs[0][0] snake_case__ : Any = self.model(**_snake_case, **_snake_case ) snake_case__ : List[Any] = { 'candidate_labels': candidate_labels, 'logits': outputs.logits_per_audio, } return model_outputs def lowercase_ ( self : Union[str, Any], _snake_case : str ) ->List[str]: snake_case__ : int = model_outputs.pop('candidate_labels' ) snake_case__ : List[Any] = model_outputs['logits'][0] if self.framework == "pt": snake_case__ : Tuple = logits.softmax(dim=0 ) snake_case__ : Union[str, Any] = probs.tolist() else: raise ValueError('`tf` framework not supported.' ) snake_case__ : Union[str, Any] = [ {'score': score, 'label': candidate_label} for score, candidate_label in sorted(zip(_snake_case, _snake_case ), key=lambda _snake_case : -x[0] ) ] return result
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'''simple docstring''' def UpperCamelCase_ ( ) -> List[Any]: '''simple docstring''' return [ a * b * (10_00 - a - b) for a in range(1 , 9_99 ) for b in range(snake_case_ , 9_99 ) if (a * a + b * b == (10_00 - a - b) ** 2) ][0] if __name__ == "__main__": print(f'{solution() = }')
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import collections import inspect import unittest from transformers import SwinvaConfig from transformers.testing_utils import require_torch, require_vision, slow, torch_device from transformers.utils import cached_property, is_torch_available, is_vision_available from ...test_configuration_common import ConfigTester from ...test_modeling_common import ModelTesterMixin, _config_zero_init, floats_tensor, ids_tensor from ...test_pipeline_mixin import PipelineTesterMixin if is_torch_available(): import torch from torch import nn from transformers import SwinvaForImageClassification, SwinvaForMaskedImageModeling, SwinvaModel from transformers.models.swinva.modeling_swinva import SWINV2_PRETRAINED_MODEL_ARCHIVE_LIST if is_vision_available(): from PIL import Image from transformers import AutoImageProcessor class snake_case__ : """simple docstring""" def __init__( self : Tuple, _snake_case : Any, _snake_case : int=1_3, _snake_case : Optional[int]=3_2, _snake_case : Tuple=2, _snake_case : Any=3, _snake_case : Tuple=1_6, _snake_case : Tuple=[1, 2, 1], _snake_case : Dict=[2, 2, 4], _snake_case : str=2, _snake_case : Union[str, Any]=2.0, _snake_case : Dict=True, _snake_case : Dict=0.0, _snake_case : str=0.0, _snake_case : str=0.1, _snake_case : List[str]="gelu", _snake_case : int=False, _snake_case : Optional[Any]=True, _snake_case : List[Any]=0.0_2, _snake_case : Union[str, Any]=1e-5, _snake_case : Union[str, Any]=True, _snake_case : List[Any]=None, _snake_case : Any=True, _snake_case : List[Any]=1_0, _snake_case : str=8, ) ->Union[str, Any]: snake_case__ : Any = parent snake_case__ : Tuple = batch_size snake_case__ : Tuple = image_size snake_case__ : Any = patch_size snake_case__ : Optional[int] = num_channels snake_case__ : Tuple = embed_dim snake_case__ : Any = depths snake_case__ : Any = num_heads snake_case__ : List[str] = window_size snake_case__ : Dict = mlp_ratio snake_case__ : Optional[int] = qkv_bias snake_case__ : Optional[Any] = hidden_dropout_prob snake_case__ : List[str] = attention_probs_dropout_prob snake_case__ : Union[str, Any] = drop_path_rate snake_case__ : str = hidden_act snake_case__ : Union[str, Any] = use_absolute_embeddings snake_case__ : Union[str, Any] = patch_norm snake_case__ : Any = layer_norm_eps snake_case__ : Tuple = initializer_range snake_case__ : Dict = is_training snake_case__ : Any = scope snake_case__ : Optional[Any] = use_labels snake_case__ : str = type_sequence_label_size snake_case__ : List[Any] = encoder_stride def lowercase_ ( self : Tuple ) ->str: snake_case__ : Tuple = floats_tensor([self.batch_size, self.num_channels, self.image_size, self.image_size] ) snake_case__ : List[Any] = None if self.use_labels: snake_case__ : Optional[Any] = ids_tensor([self.batch_size], self.type_sequence_label_size ) snake_case__ : Any = self.get_config() return config, pixel_values, labels def lowercase_ ( self : Optional[int] ) ->Optional[int]: return SwinvaConfig( image_size=self.image_size, patch_size=self.patch_size, num_channels=self.num_channels, embed_dim=self.embed_dim, depths=self.depths, num_heads=self.num_heads, window_size=self.window_size, mlp_ratio=self.mlp_ratio, qkv_bias=self.qkv_bias, hidden_dropout_prob=self.hidden_dropout_prob, attention_probs_dropout_prob=self.attention_probs_dropout_prob, drop_path_rate=self.drop_path_rate, hidden_act=self.hidden_act, use_absolute_embeddings=self.use_absolute_embeddings, path_norm=self.patch_norm, layer_norm_eps=self.layer_norm_eps, initializer_range=self.initializer_range, encoder_stride=self.encoder_stride, ) def lowercase_ ( self : Optional[int], _snake_case : str, _snake_case : List[str], _snake_case : int ) ->Dict: snake_case__ : List[Any] = SwinvaModel(config=_snake_case ) model.to(_snake_case ) model.eval() snake_case__ : Optional[int] = model(_snake_case ) snake_case__ : List[Any] = ((config.image_size // config.patch_size) ** 2) // (4 ** (len(config.depths ) - 1)) snake_case__ : List[Any] = int(config.embed_dim * 2 ** (len(config.depths ) - 1) ) self.parent.assertEqual(result.last_hidden_state.shape, (self.batch_size, expected_seq_len, expected_dim) ) def lowercase_ ( self : Optional[Any], _snake_case : Any, _snake_case : List[str], _snake_case : Dict ) ->List[Any]: snake_case__ : List[str] = SwinvaForMaskedImageModeling(config=_snake_case ) model.to(_snake_case ) model.eval() snake_case__ : Union[str, Any] = model(_snake_case ) self.parent.assertEqual( result.logits.shape, (self.batch_size, self.num_channels, self.image_size, self.image_size) ) # test greyscale images snake_case__ : Optional[Any] = 1 snake_case__ : Optional[int] = SwinvaForMaskedImageModeling(_snake_case ) model.to(_snake_case ) model.eval() snake_case__ : Tuple = floats_tensor([self.batch_size, 1, self.image_size, self.image_size] ) snake_case__ : Any = model(_snake_case ) self.parent.assertEqual(result.logits.shape, (self.batch_size, 1, self.image_size, self.image_size) ) def lowercase_ ( self : List[str], _snake_case : int, _snake_case : List[Any], _snake_case : Optional[int] ) ->Any: snake_case__ : Tuple = self.type_sequence_label_size snake_case__ : int = SwinvaForImageClassification(_snake_case ) model.to(_snake_case ) model.eval() snake_case__ : Tuple = model(_snake_case, labels=_snake_case ) self.parent.assertEqual(result.logits.shape, (self.batch_size, self.type_sequence_label_size) ) def lowercase_ ( self : Any ) ->Dict: snake_case__ : str = self.prepare_config_and_inputs() snake_case__ , snake_case__ , snake_case__ : List[str] = config_and_inputs snake_case__ : Union[str, Any] = {'pixel_values': pixel_values} return config, inputs_dict @require_torch class snake_case__ ( lowerCAmelCase_ , lowerCAmelCase_ , unittest.TestCase ): """simple docstring""" _SCREAMING_SNAKE_CASE = ( (SwinvaModel, SwinvaForImageClassification, SwinvaForMaskedImageModeling) if is_torch_available() else () ) _SCREAMING_SNAKE_CASE = ( {"""feature-extraction""": SwinvaModel, """image-classification""": SwinvaForImageClassification} if is_torch_available() else {} ) _SCREAMING_SNAKE_CASE = False _SCREAMING_SNAKE_CASE = False _SCREAMING_SNAKE_CASE = False _SCREAMING_SNAKE_CASE = False def lowercase_ ( self : Union[str, Any] ) ->Dict: snake_case__ : Optional[int] = SwinvaModelTester(self ) snake_case__ : int = ConfigTester(self, config_class=_snake_case, embed_dim=3_7 ) def lowercase_ ( self : Tuple ) ->int: self.config_tester.create_and_test_config_to_json_string() self.config_tester.create_and_test_config_to_json_file() self.config_tester.create_and_test_config_from_and_save_pretrained() self.config_tester.create_and_test_config_with_num_labels() self.config_tester.check_config_can_be_init_without_params() self.config_tester.check_config_arguments_init() def lowercase_ ( self : Any ) ->str: snake_case__ : int = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_model(*_snake_case ) @unittest.skip(reason='Got `CUDA error: misaligned address` with PyTorch 2.0.0.' ) def lowercase_ ( self : Any ) ->Union[str, Any]: pass @unittest.skip(reason='Swinv2 does not use inputs_embeds' ) def lowercase_ ( self : str ) ->Union[str, Any]: pass def lowercase_ ( self : Optional[Any] ) ->Union[str, Any]: snake_case__ , snake_case__ : Optional[int] = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: snake_case__ : Union[str, Any] = model_class(_snake_case ) self.assertIsInstance(model.get_input_embeddings(), (nn.Module) ) snake_case__ : Union[str, Any] = model.get_output_embeddings() self.assertTrue(x is None or isinstance(_snake_case, nn.Linear ) ) def lowercase_ ( self : List[str] ) ->Optional[int]: snake_case__ , snake_case__ : Any = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: snake_case__ : Any = model_class(_snake_case ) snake_case__ : Dict = inspect.signature(model.forward ) # signature.parameters is an OrderedDict => so arg_names order is deterministic snake_case__ : Optional[Any] = [*signature.parameters.keys()] snake_case__ : List[Any] = ['pixel_values'] self.assertListEqual(arg_names[:1], _snake_case ) def lowercase_ ( self : str ) ->Union[str, Any]: snake_case__ , snake_case__ : Any = self.model_tester.prepare_config_and_inputs_for_common() snake_case__ : int = True for model_class in self.all_model_classes: snake_case__ : str = True snake_case__ : Union[str, Any] = False snake_case__ : Tuple = True snake_case__ : int = model_class(_snake_case ) model.to(_snake_case ) model.eval() with torch.no_grad(): snake_case__ : Optional[int] = model(**self._prepare_for_class(_snake_case, _snake_case ) ) snake_case__ : List[str] = outputs.attentions snake_case__ : List[Any] = len(self.model_tester.depths ) self.assertEqual(len(_snake_case ), _snake_case ) # check that output_attentions also work using config del inputs_dict["output_attentions"] snake_case__ : str = True snake_case__ : Tuple = config.window_size**2 snake_case__ : Optional[int] = model_class(_snake_case ) model.to(_snake_case ) model.eval() with torch.no_grad(): snake_case__ : str = model(**self._prepare_for_class(_snake_case, _snake_case ) ) snake_case__ : Tuple = outputs.attentions self.assertEqual(len(_snake_case ), _snake_case ) self.assertListEqual( list(attentions[0].shape[-3:] ), [self.model_tester.num_heads[0], window_size_squared, window_size_squared], ) snake_case__ : Optional[Any] = len(_snake_case ) # Check attention is always last and order is fine snake_case__ : Optional[int] = True snake_case__ : Dict = True snake_case__ : List[Any] = model_class(_snake_case ) model.to(_snake_case ) model.eval() with torch.no_grad(): snake_case__ : Optional[int] = model(**self._prepare_for_class(_snake_case, _snake_case ) ) if hasattr(self.model_tester, 'num_hidden_states_types' ): snake_case__ : str = self.model_tester.num_hidden_states_types else: # also another +1 for reshaped_hidden_states snake_case__ : Dict = 2 self.assertEqual(out_len + added_hidden_states, len(_snake_case ) ) snake_case__ : Any = outputs.attentions self.assertEqual(len(_snake_case ), _snake_case ) self.assertListEqual( list(self_attentions[0].shape[-3:] ), [self.model_tester.num_heads[0], window_size_squared, window_size_squared], ) def lowercase_ ( self : Dict, _snake_case : Tuple, _snake_case : Any, _snake_case : int, _snake_case : Optional[int] ) ->str: snake_case__ : Dict = model_class(_snake_case ) model.to(_snake_case ) model.eval() with torch.no_grad(): snake_case__ : List[Any] = model(**self._prepare_for_class(_snake_case, _snake_case ) ) snake_case__ : Dict = outputs.hidden_states snake_case__ : int = getattr( self.model_tester, 'expected_num_hidden_layers', len(self.model_tester.depths ) + 1 ) self.assertEqual(len(_snake_case ), _snake_case ) # Swinv2 has a different seq_length snake_case__ : int = ( config.patch_size if isinstance(config.patch_size, collections.abc.Iterable ) else (config.patch_size, config.patch_size) ) snake_case__ : Optional[Any] = (image_size[1] // patch_size[1]) * (image_size[0] // patch_size[0]) self.assertListEqual( list(hidden_states[0].shape[-2:] ), [num_patches, self.model_tester.embed_dim], ) snake_case__ : Union[str, Any] = outputs.reshaped_hidden_states self.assertEqual(len(_snake_case ), _snake_case ) snake_case__ , snake_case__ , snake_case__ , snake_case__ : str = reshaped_hidden_states[0].shape snake_case__ : Any = ( reshaped_hidden_states[0].view(_snake_case, _snake_case, height * width ).permute(0, 2, 1 ) ) self.assertListEqual( list(reshaped_hidden_states.shape[-2:] ), [num_patches, self.model_tester.embed_dim], ) def lowercase_ ( self : str ) ->List[Any]: snake_case__ , snake_case__ : Any = self.model_tester.prepare_config_and_inputs_for_common() snake_case__ : List[Any] = ( self.model_tester.image_size if isinstance(self.model_tester.image_size, collections.abc.Iterable ) else (self.model_tester.image_size, self.model_tester.image_size) ) for model_class in self.all_model_classes: snake_case__ : Optional[int] = True self.check_hidden_states_output(_snake_case, _snake_case, _snake_case, _snake_case ) # check that output_hidden_states also work using config del inputs_dict["output_hidden_states"] snake_case__ : Dict = True self.check_hidden_states_output(_snake_case, _snake_case, _snake_case, _snake_case ) def lowercase_ ( self : List[str] ) ->str: snake_case__ , snake_case__ : Optional[Any] = self.model_tester.prepare_config_and_inputs_for_common() snake_case__ : List[str] = 3 snake_case__ : Union[str, Any] = ( self.model_tester.image_size if isinstance(self.model_tester.image_size, collections.abc.Iterable ) else (self.model_tester.image_size, self.model_tester.image_size) ) snake_case__ : str = ( config.patch_size if isinstance(config.patch_size, collections.abc.Iterable ) else (config.patch_size, config.patch_size) ) snake_case__ : Tuple = image_size[0] + patch_size[0] - (image_size[0] % patch_size[0]) snake_case__ : Optional[Any] = image_size[1] + patch_size[1] - (image_size[1] % patch_size[1]) for model_class in self.all_model_classes: snake_case__ : int = True self.check_hidden_states_output(_snake_case, _snake_case, _snake_case, (padded_height, padded_width) ) # check that output_hidden_states also work using config del inputs_dict["output_hidden_states"] snake_case__ : List[str] = True self.check_hidden_states_output(_snake_case, _snake_case, _snake_case, (padded_height, padded_width) ) def lowercase_ ( self : List[str] ) ->Optional[int]: snake_case__ : Any = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_for_masked_image_modeling(*_snake_case ) def lowercase_ ( self : List[Any] ) ->str: snake_case__ : Any = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_for_image_classification(*_snake_case ) @slow def lowercase_ ( self : str ) ->Union[str, Any]: for model_name in SWINV2_PRETRAINED_MODEL_ARCHIVE_LIST[:1]: snake_case__ : Dict = SwinvaModel.from_pretrained(_snake_case ) self.assertIsNotNone(_snake_case ) def lowercase_ ( self : Optional[int] ) ->List[str]: snake_case__ , snake_case__ : Any = self.model_tester.prepare_config_and_inputs_for_common() snake_case__ : List[Any] = _config_zero_init(_snake_case ) for model_class in self.all_model_classes: snake_case__ : List[str] = model_class(config=_snake_case ) for name, param in model.named_parameters(): if "embeddings" not in name and "logit_scale" not in name and param.requires_grad: self.assertIn( ((param.data.mean() * 1e9).round() / 1e9).item(), [0.0, 1.0], msg=F'''Parameter {name} of model {model_class} seems not properly initialized''', ) @require_vision @require_torch class snake_case__ ( unittest.TestCase ): """simple docstring""" @cached_property def lowercase_ ( self : Union[str, Any] ) ->List[str]: return ( AutoImageProcessor.from_pretrained('microsoft/swinv2-tiny-patch4-window8-256' ) if is_vision_available() else None ) @slow def lowercase_ ( self : int ) ->List[Any]: snake_case__ : Any = SwinvaForImageClassification.from_pretrained('microsoft/swinv2-tiny-patch4-window8-256' ).to( _snake_case ) snake_case__ : int = self.default_image_processor snake_case__ : Union[str, Any] = Image.open('./tests/fixtures/tests_samples/COCO/000000039769.png' ) snake_case__ : Optional[Any] = image_processor(images=_snake_case, return_tensors='pt' ).to(_snake_case ) # forward pass with torch.no_grad(): snake_case__ : List[str] = model(**_snake_case ) # verify the logits snake_case__ : int = torch.Size((1, 1_0_0_0) ) self.assertEqual(outputs.logits.shape, _snake_case ) snake_case__ : Optional[int] = torch.tensor([-0.3_9_4_7, -0.4_3_0_6, 0.0_0_2_6] ).to(_snake_case ) self.assertTrue(torch.allclose(outputs.logits[0, :3], _snake_case, atol=1e-4 ) )
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"""simple docstring""" import itertools from dataclasses import dataclass from typing import Any, Callable, Dict, List, Optional, Union import pandas as pd import pyarrow as pa import datasets import datasets.config from datasets.features.features import require_storage_cast from datasets.table import table_cast from datasets.utils.py_utils import Literal UpperCAmelCase = datasets.utils.logging.get_logger(__name__) UpperCAmelCase = ["names", "prefix"] UpperCAmelCase = ["warn_bad_lines", "error_bad_lines", "mangle_dupe_cols"] UpperCAmelCase = ["encoding_errors", "on_bad_lines"] UpperCAmelCase = ["date_format"] @dataclass class UpperCAmelCase_ ( datasets.BuilderConfig): snake_case__ = ''',''' snake_case__ = None snake_case__ = '''infer''' snake_case__ = None snake_case__ = None snake_case__ = None snake_case__ = None snake_case__ = None snake_case__ = True snake_case__ = None snake_case__ = None snake_case__ = None snake_case__ = None snake_case__ = False snake_case__ = None snake_case__ = None snake_case__ = None snake_case__ = True snake_case__ = True snake_case__ = False snake_case__ = True snake_case__ = None snake_case__ = '''.''' snake_case__ = None snake_case__ = '''"''' snake_case__ = 0 snake_case__ = None snake_case__ = None snake_case__ = None snake_case__ = None snake_case__ = True snake_case__ = True snake_case__ = 0 snake_case__ = True snake_case__ = False snake_case__ = None snake_case__ = 1_00_00 snake_case__ = None snake_case__ = '''strict''' snake_case__ = '''error''' snake_case__ = None def _UpperCamelCase ( self : Dict ) -> str: if self.delimiter is not None: _UpperCamelCase = self.delimiter if self.column_names is not None: _UpperCamelCase = self.column_names @property def _UpperCamelCase ( self : Optional[Any] ) -> List[Any]: _UpperCamelCase = { 'sep': self.sep, 'header': self.header, 'names': self.names, 'index_col': self.index_col, 'usecols': self.usecols, 'prefix': self.prefix, 'mangle_dupe_cols': self.mangle_dupe_cols, 'engine': self.engine, 'converters': self.converters, 'true_values': self.true_values, 'false_values': self.false_values, 'skipinitialspace': self.skipinitialspace, 'skiprows': self.skiprows, 'nrows': self.nrows, 'na_values': self.na_values, 'keep_default_na': self.keep_default_na, 'na_filter': self.na_filter, 'verbose': self.verbose, 'skip_blank_lines': self.skip_blank_lines, 'thousands': self.thousands, 'decimal': self.decimal, 'lineterminator': self.lineterminator, 'quotechar': self.quotechar, 'quoting': self.quoting, 'escapechar': self.escapechar, 'comment': self.comment, 'encoding': self.encoding, 'dialect': self.dialect, 'error_bad_lines': self.error_bad_lines, 'warn_bad_lines': self.warn_bad_lines, 'skipfooter': self.skipfooter, 'doublequote': self.doublequote, 'memory_map': self.memory_map, 'float_precision': self.float_precision, 'chunksize': self.chunksize, 'encoding_errors': self.encoding_errors, 'on_bad_lines': self.on_bad_lines, 'date_format': self.date_format, } # some kwargs must not be passed if they don't have a default value # some others are deprecated and we can also not pass them if they are the default value for pd_read_csv_parameter in _PANDAS_READ_CSV_NO_DEFAULT_PARAMETERS + _PANDAS_READ_CSV_DEPRECATED_PARAMETERS: if pd_read_csv_kwargs[pd_read_csv_parameter] == getattr(CsvConfig() , _snake_case ): del pd_read_csv_kwargs[pd_read_csv_parameter] # Remove 2.0 new arguments if not (datasets.config.PANDAS_VERSION.major >= 2): for pd_read_csv_parameter in _PANDAS_READ_CSV_NEW_2_0_0_PARAMETERS: del pd_read_csv_kwargs[pd_read_csv_parameter] # Remove 1.3 new arguments if not (datasets.config.PANDAS_VERSION.major >= 1 and datasets.config.PANDAS_VERSION.minor >= 3): for pd_read_csv_parameter in _PANDAS_READ_CSV_NEW_1_3_0_PARAMETERS: del pd_read_csv_kwargs[pd_read_csv_parameter] return pd_read_csv_kwargs class UpperCAmelCase_ ( datasets.ArrowBasedBuilder): snake_case__ = CsvConfig def _UpperCamelCase ( self : Union[str, Any] ) -> Any: return datasets.DatasetInfo(features=self.config.features ) def _UpperCamelCase ( self : int , __UpperCamelCase : Optional[Any] ) -> Any: if not self.config.data_files: raise ValueError(F'''At least one data file must be specified, but got data_files={self.config.data_files}''' ) _UpperCamelCase = dl_manager.download_and_extract(self.config.data_files ) if isinstance(_snake_case , (str, list, tuple) ): _UpperCamelCase = data_files if isinstance(_snake_case , _snake_case ): _UpperCamelCase = [files] _UpperCamelCase = [dl_manager.iter_files(_snake_case ) for file in files] return [datasets.SplitGenerator(name=datasets.Split.TRAIN , gen_kwargs={'''files''': files} )] _UpperCamelCase = [] for split_name, files in data_files.items(): if isinstance(_snake_case , _snake_case ): _UpperCamelCase = [files] _UpperCamelCase = [dl_manager.iter_files(_snake_case ) for file in files] splits.append(datasets.SplitGenerator(name=_snake_case , gen_kwargs={'''files''': files} ) ) return splits def _UpperCamelCase ( self : List[str] , __UpperCamelCase : pa.Table ) -> pa.Table: if self.config.features is not None: _UpperCamelCase = self.config.features.arrow_schema if all(not require_storage_cast(_snake_case ) for feature in self.config.features.values() ): # cheaper cast _UpperCamelCase = pa.Table.from_arrays([pa_table[field.name] for field in schema] , schema=_snake_case ) else: # more expensive cast; allows str <-> int/float or str to Audio for example _UpperCamelCase = table_cast(_snake_case , _snake_case ) return pa_table def _UpperCamelCase ( self : str , __UpperCamelCase : List[str] ) -> List[Any]: _UpperCamelCase = self.config.features.arrow_schema if self.config.features else None # dtype allows reading an int column as str _UpperCamelCase = ( { name: dtype.to_pandas_dtype() if not require_storage_cast(_snake_case ) else object for name, dtype, feature in zip(schema.names , schema.types , self.config.features.values() ) } if schema is not None else None ) for file_idx, file in enumerate(itertools.chain.from_iterable(_snake_case ) ): _UpperCamelCase = pd.read_csv(_snake_case , iterator=_snake_case , dtype=_snake_case , **self.config.pd_read_csv_kwargs ) try: for batch_idx, df in enumerate(_snake_case ): _UpperCamelCase = pa.Table.from_pandas(_snake_case ) # Uncomment for debugging (will print the Arrow table size and elements) # logger.warning(f"pa_table: {pa_table} num rows: {pa_table.num_rows}") # logger.warning('\n'.join(str(pa_table.slice(i, 1).to_pydict()) for i in range(pa_table.num_rows))) yield (file_idx, batch_idx), self._cast_table(_snake_case ) except ValueError as e: logger.error(F'''Failed to read file \'{file}\' with error {type(_snake_case )}: {e}''' ) raise
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import unittest import numpy as np from transformers.testing_utils import require_torch, require_vision from transformers.utils import is_torch_available, is_vision_available from ...test_image_processing_common import ImageProcessingSavingTestMixin, prepare_image_inputs if is_torch_available(): import torch if is_vision_available(): from PIL import Image from transformers import PoolFormerImageProcessor class snake_case__ ( unittest.TestCase ): """simple docstring""" def __init__( self : Optional[int], _snake_case : List[Any], _snake_case : str=7, _snake_case : Tuple=3, _snake_case : List[str]=3_0, _snake_case : Tuple=4_0_0, _snake_case : Any=True, _snake_case : List[Any]=None, _snake_case : int=0.9, _snake_case : Optional[Any]=None, _snake_case : str=True, _snake_case : Union[str, Any]=[0.5, 0.5, 0.5], _snake_case : Union[str, Any]=[0.5, 0.5, 0.5], ) ->List[Any]: snake_case__ : int = size if size is not None else {'shortest_edge': 3_0} snake_case__ : Tuple = crop_size if crop_size is not None else {'height': 3_0, 'width': 3_0} snake_case__ : Union[str, Any] = parent snake_case__ : Dict = batch_size snake_case__ : int = num_channels snake_case__ : Tuple = min_resolution snake_case__ : Any = max_resolution snake_case__ : List[Any] = do_resize_and_center_crop snake_case__ : str = size snake_case__ : str = crop_pct snake_case__ : List[str] = crop_size snake_case__ : Optional[int] = do_normalize snake_case__ : Tuple = image_mean snake_case__ : Tuple = image_std def lowercase_ ( self : Optional[int] ) ->int: return { "size": self.size, "do_resize_and_center_crop": self.do_resize_and_center_crop, "crop_pct": self.crop_pct, "crop_size": self.crop_size, "do_normalize": self.do_normalize, "image_mean": self.image_mean, "image_std": self.image_std, } @require_torch @require_vision class snake_case__ ( lowerCAmelCase_ , unittest.TestCase ): """simple docstring""" _SCREAMING_SNAKE_CASE = PoolFormerImageProcessor if is_vision_available() else None def lowercase_ ( self : Union[str, Any] ) ->Dict: snake_case__ : Union[str, Any] = PoolFormerImageProcessingTester(self ) @property def lowercase_ ( self : int ) ->Dict: return self.image_processor_tester.prepare_image_processor_dict() def lowercase_ ( self : Union[str, Any] ) ->Optional[int]: snake_case__ : List[str] = self.image_processing_class(**self.image_processor_dict ) self.assertTrue(hasattr(_snake_case, 'do_resize_and_center_crop' ) ) self.assertTrue(hasattr(_snake_case, 'size' ) ) self.assertTrue(hasattr(_snake_case, 'crop_pct' ) ) self.assertTrue(hasattr(_snake_case, 'do_normalize' ) ) self.assertTrue(hasattr(_snake_case, 'image_mean' ) ) self.assertTrue(hasattr(_snake_case, 'image_std' ) ) def lowercase_ ( self : List[str] ) ->List[str]: snake_case__ : Union[str, Any] = self.image_processing_class.from_dict(self.image_processor_dict ) self.assertEqual(image_processor.size, {'shortest_edge': 3_0} ) self.assertEqual(image_processor.crop_size, {'height': 3_0, 'width': 3_0} ) snake_case__ : int = self.image_processing_class.from_dict(self.image_processor_dict, size=4_2, crop_size=8_4 ) self.assertEqual(image_processor.size, {'shortest_edge': 4_2} ) self.assertEqual(image_processor.crop_size, {'height': 8_4, 'width': 8_4} ) def lowercase_ ( self : List[Any] ) ->List[Any]: pass def lowercase_ ( self : List[str] ) ->str: # Initialize image_processing snake_case__ : Union[str, Any] = self.image_processing_class(**self.image_processor_dict ) # create random PIL images snake_case__ : List[str] = prepare_image_inputs(self.image_processor_tester, equal_resolution=_snake_case ) for image in image_inputs: self.assertIsInstance(_snake_case, Image.Image ) # Test not batched input snake_case__ : Optional[int] = image_processing(image_inputs[0], return_tensors='pt' ).pixel_values self.assertEqual( encoded_images.shape, ( 1, self.image_processor_tester.num_channels, self.image_processor_tester.crop_size['height'], self.image_processor_tester.crop_size['width'], ), ) # Test batched snake_case__ : str = image_processing(_snake_case, return_tensors='pt' ).pixel_values self.assertEqual( encoded_images.shape, ( self.image_processor_tester.batch_size, self.image_processor_tester.num_channels, self.image_processor_tester.crop_size['height'], self.image_processor_tester.crop_size['width'], ), ) def lowercase_ ( self : int ) ->List[Any]: # Initialize image_processing snake_case__ : Optional[int] = self.image_processing_class(**self.image_processor_dict ) # create random numpy tensors snake_case__ : Dict = prepare_image_inputs(self.image_processor_tester, equal_resolution=_snake_case, numpify=_snake_case ) for image in image_inputs: self.assertIsInstance(_snake_case, np.ndarray ) # Test not batched input snake_case__ : Dict = image_processing(image_inputs[0], return_tensors='pt' ).pixel_values self.assertEqual( encoded_images.shape, ( 1, self.image_processor_tester.num_channels, self.image_processor_tester.crop_size['height'], self.image_processor_tester.crop_size['width'], ), ) # Test batched snake_case__ : List[Any] = image_processing(_snake_case, return_tensors='pt' ).pixel_values self.assertEqual( encoded_images.shape, ( self.image_processor_tester.batch_size, self.image_processor_tester.num_channels, self.image_processor_tester.crop_size['height'], self.image_processor_tester.crop_size['width'], ), ) def lowercase_ ( self : List[str] ) ->List[str]: # Initialize image_processing snake_case__ : Tuple = self.image_processing_class(**self.image_processor_dict ) # create random PyTorch tensors snake_case__ : List[str] = prepare_image_inputs(self.image_processor_tester, equal_resolution=_snake_case, torchify=_snake_case ) for image in image_inputs: self.assertIsInstance(_snake_case, torch.Tensor ) # Test not batched input snake_case__ : Tuple = image_processing(image_inputs[0], return_tensors='pt' ).pixel_values self.assertEqual( encoded_images.shape, ( 1, self.image_processor_tester.num_channels, self.image_processor_tester.crop_size['height'], self.image_processor_tester.crop_size['width'], ), ) # Test batched snake_case__ : Optional[Any] = image_processing(_snake_case, return_tensors='pt' ).pixel_values self.assertEqual( encoded_images.shape, ( self.image_processor_tester.batch_size, self.image_processor_tester.num_channels, self.image_processor_tester.crop_size['height'], self.image_processor_tester.crop_size['width'], ), )
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from __future__ import annotations from random import random class A_ : def __init__( self : Tuple , UpperCAmelCase : int | None = None ) -> Optional[Any]: __lowerCAmelCase: int = value __lowerCAmelCase: List[str] = random() __lowerCAmelCase: Node | None = None __lowerCAmelCase: Node | None = None def __repr__( self : Optional[int] ) -> str: from pprint import pformat if self.left is None and self.right is None: return F'''\'{self.value}: {self.prior:.5}\'''' else: return pformat( {F'''{self.value}: {self.prior:.5}''': (self.left, self.right)} , indent=1 ) def __str__( self : int ) -> str: __lowerCAmelCase: str = str(self.value ) + ' ' __lowerCAmelCase: Optional[Any] = str(self.left or '' ) __lowerCAmelCase: List[Any] = str(self.right or '' ) return value + left + right def _a ( SCREAMING_SNAKE_CASE : Node | None , SCREAMING_SNAKE_CASE : int ) -> List[Any]: """simple docstring""" if root is None: # None tree is split into 2 Nones return None, None elif root.value is None: return None, None else: if value < root.value: __lowerCAmelCase: Optional[Any] = split(root.left , SCREAMING_SNAKE_CASE ) return left, root else: __lowerCAmelCase: int = split(root.right , SCREAMING_SNAKE_CASE ) return root, right def _a ( SCREAMING_SNAKE_CASE : Node | None , SCREAMING_SNAKE_CASE : Node | None ) -> Union[str, Any]: """simple docstring""" if (not left) or (not right): # If one node is None, return the other return left or right elif left.prior < right.prior: __lowerCAmelCase: List[str] = merge(left.right , SCREAMING_SNAKE_CASE ) return left else: __lowerCAmelCase: List[str] = merge(SCREAMING_SNAKE_CASE , right.left ) return right def _a ( SCREAMING_SNAKE_CASE : Node | None , SCREAMING_SNAKE_CASE : int ) -> Tuple: """simple docstring""" __lowerCAmelCase: Any = Node(SCREAMING_SNAKE_CASE ) __lowerCAmelCase: str = split(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ) return merge(merge(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ) , SCREAMING_SNAKE_CASE ) def _a ( SCREAMING_SNAKE_CASE : Node | None , SCREAMING_SNAKE_CASE : int ) -> Any: """simple docstring""" __lowerCAmelCase: Dict = split(SCREAMING_SNAKE_CASE , value - 1 ) __lowerCAmelCase: Union[str, Any] = split(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ) return merge(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ) def _a ( SCREAMING_SNAKE_CASE : Node | None ) -> Any: """simple docstring""" if not root: # None return else: inorder(root.left ) print(root.value , end=',' ) inorder(root.right ) def _a ( SCREAMING_SNAKE_CASE : Node | None , SCREAMING_SNAKE_CASE : str ) -> str: """simple docstring""" for arg in args.split(): if arg[0] == "+": __lowerCAmelCase: Optional[Any] = insert(SCREAMING_SNAKE_CASE , int(arg[1:] ) ) elif arg[0] == "-": __lowerCAmelCase: Dict = erase(SCREAMING_SNAKE_CASE , int(arg[1:] ) ) else: print('Unknown command' ) return root def _a ( ) -> List[str]: """simple docstring""" __lowerCAmelCase: Optional[int] = None print( 'enter numbers to create a tree, + value to add value into treap, ' '- value to erase all nodes with value. \'q\' to quit. ' ) __lowerCAmelCase: str = input() while args != "q": __lowerCAmelCase: Dict = interact_treap(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ) print(SCREAMING_SNAKE_CASE ) __lowerCAmelCase: List[str] = input() print('good by!' ) if __name__ == "__main__": import doctest doctest.testmod() main()
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from collections import deque from .hash_table import HashTable class snake_case__ ( lowerCAmelCase_ ): """simple docstring""" def __init__( self : Optional[Any], *_snake_case : Optional[Any], **_snake_case : List[Any] ) ->Optional[int]: super().__init__(*_snake_case, **_snake_case ) def lowercase_ ( self : Optional[Any], _snake_case : Tuple, _snake_case : Dict ) ->Dict: snake_case__ : int = deque([] ) if self.values[key] is None else self.values[key] self.values[key].appendleft(_snake_case ) snake_case__ : Dict = self.values[key] def lowercase_ ( self : Any ) ->Optional[Any]: return ( sum(self.charge_factor - len(_snake_case ) for slot in self.values ) / self.size_table * self.charge_factor ) def lowercase_ ( self : Union[str, Any], _snake_case : str, _snake_case : Optional[int]=None ) ->Optional[Any]: if not ( len(self.values[key] ) == self.charge_factor and self.values.count(_snake_case ) == 0 ): return key return super()._collision_resolution(_snake_case, _snake_case )
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import argparse from argparse import Namespace import torch from torch import nn from transformers import XGLMConfig, XGLMForCausalLM def _A ( SCREAMING_SNAKE_CASE : Optional[Any] ): """simple docstring""" a__ : Dict =[ 'decoder.version', 'decoder.output_projection.weight', '_float_tensor', 'decoder.embed_positions._float_tensor', ] for k in ignore_keys: state_dict.pop(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ) def _A ( SCREAMING_SNAKE_CASE : Tuple ): """simple docstring""" a__ : Tuple =emb.weight.shape a__ : List[str] =nn.Linear(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , bias=SCREAMING_SNAKE_CASE ) a__ : Tuple =emb.weight.data return lin_layer def _A ( SCREAMING_SNAKE_CASE : Any ): """simple docstring""" a__ : Any =torch.load(SCREAMING_SNAKE_CASE , map_location="cpu" ) a__ : Any =Namespace(**checkpoint["cfg"]["model"] ) a__ : Optional[Any] =checkpoint['model'] remove_ignore_keys_(SCREAMING_SNAKE_CASE ) a__ : List[Any] =state_dict['decoder.embed_tokens.weight'].shape[0] a__ : str ={key.replace("decoder" , "model" ): val for key, val in state_dict.items()} a__ : Optional[Any] =XGLMConfig( vocab_size=SCREAMING_SNAKE_CASE , max_position_embeddings=args.max_target_positions , num_layers=args.decoder_layers , attention_heads=args.decoder_attention_heads , ffn_dim=args.decoder_ffn_embed_dim , d_model=args.decoder_embed_dim , layerdrop=args.decoder_layerdrop , dropout=args.dropout , attention_dropout=args.attention_dropout , activation_dropout=args.activation_dropout , activation_function="gelu" , scale_embedding=not args.no_scale_embedding , tie_word_embeddings=args.share_decoder_input_output_embed , ) a__ : Dict =XGLMForCausalLM(SCREAMING_SNAKE_CASE ) a__ : Tuple =model.load_state_dict(SCREAMING_SNAKE_CASE , strict=SCREAMING_SNAKE_CASE ) print(SCREAMING_SNAKE_CASE ) a__ : int =make_linear_from_emb(model.model.embed_tokens ) return model if __name__ == "__main__": UpperCAmelCase : Optional[Any] = argparse.ArgumentParser() # Required parameters parser.add_argument("""fairseq_path""", type=str, help="""path to a model.pt on local filesystem.""") parser.add_argument("""pytorch_dump_folder_path""", default=None, type=str, help="""Path to the output PyTorch model.""") UpperCAmelCase : List[str] = parser.parse_args() UpperCAmelCase : int = convert_fairseq_xglm_checkpoint_from_disk(args.fairseq_path) model.save_pretrained(args.pytorch_dump_folder_path)
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def lowercase_ (A : Union[str, Any] , A : List[str] , A : int , A : Optional[int] ): global f # a global dp table for knapsack if f[i][j] < 0: if j < wt[i - 1]: snake_case__ : Union[str, Any] = mf_knapsack(i - 1 , A , A , A ) else: snake_case__ : Any = max( mf_knapsack(i - 1 , A , A , A ) , mf_knapsack(i - 1 , A , A , j - wt[i - 1] ) + val[i - 1] , ) snake_case__ : Optional[int] = val return f[i][j] def lowercase_ (A : Optional[int] , A : Union[str, Any] , A : str , A : Dict ): snake_case__ : int = [[0] * (w + 1) for _ in range(n + 1 )] for i in range(1 , n + 1 ): for w_ in range(1 , w + 1 ): if wt[i - 1] <= w_: snake_case__ : Union[str, Any] = max(val[i - 1] + dp[i - 1][w_ - wt[i - 1]] , dp[i - 1][w_] ) else: snake_case__ : str = dp[i - 1][w_] return dp[n][w_], dp def lowercase_ (A : int , A : list , A : list ): if not (isinstance(A , (list, tuple) ) and isinstance(A , (list, tuple) )): raise ValueError( 'Both the weights and values vectors must be either lists or tuples' ) snake_case__ : Dict = len(A ) if num_items != len(A ): snake_case__ : str = ( 'The number of weights must be the same as the number of values.\n' F'''But got {num_items} weights and {len(A )} values''' ) raise ValueError(A ) for i in range(A ): if not isinstance(wt[i] , A ): snake_case__ : Optional[int] = ( 'All weights must be integers but got weight of ' F'''type {type(wt[i] )} at index {i}''' ) raise TypeError(A ) snake_case__ , snake_case__ : Optional[int] = knapsack(A , A , A , A ) snake_case__ : set = set() _construct_solution(A , A , A , A , A ) return optimal_val, example_optional_set def lowercase_ (A : list , A : list , A : int , A : int , A : set ): # for the current item i at a maximum weight j to be part of an optimal subset, # the optimal value at (i, j) must be greater than the optimal value at (i-1, j). # where i - 1 means considering only the previous items at the given maximum weight if i > 0 and j > 0: if dp[i - 1][j] == dp[i][j]: _construct_solution(A , A , i - 1 , A , A ) else: optimal_set.add(A ) _construct_solution(A , A , i - 1 , j - wt[i - 1] , A ) if __name__ == "__main__": a_ :Any = [3, 2, 4, 4] a_ :List[Any] = [4, 3, 2, 3] a_ :Union[str, Any] = 4 a_ :List[str] = 6 a_ :Union[str, Any] = [[0] * (w + 1)] + [[0] + [-1] * (w + 1) for _ in range(n + 1)] a_ , a_ :List[Any] = knapsack(w, wt, val, n) print(optimal_solution) print(mf_knapsack(n, wt, val, w)) # switched the n and w # testing the dynamic programming problem with example # the optimal subset for the above example are items 3 and 4 a_ , a_ :Any = knapsack_with_example_solution(w, wt, val) assert optimal_solution == 8 assert optimal_subset == {3, 4} print("optimal_value = ", optimal_solution) print("An optimal subset corresponding to the optimal value", optimal_subset)
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from dataclasses import dataclass, field from typing import ClassVar, Dict from ..features import Features, Value from .base import TaskTemplate @dataclass(frozen=lowerCAmelCase_ ) class lowercase__( lowerCAmelCase_ ): """simple docstring""" a :List[Any] = field(default='language-modeling' , metadata={'include_in_asdict_even_if_is_default': True} ) a :Optional[int] = Features({'text': Value('string' )} ) a :int = Features({} ) a :Tuple = 'text' @property def _lowercase ( self : List[Any] ) -> Dict[str, str]: return {self.text_column: "text"}
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from typing import TYPE_CHECKING from ...utils import OptionalDependencyNotAvailable, _LazyModule, is_flax_available, is_torch_available a_ :int = { "configuration_longt5": ["LONGT5_PRETRAINED_CONFIG_ARCHIVE_MAP", "LongT5Config", "LongT5OnnxConfig"], } try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: a_ :List[str] = [ "LONGT5_PRETRAINED_MODEL_ARCHIVE_LIST", "LongT5EncoderModel", "LongT5ForConditionalGeneration", "LongT5Model", "LongT5PreTrainedModel", ] try: if not is_flax_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: a_ :int = [ "FlaxLongT5ForConditionalGeneration", "FlaxLongT5Model", "FlaxLongT5PreTrainedModel", ] if TYPE_CHECKING: from .configuration_longta import LONGT5_PRETRAINED_CONFIG_ARCHIVE_MAP, LongTaConfig, LongTaOnnxConfig try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_longta import ( LONGT5_PRETRAINED_MODEL_ARCHIVE_LIST, LongTaEncoderModel, LongTaForConditionalGeneration, LongTaModel, LongTaPreTrainedModel, ) try: if not is_flax_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_flax_longta import ( FlaxLongTaForConditionalGeneration, FlaxLongTaModel, FlaxLongTaPreTrainedModel, ) else: import sys a_ :Optional[int] = _LazyModule(__name__, globals()["__file__"], _import_structure, module_spec=__spec__)
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"""simple docstring""" import torch def lowercase ( ) -> int: if torch.cuda.is_available(): __a = torch.cuda.device_count() else: __a = 0 print(f'''Successfully ran on {num_gpus} GPUs''' ) if __name__ == "__main__": main()
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import argparse import json import os import torch from torch import nn from transformers import NllbMoeConfig, NllbMoeModel from transformers.modeling_utils import dtype_byte_size from transformers.utils import WEIGHTS_INDEX_NAME, WEIGHTS_NAME def lowercase_ (A : List[str] ): snake_case__ : Tuple = [ 'encoder.version', 'decoder.version', 'model.encoder.version', 'model.decoder.version', 'decoder.output_projection.weight', '_float_tensor', 'encoder.embed_positions._float_tensor', 'decoder.embed_positions._float_tensor', ] for k in ignore_keys: state_dict.pop(A , A ) def lowercase_ (A : str ): snake_case__ , snake_case__ : Union[str, Any] = emb.weight.shape snake_case__ : str = nn.Linear(A , A , bias=A ) snake_case__ : str = emb.weight.data return lin_layer def lowercase_ (A : Optional[int] , A : Union[str, Any]=None ): snake_case__ : Any = {} for old_key in state_dict.keys(): snake_case__ : Tuple = old_key if "moe_layer.experts." in key: if expert_idx is not None: snake_case__ : int = key.replace('moe_layer.experts.0' , F'''ffn.experts.expert_{expert_idx}''' ) else: snake_case__ : Any = key.replace('moe_layer.experts.' , 'ffn.experts.expert_' ) if "gate" in key: snake_case__ : Dict = key.replace('.moe_layer.gate.wg' , '.ffn.router.classifier' ) if "fc2" and "experts" not in key: snake_case__ : str = key.replace('.fc2.' , '.ffn.fc2.' ) if "fc1" and "experts" not in key: snake_case__ : str = key.replace('.fc1.' , '.ffn.fc1.' ) if ".encoder_attn." in key: snake_case__ : Tuple = key.replace('.encoder_attn.' , '.cross_attention.' ) if "encoder_attn_layer_norm" in key: snake_case__ : Tuple = key.replace('encoder_attn_layer_norm' , 'cross_attention_layer_norm' ) if "final_layer_norm" in key: snake_case__ : Optional[int] = key.replace('final_layer_norm' , 'ff_layer_norm' ) snake_case__ : Dict = state_dict[old_key] return new_dict def lowercase_ (A : List[Any] , A : Tuple , A : List[Any] , A : List[str] , A : str = WEIGHTS_NAME ): snake_case__ : Dict = [] snake_case__ : str = 0 os.makedirs(A , exist_ok=A ) for expert in range(A ): snake_case__ : Tuple = switch_checkpoint_path + F'''-rank-{expert}.pt''' if os.path.isfile(A ): snake_case__ : Optional[Any] = torch.load(A )['model'] remove_ignore_keys_(A ) snake_case__ : Optional[Any] = rename_fairseq_keys(A , A ) snake_case__ : Dict = os.path.join( A , weights_name.replace('.bin' , F'''-{len(A )+1:05d}-of-???.bin''' ) ) torch.save(A , A ) sharded_state_dicts.append(expert_state.keys() ) total_size += sum([value.numel() for key, value in expert_state.items()] ) * dtype_byte_size( expert_state[list(A )[0]].dtype ) # Add the last block snake_case__ : Tuple = os.path.join(A , weights_name.replace('.bin' , F'''-{len(A )+1:05d}-of-???.bin''' ) ) snake_case__ : Union[str, Any] = torch.load(switch_checkpoint_path + '-shared.pt' )['model'] remove_ignore_keys_(A ) snake_case__ : str = rename_fairseq_keys(A , A ) snake_case__ : Any = shared_weights['decoder.embed_tokens.weight'] sharded_state_dicts.append(shared_weights.keys() ) # If we only have the shared weights (dummy model/experts saved on the same file) if len(A ) == 1: snake_case__ : Any = os.path.join(A , A ) torch.save(A , A ) return {weights_name: sharded_state_dicts[0]}, None else: torch.save(A , A ) # Otherwise, let's build the index snake_case__ : Tuple = {} for idx, shard in enumerate(A ): snake_case__ : Optional[int] = weights_name.replace('.bin' , F'''-{idx+1:05d}-of-{len(A ):05d}.bin''' ) snake_case__ : List[Any] = os.path.join(A , weights_name.replace('.bin' , F'''-{idx+1:05d}-of-???.bin''' ) ) os.rename(A , os.path.join(A , A ) ) for key in shard: snake_case__ : Any = shard_file # Add the metadata snake_case__ : int = {'total_size': total_size} snake_case__ : Dict = {'metadata': metadata, 'weight_map': weight_map} with open(os.path.join(A , A ) , 'w' , encoding='utf-8' ) as f: snake_case__ : Any = json.dumps(A , indent=2 , sort_keys=A ) + '\n' f.write(A ) return metadata, index if __name__ == "__main__": a_ :int = argparse.ArgumentParser() # Required parameters parser.add_argument( "--nllb_moe_checkpoint_path", default="/home/arthur_huggingface_co/fairseq/weights/checkpoints/model_moe_54b/checkpoint_2_300000", type=str, required=False, help="Path to a directory containing a folder per layer. Follows the original Google format.", ) parser.add_argument("--dtype", default="float32", type=str, required=False, help="dtype of the saved model") parser.add_argument( "--pytorch_dump_folder_path", default="/home/arthur_huggingface_co/fairseq/weights/checkpoints/hf-converted-moe-54b", type=str, required=False, help="Path to the output pytorch model.", ) a_ :Optional[Any] = parser.parse_args() a_ , a_ :Optional[Any] = shard_on_the_fly( args.nllb_moe_checkpoint_path, args.pytorch_dump_folder_path, 128, args.dtype, ) a_ :List[str] = NllbMoeConfig.from_pretrained( "facebook/nllb-200-3.3B", encoder_sparse_step=4, decoder_sparse_step=4, num_experts=128 ) config.save_pretrained(args.pytorch_dump_folder_path) a_ :int = NllbMoeModel.from_pretrained(args.pytorch_dump_folder_path) print("Done") model.save_pretrained(args.pytorch_dump_folder_path)
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'''simple docstring''' def __lowerCAmelCase ( snake_case__ , snake_case__ , snake_case__ ): return not any( neighbour == 1 and colored_vertices[i] == color for i, neighbour in enumerate(snake_case__ ) ) def __lowerCAmelCase ( snake_case__ , snake_case__ , snake_case__ , snake_case__ ): # Base Case if index == len(snake_case__ ): return True # Recursive Step for i in range(snake_case__ ): if valid_coloring(graph[index] , snake_case__ , snake_case__ ): # Color current vertex __UpperCamelCase : Tuple = i # Validate coloring if util_color(snake_case__ , snake_case__ , snake_case__ , index + 1 ): return True # Backtrack __UpperCamelCase : int = -1 return False def __lowerCAmelCase ( snake_case__ , snake_case__ ): __UpperCamelCase : Union[str, Any] = [-1] * len(snake_case__ ) if util_color(snake_case__ , snake_case__ , snake_case__ , 0 ): return colored_vertices return []
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from typing import TYPE_CHECKING from ...utils import ( OptionalDependencyNotAvailable, _LazyModule, is_sentencepiece_available, is_tokenizers_available, is_torch_available, ) a_ :Optional[Any] = {"configuration_reformer": ["REFORMER_PRETRAINED_CONFIG_ARCHIVE_MAP", "ReformerConfig"]} try: if not is_sentencepiece_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: a_ :str = ["ReformerTokenizer"] try: if not is_tokenizers_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: a_ :int = ["ReformerTokenizerFast"] try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: a_ :List[str] = [ "REFORMER_PRETRAINED_MODEL_ARCHIVE_LIST", "ReformerAttention", "ReformerForMaskedLM", "ReformerForQuestionAnswering", "ReformerForSequenceClassification", "ReformerLayer", "ReformerModel", "ReformerModelWithLMHead", "ReformerPreTrainedModel", ] if TYPE_CHECKING: from .configuration_reformer import REFORMER_PRETRAINED_CONFIG_ARCHIVE_MAP, ReformerConfig try: if not is_sentencepiece_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .tokenization_reformer import ReformerTokenizer try: if not is_tokenizers_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .tokenization_reformer_fast import ReformerTokenizerFast try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_reformer import ( REFORMER_PRETRAINED_MODEL_ARCHIVE_LIST, ReformerAttention, ReformerForMaskedLM, ReformerForQuestionAnswering, ReformerForSequenceClassification, ReformerLayer, ReformerModel, ReformerModelWithLMHead, ReformerPreTrainedModel, ) else: import sys a_ :Optional[Any] = _LazyModule(__name__, globals()["__file__"], _import_structure, module_spec=__spec__)
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import unittest import numpy as np from transformers.testing_utils import require_torch, require_vision from transformers.utils import is_torch_available, is_vision_available from ...test_image_processing_common import ImageProcessingSavingTestMixin, prepare_image_inputs if is_torch_available(): import torch if is_vision_available(): from PIL import Image from transformers import PoolFormerImageProcessor class lowercase ( unittest.TestCase ): def __init__( self , _a , _a=7 , _a=3 , _a=30 , _a=400 , _a=True , _a=None , _a=0.9 , _a=None , _a=True , _a=[0.5, 0.5, 0.5] , _a=[0.5, 0.5, 0.5] , ) -> List[Any]: _A : int = size if size is not None else {'shortest_edge': 30} _A : Tuple = crop_size if crop_size is not None else {'height': 30, 'width': 30} _A : Union[str, Any] = parent _A : Dict = batch_size _A : int = num_channels _A : Tuple = min_resolution _A : Any = max_resolution _A : List[Any] = do_resize_and_center_crop _A : str = size _A : str = crop_pct _A : List[str] = crop_size _A : Optional[int] = do_normalize _A : Tuple = image_mean _A : Tuple = image_std def a__ ( self ) -> int: return { "size": self.size, "do_resize_and_center_crop": self.do_resize_and_center_crop, "crop_pct": self.crop_pct, "crop_size": self.crop_size, "do_normalize": self.do_normalize, "image_mean": self.image_mean, "image_std": self.image_std, } @require_torch @require_vision class lowercase ( lowerCAmelCase_,unittest.TestCase ): _a = PoolFormerImageProcessor if is_vision_available() else None def a__ ( self ) -> Dict: _A : Union[str, Any] = PoolFormerImageProcessingTester(self ) @property def a__ ( self ) -> Dict: return self.image_processor_tester.prepare_image_processor_dict() def a__ ( self ) -> Optional[int]: _A : List[str] = self.image_processing_class(**self.image_processor_dict ) self.assertTrue(hasattr(_snake_case , """do_resize_and_center_crop""" ) ) self.assertTrue(hasattr(_snake_case , """size""" ) ) self.assertTrue(hasattr(_snake_case , """crop_pct""" ) ) self.assertTrue(hasattr(_snake_case , """do_normalize""" ) ) self.assertTrue(hasattr(_snake_case , """image_mean""" ) ) self.assertTrue(hasattr(_snake_case , """image_std""" ) ) def a__ ( self ) -> List[str]: _A : Union[str, Any] = self.image_processing_class.from_dict(self.image_processor_dict ) self.assertEqual(image_processor.size , {"""shortest_edge""": 30} ) self.assertEqual(image_processor.crop_size , {"""height""": 30, """width""": 30} ) _A : int = self.image_processing_class.from_dict(self.image_processor_dict , size=42 , crop_size=84 ) self.assertEqual(image_processor.size , {"""shortest_edge""": 42} ) self.assertEqual(image_processor.crop_size , {"""height""": 84, """width""": 84} ) def a__ ( self ) -> List[Any]: pass def a__ ( self ) -> str: # Initialize image_processing _A : Union[str, Any] = self.image_processing_class(**self.image_processor_dict ) # create random PIL images _A : List[str] = prepare_image_inputs(self.image_processor_tester , equal_resolution=_snake_case ) for image in image_inputs: self.assertIsInstance(_snake_case , Image.Image ) # Test not batched input _A : Optional[int] = image_processing(image_inputs[0] , return_tensors="""pt""" ).pixel_values self.assertEqual( encoded_images.shape , ( 1, self.image_processor_tester.num_channels, self.image_processor_tester.crop_size["""height"""], self.image_processor_tester.crop_size["""width"""], ) , ) # Test batched _A : str = image_processing(_snake_case , return_tensors="""pt""" ).pixel_values self.assertEqual( encoded_images.shape , ( self.image_processor_tester.batch_size, self.image_processor_tester.num_channels, self.image_processor_tester.crop_size["""height"""], self.image_processor_tester.crop_size["""width"""], ) , ) def a__ ( self ) -> List[Any]: # Initialize image_processing _A : Optional[int] = self.image_processing_class(**self.image_processor_dict ) # create random numpy tensors _A : Dict = prepare_image_inputs(self.image_processor_tester , equal_resolution=_snake_case , numpify=_snake_case ) for image in image_inputs: self.assertIsInstance(_snake_case , np.ndarray ) # Test not batched input _A : Dict = image_processing(image_inputs[0] , return_tensors="""pt""" ).pixel_values self.assertEqual( encoded_images.shape , ( 1, self.image_processor_tester.num_channels, self.image_processor_tester.crop_size["""height"""], self.image_processor_tester.crop_size["""width"""], ) , ) # Test batched _A : List[Any] = image_processing(_snake_case , return_tensors="""pt""" ).pixel_values self.assertEqual( encoded_images.shape , ( self.image_processor_tester.batch_size, self.image_processor_tester.num_channels, self.image_processor_tester.crop_size["""height"""], self.image_processor_tester.crop_size["""width"""], ) , ) def a__ ( self ) -> List[str]: # Initialize image_processing _A : Tuple = self.image_processing_class(**self.image_processor_dict ) # create random PyTorch tensors _A : List[str] = prepare_image_inputs(self.image_processor_tester , equal_resolution=_snake_case , torchify=_snake_case ) for image in image_inputs: self.assertIsInstance(_snake_case , torch.Tensor ) # Test not batched input _A : Tuple = image_processing(image_inputs[0] , return_tensors="""pt""" ).pixel_values self.assertEqual( encoded_images.shape , ( 1, self.image_processor_tester.num_channels, self.image_processor_tester.crop_size["""height"""], self.image_processor_tester.crop_size["""width"""], ) , ) # Test batched _A : Optional[Any] = image_processing(_snake_case , return_tensors="""pt""" ).pixel_values self.assertEqual( encoded_images.shape , ( self.image_processor_tester.batch_size, self.image_processor_tester.num_channels, self.image_processor_tester.crop_size["""height"""], self.image_processor_tester.crop_size["""width"""], ) , )
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import itertools import random import unittest import numpy as np from transformers import BatchFeature, SpeechTaFeatureExtractor from transformers.testing_utils import require_torch from transformers.utils.import_utils import is_torch_available from ...test_sequence_feature_extraction_common import SequenceFeatureExtractionTestMixin if is_torch_available(): import torch a_ :Any = random.Random() def lowercase_ (A : int , A : Union[str, Any]=1.0 , A : List[str]=None , A : Any=None ): if rng is None: snake_case__ : List[str] = global_rng snake_case__ : int = [] for batch_idx in range(shape[0] ): values.append([] ) for _ in range(shape[1] ): values[-1].append(rng.random() * scale ) return values @require_torch class snake_case__ ( unittest.TestCase ): """simple docstring""" def __init__( self : Optional[Any], _snake_case : List[str], _snake_case : Tuple=7, _snake_case : Union[str, Any]=4_0_0, _snake_case : Any=2_0_0_0, _snake_case : Dict=1, _snake_case : Optional[Any]=0.0, _snake_case : List[Any]=1_6_0_0_0, _snake_case : List[Any]=True, _snake_case : List[Any]=8_0, _snake_case : Dict=1_6, _snake_case : str=6_4, _snake_case : Tuple="hann_window", _snake_case : Union[str, Any]=8_0, _snake_case : Optional[Any]=7_6_0_0, _snake_case : str=1e-10, _snake_case : Any=True, ) ->Union[str, Any]: snake_case__ : Optional[int] = parent snake_case__ : Optional[Any] = batch_size snake_case__ : List[Any] = min_seq_length snake_case__ : List[Any] = max_seq_length snake_case__ : Any = (self.max_seq_length - self.min_seq_length) // (self.batch_size - 1) snake_case__ : Tuple = feature_size snake_case__ : List[Any] = padding_value snake_case__ : Any = sampling_rate snake_case__ : Dict = do_normalize snake_case__ : Union[str, Any] = num_mel_bins snake_case__ : Any = hop_length snake_case__ : Any = win_length snake_case__ : Any = win_function snake_case__ : Optional[int] = fmin snake_case__ : int = fmax snake_case__ : Union[str, Any] = mel_floor snake_case__ : Union[str, Any] = return_attention_mask def lowercase_ ( self : Optional[int] ) ->List[str]: return { "feature_size": self.feature_size, "padding_value": self.padding_value, "sampling_rate": self.sampling_rate, "do_normalize": self.do_normalize, "num_mel_bins": self.num_mel_bins, "hop_length": self.hop_length, "win_length": self.win_length, "win_function": self.win_function, "fmin": self.fmin, "fmax": self.fmax, "mel_floor": self.mel_floor, "return_attention_mask": self.return_attention_mask, } def lowercase_ ( self : Any, _snake_case : Optional[Any]=False, _snake_case : List[str]=False ) ->Union[str, Any]: def _flatten(_snake_case : List[str] ): return list(itertools.chain(*_snake_case ) ) if equal_length: snake_case__ : Any = floats_list((self.batch_size, self.max_seq_length) ) else: # make sure that inputs increase in size snake_case__ : int = [ _flatten(floats_list((x, self.feature_size) ) ) for x in range(self.min_seq_length, self.max_seq_length, self.seq_length_diff ) ] if numpify: snake_case__ : Any = [np.asarray(_snake_case ) for x in speech_inputs] return speech_inputs def lowercase_ ( self : Union[str, Any], _snake_case : str=False, _snake_case : Dict=False ) ->List[str]: if equal_length: snake_case__ : Optional[Any] = [floats_list((self.max_seq_length, self.num_mel_bins) ) for _ in range(self.batch_size )] else: # make sure that inputs increase in size snake_case__ : List[str] = [ floats_list((x, self.num_mel_bins) ) for x in range(self.min_seq_length, self.max_seq_length, self.seq_length_diff ) ] if numpify: snake_case__ : int = [np.asarray(_snake_case ) for x in speech_inputs] return speech_inputs @require_torch class snake_case__ ( lowerCAmelCase_ , unittest.TestCase ): """simple docstring""" _SCREAMING_SNAKE_CASE = SpeechTaFeatureExtractor def lowercase_ ( self : int ) ->Union[str, Any]: snake_case__ : List[str] = SpeechTaFeatureExtractionTester(self ) def lowercase_ ( self : Any, _snake_case : Dict ) ->Any: self.assertTrue(np.all(np.mean(_snake_case, axis=0 ) < 1e-3 ) ) self.assertTrue(np.all(np.abs(np.var(_snake_case, axis=0 ) - 1 ) < 1e-3 ) ) def lowercase_ ( self : List[Any] ) ->Union[str, Any]: # Tests that all call wrap to encode_plus and batch_encode_plus snake_case__ : Optional[Any] = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) # create three inputs of length 800, 1000, and 1200 snake_case__ : int = [floats_list((1, x) )[0] for x in range(8_0_0, 1_4_0_0, 2_0_0 )] snake_case__ : Tuple = [np.asarray(_snake_case ) for speech_input in speech_inputs] # Test not batched input snake_case__ : str = feat_extract(speech_inputs[0], return_tensors='np' ).input_values snake_case__ : List[str] = feat_extract(np_speech_inputs[0], return_tensors='np' ).input_values self.assertTrue(np.allclose(_snake_case, _snake_case, atol=1e-3 ) ) # Test batched snake_case__ : Any = feat_extract(_snake_case, return_tensors='np' ).input_values snake_case__ : Union[str, Any] = feat_extract(_snake_case, return_tensors='np' ).input_values for enc_seq_a, enc_seq_a in zip(_snake_case, _snake_case ): self.assertTrue(np.allclose(_snake_case, _snake_case, atol=1e-3 ) ) def lowercase_ ( self : int ) ->Optional[int]: snake_case__ : List[Any] = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) snake_case__ : Tuple = [floats_list((1, x) )[0] for x in range(8_0_0, 1_4_0_0, 2_0_0 )] snake_case__ : int = ['longest', 'max_length', 'do_not_pad'] snake_case__ : List[str] = [None, 1_6_0_0, None] for max_length, padding in zip(_snake_case, _snake_case ): snake_case__ : Optional[int] = feat_extract(_snake_case, padding=_snake_case, max_length=_snake_case, return_tensors='np' ) snake_case__ : Optional[int] = processed.input_values self._check_zero_mean_unit_variance(input_values[0][:8_0_0] ) self.assertTrue(input_values[0][8_0_0:].sum() < 1e-6 ) self._check_zero_mean_unit_variance(input_values[1][:1_0_0_0] ) self.assertTrue(input_values[0][1_0_0_0:].sum() < 1e-6 ) self._check_zero_mean_unit_variance(input_values[2][:1_2_0_0] ) def lowercase_ ( self : Union[str, Any] ) ->Optional[Any]: snake_case__ : Optional[Any] = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) snake_case__ : Tuple = range(8_0_0, 1_4_0_0, 2_0_0 ) snake_case__ : Optional[Any] = [floats_list((1, x) )[0] for x in lengths] snake_case__ : Union[str, Any] = ['longest', 'max_length', 'do_not_pad'] snake_case__ : str = [None, 1_6_0_0, None] for max_length, padding in zip(_snake_case, _snake_case ): snake_case__ : List[str] = feat_extract(_snake_case, max_length=_snake_case, padding=_snake_case ) snake_case__ : Tuple = processed.input_values self._check_zero_mean_unit_variance(input_values[0][:8_0_0] ) self._check_zero_mean_unit_variance(input_values[1][:1_0_0_0] ) self._check_zero_mean_unit_variance(input_values[2][:1_2_0_0] ) def lowercase_ ( self : List[Any] ) ->Optional[Any]: snake_case__ : Any = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) snake_case__ : str = [floats_list((1, x) )[0] for x in range(8_0_0, 1_4_0_0, 2_0_0 )] snake_case__ : Optional[Any] = feat_extract( _snake_case, truncation=_snake_case, max_length=1_0_0_0, padding='max_length', return_tensors='np' ) snake_case__ : int = processed.input_values self._check_zero_mean_unit_variance(input_values[0, :8_0_0] ) self._check_zero_mean_unit_variance(input_values[1] ) self._check_zero_mean_unit_variance(input_values[2] ) def lowercase_ ( self : int ) ->Union[str, Any]: snake_case__ : str = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) snake_case__ : Dict = [floats_list((1, x) )[0] for x in range(8_0_0, 1_4_0_0, 2_0_0 )] snake_case__ : str = feat_extract( _snake_case, truncation=_snake_case, max_length=1_0_0_0, padding='longest', return_tensors='np' ) snake_case__ : Dict = processed.input_values self._check_zero_mean_unit_variance(input_values[0, :8_0_0] ) self._check_zero_mean_unit_variance(input_values[1, :1_0_0_0] ) self._check_zero_mean_unit_variance(input_values[2] ) # make sure that if max_length < longest -> then pad to max_length self.assertTrue(input_values.shape == (3, 1_0_0_0) ) snake_case__ : Tuple = [floats_list((1, x) )[0] for x in range(8_0_0, 1_4_0_0, 2_0_0 )] snake_case__ : List[str] = feat_extract( _snake_case, truncation=_snake_case, max_length=2_0_0_0, padding='longest', return_tensors='np' ) snake_case__ : Optional[Any] = processed.input_values self._check_zero_mean_unit_variance(input_values[0, :8_0_0] ) self._check_zero_mean_unit_variance(input_values[1, :1_0_0_0] ) self._check_zero_mean_unit_variance(input_values[2] ) # make sure that if max_length > longest -> then pad to longest self.assertTrue(input_values.shape == (3, 1_2_0_0) ) def lowercase_ ( self : List[str] ) ->Dict: snake_case__ : Dict = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) snake_case__ : List[Any] = np.random.rand(1_0_0 ).astype(np.floataa ) snake_case__ : int = np_speech_inputs.tolist() for inputs in [py_speech_inputs, np_speech_inputs]: snake_case__ : int = feature_extractor.pad([{'input_values': inputs}], return_tensors='np' ) self.assertTrue(np_processed.input_values.dtype == np.floataa ) snake_case__ : Optional[int] = feature_extractor.pad([{'input_values': inputs}], return_tensors='pt' ) self.assertTrue(pt_processed.input_values.dtype == torch.floataa ) def lowercase_ ( self : Optional[int] ) ->Optional[Any]: # Tests that all call wrap to encode_plus and batch_encode_plus snake_case__ : str = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) # create three inputs of length 800, 1000, and 1200 snake_case__ : List[Any] = [floats_list((1, x) )[0] for x in range(8_0_0, 1_4_0_0, 2_0_0 )] snake_case__ : Dict = [np.asarray(_snake_case ) for speech_input in speech_inputs] # Test feature size snake_case__ : Optional[int] = feature_extractor(audio_target=_snake_case, padding=_snake_case, return_tensors='np' ).input_values self.assertTrue(input_values.ndim == 3 ) self.assertTrue(input_values.shape[-1] == feature_extractor.num_mel_bins ) # Test not batched input snake_case__ : Dict = feature_extractor(speech_inputs[0], return_tensors='np' ).input_values snake_case__ : Any = feature_extractor(np_speech_inputs[0], return_tensors='np' ).input_values self.assertTrue(np.allclose(_snake_case, _snake_case, atol=1e-3 ) ) # Test batched snake_case__ : Dict = feature_extractor(_snake_case, return_tensors='np' ).input_values snake_case__ : Dict = feature_extractor(_snake_case, return_tensors='np' ).input_values for enc_seq_a, enc_seq_a in zip(_snake_case, _snake_case ): self.assertTrue(np.allclose(_snake_case, _snake_case, atol=1e-3 ) ) # Test 2-D numpy arrays are batched. snake_case__ : Optional[Any] = [floats_list((1, x) )[0] for x in (8_0_0, 8_0_0, 8_0_0)] snake_case__ : int = np.asarray(_snake_case ) snake_case__ : Union[str, Any] = feature_extractor(_snake_case, return_tensors='np' ).input_values snake_case__ : Union[str, Any] = feature_extractor(_snake_case, return_tensors='np' ).input_values for enc_seq_a, enc_seq_a in zip(_snake_case, _snake_case ): self.assertTrue(np.allclose(_snake_case, _snake_case, atol=1e-3 ) ) def lowercase_ ( self : Union[str, Any] ) ->str: snake_case__ : int = self.feat_extract_tester.prepare_inputs_for_target() snake_case__ : List[str] = self.feature_extraction_class(**self.feat_extract_dict ) snake_case__ : Optional[Any] = feat_extract.model_input_names[0] snake_case__ : Tuple = BatchFeature({input_name: speech_inputs} ) self.assertTrue(all(len(_snake_case ) == len(_snake_case ) for x, y in zip(_snake_case, processed_features[input_name] ) ) ) snake_case__ : int = self.feat_extract_tester.prepare_inputs_for_target(equal_length=_snake_case ) snake_case__ : Union[str, Any] = BatchFeature({input_name: speech_inputs}, tensor_type='np' ) snake_case__ : Dict = processed_features[input_name] if len(batch_features_input.shape ) < 3: snake_case__ : List[str] = batch_features_input[:, :, None] self.assertTrue( batch_features_input.shape == (self.feat_extract_tester.batch_size, len(speech_inputs[0] ), self.feat_extract_tester.num_mel_bins) ) @require_torch def lowercase_ ( self : List[str] ) ->Any: snake_case__ : int = self.feat_extract_tester.prepare_inputs_for_target(equal_length=_snake_case ) snake_case__ : Optional[Any] = self.feature_extraction_class(**self.feat_extract_dict ) snake_case__ : Tuple = feat_extract.model_input_names[0] snake_case__ : List[Any] = BatchFeature({input_name: speech_inputs}, tensor_type='pt' ) snake_case__ : Tuple = processed_features[input_name] if len(batch_features_input.shape ) < 3: snake_case__ : Any = batch_features_input[:, :, None] self.assertTrue( batch_features_input.shape == (self.feat_extract_tester.batch_size, len(speech_inputs[0] ), self.feat_extract_tester.num_mel_bins) ) @require_torch def lowercase_ ( self : Optional[int] ) ->Tuple: snake_case__ : Dict = self.feature_extraction_class(**self.feat_extract_dict ) snake_case__ : Union[str, Any] = self.feat_extract_tester.prepare_inputs_for_target() snake_case__ : Optional[Any] = feat_extract.model_input_names[0] snake_case__ : List[str] = BatchFeature({input_name: speech_inputs} ) snake_case__ : int = feat_extract.num_mel_bins # hack! snake_case__ : Tuple = feat_extract.pad(_snake_case, padding='longest', return_tensors='np' )[input_name] snake_case__ : Union[str, Any] = feat_extract.pad(_snake_case, padding='longest', return_tensors='pt' )[input_name] self.assertTrue(abs(input_np.astype(np.floataa ).sum() - input_pt.numpy().astype(np.floataa ).sum() ) < 1e-2 ) def lowercase_ ( self : int ) ->Any: snake_case__ : Any = self.feat_extract_dict snake_case__ : List[Any] = True snake_case__ : Union[str, Any] = self.feature_extraction_class(**_snake_case ) snake_case__ : Any = self.feat_extract_tester.prepare_inputs_for_target() snake_case__ : List[Any] = [len(_snake_case ) for x in speech_inputs] snake_case__ : Union[str, Any] = feat_extract.model_input_names[0] snake_case__ : Optional[int] = BatchFeature({input_name: speech_inputs} ) snake_case__ : List[str] = feat_extract.num_mel_bins # hack! snake_case__ : str = feat_extract.pad(_snake_case, padding='longest', return_tensors='np' ) self.assertIn('attention_mask', _snake_case ) self.assertListEqual(list(processed.attention_mask.shape ), list(processed[input_name].shape[:2] ) ) self.assertListEqual(processed.attention_mask.sum(-1 ).tolist(), _snake_case ) def lowercase_ ( self : Optional[int] ) ->str: snake_case__ : int = self.feat_extract_dict snake_case__ : List[str] = True snake_case__ : Tuple = self.feature_extraction_class(**_snake_case ) snake_case__ : List[str] = self.feat_extract_tester.prepare_inputs_for_target() snake_case__ : str = [len(_snake_case ) for x in speech_inputs] snake_case__ : Optional[Any] = feat_extract.model_input_names[0] snake_case__ : Optional[int] = BatchFeature({input_name: speech_inputs} ) snake_case__ : Optional[Any] = min(_snake_case ) snake_case__ : Union[str, Any] = feat_extract.num_mel_bins # hack! snake_case__ : Tuple = feat_extract.pad( _snake_case, padding='max_length', max_length=_snake_case, truncation=_snake_case, return_tensors='np' ) self.assertIn('attention_mask', _snake_case ) self.assertListEqual( list(processed_pad.attention_mask.shape ), [processed_pad[input_name].shape[0], max_length] ) self.assertListEqual( processed_pad.attention_mask[:, :max_length].sum(-1 ).tolist(), [max_length for x in speech_inputs] ) def lowercase_ ( self : List[Any], _snake_case : Optional[int] ) ->Optional[Any]: from datasets import load_dataset snake_case__ : str = load_dataset('hf-internal-testing/librispeech_asr_dummy', 'clean', split='validation' ) # automatic decoding with librispeech snake_case__ : Dict = ds.sort('id' ).select(range(_snake_case ) )[:num_samples]['audio'] return [x["array"] for x in speech_samples] def lowercase_ ( self : str ) ->str: # fmt: off snake_case__ : List[Any] = torch.tensor( [2.3804e-03, 2.0752e-03, 1.9836e-03, 2.1057e-03, 1.6174e-03, 3.0518e-04, 9.1553e-05, 3.3569e-04, 9.7656e-04, 1.8311e-03, 2.0142e-03, 2.1057e-03, 1.7395e-03, 4.5776e-04, -3.9673e-04, 4.5776e-04, 1.0071e-03, 9.1553e-05, 4.8828e-04, 1.1597e-03, 7.3242e-04, 9.4604e-04, 1.8005e-03, 1.8311e-03, 8.8501e-04, 4.2725e-04, 4.8828e-04, 7.3242e-04, 1.0986e-03, 2.1057e-03] ) # fmt: on snake_case__ : Union[str, Any] = self._load_datasamples(1 ) snake_case__ : Optional[int] = SpeechTaFeatureExtractor() snake_case__ : List[Any] = feature_extractor(_snake_case, return_tensors='pt' ).input_values self.assertEquals(input_values.shape, (1, 9_3_6_8_0) ) self.assertTrue(torch.allclose(input_values[0, :3_0], _snake_case, atol=1e-6 ) ) def lowercase_ ( self : Any ) ->str: # fmt: off snake_case__ : Optional[Any] = torch.tensor( [-2.6_8_7_0, -3.0_1_0_4, -3.1_3_5_6, -3.5_3_5_2, -3.0_0_4_4, -3.0_3_5_3, -3.4_7_1_9, -3.6_7_7_7, -3.1_5_2_0, -2.9_4_3_5, -2.6_5_5_3, -2.8_7_9_5, -2.9_9_4_4, -2.5_9_2_1, -3.0_2_7_9, -3.0_3_8_6, -3.0_8_6_4, -3.1_2_9_1, -3.2_3_5_3, -2.7_4_4_4, -2.6_8_3_1, -2.7_2_8_7, -3.1_7_6_1, -3.1_5_7_1, -3.2_7_2_6, -3.0_5_8_2, -3.1_0_0_7, -3.4_5_3_3, -3.4_6_9_5, -3.0_9_9_8] ) # fmt: on snake_case__ : List[str] = self._load_datasamples(1 ) snake_case__ : str = SpeechTaFeatureExtractor() snake_case__ : Optional[Any] = feature_extractor(audio_target=_snake_case, return_tensors='pt' ).input_values self.assertEquals(input_values.shape, (1, 3_6_6, 8_0) ) self.assertTrue(torch.allclose(input_values[0, 0, :3_0], _snake_case, atol=1e-4 ) )
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import unittest from transformers import AutoTokenizer, is_flax_available from transformers.testing_utils import require_flax, require_sentencepiece, require_tokenizers, slow if is_flax_available(): import jax.numpy as jnp from transformers import FlaxXLMRobertaModel @require_sentencepiece @require_tokenizers @require_flax class __lowerCAmelCase ( unittest.TestCase ): @slow def _lowerCamelCase ( self : Optional[Any]) -> Optional[Any]: """simple docstring""" _UpperCAmelCase = FlaxXLMRobertaModel.from_pretrained('xlm-roberta-base') _UpperCAmelCase = AutoTokenizer.from_pretrained('xlm-roberta-base') _UpperCAmelCase = 'The dog is cute and lives in the garden house' _UpperCAmelCase = jnp.array([tokenizer.encode(_snake_case)]) _UpperCAmelCase = (1, 12, 7_68) # batch_size, sequence_length, embedding_vector_dim _UpperCAmelCase = jnp.array( [[-0.0_1_0_1, 0.1_2_1_8, -0.0_8_0_3, 0.0_8_0_1, 0.1_3_2_7, 0.0_7_7_6, -0.1_2_1_5, 0.2_3_8_3, 0.3_3_3_8, 0.3_1_0_6, 0.0_3_0_0, 0.0_2_5_2]]) _UpperCAmelCase = model(_snake_case)['last_hidden_state'] self.assertEqual(output.shape , _snake_case) # compare the actual values for a slice of last dim self.assertTrue(jnp.allclose(output[:, :, -1] , _snake_case , atol=1E-3))
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# Copyright 2023 The HuggingFace Inc. team. All rights reserved. # # Licensed under the Apache License, Version 2.0 (the "License"); # you may not use this file except in compliance with the License. # You may obtain a copy of the License at # # http://www.apache.org/licenses/LICENSE-2.0 # # Unless required by applicable law or agreed to in writing, software # distributed under the License is distributed on an "AS IS" BASIS, # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. # See the License for the specific language governing permissions and # limitations under the License. from ..models.auto import AutoModelForSeqaSeqLM, AutoTokenizer from .base import PipelineTool class snake_case__ ( lowerCAmelCase_ ): """simple docstring""" _SCREAMING_SNAKE_CASE = """philschmid/bart-large-cnn-samsum""" _SCREAMING_SNAKE_CASE = ( """This is a tool that summarizes an English text. It takes an input `text` containing the text to summarize, """ """and returns a summary of the text.""" ) _SCREAMING_SNAKE_CASE = """summarizer""" _SCREAMING_SNAKE_CASE = AutoTokenizer _SCREAMING_SNAKE_CASE = AutoModelForSeqaSeqLM _SCREAMING_SNAKE_CASE = ["""text"""] _SCREAMING_SNAKE_CASE = ["""text"""] def lowercase_ ( self : Optional[Any], _snake_case : str ) ->Any: return self.pre_processor(_snake_case, return_tensors='pt', truncation=_snake_case ) def lowercase_ ( self : int, _snake_case : List[Any] ) ->Any: return self.model.generate(**_snake_case )[0] def lowercase_ ( self : int, _snake_case : int ) ->str: return self.pre_processor.decode(_snake_case, skip_special_tokens=_snake_case, clean_up_tokenization_spaces=_snake_case )
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from __future__ import annotations def __UpperCAmelCase ( a_ , a_): snake_case_ = [] snake_case_ = [] snake_case_ = 0 snake_case_ = sum(a_) create_state_space_tree(a_ , a_ , a_ , a_ , a_ , a_) return result def __UpperCAmelCase ( a_ , a_ , a_ , a_ , a_ , a_ , ): if sum(a_) > max_sum or (remaining_nums_sum + sum(a_)) < max_sum: return if sum(a_) == max_sum: result.append(a_) return for index in range(a_ , len(a_)): create_state_space_tree( a_ , a_ , index + 1 , [*path, nums[index]] , a_ , remaining_nums_sum - nums[index] , ) lowercase = [3, 34, 4, 12, 5, 2] lowercase = 9 lowercase = generate_sum_of_subsets_soln(nums, max_sum) print(*result)
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import argparse import torch from transformers import LxmertConfig, LxmertForPreTraining, load_tf_weights_in_lxmert from transformers.utils import logging logging.set_verbosity_info() def lowercase_ (A : str , A : List[Any] , A : Any ): # Initialise PyTorch model snake_case__ : List[Any] = LxmertConfig.from_json_file(A ) print(F'''Building PyTorch model from configuration: {config}''' ) snake_case__ : List[str] = LxmertForPreTraining(A ) # Load weights from tf checkpoint load_tf_weights_in_lxmert(A , A , A ) # Save pytorch-model print(F'''Save PyTorch model to {pytorch_dump_path}''' ) torch.save(model.state_dict() , A ) if __name__ == "__main__": a_ :Union[str, Any] = argparse.ArgumentParser() # Required parameters parser.add_argument( "--tf_checkpoint_path", default=None, type=str, required=True, help="Path to the TensorFlow checkpoint path." ) parser.add_argument( "--config_file", default=None, type=str, required=True, help="The config json file corresponding to the pre-trained model. \nThis specifies the model architecture.", ) parser.add_argument( "--pytorch_dump_path", default=None, type=str, required=True, help="Path to the output PyTorch model." ) a_ :Optional[int] = parser.parse_args() convert_tf_checkpoint_to_pytorch(args.tf_checkpoint_path, args.config_file, args.pytorch_dump_path)
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"""simple docstring""" import argparse import torch from transformers import GPTaConfig, GPTaModel, load_tf_weights_in_gpta from transformers.utils import CONFIG_NAME, WEIGHTS_NAME, logging logging.set_verbosity_info() def lowercase (SCREAMING_SNAKE_CASE_ : List[str] , SCREAMING_SNAKE_CASE_ : Optional[Any] , SCREAMING_SNAKE_CASE_ : Dict ) -> int: # Construct model if gpta_config_file == "": SCREAMING_SNAKE_CASE = GPTaConfig() else: SCREAMING_SNAKE_CASE = GPTaConfig.from_json_file(SCREAMING_SNAKE_CASE_ ) SCREAMING_SNAKE_CASE = GPTaModel(SCREAMING_SNAKE_CASE_ ) # Load weights from numpy load_tf_weights_in_gpta(SCREAMING_SNAKE_CASE_ , SCREAMING_SNAKE_CASE_ , SCREAMING_SNAKE_CASE_ ) # Save pytorch-model SCREAMING_SNAKE_CASE = pytorch_dump_folder_path + '/' + WEIGHTS_NAME SCREAMING_SNAKE_CASE = pytorch_dump_folder_path + '/' + CONFIG_NAME print(F'Save PyTorch model to {pytorch_weights_dump_path}' ) torch.save(model.state_dict() , SCREAMING_SNAKE_CASE_ ) print(F'Save configuration file to {pytorch_config_dump_path}' ) with open(SCREAMING_SNAKE_CASE_ , 'w' , encoding='utf-8' ) as f: f.write(config.to_json_string() ) if __name__ == "__main__": __UpperCamelCase = argparse.ArgumentParser() # Required parameters parser.add_argument( '''--gpt2_checkpoint_path''', default=None, type=str, required=True, help='''Path to the TensorFlow checkpoint path.''' ) parser.add_argument( '''--pytorch_dump_folder_path''', default=None, type=str, required=True, help='''Path to the output PyTorch model.''' ) parser.add_argument( '''--gpt2_config_file''', default='''''', type=str, help=( '''An optional config json file corresponding to the pre-trained OpenAI model. \n''' '''This specifies the model architecture.''' ), ) __UpperCamelCase = parser.parse_args() convert_gpta_checkpoint_to_pytorch(args.gpta_checkpoint_path, args.gpta_config_file, args.pytorch_dump_folder_path)
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import argparse import fairseq import torch from torch import nn from transformers import ( MBartaaTokenizer, MBartConfig, MBartForCausalLM, SpeechEncoderDecoderConfig, SpeechEncoderDecoderModel, WavaVecaConfig, WavaVecaFeatureExtractor, WavaVecaModel, logging, ) logging.set_verbosity_info() a_ :Tuple = logging.get_logger(__name__) a_ :List[Any] = { "post_extract_proj": "feature_projection.projection", "encoder.pos_conv.0": "encoder.pos_conv_embed.conv", "self_attn.k_proj": "encoder.layers.*.attention.k_proj", "self_attn.v_proj": "encoder.layers.*.attention.v_proj", "self_attn.q_proj": "encoder.layers.*.attention.q_proj", "self_attn.out_proj": "encoder.layers.*.attention.out_proj", "self_attn_layer_norm": "encoder.layers.*.layer_norm", "fc1": "encoder.layers.*.feed_forward.intermediate_dense", "fc2": "encoder.layers.*.feed_forward.output_dense", "final_layer_norm": "encoder.layers.*.final_layer_norm", "encoder.layer_norm": "encoder.layer_norm", "w2v_model.layer_norm": "feature_projection.layer_norm", "quantizer.weight_proj": "quantizer.weight_proj", "quantizer.vars": "quantizer.codevectors", "project_q": "project_q", "final_proj": "project_hid", "w2v_encoder.proj": "lm_head", "mask_emb": "masked_spec_embed", } a_ :Optional[int] = [ "lm_head", "quantizer.weight_proj", "quantizer.codevectors", "project_q", "project_hid", ] def lowercase_ (A : Union[str, Any] , A : str , A : Dict , A : Optional[Any] , A : Optional[Any] ): for attribute in key.split('.' ): snake_case__ : Any = getattr(A , A ) if weight_type is not None: snake_case__ : Optional[Any] = getattr(A , A ).shape else: snake_case__ : Optional[int] = hf_pointer.shape assert hf_shape == value.shape, ( F'''Shape of hf {key + "." + weight_type if weight_type is not None else ""} is {hf_shape}, but should be''' F''' {value.shape} for {full_name}''' ) if weight_type == "weight": snake_case__ : Tuple = value elif weight_type == "weight_g": snake_case__ : Tuple = value elif weight_type == "weight_v": snake_case__ : List[Any] = value elif weight_type == "bias": snake_case__ : List[Any] = value else: snake_case__ : Optional[Any] = value logger.info(F'''{key + "." + weight_type if weight_type is not None else ""} was initialized from {full_name}.''' ) def lowercase_ (A : str , A : Any ): snake_case__ : Union[str, Any] = [] snake_case__ : Union[str, Any] = fairseq_model.state_dict() snake_case__ : Union[str, Any] = hf_model.feature_extractor snake_case__ : Any = hf_model.adapter for name, value in fairseq_dict.items(): snake_case__ : Any = False if "conv_layers" in name: load_conv_layer( A , A , A , A , hf_model.config.feat_extract_norm == 'group' , ) snake_case__ : List[Any] = True elif any(x in name for x in ['adaptor', 'w2v_encoder.proj.', 'w2v_proj_ln.'] ): load_adapter(A , A , A , A ) snake_case__ : Optional[Any] = True else: for key, mapped_key in MAPPING.items(): if key in name or key.split('w2v_model.' )[-1] == name.split('.' )[0]: snake_case__ : Tuple = True if "*" in mapped_key: snake_case__ : List[Any] = name.split(A )[0].split('.' )[-2] snake_case__ : Optional[int] = mapped_key.replace('*' , A ) if "weight_g" in name: snake_case__ : Optional[int] = 'weight_g' elif "weight_v" in name: snake_case__ : Optional[Any] = 'weight_v' elif "bias" in name: snake_case__ : Union[str, Any] = 'bias' elif "weight" in name: snake_case__ : Optional[int] = 'weight' else: snake_case__ : Tuple = None set_recursively(A , A , A , A , A ) continue if not is_used: unused_weights.append(A ) logger.warning(F'''Unused weights: {unused_weights}''' ) def lowercase_ (A : Union[str, Any] , A : Any , A : str , A : str , A : int ): snake_case__ : str = full_name.split('conv_layers.' )[-1] snake_case__ : Optional[int] = name.split('.' ) snake_case__ : Tuple = int(items[0] ) snake_case__ : Any = int(items[1] ) if type_id == 0: if "bias" in name: assert value.shape == feature_extractor.conv_layers[layer_id].conv.bias.data.shape, ( F'''{full_name} has size {value.shape}, but''' F''' {feature_extractor.conv_layers[layer_id].conv.bias.data.shape} was found.''' ) snake_case__ : Union[str, Any] = value logger.info(F'''Feat extract conv layer {layer_id} was initialized from {full_name}.''' ) elif "weight" in name: assert value.shape == feature_extractor.conv_layers[layer_id].conv.weight.data.shape, ( F'''{full_name} has size {value.shape}, but''' F''' {feature_extractor.conv_layers[layer_id].conv.weight.data.shape} was found.''' ) snake_case__ : Union[str, Any] = value logger.info(F'''Feat extract conv layer {layer_id} was initialized from {full_name}.''' ) elif (type_id == 2 and not use_group_norm) or (type_id == 2 and layer_id == 0 and use_group_norm): if "bias" in name: assert value.shape == feature_extractor.conv_layers[layer_id].layer_norm.bias.data.shape, ( F'''{full_name} has size {value.shape}, but {feature_extractor[layer_id].layer_norm.bias.data.shape} was''' " found." ) snake_case__ : Optional[int] = value logger.info(F'''Feat extract layer norm weight of layer {layer_id} was initialized from {full_name}.''' ) elif "weight" in name: assert value.shape == feature_extractor.conv_layers[layer_id].layer_norm.weight.data.shape, ( F'''{full_name} has size {value.shape}, but''' F''' {feature_extractor[layer_id].layer_norm.weight.data.shape} was found.''' ) snake_case__ : Optional[Any] = value logger.info(F'''Feat extract layer norm weight of layer {layer_id} was initialized from {full_name}.''' ) else: unused_weights.append(A ) def lowercase_ (A : Optional[Any] , A : Any , A : Tuple , A : Any ): snake_case__ : List[str] = full_name.split('adaptor.' )[-1] snake_case__ : Tuple = name.split('.' ) if items[1].isdigit(): snake_case__ : Optional[int] = int(items[1] ) else: snake_case__ : Any = None if "adaptor" not in full_name: if "proj_ln" in full_name: # has to be layer norm if "bias" in name: assert ( value.shape == adapter.proj_layer_norm.bias.data.shape ), F'''{full_name} has size {value.shape}, but {adapter.proj_layer_norm.bias.data.shape} was found.''' snake_case__ : List[Any] = value logger.info(F'''Adapter proj layer norm bias was initialized from {full_name}.''' ) if "weight" in name: assert ( value.shape == adapter.proj_layer_norm.weight.data.shape ), F'''{full_name} has size {value.shape}, but {adapter.proj_layer_norm.weight.data.shape} was found.''' snake_case__ : int = value else: # has to be projection layer if "bias" in name: assert ( value.shape == adapter.proj.bias.data.shape ), F'''{full_name} has size {value.shape}, but {adapter.proj.bias.data.shape} was found.''' snake_case__ : str = value logger.info(F'''Adapter proj layer bias was initialized from {full_name}.''' ) if "weight" in name: assert ( value.shape == adapter.proj.weight.data.shape ), F'''{full_name} has size {value.shape}, but {adapter.proj.weight.data.shape} was found.''' snake_case__ : Dict = value logger.info(F'''Adapter proj layer weight was initialized from {full_name}.''' ) elif isinstance(A , A ): if "bias" in name: assert ( value.shape == adapter.layers[layer_id].conv.bias.data.shape ), F'''{full_name} has size {value.shape}, but {adapter.layers[layer_id].conv.bias.data.shape} was found.''' snake_case__ : List[str] = value logger.info(F'''Adapter layer {layer_id} bias was initialized from {full_name}.''' ) elif "weight" in name: assert ( value.shape == adapter.layers[layer_id].conv.weight.data.shape ), F'''{full_name} has size {value.shape}, but {adapter.layers[layer_id].conv.weight.data.shape} was found.''' snake_case__ : List[str] = value logger.info(F'''Adapter layer {layer_id} bias was initialized from {full_name}.''' ) else: unused_weights.append(A ) def lowercase_ (A : int ): snake_case__ , snake_case__ : Union[str, Any] = emb.weight.shape snake_case__ : int = nn.Linear(A , A , bias=A ) snake_case__ : Optional[Any] = emb.weight.data return lin_layer @torch.no_grad() def lowercase_ (A : Tuple , A : Tuple , A : Any , A : Optional[Any] , A : int , A : Optional[Any] , A : Union[str, Any] , A : Union[str, Any] , A : Optional[Any] , A : List[Any] , A : Union[str, Any] , ): snake_case__ : Optional[Any] = WavaVecaConfig.from_pretrained( A , add_adapter=A , adapter_stride=A , adapter_kernel_size=A , use_auth_token=A , output_hidden_size=A , ) snake_case__ : Dict = MBartConfig.from_pretrained(A ) # load model snake_case__ , snake_case__ , snake_case__ : Any = fairseq.checkpoint_utils.load_model_ensemble_and_task( [checkpoint_path] , arg_overrides={ 'config_yaml': config_yaml_path, 'data': '/'.join(dict_path.split('/' )[:-1] ), 'w2v_path': checkpoint_path, 'load_pretrained_decoder_from': None, } , ) snake_case__ : List[Any] = model[0].eval() # load feature extractor snake_case__ : str = WavaVecaFeatureExtractor.from_pretrained(A , use_auth_token=A ) # set weights for wav2vec2 encoder snake_case__ : List[str] = WavaVecaModel(A ) recursively_load_weights_wavaveca(model.encoder , A ) # load decoder weights snake_case__ : Any = MBartForCausalLM(A ) snake_case__ , snake_case__ : int = hf_decoder.model.decoder.load_state_dict(model.decoder.state_dict() , strict=A ) logger.warning(F'''The following keys are missing when loading the decoder weights: {missing_keys}''' ) logger.warning(F'''The following keys are unexpected when loading the decoder weights: {unexpected_keys}''' ) snake_case__ : Union[str, Any] = SpeechEncoderDecoderModel(encoder=A , decoder=A ) snake_case__ : str = False snake_case__ : int = MBartaaTokenizer(A ) tokenizer.save_pretrained(A ) snake_case__ : Any = hf_wavavec.config.to_dict() snake_case__ : Tuple = tokenizer.pad_token_id snake_case__ : Union[str, Any] = tokenizer.bos_token_id snake_case__ : Dict = tokenizer.eos_token_id snake_case__ : Optional[int] = 'mbart50' snake_case__ : Union[str, Any] = 'wav2vec2' snake_case__ : List[str] = tokenizer.eos_token_id snake_case__ : Union[str, Any] = 2_5_0_0_0_4 snake_case__ : int = tokenizer.eos_token_id snake_case__ : Union[str, Any] = SpeechEncoderDecoderConfig.from_dict(A ) hf_wavavec.save_pretrained(A ) feature_extractor.save_pretrained(A ) if __name__ == "__main__": a_ :str = argparse.ArgumentParser() parser.add_argument("--pytorch_dump_folder_path", default=None, type=str, help="Path to the output PyTorch model.") parser.add_argument("--checkpoint_path", default=None, type=str, help="Path to fairseq checkpoint") parser.add_argument("--dict_path", default=None, type=str, help="Path to dict of fine-tuned model") parser.add_argument("--config_yaml_path", default=None, type=str, help="Path to yaml file of fine-tuned model") parser.add_argument( "--encoder_config_path", default="facebook/wav2vec2-xls-r-1b", type=str, help="Path to hf encoder wav2vec2 checkpoint config", ) parser.add_argument( "--decoder_config_path", default="facebook/mbart-large-50-one-to-many-mmt", type=str, help="Path to hf decoder checkpoint config", ) parser.add_argument("--add_adapter", default=True, type=bool, help="whethere to add model adapter layers") parser.add_argument("--adapter_stride", default=2, type=int, help="stride of adapter layers") parser.add_argument("--adapter_kernel_size", default=3, type=int, help="kernel size of adapter layers") parser.add_argument("--encoder_output_dim", default=1_024, type=int, help="encoder output dim") parser.add_argument("--start_token_id", default=250_004, type=int, help="`decoder_start_token_id` of model config") a_ :Union[str, Any] = parser.parse_args() convert_wavaveca_checkpoint( args.checkpoint_path, args.pytorch_dump_folder_path, args.dict_path, args.config_yaml_path, encoder_config_path=args.encoder_config_path, decoder_config_path=args.decoder_config_path, add_adapter=args.add_adapter, adapter_kernel_size=args.adapter_kernel_size, adapter_stride=args.adapter_stride, decoder_start_token_id=args.start_token_id, encoder_output_dim=args.encoder_output_dim, )
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'''simple docstring''' import json import os import torch from diffusers import UNetaDModel os.makedirs('''hub/hopper-medium-v2/unet/hor32''', exist_ok=True) os.makedirs('''hub/hopper-medium-v2/unet/hor128''', exist_ok=True) os.makedirs('''hub/hopper-medium-v2/value_function''', exist_ok=True) def UpperCamelCase_ ( snake_case_ : int ) -> Optional[Any]: '''simple docstring''' if hor == 1_28: __lowerCAmelCase = ('DownResnetBlock1D', 'DownResnetBlock1D', 'DownResnetBlock1D') __lowerCAmelCase = (32, 1_28, 2_56) __lowerCAmelCase = ('UpResnetBlock1D', 'UpResnetBlock1D') elif hor == 32: __lowerCAmelCase = ('DownResnetBlock1D', 'DownResnetBlock1D', 'DownResnetBlock1D', 'DownResnetBlock1D') __lowerCAmelCase = (32, 64, 1_28, 2_56) __lowerCAmelCase = ('UpResnetBlock1D', 'UpResnetBlock1D', 'UpResnetBlock1D') __lowerCAmelCase = torch.load(f"""/Users/bglickenhaus/Documents/diffuser/temporal_unet-hopper-mediumv2-hor{hor}.torch""" ) __lowerCAmelCase = model.state_dict() __lowerCAmelCase = { 'down_block_types': down_block_types, 'block_out_channels': block_out_channels, 'up_block_types': up_block_types, 'layers_per_block': 1, 'use_timestep_embedding': True, 'out_block_type': 'OutConv1DBlock', 'norm_num_groups': 8, 'downsample_each_block': False, 'in_channels': 14, 'out_channels': 14, 'extra_in_channels': 0, 'time_embedding_type': 'positional', 'flip_sin_to_cos': False, 'freq_shift': 1, 'sample_size': 6_55_36, 'mid_block_type': 'MidResTemporalBlock1D', 'act_fn': 'mish', } __lowerCAmelCase = UNetaDModel(**snake_case_ ) print(f"""length of state dict: {len(state_dict.keys() )}""" ) print(f"""length of value function dict: {len(hf_value_function.state_dict().keys() )}""" ) __lowerCAmelCase = dict(zip(model.state_dict().keys() , hf_value_function.state_dict().keys() ) ) for k, v in mapping.items(): __lowerCAmelCase = state_dict.pop(snake_case_ ) hf_value_function.load_state_dict(snake_case_ ) torch.save(hf_value_function.state_dict() , f"""hub/hopper-medium-v2/unet/hor{hor}/diffusion_pytorch_model.bin""" ) with open(f"""hub/hopper-medium-v2/unet/hor{hor}/config.json""" , """w""" ) as f: json.dump(snake_case_ , snake_case_ ) def UpperCamelCase_ ( ) -> Tuple: '''simple docstring''' __lowerCAmelCase = { 'in_channels': 14, 'down_block_types': ('DownResnetBlock1D', 'DownResnetBlock1D', 'DownResnetBlock1D', 'DownResnetBlock1D'), 'up_block_types': (), 'out_block_type': 'ValueFunction', 'mid_block_type': 'ValueFunctionMidBlock1D', 'block_out_channels': (32, 64, 1_28, 2_56), 'layers_per_block': 1, 'downsample_each_block': True, 'sample_size': 6_55_36, 'out_channels': 14, 'extra_in_channels': 0, 'time_embedding_type': 'positional', 'use_timestep_embedding': True, 'flip_sin_to_cos': False, 'freq_shift': 1, 'norm_num_groups': 8, 'act_fn': 'mish', } __lowerCAmelCase = torch.load("""/Users/bglickenhaus/Documents/diffuser/value_function-hopper-mediumv2-hor32.torch""" ) __lowerCAmelCase = model __lowerCAmelCase = UNetaDModel(**snake_case_ ) print(f"""length of state dict: {len(state_dict.keys() )}""" ) print(f"""length of value function dict: {len(hf_value_function.state_dict().keys() )}""" ) __lowerCAmelCase = dict(zip(state_dict.keys() , hf_value_function.state_dict().keys() ) ) for k, v in mapping.items(): __lowerCAmelCase = state_dict.pop(snake_case_ ) hf_value_function.load_state_dict(snake_case_ ) torch.save(hf_value_function.state_dict() , """hub/hopper-medium-v2/value_function/diffusion_pytorch_model.bin""" ) with open("""hub/hopper-medium-v2/value_function/config.json""" , """w""" ) as f: json.dump(snake_case_ , snake_case_ ) if __name__ == "__main__": unet(32) # unet(128) value_function()
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from collections import OrderedDict from typing import TYPE_CHECKING, Any, Mapping, Optional, Union from ...configuration_utils import PretrainedConfig from ...onnx import OnnxConfig from ...utils import logging if TYPE_CHECKING: from ... import FeatureExtractionMixin, PreTrainedTokenizerBase, TensorType a_ :Tuple = logging.get_logger(__name__) a_ :Union[str, Any] = { "microsoft/deberta-v2-xlarge": "https://huggingface.co/microsoft/deberta-v2-xlarge/resolve/main/config.json", "microsoft/deberta-v2-xxlarge": "https://huggingface.co/microsoft/deberta-v2-xxlarge/resolve/main/config.json", "microsoft/deberta-v2-xlarge-mnli": ( "https://huggingface.co/microsoft/deberta-v2-xlarge-mnli/resolve/main/config.json" ), "microsoft/deberta-v2-xxlarge-mnli": ( "https://huggingface.co/microsoft/deberta-v2-xxlarge-mnli/resolve/main/config.json" ), } class snake_case__ ( lowerCAmelCase_ ): """simple docstring""" _SCREAMING_SNAKE_CASE = """deberta-v2""" def __init__( self : Union[str, Any], _snake_case : Dict=1_2_8_1_0_0, _snake_case : Any=1_5_3_6, _snake_case : Tuple=2_4, _snake_case : int=2_4, _snake_case : Optional[int]=6_1_4_4, _snake_case : Optional[int]="gelu", _snake_case : Optional[int]=0.1, _snake_case : List[str]=0.1, _snake_case : str=5_1_2, _snake_case : Optional[int]=0, _snake_case : Optional[int]=0.0_2, _snake_case : Dict=1e-7, _snake_case : int=False, _snake_case : Any=-1, _snake_case : List[str]=0, _snake_case : Tuple=True, _snake_case : Any=None, _snake_case : Union[str, Any]=0, _snake_case : Tuple="gelu", **_snake_case : Union[str, Any], ) ->Optional[int]: super().__init__(**_snake_case ) snake_case__ : Dict = hidden_size snake_case__ : Optional[int] = num_hidden_layers snake_case__ : Any = num_attention_heads snake_case__ : List[Any] = intermediate_size snake_case__ : List[Any] = hidden_act snake_case__ : Union[str, Any] = hidden_dropout_prob snake_case__ : Dict = attention_probs_dropout_prob snake_case__ : List[str] = max_position_embeddings snake_case__ : List[str] = type_vocab_size snake_case__ : Optional[Any] = initializer_range snake_case__ : Optional[int] = relative_attention snake_case__ : Tuple = max_relative_positions snake_case__ : Union[str, Any] = pad_token_id snake_case__ : Optional[int] = position_biased_input # Backwards compatibility if type(_snake_case ) == str: snake_case__ : int = [x.strip() for x in pos_att_type.lower().split('|' )] snake_case__ : List[str] = pos_att_type snake_case__ : Union[str, Any] = vocab_size snake_case__ : Optional[int] = layer_norm_eps snake_case__ : Optional[int] = kwargs.get('pooler_hidden_size', _snake_case ) snake_case__ : int = pooler_dropout snake_case__ : str = pooler_hidden_act class snake_case__ ( lowerCAmelCase_ ): """simple docstring""" @property def lowercase_ ( self : Optional[int] ) ->Mapping[str, Mapping[int, str]]: if self.task == "multiple-choice": snake_case__ : List[Any] = {0: 'batch', 1: 'choice', 2: 'sequence'} else: snake_case__ : int = {0: 'batch', 1: 'sequence'} if self._config.type_vocab_size > 0: return OrderedDict( [('input_ids', dynamic_axis), ('attention_mask', dynamic_axis), ('token_type_ids', dynamic_axis)] ) else: return OrderedDict([('input_ids', dynamic_axis), ('attention_mask', dynamic_axis)] ) @property def lowercase_ ( self : Dict ) ->int: return 1_2 def lowercase_ ( self : Tuple, _snake_case : Union["PreTrainedTokenizerBase", "FeatureExtractionMixin"], _snake_case : int = -1, _snake_case : int = -1, _snake_case : int = -1, _snake_case : bool = False, _snake_case : Optional["TensorType"] = None, _snake_case : int = 3, _snake_case : int = 4_0, _snake_case : int = 4_0, _snake_case : "PreTrainedTokenizerBase" = None, ) ->Mapping[str, Any]: snake_case__ : Union[str, Any] = super().generate_dummy_inputs(preprocessor=_snake_case, framework=_snake_case ) if self._config.type_vocab_size == 0 and "token_type_ids" in dummy_inputs: del dummy_inputs["token_type_ids"] return dummy_inputs
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"""simple docstring""" import copy from dataclasses import dataclass, field from typing import ClassVar, Dict from ..features import ClassLabel, Features, Value from .base import TaskTemplate @dataclass(frozen=lowerCAmelCase_) class UpperCAmelCase_ ( lowerCAmelCase_): snake_case__ = field(default='''text-classification''' , metadata={'''include_in_asdict_even_if_is_default''': True}) snake_case__ = Features({'''text''': Value('''string''')}) snake_case__ = Features({'''labels''': ClassLabel}) snake_case__ = '''text''' snake_case__ = '''labels''' def _UpperCamelCase ( self : List[str] , __UpperCamelCase : Optional[Any] ) -> Any: if self.label_column not in features: raise ValueError(F'''Column {self.label_column} is not present in features.''' ) if not isinstance(features[self.label_column] , _snake_case ): raise ValueError(F'''Column {self.label_column} is not a ClassLabel.''' ) _UpperCamelCase = copy.deepcopy(self ) _UpperCamelCase = self.label_schema.copy() _UpperCamelCase = features[self.label_column] _UpperCamelCase = label_schema return task_template @property def _UpperCamelCase ( self : Optional[int] ) -> Dict[str, str]: return { self.text_column: "text", self.label_column: "labels", }
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import argparse import json import pickle from pathlib import Path import requests import torch from huggingface_hub import hf_hub_download from PIL import Image from transformers import MaskFormerConfig, MaskFormerForInstanceSegmentation, MaskFormerImageProcessor, SwinConfig from transformers.utils import logging logging.set_verbosity_info() a_ :str = logging.get_logger(__name__) def lowercase_ (A : str ): snake_case__ : Tuple = SwinConfig.from_pretrained( 'microsoft/swin-tiny-patch4-window7-224' , out_features=['stage1', 'stage2', 'stage3', 'stage4'] ) snake_case__ : List[Any] = MaskFormerConfig(backbone_config=A ) snake_case__ : Union[str, Any] = 'huggingface/label-files' if "ade20k-full" in model_name: # this should be ok snake_case__ : Dict = 8_4_7 snake_case__ : List[str] = 'maskformer-ade20k-full-id2label.json' elif "ade" in model_name: # this should be ok snake_case__ : Union[str, Any] = 1_5_0 snake_case__ : Any = 'ade20k-id2label.json' elif "coco-stuff" in model_name: # this should be ok snake_case__ : List[str] = 1_7_1 snake_case__ : Union[str, Any] = 'maskformer-coco-stuff-id2label.json' elif "coco" in model_name: # TODO snake_case__ : Dict = 1_3_3 snake_case__ : str = 'coco-panoptic-id2label.json' elif "cityscapes" in model_name: # this should be ok snake_case__ : List[str] = 1_9 snake_case__ : Union[str, Any] = 'cityscapes-id2label.json' elif "vistas" in model_name: # this should be ok snake_case__ : Tuple = 6_5 snake_case__ : List[str] = 'mapillary-vistas-id2label.json' snake_case__ : Dict = json.load(open(hf_hub_download(A , A , repo_type='dataset' ) , 'r' ) ) snake_case__ : List[str] = {int(A ): v for k, v in idalabel.items()} return config def lowercase_ (A : Any ): snake_case__ : Optional[int] = [] # stem # fmt: off rename_keys.append(('backbone.patch_embed.proj.weight', 'model.pixel_level_module.encoder.model.embeddings.patch_embeddings.projection.weight') ) rename_keys.append(('backbone.patch_embed.proj.bias', 'model.pixel_level_module.encoder.model.embeddings.patch_embeddings.projection.bias') ) rename_keys.append(('backbone.patch_embed.norm.weight', 'model.pixel_level_module.encoder.model.embeddings.norm.weight') ) rename_keys.append(('backbone.patch_embed.norm.bias', 'model.pixel_level_module.encoder.model.embeddings.norm.bias') ) # stages for i in range(len(config.backbone_config.depths ) ): for j in range(config.backbone_config.depths[i] ): rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.norm1.weight''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.layernorm_before.weight''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.norm1.bias''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.layernorm_before.bias''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.attn.relative_position_bias_table''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.attention.self.relative_position_bias_table''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.attn.relative_position_index''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.attention.self.relative_position_index''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.attn.proj.weight''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.attention.output.dense.weight''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.attn.proj.bias''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.attention.output.dense.bias''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.norm2.weight''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.layernorm_after.weight''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.norm2.bias''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.layernorm_after.bias''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.mlp.fc1.weight''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.intermediate.dense.weight''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.mlp.fc1.bias''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.intermediate.dense.bias''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.mlp.fc2.weight''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.output.dense.weight''') ) rename_keys.append((F'''backbone.layers.{i}.blocks.{j}.mlp.fc2.bias''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.output.dense.bias''') ) if i < 3: rename_keys.append((F'''backbone.layers.{i}.downsample.reduction.weight''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.downsample.reduction.weight''') ) rename_keys.append((F'''backbone.layers.{i}.downsample.norm.weight''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.downsample.norm.weight''') ) rename_keys.append((F'''backbone.layers.{i}.downsample.norm.bias''', F'''model.pixel_level_module.encoder.model.encoder.layers.{i}.downsample.norm.bias''') ) rename_keys.append((F'''backbone.norm{i}.weight''', F'''model.pixel_level_module.encoder.hidden_states_norms.{i}.weight''') ) rename_keys.append((F'''backbone.norm{i}.bias''', F'''model.pixel_level_module.encoder.hidden_states_norms.{i}.bias''') ) # FPN rename_keys.append(('sem_seg_head.layer_4.weight', 'model.pixel_level_module.decoder.fpn.stem.0.weight') ) rename_keys.append(('sem_seg_head.layer_4.norm.weight', 'model.pixel_level_module.decoder.fpn.stem.1.weight') ) rename_keys.append(('sem_seg_head.layer_4.norm.bias', 'model.pixel_level_module.decoder.fpn.stem.1.bias') ) for source_index, target_index in zip(range(3 , 0 , -1 ) , range(0 , 3 ) ): rename_keys.append((F'''sem_seg_head.adapter_{source_index}.weight''', F'''model.pixel_level_module.decoder.fpn.layers.{target_index}.proj.0.weight''') ) rename_keys.append((F'''sem_seg_head.adapter_{source_index}.norm.weight''', F'''model.pixel_level_module.decoder.fpn.layers.{target_index}.proj.1.weight''') ) rename_keys.append((F'''sem_seg_head.adapter_{source_index}.norm.bias''', F'''model.pixel_level_module.decoder.fpn.layers.{target_index}.proj.1.bias''') ) rename_keys.append((F'''sem_seg_head.layer_{source_index}.weight''', F'''model.pixel_level_module.decoder.fpn.layers.{target_index}.block.0.weight''') ) rename_keys.append((F'''sem_seg_head.layer_{source_index}.norm.weight''', F'''model.pixel_level_module.decoder.fpn.layers.{target_index}.block.1.weight''') ) rename_keys.append((F'''sem_seg_head.layer_{source_index}.norm.bias''', F'''model.pixel_level_module.decoder.fpn.layers.{target_index}.block.1.bias''') ) rename_keys.append(('sem_seg_head.mask_features.weight', 'model.pixel_level_module.decoder.mask_projection.weight') ) rename_keys.append(('sem_seg_head.mask_features.bias', 'model.pixel_level_module.decoder.mask_projection.bias') ) # Transformer decoder for idx in range(config.decoder_config.decoder_layers ): # self-attention out projection rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.self_attn.out_proj.weight''', F'''model.transformer_module.decoder.layers.{idx}.self_attn.out_proj.weight''') ) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.self_attn.out_proj.bias''', F'''model.transformer_module.decoder.layers.{idx}.self_attn.out_proj.bias''') ) # cross-attention out projection rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.multihead_attn.out_proj.weight''', F'''model.transformer_module.decoder.layers.{idx}.encoder_attn.out_proj.weight''') ) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.multihead_attn.out_proj.bias''', F'''model.transformer_module.decoder.layers.{idx}.encoder_attn.out_proj.bias''') ) # MLP 1 rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.linear1.weight''', F'''model.transformer_module.decoder.layers.{idx}.fc1.weight''') ) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.linear1.bias''', F'''model.transformer_module.decoder.layers.{idx}.fc1.bias''') ) # MLP 2 rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.linear2.weight''', F'''model.transformer_module.decoder.layers.{idx}.fc2.weight''') ) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.linear2.bias''', F'''model.transformer_module.decoder.layers.{idx}.fc2.bias''') ) # layernorm 1 (self-attention layernorm) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.norm1.weight''', F'''model.transformer_module.decoder.layers.{idx}.self_attn_layer_norm.weight''') ) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.norm1.bias''', F'''model.transformer_module.decoder.layers.{idx}.self_attn_layer_norm.bias''') ) # layernorm 2 (cross-attention layernorm) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.norm2.weight''', F'''model.transformer_module.decoder.layers.{idx}.encoder_attn_layer_norm.weight''') ) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.norm2.bias''', F'''model.transformer_module.decoder.layers.{idx}.encoder_attn_layer_norm.bias''') ) # layernorm 3 (final layernorm) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.norm3.weight''', F'''model.transformer_module.decoder.layers.{idx}.final_layer_norm.weight''') ) rename_keys.append((F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.norm3.bias''', F'''model.transformer_module.decoder.layers.{idx}.final_layer_norm.bias''') ) rename_keys.append(('sem_seg_head.predictor.transformer.decoder.norm.weight', 'model.transformer_module.decoder.layernorm.weight') ) rename_keys.append(('sem_seg_head.predictor.transformer.decoder.norm.bias', 'model.transformer_module.decoder.layernorm.bias') ) # heads on top rename_keys.append(('sem_seg_head.predictor.query_embed.weight', 'model.transformer_module.queries_embedder.weight') ) rename_keys.append(('sem_seg_head.predictor.input_proj.weight', 'model.transformer_module.input_projection.weight') ) rename_keys.append(('sem_seg_head.predictor.input_proj.bias', 'model.transformer_module.input_projection.bias') ) rename_keys.append(('sem_seg_head.predictor.class_embed.weight', 'class_predictor.weight') ) rename_keys.append(('sem_seg_head.predictor.class_embed.bias', 'class_predictor.bias') ) for i in range(3 ): rename_keys.append((F'''sem_seg_head.predictor.mask_embed.layers.{i}.weight''', F'''mask_embedder.{i}.0.weight''') ) rename_keys.append((F'''sem_seg_head.predictor.mask_embed.layers.{i}.bias''', F'''mask_embedder.{i}.0.bias''') ) # fmt: on return rename_keys def lowercase_ (A : Tuple , A : Tuple , A : Optional[Any] ): snake_case__ : Optional[int] = dct.pop(A ) snake_case__ : Union[str, Any] = val def lowercase_ (A : Optional[Any] , A : Tuple ): snake_case__ : Optional[int] = [int(backbone_config.embed_dim * 2**i ) for i in range(len(backbone_config.depths ) )] for i in range(len(backbone_config.depths ) ): snake_case__ : Optional[int] = num_features[i] for j in range(backbone_config.depths[i] ): # fmt: off # read in weights + bias of input projection layer (in original implementation, this is a single matrix + bias) snake_case__ : int = state_dict.pop(F'''backbone.layers.{i}.blocks.{j}.attn.qkv.weight''' ) snake_case__ : Tuple = state_dict.pop(F'''backbone.layers.{i}.blocks.{j}.attn.qkv.bias''' ) # next, add query, keys and values (in that order) to the state dict snake_case__ : str = in_proj_weight[:dim, :] snake_case__ : int = in_proj_bias[: dim] snake_case__ : List[Any] = in_proj_weight[ dim : dim * 2, : ] snake_case__ : List[str] = in_proj_bias[ dim : dim * 2 ] snake_case__ : List[Any] = in_proj_weight[ -dim :, : ] snake_case__ : Dict = in_proj_bias[-dim :] # fmt: on def lowercase_ (A : List[str] , A : List[Any] ): # fmt: off snake_case__ : str = config.decoder_config.hidden_size for idx in range(config.decoder_config.decoder_layers ): # read in weights + bias of self-attention input projection layer (in the original implementation, this is a single matrix + bias) snake_case__ : List[Any] = state_dict.pop(F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.self_attn.in_proj_weight''' ) snake_case__ : int = state_dict.pop(F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.self_attn.in_proj_bias''' ) # next, add query, keys and values (in that order) to the state dict snake_case__ : Any = in_proj_weight[: hidden_size, :] snake_case__ : Tuple = in_proj_bias[:config.hidden_size] snake_case__ : List[str] = in_proj_weight[hidden_size : hidden_size * 2, :] snake_case__ : Dict = in_proj_bias[hidden_size : hidden_size * 2] snake_case__ : Any = in_proj_weight[-hidden_size :, :] snake_case__ : int = in_proj_bias[-hidden_size :] # read in weights + bias of cross-attention input projection layer (in the original implementation, this is a single matrix + bias) snake_case__ : List[Any] = state_dict.pop(F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.multihead_attn.in_proj_weight''' ) snake_case__ : List[str] = state_dict.pop(F'''sem_seg_head.predictor.transformer.decoder.layers.{idx}.multihead_attn.in_proj_bias''' ) # next, add query, keys and values (in that order) to the state dict snake_case__ : Optional[int] = in_proj_weight[: hidden_size, :] snake_case__ : Optional[Any] = in_proj_bias[:config.hidden_size] snake_case__ : int = in_proj_weight[hidden_size : hidden_size * 2, :] snake_case__ : List[str] = in_proj_bias[hidden_size : hidden_size * 2] snake_case__ : List[str] = in_proj_weight[-hidden_size :, :] snake_case__ : str = in_proj_bias[-hidden_size :] # fmt: on def lowercase_ (): snake_case__ : Any = 'http://images.cocodataset.org/val2017/000000039769.jpg' snake_case__ : int = Image.open(requests.get(A , stream=A ).raw ) return im @torch.no_grad() def lowercase_ (A : str , A : str , A : str , A : bool = False ): snake_case__ : Optional[int] = get_maskformer_config(A ) # load original state_dict with open(A , 'rb' ) as f: snake_case__ : List[Any] = pickle.load(A ) snake_case__ : Optional[int] = data['model'] # for name, param in state_dict.items(): # print(name, param.shape) # rename keys snake_case__ : List[str] = create_rename_keys(A ) for src, dest in rename_keys: rename_key(A , A , A ) read_in_swin_q_k_v(A , config.backbone_config ) read_in_decoder_q_k_v(A , A ) # update to torch tensors for key, value in state_dict.items(): snake_case__ : int = torch.from_numpy(A ) # load 🤗 model snake_case__ : str = MaskFormerForInstanceSegmentation(A ) model.eval() for name, param in model.named_parameters(): print(A , param.shape ) snake_case__ , snake_case__ : Union[str, Any] = model.load_state_dict(A , strict=A ) assert missing_keys == [ "model.pixel_level_module.encoder.model.layernorm.weight", "model.pixel_level_module.encoder.model.layernorm.bias", ] assert len(A ) == 0, F'''Unexpected keys: {unexpected_keys}''' # verify results snake_case__ : Optional[Any] = prepare_img() if "vistas" in model_name: snake_case__ : int = 6_5 elif "cityscapes" in model_name: snake_case__ : Dict = 6_5_5_3_5 else: snake_case__ : Tuple = 2_5_5 snake_case__ : Optional[int] = True if 'ade' in model_name else False snake_case__ : Dict = MaskFormerImageProcessor(ignore_index=A , reduce_labels=A ) snake_case__ : Any = image_processor(A , return_tensors='pt' ) snake_case__ : Any = model(**A ) print('Logits:' , outputs.class_queries_logits[0, :3, :3] ) if model_name == "maskformer-swin-tiny-ade": snake_case__ : Tuple = torch.tensor( [[3.6353, -4.4770, -2.6065], [0.5081, -4.2394, -3.5343], [2.1909, -5.0353, -1.9323]] ) assert torch.allclose(outputs.class_queries_logits[0, :3, :3] , A , atol=1e-4 ) print('Looks ok!' ) if pytorch_dump_folder_path is not None: print(F'''Saving model and image processor to {pytorch_dump_folder_path}''' ) Path(A ).mkdir(exist_ok=A ) model.save_pretrained(A ) image_processor.save_pretrained(A ) if push_to_hub: print('Pushing model and image processor to the hub...' ) model.push_to_hub(F'''nielsr/{model_name}''' ) image_processor.push_to_hub(F'''nielsr/{model_name}''' ) if __name__ == "__main__": a_ :Optional[int] = argparse.ArgumentParser() # Required parameters parser.add_argument( "--model_name", default="maskformer-swin-tiny-ade", type=str, help=("Name of the MaskFormer model you'd like to convert",), ) parser.add_argument( "--checkpoint_path", default="/Users/nielsrogge/Documents/MaskFormer_checkpoints/MaskFormer-Swin-tiny-ADE20k/model.pkl", type=str, help="Path to the original state dict (.pth file).", ) parser.add_argument( "--pytorch_dump_folder_path", default=None, type=str, help="Path to the output PyTorch model directory." ) parser.add_argument( "--push_to_hub", action="store_true", help="Whether or not to push the converted model to the 🤗 hub." ) a_ :Dict = parser.parse_args() convert_maskformer_checkpoint( args.model_name, args.checkpoint_path, args.pytorch_dump_folder_path, args.push_to_hub )
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from datetime import datetime import matplotlib.pyplot as plt import torch def _a ( SCREAMING_SNAKE_CASE : int ) -> List[str]: """simple docstring""" for param in module.parameters(): __lowerCAmelCase: str = False def _a ( ) -> Any: """simple docstring""" __lowerCAmelCase: Optional[Any] = 'cuda' if torch.cuda.is_available() else 'cpu' if torch.backends.mps.is_available() and torch.backends.mps.is_built(): __lowerCAmelCase: Optional[Any] = 'mps' if device == "mps": print( 'WARNING: MPS currently doesn\'t seem to work, and messes up backpropagation without any visible torch' ' errors. I recommend using CUDA on a colab notebook or CPU instead if you\'re facing inexplicable issues' ' with generations.' ) return device def _a ( SCREAMING_SNAKE_CASE : Optional[int] ) -> int: """simple docstring""" __lowerCAmelCase: List[Any] = plt.imshow(SCREAMING_SNAKE_CASE ) fig.axes.get_xaxis().set_visible(SCREAMING_SNAKE_CASE ) fig.axes.get_yaxis().set_visible(SCREAMING_SNAKE_CASE ) plt.show() def _a ( ) -> Tuple: """simple docstring""" __lowerCAmelCase: Union[str, Any] = datetime.now() __lowerCAmelCase: Union[str, Any] = current_time.strftime('%H:%M:%S' ) return timestamp
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import unittest from transformers import is_torch_available from transformers.testing_utils import require_torch, slow, torch_device from ...generation.test_utils import GenerationTesterMixin from ...test_configuration_common import ConfigTester from ...test_modeling_common import ModelTesterMixin, ids_tensor from ...test_pipeline_mixin import PipelineTesterMixin if is_torch_available(): import torch from transformers import ( OPENAI_GPT_PRETRAINED_MODEL_ARCHIVE_LIST, OpenAIGPTConfig, OpenAIGPTDoubleHeadsModel, OpenAIGPTForSequenceClassification, OpenAIGPTLMHeadModel, OpenAIGPTModel, ) class snake_case__ : """simple docstring""" def __init__( self : List[str], _snake_case : Any, _snake_case : int=1_3, _snake_case : Optional[int]=7, _snake_case : int=True, _snake_case : Optional[Any]=True, _snake_case : Optional[Any]=True, _snake_case : Union[str, Any]=9_9, _snake_case : Optional[Any]=3_2, _snake_case : Tuple=5, _snake_case : str=4, _snake_case : Any=3_7, _snake_case : int="gelu", _snake_case : Optional[Any]=0.1, _snake_case : str=0.1, _snake_case : str=5_1_2, _snake_case : Dict=1_6, _snake_case : str=2, _snake_case : Union[str, Any]=0.0_2, _snake_case : Optional[int]=3, _snake_case : Union[str, Any]=4, _snake_case : Tuple=None, ) ->Optional[Any]: snake_case__ : Optional[int] = parent snake_case__ : List[Any] = batch_size snake_case__ : Tuple = seq_length snake_case__ : str = is_training snake_case__ : Optional[int] = use_token_type_ids snake_case__ : Any = use_labels snake_case__ : Dict = vocab_size snake_case__ : str = hidden_size snake_case__ : Union[str, Any] = num_hidden_layers snake_case__ : List[str] = num_attention_heads snake_case__ : Union[str, Any] = intermediate_size snake_case__ : List[Any] = hidden_act snake_case__ : int = hidden_dropout_prob snake_case__ : str = attention_probs_dropout_prob snake_case__ : Any = max_position_embeddings snake_case__ : Union[str, Any] = type_vocab_size snake_case__ : Optional[Any] = type_sequence_label_size snake_case__ : Optional[int] = initializer_range snake_case__ : Optional[int] = num_labels snake_case__ : str = num_choices snake_case__ : int = scope snake_case__ : List[str] = self.vocab_size - 1 def lowercase_ ( self : Union[str, Any] ) ->Tuple: snake_case__ : List[str] = ids_tensor([self.batch_size, self.seq_length], self.vocab_size ) snake_case__ : List[str] = None if self.use_token_type_ids: snake_case__ : Optional[Any] = ids_tensor([self.batch_size, self.seq_length], self.type_vocab_size ) snake_case__ : Tuple = None snake_case__ : str = None snake_case__ : List[Any] = None if self.use_labels: snake_case__ : Dict = ids_tensor([self.batch_size], self.type_sequence_label_size ) snake_case__ : int = ids_tensor([self.batch_size, self.seq_length], self.num_labels ) snake_case__ : List[str] = ids_tensor([self.batch_size], self.num_choices ) snake_case__ : Union[str, Any] = OpenAIGPTConfig( vocab_size=self.vocab_size, n_embd=self.hidden_size, n_layer=self.num_hidden_layers, n_head=self.num_attention_heads, n_positions=self.max_position_embeddings, pad_token_id=self.pad_token_id, ) snake_case__ : List[str] = ids_tensor([self.num_hidden_layers, self.num_attention_heads], 2 ) return ( config, input_ids, head_mask, token_type_ids, sequence_labels, token_labels, choice_labels, ) def lowercase_ ( self : Any, _snake_case : List[str], _snake_case : Any, _snake_case : List[Any], _snake_case : Tuple, *_snake_case : Optional[Any] ) ->Tuple: snake_case__ : Union[str, Any] = OpenAIGPTModel(config=_snake_case ) model.to(_snake_case ) model.eval() snake_case__ : Optional[Any] = model(_snake_case, token_type_ids=_snake_case, head_mask=_snake_case ) snake_case__ : Union[str, Any] = model(_snake_case, token_type_ids=_snake_case ) snake_case__ : Optional[Any] = model(_snake_case ) self.parent.assertEqual(result.last_hidden_state.shape, (self.batch_size, self.seq_length, self.hidden_size) ) def lowercase_ ( self : Optional[int], _snake_case : Optional[Any], _snake_case : Union[str, Any], _snake_case : Optional[int], _snake_case : List[Any], *_snake_case : Dict ) ->Optional[int]: snake_case__ : Optional[Any] = OpenAIGPTLMHeadModel(_snake_case ) model.to(_snake_case ) model.eval() snake_case__ : Tuple = model(_snake_case, token_type_ids=_snake_case, labels=_snake_case ) self.parent.assertEqual(result.loss.shape, () ) self.parent.assertEqual(result.logits.shape, (self.batch_size, self.seq_length, self.vocab_size) ) def lowercase_ ( self : int, _snake_case : Tuple, _snake_case : List[str], _snake_case : List[Any], _snake_case : List[Any], *_snake_case : List[Any] ) ->Optional[int]: snake_case__ : List[str] = OpenAIGPTDoubleHeadsModel(_snake_case ) model.to(_snake_case ) model.eval() snake_case__ : Optional[Any] = model(_snake_case, token_type_ids=_snake_case, labels=_snake_case ) self.parent.assertEqual(result.loss.shape, () ) self.parent.assertEqual(result.logits.shape, (self.batch_size, self.seq_length, self.vocab_size) ) def lowercase_ ( self : Optional[int], _snake_case : Tuple, _snake_case : Dict, _snake_case : List[str], _snake_case : Optional[Any], *_snake_case : Union[str, Any] ) ->str: snake_case__ : List[str] = self.num_labels snake_case__ : Dict = OpenAIGPTForSequenceClassification(_snake_case ) model.to(_snake_case ) model.eval() snake_case__ : List[str] = ids_tensor([self.batch_size], self.type_sequence_label_size ) snake_case__ : List[str] = model(_snake_case, token_type_ids=_snake_case, labels=_snake_case ) self.parent.assertEqual(result.logits.shape, (self.batch_size, self.num_labels) ) def lowercase_ ( self : Dict ) ->int: snake_case__ : List[Any] = self.prepare_config_and_inputs() ( ( snake_case__ ) , ( snake_case__ ) , ( snake_case__ ) , ( snake_case__ ) , ( snake_case__ ) , ( snake_case__ ) , ( snake_case__ ) , ) : Optional[Any] = config_and_inputs snake_case__ : str = { 'input_ids': input_ids, 'token_type_ids': token_type_ids, 'head_mask': head_mask, } return config, inputs_dict @require_torch class snake_case__ ( lowerCAmelCase_ , lowerCAmelCase_ , lowerCAmelCase_ , unittest.TestCase ): """simple docstring""" _SCREAMING_SNAKE_CASE = ( (OpenAIGPTModel, OpenAIGPTLMHeadModel, OpenAIGPTDoubleHeadsModel, OpenAIGPTForSequenceClassification) if is_torch_available() else () ) _SCREAMING_SNAKE_CASE = ( (OpenAIGPTLMHeadModel,) if is_torch_available() else () ) # TODO (PVP): Add Double HeadsModel when generate() function is changed accordingly _SCREAMING_SNAKE_CASE = ( { """feature-extraction""": OpenAIGPTModel, """text-classification""": OpenAIGPTForSequenceClassification, """text-generation""": OpenAIGPTLMHeadModel, """zero-shot""": OpenAIGPTForSequenceClassification, } if is_torch_available() else {} ) def lowercase_ ( self : Optional[int], _snake_case : Union[str, Any], _snake_case : int, _snake_case : Tuple, _snake_case : Tuple, _snake_case : List[str] ) ->Optional[Any]: if pipeline_test_casse_name == "ZeroShotClassificationPipelineTests": # Get `tokenizer does not have a padding token` error for both fast/slow tokenizers. # `OpenAIGPTConfig` was never used in pipeline tests, either because of a missing checkpoint or because a # tiny config could not be created. return True return False def lowercase_ ( self : Optional[Any], _snake_case : Union[str, Any], _snake_case : List[str], _snake_case : Any=False ) ->Tuple: snake_case__ : Optional[int] = super()._prepare_for_class(_snake_case, _snake_case, return_labels=_snake_case ) if return_labels: if model_class.__name__ == "OpenAIGPTDoubleHeadsModel": snake_case__ : Union[str, Any] = torch.zeros( (self.model_tester.batch_size, self.model_tester.num_choices, self.model_tester.seq_length), dtype=torch.long, device=_snake_case, ) snake_case__ : List[Any] = inputs_dict['labels'] snake_case__ : List[Any] = inputs_dict['labels'] snake_case__ : Any = torch.zeros( (self.model_tester.batch_size, self.model_tester.num_choices), dtype=torch.long, device=_snake_case, ) snake_case__ : Tuple = torch.zeros( self.model_tester.batch_size, dtype=torch.long, device=_snake_case ) return inputs_dict def lowercase_ ( self : Union[str, Any] ) ->List[str]: snake_case__ : List[str] = OpenAIGPTModelTester(self ) snake_case__ : Any = ConfigTester(self, config_class=_snake_case, n_embd=3_7 ) def lowercase_ ( self : Optional[int] ) ->str: self.config_tester.run_common_tests() def lowercase_ ( self : int ) ->Tuple: snake_case__ : str = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_openai_gpt_model(*_snake_case ) def lowercase_ ( self : Tuple ) ->List[str]: snake_case__ : Optional[int] = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_lm_head_model(*_snake_case ) def lowercase_ ( self : Dict ) ->int: snake_case__ : Optional[Any] = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_double_lm_head_model(*_snake_case ) def lowercase_ ( self : int ) ->str: snake_case__ : List[Any] = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_openai_gpt_for_sequence_classification(*_snake_case ) @slow def lowercase_ ( self : Optional[Any] ) ->str: for model_name in OPENAI_GPT_PRETRAINED_MODEL_ARCHIVE_LIST[:1]: snake_case__ : Optional[int] = OpenAIGPTModel.from_pretrained(_snake_case ) self.assertIsNotNone(_snake_case ) @require_torch class snake_case__ ( unittest.TestCase ): """simple docstring""" @slow def lowercase_ ( self : Tuple ) ->Optional[int]: snake_case__ : Union[str, Any] = OpenAIGPTLMHeadModel.from_pretrained('openai-gpt' ) model.to(_snake_case ) snake_case__ : Tuple = torch.tensor([[4_8_1, 4_7_3_5, 5_4_4]], dtype=torch.long, device=_snake_case ) # the president is snake_case__ : int = [ 4_8_1, 4_7_3_5, 5_4_4, 2_4_6, 9_6_3, 8_7_0, 7_6_2, 2_3_9, 2_4_4, 4_0_4_7_7, 2_4_4, 2_4_9, 7_1_9, 8_8_1, 4_8_7, 5_4_4, 2_4_0, 2_4_4, 6_0_3, 4_8_1, ] # the president is a very good man. " \n " i\'m sure he is, " said the snake_case__ : Optional[int] = model.generate(_snake_case, do_sample=_snake_case ) self.assertListEqual(output_ids[0].tolist(), _snake_case )
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import numpy as np import torch from torch.utils.data import Dataset from utils import logger class __lowerCAmelCase ( lowerCAmelCase_): def __init__( self , lowerCAmelCase__ , lowerCAmelCase__ ) -> Tuple: '''simple docstring''' a__ : Union[str, Any] =params a__ : Optional[Any] =np.array(_snake_case ) a__ : Tuple =np.array([len(_snake_case ) for t in data] ) self.check() self.remove_long_sequences() self.remove_empty_sequences() self.remove_unknown_sequences() self.check() self.print_statistics() def __getitem__( self , lowerCAmelCase__ ) -> str: '''simple docstring''' return (self.token_ids[index], self.lengths[index]) def __len__( self ) -> str: '''simple docstring''' return len(self.lengths ) def _lowercase ( self ) -> Optional[int]: '''simple docstring''' assert len(self.token_ids ) == len(self.lengths ) assert all(self.lengths[i] == len(self.token_ids[i] ) for i in range(len(self.lengths ) ) ) def _lowercase ( self ) -> Optional[int]: '''simple docstring''' a__ : Dict =self.params.max_model_input_size a__ : int =self.lengths > max_len logger.info(F'''Splitting {sum(_snake_case )} too long sequences.''' ) def divide_chunks(lowerCAmelCase__ , lowerCAmelCase__ ): return [l[i : i + n] for i in range(0 , len(_snake_case ) , _snake_case )] a__ : Dict =[] a__ : Any =[] if self.params.mlm: a__ : str =self.params.special_tok_ids['cls_token'], self.params.special_tok_ids['sep_token'] else: a__ : Dict =self.params.special_tok_ids['bos_token'], self.params.special_tok_ids['eos_token'] for seq_, len_ in zip(self.token_ids , self.lengths ): assert (seq_[0] == cls_id) and (seq_[-1] == sep_id), seq_ if len_ <= max_len: new_tok_ids.append(seq_ ) new_lengths.append(len_ ) else: a__ : int =[] for sub_s in divide_chunks(seq_ , max_len - 2 ): if sub_s[0] != cls_id: a__ : List[Any] =np.insert(_snake_case , 0 , _snake_case ) if sub_s[-1] != sep_id: a__ : Optional[Any] =np.insert(_snake_case , len(_snake_case ) , _snake_case ) assert len(_snake_case ) <= max_len assert (sub_s[0] == cls_id) and (sub_s[-1] == sep_id), sub_s sub_seqs.append(_snake_case ) new_tok_ids.extend(_snake_case ) new_lengths.extend([len(_snake_case ) for l in sub_seqs] ) a__ : int =np.array(_snake_case ) a__ : Union[str, Any] =np.array(_snake_case ) def _lowercase ( self ) -> Optional[int]: '''simple docstring''' a__ : int =len(self ) a__ : Dict =self.lengths > 1_1 a__ : List[Any] =self.token_ids[indices] a__ : Any =self.lengths[indices] a__ : Dict =len(self ) logger.info(F'''Remove {init_size - new_size} too short (<=11 tokens) sequences.''' ) def _lowercase ( self ) -> Tuple: '''simple docstring''' if "unk_token" not in self.params.special_tok_ids: return else: a__ : str =self.params.special_tok_ids['unk_token'] a__ : str =len(self ) a__ : Any =np.array([np.count_nonzero(a == unk_token_id ) for a in self.token_ids] ) a__ : Any =(unk_occs / self.lengths) < 0.5 a__ : Optional[int] =self.token_ids[indices] a__ : List[str] =self.lengths[indices] a__ : List[Any] =len(self ) logger.info(F'''Remove {init_size - new_size} sequences with a high level of unknown tokens (50%).''' ) def _lowercase ( self ) -> Optional[int]: '''simple docstring''' if not self.params.is_master: return logger.info(F'''{len(self )} sequences''' ) # data_len = sum(self.lengths) # nb_unique_tokens = len(Counter(list(chain(*self.token_ids)))) # logger.info(f'{data_len} tokens ({nb_unique_tokens} unique)') # unk_idx = self.params.special_tok_ids['unk_token'] # nb_unknown = sum([(t==unk_idx).sum() for t in self.token_ids]) # logger.info(f'{nb_unknown} unknown tokens (covering {100*nb_unknown/data_len:.2f}% of the data)') def _lowercase ( self , lowerCAmelCase__ ) -> List[Any]: '''simple docstring''' a__ : Any =[t[0] for t in batch] a__ : Optional[Any] =[t[1] for t in batch] assert len(_snake_case ) == len(_snake_case ) # Max for paddings a__ : Tuple =max(_snake_case ) # Pad token ids if self.params.mlm: a__ : Dict =self.params.special_tok_ids['pad_token'] else: a__ : List[Any] =self.params.special_tok_ids['unk_token'] a__ : Union[str, Any] =[list(t.astype(_snake_case ) ) + [pad_idx] * (max_seq_len_ - len(_snake_case )) for t in token_ids] assert len(tk_ ) == len(_snake_case ) assert all(len(_snake_case ) == max_seq_len_ for t in tk_ ) a__ : int =torch.tensor(tk_ ) # (bs, max_seq_len_) a__ : Optional[int] =torch.tensor(_snake_case ) # (bs) return tk_t, lg_t
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import os import unittest from transformers.models.transfo_xl.tokenization_transfo_xl import VOCAB_FILES_NAMES, TransfoXLTokenizer from ...test_tokenization_common import TokenizerTesterMixin class snake_case__ ( lowerCAmelCase_ , unittest.TestCase ): """simple docstring""" _SCREAMING_SNAKE_CASE = TransfoXLTokenizer _SCREAMING_SNAKE_CASE = False _SCREAMING_SNAKE_CASE = False def lowercase_ ( self : Optional[int] ) ->Any: super().setUp() snake_case__ : Tuple = [ '<unk>', '[CLS]', '[SEP]', 'want', 'unwanted', 'wa', 'un', 'running', ',', 'low', 'l', ] snake_case__ : Any = os.path.join(self.tmpdirname, VOCAB_FILES_NAMES['vocab_file'] ) with open(self.vocab_file, 'w', encoding='utf-8' ) as vocab_writer: vocab_writer.write(''.join([x + '\n' for x in vocab_tokens] ) ) def lowercase_ ( self : Union[str, Any], **_snake_case : List[Any] ) ->Dict: snake_case__ : str = True return TransfoXLTokenizer.from_pretrained(self.tmpdirname, **_snake_case ) def lowercase_ ( self : Optional[Any], _snake_case : str ) ->Dict: snake_case__ : List[Any] = '<unk> UNwanted , running' snake_case__ : List[Any] = '<unk> unwanted, running' return input_text, output_text def lowercase_ ( self : List[Any] ) ->Tuple: snake_case__ : Dict = TransfoXLTokenizer(vocab_file=self.vocab_file, lower_case=_snake_case ) snake_case__ : str = tokenizer.tokenize('<unk> UNwanted , running' ) self.assertListEqual(_snake_case, ['<unk>', 'unwanted', ',', 'running'] ) self.assertListEqual(tokenizer.convert_tokens_to_ids(_snake_case ), [0, 4, 8, 7] ) def lowercase_ ( self : List[str] ) ->List[Any]: snake_case__ : str = TransfoXLTokenizer(lower_case=_snake_case ) self.assertListEqual( tokenizer.tokenize(' \tHeLLo ! how \n Are yoU ? ' ), ['hello', '!', 'how', 'are', 'you', '?'] ) def lowercase_ ( self : Optional[int] ) ->Optional[Any]: snake_case__ : Optional[int] = TransfoXLTokenizer(lower_case=_snake_case ) self.assertListEqual( tokenizer.tokenize(' \tHeLLo ! how \n Are yoU ? ' ), ['HeLLo', '!', 'how', 'Are', 'yoU', '?'] ) def lowercase_ ( self : Optional[int] ) ->Union[str, Any]: snake_case__ : List[Any] = TransfoXLTokenizer(lower_case=_snake_case ) snake_case__ : Dict = 'Hello (bracket) and side-scrolled [and] Henry\'s $5,000 with 3.34 m. What\'s up!?' snake_case__ : List[Any] = [ 'Hello', '(', 'bracket', ')', 'and', 'side', '@-@', 'scrolled', '[', 'and', ']', 'Henry', '\'s', '$', '5', '@,@', '000', 'with', '3', '@.@', '34', 'm', '.', 'What', '\'s', 'up', '!', '?', ] self.assertListEqual(tokenizer.tokenize(_snake_case ), _snake_case ) self.assertEqual(tokenizer.convert_tokens_to_string(_snake_case ), _snake_case ) def lowercase_ ( self : Dict ) ->Any: snake_case__ : Dict = self.get_tokenizer() snake_case__ : Optional[Any] = len(_snake_case ) tokenizer.add_tokens(['new1', 'new2'] ) tokenizer.move_added_token('new1', 1 ) # Check that moved token is not copied (duplicate) self.assertEqual(len(_snake_case ), original_len + 2 ) # Check that token is moved to specified id self.assertEqual(tokenizer.encode('new1' ), [1] ) self.assertEqual(tokenizer.decode([1] ), 'new1' )
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from typing import TYPE_CHECKING from ...utils import ( OptionalDependencyNotAvailable, _LazyModule, is_flax_available, is_tf_available, is_tokenizers_available, is_torch_available, is_vision_available, ) __a = { "configuration_owlvit": [ "OWLVIT_PRETRAINED_CONFIG_ARCHIVE_MAP", "OwlViTConfig", "OwlViTOnnxConfig", "OwlViTTextConfig", "OwlViTVisionConfig", ], "processing_owlvit": ["OwlViTProcessor"], } try: if not is_vision_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __a = ["OwlViTFeatureExtractor"] __a = ["OwlViTImageProcessor"] try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __a = [ "OWLVIT_PRETRAINED_MODEL_ARCHIVE_LIST", "OwlViTModel", "OwlViTPreTrainedModel", "OwlViTTextModel", "OwlViTVisionModel", "OwlViTForObjectDetection", ] if TYPE_CHECKING: from .configuration_owlvit import ( OWLVIT_PRETRAINED_CONFIG_ARCHIVE_MAP, OwlViTConfig, OwlViTOnnxConfig, OwlViTTextConfig, OwlViTVisionConfig, ) from .processing_owlvit import OwlViTProcessor try: if not is_vision_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .feature_extraction_owlvit import OwlViTFeatureExtractor from .image_processing_owlvit import OwlViTImageProcessor try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_owlvit import ( OWLVIT_PRETRAINED_MODEL_ARCHIVE_LIST, OwlViTForObjectDetection, OwlViTModel, OwlViTPreTrainedModel, OwlViTTextModel, OwlViTVisionModel, ) else: import sys __a = _LazyModule(__name__, globals()['__file__'], _import_structure, module_spec=__spec__)
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from ...configuration_utils import PretrainedConfig from ...utils import logging a_ :Optional[int] = logging.get_logger(__name__) a_ :Dict = {"openai-gpt": "https://huggingface.co/openai-gpt/resolve/main/config.json"} class snake_case__ ( lowerCAmelCase_ ): """simple docstring""" _SCREAMING_SNAKE_CASE = """openai-gpt""" _SCREAMING_SNAKE_CASE = { """max_position_embeddings""": """n_positions""", """hidden_size""": """n_embd""", """num_attention_heads""": """n_head""", """num_hidden_layers""": """n_layer""", } def __init__( self : Optional[int], _snake_case : Dict=4_0_4_7_8, _snake_case : str=5_1_2, _snake_case : int=7_6_8, _snake_case : Tuple=1_2, _snake_case : Any=1_2, _snake_case : str="gelu", _snake_case : List[str]=0.1, _snake_case : Any=0.1, _snake_case : Dict=0.1, _snake_case : int=1e-5, _snake_case : Optional[Any]=0.0_2, _snake_case : List[Any]="cls_index", _snake_case : Any=True, _snake_case : Any=None, _snake_case : int=True, _snake_case : Optional[Any]=0.1, **_snake_case : List[Any], ) ->Optional[int]: snake_case__ : int = vocab_size snake_case__ : Dict = n_positions snake_case__ : str = n_embd snake_case__ : str = n_layer snake_case__ : List[Any] = n_head snake_case__ : List[Any] = afn snake_case__ : Optional[Any] = resid_pdrop snake_case__ : List[str] = embd_pdrop snake_case__ : List[Any] = attn_pdrop snake_case__ : Optional[int] = layer_norm_epsilon snake_case__ : str = initializer_range snake_case__ : List[str] = summary_type snake_case__ : Optional[int] = summary_use_proj snake_case__ : List[str] = summary_activation snake_case__ : Optional[Any] = summary_first_dropout snake_case__ : int = summary_proj_to_labels super().__init__(**_snake_case )
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"""simple docstring""" import json import os import unittest from transformers.models.roc_bert.tokenization_roc_bert import ( VOCAB_FILES_NAMES, RoCBertBasicTokenizer, RoCBertTokenizer, RoCBertWordpieceTokenizer, _is_control, _is_punctuation, _is_whitespace, ) from transformers.testing_utils import require_tokenizers, slow from ...test_tokenization_common import TokenizerTesterMixin, filter_non_english @require_tokenizers class __lowerCAmelCase ( lowerCAmelCase_ , unittest.TestCase ): '''simple docstring''' __UpperCAmelCase : List[str] = RoCBertTokenizer __UpperCAmelCase : Tuple = None __UpperCAmelCase : Union[str, Any] = False __UpperCAmelCase : Tuple = True __UpperCAmelCase : str = filter_non_english def __UpperCAmelCase ( self ): super().setUp() __a = ['[UNK]', '[CLS]', '[SEP]', '[PAD]', '[MASK]', '你', '好', '是', '谁', 'a', 'b', 'c', 'd'] __a = {} __a = {} for i, value in enumerate(_snake_case ): __a = i __a = i __a = os.path.join(self.tmpdirname , VOCAB_FILES_NAMES['''vocab_file'''] ) __a = os.path.join(self.tmpdirname , VOCAB_FILES_NAMES['''word_shape_file'''] ) __a = os.path.join(self.tmpdirname , VOCAB_FILES_NAMES['''word_pronunciation_file'''] ) with open(self.vocab_file , '''w''' , encoding='''utf-8''' ) as vocab_writer: vocab_writer.write(''''''.join([x + '''\n''' for x in vocab_tokens] ) ) with open(self.word_shape_file , '''w''' , encoding='''utf-8''' ) as word_shape_writer: json.dump(_snake_case , _snake_case , ensure_ascii=_snake_case ) with open(self.word_pronunciation_file , '''w''' , encoding='''utf-8''' ) as word_pronunciation_writer: json.dump(_snake_case , _snake_case , ensure_ascii=_snake_case ) def __UpperCAmelCase ( self ): __a = self.tokenizer_class(self.vocab_file , self.word_shape_file , self.word_pronunciation_file ) __a = tokenizer.tokenize('''你好[SEP]你是谁''' ) self.assertListEqual(_snake_case , ['''你''', '''好''', '''[SEP]''', '''你''', '''是''', '''谁'''] ) self.assertListEqual(tokenizer.convert_tokens_to_ids(_snake_case ) , [5, 6, 2, 5, 7, 8] ) self.assertListEqual(tokenizer.convert_tokens_to_shape_ids(_snake_case ) , [5, 6, 2, 5, 7, 8] ) self.assertListEqual(tokenizer.convert_tokens_to_pronunciation_ids(_snake_case ) , [5, 6, 2, 5, 7, 8] ) def __UpperCAmelCase ( self ): __a = RoCBertBasicTokenizer() self.assertListEqual(tokenizer.tokenize('''ah\u535A\u63A8zz''' ) , ['''ah''', '''\u535A''', '''\u63A8''', '''zz'''] ) def __UpperCAmelCase ( self ): __a = RoCBertBasicTokenizer(do_lower_case=_snake_case ) self.assertListEqual( tokenizer.tokenize(''' \tHeLLo!how \n Are yoU? ''' ) , ['''hello''', '''!''', '''how''', '''are''', '''you''', '''?'''] ) self.assertListEqual(tokenizer.tokenize('''H\u00E9llo''' ) , ['''hello'''] ) def __UpperCAmelCase ( self ): __a = RoCBertBasicTokenizer(do_lower_case=_snake_case , strip_accents=_snake_case ) self.assertListEqual( tokenizer.tokenize(''' \tHäLLo!how \n Are yoU? ''' ) , ['''hällo''', '''!''', '''how''', '''are''', '''you''', '''?'''] ) self.assertListEqual(tokenizer.tokenize('''H\u00E9llo''' ) , ['''h\u00E9llo'''] ) def __UpperCAmelCase ( self ): __a = RoCBertBasicTokenizer(do_lower_case=_snake_case , strip_accents=_snake_case ) self.assertListEqual( tokenizer.tokenize(''' \tHäLLo!how \n Are yoU? ''' ) , ['''hallo''', '''!''', '''how''', '''are''', '''you''', '''?'''] ) self.assertListEqual(tokenizer.tokenize('''H\u00E9llo''' ) , ['''hello'''] ) def __UpperCAmelCase ( self ): __a = RoCBertBasicTokenizer(do_lower_case=_snake_case ) self.assertListEqual( tokenizer.tokenize(''' \tHäLLo!how \n Are yoU? ''' ) , ['''hallo''', '''!''', '''how''', '''are''', '''you''', '''?'''] ) self.assertListEqual(tokenizer.tokenize('''H\u00E9llo''' ) , ['''hello'''] ) def __UpperCAmelCase ( self ): __a = RoCBertBasicTokenizer(do_lower_case=_snake_case ) self.assertListEqual( tokenizer.tokenize(''' \tHeLLo!how \n Are yoU? ''' ) , ['''HeLLo''', '''!''', '''how''', '''Are''', '''yoU''', '''?'''] ) def __UpperCAmelCase ( self ): __a = RoCBertBasicTokenizer(do_lower_case=_snake_case , strip_accents=_snake_case ) self.assertListEqual( tokenizer.tokenize(''' \tHäLLo!how \n Are yoU? ''' ) , ['''HäLLo''', '''!''', '''how''', '''Are''', '''yoU''', '''?'''] ) def __UpperCAmelCase ( self ): __a = RoCBertBasicTokenizer(do_lower_case=_snake_case , strip_accents=_snake_case ) self.assertListEqual( tokenizer.tokenize(''' \tHäLLo!how \n Are yoU? ''' ) , ['''HaLLo''', '''!''', '''how''', '''Are''', '''yoU''', '''?'''] ) def __UpperCAmelCase ( self ): __a = RoCBertBasicTokenizer(do_lower_case=_snake_case , never_split=['''[UNK]'''] ) self.assertListEqual( tokenizer.tokenize(''' \tHeLLo!how \n Are yoU? [UNK]''' ) , ['''HeLLo''', '''!''', '''how''', '''Are''', '''yoU''', '''?''', '''[UNK]'''] ) def __UpperCAmelCase ( self ): __a = ['[UNK]', '[CLS]', '[SEP]', 'want', '##want', '##ed', 'wa', 'un', 'runn', '##ing'] __a = {} for i, token in enumerate(_snake_case ): __a = i __a = RoCBertWordpieceTokenizer(vocab=_snake_case , unk_token='''[UNK]''' ) self.assertListEqual(tokenizer.tokenize('''''' ) , [] ) self.assertListEqual(tokenizer.tokenize('''unwanted running''' ) , ['''un''', '''##want''', '''##ed''', '''runn''', '''##ing'''] ) self.assertListEqual(tokenizer.tokenize('''unwantedX running''' ) , ['''[UNK]''', '''runn''', '''##ing'''] ) def __UpperCAmelCase ( self ): self.assertTrue(_is_whitespace(''' ''' ) ) self.assertTrue(_is_whitespace('''\t''' ) ) self.assertTrue(_is_whitespace('''\r''' ) ) self.assertTrue(_is_whitespace('''\n''' ) ) self.assertTrue(_is_whitespace('''\u00A0''' ) ) self.assertFalse(_is_whitespace('''A''' ) ) self.assertFalse(_is_whitespace('''-''' ) ) def __UpperCAmelCase ( self ): self.assertTrue(_is_control('''\u0005''' ) ) self.assertFalse(_is_control('''A''' ) ) self.assertFalse(_is_control(''' ''' ) ) self.assertFalse(_is_control('''\t''' ) ) self.assertFalse(_is_control('''\r''' ) ) def __UpperCAmelCase ( self ): self.assertTrue(_is_punctuation('''-''' ) ) self.assertTrue(_is_punctuation('''$''' ) ) self.assertTrue(_is_punctuation('''`''' ) ) self.assertTrue(_is_punctuation('''.''' ) ) self.assertFalse(_is_punctuation('''A''' ) ) self.assertFalse(_is_punctuation(''' ''' ) ) def __UpperCAmelCase ( self ): __a = self.get_tokenizer() # Example taken from the issue https://github.com/huggingface/tokenizers/issues/340 self.assertListEqual([tokenizer.tokenize(_snake_case ) for t in ['''Test''', '''\xad''', '''test''']] , [['''[UNK]'''], [], ['''[UNK]''']] ) if self.test_rust_tokenizer: __a = self.get_rust_tokenizer() self.assertListEqual( [rust_tokenizer.tokenize(_snake_case ) for t in ['''Test''', '''\xad''', '''test''']] , [['''[UNK]'''], [], ['''[UNK]''']] ) def __UpperCAmelCase ( self ): for tokenizer, pretrained_name, kwargs in self.tokenizers_list: with self.subTest(f'''{tokenizer.__class__.__name__} ({pretrained_name})''' ): __a = self.rust_tokenizer_class.from_pretrained(_snake_case , **_snake_case ) __a = f'''A, naïve {tokenizer_r.mask_token} AllenNLP sentence.''' __a = tokenizer_r.encode_plus( _snake_case , return_attention_mask=_snake_case , return_token_type_ids=_snake_case , return_offsets_mapping=_snake_case , add_special_tokens=_snake_case , ) __a = tokenizer_r.do_lower_case if hasattr(_snake_case , '''do_lower_case''' ) else False __a = ( [ ((0, 0), tokenizer_r.cls_token), ((0, 1), 'A'), ((1, 2), ','), ((3, 5), 'na'), ((5, 6), '##ï'), ((6, 8), '##ve'), ((9, 15), tokenizer_r.mask_token), ((16, 21), 'Allen'), ((21, 23), '##NL'), ((23, 24), '##P'), ((25, 33), 'sentence'), ((33, 34), '.'), ((0, 0), tokenizer_r.sep_token), ] if not do_lower_case else [ ((0, 0), tokenizer_r.cls_token), ((0, 1), 'a'), ((1, 2), ','), ((3, 8), 'naive'), ((9, 15), tokenizer_r.mask_token), ((16, 21), 'allen'), ((21, 23), '##nl'), ((23, 24), '##p'), ((25, 33), 'sentence'), ((33, 34), '.'), ((0, 0), tokenizer_r.sep_token), ] ) self.assertEqual( [e[1] for e in expected_results] , tokenizer_r.convert_ids_to_tokens(tokens['''input_ids'''] ) ) self.assertEqual([e[0] for e in expected_results] , tokens['''offset_mapping'''] ) def __UpperCAmelCase ( self ): __a = ['的', '人', '有'] __a = ''.join(_snake_case ) for tokenizer, pretrained_name, kwargs in self.tokenizers_list: with self.subTest(f'''{tokenizer.__class__.__name__} ({pretrained_name})''' ): __a = True __a = self.tokenizer_class.from_pretrained(_snake_case , **_snake_case ) __a = self.rust_tokenizer_class.from_pretrained(_snake_case , **_snake_case ) __a = tokenizer_p.encode(_snake_case , add_special_tokens=_snake_case ) __a = tokenizer_r.encode(_snake_case , add_special_tokens=_snake_case ) __a = tokenizer_r.convert_ids_to_tokens(_snake_case ) __a = tokenizer_p.convert_ids_to_tokens(_snake_case ) # it is expected that each Chinese character is not preceded by "##" self.assertListEqual(_snake_case , _snake_case ) self.assertListEqual(_snake_case , _snake_case ) __a = False __a = self.rust_tokenizer_class.from_pretrained(_snake_case , **_snake_case ) __a = self.tokenizer_class.from_pretrained(_snake_case , **_snake_case ) __a = tokenizer_r.encode(_snake_case , add_special_tokens=_snake_case ) __a = tokenizer_p.encode(_snake_case , add_special_tokens=_snake_case ) __a = tokenizer_r.convert_ids_to_tokens(_snake_case ) __a = tokenizer_p.convert_ids_to_tokens(_snake_case ) # it is expected that only the first Chinese character is not preceded by "##". __a = [ f'''##{token}''' if idx != 0 else token for idx, token in enumerate(_snake_case ) ] self.assertListEqual(_snake_case , _snake_case ) self.assertListEqual(_snake_case , _snake_case ) @slow def __UpperCAmelCase ( self ): __a = self.tokenizer_class(self.vocab_file , self.word_shape_file , self.word_pronunciation_file ) __a = tokenizer.encode('''你好''' , add_special_tokens=_snake_case ) __a = tokenizer.encode('''你是谁''' , add_special_tokens=_snake_case ) __a = tokenizer.build_inputs_with_special_tokens(_snake_case ) __a = tokenizer.build_inputs_with_special_tokens(_snake_case , _snake_case ) assert encoded_sentence == [1] + text + [2] assert encoded_pair == [1] + text + [2] + text_a + [2] def __UpperCAmelCase ( self ): __a = self.get_tokenizers(do_lower_case=_snake_case ) for tokenizer in tokenizers: with self.subTest(f'''{tokenizer.__class__.__name__}''' ): __a = '你好,你是谁' __a = tokenizer.tokenize(_snake_case ) __a = tokenizer.convert_tokens_to_ids(_snake_case ) __a = tokenizer.convert_tokens_to_shape_ids(_snake_case ) __a = tokenizer.convert_tokens_to_pronunciation_ids(_snake_case ) __a = tokenizer.prepare_for_model( _snake_case , _snake_case , _snake_case , add_special_tokens=_snake_case ) __a = tokenizer.encode_plus(_snake_case , add_special_tokens=_snake_case ) self.assertEqual(_snake_case , _snake_case )
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import argparse import logging import os from datetime import datetime import numpy as np import torch from torch import nn from torch.utils.data import DataLoader, RandomSampler, TensorDataset from tqdm import tqdm from transformers import GPTaLMHeadModel a_ :Optional[Any] = logging.getLogger(__name__) def lowercase_ (A : List[Any] , A : List[Any] ): # save results if os.path.exists(A ): if os.path.exists(os.path.join(A , 'config.json' ) ) and os.path.isfile( os.path.join(A , 'config.json' ) ): os.remove(os.path.join(A , 'config.json' ) ) if os.path.exists(os.path.join(A , 'pytorch_model.bin' ) ) and os.path.isfile( os.path.join(A , 'pytorch_model.bin' ) ): os.remove(os.path.join(A , 'pytorch_model.bin' ) ) else: os.makedirs(A ) model.save_pretrained(A ) def lowercase_ (A : Any , A : Optional[Any]=False ): snake_case__ : str = 2 if unlogit: snake_case__ : Dict = torch.pow(A , A ) snake_case__ : Any = p * torch.log(A ) snake_case__ : Tuple = 0 return -plogp.sum(dim=-1 ) def lowercase_ (A : List[str] ): logger.info('lv, h >\t' + '\t'.join(F'''{x + 1}''' for x in range(len(A ) ) ) ) for row in range(len(A ) ): if tensor.dtype != torch.long: logger.info(F'''layer {row + 1}:\t''' + '\t'.join(F'''{x:.5f}''' for x in tensor[row].cpu().data ) ) else: logger.info(F'''layer {row + 1}:\t''' + '\t'.join(F'''{x:d}''' for x in tensor[row].cpu().data ) ) def lowercase_ (A : Tuple , A : Optional[Any] , A : str , A : int=True , A : Optional[int]=True , A : Any=None , A : int=False ): snake_case__ , snake_case__ : Optional[Any] = model.config.num_hidden_layers, model.config.num_attention_heads snake_case__ : int = torch.zeros(A , A ).to(args.device ) snake_case__ : Any = torch.zeros(A , A ).to(args.device ) if head_mask is None: snake_case__ : Dict = torch.ones(A , A ).to(args.device ) head_mask.requires_grad_(requires_grad=A ) # If actually pruned attention multi-head, set head mask to None to avoid shape mismatch if actually_pruned: snake_case__ : Optional[int] = None snake_case__ : List[Any] = 0.0 snake_case__ : str = 0.0 for step, inputs in enumerate(tqdm(A , desc='Iteration' , disable=args.local_rank not in [-1, 0] ) ): snake_case__ : Union[str, Any] = tuple(t.to(args.device ) for t in inputs ) ((snake_case__) , ) : Optional[Any] = inputs # Do a forward pass (not with torch.no_grad() since we need gradients for importance score - see below) snake_case__ : Union[str, Any] = model(A , labels=A , head_mask=A ) # (loss), lm_logits, presents, (all hidden_states), (attentions) snake_case__ , snake_case__ , snake_case__ : Dict = ( outputs[0], outputs[1], outputs[-1], ) # Loss and logits are the first, attention the last loss.backward() # Backpropagate to populate the gradients in the head mask total_loss += loss.detach().cpu().numpy() if compute_entropy: for layer, attn in enumerate(A ): snake_case__ : Optional[Any] = entropy(attn.detach() , A ) attn_entropy[layer] += masked_entropy.sum(-1 ).sum(0 ).sum(0 ).detach() if compute_importance: head_importance += head_mask.grad.abs().detach() tot_tokens += torch.ones_like(A ).float().detach().sum().data # Normalize attn_entropy /= tot_tokens head_importance /= tot_tokens # Layerwise importance normalization if not args.dont_normalize_importance_by_layer: snake_case__ : Union[str, Any] = 2 snake_case__ : List[Any] = torch.pow(torch.pow(A , A ).sum(-1 ) , 1 / exponent ) head_importance /= norm_by_layer.unsqueeze(-1 ) + 1e-20 if not args.dont_normalize_global_importance: snake_case__ : Tuple = (head_importance - head_importance.min()) / (head_importance.max() - head_importance.min()) # Print matrices if compute_entropy: logger.info('Attention entropies' ) print_ad_tensor(A ) if compute_importance: logger.info('Head importance scores' ) print_ad_tensor(A ) logger.info('Head ranked by importance scores' ) snake_case__ : Tuple = torch.zeros(head_importance.numel() , dtype=torch.long , device=args.device ) snake_case__ : Union[str, Any] = torch.arange( head_importance.numel() , device=args.device ) snake_case__ : str = head_ranks.view_as(A ) print_ad_tensor(A ) return attn_entropy, head_importance, total_loss def lowercase_ (A : Optional[int] , A : Dict , A : Optional[int] ): snake_case__ , snake_case__ , snake_case__ : Any = compute_heads_importance(A , A , A , compute_entropy=A ) snake_case__ : Tuple = 1 / loss # instead of downsteam score use the LM loss logger.info('Pruning: original score: %f, threshold: %f' , A , original_score * args.masking_threshold ) snake_case__ : Optional[Any] = torch.ones_like(A ) snake_case__ : Union[str, Any] = max(1 , int(new_head_mask.numel() * args.masking_amount ) ) snake_case__ : Dict = original_score while current_score >= original_score * args.masking_threshold: snake_case__ : int = new_head_mask.clone().detach() # save current head mask # heads from least important to most - keep only not-masked heads snake_case__ : List[Any] = float('Inf' ) snake_case__ : Union[str, Any] = head_importance.view(-1 ).sort()[1] if len(A ) <= num_to_mask: print('BREAK BY num_to_mask' ) break # mask heads snake_case__ : int = current_heads_to_mask[:num_to_mask] logger.info('Heads to mask: %s' , str(current_heads_to_mask.tolist() ) ) snake_case__ : int = new_head_mask.view(-1 ) snake_case__ : int = 0.0 snake_case__ : Union[str, Any] = new_head_mask.view_as(A ) snake_case__ : List[str] = new_head_mask.clone().detach() print_ad_tensor(A ) # Compute metric and head importance again snake_case__ , snake_case__ , snake_case__ : Any = compute_heads_importance( A , A , A , compute_entropy=A , head_mask=A ) snake_case__ : Dict = 1 / loss logger.info( 'Masking: current score: %f, remaining heads %d (%.1f percents)' , A , new_head_mask.sum() , new_head_mask.sum() / new_head_mask.numel() * 1_0_0 , ) logger.info('Final head mask' ) print_ad_tensor(A ) np.save(os.path.join(args.output_dir , 'head_mask.npy' ) , head_mask.detach().cpu().numpy() ) return head_mask def lowercase_ (A : List[str] , A : Tuple , A : Optional[Any] , A : int ): snake_case__ : Any = datetime.now() snake_case__ , snake_case__ , snake_case__ : str = compute_heads_importance( A , A , A , compute_entropy=A , compute_importance=A , head_mask=A ) snake_case__ : Tuple = 1 / loss snake_case__ : Dict = datetime.now() - before_time snake_case__ : Union[str, Any] = sum(p.numel() for p in model.parameters() ) snake_case__ : Optional[Any] = { layer: (1 - head_mask[layer].long()).nonzero().squeeze().tolist() for layer in range(len(A ) ) } for k, v in heads_to_prune.items(): if isinstance(A , A ): snake_case__ : Any = [ v, ] assert sum(len(A ) for h in heads_to_prune.values() ) == (1 - head_mask.long()).sum().item() model.prune_heads(A ) snake_case__ : Dict = sum(p.numel() for p in model.parameters() ) snake_case__ : Tuple = datetime.now() snake_case__ , snake_case__ , snake_case__ : Dict = compute_heads_importance( A , A , A , compute_entropy=A , compute_importance=A , head_mask=A , actually_pruned=A , ) snake_case__ : Any = 1 / loss snake_case__ : int = datetime.now() - before_time logger.info( 'Pruning: original num of params: %.2e, after pruning %.2e (%.1f percents)' , A , A , pruned_num_params / original_num_params * 1_0_0 , ) logger.info('Pruning: score with masking: %f score with pruning: %f' , A , A ) logger.info('Pruning: speed ratio (original timing / new timing): %f percents' , original_time / new_time * 1_0_0 ) save_model(A , args.output_dir ) def lowercase_ (): snake_case__ : str = argparse.ArgumentParser() # Required parameters parser.add_argument( '--data_dir' , default=A , type=A , required=A , help='The input data dir. Should contain the .tsv files (or other data files) for the task.' , ) parser.add_argument( '--model_name_or_path' , default=A , type=A , required=A , help='Path to pretrained model or model identifier from huggingface.co/models' , ) parser.add_argument( '--output_dir' , default=A , type=A , required=A , help='The output directory where the model predictions and checkpoints will be written.' , ) # Other parameters parser.add_argument( '--config_name' , default='' , type=A , help='Pretrained config name or path if not the same as model_name_or_path' , ) parser.add_argument( '--tokenizer_name' , default='' , type=A , help='Pretrained tokenizer name or path if not the same as model_name_or_path' , ) parser.add_argument( '--cache_dir' , default=A , type=A , help='Where do you want to store the pre-trained models downloaded from s3' , ) parser.add_argument( '--data_subset' , type=A , default=-1 , help='If > 0: limit the data to a subset of data_subset instances.' ) parser.add_argument( '--overwrite_output_dir' , action='store_true' , help='Whether to overwrite data in output directory' ) parser.add_argument( '--overwrite_cache' , action='store_true' , help='Overwrite the cached training and evaluation sets' ) parser.add_argument( '--dont_normalize_importance_by_layer' , action='store_true' , help='Don\'t normalize importance score by layers' ) parser.add_argument( '--dont_normalize_global_importance' , action='store_true' , help='Don\'t normalize all importance scores between 0 and 1' , ) parser.add_argument( '--try_masking' , action='store_true' , help='Whether to try to mask head until a threshold of accuracy.' ) parser.add_argument( '--masking_threshold' , default=0.9 , type=A , help='masking threshold in term of metrics (stop masking when metric < threshold * original metric value).' , ) parser.add_argument( '--masking_amount' , default=0.1 , type=A , help='Amount to heads to masking at each masking step.' ) parser.add_argument('--metric_name' , default='acc' , type=A , help='Metric to use for head masking.' ) parser.add_argument( '--max_seq_length' , default=1_2_8 , type=A , help=( 'The maximum total input sequence length after WordPiece tokenization. \n' 'Sequences longer than this will be truncated, sequences shorter padded.' ) , ) parser.add_argument('--batch_size' , default=1 , type=A , help='Batch size.' ) parser.add_argument('--seed' , type=A , default=4_2 ) parser.add_argument('--local_rank' , type=A , default=-1 , help='local_rank for distributed training on gpus' ) parser.add_argument('--no_cuda' , action='store_true' , help='Whether not to use CUDA when available' ) parser.add_argument('--server_ip' , type=A , default='' , help='Can be used for distant debugging.' ) parser.add_argument('--server_port' , type=A , default='' , help='Can be used for distant debugging.' ) snake_case__ : Optional[int] = parser.parse_args() if args.server_ip and args.server_port: # Distant debugging - see https://code.visualstudio.com/docs/python/debugging#_attach-to-a-local-script import ptvsd print('Waiting for debugger attach' ) ptvsd.enable_attach(address=(args.server_ip, args.server_port) , redirect_output=A ) ptvsd.wait_for_attach() # Setup devices and distributed training if args.local_rank == -1 or args.no_cuda: snake_case__ : List[Any] = torch.device('cuda' if torch.cuda.is_available() and not args.no_cuda else 'cpu' ) snake_case__ : Optional[Any] = 0 if args.no_cuda else torch.cuda.device_count() else: torch.cuda.set_device(args.local_rank ) snake_case__ : int = torch.device('cuda' , args.local_rank ) snake_case__ : List[str] = 1 torch.distributed.init_process_group(backend='nccl' ) # Initializes the distributed backend # Setup logging logging.basicConfig(level=logging.INFO if args.local_rank in [-1, 0] else logging.WARN ) logger.info('device: {} n_gpu: {}, distributed: {}'.format(args.device , args.n_gpu , bool(args.local_rank != -1 ) ) ) snake_case__ : Any = GPTaLMHeadModel.from_pretrained(args.model_name_or_path ) # Distributed and parallel training model.to(args.device ) if args.local_rank != -1: snake_case__ : List[str] = nn.parallel.DistributedDataParallel( A , device_ids=[args.local_rank] , output_device=args.local_rank , find_unused_parameters=A ) elif args.n_gpu > 1: snake_case__ : Optional[int] = nn.DataParallel(A ) # Print/save training arguments os.makedirs(args.output_dir , exist_ok=A ) torch.save(A , os.path.join(args.output_dir , 'run_args.bin' ) ) logger.info('Training/evaluation parameters %s' , A ) # Prepare dataset snake_case__ : Optional[Any] = np.concatenate( [ np.loadtxt(args.data_dir , dtype=np.intaa ), ] ) snake_case__ : List[str] = (torch.from_numpy(A ),) snake_case__ : int = TensorDataset(*A ) snake_case__ : Union[str, Any] = RandomSampler(A ) snake_case__ : Any = DataLoader(A , sampler=A , batch_size=args.batch_size ) # Compute head entropy and importance score compute_heads_importance(A , A , A ) # Try head masking (set heads to zero until the score goes under a threshole) # and head pruning (remove masked heads and see the effect on the network) if args.try_masking and args.masking_threshold > 0.0 and args.masking_threshold < 1.0: snake_case__ : Dict = mask_heads(A , A , A ) prune_heads(A , A , A , A ) if __name__ == "__main__": main()
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