Datasets:
infinityofspace
/
python_codestyles-random-500

Dataset card Data Studio Files
xet
Community
code
stringlengths
87
55.2k
code_codestyle
int64
0
349
style_context
stringlengths
135
49.1k
style_context_codestyle
int64
0
349
label
int64
0
1
"""simple docstring""" from typing import TYPE_CHECKING from ...utils import ( OptionalDependencyNotAvailable, _LazyModule, is_flax_available, is_tf_available, is_tokenizers_available, is_torch_available, ) _A : Union[str, Any] = { """configuration_distilbert""": [ """DISTILBERT_PRETRAINED_CONFIG_ARCHIVE_MAP""", """DistilBertConfig""", """DistilBertOnnxConfig""", ], """tokenization_distilbert""": ["""DistilBertTokenizer"""], } try: if not is_tokenizers_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: _A : int = ["""DistilBertTokenizerFast"""] try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: _A : List[Any] = [ """DISTILBERT_PRETRAINED_MODEL_ARCHIVE_LIST""", """DistilBertForMaskedLM""", """DistilBertForMultipleChoice""", """DistilBertForQuestionAnswering""", """DistilBertForSequenceClassification""", """DistilBertForTokenClassification""", """DistilBertModel""", """DistilBertPreTrainedModel""", ] try: if not is_tf_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: _A : str = [ """TF_DISTILBERT_PRETRAINED_MODEL_ARCHIVE_LIST""", """TFDistilBertForMaskedLM""", """TFDistilBertForMultipleChoice""", """TFDistilBertForQuestionAnswering""", """TFDistilBertForSequenceClassification""", """TFDistilBertForTokenClassification""", """TFDistilBertMainLayer""", """TFDistilBertModel""", """TFDistilBertPreTrainedModel""", ] try: if not is_flax_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: _A : Union[str, Any] = [ """FlaxDistilBertForMaskedLM""", """FlaxDistilBertForMultipleChoice""", """FlaxDistilBertForQuestionAnswering""", """FlaxDistilBertForSequenceClassification""", """FlaxDistilBertForTokenClassification""", """FlaxDistilBertModel""", """FlaxDistilBertPreTrainedModel""", ] if TYPE_CHECKING: from .configuration_distilbert import ( DISTILBERT_PRETRAINED_CONFIG_ARCHIVE_MAP, DistilBertConfig, DistilBertOnnxConfig, ) from .tokenization_distilbert import DistilBertTokenizer try: if not is_tokenizers_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .tokenization_distilbert_fast import DistilBertTokenizerFast try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_distilbert import ( DISTILBERT_PRETRAINED_MODEL_ARCHIVE_LIST, DistilBertForMaskedLM, DistilBertForMultipleChoice, DistilBertForQuestionAnswering, DistilBertForSequenceClassification, DistilBertForTokenClassification, DistilBertModel, DistilBertPreTrainedModel, ) try: if not is_tf_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_tf_distilbert import ( TF_DISTILBERT_PRETRAINED_MODEL_ARCHIVE_LIST, TFDistilBertForMaskedLM, TFDistilBertForMultipleChoice, TFDistilBertForQuestionAnswering, TFDistilBertForSequenceClassification, TFDistilBertForTokenClassification, TFDistilBertMainLayer, TFDistilBertModel, TFDistilBertPreTrainedModel, ) try: if not is_flax_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_flax_distilbert import ( FlaxDistilBertForMaskedLM, FlaxDistilBertForMultipleChoice, FlaxDistilBertForQuestionAnswering, FlaxDistilBertForSequenceClassification, FlaxDistilBertForTokenClassification, FlaxDistilBertModel, FlaxDistilBertPreTrainedModel, ) else: import sys _A : Optional[int] = _LazyModule(__name__, globals()["""__file__"""], _import_structure, module_spec=__spec__)
202
from dataclasses import dataclass from typing import Optional, Tuple import torch from torch import nn from transformers import RobertaPreTrainedModel, XLMRobertaConfig, XLMRobertaModel from transformers.utils import ModelOutput @dataclass class A ( UpperCAmelCase_ ): __UpperCAmelCase : Optional[torch.FloatTensor] = None __UpperCAmelCase : torch.FloatTensor = None __UpperCAmelCase : Optional[Tuple[torch.FloatTensor]] = None __UpperCAmelCase : Optional[Tuple[torch.FloatTensor]] = None class A ( UpperCAmelCase_ ): def __init__(self : Union[str, Any] , __UpperCAmelCase : Tuple=1 , __UpperCAmelCase : str=0 , __UpperCAmelCase : str=2 , __UpperCAmelCase : Union[str, Any]=5_1_2 , __UpperCAmelCase : List[str]="cls" , __UpperCAmelCase : Optional[int]=False , __UpperCAmelCase : str=True , **__UpperCAmelCase : str , ) -> int: """simple docstring""" super().__init__(pad_token_id=__UpperCAmelCase , bos_token_id=__UpperCAmelCase , eos_token_id=__UpperCAmelCase , **__UpperCAmelCase ) UpperCAmelCase__ = project_dim UpperCAmelCase__ = pooler_fn UpperCAmelCase__ = learn_encoder UpperCAmelCase__ = use_attention_mask class A ( UpperCAmelCase_ ): __UpperCAmelCase : Tuple = [r'pooler', r'logit_scale'] __UpperCAmelCase : int = [r'position_ids', r'predictions.decoder.bias'] __UpperCAmelCase : Any = 'roberta' __UpperCAmelCase : List[str] = RobertaSeriesConfig def __init__(self : Tuple , __UpperCAmelCase : Optional[int] ) -> int: """simple docstring""" super().__init__(__UpperCAmelCase ) UpperCAmelCase__ = XLMRobertaModel(__UpperCAmelCase ) UpperCAmelCase__ = nn.Linear(config.hidden_size , config.project_dim ) UpperCAmelCase__ = getattr(__UpperCAmelCase , "has_pre_transformation" , __UpperCAmelCase ) if self.has_pre_transformation: UpperCAmelCase__ = nn.Linear(config.hidden_size , config.project_dim ) UpperCAmelCase__ = nn.LayerNorm(config.hidden_size , eps=config.layer_norm_eps ) self.post_init() def lowercase_ (self : Optional[Any] , __UpperCAmelCase : Optional[torch.Tensor] = None , __UpperCAmelCase : Optional[torch.Tensor] = None , __UpperCAmelCase : Optional[torch.Tensor] = None , __UpperCAmelCase : Optional[torch.Tensor] = None , __UpperCAmelCase : Optional[torch.Tensor] = None , __UpperCAmelCase : Optional[torch.Tensor] = None , __UpperCAmelCase : Optional[torch.Tensor] = None , __UpperCAmelCase : Optional[torch.Tensor] = None , __UpperCAmelCase : Optional[bool] = None , __UpperCAmelCase : Optional[bool] = None , __UpperCAmelCase : Optional[bool] = None , ) -> Optional[int]: """simple docstring""" UpperCAmelCase__ = return_dict if return_dict is not None else self.config.use_return_dict UpperCAmelCase__ = self.base_model( input_ids=__UpperCAmelCase , attention_mask=__UpperCAmelCase , token_type_ids=__UpperCAmelCase , position_ids=__UpperCAmelCase , head_mask=__UpperCAmelCase , inputs_embeds=__UpperCAmelCase , encoder_hidden_states=__UpperCAmelCase , encoder_attention_mask=__UpperCAmelCase , output_attentions=__UpperCAmelCase , output_hidden_states=True if self.has_pre_transformation else output_hidden_states , return_dict=__UpperCAmelCase , ) if self.has_pre_transformation: UpperCAmelCase__ = outputs["hidden_states"][-2] UpperCAmelCase__ = self.pre_LN(__UpperCAmelCase ) UpperCAmelCase__ = self.transformation_pre(__UpperCAmelCase ) return TransformationModelOutput( projection_state=__UpperCAmelCase , last_hidden_state=outputs.last_hidden_state , hidden_states=outputs.hidden_states , attentions=outputs.attentions , ) else: UpperCAmelCase__ = self.transformation(outputs.last_hidden_state ) return TransformationModelOutput( projection_state=__UpperCAmelCase , last_hidden_state=outputs.last_hidden_state , hidden_states=outputs.hidden_states , attentions=outputs.attentions , )
65
0
"""simple docstring""" import contextlib import csv import json import os import sqlitea import tarfile import textwrap import zipfile import pyarrow as pa import pyarrow.parquet as pq import pytest import datasets import datasets.config @pytest.fixture(scope="session" ) def snake_case ( ): UpperCAmelCase_ : Any = 10 UpperCAmelCase_ : Tuple = datasets.Features( { "tokens": datasets.Sequence(datasets.Value("string" ) ), "labels": datasets.Sequence(datasets.ClassLabel(names=["negative", "positive"] ) ), "answers": datasets.Sequence( { "text": datasets.Value("string" ), "answer_start": datasets.Value("int32" ), } ), "id": datasets.Value("int64" ), } ) UpperCAmelCase_ : Any = datasets.Dataset.from_dict( { "tokens": [["foo"] * 5] * n, "labels": [[1] * 5] * n, "answers": [{"answer_start": [97], "text": ["1976"]}] * 10, "id": list(range(__A ) ), } ,features=__A ,) return dataset @pytest.fixture(scope="session" ) def snake_case ( A__ ,A__ ): UpperCAmelCase_ : Optional[int] = str(tmp_path_factory.mktemp("data" ) / "file.arrow" ) dataset.map(cache_file_name=__A ) return filename # FILE_CONTENT + files lowerCamelCase_ = '''\\n Text data.\n Second line of data.''' @pytest.fixture(scope="session" ) def snake_case ( A__ ): UpperCAmelCase_ : Optional[Any] = tmp_path_factory.mktemp("data" ) / "file.txt" UpperCAmelCase_ : List[str] = FILE_CONTENT with open(__A ,"w" ) as f: f.write(__A ) return filename @pytest.fixture(scope="session" ) def snake_case ( A__ ): import bza UpperCAmelCase_ : Tuple = tmp_path_factory.mktemp("data" ) / "file.txt.bz2" UpperCAmelCase_ : Tuple = bytes(__A ,"utf-8" ) with bza.open(__A ,"wb" ) as f: f.write(__A ) return path @pytest.fixture(scope="session" ) def snake_case ( A__ ): import gzip UpperCAmelCase_ : Optional[Any] = str(tmp_path_factory.mktemp("data" ) / "file.txt.gz" ) UpperCAmelCase_ : Union[str, Any] = bytes(__A ,"utf-8" ) with gzip.open(__A ,"wb" ) as f: f.write(__A ) return path @pytest.fixture(scope="session" ) def snake_case ( A__ ): if datasets.config.LZ4_AVAILABLE: import lza.frame UpperCAmelCase_ : int = tmp_path_factory.mktemp("data" ) / "file.txt.lz4" UpperCAmelCase_ : Dict = bytes(__A ,"utf-8" ) with lza.frame.open(__A ,"wb" ) as f: f.write(__A ) return path @pytest.fixture(scope="session" ) def snake_case ( A__ ,A__ ): if datasets.config.PY7ZR_AVAILABLE: import pyazr UpperCAmelCase_ : Union[str, Any] = tmp_path_factory.mktemp("data" ) / "file.txt.7z" with pyazr.SevenZipFile(__A ,"w" ) as archive: archive.write(__A ,arcname=os.path.basename(__A ) ) return path @pytest.fixture(scope="session" ) def snake_case ( A__ ,A__ ): import tarfile UpperCAmelCase_ : Dict = tmp_path_factory.mktemp("data" ) / "file.txt.tar" with tarfile.TarFile(__A ,"w" ) as f: f.add(__A ,arcname=os.path.basename(__A ) ) return path @pytest.fixture(scope="session" ) def snake_case ( A__ ): import lzma UpperCAmelCase_ : List[Any] = tmp_path_factory.mktemp("data" ) / "file.txt.xz" UpperCAmelCase_ : Tuple = bytes(__A ,"utf-8" ) with lzma.open(__A ,"wb" ) as f: f.write(__A ) return path @pytest.fixture(scope="session" ) def snake_case ( A__ ,A__ ): import zipfile UpperCAmelCase_ : int = tmp_path_factory.mktemp("data" ) / "file.txt.zip" with zipfile.ZipFile(__A ,"w" ) as f: f.write(__A ,arcname=os.path.basename(__A ) ) return path @pytest.fixture(scope="session" ) def snake_case ( A__ ): if datasets.config.ZSTANDARD_AVAILABLE: import zstandard as zstd UpperCAmelCase_ : Dict = tmp_path_factory.mktemp("data" ) / "file.txt.zst" UpperCAmelCase_ : Optional[Any] = bytes(__A ,"utf-8" ) with zstd.open(__A ,"wb" ) as f: f.write(__A ) return path @pytest.fixture(scope="session" ) def snake_case ( A__ ): UpperCAmelCase_ : Any = tmp_path_factory.mktemp("data" ) / "file.xml" UpperCAmelCase_ : List[Any] = textwrap.dedent( "\\n <?xml version=\"1.0\" encoding=\"UTF-8\" ?>\n <tmx version=\"1.4\">\n <header segtype=\"sentence\" srclang=\"ca\" />\n <body>\n <tu>\n <tuv xml:lang=\"ca\"><seg>Contingut 1</seg></tuv>\n <tuv xml:lang=\"en\"><seg>Content 1</seg></tuv>\n </tu>\n <tu>\n <tuv xml:lang=\"ca\"><seg>Contingut 2</seg></tuv>\n <tuv xml:lang=\"en\"><seg>Content 2</seg></tuv>\n </tu>\n <tu>\n <tuv xml:lang=\"ca\"><seg>Contingut 3</seg></tuv>\n <tuv xml:lang=\"en\"><seg>Content 3</seg></tuv>\n </tu>\n <tu>\n <tuv xml:lang=\"ca\"><seg>Contingut 4</seg></tuv>\n <tuv xml:lang=\"en\"><seg>Content 4</seg></tuv>\n </tu>\n <tu>\n <tuv xml:lang=\"ca\"><seg>Contingut 5</seg></tuv>\n <tuv xml:lang=\"en\"><seg>Content 5</seg></tuv>\n </tu>\n </body>\n </tmx>" ) with open(__A ,"w" ) as f: f.write(__A ) return filename lowerCamelCase_ = [ {'''col_1''': '''0''', '''col_2''': 0, '''col_3''': 0.0}, {'''col_1''': '''1''', '''col_2''': 1, '''col_3''': 1.0}, {'''col_1''': '''2''', '''col_2''': 2, '''col_3''': 2.0}, {'''col_1''': '''3''', '''col_2''': 3, '''col_3''': 3.0}, ] lowerCamelCase_ = [ {'''col_1''': '''4''', '''col_2''': 4, '''col_3''': 4.0}, {'''col_1''': '''5''', '''col_2''': 5, '''col_3''': 5.0}, ] lowerCamelCase_ = { '''col_1''': ['''0''', '''1''', '''2''', '''3'''], '''col_2''': [0, 1, 2, 3], '''col_3''': [0.0, 1.0, 2.0, 3.0], } lowerCamelCase_ = [ {'''col_3''': 0.0, '''col_1''': '''0''', '''col_2''': 0}, {'''col_3''': 1.0, '''col_1''': '''1''', '''col_2''': 1}, ] lowerCamelCase_ = [ {'''col_1''': '''s0''', '''col_2''': 0, '''col_3''': 0.0}, {'''col_1''': '''s1''', '''col_2''': 1, '''col_3''': 1.0}, {'''col_1''': '''s2''', '''col_2''': 2, '''col_3''': 2.0}, {'''col_1''': '''s3''', '''col_2''': 3, '''col_3''': 3.0}, ] @pytest.fixture(scope="session" ) def snake_case ( ): return DATA_DICT_OF_LISTS @pytest.fixture(scope="session" ) def snake_case ( A__ ): UpperCAmelCase_ : Dict = datasets.Dataset.from_dict(__A ) UpperCAmelCase_ : Any = str(tmp_path_factory.mktemp("data" ) / "dataset.arrow" ) dataset.map(cache_file_name=__A ) return path @pytest.fixture(scope="session" ) def snake_case ( A__ ): UpperCAmelCase_ : Optional[Any] = str(tmp_path_factory.mktemp("data" ) / "dataset.sqlite" ) with contextlib.closing(sqlitea.connect(__A ) ) as con: UpperCAmelCase_ : Tuple = con.cursor() cur.execute("CREATE TABLE dataset(col_1 text, col_2 int, col_3 real)" ) for item in DATA: cur.execute("INSERT INTO dataset(col_1, col_2, col_3) VALUES (?, ?, ?)" ,tuple(item.values() ) ) con.commit() return path @pytest.fixture(scope="session" ) def snake_case ( A__ ): UpperCAmelCase_ : Any = str(tmp_path_factory.mktemp("data" ) / "dataset.csv" ) with open(__A ,"w" ,newline="" ) as f: UpperCAmelCase_ : str = csv.DictWriter(__A ,fieldnames=["col_1", "col_2", "col_3"] ) writer.writeheader() for item in DATA: writer.writerow(__A ) return path @pytest.fixture(scope="session" ) def snake_case ( A__ ): UpperCAmelCase_ : int = str(tmp_path_factory.mktemp("data" ) / "dataset2.csv" ) with open(__A ,"w" ,newline="" ) as f: UpperCAmelCase_ : List[Any] = csv.DictWriter(__A ,fieldnames=["col_1", "col_2", "col_3"] ) writer.writeheader() for item in DATA: writer.writerow(__A ) return path @pytest.fixture(scope="session" ) def snake_case ( A__ ,A__ ): import bza UpperCAmelCase_ : Any = tmp_path_factory.mktemp("data" ) / "dataset.csv.bz2" with open(__A ,"rb" ) as f: UpperCAmelCase_ : Dict = f.read() # data = bytes(FILE_CONTENT, "utf-8") with bza.open(__A ,"wb" ) as f: f.write(__A ) return path @pytest.fixture(scope="session" ) def snake_case ( A__ ,A__ ,A__ ): UpperCAmelCase_ : Union[str, Any] = tmp_path_factory.mktemp("data" ) / "dataset.csv.zip" with zipfile.ZipFile(__A ,"w" ) as f: f.write(__A ,arcname=os.path.basename(__A ) ) f.write(__A ,arcname=os.path.basename(__A ) ) return path @pytest.fixture(scope="session" ) def snake_case ( A__ ,A__ ,A__ ): UpperCAmelCase_ : Dict = tmp_path_factory.mktemp("data" ) / "dataset.csv.zip" with zipfile.ZipFile(__A ,"w" ) as f: f.write(__A ,arcname=os.path.basename(csv_path.replace(".csv" ,".CSV" ) ) ) f.write(__A ,arcname=os.path.basename(csva_path.replace(".csv" ,".CSV" ) ) ) return path @pytest.fixture(scope="session" ) def snake_case ( A__ ,A__ ,A__ ): UpperCAmelCase_ : Optional[Any] = tmp_path_factory.mktemp("data" ) / "dataset_with_dir.csv.zip" with zipfile.ZipFile(__A ,"w" ) as f: f.write(__A ,arcname=os.path.join("main_dir" ,os.path.basename(__A ) ) ) f.write(__A ,arcname=os.path.join("main_dir" ,os.path.basename(__A ) ) ) return path @pytest.fixture(scope="session" ) def snake_case ( A__ ): UpperCAmelCase_ : List[Any] = str(tmp_path_factory.mktemp("data" ) / "dataset.parquet" ) UpperCAmelCase_ : str = pa.schema( { "col_1": pa.string(), "col_2": pa.intaa(), "col_3": pa.floataa(), } ) with open(__A ,"wb" ) as f: UpperCAmelCase_ : str = pq.ParquetWriter(__A ,schema=__A ) UpperCAmelCase_ : List[str] = pa.Table.from_pydict({k: [DATA[i][k] for i in range(len(__A ) )] for k in DATA[0]} ,schema=__A ) writer.write_table(__A ) writer.close() return path @pytest.fixture(scope="session" ) def snake_case ( A__ ): UpperCAmelCase_ : List[str] = str(tmp_path_factory.mktemp("data" ) / "dataset.json" ) UpperCAmelCase_ : str = {"data": DATA} with open(__A ,"w" ) as f: json.dump(__A ,__A ) return path @pytest.fixture(scope="session" ) def snake_case ( A__ ): UpperCAmelCase_ : Optional[Any] = str(tmp_path_factory.mktemp("data" ) / "dataset.json" ) UpperCAmelCase_ : Dict = {"data": DATA_DICT_OF_LISTS} with open(__A ,"w" ) as f: json.dump(__A ,__A ) return path @pytest.fixture(scope="session" ) def snake_case ( A__ ): UpperCAmelCase_ : Optional[Any] = str(tmp_path_factory.mktemp("data" ) / "dataset.jsonl" ) with open(__A ,"w" ) as f: for item in DATA: f.write(json.dumps(__A ) + "\n" ) return path @pytest.fixture(scope="session" ) def snake_case ( A__ ): UpperCAmelCase_ : Optional[int] = str(tmp_path_factory.mktemp("data" ) / "dataset2.jsonl" ) with open(__A ,"w" ) as f: for item in DATA: f.write(json.dumps(__A ) + "\n" ) return path @pytest.fixture(scope="session" ) def snake_case ( A__ ): UpperCAmelCase_ : Any = str(tmp_path_factory.mktemp("data" ) / "dataset_312.jsonl" ) with open(__A ,"w" ) as f: for item in DATA_312: f.write(json.dumps(__A ) + "\n" ) return path @pytest.fixture(scope="session" ) def snake_case ( A__ ): UpperCAmelCase_ : Tuple = str(tmp_path_factory.mktemp("data" ) / "dataset-str.jsonl" ) with open(__A ,"w" ) as f: for item in DATA_STR: f.write(json.dumps(__A ) + "\n" ) return path @pytest.fixture(scope="session" ) def snake_case ( A__ ,A__ ): import gzip UpperCAmelCase_ : List[str] = str(tmp_path_factory.mktemp("data" ) / "dataset.txt.gz" ) with open(__A ,"rb" ) as orig_file: with gzip.open(__A ,"wb" ) as zipped_file: zipped_file.writelines(__A ) return path @pytest.fixture(scope="session" ) def snake_case ( A__ ,A__ ): import gzip UpperCAmelCase_ : List[Any] = str(tmp_path_factory.mktemp("data" ) / "dataset.jsonl.gz" ) with open(__A ,"rb" ) as orig_file: with gzip.open(__A ,"wb" ) as zipped_file: zipped_file.writelines(__A ) return path @pytest.fixture(scope="session" ) def snake_case ( A__ ,A__ ,A__ ): UpperCAmelCase_ : str = tmp_path_factory.mktemp("data" ) / "dataset.jsonl.zip" with zipfile.ZipFile(__A ,"w" ) as f: f.write(__A ,arcname=os.path.basename(__A ) ) f.write(__A ,arcname=os.path.basename(__A ) ) return path @pytest.fixture(scope="session" ) def snake_case ( A__ ,A__ ,A__ ,A__ ): UpperCAmelCase_ : List[Any] = tmp_path_factory.mktemp("data" ) / "dataset_nested.jsonl.zip" with zipfile.ZipFile(__A ,"w" ) as f: f.write(__A ,arcname=os.path.join("nested" ,os.path.basename(__A ) ) ) return path @pytest.fixture(scope="session" ) def snake_case ( A__ ,A__ ,A__ ): UpperCAmelCase_ : Tuple = tmp_path_factory.mktemp("data" ) / "dataset_with_dir.jsonl.zip" with zipfile.ZipFile(__A ,"w" ) as f: f.write(__A ,arcname=os.path.join("main_dir" ,os.path.basename(__A ) ) ) f.write(__A ,arcname=os.path.join("main_dir" ,os.path.basename(__A ) ) ) return path @pytest.fixture(scope="session" ) def snake_case ( A__ ,A__ ,A__ ): UpperCAmelCase_ : Optional[Any] = tmp_path_factory.mktemp("data" ) / "dataset.jsonl.tar" with tarfile.TarFile(__A ,"w" ) as f: f.add(__A ,arcname=os.path.basename(__A ) ) f.add(__A ,arcname=os.path.basename(__A ) ) return path @pytest.fixture(scope="session" ) def snake_case ( A__ ,A__ ,A__ ,A__ ): UpperCAmelCase_ : Union[str, Any] = tmp_path_factory.mktemp("data" ) / "dataset_nested.jsonl.tar" with tarfile.TarFile(__A ,"w" ) as f: f.add(__A ,arcname=os.path.join("nested" ,os.path.basename(__A ) ) ) return path @pytest.fixture(scope="session" ) def snake_case ( A__ ): UpperCAmelCase_ : Tuple = ["0", "1", "2", "3"] UpperCAmelCase_ : str = str(tmp_path_factory.mktemp("data" ) / "dataset.txt" ) with open(__A ,"w" ) as f: for item in data: f.write(item + "\n" ) return path @pytest.fixture(scope="session" ) def snake_case ( A__ ): UpperCAmelCase_ : Optional[Any] = ["0", "1", "2", "3"] UpperCAmelCase_ : str = str(tmp_path_factory.mktemp("data" ) / "dataset2.txt" ) with open(__A ,"w" ) as f: for item in data: f.write(item + "\n" ) return path @pytest.fixture(scope="session" ) def snake_case ( A__ ): UpperCAmelCase_ : Dict = ["0", "1", "2", "3"] UpperCAmelCase_ : List[Any] = tmp_path_factory.mktemp("data" ) / "dataset.abc" with open(__A ,"w" ) as f: for item in data: f.write(item + "\n" ) return path @pytest.fixture(scope="session" ) def snake_case ( A__ ,A__ ,A__ ): UpperCAmelCase_ : Tuple = tmp_path_factory.mktemp("data" ) / "dataset.text.zip" with zipfile.ZipFile(__A ,"w" ) as f: f.write(__A ,arcname=os.path.basename(__A ) ) f.write(__A ,arcname=os.path.basename(__A ) ) return path @pytest.fixture(scope="session" ) def snake_case ( A__ ,A__ ,A__ ): UpperCAmelCase_ : Tuple = tmp_path_factory.mktemp("data" ) / "dataset_with_dir.text.zip" with zipfile.ZipFile(__A ,"w" ) as f: f.write(__A ,arcname=os.path.join("main_dir" ,os.path.basename(__A ) ) ) f.write(__A ,arcname=os.path.join("main_dir" ,os.path.basename(__A ) ) ) return path @pytest.fixture(scope="session" ) def snake_case ( A__ ,A__ ,A__ ): UpperCAmelCase_ : List[Any] = tmp_path_factory.mktemp("data" ) / "dataset.ext.zip" with zipfile.ZipFile(__A ,"w" ) as f: f.write(__A ,arcname=os.path.basename("unsupported.ext" ) ) f.write(__A ,arcname=os.path.basename("unsupported_2.ext" ) ) return path @pytest.fixture(scope="session" ) def snake_case ( A__ ): UpperCAmelCase_ : List[Any] = "\n".join(["First", "Second\u2029with Unicode new line", "Third"] ) UpperCAmelCase_ : Optional[int] = str(tmp_path_factory.mktemp("data" ) / "dataset_with_unicode_new_lines.txt" ) with open(__A ,"w" ,encoding="utf-8" ) as f: f.write(__A ) return path @pytest.fixture(scope="session" ) def snake_case ( ): return os.path.join("tests" ,"features" ,"data" ,"test_image_rgb.jpg" ) @pytest.fixture(scope="session" ) def snake_case ( ): return os.path.join("tests" ,"features" ,"data" ,"test_audio_44100.wav" ) @pytest.fixture(scope="session" ) def snake_case ( A__ ,A__ ): UpperCAmelCase_ : Any = tmp_path_factory.mktemp("data" ) / "dataset.img.zip" with zipfile.ZipFile(__A ,"w" ) as f: f.write(__A ,arcname=os.path.basename(__A ) ) f.write(__A ,arcname=os.path.basename(__A ).replace(".jpg" ,"2.jpg" ) ) return path @pytest.fixture(scope="session" ) def snake_case ( A__ ): UpperCAmelCase_ : Union[str, Any] = tmp_path_factory.mktemp("data_dir" ) (data_dir / "subdir").mkdir() with open(data_dir / "subdir" / "train.txt" ,"w" ) as f: f.write("foo\n" * 10 ) with open(data_dir / "subdir" / "test.txt" ,"w" ) as f: f.write("bar\n" * 10 ) # hidden file with open(data_dir / "subdir" / ".test.txt" ,"w" ) as f: f.write("bar\n" * 10 ) # hidden directory (data_dir / ".subdir").mkdir() with open(data_dir / ".subdir" / "train.txt" ,"w" ) as f: f.write("foo\n" * 10 ) with open(data_dir / ".subdir" / "test.txt" ,"w" ) as f: f.write("bar\n" * 10 ) return data_dir
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import json import os import subprocess import unittest from ast import literal_eval import pytest from parameterized import parameterized_class from . import is_sagemaker_available if is_sagemaker_available(): from sagemaker import Session, TrainingJobAnalytics from sagemaker.huggingface import HuggingFace @pytest.mark.skipif( literal_eval(os.getenv('TEST_SAGEMAKER' , 'False' ) ) is not True , reason='Skipping test because should only be run when releasing minor transformers version' , ) @pytest.mark.usefixtures('sm_env' ) @parameterized_class( [ { 'framework': 'pytorch', 'script': 'run_glue.py', 'model_name_or_path': 'distilbert-base-cased', 'instance_type': 'ml.g4dn.xlarge', 'results': {'train_runtime': 6_50, 'eval_accuracy': 0.6, 'eval_loss': 0.9}, }, { 'framework': 'tensorflow', 'script': 'run_tf.py', 'model_name_or_path': 'distilbert-base-cased', 'instance_type': 'ml.g4dn.xlarge', 'results': {'train_runtime': 6_00, 'eval_accuracy': 0.3, 'eval_loss': 0.9}, }, ] ) class A ( unittest.TestCase ): def lowercase_ (self : int ) -> Optional[Any]: """simple docstring""" if self.framework == "pytorch": subprocess.run( f"""cp ./examples/pytorch/text-classification/run_glue.py {self.env.test_path}/run_glue.py""".split() , encoding="utf-8" , check=__UpperCAmelCase , ) assert hasattr(self , "env" ) def lowercase_ (self : List[Any] , __UpperCAmelCase : Optional[int]=1 ) -> Dict: """simple docstring""" return HuggingFace( entry_point=self.script , source_dir=self.env.test_path , role=self.env.role , image_uri=self.env.image_uri , base_job_name=f"""{self.env.base_job_name}-single""" , instance_count=__UpperCAmelCase , instance_type=self.instance_type , debugger_hook_config=__UpperCAmelCase , hyperparameters={**self.env.hyperparameters, "model_name_or_path": self.model_name_or_path} , metric_definitions=self.env.metric_definitions , py_version="py36" , ) def lowercase_ (self : Optional[Any] , __UpperCAmelCase : Tuple ) -> Optional[int]: """simple docstring""" TrainingJobAnalytics(__UpperCAmelCase ).export_csv(f"""{self.env.test_path}/{job_name}_metrics.csv""" ) def lowercase_ (self : Any ) -> Optional[Any]: """simple docstring""" UpperCAmelCase__ = self.create_estimator() # run training estimator.fit() # result dataframe UpperCAmelCase__ = TrainingJobAnalytics(estimator.latest_training_job.name ).dataframe() # extract kpis UpperCAmelCase__ = list(result_metrics_df[result_metrics_df.metric_name == "eval_accuracy"]["value"] ) UpperCAmelCase__ = list(result_metrics_df[result_metrics_df.metric_name == "eval_loss"]["value"] ) # get train time from SageMaker job, this includes starting, preprocessing, stopping UpperCAmelCase__ = ( Session().describe_training_job(estimator.latest_training_job.name ).get("TrainingTimeInSeconds" , 9_9_9_9_9_9 ) ) # assert kpis assert train_runtime <= self.results["train_runtime"] assert all(t >= self.results["eval_accuracy"] for t in eval_accuracy ) assert all(t <= self.results["eval_loss"] for t in eval_loss ) # dump tests result into json file to share in PR with open(f"""{estimator.latest_training_job.name}.json""" , "w" ) as outfile: json.dump({"train_time": train_runtime, "eval_accuracy": eval_accuracy, "eval_loss": eval_loss} , __UpperCAmelCase )
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"""simple docstring""" from ...configuration_utils import PretrainedConfig from ...utils import logging from ...utils.backbone_utils import BackboneConfigMixin, get_aligned_output_features_output_indices lowerCAmelCase__ = logging.get_logger(__name__) lowerCAmelCase__ = { '''shi-labs/nat-mini-in1k-224''': '''https://huggingface.co/shi-labs/nat-mini-in1k-224/resolve/main/config.json''', # See all Nat models at https://huggingface.co/models?filter=nat } class _lowerCamelCase ( UpperCAmelCase_ , UpperCAmelCase_ ): UpperCAmelCase_ = 'nat' UpperCAmelCase_ = { 'num_attention_heads': 'num_heads', 'num_hidden_layers': 'num_layers', } def __init__(self , __a=4 , __a=3 , __a=64 , __a=[3, 4, 6, 5] , __a=[2, 4, 8, 16] , __a=7 , __a=3.0 , __a=True , __a=0.0 , __a=0.0 , __a=0.1 , __a="gelu" , __a=0.02 , __a=1e-5 , __a=0.0 , __a=None , __a=None , **__a , ) -> Union[str, Any]: super().__init__(**__UpperCAmelCase ) UpperCamelCase = patch_size UpperCamelCase = num_channels UpperCamelCase = embed_dim UpperCamelCase = depths UpperCamelCase = len(__UpperCAmelCase ) UpperCamelCase = num_heads UpperCamelCase = kernel_size UpperCamelCase = mlp_ratio UpperCamelCase = qkv_bias UpperCamelCase = hidden_dropout_prob UpperCamelCase = attention_probs_dropout_prob UpperCamelCase = drop_path_rate UpperCamelCase = hidden_act UpperCamelCase = layer_norm_eps UpperCamelCase = initializer_range # we set the hidden_size attribute in order to make Nat work with VisionEncoderDecoderModel # this indicates the channel dimension after the last stage of the model UpperCamelCase = int(embed_dim * 2 ** (len(__UpperCAmelCase ) - 1) ) UpperCamelCase = layer_scale_init_value UpperCamelCase = ["stem"] + [F"stage{idx}" for idx in range(1 , len(__UpperCAmelCase ) + 1 )] UpperCamelCase , UpperCamelCase = get_aligned_output_features_output_indices( out_features=__UpperCAmelCase , out_indices=__UpperCAmelCase , stage_names=self.stage_names )
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import math import random def lowerCAmelCase_ ( __A, __A = False ) -> float: '''simple docstring''' if deriv: return value * (1 - value) return 1 / (1 + math.exp(-value )) # Initial Value UpperCamelCase__ = 0.0_2 def lowerCAmelCase_ ( __A, __A ) -> float: '''simple docstring''' UpperCAmelCase__ = float(2 * (random.randint(1, 100 )) - 1 ) for _ in range(__A ): # Forward propagation UpperCAmelCase__ = sigmoid_function(INITIAL_VALUE * weight ) # How much did we miss? UpperCAmelCase__ = (expected / 100) - layer_a # Error delta UpperCAmelCase__ = layer_1_error * sigmoid_function(__A, __A ) # Update weight weight += INITIAL_VALUE * layer_1_delta return layer_a * 100 if __name__ == "__main__": import doctest doctest.testmod() UpperCamelCase__ = int(input('Expected value: ')) UpperCamelCase__ = int(input('Number of propagations: ')) print(forward_propagation(expected, number_propagations))
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def lowercase_ (A : Any , A : Dict ): if len(__A ) != len(__A ): raise ValueError('String lengths must match!' ) snake_case__ : List[str] = 0 for chara, chara in zip(__A , __A ): if chara != chara: count += 1 return count if __name__ == "__main__": import doctest doctest.testmod()
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from __future__ import annotations class A : def __init__(self : Union[str, Any] , __UpperCAmelCase : list[list[int]] ) -> List[str]: """simple docstring""" UpperCAmelCase__ = TypeError( "Matrices must be formed from a list of zero or more lists containing at " "least one and the same number of values, each of which must be of type " "int or float." ) if len(__UpperCAmelCase ) != 0: UpperCAmelCase__ = len(rows[0] ) if cols == 0: raise error for row in rows: if len(__UpperCAmelCase ) != cols: raise error for value in row: if not isinstance(__UpperCAmelCase , (int, float) ): raise error UpperCAmelCase__ = rows else: UpperCAmelCase__ = [] def lowercase_ (self : Any ) -> list[list[int]]: """simple docstring""" return [[row[i] for row in self.rows] for i in range(len(self.rows[0] ) )] @property def lowercase_ (self : Any ) -> int: """simple docstring""" return len(self.rows ) @property def lowercase_ (self : Union[str, Any] ) -> int: """simple docstring""" return len(self.rows[0] ) @property def lowercase_ (self : List[Any] ) -> tuple[int, int]: """simple docstring""" return (self.num_rows, self.num_columns) @property def lowercase_ (self : Tuple ) -> bool: """simple docstring""" return self.order[0] == self.order[1] def lowercase_ (self : Any ) -> Matrix: """simple docstring""" UpperCAmelCase__ = [ [0 if column_num != row_num else 1 for column_num in range(self.num_rows )] for row_num in range(self.num_rows ) ] return Matrix(__UpperCAmelCase ) def lowercase_ (self : int ) -> int: """simple docstring""" if not self.is_square: return 0 if self.order == (0, 0): return 1 if self.order == (1, 1): return int(self.rows[0][0] ) if self.order == (2, 2): return int( (self.rows[0][0] * self.rows[1][1]) - (self.rows[0][1] * self.rows[1][0]) ) else: return sum( self.rows[0][column] * self.cofactors().rows[0][column] for column in range(self.num_columns ) ) def lowercase_ (self : Tuple ) -> bool: """simple docstring""" return bool(self.determinant() ) def lowercase_ (self : Dict , __UpperCAmelCase : int , __UpperCAmelCase : int ) -> int: """simple docstring""" UpperCAmelCase__ = [ [ self.rows[other_row][other_column] for other_column in range(self.num_columns ) if other_column != column ] for other_row in range(self.num_rows ) if other_row != row ] return Matrix(__UpperCAmelCase ).determinant() def lowercase_ (self : int , __UpperCAmelCase : int , __UpperCAmelCase : int ) -> int: """simple docstring""" if (row + column) % 2 == 0: return self.get_minor(__UpperCAmelCase , __UpperCAmelCase ) return -1 * self.get_minor(__UpperCAmelCase , __UpperCAmelCase ) def lowercase_ (self : Union[str, Any] ) -> Matrix: """simple docstring""" return Matrix( [ [self.get_minor(__UpperCAmelCase , __UpperCAmelCase ) for column in range(self.num_columns )] for row in range(self.num_rows ) ] ) def lowercase_ (self : List[str] ) -> Matrix: """simple docstring""" return Matrix( [ [ self.minors().rows[row][column] if (row + column) % 2 == 0 else self.minors().rows[row][column] * -1 for column in range(self.minors().num_columns ) ] for row in range(self.minors().num_rows ) ] ) def lowercase_ (self : Optional[Any] ) -> Matrix: """simple docstring""" UpperCAmelCase__ = [ [self.cofactors().rows[column][row] for column in range(self.num_columns )] for row in range(self.num_rows ) ] return Matrix(__UpperCAmelCase ) def lowercase_ (self : List[Any] ) -> Matrix: """simple docstring""" UpperCAmelCase__ = self.determinant() if not determinant: raise TypeError("Only matrices with a non-zero determinant have an inverse" ) return self.adjugate() * (1 / determinant) def __repr__(self : Dict ) -> str: """simple docstring""" return str(self.rows ) def __str__(self : Optional[Any] ) -> str: """simple docstring""" if self.num_rows == 0: return "[]" if self.num_rows == 1: return "[[" + ". ".join(str(self.rows[0] ) ) + "]]" return ( "[" + "\n ".join( [ "[" + ". ".join([str(__UpperCAmelCase ) for value in row] ) + ".]" for row in self.rows ] ) + "]" ) def lowercase_ (self : Optional[int] , __UpperCAmelCase : list[int] , __UpperCAmelCase : int | None = None ) -> None: """simple docstring""" UpperCAmelCase__ = TypeError("Row must be a list containing all ints and/or floats" ) if not isinstance(__UpperCAmelCase , __UpperCAmelCase ): raise type_error for value in row: if not isinstance(__UpperCAmelCase , (int, float) ): raise type_error if len(__UpperCAmelCase ) != self.num_columns: raise ValueError( "Row must be equal in length to the other rows in the matrix" ) if position is None: self.rows.append(__UpperCAmelCase ) else: UpperCAmelCase__ = self.rows[0:position] + [row] + self.rows[position:] def lowercase_ (self : Union[str, Any] , __UpperCAmelCase : list[int] , __UpperCAmelCase : int | None = None ) -> None: """simple docstring""" UpperCAmelCase__ = TypeError( "Column must be a list containing all ints and/or floats" ) if not isinstance(__UpperCAmelCase , __UpperCAmelCase ): raise type_error for value in column: if not isinstance(__UpperCAmelCase , (int, float) ): raise type_error if len(__UpperCAmelCase ) != self.num_rows: raise ValueError( "Column must be equal in length to the other columns in the matrix" ) if position is None: UpperCAmelCase__ = [self.rows[i] + [column[i]] for i in range(self.num_rows )] else: UpperCAmelCase__ = [ self.rows[i][0:position] + [column[i]] + self.rows[i][position:] for i in range(self.num_rows ) ] def __eq__(self : Any , __UpperCAmelCase : object ) -> bool: """simple docstring""" if not isinstance(__UpperCAmelCase , __UpperCAmelCase ): return NotImplemented return self.rows == other.rows def __ne__(self : int , __UpperCAmelCase : object ) -> bool: """simple docstring""" return not self == other def __neg__(self : Dict ) -> Matrix: """simple docstring""" return self * -1 def __add__(self : Dict , __UpperCAmelCase : Matrix ) -> Matrix: """simple docstring""" if self.order != other.order: raise ValueError("Addition requires matrices of the same order" ) return Matrix( [ [self.rows[i][j] + other.rows[i][j] for j in range(self.num_columns )] for i in range(self.num_rows ) ] ) def __sub__(self : Optional[Any] , __UpperCAmelCase : Matrix ) -> Matrix: """simple docstring""" if self.order != other.order: raise ValueError("Subtraction requires matrices of the same order" ) return Matrix( [ [self.rows[i][j] - other.rows[i][j] for j in range(self.num_columns )] for i in range(self.num_rows ) ] ) def __mul__(self : Tuple , __UpperCAmelCase : Matrix | int | float ) -> Matrix: """simple docstring""" if isinstance(__UpperCAmelCase , (int, float) ): return Matrix( [[int(element * other ) for element in row] for row in self.rows] ) elif isinstance(__UpperCAmelCase , __UpperCAmelCase ): if self.num_columns != other.num_rows: raise ValueError( "The number of columns in the first matrix must " "be equal to the number of rows in the second" ) return Matrix( [ [Matrix.dot_product(__UpperCAmelCase , __UpperCAmelCase ) for column in other.columns()] for row in self.rows ] ) else: raise TypeError( "A Matrix can only be multiplied by an int, float, or another matrix" ) def __pow__(self : List[Any] , __UpperCAmelCase : int ) -> Matrix: """simple docstring""" if not isinstance(__UpperCAmelCase , __UpperCAmelCase ): raise TypeError("A Matrix can only be raised to the power of an int" ) if not self.is_square: raise ValueError("Only square matrices can be raised to a power" ) if other == 0: return self.identity() if other < 0: if self.is_invertable(): return self.inverse() ** (-other) raise ValueError( "Only invertable matrices can be raised to a negative power" ) UpperCAmelCase__ = self for _ in range(other - 1 ): result *= self return result @classmethod def lowercase_ (cls : Dict , __UpperCAmelCase : list[int] , __UpperCAmelCase : list[int] ) -> int: """simple docstring""" return sum(row[i] * column[i] for i in range(len(__UpperCAmelCase ) ) ) if __name__ == "__main__": import doctest doctest.testmod()
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from typing import List from ...configuration_utils import PretrainedConfig from ...utils import logging lowerCAmelCase__ : Union[str, Any] =logging.get_logger(__name__) lowerCAmelCase__ : str ={ '''snap-research/efficientformer-l1-300''': ( '''https://huggingface.co/snap-research/efficientformer-l1-300/resolve/main/config.json''' ), } class UpperCAmelCase_ ( UpperCAmelCase_ ): '''simple docstring''' UpperCamelCase__ : Tuple = 'efficientformer' def __init__( self , _A = [3, 2, 6, 4] , _A = [48, 96, 224, 448] , _A = [True, True, True, True] , _A = 448 , _A = 32 , _A = 4 , _A = 7 , _A = 5 , _A = 8 , _A = 4 , _A = 0.0 , _A = 16 , _A = 3 , _A = 3 , _A = 3 , _A = 2 , _A = 1 , _A = 0.0 , _A = 1 , _A = True , _A = True , _A = 1e-5 , _A = "gelu" , _A = 0.0_2 , _A = 1e-12 , _A = 224 , _A = 1e-05 , **_A , ): '''simple docstring''' super().__init__(**__UpperCAmelCase ) __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 json import os from typing import Dict, List, Optional, Tuple from ...tokenization_utils import PreTrainedTokenizer from ...utils import logging UpperCamelCase__ = logging.get_logger(__name__) UpperCamelCase__ = { 'vocab_file': 'vocab.json', 'tokenizer_config_file': 'tokenizer_config.json', 'merges_file': 'merges.txt', } UpperCamelCase__ = { 'vocab_file': { 'facebook/s2t-wav2vec2-large-en-de': ( 'https://huggingface.co/facebook/s2t-wav2vec2-large-en-de/resolve/main/vocab.json' ), }, 'tokenizer_config_file': { 'facebook/s2t-wav2vec2-large-en-de': ( 'https://huggingface.co/facebook/s2t-wav2vec2-large-en-de/resolve/main/tokenizer_config.json' ), }, 'merges_file': { 'facebook/s2t-wav2vec2-large-en-de': ( 'https://huggingface.co/facebook/s2t-wav2vec2-large-en-de/resolve/main/merges.txt' ), }, } UpperCamelCase__ = '</w>' UpperCamelCase__ = '@@ ' def lowerCAmelCase_ ( __A ) -> str: '''simple docstring''' UpperCAmelCase__ = set() UpperCAmelCase__ = word[0] for char in word[1:]: pairs.add((prev_char, char) ) UpperCAmelCase__ = char return pairs # Speech2Text2 has no max input length UpperCamelCase__ = {'facebook/s2t-wav2vec2-large-en-de': 1_0_2_4} class A ( UpperCAmelCase_ ): __UpperCAmelCase : str = VOCAB_FILES_NAMES __UpperCAmelCase : str = PRETRAINED_VOCAB_FILES_MAP __UpperCAmelCase : Union[str, Any] = PRETRAINED_POSITIONAL_EMBEDDINGS_SIZES __UpperCAmelCase : Dict = ['input_ids', 'attention_mask'] def __init__(self : Tuple , __UpperCAmelCase : List[Any] , __UpperCAmelCase : Dict="<s>" , __UpperCAmelCase : Tuple="<pad>" , __UpperCAmelCase : str="</s>" , __UpperCAmelCase : int="<unk>" , __UpperCAmelCase : List[str]=False , __UpperCAmelCase : str=None , **__UpperCAmelCase : Optional[Any] , ) -> Tuple: """simple docstring""" super().__init__( unk_token=__UpperCAmelCase , bos_token=__UpperCAmelCase , eos_token=__UpperCAmelCase , pad_token=__UpperCAmelCase , do_lower_case=__UpperCAmelCase , **__UpperCAmelCase , ) UpperCAmelCase__ = do_lower_case with open(__UpperCAmelCase , encoding="utf-8" ) as vocab_handle: UpperCAmelCase__ = json.load(__UpperCAmelCase ) UpperCAmelCase__ = {v: k for k, v in self.encoder.items()} if merges_file is None: logger.info(f"""No merges files provided. {self.__class__.__name__} can only be used for decoding.""" ) UpperCAmelCase__ = None UpperCAmelCase__ = None else: with open(__UpperCAmelCase , encoding="utf-8" ) as merges_handle: UpperCAmelCase__ = merges_handle.read().split("\n" )[:-1] UpperCAmelCase__ = [tuple(merge.split()[:2] ) for merge in merges] UpperCAmelCase__ = dict(zip(__UpperCAmelCase , range(len(__UpperCAmelCase ) ) ) ) UpperCAmelCase__ = {} @property def lowercase_ (self : List[str] ) -> int: """simple docstring""" return len(self.decoder ) def lowercase_ (self : Union[str, Any] ) -> Dict: """simple docstring""" return dict(self.encoder , **self.added_tokens_encoder ) def lowercase_ (self : Dict , __UpperCAmelCase : Union[str, Any] ) -> str: """simple docstring""" UpperCAmelCase__ = tuple(token[:-1] ) + (token[-1] + BPE_TOKEN_MERGES,) if token in self.cache: return self.cache[token] UpperCAmelCase__ = get_pairs(__UpperCAmelCase ) if not pairs: return token while True: UpperCAmelCase__ = min(__UpperCAmelCase , key=lambda __UpperCAmelCase : self.bpe_ranks.get(__UpperCAmelCase , float("inf" ) ) ) if bigram not in self.bpe_ranks: break UpperCAmelCase__ , UpperCAmelCase__ = bigram UpperCAmelCase__ = [] UpperCAmelCase__ = 0 while i < len(__UpperCAmelCase ): try: UpperCAmelCase__ = word.index(__UpperCAmelCase , __UpperCAmelCase ) except ValueError: new_word.extend(word[i:] ) break else: new_word.extend(word[i:j] ) UpperCAmelCase__ = j if word[i] == first and i < len(__UpperCAmelCase ) - 1 and word[i + 1] == second: new_word.append(first + second ) i += 2 else: new_word.append(word[i] ) i += 1 UpperCAmelCase__ = tuple(__UpperCAmelCase ) UpperCAmelCase__ = new_word if len(__UpperCAmelCase ) == 1: break else: UpperCAmelCase__ = get_pairs(__UpperCAmelCase ) UpperCAmelCase__ = " ".join(__UpperCAmelCase ) if word == "\n " + BPE_TOKEN_MERGES: UpperCAmelCase__ = "\n" + BPE_TOKEN_MERGES if word.endswith(__UpperCAmelCase ): UpperCAmelCase__ = word.replace(__UpperCAmelCase , "" ) UpperCAmelCase__ = word.replace(" " , __UpperCAmelCase ) UpperCAmelCase__ = word return word def lowercase_ (self : Tuple , __UpperCAmelCase : int ) -> Optional[int]: """simple docstring""" if self.bpe_ranks is None: raise ValueError( "This tokenizer was instantiated without a `merges.txt` file, so" " that it can only be used for decoding, not for encoding." "Make sure to provide `merges.txt` file at instantiation to enable " "encoding." ) if self.do_lower_case: UpperCAmelCase__ = text.lower() UpperCAmelCase__ = text.split() UpperCAmelCase__ = [] for token in text: if token: split_tokens.extend(list(self.bpe(__UpperCAmelCase ).split(" " ) ) ) return split_tokens def lowercase_ (self : Union[str, Any] , __UpperCAmelCase : str ) -> int: """simple docstring""" return self.encoder.get(__UpperCAmelCase , self.encoder.get(self.unk_token ) ) def lowercase_ (self : Any , __UpperCAmelCase : int ) -> str: """simple docstring""" UpperCAmelCase__ = self.decoder.get(__UpperCAmelCase , self.unk_token ) return result def lowercase_ (self : Dict , __UpperCAmelCase : List[str] ) -> str: """simple docstring""" UpperCAmelCase__ = " ".join(__UpperCAmelCase ) # make sure @@ tokens are concatenated UpperCAmelCase__ = "".join(string.split(__UpperCAmelCase ) ) return string def lowercase_ (self : Union[str, Any] , __UpperCAmelCase : str , __UpperCAmelCase : Optional[str] = None ) -> Tuple[str]: """simple docstring""" if not os.path.isdir(__UpperCAmelCase ): logger.error(f"""Vocabulary path ({save_directory}) should be a directory""" ) return UpperCAmelCase__ = os.path.join( __UpperCAmelCase , (filename_prefix + "-" if filename_prefix else "") + VOCAB_FILES_NAMES["vocab_file"] ) UpperCAmelCase__ = os.path.join( __UpperCAmelCase , (filename_prefix + "-" if filename_prefix else "") + VOCAB_FILES_NAMES["merges_file"] ) with open(__UpperCAmelCase , "w" , encoding="utf-8" ) as f: f.write(json.dumps(self.encoder , indent=2 , sort_keys=__UpperCAmelCase , ensure_ascii=__UpperCAmelCase ) + "\n" ) UpperCAmelCase__ = 0 if self.bpe_ranks is None: return (vocab_file,) with open(__UpperCAmelCase , "w" , encoding="utf-8" ) as writer: for bpe_tokens, token_index in sorted(self.bpe_ranks.items() , key=lambda __UpperCAmelCase : kv[1] ): if index != token_index: logger.warning( f"""Saving vocabulary to {merges_file}: BPE merge indices are not consecutive.""" " Please check that the tokenizer is not corrupted!" ) UpperCAmelCase__ = token_index writer.write(" ".join(__UpperCAmelCase ) + "\n" ) index += 1 return (vocab_file, merges_file)
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"""simple docstring""" import warnings from diffusers import StableDiffusionImgaImgPipeline # noqa F401 warnings.warn( """The `image_to_image.py` script is outdated. Please use directly `from diffusers import""" """ StableDiffusionImg2ImgPipeline` instead.""" )
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from dataclasses import dataclass from typing import Optional import numpy as np import torch import torch.nn as nn from ..utils import BaseOutput, is_torch_version, randn_tensor from .attention_processor import SpatialNorm from .unet_ad_blocks import UNetMidBlockaD, get_down_block, get_up_block @dataclass class A ( UpperCAmelCase_ ): __UpperCAmelCase : torch.FloatTensor class A ( nn.Module ): def __init__(self : Union[str, Any] , __UpperCAmelCase : int=3 , __UpperCAmelCase : Dict=3 , __UpperCAmelCase : Optional[Any]=("DownEncoderBlock2D",) , __UpperCAmelCase : int=(6_4,) , __UpperCAmelCase : Union[str, Any]=2 , __UpperCAmelCase : Any=3_2 , __UpperCAmelCase : str="silu" , __UpperCAmelCase : Any=True , ) -> Dict: """simple docstring""" super().__init__() UpperCAmelCase__ = layers_per_block UpperCAmelCase__ = torch.nn.Convad( __UpperCAmelCase , block_out_channels[0] , kernel_size=3 , stride=1 , padding=1 , ) UpperCAmelCase__ = None UpperCAmelCase__ = nn.ModuleList([] ) # down UpperCAmelCase__ = block_out_channels[0] for i, down_block_type in enumerate(__UpperCAmelCase ): UpperCAmelCase__ = output_channel UpperCAmelCase__ = block_out_channels[i] UpperCAmelCase__ = i == len(__UpperCAmelCase ) - 1 UpperCAmelCase__ = get_down_block( __UpperCAmelCase , num_layers=self.layers_per_block , in_channels=__UpperCAmelCase , out_channels=__UpperCAmelCase , add_downsample=not is_final_block , resnet_eps=1E-6 , downsample_padding=0 , resnet_act_fn=__UpperCAmelCase , resnet_groups=__UpperCAmelCase , attention_head_dim=__UpperCAmelCase , temb_channels=__UpperCAmelCase , ) self.down_blocks.append(__UpperCAmelCase ) # mid UpperCAmelCase__ = UNetMidBlockaD( in_channels=block_out_channels[-1] , resnet_eps=1E-6 , resnet_act_fn=__UpperCAmelCase , output_scale_factor=1 , resnet_time_scale_shift="default" , attention_head_dim=block_out_channels[-1] , resnet_groups=__UpperCAmelCase , temb_channels=__UpperCAmelCase , ) # out UpperCAmelCase__ = nn.GroupNorm(num_channels=block_out_channels[-1] , num_groups=__UpperCAmelCase , eps=1E-6 ) UpperCAmelCase__ = nn.SiLU() UpperCAmelCase__ = 2 * out_channels if double_z else out_channels UpperCAmelCase__ = nn.Convad(block_out_channels[-1] , __UpperCAmelCase , 3 , padding=1 ) UpperCAmelCase__ = False def lowercase_ (self : List[Any] , __UpperCAmelCase : int ) -> str: """simple docstring""" UpperCAmelCase__ = x UpperCAmelCase__ = self.conv_in(__UpperCAmelCase ) if self.training and self.gradient_checkpointing: def create_custom_forward(__UpperCAmelCase : int ): def custom_forward(*__UpperCAmelCase : Optional[Any] ): return module(*__UpperCAmelCase ) return custom_forward # down if is_torch_version(">=" , "1.11.0" ): for down_block in self.down_blocks: UpperCAmelCase__ = torch.utils.checkpoint.checkpoint( create_custom_forward(__UpperCAmelCase ) , __UpperCAmelCase , use_reentrant=__UpperCAmelCase ) # middle UpperCAmelCase__ = torch.utils.checkpoint.checkpoint( create_custom_forward(self.mid_block ) , __UpperCAmelCase , use_reentrant=__UpperCAmelCase ) else: for down_block in self.down_blocks: UpperCAmelCase__ = torch.utils.checkpoint.checkpoint(create_custom_forward(__UpperCAmelCase ) , __UpperCAmelCase ) # middle UpperCAmelCase__ = torch.utils.checkpoint.checkpoint(create_custom_forward(self.mid_block ) , __UpperCAmelCase ) else: # down for down_block in self.down_blocks: UpperCAmelCase__ = down_block(__UpperCAmelCase ) # middle UpperCAmelCase__ = self.mid_block(__UpperCAmelCase ) # post-process UpperCAmelCase__ = self.conv_norm_out(__UpperCAmelCase ) UpperCAmelCase__ = self.conv_act(__UpperCAmelCase ) UpperCAmelCase__ = self.conv_out(__UpperCAmelCase ) return sample class A ( nn.Module ): def __init__(self : List[Any] , __UpperCAmelCase : str=3 , __UpperCAmelCase : Union[str, Any]=3 , __UpperCAmelCase : Optional[int]=("UpDecoderBlock2D",) , __UpperCAmelCase : str=(6_4,) , __UpperCAmelCase : Optional[Any]=2 , __UpperCAmelCase : Tuple=3_2 , __UpperCAmelCase : Any="silu" , __UpperCAmelCase : Any="group" , ) -> Dict: """simple docstring""" super().__init__() UpperCAmelCase__ = layers_per_block UpperCAmelCase__ = nn.Convad( __UpperCAmelCase , block_out_channels[-1] , kernel_size=3 , stride=1 , padding=1 , ) UpperCAmelCase__ = None UpperCAmelCase__ = nn.ModuleList([] ) UpperCAmelCase__ = in_channels if norm_type == "spatial" else None # mid UpperCAmelCase__ = UNetMidBlockaD( in_channels=block_out_channels[-1] , resnet_eps=1E-6 , resnet_act_fn=__UpperCAmelCase , output_scale_factor=1 , resnet_time_scale_shift="default" if norm_type == "group" else norm_type , attention_head_dim=block_out_channels[-1] , resnet_groups=__UpperCAmelCase , temb_channels=__UpperCAmelCase , ) # up UpperCAmelCase__ = list(reversed(__UpperCAmelCase ) ) UpperCAmelCase__ = reversed_block_out_channels[0] for i, up_block_type in enumerate(__UpperCAmelCase ): UpperCAmelCase__ = output_channel UpperCAmelCase__ = reversed_block_out_channels[i] UpperCAmelCase__ = i == len(__UpperCAmelCase ) - 1 UpperCAmelCase__ = get_up_block( __UpperCAmelCase , num_layers=self.layers_per_block + 1 , in_channels=__UpperCAmelCase , out_channels=__UpperCAmelCase , prev_output_channel=__UpperCAmelCase , add_upsample=not is_final_block , resnet_eps=1E-6 , resnet_act_fn=__UpperCAmelCase , resnet_groups=__UpperCAmelCase , attention_head_dim=__UpperCAmelCase , temb_channels=__UpperCAmelCase , resnet_time_scale_shift=__UpperCAmelCase , ) self.up_blocks.append(__UpperCAmelCase ) UpperCAmelCase__ = output_channel # out if norm_type == "spatial": UpperCAmelCase__ = SpatialNorm(block_out_channels[0] , __UpperCAmelCase ) else: UpperCAmelCase__ = nn.GroupNorm(num_channels=block_out_channels[0] , num_groups=__UpperCAmelCase , eps=1E-6 ) UpperCAmelCase__ = nn.SiLU() UpperCAmelCase__ = nn.Convad(block_out_channels[0] , __UpperCAmelCase , 3 , padding=1 ) UpperCAmelCase__ = False def lowercase_ (self : Optional[int] , __UpperCAmelCase : Tuple , __UpperCAmelCase : Dict=None ) -> List[Any]: """simple docstring""" UpperCAmelCase__ = z UpperCAmelCase__ = self.conv_in(__UpperCAmelCase ) UpperCAmelCase__ = next(iter(self.up_blocks.parameters() ) ).dtype if self.training and self.gradient_checkpointing: def create_custom_forward(__UpperCAmelCase : str ): def custom_forward(*__UpperCAmelCase : List[str] ): return module(*__UpperCAmelCase ) return custom_forward if is_torch_version(">=" , "1.11.0" ): # middle UpperCAmelCase__ = torch.utils.checkpoint.checkpoint( create_custom_forward(self.mid_block ) , __UpperCAmelCase , __UpperCAmelCase , use_reentrant=__UpperCAmelCase ) UpperCAmelCase__ = sample.to(__UpperCAmelCase ) # up for up_block in self.up_blocks: UpperCAmelCase__ = torch.utils.checkpoint.checkpoint( create_custom_forward(__UpperCAmelCase ) , __UpperCAmelCase , __UpperCAmelCase , use_reentrant=__UpperCAmelCase ) else: # middle UpperCAmelCase__ = torch.utils.checkpoint.checkpoint( create_custom_forward(self.mid_block ) , __UpperCAmelCase , __UpperCAmelCase ) UpperCAmelCase__ = sample.to(__UpperCAmelCase ) # up for up_block in self.up_blocks: UpperCAmelCase__ = torch.utils.checkpoint.checkpoint(create_custom_forward(__UpperCAmelCase ) , __UpperCAmelCase , __UpperCAmelCase ) else: # middle UpperCAmelCase__ = self.mid_block(__UpperCAmelCase , __UpperCAmelCase ) UpperCAmelCase__ = sample.to(__UpperCAmelCase ) # up for up_block in self.up_blocks: UpperCAmelCase__ = up_block(__UpperCAmelCase , __UpperCAmelCase ) # post-process if latent_embeds is None: UpperCAmelCase__ = self.conv_norm_out(__UpperCAmelCase ) else: UpperCAmelCase__ = self.conv_norm_out(__UpperCAmelCase , __UpperCAmelCase ) UpperCAmelCase__ = self.conv_act(__UpperCAmelCase ) UpperCAmelCase__ = self.conv_out(__UpperCAmelCase ) return sample class A ( nn.Module ): def __init__(self : Optional[Any] , __UpperCAmelCase : str , __UpperCAmelCase : List[str] , __UpperCAmelCase : List[str] , __UpperCAmelCase : Dict=None , __UpperCAmelCase : Union[str, Any]="random" , __UpperCAmelCase : Dict=False , __UpperCAmelCase : Union[str, Any]=True ) -> Dict: """simple docstring""" super().__init__() UpperCAmelCase__ = n_e UpperCAmelCase__ = vq_embed_dim UpperCAmelCase__ = beta UpperCAmelCase__ = legacy UpperCAmelCase__ = nn.Embedding(self.n_e , self.vq_embed_dim ) self.embedding.weight.data.uniform_(-1.0 / self.n_e , 1.0 / self.n_e ) UpperCAmelCase__ = remap if self.remap is not None: self.register_buffer("used" , torch.tensor(np.load(self.remap ) ) ) UpperCAmelCase__ = self.used.shape[0] UpperCAmelCase__ = unknown_index # "random" or "extra" or integer if self.unknown_index == "extra": UpperCAmelCase__ = self.re_embed UpperCAmelCase__ = self.re_embed + 1 print( f"""Remapping {self.n_e} indices to {self.re_embed} indices. """ f"""Using {self.unknown_index} for unknown indices.""" ) else: UpperCAmelCase__ = n_e UpperCAmelCase__ = sane_index_shape def lowercase_ (self : str , __UpperCAmelCase : str ) -> List[str]: """simple docstring""" UpperCAmelCase__ = inds.shape assert len(__UpperCAmelCase ) > 1 UpperCAmelCase__ = inds.reshape(ishape[0] , -1 ) UpperCAmelCase__ = self.used.to(__UpperCAmelCase ) UpperCAmelCase__ = (inds[:, :, None] == used[None, None, ...]).long() UpperCAmelCase__ = match.argmax(-1 ) UpperCAmelCase__ = match.sum(2 ) < 1 if self.unknown_index == "random": UpperCAmelCase__ = torch.randint(0 , self.re_embed , size=new[unknown].shape ).to(device=new.device ) else: UpperCAmelCase__ = self.unknown_index return new.reshape(__UpperCAmelCase ) def lowercase_ (self : Tuple , __UpperCAmelCase : Optional[int] ) -> Dict: """simple docstring""" UpperCAmelCase__ = inds.shape assert len(__UpperCAmelCase ) > 1 UpperCAmelCase__ = inds.reshape(ishape[0] , -1 ) UpperCAmelCase__ = self.used.to(__UpperCAmelCase ) if self.re_embed > self.used.shape[0]: # extra token UpperCAmelCase__ = 0 # simply set to zero UpperCAmelCase__ = torch.gather(used[None, :][inds.shape[0] * [0], :] , 1 , __UpperCAmelCase ) return back.reshape(__UpperCAmelCase ) def lowercase_ (self : Optional[Any] , __UpperCAmelCase : Dict ) -> List[str]: """simple docstring""" UpperCAmelCase__ = z.permute(0 , 2 , 3 , 1 ).contiguous() UpperCAmelCase__ = z.view(-1 , self.vq_embed_dim ) # distances from z to embeddings e_j (z - e)^2 = z^2 + e^2 - 2 e * z UpperCAmelCase__ = torch.argmin(torch.cdist(__UpperCAmelCase , self.embedding.weight ) , dim=1 ) UpperCAmelCase__ = self.embedding(__UpperCAmelCase ).view(z.shape ) UpperCAmelCase__ = None UpperCAmelCase__ = None # compute loss for embedding if not self.legacy: UpperCAmelCase__ = self.beta * torch.mean((z_q.detach() - z) ** 2 ) + torch.mean((z_q - z.detach()) ** 2 ) else: UpperCAmelCase__ = torch.mean((z_q.detach() - z) ** 2 ) + self.beta * torch.mean((z_q - z.detach()) ** 2 ) # preserve gradients UpperCAmelCase__ = z + (z_q - z).detach() # reshape back to match original input shape UpperCAmelCase__ = z_q.permute(0 , 3 , 1 , 2 ).contiguous() if self.remap is not None: UpperCAmelCase__ = min_encoding_indices.reshape(z.shape[0] , -1 ) # add batch axis UpperCAmelCase__ = self.remap_to_used(__UpperCAmelCase ) UpperCAmelCase__ = min_encoding_indices.reshape(-1 , 1 ) # flatten if self.sane_index_shape: UpperCAmelCase__ = min_encoding_indices.reshape(z_q.shape[0] , z_q.shape[2] , z_q.shape[3] ) return z_q, loss, (perplexity, min_encodings, min_encoding_indices) def lowercase_ (self : Optional[int] , __UpperCAmelCase : int , __UpperCAmelCase : Optional[Any] ) -> Any: """simple docstring""" if self.remap is not None: UpperCAmelCase__ = indices.reshape(shape[0] , -1 ) # add batch axis UpperCAmelCase__ = self.unmap_to_all(__UpperCAmelCase ) UpperCAmelCase__ = indices.reshape(-1 ) # flatten again # get quantized latent vectors UpperCAmelCase__ = self.embedding(__UpperCAmelCase ) if shape is not None: UpperCAmelCase__ = z_q.view(__UpperCAmelCase ) # reshape back to match original input shape UpperCAmelCase__ = z_q.permute(0 , 3 , 1 , 2 ).contiguous() return z_q class A ( UpperCAmelCase_ ): def __init__(self : Any , __UpperCAmelCase : Dict , __UpperCAmelCase : str=False ) -> Tuple: """simple docstring""" UpperCAmelCase__ = parameters UpperCAmelCase__ , UpperCAmelCase__ = torch.chunk(__UpperCAmelCase , 2 , dim=1 ) UpperCAmelCase__ = torch.clamp(self.logvar , -30.0 , 20.0 ) UpperCAmelCase__ = deterministic UpperCAmelCase__ = torch.exp(0.5 * self.logvar ) UpperCAmelCase__ = torch.exp(self.logvar ) if self.deterministic: UpperCAmelCase__ = UpperCAmelCase__ = torch.zeros_like( self.mean , device=self.parameters.device , dtype=self.parameters.dtype ) def lowercase_ (self : Union[str, Any] , __UpperCAmelCase : Optional[torch.Generator] = None ) -> torch.FloatTensor: """simple docstring""" UpperCAmelCase__ = randn_tensor( self.mean.shape , generator=__UpperCAmelCase , device=self.parameters.device , dtype=self.parameters.dtype ) UpperCAmelCase__ = self.mean + self.std * sample return x def lowercase_ (self : str , __UpperCAmelCase : int=None ) -> Any: """simple docstring""" if self.deterministic: return torch.Tensor([0.0] ) else: if other is None: return 0.5 * torch.sum(torch.pow(self.mean , 2 ) + self.var - 1.0 - self.logvar , dim=[1, 2, 3] ) else: return 0.5 * torch.sum( torch.pow(self.mean - other.mean , 2 ) / other.var + self.var / other.var - 1.0 - self.logvar + other.logvar , dim=[1, 2, 3] , ) def lowercase_ (self : Dict , __UpperCAmelCase : Tuple , __UpperCAmelCase : Any=[1, 2, 3] ) -> Dict: """simple docstring""" if self.deterministic: return torch.Tensor([0.0] ) UpperCAmelCase__ = np.log(2.0 * np.pi ) return 0.5 * torch.sum(logtwopi + self.logvar + torch.pow(sample - self.mean , 2 ) / self.var , dim=__UpperCAmelCase ) def lowercase_ (self : Tuple ) -> Optional[Any]: """simple docstring""" return self.mean
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"""simple docstring""" from collections.abc import Generator def __lowercase ( ): snake_case_, snake_case_ : Dict = 0, 1 while True: snake_case_, snake_case_ : Any = b, a + b yield b def __lowercase ( _a = 1_000 ): snake_case_ : Optional[int] = 1 snake_case_ : Optional[int] = fibonacci_generator() while len(str(next(__A ) ) ) < n: answer += 1 return answer + 1 if __name__ == "__main__": print(solution(int(str(input()).strip())))
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import asyncio import os import re import sys import tempfile import unittest from contextlib import contextmanager from copy import deepcopy from distutils.util import strtobool from enum import Enum from importlib.util import find_spec from pathlib import Path from unittest.mock import patch import pyarrow as pa import pytest import requests from packaging import version from datasets import config if config.PY_VERSION < version.parse('3.8'): import importlib_metadata else: import importlib.metadata as importlib_metadata def lowerCAmelCase_ ( __A, __A=False ) -> Any: '''simple docstring''' try: UpperCAmelCase__ = os.environ[key] except KeyError: # KEY isn't set, default to `default`. UpperCAmelCase__ = default else: # KEY is set, convert it to True or False. try: UpperCAmelCase__ = strtobool(__A ) except ValueError: # More values are supported, but let's keep the message simple. raise ValueError(f"""If set, {key} must be yes or no.""" ) return _value UpperCamelCase__ = parse_flag_from_env('RUN_SLOW', default=False) UpperCamelCase__ = parse_flag_from_env('RUN_REMOTE', default=False) UpperCamelCase__ = parse_flag_from_env('RUN_LOCAL', default=True) UpperCamelCase__ = parse_flag_from_env('RUN_PACKAGED', default=True) # Compression UpperCamelCase__ = pytest.mark.skipif(not config.LZ4_AVAILABLE, reason='test requires lz4') UpperCamelCase__ = pytest.mark.skipif(not config.PY7ZR_AVAILABLE, reason='test requires py7zr') UpperCamelCase__ = pytest.mark.skipif(not config.ZSTANDARD_AVAILABLE, reason='test requires zstandard') # Audio UpperCamelCase__ = pytest.mark.skipif( # On Windows and OS X, soundfile installs sndfile find_spec('soundfile') is None or version.parse(importlib_metadata.version('soundfile')) < version.parse('0.12.0'), reason='test requires sndfile>=0.12.1: \'pip install \"soundfile>=0.12.1\"\'; ', ) # Beam UpperCamelCase__ = pytest.mark.skipif( not config.BEAM_AVAILABLE or config.DILL_VERSION >= version.parse('0.3.2'), reason='test requires apache-beam and a compatible dill version', ) # Dill-cloudpickle compatibility UpperCamelCase__ = pytest.mark.skipif( config.DILL_VERSION <= version.parse('0.3.2'), reason='test requires dill>0.3.2 for cloudpickle compatibility', ) # Windows UpperCamelCase__ = pytest.mark.skipif( sys.platform == 'win32', reason='test should not be run on Windows', ) def lowerCAmelCase_ ( __A ) -> Any: '''simple docstring''' try: import faiss # noqa except ImportError: UpperCAmelCase__ = unittest.skip("test requires faiss" )(__A ) return test_case def lowerCAmelCase_ ( __A ) -> Optional[Any]: '''simple docstring''' try: import regex # noqa except ImportError: UpperCAmelCase__ = unittest.skip("test requires regex" )(__A ) return test_case def lowerCAmelCase_ ( __A ) -> List[str]: '''simple docstring''' try: import elasticsearch # noqa except ImportError: UpperCAmelCase__ = unittest.skip("test requires elasticsearch" )(__A ) return test_case def lowerCAmelCase_ ( __A ) -> List[Any]: '''simple docstring''' try: import sqlalchemy # noqa except ImportError: UpperCAmelCase__ = unittest.skip("test requires sqlalchemy" )(__A ) return test_case def lowerCAmelCase_ ( __A ) -> List[str]: '''simple docstring''' if not config.TORCH_AVAILABLE: UpperCAmelCase__ = unittest.skip("test requires PyTorch" )(__A ) return test_case def lowerCAmelCase_ ( __A ) -> Union[str, Any]: '''simple docstring''' if not config.TF_AVAILABLE: UpperCAmelCase__ = unittest.skip("test requires TensorFlow" )(__A ) return test_case def lowerCAmelCase_ ( __A ) -> Any: '''simple docstring''' if not config.JAX_AVAILABLE: UpperCAmelCase__ = unittest.skip("test requires JAX" )(__A ) return test_case def lowerCAmelCase_ ( __A ) -> int: '''simple docstring''' if not config.PIL_AVAILABLE: UpperCAmelCase__ = unittest.skip("test requires Pillow" )(__A ) return test_case def lowerCAmelCase_ ( __A ) -> Tuple: '''simple docstring''' try: import transformers # noqa F401 except ImportError: return unittest.skip("test requires transformers" )(__A ) else: return test_case def lowerCAmelCase_ ( __A ) -> Dict: '''simple docstring''' try: import tiktoken # noqa F401 except ImportError: return unittest.skip("test requires tiktoken" )(__A ) else: return test_case def lowerCAmelCase_ ( __A ) -> Optional[Any]: '''simple docstring''' try: import spacy # noqa F401 except ImportError: return unittest.skip("test requires spacy" )(__A ) else: return test_case def lowerCAmelCase_ ( __A ) -> Optional[int]: '''simple docstring''' def _require_spacy_model(__A ): try: import spacy # noqa F401 spacy.load(__A ) except ImportError: return unittest.skip("test requires spacy" )(__A ) except OSError: return unittest.skip("test requires spacy model '{}'".format(__A ) )(__A ) else: return test_case return _require_spacy_model def lowerCAmelCase_ ( __A ) -> Optional[Any]: '''simple docstring''' try: import pyspark # noqa F401 except ImportError: return unittest.skip("test requires pyspark" )(__A ) else: return test_case def lowerCAmelCase_ ( __A ) -> Tuple: '''simple docstring''' try: import joblibspark # noqa F401 except ImportError: return unittest.skip("test requires joblibspark" )(__A ) else: return test_case def lowerCAmelCase_ ( __A ) -> Optional[int]: '''simple docstring''' if not _run_slow_tests or _run_slow_tests == 0: UpperCAmelCase__ = unittest.skip("test is slow" )(__A ) return test_case def lowerCAmelCase_ ( __A ) -> List[Any]: '''simple docstring''' if not _run_local_tests or _run_local_tests == 0: UpperCAmelCase__ = unittest.skip("test is local" )(__A ) return test_case def lowerCAmelCase_ ( __A ) -> Optional[Any]: '''simple docstring''' if not _run_packaged_tests or _run_packaged_tests == 0: UpperCAmelCase__ = unittest.skip("test is packaged" )(__A ) return test_case def lowerCAmelCase_ ( __A ) -> Any: '''simple docstring''' if not _run_remote_tests or _run_remote_tests == 0: UpperCAmelCase__ = unittest.skip("test requires remote" )(__A ) return test_case def lowerCAmelCase_ ( *__A ) -> Optional[int]: '''simple docstring''' def decorate(cls ): for name, fn in cls.__dict__.items(): if callable(__A ) and name.startswith("test" ): for decorator in decorators: UpperCAmelCase__ = decorator(__A ) setattr(cls, __A, __A ) return cls return decorate class A ( UpperCAmelCase_ ): pass class A ( UpperCAmelCase_ ): __UpperCAmelCase : Union[str, Any] = 0 __UpperCAmelCase : str = 1 __UpperCAmelCase : int = 2 @contextmanager def lowerCAmelCase_ ( __A=OfflineSimulationMode.CONNECTION_FAILS, __A=1e-16 ) -> List[str]: '''simple docstring''' UpperCAmelCase__ = requests.Session().request def timeout_request(__A, __A, __A, **__A ): # Change the url to an invalid url so that the connection hangs UpperCAmelCase__ = "https://10.255.255.1" if kwargs.get("timeout" ) is None: raise RequestWouldHangIndefinitelyError( f"""Tried a call to {url} in offline mode with no timeout set. Please set a timeout.""" ) UpperCAmelCase__ = timeout try: return online_request(__A, __A, **__A ) except Exception as e: # The following changes in the error are just here to make the offline timeout error prettier UpperCAmelCase__ = url UpperCAmelCase__ = e.args[0] UpperCAmelCase__ = (max_retry_error.args[0].replace("10.255.255.1", f"""OfflineMock[{url}]""" ),) UpperCAmelCase__ = (max_retry_error,) raise def raise_connection_error(__A, __A, **__A ): raise requests.ConnectionError("Offline mode is enabled.", request=__A ) if mode is OfflineSimulationMode.CONNECTION_FAILS: with patch("requests.Session.send", __A ): yield elif mode is OfflineSimulationMode.CONNECTION_TIMES_OUT: # inspired from https://stackoverflow.com/a/904609 with patch("requests.Session.request", __A ): yield elif mode is OfflineSimulationMode.HF_DATASETS_OFFLINE_SET_TO_1: with patch("datasets.config.HF_DATASETS_OFFLINE", __A ): yield else: raise ValueError("Please use a value from the OfflineSimulationMode enum." ) @contextmanager def lowerCAmelCase_ ( *__A, **__A ) -> str: '''simple docstring''' UpperCAmelCase__ = str(Path().resolve() ) with tempfile.TemporaryDirectory(*__A, **__A ) as tmp_dir: try: os.chdir(__A ) yield finally: os.chdir(__A ) @contextmanager def lowerCAmelCase_ ( ) -> Optional[Any]: '''simple docstring''' import gc gc.collect() UpperCAmelCase__ = pa.total_allocated_bytes() yield assert pa.total_allocated_bytes() - previous_allocated_memory > 0, "Arrow memory didn't increase." @contextmanager def lowerCAmelCase_ ( ) -> List[str]: '''simple docstring''' import gc gc.collect() UpperCAmelCase__ = pa.total_allocated_bytes() yield assert pa.total_allocated_bytes() - previous_allocated_memory <= 0, "Arrow memory wasn't expected to increase." def lowerCAmelCase_ ( __A, __A ) -> List[str]: '''simple docstring''' return deepcopy(__A ).integers(0, 100, 10 ).tolist() == deepcopy(__A ).integers(0, 100, 10 ).tolist() def lowerCAmelCase_ ( __A ) -> Optional[int]: '''simple docstring''' import decorator from requests.exceptions import HTTPError def _wrapper(__A, *__A, **__A ): try: return func(*__A, **__A ) except HTTPError as err: if str(__A ).startswith("500" ) or str(__A ).startswith("502" ): pytest.xfail(str(__A ) ) raise err return decorator.decorator(_wrapper, __A ) class A : def __init__(self : Optional[Any] , __UpperCAmelCase : int , __UpperCAmelCase : int , __UpperCAmelCase : List[str] ) -> Union[str, Any]: """simple docstring""" UpperCAmelCase__ = returncode UpperCAmelCase__ = stdout UpperCAmelCase__ = stderr async def lowerCAmelCase_ ( __A, __A ) -> Optional[int]: '''simple docstring''' while True: UpperCAmelCase__ = await stream.readline() if line: callback(__A ) else: break async def lowerCAmelCase_ ( __A, __A=None, __A=None, __A=None, __A=False, __A=False ) -> _RunOutput: '''simple docstring''' if echo: print("\nRunning: ", " ".join(__A ) ) UpperCAmelCase__ = await asyncio.create_subprocess_exec( cmd[0], *cmd[1:], stdin=__A, stdout=asyncio.subprocess.PIPE, stderr=asyncio.subprocess.PIPE, env=__A, ) # note: there is a warning for a possible deadlock when using `wait` with huge amounts of data in the pipe # https://docs.python.org/3/library/asyncio-subprocess.html#asyncio.asyncio.subprocess.Process.wait # # If it starts hanging, will need to switch to the following code. The problem is that no data # will be seen until it's done and if it hangs for example there will be no debug info. # out, err = await p.communicate() # return _RunOutput(p.returncode, out, err) UpperCAmelCase__ = [] UpperCAmelCase__ = [] def tee(__A, __A, __A, __A="" ): UpperCAmelCase__ = line.decode("utf-8" ).rstrip() sink.append(__A ) if not quiet: print(__A, __A, file=__A ) # XXX: the timeout doesn't seem to make any difference here await asyncio.wait( [ _read_stream(p.stdout, lambda __A : tee(__A, __A, sys.stdout, label="stdout:" ) ), _read_stream(p.stderr, lambda __A : tee(__A, __A, sys.stderr, label="stderr:" ) ), ], timeout=__A, ) return _RunOutput(await p.wait(), __A, __A ) def lowerCAmelCase_ ( __A, __A=None, __A=None, __A=180, __A=False, __A=True ) -> _RunOutput: '''simple docstring''' UpperCAmelCase__ = asyncio.get_event_loop() UpperCAmelCase__ = loop.run_until_complete( _stream_subprocess(__A, env=__A, stdin=__A, timeout=__A, quiet=__A, echo=__A ) ) UpperCAmelCase__ = " ".join(__A ) if result.returncode > 0: UpperCAmelCase__ = "\n".join(result.stderr ) raise RuntimeError( f"""'{cmd_str}' failed with returncode {result.returncode}\n\n""" f"""The combined stderr from workers follows:\n{stderr}""" ) # check that the subprocess actually did run and produced some output, should the test rely on # the remote side to do the testing if not result.stdout and not result.stderr: raise RuntimeError(f"""'{cmd_str}' produced no output.""" ) return result def lowerCAmelCase_ ( ) -> Tuple: '''simple docstring''' UpperCAmelCase__ = os.environ.get("PYTEST_XDIST_WORKER", "gw0" ) UpperCAmelCase__ = re.sub(r"^gw", "", __A, 0, re.M ) return int(__A ) def lowerCAmelCase_ ( ) -> List[Any]: '''simple docstring''' UpperCAmelCase__ = 29_500 UpperCAmelCase__ = pytest_xdist_worker_id() return port + uniq_delta
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0
from typing import TYPE_CHECKING from ...utils import OptionalDependencyNotAvailable, _LazyModule, is_torch_available _lowerCamelCase : Optional[Any] = { "configuration_jukebox": [ "JUKEBOX_PRETRAINED_CONFIG_ARCHIVE_MAP", "JukeboxConfig", "JukeboxPriorConfig", "JukeboxVQVAEConfig", ], "tokenization_jukebox": ["JukeboxTokenizer"], } try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: _lowerCamelCase : Dict = [ "JUKEBOX_PRETRAINED_MODEL_ARCHIVE_LIST", "JukeboxModel", "JukeboxPreTrainedModel", "JukeboxVQVAE", "JukeboxPrior", ] if TYPE_CHECKING: from .configuration_jukebox import ( JUKEBOX_PRETRAINED_CONFIG_ARCHIVE_MAP, JukeboxConfig, JukeboxPriorConfig, JukeboxVQVAEConfig, ) from .tokenization_jukebox import JukeboxTokenizer try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_jukebox import ( JUKEBOX_PRETRAINED_MODEL_ARCHIVE_LIST, JukeboxModel, JukeboxPreTrainedModel, JukeboxPrior, JukeboxVQVAE, ) else: import sys _lowerCamelCase : Tuple = _LazyModule(__name__, globals()["__file__"], _import_structure, module_spec=__spec__)
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def lowerCAmelCase_ ( __A, __A ) -> float: '''simple docstring''' def get_matched_characters(__A, __A ) -> str: UpperCAmelCase__ = [] UpperCAmelCase__ = min(len(_stra ), len(_stra ) ) // 2 for i, l in enumerate(_stra ): UpperCAmelCase__ = int(max(0, i - limit ) ) UpperCAmelCase__ = int(min(i + limit + 1, len(_stra ) ) ) if l in _stra[left:right]: matched.append(__A ) UpperCAmelCase__ = f"""{_stra[0:_stra.index(__A )]} {_stra[_stra.index(__A ) + 1:]}""" return "".join(__A ) # matching characters UpperCAmelCase__ = get_matched_characters(__A, __A ) UpperCAmelCase__ = get_matched_characters(__A, __A ) UpperCAmelCase__ = len(__A ) # transposition UpperCAmelCase__ = ( len([(ca, ca) for ca, ca in zip(__A, __A ) if ca != ca] ) // 2 ) if not match_count: UpperCAmelCase__ = 0.0 else: UpperCAmelCase__ = ( 1 / 3 * ( match_count / len(__A ) + match_count / len(__A ) + (match_count - transpositions) / match_count ) ) # common prefix up to 4 characters UpperCAmelCase__ = 0 for ca, ca in zip(stra[:4], stra[:4] ): if ca == ca: prefix_len += 1 else: break return jaro + 0.1 * prefix_len * (1 - jaro) if __name__ == "__main__": import doctest doctest.testmod() print(jaro_winkler('hello', 'world'))
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"""simple docstring""" import importlib.util import os import platform from argparse import ArgumentParser import huggingface_hub from .. import __version__ as version from ..utils import ( is_accelerate_available, is_flax_available, is_safetensors_available, is_tf_available, is_torch_available, ) from . import BaseTransformersCLICommand def _lowerCamelCase( a ): return EnvironmentCommand() def _lowerCamelCase( a ): return EnvironmentCommand(args.accelerate_config_file ) class snake_case__ ( UpperCAmelCase_ ): @staticmethod def a__ ( lowerCamelCase ): __a = parser.add_parser("env" ) download_parser.set_defaults(func=__UpperCAmelCase ) download_parser.add_argument( "--accelerate-config_file" , default=__UpperCAmelCase , help="The accelerate config file to use for the default values in the launching script." , ) download_parser.set_defaults(func=__UpperCAmelCase ) def __init__( self , lowerCamelCase , *lowerCamelCase ): __a = accelerate_config_file def a__ ( self ): __a = "not installed" if is_safetensors_available(): import safetensors __a = safetensors.__version__ elif importlib.util.find_spec("safetensors" ) is not None: import safetensors __a = F"{safetensors.__version__} but is ignored because of PyTorch version too old." __a = "not installed" __a = __a = "not found" if is_accelerate_available(): import accelerate from accelerate.commands.config import default_config_file, load_config_from_file __a = accelerate.__version__ # Get the default from the config file. if self._accelerate_config_file is not None or os.path.isfile(__UpperCAmelCase ): __a = load_config_from_file(self._accelerate_config_file ).to_dict() __a = ( "\n".join([F"\t- {prop}: {val}" for prop, val in accelerate_config.items()] ) if isinstance(__UpperCAmelCase , __UpperCAmelCase ) else F"\t{accelerate_config}" ) __a = "not installed" __a = "NA" if is_torch_available(): import torch __a = torch.__version__ __a = torch.cuda.is_available() __a = "not installed" __a = "NA" if is_tf_available(): import tensorflow as tf __a = tf.__version__ try: # deprecated in v2.1 __a = tf.test.is_gpu_available() except AttributeError: # returns list of devices, convert to bool __a = bool(tf.config.list_physical_devices("GPU" ) ) __a = "not installed" __a = "not installed" __a = "not installed" __a = "NA" if is_flax_available(): import flax import jax import jaxlib __a = flax.__version__ __a = jax.__version__ __a = jaxlib.__version__ __a = jax.lib.xla_bridge.get_backend().platform __a = { "`transformers` version": version, "Platform": platform.platform(), "Python version": platform.python_version(), "Huggingface_hub version": huggingface_hub.__version__, "Safetensors version": F"{safetensors_version}", "Accelerate version": F"{accelerate_version}", "Accelerate config": F"{accelerate_config_str}", "PyTorch version (GPU?)": F"{pt_version} ({pt_cuda_available})", "Tensorflow version (GPU?)": F"{tf_version} ({tf_cuda_available})", "Flax version (CPU?/GPU?/TPU?)": F"{flax_version} ({jax_backend})", "Jax version": F"{jax_version}", "JaxLib version": F"{jaxlib_version}", "Using GPU in script?": "<fill in>", "Using distributed or parallel set-up in script?": "<fill in>", } print("\nCopy-and-paste the text below in your GitHub issue and FILL OUT the two last points.\n" ) print(self.format_dict(__UpperCAmelCase ) ) return info @staticmethod def a__ ( lowerCamelCase ): return "\n".join([F"- {prop}: {val}" for prop, val in d.items()] ) + "\n"
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def lowerCAmelCase_ ( __A, __A ) -> None: '''simple docstring''' UpperCAmelCase__ = len(__A ) print("The following activities are selected:" ) # The first activity is always selected UpperCAmelCase__ = 0 print(__A, end="," ) # Consider rest of the activities for j in range(__A ): # If this activity has start time greater than # or equal to the finish time of previously # selected activity, then select it if start[j] >= finish[i]: print(__A, end="," ) UpperCAmelCase__ = j if __name__ == "__main__": import doctest doctest.testmod() UpperCamelCase__ = [1, 3, 0, 5, 8, 5] UpperCamelCase__ = [2, 4, 6, 7, 9, 9] print_max_activities(start, finish)
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0
"""simple docstring""" from math import ceil def lowerCAmelCase__ ( UpperCamelCase__ = 1_0_0_1 ): '''simple docstring''' _a : Dict = 1 for i in range(1 , int(ceil(n / 2.0 ) ) ): _a : List[Any] = 2 * i + 1 _a : str = 2 * i _a : str = total + 4 * odd**2 - 6 * even return total if __name__ == "__main__": import sys if len(sys.argv) == 1: print(solution()) else: try: _snake_case = int(sys.argv[1]) print(solution(n)) except ValueError: print('Invalid entry - please enter a number')
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import argparse import os import jax as jnp import numpy as onp import torch import torch.nn as nn from music_spectrogram_diffusion import inference from tax import checkpoints from diffusers import DDPMScheduler, OnnxRuntimeModel, SpectrogramDiffusionPipeline from diffusers.pipelines.spectrogram_diffusion import SpectrogramContEncoder, SpectrogramNotesEncoder, TaFilmDecoder UpperCamelCase__ = 'base_with_context' def lowerCAmelCase_ ( __A, __A ) -> int: '''simple docstring''' UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(weights["token_embedder"]["embedding"] ) ) UpperCAmelCase__ = nn.Parameter( torch.FloatTensor(weights["Embed_0"]["embedding"] ), requires_grad=__A ) for lyr_num, lyr in enumerate(model.encoders ): UpperCAmelCase__ = weights[f"""layers_{lyr_num}"""] UpperCAmelCase__ = nn.Parameter( torch.FloatTensor(ly_weight["pre_attention_layer_norm"]["scale"] ) ) UpperCAmelCase__ = ly_weight["attention"] UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(attention_weights["query"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(attention_weights["key"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(attention_weights["value"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(attention_weights["out"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(ly_weight["pre_mlp_layer_norm"]["scale"] ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(ly_weight["mlp"]["wi_0"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(ly_weight["mlp"]["wi_1"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(ly_weight["mlp"]["wo"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(weights["encoder_norm"]["scale"] ) ) return model def lowerCAmelCase_ ( __A, __A ) -> Tuple: '''simple docstring''' UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(weights["input_proj"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter( torch.FloatTensor(weights["Embed_0"]["embedding"] ), requires_grad=__A ) for lyr_num, lyr in enumerate(model.encoders ): UpperCAmelCase__ = weights[f"""layers_{lyr_num}"""] UpperCAmelCase__ = ly_weight["attention"] UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(attention_weights["query"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(attention_weights["key"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(attention_weights["value"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(attention_weights["out"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter( torch.FloatTensor(ly_weight["pre_attention_layer_norm"]["scale"] ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(ly_weight["mlp"]["wi_0"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(ly_weight["mlp"]["wi_1"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(ly_weight["mlp"]["wo"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(ly_weight["pre_mlp_layer_norm"]["scale"] ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(weights["encoder_norm"]["scale"] ) ) return model def lowerCAmelCase_ ( __A, __A ) -> List[Any]: '''simple docstring''' UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(weights["time_emb_dense0"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(weights["time_emb_dense1"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter( torch.FloatTensor(weights["Embed_0"]["embedding"] ), requires_grad=__A ) UpperCAmelCase__ = nn.Parameter( torch.FloatTensor(weights["continuous_inputs_projection"]["kernel"].T ) ) for lyr_num, lyr in enumerate(model.decoders ): UpperCAmelCase__ = weights[f"""layers_{lyr_num}"""] UpperCAmelCase__ = nn.Parameter( torch.FloatTensor(ly_weight["pre_self_attention_layer_norm"]["scale"] ) ) UpperCAmelCase__ = nn.Parameter( torch.FloatTensor(ly_weight["FiLMLayer_0"]["DenseGeneral_0"]["kernel"].T ) ) UpperCAmelCase__ = ly_weight["self_attention"] UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(attention_weights["query"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(attention_weights["key"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(attention_weights["value"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(attention_weights["out"]["kernel"].T ) ) UpperCAmelCase__ = ly_weight["MultiHeadDotProductAttention_0"] UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(attention_weights["query"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(attention_weights["key"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(attention_weights["value"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(attention_weights["out"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter( torch.FloatTensor(ly_weight["pre_cross_attention_layer_norm"]["scale"] ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(ly_weight["pre_mlp_layer_norm"]["scale"] ) ) UpperCAmelCase__ = nn.Parameter( torch.FloatTensor(ly_weight["FiLMLayer_1"]["DenseGeneral_0"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(ly_weight["mlp"]["wi_0"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(ly_weight["mlp"]["wi_1"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(ly_weight["mlp"]["wo"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(weights["decoder_norm"]["scale"] ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(weights["spec_out_dense"]["kernel"].T ) ) return model def lowerCAmelCase_ ( __A ) -> int: '''simple docstring''' UpperCAmelCase__ = checkpoints.load_tax_checkpoint(args.checkpoint_path ) UpperCAmelCase__ = jnp.tree_util.tree_map(onp.array, __A ) UpperCAmelCase__ = [ "from __gin__ import dynamic_registration", "from music_spectrogram_diffusion.models.diffusion import diffusion_utils", "diffusion_utils.ClassifierFreeGuidanceConfig.eval_condition_weight = 2.0", "diffusion_utils.DiffusionConfig.classifier_free_guidance = @diffusion_utils.ClassifierFreeGuidanceConfig()", ] UpperCAmelCase__ = os.path.join(args.checkpoint_path, "..", "config.gin" ) UpperCAmelCase__ = inference.parse_training_gin_file(__A, __A ) UpperCAmelCase__ = inference.InferenceModel(args.checkpoint_path, __A ) UpperCAmelCase__ = DDPMScheduler(beta_schedule="squaredcos_cap_v2", variance_type="fixed_large" ) UpperCAmelCase__ = SpectrogramNotesEncoder( max_length=synth_model.sequence_length["inputs"], vocab_size=synth_model.model.module.config.vocab_size, d_model=synth_model.model.module.config.emb_dim, dropout_rate=synth_model.model.module.config.dropout_rate, num_layers=synth_model.model.module.config.num_encoder_layers, num_heads=synth_model.model.module.config.num_heads, d_kv=synth_model.model.module.config.head_dim, d_ff=synth_model.model.module.config.mlp_dim, feed_forward_proj="gated-gelu", ) UpperCAmelCase__ = SpectrogramContEncoder( input_dims=synth_model.audio_codec.n_dims, targets_context_length=synth_model.sequence_length["targets_context"], d_model=synth_model.model.module.config.emb_dim, dropout_rate=synth_model.model.module.config.dropout_rate, num_layers=synth_model.model.module.config.num_encoder_layers, num_heads=synth_model.model.module.config.num_heads, d_kv=synth_model.model.module.config.head_dim, d_ff=synth_model.model.module.config.mlp_dim, feed_forward_proj="gated-gelu", ) UpperCAmelCase__ = TaFilmDecoder( input_dims=synth_model.audio_codec.n_dims, targets_length=synth_model.sequence_length["targets_context"], max_decoder_noise_time=synth_model.model.module.config.max_decoder_noise_time, d_model=synth_model.model.module.config.emb_dim, num_layers=synth_model.model.module.config.num_decoder_layers, num_heads=synth_model.model.module.config.num_heads, d_kv=synth_model.model.module.config.head_dim, d_ff=synth_model.model.module.config.mlp_dim, dropout_rate=synth_model.model.module.config.dropout_rate, ) UpperCAmelCase__ = load_notes_encoder(ta_checkpoint["target"]["token_encoder"], __A ) UpperCAmelCase__ = load_continuous_encoder(ta_checkpoint["target"]["continuous_encoder"], __A ) UpperCAmelCase__ = load_decoder(ta_checkpoint["target"]["decoder"], __A ) UpperCAmelCase__ = OnnxRuntimeModel.from_pretrained("kashif/soundstream_mel_decoder" ) UpperCAmelCase__ = SpectrogramDiffusionPipeline( notes_encoder=__A, continuous_encoder=__A, decoder=__A, scheduler=__A, melgan=__A, ) if args.save: pipe.save_pretrained(args.output_path ) if __name__ == "__main__": UpperCamelCase__ = argparse.ArgumentParser() parser.add_argument('--output_path', default=None, type=str, required=True, help='Path to the converted model.') parser.add_argument( '--save', default=True, type=bool, required=False, help='Whether to save the converted model or not.' ) parser.add_argument( '--checkpoint_path', default=f'''{MODEL}/checkpoint_500000''', type=str, required=False, help='Path to the original jax model checkpoint.', ) UpperCamelCase__ = parser.parse_args() main(args)
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"""simple docstring""" import json from typing import List, Optional, Tuple from tokenizers import normalizers from ...tokenization_utils_fast import PreTrainedTokenizerFast from ...utils import logging from .tokenization_bert import BertTokenizer A_ = logging.get_logger(__name__) A_ = {'''vocab_file''': '''vocab.txt''', '''tokenizer_file''': '''tokenizer.json'''} A_ = { '''vocab_file''': { '''bert-base-uncased''': '''https://huggingface.co/bert-base-uncased/resolve/main/vocab.txt''', '''bert-large-uncased''': '''https://huggingface.co/bert-large-uncased/resolve/main/vocab.txt''', '''bert-base-cased''': '''https://huggingface.co/bert-base-cased/resolve/main/vocab.txt''', '''bert-large-cased''': '''https://huggingface.co/bert-large-cased/resolve/main/vocab.txt''', '''bert-base-multilingual-uncased''': ( '''https://huggingface.co/bert-base-multilingual-uncased/resolve/main/vocab.txt''' ), '''bert-base-multilingual-cased''': '''https://huggingface.co/bert-base-multilingual-cased/resolve/main/vocab.txt''', '''bert-base-chinese''': '''https://huggingface.co/bert-base-chinese/resolve/main/vocab.txt''', '''bert-base-german-cased''': '''https://huggingface.co/bert-base-german-cased/resolve/main/vocab.txt''', '''bert-large-uncased-whole-word-masking''': ( '''https://huggingface.co/bert-large-uncased-whole-word-masking/resolve/main/vocab.txt''' ), '''bert-large-cased-whole-word-masking''': ( '''https://huggingface.co/bert-large-cased-whole-word-masking/resolve/main/vocab.txt''' ), '''bert-large-uncased-whole-word-masking-finetuned-squad''': ( '''https://huggingface.co/bert-large-uncased-whole-word-masking-finetuned-squad/resolve/main/vocab.txt''' ), '''bert-large-cased-whole-word-masking-finetuned-squad''': ( '''https://huggingface.co/bert-large-cased-whole-word-masking-finetuned-squad/resolve/main/vocab.txt''' ), '''bert-base-cased-finetuned-mrpc''': ( '''https://huggingface.co/bert-base-cased-finetuned-mrpc/resolve/main/vocab.txt''' ), '''bert-base-german-dbmdz-cased''': '''https://huggingface.co/bert-base-german-dbmdz-cased/resolve/main/vocab.txt''', '''bert-base-german-dbmdz-uncased''': ( '''https://huggingface.co/bert-base-german-dbmdz-uncased/resolve/main/vocab.txt''' ), '''TurkuNLP/bert-base-finnish-cased-v1''': ( '''https://huggingface.co/TurkuNLP/bert-base-finnish-cased-v1/resolve/main/vocab.txt''' ), '''TurkuNLP/bert-base-finnish-uncased-v1''': ( '''https://huggingface.co/TurkuNLP/bert-base-finnish-uncased-v1/resolve/main/vocab.txt''' ), '''wietsedv/bert-base-dutch-cased''': ( '''https://huggingface.co/wietsedv/bert-base-dutch-cased/resolve/main/vocab.txt''' ), }, '''tokenizer_file''': { '''bert-base-uncased''': '''https://huggingface.co/bert-base-uncased/resolve/main/tokenizer.json''', '''bert-large-uncased''': '''https://huggingface.co/bert-large-uncased/resolve/main/tokenizer.json''', '''bert-base-cased''': '''https://huggingface.co/bert-base-cased/resolve/main/tokenizer.json''', '''bert-large-cased''': '''https://huggingface.co/bert-large-cased/resolve/main/tokenizer.json''', '''bert-base-multilingual-uncased''': ( '''https://huggingface.co/bert-base-multilingual-uncased/resolve/main/tokenizer.json''' ), '''bert-base-multilingual-cased''': ( '''https://huggingface.co/bert-base-multilingual-cased/resolve/main/tokenizer.json''' ), '''bert-base-chinese''': '''https://huggingface.co/bert-base-chinese/resolve/main/tokenizer.json''', '''bert-base-german-cased''': '''https://huggingface.co/bert-base-german-cased/resolve/main/tokenizer.json''', '''bert-large-uncased-whole-word-masking''': ( '''https://huggingface.co/bert-large-uncased-whole-word-masking/resolve/main/tokenizer.json''' ), '''bert-large-cased-whole-word-masking''': ( '''https://huggingface.co/bert-large-cased-whole-word-masking/resolve/main/tokenizer.json''' ), '''bert-large-uncased-whole-word-masking-finetuned-squad''': ( '''https://huggingface.co/bert-large-uncased-whole-word-masking-finetuned-squad/resolve/main/tokenizer.json''' ), '''bert-large-cased-whole-word-masking-finetuned-squad''': ( '''https://huggingface.co/bert-large-cased-whole-word-masking-finetuned-squad/resolve/main/tokenizer.json''' ), '''bert-base-cased-finetuned-mrpc''': ( '''https://huggingface.co/bert-base-cased-finetuned-mrpc/resolve/main/tokenizer.json''' ), '''bert-base-german-dbmdz-cased''': ( '''https://huggingface.co/bert-base-german-dbmdz-cased/resolve/main/tokenizer.json''' ), '''bert-base-german-dbmdz-uncased''': ( '''https://huggingface.co/bert-base-german-dbmdz-uncased/resolve/main/tokenizer.json''' ), '''TurkuNLP/bert-base-finnish-cased-v1''': ( '''https://huggingface.co/TurkuNLP/bert-base-finnish-cased-v1/resolve/main/tokenizer.json''' ), '''TurkuNLP/bert-base-finnish-uncased-v1''': ( '''https://huggingface.co/TurkuNLP/bert-base-finnish-uncased-v1/resolve/main/tokenizer.json''' ), '''wietsedv/bert-base-dutch-cased''': ( '''https://huggingface.co/wietsedv/bert-base-dutch-cased/resolve/main/tokenizer.json''' ), }, } A_ = { '''bert-base-uncased''': 5_12, '''bert-large-uncased''': 5_12, '''bert-base-cased''': 5_12, '''bert-large-cased''': 5_12, '''bert-base-multilingual-uncased''': 5_12, '''bert-base-multilingual-cased''': 5_12, '''bert-base-chinese''': 5_12, '''bert-base-german-cased''': 5_12, '''bert-large-uncased-whole-word-masking''': 5_12, '''bert-large-cased-whole-word-masking''': 5_12, '''bert-large-uncased-whole-word-masking-finetuned-squad''': 5_12, '''bert-large-cased-whole-word-masking-finetuned-squad''': 5_12, '''bert-base-cased-finetuned-mrpc''': 5_12, '''bert-base-german-dbmdz-cased''': 5_12, '''bert-base-german-dbmdz-uncased''': 5_12, '''TurkuNLP/bert-base-finnish-cased-v1''': 5_12, '''TurkuNLP/bert-base-finnish-uncased-v1''': 5_12, '''wietsedv/bert-base-dutch-cased''': 5_12, } A_ = { '''bert-base-uncased''': {'''do_lower_case''': True}, '''bert-large-uncased''': {'''do_lower_case''': True}, '''bert-base-cased''': {'''do_lower_case''': False}, '''bert-large-cased''': {'''do_lower_case''': False}, '''bert-base-multilingual-uncased''': {'''do_lower_case''': True}, '''bert-base-multilingual-cased''': {'''do_lower_case''': False}, '''bert-base-chinese''': {'''do_lower_case''': False}, '''bert-base-german-cased''': {'''do_lower_case''': False}, '''bert-large-uncased-whole-word-masking''': {'''do_lower_case''': True}, '''bert-large-cased-whole-word-masking''': {'''do_lower_case''': False}, '''bert-large-uncased-whole-word-masking-finetuned-squad''': {'''do_lower_case''': True}, '''bert-large-cased-whole-word-masking-finetuned-squad''': {'''do_lower_case''': False}, '''bert-base-cased-finetuned-mrpc''': {'''do_lower_case''': False}, '''bert-base-german-dbmdz-cased''': {'''do_lower_case''': False}, '''bert-base-german-dbmdz-uncased''': {'''do_lower_case''': True}, '''TurkuNLP/bert-base-finnish-cased-v1''': {'''do_lower_case''': False}, '''TurkuNLP/bert-base-finnish-uncased-v1''': {'''do_lower_case''': True}, '''wietsedv/bert-base-dutch-cased''': {'''do_lower_case''': False}, } class lowercase( UpperCAmelCase_ ): '''simple docstring''' lowercase__ = VOCAB_FILES_NAMES lowercase__ = PRETRAINED_VOCAB_FILES_MAP lowercase__ = PRETRAINED_INIT_CONFIGURATION lowercase__ = PRETRAINED_POSITIONAL_EMBEDDINGS_SIZES lowercase__ = BertTokenizer def __init__( self: Any, a_: Optional[int]=None, a_: Any=None, a_: Dict=True, a_: str="[UNK]", a_: List[str]="[SEP]", a_: int="[PAD]", a_: List[Any]="[CLS]", a_: str="[MASK]", a_: List[str]=True, a_: Tuple=None, **a_: int, ): '''simple docstring''' super().__init__( __UpperCAmelCase, tokenizer_file=__UpperCAmelCase, do_lower_case=__UpperCAmelCase, unk_token=__UpperCAmelCase, sep_token=__UpperCAmelCase, pad_token=__UpperCAmelCase, cls_token=__UpperCAmelCase, mask_token=__UpperCAmelCase, tokenize_chinese_chars=__UpperCAmelCase, strip_accents=__UpperCAmelCase, **__UpperCAmelCase, ) _snake_case : Tuple = json.loads(self.backend_tokenizer.normalizer.__getstate__() ) if ( normalizer_state.get("""lowercase""", __UpperCAmelCase ) != do_lower_case or normalizer_state.get("""strip_accents""", __UpperCAmelCase ) != strip_accents or normalizer_state.get("""handle_chinese_chars""", __UpperCAmelCase ) != tokenize_chinese_chars ): _snake_case : List[Any] = getattr(__UpperCAmelCase, normalizer_state.pop("""type""" ) ) _snake_case : int = do_lower_case _snake_case : Union[str, Any] = strip_accents _snake_case : Any = tokenize_chinese_chars _snake_case : Union[str, Any] = normalizer_class(**__UpperCAmelCase ) _snake_case : str = do_lower_case def UpperCamelCase_ ( self: int, a_: str, a_: List[str]=None ): '''simple docstring''' _snake_case : str = [self.cls_token_id] + token_ids_a + [self.sep_token_id] if token_ids_a: output += token_ids_a + [self.sep_token_id] return output def UpperCamelCase_ ( self: Dict, a_: List[int], a_: Optional[List[int]] = None ): '''simple docstring''' _snake_case : Optional[Any] = [self.sep_token_id] _snake_case : Dict = [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 UpperCamelCase_ ( self: Union[str, Any], a_: str, a_: Optional[str] = None ): '''simple docstring''' _snake_case : Optional[Any] = self._tokenizer.model.save(__UpperCAmelCase, name=__UpperCAmelCase ) return tuple(__UpperCAmelCase )
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import math def lowerCAmelCase_ ( __A ) -> bool: '''simple docstring''' return math.sqrt(__A ) * math.sqrt(__A ) == num def lowerCAmelCase_ ( __A ) -> bool: '''simple docstring''' UpperCAmelCase__ = 0 UpperCAmelCase__ = n while left <= right: UpperCAmelCase__ = (left + right) // 2 if mid**2 == n: return True elif mid**2 > n: UpperCAmelCase__ = mid - 1 else: UpperCAmelCase__ = mid + 1 return False if __name__ == "__main__": import doctest doctest.testmod()
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"""simple docstring""" import pandas as pd from matplotlib import pyplot as plt from sklearn.linear_model import LinearRegression # Splitting the dataset into the Training set and Test set from sklearn.model_selection import train_test_split # Fitting Polynomial Regression to the dataset from sklearn.preprocessing import PolynomialFeatures # Importing the dataset _A : Union[str, Any] = pd.read_csv( """https://s3.us-west-2.amazonaws.com/public.gamelab.fun/dataset/""" """position_salaries.csv""" ) _A : Any = dataset.iloc[:, 1:2].values _A : Optional[int] = dataset.iloc[:, 2].values _A , _A , _A , _A : Optional[int] = train_test_split(X, y, test_size=0.2, random_state=0) _A : Optional[Any] = PolynomialFeatures(degree=4) _A : Tuple = poly_reg.fit_transform(X) _A : List[str] = LinearRegression() pol_reg.fit(X_poly, y) def __magic_name__ ( ) -> str: plt.scatter(__A , __A , color="red" ) plt.plot(__A , pol_reg.predict(poly_reg.fit_transform(__A ) ) , color="blue" ) plt.title("Truth or Bluff (Linear Regression)" ) plt.xlabel("Position level" ) plt.ylabel("Salary" ) plt.show() if __name__ == "__main__": viz_polymonial() # Predicting a new result with Polymonial Regression pol_reg.predict(poly_reg.fit_transform([[5.5]])) # output should be 132148.43750003
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import math from dataclasses import dataclass from typing import Optional, Tuple, Union import numpy as np import torch from ..configuration_utils import ConfigMixin, register_to_config from ..utils import BaseOutput, randn_tensor from .scheduling_utils import SchedulerMixin @dataclass # Copied from diffusers.schedulers.scheduling_ddpm.DDPMSchedulerOutput with DDPM->UnCLIP class A ( UpperCAmelCase_ ): __UpperCAmelCase : torch.FloatTensor __UpperCAmelCase : Optional[torch.FloatTensor] = None def lowerCAmelCase_ ( __A, __A=0.999, __A="cosine", ) -> Tuple: '''simple docstring''' if alpha_transform_type == "cosine": def alpha_bar_fn(__A ): return math.cos((t + 0.008) / 1.008 * math.pi / 2 ) ** 2 elif alpha_transform_type == "exp": def alpha_bar_fn(__A ): return math.exp(t * -12.0 ) else: raise ValueError(f"""Unsupported alpha_tranform_type: {alpha_transform_type}""" ) UpperCAmelCase__ = [] for i in range(__A ): UpperCAmelCase__ = i / num_diffusion_timesteps UpperCAmelCase__ = (i + 1) / num_diffusion_timesteps betas.append(min(1 - alpha_bar_fn(__A ) / alpha_bar_fn(__A ), __A ) ) return torch.tensor(__A, dtype=torch.floataa ) class A ( UpperCAmelCase_ , UpperCAmelCase_ ): @register_to_config def __init__(self : List[str] , __UpperCAmelCase : int = 1_0_0_0 , __UpperCAmelCase : str = "fixed_small_log" , __UpperCAmelCase : bool = True , __UpperCAmelCase : Optional[float] = 1.0 , __UpperCAmelCase : str = "epsilon" , __UpperCAmelCase : str = "squaredcos_cap_v2" , ) -> Optional[int]: """simple docstring""" if beta_schedule != "squaredcos_cap_v2": raise ValueError("UnCLIPScheduler only supports `beta_schedule`: 'squaredcos_cap_v2'" ) UpperCAmelCase__ = betas_for_alpha_bar(__UpperCAmelCase ) UpperCAmelCase__ = 1.0 - self.betas UpperCAmelCase__ = torch.cumprod(self.alphas , dim=0 ) UpperCAmelCase__ = torch.tensor(1.0 ) # standard deviation of the initial noise distribution UpperCAmelCase__ = 1.0 # setable values UpperCAmelCase__ = None UpperCAmelCase__ = torch.from_numpy(np.arange(0 , __UpperCAmelCase )[::-1].copy() ) UpperCAmelCase__ = variance_type def lowercase_ (self : List[str] , __UpperCAmelCase : torch.FloatTensor , __UpperCAmelCase : Optional[int] = None ) -> torch.FloatTensor: """simple docstring""" return sample def lowercase_ (self : int , __UpperCAmelCase : int , __UpperCAmelCase : Union[str, torch.device] = None ) -> Any: """simple docstring""" UpperCAmelCase__ = num_inference_steps UpperCAmelCase__ = (self.config.num_train_timesteps - 1) / (self.num_inference_steps - 1) UpperCAmelCase__ = (np.arange(0 , __UpperCAmelCase ) * step_ratio).round()[::-1].copy().astype(np.intaa ) UpperCAmelCase__ = torch.from_numpy(__UpperCAmelCase ).to(__UpperCAmelCase ) def lowercase_ (self : Any , __UpperCAmelCase : Dict , __UpperCAmelCase : Optional[int]=None , __UpperCAmelCase : Tuple=None , __UpperCAmelCase : List[str]=None ) -> Tuple: """simple docstring""" if prev_timestep is None: UpperCAmelCase__ = t - 1 UpperCAmelCase__ = self.alphas_cumprod[t] UpperCAmelCase__ = self.alphas_cumprod[prev_timestep] if prev_timestep >= 0 else self.one UpperCAmelCase__ = 1 - alpha_prod_t UpperCAmelCase__ = 1 - alpha_prod_t_prev if prev_timestep == t - 1: UpperCAmelCase__ = self.betas[t] else: UpperCAmelCase__ = 1 - alpha_prod_t / alpha_prod_t_prev # For t > 0, compute predicted variance βt (see formula (6) and (7) from https://arxiv.org/pdf/2006.11239.pdf) # and sample from it to get previous sample # x_{t-1} ~ N(pred_prev_sample, variance) == add variance to pred_sample UpperCAmelCase__ = beta_prod_t_prev / beta_prod_t * beta if variance_type is None: UpperCAmelCase__ = self.config.variance_type # hacks - were probably added for training stability if variance_type == "fixed_small_log": UpperCAmelCase__ = torch.log(torch.clamp(__UpperCAmelCase , min=1E-20 ) ) UpperCAmelCase__ = torch.exp(0.5 * variance ) elif variance_type == "learned_range": # NOTE difference with DDPM scheduler UpperCAmelCase__ = variance.log() UpperCAmelCase__ = beta.log() UpperCAmelCase__ = (predicted_variance + 1) / 2 UpperCAmelCase__ = frac * max_log + (1 - frac) * min_log return variance def lowercase_ (self : Optional[int] , __UpperCAmelCase : torch.FloatTensor , __UpperCAmelCase : int , __UpperCAmelCase : torch.FloatTensor , __UpperCAmelCase : Optional[int] = None , __UpperCAmelCase : List[str]=None , __UpperCAmelCase : bool = True , ) -> Union[UnCLIPSchedulerOutput, Tuple]: """simple docstring""" UpperCAmelCase__ = timestep if model_output.shape[1] == sample.shape[1] * 2 and self.variance_type == "learned_range": UpperCAmelCase__ , UpperCAmelCase__ = torch.split(__UpperCAmelCase , sample.shape[1] , dim=1 ) else: UpperCAmelCase__ = None # 1. compute alphas, betas if prev_timestep is None: UpperCAmelCase__ = t - 1 UpperCAmelCase__ = self.alphas_cumprod[t] UpperCAmelCase__ = self.alphas_cumprod[prev_timestep] if prev_timestep >= 0 else self.one UpperCAmelCase__ = 1 - alpha_prod_t UpperCAmelCase__ = 1 - alpha_prod_t_prev if prev_timestep == t - 1: UpperCAmelCase__ = self.betas[t] UpperCAmelCase__ = self.alphas[t] else: UpperCAmelCase__ = 1 - alpha_prod_t / alpha_prod_t_prev UpperCAmelCase__ = 1 - beta # 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 self.config.prediction_type == "epsilon": UpperCAmelCase__ = (sample - beta_prod_t ** 0.5 * model_output) / alpha_prod_t ** 0.5 elif self.config.prediction_type == "sample": UpperCAmelCase__ = model_output else: raise ValueError( f"""prediction_type given as {self.config.prediction_type} must be one of `epsilon` or `sample`""" " for the UnCLIPScheduler." ) # 3. Clip "predicted x_0" if self.config.clip_sample: UpperCAmelCase__ = torch.clamp( __UpperCAmelCase , -self.config.clip_sample_range , self.config.clip_sample_range ) # 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 UpperCAmelCase__ = (alpha_prod_t_prev ** 0.5 * beta) / beta_prod_t UpperCAmelCase__ = alpha ** 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 UpperCAmelCase__ = pred_original_sample_coeff * pred_original_sample + current_sample_coeff * sample # 6. Add noise UpperCAmelCase__ = 0 if t > 0: UpperCAmelCase__ = randn_tensor( model_output.shape , dtype=model_output.dtype , generator=__UpperCAmelCase , device=model_output.device ) UpperCAmelCase__ = self._get_variance( __UpperCAmelCase , predicted_variance=__UpperCAmelCase , prev_timestep=__UpperCAmelCase , ) if self.variance_type == "fixed_small_log": UpperCAmelCase__ = variance elif self.variance_type == "learned_range": UpperCAmelCase__ = (0.5 * variance).exp() else: raise ValueError( f"""variance_type given as {self.variance_type} must be one of `fixed_small_log` or `learned_range`""" " for the UnCLIPScheduler." ) UpperCAmelCase__ = variance * variance_noise UpperCAmelCase__ = pred_prev_sample + variance if not return_dict: return (pred_prev_sample,) return UnCLIPSchedulerOutput(prev_sample=__UpperCAmelCase , pred_original_sample=__UpperCAmelCase ) def lowercase_ (self : Union[str, Any] , __UpperCAmelCase : torch.FloatTensor , __UpperCAmelCase : torch.FloatTensor , __UpperCAmelCase : torch.IntTensor , ) -> torch.FloatTensor: """simple docstring""" UpperCAmelCase__ = self.alphas_cumprod.to(device=original_samples.device , dtype=original_samples.dtype ) UpperCAmelCase__ = timesteps.to(original_samples.device ) UpperCAmelCase__ = alphas_cumprod[timesteps] ** 0.5 UpperCAmelCase__ = sqrt_alpha_prod.flatten() while len(sqrt_alpha_prod.shape ) < len(original_samples.shape ): UpperCAmelCase__ = sqrt_alpha_prod.unsqueeze(-1 ) UpperCAmelCase__ = (1 - alphas_cumprod[timesteps]) ** 0.5 UpperCAmelCase__ = sqrt_one_minus_alpha_prod.flatten() while len(sqrt_one_minus_alpha_prod.shape ) < len(original_samples.shape ): UpperCAmelCase__ = sqrt_one_minus_alpha_prod.unsqueeze(-1 ) UpperCAmelCase__ = sqrt_alpha_prod * original_samples + sqrt_one_minus_alpha_prod * noise return noisy_samples
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"""simple docstring""" import warnings from ...utils import logging from .image_processing_yolos import YolosImageProcessor lowerCamelCase_ = logging.get_logger(__name__) class UpperCamelCase_ (UpperCAmelCase_ ): def __init__( self : List[str] , *lowerCAmelCase_ : List[str] , **lowerCAmelCase_ : str ) -> None: warnings.warn( "The class YolosFeatureExtractor is deprecated and will be removed in version 5 of Transformers. Please" " use YolosImageProcessor instead." , __UpperCAmelCase , ) super().__init__(*__UpperCAmelCase , **__UpperCAmelCase )
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import inspect import os import unittest import torch import accelerate from accelerate import Accelerator from accelerate.test_utils import execute_subprocess_async, require_multi_gpu from accelerate.utils import patch_environment class A ( unittest.TestCase ): def lowercase_ (self : Union[str, Any] ) -> str: """simple docstring""" UpperCAmelCase__ = inspect.getfile(accelerate.test_utils ) UpperCAmelCase__ = os.path.sep.join(mod_file.split(os.path.sep )[:-1] + ["scripts", "test_script.py"] ) UpperCAmelCase__ = os.path.sep.join( mod_file.split(os.path.sep )[:-1] + ["scripts", "test_distributed_data_loop.py"] ) UpperCAmelCase__ = os.path.sep.join(mod_file.split(os.path.sep )[:-1] + ["scripts", "test_ops.py"] ) @require_multi_gpu def lowercase_ (self : List[str] ) -> Any: """simple docstring""" print(f"""Found {torch.cuda.device_count()} devices.""" ) UpperCAmelCase__ = ["torchrun", f"""--nproc_per_node={torch.cuda.device_count()}""", self.test_file_path] with patch_environment(omp_num_threads=1 ): execute_subprocess_async(__UpperCAmelCase , env=os.environ.copy() ) @require_multi_gpu def lowercase_ (self : str ) -> str: """simple docstring""" print(f"""Found {torch.cuda.device_count()} devices.""" ) UpperCAmelCase__ = ["torchrun", f"""--nproc_per_node={torch.cuda.device_count()}""", self.operation_file_path] print(f"""Command: {cmd}""" ) with patch_environment(omp_num_threads=1 ): execute_subprocess_async(__UpperCAmelCase , env=os.environ.copy() ) @require_multi_gpu def lowercase_ (self : Tuple ) -> int: """simple docstring""" UpperCAmelCase__ = ["torchrun", f"""--nproc_per_node={torch.cuda.device_count()}""", inspect.getfile(self.__class__ )] with patch_environment(omp_num_threads=1 ): execute_subprocess_async(__UpperCAmelCase , env=os.environ.copy() ) @require_multi_gpu def lowercase_ (self : Dict ) -> str: """simple docstring""" print(f"""Found {torch.cuda.device_count()} devices, using 2 devices only""" ) UpperCAmelCase__ = ["torchrun", f"""--nproc_per_node={torch.cuda.device_count()}""", self.data_loop_file_path] with patch_environment(omp_num_threads=1 , cuda_visible_devices="0,1" ): execute_subprocess_async(__UpperCAmelCase , env=os.environ.copy() ) if __name__ == "__main__": UpperCamelCase__ = Accelerator() UpperCamelCase__ = (accelerator.state.process_index + 2, 1_0) UpperCamelCase__ = torch.randint(0, 1_0, shape).to(accelerator.device) UpperCamelCase__ = '' UpperCamelCase__ = accelerator.pad_across_processes(tensor) if tensora.shape[0] != accelerator.state.num_processes + 1: error_msg += f"Found shape {tensora.shape} but should have {accelerator.state.num_processes + 1} at dim 0." if not torch.equal(tensora[: accelerator.state.process_index + 2], tensor): error_msg += "Tensors have different values." if not torch.all(tensora[accelerator.state.process_index + 2 :] == 0): error_msg += "Padding was not done with the right value (0)." UpperCamelCase__ = accelerator.pad_across_processes(tensor, pad_first=True) if tensora.shape[0] != accelerator.state.num_processes + 1: error_msg += f"Found shape {tensora.shape} but should have {accelerator.state.num_processes + 1} at dim 0." UpperCamelCase__ = accelerator.state.num_processes - accelerator.state.process_index - 1 if not torch.equal(tensora[index:], tensor): error_msg += "Tensors have different values." if not torch.all(tensora[:index] == 0): error_msg += "Padding was not done with the right value (0)." # Raise error at the end to make sure we don't stop at the first failure. if len(error_msg) > 0: raise ValueError(error_msg)
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"""simple docstring""" from argparse import ArgumentParser from .add_new_model import AddNewModelCommand from .add_new_model_like import AddNewModelLikeCommand from .convert import ConvertCommand from .download import DownloadCommand from .env import EnvironmentCommand from .lfs import LfsCommands from .pt_to_tf import PTtoTFCommand from .run import RunCommand from .serving import ServeCommand from .user import UserCommands def a__ ( ): """simple docstring""" UpperCamelCase = ArgumentParser("Transformers CLI tool" , usage="transformers-cli <command> [<args>]" ) UpperCamelCase = parser.add_subparsers(help="transformers-cli command helpers" ) # Register commands ConvertCommand.register_subcommand(__A ) DownloadCommand.register_subcommand(__A ) EnvironmentCommand.register_subcommand(__A ) RunCommand.register_subcommand(__A ) ServeCommand.register_subcommand(__A ) UserCommands.register_subcommand(__A ) AddNewModelCommand.register_subcommand(__A ) AddNewModelLikeCommand.register_subcommand(__A ) LfsCommands.register_subcommand(__A ) PTtoTFCommand.register_subcommand(__A ) # Let's go UpperCamelCase = parser.parse_args() if not hasattr(__A , "func" ): parser.print_help() exit(1 ) # Run UpperCamelCase = args.func(__A ) service.run() if __name__ == "__main__": main()
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import argparse import torch from torch import nn from transformers import MBartConfig, MBartForConditionalGeneration def lowerCAmelCase_ ( __A ) -> Dict: '''simple docstring''' UpperCAmelCase__ = [ "encoder.version", "decoder.version", "model.encoder.version", "model.decoder.version", "_float_tensor", "decoder.output_projection.weight", ] for k in ignore_keys: state_dict.pop(__A, __A ) def lowerCAmelCase_ ( __A ) -> Optional[int]: '''simple docstring''' UpperCAmelCase__ , UpperCAmelCase__ = emb.weight.shape UpperCAmelCase__ = nn.Linear(__A, __A, bias=__A ) UpperCAmelCase__ = emb.weight.data return lin_layer def lowerCAmelCase_ ( __A, __A="facebook/mbart-large-en-ro", __A=False, __A=False ) -> Tuple: '''simple docstring''' UpperCAmelCase__ = torch.load(__A, map_location="cpu" )["model"] remove_ignore_keys_(__A ) UpperCAmelCase__ = state_dict["encoder.embed_tokens.weight"].shape[0] UpperCAmelCase__ = MBartConfig.from_pretrained(__A, vocab_size=__A ) if mbart_aa and finetuned: UpperCAmelCase__ = "relu" UpperCAmelCase__ = state_dict["decoder.embed_tokens.weight"] UpperCAmelCase__ = MBartForConditionalGeneration(__A ) model.model.load_state_dict(__A ) if finetuned: UpperCAmelCase__ = make_linear_from_emb(model.model.shared ) return model if __name__ == "__main__": UpperCamelCase__ = argparse.ArgumentParser() # Required parameters parser.add_argument( 'fairseq_path', type=str, help='bart.large, bart.large.cnn or a 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.') parser.add_argument( '--hf_config', default='facebook/mbart-large-cc25', type=str, help='Which huggingface architecture to use: mbart-large', ) parser.add_argument('--mbart_50', action='store_true', help='whether the model is mMART-50 checkpoint') parser.add_argument('--finetuned', action='store_true', help='whether the model is a fine-tuned checkpoint') UpperCamelCase__ = parser.parse_args() UpperCamelCase__ = convert_fairseq_mbart_checkpoint_from_disk( args.fairseq_path, hf_config_path=args.hf_config, finetuned=args.finetuned, mbart_aa=args.mbart_aa ) model.save_pretrained(args.pytorch_dump_folder_path)
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import copy import os from typing import Union from ...configuration_utils import PretrainedConfig from ...utils import logging a_ :List[str] = logging.get_logger(__name__) a_ :Any = { "BAAI/AltCLIP": "https://huggingface.co/BAAI/AltCLIP/resolve/main/config.json", # See all AltCLIP models at https://huggingface.co/models?filter=altclip } class snake_case__ ( UpperCAmelCase_ ): """simple docstring""" _SCREAMING_SNAKE_CASE = 'altclip_text_model' def __init__( self : List[str], _snake_case : str=2_5_0_0_0_2, _snake_case : str=1_0_2_4, _snake_case : Dict=2_4, _snake_case : int=1_6, _snake_case : Optional[Any]=4_0_9_6, _snake_case : str="gelu", _snake_case : int=0.1, _snake_case : Any=0.1, _snake_case : Optional[int]=5_1_4, _snake_case : List[Any]=1, _snake_case : int=0.0_2, _snake_case : Any=0.0_2, _snake_case : Optional[Any]=1e-05, _snake_case : Any=1, _snake_case : Dict=0, _snake_case : Any=2, _snake_case : Optional[Any]="absolute", _snake_case : List[Any]=True, _snake_case : int=7_6_8, **_snake_case : Union[str, Any], ) ->List[Any]: super().__init__(pad_token_id=__UpperCAmelCase, bos_token_id=__UpperCAmelCase, eos_token_id=__UpperCAmelCase, **__UpperCAmelCase ) snake_case__ : List[str] = vocab_size snake_case__ : int = hidden_size snake_case__ : Dict = num_hidden_layers snake_case__ : Dict = num_attention_heads snake_case__ : Union[str, Any] = hidden_act snake_case__ : Tuple = intermediate_size snake_case__ : Any = hidden_dropout_prob snake_case__ : Dict = attention_probs_dropout_prob snake_case__ : Union[str, Any] = max_position_embeddings snake_case__ : Tuple = type_vocab_size snake_case__ : Optional[int] = initializer_range snake_case__ : Any = initializer_factor snake_case__ : int = layer_norm_eps snake_case__ : List[Any] = position_embedding_type snake_case__ : Dict = use_cache snake_case__ : List[Any] = project_dim class snake_case__ ( UpperCAmelCase_ ): """simple docstring""" _SCREAMING_SNAKE_CASE = 'altclip_vision_model' def __init__( self : str, _snake_case : List[Any]=7_6_8, _snake_case : Optional[Any]=3_0_7_2, _snake_case : Union[str, Any]=5_1_2, _snake_case : List[str]=1_2, _snake_case : Optional[int]=1_2, _snake_case : Any=3, _snake_case : List[str]=2_2_4, _snake_case : Union[str, Any]=3_2, _snake_case : Optional[Any]="quick_gelu", _snake_case : Optional[Any]=1e-5, _snake_case : Dict=0.0, _snake_case : Optional[Any]=0.0_2, _snake_case : Optional[Any]=1.0, **_snake_case : Optional[Any], ) ->Any: super().__init__(**__UpperCAmelCase ) snake_case__ : Any = hidden_size snake_case__ : Optional[Any] = intermediate_size snake_case__ : str = projection_dim snake_case__ : Optional[Any] = num_hidden_layers snake_case__ : int = num_attention_heads snake_case__ : List[Any] = num_channels snake_case__ : Tuple = patch_size snake_case__ : Any = image_size snake_case__ : List[Any] = initializer_range snake_case__ : List[Any] = initializer_factor snake_case__ : Dict = attention_dropout snake_case__ : Dict = layer_norm_eps snake_case__ : str = hidden_act @classmethod def lowercase_ ( cls : Any, _snake_case : Union[str, os.PathLike], **_snake_case : Optional[Any] ) ->"PretrainedConfig": cls._set_token_in_kwargs(__UpperCAmelCase ) snake_case__ , snake_case__ : str = cls.get_config_dict(__UpperCAmelCase, **__UpperCAmelCase ) # get the vision config dict if we are loading from AltCLIPConfig if config_dict.get('model_type' ) == "altclip": snake_case__ : Dict = config_dict['vision_config'] if "model_type" in config_dict and hasattr(cls, 'model_type' ) and config_dict["model_type"] != cls.model_type: logger.warning( F'''You are using a model of type {config_dict["model_type"]} to instantiate a model of type ''' F'''{cls.model_type}. This is not supported for all configurations of models and can yield errors.''' ) return cls.from_dict(__UpperCAmelCase, **__UpperCAmelCase ) class snake_case__ ( UpperCAmelCase_ ): """simple docstring""" _SCREAMING_SNAKE_CASE = 'altclip' _SCREAMING_SNAKE_CASE = True def __init__( self : Tuple, _snake_case : Optional[int]=None, _snake_case : Any=None, _snake_case : List[Any]=7_6_8, _snake_case : Optional[Any]=2.6_5_9_2, **_snake_case : List[str] ) ->str: snake_case__ : int = kwargs.pop('text_config_dict', __UpperCAmelCase ) snake_case__ : Tuple = kwargs.pop('vision_config_dict', __UpperCAmelCase ) super().__init__(**__UpperCAmelCase ) # Instead of simply assigning `[text|vision]_config_dict` to `[text|vision]_config`, we use the values in # `[text|vision]_config_dict` to update the values in `[text|vision]_config`. The values should be same in most # cases, but we don't want to break anything regarding `_config_dict` that existed before commit `8827e1b2`. if text_config_dict is not None: if text_config is None: snake_case__ : Any = {} # This is the complete result when using `text_config_dict`. snake_case__ : Optional[Any] = AltCLIPTextConfig(**__UpperCAmelCase ).to_dict() # Give a warning if the values exist in both `_text_config_dict` and `text_config` but being different. for key, value in _text_config_dict.items(): if key in text_config and value != text_config[key] and key not in ["transformers_version"]: # If specified in `text_config_dict` if key in text_config_dict: snake_case__ : Union[str, Any] = ( F'''`{key}` is found in both `text_config_dict` and `text_config` but with different values. ''' F'''The value `text_config_dict[\"{key}\"]` will be used instead.''' ) # If inferred from default argument values (just to be super careful) else: snake_case__ : Optional[Any] = ( F'''`text_config_dict` is provided which will be used to initialize `AltCLIPTextConfig`. The ''' F'''value `text_config[\"{key}\"]` will be overriden.''' ) logger.warning(__UpperCAmelCase ) # Update all values in `text_config` with the ones in `_text_config_dict`. text_config.update(_text_config_dict ) if vision_config_dict is not None: if vision_config is None: snake_case__ : List[Any] = {} # This is the complete result when using `vision_config_dict`. snake_case__ : List[Any] = AltCLIPVisionConfig(**__UpperCAmelCase ).to_dict() # convert keys to string instead of integer if "id2label" in _vision_config_dict: snake_case__ : Optional[int] = { str(__UpperCAmelCase ): value for key, value in _vision_config_dict['id2label'].items() } # Give a warning if the values exist in both `_vision_config_dict` and `vision_config` but being different. for key, value in _vision_config_dict.items(): if key in vision_config and value != vision_config[key] and key not in ["transformers_version"]: # If specified in `vision_config_dict` if key in vision_config_dict: snake_case__ : str = ( F'''`{key}` is found in both `vision_config_dict` and `vision_config` but with different ''' F'''values. The value `vision_config_dict[\"{key}\"]` will be used instead.''' ) # If inferred from default argument values (just to be super careful) else: snake_case__ : Dict = ( F'''`vision_config_dict` is provided which will be used to initialize `AltCLIPVisionConfig`. ''' F'''The value `vision_config[\"{key}\"]` will be overriden.''' ) logger.warning(__UpperCAmelCase ) # Update all values in `vision_config` with the ones in `_vision_config_dict`. vision_config.update(_vision_config_dict ) if text_config is None: snake_case__ : List[Any] = {} logger.info('`text_config` is `None`. Initializing the `AltCLIPTextConfig` with default values.' ) if vision_config is None: snake_case__ : Optional[int] = {} logger.info('`vision_config` is `None`. initializing the `AltCLIPVisionConfig` with default values.' ) snake_case__ : Tuple = AltCLIPTextConfig(**__UpperCAmelCase ) snake_case__ : Dict = AltCLIPVisionConfig(**__UpperCAmelCase ) snake_case__ : Optional[Any] = projection_dim snake_case__ : Tuple = logit_scale_init_value snake_case__ : str = 1.0 @classmethod def lowercase_ ( cls : List[str], _snake_case : AltCLIPTextConfig, _snake_case : AltCLIPVisionConfig, **_snake_case : Union[str, Any] ) ->Any: return cls(text_config=text_config.to_dict(), vision_config=vision_config.to_dict(), **__UpperCAmelCase ) def lowercase_ ( self : Any ) ->Optional[Any]: snake_case__ : str = copy.deepcopy(self.__dict__ ) snake_case__ : List[Any] = self.text_config.to_dict() snake_case__ : Tuple = self.vision_config.to_dict() snake_case__ : Tuple = self.__class__.model_type return output
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from .dependency_versions_table import deps from .utils.versions import require_version, require_version_core # define which module versions we always want to check at run time # (usually the ones defined in `install_requires` in setup.py) # # order specific notes: # - tqdm must be checked before tokenizers UpperCamelCase__ = [ 'python', 'tqdm', 'regex', 'requests', 'packaging', 'filelock', 'numpy', 'tokenizers', 'huggingface-hub', 'safetensors', 'accelerate', 'pyyaml', ] for pkg in pkgs_to_check_at_runtime: if pkg in deps: if pkg == "tokenizers": # must be loaded here, or else tqdm check may fail from .utils import is_tokenizers_available if not is_tokenizers_available(): continue # not required, check version only if installed elif pkg == "accelerate": # must be loaded here, or else tqdm check may fail from .utils import is_accelerate_available # Maybe switch to is_torch_available in the future here so that Accelerate is hard dep of # Transformers with PyTorch if not is_accelerate_available(): continue # not required, check version only if installed require_version_core(deps[pkg]) else: raise ValueError(f'''can\'t find {pkg} in {deps.keys()}, check dependency_versions_table.py''') def lowerCAmelCase_ ( __A, __A=None ) -> Dict: '''simple docstring''' require_version(deps[pkg], __A )
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import inspect import unittest from transformers import RegNetConfig from transformers.file_utils import cached_property, is_torch_available, is_vision_available from transformers.testing_utils import require_torch, require_vision, 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 if is_torch_available(): import torch from torch import nn from transformers import RegNetForImageClassification, RegNetModel from transformers.models.regnet.modeling_regnet import REGNET_PRETRAINED_MODEL_ARCHIVE_LIST if is_vision_available(): from PIL import Image from transformers import AutoImageProcessor class UpperCAmelCase_ : '''simple docstring''' def __init__( self , _A , _A=3 , _A=32 , _A=3 , _A=10 , _A=[10, 20, 30, 40] , _A=[1, 1, 2, 1] , _A=True , _A=True , _A="relu" , _A=3 , _A=None , ): '''simple docstring''' __SCREAMING_SNAKE_CASE = parent __SCREAMING_SNAKE_CASE = batch_size __SCREAMING_SNAKE_CASE = image_size __SCREAMING_SNAKE_CASE = num_channels __SCREAMING_SNAKE_CASE = embeddings_size __SCREAMING_SNAKE_CASE = hidden_sizes __SCREAMING_SNAKE_CASE = depths __SCREAMING_SNAKE_CASE = is_training __SCREAMING_SNAKE_CASE = use_labels __SCREAMING_SNAKE_CASE = hidden_act __SCREAMING_SNAKE_CASE = num_labels __SCREAMING_SNAKE_CASE = scope __SCREAMING_SNAKE_CASE = len(__UpperCAmelCase ) def _A ( self ): '''simple docstring''' __SCREAMING_SNAKE_CASE = floats_tensor([self.batch_size, self.num_channels, self.image_size, self.image_size] ) __SCREAMING_SNAKE_CASE = None if self.use_labels: __SCREAMING_SNAKE_CASE = ids_tensor([self.batch_size] , self.num_labels ) __SCREAMING_SNAKE_CASE = self.get_config() return config, pixel_values, labels def _A ( self ): '''simple docstring''' return RegNetConfig( num_channels=self.num_channels , embeddings_size=self.embeddings_size , hidden_sizes=self.hidden_sizes , depths=self.depths , hidden_act=self.hidden_act , num_labels=self.num_labels , ) def _A ( self , _A , _A , _A ): '''simple docstring''' __SCREAMING_SNAKE_CASE = RegNetModel(config=__UpperCAmelCase ) model.to(__UpperCAmelCase ) model.eval() __SCREAMING_SNAKE_CASE = model(__UpperCAmelCase ) # expected last hidden states: B, C, H // 32, W // 32 self.parent.assertEqual( result.last_hidden_state.shape , (self.batch_size, self.hidden_sizes[-1], self.image_size // 32, self.image_size // 32) , ) def _A ( self , _A , _A , _A ): '''simple docstring''' __SCREAMING_SNAKE_CASE = self.num_labels __SCREAMING_SNAKE_CASE = RegNetForImageClassification(__UpperCAmelCase ) model.to(__UpperCAmelCase ) model.eval() __SCREAMING_SNAKE_CASE = model(__UpperCAmelCase , labels=__UpperCAmelCase ) self.parent.assertEqual(result.logits.shape , (self.batch_size, self.num_labels) ) def _A ( self ): '''simple docstring''' __SCREAMING_SNAKE_CASE = self.prepare_config_and_inputs() __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE = config_and_inputs __SCREAMING_SNAKE_CASE = {'pixel_values': pixel_values} return config, inputs_dict @require_torch class UpperCAmelCase_ ( UpperCAmelCase_ , UpperCAmelCase_ , unittest.TestCase ): '''simple docstring''' UpperCamelCase__ : str = (RegNetModel, RegNetForImageClassification) if is_torch_available() else () UpperCamelCase__ : Dict = ( {'feature-extraction': RegNetModel, 'image-classification': RegNetForImageClassification} if is_torch_available() else {} ) UpperCamelCase__ : Union[str, Any] = False UpperCamelCase__ : Dict = False UpperCamelCase__ : str = False UpperCamelCase__ : Any = False def _A ( self ): '''simple docstring''' __SCREAMING_SNAKE_CASE = RegNetModelTester(self ) __SCREAMING_SNAKE_CASE = ConfigTester(self , config_class=__UpperCAmelCase , has_text_modality=__UpperCAmelCase ) def _A ( self ): '''simple docstring''' self.create_and_test_config_common_properties() 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 _A ( self ): '''simple docstring''' return @unittest.skip(reason='RegNet does not use inputs_embeds' ) def _A ( self ): '''simple docstring''' pass @unittest.skip(reason='RegNet does not support input and output embeddings' ) def _A ( self ): '''simple docstring''' pass def _A ( self ): '''simple docstring''' __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: __SCREAMING_SNAKE_CASE = model_class(__UpperCAmelCase ) __SCREAMING_SNAKE_CASE = inspect.signature(model.forward ) # signature.parameters is an OrderedDict => so arg_names order is deterministic __SCREAMING_SNAKE_CASE = [*signature.parameters.keys()] __SCREAMING_SNAKE_CASE = ['pixel_values'] self.assertListEqual(arg_names[:1] , __UpperCAmelCase ) def _A ( self ): '''simple docstring''' __SCREAMING_SNAKE_CASE = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_model(*__UpperCAmelCase ) def _A ( self ): '''simple docstring''' __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: __SCREAMING_SNAKE_CASE = model_class(config=__UpperCAmelCase ) for name, module in model.named_modules(): if isinstance(__UpperCAmelCase , (nn.BatchNormad, nn.GroupNorm) ): self.assertTrue( torch.all(module.weight == 1 ) , msg=f"""Parameter {name} of model {model_class} seems not properly initialized""" , ) self.assertTrue( torch.all(module.bias == 0 ) , msg=f"""Parameter {name} of model {model_class} seems not properly initialized""" , ) def _A ( self ): '''simple docstring''' def check_hidden_states_output(_A , _A , _A ): __SCREAMING_SNAKE_CASE = model_class(__UpperCAmelCase ) model.to(__UpperCAmelCase ) model.eval() with torch.no_grad(): __SCREAMING_SNAKE_CASE = model(**self._prepare_for_class(__UpperCAmelCase , __UpperCAmelCase ) ) __SCREAMING_SNAKE_CASE = outputs.encoder_hidden_states if config.is_encoder_decoder else outputs.hidden_states __SCREAMING_SNAKE_CASE = self.model_tester.num_stages self.assertEqual(len(__UpperCAmelCase ) , expected_num_stages + 1 ) # RegNet's feature maps are of shape (batch_size, num_channels, height, width) self.assertListEqual( list(hidden_states[0].shape[-2:] ) , [self.model_tester.image_size // 2, self.model_tester.image_size // 2] , ) __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE = self.model_tester.prepare_config_and_inputs_for_common() __SCREAMING_SNAKE_CASE = ['basic', 'bottleneck'] for model_class in self.all_model_classes: for layer_type in layers_type: __SCREAMING_SNAKE_CASE = layer_type __SCREAMING_SNAKE_CASE = True check_hidden_states_output(__UpperCAmelCase , __UpperCAmelCase , __UpperCAmelCase ) # check that output_hidden_states also work using config del inputs_dict["output_hidden_states"] __SCREAMING_SNAKE_CASE = True check_hidden_states_output(__UpperCAmelCase , __UpperCAmelCase , __UpperCAmelCase ) def _A ( self ): '''simple docstring''' __SCREAMING_SNAKE_CASE = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_for_image_classification(*__UpperCAmelCase ) @slow def _A ( self ): '''simple docstring''' for model_name in REGNET_PRETRAINED_MODEL_ARCHIVE_LIST[:1]: __SCREAMING_SNAKE_CASE = RegNetModel.from_pretrained(__UpperCAmelCase ) self.assertIsNotNone(__UpperCAmelCase ) def __lowercase ( ) -> Tuple: __SCREAMING_SNAKE_CASE = Image.open('./tests/fixtures/tests_samples/COCO/000000039769.png' ) return image @require_torch @require_vision class UpperCAmelCase_ ( unittest.TestCase ): '''simple docstring''' @cached_property def _A ( self ): '''simple docstring''' return ( AutoImageProcessor.from_pretrained(REGNET_PRETRAINED_MODEL_ARCHIVE_LIST[0] ) if is_vision_available() else None ) @slow def _A ( self ): '''simple docstring''' __SCREAMING_SNAKE_CASE = RegNetForImageClassification.from_pretrained(REGNET_PRETRAINED_MODEL_ARCHIVE_LIST[0] ).to(__UpperCAmelCase ) __SCREAMING_SNAKE_CASE = self.default_image_processor __SCREAMING_SNAKE_CASE = prepare_img() __SCREAMING_SNAKE_CASE = image_processor(images=__UpperCAmelCase , return_tensors='pt' ).to(__UpperCAmelCase ) # forward pass with torch.no_grad(): __SCREAMING_SNAKE_CASE = model(**__UpperCAmelCase ) # verify the logits __SCREAMING_SNAKE_CASE = torch.Size((1, 1_000) ) self.assertEqual(outputs.logits.shape , __UpperCAmelCase ) __SCREAMING_SNAKE_CASE = torch.tensor([-0.4_1_8_0, -1.5_0_5_1, -3.4_8_3_6] ).to(__UpperCAmelCase ) self.assertTrue(torch.allclose(outputs.logits[0, :3] , __UpperCAmelCase , atol=1e-4 ) )
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import argparse import logging import pickle import random import time import numpy as np from transformers import BertTokenizer, GPTaTokenizer, RobertaTokenizer logging.basicConfig( format='%(asctime)s - %(levelname)s - %(name)s - %(message)s', datefmt='%m/%d/%Y %H:%M:%S', level=logging.INFO ) UpperCamelCase__ = logging.getLogger(__name__) def lowerCAmelCase_ ( ) -> int: '''simple docstring''' UpperCAmelCase__ = argparse.ArgumentParser( description="Preprocess the data to avoid re-doing it several times by (tokenization + token_to_ids)." ) parser.add_argument("--file_path", type=__A, default="data/dump.txt", help="The path to the data." ) parser.add_argument("--tokenizer_type", type=__A, default="bert", choices=["bert", "roberta", "gpt2"] ) parser.add_argument("--tokenizer_name", type=__A, default="bert-base-uncased", help="The tokenizer to use." ) parser.add_argument("--dump_file", type=__A, default="data/dump", help="The dump file prefix." ) UpperCAmelCase__ = parser.parse_args() logger.info(f"""Loading Tokenizer ({args.tokenizer_name})""" ) if args.tokenizer_type == "bert": UpperCAmelCase__ = BertTokenizer.from_pretrained(args.tokenizer_name ) UpperCAmelCase__ = tokenizer.special_tokens_map["cls_token"] # `[CLS]` UpperCAmelCase__ = tokenizer.special_tokens_map["sep_token"] # `[SEP]` elif args.tokenizer_type == "roberta": UpperCAmelCase__ = RobertaTokenizer.from_pretrained(args.tokenizer_name ) UpperCAmelCase__ = tokenizer.special_tokens_map["cls_token"] # `<s>` UpperCAmelCase__ = tokenizer.special_tokens_map["sep_token"] # `</s>` elif args.tokenizer_type == "gpt2": UpperCAmelCase__ = GPTaTokenizer.from_pretrained(args.tokenizer_name ) UpperCAmelCase__ = tokenizer.special_tokens_map["bos_token"] # `<|endoftext|>` UpperCAmelCase__ = tokenizer.special_tokens_map["eos_token"] # `<|endoftext|>` logger.info(f"""Loading text from {args.file_path}""" ) with open(args.file_path, "r", encoding="utf8" ) as fp: UpperCAmelCase__ = fp.readlines() logger.info("Start encoding" ) logger.info(f"""{len(__A )} examples to process.""" ) UpperCAmelCase__ = [] UpperCAmelCase__ = 0 UpperCAmelCase__ = 10_000 UpperCAmelCase__ = time.time() for text in data: UpperCAmelCase__ = f"""{bos} {text.strip()} {sep}""" UpperCAmelCase__ = tokenizer.encode(__A, add_special_tokens=__A ) rslt.append(__A ) iter += 1 if iter % interval == 0: UpperCAmelCase__ = time.time() logger.info(f"""{iter} examples processed. - {(end-start):.2f}s/{interval}expl""" ) UpperCAmelCase__ = time.time() logger.info("Finished binarization" ) logger.info(f"""{len(__A )} examples processed.""" ) UpperCAmelCase__ = f"""{args.dump_file}.{args.tokenizer_name}.pickle""" UpperCAmelCase__ = tokenizer.vocab_size if vocab_size < (1 << 16): UpperCAmelCase__ = [np.uintaa(__A ) for d in rslt] else: UpperCAmelCase__ = [np.intaa(__A ) for d in rslt] random.shuffle(rslt_ ) logger.info(f"""Dump to {dp_file}""" ) with open(__A, "wb" ) as handle: pickle.dump(rslt_, __A, protocol=pickle.HIGHEST_PROTOCOL ) if __name__ == "__main__": main()
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"""simple docstring""" def __lowerCAmelCase ( lowercase : Union[str, Any] ) -> int: """simple docstring""" if divisor % 5 == 0 or divisor % 2 == 0: return 0 snake_case : List[Any] = 1 snake_case : Any = 1 while repunit: snake_case : Union[str, Any] = (10 * repunit + 1) % divisor repunit_index += 1 return repunit_index def __lowerCAmelCase ( lowercase : Any = 100_0000 ) -> int: """simple docstring""" snake_case : Optional[int] = limit - 1 if divisor % 2 == 0: divisor += 1 while least_divisible_repunit(__A ) <= limit: divisor += 2 return divisor if __name__ == "__main__": print(F'''{solution() = }''')
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from manim import * class A ( UpperCAmelCase_ ): def lowercase_ (self : Union[str, Any] ) -> List[str]: """simple docstring""" UpperCAmelCase__ = Rectangle(height=0.5 , width=0.5 ) UpperCAmelCase__ = Rectangle(height=0.46 , width=0.46 ).set_stroke(width=0 ) UpperCAmelCase__ = Rectangle(height=0.25 , width=0.25 ) UpperCAmelCase__ = [mem.copy() for i in range(6 )] UpperCAmelCase__ = [mem.copy() for i in range(6 )] UpperCAmelCase__ = VGroup(*__UpperCAmelCase ).arrange(__UpperCAmelCase , buff=0 ) UpperCAmelCase__ = VGroup(*__UpperCAmelCase ).arrange(__UpperCAmelCase , buff=0 ) UpperCAmelCase__ = VGroup(__UpperCAmelCase , __UpperCAmelCase ).arrange(__UpperCAmelCase , buff=0 ) UpperCAmelCase__ = Text("CPU" , font_size=2_4 ) UpperCAmelCase__ = Group(__UpperCAmelCase , __UpperCAmelCase ).arrange(__UpperCAmelCase , buff=0.5 , aligned_edge=__UpperCAmelCase ) cpu.move_to([-2.5, -0.5, 0] ) self.add(__UpperCAmelCase ) UpperCAmelCase__ = [mem.copy() for i in range(4 )] UpperCAmelCase__ = VGroup(*__UpperCAmelCase ).arrange(__UpperCAmelCase , buff=0 ) UpperCAmelCase__ = Text("GPU" , font_size=2_4 ) UpperCAmelCase__ = Group(__UpperCAmelCase , __UpperCAmelCase ).arrange(__UpperCAmelCase , buff=0.5 , aligned_edge=__UpperCAmelCase ) gpu.move_to([-1, -1, 0] ) self.add(__UpperCAmelCase ) UpperCAmelCase__ = [mem.copy() for i in range(6 )] UpperCAmelCase__ = VGroup(*__UpperCAmelCase ).arrange(__UpperCAmelCase , buff=0 ) UpperCAmelCase__ = Text("Model" , font_size=2_4 ) UpperCAmelCase__ = Group(__UpperCAmelCase , __UpperCAmelCase ).arrange(__UpperCAmelCase , buff=0.5 , aligned_edge=__UpperCAmelCase ) model.move_to([3, -1.0, 0] ) self.add(__UpperCAmelCase ) UpperCAmelCase__ = [] UpperCAmelCase__ = [] for i, rect in enumerate(__UpperCAmelCase ): UpperCAmelCase__ = fill.copy().set_fill(__UpperCAmelCase , opacity=0.8 ) target.move_to(__UpperCAmelCase ) model_arr.append(__UpperCAmelCase ) UpperCAmelCase__ = Rectangle(height=0.46 , width=0.46 ).set_stroke(width=0.0 ).set_fill(__UpperCAmelCase , opacity=0.8 ) cpu_target.move_to(cpu_left_col_base[i] ) model_cpu_arr.append(__UpperCAmelCase ) self.add(*__UpperCAmelCase , *__UpperCAmelCase ) UpperCAmelCase__ = [meta_mem.copy() for i in range(6 )] UpperCAmelCase__ = [meta_mem.copy() for i in range(6 )] UpperCAmelCase__ = VGroup(*__UpperCAmelCase ).arrange(__UpperCAmelCase , buff=0 ) UpperCAmelCase__ = VGroup(*__UpperCAmelCase ).arrange(__UpperCAmelCase , buff=0 ) UpperCAmelCase__ = VGroup(__UpperCAmelCase , __UpperCAmelCase ).arrange(__UpperCAmelCase , buff=0 ) UpperCAmelCase__ = Text("Disk" , font_size=2_4 ) UpperCAmelCase__ = Group(__UpperCAmelCase , __UpperCAmelCase ).arrange(__UpperCAmelCase , buff=0.5 , aligned_edge=__UpperCAmelCase ) disk.move_to([-4, -1.25, 0] ) self.add(__UpperCAmelCase , __UpperCAmelCase ) UpperCAmelCase__ = Square(side_length=2.2 ) key.move_to([-5, 2, 0] ) UpperCAmelCase__ = MarkupText( f"""<b>Key:</b>\n\n<span fgcolor='{YELLOW}'>●</span> Empty Model""" , font_size=1_8 , ) key_text.move_to([-5, 2.4, 0] ) self.add(__UpperCAmelCase , __UpperCAmelCase ) UpperCAmelCase__ = MarkupText( f"""<span fgcolor='{BLUE}'>●</span> Checkpoint""" , font_size=1_8 , ) blue_text.next_to(__UpperCAmelCase , DOWN * 2.4 , aligned_edge=key_text.get_left() ) self.add(__UpperCAmelCase ) UpperCAmelCase__ = MarkupText( f"""Now watch as an input is passed through the model\nand how the memory is utilized and handled.""" , font_size=2_4 , ) step_a.move_to([2, 2, 0] ) self.play(Write(__UpperCAmelCase ) ) UpperCAmelCase__ = Square(0.3 ) input.set_fill(__UpperCAmelCase , opacity=1.0 ) input.set_stroke(width=0.0 ) input.next_to(model_base[0] , __UpperCAmelCase , buff=0.5 ) self.play(Write(__UpperCAmelCase ) ) input.generate_target() input.target.next_to(model_arr[0] , direction=__UpperCAmelCase , buff=0.02 ) self.play(MoveToTarget(__UpperCAmelCase ) ) self.play(FadeOut(__UpperCAmelCase ) ) UpperCAmelCase__ = Arrow(start=__UpperCAmelCase , end=__UpperCAmelCase , color=__UpperCAmelCase , buff=0.5 ) a.next_to(model_arr[0].get_left() , __UpperCAmelCase , buff=0.2 ) model_cpu_arr[0].generate_target() model_cpu_arr[0].target.move_to(gpu_rect[0] ) UpperCAmelCase__ = MarkupText( f"""As the input reaches a layer, the hook triggers\nand weights are moved from the CPU\nto the GPU and back.""" , font_size=2_4 , ) step_a.move_to([2, 2, 0] ) self.play(Write(__UpperCAmelCase , run_time=3 ) ) UpperCAmelCase__ = {"run_time": 1, "fade_in": True, "fade_out": True, "buff": 0.02} self.play( Write(__UpperCAmelCase ) , Circumscribe(model_arr[0] , color=__UpperCAmelCase , **__UpperCAmelCase ) , Circumscribe(model_cpu_arr[0] , color=__UpperCAmelCase , **__UpperCAmelCase ) , Circumscribe(gpu_rect[0] , color=__UpperCAmelCase , **__UpperCAmelCase ) , ) self.play(MoveToTarget(model_cpu_arr[0] ) ) UpperCAmelCase__ = a.copy() for i in range(6 ): a_c.next_to(model_arr[i].get_right() + 0.02 , __UpperCAmelCase , buff=0.2 ) input.generate_target() input.target.move_to(model_arr[i].get_right() + 0.02 ) UpperCAmelCase__ = AnimationGroup( FadeOut(__UpperCAmelCase , run_time=0.5 ) , MoveToTarget(__UpperCAmelCase , run_time=0.5 ) , FadeIn(__UpperCAmelCase , run_time=0.5 ) , lag_ratio=0.2 ) self.play(__UpperCAmelCase ) model_cpu_arr[i].generate_target() model_cpu_arr[i].target.move_to(cpu_left_col_base[i] ) if i < 5: model_cpu_arr[i + 1].generate_target() model_cpu_arr[i + 1].target.move_to(gpu_rect[0] ) if i >= 1: UpperCAmelCase__ = 0.7 self.play( Circumscribe(model_arr[i] , **__UpperCAmelCase ) , Circumscribe(cpu_left_col_base[i] , **__UpperCAmelCase ) , Circumscribe(cpu_left_col_base[i + 1] , color=__UpperCAmelCase , **__UpperCAmelCase ) , Circumscribe(gpu_rect[0] , color=__UpperCAmelCase , **__UpperCAmelCase ) , Circumscribe(model_arr[i + 1] , color=__UpperCAmelCase , **__UpperCAmelCase ) , ) if i < 1: self.play( MoveToTarget(model_cpu_arr[i] ) , MoveToTarget(model_cpu_arr[i + 1] ) , ) else: self.play( MoveToTarget(model_cpu_arr[i] , run_time=0.7 ) , MoveToTarget(model_cpu_arr[i + 1] , run_time=0.7 ) , ) else: model_cpu_arr[i].generate_target() model_cpu_arr[i].target.move_to(cpu_left_col_base[-1] ) input.generate_target() input.target.next_to(model_arr[-1].get_right() , RIGHT + 0.02 , buff=0.2 ) self.play( Circumscribe(model_arr[-1] , color=__UpperCAmelCase , **__UpperCAmelCase ) , Circumscribe(cpu_left_col_base[-1] , color=__UpperCAmelCase , **__UpperCAmelCase ) , Circumscribe(gpu_rect[0] , color=__UpperCAmelCase , **__UpperCAmelCase ) , ) self.play(MoveToTarget(model_cpu_arr[i] ) ) UpperCAmelCase__ = a_c UpperCAmelCase__ = a_c.copy() input.generate_target() input.target.next_to(model_base[-1] , RIGHT + 0.02 , buff=0.5 ) self.play( FadeOut(__UpperCAmelCase ) , FadeOut(__UpperCAmelCase , run_time=0.5 ) , ) UpperCAmelCase__ = MarkupText(f"""Inference on a model too large for GPU memory\nis successfully completed.""" , font_size=2_4 ) step_a.move_to([2, 2, 0] ) self.play(Write(__UpperCAmelCase , run_time=3 ) , MoveToTarget(__UpperCAmelCase ) ) self.wait()
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"""simple docstring""" import argparse import logging import pickle import random import time import numpy as np from transformers import BertTokenizer, GPTaTokenizer, RobertaTokenizer logging.basicConfig( format='''%(asctime)s - %(levelname)s - %(name)s - %(message)s''', datefmt='''%m/%d/%Y %H:%M:%S''', level=logging.INFO ) lowercase__ : str = logging.getLogger(__name__) def __lowercase ( ): snake_case_ : Union[str, Any] = argparse.ArgumentParser( description='''Preprocess the data to avoid re-doing it several times by (tokenization + token_to_ids).''' ) parser.add_argument('''--file_path''' , type=__A , default='''data/dump.txt''' , help='''The path to the data.''' ) parser.add_argument('''--tokenizer_type''' , type=__A , default='''bert''' , choices=['''bert''', '''roberta''', '''gpt2'''] ) parser.add_argument('''--tokenizer_name''' , type=__A , default='''bert-base-uncased''' , help='''The tokenizer to use.''' ) parser.add_argument('''--dump_file''' , type=__A , default='''data/dump''' , help='''The dump file prefix.''' ) snake_case_ : Union[str, Any] = parser.parse_args() logger.info(f"Loading Tokenizer ({args.tokenizer_name})" ) if args.tokenizer_type == "bert": snake_case_ : Dict = BertTokenizer.from_pretrained(args.tokenizer_name ) snake_case_ : int = tokenizer.special_tokens_map['''cls_token'''] # `[CLS]` snake_case_ : List[Any] = tokenizer.special_tokens_map['''sep_token'''] # `[SEP]` elif args.tokenizer_type == "roberta": snake_case_ : Any = RobertaTokenizer.from_pretrained(args.tokenizer_name ) snake_case_ : Optional[Any] = tokenizer.special_tokens_map['''cls_token'''] # `<s>` snake_case_ : List[Any] = tokenizer.special_tokens_map['''sep_token'''] # `</s>` elif args.tokenizer_type == "gpt2": snake_case_ : Union[str, Any] = GPTaTokenizer.from_pretrained(args.tokenizer_name ) snake_case_ : int = tokenizer.special_tokens_map['''bos_token'''] # `<|endoftext|>` snake_case_ : str = tokenizer.special_tokens_map['''eos_token'''] # `<|endoftext|>` logger.info(f"Loading text from {args.file_path}" ) with open(args.file_path , '''r''' , encoding='''utf8''' ) as fp: snake_case_ : Dict = fp.readlines() logger.info('''Start encoding''' ) logger.info(f"{len(__A )} examples to process." ) snake_case_ : Any = [] snake_case_ : Any = 0 snake_case_ : List[str] = 10_000 snake_case_ : Any = time.time() for text in data: snake_case_ : str = f"{bos} {text.strip()} {sep}" snake_case_ : List[Any] = tokenizer.encode(__A , add_special_tokens=__A ) rslt.append(__A ) iter += 1 if iter % interval == 0: snake_case_ : Optional[Any] = time.time() logger.info(f"{iter} examples processed. - {(end-start):.2f}s/{interval}expl" ) snake_case_ : Optional[Any] = time.time() logger.info('''Finished binarization''' ) logger.info(f"{len(__A )} examples processed." ) snake_case_ : int = f"{args.dump_file}.{args.tokenizer_name}.pickle" snake_case_ : List[Any] = tokenizer.vocab_size if vocab_size < (1 << 16): snake_case_ : Union[str, Any] = [np.uintaa(__A ) for d in rslt] else: snake_case_ : Union[str, Any] = [np.intaa(__A ) for d in rslt] random.shuffle(rslt_ ) logger.info(f"Dump to {dp_file}" ) with open(__A , '''wb''' ) as handle: pickle.dump(rslt_ , __A , protocol=pickle.HIGHEST_PROTOCOL ) if __name__ == "__main__": main()
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from __future__ import annotations from scipy.special import comb # type: ignore class A : def __init__(self : List[Any] , __UpperCAmelCase : list[tuple[float, float]] ) -> List[str]: """simple docstring""" UpperCAmelCase__ = list_of_points # Degree determines the flexibility of the curve. # Degree = 1 will produce a straight line. UpperCAmelCase__ = len(__UpperCAmelCase ) - 1 def lowercase_ (self : int , __UpperCAmelCase : float ) -> list[float]: """simple docstring""" assert 0 <= t <= 1, "Time t must be between 0 and 1." UpperCAmelCase__ = [] for i in range(len(self.list_of_points ) ): # basis function for each i output_values.append( comb(self.degree , __UpperCAmelCase ) * ((1 - t) ** (self.degree - i)) * (t**i) ) # the basis must sum up to 1 for it to produce a valid Bezier curve. assert round(sum(__UpperCAmelCase ) , 5 ) == 1 return output_values def lowercase_ (self : Dict , __UpperCAmelCase : float ) -> tuple[float, float]: """simple docstring""" assert 0 <= t <= 1, "Time t must be between 0 and 1." UpperCAmelCase__ = self.basis_function(__UpperCAmelCase ) UpperCAmelCase__ = 0.0 UpperCAmelCase__ = 0.0 for i in range(len(self.list_of_points ) ): # For all points, sum up the product of i-th basis function and i-th point. x += basis_function[i] * self.list_of_points[i][0] y += basis_function[i] * self.list_of_points[i][1] return (x, y) def lowercase_ (self : Optional[int] , __UpperCAmelCase : float = 0.01 ) -> Optional[int]: """simple docstring""" from matplotlib import pyplot as plt # type: ignore UpperCAmelCase__ = [] # x coordinates of points to plot UpperCAmelCase__ = [] # y coordinates of points to plot UpperCAmelCase__ = 0.0 while t <= 1: UpperCAmelCase__ = self.bezier_curve_function(__UpperCAmelCase ) to_plot_x.append(value[0] ) to_plot_y.append(value[1] ) t += step_size UpperCAmelCase__ = [i[0] for i in self.list_of_points] UpperCAmelCase__ = [i[1] for i in self.list_of_points] plt.plot( __UpperCAmelCase , __UpperCAmelCase , color="blue" , label="Curve of Degree " + str(self.degree ) , ) plt.scatter(__UpperCAmelCase , __UpperCAmelCase , color="red" , label="Control Points" ) plt.legend() plt.show() if __name__ == "__main__": import doctest doctest.testmod() BezierCurve([(1, 2), (3, 5)]).plot_curve() # degree 1 BezierCurve([(0, 0), (5, 5), (5, 0)]).plot_curve() # degree 2 BezierCurve([(0, 0), (5, 5), (5, 0), (2.5, -2.5)]).plot_curve() # degree 3
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from __future__ import annotations import copy import inspect import unittest import numpy as np from transformers import is_tf_available, is_vision_available from transformers.models.auto import get_values from transformers.testing_utils import require_tf, slow from transformers.utils import cached_property from ...test_configuration_common import ConfigTester from ...test_modeling_tf_common import TFModelTesterMixin, floats_tensor, ids_tensor, random_attention_mask from ...test_pipeline_mixin import PipelineTesterMixin if is_tf_available(): import tensorflow as tf from transformers import ( TF_LAYOUTLMV3_PRETRAINED_MODEL_ARCHIVE_LIST, TF_MODEL_FOR_MULTIPLE_CHOICE_MAPPING, TF_MODEL_FOR_QUESTION_ANSWERING_MAPPING, TF_MODEL_FOR_SEQUENCE_CLASSIFICATION_MAPPING, TF_MODEL_FOR_TOKEN_CLASSIFICATION_MAPPING, LayoutLMvaConfig, TFLayoutLMvaForQuestionAnswering, TFLayoutLMvaForSequenceClassification, TFLayoutLMvaForTokenClassification, TFLayoutLMvaModel, ) if is_vision_available(): from PIL import Image from transformers import LayoutLMvaImageProcessor class __UpperCAmelCase : def __init__( self : int, __A : Any, __A : str=2, __A : str=3, __A : Tuple=4, __A : List[Any]=2, __A : int=7, __A : Dict=True, __A : List[Any]=True, __A : Tuple=True, __A : Union[str, Any]=True, __A : Dict=9_9, __A : List[str]=3_6, __A : Optional[Any]=2, __A : int=4, __A : Optional[Any]=3_7, __A : List[str]="gelu", __A : Dict=0.1, __A : Any=0.1, __A : int=5_1_2, __A : str=1_6, __A : str=2, __A : Any=0.0_2, __A : str=6, __A : str=6, __A : Any=3, __A : List[Any]=4, __A : Dict=None, __A : List[Any]=1_0_0_0, ): UpperCAmelCase : Union[str, Any] = parent UpperCAmelCase : Any = batch_size UpperCAmelCase : int = num_channels UpperCAmelCase : int = image_size UpperCAmelCase : str = patch_size UpperCAmelCase : Dict = is_training UpperCAmelCase : Union[str, Any] = use_input_mask UpperCAmelCase : Optional[int] = use_token_type_ids UpperCAmelCase : int = use_labels UpperCAmelCase : List[str] = vocab_size UpperCAmelCase : Dict = hidden_size UpperCAmelCase : Optional[Any] = num_hidden_layers UpperCAmelCase : Any = num_attention_heads UpperCAmelCase : str = intermediate_size UpperCAmelCase : str = hidden_act UpperCAmelCase : Optional[int] = hidden_dropout_prob UpperCAmelCase : Optional[Any] = attention_probs_dropout_prob UpperCAmelCase : Any = max_position_embeddings UpperCAmelCase : List[Any] = type_vocab_size UpperCAmelCase : List[str] = type_sequence_label_size UpperCAmelCase : int = initializer_range UpperCAmelCase : Optional[Any] = coordinate_size UpperCAmelCase : Tuple = shape_size UpperCAmelCase : int = num_labels UpperCAmelCase : List[str] = num_choices UpperCAmelCase : str = scope UpperCAmelCase : List[Any] = range_bbox # LayoutLMv3's sequence length equals the number of text tokens + number of patches + 1 (we add 1 for the CLS token) UpperCAmelCase : int = text_seq_length UpperCAmelCase : Optional[int] = (image_size // patch_size) ** 2 + 1 UpperCAmelCase : Union[str, Any] = self.text_seq_length + self.image_seq_length def __magic_name__ ( self : Optional[int] ): UpperCAmelCase : Dict = ids_tensor([self.batch_size, self.text_seq_length], self.vocab_size ) UpperCAmelCase : Any = ids_tensor([self.batch_size, self.text_seq_length, 4], self.range_bbox ) UpperCAmelCase : str = bbox.numpy() # Ensure that bbox is legal for i in range(bbox.shape[0] ): for j in range(bbox.shape[1] ): if bbox[i, j, 3] < bbox[i, j, 1]: UpperCAmelCase : Dict = bbox[i, j, 3] UpperCAmelCase : str = bbox[i, j, 1] UpperCAmelCase : List[str] = tmp_coordinate if bbox[i, j, 2] < bbox[i, j, 0]: UpperCAmelCase : List[str] = bbox[i, j, 2] UpperCAmelCase : int = bbox[i, j, 0] UpperCAmelCase : int = tmp_coordinate UpperCAmelCase : Tuple = tf.constant(__UpperCAmelCase ) UpperCAmelCase : Tuple = floats_tensor([self.batch_size, self.num_channels, self.image_size, self.image_size] ) UpperCAmelCase : Tuple = None if self.use_input_mask: UpperCAmelCase : str = random_attention_mask([self.batch_size, self.text_seq_length] ) UpperCAmelCase : List[Any] = None if self.use_token_type_ids: UpperCAmelCase : List[str] = ids_tensor([self.batch_size, self.text_seq_length], self.type_vocab_size ) UpperCAmelCase : str = None UpperCAmelCase : Optional[Any] = None if self.use_labels: UpperCAmelCase : Optional[int] = ids_tensor([self.batch_size], self.type_sequence_label_size ) UpperCAmelCase : Optional[int] = ids_tensor([self.batch_size, self.text_seq_length], self.num_labels ) UpperCAmelCase : Optional[Any] = LayoutLMvaConfig( 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, initializer_range=self.initializer_range, coordinate_size=self.coordinate_size, shape_size=self.shape_size, input_size=self.image_size, patch_size=self.patch_size, ) return config, input_ids, bbox, pixel_values, token_type_ids, input_mask, sequence_labels, token_labels def __magic_name__ ( self : int, __A : Optional[Any], __A : Dict, __A : str, __A : Optional[Any], __A : Union[str, Any], __A : Optional[Any] ): UpperCAmelCase : Optional[int] = TFLayoutLMvaModel(config=__UpperCAmelCase ) # text + image UpperCAmelCase : str = model(__UpperCAmelCase, pixel_values=__UpperCAmelCase, training=__UpperCAmelCase ) UpperCAmelCase : int = model( __UpperCAmelCase, bbox=__UpperCAmelCase, pixel_values=__UpperCAmelCase, attention_mask=__UpperCAmelCase, token_type_ids=__UpperCAmelCase, training=__UpperCAmelCase, ) UpperCAmelCase : Tuple = model(__UpperCAmelCase, bbox=__UpperCAmelCase, pixel_values=__UpperCAmelCase, training=__UpperCAmelCase ) self.parent.assertEqual(result.last_hidden_state.shape, (self.batch_size, self.seq_length, self.hidden_size) ) # text only UpperCAmelCase : Tuple = model(__UpperCAmelCase, training=__UpperCAmelCase ) self.parent.assertEqual( result.last_hidden_state.shape, (self.batch_size, self.text_seq_length, self.hidden_size) ) # image only UpperCAmelCase : Optional[Any] = model({'''pixel_values''': pixel_values}, training=__UpperCAmelCase ) self.parent.assertEqual( result.last_hidden_state.shape, (self.batch_size, self.image_seq_length, self.hidden_size) ) def __magic_name__ ( self : List[Any], __A : str, __A : Optional[Any], __A : List[Any], __A : Optional[int], __A : List[str], __A : Dict, __A : List[Any] ): UpperCAmelCase : str = self.num_labels UpperCAmelCase : Union[str, Any] = TFLayoutLMvaForSequenceClassification(config=__UpperCAmelCase ) UpperCAmelCase : Any = model( __UpperCAmelCase, bbox=__UpperCAmelCase, pixel_values=__UpperCAmelCase, attention_mask=__UpperCAmelCase, token_type_ids=__UpperCAmelCase, labels=__UpperCAmelCase, training=__UpperCAmelCase, ) self.parent.assertEqual(result.logits.shape, (self.batch_size, self.num_labels) ) def __magic_name__ ( self : Optional[Any], __A : Optional[Any], __A : str, __A : Optional[Any], __A : Union[str, Any], __A : Dict, __A : int, __A : Union[str, Any] ): UpperCAmelCase : Union[str, Any] = self.num_labels UpperCAmelCase : Tuple = TFLayoutLMvaForTokenClassification(config=__UpperCAmelCase ) UpperCAmelCase : Optional[int] = model( __UpperCAmelCase, bbox=__UpperCAmelCase, pixel_values=__UpperCAmelCase, attention_mask=__UpperCAmelCase, token_type_ids=__UpperCAmelCase, labels=__UpperCAmelCase, training=__UpperCAmelCase, ) self.parent.assertEqual(result.logits.shape, (self.batch_size, self.text_seq_length, self.num_labels) ) def __magic_name__ ( self : str, __A : Optional[Any], __A : Tuple, __A : List[Any], __A : List[Any], __A : List[str], __A : Optional[int], __A : Optional[Any] ): UpperCAmelCase : Dict = 2 UpperCAmelCase : Optional[Any] = TFLayoutLMvaForQuestionAnswering(config=__UpperCAmelCase ) UpperCAmelCase : Dict = model( __UpperCAmelCase, bbox=__UpperCAmelCase, pixel_values=__UpperCAmelCase, attention_mask=__UpperCAmelCase, token_type_ids=__UpperCAmelCase, start_positions=__UpperCAmelCase, end_positions=__UpperCAmelCase, training=__UpperCAmelCase, ) 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 __magic_name__ ( self : Tuple ): UpperCAmelCase : List[Any] = self.prepare_config_and_inputs() ((UpperCAmelCase) , (UpperCAmelCase) , (UpperCAmelCase) , (UpperCAmelCase) , (UpperCAmelCase) , (UpperCAmelCase) , (UpperCAmelCase) , (UpperCAmelCase)) : Optional[Any] = config_and_inputs UpperCAmelCase : Dict = { '''input_ids''': input_ids, '''bbox''': bbox, '''pixel_values''': pixel_values, '''token_type_ids''': token_type_ids, '''attention_mask''': input_mask, } return config, inputs_dict @require_tf class __UpperCAmelCase ( UpperCAmelCase_ , UpperCAmelCase_ , unittest.TestCase ): UpperCamelCase = ( ( TFLayoutLMvaModel, TFLayoutLMvaForQuestionAnswering, TFLayoutLMvaForSequenceClassification, TFLayoutLMvaForTokenClassification, ) if is_tf_available() else () ) UpperCamelCase = ( {'document-question-answering': TFLayoutLMvaForQuestionAnswering, 'feature-extraction': TFLayoutLMvaModel} if is_tf_available() else {} ) UpperCamelCase = False UpperCamelCase = False UpperCamelCase = False def __magic_name__ ( self : int, __A : Any, __A : Tuple, __A : int, __A : Optional[Any], __A : int ): return True def __magic_name__ ( self : str, __A : Union[str, Any], __A : Optional[Any], __A : List[str]=False ): UpperCAmelCase : int = copy.deepcopy(__UpperCAmelCase ) if model_class in get_values(__UpperCAmelCase ): UpperCAmelCase : int = { k: tf.tile(tf.expand_dims(__UpperCAmelCase, 1 ), (1, self.model_tester.num_choices) + (1,) * (v.ndim - 1) ) if isinstance(__UpperCAmelCase, tf.Tensor ) and v.ndim > 0 else v for k, v in inputs_dict.items() } if return_labels: if model_class in get_values(__UpperCAmelCase ): UpperCAmelCase : Dict = tf.ones(self.model_tester.batch_size, dtype=tf.intaa ) elif model_class in get_values(__UpperCAmelCase ): UpperCAmelCase : List[str] = tf.zeros(self.model_tester.batch_size, dtype=tf.intaa ) UpperCAmelCase : str = tf.zeros(self.model_tester.batch_size, dtype=tf.intaa ) elif model_class in get_values(__UpperCAmelCase ): UpperCAmelCase : str = tf.zeros(self.model_tester.batch_size, dtype=tf.intaa ) elif model_class in get_values(__UpperCAmelCase ): UpperCAmelCase : Dict = tf.zeros( (self.model_tester.batch_size, self.model_tester.text_seq_length), dtype=tf.intaa ) return inputs_dict def __magic_name__ ( self : int ): UpperCAmelCase : Dict = TFLayoutLMvaModelTester(self ) UpperCAmelCase : Optional[int] = ConfigTester(self, config_class=__UpperCAmelCase, hidden_size=3_7 ) def __magic_name__ ( self : Tuple ): self.config_tester.run_common_tests() def __magic_name__ ( self : Union[str, Any] ): UpperCAmelCase , UpperCAmelCase : Dict = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: UpperCAmelCase : str = model_class(__UpperCAmelCase ) if getattr(__UpperCAmelCase, '''hf_compute_loss''', __UpperCAmelCase ): # The number of elements in the loss should be the same as the number of elements in the label UpperCAmelCase : Optional[int] = self._prepare_for_class(inputs_dict.copy(), __UpperCAmelCase, return_labels=__UpperCAmelCase ) UpperCAmelCase : Union[str, Any] = prepared_for_class[ sorted(prepared_for_class.keys() - inputs_dict.keys(), reverse=__UpperCAmelCase )[0] ] UpperCAmelCase : Tuple = added_label.shape.as_list()[:1] # Test that model correctly compute the loss with kwargs UpperCAmelCase : Dict = self._prepare_for_class(inputs_dict.copy(), __UpperCAmelCase, return_labels=__UpperCAmelCase ) UpperCAmelCase : Tuple = prepared_for_class.pop('''input_ids''' ) UpperCAmelCase : Union[str, Any] = model(__UpperCAmelCase, **__UpperCAmelCase )[0] self.assertTrue(loss.shape.as_list() == expected_loss_size or loss.shape.as_list() == [1] ) # Test that model correctly compute the loss when we mask some positions UpperCAmelCase : Union[str, Any] = self._prepare_for_class(inputs_dict.copy(), __UpperCAmelCase, return_labels=__UpperCAmelCase ) UpperCAmelCase : str = prepared_for_class.pop('''input_ids''' ) if "labels" in prepared_for_class: UpperCAmelCase : Any = prepared_for_class['''labels'''].numpy() if len(labels.shape ) > 1 and labels.shape[1] != 1: UpperCAmelCase : str = -1_0_0 UpperCAmelCase : Union[str, Any] = tf.convert_to_tensor(__UpperCAmelCase ) UpperCAmelCase : int = model(__UpperCAmelCase, **__UpperCAmelCase )[0] self.assertTrue(loss.shape.as_list() == expected_loss_size or loss.shape.as_list() == [1] ) self.assertTrue(not np.any(np.isnan(loss.numpy() ) ) ) # Test that model correctly compute the loss with a dict UpperCAmelCase : Dict = self._prepare_for_class(inputs_dict.copy(), __UpperCAmelCase, return_labels=__UpperCAmelCase ) UpperCAmelCase : int = model(__UpperCAmelCase )[0] self.assertTrue(loss.shape.as_list() == expected_loss_size or loss.shape.as_list() == [1] ) # Test that model correctly compute the loss with a tuple UpperCAmelCase : Optional[Any] = self._prepare_for_class(inputs_dict.copy(), __UpperCAmelCase, return_labels=__UpperCAmelCase ) # Get keys that were added with the _prepare_for_class function UpperCAmelCase : Tuple = prepared_for_class.keys() - inputs_dict.keys() UpperCAmelCase : List[str] = inspect.signature(model.call ).parameters UpperCAmelCase : Tuple = list(signature.keys() ) # Create a dictionary holding the location of the tensors in the tuple UpperCAmelCase : Tuple = {0: '''input_ids'''} for label_key in label_keys: UpperCAmelCase : str = signature_names.index(__UpperCAmelCase ) UpperCAmelCase : List[str] = label_key UpperCAmelCase : Dict = sorted(tuple_index_mapping.items() ) # Initialize a list with their default values, update the values and convert to a tuple UpperCAmelCase : Union[str, Any] = [] for name in signature_names: if name != "kwargs": list_input.append(signature[name].default ) for index, value in sorted_tuple_index_mapping: UpperCAmelCase : Tuple = prepared_for_class[value] UpperCAmelCase : int = tuple(__UpperCAmelCase ) # Send to model UpperCAmelCase : Union[str, Any] = model(tuple_input[:-1] )[0] self.assertTrue(loss.shape.as_list() == expected_loss_size or loss.shape.as_list() == [1] ) def __magic_name__ ( self : Optional[int] ): ( ( UpperCAmelCase ) , ( UpperCAmelCase ) , ( UpperCAmelCase ) , ( UpperCAmelCase ) , ( UpperCAmelCase ) , ( UpperCAmelCase ) , ( UpperCAmelCase ) , ( UpperCAmelCase ) , ) : Any = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_model(__UpperCAmelCase, __UpperCAmelCase, __UpperCAmelCase, __UpperCAmelCase, __UpperCAmelCase, __UpperCAmelCase ) def __magic_name__ ( self : Union[str, Any] ): ( ( UpperCAmelCase ) , ( UpperCAmelCase ) , ( UpperCAmelCase ) , ( UpperCAmelCase ) , ( UpperCAmelCase ) , ( UpperCAmelCase ) , ( UpperCAmelCase ) , ( UpperCAmelCase ) , ) : str = self.model_tester.prepare_config_and_inputs() for type in ["absolute", "relative_key", "relative_key_query"]: UpperCAmelCase : Tuple = type self.model_tester.create_and_check_model(__UpperCAmelCase, __UpperCAmelCase, __UpperCAmelCase, __UpperCAmelCase, __UpperCAmelCase, __UpperCAmelCase ) def __magic_name__ ( self : Optional[int] ): ( ( UpperCAmelCase ) , ( UpperCAmelCase ) , ( UpperCAmelCase ) , ( UpperCAmelCase ) , ( UpperCAmelCase ) , ( UpperCAmelCase ) , ( UpperCAmelCase ) , ( UpperCAmelCase ) , ) : List[str] = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_for_sequence_classification( __UpperCAmelCase, __UpperCAmelCase, __UpperCAmelCase, __UpperCAmelCase, __UpperCAmelCase, __UpperCAmelCase, __UpperCAmelCase ) def __magic_name__ ( self : List[Any] ): ( ( UpperCAmelCase ) , ( UpperCAmelCase ) , ( UpperCAmelCase ) , ( UpperCAmelCase ) , ( UpperCAmelCase ) , ( UpperCAmelCase ) , ( UpperCAmelCase ) , ( UpperCAmelCase ) , ) : List[str] = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_for_token_classification( __UpperCAmelCase, __UpperCAmelCase, __UpperCAmelCase, __UpperCAmelCase, __UpperCAmelCase, __UpperCAmelCase, __UpperCAmelCase ) def __magic_name__ ( self : int ): ( ( UpperCAmelCase ) , ( UpperCAmelCase ) , ( UpperCAmelCase ) , ( UpperCAmelCase ) , ( UpperCAmelCase ) , ( UpperCAmelCase ) , ( UpperCAmelCase ) , ( UpperCAmelCase ) , ) : Dict = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_for_question_answering( __UpperCAmelCase, __UpperCAmelCase, __UpperCAmelCase, __UpperCAmelCase, __UpperCAmelCase, __UpperCAmelCase, __UpperCAmelCase ) @slow def __magic_name__ ( self : Any ): for model_name in TF_LAYOUTLMV3_PRETRAINED_MODEL_ARCHIVE_LIST[:1]: UpperCAmelCase : Union[str, Any] = TFLayoutLMvaModel.from_pretrained(__UpperCAmelCase ) self.assertIsNotNone(__UpperCAmelCase ) def a__ ( ) -> int: UpperCAmelCase : Any = Image.open('''./tests/fixtures/tests_samples/COCO/000000039769.png''' ) return image @require_tf class __UpperCAmelCase ( unittest.TestCase ): @cached_property def __magic_name__ ( self : int ): return LayoutLMvaImageProcessor(apply_ocr=__UpperCAmelCase ) if is_vision_available() else None @slow def __magic_name__ ( self : Tuple ): UpperCAmelCase : Optional[Any] = TFLayoutLMvaModel.from_pretrained('''microsoft/layoutlmv3-base''' ) UpperCAmelCase : Dict = self.default_image_processor UpperCAmelCase : List[Any] = prepare_img() UpperCAmelCase : Any = image_processor(images=__UpperCAmelCase, return_tensors='''tf''' ).pixel_values UpperCAmelCase : Optional[Any] = tf.constant([[1, 2]] ) UpperCAmelCase : Optional[Any] = tf.expand_dims(tf.constant([[1, 2, 3, 4], [5, 6, 7, 8]] ), axis=0 ) # forward pass UpperCAmelCase : Optional[Any] = model(input_ids=__UpperCAmelCase, bbox=__UpperCAmelCase, pixel_values=__UpperCAmelCase, training=__UpperCAmelCase ) # verify the logits UpperCAmelCase : int = (1, 1_9_9, 7_6_8) self.assertEqual(outputs.last_hidden_state.shape, __UpperCAmelCase ) UpperCAmelCase : Tuple = tf.constant( [[-0.0_5_2_9, 0.3_6_1_8, 0.1_6_3_2], [-0.1_5_8_7, -0.1_6_6_7, -0.0_4_0_0], [-0.1_5_5_7, -0.1_6_7_1, -0.0_5_0_5]] ) self.assertTrue(np.allclose(outputs.last_hidden_state[0, :3, :3], __UpperCAmelCase, atol=1E-4 ) )
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import os import tempfile import unittest from transformers.models.marian.convert_marian_tatoeba_to_pytorch import DEFAULT_REPO, TatoebaConverter from transformers.testing_utils import slow from transformers.utils import cached_property @unittest.skipUnless(os.path.exists(UpperCAmelCase_ ) , 'Tatoeba directory does not exist.' ) class A ( unittest.TestCase ): @cached_property def lowercase_ (self : Optional[int] ) -> List[Any]: """simple docstring""" UpperCAmelCase__ = tempfile.mkdtemp() return TatoebaConverter(save_dir=__UpperCAmelCase ) @slow def lowercase_ (self : List[Any] ) -> Optional[int]: """simple docstring""" self.resolver.convert_models(["heb-eng"] ) @slow def lowercase_ (self : Dict ) -> List[str]: """simple docstring""" UpperCAmelCase__ , UpperCAmelCase__ = self.resolver.write_model_card("opus-mt-he-en" , dry_run=__UpperCAmelCase ) assert mmeta["long_pair"] == "heb-eng"
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"""simple docstring""" from numpy import exp, pi, sqrt def _lowerCamelCase( a , a = 0.0 , a = 1.0 ): return 1 / sqrt(2 * pi * sigma**2 ) * exp(-((x - mu) ** 2) / (2 * sigma**2) ) if __name__ == "__main__": import doctest doctest.testmod()
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import numpy as np import skfuzzy as fuzz if __name__ == "__main__": # Create universe of discourse in Python using linspace () UpperCamelCase__ = np.linspace(start=0, stop=7_5, num=7_5, endpoint=True, retstep=False) # Create two fuzzy sets by defining any membership function # (trapmf(), gbellmf(), gaussmf(), etc). UpperCamelCase__ = [0, 2_5, 5_0] UpperCamelCase__ = [2_5, 5_0, 7_5] UpperCamelCase__ = fuzz.membership.trimf(X, abca) UpperCamelCase__ = fuzz.membership.trimf(X, abca) # Compute the different operations using inbuilt functions. UpperCamelCase__ = np.ones(7_5) UpperCamelCase__ = np.zeros((7_5,)) # 1. Union = max(µA(x), µB(x)) UpperCamelCase__ = fuzz.fuzzy_or(X, young, X, middle_aged)[1] # 2. Intersection = min(µA(x), µB(x)) UpperCamelCase__ = fuzz.fuzzy_and(X, young, X, middle_aged)[1] # 3. Complement (A) = (1- min(µA(x)) UpperCamelCase__ = fuzz.fuzzy_not(young) # 4. Difference (A/B) = min(µA(x),(1- µB(x))) UpperCamelCase__ = fuzz.fuzzy_and(X, young, X, fuzz.fuzzy_not(middle_aged)[1])[1] # 5. Algebraic Sum = [µA(x) + µB(x) – (µA(x) * µB(x))] UpperCamelCase__ = young + middle_aged - (young * middle_aged) # 6. Algebraic Product = (µA(x) * µB(x)) UpperCamelCase__ = young * middle_aged # 7. Bounded Sum = min[1,(µA(x), µB(x))] UpperCamelCase__ = fuzz.fuzzy_and(X, one, X, young + middle_aged)[1] # 8. Bounded difference = min[0,(µA(x), µB(x))] UpperCamelCase__ = fuzz.fuzzy_or(X, zero, X, young - middle_aged)[1] # max-min composition # max-product composition # Plot each set A, set B and each operation result using plot() and subplot(). from matplotlib import pyplot as plt plt.figure() plt.subplot(4, 3, 1) plt.plot(X, young) plt.title('Young') plt.grid(True) plt.subplot(4, 3, 2) plt.plot(X, middle_aged) plt.title('Middle aged') plt.grid(True) plt.subplot(4, 3, 3) plt.plot(X, union) plt.title('union') plt.grid(True) plt.subplot(4, 3, 4) plt.plot(X, intersection) plt.title('intersection') plt.grid(True) plt.subplot(4, 3, 5) plt.plot(X, complement_a) plt.title('complement_a') plt.grid(True) plt.subplot(4, 3, 6) plt.plot(X, difference) plt.title('difference a/b') plt.grid(True) plt.subplot(4, 3, 7) plt.plot(X, alg_sum) plt.title('alg_sum') plt.grid(True) plt.subplot(4, 3, 8) plt.plot(X, alg_product) plt.title('alg_product') plt.grid(True) plt.subplot(4, 3, 9) plt.plot(X, bdd_sum) plt.title('bdd_sum') plt.grid(True) plt.subplot(4, 3, 1_0) plt.plot(X, bdd_difference) plt.title('bdd_difference') plt.grid(True) plt.subplots_adjust(hspace=0.5) plt.show()
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"""simple docstring""" import logging import os from .state import PartialState class UpperCamelCase ( logging.LoggerAdapter ): @staticmethod def _lowercase ( UpperCAmelCase__ : Dict ) -> Optional[Any]: _a : Tuple = PartialState() return not main_process_only or (main_process_only and state.is_main_process) def _lowercase ( self : Union[str, Any] , UpperCAmelCase__ : int , UpperCAmelCase__ : Optional[int] , *UpperCAmelCase__ : str , **UpperCAmelCase__ : Union[str, Any] ) -> List[str]: if PartialState._shared_state == {}: raise RuntimeError( """You must initialize the accelerate state by calling either `PartialState()` or `Accelerator()` before using the logging utility.""" ) _a : Dict = kwargs.pop("""main_process_only""" , __UpperCAmelCase ) _a : str = kwargs.pop("""in_order""" , __UpperCAmelCase ) if self.isEnabledFor(__UpperCAmelCase ): if self._should_log(__UpperCAmelCase ): _a , _a : Optional[Any] = self.process(__UpperCAmelCase , __UpperCAmelCase ) self.logger.log(__UpperCAmelCase , __UpperCAmelCase , *__UpperCAmelCase , **__UpperCAmelCase ) elif in_order: _a : str = PartialState() for i in range(state.num_processes ): if i == state.process_index: _a , _a : List[Any] = self.process(__UpperCAmelCase , __UpperCAmelCase ) self.logger.log(__UpperCAmelCase , __UpperCAmelCase , *__UpperCAmelCase , **__UpperCAmelCase ) state.wait_for_everyone() def lowerCAmelCase__ ( UpperCamelCase__ , UpperCamelCase__ = None ): '''simple docstring''' if log_level is None: _a : List[str] = os.environ.get("""ACCELERATE_LOG_LEVEL""" , __A ) _a : Optional[Any] = logging.getLogger(__A ) if log_level is not None: logger.setLevel(log_level.upper() ) logger.root.setLevel(log_level.upper() ) return MultiProcessAdapter(__A , {} )
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from __future__ import annotations from collections import deque class A : def __init__(self : Dict , __UpperCAmelCase : list[str] ) -> Optional[int]: """simple docstring""" UpperCAmelCase__ = [] self.adlist.append( {"value": "", "next_states": [], "fail_state": 0, "output": []} ) for keyword in keywords: self.add_keyword(__UpperCAmelCase ) self.set_fail_transitions() def lowercase_ (self : Tuple , __UpperCAmelCase : int , __UpperCAmelCase : str ) -> int | None: """simple docstring""" for state in self.adlist[current_state]["next_states"]: if char == self.adlist[state]["value"]: return state return None def lowercase_ (self : Dict , __UpperCAmelCase : str ) -> None: """simple docstring""" UpperCAmelCase__ = 0 for character in keyword: UpperCAmelCase__ = self.find_next_state(__UpperCAmelCase , __UpperCAmelCase ) if next_state is None: self.adlist.append( { "value": character, "next_states": [], "fail_state": 0, "output": [], } ) self.adlist[current_state]["next_states"].append(len(self.adlist ) - 1 ) UpperCAmelCase__ = len(self.adlist ) - 1 else: UpperCAmelCase__ = next_state self.adlist[current_state]["output"].append(__UpperCAmelCase ) def lowercase_ (self : Optional[int] ) -> None: """simple docstring""" UpperCAmelCase__ = deque() for node in self.adlist[0]["next_states"]: q.append(__UpperCAmelCase ) UpperCAmelCase__ = 0 while q: UpperCAmelCase__ = q.popleft() for child in self.adlist[r]["next_states"]: q.append(__UpperCAmelCase ) UpperCAmelCase__ = self.adlist[r]["fail_state"] while ( self.find_next_state(__UpperCAmelCase , self.adlist[child]["value"] ) is None and state != 0 ): UpperCAmelCase__ = self.adlist[state]["fail_state"] UpperCAmelCase__ = self.find_next_state( __UpperCAmelCase , self.adlist[child]["value"] ) if self.adlist[child]["fail_state"] is None: UpperCAmelCase__ = 0 UpperCAmelCase__ = ( self.adlist[child]["output"] + self.adlist[self.adlist[child]["fail_state"]]["output"] ) def lowercase_ (self : Union[str, Any] , __UpperCAmelCase : str ) -> dict[str, list[int]]: """simple docstring""" UpperCAmelCase__ = {} # returns a dict with keywords and list of its occurrences UpperCAmelCase__ = 0 for i in range(len(__UpperCAmelCase ) ): while ( self.find_next_state(__UpperCAmelCase , string[i] ) is None and current_state != 0 ): UpperCAmelCase__ = self.adlist[current_state]["fail_state"] UpperCAmelCase__ = self.find_next_state(__UpperCAmelCase , string[i] ) if next_state is None: UpperCAmelCase__ = 0 else: UpperCAmelCase__ = next_state for key in self.adlist[current_state]["output"]: if key not in result: UpperCAmelCase__ = [] result[key].append(i - len(__UpperCAmelCase ) + 1 ) return result if __name__ == "__main__": import doctest doctest.testmod()
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"""simple docstring""" from __future__ import annotations def UpperCAmelCase__ (snake_case__ : Any = 4 ): """simple docstring""" _snake_case : int = abs(__A ) or 4 return [[1 + x + y * row_size for x in range(__A )] for y in range(__A )] def UpperCAmelCase__ (snake_case__ : Union[str, Any] ): """simple docstring""" return reverse_row(transpose(__A ) ) # OR.. transpose(reverse_column(matrix)) def UpperCAmelCase__ (snake_case__ : Optional[Any] ): """simple docstring""" return reverse_row(reverse_column(__A ) ) # OR.. reverse_column(reverse_row(matrix)) def UpperCAmelCase__ (snake_case__ : Dict ): """simple docstring""" return reverse_column(transpose(__A ) ) # OR.. transpose(reverse_row(matrix)) def UpperCAmelCase__ (snake_case__ : Any ): """simple docstring""" _snake_case : Optional[Any] = [list(__A ) for x in zip(*__A )] return matrix def UpperCAmelCase__ (snake_case__ : Optional[int] ): """simple docstring""" _snake_case : List[str] = matrix[::-1] return matrix def UpperCAmelCase__ (snake_case__ : Dict ): """simple docstring""" _snake_case : str = [x[::-1] for x in matrix] return matrix def UpperCAmelCase__ (snake_case__ : List[str] ): """simple docstring""" for i in matrix: print(*__A ) if __name__ == "__main__": A_ = make_matrix() print('''\norigin:\n''') print_matrix(matrix) print('''\nrotate 90 counterclockwise:\n''') print_matrix(rotate_aa(matrix)) A_ = make_matrix() print('''\norigin:\n''') print_matrix(matrix) print('''\nrotate 180:\n''') print_matrix(rotate_aaa(matrix)) A_ = make_matrix() print('''\norigin:\n''') print_matrix(matrix) print('''\nrotate 270 counterclockwise:\n''') print_matrix(rotate_aaa(matrix))
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import warnings from typing import Any, Dict, List, Optional, Union import numpy as np from ...audio_utils import mel_filter_bank, optimal_fft_length, spectrogram, window_function from ...feature_extraction_sequence_utils import SequenceFeatureExtractor from ...feature_extraction_utils import BatchFeature from ...utils import PaddingStrategy, TensorType, logging UpperCamelCase__ = logging.get_logger(__name__) class A ( UpperCAmelCase_ ): __UpperCAmelCase : int = ['input_values', 'attention_mask'] def __init__(self : Any , __UpperCAmelCase : int = 1 , __UpperCAmelCase : int = 1_6_0_0_0 , __UpperCAmelCase : float = 0.0 , __UpperCAmelCase : bool = False , __UpperCAmelCase : int = 8_0 , __UpperCAmelCase : int = 1_6 , __UpperCAmelCase : int = 6_4 , __UpperCAmelCase : str = "hann_window" , __UpperCAmelCase : float = 1.0 , __UpperCAmelCase : float = 8_0 , __UpperCAmelCase : float = 7_6_0_0 , __UpperCAmelCase : float = 1E-10 , __UpperCAmelCase : int = 2 , __UpperCAmelCase : bool = True , **__UpperCAmelCase : Any , ) -> str: """simple docstring""" super().__init__(feature_size=__UpperCAmelCase , sampling_rate=__UpperCAmelCase , padding_value=__UpperCAmelCase , **__UpperCAmelCase ) UpperCAmelCase__ = do_normalize UpperCAmelCase__ = return_attention_mask UpperCAmelCase__ = num_mel_bins UpperCAmelCase__ = hop_length UpperCAmelCase__ = win_length UpperCAmelCase__ = win_function UpperCAmelCase__ = frame_signal_scale UpperCAmelCase__ = fmin UpperCAmelCase__ = fmax UpperCAmelCase__ = mel_floor UpperCAmelCase__ = reduction_factor UpperCAmelCase__ = win_length * sampling_rate // 1_0_0_0 UpperCAmelCase__ = hop_length * sampling_rate // 1_0_0_0 UpperCAmelCase__ = optimal_fft_length(self.sample_size ) UpperCAmelCase__ = (self.n_fft // 2) + 1 UpperCAmelCase__ = window_function(window_length=self.sample_size , name=self.win_function , periodic=__UpperCAmelCase ) UpperCAmelCase__ = mel_filter_bank( num_frequency_bins=self.n_freqs , num_mel_filters=self.num_mel_bins , min_frequency=self.fmin , max_frequency=self.fmax , sampling_rate=self.sampling_rate , norm="slaney" , mel_scale="slaney" , ) if frame_signal_scale != 1.0: warnings.warn( "The argument `frame_signal_scale` is deprecated and will be removed in version 4.30.0 of Transformers" , __UpperCAmelCase , ) if reduction_factor != 2.0: warnings.warn( "The argument `reduction_factor` is deprecated and will be removed in version 4.30.0 of Transformers" , __UpperCAmelCase , ) @staticmethod # Copied from transformers.models.wav2vec2.feature_extraction_wav2vec2.Wav2Vec2FeatureExtractor.zero_mean_unit_var_norm def lowercase_ (__UpperCAmelCase : List[np.ndarray] , __UpperCAmelCase : List[np.ndarray] , __UpperCAmelCase : float = 0.0 ) -> List[np.ndarray]: """simple docstring""" if attention_mask is not None: UpperCAmelCase__ = np.array(__UpperCAmelCase , np.intaa ) UpperCAmelCase__ = [] for vector, length in zip(__UpperCAmelCase , attention_mask.sum(-1 ) ): UpperCAmelCase__ = (vector - vector[:length].mean()) / np.sqrt(vector[:length].var() + 1E-7 ) if length < normed_slice.shape[0]: UpperCAmelCase__ = padding_value normed_input_values.append(__UpperCAmelCase ) else: UpperCAmelCase__ = [(x - x.mean()) / np.sqrt(x.var() + 1E-7 ) for x in input_values] return normed_input_values def lowercase_ (self : Optional[int] , __UpperCAmelCase : np.ndarray , ) -> np.ndarray: """simple docstring""" UpperCAmelCase__ = spectrogram( __UpperCAmelCase , window=self.window , frame_length=self.sample_size , hop_length=self.sample_stride , fft_length=self.n_fft , mel_filters=self.mel_filters , mel_floor=self.mel_floor , log_mel="log10" , ) return log_mel_spec.T def __call__(self : Any , __UpperCAmelCase : Optional[Union[np.ndarray, List[float], List[np.ndarray], List[List[float]]]] = None , __UpperCAmelCase : Optional[Union[np.ndarray, List[float], List[np.ndarray], List[List[float]]]] = None , __UpperCAmelCase : Union[bool, str, PaddingStrategy] = False , __UpperCAmelCase : Optional[int] = None , __UpperCAmelCase : bool = False , __UpperCAmelCase : Optional[int] = None , __UpperCAmelCase : Optional[bool] = None , __UpperCAmelCase : Optional[Union[str, TensorType]] = None , __UpperCAmelCase : Optional[int] = None , **__UpperCAmelCase : str , ) -> BatchFeature: """simple docstring""" if audio is None and audio_target is None: raise ValueError("You must provide either `audio` or `audio_target` values." ) if sampling_rate is not None: if sampling_rate != self.sampling_rate: raise ValueError( f"""The model corresponding to this feature extractor: {self} was trained using a sampling rate of""" f""" {self.sampling_rate}. Please make sure that the provided audio input was sampled with""" f""" {self.sampling_rate} and not {sampling_rate}.""" ) else: logger.warning( "It is strongly recommended to pass the ``sampling_rate`` argument to this function. " "Failing to do so can result in silent errors that might be hard to debug." ) if audio is not None: UpperCAmelCase__ = self._process_audio( __UpperCAmelCase , __UpperCAmelCase , __UpperCAmelCase , __UpperCAmelCase , __UpperCAmelCase , __UpperCAmelCase , __UpperCAmelCase , __UpperCAmelCase , **__UpperCAmelCase , ) else: UpperCAmelCase__ = None if audio_target is not None: UpperCAmelCase__ = self._process_audio( __UpperCAmelCase , __UpperCAmelCase , __UpperCAmelCase , __UpperCAmelCase , __UpperCAmelCase , __UpperCAmelCase , __UpperCAmelCase , __UpperCAmelCase , **__UpperCAmelCase , ) if inputs is None: return inputs_target else: UpperCAmelCase__ = inputs_target["input_values"] UpperCAmelCase__ = inputs_target.get("attention_mask" ) if decoder_attention_mask is not None: UpperCAmelCase__ = decoder_attention_mask return inputs def lowercase_ (self : Optional[int] , __UpperCAmelCase : Union[np.ndarray, List[float], List[np.ndarray], List[List[float]]] , __UpperCAmelCase : bool = False , __UpperCAmelCase : Union[bool, str, PaddingStrategy] = False , __UpperCAmelCase : Optional[int] = None , __UpperCAmelCase : bool = False , __UpperCAmelCase : Optional[int] = None , __UpperCAmelCase : Optional[bool] = None , __UpperCAmelCase : Optional[Union[str, TensorType]] = None , **__UpperCAmelCase : Any , ) -> BatchFeature: """simple docstring""" UpperCAmelCase__ = isinstance(__UpperCAmelCase , np.ndarray ) and len(speech.shape ) > 1 if is_batched_numpy and len(speech.shape ) > 2: raise ValueError(f"""Only mono-channel audio is supported for input to {self}""" ) UpperCAmelCase__ = is_batched_numpy or ( isinstance(__UpperCAmelCase , (list, tuple) ) and (isinstance(speech[0] , (np.ndarray, tuple, list) )) ) if is_batched: UpperCAmelCase__ = [np.asarray(__UpperCAmelCase , dtype=np.floataa ) for speech in speech] elif not is_batched and not isinstance(__UpperCAmelCase , np.ndarray ): UpperCAmelCase__ = np.asarray(__UpperCAmelCase , dtype=np.floataa ) elif isinstance(__UpperCAmelCase , np.ndarray ) and speech.dtype is np.dtype(np.floataa ): UpperCAmelCase__ = speech.astype(np.floataa ) # always return batch if not is_batched: UpperCAmelCase__ = [speech] # needed to make pad() work on spectrogram inputs UpperCAmelCase__ = self.feature_size # convert into correct format for padding if is_target: UpperCAmelCase__ = [self._extract_mel_features(__UpperCAmelCase ) for waveform in speech] UpperCAmelCase__ = BatchFeature({"input_values": features} ) UpperCAmelCase__ = self.num_mel_bins else: UpperCAmelCase__ = BatchFeature({"input_values": speech} ) UpperCAmelCase__ = self.pad( __UpperCAmelCase , padding=__UpperCAmelCase , max_length=__UpperCAmelCase , truncation=__UpperCAmelCase , pad_to_multiple_of=__UpperCAmelCase , return_attention_mask=__UpperCAmelCase , **__UpperCAmelCase , ) UpperCAmelCase__ = feature_size_hack # convert input values to correct format UpperCAmelCase__ = padded_inputs["input_values"] if not isinstance(input_values[0] , np.ndarray ): UpperCAmelCase__ = [np.asarray(__UpperCAmelCase , dtype=np.floataa ) for array in input_values] elif ( not isinstance(__UpperCAmelCase , np.ndarray ) and isinstance(input_values[0] , np.ndarray ) and input_values[0].dtype is np.dtype(np.floataa ) ): UpperCAmelCase__ = [array.astype(np.floataa ) for array in input_values] elif isinstance(__UpperCAmelCase , np.ndarray ) and input_values.dtype is np.dtype(np.floataa ): UpperCAmelCase__ = input_values.astype(np.floataa ) # convert attention_mask to correct format UpperCAmelCase__ = padded_inputs.get("attention_mask" ) if attention_mask is not None: UpperCAmelCase__ = [np.asarray(__UpperCAmelCase , dtype=np.intaa ) for array in attention_mask] # zero-mean and unit-variance normalization if not is_target and self.do_normalize: UpperCAmelCase__ = ( attention_mask if self._get_padding_strategies(__UpperCAmelCase , max_length=__UpperCAmelCase ) is not PaddingStrategy.DO_NOT_PAD else None ) UpperCAmelCase__ = self.zero_mean_unit_var_norm( padded_inputs["input_values"] , attention_mask=__UpperCAmelCase , padding_value=self.padding_value ) if return_tensors is not None: UpperCAmelCase__ = padded_inputs.convert_to_tensors(__UpperCAmelCase ) return padded_inputs def lowercase_ (self : Tuple ) -> Dict[str, Any]: """simple docstring""" UpperCAmelCase__ = super().to_dict() # Don't serialize these as they are derived from the other properties. UpperCAmelCase__ = ["window", "mel_filters", "sample_size", "sample_stride", "n_fft", "n_freqs"] for name in names: if name in output: del output[name] return output
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"""simple docstring""" from bisect import bisect from itertools import accumulate def __magic_name__ ( __snake_case : Optional[Any] , __snake_case : Union[str, Any] , __snake_case : List[str] , __snake_case : Tuple ) -> Union[str, Any]: lowercase : Optional[Any] = sorted(zip(__A , __A ) , key=lambda __snake_case : x[0] / x[1] , reverse=__A ) lowercase , lowercase : Union[str, Any] = [i[0] for i in r], [i[1] for i in r] lowercase : Tuple = list(accumulate(__A ) ) lowercase : List[str] = bisect(__A , __A ) return ( 0 if k == 0 else sum(vl[:k] ) + (w - acc[k - 1]) * (vl[k]) / (wt[k]) if k != n else sum(vl[:k] ) ) if __name__ == "__main__": import doctest doctest.testmod()
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from dataclasses import dataclass from typing import Optional, Tuple import torch from torch import nn from transformers import RobertaPreTrainedModel, XLMRobertaConfig, XLMRobertaModel from transformers.utils import ModelOutput @dataclass class A ( UpperCAmelCase_ ): __UpperCAmelCase : Optional[torch.FloatTensor] = None __UpperCAmelCase : torch.FloatTensor = None __UpperCAmelCase : Optional[Tuple[torch.FloatTensor]] = None __UpperCAmelCase : Optional[Tuple[torch.FloatTensor]] = None class A ( UpperCAmelCase_ ): def __init__(self : Union[str, Any] , __UpperCAmelCase : Tuple=1 , __UpperCAmelCase : str=0 , __UpperCAmelCase : str=2 , __UpperCAmelCase : Union[str, Any]=5_1_2 , __UpperCAmelCase : List[str]="cls" , __UpperCAmelCase : Optional[int]=False , __UpperCAmelCase : str=True , **__UpperCAmelCase : str , ) -> int: """simple docstring""" super().__init__(pad_token_id=__UpperCAmelCase , bos_token_id=__UpperCAmelCase , eos_token_id=__UpperCAmelCase , **__UpperCAmelCase ) UpperCAmelCase__ = project_dim UpperCAmelCase__ = pooler_fn UpperCAmelCase__ = learn_encoder UpperCAmelCase__ = use_attention_mask class A ( UpperCAmelCase_ ): __UpperCAmelCase : Tuple = [r'pooler', r'logit_scale'] __UpperCAmelCase : int = [r'position_ids', r'predictions.decoder.bias'] __UpperCAmelCase : Any = 'roberta' __UpperCAmelCase : List[str] = RobertaSeriesConfig def __init__(self : Tuple , __UpperCAmelCase : Optional[int] ) -> int: """simple docstring""" super().__init__(__UpperCAmelCase ) UpperCAmelCase__ = XLMRobertaModel(__UpperCAmelCase ) UpperCAmelCase__ = nn.Linear(config.hidden_size , config.project_dim ) UpperCAmelCase__ = getattr(__UpperCAmelCase , "has_pre_transformation" , __UpperCAmelCase ) if self.has_pre_transformation: UpperCAmelCase__ = nn.Linear(config.hidden_size , config.project_dim ) UpperCAmelCase__ = nn.LayerNorm(config.hidden_size , eps=config.layer_norm_eps ) self.post_init() def lowercase_ (self : Optional[Any] , __UpperCAmelCase : Optional[torch.Tensor] = None , __UpperCAmelCase : Optional[torch.Tensor] = None , __UpperCAmelCase : Optional[torch.Tensor] = None , __UpperCAmelCase : Optional[torch.Tensor] = None , __UpperCAmelCase : Optional[torch.Tensor] = None , __UpperCAmelCase : Optional[torch.Tensor] = None , __UpperCAmelCase : Optional[torch.Tensor] = None , __UpperCAmelCase : Optional[torch.Tensor] = None , __UpperCAmelCase : Optional[bool] = None , __UpperCAmelCase : Optional[bool] = None , __UpperCAmelCase : Optional[bool] = None , ) -> Optional[int]: """simple docstring""" UpperCAmelCase__ = return_dict if return_dict is not None else self.config.use_return_dict UpperCAmelCase__ = self.base_model( input_ids=__UpperCAmelCase , attention_mask=__UpperCAmelCase , token_type_ids=__UpperCAmelCase , position_ids=__UpperCAmelCase , head_mask=__UpperCAmelCase , inputs_embeds=__UpperCAmelCase , encoder_hidden_states=__UpperCAmelCase , encoder_attention_mask=__UpperCAmelCase , output_attentions=__UpperCAmelCase , output_hidden_states=True if self.has_pre_transformation else output_hidden_states , return_dict=__UpperCAmelCase , ) if self.has_pre_transformation: UpperCAmelCase__ = outputs["hidden_states"][-2] UpperCAmelCase__ = self.pre_LN(__UpperCAmelCase ) UpperCAmelCase__ = self.transformation_pre(__UpperCAmelCase ) return TransformationModelOutput( projection_state=__UpperCAmelCase , last_hidden_state=outputs.last_hidden_state , hidden_states=outputs.hidden_states , attentions=outputs.attentions , ) else: UpperCAmelCase__ = self.transformation(outputs.last_hidden_state ) return TransformationModelOutput( projection_state=__UpperCAmelCase , last_hidden_state=outputs.last_hidden_state , hidden_states=outputs.hidden_states , attentions=outputs.attentions , )
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"""simple docstring""" import random import timeit from functools import wraps from typing import Callable, Optional from ..configuration_utils import PretrainedConfig from ..models.auto.modeling_tf_auto import TF_MODEL_MAPPING, TF_MODEL_WITH_LM_HEAD_MAPPING from ..utils import is_pyanvml_available, is_tf_available, logging from .benchmark_utils import ( Benchmark, Memory, MemorySummary, measure_peak_memory_cpu, start_memory_tracing, stop_memory_tracing, ) if is_tf_available(): import tensorflow as tf from tensorflow.python.framework.errors_impl import ResourceExhaustedError from .benchmark_args_tf import TensorFlowBenchmarkArguments if is_pyanvml_available(): import pyanvml.pyanvml as nvml lowerCamelCase_ = logging.get_logger(__name__) def snake_case ( A__ ,A__ ): def run_func(A__ ): @wraps(__A ) def run_in_eager_mode(*A__ ,**A__ ): return func(*__A ,**__A ) @wraps(__A ) @tf.function(experimental_compile=__A ) def run_in_graph_mode(*A__ ,**A__ ): return func(*__A ,**__A ) if do_eager_mode is True: if use_xla is not False: raise ValueError( "Cannot run model in XLA, if `args.eager_mode` is set to `True`. Please set `args.eager_mode=False`." ) return run_in_eager_mode else: return run_in_graph_mode return run_func def snake_case ( A__ ,A__ ,A__ ): UpperCAmelCase_ : Tuple = random.Random() UpperCAmelCase_ : Optional[Any] = [rng.randint(0 ,vocab_size - 1 ) for i in range(batch_size * sequence_length )] return tf.constant(__A ,shape=(batch_size, sequence_length) ,dtype=tf.intaa ) class UpperCamelCase_ (UpperCAmelCase_ ): __magic_name__ = 42 __magic_name__ = 42 __magic_name__ = "TensorFlow" @property def _SCREAMING_SNAKE_CASE ( self : Any ) -> str: return tf.__version__ def _SCREAMING_SNAKE_CASE ( self : Optional[Any] , lowerCAmelCase_ : str , lowerCAmelCase_ : int , lowerCAmelCase_ : int ) -> float: UpperCAmelCase_ : Union[str, Any] = self.args.strategy if strategy is None: raise ValueError("A device strategy has to be initialized before using TensorFlow." ) UpperCAmelCase_ : Tuple = self._prepare_inference_func(__UpperCAmelCase , __UpperCAmelCase , __UpperCAmelCase ) return self._measure_speed(_inference ) def _SCREAMING_SNAKE_CASE ( self : str , lowerCAmelCase_ : str , lowerCAmelCase_ : int , lowerCAmelCase_ : int ) -> float: UpperCAmelCase_ : Any = self.args.strategy if strategy is None: raise ValueError("A device strategy has to be initialized before using TensorFlow." ) UpperCAmelCase_ : int = self._prepare_train_func(__UpperCAmelCase , __UpperCAmelCase , __UpperCAmelCase ) return self._measure_speed(_train ) def _SCREAMING_SNAKE_CASE ( self : Tuple , lowerCAmelCase_ : str , lowerCAmelCase_ : int , lowerCAmelCase_ : int ) -> [Memory, Optional[MemorySummary]]: if self.args.is_gpu: tf.config.experimental.set_memory_growth(self.args.gpu_list[self.args.device_idx] , __UpperCAmelCase ) UpperCAmelCase_ : List[Any] = self.args.strategy if strategy is None: raise ValueError("A device strategy has to be initialized before using TensorFlow." ) UpperCAmelCase_ : Optional[int] = self._prepare_inference_func(__UpperCAmelCase , __UpperCAmelCase , __UpperCAmelCase ) return self._measure_memory(_inference ) def _SCREAMING_SNAKE_CASE ( self : Dict , lowerCAmelCase_ : str , lowerCAmelCase_ : int , lowerCAmelCase_ : int ) -> [Memory, Optional[MemorySummary]]: if self.args.is_gpu: tf.config.experimental.set_memory_growth(self.args.gpu_list[self.args.device_idx] , __UpperCAmelCase ) UpperCAmelCase_ : List[Any] = self.args.strategy if strategy is None: raise ValueError("A device strategy has to be initialized before using TensorFlow." ) UpperCAmelCase_ : Optional[Any] = self._prepare_train_func(__UpperCAmelCase , __UpperCAmelCase , __UpperCAmelCase ) return self._measure_memory(_train ) def _SCREAMING_SNAKE_CASE ( self : Optional[int] , lowerCAmelCase_ : str , lowerCAmelCase_ : int , lowerCAmelCase_ : int ) -> Callable[[], None]: UpperCAmelCase_ : Dict = self.config_dict[model_name] if self.args.fpaa: raise NotImplementedError("Mixed precision is currently not supported." ) UpperCAmelCase_ : int = ( hasattr(__UpperCAmelCase , "architectures" ) and isinstance(config.architectures , __UpperCAmelCase ) and len(config.architectures ) > 0 ) if not self.args.only_pretrain_model and has_model_class_in_config: try: UpperCAmelCase_ : List[Any] = "TF" + config.architectures[0] # prepend 'TF' for tensorflow model UpperCAmelCase_ : Optional[int] = __import__("transformers" , fromlist=[model_class] ) UpperCAmelCase_ : Dict = getattr(__UpperCAmelCase , __UpperCAmelCase ) UpperCAmelCase_ : str = model_cls(__UpperCAmelCase ) except ImportError: raise ImportError( f"""{model_class} does not exist. If you just want to test the pretrained model, you might want to""" " set `--only_pretrain_model` or `args.only_pretrain_model=True`." ) else: UpperCAmelCase_ : List[str] = TF_MODEL_MAPPING[config.__class__](__UpperCAmelCase ) # encoder-decoder has vocab size saved differently UpperCAmelCase_ : List[str] = config.vocab_size if hasattr(__UpperCAmelCase , "vocab_size" ) else config.encoder.vocab_size UpperCAmelCase_ : Any = random_input_ids(__UpperCAmelCase , __UpperCAmelCase , __UpperCAmelCase ) @run_with_tf_optimizations(self.args.eager_mode , self.args.use_xla ) def encoder_decoder_forward(): return model(__UpperCAmelCase , decoder_input_ids=__UpperCAmelCase , training=__UpperCAmelCase ) @run_with_tf_optimizations(self.args.eager_mode , self.args.use_xla ) def encoder_forward(): return model(__UpperCAmelCase , training=__UpperCAmelCase ) UpperCAmelCase_ : Tuple = encoder_decoder_forward if config.is_encoder_decoder else encoder_forward return _inference def _SCREAMING_SNAKE_CASE ( self : List[str] , lowerCAmelCase_ : str , lowerCAmelCase_ : int , lowerCAmelCase_ : int ) -> Callable[[], None]: UpperCAmelCase_ : Union[str, Any] = self.config_dict[model_name] if self.args.eager_mode is not False: raise ValueError("Training cannot be done in eager mode. Please make sure that `args.eager_mode = False`." ) if self.args.fpaa: raise NotImplementedError("Mixed precision is currently not supported." ) UpperCAmelCase_ : int = ( hasattr(__UpperCAmelCase , "architectures" ) and isinstance(config.architectures , __UpperCAmelCase ) and len(config.architectures ) > 0 ) if not self.args.only_pretrain_model and has_model_class_in_config: try: UpperCAmelCase_ : Optional[Any] = "TF" + config.architectures[0] # prepend 'TF' for tensorflow model UpperCAmelCase_ : Dict = __import__("transformers" , fromlist=[model_class] ) UpperCAmelCase_ : List[Any] = getattr(__UpperCAmelCase , __UpperCAmelCase ) UpperCAmelCase_ : List[Any] = model_cls(__UpperCAmelCase ) except ImportError: raise ImportError( f"""{model_class} does not exist. If you just want to test the pretrained model, you might want to""" " set `--only_pretrain_model` or `args.only_pretrain_model=True`." ) else: UpperCAmelCase_ : List[str] = TF_MODEL_WITH_LM_HEAD_MAPPING[config.__class__](__UpperCAmelCase ) # encoder-decoder has vocab size saved differently UpperCAmelCase_ : List[Any] = config.vocab_size if hasattr(__UpperCAmelCase , "vocab_size" ) else config.encoder.vocab_size UpperCAmelCase_ : int = random_input_ids(__UpperCAmelCase , __UpperCAmelCase , __UpperCAmelCase ) @run_with_tf_optimizations(self.args.eager_mode , self.args.use_xla ) def encoder_decoder_train(): UpperCAmelCase_ : Any = model(__UpperCAmelCase , decoder_input_ids=__UpperCAmelCase , labels=__UpperCAmelCase , training=__UpperCAmelCase )[0] UpperCAmelCase_ : int = tf.gradients(__UpperCAmelCase , model.trainable_variables ) return gradients @run_with_tf_optimizations(self.args.eager_mode , self.args.use_xla ) def encoder_train(): UpperCAmelCase_ : str = model(__UpperCAmelCase , labels=__UpperCAmelCase , training=__UpperCAmelCase )[0] UpperCAmelCase_ : str = tf.gradients(__UpperCAmelCase , model.trainable_variables ) return gradients UpperCAmelCase_ : Tuple = encoder_decoder_train if config.is_encoder_decoder else encoder_train return _train def _SCREAMING_SNAKE_CASE ( self : Tuple , lowerCAmelCase_ : Dict ) -> float: with self.args.strategy.scope(): try: if self.args.is_tpu or self.args.use_xla: # run additional 10 times to stabilize compilation for tpu logger.info("Do inference on TPU. Running model 5 times to stabilize compilation" ) timeit.repeat(__UpperCAmelCase , repeat=1 , number=5 ) # as written in https://docs.python.org/2/library/timeit.html#timeit.Timer.repeat, min should be taken rather than the average UpperCAmelCase_ : Any = timeit.repeat( __UpperCAmelCase , repeat=self.args.repeat , number=10 , ) return min(__UpperCAmelCase ) / 1_0.0 except ResourceExhaustedError as e: self.print_fn(f"""Doesn't fit on GPU. {e}""" ) def _SCREAMING_SNAKE_CASE ( self : Union[str, Any] , lowerCAmelCase_ : Callable[[], None] ) -> [Memory, MemorySummary]: logger.info( "Note that TensorFlow allocates more memory than " "it might need to speed up computation. " "The memory reported here corresponds to the memory " "reported by `nvidia-smi`, which can vary depending " "on total available memory on the GPU that is used." ) with self.args.strategy.scope(): try: if self.args.trace_memory_line_by_line: if not self.args.eager_mode: raise ValueError( "`args.eager_mode` is set to `False`. Make sure to run model in eager mode to measure memory" " consumption line by line." ) UpperCAmelCase_ : List[Any] = start_memory_tracing("transformers" ) if self.args.is_tpu: # tpu raise NotImplementedError( "Memory Benchmarking is currently not implemented for TPU. Please disable memory benchmarking" " with `args.memory=False`" ) elif self.args.is_gpu: # gpu if not is_pyanvml_available(): logger.warning( "py3nvml not installed, we won't log GPU memory usage. " "Install py3nvml (pip install py3nvml) to log information about GPU." ) UpperCAmelCase_ : Tuple = "N/A" else: logger.info( "Measuring total GPU usage on GPU device. Make sure to not have additional processes" " running on the same GPU." ) # init nvml nvml.nvmlInit() func() UpperCAmelCase_ : Tuple = nvml.nvmlDeviceGetHandleByIndex(self.args.device_idx ) UpperCAmelCase_ : int = nvml.nvmlDeviceGetMemoryInfo(__UpperCAmelCase ) UpperCAmelCase_ : Any = meminfo.used UpperCAmelCase_ : Tuple = Memory(__UpperCAmelCase ) # shutdown nvml nvml.nvmlShutdown() else: # cpu if self.args.trace_memory_line_by_line: logger.info( "When enabling line by line tracing, the max peak memory for CPU is inaccurate in" " TensorFlow." ) UpperCAmelCase_ : Dict = None else: UpperCAmelCase_ : Tuple = measure_peak_memory_cpu(__UpperCAmelCase ) UpperCAmelCase_ : Optional[Any] = Memory(__UpperCAmelCase ) if isinstance(__UpperCAmelCase , __UpperCAmelCase ) else memory_bytes if self.args.trace_memory_line_by_line: UpperCAmelCase_ : List[Any] = stop_memory_tracing(__UpperCAmelCase ) if memory is None: UpperCAmelCase_ : Union[str, Any] = summary.total else: UpperCAmelCase_ : str = None return memory, summary except ResourceExhaustedError as e: self.print_fn(f"""Doesn't fit on GPU. {e}""" ) return "N/A", None
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import json import os import subprocess import unittest from ast import literal_eval import pytest from parameterized import parameterized_class from . import is_sagemaker_available if is_sagemaker_available(): from sagemaker import Session, TrainingJobAnalytics from sagemaker.huggingface import HuggingFace @pytest.mark.skipif( literal_eval(os.getenv('TEST_SAGEMAKER' , 'False' ) ) is not True , reason='Skipping test because should only be run when releasing minor transformers version' , ) @pytest.mark.usefixtures('sm_env' ) @parameterized_class( [ { 'framework': 'pytorch', 'script': 'run_glue.py', 'model_name_or_path': 'distilbert-base-cased', 'instance_type': 'ml.g4dn.xlarge', 'results': {'train_runtime': 6_50, 'eval_accuracy': 0.6, 'eval_loss': 0.9}, }, { 'framework': 'tensorflow', 'script': 'run_tf.py', 'model_name_or_path': 'distilbert-base-cased', 'instance_type': 'ml.g4dn.xlarge', 'results': {'train_runtime': 6_00, 'eval_accuracy': 0.3, 'eval_loss': 0.9}, }, ] ) class A ( unittest.TestCase ): def lowercase_ (self : int ) -> Optional[Any]: """simple docstring""" if self.framework == "pytorch": subprocess.run( f"""cp ./examples/pytorch/text-classification/run_glue.py {self.env.test_path}/run_glue.py""".split() , encoding="utf-8" , check=__UpperCAmelCase , ) assert hasattr(self , "env" ) def lowercase_ (self : List[Any] , __UpperCAmelCase : Optional[int]=1 ) -> Dict: """simple docstring""" return HuggingFace( entry_point=self.script , source_dir=self.env.test_path , role=self.env.role , image_uri=self.env.image_uri , base_job_name=f"""{self.env.base_job_name}-single""" , instance_count=__UpperCAmelCase , instance_type=self.instance_type , debugger_hook_config=__UpperCAmelCase , hyperparameters={**self.env.hyperparameters, "model_name_or_path": self.model_name_or_path} , metric_definitions=self.env.metric_definitions , py_version="py36" , ) def lowercase_ (self : Optional[Any] , __UpperCAmelCase : Tuple ) -> Optional[int]: """simple docstring""" TrainingJobAnalytics(__UpperCAmelCase ).export_csv(f"""{self.env.test_path}/{job_name}_metrics.csv""" ) def lowercase_ (self : Any ) -> Optional[Any]: """simple docstring""" UpperCAmelCase__ = self.create_estimator() # run training estimator.fit() # result dataframe UpperCAmelCase__ = TrainingJobAnalytics(estimator.latest_training_job.name ).dataframe() # extract kpis UpperCAmelCase__ = list(result_metrics_df[result_metrics_df.metric_name == "eval_accuracy"]["value"] ) UpperCAmelCase__ = list(result_metrics_df[result_metrics_df.metric_name == "eval_loss"]["value"] ) # get train time from SageMaker job, this includes starting, preprocessing, stopping UpperCAmelCase__ = ( Session().describe_training_job(estimator.latest_training_job.name ).get("TrainingTimeInSeconds" , 9_9_9_9_9_9 ) ) # assert kpis assert train_runtime <= self.results["train_runtime"] assert all(t >= self.results["eval_accuracy"] for t in eval_accuracy ) assert all(t <= self.results["eval_loss"] for t in eval_loss ) # dump tests result into json file to share in PR with open(f"""{estimator.latest_training_job.name}.json""" , "w" ) as outfile: json.dump({"train_time": train_runtime, "eval_accuracy": eval_accuracy, "eval_loss": eval_loss} , __UpperCAmelCase )
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"""simple docstring""" import math import tensorflow as tf from packaging import version def a__ ( _SCREAMING_SNAKE_CASE ): """simple docstring""" UpperCamelCase = tf.convert_to_tensor(__A ) UpperCamelCase = 0.5 * (1.0 + tf.math.erf(x / tf.cast(tf.sqrt(2.0 ) , x.dtype ) )) return x * cdf def a__ ( _SCREAMING_SNAKE_CASE ): """simple docstring""" UpperCamelCase = tf.convert_to_tensor(__A ) UpperCamelCase = tf.cast(math.pi , x.dtype ) UpperCamelCase = tf.cast(0.04_47_15 , x.dtype ) UpperCamelCase = 0.5 * (1.0 + tf.tanh(tf.sqrt(2.0 / pi ) * (x + coeff * tf.pow(__A , 3 )) )) return x * cdf def a__ ( _SCREAMING_SNAKE_CASE ): """simple docstring""" UpperCamelCase = tf.convert_to_tensor(__A ) return x * tf.tanh(tf.math.softplus(__A ) ) def a__ ( _SCREAMING_SNAKE_CASE ): """simple docstring""" UpperCamelCase = tf.convert_to_tensor(__A ) UpperCamelCase = tf.cast(0.04_47_15 , x.dtype ) UpperCamelCase = tf.cast(0.79_78_84_56_08 , x.dtype ) return 0.5 * x * (1.0 + tf.tanh(x * coeffa * (1.0 + coeffa * x * x) )) def a__ ( _SCREAMING_SNAKE_CASE ): """simple docstring""" UpperCamelCase = tf.convert_to_tensor(__A ) UpperCamelCase = tf.cast(1.7_02 , x.dtype ) return x * tf.math.sigmoid(coeff * x ) def a__ ( _SCREAMING_SNAKE_CASE ): """simple docstring""" return tf.clip_by_value(_gelu(__A ) , -10 , 10 ) def a__ ( _SCREAMING_SNAKE_CASE , _SCREAMING_SNAKE_CASE=-1 ): """simple docstring""" UpperCamelCase , UpperCamelCase = tf.split(__A , 2 , axis=__A ) return a * tf.math.sigmoid(__A ) if version.parse(tf.version.VERSION) >= version.parse('''2.4'''): def a__ ( _SCREAMING_SNAKE_CASE ): """simple docstring""" return tf.keras.activations.gelu(__A , approximate=__A ) lowerCAmelCase__ = tf.keras.activations.gelu lowerCAmelCase__ = approximate_gelu_wrap else: lowerCAmelCase__ = _gelu lowerCAmelCase__ = _gelu_new lowerCAmelCase__ = { '''gelu''': gelu, '''gelu_10''': gelu_aa, '''gelu_fast''': gelu_fast, '''gelu_new''': gelu_new, '''glu''': glu, '''mish''': mish, '''quick_gelu''': quick_gelu, '''relu''': tf.keras.activations.relu, '''sigmoid''': tf.keras.activations.sigmoid, '''silu''': tf.keras.activations.swish, '''swish''': tf.keras.activations.swish, '''tanh''': tf.keras.activations.tanh, } def a__ ( _SCREAMING_SNAKE_CASE ): """simple docstring""" if activation_string in ACTaFN: return ACTaFN[activation_string] else: raise KeyError(F"function {activation_string} not found in ACT2FN mapping {list(ACTaFN.keys() )}" )
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import math import random def lowerCAmelCase_ ( __A, __A = False ) -> float: '''simple docstring''' if deriv: return value * (1 - value) return 1 / (1 + math.exp(-value )) # Initial Value UpperCamelCase__ = 0.0_2 def lowerCAmelCase_ ( __A, __A ) -> float: '''simple docstring''' UpperCAmelCase__ = float(2 * (random.randint(1, 100 )) - 1 ) for _ in range(__A ): # Forward propagation UpperCAmelCase__ = sigmoid_function(INITIAL_VALUE * weight ) # How much did we miss? UpperCAmelCase__ = (expected / 100) - layer_a # Error delta UpperCAmelCase__ = layer_1_error * sigmoid_function(__A, __A ) # Update weight weight += INITIAL_VALUE * layer_1_delta return layer_a * 100 if __name__ == "__main__": import doctest doctest.testmod() UpperCamelCase__ = int(input('Expected value: ')) UpperCamelCase__ = int(input('Number of propagations: ')) print(forward_propagation(expected, number_propagations))
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import tempfile import unittest from transformers import AutoModelForSeqaSeqLM, AutoTokenizer from transformers.testing_utils import ( is_torch_available, require_optimum, require_torch, slow, ) if is_torch_available(): import torch @require_torch @require_optimum @slow class snake_case__ ( unittest.TestCase ): """simple docstring""" def lowercase_ ( self : Optional[int] ) ->Tuple: snake_case__ : str = 'hf-internal-testing/tiny-random-t5' snake_case__ : Tuple = AutoTokenizer.from_pretrained(__UpperCAmelCase ) snake_case__ : Any = AutoModelForSeqaSeqLM.from_pretrained(__UpperCAmelCase ) snake_case__ : Any = tokenizer('This is me', return_tensors='pt' ) snake_case__ : Optional[Any] = model.to_bettertransformer() self.assertTrue(any('BetterTransformer' in mod.__class__.__name__ for _, mod in model.named_modules() ) ) snake_case__ : Tuple = model.generate(**__UpperCAmelCase ) snake_case__ : List[str] = model.reverse_bettertransformer() self.assertFalse(any('BetterTransformer' in mod.__class__.__name__ for _, mod in model.named_modules() ) ) with tempfile.TemporaryDirectory() as tmpdirname: model.save_pretrained(__UpperCAmelCase ) snake_case__ : str = AutoModelForSeqaSeqLM.from_pretrained(__UpperCAmelCase ) self.assertFalse( any('BetterTransformer' in mod.__class__.__name__ for _, mod in model_reloaded.named_modules() ) ) snake_case__ : str = model_reloaded.generate(**__UpperCAmelCase ) self.assertTrue(torch.allclose(__UpperCAmelCase, __UpperCAmelCase ) ) def lowercase_ ( self : Dict ) ->Tuple: snake_case__ : Optional[Any] = 'hf-internal-testing/tiny-random-t5' snake_case__ : List[str] = AutoModelForSeqaSeqLM.from_pretrained(__UpperCAmelCase ) snake_case__ : Dict = model.to_bettertransformer() with tempfile.TemporaryDirectory() as tmpdirname: with self.assertRaises(__UpperCAmelCase ): model.save_pretrained(__UpperCAmelCase ) snake_case__ : Union[str, Any] = model.reverse_bettertransformer() model.save_pretrained(__UpperCAmelCase )
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from __future__ import annotations class A : def __init__(self : Union[str, Any] , __UpperCAmelCase : list[list[int]] ) -> List[str]: """simple docstring""" UpperCAmelCase__ = TypeError( "Matrices must be formed from a list of zero or more lists containing at " "least one and the same number of values, each of which must be of type " "int or float." ) if len(__UpperCAmelCase ) != 0: UpperCAmelCase__ = len(rows[0] ) if cols == 0: raise error for row in rows: if len(__UpperCAmelCase ) != cols: raise error for value in row: if not isinstance(__UpperCAmelCase , (int, float) ): raise error UpperCAmelCase__ = rows else: UpperCAmelCase__ = [] def lowercase_ (self : Any ) -> list[list[int]]: """simple docstring""" return [[row[i] for row in self.rows] for i in range(len(self.rows[0] ) )] @property def lowercase_ (self : Any ) -> int: """simple docstring""" return len(self.rows ) @property def lowercase_ (self : Union[str, Any] ) -> int: """simple docstring""" return len(self.rows[0] ) @property def lowercase_ (self : List[Any] ) -> tuple[int, int]: """simple docstring""" return (self.num_rows, self.num_columns) @property def lowercase_ (self : Tuple ) -> bool: """simple docstring""" return self.order[0] == self.order[1] def lowercase_ (self : Any ) -> Matrix: """simple docstring""" UpperCAmelCase__ = [ [0 if column_num != row_num else 1 for column_num in range(self.num_rows )] for row_num in range(self.num_rows ) ] return Matrix(__UpperCAmelCase ) def lowercase_ (self : int ) -> int: """simple docstring""" if not self.is_square: return 0 if self.order == (0, 0): return 1 if self.order == (1, 1): return int(self.rows[0][0] ) if self.order == (2, 2): return int( (self.rows[0][0] * self.rows[1][1]) - (self.rows[0][1] * self.rows[1][0]) ) else: return sum( self.rows[0][column] * self.cofactors().rows[0][column] for column in range(self.num_columns ) ) def lowercase_ (self : Tuple ) -> bool: """simple docstring""" return bool(self.determinant() ) def lowercase_ (self : Dict , __UpperCAmelCase : int , __UpperCAmelCase : int ) -> int: """simple docstring""" UpperCAmelCase__ = [ [ self.rows[other_row][other_column] for other_column in range(self.num_columns ) if other_column != column ] for other_row in range(self.num_rows ) if other_row != row ] return Matrix(__UpperCAmelCase ).determinant() def lowercase_ (self : int , __UpperCAmelCase : int , __UpperCAmelCase : int ) -> int: """simple docstring""" if (row + column) % 2 == 0: return self.get_minor(__UpperCAmelCase , __UpperCAmelCase ) return -1 * self.get_minor(__UpperCAmelCase , __UpperCAmelCase ) def lowercase_ (self : Union[str, Any] ) -> Matrix: """simple docstring""" return Matrix( [ [self.get_minor(__UpperCAmelCase , __UpperCAmelCase ) for column in range(self.num_columns )] for row in range(self.num_rows ) ] ) def lowercase_ (self : List[str] ) -> Matrix: """simple docstring""" return Matrix( [ [ self.minors().rows[row][column] if (row + column) % 2 == 0 else self.minors().rows[row][column] * -1 for column in range(self.minors().num_columns ) ] for row in range(self.minors().num_rows ) ] ) def lowercase_ (self : Optional[Any] ) -> Matrix: """simple docstring""" UpperCAmelCase__ = [ [self.cofactors().rows[column][row] for column in range(self.num_columns )] for row in range(self.num_rows ) ] return Matrix(__UpperCAmelCase ) def lowercase_ (self : List[Any] ) -> Matrix: """simple docstring""" UpperCAmelCase__ = self.determinant() if not determinant: raise TypeError("Only matrices with a non-zero determinant have an inverse" ) return self.adjugate() * (1 / determinant) def __repr__(self : Dict ) -> str: """simple docstring""" return str(self.rows ) def __str__(self : Optional[Any] ) -> str: """simple docstring""" if self.num_rows == 0: return "[]" if self.num_rows == 1: return "[[" + ". ".join(str(self.rows[0] ) ) + "]]" return ( "[" + "\n ".join( [ "[" + ". ".join([str(__UpperCAmelCase ) for value in row] ) + ".]" for row in self.rows ] ) + "]" ) def lowercase_ (self : Optional[int] , __UpperCAmelCase : list[int] , __UpperCAmelCase : int | None = None ) -> None: """simple docstring""" UpperCAmelCase__ = TypeError("Row must be a list containing all ints and/or floats" ) if not isinstance(__UpperCAmelCase , __UpperCAmelCase ): raise type_error for value in row: if not isinstance(__UpperCAmelCase , (int, float) ): raise type_error if len(__UpperCAmelCase ) != self.num_columns: raise ValueError( "Row must be equal in length to the other rows in the matrix" ) if position is None: self.rows.append(__UpperCAmelCase ) else: UpperCAmelCase__ = self.rows[0:position] + [row] + self.rows[position:] def lowercase_ (self : Union[str, Any] , __UpperCAmelCase : list[int] , __UpperCAmelCase : int | None = None ) -> None: """simple docstring""" UpperCAmelCase__ = TypeError( "Column must be a list containing all ints and/or floats" ) if not isinstance(__UpperCAmelCase , __UpperCAmelCase ): raise type_error for value in column: if not isinstance(__UpperCAmelCase , (int, float) ): raise type_error if len(__UpperCAmelCase ) != self.num_rows: raise ValueError( "Column must be equal in length to the other columns in the matrix" ) if position is None: UpperCAmelCase__ = [self.rows[i] + [column[i]] for i in range(self.num_rows )] else: UpperCAmelCase__ = [ self.rows[i][0:position] + [column[i]] + self.rows[i][position:] for i in range(self.num_rows ) ] def __eq__(self : Any , __UpperCAmelCase : object ) -> bool: """simple docstring""" if not isinstance(__UpperCAmelCase , __UpperCAmelCase ): return NotImplemented return self.rows == other.rows def __ne__(self : int , __UpperCAmelCase : object ) -> bool: """simple docstring""" return not self == other def __neg__(self : Dict ) -> Matrix: """simple docstring""" return self * -1 def __add__(self : Dict , __UpperCAmelCase : Matrix ) -> Matrix: """simple docstring""" if self.order != other.order: raise ValueError("Addition requires matrices of the same order" ) return Matrix( [ [self.rows[i][j] + other.rows[i][j] for j in range(self.num_columns )] for i in range(self.num_rows ) ] ) def __sub__(self : Optional[Any] , __UpperCAmelCase : Matrix ) -> Matrix: """simple docstring""" if self.order != other.order: raise ValueError("Subtraction requires matrices of the same order" ) return Matrix( [ [self.rows[i][j] - other.rows[i][j] for j in range(self.num_columns )] for i in range(self.num_rows ) ] ) def __mul__(self : Tuple , __UpperCAmelCase : Matrix | int | float ) -> Matrix: """simple docstring""" if isinstance(__UpperCAmelCase , (int, float) ): return Matrix( [[int(element * other ) for element in row] for row in self.rows] ) elif isinstance(__UpperCAmelCase , __UpperCAmelCase ): if self.num_columns != other.num_rows: raise ValueError( "The number of columns in the first matrix must " "be equal to the number of rows in the second" ) return Matrix( [ [Matrix.dot_product(__UpperCAmelCase , __UpperCAmelCase ) for column in other.columns()] for row in self.rows ] ) else: raise TypeError( "A Matrix can only be multiplied by an int, float, or another matrix" ) def __pow__(self : List[Any] , __UpperCAmelCase : int ) -> Matrix: """simple docstring""" if not isinstance(__UpperCAmelCase , __UpperCAmelCase ): raise TypeError("A Matrix can only be raised to the power of an int" ) if not self.is_square: raise ValueError("Only square matrices can be raised to a power" ) if other == 0: return self.identity() if other < 0: if self.is_invertable(): return self.inverse() ** (-other) raise ValueError( "Only invertable matrices can be raised to a negative power" ) UpperCAmelCase__ = self for _ in range(other - 1 ): result *= self return result @classmethod def lowercase_ (cls : Dict , __UpperCAmelCase : list[int] , __UpperCAmelCase : list[int] ) -> int: """simple docstring""" return sum(row[i] * column[i] for i in range(len(__UpperCAmelCase ) ) ) if __name__ == "__main__": import doctest doctest.testmod()
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import argparse import pickle import numpy as np import torch from torch import nn from transformers import ReformerConfig, ReformerModelWithLMHead from transformers.utils import logging logging.set_verbosity_info() def __lowercase ( a__ , a__ , a__=None ) -> List[str]: assert torch_layer.weight.shape == weight.shape, f"""{torch_layer} layer.weight does not match""" __SCREAMING_SNAKE_CASE = nn.Parameter(__A ) if bias is not None: assert torch_layer.bias.shape == bias.shape, f"""{torch_layer} layer.bias does not match""" __SCREAMING_SNAKE_CASE = nn.Parameter(__A ) def __lowercase ( a__ , a__ , a__ ) -> Dict: __SCREAMING_SNAKE_CASE = np.asarray(weights[0] ) __SCREAMING_SNAKE_CASE = np.asarray(weights[1] ) __SCREAMING_SNAKE_CASE = np.asarray(weights[2] ) set_param( torch_layer.self_attention.query_key , torch.tensor(__A ).transpose(1 , 2 ).contiguous().view(-1 , __A ) , ) set_param( torch_layer.self_attention.value , torch.tensor(__A ).transpose(1 , 2 ).contiguous().view(-1 , __A ) , ) set_param( torch_layer.output.dense , torch.tensor(__A ).view(-1 , __A ).contiguous().transpose(0 , 1 ) , ) def __lowercase ( a__ , a__ , a__ ) -> Optional[Any]: __SCREAMING_SNAKE_CASE = np.asarray(weights[0] ) __SCREAMING_SNAKE_CASE = np.asarray(weights[1] ) __SCREAMING_SNAKE_CASE = np.asarray(weights[2] ) __SCREAMING_SNAKE_CASE = np.asarray(weights[3] ) set_param( torch_layer.self_attention.query , torch.tensor(__A ).transpose(1 , 2 ).contiguous().view(-1 , __A ) , ) set_param( torch_layer.self_attention.key , torch.tensor(__A ).transpose(1 , 2 ).contiguous().view(-1 , __A ) , ) set_param( torch_layer.self_attention.value , torch.tensor(__A ).transpose(1 , 2 ).contiguous().view(-1 , __A ) , ) set_param( torch_layer.output.dense , torch.tensor(__A ).view(-1 , __A ).contiguous().transpose(0 , 1 ) , ) def __lowercase ( a__ , a__ , a__ ) -> Dict: __SCREAMING_SNAKE_CASE = weights[0][0][0] __SCREAMING_SNAKE_CASE = np.asarray(layer_norm_a[0] ) __SCREAMING_SNAKE_CASE = np.asarray(layer_norm_a[1] ) set_param( torch_block.attention.layer_norm , torch.tensor(__A ) , torch.tensor(__A ) , ) # lsh weights + output __SCREAMING_SNAKE_CASE = weights[0][1] if len(__A ) < 4: set_layer_weights_in_torch_lsh(__A , torch_block.attention , __A ) else: set_layer_weights_in_torch_local(__A , torch_block.attention , __A ) # intermediate weighs __SCREAMING_SNAKE_CASE = weights[2][0][1][2] # Chunked Feed Forward if len(__A ) == 4: __SCREAMING_SNAKE_CASE = intermediate_weights[2] # layernorm 2 __SCREAMING_SNAKE_CASE = np.asarray(intermediate_weights[0][0] ) __SCREAMING_SNAKE_CASE = np.asarray(intermediate_weights[0][1] ) set_param( torch_block.feed_forward.layer_norm , torch.tensor(__A ) , torch.tensor(__A ) , ) # intermediate dense __SCREAMING_SNAKE_CASE = np.asarray(intermediate_weights[1][0] ) __SCREAMING_SNAKE_CASE = np.asarray(intermediate_weights[1][1] ) set_param( torch_block.feed_forward.dense.dense , torch.tensor(__A ).transpose(0 , 1 ).contiguous() , torch.tensor(__A ) , ) # intermediate out __SCREAMING_SNAKE_CASE = np.asarray(intermediate_weights[4][0] ) __SCREAMING_SNAKE_CASE = np.asarray(intermediate_weights[4][1] ) set_param( torch_block.feed_forward.output.dense , torch.tensor(__A ).transpose(0 , 1 ).contiguous() , torch.tensor(__A ) , ) def __lowercase ( a__ , a__ , a__ ) -> str: __SCREAMING_SNAKE_CASE = torch_model.reformer # word embeds __SCREAMING_SNAKE_CASE = np.asarray(weights[1] ) set_param( torch_model_reformer.embeddings.word_embeddings , torch.tensor(__A ) , ) if isinstance(weights[3] , __A ): __SCREAMING_SNAKE_CASE = torch_model_reformer.embeddings.position_embeddings for emb_idx in range(len(position_embeddings.weights ) ): __SCREAMING_SNAKE_CASE = np.asarray(weights[3][emb_idx][0] ) assert ( position_embeddings.weights[emb_idx].shape == emb_weights.shape ), f"""{position_embeddings[emb_idx]} emb does not match""" __SCREAMING_SNAKE_CASE = nn.Parameter(torch.tensor(__A ) ) __SCREAMING_SNAKE_CASE = weights[5] assert len(torch_model_reformer.encoder.layers ) * 4 == len( __A ), "HF and trax model do not have the same number of layers" for layer_idx, layer in enumerate(torch_model_reformer.encoder.layers ): __SCREAMING_SNAKE_CASE = trax_layer_weights[4 * layer_idx : 4 * (layer_idx + 1)] set_block_weights_in_torch(__A , __A , __A ) # output layer norm __SCREAMING_SNAKE_CASE = np.asarray(weights[7][0] ) __SCREAMING_SNAKE_CASE = np.asarray(weights[7][1] ) set_param( torch_model_reformer.encoder.layer_norm , torch.tensor(__A ) , torch.tensor(__A ) , ) # output embeddings __SCREAMING_SNAKE_CASE = np.asarray(weights[9][0] ) __SCREAMING_SNAKE_CASE = np.asarray(weights[9][1] ) set_param( torch_model.lm_head.decoder , torch.tensor(__A ).transpose(0 , 1 ).contiguous() , torch.tensor(__A ) , ) def __lowercase ( a__ , a__ , a__ ) -> str: __SCREAMING_SNAKE_CASE = ReformerConfig.from_json_file(__A ) print(f"""Building PyTorch model from configuration: {config}""" ) __SCREAMING_SNAKE_CASE = ReformerModelWithLMHead(__A ) with open(__A , 'rb' ) as f: __SCREAMING_SNAKE_CASE = pickle.load(__A )['weights'] set_model_weights_in_torch(__A , __A , config.hidden_size ) # Save pytorch-model print(f"""Save PyTorch model to {pytorch_dump_path}""" ) torch.save(model.state_dict() , __A ) if __name__ == "__main__": lowerCAmelCase__ : List[str] =argparse.ArgumentParser() # Required parameters parser.add_argument( '''--trax_model_pkl_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 Reformer model. \n''' '''This specifies the model architecture.''' ), ) parser.add_argument( '''--pytorch_dump_path''', default=None, type=str, required=True, help='''Path to the output PyTorch model.''' ) lowerCAmelCase__ : List[Any] =parser.parse_args() convert_trax_checkpoint_to_pytorch(args.trax_model_pkl_path, args.config_file, args.pytorch_dump_path)
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import json import os from typing import Dict, List, Optional, Tuple from ...tokenization_utils import PreTrainedTokenizer from ...utils import logging UpperCamelCase__ = logging.get_logger(__name__) UpperCamelCase__ = { 'vocab_file': 'vocab.json', 'tokenizer_config_file': 'tokenizer_config.json', 'merges_file': 'merges.txt', } UpperCamelCase__ = { 'vocab_file': { 'facebook/s2t-wav2vec2-large-en-de': ( 'https://huggingface.co/facebook/s2t-wav2vec2-large-en-de/resolve/main/vocab.json' ), }, 'tokenizer_config_file': { 'facebook/s2t-wav2vec2-large-en-de': ( 'https://huggingface.co/facebook/s2t-wav2vec2-large-en-de/resolve/main/tokenizer_config.json' ), }, 'merges_file': { 'facebook/s2t-wav2vec2-large-en-de': ( 'https://huggingface.co/facebook/s2t-wav2vec2-large-en-de/resolve/main/merges.txt' ), }, } UpperCamelCase__ = '</w>' UpperCamelCase__ = '@@ ' def lowerCAmelCase_ ( __A ) -> str: '''simple docstring''' UpperCAmelCase__ = set() UpperCAmelCase__ = word[0] for char in word[1:]: pairs.add((prev_char, char) ) UpperCAmelCase__ = char return pairs # Speech2Text2 has no max input length UpperCamelCase__ = {'facebook/s2t-wav2vec2-large-en-de': 1_0_2_4} class A ( UpperCAmelCase_ ): __UpperCAmelCase : str = VOCAB_FILES_NAMES __UpperCAmelCase : str = PRETRAINED_VOCAB_FILES_MAP __UpperCAmelCase : Union[str, Any] = PRETRAINED_POSITIONAL_EMBEDDINGS_SIZES __UpperCAmelCase : Dict = ['input_ids', 'attention_mask'] def __init__(self : Tuple , __UpperCAmelCase : List[Any] , __UpperCAmelCase : Dict="<s>" , __UpperCAmelCase : Tuple="<pad>" , __UpperCAmelCase : str="</s>" , __UpperCAmelCase : int="<unk>" , __UpperCAmelCase : List[str]=False , __UpperCAmelCase : str=None , **__UpperCAmelCase : Optional[Any] , ) -> Tuple: """simple docstring""" super().__init__( unk_token=__UpperCAmelCase , bos_token=__UpperCAmelCase , eos_token=__UpperCAmelCase , pad_token=__UpperCAmelCase , do_lower_case=__UpperCAmelCase , **__UpperCAmelCase , ) UpperCAmelCase__ = do_lower_case with open(__UpperCAmelCase , encoding="utf-8" ) as vocab_handle: UpperCAmelCase__ = json.load(__UpperCAmelCase ) UpperCAmelCase__ = {v: k for k, v in self.encoder.items()} if merges_file is None: logger.info(f"""No merges files provided. {self.__class__.__name__} can only be used for decoding.""" ) UpperCAmelCase__ = None UpperCAmelCase__ = None else: with open(__UpperCAmelCase , encoding="utf-8" ) as merges_handle: UpperCAmelCase__ = merges_handle.read().split("\n" )[:-1] UpperCAmelCase__ = [tuple(merge.split()[:2] ) for merge in merges] UpperCAmelCase__ = dict(zip(__UpperCAmelCase , range(len(__UpperCAmelCase ) ) ) ) UpperCAmelCase__ = {} @property def lowercase_ (self : List[str] ) -> int: """simple docstring""" return len(self.decoder ) def lowercase_ (self : Union[str, Any] ) -> Dict: """simple docstring""" return dict(self.encoder , **self.added_tokens_encoder ) def lowercase_ (self : Dict , __UpperCAmelCase : Union[str, Any] ) -> str: """simple docstring""" UpperCAmelCase__ = tuple(token[:-1] ) + (token[-1] + BPE_TOKEN_MERGES,) if token in self.cache: return self.cache[token] UpperCAmelCase__ = get_pairs(__UpperCAmelCase ) if not pairs: return token while True: UpperCAmelCase__ = min(__UpperCAmelCase , key=lambda __UpperCAmelCase : self.bpe_ranks.get(__UpperCAmelCase , float("inf" ) ) ) if bigram not in self.bpe_ranks: break UpperCAmelCase__ , UpperCAmelCase__ = bigram UpperCAmelCase__ = [] UpperCAmelCase__ = 0 while i < len(__UpperCAmelCase ): try: UpperCAmelCase__ = word.index(__UpperCAmelCase , __UpperCAmelCase ) except ValueError: new_word.extend(word[i:] ) break else: new_word.extend(word[i:j] ) UpperCAmelCase__ = j if word[i] == first and i < len(__UpperCAmelCase ) - 1 and word[i + 1] == second: new_word.append(first + second ) i += 2 else: new_word.append(word[i] ) i += 1 UpperCAmelCase__ = tuple(__UpperCAmelCase ) UpperCAmelCase__ = new_word if len(__UpperCAmelCase ) == 1: break else: UpperCAmelCase__ = get_pairs(__UpperCAmelCase ) UpperCAmelCase__ = " ".join(__UpperCAmelCase ) if word == "\n " + BPE_TOKEN_MERGES: UpperCAmelCase__ = "\n" + BPE_TOKEN_MERGES if word.endswith(__UpperCAmelCase ): UpperCAmelCase__ = word.replace(__UpperCAmelCase , "" ) UpperCAmelCase__ = word.replace(" " , __UpperCAmelCase ) UpperCAmelCase__ = word return word def lowercase_ (self : Tuple , __UpperCAmelCase : int ) -> Optional[int]: """simple docstring""" if self.bpe_ranks is None: raise ValueError( "This tokenizer was instantiated without a `merges.txt` file, so" " that it can only be used for decoding, not for encoding." "Make sure to provide `merges.txt` file at instantiation to enable " "encoding." ) if self.do_lower_case: UpperCAmelCase__ = text.lower() UpperCAmelCase__ = text.split() UpperCAmelCase__ = [] for token in text: if token: split_tokens.extend(list(self.bpe(__UpperCAmelCase ).split(" " ) ) ) return split_tokens def lowercase_ (self : Union[str, Any] , __UpperCAmelCase : str ) -> int: """simple docstring""" return self.encoder.get(__UpperCAmelCase , self.encoder.get(self.unk_token ) ) def lowercase_ (self : Any , __UpperCAmelCase : int ) -> str: """simple docstring""" UpperCAmelCase__ = self.decoder.get(__UpperCAmelCase , self.unk_token ) return result def lowercase_ (self : Dict , __UpperCAmelCase : List[str] ) -> str: """simple docstring""" UpperCAmelCase__ = " ".join(__UpperCAmelCase ) # make sure @@ tokens are concatenated UpperCAmelCase__ = "".join(string.split(__UpperCAmelCase ) ) return string def lowercase_ (self : Union[str, Any] , __UpperCAmelCase : str , __UpperCAmelCase : Optional[str] = None ) -> Tuple[str]: """simple docstring""" if not os.path.isdir(__UpperCAmelCase ): logger.error(f"""Vocabulary path ({save_directory}) should be a directory""" ) return UpperCAmelCase__ = os.path.join( __UpperCAmelCase , (filename_prefix + "-" if filename_prefix else "") + VOCAB_FILES_NAMES["vocab_file"] ) UpperCAmelCase__ = os.path.join( __UpperCAmelCase , (filename_prefix + "-" if filename_prefix else "") + VOCAB_FILES_NAMES["merges_file"] ) with open(__UpperCAmelCase , "w" , encoding="utf-8" ) as f: f.write(json.dumps(self.encoder , indent=2 , sort_keys=__UpperCAmelCase , ensure_ascii=__UpperCAmelCase ) + "\n" ) UpperCAmelCase__ = 0 if self.bpe_ranks is None: return (vocab_file,) with open(__UpperCAmelCase , "w" , encoding="utf-8" ) as writer: for bpe_tokens, token_index in sorted(self.bpe_ranks.items() , key=lambda __UpperCAmelCase : kv[1] ): if index != token_index: logger.warning( f"""Saving vocabulary to {merges_file}: BPE merge indices are not consecutive.""" " Please check that the tokenizer is not corrupted!" ) UpperCAmelCase__ = token_index writer.write(" ".join(__UpperCAmelCase ) + "\n" ) index += 1 return (vocab_file, merges_file)
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"""simple docstring""" from collections import namedtuple import requests from lxml import html # type: ignore __snake_case = namedtuple("""covid_data""", """cases deaths recovered""") def __lowerCAmelCase ( lowercase : Dict = "https://www.worldometers.info/coronavirus/" ) -> covid_data: """simple docstring""" snake_case : Union[str, Any] = "//div[@class = \"maincounter-number\"]/span/text()" return covid_data(*html.fromstring(requests.get(__A ).content ).xpath(__A ) ) __snake_case = """Total COVID-19 cases in the world: {}\nTotal deaths due to COVID-19 in the world: {}\nTotal COVID-19 patients recovered in the world: {}""" print(fmt.format(*covid_stats()))
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from dataclasses import dataclass from typing import Optional import numpy as np import torch import torch.nn as nn from ..utils import BaseOutput, is_torch_version, randn_tensor from .attention_processor import SpatialNorm from .unet_ad_blocks import UNetMidBlockaD, get_down_block, get_up_block @dataclass class A ( UpperCAmelCase_ ): __UpperCAmelCase : torch.FloatTensor class A ( nn.Module ): def __init__(self : Union[str, Any] , __UpperCAmelCase : int=3 , __UpperCAmelCase : Dict=3 , __UpperCAmelCase : Optional[Any]=("DownEncoderBlock2D",) , __UpperCAmelCase : int=(6_4,) , __UpperCAmelCase : Union[str, Any]=2 , __UpperCAmelCase : Any=3_2 , __UpperCAmelCase : str="silu" , __UpperCAmelCase : Any=True , ) -> Dict: """simple docstring""" super().__init__() UpperCAmelCase__ = layers_per_block UpperCAmelCase__ = torch.nn.Convad( __UpperCAmelCase , block_out_channels[0] , kernel_size=3 , stride=1 , padding=1 , ) UpperCAmelCase__ = None UpperCAmelCase__ = nn.ModuleList([] ) # down UpperCAmelCase__ = block_out_channels[0] for i, down_block_type in enumerate(__UpperCAmelCase ): UpperCAmelCase__ = output_channel UpperCAmelCase__ = block_out_channels[i] UpperCAmelCase__ = i == len(__UpperCAmelCase ) - 1 UpperCAmelCase__ = get_down_block( __UpperCAmelCase , num_layers=self.layers_per_block , in_channels=__UpperCAmelCase , out_channels=__UpperCAmelCase , add_downsample=not is_final_block , resnet_eps=1E-6 , downsample_padding=0 , resnet_act_fn=__UpperCAmelCase , resnet_groups=__UpperCAmelCase , attention_head_dim=__UpperCAmelCase , temb_channels=__UpperCAmelCase , ) self.down_blocks.append(__UpperCAmelCase ) # mid UpperCAmelCase__ = UNetMidBlockaD( in_channels=block_out_channels[-1] , resnet_eps=1E-6 , resnet_act_fn=__UpperCAmelCase , output_scale_factor=1 , resnet_time_scale_shift="default" , attention_head_dim=block_out_channels[-1] , resnet_groups=__UpperCAmelCase , temb_channels=__UpperCAmelCase , ) # out UpperCAmelCase__ = nn.GroupNorm(num_channels=block_out_channels[-1] , num_groups=__UpperCAmelCase , eps=1E-6 ) UpperCAmelCase__ = nn.SiLU() UpperCAmelCase__ = 2 * out_channels if double_z else out_channels UpperCAmelCase__ = nn.Convad(block_out_channels[-1] , __UpperCAmelCase , 3 , padding=1 ) UpperCAmelCase__ = False def lowercase_ (self : List[Any] , __UpperCAmelCase : int ) -> str: """simple docstring""" UpperCAmelCase__ = x UpperCAmelCase__ = self.conv_in(__UpperCAmelCase ) if self.training and self.gradient_checkpointing: def create_custom_forward(__UpperCAmelCase : int ): def custom_forward(*__UpperCAmelCase : Optional[Any] ): return module(*__UpperCAmelCase ) return custom_forward # down if is_torch_version(">=" , "1.11.0" ): for down_block in self.down_blocks: UpperCAmelCase__ = torch.utils.checkpoint.checkpoint( create_custom_forward(__UpperCAmelCase ) , __UpperCAmelCase , use_reentrant=__UpperCAmelCase ) # middle UpperCAmelCase__ = torch.utils.checkpoint.checkpoint( create_custom_forward(self.mid_block ) , __UpperCAmelCase , use_reentrant=__UpperCAmelCase ) else: for down_block in self.down_blocks: UpperCAmelCase__ = torch.utils.checkpoint.checkpoint(create_custom_forward(__UpperCAmelCase ) , __UpperCAmelCase ) # middle UpperCAmelCase__ = torch.utils.checkpoint.checkpoint(create_custom_forward(self.mid_block ) , __UpperCAmelCase ) else: # down for down_block in self.down_blocks: UpperCAmelCase__ = down_block(__UpperCAmelCase ) # middle UpperCAmelCase__ = self.mid_block(__UpperCAmelCase ) # post-process UpperCAmelCase__ = self.conv_norm_out(__UpperCAmelCase ) UpperCAmelCase__ = self.conv_act(__UpperCAmelCase ) UpperCAmelCase__ = self.conv_out(__UpperCAmelCase ) return sample class A ( nn.Module ): def __init__(self : List[Any] , __UpperCAmelCase : str=3 , __UpperCAmelCase : Union[str, Any]=3 , __UpperCAmelCase : Optional[int]=("UpDecoderBlock2D",) , __UpperCAmelCase : str=(6_4,) , __UpperCAmelCase : Optional[Any]=2 , __UpperCAmelCase : Tuple=3_2 , __UpperCAmelCase : Any="silu" , __UpperCAmelCase : Any="group" , ) -> Dict: """simple docstring""" super().__init__() UpperCAmelCase__ = layers_per_block UpperCAmelCase__ = nn.Convad( __UpperCAmelCase , block_out_channels[-1] , kernel_size=3 , stride=1 , padding=1 , ) UpperCAmelCase__ = None UpperCAmelCase__ = nn.ModuleList([] ) UpperCAmelCase__ = in_channels if norm_type == "spatial" else None # mid UpperCAmelCase__ = UNetMidBlockaD( in_channels=block_out_channels[-1] , resnet_eps=1E-6 , resnet_act_fn=__UpperCAmelCase , output_scale_factor=1 , resnet_time_scale_shift="default" if norm_type == "group" else norm_type , attention_head_dim=block_out_channels[-1] , resnet_groups=__UpperCAmelCase , temb_channels=__UpperCAmelCase , ) # up UpperCAmelCase__ = list(reversed(__UpperCAmelCase ) ) UpperCAmelCase__ = reversed_block_out_channels[0] for i, up_block_type in enumerate(__UpperCAmelCase ): UpperCAmelCase__ = output_channel UpperCAmelCase__ = reversed_block_out_channels[i] UpperCAmelCase__ = i == len(__UpperCAmelCase ) - 1 UpperCAmelCase__ = get_up_block( __UpperCAmelCase , num_layers=self.layers_per_block + 1 , in_channels=__UpperCAmelCase , out_channels=__UpperCAmelCase , prev_output_channel=__UpperCAmelCase , add_upsample=not is_final_block , resnet_eps=1E-6 , resnet_act_fn=__UpperCAmelCase , resnet_groups=__UpperCAmelCase , attention_head_dim=__UpperCAmelCase , temb_channels=__UpperCAmelCase , resnet_time_scale_shift=__UpperCAmelCase , ) self.up_blocks.append(__UpperCAmelCase ) UpperCAmelCase__ = output_channel # out if norm_type == "spatial": UpperCAmelCase__ = SpatialNorm(block_out_channels[0] , __UpperCAmelCase ) else: UpperCAmelCase__ = nn.GroupNorm(num_channels=block_out_channels[0] , num_groups=__UpperCAmelCase , eps=1E-6 ) UpperCAmelCase__ = nn.SiLU() UpperCAmelCase__ = nn.Convad(block_out_channels[0] , __UpperCAmelCase , 3 , padding=1 ) UpperCAmelCase__ = False def lowercase_ (self : Optional[int] , __UpperCAmelCase : Tuple , __UpperCAmelCase : Dict=None ) -> List[Any]: """simple docstring""" UpperCAmelCase__ = z UpperCAmelCase__ = self.conv_in(__UpperCAmelCase ) UpperCAmelCase__ = next(iter(self.up_blocks.parameters() ) ).dtype if self.training and self.gradient_checkpointing: def create_custom_forward(__UpperCAmelCase : str ): def custom_forward(*__UpperCAmelCase : List[str] ): return module(*__UpperCAmelCase ) return custom_forward if is_torch_version(">=" , "1.11.0" ): # middle UpperCAmelCase__ = torch.utils.checkpoint.checkpoint( create_custom_forward(self.mid_block ) , __UpperCAmelCase , __UpperCAmelCase , use_reentrant=__UpperCAmelCase ) UpperCAmelCase__ = sample.to(__UpperCAmelCase ) # up for up_block in self.up_blocks: UpperCAmelCase__ = torch.utils.checkpoint.checkpoint( create_custom_forward(__UpperCAmelCase ) , __UpperCAmelCase , __UpperCAmelCase , use_reentrant=__UpperCAmelCase ) else: # middle UpperCAmelCase__ = torch.utils.checkpoint.checkpoint( create_custom_forward(self.mid_block ) , __UpperCAmelCase , __UpperCAmelCase ) UpperCAmelCase__ = sample.to(__UpperCAmelCase ) # up for up_block in self.up_blocks: UpperCAmelCase__ = torch.utils.checkpoint.checkpoint(create_custom_forward(__UpperCAmelCase ) , __UpperCAmelCase , __UpperCAmelCase ) else: # middle UpperCAmelCase__ = self.mid_block(__UpperCAmelCase , __UpperCAmelCase ) UpperCAmelCase__ = sample.to(__UpperCAmelCase ) # up for up_block in self.up_blocks: UpperCAmelCase__ = up_block(__UpperCAmelCase , __UpperCAmelCase ) # post-process if latent_embeds is None: UpperCAmelCase__ = self.conv_norm_out(__UpperCAmelCase ) else: UpperCAmelCase__ = self.conv_norm_out(__UpperCAmelCase , __UpperCAmelCase ) UpperCAmelCase__ = self.conv_act(__UpperCAmelCase ) UpperCAmelCase__ = self.conv_out(__UpperCAmelCase ) return sample class A ( nn.Module ): def __init__(self : Optional[Any] , __UpperCAmelCase : str , __UpperCAmelCase : List[str] , __UpperCAmelCase : List[str] , __UpperCAmelCase : Dict=None , __UpperCAmelCase : Union[str, Any]="random" , __UpperCAmelCase : Dict=False , __UpperCAmelCase : Union[str, Any]=True ) -> Dict: """simple docstring""" super().__init__() UpperCAmelCase__ = n_e UpperCAmelCase__ = vq_embed_dim UpperCAmelCase__ = beta UpperCAmelCase__ = legacy UpperCAmelCase__ = nn.Embedding(self.n_e , self.vq_embed_dim ) self.embedding.weight.data.uniform_(-1.0 / self.n_e , 1.0 / self.n_e ) UpperCAmelCase__ = remap if self.remap is not None: self.register_buffer("used" , torch.tensor(np.load(self.remap ) ) ) UpperCAmelCase__ = self.used.shape[0] UpperCAmelCase__ = unknown_index # "random" or "extra" or integer if self.unknown_index == "extra": UpperCAmelCase__ = self.re_embed UpperCAmelCase__ = self.re_embed + 1 print( f"""Remapping {self.n_e} indices to {self.re_embed} indices. """ f"""Using {self.unknown_index} for unknown indices.""" ) else: UpperCAmelCase__ = n_e UpperCAmelCase__ = sane_index_shape def lowercase_ (self : str , __UpperCAmelCase : str ) -> List[str]: """simple docstring""" UpperCAmelCase__ = inds.shape assert len(__UpperCAmelCase ) > 1 UpperCAmelCase__ = inds.reshape(ishape[0] , -1 ) UpperCAmelCase__ = self.used.to(__UpperCAmelCase ) UpperCAmelCase__ = (inds[:, :, None] == used[None, None, ...]).long() UpperCAmelCase__ = match.argmax(-1 ) UpperCAmelCase__ = match.sum(2 ) < 1 if self.unknown_index == "random": UpperCAmelCase__ = torch.randint(0 , self.re_embed , size=new[unknown].shape ).to(device=new.device ) else: UpperCAmelCase__ = self.unknown_index return new.reshape(__UpperCAmelCase ) def lowercase_ (self : Tuple , __UpperCAmelCase : Optional[int] ) -> Dict: """simple docstring""" UpperCAmelCase__ = inds.shape assert len(__UpperCAmelCase ) > 1 UpperCAmelCase__ = inds.reshape(ishape[0] , -1 ) UpperCAmelCase__ = self.used.to(__UpperCAmelCase ) if self.re_embed > self.used.shape[0]: # extra token UpperCAmelCase__ = 0 # simply set to zero UpperCAmelCase__ = torch.gather(used[None, :][inds.shape[0] * [0], :] , 1 , __UpperCAmelCase ) return back.reshape(__UpperCAmelCase ) def lowercase_ (self : Optional[Any] , __UpperCAmelCase : Dict ) -> List[str]: """simple docstring""" UpperCAmelCase__ = z.permute(0 , 2 , 3 , 1 ).contiguous() UpperCAmelCase__ = z.view(-1 , self.vq_embed_dim ) # distances from z to embeddings e_j (z - e)^2 = z^2 + e^2 - 2 e * z UpperCAmelCase__ = torch.argmin(torch.cdist(__UpperCAmelCase , self.embedding.weight ) , dim=1 ) UpperCAmelCase__ = self.embedding(__UpperCAmelCase ).view(z.shape ) UpperCAmelCase__ = None UpperCAmelCase__ = None # compute loss for embedding if not self.legacy: UpperCAmelCase__ = self.beta * torch.mean((z_q.detach() - z) ** 2 ) + torch.mean((z_q - z.detach()) ** 2 ) else: UpperCAmelCase__ = torch.mean((z_q.detach() - z) ** 2 ) + self.beta * torch.mean((z_q - z.detach()) ** 2 ) # preserve gradients UpperCAmelCase__ = z + (z_q - z).detach() # reshape back to match original input shape UpperCAmelCase__ = z_q.permute(0 , 3 , 1 , 2 ).contiguous() if self.remap is not None: UpperCAmelCase__ = min_encoding_indices.reshape(z.shape[0] , -1 ) # add batch axis UpperCAmelCase__ = self.remap_to_used(__UpperCAmelCase ) UpperCAmelCase__ = min_encoding_indices.reshape(-1 , 1 ) # flatten if self.sane_index_shape: UpperCAmelCase__ = min_encoding_indices.reshape(z_q.shape[0] , z_q.shape[2] , z_q.shape[3] ) return z_q, loss, (perplexity, min_encodings, min_encoding_indices) def lowercase_ (self : Optional[int] , __UpperCAmelCase : int , __UpperCAmelCase : Optional[Any] ) -> Any: """simple docstring""" if self.remap is not None: UpperCAmelCase__ = indices.reshape(shape[0] , -1 ) # add batch axis UpperCAmelCase__ = self.unmap_to_all(__UpperCAmelCase ) UpperCAmelCase__ = indices.reshape(-1 ) # flatten again # get quantized latent vectors UpperCAmelCase__ = self.embedding(__UpperCAmelCase ) if shape is not None: UpperCAmelCase__ = z_q.view(__UpperCAmelCase ) # reshape back to match original input shape UpperCAmelCase__ = z_q.permute(0 , 3 , 1 , 2 ).contiguous() return z_q class A ( UpperCAmelCase_ ): def __init__(self : Any , __UpperCAmelCase : Dict , __UpperCAmelCase : str=False ) -> Tuple: """simple docstring""" UpperCAmelCase__ = parameters UpperCAmelCase__ , UpperCAmelCase__ = torch.chunk(__UpperCAmelCase , 2 , dim=1 ) UpperCAmelCase__ = torch.clamp(self.logvar , -30.0 , 20.0 ) UpperCAmelCase__ = deterministic UpperCAmelCase__ = torch.exp(0.5 * self.logvar ) UpperCAmelCase__ = torch.exp(self.logvar ) if self.deterministic: UpperCAmelCase__ = UpperCAmelCase__ = torch.zeros_like( self.mean , device=self.parameters.device , dtype=self.parameters.dtype ) def lowercase_ (self : Union[str, Any] , __UpperCAmelCase : Optional[torch.Generator] = None ) -> torch.FloatTensor: """simple docstring""" UpperCAmelCase__ = randn_tensor( self.mean.shape , generator=__UpperCAmelCase , device=self.parameters.device , dtype=self.parameters.dtype ) UpperCAmelCase__ = self.mean + self.std * sample return x def lowercase_ (self : str , __UpperCAmelCase : int=None ) -> Any: """simple docstring""" if self.deterministic: return torch.Tensor([0.0] ) else: if other is None: return 0.5 * torch.sum(torch.pow(self.mean , 2 ) + self.var - 1.0 - self.logvar , dim=[1, 2, 3] ) else: return 0.5 * torch.sum( torch.pow(self.mean - other.mean , 2 ) / other.var + self.var / other.var - 1.0 - self.logvar + other.logvar , dim=[1, 2, 3] , ) def lowercase_ (self : Dict , __UpperCAmelCase : Tuple , __UpperCAmelCase : Any=[1, 2, 3] ) -> Dict: """simple docstring""" if self.deterministic: return torch.Tensor([0.0] ) UpperCAmelCase__ = np.log(2.0 * np.pi ) return 0.5 * torch.sum(logtwopi + self.logvar + torch.pow(sample - self.mean , 2 ) / self.var , dim=__UpperCAmelCase ) def lowercase_ (self : Tuple ) -> Optional[Any]: """simple docstring""" return self.mean
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0
"""simple docstring""" # Copyright 2022 The HuggingFace Team and The OpenBMB 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 lowercase__ : Tuple = { '''configuration_cpmant''': ['''CPMANT_PRETRAINED_CONFIG_ARCHIVE_MAP''', '''CpmAntConfig'''], '''tokenization_cpmant''': ['''CpmAntTokenizer'''], } try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: lowercase__ : List[str] = [ '''CPMANT_PRETRAINED_MODEL_ARCHIVE_LIST''', '''CpmAntForCausalLM''', '''CpmAntModel''', '''CpmAntPreTrainedModel''', ] if TYPE_CHECKING: from .configuration_cpmant import CPMANT_PRETRAINED_CONFIG_ARCHIVE_MAP, CpmAntConfig from .tokenization_cpmant import CpmAntTokenizer try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_cpmant import ( CPMANT_PRETRAINED_MODEL_ARCHIVE_LIST, CpmAntForCausalLM, CpmAntModel, CpmAntPreTrainedModel, ) else: import sys lowercase__ : Optional[int] = _LazyModule(__name__, globals()['''__file__'''], _import_structure, module_spec=__spec__)
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import asyncio import os import re import sys import tempfile import unittest from contextlib import contextmanager from copy import deepcopy from distutils.util import strtobool from enum import Enum from importlib.util import find_spec from pathlib import Path from unittest.mock import patch import pyarrow as pa import pytest import requests from packaging import version from datasets import config if config.PY_VERSION < version.parse('3.8'): import importlib_metadata else: import importlib.metadata as importlib_metadata def lowerCAmelCase_ ( __A, __A=False ) -> Any: '''simple docstring''' try: UpperCAmelCase__ = os.environ[key] except KeyError: # KEY isn't set, default to `default`. UpperCAmelCase__ = default else: # KEY is set, convert it to True or False. try: UpperCAmelCase__ = strtobool(__A ) except ValueError: # More values are supported, but let's keep the message simple. raise ValueError(f"""If set, {key} must be yes or no.""" ) return _value UpperCamelCase__ = parse_flag_from_env('RUN_SLOW', default=False) UpperCamelCase__ = parse_flag_from_env('RUN_REMOTE', default=False) UpperCamelCase__ = parse_flag_from_env('RUN_LOCAL', default=True) UpperCamelCase__ = parse_flag_from_env('RUN_PACKAGED', default=True) # Compression UpperCamelCase__ = pytest.mark.skipif(not config.LZ4_AVAILABLE, reason='test requires lz4') UpperCamelCase__ = pytest.mark.skipif(not config.PY7ZR_AVAILABLE, reason='test requires py7zr') UpperCamelCase__ = pytest.mark.skipif(not config.ZSTANDARD_AVAILABLE, reason='test requires zstandard') # Audio UpperCamelCase__ = pytest.mark.skipif( # On Windows and OS X, soundfile installs sndfile find_spec('soundfile') is None or version.parse(importlib_metadata.version('soundfile')) < version.parse('0.12.0'), reason='test requires sndfile>=0.12.1: \'pip install \"soundfile>=0.12.1\"\'; ', ) # Beam UpperCamelCase__ = pytest.mark.skipif( not config.BEAM_AVAILABLE or config.DILL_VERSION >= version.parse('0.3.2'), reason='test requires apache-beam and a compatible dill version', ) # Dill-cloudpickle compatibility UpperCamelCase__ = pytest.mark.skipif( config.DILL_VERSION <= version.parse('0.3.2'), reason='test requires dill>0.3.2 for cloudpickle compatibility', ) # Windows UpperCamelCase__ = pytest.mark.skipif( sys.platform == 'win32', reason='test should not be run on Windows', ) def lowerCAmelCase_ ( __A ) -> Any: '''simple docstring''' try: import faiss # noqa except ImportError: UpperCAmelCase__ = unittest.skip("test requires faiss" )(__A ) return test_case def lowerCAmelCase_ ( __A ) -> Optional[Any]: '''simple docstring''' try: import regex # noqa except ImportError: UpperCAmelCase__ = unittest.skip("test requires regex" )(__A ) return test_case def lowerCAmelCase_ ( __A ) -> List[str]: '''simple docstring''' try: import elasticsearch # noqa except ImportError: UpperCAmelCase__ = unittest.skip("test requires elasticsearch" )(__A ) return test_case def lowerCAmelCase_ ( __A ) -> List[Any]: '''simple docstring''' try: import sqlalchemy # noqa except ImportError: UpperCAmelCase__ = unittest.skip("test requires sqlalchemy" )(__A ) return test_case def lowerCAmelCase_ ( __A ) -> List[str]: '''simple docstring''' if not config.TORCH_AVAILABLE: UpperCAmelCase__ = unittest.skip("test requires PyTorch" )(__A ) return test_case def lowerCAmelCase_ ( __A ) -> Union[str, Any]: '''simple docstring''' if not config.TF_AVAILABLE: UpperCAmelCase__ = unittest.skip("test requires TensorFlow" )(__A ) return test_case def lowerCAmelCase_ ( __A ) -> Any: '''simple docstring''' if not config.JAX_AVAILABLE: UpperCAmelCase__ = unittest.skip("test requires JAX" )(__A ) return test_case def lowerCAmelCase_ ( __A ) -> int: '''simple docstring''' if not config.PIL_AVAILABLE: UpperCAmelCase__ = unittest.skip("test requires Pillow" )(__A ) return test_case def lowerCAmelCase_ ( __A ) -> Tuple: '''simple docstring''' try: import transformers # noqa F401 except ImportError: return unittest.skip("test requires transformers" )(__A ) else: return test_case def lowerCAmelCase_ ( __A ) -> Dict: '''simple docstring''' try: import tiktoken # noqa F401 except ImportError: return unittest.skip("test requires tiktoken" )(__A ) else: return test_case def lowerCAmelCase_ ( __A ) -> Optional[Any]: '''simple docstring''' try: import spacy # noqa F401 except ImportError: return unittest.skip("test requires spacy" )(__A ) else: return test_case def lowerCAmelCase_ ( __A ) -> Optional[int]: '''simple docstring''' def _require_spacy_model(__A ): try: import spacy # noqa F401 spacy.load(__A ) except ImportError: return unittest.skip("test requires spacy" )(__A ) except OSError: return unittest.skip("test requires spacy model '{}'".format(__A ) )(__A ) else: return test_case return _require_spacy_model def lowerCAmelCase_ ( __A ) -> Optional[Any]: '''simple docstring''' try: import pyspark # noqa F401 except ImportError: return unittest.skip("test requires pyspark" )(__A ) else: return test_case def lowerCAmelCase_ ( __A ) -> Tuple: '''simple docstring''' try: import joblibspark # noqa F401 except ImportError: return unittest.skip("test requires joblibspark" )(__A ) else: return test_case def lowerCAmelCase_ ( __A ) -> Optional[int]: '''simple docstring''' if not _run_slow_tests or _run_slow_tests == 0: UpperCAmelCase__ = unittest.skip("test is slow" )(__A ) return test_case def lowerCAmelCase_ ( __A ) -> List[Any]: '''simple docstring''' if not _run_local_tests or _run_local_tests == 0: UpperCAmelCase__ = unittest.skip("test is local" )(__A ) return test_case def lowerCAmelCase_ ( __A ) -> Optional[Any]: '''simple docstring''' if not _run_packaged_tests or _run_packaged_tests == 0: UpperCAmelCase__ = unittest.skip("test is packaged" )(__A ) return test_case def lowerCAmelCase_ ( __A ) -> Any: '''simple docstring''' if not _run_remote_tests or _run_remote_tests == 0: UpperCAmelCase__ = unittest.skip("test requires remote" )(__A ) return test_case def lowerCAmelCase_ ( *__A ) -> Optional[int]: '''simple docstring''' def decorate(cls ): for name, fn in cls.__dict__.items(): if callable(__A ) and name.startswith("test" ): for decorator in decorators: UpperCAmelCase__ = decorator(__A ) setattr(cls, __A, __A ) return cls return decorate class A ( UpperCAmelCase_ ): pass class A ( UpperCAmelCase_ ): __UpperCAmelCase : Union[str, Any] = 0 __UpperCAmelCase : str = 1 __UpperCAmelCase : int = 2 @contextmanager def lowerCAmelCase_ ( __A=OfflineSimulationMode.CONNECTION_FAILS, __A=1e-16 ) -> List[str]: '''simple docstring''' UpperCAmelCase__ = requests.Session().request def timeout_request(__A, __A, __A, **__A ): # Change the url to an invalid url so that the connection hangs UpperCAmelCase__ = "https://10.255.255.1" if kwargs.get("timeout" ) is None: raise RequestWouldHangIndefinitelyError( f"""Tried a call to {url} in offline mode with no timeout set. Please set a timeout.""" ) UpperCAmelCase__ = timeout try: return online_request(__A, __A, **__A ) except Exception as e: # The following changes in the error are just here to make the offline timeout error prettier UpperCAmelCase__ = url UpperCAmelCase__ = e.args[0] UpperCAmelCase__ = (max_retry_error.args[0].replace("10.255.255.1", f"""OfflineMock[{url}]""" ),) UpperCAmelCase__ = (max_retry_error,) raise def raise_connection_error(__A, __A, **__A ): raise requests.ConnectionError("Offline mode is enabled.", request=__A ) if mode is OfflineSimulationMode.CONNECTION_FAILS: with patch("requests.Session.send", __A ): yield elif mode is OfflineSimulationMode.CONNECTION_TIMES_OUT: # inspired from https://stackoverflow.com/a/904609 with patch("requests.Session.request", __A ): yield elif mode is OfflineSimulationMode.HF_DATASETS_OFFLINE_SET_TO_1: with patch("datasets.config.HF_DATASETS_OFFLINE", __A ): yield else: raise ValueError("Please use a value from the OfflineSimulationMode enum." ) @contextmanager def lowerCAmelCase_ ( *__A, **__A ) -> str: '''simple docstring''' UpperCAmelCase__ = str(Path().resolve() ) with tempfile.TemporaryDirectory(*__A, **__A ) as tmp_dir: try: os.chdir(__A ) yield finally: os.chdir(__A ) @contextmanager def lowerCAmelCase_ ( ) -> Optional[Any]: '''simple docstring''' import gc gc.collect() UpperCAmelCase__ = pa.total_allocated_bytes() yield assert pa.total_allocated_bytes() - previous_allocated_memory > 0, "Arrow memory didn't increase." @contextmanager def lowerCAmelCase_ ( ) -> List[str]: '''simple docstring''' import gc gc.collect() UpperCAmelCase__ = pa.total_allocated_bytes() yield assert pa.total_allocated_bytes() - previous_allocated_memory <= 0, "Arrow memory wasn't expected to increase." def lowerCAmelCase_ ( __A, __A ) -> List[str]: '''simple docstring''' return deepcopy(__A ).integers(0, 100, 10 ).tolist() == deepcopy(__A ).integers(0, 100, 10 ).tolist() def lowerCAmelCase_ ( __A ) -> Optional[int]: '''simple docstring''' import decorator from requests.exceptions import HTTPError def _wrapper(__A, *__A, **__A ): try: return func(*__A, **__A ) except HTTPError as err: if str(__A ).startswith("500" ) or str(__A ).startswith("502" ): pytest.xfail(str(__A ) ) raise err return decorator.decorator(_wrapper, __A ) class A : def __init__(self : Optional[Any] , __UpperCAmelCase : int , __UpperCAmelCase : int , __UpperCAmelCase : List[str] ) -> Union[str, Any]: """simple docstring""" UpperCAmelCase__ = returncode UpperCAmelCase__ = stdout UpperCAmelCase__ = stderr async def lowerCAmelCase_ ( __A, __A ) -> Optional[int]: '''simple docstring''' while True: UpperCAmelCase__ = await stream.readline() if line: callback(__A ) else: break async def lowerCAmelCase_ ( __A, __A=None, __A=None, __A=None, __A=False, __A=False ) -> _RunOutput: '''simple docstring''' if echo: print("\nRunning: ", " ".join(__A ) ) UpperCAmelCase__ = await asyncio.create_subprocess_exec( cmd[0], *cmd[1:], stdin=__A, stdout=asyncio.subprocess.PIPE, stderr=asyncio.subprocess.PIPE, env=__A, ) # note: there is a warning for a possible deadlock when using `wait` with huge amounts of data in the pipe # https://docs.python.org/3/library/asyncio-subprocess.html#asyncio.asyncio.subprocess.Process.wait # # If it starts hanging, will need to switch to the following code. The problem is that no data # will be seen until it's done and if it hangs for example there will be no debug info. # out, err = await p.communicate() # return _RunOutput(p.returncode, out, err) UpperCAmelCase__ = [] UpperCAmelCase__ = [] def tee(__A, __A, __A, __A="" ): UpperCAmelCase__ = line.decode("utf-8" ).rstrip() sink.append(__A ) if not quiet: print(__A, __A, file=__A ) # XXX: the timeout doesn't seem to make any difference here await asyncio.wait( [ _read_stream(p.stdout, lambda __A : tee(__A, __A, sys.stdout, label="stdout:" ) ), _read_stream(p.stderr, lambda __A : tee(__A, __A, sys.stderr, label="stderr:" ) ), ], timeout=__A, ) return _RunOutput(await p.wait(), __A, __A ) def lowerCAmelCase_ ( __A, __A=None, __A=None, __A=180, __A=False, __A=True ) -> _RunOutput: '''simple docstring''' UpperCAmelCase__ = asyncio.get_event_loop() UpperCAmelCase__ = loop.run_until_complete( _stream_subprocess(__A, env=__A, stdin=__A, timeout=__A, quiet=__A, echo=__A ) ) UpperCAmelCase__ = " ".join(__A ) if result.returncode > 0: UpperCAmelCase__ = "\n".join(result.stderr ) raise RuntimeError( f"""'{cmd_str}' failed with returncode {result.returncode}\n\n""" f"""The combined stderr from workers follows:\n{stderr}""" ) # check that the subprocess actually did run and produced some output, should the test rely on # the remote side to do the testing if not result.stdout and not result.stderr: raise RuntimeError(f"""'{cmd_str}' produced no output.""" ) return result def lowerCAmelCase_ ( ) -> Tuple: '''simple docstring''' UpperCAmelCase__ = os.environ.get("PYTEST_XDIST_WORKER", "gw0" ) UpperCAmelCase__ = re.sub(r"^gw", "", __A, 0, re.M ) return int(__A ) def lowerCAmelCase_ ( ) -> List[Any]: '''simple docstring''' UpperCAmelCase__ = 29_500 UpperCAmelCase__ = pytest_xdist_worker_id() return port + uniq_delta
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from __future__ import annotations import typing from collections import Counter def a__ ( UpperCAmelCase : Optional[Any] ) -> typing.Counter[int]: UpperCAmelCase : Dict = Counter() for base in range(1 , max_perimeter + 1 ): for perpendicular in range(__A , max_perimeter + 1 ): UpperCAmelCase : List[Any] = (base * base + perpendicular * perpendicular) ** 0.5 if hypotenuse == int(__A ): UpperCAmelCase : Any = int(base + perpendicular + hypotenuse ) if perimeter > max_perimeter: continue triplets[perimeter] += 1 return triplets def a__ ( UpperCAmelCase : List[str] = 1_000 ) -> int: UpperCAmelCase : Any = pythagorean_triple(__A ) return triplets.most_common(1 )[0][0] if __name__ == "__main__": print(f"""Perimeter {solution()} has maximum solutions""")
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def lowerCAmelCase_ ( __A, __A ) -> float: '''simple docstring''' def get_matched_characters(__A, __A ) -> str: UpperCAmelCase__ = [] UpperCAmelCase__ = min(len(_stra ), len(_stra ) ) // 2 for i, l in enumerate(_stra ): UpperCAmelCase__ = int(max(0, i - limit ) ) UpperCAmelCase__ = int(min(i + limit + 1, len(_stra ) ) ) if l in _stra[left:right]: matched.append(__A ) UpperCAmelCase__ = f"""{_stra[0:_stra.index(__A )]} {_stra[_stra.index(__A ) + 1:]}""" return "".join(__A ) # matching characters UpperCAmelCase__ = get_matched_characters(__A, __A ) UpperCAmelCase__ = get_matched_characters(__A, __A ) UpperCAmelCase__ = len(__A ) # transposition UpperCAmelCase__ = ( len([(ca, ca) for ca, ca in zip(__A, __A ) if ca != ca] ) // 2 ) if not match_count: UpperCAmelCase__ = 0.0 else: UpperCAmelCase__ = ( 1 / 3 * ( match_count / len(__A ) + match_count / len(__A ) + (match_count - transpositions) / match_count ) ) # common prefix up to 4 characters UpperCAmelCase__ = 0 for ca, ca in zip(stra[:4], stra[:4] ): if ca == ca: prefix_len += 1 else: break return jaro + 0.1 * prefix_len * (1 - jaro) if __name__ == "__main__": import doctest doctest.testmod() print(jaro_winkler('hello', 'world'))
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"""simple docstring""" from __future__ import annotations def _lowerCamelCase( a ): return [ord(__A ) - 9_6 for elem in plain] def _lowerCamelCase( a ): return "".join(chr(elem + 9_6 ) for elem in encoded ) def _lowerCamelCase( ): __a = encode(input("-> " ).strip().lower() ) print("Encoded: " , __A ) print("Decoded:" , decode(__A ) ) if __name__ == "__main__": main()
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def lowerCAmelCase_ ( __A, __A ) -> None: '''simple docstring''' UpperCAmelCase__ = len(__A ) print("The following activities are selected:" ) # The first activity is always selected UpperCAmelCase__ = 0 print(__A, end="," ) # Consider rest of the activities for j in range(__A ): # If this activity has start time greater than # or equal to the finish time of previously # selected activity, then select it if start[j] >= finish[i]: print(__A, end="," ) UpperCAmelCase__ = j if __name__ == "__main__": import doctest doctest.testmod() UpperCamelCase__ = [1, 3, 0, 5, 8, 5] UpperCamelCase__ = [2, 4, 6, 7, 9, 9] print_max_activities(start, finish)
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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_xlnet import XLNetTokenizer else: _snake_case = None _snake_case = logging.get_logger(__name__) _snake_case = {'vocab_file': 'spiece.model', 'tokenizer_file': 'tokenizer.json'} _snake_case = { 'vocab_file': { 'xlnet-base-cased': 'https://huggingface.co/xlnet-base-cased/resolve/main/spiece.model', 'xlnet-large-cased': 'https://huggingface.co/xlnet-large-cased/resolve/main/spiece.model', }, 'tokenizer_file': { 'xlnet-base-cased': 'https://huggingface.co/xlnet-base-cased/resolve/main/tokenizer.json', 'xlnet-large-cased': 'https://huggingface.co/xlnet-large-cased/resolve/main/tokenizer.json', }, } _snake_case = { 'xlnet-base-cased': None, 'xlnet-large-cased': None, } _snake_case = '▁' # Segments (not really needed) _snake_case = 0 _snake_case = 1 _snake_case = 2 _snake_case = 3 _snake_case = 4 class UpperCamelCase ( UpperCAmelCase_ ): UpperCamelCase : int = VOCAB_FILES_NAMES UpperCamelCase : List[str] = PRETRAINED_VOCAB_FILES_MAP UpperCamelCase : int = PRETRAINED_POSITIONAL_EMBEDDINGS_SIZES UpperCamelCase : str = 'left' UpperCamelCase : List[str] = XLNetTokenizer def __init__( self : Union[str, Any] , UpperCAmelCase__ : Optional[int]=None , UpperCAmelCase__ : List[str]=None , UpperCAmelCase__ : List[Any]=False , UpperCAmelCase__ : Union[str, Any]=True , UpperCAmelCase__ : Union[str, Any]=False , UpperCAmelCase__ : str="<s>" , UpperCAmelCase__ : Tuple="</s>" , UpperCAmelCase__ : List[Any]="<unk>" , UpperCAmelCase__ : int="<sep>" , UpperCAmelCase__ : Optional[Any]="<pad>" , UpperCAmelCase__ : str="<cls>" , UpperCAmelCase__ : Union[str, Any]="<mask>" , UpperCAmelCase__ : Optional[int]=["<eop>", "<eod>"] , **UpperCAmelCase__ : Any , ) -> Any: _a : Optional[int] = AddedToken(__UpperCAmelCase , lstrip=__UpperCAmelCase , rstrip=__UpperCAmelCase ) if isinstance(__UpperCAmelCase , __UpperCAmelCase ) else mask_token super().__init__( vocab_file=__UpperCAmelCase , tokenizer_file=__UpperCAmelCase , do_lower_case=__UpperCAmelCase , remove_space=__UpperCAmelCase , keep_accents=__UpperCAmelCase , bos_token=__UpperCAmelCase , eos_token=__UpperCAmelCase , unk_token=__UpperCAmelCase , sep_token=__UpperCAmelCase , pad_token=__UpperCAmelCase , cls_token=__UpperCAmelCase , mask_token=__UpperCAmelCase , additional_special_tokens=__UpperCAmelCase , **__UpperCAmelCase , ) _a : str = 3 _a : Dict = do_lower_case _a : Optional[Any] = remove_space _a : List[str] = keep_accents _a : str = vocab_file _a : str = False if not self.vocab_file else True def _lowercase ( self : Optional[Any] , UpperCAmelCase__ : List[int] , UpperCAmelCase__ : Optional[List[int]] = None ) -> List[int]: _a : Any = [self.sep_token_id] _a : Dict = [self.cls_token_id] if token_ids_a is None: return token_ids_a + sep + cls return token_ids_a + sep + token_ids_a + sep + cls def _lowercase ( self : str , UpperCAmelCase__ : List[int] , UpperCAmelCase__ : Optional[List[int]] = None ) -> List[int]: _a : Tuple = [self.sep_token_id] _a : List[str] = [2] if token_ids_a is None: return len(token_ids_a + sep ) * [0] + cls_segment_id return len(token_ids_a + sep ) * [0] + len(token_ids_a + sep ) * [1] + cls_segment_id def _lowercase ( self : int , UpperCAmelCase__ : str , UpperCAmelCase__ : Optional[str] = None ) -> Tuple[str]: if not self.can_save_slow_tokenizer: raise ValueError( """Your fast tokenizer does not have the necessary information to save the vocabulary for a slow """ """tokenizer.""" ) if not os.path.isdir(__UpperCAmelCase ): logger.error(f"""Vocabulary path ({save_directory}) should be a directory""" ) return _a : int = os.path.join( __UpperCAmelCase , (filename_prefix + """-""" if filename_prefix else """""") + VOCAB_FILES_NAMES["""vocab_file"""] ) if os.path.abspath(self.vocab_file ) != os.path.abspath(__UpperCAmelCase ): copyfile(self.vocab_file , __UpperCAmelCase ) return (out_vocab_file,)
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import argparse import os import jax as jnp import numpy as onp import torch import torch.nn as nn from music_spectrogram_diffusion import inference from tax import checkpoints from diffusers import DDPMScheduler, OnnxRuntimeModel, SpectrogramDiffusionPipeline from diffusers.pipelines.spectrogram_diffusion import SpectrogramContEncoder, SpectrogramNotesEncoder, TaFilmDecoder UpperCamelCase__ = 'base_with_context' def lowerCAmelCase_ ( __A, __A ) -> int: '''simple docstring''' UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(weights["token_embedder"]["embedding"] ) ) UpperCAmelCase__ = nn.Parameter( torch.FloatTensor(weights["Embed_0"]["embedding"] ), requires_grad=__A ) for lyr_num, lyr in enumerate(model.encoders ): UpperCAmelCase__ = weights[f"""layers_{lyr_num}"""] UpperCAmelCase__ = nn.Parameter( torch.FloatTensor(ly_weight["pre_attention_layer_norm"]["scale"] ) ) UpperCAmelCase__ = ly_weight["attention"] UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(attention_weights["query"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(attention_weights["key"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(attention_weights["value"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(attention_weights["out"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(ly_weight["pre_mlp_layer_norm"]["scale"] ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(ly_weight["mlp"]["wi_0"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(ly_weight["mlp"]["wi_1"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(ly_weight["mlp"]["wo"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(weights["encoder_norm"]["scale"] ) ) return model def lowerCAmelCase_ ( __A, __A ) -> Tuple: '''simple docstring''' UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(weights["input_proj"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter( torch.FloatTensor(weights["Embed_0"]["embedding"] ), requires_grad=__A ) for lyr_num, lyr in enumerate(model.encoders ): UpperCAmelCase__ = weights[f"""layers_{lyr_num}"""] UpperCAmelCase__ = ly_weight["attention"] UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(attention_weights["query"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(attention_weights["key"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(attention_weights["value"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(attention_weights["out"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter( torch.FloatTensor(ly_weight["pre_attention_layer_norm"]["scale"] ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(ly_weight["mlp"]["wi_0"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(ly_weight["mlp"]["wi_1"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(ly_weight["mlp"]["wo"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(ly_weight["pre_mlp_layer_norm"]["scale"] ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(weights["encoder_norm"]["scale"] ) ) return model def lowerCAmelCase_ ( __A, __A ) -> List[Any]: '''simple docstring''' UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(weights["time_emb_dense0"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(weights["time_emb_dense1"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter( torch.FloatTensor(weights["Embed_0"]["embedding"] ), requires_grad=__A ) UpperCAmelCase__ = nn.Parameter( torch.FloatTensor(weights["continuous_inputs_projection"]["kernel"].T ) ) for lyr_num, lyr in enumerate(model.decoders ): UpperCAmelCase__ = weights[f"""layers_{lyr_num}"""] UpperCAmelCase__ = nn.Parameter( torch.FloatTensor(ly_weight["pre_self_attention_layer_norm"]["scale"] ) ) UpperCAmelCase__ = nn.Parameter( torch.FloatTensor(ly_weight["FiLMLayer_0"]["DenseGeneral_0"]["kernel"].T ) ) UpperCAmelCase__ = ly_weight["self_attention"] UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(attention_weights["query"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(attention_weights["key"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(attention_weights["value"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(attention_weights["out"]["kernel"].T ) ) UpperCAmelCase__ = ly_weight["MultiHeadDotProductAttention_0"] UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(attention_weights["query"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(attention_weights["key"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(attention_weights["value"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(attention_weights["out"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter( torch.FloatTensor(ly_weight["pre_cross_attention_layer_norm"]["scale"] ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(ly_weight["pre_mlp_layer_norm"]["scale"] ) ) UpperCAmelCase__ = nn.Parameter( torch.FloatTensor(ly_weight["FiLMLayer_1"]["DenseGeneral_0"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(ly_weight["mlp"]["wi_0"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(ly_weight["mlp"]["wi_1"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(ly_weight["mlp"]["wo"]["kernel"].T ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(weights["decoder_norm"]["scale"] ) ) UpperCAmelCase__ = nn.Parameter(torch.FloatTensor(weights["spec_out_dense"]["kernel"].T ) ) return model def lowerCAmelCase_ ( __A ) -> int: '''simple docstring''' UpperCAmelCase__ = checkpoints.load_tax_checkpoint(args.checkpoint_path ) UpperCAmelCase__ = jnp.tree_util.tree_map(onp.array, __A ) UpperCAmelCase__ = [ "from __gin__ import dynamic_registration", "from music_spectrogram_diffusion.models.diffusion import diffusion_utils", "diffusion_utils.ClassifierFreeGuidanceConfig.eval_condition_weight = 2.0", "diffusion_utils.DiffusionConfig.classifier_free_guidance = @diffusion_utils.ClassifierFreeGuidanceConfig()", ] UpperCAmelCase__ = os.path.join(args.checkpoint_path, "..", "config.gin" ) UpperCAmelCase__ = inference.parse_training_gin_file(__A, __A ) UpperCAmelCase__ = inference.InferenceModel(args.checkpoint_path, __A ) UpperCAmelCase__ = DDPMScheduler(beta_schedule="squaredcos_cap_v2", variance_type="fixed_large" ) UpperCAmelCase__ = SpectrogramNotesEncoder( max_length=synth_model.sequence_length["inputs"], vocab_size=synth_model.model.module.config.vocab_size, d_model=synth_model.model.module.config.emb_dim, dropout_rate=synth_model.model.module.config.dropout_rate, num_layers=synth_model.model.module.config.num_encoder_layers, num_heads=synth_model.model.module.config.num_heads, d_kv=synth_model.model.module.config.head_dim, d_ff=synth_model.model.module.config.mlp_dim, feed_forward_proj="gated-gelu", ) UpperCAmelCase__ = SpectrogramContEncoder( input_dims=synth_model.audio_codec.n_dims, targets_context_length=synth_model.sequence_length["targets_context"], d_model=synth_model.model.module.config.emb_dim, dropout_rate=synth_model.model.module.config.dropout_rate, num_layers=synth_model.model.module.config.num_encoder_layers, num_heads=synth_model.model.module.config.num_heads, d_kv=synth_model.model.module.config.head_dim, d_ff=synth_model.model.module.config.mlp_dim, feed_forward_proj="gated-gelu", ) UpperCAmelCase__ = TaFilmDecoder( input_dims=synth_model.audio_codec.n_dims, targets_length=synth_model.sequence_length["targets_context"], max_decoder_noise_time=synth_model.model.module.config.max_decoder_noise_time, d_model=synth_model.model.module.config.emb_dim, num_layers=synth_model.model.module.config.num_decoder_layers, num_heads=synth_model.model.module.config.num_heads, d_kv=synth_model.model.module.config.head_dim, d_ff=synth_model.model.module.config.mlp_dim, dropout_rate=synth_model.model.module.config.dropout_rate, ) UpperCAmelCase__ = load_notes_encoder(ta_checkpoint["target"]["token_encoder"], __A ) UpperCAmelCase__ = load_continuous_encoder(ta_checkpoint["target"]["continuous_encoder"], __A ) UpperCAmelCase__ = load_decoder(ta_checkpoint["target"]["decoder"], __A ) UpperCAmelCase__ = OnnxRuntimeModel.from_pretrained("kashif/soundstream_mel_decoder" ) UpperCAmelCase__ = SpectrogramDiffusionPipeline( notes_encoder=__A, continuous_encoder=__A, decoder=__A, scheduler=__A, melgan=__A, ) if args.save: pipe.save_pretrained(args.output_path ) if __name__ == "__main__": UpperCamelCase__ = argparse.ArgumentParser() parser.add_argument('--output_path', default=None, type=str, required=True, help='Path to the converted model.') parser.add_argument( '--save', default=True, type=bool, required=False, help='Whether to save the converted model or not.' ) parser.add_argument( '--checkpoint_path', default=f'''{MODEL}/checkpoint_500000''', type=str, required=False, help='Path to the original jax model checkpoint.', ) UpperCamelCase__ = parser.parse_args() main(args)
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"""simple docstring""" import os from shutil import copyfile from typing import Any, Dict, List, Optional, Tuple import sentencepiece as spm from ...tokenization_utils import PreTrainedTokenizer from ...utils import logging A_ = logging.get_logger(__name__) A_ = {'''vocab_file''': '''spm_char.model'''} A_ = { '''vocab_file''': { '''microsoft/speecht5_asr''': '''https://huggingface.co/microsoft/speecht5_asr/resolve/main/spm_char.model''', '''microsoft/speecht5_tts''': '''https://huggingface.co/microsoft/speecht5_tts/resolve/main/spm_char.model''', '''microsoft/speecht5_vc''': '''https://huggingface.co/microsoft/speecht5_vc/resolve/main/spm_char.model''', } } A_ = { '''microsoft/speecht5_asr''': 10_24, '''microsoft/speecht5_tts''': 10_24, '''microsoft/speecht5_vc''': 10_24, } class lowercase( UpperCAmelCase_ ): '''simple docstring''' lowercase__ = VOCAB_FILES_NAMES lowercase__ = PRETRAINED_VOCAB_FILES_MAP lowercase__ = PRETRAINED_POSITIONAL_EMBEDDINGS_SIZES lowercase__ = ['input_ids', 'attention_mask'] def __init__( self: Tuple, a_: Optional[Any], a_: List[str]="<s>", a_: Union[str, Any]="</s>", a_: List[str]="<unk>", a_: Any="<pad>", a_: Optional[Dict[str, Any]] = None, **a_: Optional[Any], ): '''simple docstring''' _snake_case : List[Any] = {} if sp_model_kwargs is None else sp_model_kwargs super().__init__( bos_token=__UpperCAmelCase, eos_token=__UpperCAmelCase, unk_token=__UpperCAmelCase, pad_token=__UpperCAmelCase, sp_model_kwargs=self.sp_model_kwargs, **__UpperCAmelCase, ) _snake_case : int = vocab_file _snake_case : List[Any] = spm.SentencePieceProcessor(**self.sp_model_kwargs ) self.sp_model.Load(__UpperCAmelCase ) @property def UpperCamelCase_ ( self: Optional[Any] ): '''simple docstring''' return self.sp_model.get_piece_size() def UpperCamelCase_ ( self: List[Any] ): '''simple docstring''' _snake_case : Tuple = {self.convert_ids_to_tokens(__UpperCAmelCase ): i for i in range(self.vocab_size )} vocab.update(self.added_tokens_encoder ) return vocab def __getstate__( self: Tuple ): '''simple docstring''' _snake_case : Tuple = self.__dict__.copy() _snake_case : Any = None return state def __setstate__( self: Union[str, Any], a_: str ): '''simple docstring''' _snake_case : str = d # for backward compatibility if not hasattr(self, """sp_model_kwargs""" ): _snake_case : Optional[Any] = {} _snake_case : Union[str, Any] = spm.SentencePieceProcessor(**self.sp_model_kwargs ) self.sp_model.Load(self.vocab_file ) def UpperCamelCase_ ( self: Optional[Any], a_: str ): '''simple docstring''' return self.sp_model.encode(__UpperCAmelCase, out_type=__UpperCAmelCase ) def UpperCamelCase_ ( self: Tuple, a_: Tuple ): '''simple docstring''' return self.sp_model.piece_to_id(__UpperCAmelCase ) def UpperCamelCase_ ( self: str, a_: Dict ): '''simple docstring''' _snake_case : Optional[int] = self.sp_model.IdToPiece(__UpperCAmelCase ) return token def UpperCamelCase_ ( self: Any, a_: List[Any] ): '''simple docstring''' _snake_case : List[Any] = [] _snake_case : Tuple = """""" for token in tokens: # make sure that special tokens are not decoded using sentencepiece model if token in self.all_special_tokens: out_string += self.sp_model.decode(__UpperCAmelCase ) + token _snake_case : Tuple = [] else: current_sub_tokens.append(__UpperCAmelCase ) out_string += self.sp_model.decode(__UpperCAmelCase ) return out_string.strip() def UpperCamelCase_ ( self: Any, a_: int, a_: Optional[Any]=None ): '''simple docstring''' if token_ids_a is None: return token_ids_a + [self.eos_token_id] # We don't expect to process pairs, but leave the pair logic for API consistency return token_ids_a + token_ids_a + [self.eos_token_id] def UpperCamelCase_ ( self: int, a_: List[int], a_: Optional[List[int]] = None, a_: bool = False ): '''simple docstring''' if already_has_special_tokens: return super().get_special_tokens_mask( token_ids_a=__UpperCAmelCase, token_ids_a=__UpperCAmelCase, already_has_special_tokens=__UpperCAmelCase ) _snake_case : Optional[Any] = [1] if token_ids_a is None: return ([0] * len(__UpperCAmelCase )) + suffix_ones return ([0] * len(__UpperCAmelCase )) + ([0] * len(__UpperCAmelCase )) + suffix_ones def UpperCamelCase_ ( self: List[str], a_: str, a_: Optional[str] = None ): '''simple docstring''' if not os.path.isdir(__UpperCAmelCase ): logger.error(f"Vocabulary path ({save_directory}) should be a directory" ) return _snake_case : int = os.path.join( __UpperCAmelCase, (filename_prefix + """-""" if filename_prefix else """""") + VOCAB_FILES_NAMES["""vocab_file"""] ) if os.path.abspath(self.vocab_file ) != os.path.abspath(__UpperCAmelCase ) and os.path.isfile(self.vocab_file ): copyfile(self.vocab_file, __UpperCAmelCase ) elif not os.path.isfile(self.vocab_file ): with open(__UpperCAmelCase, """wb""" ) as fi: _snake_case : str = self.sp_model.serialized_model_proto() fi.write(__UpperCAmelCase ) return (out_vocab_file,)
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import math def lowerCAmelCase_ ( __A ) -> bool: '''simple docstring''' return math.sqrt(__A ) * math.sqrt(__A ) == num def lowerCAmelCase_ ( __A ) -> bool: '''simple docstring''' UpperCAmelCase__ = 0 UpperCAmelCase__ = n while left <= right: UpperCAmelCase__ = (left + right) // 2 if mid**2 == n: return True elif mid**2 > n: UpperCAmelCase__ = mid - 1 else: UpperCAmelCase__ = mid + 1 return False if __name__ == "__main__": import doctest doctest.testmod()
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"""simple docstring""" import mpmath # for roots of unity import numpy as np class a__ : def __init__( self , _a=None , _a=None ): lowercase : Tuple = list(poly_a or [0] )[:] lowercase : List[str] = list(poly_b or [0] )[:] # Remove leading zero coefficients while self.polyA[-1] == 0: self.polyA.pop() lowercase : Tuple = len(self.polyA ) while self.polyB[-1] == 0: self.polyB.pop() lowercase : Optional[Any] = len(self.polyB ) # Add 0 to make lengths equal a power of 2 lowercase : int = int( 2 ** np.ceil(np.loga(len(self.polyA ) + len(self.polyB ) - 1 ) ) ) while len(self.polyA ) < self.c_max_length: self.polyA.append(0 ) while len(self.polyB ) < self.c_max_length: self.polyB.append(0 ) # A complex root used for the fourier transform lowercase : int = complex(mpmath.root(x=1 , n=self.c_max_length , k=1 ) ) # The product lowercase : Tuple = self.__multiply() def __magic_name__ ( self , _a ): lowercase : Optional[int] = [[x] for x in self.polyA] if which == "A" else [[x] for x in self.polyB] # Corner case if len(__UpperCAmelCase ) <= 1: return dft[0] # lowercase : Optional[int] = self.c_max_length // 2 while next_ncol > 0: lowercase : Any = [[] for i in range(__UpperCAmelCase )] lowercase : Union[str, Any] = self.root**next_ncol # First half of next step lowercase : str = 1 for j in range(self.c_max_length // (next_ncol * 2) ): for i in range(__UpperCAmelCase ): new_dft[i].append(dft[i][j] + current_root * dft[i + next_ncol][j] ) current_root *= root # Second half of next step lowercase : Union[str, Any] = 1 for j in range(self.c_max_length // (next_ncol * 2) ): for i in range(__UpperCAmelCase ): new_dft[i].append(dft[i][j] - current_root * dft[i + next_ncol][j] ) current_root *= root # Update lowercase : int = new_dft lowercase : str = next_ncol // 2 return dft[0] def __magic_name__ ( self ): lowercase : Optional[Any] = self.__dft("A" ) lowercase : Tuple = self.__dft("B" ) lowercase : Dict = [[dft_a[i] * dft_b[i] for i in range(self.c_max_length )]] del dft_a del dft_b # Corner Case if len(inverce_c[0] ) <= 1: return inverce_c[0] # Inverse DFT lowercase : Tuple = 2 while next_ncol <= self.c_max_length: lowercase : Dict = [[] for i in range(__UpperCAmelCase )] lowercase : List[Any] = self.root ** (next_ncol // 2) lowercase : List[Any] = 1 # First half of next step for j in range(self.c_max_length // next_ncol ): for i in range(next_ncol // 2 ): # Even positions new_inverse_c[i].append( ( inverce_c[i][j] + inverce_c[i][j + self.c_max_length // next_ncol] ) / 2 ) # Odd positions new_inverse_c[i + next_ncol // 2].append( ( inverce_c[i][j] - inverce_c[i][j + self.c_max_length // next_ncol] ) / (2 * current_root) ) current_root *= root # Update lowercase : Optional[Any] = new_inverse_c next_ncol *= 2 # Unpack lowercase : Union[str, Any] = [round(x[0].real , 8 ) + round(x[0].imag , 8 ) * 1j for x in inverce_c] # Remove leading 0's while inverce_c[-1] == 0: inverce_c.pop() return inverce_c def __str__( self ): lowercase : Any = "A = " + " + ".join( f"""{coef}*x^{i}""" for coef, i in enumerate(self.polyA[: self.len_A] ) ) lowercase : List[Any] = "B = " + " + ".join( f"""{coef}*x^{i}""" for coef, i in enumerate(self.polyB[: self.len_B] ) ) lowercase : Any = "A*B = " + " + ".join( f"""{coef}*x^{i}""" for coef, i in enumerate(self.product ) ) return f"""{a}\n{b}\n{c}""" # Unit tests if __name__ == "__main__": import doctest doctest.testmod()
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import math from dataclasses import dataclass from typing import Optional, Tuple, Union import numpy as np import torch from ..configuration_utils import ConfigMixin, register_to_config from ..utils import BaseOutput, randn_tensor from .scheduling_utils import SchedulerMixin @dataclass # Copied from diffusers.schedulers.scheduling_ddpm.DDPMSchedulerOutput with DDPM->UnCLIP class A ( UpperCAmelCase_ ): __UpperCAmelCase : torch.FloatTensor __UpperCAmelCase : Optional[torch.FloatTensor] = None def lowerCAmelCase_ ( __A, __A=0.999, __A="cosine", ) -> Tuple: '''simple docstring''' if alpha_transform_type == "cosine": def alpha_bar_fn(__A ): return math.cos((t + 0.008) / 1.008 * math.pi / 2 ) ** 2 elif alpha_transform_type == "exp": def alpha_bar_fn(__A ): return math.exp(t * -12.0 ) else: raise ValueError(f"""Unsupported alpha_tranform_type: {alpha_transform_type}""" ) UpperCAmelCase__ = [] for i in range(__A ): UpperCAmelCase__ = i / num_diffusion_timesteps UpperCAmelCase__ = (i + 1) / num_diffusion_timesteps betas.append(min(1 - alpha_bar_fn(__A ) / alpha_bar_fn(__A ), __A ) ) return torch.tensor(__A, dtype=torch.floataa ) class A ( UpperCAmelCase_ , UpperCAmelCase_ ): @register_to_config def __init__(self : List[str] , __UpperCAmelCase : int = 1_0_0_0 , __UpperCAmelCase : str = "fixed_small_log" , __UpperCAmelCase : bool = True , __UpperCAmelCase : Optional[float] = 1.0 , __UpperCAmelCase : str = "epsilon" , __UpperCAmelCase : str = "squaredcos_cap_v2" , ) -> Optional[int]: """simple docstring""" if beta_schedule != "squaredcos_cap_v2": raise ValueError("UnCLIPScheduler only supports `beta_schedule`: 'squaredcos_cap_v2'" ) UpperCAmelCase__ = betas_for_alpha_bar(__UpperCAmelCase ) UpperCAmelCase__ = 1.0 - self.betas UpperCAmelCase__ = torch.cumprod(self.alphas , dim=0 ) UpperCAmelCase__ = torch.tensor(1.0 ) # standard deviation of the initial noise distribution UpperCAmelCase__ = 1.0 # setable values UpperCAmelCase__ = None UpperCAmelCase__ = torch.from_numpy(np.arange(0 , __UpperCAmelCase )[::-1].copy() ) UpperCAmelCase__ = variance_type def lowercase_ (self : List[str] , __UpperCAmelCase : torch.FloatTensor , __UpperCAmelCase : Optional[int] = None ) -> torch.FloatTensor: """simple docstring""" return sample def lowercase_ (self : int , __UpperCAmelCase : int , __UpperCAmelCase : Union[str, torch.device] = None ) -> Any: """simple docstring""" UpperCAmelCase__ = num_inference_steps UpperCAmelCase__ = (self.config.num_train_timesteps - 1) / (self.num_inference_steps - 1) UpperCAmelCase__ = (np.arange(0 , __UpperCAmelCase ) * step_ratio).round()[::-1].copy().astype(np.intaa ) UpperCAmelCase__ = torch.from_numpy(__UpperCAmelCase ).to(__UpperCAmelCase ) def lowercase_ (self : Any , __UpperCAmelCase : Dict , __UpperCAmelCase : Optional[int]=None , __UpperCAmelCase : Tuple=None , __UpperCAmelCase : List[str]=None ) -> Tuple: """simple docstring""" if prev_timestep is None: UpperCAmelCase__ = t - 1 UpperCAmelCase__ = self.alphas_cumprod[t] UpperCAmelCase__ = self.alphas_cumprod[prev_timestep] if prev_timestep >= 0 else self.one UpperCAmelCase__ = 1 - alpha_prod_t UpperCAmelCase__ = 1 - alpha_prod_t_prev if prev_timestep == t - 1: UpperCAmelCase__ = self.betas[t] else: UpperCAmelCase__ = 1 - alpha_prod_t / alpha_prod_t_prev # For t > 0, compute predicted variance βt (see formula (6) and (7) from https://arxiv.org/pdf/2006.11239.pdf) # and sample from it to get previous sample # x_{t-1} ~ N(pred_prev_sample, variance) == add variance to pred_sample UpperCAmelCase__ = beta_prod_t_prev / beta_prod_t * beta if variance_type is None: UpperCAmelCase__ = self.config.variance_type # hacks - were probably added for training stability if variance_type == "fixed_small_log": UpperCAmelCase__ = torch.log(torch.clamp(__UpperCAmelCase , min=1E-20 ) ) UpperCAmelCase__ = torch.exp(0.5 * variance ) elif variance_type == "learned_range": # NOTE difference with DDPM scheduler UpperCAmelCase__ = variance.log() UpperCAmelCase__ = beta.log() UpperCAmelCase__ = (predicted_variance + 1) / 2 UpperCAmelCase__ = frac * max_log + (1 - frac) * min_log return variance def lowercase_ (self : Optional[int] , __UpperCAmelCase : torch.FloatTensor , __UpperCAmelCase : int , __UpperCAmelCase : torch.FloatTensor , __UpperCAmelCase : Optional[int] = None , __UpperCAmelCase : List[str]=None , __UpperCAmelCase : bool = True , ) -> Union[UnCLIPSchedulerOutput, Tuple]: """simple docstring""" UpperCAmelCase__ = timestep if model_output.shape[1] == sample.shape[1] * 2 and self.variance_type == "learned_range": UpperCAmelCase__ , UpperCAmelCase__ = torch.split(__UpperCAmelCase , sample.shape[1] , dim=1 ) else: UpperCAmelCase__ = None # 1. compute alphas, betas if prev_timestep is None: UpperCAmelCase__ = t - 1 UpperCAmelCase__ = self.alphas_cumprod[t] UpperCAmelCase__ = self.alphas_cumprod[prev_timestep] if prev_timestep >= 0 else self.one UpperCAmelCase__ = 1 - alpha_prod_t UpperCAmelCase__ = 1 - alpha_prod_t_prev if prev_timestep == t - 1: UpperCAmelCase__ = self.betas[t] UpperCAmelCase__ = self.alphas[t] else: UpperCAmelCase__ = 1 - alpha_prod_t / alpha_prod_t_prev UpperCAmelCase__ = 1 - beta # 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 self.config.prediction_type == "epsilon": UpperCAmelCase__ = (sample - beta_prod_t ** 0.5 * model_output) / alpha_prod_t ** 0.5 elif self.config.prediction_type == "sample": UpperCAmelCase__ = model_output else: raise ValueError( f"""prediction_type given as {self.config.prediction_type} must be one of `epsilon` or `sample`""" " for the UnCLIPScheduler." ) # 3. Clip "predicted x_0" if self.config.clip_sample: UpperCAmelCase__ = torch.clamp( __UpperCAmelCase , -self.config.clip_sample_range , self.config.clip_sample_range ) # 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 UpperCAmelCase__ = (alpha_prod_t_prev ** 0.5 * beta) / beta_prod_t UpperCAmelCase__ = alpha ** 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 UpperCAmelCase__ = pred_original_sample_coeff * pred_original_sample + current_sample_coeff * sample # 6. Add noise UpperCAmelCase__ = 0 if t > 0: UpperCAmelCase__ = randn_tensor( model_output.shape , dtype=model_output.dtype , generator=__UpperCAmelCase , device=model_output.device ) UpperCAmelCase__ = self._get_variance( __UpperCAmelCase , predicted_variance=__UpperCAmelCase , prev_timestep=__UpperCAmelCase , ) if self.variance_type == "fixed_small_log": UpperCAmelCase__ = variance elif self.variance_type == "learned_range": UpperCAmelCase__ = (0.5 * variance).exp() else: raise ValueError( f"""variance_type given as {self.variance_type} must be one of `fixed_small_log` or `learned_range`""" " for the UnCLIPScheduler." ) UpperCAmelCase__ = variance * variance_noise UpperCAmelCase__ = pred_prev_sample + variance if not return_dict: return (pred_prev_sample,) return UnCLIPSchedulerOutput(prev_sample=__UpperCAmelCase , pred_original_sample=__UpperCAmelCase ) def lowercase_ (self : Union[str, Any] , __UpperCAmelCase : torch.FloatTensor , __UpperCAmelCase : torch.FloatTensor , __UpperCAmelCase : torch.IntTensor , ) -> torch.FloatTensor: """simple docstring""" UpperCAmelCase__ = self.alphas_cumprod.to(device=original_samples.device , dtype=original_samples.dtype ) UpperCAmelCase__ = timesteps.to(original_samples.device ) UpperCAmelCase__ = alphas_cumprod[timesteps] ** 0.5 UpperCAmelCase__ = sqrt_alpha_prod.flatten() while len(sqrt_alpha_prod.shape ) < len(original_samples.shape ): UpperCAmelCase__ = sqrt_alpha_prod.unsqueeze(-1 ) UpperCAmelCase__ = (1 - alphas_cumprod[timesteps]) ** 0.5 UpperCAmelCase__ = sqrt_one_minus_alpha_prod.flatten() while len(sqrt_one_minus_alpha_prod.shape ) < len(original_samples.shape ): UpperCAmelCase__ = sqrt_one_minus_alpha_prod.unsqueeze(-1 ) UpperCAmelCase__ = sqrt_alpha_prod * original_samples + sqrt_one_minus_alpha_prod * noise return noisy_samples
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"""simple docstring""" import json import os import re import sys import urllib.request import requests from bsa import BeautifulSoup lowerCamelCase_ = { '''User-Agent''': '''Mozilla/5.0 (Windows NT 10.0; Win64; x64) AppleWebKit/537.36''' ''' (KHTML, like Gecko) Chrome/70.0.3538.102 Safari/537.36 Edge/18.19582''' } def snake_case ( A__ = "dhaka" ,A__ = 5 ): UpperCAmelCase_ : List[str] = min(__A ,50 ) # Prevent abuse! UpperCAmelCase_ : List[str] = { "q": query, "tbm": "isch", "hl": "en", "ijn": "0", } UpperCAmelCase_ : Optional[Any] = requests.get("https://www.google.com/search" ,params=__A ,headers=__A ) UpperCAmelCase_ : str = BeautifulSoup(html.text ,"html.parser" ) UpperCAmelCase_ : Any = "".join( re.findall(r"AF_initDataCallback\(([^<]+)\);" ,str(soup.select("script" ) ) ) ) UpperCAmelCase_ : List[Any] = json.dumps(__A ) UpperCAmelCase_ : str = json.loads(__A ) UpperCAmelCase_ : List[str] = re.findall( r"\[\"GRID_STATE0\",null,\[\[1,\[0,\".*?\",(.*),\"All\"," ,__A ,) if not matched_google_image_data: return 0 UpperCAmelCase_ : str = re.sub( r"\[\"(https\:\/\/encrypted-tbn0\.gstatic\.com\/images\?.*?)\",\d+,\d+\]" ,"" ,str(__A ) ,) UpperCAmelCase_ : int = re.findall( r"(?:'|,),\[\"(https:|http.*?)\",\d+,\d+\]" ,__A ,) for index, fixed_full_res_image in enumerate(__A ): if index >= max_images: return index UpperCAmelCase_ : List[str] = bytes(__A ,"ascii" ).decode( "unicode-escape" ) UpperCAmelCase_ : List[Any] = bytes(__A ,"ascii" ).decode( "unicode-escape" ) UpperCAmelCase_ : List[str] = urllib.request.build_opener() UpperCAmelCase_ : Any = [ ( "User-Agent", "Mozilla/5.0 (Windows NT 10.0; Win64; x64) AppleWebKit/537.36" " (KHTML, like Gecko) Chrome/70.0.3538.102 Safari/537.36 Edge/18.19582", ) ] urllib.request.install_opener(__A ) UpperCAmelCase_ : int = F"""query_{query.replace(' ' ,'_' )}""" if not os.path.exists(__A ): os.makedirs(__A ) urllib.request.urlretrieve( # noqa: S310 __A ,F"""{path_name}/original_size_img_{index}.jpg""" ) return index if __name__ == "__main__": try: lowerCamelCase_ = download_images_from_google_query(sys.argv[1]) print(f'{image_count} images were downloaded to disk.') except IndexError: print('''Please provide a search term.''') raise
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import inspect import os import unittest import torch import accelerate from accelerate import Accelerator from accelerate.test_utils import execute_subprocess_async, require_multi_gpu from accelerate.utils import patch_environment class A ( unittest.TestCase ): def lowercase_ (self : Union[str, Any] ) -> str: """simple docstring""" UpperCAmelCase__ = inspect.getfile(accelerate.test_utils ) UpperCAmelCase__ = os.path.sep.join(mod_file.split(os.path.sep )[:-1] + ["scripts", "test_script.py"] ) UpperCAmelCase__ = os.path.sep.join( mod_file.split(os.path.sep )[:-1] + ["scripts", "test_distributed_data_loop.py"] ) UpperCAmelCase__ = os.path.sep.join(mod_file.split(os.path.sep )[:-1] + ["scripts", "test_ops.py"] ) @require_multi_gpu def lowercase_ (self : List[str] ) -> Any: """simple docstring""" print(f"""Found {torch.cuda.device_count()} devices.""" ) UpperCAmelCase__ = ["torchrun", f"""--nproc_per_node={torch.cuda.device_count()}""", self.test_file_path] with patch_environment(omp_num_threads=1 ): execute_subprocess_async(__UpperCAmelCase , env=os.environ.copy() ) @require_multi_gpu def lowercase_ (self : str ) -> str: """simple docstring""" print(f"""Found {torch.cuda.device_count()} devices.""" ) UpperCAmelCase__ = ["torchrun", f"""--nproc_per_node={torch.cuda.device_count()}""", self.operation_file_path] print(f"""Command: {cmd}""" ) with patch_environment(omp_num_threads=1 ): execute_subprocess_async(__UpperCAmelCase , env=os.environ.copy() ) @require_multi_gpu def lowercase_ (self : Tuple ) -> int: """simple docstring""" UpperCAmelCase__ = ["torchrun", f"""--nproc_per_node={torch.cuda.device_count()}""", inspect.getfile(self.__class__ )] with patch_environment(omp_num_threads=1 ): execute_subprocess_async(__UpperCAmelCase , env=os.environ.copy() ) @require_multi_gpu def lowercase_ (self : Dict ) -> str: """simple docstring""" print(f"""Found {torch.cuda.device_count()} devices, using 2 devices only""" ) UpperCAmelCase__ = ["torchrun", f"""--nproc_per_node={torch.cuda.device_count()}""", self.data_loop_file_path] with patch_environment(omp_num_threads=1 , cuda_visible_devices="0,1" ): execute_subprocess_async(__UpperCAmelCase , env=os.environ.copy() ) if __name__ == "__main__": UpperCamelCase__ = Accelerator() UpperCamelCase__ = (accelerator.state.process_index + 2, 1_0) UpperCamelCase__ = torch.randint(0, 1_0, shape).to(accelerator.device) UpperCamelCase__ = '' UpperCamelCase__ = accelerator.pad_across_processes(tensor) if tensora.shape[0] != accelerator.state.num_processes + 1: error_msg += f"Found shape {tensora.shape} but should have {accelerator.state.num_processes + 1} at dim 0." if not torch.equal(tensora[: accelerator.state.process_index + 2], tensor): error_msg += "Tensors have different values." if not torch.all(tensora[accelerator.state.process_index + 2 :] == 0): error_msg += "Padding was not done with the right value (0)." UpperCamelCase__ = accelerator.pad_across_processes(tensor, pad_first=True) if tensora.shape[0] != accelerator.state.num_processes + 1: error_msg += f"Found shape {tensora.shape} but should have {accelerator.state.num_processes + 1} at dim 0." UpperCamelCase__ = accelerator.state.num_processes - accelerator.state.process_index - 1 if not torch.equal(tensora[index:], tensor): error_msg += "Tensors have different values." if not torch.all(tensora[:index] == 0): error_msg += "Padding was not done with the right value (0)." # Raise error at the end to make sure we don't stop at the first failure. if len(error_msg) > 0: raise ValueError(error_msg)
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"""simple docstring""" import random def a__ ( _SCREAMING_SNAKE_CASE , _SCREAMING_SNAKE_CASE , _SCREAMING_SNAKE_CASE ): """simple docstring""" UpperCamelCase = a[left_index] UpperCamelCase = left_index + 1 for j in range(left_index + 1 , __A ): if a[j] < pivot: UpperCamelCase , UpperCamelCase = a[i], a[j] i += 1 UpperCamelCase , UpperCamelCase = a[i - 1], a[left_index] return i - 1 def a__ ( _SCREAMING_SNAKE_CASE , _SCREAMING_SNAKE_CASE , _SCREAMING_SNAKE_CASE ): """simple docstring""" if left < right: UpperCamelCase = random.randint(__A , right - 1 ) UpperCamelCase , UpperCamelCase = ( a[left], a[pivot], ) # switches the pivot with the left most bound UpperCamelCase = partition(__A , __A , __A ) quick_sort_random( __A , __A , __A ) # recursive quicksort to the left of the pivot point quick_sort_random( __A , pivot_index + 1 , __A ) # recursive quicksort to the right of the pivot point def a__ ( ): """simple docstring""" UpperCamelCase = input("Enter numbers separated by a comma:\n" ).strip() UpperCamelCase = [int(__A ) for item in user_input.split("," )] quick_sort_random(__A , 0 , len(__A ) ) print(__A ) if __name__ == "__main__": main()
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import argparse import torch from torch import nn from transformers import MBartConfig, MBartForConditionalGeneration def lowerCAmelCase_ ( __A ) -> Dict: '''simple docstring''' UpperCAmelCase__ = [ "encoder.version", "decoder.version", "model.encoder.version", "model.decoder.version", "_float_tensor", "decoder.output_projection.weight", ] for k in ignore_keys: state_dict.pop(__A, __A ) def lowerCAmelCase_ ( __A ) -> Optional[int]: '''simple docstring''' UpperCAmelCase__ , UpperCAmelCase__ = emb.weight.shape UpperCAmelCase__ = nn.Linear(__A, __A, bias=__A ) UpperCAmelCase__ = emb.weight.data return lin_layer def lowerCAmelCase_ ( __A, __A="facebook/mbart-large-en-ro", __A=False, __A=False ) -> Tuple: '''simple docstring''' UpperCAmelCase__ = torch.load(__A, map_location="cpu" )["model"] remove_ignore_keys_(__A ) UpperCAmelCase__ = state_dict["encoder.embed_tokens.weight"].shape[0] UpperCAmelCase__ = MBartConfig.from_pretrained(__A, vocab_size=__A ) if mbart_aa and finetuned: UpperCAmelCase__ = "relu" UpperCAmelCase__ = state_dict["decoder.embed_tokens.weight"] UpperCAmelCase__ = MBartForConditionalGeneration(__A ) model.model.load_state_dict(__A ) if finetuned: UpperCAmelCase__ = make_linear_from_emb(model.model.shared ) return model if __name__ == "__main__": UpperCamelCase__ = argparse.ArgumentParser() # Required parameters parser.add_argument( 'fairseq_path', type=str, help='bart.large, bart.large.cnn or a 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.') parser.add_argument( '--hf_config', default='facebook/mbart-large-cc25', type=str, help='Which huggingface architecture to use: mbart-large', ) parser.add_argument('--mbart_50', action='store_true', help='whether the model is mMART-50 checkpoint') parser.add_argument('--finetuned', action='store_true', help='whether the model is a fine-tuned checkpoint') UpperCamelCase__ = parser.parse_args() UpperCamelCase__ = convert_fairseq_mbart_checkpoint_from_disk( args.fairseq_path, hf_config_path=args.hf_config, finetuned=args.finetuned, mbart_aa=args.mbart_aa ) model.save_pretrained(args.pytorch_dump_folder_path)
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import os import shutil from pathlib import Path from typing import Optional, Union import numpy as np from huggingface_hub import hf_hub_download from ..utils import ONNX_EXTERNAL_WEIGHTS_NAME, ONNX_WEIGHTS_NAME, is_onnx_available, logging if is_onnx_available(): import onnxruntime as ort a_ :Tuple = logging.get_logger(__name__) a_ :str = { "tensor(bool)": np.bool_, "tensor(int8)": np.inta, "tensor(uint8)": np.uinta, "tensor(int16)": np.intaa, "tensor(uint16)": np.uintaa, "tensor(int32)": np.intaa, "tensor(uint32)": np.uintaa, "tensor(int64)": np.intaa, "tensor(uint64)": np.uintaa, "tensor(float16)": np.floataa, "tensor(float)": np.floataa, "tensor(double)": np.floataa, } class snake_case__ : """simple docstring""" def __init__( self : Union[str, Any], _snake_case : int=None, **_snake_case : Optional[int] ) ->int: logger.info('`diffusers.OnnxRuntimeModel` is experimental and might change in the future.' ) snake_case__ : Union[str, Any] = model snake_case__ : Dict = kwargs.get('model_save_dir', __UpperCAmelCase ) snake_case__ : Tuple = kwargs.get('latest_model_name', __UpperCAmelCase ) def __call__( self : Tuple, **_snake_case : int ) ->Any: snake_case__ : Union[str, Any] = {k: np.array(__UpperCAmelCase ) for k, v in kwargs.items()} return self.model.run(__UpperCAmelCase, __UpperCAmelCase ) @staticmethod def lowercase_ ( _snake_case : Union[str, Path], _snake_case : Tuple=None, _snake_case : Dict=None ) ->List[str]: if provider is None: logger.info('No onnxruntime provider specified, using CPUExecutionProvider' ) snake_case__ : Dict = 'CPUExecutionProvider' return ort.InferenceSession(__UpperCAmelCase, providers=[provider], sess_options=__UpperCAmelCase ) def lowercase_ ( self : Dict, _snake_case : Union[str, Path], _snake_case : Optional[str] = None, **_snake_case : List[str] ) ->Union[str, Any]: snake_case__ : List[str] = file_name if file_name is not None else ONNX_WEIGHTS_NAME snake_case__ : List[str] = self.model_save_dir.joinpath(self.latest_model_name ) snake_case__ : List[str] = Path(__UpperCAmelCase ).joinpath(__UpperCAmelCase ) try: shutil.copyfile(__UpperCAmelCase, __UpperCAmelCase ) except shutil.SameFileError: pass # copy external weights (for models >2GB) snake_case__ : int = self.model_save_dir.joinpath(__UpperCAmelCase ) if src_path.exists(): snake_case__ : str = Path(__UpperCAmelCase ).joinpath(__UpperCAmelCase ) try: shutil.copyfile(__UpperCAmelCase, __UpperCAmelCase ) except shutil.SameFileError: pass def lowercase_ ( self : List[str], _snake_case : Union[str, os.PathLike], **_snake_case : Tuple, ) ->Union[str, Any]: if os.path.isfile(__UpperCAmelCase ): logger.error(F'''Provided path ({save_directory}) should be a directory, not a file''' ) return os.makedirs(__UpperCAmelCase, exist_ok=__UpperCAmelCase ) # saving model weights/files self._save_pretrained(__UpperCAmelCase, **__UpperCAmelCase ) @classmethod def lowercase_ ( cls : List[Any], _snake_case : Union[str, Path], _snake_case : Optional[Union[bool, str, None]] = None, _snake_case : Optional[Union[str, None]] = None, _snake_case : bool = False, _snake_case : Optional[str] = None, _snake_case : Optional[str] = None, _snake_case : Optional[str] = None, _snake_case : Optional["ort.SessionOptions"] = None, **_snake_case : Union[str, Any], ) ->Union[str, Any]: snake_case__ : List[Any] = file_name if file_name is not None else ONNX_WEIGHTS_NAME # load model from local directory if os.path.isdir(__UpperCAmelCase ): snake_case__ : str = OnnxRuntimeModel.load_model( os.path.join(__UpperCAmelCase, __UpperCAmelCase ), provider=__UpperCAmelCase, sess_options=__UpperCAmelCase ) snake_case__ : str = Path(__UpperCAmelCase ) # load model from hub else: # download model snake_case__ : str = hf_hub_download( repo_id=__UpperCAmelCase, filename=__UpperCAmelCase, use_auth_token=__UpperCAmelCase, revision=__UpperCAmelCase, cache_dir=__UpperCAmelCase, force_download=__UpperCAmelCase, ) snake_case__ : Any = Path(__UpperCAmelCase ).parent snake_case__ : Optional[int] = Path(__UpperCAmelCase ).name snake_case__ : Optional[Any] = OnnxRuntimeModel.load_model(__UpperCAmelCase, provider=__UpperCAmelCase, sess_options=__UpperCAmelCase ) return cls(model=__UpperCAmelCase, **__UpperCAmelCase ) @classmethod def lowercase_ ( cls : Union[str, Any], _snake_case : Union[str, Path], _snake_case : bool = True, _snake_case : Optional[str] = None, _snake_case : Optional[str] = None, **_snake_case : int, ) ->int: snake_case__ : int = None if len(str(__UpperCAmelCase ).split('@' ) ) == 2: snake_case__ , snake_case__ : List[Any] = model_id.split('@' ) return cls._from_pretrained( model_id=__UpperCAmelCase, revision=__UpperCAmelCase, cache_dir=__UpperCAmelCase, force_download=__UpperCAmelCase, use_auth_token=__UpperCAmelCase, **__UpperCAmelCase, )
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from .dependency_versions_table import deps from .utils.versions import require_version, require_version_core # define which module versions we always want to check at run time # (usually the ones defined in `install_requires` in setup.py) # # order specific notes: # - tqdm must be checked before tokenizers UpperCamelCase__ = [ 'python', 'tqdm', 'regex', 'requests', 'packaging', 'filelock', 'numpy', 'tokenizers', 'huggingface-hub', 'safetensors', 'accelerate', 'pyyaml', ] for pkg in pkgs_to_check_at_runtime: if pkg in deps: if pkg == "tokenizers": # must be loaded here, or else tqdm check may fail from .utils import is_tokenizers_available if not is_tokenizers_available(): continue # not required, check version only if installed elif pkg == "accelerate": # must be loaded here, or else tqdm check may fail from .utils import is_accelerate_available # Maybe switch to is_torch_available in the future here so that Accelerate is hard dep of # Transformers with PyTorch if not is_accelerate_available(): continue # not required, check version only if installed require_version_core(deps[pkg]) else: raise ValueError(f'''can\'t find {pkg} in {deps.keys()}, check dependency_versions_table.py''') def lowerCAmelCase_ ( __A, __A=None ) -> Dict: '''simple docstring''' require_version(deps[pkg], __A )
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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__ : Union[str, Any] =logging.get_logger(__name__) lowerCAmelCase__ : int ={'''vocab_file''': '''vocab.json''', '''merges_file''': '''merges.txt''', '''tokenizer_file''': '''tokenizer.json'''} # See all BART models at https://huggingface.co/models?filter=bart lowerCAmelCase__ : Any ={ '''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__ : Tuple ={ '''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 UpperCAmelCase_ ( UpperCAmelCase_ ): '''simple docstring''' UpperCamelCase__ : int = VOCAB_FILES_NAMES UpperCamelCase__ : List[Any] = PRETRAINED_VOCAB_FILES_MAP UpperCamelCase__ : str = PRETRAINED_POSITIONAL_EMBEDDINGS_SIZES UpperCamelCase__ : Union[str, Any] = ['input_ids', 'attention_mask'] UpperCamelCase__ : Dict = BartTokenizer def __init__( self , _A=None , _A=None , _A=None , _A="replace" , _A="<s>" , _A="</s>" , _A="</s>" , _A="<s>" , _A="<unk>" , _A="<pad>" , _A="<mask>" , _A=False , _A=True , **_A , ): '''simple docstring''' super().__init__( __UpperCAmelCase , __UpperCAmelCase , tokenizer_file=__UpperCAmelCase , errors=__UpperCAmelCase , bos_token=__UpperCAmelCase , eos_token=__UpperCAmelCase , sep_token=__UpperCAmelCase , cls_token=__UpperCAmelCase , unk_token=__UpperCAmelCase , pad_token=__UpperCAmelCase , mask_token=__UpperCAmelCase , add_prefix_space=__UpperCAmelCase , trim_offsets=__UpperCAmelCase , **__UpperCAmelCase , ) __SCREAMING_SNAKE_CASE = json.loads(self.backend_tokenizer.pre_tokenizer.__getstate__() ) if pre_tok_state.get('add_prefix_space' , __UpperCAmelCase ) != add_prefix_space: __SCREAMING_SNAKE_CASE = getattr(__UpperCAmelCase , pre_tok_state.pop('type' ) ) __SCREAMING_SNAKE_CASE = add_prefix_space __SCREAMING_SNAKE_CASE = pre_tok_class(**__UpperCAmelCase ) __SCREAMING_SNAKE_CASE = add_prefix_space # the pre_tokenizer is already updated in the GPT2TokenizerFast `__init__` __SCREAMING_SNAKE_CASE = 'post_processor' __SCREAMING_SNAKE_CASE = getattr(self.backend_tokenizer , __UpperCAmelCase , __UpperCAmelCase ) if tokenizer_component_instance: __SCREAMING_SNAKE_CASE = 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: __SCREAMING_SNAKE_CASE = tuple(state['sep'] ) if "cls" in state: __SCREAMING_SNAKE_CASE = tuple(state['cls'] ) __SCREAMING_SNAKE_CASE = False if state.get('add_prefix_space' , __UpperCAmelCase ) != add_prefix_space: __SCREAMING_SNAKE_CASE = add_prefix_space __SCREAMING_SNAKE_CASE = True if state.get('trim_offsets' , __UpperCAmelCase ) != trim_offsets: __SCREAMING_SNAKE_CASE = trim_offsets __SCREAMING_SNAKE_CASE = True if changes_to_apply: __SCREAMING_SNAKE_CASE = getattr(__UpperCAmelCase , state.pop('type' ) ) __SCREAMING_SNAKE_CASE = component_class(**__UpperCAmelCase ) setattr(self.backend_tokenizer , __UpperCAmelCase , __UpperCAmelCase ) @property def _A ( self ): '''simple docstring''' 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 , _A ): '''simple docstring''' __SCREAMING_SNAKE_CASE = AddedToken(__UpperCAmelCase , lstrip=__UpperCAmelCase , rstrip=__UpperCAmelCase ) if isinstance(__UpperCAmelCase , __UpperCAmelCase ) else value __SCREAMING_SNAKE_CASE = value def _A ( self , *_A , **_A ): '''simple docstring''' __SCREAMING_SNAKE_CASE = kwargs.get('is_split_into_words' , __UpperCAmelCase ) 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(*__UpperCAmelCase , **__UpperCAmelCase ) def _A ( self , *_A , **_A ): '''simple docstring''' __SCREAMING_SNAKE_CASE = kwargs.get('is_split_into_words' , __UpperCAmelCase ) 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(*__UpperCAmelCase , **__UpperCAmelCase ) def _A ( self , _A , _A = None ): '''simple docstring''' __SCREAMING_SNAKE_CASE = self._tokenizer.model.save(__UpperCAmelCase , name=__UpperCAmelCase ) return tuple(__UpperCAmelCase ) def _A ( self , _A , _A=None ): '''simple docstring''' __SCREAMING_SNAKE_CASE = [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 , _A , _A = None ): '''simple docstring''' __SCREAMING_SNAKE_CASE = [self.sep_token_id] __SCREAMING_SNAKE_CASE = [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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import argparse import logging import pickle import random import time import numpy as np from transformers import BertTokenizer, GPTaTokenizer, RobertaTokenizer logging.basicConfig( format='%(asctime)s - %(levelname)s - %(name)s - %(message)s', datefmt='%m/%d/%Y %H:%M:%S', level=logging.INFO ) UpperCamelCase__ = logging.getLogger(__name__) def lowerCAmelCase_ ( ) -> int: '''simple docstring''' UpperCAmelCase__ = argparse.ArgumentParser( description="Preprocess the data to avoid re-doing it several times by (tokenization + token_to_ids)." ) parser.add_argument("--file_path", type=__A, default="data/dump.txt", help="The path to the data." ) parser.add_argument("--tokenizer_type", type=__A, default="bert", choices=["bert", "roberta", "gpt2"] ) parser.add_argument("--tokenizer_name", type=__A, default="bert-base-uncased", help="The tokenizer to use." ) parser.add_argument("--dump_file", type=__A, default="data/dump", help="The dump file prefix." ) UpperCAmelCase__ = parser.parse_args() logger.info(f"""Loading Tokenizer ({args.tokenizer_name})""" ) if args.tokenizer_type == "bert": UpperCAmelCase__ = BertTokenizer.from_pretrained(args.tokenizer_name ) UpperCAmelCase__ = tokenizer.special_tokens_map["cls_token"] # `[CLS]` UpperCAmelCase__ = tokenizer.special_tokens_map["sep_token"] # `[SEP]` elif args.tokenizer_type == "roberta": UpperCAmelCase__ = RobertaTokenizer.from_pretrained(args.tokenizer_name ) UpperCAmelCase__ = tokenizer.special_tokens_map["cls_token"] # `<s>` UpperCAmelCase__ = tokenizer.special_tokens_map["sep_token"] # `</s>` elif args.tokenizer_type == "gpt2": UpperCAmelCase__ = GPTaTokenizer.from_pretrained(args.tokenizer_name ) UpperCAmelCase__ = tokenizer.special_tokens_map["bos_token"] # `<|endoftext|>` UpperCAmelCase__ = tokenizer.special_tokens_map["eos_token"] # `<|endoftext|>` logger.info(f"""Loading text from {args.file_path}""" ) with open(args.file_path, "r", encoding="utf8" ) as fp: UpperCAmelCase__ = fp.readlines() logger.info("Start encoding" ) logger.info(f"""{len(__A )} examples to process.""" ) UpperCAmelCase__ = [] UpperCAmelCase__ = 0 UpperCAmelCase__ = 10_000 UpperCAmelCase__ = time.time() for text in data: UpperCAmelCase__ = f"""{bos} {text.strip()} {sep}""" UpperCAmelCase__ = tokenizer.encode(__A, add_special_tokens=__A ) rslt.append(__A ) iter += 1 if iter % interval == 0: UpperCAmelCase__ = time.time() logger.info(f"""{iter} examples processed. - {(end-start):.2f}s/{interval}expl""" ) UpperCAmelCase__ = time.time() logger.info("Finished binarization" ) logger.info(f"""{len(__A )} examples processed.""" ) UpperCAmelCase__ = f"""{args.dump_file}.{args.tokenizer_name}.pickle""" UpperCAmelCase__ = tokenizer.vocab_size if vocab_size < (1 << 16): UpperCAmelCase__ = [np.uintaa(__A ) for d in rslt] else: UpperCAmelCase__ = [np.intaa(__A ) for d in rslt] random.shuffle(rslt_ ) logger.info(f"""Dump to {dp_file}""" ) with open(__A, "wb" ) as handle: pickle.dump(rslt_, __A, protocol=pickle.HIGHEST_PROTOCOL ) if __name__ == "__main__": main()
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"""simple docstring""" import argparse from collections import OrderedDict from pathlib import Path import torch from transformers import ( VisualBertConfig, VisualBertForMultipleChoice, VisualBertForPreTraining, VisualBertForQuestionAnswering, VisualBertForVisualReasoning, ) from transformers.utils import logging logging.set_verbosity_info() __snake_case = logging.get_logger(__name__) __snake_case = [ ("""bert.bert""", """visual_bert"""), ("""bert.cls""", """cls"""), ("""bert.classifier""", """cls"""), ("""token_type_embeddings_visual""", """visual_token_type_embeddings"""), ("""position_embeddings_visual""", """visual_position_embeddings"""), ("""projection""", """visual_projection"""), ] __snake_case = [ """nlvr2_coco_pre_trained.th""", """nlvr2_fine_tuned.th""", """nlvr2_pre_trained.th""", """vcr_coco_pre_train.th""", """vcr_fine_tune.th""", """vcr_pre_train.th""", """vqa_coco_pre_trained.th""", """vqa_fine_tuned.th""", """vqa_pre_trained.th""", ] def __lowerCAmelCase ( lowercase : Union[str, Any] ) -> Optional[Any]: """simple docstring""" snake_case : Union[str, Any] = torch.load(__A , map_location="cpu" ) return sd def __lowerCAmelCase ( lowercase : str , lowercase : Any , lowercase : Dict=rename_keys_prefix ) -> Optional[Any]: """simple docstring""" snake_case : Tuple = OrderedDict() snake_case : Union[str, Any] = torch.arange(config.max_position_embeddings ).expand((1, -1) ) # detector_d = OrderedDict() for key in d: if "detector" in key: # detector_d[key.replace('detector.','')] = d[key] continue snake_case : Optional[Any] = key for name_pair in rename_keys_prefix: snake_case : Optional[Any] = new_key.replace(name_pair[0] , name_pair[1] ) snake_case : str = d[key] if key == "bert.cls.predictions.decoder.weight": # Old bert code didn't have `decoder.bias`, but was added separately snake_case : Union[str, Any] = new_d["cls.predictions.bias"] return new_d @torch.no_grad() def __lowerCAmelCase ( lowercase : Optional[Any] , lowercase : List[Any] ) -> List[Any]: """simple docstring""" assert ( checkpoint_path.split("/" )[-1] in ACCEPTABLE_CHECKPOINTS ), F'The checkpoint provided must be in {ACCEPTABLE_CHECKPOINTS}.' # Get Config if "pre" in checkpoint_path: snake_case : Any = "pretraining" if "vcr" in checkpoint_path: snake_case : str = {"visual_embedding_dim": 512} elif "vqa_advanced" in checkpoint_path: snake_case : Optional[int] = {"visual_embedding_dim": 2048} elif "vqa" in checkpoint_path: snake_case : List[Any] = {"visual_embedding_dim": 2048} elif "nlvr" in checkpoint_path: snake_case : Any = {"visual_embedding_dim": 1024} else: raise NotImplementedError(F'No implementation found for `{checkpoint_path}`.' ) else: if "vcr" in checkpoint_path: snake_case : int = {"visual_embedding_dim": 512} snake_case : Dict = "multichoice" elif "vqa_advanced" in checkpoint_path: snake_case : List[str] = {"visual_embedding_dim": 2048} snake_case : Optional[Any] = "vqa_advanced" elif "vqa" in checkpoint_path: snake_case : Tuple = {"visual_embedding_dim": 2048, "num_labels": 3129} snake_case : str = "vqa" elif "nlvr" in checkpoint_path: snake_case : int = { "visual_embedding_dim": 1024, "num_labels": 2, } snake_case : Dict = "nlvr" snake_case : List[Any] = VisualBertConfig(**__A ) # Load State Dict snake_case : Tuple = load_state_dict(__A ) snake_case : List[str] = get_new_dict(__A , __A ) if model_type == "pretraining": snake_case : int = VisualBertForPreTraining(__A ) elif model_type == "vqa": snake_case : Any = VisualBertForQuestionAnswering(__A ) elif model_type == "nlvr": snake_case : str = VisualBertForVisualReasoning(__A ) elif model_type == "multichoice": snake_case : Dict = VisualBertForMultipleChoice(__A ) model.load_state_dict(__A ) # Save Checkpoints Path(__A ).mkdir(exist_ok=__A ) model.save_pretrained(__A ) if __name__ == "__main__": __snake_case = argparse.ArgumentParser() # Required parameters parser.add_argument("""orig_checkpoint_path""", type=str, help="""A path to .th on local filesystem.""") parser.add_argument("""pytorch_dump_folder_path""", type=str, help="""Path to the output PyTorch model.""") __snake_case = parser.parse_args() convert_visual_bert_checkpoint(args.orig_checkpoint_path, args.pytorch_dump_folder_path)
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from manim import * class A ( UpperCAmelCase_ ): def lowercase_ (self : Union[str, Any] ) -> List[str]: """simple docstring""" UpperCAmelCase__ = Rectangle(height=0.5 , width=0.5 ) UpperCAmelCase__ = Rectangle(height=0.46 , width=0.46 ).set_stroke(width=0 ) UpperCAmelCase__ = Rectangle(height=0.25 , width=0.25 ) UpperCAmelCase__ = [mem.copy() for i in range(6 )] UpperCAmelCase__ = [mem.copy() for i in range(6 )] UpperCAmelCase__ = VGroup(*__UpperCAmelCase ).arrange(__UpperCAmelCase , buff=0 ) UpperCAmelCase__ = VGroup(*__UpperCAmelCase ).arrange(__UpperCAmelCase , buff=0 ) UpperCAmelCase__ = VGroup(__UpperCAmelCase , __UpperCAmelCase ).arrange(__UpperCAmelCase , buff=0 ) UpperCAmelCase__ = Text("CPU" , font_size=2_4 ) UpperCAmelCase__ = Group(__UpperCAmelCase , __UpperCAmelCase ).arrange(__UpperCAmelCase , buff=0.5 , aligned_edge=__UpperCAmelCase ) cpu.move_to([-2.5, -0.5, 0] ) self.add(__UpperCAmelCase ) UpperCAmelCase__ = [mem.copy() for i in range(4 )] UpperCAmelCase__ = VGroup(*__UpperCAmelCase ).arrange(__UpperCAmelCase , buff=0 ) UpperCAmelCase__ = Text("GPU" , font_size=2_4 ) UpperCAmelCase__ = Group(__UpperCAmelCase , __UpperCAmelCase ).arrange(__UpperCAmelCase , buff=0.5 , aligned_edge=__UpperCAmelCase ) gpu.move_to([-1, -1, 0] ) self.add(__UpperCAmelCase ) UpperCAmelCase__ = [mem.copy() for i in range(6 )] UpperCAmelCase__ = VGroup(*__UpperCAmelCase ).arrange(__UpperCAmelCase , buff=0 ) UpperCAmelCase__ = Text("Model" , font_size=2_4 ) UpperCAmelCase__ = Group(__UpperCAmelCase , __UpperCAmelCase ).arrange(__UpperCAmelCase , buff=0.5 , aligned_edge=__UpperCAmelCase ) model.move_to([3, -1.0, 0] ) self.add(__UpperCAmelCase ) UpperCAmelCase__ = [] UpperCAmelCase__ = [] for i, rect in enumerate(__UpperCAmelCase ): UpperCAmelCase__ = fill.copy().set_fill(__UpperCAmelCase , opacity=0.8 ) target.move_to(__UpperCAmelCase ) model_arr.append(__UpperCAmelCase ) UpperCAmelCase__ = Rectangle(height=0.46 , width=0.46 ).set_stroke(width=0.0 ).set_fill(__UpperCAmelCase , opacity=0.8 ) cpu_target.move_to(cpu_left_col_base[i] ) model_cpu_arr.append(__UpperCAmelCase ) self.add(*__UpperCAmelCase , *__UpperCAmelCase ) UpperCAmelCase__ = [meta_mem.copy() for i in range(6 )] UpperCAmelCase__ = [meta_mem.copy() for i in range(6 )] UpperCAmelCase__ = VGroup(*__UpperCAmelCase ).arrange(__UpperCAmelCase , buff=0 ) UpperCAmelCase__ = VGroup(*__UpperCAmelCase ).arrange(__UpperCAmelCase , buff=0 ) UpperCAmelCase__ = VGroup(__UpperCAmelCase , __UpperCAmelCase ).arrange(__UpperCAmelCase , buff=0 ) UpperCAmelCase__ = Text("Disk" , font_size=2_4 ) UpperCAmelCase__ = Group(__UpperCAmelCase , __UpperCAmelCase ).arrange(__UpperCAmelCase , buff=0.5 , aligned_edge=__UpperCAmelCase ) disk.move_to([-4, -1.25, 0] ) self.add(__UpperCAmelCase , __UpperCAmelCase ) UpperCAmelCase__ = Square(side_length=2.2 ) key.move_to([-5, 2, 0] ) UpperCAmelCase__ = MarkupText( f"""<b>Key:</b>\n\n<span fgcolor='{YELLOW}'>●</span> Empty Model""" , font_size=1_8 , ) key_text.move_to([-5, 2.4, 0] ) self.add(__UpperCAmelCase , __UpperCAmelCase ) UpperCAmelCase__ = MarkupText( f"""<span fgcolor='{BLUE}'>●</span> Checkpoint""" , font_size=1_8 , ) blue_text.next_to(__UpperCAmelCase , DOWN * 2.4 , aligned_edge=key_text.get_left() ) self.add(__UpperCAmelCase ) UpperCAmelCase__ = MarkupText( f"""Now watch as an input is passed through the model\nand how the memory is utilized and handled.""" , font_size=2_4 , ) step_a.move_to([2, 2, 0] ) self.play(Write(__UpperCAmelCase ) ) UpperCAmelCase__ = Square(0.3 ) input.set_fill(__UpperCAmelCase , opacity=1.0 ) input.set_stroke(width=0.0 ) input.next_to(model_base[0] , __UpperCAmelCase , buff=0.5 ) self.play(Write(__UpperCAmelCase ) ) input.generate_target() input.target.next_to(model_arr[0] , direction=__UpperCAmelCase , buff=0.02 ) self.play(MoveToTarget(__UpperCAmelCase ) ) self.play(FadeOut(__UpperCAmelCase ) ) UpperCAmelCase__ = Arrow(start=__UpperCAmelCase , end=__UpperCAmelCase , color=__UpperCAmelCase , buff=0.5 ) a.next_to(model_arr[0].get_left() , __UpperCAmelCase , buff=0.2 ) model_cpu_arr[0].generate_target() model_cpu_arr[0].target.move_to(gpu_rect[0] ) UpperCAmelCase__ = MarkupText( f"""As the input reaches a layer, the hook triggers\nand weights are moved from the CPU\nto the GPU and back.""" , font_size=2_4 , ) step_a.move_to([2, 2, 0] ) self.play(Write(__UpperCAmelCase , run_time=3 ) ) UpperCAmelCase__ = {"run_time": 1, "fade_in": True, "fade_out": True, "buff": 0.02} self.play( Write(__UpperCAmelCase ) , Circumscribe(model_arr[0] , color=__UpperCAmelCase , **__UpperCAmelCase ) , Circumscribe(model_cpu_arr[0] , color=__UpperCAmelCase , **__UpperCAmelCase ) , Circumscribe(gpu_rect[0] , color=__UpperCAmelCase , **__UpperCAmelCase ) , ) self.play(MoveToTarget(model_cpu_arr[0] ) ) UpperCAmelCase__ = a.copy() for i in range(6 ): a_c.next_to(model_arr[i].get_right() + 0.02 , __UpperCAmelCase , buff=0.2 ) input.generate_target() input.target.move_to(model_arr[i].get_right() + 0.02 ) UpperCAmelCase__ = AnimationGroup( FadeOut(__UpperCAmelCase , run_time=0.5 ) , MoveToTarget(__UpperCAmelCase , run_time=0.5 ) , FadeIn(__UpperCAmelCase , run_time=0.5 ) , lag_ratio=0.2 ) self.play(__UpperCAmelCase ) model_cpu_arr[i].generate_target() model_cpu_arr[i].target.move_to(cpu_left_col_base[i] ) if i < 5: model_cpu_arr[i + 1].generate_target() model_cpu_arr[i + 1].target.move_to(gpu_rect[0] ) if i >= 1: UpperCAmelCase__ = 0.7 self.play( Circumscribe(model_arr[i] , **__UpperCAmelCase ) , Circumscribe(cpu_left_col_base[i] , **__UpperCAmelCase ) , Circumscribe(cpu_left_col_base[i + 1] , color=__UpperCAmelCase , **__UpperCAmelCase ) , Circumscribe(gpu_rect[0] , color=__UpperCAmelCase , **__UpperCAmelCase ) , Circumscribe(model_arr[i + 1] , color=__UpperCAmelCase , **__UpperCAmelCase ) , ) if i < 1: self.play( MoveToTarget(model_cpu_arr[i] ) , MoveToTarget(model_cpu_arr[i + 1] ) , ) else: self.play( MoveToTarget(model_cpu_arr[i] , run_time=0.7 ) , MoveToTarget(model_cpu_arr[i + 1] , run_time=0.7 ) , ) else: model_cpu_arr[i].generate_target() model_cpu_arr[i].target.move_to(cpu_left_col_base[-1] ) input.generate_target() input.target.next_to(model_arr[-1].get_right() , RIGHT + 0.02 , buff=0.2 ) self.play( Circumscribe(model_arr[-1] , color=__UpperCAmelCase , **__UpperCAmelCase ) , Circumscribe(cpu_left_col_base[-1] , color=__UpperCAmelCase , **__UpperCAmelCase ) , Circumscribe(gpu_rect[0] , color=__UpperCAmelCase , **__UpperCAmelCase ) , ) self.play(MoveToTarget(model_cpu_arr[i] ) ) UpperCAmelCase__ = a_c UpperCAmelCase__ = a_c.copy() input.generate_target() input.target.next_to(model_base[-1] , RIGHT + 0.02 , buff=0.5 ) self.play( FadeOut(__UpperCAmelCase ) , FadeOut(__UpperCAmelCase , run_time=0.5 ) , ) UpperCAmelCase__ = MarkupText(f"""Inference on a model too large for GPU memory\nis successfully completed.""" , font_size=2_4 ) step_a.move_to([2, 2, 0] ) self.play(Write(__UpperCAmelCase , run_time=3 ) , MoveToTarget(__UpperCAmelCase ) ) self.wait()
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"""simple docstring""" # 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. import numpy as np import torch from ..models.clipseg import CLIPSegForImageSegmentation from ..utils import is_vision_available, requires_backends from .base import PipelineTool if is_vision_available(): from PIL import Image class _UpperCAmelCase ( UpperCAmelCase_): _lowerCAmelCase : List[str] = ( 'This is a tool that creates a segmentation mask of an image according to a label. It cannot create an image.' 'It takes two arguments named `image` which should be the original image, and `label` which should be a text ' 'describing the elements what should be identified in the segmentation mask. The tool returns the mask.' ) _lowerCAmelCase : Tuple = 'CIDAS/clipseg-rd64-refined' _lowerCAmelCase : str = 'image_segmenter' _lowerCAmelCase : Any = CLIPSegForImageSegmentation _lowerCAmelCase : str = ['image', 'text'] _lowerCAmelCase : Tuple = ['image'] def __init__( self : Union[str, Any] , *lowercase_ : int , **lowercase_ : Dict ): requires_backends(self , ['''vision'''] ) super().__init__(*__UpperCAmelCase , **__UpperCAmelCase ) def _snake_case ( self : List[str] , lowercase_ : "Image" , lowercase_ : str ): return self.pre_processor(text=[label] , images=[image] , padding=__UpperCAmelCase , return_tensors='''pt''' ) def _snake_case ( self : Optional[int] , lowercase_ : str ): with torch.no_grad(): snake_case_ : Optional[int] = self.model(**__UpperCAmelCase ).logits return logits def _snake_case ( self : Union[str, Any] , lowercase_ : int ): snake_case_ : Union[str, Any] = outputs.cpu().detach().numpy() snake_case_ : Union[str, Any] = 0 snake_case_ : List[str] = 1 return Image.fromarray((array * 255).astype(np.uinta ) )
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from __future__ import annotations from scipy.special import comb # type: ignore class A : def __init__(self : List[Any] , __UpperCAmelCase : list[tuple[float, float]] ) -> List[str]: """simple docstring""" UpperCAmelCase__ = list_of_points # Degree determines the flexibility of the curve. # Degree = 1 will produce a straight line. UpperCAmelCase__ = len(__UpperCAmelCase ) - 1 def lowercase_ (self : int , __UpperCAmelCase : float ) -> list[float]: """simple docstring""" assert 0 <= t <= 1, "Time t must be between 0 and 1." UpperCAmelCase__ = [] for i in range(len(self.list_of_points ) ): # basis function for each i output_values.append( comb(self.degree , __UpperCAmelCase ) * ((1 - t) ** (self.degree - i)) * (t**i) ) # the basis must sum up to 1 for it to produce a valid Bezier curve. assert round(sum(__UpperCAmelCase ) , 5 ) == 1 return output_values def lowercase_ (self : Dict , __UpperCAmelCase : float ) -> tuple[float, float]: """simple docstring""" assert 0 <= t <= 1, "Time t must be between 0 and 1." UpperCAmelCase__ = self.basis_function(__UpperCAmelCase ) UpperCAmelCase__ = 0.0 UpperCAmelCase__ = 0.0 for i in range(len(self.list_of_points ) ): # For all points, sum up the product of i-th basis function and i-th point. x += basis_function[i] * self.list_of_points[i][0] y += basis_function[i] * self.list_of_points[i][1] return (x, y) def lowercase_ (self : Optional[int] , __UpperCAmelCase : float = 0.01 ) -> Optional[int]: """simple docstring""" from matplotlib import pyplot as plt # type: ignore UpperCAmelCase__ = [] # x coordinates of points to plot UpperCAmelCase__ = [] # y coordinates of points to plot UpperCAmelCase__ = 0.0 while t <= 1: UpperCAmelCase__ = self.bezier_curve_function(__UpperCAmelCase ) to_plot_x.append(value[0] ) to_plot_y.append(value[1] ) t += step_size UpperCAmelCase__ = [i[0] for i in self.list_of_points] UpperCAmelCase__ = [i[1] for i in self.list_of_points] plt.plot( __UpperCAmelCase , __UpperCAmelCase , color="blue" , label="Curve of Degree " + str(self.degree ) , ) plt.scatter(__UpperCAmelCase , __UpperCAmelCase , color="red" , label="Control Points" ) plt.legend() plt.show() if __name__ == "__main__": import doctest doctest.testmod() BezierCurve([(1, 2), (3, 5)]).plot_curve() # degree 1 BezierCurve([(0, 0), (5, 5), (5, 0)]).plot_curve() # degree 2 BezierCurve([(0, 0), (5, 5), (5, 0), (2.5, -2.5)]).plot_curve() # degree 3
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"""simple docstring""" # 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 typing import TYPE_CHECKING from ..models.auto import AutoModelForVisionaSeq from ..utils import requires_backends from .base import PipelineTool if TYPE_CHECKING: from PIL import Image class lowerCamelCase ( _lowerCAmelCase ): '''simple docstring''' _A : Optional[Any] = """Salesforce/blip-image-captioning-base""" _A : Dict = ( """This is a tool that generates a description of an image. It takes an input named `image` which should be the """ """image to caption, and returns a text that contains the description in English.""" ) _A : int = """image_captioner""" _A : Optional[int] = AutoModelForVisionaSeq _A : List[str] = ["""image"""] _A : Tuple = ["""text"""] def __init__( self: List[Any] , *snake_case: Optional[int] , **snake_case: str ) -> Optional[int]: requires_backends(self , ["""vision"""] ) super().__init__(*snake_case , **snake_case ) def lowerCAmelCase_ ( self: Any , snake_case: "Image" ) -> Optional[Any]: return self.pre_processor(images=snake_case , return_tensors="""pt""" ) def lowerCAmelCase_ ( self: Any , snake_case: List[str] ) -> List[str]: return self.model.generate(**snake_case ) def lowerCAmelCase_ ( self: Tuple , snake_case: Tuple ) -> Tuple: return self.pre_processor.batch_decode(snake_case , skip_special_tokens=snake_case )[0].strip()
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"""simple docstring""" import numpy as np import pandas as pd from sklearn.preprocessing import MinMaxScaler from tensorflow.keras.layers import LSTM, Dense from tensorflow.keras.models import Sequential if __name__ == "__main__": __a = pd.read_csv("sample_data.csv", header=None) __a = df.shape[:1][0] # If you're using some other dataset input the target column __a = df.iloc[:, 1:2] __a = actual_data.values.reshape(len_data, 1) __a = MinMaxScaler().fit_transform(actual_data) __a = 10 __a = 5 __a = 20 __a = len_data - periods * look_back __a = actual_data[:division] __a = actual_data[division - look_back :] __a , __a = [], [] __a , __a = [], [] for i in range(0, len(train_data) - forward_days - look_back + 1): train_x.append(train_data[i : i + look_back]) train_y.append(train_data[i + look_back : i + look_back + forward_days]) for i in range(0, len(test_data) - forward_days - look_back + 1): test_x.append(test_data[i : i + look_back]) test_y.append(test_data[i + look_back : i + look_back + forward_days]) __a = np.array(train_x) __a = np.array(test_x) __a = np.array([list(i.ravel()) for i in train_y]) __a = np.array([list(i.ravel()) for i in test_y]) __a = Sequential() model.add(LSTM(1_28, input_shape=(look_back, 1), return_sequences=True)) model.add(LSTM(64, input_shape=(1_28, 1))) model.add(Dense(forward_days)) model.compile(loss="mean_squared_error", optimizer="adam") __a = model.fit( x_train, y_train, epochs=1_50, verbose=1, shuffle=True, batch_size=4 ) __a = model.predict(x_test)
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"""simple docstring""" from math import factorial, radians def A_ ( _lowercase, _lowercase = 18, _lowercase = 10 ): '''simple docstring''' snake_case_ :Tuple = angle_in_degrees - ((angle_in_degrees // 360.0) * 360.0) # Converting from degrees to radians snake_case_ :Tuple = radians(_lowercase ) snake_case_ :Dict = angle_in_radians snake_case_ :Any = 3 snake_case_ :Dict = -1 for _ in range(_lowercase ): result += (b * (angle_in_radians**a)) / factorial(_lowercase ) snake_case_ :Dict = -b # One positive term and the next will be negative and so on... a += 2 # Increased by 2 for every term. return round(_lowercase, _lowercase ) if __name__ == "__main__": __import__("doctest").testmod()
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"""simple docstring""" from typing import TYPE_CHECKING from ...utils import OptionalDependencyNotAvailable, _LazyModule, is_tokenizers_available, is_torch_available __a = { "configuration_altclip": [ "ALTCLIP_PRETRAINED_CONFIG_ARCHIVE_MAP", "AltCLIPConfig", "AltCLIPTextConfig", "AltCLIPVisionConfig", ], "processing_altclip": ["AltCLIPProcessor"], } try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __a = [ "ALTCLIP_PRETRAINED_MODEL_ARCHIVE_LIST", "AltCLIPPreTrainedModel", "AltCLIPModel", "AltCLIPTextModel", "AltCLIPVisionModel", ] if TYPE_CHECKING: from .configuration_altclip import ( ALTCLIP_PRETRAINED_CONFIG_ARCHIVE_MAP, AltCLIPConfig, AltCLIPTextConfig, AltCLIPVisionConfig, ) from .processing_altclip import AltCLIPProcessor try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_altclip import ( ALTCLIP_PRETRAINED_MODEL_ARCHIVE_LIST, AltCLIPModel, AltCLIPPreTrainedModel, AltCLIPTextModel, AltCLIPVisionModel, ) else: import sys __a = _LazyModule(__name__, globals()["__file__"], _import_structure, module_spec=__spec__)
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"""simple docstring""" import re from flax.core.frozen_dict import freeze from flax.traverse_util import flatten_dict, unflatten_dict from jax.experimental import PartitionSpec as P # Sentinels __a = object() # For specifying empty leaf dict `{}` __a = object() def A_ ( _lowercase, _lowercase ): '''simple docstring''' snake_case_ :List[str] = tuple((re.compile(x + """$""" ) for x in qs) ) for i in range(len(_lowercase ) - len(_lowercase ) + 1 ): snake_case_ :Union[str, Any] = [x.match(_lowercase ) for x, y in zip(_lowercase, ks[i:] )] if matches and all(_lowercase ): return True return False def A_ ( _lowercase ): '''simple docstring''' def replace(_lowercase, _lowercase ): for rule, replacement in rules: if _match(_lowercase, _lowercase ): return replacement return val return replace def A_ ( ): '''simple docstring''' return [ # embeddings (("transformer", "wpe", "embedding"), P("""mp""", _lowercase )), (("transformer", "wte", "embedding"), P("""mp""", _lowercase )), # atention (("attention", "(q_proj|k_proj|v_proj)", "kernel"), P(_lowercase, """mp""" )), (("attention", "out_proj", "kernel"), P("""mp""", _lowercase )), (("attention", "out_proj", "bias"), None), # mlp (("mlp", "c_fc", "kernel"), P(_lowercase, """mp""" )), (("mlp", "c_fc", "bias"), P("""mp""" )), (("mlp", "c_proj", "kernel"), P("""mp""", _lowercase )), (("mlp", "c_proj", "bias"), None), # layer norms ((r"ln_\d+", "bias"), None), ((r"\d+", r"ln_\d+", "scale"), None), (("ln_f", "bias"), None), (("ln_f", "scale"), None), ] def A_ ( _lowercase ): '''simple docstring''' snake_case_ :Optional[Any] = _get_partition_rules() snake_case_ :Dict = _replacement_rules(_lowercase ) snake_case_ :Tuple = {k: _unmatched for k in flatten_dict(_lowercase )} snake_case_ :List[str] = {k: replace(_lowercase, _lowercase ) for k, v in initd.items()} assert _unmatched not in result.values(), "Incomplete partition spec." return freeze(unflatten_dict(_lowercase ) )
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"""simple docstring""" import argparse import gdown import numpy as np import torch from huggingface_hub import hf_hub_download from transformers import ( CLIPTokenizer, CLIPTokenizerFast, VideoMAEImageProcessor, XCLIPConfig, XCLIPModel, XCLIPProcessor, XCLIPTextConfig, XCLIPVisionConfig, ) def A_ ( _lowercase, _lowercase ): '''simple docstring''' snake_case_ :int = XCLIPTextConfig() # derive patch size from model name snake_case_ :Union[str, Any] = model_name.find("""patch""" ) snake_case_ :List[str] = int(model_name[start_idx + len("""patch""" ) : start_idx + len("""patch""" ) + 2] ) snake_case_ :Any = XCLIPVisionConfig(patch_size=_lowercase, num_frames=_lowercase ) if "large" in model_name: snake_case_ :Optional[Any] = 768 snake_case_ :Union[str, Any] = 3072 snake_case_ :Any = 12 snake_case_ :Any = 1024 snake_case_ :str = 4096 snake_case_ :Union[str, Any] = 16 snake_case_ :Union[str, Any] = 24 snake_case_ :Tuple = 768 snake_case_ :Any = 3072 if model_name == "xclip-large-patch14-16-frames": snake_case_ :Any = 336 snake_case_ :Any = XCLIPConfig.from_text_vision_configs(_lowercase, _lowercase ) if "large" in model_name: snake_case_ :List[Any] = 768 return config def A_ ( _lowercase ): '''simple docstring''' if name == "token_embedding.weight": snake_case_ :Optional[Any] = name.replace("""token_embedding.weight""", """text_model.embeddings.token_embedding.weight""" ) if name == "positional_embedding": snake_case_ :Tuple = name.replace("""positional_embedding""", """text_model.embeddings.position_embedding.weight""" ) if "ln_1" in name: snake_case_ :Dict = name.replace("""ln_1""", """layer_norm1""" ) if "ln_2" in name: snake_case_ :str = name.replace("""ln_2""", """layer_norm2""" ) if "c_fc" in name: snake_case_ :str = name.replace("""c_fc""", """fc1""" ) if "c_proj" in name: snake_case_ :int = name.replace("""c_proj""", """fc2""" ) if name.startswith("""transformer.resblocks""" ): snake_case_ :Union[str, Any] = name.replace("""transformer.resblocks""", """text_model.encoder.layers""" ) if "attn.out_proj" in name and "message" not in name: snake_case_ :Union[str, Any] = name.replace("""attn.out_proj""", """self_attn.out_proj""" ) if "ln_final" in name: snake_case_ :Union[str, Any] = name.replace("""ln_final""", """text_model.final_layer_norm""" ) # visual encoder if name == "visual.class_embedding": snake_case_ :Any = name.replace("""visual.class_embedding""", """vision_model.embeddings.class_embedding""" ) if name == "visual.positional_embedding": snake_case_ :Optional[int] = name.replace("""visual.positional_embedding""", """vision_model.embeddings.position_embedding.weight""" ) if name.startswith("""visual.transformer.resblocks""" ): snake_case_ :Union[str, Any] = name.replace("""visual.transformer.resblocks""", """vision_model.encoder.layers""" ) if "visual.conv1" in name: snake_case_ :int = name.replace("""visual.conv1""", """vision_model.embeddings.patch_embedding""" ) if "visual.ln_pre" in name: snake_case_ :Any = name.replace("""visual.ln_pre""", """vision_model.pre_layernorm""" ) if "visual.ln_post" in name: snake_case_ :str = name.replace("""visual.ln_post""", """vision_model.post_layernorm""" ) if "visual.proj" in name: snake_case_ :Union[str, Any] = name.replace("""visual.proj""", """visual_projection.weight""" ) if "text_projection" in name: snake_case_ :Dict = name.replace("""text_projection""", """text_projection.weight""" ) # things on top if "prompts_visual_proj" in name: snake_case_ :List[str] = name.replace("""prompts_visual_proj""", """prompts_visual_projection""" ) if "prompts_visual_ln" in name: snake_case_ :Dict = name.replace("""prompts_visual_ln""", """prompts_visual_layernorm""" ) # mit if name == "mit.positional_embedding": snake_case_ :str = name.replace("""positional""", """position""" ) if name.startswith("""mit.resblocks""" ): snake_case_ :Dict = name.replace("""mit.resblocks""", """mit.encoder.layers""" ) # prompts generator if name.startswith("""prompts_generator.norm""" ): snake_case_ :Union[str, Any] = name.replace("""prompts_generator.norm""", """prompts_generator.layernorm""" ) return name def A_ ( _lowercase, _lowercase ): '''simple docstring''' for key in orig_state_dict.copy().keys(): snake_case_ :Dict = orig_state_dict.pop(_lowercase ) if "attn.in_proj" in key: snake_case_ :Optional[Any] = key.split(""".""" ) if key.startswith("""visual""" ): snake_case_ :Any = key_split[3] snake_case_ :Optional[Any] = config.vision_config.hidden_size if "message_attn" in key: if "weight" in key: snake_case_ :str = val[ :dim, : ] snake_case_ :Optional[int] = val[ dim : dim * 2, : ] snake_case_ :Union[str, Any] = val[ -dim:, : ] else: snake_case_ :Dict = val[ :dim ] snake_case_ :Optional[int] = val[ dim : dim * 2 ] snake_case_ :Optional[int] = val[ -dim: ] else: if "weight" in key: snake_case_ :Optional[Any] = val[ :dim, : ] snake_case_ :List[str] = val[ dim : dim * 2, : ] snake_case_ :Dict = val[ -dim:, : ] else: snake_case_ :Union[str, Any] = val[:dim] snake_case_ :Union[str, Any] = val[ dim : dim * 2 ] snake_case_ :Union[str, Any] = val[-dim:] elif key.startswith("""mit""" ): snake_case_ :Tuple = key_split[2] snake_case_ :Union[str, Any] = config.vision_config.mit_hidden_size if "weight" in key: snake_case_ :Optional[int] = val[:dim, :] snake_case_ :Optional[int] = val[dim : dim * 2, :] snake_case_ :str = val[-dim:, :] else: snake_case_ :str = val[:dim] snake_case_ :Any = val[dim : dim * 2] snake_case_ :int = val[-dim:] else: snake_case_ :Tuple = key_split[2] snake_case_ :Any = config.text_config.hidden_size if "weight" in key: snake_case_ :Dict = val[:dim, :] snake_case_ :Dict = val[ dim : dim * 2, : ] snake_case_ :List[str] = val[-dim:, :] else: snake_case_ :Any = val[:dim] snake_case_ :Tuple = val[ dim : dim * 2 ] snake_case_ :List[str] = val[-dim:] else: snake_case_ :Optional[int] = rename_key(_lowercase ) if new_key_name in ["visual_projection.weight", "text_projection.weight"]: snake_case_ :Optional[Any] = val.T snake_case_ :Tuple = val return orig_state_dict def A_ ( _lowercase ): '''simple docstring''' if num_frames == 8: snake_case_ :str = """eating_spaghetti_8_frames.npy""" elif num_frames == 16: snake_case_ :int = """eating_spaghetti.npy""" elif num_frames == 32: snake_case_ :List[str] = """eating_spaghetti_32_frames.npy""" snake_case_ :int = hf_hub_download( repo_id="""hf-internal-testing/spaghetti-video""", filename=_lowercase, repo_type="""dataset""", ) snake_case_ :Union[str, Any] = np.load(_lowercase ) return list(_lowercase ) def A_ ( _lowercase, _lowercase=None, _lowercase=False ): '''simple docstring''' snake_case_ :List[Any] = { # fully supervised kinetics-400 checkpoints """xclip-base-patch32""": """https://github.com/nbl97/X-CLIP_Model_Zoo/releases/download/v1.0/k400_32_8.pth""", """xclip-base-patch32-16-frames""": ( """https://github.com/nbl97/X-CLIP_Model_Zoo/releases/download/v1.0/k400_32_16.pth""" ), """xclip-base-patch16""": """https://github.com/nbl97/X-CLIP_Model_Zoo/releases/download/v1.0/k400_16_8.pth""", """xclip-base-patch16-16-frames""": ( """https://github.com/nbl97/X-CLIP_Model_Zoo/releases/download/v1.0/k400_16_16.pth""" ), """xclip-large-patch14""": """https://drive.google.com/u/0/uc?id=1NUOImq0o5DlQTST17iIP3vG7DgmHQuCx&amp;export=download&amp;confirm=t&amp;uuid=b26caedc-88e2-473e-830a-9d158b653cdb""", """xclip-large-patch14-16-frames""": """https://drive.google.com/u/0/uc?id=1FOYgnJc097OJ4lGwtRCCydQyVPJEOH7d&amp;export=download&amp;confirm=t&amp;uuid=538fa810-e671-4050-b385-9a623f89804f""", # fully supervised kinetics-600 checkpoints """xclip-base-patch16-kinetics-600""": ( """https://github.com/nbl97/X-CLIP_Model_Zoo/releases/download/v1.0/k600_16_8.pth""" ), """xclip-base-patch16-kinetics-600-16-frames""": ( """https://github.com/nbl97/X-CLIP_Model_Zoo/releases/download/v1.0/k600_16_16.pth""" ), """xclip-large-patch14-kinetics-600""": """https://drive.google.com/u/0/uc?id=1FV8C1INuM91sLAN4ImjzePLIlpMSihwV&amp;export=download&amp;confirm=t&amp;uuid=141d4977-4a65-44ae-864f-4b0c19f838be""", # few shot """xclip-base-patch16-hmdb-2-shot""": ( """https://github.com/nbl97/X-CLIP_Model_Zoo/releases/download/v1.0/few_hmdb_2.pth""" ), """xclip-base-patch16-hmdb-4-shot""": ( """https://github.com/nbl97/X-CLIP_Model_Zoo/releases/download/v1.0/few_hmdb_4.pth""" ), """xclip-base-patch16-hmdb-8-shot""": ( """https://github.com/nbl97/X-CLIP_Model_Zoo/releases/download/v1.0/few_hmdb_8.pth""" ), """xclip-base-patch16-hmdb-16-shot""": ( """https://github.com/nbl97/X-CLIP_Model_Zoo/releases/download/v1.0/few_hmdb_16.pth""" ), """xclip-base-patch16-ucf-2-shot""": ( """https://github.com/nbl97/X-CLIP_Model_Zoo/releases/download/v1.0/few_ucf_2.pth""" ), """xclip-base-patch16-ucf-4-shot""": ( """https://github.com/nbl97/X-CLIP_Model_Zoo/releases/download/v1.0/few_ucf_4.pth""" ), """xclip-base-patch16-ucf-8-shot""": ( """https://github.com/nbl97/X-CLIP_Model_Zoo/releases/download/v1.0/few_ucf_8.pth""" ), """xclip-base-patch16-ucf-16-shot""": ( """https://github.com/nbl97/X-CLIP_Model_Zoo/releases/download/v1.0/few_ucf_16.pth""" ), # zero shot """xclip-base-patch16-zero-shot""": """https://github.com/nbl97/X-CLIP_Model_Zoo/releases/download/v1.0/zero.pth""", } snake_case_ :Optional[int] = model_to_url[model_name] snake_case_ :int = 8 if "16-frames" in model_name: snake_case_ :List[Any] = 16 elif "shot" in model_name: snake_case_ :Dict = 32 snake_case_ :Optional[int] = get_xclip_config(_lowercase, _lowercase ) snake_case_ :Optional[Any] = XCLIPModel(_lowercase ) model.eval() if "drive" in checkpoint_url: snake_case_ :List[str] = """pytorch_model.bin""" gdown.cached_download(_lowercase, _lowercase, quiet=_lowercase ) snake_case_ :List[Any] = torch.load(_lowercase, map_location="""cpu""" )["""model"""] else: snake_case_ :Tuple = torch.hub.load_state_dict_from_url(_lowercase )["""model"""] snake_case_ :Union[str, Any] = convert_state_dict(_lowercase, _lowercase ) snake_case_ :str = XCLIPModel(_lowercase ) snake_case_, snake_case_ :Optional[int] = model.load_state_dict(_lowercase, strict=_lowercase ) assert missing_keys == ["text_model.embeddings.position_ids", "vision_model.embeddings.position_ids"] model.eval() snake_case_ :List[str] = 336 if model_name == """xclip-large-patch14-16-frames""" else 224 snake_case_ :List[Any] = VideoMAEImageProcessor(size=_lowercase ) snake_case_ :Any = CLIPTokenizer.from_pretrained("""openai/clip-vit-base-patch32""" ) snake_case_ :str = CLIPTokenizerFast.from_pretrained("""openai/clip-vit-base-patch32""" ) snake_case_ :Optional[Any] = XCLIPProcessor(image_processor=_lowercase, tokenizer=_lowercase ) snake_case_ :Optional[int] = prepare_video(_lowercase ) snake_case_ :Optional[Any] = processor( text=["""playing sports""", """eating spaghetti""", """go shopping"""], videos=_lowercase, return_tensors="""pt""", padding=_lowercase ) print("""Shape of pixel values:""", inputs.pixel_values.shape ) with torch.no_grad(): snake_case_ :List[Any] = model(**_lowercase ) # Verify outputs snake_case_ :List[Any] = outputs.logits_per_video snake_case_ :Any = logits_per_video.softmax(dim=1 ) print("""Probs:""", _lowercase ) # kinetics-400 if model_name == "xclip-base-patch32": snake_case_ :Union[str, Any] = torch.tensor([[0.0019, 0.9951, 0.0030]] ) elif model_name == "xclip-base-patch32-16-frames": snake_case_ :str = torch.tensor([[7.09_99e-04, 9.98_83e-01, 4.55_80e-04]] ) elif model_name == "xclip-base-patch16": snake_case_ :Tuple = torch.tensor([[0.0083, 0.9681, 0.0236]] ) elif model_name == "xclip-base-patch16-16-frames": snake_case_ :Any = torch.tensor([[7.69_37e-04, 9.97_28e-01, 1.94_73e-03]] ) elif model_name == "xclip-large-patch14": snake_case_ :str = torch.tensor([[0.0062, 0.9864, 0.0075]] ) elif model_name == "xclip-large-patch14-16-frames": snake_case_ :Tuple = torch.tensor([[3.38_77e-04, 9.99_37e-01, 2.88_88e-04]] ) # kinetics-600 elif model_name == "xclip-base-patch16-kinetics-600": snake_case_ :List[Any] = torch.tensor([[0.0555, 0.8914, 0.0531]] ) elif model_name == "xclip-base-patch16-kinetics-600-16-frames": snake_case_ :Union[str, Any] = torch.tensor([[3.85_54e-04, 9.99_29e-01, 3.27_54e-04]] ) elif model_name == "xclip-large-patch14-kinetics-600": snake_case_ :List[Any] = torch.tensor([[0.0036, 0.9920, 0.0045]] ) # few shot elif model_name == "xclip-base-patch16-hmdb-2-shot": snake_case_ :Dict = torch.tensor([[7.18_90e-06, 9.99_94e-01, 5.65_59e-05]] ) elif model_name == "xclip-base-patch16-hmdb-4-shot": snake_case_ :Union[str, Any] = torch.tensor([[1.03_20e-05, 9.99_93e-01, 6.24_35e-05]] ) elif model_name == "xclip-base-patch16-hmdb-8-shot": snake_case_ :str = torch.tensor([[4.13_77e-06, 9.99_90e-01, 9.83_86e-05]] ) elif model_name == "xclip-base-patch16-hmdb-16-shot": snake_case_ :str = torch.tensor([[4.13_47e-05, 9.99_62e-01, 3.34_11e-04]] ) elif model_name == "xclip-base-patch16-ucf-2-shot": snake_case_ :int = torch.tensor([[8.58_57e-05, 9.99_28e-01, 6.32_91e-04]] ) elif model_name == "xclip-base-patch16-ucf-4-shot": snake_case_ :Optional[int] = torch.tensor([[8.58_57e-05, 9.99_28e-01, 6.32_91e-04]] ) elif model_name == "xclip-base-patch16-ucf-8-shot": snake_case_ :Any = torch.tensor([[0.0027, 0.9904, 0.0070]] ) elif model_name == "xclip-base-patch16-ucf-16-shot": snake_case_ :Tuple = torch.tensor([[9.82_19e-04, 9.95_93e-01, 3.08_63e-03]] ) # zero shot elif model_name == "xclip-base-patch16-zero-shot": snake_case_ :Union[str, Any] = torch.tensor([[3.50_82e-04, 9.97_85e-01, 1.79_66e-03]] ) else: raise ValueError(f"""Model name {model_name} not supported""" ) assert torch.allclose(_lowercase, _lowercase, atol=1e-3 ) print("""Looks ok!""" ) if pytorch_dump_folder_path is not None: print(f"""Saving model {model_name} to {pytorch_dump_folder_path}""" ) model.save_pretrained(_lowercase ) if push_to_hub: print("""Pushing model, processor and slow tokenizer files to the hub...""" ) model.push_to_hub(_lowercase, organization="""nielsr""" ) processor.push_to_hub(_lowercase, organization="""nielsr""" ) slow_tokenizer.push_to_hub(_lowercase, organization="""nielsr""" ) if __name__ == "__main__": __a = argparse.ArgumentParser() # Required parameters parser.add_argument( "--model_name", default="xclip-base-patch32", type=str, help="Name of the model.", ) 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 = parser.parse_args() convert_xclip_checkpoint(args.model_name, args.pytorch_dump_folder_path, args.push_to_hub)
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"""simple docstring""" def A_ ( _lowercase = 100 ): '''simple docstring''' snake_case_ :Dict = set() snake_case_ :Tuple = 0 snake_case_ :Optional[int] = n + 1 # maximum limit for a in range(2, _lowercase ): for b in range(2, _lowercase ): snake_case_ :Optional[Any] = a**b # calculates the current power collect_powers.add(_lowercase ) # adds the result to the set return len(_lowercase ) if __name__ == "__main__": print("Number of terms ", solution(int(str(input()).strip())))
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"""simple docstring""" import unittest import numpy as np from transformers import BertConfig, is_flax_available from transformers.testing_utils import require_flax, slow from ...test_modeling_flax_common import FlaxModelTesterMixin, floats_tensor, ids_tensor, random_attention_mask if is_flax_available(): from transformers.models.bert.modeling_flax_bert import ( FlaxBertForMaskedLM, FlaxBertForMultipleChoice, FlaxBertForNextSentencePrediction, FlaxBertForPreTraining, FlaxBertForQuestionAnswering, FlaxBertForSequenceClassification, FlaxBertForTokenClassification, FlaxBertModel, ) class lowerCamelCase ( unittest.TestCase ): '''simple docstring''' def __init__( self: List[Any] , snake_case: List[str] , snake_case: Optional[Any]=13 , snake_case: List[str]=7 , snake_case: Dict=True , snake_case: List[str]=True , snake_case: Optional[int]=True , snake_case: Any=True , snake_case: Optional[Any]=99 , snake_case: Tuple=32 , snake_case: Tuple=5 , snake_case: Dict=4 , snake_case: Optional[Any]=37 , snake_case: Union[str, Any]="gelu" , snake_case: Tuple=0.1 , snake_case: List[Any]=0.1 , snake_case: List[str]=512 , snake_case: Optional[int]=16 , snake_case: int=2 , snake_case: List[Any]=0.0_2 , snake_case: Union[str, Any]=4 , ) -> List[str]: snake_case_ :Dict = parent snake_case_ :Any = batch_size snake_case_ :Any = seq_length snake_case_ :List[str] = is_training snake_case_ :Optional[Any] = use_attention_mask snake_case_ :Dict = use_token_type_ids snake_case_ :Union[str, Any] = use_labels snake_case_ :str = vocab_size snake_case_ :int = hidden_size snake_case_ :List[str] = num_hidden_layers snake_case_ :Dict = num_attention_heads snake_case_ :Any = intermediate_size snake_case_ :Tuple = hidden_act snake_case_ :int = hidden_dropout_prob snake_case_ :Optional[Any] = attention_probs_dropout_prob snake_case_ :Any = max_position_embeddings snake_case_ :Union[str, Any] = type_vocab_size snake_case_ :Optional[int] = type_sequence_label_size snake_case_ :Union[str, Any] = initializer_range snake_case_ :Tuple = num_choices def lowerCAmelCase_ ( self: Tuple ) -> str: snake_case_ :Optional[Any] = ids_tensor([self.batch_size, self.seq_length] , self.vocab_size ) snake_case_ :Union[str, Any] = None if self.use_attention_mask: snake_case_ :str = random_attention_mask([self.batch_size, self.seq_length] ) snake_case_ :Any = None if self.use_token_type_ids: snake_case_ :List[str] = ids_tensor([self.batch_size, self.seq_length] , self.type_vocab_size ) snake_case_ :int = BertConfig( 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 , ) return config, input_ids, token_type_ids, attention_mask def lowerCAmelCase_ ( self: Optional[int] ) -> int: snake_case_ :str = self.prepare_config_and_inputs() snake_case_, snake_case_, snake_case_, snake_case_ :Optional[int] = config_and_inputs snake_case_ :Union[str, Any] = {"""input_ids""": input_ids, """token_type_ids""": token_type_ids, """attention_mask""": attention_mask} return config, inputs_dict def lowerCAmelCase_ ( self: Optional[Any] ) -> Any: snake_case_ :int = self.prepare_config_and_inputs() snake_case_, snake_case_, snake_case_, snake_case_ :Dict = config_and_inputs snake_case_ :Union[str, Any] = True snake_case_ :Optional[int] = floats_tensor([self.batch_size, self.seq_length, self.hidden_size] ) snake_case_ :Tuple = ids_tensor([self.batch_size, self.seq_length] , vocab_size=2 ) return ( config, input_ids, attention_mask, encoder_hidden_states, encoder_attention_mask, ) @require_flax class lowerCamelCase ( _lowerCAmelCase , unittest.TestCase ): '''simple docstring''' _A : List[str] = True _A : Dict = ( ( FlaxBertModel, FlaxBertForPreTraining, FlaxBertForMaskedLM, FlaxBertForMultipleChoice, FlaxBertForQuestionAnswering, FlaxBertForNextSentencePrediction, FlaxBertForSequenceClassification, FlaxBertForTokenClassification, FlaxBertForQuestionAnswering, ) if is_flax_available() else () ) def lowerCAmelCase_ ( self: int ) -> List[str]: snake_case_ :Any = FlaxBertModelTester(self ) @slow def lowerCAmelCase_ ( self: List[str] ) -> Dict: # Only check this for base model, not necessary for all model classes. # This will also help speed-up tests. snake_case_ :Dict = FlaxBertModel.from_pretrained("""bert-base-cased""" ) snake_case_ :Dict = model(np.ones((1, 1) ) ) self.assertIsNotNone(snake_case )
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"""simple docstring""" __a = {} def A_ ( _lowercase, _lowercase, _lowercase ): '''simple docstring''' if late == 3 or absent == 2: return 0 # if we have no days left, and have not failed any other rules, # we have a prize string if days == 0: return 1 # No easy solution, so now we need to do the recursive calculation # First, check if the combination is already in the cache, and # if yes, return the stored value from there since we already # know the number of possible prize strings from this point on snake_case_ :str = (days, absent, late) if key in cache: return cache[key] # now we calculate the three possible ways that can unfold from # this point on, depending on our attendance today # 1) if we are late (but not absent), the "absent" counter stays as # it is, but the "late" counter increases by one snake_case_ :Any = _calculate(days - 1, _lowercase, late + 1 ) # 2) if we are absent, the "absent" counter increases by 1, and the # "late" counter resets to 0 snake_case_ :Optional[int] = _calculate(days - 1, absent + 1, 0 ) # 3) if we are on time, this resets the "late" counter and keeps the # absent counter snake_case_ :str = _calculate(days - 1, _lowercase, 0 ) snake_case_ :Optional[Any] = state_late + state_absent + state_ontime snake_case_ :Optional[Any] = prizestrings return prizestrings def A_ ( _lowercase = 30 ): '''simple docstring''' return _calculate(_lowercase, absent=0, late=0 ) if __name__ == "__main__": print(solution())
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"""simple docstring""" import math class lowerCamelCase : '''simple docstring''' def lowerCAmelCase_ ( self: Tuple , snake_case: list[list[float]] , snake_case: list[int] ) -> int: snake_case_ :Any = 0.0 snake_case_ :Tuple = 0.0 for i in range(len(snake_case ) ): da += math.pow((sample[i] - weights[0][i]) , 2 ) da += math.pow((sample[i] - weights[1][i]) , 2 ) return 0 if da > da else 1 return 0 def lowerCAmelCase_ ( self: Optional[int] , snake_case: list[list[int | float]] , snake_case: list[int] , snake_case: int , snake_case: float ) -> list[list[int | float]]: for i in range(len(snake_case ) ): weights[j][i] += alpha * (sample[i] - weights[j][i]) return weights def A_ ( ): '''simple docstring''' snake_case_ :Dict = [[1, 1, 0, 0], [0, 0, 0, 1], [1, 0, 0, 0], [0, 0, 1, 1]] # weight initialization ( n, C ) snake_case_ :List[Any] = [[0.2, 0.6, 0.5, 0.9], [0.8, 0.4, 0.7, 0.3]] # training snake_case_ :Optional[Any] = SelfOrganizingMap() snake_case_ :Dict = 3 snake_case_ :Dict = 0.5 for _ in range(_lowercase ): for j in range(len(_lowercase ) ): # training sample snake_case_ :List[Any] = training_samples[j] # Compute the winning vector snake_case_ :Optional[int] = self_organizing_map.get_winner(_lowercase, _lowercase ) # Update the winning vector snake_case_ :List[str] = self_organizing_map.update(_lowercase, _lowercase, _lowercase, _lowercase ) # classify test sample snake_case_ :str = [0, 0, 0, 1] snake_case_ :List[Any] = self_organizing_map.get_winner(_lowercase, _lowercase ) # results print(f"""Clusters that the test sample belongs to : {winner}""" ) print(f"""Weights that have been trained : {weights}""" ) # running the main() function if __name__ == "__main__": main()
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"""simple docstring""" import argparse import os.path as osp import re import torch from safetensors.torch import load_file, save_file # =================# # UNet Conversion # # =================# __a = [ # (stable-diffusion, HF Diffusers) ("time_embed.0.weight", "time_embedding.linear_1.weight"), ("time_embed.0.bias", "time_embedding.linear_1.bias"), ("time_embed.2.weight", "time_embedding.linear_2.weight"), ("time_embed.2.bias", "time_embedding.linear_2.bias"), ("input_blocks.0.0.weight", "conv_in.weight"), ("input_blocks.0.0.bias", "conv_in.bias"), ("out.0.weight", "conv_norm_out.weight"), ("out.0.bias", "conv_norm_out.bias"), ("out.2.weight", "conv_out.weight"), ("out.2.bias", "conv_out.bias"), ] __a = [ # (stable-diffusion, HF Diffusers) ("in_layers.0", "norm1"), ("in_layers.2", "conv1"), ("out_layers.0", "norm2"), ("out_layers.3", "conv2"), ("emb_layers.1", "time_emb_proj"), ("skip_connection", "conv_shortcut"), ] __a = [] # hardcoded number of downblocks and resnets/attentions... # would need smarter logic for other networks. for i in range(4): # loop over downblocks/upblocks for j in range(2): # loop over resnets/attentions for downblocks __a = F"""down_blocks.{i}.resnets.{j}.""" __a = F"""input_blocks.{3*i + j + 1}.0.""" unet_conversion_map_layer.append((sd_down_res_prefix, hf_down_res_prefix)) if i < 3: # no attention layers in down_blocks.3 __a = F"""down_blocks.{i}.attentions.{j}.""" __a = F"""input_blocks.{3*i + j + 1}.1.""" unet_conversion_map_layer.append((sd_down_atn_prefix, hf_down_atn_prefix)) for j in range(3): # loop over resnets/attentions for upblocks __a = F"""up_blocks.{i}.resnets.{j}.""" __a = F"""output_blocks.{3*i + j}.0.""" unet_conversion_map_layer.append((sd_up_res_prefix, hf_up_res_prefix)) if i > 0: # no attention layers in up_blocks.0 __a = F"""up_blocks.{i}.attentions.{j}.""" __a = F"""output_blocks.{3*i + j}.1.""" unet_conversion_map_layer.append((sd_up_atn_prefix, hf_up_atn_prefix)) if i < 3: # no downsample in down_blocks.3 __a = F"""down_blocks.{i}.downsamplers.0.conv.""" __a = F"""input_blocks.{3*(i+1)}.0.op.""" unet_conversion_map_layer.append((sd_downsample_prefix, hf_downsample_prefix)) # no upsample in up_blocks.3 __a = F"""up_blocks.{i}.upsamplers.0.""" __a = F"""output_blocks.{3*i + 2}.{1 if i == 0 else 2}.""" unet_conversion_map_layer.append((sd_upsample_prefix, hf_upsample_prefix)) __a = "mid_block.attentions.0." __a = "middle_block.1." unet_conversion_map_layer.append((sd_mid_atn_prefix, hf_mid_atn_prefix)) for j in range(2): __a = F"""mid_block.resnets.{j}.""" __a = F"""middle_block.{2*j}.""" unet_conversion_map_layer.append((sd_mid_res_prefix, hf_mid_res_prefix)) def A_ ( _lowercase ): '''simple docstring''' snake_case_ :str = {k: k for k in unet_state_dict.keys()} for sd_name, hf_name in unet_conversion_map: snake_case_ :List[str] = sd_name for k, v in mapping.items(): if "resnets" in k: for sd_part, hf_part in unet_conversion_map_resnet: snake_case_ :List[str] = v.replace(_lowercase, _lowercase ) snake_case_ :str = v for k, v in mapping.items(): for sd_part, hf_part in unet_conversion_map_layer: snake_case_ :Optional[Any] = v.replace(_lowercase, _lowercase ) snake_case_ :str = v snake_case_ :Optional[Any] = {v: unet_state_dict[k] for k, v in mapping.items()} return new_state_dict # ================# # VAE Conversion # # ================# __a = [ # (stable-diffusion, HF Diffusers) ("nin_shortcut", "conv_shortcut"), ("norm_out", "conv_norm_out"), ("mid.attn_1.", "mid_block.attentions.0."), ] for i in range(4): # down_blocks have two resnets for j in range(2): __a = F"""encoder.down_blocks.{i}.resnets.{j}.""" __a = F"""encoder.down.{i}.block.{j}.""" vae_conversion_map.append((sd_down_prefix, hf_down_prefix)) if i < 3: __a = F"""down_blocks.{i}.downsamplers.0.""" __a = F"""down.{i}.downsample.""" vae_conversion_map.append((sd_downsample_prefix, hf_downsample_prefix)) __a = F"""up_blocks.{i}.upsamplers.0.""" __a = F"""up.{3-i}.upsample.""" vae_conversion_map.append((sd_upsample_prefix, hf_upsample_prefix)) # up_blocks have three resnets # also, up blocks in hf are numbered in reverse from sd for j in range(3): __a = F"""decoder.up_blocks.{i}.resnets.{j}.""" __a = F"""decoder.up.{3-i}.block.{j}.""" vae_conversion_map.append((sd_up_prefix, hf_up_prefix)) # this part accounts for mid blocks in both the encoder and the decoder for i in range(2): __a = F"""mid_block.resnets.{i}.""" __a = F"""mid.block_{i+1}.""" vae_conversion_map.append((sd_mid_res_prefix, hf_mid_res_prefix)) __a = [ # (stable-diffusion, HF Diffusers) ("norm.", "group_norm."), ("q.", "query."), ("k.", "key."), ("v.", "value."), ("proj_out.", "proj_attn."), ] def A_ ( _lowercase ): '''simple docstring''' return w.reshape(*w.shape, 1, 1 ) def A_ ( _lowercase ): '''simple docstring''' snake_case_ :Optional[Any] = {k: k for k in vae_state_dict.keys()} for k, v in mapping.items(): for sd_part, hf_part in vae_conversion_map: snake_case_ :str = v.replace(_lowercase, _lowercase ) snake_case_ :Any = v for k, v in mapping.items(): if "attentions" in k: for sd_part, hf_part in vae_conversion_map_attn: snake_case_ :Any = v.replace(_lowercase, _lowercase ) snake_case_ :Optional[Any] = v snake_case_ :Tuple = {v: vae_state_dict[k] for k, v in mapping.items()} snake_case_ :str = ["""q""", """k""", """v""", """proj_out"""] for k, v in new_state_dict.items(): for weight_name in weights_to_convert: if f"""mid.attn_1.{weight_name}.weight""" in k: print(f"""Reshaping {k} for SD format""" ) snake_case_ :List[Any] = reshape_weight_for_sd(_lowercase ) return new_state_dict # =========================# # Text Encoder Conversion # # =========================# __a = [ # (stable-diffusion, HF Diffusers) ("resblocks.", "text_model.encoder.layers."), ("ln_1", "layer_norm1"), ("ln_2", "layer_norm2"), (".c_fc.", ".fc1."), (".c_proj.", ".fc2."), (".attn", ".self_attn"), ("ln_final.", "transformer.text_model.final_layer_norm."), ("token_embedding.weight", "transformer.text_model.embeddings.token_embedding.weight"), ("positional_embedding", "transformer.text_model.embeddings.position_embedding.weight"), ] __a = {re.escape(x[1]): x[0] for x in textenc_conversion_lst} __a = re.compile("|".join(protected.keys())) # Ordering is from https://github.com/pytorch/pytorch/blob/master/test/cpp/api/modules.cpp __a = {"q": 0, "k": 1, "v": 2} def A_ ( _lowercase ): '''simple docstring''' snake_case_ :int = {} snake_case_ :Tuple = {} snake_case_ :Union[str, Any] = {} for k, v in text_enc_dict.items(): if ( k.endswith(""".self_attn.q_proj.weight""" ) or k.endswith(""".self_attn.k_proj.weight""" ) or k.endswith(""".self_attn.v_proj.weight""" ) ): snake_case_ :Union[str, Any] = k[: -len(""".q_proj.weight""" )] snake_case_ :Optional[Any] = k[-len("""q_proj.weight""" )] if k_pre not in capture_qkv_weight: snake_case_ :int = [None, None, None] snake_case_ :Union[str, Any] = v continue if ( k.endswith(""".self_attn.q_proj.bias""" ) or k.endswith(""".self_attn.k_proj.bias""" ) or k.endswith(""".self_attn.v_proj.bias""" ) ): snake_case_ :List[Any] = k[: -len(""".q_proj.bias""" )] snake_case_ :Tuple = k[-len("""q_proj.bias""" )] if k_pre not in capture_qkv_bias: snake_case_ :Dict = [None, None, None] snake_case_ :List[str] = v continue snake_case_ :Union[str, Any] = textenc_pattern.sub(lambda _lowercase : protected[re.escape(m.group(0 ) )], _lowercase ) snake_case_ :Dict = v for k_pre, tensors in capture_qkv_weight.items(): if None in tensors: raise Exception("""CORRUPTED MODEL: one of the q-k-v values for the text encoder was missing""" ) snake_case_ :Tuple = textenc_pattern.sub(lambda _lowercase : protected[re.escape(m.group(0 ) )], _lowercase ) snake_case_ :Tuple = torch.cat(_lowercase ) for k_pre, tensors in capture_qkv_bias.items(): if None in tensors: raise Exception("""CORRUPTED MODEL: one of the q-k-v values for the text encoder was missing""" ) snake_case_ :Any = textenc_pattern.sub(lambda _lowercase : protected[re.escape(m.group(0 ) )], _lowercase ) snake_case_ :List[str] = torch.cat(_lowercase ) return new_state_dict def A_ ( _lowercase ): '''simple docstring''' return text_enc_dict if __name__ == "__main__": __a = argparse.ArgumentParser() parser.add_argument("--model_path", default=None, type=str, required=True, help="Path to the model to convert.") parser.add_argument("--checkpoint_path", default=None, type=str, required=True, help="Path to the output model.") parser.add_argument("--half", action="store_true", help="Save weights in half precision.") parser.add_argument( "--use_safetensors", action="store_true", help="Save weights use safetensors, default is ckpt." ) __a = parser.parse_args() assert args.model_path is not None, "Must provide a model path!" assert args.checkpoint_path is not None, "Must provide a checkpoint path!" # Path for safetensors __a = osp.join(args.model_path, "unet", "diffusion_pytorch_model.safetensors") __a = osp.join(args.model_path, "vae", "diffusion_pytorch_model.safetensors") __a = osp.join(args.model_path, "text_encoder", "model.safetensors") # Load models from safetensors if it exists, if it doesn't pytorch if osp.exists(unet_path): __a = load_file(unet_path, device="cpu") else: __a = osp.join(args.model_path, "unet", "diffusion_pytorch_model.bin") __a = torch.load(unet_path, map_location="cpu") if osp.exists(vae_path): __a = load_file(vae_path, device="cpu") else: __a = osp.join(args.model_path, "vae", "diffusion_pytorch_model.bin") __a = torch.load(vae_path, map_location="cpu") if osp.exists(text_enc_path): __a = load_file(text_enc_path, device="cpu") else: __a = osp.join(args.model_path, "text_encoder", "pytorch_model.bin") __a = torch.load(text_enc_path, map_location="cpu") # Convert the UNet model __a = convert_unet_state_dict(unet_state_dict) __a = {"model.diffusion_model." + k: v for k, v in unet_state_dict.items()} # Convert the VAE model __a = convert_vae_state_dict(vae_state_dict) __a = {"first_stage_model." + k: v for k, v in vae_state_dict.items()} # Easiest way to identify v2.0 model seems to be that the text encoder (OpenCLIP) is deeper __a = "text_model.encoder.layers.22.layer_norm2.bias" in text_enc_dict if is_vaa_model: # Need to add the tag 'transformer' in advance so we can knock it out from the final layer-norm __a = {"transformer." + k: v for k, v in text_enc_dict.items()} __a = convert_text_enc_state_dict_vaa(text_enc_dict) __a = {"cond_stage_model.model." + k: v for k, v in text_enc_dict.items()} else: __a = convert_text_enc_state_dict(text_enc_dict) __a = {"cond_stage_model.transformer." + k: v for k, v in text_enc_dict.items()} # Put together new checkpoint __a = {**unet_state_dict, **vae_state_dict, **text_enc_dict} if args.half: __a = {k: v.half() for k, v in state_dict.items()} if args.use_safetensors: save_file(state_dict, args.checkpoint_path) else: __a = {"state_dict": state_dict} torch.save(state_dict, args.checkpoint_path)
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"""simple docstring""" 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 : '''simple docstring''' def __init__( self: Optional[int] , snake_case: Any , snake_case: Optional[Any]=13 , snake_case: Tuple=32 , snake_case: Optional[int]=2 , snake_case: Tuple=3 , snake_case: Tuple=16 , snake_case: Optional[Any]=[1, 2, 1] , snake_case: Optional[int]=[2, 2, 4] , snake_case: Optional[int]=2 , snake_case: int=2.0 , snake_case: Union[str, Any]=True , snake_case: List[str]=0.0 , snake_case: List[Any]=0.0 , snake_case: Optional[Any]=0.1 , snake_case: List[Any]="gelu" , snake_case: Optional[int]=False , snake_case: Union[str, Any]=True , snake_case: Union[str, Any]=0.0_2 , snake_case: Optional[int]=1E-5 , snake_case: Optional[Any]=True , snake_case: List[Any]=None , snake_case: List[Any]=True , snake_case: Optional[Any]=10 , snake_case: str=8 , ) -> Tuple: snake_case_ :Dict = parent snake_case_ :Any = batch_size snake_case_ :List[Any] = image_size snake_case_ :List[Any] = patch_size snake_case_ :int = num_channels snake_case_ :Tuple = embed_dim snake_case_ :str = depths snake_case_ :str = num_heads snake_case_ :Optional[int] = window_size snake_case_ :Tuple = mlp_ratio snake_case_ :Any = qkv_bias snake_case_ :List[Any] = hidden_dropout_prob snake_case_ :Optional[Any] = attention_probs_dropout_prob snake_case_ :Union[str, Any] = drop_path_rate snake_case_ :Any = hidden_act snake_case_ :Optional[Any] = use_absolute_embeddings snake_case_ :Union[str, Any] = patch_norm snake_case_ :Dict = layer_norm_eps snake_case_ :str = initializer_range snake_case_ :Tuple = is_training snake_case_ :Tuple = scope snake_case_ :Union[str, Any] = use_labels snake_case_ :Optional[Any] = type_sequence_label_size snake_case_ :Dict = encoder_stride def lowerCAmelCase_ ( self: int ) -> int: snake_case_ :List[str] = floats_tensor([self.batch_size, self.num_channels, self.image_size, self.image_size] ) snake_case_ :Any = None if self.use_labels: snake_case_ :str = ids_tensor([self.batch_size] , self.type_sequence_label_size ) snake_case_ :int = self.get_config() return config, pixel_values, labels def lowerCAmelCase_ ( self: str ) -> Union[str, Any]: 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 lowerCAmelCase_ ( self: str , snake_case: Optional[int] , snake_case: Dict , snake_case: str ) -> List[Any]: snake_case_ :Union[str, Any] = SwinvaModel(config=snake_case ) model.to(snake_case ) model.eval() snake_case_ :Optional[int] = model(snake_case ) snake_case_ :Optional[Any] = ((config.image_size // config.patch_size) ** 2) // (4 ** (len(config.depths ) - 1)) snake_case_ :int = 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 lowerCAmelCase_ ( self: int , snake_case: List[str] , snake_case: Tuple , snake_case: int ) -> Any: snake_case_ :Dict = SwinvaForMaskedImageModeling(config=snake_case ) model.to(snake_case ) model.eval() snake_case_ :Tuple = 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_ :List[Any] = 1 snake_case_ :int = SwinvaForMaskedImageModeling(snake_case ) model.to(snake_case ) model.eval() snake_case_ :Union[str, Any] = floats_tensor([self.batch_size, 1, self.image_size, self.image_size] ) snake_case_ :int = model(snake_case ) self.parent.assertEqual(result.logits.shape , (self.batch_size, 1, self.image_size, self.image_size) ) def lowerCAmelCase_ ( self: List[Any] , snake_case: Any , snake_case: List[str] , snake_case: Union[str, Any] ) -> Tuple: snake_case_ :int = self.type_sequence_label_size snake_case_ :List[Any] = SwinvaForImageClassification(snake_case ) model.to(snake_case ) model.eval() snake_case_ :Dict = model(snake_case , labels=snake_case ) self.parent.assertEqual(result.logits.shape , (self.batch_size, self.type_sequence_label_size) ) def lowerCAmelCase_ ( self: int ) -> str: snake_case_ :Any = self.prepare_config_and_inputs() snake_case_, snake_case_, snake_case_ :List[str] = config_and_inputs snake_case_ :List[Any] = {"""pixel_values""": pixel_values} return config, inputs_dict @require_torch class lowerCamelCase ( _lowerCAmelCase , _lowerCAmelCase , unittest.TestCase ): '''simple docstring''' _A : Optional[Any] = ( (SwinvaModel, SwinvaForImageClassification, SwinvaForMaskedImageModeling) if is_torch_available() else () ) _A : Any = ( {"""feature-extraction""": SwinvaModel, """image-classification""": SwinvaForImageClassification} if is_torch_available() else {} ) _A : List[Any] = False _A : List[str] = False _A : Tuple = False _A : List[str] = False def lowerCAmelCase_ ( self: Dict ) -> List[Any]: snake_case_ :Optional[int] = SwinvaModelTester(self ) snake_case_ :List[str] = ConfigTester(self , config_class=snake_case , embed_dim=37 ) def lowerCAmelCase_ ( self: Union[str, Any] ) -> List[Any]: 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 lowerCAmelCase_ ( self: Union[str, Any] ) -> Tuple: snake_case_ :List[str] = 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 lowerCAmelCase_ ( self: Union[str, Any] ) -> str: pass @unittest.skip(reason="""Swinv2 does not use inputs_embeds""" ) def lowerCAmelCase_ ( self: int ) -> Dict: pass def lowerCAmelCase_ ( self: List[str] ) -> Union[str, Any]: snake_case_, snake_case_ :List[str] = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: snake_case_ :Optional[int] = model_class(snake_case ) self.assertIsInstance(model.get_input_embeddings() , (nn.Module) ) snake_case_ :List[Any] = model.get_output_embeddings() self.assertTrue(x is None or isinstance(snake_case , nn.Linear ) ) def lowerCAmelCase_ ( self: Dict ) -> Optional[int]: snake_case_, snake_case_ :Union[str, Any] = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: snake_case_ :Optional[int] = model_class(snake_case ) snake_case_ :List[Any] = inspect.signature(model.forward ) # signature.parameters is an OrderedDict => so arg_names order is deterministic snake_case_ :int = [*signature.parameters.keys()] snake_case_ :List[Any] = ["""pixel_values"""] self.assertListEqual(arg_names[:1] , snake_case ) def lowerCAmelCase_ ( self: List[str] ) -> Optional[Any]: snake_case_, snake_case_ :List[str] = self.model_tester.prepare_config_and_inputs_for_common() snake_case_ :List[str] = True for model_class in self.all_model_classes: snake_case_ :List[Any] = True snake_case_ :Any = False snake_case_ :Optional[int] = True snake_case_ :Tuple = model_class(snake_case ) model.to(snake_case ) model.eval() with torch.no_grad(): snake_case_ :Any = model(**self._prepare_for_class(snake_case , snake_case ) ) snake_case_ :str = outputs.attentions snake_case_ :Dict = 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_ :Union[str, Any] = True snake_case_ :Tuple = config.window_size**2 snake_case_ :Any = model_class(snake_case ) model.to(snake_case ) model.eval() with torch.no_grad(): snake_case_ :Union[str, Any] = model(**self._prepare_for_class(snake_case , snake_case ) ) snake_case_ :int = 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_ :Any = len(snake_case ) # Check attention is always last and order is fine snake_case_ :int = True snake_case_ :Dict = True snake_case_ :Optional[int] = model_class(snake_case ) model.to(snake_case ) model.eval() with torch.no_grad(): snake_case_ :Dict = model(**self._prepare_for_class(snake_case , snake_case ) ) if hasattr(self.model_tester , """num_hidden_states_types""" ): snake_case_ :Any = self.model_tester.num_hidden_states_types else: # also another +1 for reshaped_hidden_states snake_case_ :int = 2 self.assertEqual(out_len + added_hidden_states , len(snake_case ) ) snake_case_ :str = 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 lowerCAmelCase_ ( self: int , snake_case: Dict , snake_case: Dict , snake_case: Optional[Any] , snake_case: Dict ) -> List[str]: snake_case_ :Dict = 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_ :str = outputs.hidden_states snake_case_ :List[Any] = 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_ :List[Any] = ( config.patch_size if isinstance(config.patch_size , collections.abc.Iterable ) else (config.patch_size, config.patch_size) ) snake_case_ :Optional[int] = (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_ :str = outputs.reshaped_hidden_states self.assertEqual(len(snake_case ) , snake_case ) snake_case_, snake_case_, snake_case_, snake_case_ :Any = reshaped_hidden_states[0].shape snake_case_ :int = ( 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 lowerCAmelCase_ ( self: Any ) -> Any: snake_case_, snake_case_ :List[Any] = self.model_tester.prepare_config_and_inputs_for_common() 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) ) for model_class in self.all_model_classes: snake_case_ :Union[str, Any] = 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_ :List[str] = True self.check_hidden_states_output(snake_case , snake_case , snake_case , snake_case ) def lowerCAmelCase_ ( self: Tuple ) -> Any: snake_case_, snake_case_ :Union[str, Any] = self.model_tester.prepare_config_and_inputs_for_common() snake_case_ :Optional[int] = 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_ :Any = image_size[0] + patch_size[0] - (image_size[0] % patch_size[0]) snake_case_ :int = image_size[1] + patch_size[1] - (image_size[1] % patch_size[1]) for model_class in self.all_model_classes: snake_case_ :str = 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_ :Tuple = True self.check_hidden_states_output(snake_case , snake_case , snake_case , (padded_height, padded_width) ) def lowerCAmelCase_ ( self: Any ) -> Tuple: snake_case_ :int = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_for_masked_image_modeling(*snake_case ) def lowerCAmelCase_ ( self: Optional[int] ) -> Dict: snake_case_ :Any = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_for_image_classification(*snake_case ) @slow def lowerCAmelCase_ ( self: List[Any] ) -> Dict: for model_name in SWINV2_PRETRAINED_MODEL_ARCHIVE_LIST[:1]: snake_case_ :List[str] = SwinvaModel.from_pretrained(snake_case ) self.assertIsNotNone(snake_case ) def lowerCAmelCase_ ( self: Optional[int] ) -> List[Any]: snake_case_, snake_case_ :str = self.model_tester.prepare_config_and_inputs_for_common() snake_case_ :Optional[int] = _config_zero_init(snake_case ) for model_class in self.all_model_classes: snake_case_ :Tuple = 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 ): '''simple docstring''' @cached_property def lowerCAmelCase_ ( self: Optional[int] ) -> List[Any]: return ( AutoImageProcessor.from_pretrained("""microsoft/swinv2-tiny-patch4-window8-256""" ) if is_vision_available() else None ) @slow def lowerCAmelCase_ ( self: List[str] ) -> List[str]: snake_case_ :Tuple = SwinvaForImageClassification.from_pretrained("""microsoft/swinv2-tiny-patch4-window8-256""" ).to( snake_case ) snake_case_ :str = self.default_image_processor snake_case_ :List[Any] = Image.open("""./tests/fixtures/tests_samples/COCO/000000039769.png""" ) snake_case_ :str = image_processor(images=snake_case , return_tensors="""pt""" ).to(snake_case ) # forward pass with torch.no_grad(): snake_case_ :Tuple = model(**snake_case ) # verify the logits snake_case_ :Dict = torch.Size((1, 1_000) ) self.assertEqual(outputs.logits.shape , snake_case ) snake_case_ :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 typing import Optional import numpy as np import torch from torch import nn from transformers import GPTaConfig, GPTaLMHeadModel from transformers.modeling_utils import ModuleUtilsMixin from ...configuration_utils import ConfigMixin, register_to_config from ...models import ModelMixin class lowerCamelCase ( _lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase ): '''simple docstring''' _A : List[Any] = [R"""h\.\d+\.attn\.bias""", R"""h\.\d+\.attn\.masked_bias"""] @register_to_config def __init__( self: Union[str, Any] , snake_case: int , snake_case: int , snake_case: Optional[int] = None , snake_case: int = 50_257 , snake_case: int = 1_024 , snake_case: int = 768 , snake_case: int = 12 , snake_case: int = 12 , snake_case: Optional[int] = None , snake_case: str = "gelu_new" , snake_case: float = 0.1 , snake_case: float = 0.1 , snake_case: float = 0.1 , snake_case: float = 1E-5 , snake_case: float = 0.0_2 , snake_case: bool = True , snake_case: bool = True , snake_case: bool = False , snake_case: bool = False , ) -> Tuple: super().__init__() snake_case_ :Tuple = prefix_length if prefix_inner_dim != n_embd and prefix_hidden_dim is None: raise ValueError( f"""`prefix_hidden_dim` cannot be `None` when `prefix_inner_dim`: {prefix_hidden_dim} and""" f""" `n_embd`: {n_embd} are not equal.""" ) snake_case_ :Union[str, Any] = prefix_inner_dim snake_case_ :Optional[Any] = prefix_hidden_dim snake_case_ :Dict = ( nn.Linear(self.prefix_inner_dim , self.prefix_hidden_dim ) if self.prefix_hidden_dim is not None else nn.Identity() ) snake_case_ :str = ( nn.Linear(self.prefix_hidden_dim , snake_case ) if self.prefix_hidden_dim is not None else nn.Identity() ) snake_case_ :Any = GPTaConfig( vocab_size=snake_case , n_positions=snake_case , n_embd=snake_case , n_layer=snake_case , n_head=snake_case , n_inner=snake_case , activation_function=snake_case , resid_pdrop=snake_case , embd_pdrop=snake_case , attn_pdrop=snake_case , layer_norm_epsilon=snake_case , initializer_range=snake_case , scale_attn_weights=snake_case , use_cache=snake_case , scale_attn_by_inverse_layer_idx=snake_case , reorder_and_upcast_attn=snake_case , ) snake_case_ :Dict = GPTaLMHeadModel(snake_case ) def lowerCAmelCase_ ( self: int , snake_case: torch.Tensor , snake_case: torch.Tensor , snake_case: Optional[torch.Tensor] = None , snake_case: Optional[torch.Tensor] = None , ) -> Union[str, Any]: snake_case_ :Tuple = self.transformer.transformer.wte(snake_case ) snake_case_ :str = self.encode_prefix(snake_case ) snake_case_ :List[Any] = self.decode_prefix(snake_case ) snake_case_ :Dict = torch.cat((prefix_embeds, embedding_text) , dim=1 ) if labels is not None: snake_case_ :Tuple = self.get_dummy_token(input_ids.shape[0] , input_ids.device ) snake_case_ :Union[str, Any] = torch.cat((dummy_token, input_ids) , dim=1 ) snake_case_ :Tuple = self.transformer(inputs_embeds=snake_case , labels=snake_case , attention_mask=snake_case ) if self.prefix_hidden_dim is not None: return out, hidden else: return out def lowerCAmelCase_ ( self: List[str] , snake_case: int , snake_case: torch.device ) -> torch.Tensor: return torch.zeros(snake_case , self.prefix_length , dtype=torch.intaa , device=snake_case ) def lowerCAmelCase_ ( self: Any , snake_case: int ) -> List[Any]: return self.encode_prefix(snake_case ) @torch.no_grad() def lowerCAmelCase_ ( self: List[str] , snake_case: Tuple , snake_case: int , snake_case: List[Any] ) -> Dict: snake_case_ :List[Any] = torch.split(snake_case , 1 , dim=0 ) snake_case_ :Optional[int] = [] snake_case_ :str = [] for feature in features: snake_case_ :Tuple = self.decode_prefix(feature.to(snake_case ) ) # back to the clip feature # Only support beam search for now snake_case_, snake_case_ :Union[str, Any] = self.generate_beam( input_embeds=snake_case , device=snake_case , eos_token_id=snake_case ) generated_tokens.append(output_tokens[0] ) generated_seq_lengths.append(seq_lengths[0] ) snake_case_ :Optional[int] = torch.stack(snake_case ) snake_case_ :Tuple = torch.stack(snake_case ) return generated_tokens, generated_seq_lengths @torch.no_grad() def lowerCAmelCase_ ( self: Tuple , snake_case: List[Any]=None , snake_case: Dict=None , snake_case: List[Any]=None , snake_case: int = 5 , snake_case: int = 67 , snake_case: float = 1.0 , snake_case: Optional[int] = None , ) -> Tuple: snake_case_ :int = eos_token_id snake_case_ :Tuple = None snake_case_ :Union[str, Any] = None snake_case_ :int = torch.ones(snake_case , device=snake_case , dtype=torch.int ) snake_case_ :List[Any] = torch.zeros(snake_case , device=snake_case , dtype=torch.bool ) if input_embeds is not None: snake_case_ :str = input_embeds else: snake_case_ :Optional[int] = self.transformer.transformer.wte(snake_case ) for i in range(snake_case ): snake_case_ :str = self.transformer(inputs_embeds=snake_case ) snake_case_ :int = outputs.logits snake_case_ :Tuple = logits[:, -1, :] / (temperature if temperature > 0 else 1.0) snake_case_ :List[str] = logits.softmax(-1 ).log() if scores is None: snake_case_, snake_case_ :Optional[int] = logits.topk(snake_case , -1 ) snake_case_ :Union[str, Any] = generated.expand(snake_case , *generated.shape[1:] ) snake_case_, snake_case_ :Optional[Any] = next_tokens.permute(1 , 0 ), scores.squeeze(0 ) if tokens is None: snake_case_ :str = next_tokens else: snake_case_ :Any = tokens.expand(snake_case , *tokens.shape[1:] ) snake_case_ :Any = torch.cat((tokens, next_tokens) , dim=1 ) else: snake_case_ :Union[str, Any] = -float(np.inf ) snake_case_ :Optional[Any] = 0 snake_case_ :Any = scores[:, None] + logits seq_lengths[~is_stopped] += 1 snake_case_ :Any = scores_sum / seq_lengths[:, None] snake_case_, snake_case_ :str = scores_sum_average.view(-1 ).topk(snake_case , -1 ) snake_case_ :List[str] = next_tokens // scores_sum.shape[1] snake_case_ :Optional[Any] = seq_lengths[next_tokens_source] snake_case_ :List[str] = next_tokens % scores_sum.shape[1] snake_case_ :Union[str, Any] = next_tokens.unsqueeze(1 ) snake_case_ :Optional[int] = tokens[next_tokens_source] snake_case_ :Dict = torch.cat((tokens, next_tokens) , dim=1 ) snake_case_ :List[str] = generated[next_tokens_source] snake_case_ :str = scores_sum_average * seq_lengths snake_case_ :str = is_stopped[next_tokens_source] snake_case_ :List[str] = self.transformer.transformer.wte(next_tokens.squeeze() ).view(generated.shape[0] , 1 , -1 ) snake_case_ :Optional[int] = torch.cat((generated, next_token_embed) , dim=1 ) snake_case_ :Optional[int] = is_stopped + next_tokens.eq(snake_case ).squeeze() if is_stopped.all(): break snake_case_ :Union[str, Any] = scores / seq_lengths snake_case_ :List[str] = scores.argsort(descending=snake_case ) # tokens tensors are already padded to max_seq_length snake_case_ :Union[str, Any] = [tokens[i] for i in order] snake_case_ :Optional[Any] = torch.stack(snake_case , dim=0 ) snake_case_ :List[Any] = torch.tensor([seq_lengths[i] for i in order] , dtype=seq_lengths.dtype ) return output_texts, seq_lengths
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"""simple docstring""" import re def A_ ( _lowercase ): '''simple docstring''' snake_case_ :Optional[int] = re.compile( r"""^(?:0|94|\+94|0{2}94)""" r"""7(0|1|2|4|5|6|7|8)""" r"""(-| |)""" r"""\d{7}$""" ) return bool(re.search(_lowercase, _lowercase ) ) if __name__ == "__main__": __a = "0094702343221" print(is_sri_lankan_phone_number(phone))
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"""simple docstring""" from typing import TYPE_CHECKING from ...utils import ( OptionalDependencyNotAvailable, _LazyModule, is_flax_available, is_tf_available, is_torch_available, ) __a = { "configuration_vision_text_dual_encoder": ["VisionTextDualEncoderConfig"], "processing_vision_text_dual_encoder": ["VisionTextDualEncoderProcessor"], } try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __a = ["VisionTextDualEncoderModel"] try: if not is_flax_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __a = ["FlaxVisionTextDualEncoderModel"] try: if not is_tf_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __a = ["TFVisionTextDualEncoderModel"] if TYPE_CHECKING: from .configuration_vision_text_dual_encoder import VisionTextDualEncoderConfig from .processing_vision_text_dual_encoder import VisionTextDualEncoderProcessor try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_vision_text_dual_encoder import VisionTextDualEncoderModel try: if not is_flax_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_flax_vision_text_dual_encoder import FlaxVisionTextDualEncoderModel try: if not is_tf_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_tf_vision_text_dual_encoder import TFVisionTextDualEncoderModel else: import sys __a = _LazyModule(__name__, globals()["__file__"], _import_structure)
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"""simple docstring""" import argparse import json import os import pickle import shutil import numpy as np import torch from distiller import Distiller from lm_seqs_dataset import LmSeqsDataset from transformers import ( BertConfig, BertForMaskedLM, BertTokenizer, DistilBertConfig, DistilBertForMaskedLM, DistilBertTokenizer, GPTaConfig, GPTaLMHeadModel, GPTaTokenizer, RobertaConfig, RobertaForMaskedLM, RobertaTokenizer, ) from utils import git_log, init_gpu_params, logger, set_seed __a = { "distilbert": (DistilBertConfig, DistilBertForMaskedLM, DistilBertTokenizer), "roberta": (RobertaConfig, RobertaForMaskedLM, RobertaTokenizer), "bert": (BertConfig, BertForMaskedLM, BertTokenizer), "gpt2": (GPTaConfig, GPTaLMHeadModel, GPTaTokenizer), } def A_ ( _lowercase ): '''simple docstring''' assert (args.mlm and args.alpha_mlm > 0.0) or (not args.mlm and args.alpha_mlm == 0.0) assert (args.alpha_mlm > 0.0 and args.alpha_clm == 0.0) or (args.alpha_mlm == 0.0 and args.alpha_clm > 0.0) if args.mlm: assert os.path.isfile(args.token_counts ) assert (args.student_type in ["roberta", "distilbert"]) and (args.teacher_type in ["roberta", "bert"]) else: assert (args.student_type in ["gpt2"]) and (args.teacher_type in ["gpt2"]) assert args.teacher_type == args.student_type or ( args.student_type == "distilbert" and args.teacher_type == "bert" ) assert os.path.isfile(args.student_config ) if args.student_pretrained_weights is not None: assert os.path.isfile(args.student_pretrained_weights ) if args.freeze_token_type_embds: assert args.student_type in ["roberta"] assert args.alpha_ce >= 0.0 assert args.alpha_mlm >= 0.0 assert args.alpha_clm >= 0.0 assert args.alpha_mse >= 0.0 assert args.alpha_cos >= 0.0 assert args.alpha_ce + args.alpha_mlm + args.alpha_clm + args.alpha_mse + args.alpha_cos > 0.0 def A_ ( _lowercase, _lowercase ): '''simple docstring''' if args.student_type == "roberta": snake_case_ :Tuple = False elif args.student_type == "gpt2": snake_case_ :Union[str, Any] = False def A_ ( _lowercase, _lowercase ): '''simple docstring''' if args.student_type == "roberta": snake_case_ :List[str] = False def A_ ( ): '''simple docstring''' snake_case_ :Union[str, Any] = argparse.ArgumentParser(description="""Training""" ) parser.add_argument("""--force""", action="""store_true""", help="""Overwrite dump_path if it already exists.""" ) parser.add_argument( """--dump_path""", type=_lowercase, required=_lowercase, help="""The output directory (log, checkpoints, parameters, etc.)""" ) parser.add_argument( """--data_file""", type=_lowercase, required=_lowercase, help="""The binarized file (tokenized + tokens_to_ids) and grouped by sequence.""", ) parser.add_argument( """--student_type""", type=_lowercase, choices=["""distilbert""", """roberta""", """gpt2"""], required=_lowercase, help="""The student type (DistilBERT, RoBERTa).""", ) parser.add_argument("""--student_config""", type=_lowercase, required=_lowercase, help="""Path to the student configuration.""" ) parser.add_argument( """--student_pretrained_weights""", default=_lowercase, type=_lowercase, help="""Load student initialization checkpoint.""" ) parser.add_argument( """--teacher_type""", choices=["""bert""", """roberta""", """gpt2"""], required=_lowercase, help="""Teacher type (BERT, RoBERTa).""" ) parser.add_argument("""--teacher_name""", type=_lowercase, required=_lowercase, help="""The teacher model.""" ) parser.add_argument("""--temperature""", default=2.0, type=_lowercase, help="""Temperature for the softmax temperature.""" ) parser.add_argument( """--alpha_ce""", default=0.5, type=_lowercase, help="""Linear weight for the distillation loss. Must be >=0.""" ) parser.add_argument( """--alpha_mlm""", default=0.0, type=_lowercase, help="""Linear weight for the MLM loss. Must be >=0. Should be used in conjunction with `mlm` flag.""", ) parser.add_argument("""--alpha_clm""", default=0.5, type=_lowercase, help="""Linear weight for the CLM loss. Must be >=0.""" ) parser.add_argument("""--alpha_mse""", default=0.0, type=_lowercase, help="""Linear weight of the MSE loss. Must be >=0.""" ) parser.add_argument( """--alpha_cos""", default=0.0, type=_lowercase, help="""Linear weight of the cosine embedding loss. Must be >=0.""" ) parser.add_argument( """--mlm""", action="""store_true""", help="""The LM step: MLM or CLM. If `mlm` is True, the MLM is used over CLM.""" ) parser.add_argument( """--mlm_mask_prop""", default=0.15, type=_lowercase, help="""Proportion of tokens for which we need to make a prediction.""", ) parser.add_argument("""--word_mask""", default=0.8, type=_lowercase, help="""Proportion of tokens to mask out.""" ) parser.add_argument("""--word_keep""", default=0.1, type=_lowercase, help="""Proportion of tokens to keep.""" ) parser.add_argument("""--word_rand""", default=0.1, type=_lowercase, help="""Proportion of tokens to randomly replace.""" ) parser.add_argument( """--mlm_smoothing""", default=0.7, type=_lowercase, help="""Smoothing parameter to emphasize more rare tokens (see XLM, similar to word2vec).""", ) parser.add_argument("""--token_counts""", type=_lowercase, help="""The token counts in the data_file for MLM.""" ) parser.add_argument( """--restrict_ce_to_mask""", action="""store_true""", help="""If true, compute the distillation loss only the [MLM] prediction distribution.""", ) parser.add_argument( """--freeze_pos_embs""", action="""store_true""", help="""Freeze positional embeddings during distillation. For student_type in ['roberta', 'gpt2'] only.""", ) parser.add_argument( """--freeze_token_type_embds""", action="""store_true""", help="""Freeze token type embeddings during distillation if existent. For student_type in ['roberta'] only.""", ) parser.add_argument("""--n_epoch""", type=_lowercase, default=3, help="""Number of pass on the whole dataset.""" ) parser.add_argument("""--batch_size""", type=_lowercase, default=5, help="""Batch size (for each process).""" ) parser.add_argument( """--group_by_size""", action="""store_false""", help="""If true, group sequences that have similar length into the same batch. Default is true.""", ) parser.add_argument( """--gradient_accumulation_steps""", type=_lowercase, default=50, help="""Gradient accumulation for larger training batches.""", ) parser.add_argument("""--warmup_prop""", default=0.05, type=_lowercase, help="""Linear warmup proportion.""" ) parser.add_argument("""--weight_decay""", default=0.0, type=_lowercase, help="""Weight decay if we apply some.""" ) parser.add_argument("""--learning_rate""", default=5e-4, type=_lowercase, help="""The initial learning rate for Adam.""" ) parser.add_argument("""--adam_epsilon""", default=1e-6, type=_lowercase, help="""Epsilon for Adam optimizer.""" ) parser.add_argument("""--max_grad_norm""", default=5.0, type=_lowercase, help="""Max gradient norm.""" ) parser.add_argument("""--initializer_range""", default=0.02, type=_lowercase, help="""Random initialization range.""" ) parser.add_argument( """--fp16""", action="""store_true""", help="""Whether to use 16-bit (mixed) precision (through NVIDIA apex) instead of 32-bit""", ) parser.add_argument( """--fp16_opt_level""", type=_lowercase, default="""O1""", help=( """For fp16: Apex AMP optimization level selected in ['O0', 'O1', 'O2', and 'O3'].""" """See details at https://nvidia.github.io/apex/amp.html""" ), ) parser.add_argument("""--n_gpu""", type=_lowercase, default=1, help="""Number of GPUs in the node.""" ) parser.add_argument("""--local_rank""", type=_lowercase, default=-1, help="""Distributed training - Local rank""" ) parser.add_argument("""--seed""", type=_lowercase, default=56, help="""Random seed""" ) parser.add_argument("""--log_interval""", type=_lowercase, default=500, help="""Tensorboard logging interval.""" ) parser.add_argument("""--checkpoint_interval""", type=_lowercase, default=4000, help="""Checkpoint interval.""" ) snake_case_ :Tuple = parser.parse_args() sanity_checks(_lowercase ) # ARGS # init_gpu_params(_lowercase ) set_seed(_lowercase ) if args.is_master: if os.path.exists(args.dump_path ): if not args.force: raise ValueError( f"""Serialization dir {args.dump_path} already exists, but you have not precised wheter to overwrite""" """ itUse `--force` if you want to overwrite it""" ) else: shutil.rmtree(args.dump_path ) if not os.path.exists(args.dump_path ): os.makedirs(args.dump_path ) logger.info(f"""Experiment will be dumped and logged in {args.dump_path}""" ) # SAVE PARAMS # logger.info(f"""Param: {args}""" ) with open(os.path.join(args.dump_path, """parameters.json""" ), """w""" ) as f: json.dump(vars(_lowercase ), _lowercase, indent=4 ) git_log(args.dump_path ) snake_case_, snake_case_, snake_case_ :Any = MODEL_CLASSES[args.student_type] snake_case_, snake_case_, snake_case_ :int = MODEL_CLASSES[args.teacher_type] # TOKENIZER # snake_case_ :Any = teacher_tokenizer_class.from_pretrained(args.teacher_name ) snake_case_ :Optional[Any] = {} for tok_name, tok_symbol in tokenizer.special_tokens_map.items(): snake_case_ :Union[str, Any] = tokenizer.all_special_tokens.index(_lowercase ) snake_case_ :Union[str, Any] = tokenizer.all_special_ids[idx] logger.info(f"""Special tokens {special_tok_ids}""" ) snake_case_ :str = special_tok_ids snake_case_ :Any = tokenizer.max_model_input_sizes[args.teacher_name] # DATA LOADER # logger.info(f"""Loading data from {args.data_file}""" ) with open(args.data_file, """rb""" ) as fp: snake_case_ :str = pickle.load(_lowercase ) if args.mlm: logger.info(f"""Loading token counts from {args.token_counts} (already pre-computed)""" ) with open(args.token_counts, """rb""" ) as fp: snake_case_ :Optional[Any] = pickle.load(_lowercase ) snake_case_ :Tuple = np.maximum(_lowercase, 1 ) ** -args.mlm_smoothing for idx in special_tok_ids.values(): snake_case_ :Optional[int] = 0.0 # do not predict special tokens snake_case_ :int = torch.from_numpy(_lowercase ) else: snake_case_ :List[str] = None snake_case_ :Optional[int] = LmSeqsDataset(params=_lowercase, data=_lowercase ) logger.info("""Data loader created.""" ) # STUDENT # logger.info(f"""Loading student config from {args.student_config}""" ) snake_case_ :List[Any] = student_config_class.from_pretrained(args.student_config ) snake_case_ :Union[str, Any] = True if args.student_pretrained_weights is not None: logger.info(f"""Loading pretrained weights from {args.student_pretrained_weights}""" ) snake_case_ :List[str] = student_model_class.from_pretrained(args.student_pretrained_weights, config=_lowercase ) else: snake_case_ :Optional[int] = student_model_class(_lowercase ) if args.n_gpu > 0: student.to(f"""cuda:{args.local_rank}""" ) logger.info("""Student loaded.""" ) # TEACHER # snake_case_ :Dict = teacher_model_class.from_pretrained(args.teacher_name, output_hidden_states=_lowercase ) if args.n_gpu > 0: teacher.to(f"""cuda:{args.local_rank}""" ) logger.info(f"""Teacher loaded from {args.teacher_name}.""" ) # FREEZING # if args.freeze_pos_embs: freeze_pos_embeddings(_lowercase, _lowercase ) if args.freeze_token_type_embds: freeze_token_type_embeddings(_lowercase, _lowercase ) # SANITY CHECKS # assert student.config.vocab_size == teacher.config.vocab_size assert student.config.hidden_size == teacher.config.hidden_size assert student.config.max_position_embeddings == teacher.config.max_position_embeddings if args.mlm: assert token_probs.size(0 ) == stu_architecture_config.vocab_size # DISTILLER # torch.cuda.empty_cache() snake_case_ :Optional[int] = Distiller( params=_lowercase, dataset=_lowercase, token_probs=_lowercase, student=_lowercase, teacher=_lowercase ) distiller.train() logger.info("""Let's go get some drinks.""" ) if __name__ == "__main__": main()
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"""simple docstring""" def A_ ( _lowercase = 1000 ): '''simple docstring''' snake_case_ :List[str] = 3 snake_case_ :List[Any] = 0 while a < n: if a % 3 == 0 or a % 5 == 0: result += a elif a % 15 == 0: result -= a a += 1 return result if __name__ == "__main__": print(F"""{solution() = }""")
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"""simple docstring""" import json import os import subprocess import unittest from ast import literal_eval import pytest from parameterized import parameterized, parameterized_class from . import is_sagemaker_available if is_sagemaker_available(): from sagemaker import Session, TrainingJobAnalytics from sagemaker.huggingface import HuggingFace @pytest.mark.skipif( literal_eval(os.getenv("""TEST_SAGEMAKER""" , """False""" ) ) is not True , reason="""Skipping test because should only be run when releasing minor transformers version""" , ) @pytest.mark.usefixtures("""sm_env""" ) @parameterized_class( [ { """framework""": """pytorch""", """script""": """run_glue_model_parallelism.py""", """model_name_or_path""": """roberta-large""", """instance_type""": """ml.p3dn.24xlarge""", """results""": {"""train_runtime""": 1_6_0_0, """eval_accuracy""": 0.3, """eval_loss""": 1.2}, }, { """framework""": """pytorch""", """script""": """run_glue.py""", """model_name_or_path""": """roberta-large""", """instance_type""": """ml.p3dn.24xlarge""", """results""": {"""train_runtime""": 1_6_0_0, """eval_accuracy""": 0.3, """eval_loss""": 1.2}, }, ] ) class lowerCamelCase ( unittest.TestCase ): '''simple docstring''' def lowerCAmelCase_ ( self: Any ) -> str: if self.framework == "pytorch": subprocess.run( f"""cp ./examples/pytorch/text-classification/run_glue.py {self.env.test_path}/run_glue.py""".split() , encoding="""utf-8""" , check=snake_case , ) assert hasattr(self , """env""" ) def lowerCAmelCase_ ( self: int , snake_case: Dict ) -> List[Any]: # configuration for running training on smdistributed Model Parallel snake_case_ :Tuple = { """enabled""": True, """processes_per_host""": 8, } snake_case_ :List[Any] = { """enabled""": True, """parameters""": { """microbatches""": 4, """placement_strategy""": """spread""", """pipeline""": """interleaved""", """optimize""": """speed""", """partitions""": 4, """ddp""": True, }, } snake_case_ :Tuple = {"""smdistributed""": {"""modelparallel""": smp_options}, """mpi""": mpi_options} snake_case_ :Any = """trainer""" if self.script == """run_glue.py""" else """smtrainer""" # creates estimator return HuggingFace( entry_point=self.script , source_dir=self.env.test_path , role=self.env.role , image_uri=self.env.image_uri , base_job_name=f"""{self.env.base_job_name}-{instance_count}-smp-{name_extension}""" , instance_count=snake_case , instance_type=self.instance_type , debugger_hook_config=snake_case , hyperparameters={ **self.env.hyperparameters, """model_name_or_path""": self.model_name_or_path, """max_steps""": 500, } , metric_definitions=self.env.metric_definitions , distribution=snake_case , py_version="""py36""" , ) def lowerCAmelCase_ ( self: Any , snake_case: Tuple ) -> List[str]: TrainingJobAnalytics(snake_case ).export_csv(f"""{self.env.test_path}/{job_name}_metrics.csv""" ) @parameterized.expand([(1,)] ) def lowerCAmelCase_ ( self: Dict , snake_case: Dict ) -> List[Any]: # create estimator snake_case_ :List[Any] = self.create_estimator(snake_case ) # run training estimator.fit() # result dataframe snake_case_ :Any = TrainingJobAnalytics(estimator.latest_training_job.name ).dataframe() # extract kpis snake_case_ :Tuple = list(result_metrics_df[result_metrics_df.metric_name == """eval_accuracy"""]["""value"""] ) snake_case_ :Dict = list(result_metrics_df[result_metrics_df.metric_name == """eval_loss"""]["""value"""] ) # get train time from SageMaker job, this includes starting, preprocessing, stopping snake_case_ :int = ( Session().describe_training_job(estimator.latest_training_job.name ).get("""TrainingTimeInSeconds""" , 999_999 ) ) # assert kpis assert train_runtime <= self.results["train_runtime"] assert all(t >= self.results["""eval_accuracy"""] for t in eval_accuracy ) assert all(t <= self.results["""eval_loss"""] for t in eval_loss ) # dump tests result into json file to share in PR with open(f"""{estimator.latest_training_job.name}.json""" , """w""" ) as outfile: json.dump({"""train_time""": train_runtime, """eval_accuracy""": eval_accuracy, """eval_loss""": eval_loss} , snake_case )
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"""simple docstring""" class lowerCamelCase : '''simple docstring''' def __init__( self: Union[str, Any] ) -> None: snake_case_ :dict[str, TrieNode] = {} # Mapping from char to TrieNode snake_case_ :Optional[int] = False def lowerCAmelCase_ ( self: Optional[Any] , snake_case: list[str] ) -> None: for word in words: self.insert(snake_case ) def lowerCAmelCase_ ( self: List[str] , snake_case: str ) -> None: snake_case_ :Optional[Any] = self for char in word: if char not in curr.nodes: snake_case_ :Any = TrieNode() snake_case_ :Union[str, Any] = curr.nodes[char] snake_case_ :str = True def lowerCAmelCase_ ( self: Dict , snake_case: str ) -> bool: snake_case_ :Any = self for char in word: if char not in curr.nodes: return False snake_case_ :Union[str, Any] = curr.nodes[char] return curr.is_leaf def lowerCAmelCase_ ( self: str , snake_case: str ) -> None: def _delete(snake_case: TrieNode , snake_case: str , snake_case: int ) -> bool: if index == len(snake_case ): # If word does not exist if not curr.is_leaf: return False snake_case_ :Any = False return len(curr.nodes ) == 0 snake_case_ :Optional[int] = word[index] snake_case_ :Tuple = curr.nodes.get(snake_case ) # If char not in current trie node if not char_node: return False # Flag to check if node can be deleted snake_case_ :Dict = _delete(snake_case , snake_case , index + 1 ) if delete_curr: del curr.nodes[char] return len(curr.nodes ) == 0 return delete_curr _delete(self , snake_case , 0 ) def A_ ( _lowercase, _lowercase ): '''simple docstring''' if node.is_leaf: print(_lowercase, end=""" """ ) for key, value in node.nodes.items(): print_words(_lowercase, word + key ) def A_ ( ): '''simple docstring''' snake_case_ :Tuple = """banana bananas bandana band apple all beast""".split() snake_case_ :Dict = TrieNode() root.insert_many(_lowercase ) # print_words(root, "") assert all(root.find(_lowercase ) for word in words ) assert root.find("""banana""" ) assert not root.find("""bandanas""" ) assert not root.find("""apps""" ) assert root.find("""apple""" ) assert root.find("""all""" ) root.delete("""all""" ) assert not root.find("""all""" ) root.delete("""banana""" ) assert not root.find("""banana""" ) assert root.find("""bananas""" ) return True def A_ ( _lowercase, _lowercase ): '''simple docstring''' print(str(_lowercase ), """works!""" if passes else """doesn't work :(""" ) def A_ ( ): '''simple docstring''' assert test_trie() def A_ ( ): '''simple docstring''' print_results("""Testing trie functionality""", test_trie() ) if __name__ == "__main__": main()
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"""simple docstring""" import collections import inspect import unittest from typing import Dict, List, Tuple from transformers import MaskFormerSwinConfig from transformers.testing_utils import require_torch, require_torch_multi_gpu, torch_device from transformers.utils import is_torch_available from ...test_backbone_common import BackboneTesterMixin from ...test_configuration_common import ConfigTester from ...test_modeling_common import ModelTesterMixin, floats_tensor, ids_tensor from ...test_pipeline_mixin import PipelineTesterMixin if is_torch_available(): import torch from torch import nn from transformers import MaskFormerSwinBackbone from transformers.models.maskformer import MaskFormerSwinModel class lowerCamelCase : '''simple docstring''' def __init__( self: Dict , snake_case: Optional[Any] , snake_case: Tuple=13 , snake_case: Any=32 , snake_case: Union[str, Any]=2 , snake_case: Tuple=3 , snake_case: Union[str, Any]=16 , snake_case: Union[str, Any]=[1, 2, 1] , snake_case: Optional[Any]=[2, 2, 4] , snake_case: str=2 , snake_case: List[str]=2.0 , snake_case: Optional[int]=True , snake_case: Union[str, Any]=0.0 , snake_case: Optional[int]=0.0 , snake_case: Optional[Any]=0.1 , snake_case: List[str]="gelu" , snake_case: Any=False , snake_case: Optional[Any]=True , snake_case: Optional[int]=0.0_2 , snake_case: Any=1E-5 , snake_case: Optional[int]=True , snake_case: int=None , snake_case: Any=True , snake_case: str=10 , snake_case: Optional[Any]=8 , snake_case: Union[str, Any]=["stage1", "stage2", "stage3"] , snake_case: Tuple=[1, 2, 3] , ) -> Dict: snake_case_ :Dict = parent snake_case_ :List[Any] = batch_size snake_case_ :Dict = image_size snake_case_ :Dict = patch_size snake_case_ :Tuple = num_channels snake_case_ :List[Any] = embed_dim snake_case_ :List[str] = depths snake_case_ :str = num_heads snake_case_ :Tuple = window_size snake_case_ :Tuple = mlp_ratio snake_case_ :int = qkv_bias snake_case_ :Tuple = hidden_dropout_prob snake_case_ :Optional[Any] = attention_probs_dropout_prob snake_case_ :Dict = drop_path_rate snake_case_ :Any = hidden_act snake_case_ :Any = use_absolute_embeddings snake_case_ :int = patch_norm snake_case_ :List[Any] = layer_norm_eps snake_case_ :Tuple = initializer_range snake_case_ :str = is_training snake_case_ :int = scope snake_case_ :Tuple = use_labels snake_case_ :Tuple = type_sequence_label_size snake_case_ :str = encoder_stride snake_case_ :List[Any] = out_features snake_case_ :str = out_indices def lowerCAmelCase_ ( self: Tuple ) -> Dict: snake_case_ :Optional[int] = floats_tensor([self.batch_size, self.num_channels, self.image_size, self.image_size] ) snake_case_ :str = None if self.use_labels: snake_case_ :Optional[int] = ids_tensor([self.batch_size] , self.type_sequence_label_size ) snake_case_ :Union[str, Any] = self.get_config() return config, pixel_values, labels def lowerCAmelCase_ ( self: int ) -> Optional[Any]: return MaskFormerSwinConfig( 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 , out_features=self.out_features , out_indices=self.out_indices , ) def lowerCAmelCase_ ( self: List[Any] , snake_case: str , snake_case: int , snake_case: List[str] ) -> Any: snake_case_ :Dict = MaskFormerSwinModel(config=snake_case ) model.to(snake_case ) model.eval() snake_case_ :Tuple = model(snake_case ) snake_case_ :Dict = ((config.image_size // config.patch_size) ** 2) // (4 ** (len(config.depths ) - 1)) snake_case_ :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 lowerCAmelCase_ ( self: Optional[Any] , snake_case: int , snake_case: List[str] , snake_case: Tuple ) -> Union[str, Any]: snake_case_ :Any = MaskFormerSwinBackbone(config=snake_case ) model.to(snake_case ) model.eval() snake_case_ :Optional[Any] = model(snake_case ) # verify feature maps self.parent.assertEqual(len(result.feature_maps ) , len(config.out_features ) ) self.parent.assertListEqual(list(result.feature_maps[0].shape ) , [13, 16, 16, 16] ) # verify channels self.parent.assertEqual(len(model.channels ) , len(config.out_features ) ) self.parent.assertListEqual(model.channels , [16, 32, 64] ) # verify ValueError with self.parent.assertRaises(snake_case ): snake_case_ :Optional[Any] = ["""stem"""] snake_case_ :str = MaskFormerSwinBackbone(config=snake_case ) def lowerCAmelCase_ ( self: List[str] ) -> Optional[Any]: snake_case_ :Optional[int] = self.prepare_config_and_inputs() snake_case_, snake_case_, snake_case_ :str = config_and_inputs snake_case_ :Tuple = {"""pixel_values""": pixel_values} return config, inputs_dict @require_torch class lowerCamelCase ( _lowerCAmelCase , _lowerCAmelCase , unittest.TestCase ): '''simple docstring''' _A : Union[str, Any] = ( ( MaskFormerSwinModel, MaskFormerSwinBackbone, ) if is_torch_available() else () ) _A : str = {"""feature-extraction""": MaskFormerSwinModel} if is_torch_available() else {} _A : List[str] = False _A : Any = False _A : Dict = False _A : List[Any] = False _A : Optional[int] = False def lowerCAmelCase_ ( self: Dict ) -> Any: snake_case_ :str = MaskFormerSwinModelTester(self ) snake_case_ :Optional[Any] = ConfigTester(self , config_class=snake_case , embed_dim=37 ) @require_torch_multi_gpu @unittest.skip( reason=( """`MaskFormerSwinModel` outputs `hidden_states_spatial_dimensions` which doesn't work well with""" """ `nn.DataParallel`""" ) ) def lowerCAmelCase_ ( self: List[str] ) -> Optional[int]: pass def lowerCAmelCase_ ( self: Union[str, Any] ) -> Dict: self.create_and_test_config_common_properties() 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 lowerCAmelCase_ ( self: Any ) -> Tuple: return def lowerCAmelCase_ ( self: Any ) -> Any: snake_case_ :List[Any] = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_model(*snake_case ) def lowerCAmelCase_ ( self: Union[str, Any] ) -> int: snake_case_ :Any = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_backbone(*snake_case ) @unittest.skip("""Swin does not use inputs_embeds""" ) def lowerCAmelCase_ ( self: str ) -> List[str]: pass @unittest.skip("""Swin does not support feedforward chunking""" ) def lowerCAmelCase_ ( self: int ) -> Optional[int]: pass def lowerCAmelCase_ ( self: List[str] ) -> List[Any]: snake_case_, snake_case_ :List[Any] = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: snake_case_ :str = model_class(snake_case ) self.assertIsInstance(model.get_input_embeddings() , (nn.Module) ) snake_case_ :Dict = model.get_output_embeddings() self.assertTrue(x is None or isinstance(snake_case , nn.Linear ) ) def lowerCAmelCase_ ( self: Tuple ) -> Dict: snake_case_, snake_case_ :int = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: snake_case_ :Optional[int] = model_class(snake_case ) snake_case_ :str = inspect.signature(model.forward ) # signature.parameters is an OrderedDict => so arg_names order is deterministic snake_case_ :str = [*signature.parameters.keys()] snake_case_ :str = ["""pixel_values"""] self.assertListEqual(arg_names[:1] , snake_case ) @unittest.skip(reason="""MaskFormerSwin is only used as backbone and doesn't support output_attentions""" ) def lowerCAmelCase_ ( self: List[Any] ) -> List[Any]: pass @unittest.skip(reason="""MaskFormerSwin is only used as an internal backbone""" ) def lowerCAmelCase_ ( self: Dict ) -> List[Any]: pass def lowerCAmelCase_ ( self: Union[str, Any] , snake_case: Union[str, Any] , snake_case: int , snake_case: Any , snake_case: List[str] ) -> str: snake_case_ :List[str] = 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_ :Any = outputs.hidden_states snake_case_ :Optional[int] = getattr( self.model_tester , """expected_num_hidden_layers""" , len(self.model_tester.depths ) + 1 ) self.assertEqual(len(snake_case ) , snake_case ) # Swin has a different seq_length snake_case_ :str = ( config.patch_size if isinstance(config.patch_size , collections.abc.Iterable ) else (config.patch_size, config.patch_size) ) snake_case_ :int = (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] , ) def lowerCAmelCase_ ( self: List[Any] ) -> Optional[int]: 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_ :Tuple = 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_ :List[Any] = True self.check_hidden_states_output(snake_case , snake_case , snake_case , snake_case ) def lowerCAmelCase_ ( self: Optional[Any] ) -> Tuple: snake_case_, snake_case_ :int = self.model_tester.prepare_config_and_inputs_for_common() snake_case_ :List[Any] = 3 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) ) snake_case_ :Any = ( 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_ :List[str] = image_size[1] + patch_size[1] - (image_size[1] % patch_size[1]) for model_class in self.all_model_classes: snake_case_ :str = 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_ :Any = True self.check_hidden_states_output(snake_case , snake_case , snake_case , (padded_height, padded_width) ) @unittest.skip(reason="""MaskFormerSwin doesn't have pretrained checkpoints""" ) def lowerCAmelCase_ ( self: Union[str, Any] ) -> List[str]: pass @unittest.skip(reason="""This will be fixed once MaskFormerSwin is replaced by native Swin""" ) def lowerCAmelCase_ ( self: List[str] ) -> str: pass @unittest.skip(reason="""This will be fixed once MaskFormerSwin is replaced by native Swin""" ) def lowerCAmelCase_ ( self: str ) -> List[Any]: pass def lowerCAmelCase_ ( self: Union[str, Any] ) -> Optional[Any]: snake_case_, snake_case_ :Dict = self.model_tester.prepare_config_and_inputs_for_common() def set_nan_tensor_to_zero(snake_case: str ): snake_case_ :Optional[int] = 0 return t def check_equivalence(snake_case: List[Any] , snake_case: Union[str, Any] , snake_case: int , snake_case: Tuple={} ): with torch.no_grad(): snake_case_ :List[Any] = model(**snake_case , return_dict=snake_case , **snake_case ) snake_case_ :Any = model(**snake_case , return_dict=snake_case , **snake_case ).to_tuple() def recursive_check(snake_case: List[Any] , snake_case: int ): if isinstance(snake_case , (List, Tuple) ): for tuple_iterable_value, dict_iterable_value in zip(snake_case , snake_case ): recursive_check(snake_case , snake_case ) elif isinstance(snake_case , snake_case ): for tuple_iterable_value, dict_iterable_value in zip( tuple_object.values() , dict_object.values() ): recursive_check(snake_case , snake_case ) elif tuple_object is None: return else: self.assertTrue( torch.allclose( set_nan_tensor_to_zero(snake_case ) , set_nan_tensor_to_zero(snake_case ) , atol=1E-5 ) , msg=( """Tuple and dict output are not equal. Difference:""" f""" {torch.max(torch.abs(tuple_object - dict_object ) )}. Tuple has `nan`:""" f""" {torch.isnan(snake_case ).any()} and `inf`: {torch.isinf(snake_case )}. Dict has""" f""" `nan`: {torch.isnan(snake_case ).any()} and `inf`: {torch.isinf(snake_case )}.""" ) , ) recursive_check(snake_case , snake_case ) for model_class in self.all_model_classes: snake_case_ :int = model_class(snake_case ) model.to(snake_case ) model.eval() snake_case_ :Any = self._prepare_for_class(snake_case , snake_case ) snake_case_ :List[Any] = self._prepare_for_class(snake_case , snake_case ) check_equivalence(snake_case , snake_case , snake_case ) snake_case_ :Tuple = self._prepare_for_class(snake_case , snake_case , return_labels=snake_case ) snake_case_ :Dict = self._prepare_for_class(snake_case , snake_case , return_labels=snake_case ) check_equivalence(snake_case , snake_case , snake_case ) snake_case_ :Tuple = self._prepare_for_class(snake_case , snake_case ) snake_case_ :Any = self._prepare_for_class(snake_case , snake_case ) check_equivalence(snake_case , snake_case , snake_case , {"""output_hidden_states""": True} ) snake_case_ :Dict = self._prepare_for_class(snake_case , snake_case , return_labels=snake_case ) snake_case_ :List[str] = self._prepare_for_class(snake_case , snake_case , return_labels=snake_case ) check_equivalence(snake_case , snake_case , snake_case , {"""output_hidden_states""": True} ) @require_torch class lowerCamelCase ( unittest.TestCase , _lowerCAmelCase ): '''simple docstring''' _A : int = (MaskFormerSwinBackbone,) if is_torch_available() else () _A : Tuple = MaskFormerSwinConfig def lowerCAmelCase_ ( self: List[str] ) -> Optional[int]: snake_case_ :Optional[Any] = MaskFormerSwinModelTester(self ) def lowerCAmelCase_ ( self: int ) -> Optional[int]: snake_case_, snake_case_ :Any = self.model_tester.prepare_config_and_inputs_for_common() snake_case_ :Tuple = inputs_dict["""pixel_values"""].shape[0] for backbone_class in self.all_model_classes: snake_case_ :List[str] = backbone_class(snake_case ) backbone.to(snake_case ) backbone.eval() snake_case_ :List[Any] = backbone(**snake_case ) # Test default outputs and verify feature maps self.assertIsInstance(outputs.feature_maps , snake_case ) self.assertTrue(len(outputs.feature_maps ) == len(backbone.channels ) ) for feature_map, n_channels in zip(outputs.feature_maps , backbone.channels ): self.assertTrue(feature_map.shape[:2] , (batch_size, n_channels) ) self.assertIsNone(outputs.hidden_states ) self.assertIsNone(outputs.attentions ) # Test output_hidden_states=True snake_case_ :Union[str, Any] = backbone(**snake_case , output_hidden_states=snake_case ) self.assertIsNotNone(outputs.hidden_states ) self.assertTrue(len(outputs.hidden_states ) , len(backbone.stage_names ) ) # We skip the stem layer for hidden_states, n_channels in zip(outputs.hidden_states[1:] , backbone.channels ): for hidden_state in hidden_states: # Hidden states are in the format (batch_size, (height * width), n_channels) snake_case_, snake_case_, snake_case_ :List[Any] = hidden_state.shape self.assertTrue((h_batch_size, h_n_channels) , (batch_size, n_channels) ) # Test output_attentions=True if self.has_attentions: snake_case_ :List[Any] = backbone(**snake_case , output_attentions=snake_case ) self.assertIsNotNone(outputs.attentions )
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"""simple docstring""" import math class lowerCamelCase : '''simple docstring''' def __init__( self: List[Any] , snake_case: int=0 ) -> int: # a graph with Node 0,1,...,N-1 snake_case_ :List[str] = n snake_case_ :int = [ [math.inf for j in range(0 , snake_case )] for i in range(0 , snake_case ) ] # adjacency matrix for weight snake_case_ :str = [ [math.inf for j in range(0 , snake_case )] for i in range(0 , snake_case ) ] # dp[i][j] stores minimum distance from i to j def lowerCAmelCase_ ( self: Optional[int] , snake_case: str , snake_case: Optional[Any] , snake_case: str ) -> Tuple: snake_case_ :List[Any] = w def lowerCAmelCase_ ( self: List[str] ) -> str: for k in range(0 , self.n ): for i in range(0 , self.n ): for j in range(0 , self.n ): snake_case_ :Any = min(self.dp[i][j] , self.dp[i][k] + self.dp[k][j] ) def lowerCAmelCase_ ( self: int , snake_case: List[Any] , snake_case: Optional[Any] ) -> Union[str, Any]: return self.dp[u][v] if __name__ == "__main__": __a = Graph(5) graph.add_edge(0, 2, 9) graph.add_edge(0, 4, 10) graph.add_edge(1, 3, 5) graph.add_edge(2, 3, 7) graph.add_edge(3, 0, 10) graph.add_edge(3, 1, 2) graph.add_edge(3, 2, 1) graph.add_edge(3, 4, 6) graph.add_edge(4, 1, 3) graph.add_edge(4, 2, 4) graph.add_edge(4, 3, 9) graph.floyd_warshall() graph.show_min(1, 4) graph.show_min(0, 3)
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"""simple docstring""" import gc import math import unittest import torch from diffusers import UNetaDModel from diffusers.utils import floats_tensor, logging, slow, torch_all_close, torch_device from diffusers.utils.testing_utils import enable_full_determinism from .test_modeling_common import ModelTesterMixin, UNetTesterMixin __a = logging.get_logger(__name__) enable_full_determinism() class lowerCamelCase ( _lowerCAmelCase , _lowerCAmelCase , unittest.TestCase ): '''simple docstring''' _A : List[Any] = UNetaDModel _A : Union[str, Any] = """sample""" @property def lowerCAmelCase_ ( self: str ) -> Tuple: snake_case_ :List[str] = 4 snake_case_ :Tuple = 3 snake_case_ :Optional[Any] = (32, 32) snake_case_ :str = floats_tensor((batch_size, num_channels) + sizes ).to(snake_case ) snake_case_ :Union[str, Any] = torch.tensor([10] ).to(snake_case ) return {"sample": noise, "timestep": time_step} @property def lowerCAmelCase_ ( self: List[str] ) -> Dict: return (3, 32, 32) @property def lowerCAmelCase_ ( self: Optional[int] ) -> Optional[int]: return (3, 32, 32) def lowerCAmelCase_ ( self: Optional[int] ) -> Dict: snake_case_ :Any = { """block_out_channels""": (32, 64), """down_block_types""": ("""DownBlock2D""", """AttnDownBlock2D"""), """up_block_types""": ("""AttnUpBlock2D""", """UpBlock2D"""), """attention_head_dim""": 3, """out_channels""": 3, """in_channels""": 3, """layers_per_block""": 2, """sample_size""": 32, } snake_case_ :Tuple = self.dummy_input return init_dict, inputs_dict class lowerCamelCase ( _lowerCAmelCase , _lowerCAmelCase , unittest.TestCase ): '''simple docstring''' _A : List[str] = UNetaDModel _A : Union[str, Any] = """sample""" @property def lowerCAmelCase_ ( self: str ) -> str: snake_case_ :List[str] = 4 snake_case_ :Optional[int] = 4 snake_case_ :int = (32, 32) snake_case_ :Any = floats_tensor((batch_size, num_channels) + sizes ).to(snake_case ) snake_case_ :List[Any] = torch.tensor([10] ).to(snake_case ) return {"sample": noise, "timestep": time_step} @property def lowerCAmelCase_ ( self: Optional[int] ) -> Optional[int]: return (4, 32, 32) @property def lowerCAmelCase_ ( self: List[Any] ) -> int: return (4, 32, 32) def lowerCAmelCase_ ( self: Union[str, Any] ) -> List[Any]: snake_case_ :Dict = { """sample_size""": 32, """in_channels""": 4, """out_channels""": 4, """layers_per_block""": 2, """block_out_channels""": (32, 64), """attention_head_dim""": 32, """down_block_types""": ("""DownBlock2D""", """DownBlock2D"""), """up_block_types""": ("""UpBlock2D""", """UpBlock2D"""), } snake_case_ :List[str] = self.dummy_input return init_dict, inputs_dict def lowerCAmelCase_ ( self: Optional[int] ) -> Optional[Any]: snake_case_, snake_case_ :List[str] = UNetaDModel.from_pretrained("""fusing/unet-ldm-dummy-update""" , output_loading_info=snake_case ) self.assertIsNotNone(snake_case ) self.assertEqual(len(loading_info["""missing_keys"""] ) , 0 ) model.to(snake_case ) snake_case_ :List[str] = model(**self.dummy_input ).sample assert image is not None, "Make sure output is not None" @unittest.skipIf(torch_device != """cuda""" , """This test is supposed to run on GPU""" ) def lowerCAmelCase_ ( self: Tuple ) -> Dict: snake_case_, snake_case_ :Union[str, Any] = UNetaDModel.from_pretrained("""fusing/unet-ldm-dummy-update""" , output_loading_info=snake_case ) model.to(snake_case ) snake_case_ :Union[str, Any] = model(**self.dummy_input ).sample assert image is not None, "Make sure output is not None" @unittest.skipIf(torch_device != """cuda""" , """This test is supposed to run on GPU""" ) def lowerCAmelCase_ ( self: str ) -> Any: # by defautl model loading will use accelerate as `low_cpu_mem_usage=True` snake_case_, snake_case_ :List[str] = UNetaDModel.from_pretrained("""fusing/unet-ldm-dummy-update""" , output_loading_info=snake_case ) model_accelerate.to(snake_case ) model_accelerate.eval() snake_case_ :List[Any] = torch.randn( 1 , model_accelerate.config.in_channels , model_accelerate.config.sample_size , model_accelerate.config.sample_size , generator=torch.manual_seed(0 ) , ) snake_case_ :int = noise.to(snake_case ) snake_case_ :str = torch.tensor([10] * noise.shape[0] ).to(snake_case ) snake_case_ :Optional[int] = model_accelerate(snake_case , snake_case )["""sample"""] # two models don't need to stay in the device at the same time del model_accelerate torch.cuda.empty_cache() gc.collect() snake_case_, snake_case_ :str = UNetaDModel.from_pretrained( """fusing/unet-ldm-dummy-update""" , output_loading_info=snake_case , low_cpu_mem_usage=snake_case ) model_normal_load.to(snake_case ) model_normal_load.eval() snake_case_ :int = model_normal_load(snake_case , snake_case )["""sample"""] assert torch_all_close(snake_case , snake_case , rtol=1E-3 ) def lowerCAmelCase_ ( self: Tuple ) -> Any: snake_case_ :Tuple = UNetaDModel.from_pretrained("""fusing/unet-ldm-dummy-update""" ) model.eval() model.to(snake_case ) snake_case_ :Optional[int] = torch.randn( 1 , model.config.in_channels , model.config.sample_size , model.config.sample_size , generator=torch.manual_seed(0 ) , ) snake_case_ :int = noise.to(snake_case ) snake_case_ :List[Any] = torch.tensor([10] * noise.shape[0] ).to(snake_case ) with torch.no_grad(): snake_case_ :Union[str, Any] = model(snake_case , snake_case ).sample snake_case_ :Optional[int] = output[0, -1, -3:, -3:].flatten().cpu() # fmt: off snake_case_ :Dict = torch.tensor([-1_3.3_2_5_8, -2_0.1_1_0_0, -1_5.9_8_7_3, -1_7.6_6_1_7, -2_3.0_5_9_6, -1_7.9_4_1_9, -1_3.3_6_7_5, -1_6.1_8_8_9, -1_2.3_8_0_0] ) # fmt: on self.assertTrue(torch_all_close(snake_case , snake_case , rtol=1E-3 ) ) class lowerCamelCase ( _lowerCAmelCase , _lowerCAmelCase , unittest.TestCase ): '''simple docstring''' _A : List[Any] = UNetaDModel _A : List[Any] = """sample""" @property def lowerCAmelCase_ ( self: Union[str, Any] , snake_case: int=(32, 32) ) -> Tuple: snake_case_ :Union[str, Any] = 4 snake_case_ :Any = 3 snake_case_ :int = floats_tensor((batch_size, num_channels) + sizes ).to(snake_case ) snake_case_ :Any = torch.tensor(batch_size * [10] ).to(dtype=torch.intaa , device=snake_case ) return {"sample": noise, "timestep": time_step} @property def lowerCAmelCase_ ( self: Union[str, Any] ) -> Any: return (3, 32, 32) @property def lowerCAmelCase_ ( self: int ) -> Tuple: return (3, 32, 32) def lowerCAmelCase_ ( self: List[str] ) -> Tuple: snake_case_ :List[Any] = { """block_out_channels""": [32, 64, 64, 64], """in_channels""": 3, """layers_per_block""": 1, """out_channels""": 3, """time_embedding_type""": """fourier""", """norm_eps""": 1E-6, """mid_block_scale_factor""": math.sqrt(2.0 ), """norm_num_groups""": None, """down_block_types""": [ """SkipDownBlock2D""", """AttnSkipDownBlock2D""", """SkipDownBlock2D""", """SkipDownBlock2D""", ], """up_block_types""": [ """SkipUpBlock2D""", """SkipUpBlock2D""", """AttnSkipUpBlock2D""", """SkipUpBlock2D""", ], } snake_case_ :int = self.dummy_input return init_dict, inputs_dict @slow def lowerCAmelCase_ ( self: Optional[Any] ) -> List[Any]: snake_case_, snake_case_ :List[Any] = UNetaDModel.from_pretrained("""google/ncsnpp-celebahq-256""" , output_loading_info=snake_case ) self.assertIsNotNone(snake_case ) self.assertEqual(len(loading_info["""missing_keys"""] ) , 0 ) model.to(snake_case ) snake_case_ :Any = self.dummy_input snake_case_ :int = floats_tensor((4, 3) + (256, 256) ).to(snake_case ) snake_case_ :int = noise snake_case_ :int = model(**snake_case ) assert image is not None, "Make sure output is not None" @slow def lowerCAmelCase_ ( self: str ) -> Dict: snake_case_ :Dict = UNetaDModel.from_pretrained("""google/ncsnpp-celebahq-256""" ) model.to(snake_case ) snake_case_ :List[str] = 4 snake_case_ :Optional[int] = 3 snake_case_ :List[str] = (256, 256) snake_case_ :Tuple = torch.ones((batch_size, num_channels) + sizes ).to(snake_case ) snake_case_ :str = torch.tensor(batch_size * [1E-4] ).to(snake_case ) with torch.no_grad(): snake_case_ :Dict = model(snake_case , snake_case ).sample snake_case_ :int = output[0, -3:, -3:, -1].flatten().cpu() # fmt: off snake_case_ :Optional[Any] = torch.tensor([-4_8_4_2.8_6_9_1, -6_4_9_9.6_6_3_1, -3_8_0_0.1_9_5_3, -7_9_7_8.2_6_8_6, -1_0_9_8_0.7_1_2_9, -2_0_0_2_8.8_5_3_5, 8_1_4_8.2_8_2_2, 2_3_4_2.2_9_0_5, 5_6_7.7_6_0_8] ) # fmt: on self.assertTrue(torch_all_close(snake_case , snake_case , rtol=1E-2 ) ) def lowerCAmelCase_ ( self: List[str] ) -> List[Any]: snake_case_ :Optional[Any] = UNetaDModel.from_pretrained("""fusing/ncsnpp-ffhq-ve-dummy-update""" ) model.to(snake_case ) snake_case_ :Optional[int] = 4 snake_case_ :Optional[Any] = 3 snake_case_ :Optional[Any] = (32, 32) snake_case_ :Dict = torch.ones((batch_size, num_channels) + sizes ).to(snake_case ) snake_case_ :Any = torch.tensor(batch_size * [1E-4] ).to(snake_case ) with torch.no_grad(): snake_case_ :str = model(snake_case , snake_case ).sample snake_case_ :int = output[0, -3:, -3:, -1].flatten().cpu() # fmt: off snake_case_ :int = torch.tensor([-0.0_3_2_5, -0.0_9_0_0, -0.0_8_6_9, -0.0_3_3_2, -0.0_7_2_5, -0.0_2_7_0, -0.0_1_0_1, 0.0_2_2_7, 0.0_2_5_6] ) # fmt: on self.assertTrue(torch_all_close(snake_case , snake_case , rtol=1E-2 ) ) def lowerCAmelCase_ ( self: Dict ) -> Optional[Any]: # not required for this model pass
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"""simple docstring""" import tempfile import unittest from transformers import AutoModelForSeqaSeqLM, AutoTokenizer from transformers.testing_utils import ( is_torch_available, require_optimum, require_torch, slow, ) if is_torch_available(): import torch @require_torch @require_optimum @slow class lowerCamelCase ( unittest.TestCase ): '''simple docstring''' def lowerCAmelCase_ ( self: Tuple ) -> Dict: snake_case_ :str = """hf-internal-testing/tiny-random-t5""" snake_case_ :str = AutoTokenizer.from_pretrained(snake_case ) snake_case_ :Tuple = AutoModelForSeqaSeqLM.from_pretrained(snake_case ) snake_case_ :Optional[int] = tokenizer("""This is me""" , return_tensors="""pt""" ) snake_case_ :int = model.to_bettertransformer() self.assertTrue(any("""BetterTransformer""" in mod.__class__.__name__ for _, mod in model.named_modules() ) ) snake_case_ :Optional[int] = model.generate(**snake_case ) snake_case_ :List[str] = model.reverse_bettertransformer() self.assertFalse(any("""BetterTransformer""" in mod.__class__.__name__ for _, mod in model.named_modules() ) ) with tempfile.TemporaryDirectory() as tmpdirname: model.save_pretrained(snake_case ) snake_case_ :Union[str, Any] = AutoModelForSeqaSeqLM.from_pretrained(snake_case ) self.assertFalse( any("""BetterTransformer""" in mod.__class__.__name__ for _, mod in model_reloaded.named_modules() ) ) snake_case_ :int = model_reloaded.generate(**snake_case ) self.assertTrue(torch.allclose(snake_case , snake_case ) ) def lowerCAmelCase_ ( self: List[str] ) -> Union[str, Any]: snake_case_ :List[Any] = """hf-internal-testing/tiny-random-t5""" snake_case_ :Optional[int] = AutoModelForSeqaSeqLM.from_pretrained(snake_case ) snake_case_ :Dict = model.to_bettertransformer() with tempfile.TemporaryDirectory() as tmpdirname: with self.assertRaises(snake_case ): model.save_pretrained(snake_case ) snake_case_ :Union[str, Any] = model.reverse_bettertransformer() model.save_pretrained(snake_case )
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"""simple docstring""" from typing import TYPE_CHECKING from ...utils import OptionalDependencyNotAvailable, _LazyModule, is_torch_available, is_vision_available __a = { "configuration_mask2former": [ "MASK2FORMER_PRETRAINED_CONFIG_ARCHIVE_MAP", "Mask2FormerConfig", ], } try: if not is_vision_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __a = ["Mask2FormerImageProcessor"] try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __a = [ "MASK2FORMER_PRETRAINED_MODEL_ARCHIVE_LIST", "Mask2FormerForUniversalSegmentation", "Mask2FormerModel", "Mask2FormerPreTrainedModel", ] if TYPE_CHECKING: from .configuration_maskaformer import MASK2FORMER_PRETRAINED_CONFIG_ARCHIVE_MAP, MaskaFormerConfig try: if not is_vision_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .image_processing_maskaformer import MaskaFormerImageProcessor try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_maskaformer import ( MASK2FORMER_PRETRAINED_MODEL_ARCHIVE_LIST, MaskaFormerForUniversalSegmentation, MaskaFormerModel, MaskaFormerPreTrainedModel, ) else: import sys __a = _LazyModule(__name__, globals()["__file__"], _import_structure)
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"""simple docstring""" import argparse import os import re import packaging.version __a = "examples/" __a = { "examples": (re.compile(r"^check_min_version\(\"[^\"]+\"\)\s*$", re.MULTILINE), "check_min_version(\"VERSION\")\n"), "init": (re.compile(r"^__version__\s+=\s+\"([^\"]+)\"\s*$", re.MULTILINE), "__version__ = \"VERSION\"\n"), "setup": (re.compile(r"^(\s*)version\s*=\s*\"[^\"]+\",", re.MULTILINE), r"\1version=\"VERSION\","), "doc": (re.compile(r"^(\s*)release\s*=\s*\"[^\"]+\"$", re.MULTILINE), "release = \"VERSION\"\n"), } __a = { "init": "src/transformers/__init__.py", "setup": "setup.py", } __a = "README.md" def A_ ( _lowercase, _lowercase, _lowercase ): '''simple docstring''' with open(_lowercase, """r""", encoding="""utf-8""", newline="""\n""" ) as f: snake_case_ :Optional[Any] = f.read() snake_case_, snake_case_ :int = REPLACE_PATTERNS[pattern] snake_case_ :int = replace.replace("""VERSION""", _lowercase ) snake_case_ :List[Any] = re_pattern.sub(_lowercase, _lowercase ) with open(_lowercase, """w""", encoding="""utf-8""", newline="""\n""" ) as f: f.write(_lowercase ) def A_ ( _lowercase ): '''simple docstring''' for folder, directories, fnames in os.walk(_lowercase ): # Removing some of the folders with non-actively maintained examples from the walk if "research_projects" in directories: directories.remove("""research_projects""" ) if "legacy" in directories: directories.remove("""legacy""" ) for fname in fnames: if fname.endswith(""".py""" ): update_version_in_file(os.path.join(_lowercase, _lowercase ), _lowercase, pattern="""examples""" ) def A_ ( _lowercase, _lowercase=False ): '''simple docstring''' for pattern, fname in REPLACE_FILES.items(): update_version_in_file(_lowercase, _lowercase, _lowercase ) if not patch: update_version_in_examples(_lowercase ) def A_ ( ): '''simple docstring''' snake_case_ :Any = """🤗 Transformers currently provides the following architectures""" snake_case_ :str = """1. Want to contribute a new model?""" with open(_lowercase, """r""", encoding="""utf-8""", newline="""\n""" ) as f: snake_case_ :Union[str, Any] = f.readlines() # Find the start of the list. snake_case_ :Union[str, Any] = 0 while not lines[start_index].startswith(_start_prompt ): start_index += 1 start_index += 1 snake_case_ :Tuple = start_index # Update the lines in the model list. while not lines[index].startswith(_end_prompt ): if lines[index].startswith("""1.""" ): snake_case_ :List[str] = lines[index].replace( """https://huggingface.co/docs/transformers/main/model_doc""", """https://huggingface.co/docs/transformers/model_doc""", ) index += 1 with open(_lowercase, """w""", encoding="""utf-8""", newline="""\n""" ) as f: f.writelines(_lowercase ) def A_ ( ): '''simple docstring''' with open(REPLACE_FILES["""init"""], """r""" ) as f: snake_case_ :str = f.read() snake_case_ :str = REPLACE_PATTERNS["""init"""][0].search(_lowercase ).groups()[0] return packaging.version.parse(_lowercase ) def A_ ( _lowercase=False ): '''simple docstring''' snake_case_ :List[Any] = get_version() if patch and default_version.is_devrelease: raise ValueError("""Can't create a patch version from the dev branch, checkout a released version!""" ) if default_version.is_devrelease: snake_case_ :Optional[int] = default_version.base_version elif patch: snake_case_ :List[str] = f"""{default_version.major}.{default_version.minor}.{default_version.micro + 1}""" else: snake_case_ :Union[str, Any] = f"""{default_version.major}.{default_version.minor + 1}.0""" # Now let's ask nicely if that's the right one. snake_case_ :Dict = input(f"""Which version are you releasing? [{default_version}]""" ) if len(_lowercase ) == 0: snake_case_ :str = default_version print(f"""Updating version to {version}.""" ) global_version_update(_lowercase, patch=_lowercase ) if not patch: print("""Cleaning main README, don't forget to run `make fix-copies`.""" ) clean_main_ref_in_model_list() def A_ ( ): '''simple docstring''' snake_case_ :Optional[Any] = get_version() snake_case_ :str = f"""{current_version.major}.{current_version.minor + 1}.0.dev0""" snake_case_ :List[str] = current_version.base_version # Check with the user we got that right. snake_case_ :Union[str, Any] = input(f"""Which version are we developing now? [{dev_version}]""" ) if len(_lowercase ) == 0: snake_case_ :Union[str, Any] = dev_version print(f"""Updating version to {version}.""" ) global_version_update(_lowercase ) print("""Cleaning main README, don't forget to run `make fix-copies`.""" ) clean_main_ref_in_model_list() if __name__ == "__main__": __a = argparse.ArgumentParser() parser.add_argument("--post_release", action="store_true", help="Whether this is pre or post release.") parser.add_argument("--patch", action="store_true", help="Whether or not this is a patch release.") __a = parser.parse_args() if not args.post_release: pre_release_work(patch=args.patch) elif args.patch: print("Nothing to do after a patch :-)") else: post_release_work()
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"""simple docstring""" import gc import unittest import numpy as np import torch from transformers import CLIPTextConfig, CLIPTextModel, CLIPTokenizer from diffusers import ( AutoencoderKL, DDIMScheduler, StableDiffusionSAGPipeline, UNetaDConditionModel, ) from diffusers.utils import slow, torch_device from diffusers.utils.testing_utils import enable_full_determinism, require_torch_gpu 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() class lowerCamelCase ( _lowerCAmelCase , _lowerCAmelCase , unittest.TestCase ): '''simple docstring''' _A : str = StableDiffusionSAGPipeline _A : Optional[Any] = TEXT_TO_IMAGE_PARAMS _A : Any = TEXT_TO_IMAGE_BATCH_PARAMS _A : Tuple = TEXT_TO_IMAGE_IMAGE_PARAMS _A : Tuple = TEXT_TO_IMAGE_IMAGE_PARAMS _A : List[str] = False def lowerCAmelCase_ ( self: Optional[Any] ) -> str: torch.manual_seed(0 ) snake_case_ :Any = UNetaDConditionModel( block_out_channels=(32, 64) , layers_per_block=2 , sample_size=32 , in_channels=4 , out_channels=4 , down_block_types=("""DownBlock2D""", """CrossAttnDownBlock2D""") , up_block_types=("""CrossAttnUpBlock2D""", """UpBlock2D""") , cross_attention_dim=32 , ) snake_case_ :Any = DDIMScheduler( beta_start=0.0_0_0_8_5 , beta_end=0.0_1_2 , beta_schedule="""scaled_linear""" , clip_sample=snake_case , set_alpha_to_one=snake_case , ) torch.manual_seed(0 ) snake_case_ :Optional[int] = AutoencoderKL( block_out_channels=[32, 64] , in_channels=3 , out_channels=3 , down_block_types=["""DownEncoderBlock2D""", """DownEncoderBlock2D"""] , up_block_types=["""UpDecoderBlock2D""", """UpDecoderBlock2D"""] , latent_channels=4 , ) torch.manual_seed(0 ) snake_case_ :Union[str, Any] = CLIPTextConfig( bos_token_id=0 , eos_token_id=2 , hidden_size=32 , intermediate_size=37 , layer_norm_eps=1E-05 , num_attention_heads=4 , num_hidden_layers=5 , pad_token_id=1 , vocab_size=1_000 , ) snake_case_ :Tuple = CLIPTextModel(snake_case ) snake_case_ :str = CLIPTokenizer.from_pretrained("""hf-internal-testing/tiny-random-clip""" ) snake_case_ :Dict = { """unet""": unet, """scheduler""": scheduler, """vae""": vae, """text_encoder""": text_encoder, """tokenizer""": tokenizer, """safety_checker""": None, """feature_extractor""": None, } return components def lowerCAmelCase_ ( self: List[str] , snake_case: Tuple , snake_case: List[str]=0 ) -> str: if str(snake_case ).startswith("""mps""" ): snake_case_ :Tuple = torch.manual_seed(snake_case ) else: snake_case_ :Optional[int] = torch.Generator(device=snake_case ).manual_seed(snake_case ) snake_case_ :Any = { """prompt""": """.""", """generator""": generator, """num_inference_steps""": 2, """guidance_scale""": 1.0, """sag_scale""": 1.0, """output_type""": """numpy""", } return inputs def lowerCAmelCase_ ( self: Optional[int] ) -> str: super().test_inference_batch_single_identical(expected_max_diff=3E-3 ) @slow @require_torch_gpu class lowerCamelCase ( unittest.TestCase ): '''simple docstring''' def lowerCAmelCase_ ( self: int ) -> str: # clean up the VRAM after each test super().tearDown() gc.collect() torch.cuda.empty_cache() def lowerCAmelCase_ ( self: int ) -> List[str]: snake_case_ :Any = StableDiffusionSAGPipeline.from_pretrained("""CompVis/stable-diffusion-v1-4""" ) snake_case_ :int = sag_pipe.to(snake_case ) sag_pipe.set_progress_bar_config(disable=snake_case ) snake_case_ :Union[str, Any] = """.""" snake_case_ :str = torch.manual_seed(0 ) snake_case_ :str = sag_pipe( [prompt] , generator=snake_case , guidance_scale=7.5 , sag_scale=1.0 , num_inference_steps=20 , output_type="""np""" ) snake_case_ :List[Any] = output.images snake_case_ :Tuple = image[0, -3:, -3:, -1] assert image.shape == (1, 512, 512, 3) snake_case_ :List[Any] = np.array([0.1_5_6_8, 0.1_7_3_8, 0.1_6_9_5, 0.1_6_9_3, 0.1_5_0_7, 0.1_7_0_5, 0.1_5_4_7, 0.1_7_5_1, 0.1_9_4_9] ) assert np.abs(image_slice.flatten() - expected_slice ).max() < 5E-2 def lowerCAmelCase_ ( self: Dict ) -> str: snake_case_ :Tuple = StableDiffusionSAGPipeline.from_pretrained("""stabilityai/stable-diffusion-2-1-base""" ) snake_case_ :Optional[int] = sag_pipe.to(snake_case ) sag_pipe.set_progress_bar_config(disable=snake_case ) snake_case_ :Tuple = """.""" snake_case_ :Union[str, Any] = torch.manual_seed(0 ) snake_case_ :Tuple = sag_pipe( [prompt] , generator=snake_case , guidance_scale=7.5 , sag_scale=1.0 , num_inference_steps=20 , output_type="""np""" ) snake_case_ :Optional[int] = output.images snake_case_ :Optional[Any] = image[0, -3:, -3:, -1] assert image.shape == (1, 512, 512, 3) snake_case_ :Tuple = np.array([0.3_4_5_9, 0.2_8_7_6, 0.2_5_3_7, 0.3_0_0_2, 0.2_6_7_1, 0.2_1_6_0, 0.3_0_2_6, 0.2_2_6_2, 0.2_3_7_1] ) assert np.abs(image_slice.flatten() - expected_slice ).max() < 5E-2 def lowerCAmelCase_ ( self: List[str] ) -> List[str]: snake_case_ :Optional[int] = StableDiffusionSAGPipeline.from_pretrained("""stabilityai/stable-diffusion-2-1-base""" ) snake_case_ :int = sag_pipe.to(snake_case ) sag_pipe.set_progress_bar_config(disable=snake_case ) snake_case_ :Tuple = """.""" snake_case_ :Optional[int] = torch.manual_seed(0 ) snake_case_ :List[str] = sag_pipe( [prompt] , width=768 , height=512 , generator=snake_case , guidance_scale=7.5 , sag_scale=1.0 , num_inference_steps=20 , output_type="""np""" , ) snake_case_ :Optional[Any] = output.images assert image.shape == (1, 512, 768, 3)
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"""simple docstring""" import logging from dataclasses import dataclass, field from pathlib import Path from typing import Optional, Union from .generation.configuration_utils import GenerationConfig from .training_args import TrainingArguments from .utils import add_start_docstrings __a = logging.getLogger(__name__) @dataclass @add_start_docstrings(TrainingArguments.__doc__ ) class lowerCamelCase ( _lowerCAmelCase ): '''simple docstring''' _A : bool = field(default=_lowerCAmelCase , metadata={"""help""": """Whether to use SortishSampler or not."""} ) _A : bool = field( default=_lowerCAmelCase , metadata={"""help""": """Whether to use generate to calculate generative metrics (ROUGE, BLEU)."""} ) _A : Optional[int] = field( default=_lowerCAmelCase , metadata={ """help""": ( """The `max_length` to use on each evaluation loop when `predict_with_generate=True`. Will default """ """to the `max_length` value of the model configuration.""" ) } , ) _A : Optional[int] = field( default=_lowerCAmelCase , metadata={ """help""": ( """The `num_beams` to use on each evaluation loop when `predict_with_generate=True`. Will default """ """to the `num_beams` value of the model configuration.""" ) } , ) _A : Optional[Union[str, Path, GenerationConfig]] = field( default=_lowerCAmelCase , metadata={ """help""": """Model id, file path or url pointing to a GenerationConfig json file, to use during prediction.""" } , ) def lowerCAmelCase_ ( self: Dict ) -> str: snake_case_ :List[str] = super().to_dict() for k, v in d.items(): if isinstance(snake_case , snake_case ): snake_case_ :Dict = v.to_dict() return d
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"""simple docstring""" from __future__ import annotations from collections import Counter from random import random class lowerCamelCase : '''simple docstring''' def __init__( self: Tuple ) -> Optional[Any]: snake_case_ :Optional[int] = {} def lowerCAmelCase_ ( self: Dict , snake_case: str ) -> None: snake_case_ :str = {} def lowerCAmelCase_ ( self: Optional[int] , snake_case: str , snake_case: str , snake_case: float ) -> None: if nodea not in self.connections: self.add_node(snake_case ) if nodea not in self.connections: self.add_node(snake_case ) snake_case_ :Dict = probability def lowerCAmelCase_ ( self: List[Any] ) -> list[str]: return list(self.connections ) def lowerCAmelCase_ ( self: Any , snake_case: str ) -> str: snake_case_ :Optional[Any] = 0 snake_case_ :List[str] = random() for dest in self.connections[node]: current_probability += self.connections[node][dest] if current_probability > random_value: return dest return "" def A_ ( _lowercase, _lowercase, _lowercase ): '''simple docstring''' snake_case_ :List[str] = MarkovChainGraphUndirectedUnweighted() for nodea, nodea, probability in transitions: graph.add_transition_probability(_lowercase, _lowercase, _lowercase ) snake_case_ :int = Counter(graph.get_nodes() ) snake_case_ :Optional[Any] = start for _ in range(_lowercase ): snake_case_ :Tuple = graph.transition(_lowercase ) visited[node] += 1 return visited if __name__ == "__main__": import doctest doctest.testmod()
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"""simple docstring""" import argparse import numpy as np import torch from transformers import SpeechTaHifiGan, SpeechTaHifiGanConfig, logging logging.set_verbosity_info() __a = logging.get_logger("transformers.models.speecht5") def A_ ( _lowercase, _lowercase, _lowercase ): '''simple docstring''' hf_model.apply_weight_norm() snake_case_ :Optional[int] = checkpoint["""input_conv.weight_g"""] snake_case_ :Optional[int] = checkpoint["""input_conv.weight_v"""] snake_case_ :int = checkpoint["""input_conv.bias"""] for i in range(len(config.upsample_rates ) ): snake_case_ :int = checkpoint[f"""upsamples.{i}.1.weight_g"""] snake_case_ :int = checkpoint[f"""upsamples.{i}.1.weight_v"""] snake_case_ :str = checkpoint[f"""upsamples.{i}.1.bias"""] for i in range(len(config.upsample_rates ) * len(config.resblock_kernel_sizes ) ): for j in range(len(config.resblock_dilation_sizes ) ): snake_case_ :Optional[int] = checkpoint[f"""blocks.{i}.convs1.{j}.1.weight_g"""] snake_case_ :Union[str, Any] = checkpoint[f"""blocks.{i}.convs1.{j}.1.weight_v"""] snake_case_ :Optional[int] = checkpoint[f"""blocks.{i}.convs1.{j}.1.bias"""] snake_case_ :List[Any] = checkpoint[f"""blocks.{i}.convs2.{j}.1.weight_g"""] snake_case_ :List[Any] = checkpoint[f"""blocks.{i}.convs2.{j}.1.weight_v"""] snake_case_ :Tuple = checkpoint[f"""blocks.{i}.convs2.{j}.1.bias"""] snake_case_ :Tuple = checkpoint["""output_conv.1.weight_g"""] snake_case_ :Optional[Any] = checkpoint["""output_conv.1.weight_v"""] snake_case_ :int = checkpoint["""output_conv.1.bias"""] hf_model.remove_weight_norm() @torch.no_grad() def A_ ( _lowercase, _lowercase, _lowercase, _lowercase=None, _lowercase=None, ): '''simple docstring''' if config_path is not None: snake_case_ :Union[str, Any] = SpeechTaHifiGanConfig.from_pretrained(_lowercase ) else: snake_case_ :Tuple = SpeechTaHifiGanConfig() snake_case_ :Any = SpeechTaHifiGan(_lowercase ) snake_case_ :Any = torch.load(_lowercase ) load_weights(orig_checkpoint["""model"""]["""generator"""], _lowercase, _lowercase ) snake_case_ :Tuple = np.load(_lowercase ) snake_case_ :Optional[int] = stats[0].reshape(-1 ) snake_case_ :Optional[int] = stats[1].reshape(-1 ) snake_case_ :Any = torch.from_numpy(_lowercase ).float() snake_case_ :str = torch.from_numpy(_lowercase ).float() model.save_pretrained(_lowercase ) if repo_id: print("""Pushing to the hub...""" ) model.push_to_hub(_lowercase ) if __name__ == "__main__": __a = argparse.ArgumentParser() parser.add_argument("--checkpoint_path", required=True, default=None, type=str, help="Path to original checkpoint") parser.add_argument("--stats_path", required=True, default=None, type=str, help="Path to stats.npy file") parser.add_argument("--config_path", default=None, type=str, help="Path to hf config.json of model to convert") parser.add_argument( "--pytorch_dump_folder_path", required=True, default=None, type=str, help="Path to the output PyTorch model." ) parser.add_argument( "--push_to_hub", default=None, type=str, help="Where to upload the converted model on the 🤗 hub." ) __a = parser.parse_args() convert_hifigan_checkpoint( args.checkpoint_path, args.stats_path, args.pytorch_dump_folder_path, args.config_path, args.push_to_hub, )
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"""simple docstring""" import argparse import collections import os import re import tempfile import pandas as pd from datasets import Dataset from huggingface_hub import hf_hub_download, upload_folder from transformers.utils import direct_transformers_import # All paths are set with the intent you should run this script from the root of the repo with the command # python utils/update_metadata.py __a = "src/transformers" # This is to make sure the transformers module imported is the one in the repo. __a = direct_transformers_import(TRANSFORMERS_PATH) # Regexes that match TF/Flax/PT model names. __a = re.compile(r"TF(.*)(?:Model|Encoder|Decoder|ForConditionalGeneration)") __a = re.compile(r"Flax(.*)(?:Model|Encoder|Decoder|ForConditionalGeneration)") # Will match any TF or Flax model too so need to be in an else branch afterthe two previous regexes. __a = re.compile(r"(.*)(?:Model|Encoder|Decoder|ForConditionalGeneration)") # Fill this with tuples (pipeline_tag, model_mapping, auto_model) __a = [ ("pretraining", "MODEL_FOR_PRETRAINING_MAPPING_NAMES", "AutoModelForPreTraining"), ("feature-extraction", "MODEL_MAPPING_NAMES", "AutoModel"), ("audio-classification", "MODEL_FOR_AUDIO_CLASSIFICATION_MAPPING_NAMES", "AutoModelForAudioClassification"), ("text-generation", "MODEL_FOR_CAUSAL_LM_MAPPING_NAMES", "AutoModelForCausalLM"), ("automatic-speech-recognition", "MODEL_FOR_CTC_MAPPING_NAMES", "AutoModelForCTC"), ("image-classification", "MODEL_FOR_IMAGE_CLASSIFICATION_MAPPING_NAMES", "AutoModelForImageClassification"), ("image-segmentation", "MODEL_FOR_IMAGE_SEGMENTATION_MAPPING_NAMES", "AutoModelForImageSegmentation"), ("fill-mask", "MODEL_FOR_MASKED_LM_MAPPING_NAMES", "AutoModelForMaskedLM"), ("object-detection", "MODEL_FOR_OBJECT_DETECTION_MAPPING_NAMES", "AutoModelForObjectDetection"), ( "zero-shot-object-detection", "MODEL_FOR_ZERO_SHOT_OBJECT_DETECTION_MAPPING_NAMES", "AutoModelForZeroShotObjectDetection", ), ("question-answering", "MODEL_FOR_QUESTION_ANSWERING_MAPPING_NAMES", "AutoModelForQuestionAnswering"), ("text2text-generation", "MODEL_FOR_SEQ_TO_SEQ_CAUSAL_LM_MAPPING_NAMES", "AutoModelForSeq2SeqLM"), ("text-classification", "MODEL_FOR_SEQUENCE_CLASSIFICATION_MAPPING_NAMES", "AutoModelForSequenceClassification"), ("automatic-speech-recognition", "MODEL_FOR_SPEECH_SEQ_2_SEQ_MAPPING_NAMES", "AutoModelForSpeechSeq2Seq"), ( "table-question-answering", "MODEL_FOR_TABLE_QUESTION_ANSWERING_MAPPING_NAMES", "AutoModelForTableQuestionAnswering", ), ("token-classification", "MODEL_FOR_TOKEN_CLASSIFICATION_MAPPING_NAMES", "AutoModelForTokenClassification"), ("multiple-choice", "MODEL_FOR_MULTIPLE_CHOICE_MAPPING_NAMES", "AutoModelForMultipleChoice"), ( "next-sentence-prediction", "MODEL_FOR_NEXT_SENTENCE_PREDICTION_MAPPING_NAMES", "AutoModelForNextSentencePrediction", ), ( "audio-frame-classification", "MODEL_FOR_AUDIO_FRAME_CLASSIFICATION_MAPPING_NAMES", "AutoModelForAudioFrameClassification", ), ("audio-xvector", "MODEL_FOR_AUDIO_XVECTOR_MAPPING_NAMES", "AutoModelForAudioXVector"), ( "document-question-answering", "MODEL_FOR_DOCUMENT_QUESTION_ANSWERING_MAPPING_NAMES", "AutoModelForDocumentQuestionAnswering", ), ( "visual-question-answering", "MODEL_FOR_VISUAL_QUESTION_ANSWERING_MAPPING_NAMES", "AutoModelForVisualQuestionAnswering", ), ("image-to-text", "MODEL_FOR_FOR_VISION_2_SEQ_MAPPING_NAMES", "AutoModelForVision2Seq"), ( "zero-shot-image-classification", "MODEL_FOR_ZERO_SHOT_IMAGE_CLASSIFICATION_MAPPING_NAMES", "AutoModelForZeroShotImageClassification", ), ("depth-estimation", "MODEL_FOR_DEPTH_ESTIMATION_MAPPING_NAMES", "AutoModelForDepthEstimation"), ("video-classification", "MODEL_FOR_VIDEO_CLASSIFICATION_MAPPING_NAMES", "AutoModelForVideoClassification"), ("mask-generation", "MODEL_FOR_MASK_GENERATION_MAPPING_NAMES", "AutoModelForMaskGeneration"), ] def A_ ( _lowercase ): '''simple docstring''' snake_case_ :Any = re.finditer(""".+?(?:(?<=[a-z])(?=[A-Z])|(?<=[A-Z])(?=[A-Z][a-z])|$)""", _lowercase ) return [m.group(0 ) for m in matches] def A_ ( ): '''simple docstring''' snake_case_ :int = transformers_module.models.auto.configuration_auto.CONFIG_MAPPING_NAMES snake_case_ :Dict = { config.replace("""Config""", """""" ): model_type for model_type, config in config_maping_names.items() } # Dictionaries flagging if each model prefix has a backend in PT/TF/Flax. snake_case_ :Optional[Any] = collections.defaultdict(_lowercase ) snake_case_ :int = collections.defaultdict(_lowercase ) snake_case_ :List[str] = collections.defaultdict(_lowercase ) # Let's lookup through all transformers object (once) and find if models are supported by a given backend. for attr_name in dir(_lowercase ): snake_case_ :int = None if _re_tf_models.match(_lowercase ) is not None: snake_case_ :int = tf_models snake_case_ :List[str] = _re_tf_models.match(_lowercase ).groups()[0] elif _re_flax_models.match(_lowercase ) is not None: snake_case_ :List[Any] = flax_models snake_case_ :Any = _re_flax_models.match(_lowercase ).groups()[0] elif _re_pt_models.match(_lowercase ) is not None: snake_case_ :Optional[Any] = pt_models snake_case_ :int = _re_pt_models.match(_lowercase ).groups()[0] if lookup_dict is not None: while len(_lowercase ) > 0: if attr_name in model_prefix_to_model_type: snake_case_ :Optional[int] = True break # Try again after removing the last word in the name snake_case_ :Optional[Any] = """""".join(camel_case_split(_lowercase )[:-1] ) snake_case_ :Optional[int] = set(list(pt_models.keys() ) + list(tf_models.keys() ) + list(flax_models.keys() ) ) snake_case_ :Optional[Any] = list(_lowercase ) all_models.sort() snake_case_ :Optional[int] = {"""model_type""": all_models} snake_case_ :Optional[int] = [pt_models[t] for t in all_models] snake_case_ :Any = [tf_models[t] for t in all_models] snake_case_ :Dict = [flax_models[t] for t in all_models] # Now let's use the auto-mapping names to make sure snake_case_ :Dict = {} for t in all_models: if t in transformers_module.models.auto.processing_auto.PROCESSOR_MAPPING_NAMES: snake_case_ :Optional[Any] = """AutoProcessor""" elif t in transformers_module.models.auto.tokenization_auto.TOKENIZER_MAPPING_NAMES: snake_case_ :Tuple = """AutoTokenizer""" elif t in transformers_module.models.auto.feature_extraction_auto.FEATURE_EXTRACTOR_MAPPING_NAMES: snake_case_ :Tuple = """AutoFeatureExtractor""" else: # Default to AutoTokenizer if a model has nothing, for backward compatibility. snake_case_ :str = """AutoTokenizer""" snake_case_ :int = [processors[t] for t in all_models] return pd.DataFrame(_lowercase ) def A_ ( _lowercase ): '''simple docstring''' snake_case_ :List[Any] = [ transformers_module.models.auto.modeling_auto, transformers_module.models.auto.modeling_tf_auto, transformers_module.models.auto.modeling_flax_auto, ] for pipeline_tag, model_mapping, auto_class in PIPELINE_TAGS_AND_AUTO_MODELS: snake_case_ :Optional[int] = [model_mapping, f"""TF_{model_mapping}""", f"""FLAX_{model_mapping}"""] snake_case_ :List[str] = [auto_class, f"""TF_{auto_class}""", f"""Flax_{auto_class}"""] # Loop through all three frameworks for module, cls, mapping in zip(_lowercase, _lowercase, _lowercase ): # The type of pipeline may not exist in this framework if not hasattr(_lowercase, _lowercase ): continue # First extract all model_names snake_case_ :Tuple = [] for name in getattr(_lowercase, _lowercase ).values(): if isinstance(_lowercase, _lowercase ): model_names.append(_lowercase ) else: model_names.extend(list(_lowercase ) ) # Add pipeline tag and auto model class for those models table.update({model_name: (pipeline_tag, cls) for model_name in model_names} ) return table def A_ ( _lowercase, _lowercase ): '''simple docstring''' snake_case_ :List[Any] = get_frameworks_table() snake_case_ :str = Dataset.from_pandas(_lowercase ) snake_case_ :List[Any] = hf_hub_download( """huggingface/transformers-metadata""", """pipeline_tags.json""", repo_type="""dataset""", token=_lowercase ) snake_case_ :List[str] = Dataset.from_json(_lowercase ) snake_case_ :int = { tags_dataset[i]["""model_class"""]: (tags_dataset[i]["""pipeline_tag"""], tags_dataset[i]["""auto_class"""]) for i in range(len(_lowercase ) ) } snake_case_ :Optional[int] = update_pipeline_and_auto_class_table(_lowercase ) # Sort the model classes to avoid some nondeterministic updates to create false update commits. snake_case_ :Tuple = sorted(table.keys() ) snake_case_ :Tuple = pd.DataFrame( { """model_class""": model_classes, """pipeline_tag""": [table[m][0] for m in model_classes], """auto_class""": [table[m][1] for m in model_classes], } ) snake_case_ :Union[str, Any] = Dataset.from_pandas(_lowercase ) with tempfile.TemporaryDirectory() as tmp_dir: frameworks_dataset.to_json(os.path.join(_lowercase, """frameworks.json""" ) ) tags_dataset.to_json(os.path.join(_lowercase, """pipeline_tags.json""" ) ) if commit_sha is not None: snake_case_ :Union[str, Any] = ( f"""Update with commit {commit_sha}\n\nSee: """ f"""https://github.com/huggingface/transformers/commit/{commit_sha}""" ) else: snake_case_ :List[Any] = """Update""" upload_folder( repo_id="""huggingface/transformers-metadata""", folder_path=_lowercase, repo_type="""dataset""", token=_lowercase, commit_message=_lowercase, ) def A_ ( ): '''simple docstring''' snake_case_ :List[Any] = {tag: cls for tag, _, cls in PIPELINE_TAGS_AND_AUTO_MODELS} snake_case_ :Dict = transformers_module.pipelines.SUPPORTED_TASKS snake_case_ :List[str] = [] for key in pipeline_tasks: if key not in in_table: snake_case_ :int = pipeline_tasks[key]["""pt"""] if isinstance(_lowercase, (list, tuple) ): snake_case_ :Any = model[0] snake_case_ :str = model.__name__ if model not in in_table.values(): missing.append(_lowercase ) if len(_lowercase ) > 0: snake_case_ :Optional[int] = """, """.join(_lowercase ) raise ValueError( """The following pipeline tags are not present in the `PIPELINE_TAGS_AND_AUTO_MODELS` constant inside """ f"""`utils/update_metadata.py`: {msg}. Please add them!""" ) if __name__ == "__main__": __a = argparse.ArgumentParser() parser.add_argument("--token", type=str, help="The token to use to push to the transformers-metadata dataset.") parser.add_argument("--commit_sha", type=str, help="The sha of the commit going with this update.") parser.add_argument("--check-only", action="store_true", help="Activate to just check all pipelines are present.") __a = parser.parse_args() if args.check_only: check_pipeline_tags() else: update_metadata(args.token, args.commit_sha)
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"""simple docstring""" import qiskit def A_ ( _lowercase, _lowercase ): '''simple docstring''' snake_case_ :int = qiskit.Aer.get_backend("""aer_simulator""" ) snake_case_ :List[str] = qiskit.QuantumCircuit(4, 2 ) # encode inputs in qubits 0 and 1 if bita == 1: qc_ha.x(0 ) if bita == 1: qc_ha.x(1 ) qc_ha.barrier() # use cnots to write XOR of the inputs on qubit2 qc_ha.cx(0, 2 ) qc_ha.cx(1, 2 ) # use ccx / toffoli gate to write AND of the inputs on qubit3 qc_ha.ccx(0, 1, 3 ) qc_ha.barrier() # extract outputs qc_ha.measure(2, 0 ) # extract XOR value qc_ha.measure(3, 1 ) # extract AND value # Execute the circuit on the qasm simulator snake_case_ :Tuple = qiskit.execute(_lowercase, _lowercase, shots=1000 ) # Return the histogram data of the results of the experiment return job.result().get_counts(_lowercase ) if __name__ == "__main__": __a = half_adder(1, 1) print(F"""Half Adder Output Qubit Counts: {counts}""")
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"""simple docstring""" import argparse import glob import logging import os from argparse import Namespace from importlib import import_module import numpy as np import torch from lightning_base import BaseTransformer, add_generic_args, generic_train from seqeval.metrics import accuracy_score, fa_score, precision_score, recall_score from torch.nn import CrossEntropyLoss from torch.utils.data import DataLoader, TensorDataset from utils_ner import TokenClassificationTask __a = logging.getLogger(__name__) class lowerCamelCase ( _lowerCAmelCase ): '''simple docstring''' _A : Union[str, Any] = """token-classification""" def __init__( self: Any , snake_case: Tuple ) -> List[Any]: if type(snake_case ) == dict: snake_case_ :Optional[int] = Namespace(**snake_case ) snake_case_ :Optional[int] = import_module("""tasks""" ) try: snake_case_ :Any = getattr(snake_case , hparams.task_type ) snake_case_ :TokenClassificationTask = token_classification_task_clazz() except AttributeError: raise ValueError( f"""Task {hparams.task_type} needs to be defined as a TokenClassificationTask subclass in {module}. """ f"""Available tasks classes are: {TokenClassificationTask.__subclasses__()}""" ) snake_case_ :Any = self.token_classification_task.get_labels(hparams.labels ) snake_case_ :str = CrossEntropyLoss().ignore_index super().__init__(snake_case , len(self.labels ) , self.mode ) def lowerCAmelCase_ ( self: Dict , **snake_case: List[Any] ) -> Any: return self.model(**snake_case ) def lowerCAmelCase_ ( self: str , snake_case: Tuple , snake_case: List[Any] ) -> Optional[int]: snake_case_ :List[str] = {"""input_ids""": batch[0], """attention_mask""": batch[1], """labels""": batch[3]} if self.config.model_type != "distilbert": snake_case_ :List[str] = ( batch[2] if self.config.model_type in ["""bert""", """xlnet"""] else None ) # XLM and RoBERTa don"t use token_type_ids snake_case_ :Optional[Any] = self(**snake_case ) snake_case_ :List[str] = outputs[0] # tensorboard_logs = {"loss": loss, "rate": self.lr_scheduler.get_last_lr()[-1]} return {"loss": loss} def lowerCAmelCase_ ( self: int ) -> Dict: snake_case_ :List[Any] = self.hparams for mode in ["train", "dev", "test"]: snake_case_ :Optional[int] = self._feature_file(snake_case ) if os.path.exists(snake_case ) and not args.overwrite_cache: logger.info("""Loading features from cached file %s""" , snake_case ) snake_case_ :Optional[int] = torch.load(snake_case ) else: logger.info("""Creating features from dataset file at %s""" , args.data_dir ) snake_case_ :Optional[int] = self.token_classification_task.read_examples_from_file(args.data_dir , snake_case ) snake_case_ :Any = self.token_classification_task.convert_examples_to_features( snake_case , self.labels , args.max_seq_length , self.tokenizer , cls_token_at_end=bool(self.config.model_type in ["""xlnet"""] ) , cls_token=self.tokenizer.cls_token , cls_token_segment_id=2 if self.config.model_type in ["""xlnet"""] else 0 , sep_token=self.tokenizer.sep_token , sep_token_extra=snake_case , pad_on_left=bool(self.config.model_type in ["""xlnet"""] ) , pad_token=self.tokenizer.pad_token_id , pad_token_segment_id=self.tokenizer.pad_token_type_id , pad_token_label_id=self.pad_token_label_id , ) logger.info("""Saving features into cached file %s""" , snake_case ) torch.save(snake_case , snake_case ) def lowerCAmelCase_ ( self: Optional[int] , snake_case: int , snake_case: int , snake_case: bool = False ) -> DataLoader: snake_case_ :int = self._feature_file(snake_case ) logger.info("""Loading features from cached file %s""" , snake_case ) snake_case_ :str = torch.load(snake_case ) snake_case_ :Dict = torch.tensor([f.input_ids for f in features] , dtype=torch.long ) snake_case_ :str = torch.tensor([f.attention_mask for f in features] , dtype=torch.long ) if features[0].token_type_ids is not None: snake_case_ :List[Any] = torch.tensor([f.token_type_ids for f in features] , dtype=torch.long ) else: snake_case_ :List[str] = torch.tensor([0 for f in features] , dtype=torch.long ) # HACK(we will not use this anymore soon) snake_case_ :Any = torch.tensor([f.label_ids for f in features] , dtype=torch.long ) return DataLoader( TensorDataset(snake_case , snake_case , snake_case , snake_case ) , batch_size=snake_case ) def lowerCAmelCase_ ( self: List[str] , snake_case: Dict , snake_case: Union[str, Any] ) -> List[str]: """Compute validation""" "" snake_case_ :List[str] = {"""input_ids""": batch[0], """attention_mask""": batch[1], """labels""": batch[3]} if self.config.model_type != "distilbert": snake_case_ :Dict = ( batch[2] if self.config.model_type in ["""bert""", """xlnet"""] else None ) # XLM and RoBERTa don"t use token_type_ids snake_case_ :Dict = self(**snake_case ) snake_case_, snake_case_ :Dict = outputs[:2] snake_case_ :Union[str, Any] = logits.detach().cpu().numpy() snake_case_ :List[Any] = inputs["""labels"""].detach().cpu().numpy() return {"val_loss": tmp_eval_loss.detach().cpu(), "pred": preds, "target": out_label_ids} def lowerCAmelCase_ ( self: List[Any] , snake_case: int ) -> Tuple: snake_case_ :Union[str, Any] = torch.stack([x["""val_loss"""] for x in outputs] ).mean() snake_case_ :Tuple = np.concatenate([x["""pred"""] for x in outputs] , axis=0 ) snake_case_ :Tuple = np.argmax(snake_case , axis=2 ) snake_case_ :List[str] = np.concatenate([x["""target"""] for x in outputs] , axis=0 ) snake_case_ :Optional[Any] = dict(enumerate(self.labels ) ) snake_case_ :Dict = [[] for _ in range(out_label_ids.shape[0] )] snake_case_ :Dict = [[] for _ in range(out_label_ids.shape[0] )] for i in range(out_label_ids.shape[0] ): for j in range(out_label_ids.shape[1] ): if out_label_ids[i, j] != self.pad_token_label_id: out_label_list[i].append(label_map[out_label_ids[i][j]] ) preds_list[i].append(label_map[preds[i][j]] ) snake_case_ :str = { """val_loss""": val_loss_mean, """accuracy_score""": accuracy_score(snake_case , snake_case ), """precision""": precision_score(snake_case , snake_case ), """recall""": recall_score(snake_case , snake_case ), """f1""": fa_score(snake_case , snake_case ), } snake_case_ :List[Any] = dict(results.items() ) snake_case_ :Union[str, Any] = results return ret, preds_list, out_label_list def lowerCAmelCase_ ( self: Optional[Any] , snake_case: Dict ) -> Optional[Any]: # when stable snake_case_, snake_case_, snake_case_ :Tuple = self._eval_end(snake_case ) snake_case_ :str = ret["""log"""] return {"val_loss": logs["val_loss"], "log": logs, "progress_bar": logs} def lowerCAmelCase_ ( self: Tuple , snake_case: Optional[int] ) -> Any: # updating to test_epoch_end instead of deprecated test_end snake_case_, snake_case_, snake_case_ :Any = self._eval_end(snake_case ) # Converting to the dict required by pl # https://github.com/PyTorchLightning/pytorch-lightning/blob/master/\ # pytorch_lightning/trainer/logging.py#L139 snake_case_ :Optional[int] = ret["""log"""] # `val_loss` is the key returned by `self._eval_end()` but actually refers to `test_loss` return {"avg_test_loss": logs["val_loss"], "log": logs, "progress_bar": logs} @staticmethod def lowerCAmelCase_ ( snake_case: Any , snake_case: int ) -> Dict: # Add NER specific options BaseTransformer.add_model_specific_args(snake_case , snake_case ) parser.add_argument( """--task_type""" , default="""NER""" , type=snake_case , help="""Task type to fine tune in training (e.g. NER, POS, etc)""" ) parser.add_argument( """--max_seq_length""" , default=128 , type=snake_case , help=( """The maximum total input sequence length after tokenization. Sequences longer """ """than this will be truncated, sequences shorter will be padded.""" ) , ) parser.add_argument( """--labels""" , default="""""" , type=snake_case , help="""Path to a file containing all labels. If not specified, CoNLL-2003 labels are used.""" , ) parser.add_argument( """--gpus""" , default=0 , type=snake_case , help="""The number of GPUs allocated for this, it is by default 0 meaning none""" , ) parser.add_argument( """--overwrite_cache""" , action="""store_true""" , help="""Overwrite the cached training and evaluation sets""" ) return parser if __name__ == "__main__": __a = argparse.ArgumentParser() add_generic_args(parser, os.getcwd()) __a = NERTransformer.add_model_specific_args(parser, os.getcwd()) __a = parser.parse_args() __a = NERTransformer(args) __a = generic_train(model, args) if args.do_predict: # See https://github.com/huggingface/transformers/issues/3159 # pl use this default format to create a checkpoint: # https://github.com/PyTorchLightning/pytorch-lightning/blob/master\ # /pytorch_lightning/callbacks/model_checkpoint.py#L322 __a = sorted(glob.glob(os.path.join(args.output_dir, "checkpoint-epoch=*.ckpt"), recursive=True)) __a = model.load_from_checkpoint(checkpoints[-1]) trainer.test(model)
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"""simple docstring""" import re import time from typing import Optional import IPython.display as disp from ..trainer_callback import TrainerCallback from ..trainer_utils import IntervalStrategy, has_length def A_ ( _lowercase ): '''simple docstring''' snake_case_ :List[str] = int(_lowercase ) snake_case_, snake_case_, snake_case_ :Dict = t // 3600, (t // 60) % 60, t % 60 return f"""{h}:{m:02d}:{s:02d}""" if h != 0 else f"""{m:02d}:{s:02d}""" def A_ ( _lowercase, _lowercase, _lowercase, _lowercase, _lowercase=300 ): '''simple docstring''' return f""" <div> {prefix} <progress value='{value}' max='{total}' style='width:{width}px; height:20px; vertical-align: middle;'></progress> {label} </div> """ def A_ ( _lowercase ): '''simple docstring''' snake_case_ :Dict = """<table border=\"1\" class=\"dataframe\">\n""" html_code += """ <thead>\n <tr style="text-align: left;">\n""" for i in items[0]: html_code += f""" <th>{i}</th>\n""" html_code += " </tr>\n </thead>\n <tbody>\n" for line in items[1:]: html_code += " <tr>\n" for elt in line: snake_case_ :Any = f"""{elt:.6f}""" if isinstance(_lowercase, _lowercase ) else str(_lowercase ) html_code += f""" <td>{elt}</td>\n""" html_code += " </tr>\n" html_code += " </tbody>\n</table><p>" return html_code class lowerCamelCase : '''simple docstring''' _A : Union[str, Any] = 5 _A : List[Any] = 0.2 def __init__( self: List[Any] , snake_case: int , snake_case: Optional[str] = None , snake_case: bool = True , snake_case: Optional["NotebookTrainingTracker"] = None , snake_case: int = 300 , ) -> List[Any]: snake_case_ :Tuple = total snake_case_ :Optional[Any] = """""" if prefix is None else prefix snake_case_ :Tuple = leave snake_case_ :Union[str, Any] = parent snake_case_ :Any = width snake_case_ :List[str] = None snake_case_ :Tuple = None snake_case_ :Optional[int] = None def lowerCAmelCase_ ( self: List[Any] , snake_case: int , snake_case: bool = False , snake_case: str = None ) -> Any: snake_case_ :Any = value if comment is not None: snake_case_ :List[str] = comment if self.last_value is None: snake_case_ :Union[str, Any] = time.time() snake_case_ :int = value snake_case_ :Dict = None snake_case_ :Tuple = self.warmup snake_case_ :Optional[Any] = 1 self.update_bar(snake_case ) elif value <= self.last_value and not force_update: return elif force_update or self.first_calls > 0 or value >= min(self.last_value + self.wait_for , self.total ): if self.first_calls > 0: self.first_calls -= 1 snake_case_ :List[str] = time.time() snake_case_ :Any = current_time - self.start_time # We could have value = self.start_value if the update is called twixe with the same start value. if value > self.start_value: snake_case_ :Dict = self.elapsed_time / (value - self.start_value) else: snake_case_ :Optional[int] = None if value >= self.total: snake_case_ :Optional[int] = self.total snake_case_ :Tuple = None if not self.leave: self.close() elif self.average_time_per_item is not None: snake_case_ :Optional[int] = self.average_time_per_item * (self.total - value) self.update_bar(snake_case ) snake_case_ :str = value snake_case_ :str = current_time if self.average_time_per_item is None: snake_case_ :Optional[Any] = 1 else: snake_case_ :Dict = max(int(self.update_every / self.average_time_per_item ) , 1 ) def lowerCAmelCase_ ( self: Optional[int] , snake_case: Dict , snake_case: str=None ) -> Dict: snake_case_ :Any = """ """ * (len(str(self.total ) ) - len(str(snake_case ) )) + str(snake_case ) if self.elapsed_time is None: snake_case_ :List[Any] = f"""[{spaced_value}/{self.total} : < :""" elif self.predicted_remaining is None: snake_case_ :Any = f"""[{spaced_value}/{self.total} {format_time(self.elapsed_time )}""" else: snake_case_ :str = ( f"""[{spaced_value}/{self.total} {format_time(self.elapsed_time )} <""" f""" {format_time(self.predicted_remaining )}""" ) self.label += f""", {1/self.average_time_per_item:.2f} it/s""" self.label += "]" if self.comment is None or len(self.comment ) == 0 else f""", {self.comment}]""" self.display() def lowerCAmelCase_ ( self: Optional[Any] ) -> Any: snake_case_ :Optional[int] = html_progress_bar(self.value , self.total , self.prefix , self.label , self.width ) if self.parent is not None: # If this is a child bar, the parent will take care of the display. self.parent.display() return if self.output is None: snake_case_ :Optional[Any] = disp.display(disp.HTML(self.html_code ) , display_id=snake_case ) else: self.output.update(disp.HTML(self.html_code ) ) def lowerCAmelCase_ ( self: List[str] ) -> Any: if self.parent is None and self.output is not None: self.output.update(disp.HTML("""""" ) ) class lowerCamelCase ( _lowerCAmelCase ): '''simple docstring''' def __init__( self: Dict , snake_case: Dict , snake_case: int=None ) -> Any: super().__init__(snake_case ) snake_case_ :Optional[Any] = None if column_names is None else [column_names] snake_case_ :Union[str, Any] = None def lowerCAmelCase_ ( self: Optional[int] ) -> List[Any]: snake_case_ :Optional[int] = html_progress_bar(self.value , self.total , self.prefix , self.label , self.width ) if self.inner_table is not None: self.html_code += text_to_html_table(self.inner_table ) if self.child_bar is not None: self.html_code += self.child_bar.html_code if self.output is None: snake_case_ :List[Any] = disp.display(disp.HTML(self.html_code ) , display_id=snake_case ) else: self.output.update(disp.HTML(self.html_code ) ) def lowerCAmelCase_ ( self: Optional[Any] , snake_case: str ) -> List[Any]: if self.inner_table is None: snake_case_ :Any = [list(values.keys() ), list(values.values() )] else: snake_case_ :int = self.inner_table[0] if len(self.inner_table ) == 1: # We give a chance to update the column names at the first iteration for key in values.keys(): if key not in columns: columns.append(snake_case ) snake_case_ :Dict = columns self.inner_table.append([values[c] for c in columns] ) def lowerCAmelCase_ ( self: Any , snake_case: List[Any] , snake_case: Optional[int]=None , snake_case: List[str]=300 ) -> Any: snake_case_ :Union[str, Any] = NotebookProgressBar(snake_case , prefix=snake_case , parent=self , width=snake_case ) return self.child_bar def lowerCAmelCase_ ( self: Any ) -> Any: snake_case_ :Tuple = None self.display() class lowerCamelCase ( _lowerCAmelCase ): '''simple docstring''' def __init__( self: int ) -> Any: snake_case_ :Tuple = None snake_case_ :str = None snake_case_ :Dict = False def lowerCAmelCase_ ( self: Any , snake_case: Any , snake_case: List[Any] , snake_case: Optional[Any] , **snake_case: str ) -> Tuple: snake_case_ :Dict = """Epoch""" if args.evaluation_strategy == IntervalStrategy.EPOCH else """Step""" snake_case_ :str = 0 snake_case_ :str = 0 snake_case_ :Any = [self.first_column] + ["""Training Loss"""] if args.evaluation_strategy != IntervalStrategy.NO: column_names.append("""Validation Loss""" ) snake_case_ :Optional[int] = NotebookTrainingTracker(state.max_steps , snake_case ) def lowerCAmelCase_ ( self: Any , snake_case: Tuple , snake_case: Dict , snake_case: Union[str, Any] , **snake_case: List[Any] ) -> Optional[int]: snake_case_ :Tuple = int(state.epoch ) if int(state.epoch ) == state.epoch else f"""{state.epoch:.2f}""" self.training_tracker.update( state.global_step + 1 , comment=f"""Epoch {epoch}/{state.num_train_epochs}""" , force_update=self._force_next_update , ) snake_case_ :Dict = False def lowerCAmelCase_ ( self: List[Any] , snake_case: Dict , snake_case: str , snake_case: Dict , snake_case: Tuple=None , **snake_case: Optional[Any] ) -> Any: if not has_length(snake_case ): return if self.prediction_bar is None: if self.training_tracker is not None: snake_case_ :Optional[Any] = self.training_tracker.add_child(len(snake_case ) ) else: snake_case_ :List[str] = NotebookProgressBar(len(snake_case ) ) self.prediction_bar.update(1 ) else: self.prediction_bar.update(self.prediction_bar.value + 1 ) def lowerCAmelCase_ ( self: Union[str, Any] , snake_case: Union[str, Any] , snake_case: Optional[Any] , snake_case: Union[str, Any] , **snake_case: int ) -> Any: if self.prediction_bar is not None: self.prediction_bar.close() snake_case_ :Tuple = None def lowerCAmelCase_ ( self: Optional[Any] , snake_case: int , snake_case: List[str] , snake_case: Optional[Any] , snake_case: List[str]=None , **snake_case: int ) -> Any: # Only for when there is no evaluation if args.evaluation_strategy == IntervalStrategy.NO and "loss" in logs: snake_case_ :int = {"""Training Loss""": logs["""loss"""]} # First column is necessarily Step sine we're not in epoch eval strategy snake_case_ :Optional[Any] = state.global_step self.training_tracker.write_line(snake_case ) def lowerCAmelCase_ ( self: Optional[Any] , snake_case: Dict , snake_case: Union[str, Any] , snake_case: int , snake_case: str=None , **snake_case: List[Any] ) -> List[Any]: if self.training_tracker is not None: snake_case_ :Optional[Any] = {"""Training Loss""": """No log""", """Validation Loss""": """No log"""} for log in reversed(state.log_history ): if "loss" in log: snake_case_ :Optional[int] = log["""loss"""] break if self.first_column == "Epoch": snake_case_ :int = int(state.epoch ) else: snake_case_ :Any = state.global_step snake_case_ :str = """eval""" for k in metrics: if k.endswith("""_loss""" ): snake_case_ :List[str] = re.sub(r"""\_loss$""" , """""" , snake_case ) snake_case_ :Union[str, Any] = metrics.pop("""total_flos""" , snake_case ) snake_case_ :int = metrics.pop("""epoch""" , snake_case ) snake_case_ :List[str] = metrics.pop(f"""{metric_key_prefix}_runtime""" , snake_case ) snake_case_ :Union[str, Any] = metrics.pop(f"""{metric_key_prefix}_samples_per_second""" , snake_case ) snake_case_ :Dict = metrics.pop(f"""{metric_key_prefix}_steps_per_second""" , snake_case ) snake_case_ :Optional[int] = metrics.pop(f"""{metric_key_prefix}_jit_compilation_time""" , snake_case ) for k, v in metrics.items(): if k == f"""{metric_key_prefix}_loss""": snake_case_ :Union[str, Any] = v else: snake_case_ :Dict = k.split("""_""" ) snake_case_ :List[str] = """ """.join([part.capitalize() for part in splits[1:]] ) snake_case_ :List[str] = v self.training_tracker.write_line(snake_case ) self.training_tracker.remove_child() snake_case_ :int = None # Evaluation takes a long time so we should force the next update. snake_case_ :int = True def lowerCAmelCase_ ( self: List[str] , snake_case: Any , snake_case: Optional[int] , snake_case: Any , **snake_case: Optional[int] ) -> Any: self.training_tracker.update( state.global_step , comment=f"""Epoch {int(state.epoch )}/{state.num_train_epochs}""" , force_update=snake_case ) snake_case_ :Optional[int] = None
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"""simple docstring""" from math import factorial class lowerCamelCase : '''simple docstring''' def __init__( self: Optional[int] , snake_case: Dict , snake_case: int ) -> Tuple: snake_case_ :List[Any] = real if isinstance(snake_case , snake_case ): snake_case_ :Tuple = [1] * rank else: snake_case_ :Optional[Any] = rank def __repr__( self: List[str] ) -> Tuple: return ( f"""{self.real}+""" f"""{'+'.join(str(snake_case )+'E'+str(n+1 )for n,dual in enumerate(self.duals ) )}""" ) def lowerCAmelCase_ ( self: Optional[int] ) -> Optional[int]: snake_case_ :Any = self.duals.copy() while cur[-1] == 0: cur.pop(-1 ) return Dual(self.real , snake_case ) def __add__( self: Optional[int] , snake_case: Dict ) -> List[str]: if not isinstance(snake_case , snake_case ): return Dual(self.real + other , self.duals ) snake_case_ :List[Any] = self.duals.copy() snake_case_ :Tuple = other.duals.copy() if len(snake_case ) > len(snake_case ): o_dual.extend([1] * (len(snake_case ) - len(snake_case )) ) elif len(snake_case ) < len(snake_case ): s_dual.extend([1] * (len(snake_case ) - len(snake_case )) ) snake_case_ :Dict = [] for i in range(len(snake_case ) ): new_duals.append(s_dual[i] + o_dual[i] ) return Dual(self.real + other.real , snake_case ) _A : str = __add__ def __sub__( self: Tuple , snake_case: Union[str, Any] ) -> Tuple: return self + other * -1 def __mul__( self: str , snake_case: Tuple ) -> Optional[Any]: if not isinstance(snake_case , snake_case ): snake_case_ :Dict = [] for i in self.duals: new_duals.append(i * other ) return Dual(self.real * other , snake_case ) snake_case_ :int = [0] * (len(self.duals ) + len(other.duals ) + 1) for i, item in enumerate(self.duals ): for j, jtem in enumerate(other.duals ): new_duals[i + j + 1] += item * jtem for k in range(len(self.duals ) ): new_duals[k] += self.duals[k] * other.real for index in range(len(other.duals ) ): new_duals[index] += other.duals[index] * self.real return Dual(self.real * other.real , snake_case ) _A : int = __mul__ def __truediv__( self: List[str] , snake_case: List[str] ) -> List[str]: if not isinstance(snake_case , snake_case ): snake_case_ :Optional[Any] = [] for i in self.duals: new_duals.append(i / other ) return Dual(self.real / other , snake_case ) raise ValueError def __floordiv__( self: int , snake_case: List[Any] ) -> Any: if not isinstance(snake_case , snake_case ): snake_case_ :Optional[int] = [] for i in self.duals: new_duals.append(i // other ) return Dual(self.real // other , snake_case ) raise ValueError def __pow__( self: Optional[Any] , snake_case: Optional[int] ) -> List[Any]: if n < 0 or isinstance(snake_case , snake_case ): raise ValueError("""power must be a positive integer""" ) if n == 0: return 1 if n == 1: return self snake_case_ :str = self for _ in range(n - 1 ): x *= self return x def A_ ( _lowercase, _lowercase, _lowercase ): '''simple docstring''' if not callable(_lowercase ): raise ValueError("""differentiate() requires a function as input for func""" ) if not isinstance(_lowercase, (float, int) ): raise ValueError("""differentiate() requires a float as input for position""" ) if not isinstance(_lowercase, _lowercase ): raise ValueError("""differentiate() requires an int as input for order""" ) snake_case_ :Optional[Any] = Dual(_lowercase, 1 ) snake_case_ :List[Any] = func(_lowercase ) if order == 0: return result.real return result.duals[order - 1] * factorial(_lowercase ) if __name__ == "__main__": import doctest doctest.testmod() def A_ ( _lowercase ): '''simple docstring''' return y**2 * y**4 print(differentiate(f, 9, 2))
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"""simple docstring""" from json import JSONDecodeError # Workaround for requests.exceptions.JSONDecodeError import requests def A_ ( _lowercase = "isbn/0140328726" ): '''simple docstring''' snake_case_ :str = olid.strip().strip("""/""" ) # Remove leading/trailing whitespace & slashes if new_olid.count("""/""" ) != 1: snake_case_ :Any = f"""{olid} is not a valid Open Library olid""" raise ValueError(_lowercase ) return requests.get(f"""https://openlibrary.org/{new_olid}.json""" ).json() def A_ ( _lowercase ): '''simple docstring''' snake_case_ :Tuple = { """title""": """Title""", """publish_date""": """Publish date""", """authors""": """Authors""", """number_of_pages""": """Number of pages:""", """first_sentence""": """First sentence""", """isbn_10""": """ISBN (10)""", """isbn_13""": """ISBN (13)""", } snake_case_ :Any = {better_key: ol_book_data[key] for key, better_key in desired_keys.items()} snake_case_ :Optional[int] = [ get_openlibrary_data(author["""key"""] )["""name"""] for author in data["""Authors"""] ] snake_case_ :Optional[int] = data["""First sentence"""]["""value"""] for key, value in data.items(): if isinstance(_lowercase, _lowercase ): snake_case_ :Tuple = """, """.join(_lowercase ) return data if __name__ == "__main__": import doctest doctest.testmod() while True: __a = input("\nEnter the ISBN code to search (or 'quit' to stop): ").strip() if isbn.lower() in ("", "q", "quit", "exit", "stop"): break if len(isbn) not in (10, 13) or not isbn.isdigit(): print(F"""Sorry, {isbn} is not a valid ISBN. Please, input a valid ISBN.""") continue print(F"""\nSearching Open Library for ISBN: {isbn}...\n""") try: __a = summarize_book(get_openlibrary_data(F"""isbn/{isbn}""")) print("\n".join(F"""{key}: {value}""" for key, value in book_summary.items())) except JSONDecodeError: # Workaround for requests.exceptions.RequestException: print(F"""Sorry, there are no results for ISBN: {isbn}.""")
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"""simple docstring""" from __future__ import annotations __a = 10 def A_ ( _lowercase ): '''simple docstring''' snake_case_ :Union[str, Any] = 1 snake_case_ :List[str] = max(_lowercase ) while placement <= max_digit: # declare and initialize empty buckets snake_case_ :list[list] = [[] for _ in range(_lowercase )] # split list_of_ints between the buckets for i in list_of_ints: snake_case_ :Any = int((i / placement) % RADIX ) buckets[tmp].append(_lowercase ) # put each buckets' contents into list_of_ints snake_case_ :Optional[Any] = 0 for b in range(_lowercase ): for i in buckets[b]: snake_case_ :Union[str, Any] = i a += 1 # move to next placement *= RADIX return list_of_ints if __name__ == "__main__": import doctest doctest.testmod()
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"""simple docstring""" import logging import os import sys from dataclasses import dataclass, field from typing import Optional import evaluate import numpy as np import torch from datasets import load_dataset from PIL import Image from torchvision.transforms import ( CenterCrop, Compose, Normalize, RandomHorizontalFlip, RandomResizedCrop, Resize, ToTensor, ) import transformers from transformers import ( MODEL_FOR_IMAGE_CLASSIFICATION_MAPPING, AutoConfig, AutoImageProcessor, AutoModelForImageClassification, 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 __a = 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>=1.8.0", "To fix: pip install -r examples/pytorch/image-classification/requirements.txt") __a = list(MODEL_FOR_IMAGE_CLASSIFICATION_MAPPING.keys()) __a = tuple(conf.model_type for conf in MODEL_CONFIG_CLASSES) def A_ ( _lowercase ): '''simple docstring''' with open(_lowercase, """rb""" ) as f: snake_case_ :str = Image.open(_lowercase ) return im.convert("""RGB""" ) @dataclass class lowerCamelCase : '''simple docstring''' _A : Optional[str] = field( default=_lowerCAmelCase , metadata={ """help""": """Name of a dataset from the hub (could be your own, possibly private dataset hosted on the hub).""" } , ) _A : Optional[str] = field( default=_lowerCAmelCase , metadata={"""help""": """The configuration name of the dataset to use (via the datasets library)."""} ) _A : Optional[str] = field(default=_lowerCAmelCase , metadata={"""help""": """A folder containing the training data."""} ) _A : Optional[str] = field(default=_lowerCAmelCase , metadata={"""help""": """A folder containing the validation data."""} ) _A : Optional[float] = field( default=0.15 , metadata={"""help""": """Percent to split off of train for validation."""} ) _A : Optional[int] = field( default=_lowerCAmelCase , metadata={ """help""": ( """For debugging purposes or quicker training, truncate the number of training examples to this """ """value if set.""" ) } , ) _A : Optional[int] = field( default=_lowerCAmelCase , metadata={ """help""": ( """For debugging purposes or quicker training, truncate the number of evaluation examples to this """ """value if set.""" ) } , ) def lowerCAmelCase_ ( self: List[str] ) -> Any: if self.dataset_name is None and (self.train_dir is None and self.validation_dir is None): raise ValueError( """You must specify either a dataset name from the hub or a train and/or validation directory.""" ) @dataclass class lowerCamelCase : '''simple docstring''' _A : str = field( default="""google/vit-base-patch16-224-in21k""" , metadata={"""help""": """Path to pretrained model or model identifier from huggingface.co/models"""} , ) _A : Optional[str] = field( default=_lowerCAmelCase , metadata={"""help""": """If training from scratch, pass a model type from the list: """ + """, """.join(_lowerCAmelCase )} , ) _A : Optional[str] = field( default=_lowerCAmelCase , metadata={"""help""": """Pretrained config name or path if not the same as model_name"""} ) _A : Optional[str] = field( default=_lowerCAmelCase , metadata={"""help""": """Where do you want to store the pretrained models downloaded from s3"""} ) _A : str = field( default="""main""" , metadata={"""help""": """The specific model version to use (can be a branch name, tag name or commit id)."""} , ) _A : str = field(default=_lowerCAmelCase , metadata={"""help""": """Name or path of preprocessor config."""} ) _A : bool = field( default=_lowerCAmelCase , metadata={ """help""": ( """Will use the token generated when running `huggingface-cli login` (necessary to use this script """ """with private models).""" ) } , ) _A : bool = field( default=_lowerCAmelCase , metadata={"""help""": """Will enable to load a pretrained model whose head dimensions are different."""} , ) def A_ ( _lowercase ): '''simple docstring''' snake_case_ :Union[str, Any] = torch.stack([example["""pixel_values"""] for example in examples] ) snake_case_ :Union[str, Any] = torch.tensor([example["""labels"""] for example in examples] ) return {"pixel_values": pixel_values, "labels": labels} def A_ ( ): '''simple docstring''' snake_case_ :Any = 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. snake_case_, snake_case_, snake_case_ :int = parser.parse_json_file(json_file=os.path.abspath(sys.argv[1] ) ) else: snake_case_, snake_case_, snake_case_ :Tuple = 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_image_classification""", _lowercase, _lowercase ) # 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() snake_case_ :Optional[int] = training_args.get_process_log_level() logger.setLevel(_lowercase ) transformers.utils.logging.set_verbosity(_lowercase ) 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}""" ) # Detecting last checkpoint. snake_case_ :List[Any] = None if os.path.isdir(training_args.output_dir ) and training_args.do_train and not training_args.overwrite_output_dir: snake_case_ :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 overcome.""" ) 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.""" ) # Set seed before initializing model. set_seed(training_args.seed ) # Initialize our dataset and prepare it for the 'image-classification' task. if data_args.dataset_name is not None: snake_case_ :Optional[Any] = load_dataset( data_args.dataset_name, data_args.dataset_config_name, cache_dir=model_args.cache_dir, task="""image-classification""", use_auth_token=True if model_args.use_auth_token else None, ) else: snake_case_ :Union[str, Any] = {} if data_args.train_dir is not None: snake_case_ :Tuple = os.path.join(data_args.train_dir, """**""" ) if data_args.validation_dir is not None: snake_case_ :List[Any] = os.path.join(data_args.validation_dir, """**""" ) snake_case_ :Dict = load_dataset( """imagefolder""", data_files=_lowercase, cache_dir=model_args.cache_dir, task="""image-classification""", ) # If we don't have a validation split, split off a percentage of train as validation. snake_case_ :List[Any] = None if """validation""" in dataset.keys() else data_args.train_val_split if isinstance(data_args.train_val_split, _lowercase ) and data_args.train_val_split > 0.0: snake_case_ :Dict = dataset["""train"""].train_test_split(data_args.train_val_split ) snake_case_ :Optional[int] = split["""train"""] snake_case_ :int = split["""test"""] # Prepare label mappings. # We'll include these in the model's config to get human readable labels in the Inference API. snake_case_ :Optional[Any] = dataset["""train"""].features["""labels"""].names snake_case_, snake_case_ :Optional[Any] = {}, {} for i, label in enumerate(_lowercase ): snake_case_ :Union[str, Any] = str(_lowercase ) snake_case_ :Union[str, Any] = label # Load the accuracy metric from the datasets package snake_case_ :Any = evaluate.load("""accuracy""" ) # Define our compute_metrics function. It takes an `EvalPrediction` object (a namedtuple with a # predictions and label_ids field) and has to return a dictionary string to float. def compute_metrics(_lowercase ): return metric.compute(predictions=np.argmax(p.predictions, axis=1 ), references=p.label_ids ) snake_case_ :Tuple = AutoConfig.from_pretrained( model_args.config_name or model_args.model_name_or_path, num_labels=len(_lowercase ), labelaid=_lowercase, idalabel=_lowercase, finetuning_task="""image-classification""", cache_dir=model_args.cache_dir, revision=model_args.model_revision, use_auth_token=True if model_args.use_auth_token else None, ) snake_case_ :Optional[int] = AutoModelForImageClassification.from_pretrained( model_args.model_name_or_path, from_tf=bool(""".ckpt""" in model_args.model_name_or_path ), config=_lowercase, 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, ) snake_case_ :Union[str, Any] = AutoImageProcessor.from_pretrained( model_args.image_processor_name or model_args.model_name_or_path, cache_dir=model_args.cache_dir, revision=model_args.model_revision, use_auth_token=True if model_args.use_auth_token else None, ) # Define torchvision transforms to be applied to each image. if "shortest_edge" in image_processor.size: snake_case_ :Union[str, Any] = image_processor.size["""shortest_edge"""] else: snake_case_ :Optional[Any] = (image_processor.size["""height"""], image_processor.size["""width"""]) snake_case_ :List[Any] = Normalize(mean=image_processor.image_mean, std=image_processor.image_std ) snake_case_ :Optional[Any] = Compose( [ RandomResizedCrop(_lowercase ), RandomHorizontalFlip(), ToTensor(), normalize, ] ) snake_case_ :Any = Compose( [ Resize(_lowercase ), CenterCrop(_lowercase ), ToTensor(), normalize, ] ) def train_transforms(_lowercase ): snake_case_ :Optional[Any] = [ _train_transforms(pil_img.convert("""RGB""" ) ) for pil_img in example_batch["""image"""] ] return example_batch def val_transforms(_lowercase ): snake_case_ :List[str] = [_val_transforms(pil_img.convert("""RGB""" ) ) for pil_img in example_batch["""image"""]] return example_batch if training_args.do_train: if "train" not in dataset: raise ValueError("""--do_train requires a train dataset""" ) if data_args.max_train_samples is not None: snake_case_ :Any = ( dataset["""train"""].shuffle(seed=training_args.seed ).select(range(data_args.max_train_samples ) ) ) # Set the training transforms dataset["train"].set_transform(_lowercase ) if training_args.do_eval: if "validation" not in dataset: raise ValueError("""--do_eval requires a validation dataset""" ) if data_args.max_eval_samples is not None: snake_case_ :Optional[Any] = ( dataset["""validation"""].shuffle(seed=training_args.seed ).select(range(data_args.max_eval_samples ) ) ) # Set the validation transforms dataset["validation"].set_transform(_lowercase ) # Initalize our trainer snake_case_ :str = Trainer( model=_lowercase, args=_lowercase, train_dataset=dataset["""train"""] if training_args.do_train else None, eval_dataset=dataset["""validation"""] if training_args.do_eval else None, compute_metrics=_lowercase, tokenizer=_lowercase, data_collator=_lowercase, ) # Training if training_args.do_train: snake_case_ :Optional[Any] = None if training_args.resume_from_checkpoint is not None: snake_case_ :Optional[int] = training_args.resume_from_checkpoint elif last_checkpoint is not None: snake_case_ :Optional[Any] = last_checkpoint snake_case_ :Tuple = trainer.train(resume_from_checkpoint=_lowercase ) 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: snake_case_ :Optional[int] = trainer.evaluate() trainer.log_metrics("""eval""", _lowercase ) trainer.save_metrics("""eval""", _lowercase ) # Write model card and (optionally) push to hub snake_case_ :Union[str, Any] = { """finetuned_from""": model_args.model_name_or_path, """tasks""": """image-classification""", """dataset""": data_args.dataset_name, """tags""": ["""image-classification""", """vision"""], } if training_args.push_to_hub: trainer.push_to_hub(**_lowercase ) else: trainer.create_model_card(**_lowercase ) if __name__ == "__main__": main()
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"""simple docstring""" from typing import TYPE_CHECKING from ...utils import ( OptionalDependencyNotAvailable, _LazyModule, is_sentencepiece_available, is_tokenizers_available, is_torch_available, ) __a = {"configuration_reformer": ["REFORMER_PRETRAINED_CONFIG_ARCHIVE_MAP", "ReformerConfig"]} try: if not is_sentencepiece_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __a = ["ReformerTokenizer"] try: if not is_tokenizers_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __a = ["ReformerTokenizerFast"] try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __a = [ "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 = _LazyModule(__name__, globals()["__file__"], _import_structure, module_spec=__spec__)
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1
"""simple docstring""" from __future__ import annotations from bisect import bisect_left from functools import total_ordering from heapq import merge @total_ordering class lowerCamelCase ( _lowerCAmelCase ): '''simple docstring''' def __lt__( self: Dict , snake_case: int ) -> Optional[int]: return self[-1] < other[-1] def __eq__( self: Union[str, Any] , snake_case: Optional[Any] ) -> List[Any]: return self[-1] == other[-1] def A_ ( _lowercase ): '''simple docstring''' snake_case_ :list[Stack] = [] # sort into stacks for element in collection: snake_case_ :Optional[Any] = Stack([element] ) snake_case_ :List[str] = bisect_left(_lowercase, _lowercase ) if i != len(_lowercase ): stacks[i].append(_lowercase ) else: stacks.append(_lowercase ) # use a heap-based merge to merge stack efficiently snake_case_ :Optional[int] = merge(*(reversed(_lowercase ) for stack in stacks) ) 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(patience_sort(unsorted))
66
"""simple docstring""" import gc import unittest from diffusers import FlaxControlNetModel, FlaxStableDiffusionControlNetPipeline from diffusers.utils import is_flax_available, load_image, slow from diffusers.utils.testing_utils import require_flax if is_flax_available(): import jax import jax.numpy as jnp from flax.jax_utils import replicate from flax.training.common_utils import shard @slow @require_flax class lowerCamelCase ( unittest.TestCase ): '''simple docstring''' def lowerCAmelCase_ ( self: List[Any] ) -> Any: # clean up the VRAM after each test super().tearDown() gc.collect() def lowerCAmelCase_ ( self: Tuple ) -> Any: snake_case_, snake_case_ :List[str] = FlaxControlNetModel.from_pretrained( """lllyasviel/sd-controlnet-canny""" , from_pt=snake_case , dtype=jnp.bfloataa ) snake_case_, snake_case_ :Union[str, Any] = FlaxStableDiffusionControlNetPipeline.from_pretrained( """runwayml/stable-diffusion-v1-5""" , controlnet=snake_case , from_pt=snake_case , dtype=jnp.bfloataa ) snake_case_ :Union[str, Any] = controlnet_params snake_case_ :Union[str, Any] = """bird""" snake_case_ :List[Any] = jax.device_count() snake_case_ :List[Any] = pipe.prepare_text_inputs([prompts] * num_samples ) snake_case_ :List[str] = load_image( """https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main/sd_controlnet/bird_canny.png""" ) snake_case_ :List[str] = pipe.prepare_image_inputs([canny_image] * num_samples ) snake_case_ :Any = jax.random.PRNGKey(0 ) snake_case_ :List[str] = jax.random.split(snake_case , jax.device_count() ) snake_case_ :List[Any] = replicate(snake_case ) snake_case_ :List[str] = shard(snake_case ) snake_case_ :str = shard(snake_case ) snake_case_ :Dict = pipe( prompt_ids=snake_case , image=snake_case , params=snake_case , prng_seed=snake_case , num_inference_steps=50 , jit=snake_case , ).images assert images.shape == (jax.device_count(), 1, 768, 512, 3) snake_case_ :str = images.reshape((images.shape[0] * images.shape[1],) + images.shape[-3:] ) snake_case_ :Union[str, Any] = images[0, 253:256, 253:256, -1] snake_case_ :str = jnp.asarray(jax.device_get(image_slice.flatten() ) ) snake_case_ :Dict = jnp.array( [0.1_6_7_9_6_9, 0.1_1_6_6_9_9, 0.0_8_1_5_4_3, 0.1_5_4_2_9_7, 0.1_3_2_8_1_2, 0.1_0_8_8_8_7, 0.1_6_9_9_2_2, 0.1_6_9_9_2_2, 0.2_0_5_0_7_8] ) print(f"""output_slice: {output_slice}""" ) assert jnp.abs(output_slice - expected_slice ).max() < 1E-2 def lowerCAmelCase_ ( self: int ) -> Dict: snake_case_, snake_case_ :List[Any] = FlaxControlNetModel.from_pretrained( """lllyasviel/sd-controlnet-openpose""" , from_pt=snake_case , dtype=jnp.bfloataa ) snake_case_, snake_case_ :int = FlaxStableDiffusionControlNetPipeline.from_pretrained( """runwayml/stable-diffusion-v1-5""" , controlnet=snake_case , from_pt=snake_case , dtype=jnp.bfloataa ) snake_case_ :str = controlnet_params snake_case_ :Optional[int] = """Chef in the kitchen""" snake_case_ :Union[str, Any] = jax.device_count() snake_case_ :Any = pipe.prepare_text_inputs([prompts] * num_samples ) snake_case_ :str = load_image( """https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main/sd_controlnet/pose.png""" ) snake_case_ :Optional[Any] = pipe.prepare_image_inputs([pose_image] * num_samples ) snake_case_ :str = jax.random.PRNGKey(0 ) snake_case_ :str = jax.random.split(snake_case , jax.device_count() ) snake_case_ :Tuple = replicate(snake_case ) snake_case_ :str = shard(snake_case ) snake_case_ :int = shard(snake_case ) snake_case_ :List[str] = pipe( prompt_ids=snake_case , image=snake_case , params=snake_case , prng_seed=snake_case , num_inference_steps=50 , jit=snake_case , ).images assert images.shape == (jax.device_count(), 1, 768, 512, 3) snake_case_ :str = images.reshape((images.shape[0] * images.shape[1],) + images.shape[-3:] ) snake_case_ :int = images[0, 253:256, 253:256, -1] snake_case_ :Dict = jnp.asarray(jax.device_get(image_slice.flatten() ) ) snake_case_ :Optional[int] = jnp.array( [[0.2_7_1_4_8_4, 0.2_6_1_7_1_9, 0.2_7_5_3_9_1, 0.2_7_7_3_4_4, 0.2_7_9_2_9_7, 0.2_9_1_0_1_6, 0.2_9_4_9_2_2, 0.3_0_2_7_3_4, 0.3_0_2_7_3_4]] ) print(f"""output_slice: {output_slice}""" ) assert jnp.abs(output_slice - expected_slice ).max() < 1E-2
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1
"""simple docstring""" import json import pathlib import unittest import numpy as np from transformers.testing_utils import require_torch, require_vision, slow 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 DetrImageProcessor class lowerCamelCase ( unittest.TestCase ): '''simple docstring''' def __init__( self: Any , snake_case: Optional[Any] , snake_case: List[str]=7 , snake_case: Optional[Any]=3 , snake_case: int=30 , snake_case: str=400 , snake_case: str=True , snake_case: List[str]=None , snake_case: Union[str, Any]=True , snake_case: List[str]=1 / 255 , snake_case: Optional[int]=True , snake_case: Dict=[0.5, 0.5, 0.5] , snake_case: Optional[int]=[0.5, 0.5, 0.5] , snake_case: Union[str, Any]=True , ) -> Any: # by setting size["longest_edge"] > max_resolution we're effectively not testing this :p snake_case_ :str = size if size is not None else {"""shortest_edge""": 18, """longest_edge""": 1_333} snake_case_ :List[Any] = parent snake_case_ :str = batch_size snake_case_ :List[Any] = num_channels snake_case_ :Dict = min_resolution snake_case_ :Optional[int] = max_resolution snake_case_ :Optional[int] = do_resize snake_case_ :Union[str, Any] = size snake_case_ :Optional[int] = do_rescale snake_case_ :List[Any] = rescale_factor snake_case_ :int = do_normalize snake_case_ :int = image_mean snake_case_ :str = image_std snake_case_ :List[str] = do_pad def lowerCAmelCase_ ( self: int ) -> Dict: return { "do_resize": self.do_resize, "size": self.size, "do_rescale": self.do_rescale, "rescale_factor": self.rescale_factor, "do_normalize": self.do_normalize, "image_mean": self.image_mean, "image_std": self.image_std, "do_pad": self.do_pad, } def lowerCAmelCase_ ( self: Tuple , snake_case: Dict , snake_case: str=False ) -> Union[str, Any]: if not batched: snake_case_ :Any = image_inputs[0] if isinstance(snake_case , Image.Image ): snake_case_, snake_case_ :Optional[Any] = image.size else: snake_case_, snake_case_ :str = image.shape[1], image.shape[2] if w < h: snake_case_ :Optional[Any] = int(self.size["""shortest_edge"""] * h / w ) snake_case_ :str = self.size["""shortest_edge"""] elif w > h: snake_case_ :List[Any] = self.size["""shortest_edge"""] snake_case_ :Any = int(self.size["""shortest_edge"""] * w / h ) else: snake_case_ :int = self.size["""shortest_edge"""] snake_case_ :Optional[int] = self.size["""shortest_edge"""] else: snake_case_ :Tuple = [] for image in image_inputs: snake_case_, snake_case_ :Optional[Any] = self.get_expected_values([image] ) expected_values.append((expected_height, expected_width) ) snake_case_ :Tuple = max(snake_case , key=lambda snake_case : item[0] )[0] snake_case_ :str = max(snake_case , key=lambda snake_case : item[1] )[1] return expected_height, expected_width @require_torch @require_vision class lowerCamelCase ( _lowerCAmelCase , unittest.TestCase ): '''simple docstring''' _A : Union[str, Any] = DetrImageProcessor if is_vision_available() else None def lowerCAmelCase_ ( self: List[Any] ) -> Union[str, Any]: snake_case_ :Optional[Any] = DetrImageProcessingTester(self ) @property def lowerCAmelCase_ ( self: Dict ) -> Dict: return self.image_processor_tester.prepare_image_processor_dict() def lowerCAmelCase_ ( self: List[str] ) -> Any: snake_case_ :List[str] = 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_rescale""" ) ) self.assertTrue(hasattr(snake_case , """rescale_factor""" ) ) self.assertTrue(hasattr(snake_case , """do_resize""" ) ) self.assertTrue(hasattr(snake_case , """size""" ) ) self.assertTrue(hasattr(snake_case , """do_pad""" ) ) def lowerCAmelCase_ ( self: Dict ) -> Optional[int]: snake_case_ :Union[str, Any] = self.image_processing_class.from_dict(self.image_processor_dict ) self.assertEqual(image_processor.size , {"""shortest_edge""": 18, """longest_edge""": 1_333} ) self.assertEqual(image_processor.do_pad , snake_case ) snake_case_ :Tuple = self.image_processing_class.from_dict( self.image_processor_dict , size=42 , max_size=84 , pad_and_return_pixel_mask=snake_case ) self.assertEqual(image_processor.size , {"""shortest_edge""": 42, """longest_edge""": 84} ) self.assertEqual(image_processor.do_pad , snake_case ) def lowerCAmelCase_ ( self: Any ) -> List[str]: pass def lowerCAmelCase_ ( self: Optional[Any] ) -> Union[str, Any]: # Initialize image_processing snake_case_ :Any = self.image_processing_class(**self.image_processor_dict ) # create random PIL images snake_case_ :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_ :Dict = image_processing(image_inputs[0] , return_tensors="""pt""" ).pixel_values snake_case_, snake_case_ :Optional[int] = self.image_processor_tester.get_expected_values(snake_case ) self.assertEqual( encoded_images.shape , (1, self.image_processor_tester.num_channels, expected_height, expected_width) , ) # Test batched snake_case_, snake_case_ :List[Any] = self.image_processor_tester.get_expected_values(snake_case , batched=snake_case ) snake_case_ :Union[str, 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, expected_height, expected_width, ) , ) def lowerCAmelCase_ ( self: int ) -> List[Any]: # Initialize image_processing snake_case_ :Any = self.image_processing_class(**self.image_processor_dict ) # create random numpy tensors snake_case_ :Optional[int] = 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_ :str = image_processing(image_inputs[0] , return_tensors="""pt""" ).pixel_values snake_case_, snake_case_ :Any = self.image_processor_tester.get_expected_values(snake_case ) self.assertEqual( encoded_images.shape , (1, self.image_processor_tester.num_channels, expected_height, expected_width) , ) # Test batched snake_case_ :Optional[int] = image_processing(snake_case , return_tensors="""pt""" ).pixel_values snake_case_, snake_case_ :List[str] = self.image_processor_tester.get_expected_values(snake_case , batched=snake_case ) self.assertEqual( encoded_images.shape , ( self.image_processor_tester.batch_size, self.image_processor_tester.num_channels, expected_height, expected_width, ) , ) def lowerCAmelCase_ ( self: Any ) -> List[str]: # Initialize image_processing snake_case_ :Union[str, Any] = self.image_processing_class(**self.image_processor_dict ) # create random PyTorch tensors snake_case_ :Tuple = 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_ :Dict = image_processing(image_inputs[0] , return_tensors="""pt""" ).pixel_values snake_case_, snake_case_ :str = self.image_processor_tester.get_expected_values(snake_case ) self.assertEqual( encoded_images.shape , (1, self.image_processor_tester.num_channels, expected_height, expected_width) , ) # Test batched snake_case_ :Optional[int] = image_processing(snake_case , return_tensors="""pt""" ).pixel_values snake_case_, snake_case_ :Union[str, Any] = self.image_processor_tester.get_expected_values(snake_case , batched=snake_case ) self.assertEqual( encoded_images.shape , ( self.image_processor_tester.batch_size, self.image_processor_tester.num_channels, expected_height, expected_width, ) , ) @slow def lowerCAmelCase_ ( self: Any ) -> Optional[Any]: # prepare image and target snake_case_ :Optional[Any] = Image.open("""./tests/fixtures/tests_samples/COCO/000000039769.png""" ) with open("""./tests/fixtures/tests_samples/COCO/coco_annotations.txt""" , """r""" ) as f: snake_case_ :Dict = json.loads(f.read() ) snake_case_ :int = {"""image_id""": 39_769, """annotations""": target} # encode them snake_case_ :Optional[int] = DetrImageProcessor.from_pretrained("""facebook/detr-resnet-50""" ) snake_case_ :List[Any] = image_processing(images=snake_case , annotations=snake_case , return_tensors="""pt""" ) # verify pixel values snake_case_ :Any = torch.Size([1, 3, 800, 1_066] ) self.assertEqual(encoding["""pixel_values"""].shape , snake_case ) snake_case_ :Any = torch.tensor([0.2_7_9_6, 0.3_1_3_8, 0.3_4_8_1] ) self.assertTrue(torch.allclose(encoding["""pixel_values"""][0, 0, 0, :3] , snake_case , atol=1E-4 ) ) # verify area snake_case_ :Optional[Any] = torch.tensor([5_8_8_7.9_6_0_0, 1_1_2_5_0.2_0_6_1, 4_8_9_3_5_3.8_4_3_8, 8_3_7_1_2_2.7_5_0_0, 1_4_7_9_6_7.5_1_5_6, 1_6_5_7_3_2.3_4_3_8] ) self.assertTrue(torch.allclose(encoding["""labels"""][0]["""area"""] , snake_case ) ) # verify boxes snake_case_ :List[str] = torch.Size([6, 4] ) self.assertEqual(encoding["""labels"""][0]["""boxes"""].shape , snake_case ) snake_case_ :Any = torch.tensor([0.5_5_0_3, 0.2_7_6_5, 0.0_6_0_4, 0.2_2_1_5] ) self.assertTrue(torch.allclose(encoding["""labels"""][0]["""boxes"""][0] , snake_case , atol=1E-3 ) ) # verify image_id snake_case_ :Union[str, Any] = torch.tensor([39_769] ) self.assertTrue(torch.allclose(encoding["""labels"""][0]["""image_id"""] , snake_case ) ) # verify is_crowd snake_case_ :List[str] = torch.tensor([0, 0, 0, 0, 0, 0] ) self.assertTrue(torch.allclose(encoding["""labels"""][0]["""iscrowd"""] , snake_case ) ) # verify class_labels snake_case_ :List[str] = torch.tensor([75, 75, 63, 65, 17, 17] ) self.assertTrue(torch.allclose(encoding["""labels"""][0]["""class_labels"""] , snake_case ) ) # verify orig_size snake_case_ :List[str] = torch.tensor([480, 640] ) self.assertTrue(torch.allclose(encoding["""labels"""][0]["""orig_size"""] , snake_case ) ) # verify size snake_case_ :str = torch.tensor([800, 1_066] ) self.assertTrue(torch.allclose(encoding["""labels"""][0]["""size"""] , snake_case ) ) @slow def lowerCAmelCase_ ( self: List[str] ) -> Optional[int]: # prepare image, target and masks_path snake_case_ :Any = Image.open("""./tests/fixtures/tests_samples/COCO/000000039769.png""" ) with open("""./tests/fixtures/tests_samples/COCO/coco_panoptic_annotations.txt""" , """r""" ) as f: snake_case_ :Optional[int] = json.loads(f.read() ) snake_case_ :Optional[Any] = {"""file_name""": """000000039769.png""", """image_id""": 39_769, """segments_info""": target} snake_case_ :Tuple = pathlib.Path("""./tests/fixtures/tests_samples/COCO/coco_panoptic""" ) # encode them snake_case_ :Optional[Any] = DetrImageProcessor.from_pretrained("""facebook/detr-resnet-50-panoptic""" ) snake_case_ :Union[str, Any] = image_processing(images=snake_case , annotations=snake_case , masks_path=snake_case , return_tensors="""pt""" ) # verify pixel values snake_case_ :int = torch.Size([1, 3, 800, 1_066] ) self.assertEqual(encoding["""pixel_values"""].shape , snake_case ) snake_case_ :Dict = torch.tensor([0.2_7_9_6, 0.3_1_3_8, 0.3_4_8_1] ) self.assertTrue(torch.allclose(encoding["""pixel_values"""][0, 0, 0, :3] , snake_case , atol=1E-4 ) ) # verify area snake_case_ :Tuple = torch.tensor([1_4_7_9_7_9.6_8_7_5, 1_6_5_5_2_7.0_4_6_9, 4_8_4_6_3_8.5_9_3_8, 1_1_2_9_2.9_3_7_5, 5_8_7_9.6_5_6_2, 7_6_3_4.1_1_4_7] ) self.assertTrue(torch.allclose(encoding["""labels"""][0]["""area"""] , snake_case ) ) # verify boxes snake_case_ :str = torch.Size([6, 4] ) self.assertEqual(encoding["""labels"""][0]["""boxes"""].shape , snake_case ) snake_case_ :Tuple = torch.tensor([0.2_6_2_5, 0.5_4_3_7, 0.4_6_8_8, 0.8_6_2_5] ) self.assertTrue(torch.allclose(encoding["""labels"""][0]["""boxes"""][0] , snake_case , atol=1E-3 ) ) # verify image_id snake_case_ :Optional[Any] = torch.tensor([39_769] ) self.assertTrue(torch.allclose(encoding["""labels"""][0]["""image_id"""] , snake_case ) ) # verify is_crowd snake_case_ :Union[str, Any] = torch.tensor([0, 0, 0, 0, 0, 0] ) self.assertTrue(torch.allclose(encoding["""labels"""][0]["""iscrowd"""] , snake_case ) ) # verify class_labels snake_case_ :Dict = torch.tensor([17, 17, 63, 75, 75, 93] ) self.assertTrue(torch.allclose(encoding["""labels"""][0]["""class_labels"""] , snake_case ) ) # verify masks snake_case_ :Dict = 822_873 self.assertEqual(encoding["""labels"""][0]["""masks"""].sum().item() , snake_case ) # verify orig_size snake_case_ :Dict = torch.tensor([480, 640] ) self.assertTrue(torch.allclose(encoding["""labels"""][0]["""orig_size"""] , snake_case ) ) # verify size snake_case_ :List[str] = torch.tensor([800, 1_066] ) self.assertTrue(torch.allclose(encoding["""labels"""][0]["""size"""] , snake_case ) )
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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, ) __a = { "configuration_mobilebert": [ "MOBILEBERT_PRETRAINED_CONFIG_ARCHIVE_MAP", "MobileBertConfig", "MobileBertOnnxConfig", ], "tokenization_mobilebert": ["MobileBertTokenizer"], } try: if not is_tokenizers_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __a = ["MobileBertTokenizerFast"] try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __a = [ "MOBILEBERT_PRETRAINED_MODEL_ARCHIVE_LIST", "MobileBertForMaskedLM", "MobileBertForMultipleChoice", "MobileBertForNextSentencePrediction", "MobileBertForPreTraining", "MobileBertForQuestionAnswering", "MobileBertForSequenceClassification", "MobileBertForTokenClassification", "MobileBertLayer", "MobileBertModel", "MobileBertPreTrainedModel", "load_tf_weights_in_mobilebert", ] try: if not is_tf_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __a = [ "TF_MOBILEBERT_PRETRAINED_MODEL_ARCHIVE_LIST", "TFMobileBertForMaskedLM", "TFMobileBertForMultipleChoice", "TFMobileBertForNextSentencePrediction", "TFMobileBertForPreTraining", "TFMobileBertForQuestionAnswering", "TFMobileBertForSequenceClassification", "TFMobileBertForTokenClassification", "TFMobileBertMainLayer", "TFMobileBertModel", "TFMobileBertPreTrainedModel", ] if TYPE_CHECKING: from .configuration_mobilebert import ( MOBILEBERT_PRETRAINED_CONFIG_ARCHIVE_MAP, MobileBertConfig, MobileBertOnnxConfig, ) from .tokenization_mobilebert import MobileBertTokenizer try: if not is_tokenizers_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .tokenization_mobilebert_fast import MobileBertTokenizerFast try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_mobilebert import ( MOBILEBERT_PRETRAINED_MODEL_ARCHIVE_LIST, MobileBertForMaskedLM, MobileBertForMultipleChoice, MobileBertForNextSentencePrediction, MobileBertForPreTraining, MobileBertForQuestionAnswering, MobileBertForSequenceClassification, MobileBertForTokenClassification, MobileBertLayer, MobileBertModel, MobileBertPreTrainedModel, load_tf_weights_in_mobilebert, ) try: if not is_tf_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_tf_mobilebert import ( TF_MOBILEBERT_PRETRAINED_MODEL_ARCHIVE_LIST, TFMobileBertForMaskedLM, TFMobileBertForMultipleChoice, TFMobileBertForNextSentencePrediction, TFMobileBertForPreTraining, TFMobileBertForQuestionAnswering, TFMobileBertForSequenceClassification, TFMobileBertForTokenClassification, TFMobileBertMainLayer, TFMobileBertModel, TFMobileBertPreTrainedModel, ) else: import sys __a = _LazyModule(__name__, globals()["__file__"], _import_structure, module_spec=__spec__)
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1
"""simple docstring""" import contextlib import copy import random from typing import Any, Dict, Iterable, Optional, Union import numpy as np import torch from .utils import deprecate, is_transformers_available if is_transformers_available(): import transformers def A_ ( _lowercase ): '''simple docstring''' random.seed(_lowercase ) np.random.seed(_lowercase ) torch.manual_seed(_lowercase ) torch.cuda.manual_seed_all(_lowercase ) # ^^ safe to call this function even if cuda is not available class lowerCamelCase : '''simple docstring''' def __init__( self: List[Any] , snake_case: Iterable[torch.nn.Parameter] , snake_case: float = 0.9_9_9_9 , snake_case: float = 0.0 , snake_case: int = 0 , snake_case: bool = False , snake_case: Union[float, int] = 1.0 , snake_case: Union[float, int] = 2 / 3 , snake_case: Optional[Any] = None , snake_case: Dict[str, Any] = None , **snake_case: Union[str, Any] , ) -> str: if isinstance(snake_case , torch.nn.Module ): snake_case_ :List[str] = ( """Passing a `torch.nn.Module` to `ExponentialMovingAverage` is deprecated. """ """Please pass the parameters of the module instead.""" ) deprecate( """passing a `torch.nn.Module` to `ExponentialMovingAverage`""" , """1.0.0""" , snake_case , standard_warn=snake_case , ) snake_case_ :Any = parameters.parameters() # set use_ema_warmup to True if a torch.nn.Module is passed for backwards compatibility snake_case_ :Optional[Any] = True if kwargs.get("""max_value""" , snake_case ) is not None: snake_case_ :str = """The `max_value` argument is deprecated. Please use `decay` instead.""" deprecate("""max_value""" , """1.0.0""" , snake_case , standard_warn=snake_case ) snake_case_ :Union[str, Any] = kwargs["""max_value"""] if kwargs.get("""min_value""" , snake_case ) is not None: snake_case_ :Dict = """The `min_value` argument is deprecated. Please use `min_decay` instead.""" deprecate("""min_value""" , """1.0.0""" , snake_case , standard_warn=snake_case ) snake_case_ :str = kwargs["""min_value"""] snake_case_ :str = list(snake_case ) snake_case_ :Optional[Any] = [p.clone().detach() for p in parameters] if kwargs.get("""device""" , snake_case ) is not None: snake_case_ :Union[str, Any] = """The `device` argument is deprecated. Please use `to` instead.""" deprecate("""device""" , """1.0.0""" , snake_case , standard_warn=snake_case ) self.to(device=kwargs["""device"""] ) snake_case_ :Any = None snake_case_ :Optional[Any] = decay snake_case_ :Any = min_decay snake_case_ :List[Any] = update_after_step snake_case_ :Optional[Any] = use_ema_warmup snake_case_ :Optional[Any] = inv_gamma snake_case_ :int = power snake_case_ :int = 0 snake_case_ :Dict = None # set in `step()` snake_case_ :Dict = model_cls snake_case_ :List[Any] = model_config @classmethod def lowerCAmelCase_ ( cls: Optional[int] , snake_case: Tuple , snake_case: Dict ) -> "EMAModel": snake_case_, snake_case_ :Union[str, Any] = model_cls.load_config(snake_case , return_unused_kwargs=snake_case ) snake_case_ :Tuple = model_cls.from_pretrained(snake_case ) snake_case_ :Any = cls(model.parameters() , model_cls=snake_case , model_config=model.config ) ema_model.load_state_dict(snake_case ) return ema_model def lowerCAmelCase_ ( self: Optional[Any] , snake_case: List[Any] ) -> str: if self.model_cls is None: raise ValueError("""`save_pretrained` can only be used if `model_cls` was defined at __init__.""" ) if self.model_config is None: raise ValueError("""`save_pretrained` can only be used if `model_config` was defined at __init__.""" ) snake_case_ :List[str] = self.model_cls.from_config(self.model_config ) snake_case_ :List[str] = self.state_dict() state_dict.pop("""shadow_params""" , snake_case ) model.register_to_config(**snake_case ) self.copy_to(model.parameters() ) model.save_pretrained(snake_case ) def lowerCAmelCase_ ( self: Dict , snake_case: int ) -> float: snake_case_ :List[str] = max(0 , optimization_step - self.update_after_step - 1 ) if step <= 0: return 0.0 if self.use_ema_warmup: snake_case_ :Any = 1 - (1 + step / self.inv_gamma) ** -self.power else: snake_case_ :int = (1 + step) / (10 + step) snake_case_ :Optional[Any] = min(snake_case , self.decay ) # make sure decay is not smaller than min_decay snake_case_ :Optional[int] = max(snake_case , self.min_decay ) return cur_decay_value @torch.no_grad() def lowerCAmelCase_ ( self: int , snake_case: Iterable[torch.nn.Parameter] ) -> Optional[int]: if isinstance(snake_case , torch.nn.Module ): snake_case_ :Tuple = ( """Passing a `torch.nn.Module` to `ExponentialMovingAverage.step` is deprecated. """ """Please pass the parameters of the module instead.""" ) deprecate( """passing a `torch.nn.Module` to `ExponentialMovingAverage.step`""" , """1.0.0""" , snake_case , standard_warn=snake_case , ) snake_case_ :Any = parameters.parameters() snake_case_ :str = list(snake_case ) self.optimization_step += 1 # Compute the decay factor for the exponential moving average. snake_case_ :Union[str, Any] = self.get_decay(self.optimization_step ) snake_case_ :Optional[Any] = decay snake_case_ :Union[str, Any] = 1 - decay snake_case_ :Tuple = contextlib.nullcontext if is_transformers_available() and transformers.deepspeed.is_deepspeed_zeroa_enabled(): import deepspeed for s_param, param in zip(self.shadow_params , snake_case ): if is_transformers_available() and transformers.deepspeed.is_deepspeed_zeroa_enabled(): snake_case_ :List[Any] = deepspeed.zero.GatheredParameters(snake_case , modifier_rank=snake_case ) with context_manager(): if param.requires_grad: s_param.sub_(one_minus_decay * (s_param - param) ) else: s_param.copy_(snake_case ) def lowerCAmelCase_ ( self: int , snake_case: Iterable[torch.nn.Parameter] ) -> None: snake_case_ :int = list(snake_case ) for s_param, param in zip(self.shadow_params , snake_case ): param.data.copy_(s_param.to(param.device ).data ) def lowerCAmelCase_ ( self: str , snake_case: Optional[Any]=None , snake_case: List[str]=None ) -> None: snake_case_ :List[str] = [ p.to(device=snake_case , dtype=snake_case ) if p.is_floating_point() else p.to(device=snake_case ) for p in self.shadow_params ] def lowerCAmelCase_ ( self: Union[str, Any] ) -> dict: return { "decay": self.decay, "min_decay": self.min_decay, "optimization_step": self.optimization_step, "update_after_step": self.update_after_step, "use_ema_warmup": self.use_ema_warmup, "inv_gamma": self.inv_gamma, "power": self.power, "shadow_params": self.shadow_params, } def lowerCAmelCase_ ( self: List[Any] , snake_case: Iterable[torch.nn.Parameter] ) -> None: snake_case_ :Optional[Any] = [param.detach().cpu().clone() for param in parameters] def lowerCAmelCase_ ( self: int , snake_case: Iterable[torch.nn.Parameter] ) -> None: if self.temp_stored_params is None: raise RuntimeError("""This ExponentialMovingAverage has no `store()`ed weights """ """to `restore()`""" ) for c_param, param in zip(self.temp_stored_params , snake_case ): param.data.copy_(c_param.data ) # Better memory-wise. snake_case_ :Optional[int] = None def lowerCAmelCase_ ( self: Tuple , snake_case: dict ) -> None: snake_case_ :Optional[Any] = copy.deepcopy(snake_case ) snake_case_ :Tuple = state_dict.get("""decay""" , self.decay ) if self.decay < 0.0 or self.decay > 1.0: raise ValueError("""Decay must be between 0 and 1""" ) snake_case_ :Union[str, Any] = state_dict.get("""min_decay""" , self.min_decay ) if not isinstance(self.min_decay , snake_case ): raise ValueError("""Invalid min_decay""" ) snake_case_ :List[str] = state_dict.get("""optimization_step""" , self.optimization_step ) if not isinstance(self.optimization_step , snake_case ): raise ValueError("""Invalid optimization_step""" ) snake_case_ :Union[str, Any] = state_dict.get("""update_after_step""" , self.update_after_step ) if not isinstance(self.update_after_step , snake_case ): raise ValueError("""Invalid update_after_step""" ) snake_case_ :str = state_dict.get("""use_ema_warmup""" , self.use_ema_warmup ) if not isinstance(self.use_ema_warmup , snake_case ): raise ValueError("""Invalid use_ema_warmup""" ) snake_case_ :int = state_dict.get("""inv_gamma""" , self.inv_gamma ) if not isinstance(self.inv_gamma , (float, int) ): raise ValueError("""Invalid inv_gamma""" ) snake_case_ :Union[str, Any] = state_dict.get("""power""" , self.power ) if not isinstance(self.power , (float, int) ): raise ValueError("""Invalid power""" ) snake_case_ :Optional[int] = state_dict.get("""shadow_params""" , snake_case ) if shadow_params is not None: snake_case_ :Tuple = shadow_params if not isinstance(self.shadow_params , snake_case ): raise ValueError("""shadow_params must be a list""" ) if not all(isinstance(snake_case , torch.Tensor ) for p in self.shadow_params ): raise ValueError("""shadow_params must all be Tensors""" )
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"""simple docstring""" import argparse import json import os from collections import OrderedDict import numpy as np import tensorflow as tf import torch def A_ ( _lowercase ): '''simple docstring''' snake_case_ :Union[str, Any] = os.path.join(args.tf_model_dir, """parameters.json""" ) snake_case_ :Any = json.loads(open(_lowercase ).read() ) if not params: raise ValueError( f"""It seems that the json file at {parameter_file} is empty. Make sure you have a correct json file.""" ) if not args.output.endswith(""".pt""" ): snake_case_ :Optional[int] = args.output + """.pt""" snake_case_ :List[str] = OrderedDict() with tf.device("""/CPU:0""" ): snake_case_ :Dict = tf.train.load_checkpoint(args.tf_model_dir ) snake_case_ :str = reader.get_variable_to_shape_map() for key_name in shapes.keys(): snake_case_ :List[Any] = reader.get_tensor(_lowercase ).astype(np.floataa ) if key_name.endswith("""/adam_m""" ) or key_name.endswith("""/adam_v""" ): continue if key_name.startswith("""pasts/""" ): if key_name.startswith("""pasts/mlp""" ): snake_case_ :Any = int(key_name[9] ) elif key_name.startswith("""pasts/out""" ): snake_case_ :Optional[int] = 8 snake_case_ :List[str] = """model.sqout.%d.weight""" % (player * 2) # enter to nn.Sequencial with Tanh, so 2 at a time snake_case_ :Optional[Any] = vnp.transpose([1, 0] ).copy() # Mesh-Tensorflow is a diagonal matrix snake_case_ :List[str] = torch.tensor(_lowercase ) elif key_name.startswith("""model/moe""" ): snake_case_ :Tuple = int(key_name[9:].split("""/""" )[0] ) if key_name.endswith("""/switch_gating/kernel""" ): snake_case_ :Union[str, Any] = """model.blocks.%d.feed_forward.mlp.router.classifier.weight""" % player snake_case_ :Optional[Any] = vnp.transpose([1, 0] ).copy() # Mesh-Tensorflow is a diagonal matrix snake_case_ :Optional[Any] = torch.tensor(_lowercase ) elif key_name.endswith("""/softmlp/kernel""" ): snake_case_ :List[Any] = """model.blocks.%d.feed_forward.soft_bypass_mlp.weight""" % player snake_case_ :Optional[int] = vnp.transpose([1, 0] ).copy() # Mesh-Tensorflow is a diagonal matrix snake_case_ :Optional[Any] = torch.tensor(_lowercase ) elif key_name.endswith("""/wo/kernel""" ) or key_name.endswith("""/wi/kernel""" ): snake_case_ :Dict = key_name[-9:-7] for i in range(16 ): snake_case_ :str = """model.blocks.%d.feed_forward.mlp.experts.expert_%d.%s.weight""" % (player, i, nlayer) snake_case_ :Tuple = ( vnp[i].transpose([1, 0] ).copy() ) # In Mesh-Tensorflow, it is one array, so it is divided snake_case_ :Optional[int] = torch.tensor(_lowercase ) elif key_name.startswith("""model/mlp""" ): snake_case_ :Optional[int] = int(key_name[9:].split("""/""" )[0] ) if key_name.endswith("""/p1/kernel""" ): snake_case_ :Union[str, Any] = """model.blocks.%d.feed_forward.mlp.wi.weight""" % player snake_case_ :Dict = vnp.transpose([1, 0] ).copy() # Mesh-Tensorflow is a diagonal matrix snake_case_ :Optional[Any] = torch.tensor(_lowercase ) elif key_name.endswith("""/p1/bias""" ): snake_case_ :List[Any] = """model.blocks.%d.feed_forward.mlp.wi.bias""" % player snake_case_ :str = vnp.copy() # same because it is one dimensional snake_case_ :Optional[Any] = torch.tensor(_lowercase ) elif key_name.endswith("""/p2/kernel""" ): snake_case_ :Union[str, Any] = """model.blocks.%d.feed_forward.mlp.wo.weight""" % player snake_case_ :Dict = vnp.transpose([1, 0] ).copy() # Mesh-Tensorflow is a diagonal matrix snake_case_ :Tuple = torch.tensor(_lowercase ) elif key_name.endswith("""/p2/bias""" ): snake_case_ :Dict = """model.blocks.%d.feed_forward.mlp.wo.bias""" % player snake_case_ :Any = vnp.copy() # same because it is one dimensional snake_case_ :Optional[int] = torch.tensor(_lowercase ) elif key_name.startswith("""model/ln""" ): snake_case_ :Union[str, Any] = int(key_name[8:].split("""/""" )[0] ) if key_name.endswith("""/b""" ): snake_case_ :str = """model.blocks.%d.feed_forward.norm.bias""" % player snake_case_ :Dict = vnp.copy() # same because it is one dimensional snake_case_ :int = torch.tensor(_lowercase ) elif key_name.endswith("""/g""" ): snake_case_ :Dict = """model.blocks.%d.feed_forward.norm.weight""" % player snake_case_ :Dict = vnp.copy() # same because it is one dimensional snake_case_ :Tuple = torch.tensor(_lowercase ) elif key_name.startswith("""model/att""" ): snake_case_ :List[str] = int(key_name[9:].split("""/""" )[0] ) if key_name.endswith("""/qkv/kernel""" ): snake_case_ :Optional[int] = vnp.copy() # Compute same dimension as Mesh-tensorflow using einsum snake_case_ :Dict = state[:, 0, :, :] snake_case_ :int = state[:, 1, :, :] snake_case_ :List[str] = state[:, 2, :, :] snake_case_ :str = ( state_q.reshape([state_q.shape[0], state_q.shape[1] * state_q.shape[2]] ) .transpose([1, 0] ) .copy() ) # Mesh-Tensorflow is a diagonal matrix snake_case_ :Any = ( state_k.reshape([state_k.shape[0], state_k.shape[1] * state_k.shape[2]] ) .transpose([1, 0] ) .copy() ) # Mesh-Tensorflow is a diagonal matrix snake_case_ :Optional[int] = ( state_v.reshape([state_v.shape[0], state_v.shape[1] * state_v.shape[2]] ) .transpose([1, 0] ) .copy() ) # Mesh-Tensorflow is a diagonal matrix snake_case_ :int = """model.blocks.%d.self_attn.self_attn.q_proj.weight""" % player snake_case_ :int = torch.tensor(_lowercase ) snake_case_ :Optional[Any] = """model.blocks.%d.self_attn.self_attn.k_proj.weight""" % player snake_case_ :Dict = torch.tensor(_lowercase ) snake_case_ :Dict = """model.blocks.%d.self_attn.self_attn.v_proj.weight""" % player snake_case_ :Optional[Any] = torch.tensor(_lowercase ) elif key_name.endswith("""/o/kernel""" ): snake_case_ :str = """model.blocks.%d.self_attn.self_attn.out_proj.weight""" % player snake_case_ :str = ( vnp.reshape([vnp.shape[0] * vnp.shape[1], vnp.shape[2]] ).transpose([1, 0] ).copy() ) # Mesh-Tensorflow is a diagonal matrix snake_case_ :Any = torch.tensor(_lowercase ) elif key_name.startswith("""model/an""" ): snake_case_ :Optional[int] = int(key_name[8:].split("""/""" )[0] ) if key_name.endswith("""/b""" ): snake_case_ :Any = """model.blocks.%d.self_attn.norm.bias""" % player snake_case_ :Optional[int] = vnp.copy() # same because it is one dimensional snake_case_ :Tuple = torch.tensor(_lowercase ) elif key_name.endswith("""/g""" ): snake_case_ :Union[str, Any] = """model.blocks.%d.self_attn.norm.weight""" % player snake_case_ :Dict = vnp.copy() # same because it is one dimensional snake_case_ :Optional[int] = torch.tensor(_lowercase ) elif ( key_name.startswith("""model/wte""" ) or key_name.startswith("""model/wpe""" ) or key_name.startswith("""model/ete""" ) ): snake_case_ :List[Any] = {"""wte""": """embed_tokens""", """wpe""": """position_embeddings""", """ete""": """extra_position_embeddings"""}[ key_name[-3:] ] snake_case_ :Optional[Any] = """model.%s.weight""" % nlayer snake_case_ :Any = vnp.copy() # same in embedded snake_case_ :List[Any] = torch.tensor(_lowercase ) if key_name.startswith("""model/wte""" ): snake_case_ :Tuple = """lm_head.weight""" snake_case_ :List[str] = vnp.copy() # same in embedded snake_case_ :List[Any] = torch.tensor(_lowercase ) elif key_name.startswith("""model/wob""" ): snake_case_ :str = """final_logits_bias""" snake_case_ :Any = vnp.copy() # same in embedded snake_case_ :List[Any] = state.reshape((1, -1) ) snake_case_ :Union[str, Any] = torch.tensor(_lowercase ) elif key_name == "model/dense/kernel": snake_case_ :str = """model.last_project.weight""" snake_case_ :Dict = vnp.transpose([1, 0] ).copy() # Mesh-Tensorflow is a diagonal matrix snake_case_ :int = torch.tensor(_lowercase ) elif key_name == "model/dense_1/bias": snake_case_ :Optional[int] = """model.last_project.bias""" snake_case_ :Tuple = vnp.copy() # same because it is one dimensional snake_case_ :Any = torch.tensor(_lowercase ) torch.save(_lowercase, args.output ) if __name__ == "__main__": __a = argparse.ArgumentParser( description="model converter.", formatter_class=argparse.ArgumentDefaultsHelpFormatter ) parser.add_argument("--tf_model_dir", metavar="PATH", type=str, required=True, help="import model") parser.add_argument("--output", metavar="PATH", type=str, required=True, help="output model") __a = parser.parse_args() convert_tf_gptsan_to_pt(args)
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1
"""simple docstring""" import collections import inspect import unittest from typing import Dict, List, Tuple from transformers import MaskFormerSwinConfig from transformers.testing_utils import require_torch, require_torch_multi_gpu, torch_device from transformers.utils import is_torch_available from ...test_backbone_common import BackboneTesterMixin from ...test_configuration_common import ConfigTester from ...test_modeling_common import ModelTesterMixin, floats_tensor, ids_tensor from ...test_pipeline_mixin import PipelineTesterMixin if is_torch_available(): import torch from torch import nn from transformers import MaskFormerSwinBackbone from transformers.models.maskformer import MaskFormerSwinModel class lowerCamelCase : '''simple docstring''' def __init__( self: Dict , snake_case: Optional[Any] , snake_case: Tuple=13 , snake_case: Any=32 , snake_case: Union[str, Any]=2 , snake_case: Tuple=3 , snake_case: Union[str, Any]=16 , snake_case: Union[str, Any]=[1, 2, 1] , snake_case: Optional[Any]=[2, 2, 4] , snake_case: str=2 , snake_case: List[str]=2.0 , snake_case: Optional[int]=True , snake_case: Union[str, Any]=0.0 , snake_case: Optional[int]=0.0 , snake_case: Optional[Any]=0.1 , snake_case: List[str]="gelu" , snake_case: Any=False , snake_case: Optional[Any]=True , snake_case: Optional[int]=0.0_2 , snake_case: Any=1E-5 , snake_case: Optional[int]=True , snake_case: int=None , snake_case: Any=True , snake_case: str=10 , snake_case: Optional[Any]=8 , snake_case: Union[str, Any]=["stage1", "stage2", "stage3"] , snake_case: Tuple=[1, 2, 3] , ) -> Dict: snake_case_ :Dict = parent snake_case_ :List[Any] = batch_size snake_case_ :Dict = image_size snake_case_ :Dict = patch_size snake_case_ :Tuple = num_channels snake_case_ :List[Any] = embed_dim snake_case_ :List[str] = depths snake_case_ :str = num_heads snake_case_ :Tuple = window_size snake_case_ :Tuple = mlp_ratio snake_case_ :int = qkv_bias snake_case_ :Tuple = hidden_dropout_prob snake_case_ :Optional[Any] = attention_probs_dropout_prob snake_case_ :Dict = drop_path_rate snake_case_ :Any = hidden_act snake_case_ :Any = use_absolute_embeddings snake_case_ :int = patch_norm snake_case_ :List[Any] = layer_norm_eps snake_case_ :Tuple = initializer_range snake_case_ :str = is_training snake_case_ :int = scope snake_case_ :Tuple = use_labels snake_case_ :Tuple = type_sequence_label_size snake_case_ :str = encoder_stride snake_case_ :List[Any] = out_features snake_case_ :str = out_indices def lowerCAmelCase_ ( self: Tuple ) -> Dict: snake_case_ :Optional[int] = floats_tensor([self.batch_size, self.num_channels, self.image_size, self.image_size] ) snake_case_ :str = None if self.use_labels: snake_case_ :Optional[int] = ids_tensor([self.batch_size] , self.type_sequence_label_size ) snake_case_ :Union[str, Any] = self.get_config() return config, pixel_values, labels def lowerCAmelCase_ ( self: int ) -> Optional[Any]: return MaskFormerSwinConfig( 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 , out_features=self.out_features , out_indices=self.out_indices , ) def lowerCAmelCase_ ( self: List[Any] , snake_case: str , snake_case: int , snake_case: List[str] ) -> Any: snake_case_ :Dict = MaskFormerSwinModel(config=snake_case ) model.to(snake_case ) model.eval() snake_case_ :Tuple = model(snake_case ) snake_case_ :Dict = ((config.image_size // config.patch_size) ** 2) // (4 ** (len(config.depths ) - 1)) snake_case_ :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 lowerCAmelCase_ ( self: Optional[Any] , snake_case: int , snake_case: List[str] , snake_case: Tuple ) -> Union[str, Any]: snake_case_ :Any = MaskFormerSwinBackbone(config=snake_case ) model.to(snake_case ) model.eval() snake_case_ :Optional[Any] = model(snake_case ) # verify feature maps self.parent.assertEqual(len(result.feature_maps ) , len(config.out_features ) ) self.parent.assertListEqual(list(result.feature_maps[0].shape ) , [13, 16, 16, 16] ) # verify channels self.parent.assertEqual(len(model.channels ) , len(config.out_features ) ) self.parent.assertListEqual(model.channels , [16, 32, 64] ) # verify ValueError with self.parent.assertRaises(snake_case ): snake_case_ :Optional[Any] = ["""stem"""] snake_case_ :str = MaskFormerSwinBackbone(config=snake_case ) def lowerCAmelCase_ ( self: List[str] ) -> Optional[Any]: snake_case_ :Optional[int] = self.prepare_config_and_inputs() snake_case_, snake_case_, snake_case_ :str = config_and_inputs snake_case_ :Tuple = {"""pixel_values""": pixel_values} return config, inputs_dict @require_torch class lowerCamelCase ( _lowerCAmelCase , _lowerCAmelCase , unittest.TestCase ): '''simple docstring''' _A : Union[str, Any] = ( ( MaskFormerSwinModel, MaskFormerSwinBackbone, ) if is_torch_available() else () ) _A : str = {"""feature-extraction""": MaskFormerSwinModel} if is_torch_available() else {} _A : List[str] = False _A : Any = False _A : Dict = False _A : List[Any] = False _A : Optional[int] = False def lowerCAmelCase_ ( self: Dict ) -> Any: snake_case_ :str = MaskFormerSwinModelTester(self ) snake_case_ :Optional[Any] = ConfigTester(self , config_class=snake_case , embed_dim=37 ) @require_torch_multi_gpu @unittest.skip( reason=( """`MaskFormerSwinModel` outputs `hidden_states_spatial_dimensions` which doesn't work well with""" """ `nn.DataParallel`""" ) ) def lowerCAmelCase_ ( self: List[str] ) -> Optional[int]: pass def lowerCAmelCase_ ( self: Union[str, Any] ) -> Dict: self.create_and_test_config_common_properties() 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 lowerCAmelCase_ ( self: Any ) -> Tuple: return def lowerCAmelCase_ ( self: Any ) -> Any: snake_case_ :List[Any] = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_model(*snake_case ) def lowerCAmelCase_ ( self: Union[str, Any] ) -> int: snake_case_ :Any = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_backbone(*snake_case ) @unittest.skip("""Swin does not use inputs_embeds""" ) def lowerCAmelCase_ ( self: str ) -> List[str]: pass @unittest.skip("""Swin does not support feedforward chunking""" ) def lowerCAmelCase_ ( self: int ) -> Optional[int]: pass def lowerCAmelCase_ ( self: List[str] ) -> List[Any]: snake_case_, snake_case_ :List[Any] = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: snake_case_ :str = model_class(snake_case ) self.assertIsInstance(model.get_input_embeddings() , (nn.Module) ) snake_case_ :Dict = model.get_output_embeddings() self.assertTrue(x is None or isinstance(snake_case , nn.Linear ) ) def lowerCAmelCase_ ( self: Tuple ) -> Dict: snake_case_, snake_case_ :int = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: snake_case_ :Optional[int] = model_class(snake_case ) snake_case_ :str = inspect.signature(model.forward ) # signature.parameters is an OrderedDict => so arg_names order is deterministic snake_case_ :str = [*signature.parameters.keys()] snake_case_ :str = ["""pixel_values"""] self.assertListEqual(arg_names[:1] , snake_case ) @unittest.skip(reason="""MaskFormerSwin is only used as backbone and doesn't support output_attentions""" ) def lowerCAmelCase_ ( self: List[Any] ) -> List[Any]: pass @unittest.skip(reason="""MaskFormerSwin is only used as an internal backbone""" ) def lowerCAmelCase_ ( self: Dict ) -> List[Any]: pass def lowerCAmelCase_ ( self: Union[str, Any] , snake_case: Union[str, Any] , snake_case: int , snake_case: Any , snake_case: List[str] ) -> str: snake_case_ :List[str] = 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_ :Any = outputs.hidden_states snake_case_ :Optional[int] = getattr( self.model_tester , """expected_num_hidden_layers""" , len(self.model_tester.depths ) + 1 ) self.assertEqual(len(snake_case ) , snake_case ) # Swin has a different seq_length snake_case_ :str = ( config.patch_size if isinstance(config.patch_size , collections.abc.Iterable ) else (config.patch_size, config.patch_size) ) snake_case_ :int = (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] , ) def lowerCAmelCase_ ( self: List[Any] ) -> Optional[int]: 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_ :Tuple = 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_ :List[Any] = True self.check_hidden_states_output(snake_case , snake_case , snake_case , snake_case ) def lowerCAmelCase_ ( self: Optional[Any] ) -> Tuple: snake_case_, snake_case_ :int = self.model_tester.prepare_config_and_inputs_for_common() snake_case_ :List[Any] = 3 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) ) snake_case_ :Any = ( 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_ :List[str] = image_size[1] + patch_size[1] - (image_size[1] % patch_size[1]) for model_class in self.all_model_classes: snake_case_ :str = 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_ :Any = True self.check_hidden_states_output(snake_case , snake_case , snake_case , (padded_height, padded_width) ) @unittest.skip(reason="""MaskFormerSwin doesn't have pretrained checkpoints""" ) def lowerCAmelCase_ ( self: Union[str, Any] ) -> List[str]: pass @unittest.skip(reason="""This will be fixed once MaskFormerSwin is replaced by native Swin""" ) def lowerCAmelCase_ ( self: List[str] ) -> str: pass @unittest.skip(reason="""This will be fixed once MaskFormerSwin is replaced by native Swin""" ) def lowerCAmelCase_ ( self: str ) -> List[Any]: pass def lowerCAmelCase_ ( self: Union[str, Any] ) -> Optional[Any]: snake_case_, snake_case_ :Dict = self.model_tester.prepare_config_and_inputs_for_common() def set_nan_tensor_to_zero(snake_case: str ): snake_case_ :Optional[int] = 0 return t def check_equivalence(snake_case: List[Any] , snake_case: Union[str, Any] , snake_case: int , snake_case: Tuple={} ): with torch.no_grad(): snake_case_ :List[Any] = model(**snake_case , return_dict=snake_case , **snake_case ) snake_case_ :Any = model(**snake_case , return_dict=snake_case , **snake_case ).to_tuple() def recursive_check(snake_case: List[Any] , snake_case: int ): if isinstance(snake_case , (List, Tuple) ): for tuple_iterable_value, dict_iterable_value in zip(snake_case , snake_case ): recursive_check(snake_case , snake_case ) elif isinstance(snake_case , snake_case ): for tuple_iterable_value, dict_iterable_value in zip( tuple_object.values() , dict_object.values() ): recursive_check(snake_case , snake_case ) elif tuple_object is None: return else: self.assertTrue( torch.allclose( set_nan_tensor_to_zero(snake_case ) , set_nan_tensor_to_zero(snake_case ) , atol=1E-5 ) , msg=( """Tuple and dict output are not equal. Difference:""" f""" {torch.max(torch.abs(tuple_object - dict_object ) )}. Tuple has `nan`:""" f""" {torch.isnan(snake_case ).any()} and `inf`: {torch.isinf(snake_case )}. Dict has""" f""" `nan`: {torch.isnan(snake_case ).any()} and `inf`: {torch.isinf(snake_case )}.""" ) , ) recursive_check(snake_case , snake_case ) for model_class in self.all_model_classes: snake_case_ :int = model_class(snake_case ) model.to(snake_case ) model.eval() snake_case_ :Any = self._prepare_for_class(snake_case , snake_case ) snake_case_ :List[Any] = self._prepare_for_class(snake_case , snake_case ) check_equivalence(snake_case , snake_case , snake_case ) snake_case_ :Tuple = self._prepare_for_class(snake_case , snake_case , return_labels=snake_case ) snake_case_ :Dict = self._prepare_for_class(snake_case , snake_case , return_labels=snake_case ) check_equivalence(snake_case , snake_case , snake_case ) snake_case_ :Tuple = self._prepare_for_class(snake_case , snake_case ) snake_case_ :Any = self._prepare_for_class(snake_case , snake_case ) check_equivalence(snake_case , snake_case , snake_case , {"""output_hidden_states""": True} ) snake_case_ :Dict = self._prepare_for_class(snake_case , snake_case , return_labels=snake_case ) snake_case_ :List[str] = self._prepare_for_class(snake_case , snake_case , return_labels=snake_case ) check_equivalence(snake_case , snake_case , snake_case , {"""output_hidden_states""": True} ) @require_torch class lowerCamelCase ( unittest.TestCase , _lowerCAmelCase ): '''simple docstring''' _A : int = (MaskFormerSwinBackbone,) if is_torch_available() else () _A : Tuple = MaskFormerSwinConfig def lowerCAmelCase_ ( self: List[str] ) -> Optional[int]: snake_case_ :Optional[Any] = MaskFormerSwinModelTester(self ) def lowerCAmelCase_ ( self: int ) -> Optional[int]: snake_case_, snake_case_ :Any = self.model_tester.prepare_config_and_inputs_for_common() snake_case_ :Tuple = inputs_dict["""pixel_values"""].shape[0] for backbone_class in self.all_model_classes: snake_case_ :List[str] = backbone_class(snake_case ) backbone.to(snake_case ) backbone.eval() snake_case_ :List[Any] = backbone(**snake_case ) # Test default outputs and verify feature maps self.assertIsInstance(outputs.feature_maps , snake_case ) self.assertTrue(len(outputs.feature_maps ) == len(backbone.channels ) ) for feature_map, n_channels in zip(outputs.feature_maps , backbone.channels ): self.assertTrue(feature_map.shape[:2] , (batch_size, n_channels) ) self.assertIsNone(outputs.hidden_states ) self.assertIsNone(outputs.attentions ) # Test output_hidden_states=True snake_case_ :Union[str, Any] = backbone(**snake_case , output_hidden_states=snake_case ) self.assertIsNotNone(outputs.hidden_states ) self.assertTrue(len(outputs.hidden_states ) , len(backbone.stage_names ) ) # We skip the stem layer for hidden_states, n_channels in zip(outputs.hidden_states[1:] , backbone.channels ): for hidden_state in hidden_states: # Hidden states are in the format (batch_size, (height * width), n_channels) snake_case_, snake_case_, snake_case_ :List[Any] = hidden_state.shape self.assertTrue((h_batch_size, h_n_channels) , (batch_size, n_channels) ) # Test output_attentions=True if self.has_attentions: snake_case_ :List[Any] = backbone(**snake_case , output_attentions=snake_case ) self.assertIsNotNone(outputs.attentions )
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"""simple docstring""" import numpy as np import pandas as pd from sklearn.preprocessing import MinMaxScaler from tensorflow.keras.layers import LSTM, Dense from tensorflow.keras.models import Sequential if __name__ == "__main__": __a = pd.read_csv("sample_data.csv", header=None) __a = df.shape[:1][0] # If you're using some other dataset input the target column __a = df.iloc[:, 1:2] __a = actual_data.values.reshape(len_data, 1) __a = MinMaxScaler().fit_transform(actual_data) __a = 10 __a = 5 __a = 20 __a = len_data - periods * look_back __a = actual_data[:division] __a = actual_data[division - look_back :] __a , __a = [], [] __a , __a = [], [] for i in range(0, len(train_data) - forward_days - look_back + 1): train_x.append(train_data[i : i + look_back]) train_y.append(train_data[i + look_back : i + look_back + forward_days]) for i in range(0, len(test_data) - forward_days - look_back + 1): test_x.append(test_data[i : i + look_back]) test_y.append(test_data[i + look_back : i + look_back + forward_days]) __a = np.array(train_x) __a = np.array(test_x) __a = np.array([list(i.ravel()) for i in train_y]) __a = np.array([list(i.ravel()) for i in test_y]) __a = Sequential() model.add(LSTM(1_28, input_shape=(look_back, 1), return_sequences=True)) model.add(LSTM(64, input_shape=(1_28, 1))) model.add(Dense(forward_days)) model.compile(loss="mean_squared_error", optimizer="adam") __a = model.fit( x_train, y_train, epochs=1_50, verbose=1, shuffle=True, batch_size=4 ) __a = model.predict(x_test)
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"""simple docstring""" from collections import OrderedDict from typing import Any, List, Mapping, Optional from ... import PreTrainedTokenizer, TensorType, is_torch_available from ...configuration_utils import PretrainedConfig from ...onnx import OnnxConfigWithPast, PatchingSpec from ...utils import logging __a = logging.get_logger(__name__) __a = { "EleutherAI/gpt-j-6B": "https://huggingface.co/EleutherAI/gpt-j-6B/resolve/main/config.json", # See all GPT-J models at https://huggingface.co/models?filter=gpt_j } class lowerCamelCase ( _lowerCAmelCase ): '''simple docstring''' _A : List[Any] = """gptj""" _A : Union[str, Any] = { """max_position_embeddings""": """n_positions""", """hidden_size""": """n_embd""", """num_attention_heads""": """n_head""", """num_hidden_layers""": """n_layer""", } def __init__( self: int , snake_case: int=50_400 , snake_case: Optional[Any]=2_048 , snake_case: Any=4_096 , snake_case: Dict=28 , snake_case: Union[str, Any]=16 , snake_case: Optional[int]=64 , snake_case: List[Any]=None , snake_case: List[str]="gelu_new" , snake_case: Dict=0.0 , snake_case: Union[str, Any]=0.0 , snake_case: List[Any]=0.0 , snake_case: List[Any]=1E-5 , snake_case: Any=0.0_2 , snake_case: Union[str, Any]=True , snake_case: int=50_256 , snake_case: int=50_256 , snake_case: List[Any]=False , **snake_case: List[str] , ) -> Optional[Any]: snake_case_ :Optional[Any] = vocab_size snake_case_ :List[Any] = n_positions snake_case_ :List[str] = n_embd snake_case_ :List[str] = n_layer snake_case_ :int = n_head snake_case_ :int = n_inner snake_case_ :List[str] = rotary_dim snake_case_ :Optional[Any] = activation_function snake_case_ :int = resid_pdrop snake_case_ :List[str] = embd_pdrop snake_case_ :str = attn_pdrop snake_case_ :Union[str, Any] = layer_norm_epsilon snake_case_ :Optional[Any] = initializer_range snake_case_ :Any = use_cache snake_case_ :Tuple = bos_token_id snake_case_ :Any = eos_token_id super().__init__( bos_token_id=snake_case , eos_token_id=snake_case , tie_word_embeddings=snake_case , **snake_case ) class lowerCamelCase ( _lowerCAmelCase ): '''simple docstring''' def __init__( self: int , snake_case: PretrainedConfig , snake_case: str = "default" , snake_case: List[PatchingSpec] = None , snake_case: bool = False , ) -> Any: super().__init__(snake_case , task=snake_case , patching_specs=snake_case , use_past=snake_case ) if not getattr(self._config , """pad_token_id""" , snake_case ): # TODO: how to do that better? snake_case_ :Optional[Any] = 0 @property def lowerCAmelCase_ ( self: Optional[int] ) -> Mapping[str, Mapping[int, str]]: snake_case_ :Tuple = OrderedDict({"""input_ids""": {0: """batch""", 1: """sequence"""}} ) if self.use_past: self.fill_with_past_key_values_(snake_case , direction="""inputs""" ) snake_case_ :Optional[Any] = {0: """batch""", 1: """past_sequence + sequence"""} else: snake_case_ :Tuple = {0: """batch""", 1: """sequence"""} return common_inputs @property def lowerCAmelCase_ ( self: Tuple ) -> int: return self._config.n_layer @property def lowerCAmelCase_ ( self: Optional[int] ) -> int: return self._config.n_head def lowerCAmelCase_ ( self: int , snake_case: PreTrainedTokenizer , snake_case: int = -1 , snake_case: int = -1 , snake_case: bool = False , snake_case: Optional[TensorType] = None , ) -> Mapping[str, Any]: snake_case_ :Tuple = super(snake_case , self ).generate_dummy_inputs( snake_case , batch_size=snake_case , seq_length=snake_case , is_pair=snake_case , framework=snake_case ) # We need to order the input in the way they appears in the forward() snake_case_ :int = OrderedDict({"""input_ids""": common_inputs["""input_ids"""]} ) # Need to add the past_keys if self.use_past: if not is_torch_available(): raise ValueError("""Cannot generate dummy past_keys inputs without PyTorch installed.""" ) else: import torch snake_case_, snake_case_ :List[str] = common_inputs["""input_ids"""].shape # Not using the same length for past_key_values snake_case_ :Dict = seqlen + 2 snake_case_ :List[Any] = ( batch, self.num_attention_heads, past_key_values_length, self._config.hidden_size // self.num_attention_heads, ) snake_case_ :Optional[int] = [ (torch.zeros(snake_case ), torch.zeros(snake_case )) for _ in range(self.num_layers ) ] snake_case_ :Dict = common_inputs["""attention_mask"""] if self.use_past: snake_case_ :Optional[int] = ordered_inputs["""attention_mask"""].dtype snake_case_ :List[str] = torch.cat( [ordered_inputs["""attention_mask"""], torch.ones(snake_case , snake_case , dtype=snake_case )] , dim=1 ) return ordered_inputs @property def lowerCAmelCase_ ( self: List[str] ) -> int: return 13
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"""simple docstring""" from typing import TYPE_CHECKING from ...utils import OptionalDependencyNotAvailable, _LazyModule, is_tokenizers_available, is_torch_available __a = { "configuration_altclip": [ "ALTCLIP_PRETRAINED_CONFIG_ARCHIVE_MAP", "AltCLIPConfig", "AltCLIPTextConfig", "AltCLIPVisionConfig", ], "processing_altclip": ["AltCLIPProcessor"], } try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __a = [ "ALTCLIP_PRETRAINED_MODEL_ARCHIVE_LIST", "AltCLIPPreTrainedModel", "AltCLIPModel", "AltCLIPTextModel", "AltCLIPVisionModel", ] if TYPE_CHECKING: from .configuration_altclip import ( ALTCLIP_PRETRAINED_CONFIG_ARCHIVE_MAP, AltCLIPConfig, AltCLIPTextConfig, AltCLIPVisionConfig, ) from .processing_altclip import AltCLIPProcessor try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_altclip import ( ALTCLIP_PRETRAINED_MODEL_ARCHIVE_LIST, AltCLIPModel, AltCLIPPreTrainedModel, AltCLIPTextModel, AltCLIPVisionModel, ) else: import sys __a = _LazyModule(__name__, globals()["__file__"], _import_structure, module_spec=__spec__)
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"""simple docstring""" from __future__ import annotations import unittest from transformers import DebertaVaConfig, is_tf_available from transformers.testing_utils import require_tf, slow from ...test_configuration_common import ConfigTester from ...test_modeling_tf_common import TFModelTesterMixin, ids_tensor, random_attention_mask from ...test_pipeline_mixin import PipelineTesterMixin if is_tf_available(): import tensorflow as tf from transformers import ( TFDebertaVaForMaskedLM, TFDebertaVaForQuestionAnswering, TFDebertaVaForSequenceClassification, TFDebertaVaForTokenClassification, TFDebertaVaModel, ) class lowerCamelCase : '''simple docstring''' def __init__( self: Optional[Any] , snake_case: Tuple , snake_case: Union[str, Any]=13 , snake_case: Optional[int]=7 , snake_case: Union[str, Any]=True , snake_case: Any=True , snake_case: str=True , snake_case: Dict=True , snake_case: int=99 , snake_case: Optional[Any]=32 , snake_case: Optional[Any]=2 , snake_case: Tuple=4 , snake_case: int=37 , snake_case: Any="gelu" , snake_case: List[str]=0.1 , snake_case: List[Any]=0.1 , snake_case: Optional[int]=512 , snake_case: int=16 , snake_case: str=2 , snake_case: int=0.0_2 , snake_case: str=False , snake_case: Any=True , snake_case: List[Any]="None" , snake_case: Optional[Any]=3 , snake_case: Optional[Any]=4 , snake_case: List[str]=None , ) -> str: snake_case_ :Optional[Any] = parent snake_case_ :str = batch_size snake_case_ :Tuple = seq_length snake_case_ :Any = is_training snake_case_ :Dict = use_input_mask snake_case_ :str = use_token_type_ids snake_case_ :List[str] = use_labels snake_case_ :Optional[int] = vocab_size snake_case_ :Dict = hidden_size snake_case_ :List[Any] = num_hidden_layers snake_case_ :Optional[Any] = num_attention_heads snake_case_ :int = intermediate_size snake_case_ :Optional[Any] = hidden_act snake_case_ :Dict = hidden_dropout_prob snake_case_ :str = attention_probs_dropout_prob snake_case_ :int = max_position_embeddings snake_case_ :int = type_vocab_size snake_case_ :Tuple = type_sequence_label_size snake_case_ :Dict = initializer_range snake_case_ :List[str] = num_labels snake_case_ :Union[str, Any] = num_choices snake_case_ :str = relative_attention snake_case_ :Any = position_biased_input snake_case_ :str = pos_att_type snake_case_ :int = scope def lowerCAmelCase_ ( self: List[str] ) -> Any: snake_case_ :str = ids_tensor([self.batch_size, self.seq_length] , self.vocab_size ) snake_case_ :List[Any] = None if self.use_input_mask: snake_case_ :Tuple = random_attention_mask([self.batch_size, self.seq_length] ) snake_case_ :List[str] = None if self.use_token_type_ids: snake_case_ :Tuple = ids_tensor([self.batch_size, self.seq_length] , self.type_vocab_size ) snake_case_ :Union[str, Any] = None snake_case_ :Dict = None snake_case_ :List[str] = None if self.use_labels: snake_case_ :Union[str, Any] = ids_tensor([self.batch_size] , self.type_sequence_label_size ) snake_case_ :List[Any] = ids_tensor([self.batch_size, self.seq_length] , self.num_labels ) snake_case_ :int = DebertaVaConfig( 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 , relative_attention=self.relative_attention , position_biased_input=self.position_biased_input , initializer_range=self.initializer_range , return_dict=snake_case , ) return config, input_ids, token_type_ids, input_mask, sequence_labels, token_labels, choice_labels def lowerCAmelCase_ ( self: Optional[int] , snake_case: List[str] , snake_case: Optional[int] , snake_case: str , snake_case: Any , snake_case: List[str] , snake_case: List[str] , snake_case: str ) -> Any: snake_case_ :Any = TFDebertaVaModel(config=snake_case ) snake_case_ :List[str] = {"""input_ids""": input_ids, """attention_mask""": input_mask, """token_type_ids""": token_type_ids} snake_case_ :int = [input_ids, input_mask] snake_case_ :Dict = model(snake_case ) snake_case_ :List[Any] = model(snake_case ) self.parent.assertEqual(result.last_hidden_state.shape , (self.batch_size, self.seq_length, self.hidden_size) ) def lowerCAmelCase_ ( self: Optional[Any] , snake_case: Optional[Any] , snake_case: List[Any] , snake_case: str , snake_case: int , snake_case: List[Any] , snake_case: int , snake_case: int ) -> Optional[Any]: snake_case_ :str = TFDebertaVaForMaskedLM(config=snake_case ) snake_case_ :Optional[Any] = { """input_ids""": input_ids, """attention_mask""": input_mask, """token_type_ids""": token_type_ids, } snake_case_ :Optional[Any] = model(snake_case ) self.parent.assertEqual(result.logits.shape , (self.batch_size, self.seq_length, self.vocab_size) ) def lowerCAmelCase_ ( self: int , snake_case: str , snake_case: List[Any] , snake_case: int , snake_case: Union[str, Any] , snake_case: Tuple , snake_case: int , snake_case: str ) -> str: snake_case_ :Tuple = self.num_labels snake_case_ :Tuple = TFDebertaVaForSequenceClassification(config=snake_case ) snake_case_ :List[str] = { """input_ids""": input_ids, """attention_mask""": input_mask, """token_type_ids""": token_type_ids, } snake_case_ :int = model(snake_case ) self.parent.assertEqual(result.logits.shape , (self.batch_size, self.num_labels) ) def lowerCAmelCase_ ( self: List[Any] , snake_case: Union[str, Any] , snake_case: int , snake_case: Tuple , snake_case: int , snake_case: Optional[int] , snake_case: str , snake_case: List[Any] ) -> List[str]: snake_case_ :Optional[Any] = self.num_labels snake_case_ :Any = TFDebertaVaForTokenClassification(config=snake_case ) snake_case_ :Union[str, Any] = { """input_ids""": input_ids, """attention_mask""": input_mask, """token_type_ids""": token_type_ids, } snake_case_ :int = model(snake_case ) self.parent.assertEqual(result.logits.shape , (self.batch_size, self.seq_length, self.num_labels) ) def lowerCAmelCase_ ( self: List[str] , snake_case: Optional[int] , snake_case: str , snake_case: List[Any] , snake_case: Any , snake_case: Dict , snake_case: Union[str, Any] , snake_case: Optional[int] ) -> str: snake_case_ :Dict = TFDebertaVaForQuestionAnswering(config=snake_case ) snake_case_ :Any = { """input_ids""": input_ids, """attention_mask""": input_mask, """token_type_ids""": token_type_ids, } snake_case_ :Tuple = model(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 lowerCAmelCase_ ( self: Union[str, Any] ) -> Any: snake_case_ :Optional[int] = self.prepare_config_and_inputs() ( ( snake_case_ ), ( snake_case_ ), ( snake_case_ ), ( snake_case_ ), ( snake_case_ ), ( snake_case_ ), ( snake_case_ ), ) :Tuple = config_and_inputs snake_case_ :List[str] = {"""input_ids""": input_ids, """token_type_ids""": token_type_ids, """attention_mask""": input_mask} return config, inputs_dict @require_tf class lowerCamelCase ( _lowerCAmelCase , _lowerCAmelCase , unittest.TestCase ): '''simple docstring''' _A : Dict = ( ( TFDebertaVaModel, TFDebertaVaForMaskedLM, TFDebertaVaForQuestionAnswering, TFDebertaVaForSequenceClassification, TFDebertaVaForTokenClassification, ) if is_tf_available() else () ) _A : Any = ( { """feature-extraction""": TFDebertaVaModel, """fill-mask""": TFDebertaVaForMaskedLM, """question-answering""": TFDebertaVaForQuestionAnswering, """text-classification""": TFDebertaVaForSequenceClassification, """token-classification""": TFDebertaVaForTokenClassification, """zero-shot""": TFDebertaVaForSequenceClassification, } if is_tf_available() else {} ) _A : Any = False _A : List[Any] = False def lowerCAmelCase_ ( self: Dict ) -> List[str]: snake_case_ :Optional[Any] = TFDebertaVaModelTester(self ) snake_case_ :List[Any] = ConfigTester(self , config_class=snake_case , hidden_size=37 ) def lowerCAmelCase_ ( self: Union[str, Any] ) -> Any: self.config_tester.run_common_tests() def lowerCAmelCase_ ( self: Optional[Any] ) -> str: snake_case_ :Dict = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_model(*snake_case ) def lowerCAmelCase_ ( self: Optional[int] ) -> Optional[Any]: snake_case_ :Dict = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_for_masked_lm(*snake_case ) def lowerCAmelCase_ ( self: str ) -> List[Any]: snake_case_ :Any = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_for_question_answering(*snake_case ) def lowerCAmelCase_ ( self: List[str] ) -> Optional[int]: snake_case_ :List[str] = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_for_sequence_classification(*snake_case ) def lowerCAmelCase_ ( self: Any ) -> Optional[Any]: snake_case_ :Union[str, Any] = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_for_token_classification(*snake_case ) @slow def lowerCAmelCase_ ( self: Tuple ) -> List[Any]: snake_case_ :List[Any] = TFDebertaVaModel.from_pretrained("""kamalkraj/deberta-v2-xlarge""" ) self.assertIsNotNone(snake_case ) @require_tf class lowerCamelCase ( unittest.TestCase ): '''simple docstring''' @unittest.skip(reason="""Model not available yet""" ) def lowerCAmelCase_ ( self: Tuple ) -> int: pass @slow def lowerCAmelCase_ ( self: List[Any] ) -> int: snake_case_ :List[Any] = TFDebertaVaModel.from_pretrained("""kamalkraj/deberta-v2-xlarge""" ) snake_case_ :Optional[int] = tf.constant([[0, 31_414, 232, 328, 740, 1_140, 12_695, 69, 46_078, 1_588, 2]] ) snake_case_ :int = tf.constant([[0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1]] ) snake_case_ :Optional[int] = model(snake_case , attention_mask=snake_case )[0] snake_case_ :Tuple = tf.constant( [[[0.2_3_5_6, 0.1_9_4_8, 0.0_3_6_9], [-0.1_0_6_3, 0.3_5_8_6, -0.5_1_5_2], [-0.6_3_9_9, -0.0_2_5_9, -0.2_5_2_5]]] ) tf.debugging.assert_near(output[:, 1:4, 1:4] , snake_case , atol=1E-4 )
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"""simple docstring""" import argparse import gdown import numpy as np import torch from huggingface_hub import hf_hub_download from transformers import ( CLIPTokenizer, CLIPTokenizerFast, VideoMAEImageProcessor, XCLIPConfig, XCLIPModel, XCLIPProcessor, XCLIPTextConfig, XCLIPVisionConfig, ) def A_ ( _lowercase, _lowercase ): '''simple docstring''' snake_case_ :int = XCLIPTextConfig() # derive patch size from model name snake_case_ :Union[str, Any] = model_name.find("""patch""" ) snake_case_ :List[str] = int(model_name[start_idx + len("""patch""" ) : start_idx + len("""patch""" ) + 2] ) snake_case_ :Any = XCLIPVisionConfig(patch_size=_lowercase, num_frames=_lowercase ) if "large" in model_name: snake_case_ :Optional[Any] = 768 snake_case_ :Union[str, Any] = 3072 snake_case_ :Any = 12 snake_case_ :Any = 1024 snake_case_ :str = 4096 snake_case_ :Union[str, Any] = 16 snake_case_ :Union[str, Any] = 24 snake_case_ :Tuple = 768 snake_case_ :Any = 3072 if model_name == "xclip-large-patch14-16-frames": snake_case_ :Any = 336 snake_case_ :Any = XCLIPConfig.from_text_vision_configs(_lowercase, _lowercase ) if "large" in model_name: snake_case_ :List[Any] = 768 return config def A_ ( _lowercase ): '''simple docstring''' if name == "token_embedding.weight": snake_case_ :Optional[Any] = name.replace("""token_embedding.weight""", """text_model.embeddings.token_embedding.weight""" ) if name == "positional_embedding": snake_case_ :Tuple = name.replace("""positional_embedding""", """text_model.embeddings.position_embedding.weight""" ) if "ln_1" in name: snake_case_ :Dict = name.replace("""ln_1""", """layer_norm1""" ) if "ln_2" in name: snake_case_ :str = name.replace("""ln_2""", """layer_norm2""" ) if "c_fc" in name: snake_case_ :str = name.replace("""c_fc""", """fc1""" ) if "c_proj" in name: snake_case_ :int = name.replace("""c_proj""", """fc2""" ) if name.startswith("""transformer.resblocks""" ): snake_case_ :Union[str, Any] = name.replace("""transformer.resblocks""", """text_model.encoder.layers""" ) if "attn.out_proj" in name and "message" not in name: snake_case_ :Union[str, Any] = name.replace("""attn.out_proj""", """self_attn.out_proj""" ) if "ln_final" in name: snake_case_ :Union[str, Any] = name.replace("""ln_final""", """text_model.final_layer_norm""" ) # visual encoder if name == "visual.class_embedding": snake_case_ :Any = name.replace("""visual.class_embedding""", """vision_model.embeddings.class_embedding""" ) if name == "visual.positional_embedding": snake_case_ :Optional[int] = name.replace("""visual.positional_embedding""", """vision_model.embeddings.position_embedding.weight""" ) if name.startswith("""visual.transformer.resblocks""" ): snake_case_ :Union[str, Any] = name.replace("""visual.transformer.resblocks""", """vision_model.encoder.layers""" ) if "visual.conv1" in name: snake_case_ :int = name.replace("""visual.conv1""", """vision_model.embeddings.patch_embedding""" ) if "visual.ln_pre" in name: snake_case_ :Any = name.replace("""visual.ln_pre""", """vision_model.pre_layernorm""" ) if "visual.ln_post" in name: snake_case_ :str = name.replace("""visual.ln_post""", """vision_model.post_layernorm""" ) if "visual.proj" in name: snake_case_ :Union[str, Any] = name.replace("""visual.proj""", """visual_projection.weight""" ) if "text_projection" in name: snake_case_ :Dict = name.replace("""text_projection""", """text_projection.weight""" ) # things on top if "prompts_visual_proj" in name: snake_case_ :List[str] = name.replace("""prompts_visual_proj""", """prompts_visual_projection""" ) if "prompts_visual_ln" in name: snake_case_ :Dict = name.replace("""prompts_visual_ln""", """prompts_visual_layernorm""" ) # mit if name == "mit.positional_embedding": snake_case_ :str = name.replace("""positional""", """position""" ) if name.startswith("""mit.resblocks""" ): snake_case_ :Dict = name.replace("""mit.resblocks""", """mit.encoder.layers""" ) # prompts generator if name.startswith("""prompts_generator.norm""" ): snake_case_ :Union[str, Any] = name.replace("""prompts_generator.norm""", """prompts_generator.layernorm""" ) return name def A_ ( _lowercase, _lowercase ): '''simple docstring''' for key in orig_state_dict.copy().keys(): snake_case_ :Dict = orig_state_dict.pop(_lowercase ) if "attn.in_proj" in key: snake_case_ :Optional[Any] = key.split(""".""" ) if key.startswith("""visual""" ): snake_case_ :Any = key_split[3] snake_case_ :Optional[Any] = config.vision_config.hidden_size if "message_attn" in key: if "weight" in key: snake_case_ :str = val[ :dim, : ] snake_case_ :Optional[int] = val[ dim : dim * 2, : ] snake_case_ :Union[str, Any] = val[ -dim:, : ] else: snake_case_ :Dict = val[ :dim ] snake_case_ :Optional[int] = val[ dim : dim * 2 ] snake_case_ :Optional[int] = val[ -dim: ] else: if "weight" in key: snake_case_ :Optional[Any] = val[ :dim, : ] snake_case_ :List[str] = val[ dim : dim * 2, : ] snake_case_ :Dict = val[ -dim:, : ] else: snake_case_ :Union[str, Any] = val[:dim] snake_case_ :Union[str, Any] = val[ dim : dim * 2 ] snake_case_ :Union[str, Any] = val[-dim:] elif key.startswith("""mit""" ): snake_case_ :Tuple = key_split[2] snake_case_ :Union[str, Any] = config.vision_config.mit_hidden_size if "weight" in key: snake_case_ :Optional[int] = val[:dim, :] snake_case_ :Optional[int] = val[dim : dim * 2, :] snake_case_ :str = val[-dim:, :] else: snake_case_ :str = val[:dim] snake_case_ :Any = val[dim : dim * 2] snake_case_ :int = val[-dim:] else: snake_case_ :Tuple = key_split[2] snake_case_ :Any = config.text_config.hidden_size if "weight" in key: snake_case_ :Dict = val[:dim, :] snake_case_ :Dict = val[ dim : dim * 2, : ] snake_case_ :List[str] = val[-dim:, :] else: snake_case_ :Any = val[:dim] snake_case_ :Tuple = val[ dim : dim * 2 ] snake_case_ :List[str] = val[-dim:] else: snake_case_ :Optional[int] = rename_key(_lowercase ) if new_key_name in ["visual_projection.weight", "text_projection.weight"]: snake_case_ :Optional[Any] = val.T snake_case_ :Tuple = val return orig_state_dict def A_ ( _lowercase ): '''simple docstring''' if num_frames == 8: snake_case_ :str = """eating_spaghetti_8_frames.npy""" elif num_frames == 16: snake_case_ :int = """eating_spaghetti.npy""" elif num_frames == 32: snake_case_ :List[str] = """eating_spaghetti_32_frames.npy""" snake_case_ :int = hf_hub_download( repo_id="""hf-internal-testing/spaghetti-video""", filename=_lowercase, repo_type="""dataset""", ) snake_case_ :Union[str, Any] = np.load(_lowercase ) return list(_lowercase ) def A_ ( _lowercase, _lowercase=None, _lowercase=False ): '''simple docstring''' snake_case_ :List[Any] = { # fully supervised kinetics-400 checkpoints """xclip-base-patch32""": """https://github.com/nbl97/X-CLIP_Model_Zoo/releases/download/v1.0/k400_32_8.pth""", """xclip-base-patch32-16-frames""": ( """https://github.com/nbl97/X-CLIP_Model_Zoo/releases/download/v1.0/k400_32_16.pth""" ), """xclip-base-patch16""": """https://github.com/nbl97/X-CLIP_Model_Zoo/releases/download/v1.0/k400_16_8.pth""", """xclip-base-patch16-16-frames""": ( """https://github.com/nbl97/X-CLIP_Model_Zoo/releases/download/v1.0/k400_16_16.pth""" ), """xclip-large-patch14""": """https://drive.google.com/u/0/uc?id=1NUOImq0o5DlQTST17iIP3vG7DgmHQuCx&amp;export=download&amp;confirm=t&amp;uuid=b26caedc-88e2-473e-830a-9d158b653cdb""", """xclip-large-patch14-16-frames""": """https://drive.google.com/u/0/uc?id=1FOYgnJc097OJ4lGwtRCCydQyVPJEOH7d&amp;export=download&amp;confirm=t&amp;uuid=538fa810-e671-4050-b385-9a623f89804f""", # fully supervised kinetics-600 checkpoints """xclip-base-patch16-kinetics-600""": ( """https://github.com/nbl97/X-CLIP_Model_Zoo/releases/download/v1.0/k600_16_8.pth""" ), """xclip-base-patch16-kinetics-600-16-frames""": ( """https://github.com/nbl97/X-CLIP_Model_Zoo/releases/download/v1.0/k600_16_16.pth""" ), """xclip-large-patch14-kinetics-600""": """https://drive.google.com/u/0/uc?id=1FV8C1INuM91sLAN4ImjzePLIlpMSihwV&amp;export=download&amp;confirm=t&amp;uuid=141d4977-4a65-44ae-864f-4b0c19f838be""", # few shot """xclip-base-patch16-hmdb-2-shot""": ( """https://github.com/nbl97/X-CLIP_Model_Zoo/releases/download/v1.0/few_hmdb_2.pth""" ), """xclip-base-patch16-hmdb-4-shot""": ( """https://github.com/nbl97/X-CLIP_Model_Zoo/releases/download/v1.0/few_hmdb_4.pth""" ), """xclip-base-patch16-hmdb-8-shot""": ( """https://github.com/nbl97/X-CLIP_Model_Zoo/releases/download/v1.0/few_hmdb_8.pth""" ), """xclip-base-patch16-hmdb-16-shot""": ( """https://github.com/nbl97/X-CLIP_Model_Zoo/releases/download/v1.0/few_hmdb_16.pth""" ), """xclip-base-patch16-ucf-2-shot""": ( """https://github.com/nbl97/X-CLIP_Model_Zoo/releases/download/v1.0/few_ucf_2.pth""" ), """xclip-base-patch16-ucf-4-shot""": ( """https://github.com/nbl97/X-CLIP_Model_Zoo/releases/download/v1.0/few_ucf_4.pth""" ), """xclip-base-patch16-ucf-8-shot""": ( """https://github.com/nbl97/X-CLIP_Model_Zoo/releases/download/v1.0/few_ucf_8.pth""" ), """xclip-base-patch16-ucf-16-shot""": ( """https://github.com/nbl97/X-CLIP_Model_Zoo/releases/download/v1.0/few_ucf_16.pth""" ), # zero shot """xclip-base-patch16-zero-shot""": """https://github.com/nbl97/X-CLIP_Model_Zoo/releases/download/v1.0/zero.pth""", } snake_case_ :Optional[int] = model_to_url[model_name] snake_case_ :int = 8 if "16-frames" in model_name: snake_case_ :List[Any] = 16 elif "shot" in model_name: snake_case_ :Dict = 32 snake_case_ :Optional[int] = get_xclip_config(_lowercase, _lowercase ) snake_case_ :Optional[Any] = XCLIPModel(_lowercase ) model.eval() if "drive" in checkpoint_url: snake_case_ :List[str] = """pytorch_model.bin""" gdown.cached_download(_lowercase, _lowercase, quiet=_lowercase ) snake_case_ :List[Any] = torch.load(_lowercase, map_location="""cpu""" )["""model"""] else: snake_case_ :Tuple = torch.hub.load_state_dict_from_url(_lowercase )["""model"""] snake_case_ :Union[str, Any] = convert_state_dict(_lowercase, _lowercase ) snake_case_ :str = XCLIPModel(_lowercase ) snake_case_, snake_case_ :Optional[int] = model.load_state_dict(_lowercase, strict=_lowercase ) assert missing_keys == ["text_model.embeddings.position_ids", "vision_model.embeddings.position_ids"] model.eval() snake_case_ :List[str] = 336 if model_name == """xclip-large-patch14-16-frames""" else 224 snake_case_ :List[Any] = VideoMAEImageProcessor(size=_lowercase ) snake_case_ :Any = CLIPTokenizer.from_pretrained("""openai/clip-vit-base-patch32""" ) snake_case_ :str = CLIPTokenizerFast.from_pretrained("""openai/clip-vit-base-patch32""" ) snake_case_ :Optional[Any] = XCLIPProcessor(image_processor=_lowercase, tokenizer=_lowercase ) snake_case_ :Optional[int] = prepare_video(_lowercase ) snake_case_ :Optional[Any] = processor( text=["""playing sports""", """eating spaghetti""", """go shopping"""], videos=_lowercase, return_tensors="""pt""", padding=_lowercase ) print("""Shape of pixel values:""", inputs.pixel_values.shape ) with torch.no_grad(): snake_case_ :List[Any] = model(**_lowercase ) # Verify outputs snake_case_ :List[Any] = outputs.logits_per_video snake_case_ :Any = logits_per_video.softmax(dim=1 ) print("""Probs:""", _lowercase ) # kinetics-400 if model_name == "xclip-base-patch32": snake_case_ :Union[str, Any] = torch.tensor([[0.0019, 0.9951, 0.0030]] ) elif model_name == "xclip-base-patch32-16-frames": snake_case_ :str = torch.tensor([[7.09_99e-04, 9.98_83e-01, 4.55_80e-04]] ) elif model_name == "xclip-base-patch16": snake_case_ :Tuple = torch.tensor([[0.0083, 0.9681, 0.0236]] ) elif model_name == "xclip-base-patch16-16-frames": snake_case_ :Any = torch.tensor([[7.69_37e-04, 9.97_28e-01, 1.94_73e-03]] ) elif model_name == "xclip-large-patch14": snake_case_ :str = torch.tensor([[0.0062, 0.9864, 0.0075]] ) elif model_name == "xclip-large-patch14-16-frames": snake_case_ :Tuple = torch.tensor([[3.38_77e-04, 9.99_37e-01, 2.88_88e-04]] ) # kinetics-600 elif model_name == "xclip-base-patch16-kinetics-600": snake_case_ :List[Any] = torch.tensor([[0.0555, 0.8914, 0.0531]] ) elif model_name == "xclip-base-patch16-kinetics-600-16-frames": snake_case_ :Union[str, Any] = torch.tensor([[3.85_54e-04, 9.99_29e-01, 3.27_54e-04]] ) elif model_name == "xclip-large-patch14-kinetics-600": snake_case_ :List[Any] = torch.tensor([[0.0036, 0.9920, 0.0045]] ) # few shot elif model_name == "xclip-base-patch16-hmdb-2-shot": snake_case_ :Dict = torch.tensor([[7.18_90e-06, 9.99_94e-01, 5.65_59e-05]] ) elif model_name == "xclip-base-patch16-hmdb-4-shot": snake_case_ :Union[str, Any] = torch.tensor([[1.03_20e-05, 9.99_93e-01, 6.24_35e-05]] ) elif model_name == "xclip-base-patch16-hmdb-8-shot": snake_case_ :str = torch.tensor([[4.13_77e-06, 9.99_90e-01, 9.83_86e-05]] ) elif model_name == "xclip-base-patch16-hmdb-16-shot": snake_case_ :str = torch.tensor([[4.13_47e-05, 9.99_62e-01, 3.34_11e-04]] ) elif model_name == "xclip-base-patch16-ucf-2-shot": snake_case_ :int = torch.tensor([[8.58_57e-05, 9.99_28e-01, 6.32_91e-04]] ) elif model_name == "xclip-base-patch16-ucf-4-shot": snake_case_ :Optional[int] = torch.tensor([[8.58_57e-05, 9.99_28e-01, 6.32_91e-04]] ) elif model_name == "xclip-base-patch16-ucf-8-shot": snake_case_ :Any = torch.tensor([[0.0027, 0.9904, 0.0070]] ) elif model_name == "xclip-base-patch16-ucf-16-shot": snake_case_ :Tuple = torch.tensor([[9.82_19e-04, 9.95_93e-01, 3.08_63e-03]] ) # zero shot elif model_name == "xclip-base-patch16-zero-shot": snake_case_ :Union[str, Any] = torch.tensor([[3.50_82e-04, 9.97_85e-01, 1.79_66e-03]] ) else: raise ValueError(f"""Model name {model_name} not supported""" ) assert torch.allclose(_lowercase, _lowercase, atol=1e-3 ) print("""Looks ok!""" ) if pytorch_dump_folder_path is not None: print(f"""Saving model {model_name} to {pytorch_dump_folder_path}""" ) model.save_pretrained(_lowercase ) if push_to_hub: print("""Pushing model, processor and slow tokenizer files to the hub...""" ) model.push_to_hub(_lowercase, organization="""nielsr""" ) processor.push_to_hub(_lowercase, organization="""nielsr""" ) slow_tokenizer.push_to_hub(_lowercase, organization="""nielsr""" ) if __name__ == "__main__": __a = argparse.ArgumentParser() # Required parameters parser.add_argument( "--model_name", default="xclip-base-patch32", type=str, help="Name of the model.", ) 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 = parser.parse_args() convert_xclip_checkpoint(args.model_name, args.pytorch_dump_folder_path, args.push_to_hub)
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1
"""simple docstring""" from typing import TYPE_CHECKING from ...utils import OptionalDependencyNotAvailable, _LazyModule, is_tf_available, is_torch_available __a = { "configuration_data2vec_audio": ["DATA2VEC_AUDIO_PRETRAINED_CONFIG_ARCHIVE_MAP", "Data2VecAudioConfig"], "configuration_data2vec_text": [ "DATA2VEC_TEXT_PRETRAINED_CONFIG_ARCHIVE_MAP", "Data2VecTextConfig", "Data2VecTextOnnxConfig", ], "configuration_data2vec_vision": [ "DATA2VEC_VISION_PRETRAINED_CONFIG_ARCHIVE_MAP", "Data2VecVisionConfig", "Data2VecVisionOnnxConfig", ], } try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __a = [ "DATA2VEC_AUDIO_PRETRAINED_MODEL_ARCHIVE_LIST", "Data2VecAudioForAudioFrameClassification", "Data2VecAudioForCTC", "Data2VecAudioForSequenceClassification", "Data2VecAudioForXVector", "Data2VecAudioModel", "Data2VecAudioPreTrainedModel", ] __a = [ "DATA2VEC_TEXT_PRETRAINED_MODEL_ARCHIVE_LIST", "Data2VecTextForCausalLM", "Data2VecTextForMaskedLM", "Data2VecTextForMultipleChoice", "Data2VecTextForQuestionAnswering", "Data2VecTextForSequenceClassification", "Data2VecTextForTokenClassification", "Data2VecTextModel", "Data2VecTextPreTrainedModel", ] __a = [ "DATA2VEC_VISION_PRETRAINED_MODEL_ARCHIVE_LIST", "Data2VecVisionForImageClassification", "Data2VecVisionForMaskedImageModeling", "Data2VecVisionForSemanticSegmentation", "Data2VecVisionModel", "Data2VecVisionPreTrainedModel", ] if is_tf_available(): __a = [ "TFData2VecVisionForImageClassification", "TFData2VecVisionForSemanticSegmentation", "TFData2VecVisionModel", "TFData2VecVisionPreTrainedModel", ] if TYPE_CHECKING: from .configuration_dataavec_audio import DATA2VEC_AUDIO_PRETRAINED_CONFIG_ARCHIVE_MAP, DataaVecAudioConfig from .configuration_dataavec_text import ( DATA2VEC_TEXT_PRETRAINED_CONFIG_ARCHIVE_MAP, DataaVecTextConfig, DataaVecTextOnnxConfig, ) from .configuration_dataavec_vision import ( DATA2VEC_VISION_PRETRAINED_CONFIG_ARCHIVE_MAP, DataaVecVisionConfig, DataaVecVisionOnnxConfig, ) try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_dataavec_audio import ( DATA2VEC_AUDIO_PRETRAINED_MODEL_ARCHIVE_LIST, DataaVecAudioForAudioFrameClassification, DataaVecAudioForCTC, DataaVecAudioForSequenceClassification, DataaVecAudioForXVector, DataaVecAudioModel, DataaVecAudioPreTrainedModel, ) from .modeling_dataavec_text import ( DATA2VEC_TEXT_PRETRAINED_MODEL_ARCHIVE_LIST, DataaVecTextForCausalLM, DataaVecTextForMaskedLM, DataaVecTextForMultipleChoice, DataaVecTextForQuestionAnswering, DataaVecTextForSequenceClassification, DataaVecTextForTokenClassification, DataaVecTextModel, DataaVecTextPreTrainedModel, ) from .modeling_dataavec_vision import ( DATA2VEC_VISION_PRETRAINED_MODEL_ARCHIVE_LIST, DataaVecVisionForImageClassification, DataaVecVisionForMaskedImageModeling, DataaVecVisionForSemanticSegmentation, DataaVecVisionModel, DataaVecVisionPreTrainedModel, ) if is_tf_available(): from .modeling_tf_dataavec_vision import ( TFDataaVecVisionForImageClassification, TFDataaVecVisionForSemanticSegmentation, TFDataaVecVisionModel, TFDataaVecVisionPreTrainedModel, ) else: import sys __a = _LazyModule(__name__, globals()["__file__"], _import_structure, module_spec=__spec__)
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"""simple docstring""" import unittest import numpy as np from transformers import BertConfig, is_flax_available from transformers.testing_utils import require_flax, slow from ...test_modeling_flax_common import FlaxModelTesterMixin, floats_tensor, ids_tensor, random_attention_mask if is_flax_available(): from transformers.models.bert.modeling_flax_bert import ( FlaxBertForMaskedLM, FlaxBertForMultipleChoice, FlaxBertForNextSentencePrediction, FlaxBertForPreTraining, FlaxBertForQuestionAnswering, FlaxBertForSequenceClassification, FlaxBertForTokenClassification, FlaxBertModel, ) class lowerCamelCase ( unittest.TestCase ): '''simple docstring''' def __init__( self: List[Any] , snake_case: List[str] , snake_case: Optional[Any]=13 , snake_case: List[str]=7 , snake_case: Dict=True , snake_case: List[str]=True , snake_case: Optional[int]=True , snake_case: Any=True , snake_case: Optional[Any]=99 , snake_case: Tuple=32 , snake_case: Tuple=5 , snake_case: Dict=4 , snake_case: Optional[Any]=37 , snake_case: Union[str, Any]="gelu" , snake_case: Tuple=0.1 , snake_case: List[Any]=0.1 , snake_case: List[str]=512 , snake_case: Optional[int]=16 , snake_case: int=2 , snake_case: List[Any]=0.0_2 , snake_case: Union[str, Any]=4 , ) -> List[str]: snake_case_ :Dict = parent snake_case_ :Any = batch_size snake_case_ :Any = seq_length snake_case_ :List[str] = is_training snake_case_ :Optional[Any] = use_attention_mask snake_case_ :Dict = use_token_type_ids snake_case_ :Union[str, Any] = use_labels snake_case_ :str = vocab_size snake_case_ :int = hidden_size snake_case_ :List[str] = num_hidden_layers snake_case_ :Dict = num_attention_heads snake_case_ :Any = intermediate_size snake_case_ :Tuple = hidden_act snake_case_ :int = hidden_dropout_prob snake_case_ :Optional[Any] = attention_probs_dropout_prob snake_case_ :Any = max_position_embeddings snake_case_ :Union[str, Any] = type_vocab_size snake_case_ :Optional[int] = type_sequence_label_size snake_case_ :Union[str, Any] = initializer_range snake_case_ :Tuple = num_choices def lowerCAmelCase_ ( self: Tuple ) -> str: snake_case_ :Optional[Any] = ids_tensor([self.batch_size, self.seq_length] , self.vocab_size ) snake_case_ :Union[str, Any] = None if self.use_attention_mask: snake_case_ :str = random_attention_mask([self.batch_size, self.seq_length] ) snake_case_ :Any = None if self.use_token_type_ids: snake_case_ :List[str] = ids_tensor([self.batch_size, self.seq_length] , self.type_vocab_size ) snake_case_ :int = BertConfig( 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 , ) return config, input_ids, token_type_ids, attention_mask def lowerCAmelCase_ ( self: Optional[int] ) -> int: snake_case_ :str = self.prepare_config_and_inputs() snake_case_, snake_case_, snake_case_, snake_case_ :Optional[int] = config_and_inputs snake_case_ :Union[str, Any] = {"""input_ids""": input_ids, """token_type_ids""": token_type_ids, """attention_mask""": attention_mask} return config, inputs_dict def lowerCAmelCase_ ( self: Optional[Any] ) -> Any: snake_case_ :int = self.prepare_config_and_inputs() snake_case_, snake_case_, snake_case_, snake_case_ :Dict = config_and_inputs snake_case_ :Union[str, Any] = True snake_case_ :Optional[int] = floats_tensor([self.batch_size, self.seq_length, self.hidden_size] ) snake_case_ :Tuple = ids_tensor([self.batch_size, self.seq_length] , vocab_size=2 ) return ( config, input_ids, attention_mask, encoder_hidden_states, encoder_attention_mask, ) @require_flax class lowerCamelCase ( _lowerCAmelCase , unittest.TestCase ): '''simple docstring''' _A : List[str] = True _A : Dict = ( ( FlaxBertModel, FlaxBertForPreTraining, FlaxBertForMaskedLM, FlaxBertForMultipleChoice, FlaxBertForQuestionAnswering, FlaxBertForNextSentencePrediction, FlaxBertForSequenceClassification, FlaxBertForTokenClassification, FlaxBertForQuestionAnswering, ) if is_flax_available() else () ) def lowerCAmelCase_ ( self: int ) -> List[str]: snake_case_ :Any = FlaxBertModelTester(self ) @slow def lowerCAmelCase_ ( self: List[str] ) -> Dict: # Only check this for base model, not necessary for all model classes. # This will also help speed-up tests. snake_case_ :Dict = FlaxBertModel.from_pretrained("""bert-base-cased""" ) snake_case_ :Dict = model(np.ones((1, 1) ) ) self.assertIsNotNone(snake_case )
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"""simple docstring""" 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 lowerCamelCase ( _lowerCAmelCase , _lowerCAmelCase , unittest.TestCase ): '''simple docstring''' _A : int = StableDiffusionPanoramaPipeline _A : Optional[Any] = TEXT_TO_IMAGE_PARAMS _A : List[Any] = TEXT_TO_IMAGE_BATCH_PARAMS _A : Union[str, Any] = TEXT_TO_IMAGE_IMAGE_PARAMS _A : Dict = TEXT_TO_IMAGE_IMAGE_PARAMS def lowerCAmelCase_ ( self: List[Any] ) -> Union[str, Any]: torch.manual_seed(0 ) snake_case_ :Tuple = UNetaDConditionModel( block_out_channels=(32, 64) , layers_per_block=1 , sample_size=32 , in_channels=4 , out_channels=4 , down_block_types=("""DownBlock2D""", """CrossAttnDownBlock2D""") , up_block_types=("""CrossAttnUpBlock2D""", """UpBlock2D""") , cross_attention_dim=32 , ) snake_case_ :Dict = DDIMScheduler() torch.manual_seed(0 ) snake_case_ :Dict = AutoencoderKL( block_out_channels=[32, 64] , in_channels=3 , out_channels=3 , down_block_types=["""DownEncoderBlock2D""", """DownEncoderBlock2D"""] , up_block_types=["""UpDecoderBlock2D""", """UpDecoderBlock2D"""] , latent_channels=4 , ) torch.manual_seed(0 ) snake_case_ :Optional[int] = CLIPTextConfig( bos_token_id=0 , eos_token_id=2 , hidden_size=32 , intermediate_size=37 , layer_norm_eps=1E-05 , num_attention_heads=4 , num_hidden_layers=5 , pad_token_id=1 , vocab_size=1_000 , ) snake_case_ :Optional[Any] = CLIPTextModel(snake_case ) snake_case_ :str = CLIPTokenizer.from_pretrained("""hf-internal-testing/tiny-random-clip""" ) snake_case_ :int = { """unet""": unet, """scheduler""": scheduler, """vae""": vae, """text_encoder""": text_encoder, """tokenizer""": tokenizer, """safety_checker""": None, """feature_extractor""": None, } return components def lowerCAmelCase_ ( self: int , snake_case: Optional[Any] , snake_case: List[str]=0 ) -> str: snake_case_ :List[Any] = torch.manual_seed(snake_case ) snake_case_ :Dict = { """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 lowerCAmelCase_ ( self: Union[str, Any] ) -> Optional[int]: snake_case_ :Union[str, Any] = """cpu""" # ensure determinism for the device-dependent torch.Generator snake_case_ :int = self.get_dummy_components() snake_case_ :List[str] = StableDiffusionPanoramaPipeline(**snake_case ) snake_case_ :List[str] = sd_pipe.to(snake_case ) sd_pipe.set_progress_bar_config(disable=snake_case ) snake_case_ :Dict = self.get_dummy_inputs(snake_case ) snake_case_ :Any = sd_pipe(**snake_case ).images snake_case_ :Optional[int] = image[0, -3:, -3:, -1] assert image.shape == (1, 64, 64, 3) snake_case_ :List[Any] = np.array([0.6_1_8_6, 0.5_3_7_4, 0.4_9_1_5, 0.4_1_3_5, 0.4_1_1_4, 0.4_5_6_3, 0.5_1_2_8, 0.4_9_7_7, 0.4_7_5_7] ) assert np.abs(image_slice.flatten() - expected_slice ).max() < 1E-2 def lowerCAmelCase_ ( self: Optional[int] ) -> Union[str, Any]: super().test_inference_batch_consistent(batch_sizes=[1, 2] ) def lowerCAmelCase_ ( self: Any ) -> Optional[Any]: super().test_inference_batch_single_identical(batch_size=2 , expected_max_diff=3.25E-3 ) def lowerCAmelCase_ ( self: Dict ) -> Optional[Any]: snake_case_ :str = """cpu""" # ensure determinism for the device-dependent torch.Generator snake_case_ :str = self.get_dummy_components() snake_case_ :int = StableDiffusionPanoramaPipeline(**snake_case ) snake_case_ :Optional[int] = sd_pipe.to(snake_case ) sd_pipe.set_progress_bar_config(disable=snake_case ) snake_case_ :Any = self.get_dummy_inputs(snake_case ) snake_case_ :Optional[Any] = """french fries""" snake_case_ :Optional[Any] = sd_pipe(**snake_case , negative_prompt=snake_case ) snake_case_ :int = output.images snake_case_ :List[str] = image[0, -3:, -3:, -1] assert image.shape == (1, 64, 64, 3) snake_case_ :Union[str, Any] = np.array([0.6_1_8_7, 0.5_3_7_5, 0.4_9_1_5, 0.4_1_3_6, 0.4_1_1_4, 0.4_5_6_3, 0.5_1_2_8, 0.4_9_7_6, 0.4_7_5_7] ) assert np.abs(image_slice.flatten() - expected_slice ).max() < 1E-2 def lowerCAmelCase_ ( self: Tuple ) -> Optional[int]: snake_case_ :List[str] = """cpu""" # ensure determinism for the device-dependent torch.Generator snake_case_ :Optional[int] = self.get_dummy_components() snake_case_ :List[Any] = StableDiffusionPanoramaPipeline(**snake_case ) snake_case_ :Optional[Any] = sd_pipe.to(snake_case ) sd_pipe.set_progress_bar_config(disable=snake_case ) snake_case_ :Tuple = self.get_dummy_inputs(snake_case ) snake_case_ :Optional[int] = sd_pipe(**snake_case , view_batch_size=2 ) snake_case_ :Dict = output.images snake_case_ :List[str] = image[0, -3:, -3:, -1] assert image.shape == (1, 64, 64, 3) snake_case_ :Dict = np.array([0.6_1_8_7, 0.5_3_7_5, 0.4_9_1_5, 0.4_1_3_6, 0.4_1_1_4, 0.4_5_6_3, 0.5_1_2_8, 0.4_9_7_6, 0.4_7_5_7] ) assert np.abs(image_slice.flatten() - expected_slice ).max() < 1E-2 def lowerCAmelCase_ ( self: Dict ) -> str: snake_case_ :Tuple = """cpu""" # ensure determinism for the device-dependent torch.Generator snake_case_ :Optional[int] = self.get_dummy_components() snake_case_ :int = EulerAncestralDiscreteScheduler( beta_start=0.0_0_0_8_5 , beta_end=0.0_1_2 , beta_schedule="""scaled_linear""" ) snake_case_ :Any = StableDiffusionPanoramaPipeline(**snake_case ) snake_case_ :Optional[int] = sd_pipe.to(snake_case ) sd_pipe.set_progress_bar_config(disable=snake_case ) snake_case_ :str = self.get_dummy_inputs(snake_case ) snake_case_ :Tuple = sd_pipe(**snake_case ).images snake_case_ :Tuple = image[0, -3:, -3:, -1] assert image.shape == (1, 64, 64, 3) snake_case_ :Any = np.array([0.4_0_2_4, 0.6_5_1_0, 0.4_9_0_1, 0.5_3_7_8, 0.5_8_1_3, 0.5_6_2_2, 0.4_7_9_5, 0.4_4_6_7, 0.4_9_5_2] ) assert np.abs(image_slice.flatten() - expected_slice ).max() < 1E-2 def lowerCAmelCase_ ( self: Optional[Any] ) -> Any: snake_case_ :Union[str, Any] = """cpu""" # ensure determinism for the device-dependent torch.Generator snake_case_ :Dict = self.get_dummy_components() snake_case_ :List[str] = PNDMScheduler( beta_start=0.0_0_0_8_5 , beta_end=0.0_1_2 , beta_schedule="""scaled_linear""" , skip_prk_steps=snake_case ) snake_case_ :Optional[Any] = StableDiffusionPanoramaPipeline(**snake_case ) snake_case_ :Union[str, Any] = sd_pipe.to(snake_case ) sd_pipe.set_progress_bar_config(disable=snake_case ) snake_case_ :int = self.get_dummy_inputs(snake_case ) snake_case_ :Tuple = sd_pipe(**snake_case ).images snake_case_ :Optional[int] = image[0, -3:, -3:, -1] assert image.shape == (1, 64, 64, 3) snake_case_ :int = np.array([0.6_3_9_1, 0.6_2_9_1, 0.4_8_6_1, 0.5_1_3_4, 0.5_5_5_2, 0.4_5_7_8, 0.5_0_3_2, 0.5_0_2_3, 0.4_5_3_9] ) assert np.abs(image_slice.flatten() - expected_slice ).max() < 1E-2 @slow @require_torch_gpu class lowerCamelCase ( unittest.TestCase ): '''simple docstring''' def lowerCAmelCase_ ( self: Dict ) -> Union[str, Any]: super().tearDown() gc.collect() torch.cuda.empty_cache() def lowerCAmelCase_ ( self: Any , snake_case: Union[str, Any]=0 ) -> int: snake_case_ :str = torch.manual_seed(snake_case ) snake_case_ :Optional[int] = { """prompt""": """a photo of the dolomites""", """generator""": generator, """num_inference_steps""": 3, """guidance_scale""": 7.5, """output_type""": """numpy""", } return inputs def lowerCAmelCase_ ( self: Union[str, Any] ) -> Optional[Any]: snake_case_ :List[str] = """stabilityai/stable-diffusion-2-base""" snake_case_ :Optional[Any] = DDIMScheduler.from_pretrained(snake_case , subfolder="""scheduler""" ) snake_case_ :Union[str, Any] = 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() snake_case_ :int = self.get_inputs() snake_case_ :str = pipe(**snake_case ).images snake_case_ :int = image[0, -3:, -3:, -1].flatten() assert image.shape == (1, 512, 2_048, 3) snake_case_ :Union[str, Any] = np.array( [ 0.3_6_9_6_8_3_9_2, 0.2_7_0_2_5_3_7_2, 0.3_2_4_4_6_7_6_6, 0.2_8_3_7_9_3_8_7, 0.3_6_3_6_3_2_7_4, 0.3_0_7_3_3_3_4_7, 0.2_7_1_0_0_0_2_7, 0.2_7_0_5_4_1_2_5, 0.2_5_5_3_6_0_9_6, ] ) assert np.abs(expected_slice - image_slice ).max() < 1E-2 def lowerCAmelCase_ ( self: int ) -> Tuple: snake_case_ :Any = StableDiffusionPanoramaPipeline.from_pretrained( """stabilityai/stable-diffusion-2-base""" , safety_checker=snake_case ) snake_case_ :Dict = LMSDiscreteScheduler.from_config(pipe.scheduler.config ) pipe.to(snake_case ) pipe.set_progress_bar_config(disable=snake_case ) pipe.enable_attention_slicing() snake_case_ :str = self.get_inputs() snake_case_ :List[Any] = pipe(**snake_case ).images snake_case_ :Any = image[0, -3:, -3:, -1].flatten() assert image.shape == (1, 512, 2_048, 3) snake_case_ :str = 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 lowerCAmelCase_ ( self: List[Any] ) -> int: snake_case_ :Any = 0 def callback_fn(snake_case: int , snake_case: int , snake_case: torch.FloatTensor ) -> None: snake_case_ :Union[str, Any] = True nonlocal number_of_steps number_of_steps += 1 if step == 1: snake_case_ :Optional[int] = latents.detach().cpu().numpy() assert latents.shape == (1, 4, 64, 256) snake_case_ :List[str] = latents[0, -3:, -3:, -1] snake_case_ :Optional[Any] = np.array( [ 0.1_8_6_8_1_8_6_9, 0.3_3_9_0_7_8_1_6, 0.5_3_6_1_2_7_6, 0.1_4_4_3_2_8_6_5, -0.0_2_8_5_6_6_1_1, -0.7_3_9_4_1_1_2_3, 0.2_3_3_9_7_9_8_7, 0.4_7_3_2_2_6_8_2, -0.3_7_8_2_3_1_6_4, ] ) assert np.abs(latents_slice.flatten() - expected_slice ).max() < 5E-2 elif step == 2: snake_case_ :Optional[int] = latents.detach().cpu().numpy() assert latents.shape == (1, 4, 64, 256) snake_case_ :Any = latents[0, -3:, -3:, -1] snake_case_ :Optional[int] = np.array( [ 0.1_8_5_3_9_6_4_5, 0.3_3_9_8_7_2_4_8, 0.5_3_7_8_5_5_9, 0.1_4_4_3_7_1_4_2, -0.0_2_4_5_5_2_6_1, -0.7_3_3_8_3_1_7, 0.2_3_9_9_0_7_5_5, 0.4_7_3_5_6_2_7_2, -0.3_7_8_6_5_0_5, ] ) assert np.abs(latents_slice.flatten() - expected_slice ).max() < 5E-2 snake_case_ :int = False snake_case_ :Optional[int] = """stabilityai/stable-diffusion-2-base""" snake_case_ :List[Any] = DDIMScheduler.from_pretrained(snake_case , subfolder="""scheduler""" ) snake_case_ :List[str] = StableDiffusionPanoramaPipeline.from_pretrained(snake_case , scheduler=snake_case , safety_checker=snake_case ) snake_case_ :Optional[int] = pipe.to(snake_case ) pipe.set_progress_bar_config(disable=snake_case ) pipe.enable_attention_slicing() snake_case_ :Any = self.get_inputs() pipe(**snake_case , callback=snake_case , callback_steps=1 ) assert callback_fn.has_been_called assert number_of_steps == 3 def lowerCAmelCase_ ( self: Tuple ) -> int: torch.cuda.empty_cache() torch.cuda.reset_max_memory_allocated() torch.cuda.reset_peak_memory_stats() snake_case_ :List[str] = """stabilityai/stable-diffusion-2-base""" snake_case_ :List[str] = DDIMScheduler.from_pretrained(snake_case , subfolder="""scheduler""" ) snake_case_ :Optional[int] = StableDiffusionPanoramaPipeline.from_pretrained(snake_case , scheduler=snake_case , safety_checker=snake_case ) snake_case_ :List[str] = pipe.to(snake_case ) pipe.set_progress_bar_config(disable=snake_case ) pipe.enable_attention_slicing(1 ) pipe.enable_sequential_cpu_offload() snake_case_ :int = self.get_inputs() snake_case_ :List[Any] = pipe(**snake_case ) snake_case_ :int = torch.cuda.max_memory_allocated() # make sure that less than 5.2 GB is allocated assert mem_bytes < 5.5 * 10**9
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"""simple docstring""" import math class lowerCamelCase : '''simple docstring''' def lowerCAmelCase_ ( self: Tuple , snake_case: list[list[float]] , snake_case: list[int] ) -> int: snake_case_ :Any = 0.0 snake_case_ :Tuple = 0.0 for i in range(len(snake_case ) ): da += math.pow((sample[i] - weights[0][i]) , 2 ) da += math.pow((sample[i] - weights[1][i]) , 2 ) return 0 if da > da else 1 return 0 def lowerCAmelCase_ ( self: Optional[int] , snake_case: list[list[int | float]] , snake_case: list[int] , snake_case: int , snake_case: float ) -> list[list[int | float]]: for i in range(len(snake_case ) ): weights[j][i] += alpha * (sample[i] - weights[j][i]) return weights def A_ ( ): '''simple docstring''' snake_case_ :Dict = [[1, 1, 0, 0], [0, 0, 0, 1], [1, 0, 0, 0], [0, 0, 1, 1]] # weight initialization ( n, C ) snake_case_ :List[Any] = [[0.2, 0.6, 0.5, 0.9], [0.8, 0.4, 0.7, 0.3]] # training snake_case_ :Optional[Any] = SelfOrganizingMap() snake_case_ :Dict = 3 snake_case_ :Dict = 0.5 for _ in range(_lowercase ): for j in range(len(_lowercase ) ): # training sample snake_case_ :List[Any] = training_samples[j] # Compute the winning vector snake_case_ :Optional[int] = self_organizing_map.get_winner(_lowercase, _lowercase ) # Update the winning vector snake_case_ :List[str] = self_organizing_map.update(_lowercase, _lowercase, _lowercase, _lowercase ) # classify test sample snake_case_ :str = [0, 0, 0, 1] snake_case_ :List[Any] = self_organizing_map.get_winner(_lowercase, _lowercase ) # results print(f"""Clusters that the test sample belongs to : {winner}""" ) print(f"""Weights that have been trained : {weights}""" ) # running the main() function if __name__ == "__main__": main()
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"""simple docstring""" from ..utils import is_flax_available, is_torch_available if is_torch_available(): from .autoencoder_kl import AutoencoderKL from .controlnet import ControlNetModel from .dual_transformer_ad import DualTransformeraDModel from .modeling_utils import ModelMixin from .prior_transformer import PriorTransformer from .ta_film_transformer import TaFilmDecoder from .transformer_ad import TransformeraDModel from .unet_ad import UNetaDModel from .unet_ad import UNetaDModel from .unet_ad_condition import UNetaDConditionModel from .unet_ad_condition import UNetaDConditionModel from .vq_model import VQModel if is_flax_available(): from .controlnet_flax import FlaxControlNetModel from .unet_ad_condition_flax import FlaxUNetaDConditionModel from .vae_flax import FlaxAutoencoderKL
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"""simple docstring""" 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 : '''simple docstring''' def __init__( self: Optional[int] , snake_case: Any , snake_case: Optional[Any]=13 , snake_case: Tuple=32 , snake_case: Optional[int]=2 , snake_case: Tuple=3 , snake_case: Tuple=16 , snake_case: Optional[Any]=[1, 2, 1] , snake_case: Optional[int]=[2, 2, 4] , snake_case: Optional[int]=2 , snake_case: int=2.0 , snake_case: Union[str, Any]=True , snake_case: List[str]=0.0 , snake_case: List[Any]=0.0 , snake_case: Optional[Any]=0.1 , snake_case: List[Any]="gelu" , snake_case: Optional[int]=False , snake_case: Union[str, Any]=True , snake_case: Union[str, Any]=0.0_2 , snake_case: Optional[int]=1E-5 , snake_case: Optional[Any]=True , snake_case: List[Any]=None , snake_case: List[Any]=True , snake_case: Optional[Any]=10 , snake_case: str=8 , ) -> Tuple: snake_case_ :Dict = parent snake_case_ :Any = batch_size snake_case_ :List[Any] = image_size snake_case_ :List[Any] = patch_size snake_case_ :int = num_channels snake_case_ :Tuple = embed_dim snake_case_ :str = depths snake_case_ :str = num_heads snake_case_ :Optional[int] = window_size snake_case_ :Tuple = mlp_ratio snake_case_ :Any = qkv_bias snake_case_ :List[Any] = hidden_dropout_prob snake_case_ :Optional[Any] = attention_probs_dropout_prob snake_case_ :Union[str, Any] = drop_path_rate snake_case_ :Any = hidden_act snake_case_ :Optional[Any] = use_absolute_embeddings snake_case_ :Union[str, Any] = patch_norm snake_case_ :Dict = layer_norm_eps snake_case_ :str = initializer_range snake_case_ :Tuple = is_training snake_case_ :Tuple = scope snake_case_ :Union[str, Any] = use_labels snake_case_ :Optional[Any] = type_sequence_label_size snake_case_ :Dict = encoder_stride def lowerCAmelCase_ ( self: int ) -> int: snake_case_ :List[str] = floats_tensor([self.batch_size, self.num_channels, self.image_size, self.image_size] ) snake_case_ :Any = None if self.use_labels: snake_case_ :str = ids_tensor([self.batch_size] , self.type_sequence_label_size ) snake_case_ :int = self.get_config() return config, pixel_values, labels def lowerCAmelCase_ ( self: str ) -> Union[str, Any]: 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 lowerCAmelCase_ ( self: str , snake_case: Optional[int] , snake_case: Dict , snake_case: str ) -> List[Any]: snake_case_ :Union[str, Any] = SwinvaModel(config=snake_case ) model.to(snake_case ) model.eval() snake_case_ :Optional[int] = model(snake_case ) snake_case_ :Optional[Any] = ((config.image_size // config.patch_size) ** 2) // (4 ** (len(config.depths ) - 1)) snake_case_ :int = 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 lowerCAmelCase_ ( self: int , snake_case: List[str] , snake_case: Tuple , snake_case: int ) -> Any: snake_case_ :Dict = SwinvaForMaskedImageModeling(config=snake_case ) model.to(snake_case ) model.eval() snake_case_ :Tuple = 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_ :List[Any] = 1 snake_case_ :int = SwinvaForMaskedImageModeling(snake_case ) model.to(snake_case ) model.eval() snake_case_ :Union[str, Any] = floats_tensor([self.batch_size, 1, self.image_size, self.image_size] ) snake_case_ :int = model(snake_case ) self.parent.assertEqual(result.logits.shape , (self.batch_size, 1, self.image_size, self.image_size) ) def lowerCAmelCase_ ( self: List[Any] , snake_case: Any , snake_case: List[str] , snake_case: Union[str, Any] ) -> Tuple: snake_case_ :int = self.type_sequence_label_size snake_case_ :List[Any] = SwinvaForImageClassification(snake_case ) model.to(snake_case ) model.eval() snake_case_ :Dict = model(snake_case , labels=snake_case ) self.parent.assertEqual(result.logits.shape , (self.batch_size, self.type_sequence_label_size) ) def lowerCAmelCase_ ( self: int ) -> str: snake_case_ :Any = self.prepare_config_and_inputs() snake_case_, snake_case_, snake_case_ :List[str] = config_and_inputs snake_case_ :List[Any] = {"""pixel_values""": pixel_values} return config, inputs_dict @require_torch class lowerCamelCase ( _lowerCAmelCase , _lowerCAmelCase , unittest.TestCase ): '''simple docstring''' _A : Optional[Any] = ( (SwinvaModel, SwinvaForImageClassification, SwinvaForMaskedImageModeling) if is_torch_available() else () ) _A : Any = ( {"""feature-extraction""": SwinvaModel, """image-classification""": SwinvaForImageClassification} if is_torch_available() else {} ) _A : List[Any] = False _A : List[str] = False _A : Tuple = False _A : List[str] = False def lowerCAmelCase_ ( self: Dict ) -> List[Any]: snake_case_ :Optional[int] = SwinvaModelTester(self ) snake_case_ :List[str] = ConfigTester(self , config_class=snake_case , embed_dim=37 ) def lowerCAmelCase_ ( self: Union[str, Any] ) -> List[Any]: 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 lowerCAmelCase_ ( self: Union[str, Any] ) -> Tuple: snake_case_ :List[str] = 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 lowerCAmelCase_ ( self: Union[str, Any] ) -> str: pass @unittest.skip(reason="""Swinv2 does not use inputs_embeds""" ) def lowerCAmelCase_ ( self: int ) -> Dict: pass def lowerCAmelCase_ ( self: List[str] ) -> Union[str, Any]: snake_case_, snake_case_ :List[str] = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: snake_case_ :Optional[int] = model_class(snake_case ) self.assertIsInstance(model.get_input_embeddings() , (nn.Module) ) snake_case_ :List[Any] = model.get_output_embeddings() self.assertTrue(x is None or isinstance(snake_case , nn.Linear ) ) def lowerCAmelCase_ ( self: Dict ) -> Optional[int]: snake_case_, snake_case_ :Union[str, Any] = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: snake_case_ :Optional[int] = model_class(snake_case ) snake_case_ :List[Any] = inspect.signature(model.forward ) # signature.parameters is an OrderedDict => so arg_names order is deterministic snake_case_ :int = [*signature.parameters.keys()] snake_case_ :List[Any] = ["""pixel_values"""] self.assertListEqual(arg_names[:1] , snake_case ) def lowerCAmelCase_ ( self: List[str] ) -> Optional[Any]: snake_case_, snake_case_ :List[str] = self.model_tester.prepare_config_and_inputs_for_common() snake_case_ :List[str] = True for model_class in self.all_model_classes: snake_case_ :List[Any] = True snake_case_ :Any = False snake_case_ :Optional[int] = True snake_case_ :Tuple = model_class(snake_case ) model.to(snake_case ) model.eval() with torch.no_grad(): snake_case_ :Any = model(**self._prepare_for_class(snake_case , snake_case ) ) snake_case_ :str = outputs.attentions snake_case_ :Dict = 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_ :Union[str, Any] = True snake_case_ :Tuple = config.window_size**2 snake_case_ :Any = model_class(snake_case ) model.to(snake_case ) model.eval() with torch.no_grad(): snake_case_ :Union[str, Any] = model(**self._prepare_for_class(snake_case , snake_case ) ) snake_case_ :int = 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_ :Any = len(snake_case ) # Check attention is always last and order is fine snake_case_ :int = True snake_case_ :Dict = True snake_case_ :Optional[int] = model_class(snake_case ) model.to(snake_case ) model.eval() with torch.no_grad(): snake_case_ :Dict = model(**self._prepare_for_class(snake_case , snake_case ) ) if hasattr(self.model_tester , """num_hidden_states_types""" ): snake_case_ :Any = self.model_tester.num_hidden_states_types else: # also another +1 for reshaped_hidden_states snake_case_ :int = 2 self.assertEqual(out_len + added_hidden_states , len(snake_case ) ) snake_case_ :str = 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 lowerCAmelCase_ ( self: int , snake_case: Dict , snake_case: Dict , snake_case: Optional[Any] , snake_case: Dict ) -> List[str]: snake_case_ :Dict = 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_ :str = outputs.hidden_states snake_case_ :List[Any] = 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_ :List[Any] = ( config.patch_size if isinstance(config.patch_size , collections.abc.Iterable ) else (config.patch_size, config.patch_size) ) snake_case_ :Optional[int] = (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_ :str = outputs.reshaped_hidden_states self.assertEqual(len(snake_case ) , snake_case ) snake_case_, snake_case_, snake_case_, snake_case_ :Any = reshaped_hidden_states[0].shape snake_case_ :int = ( 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 lowerCAmelCase_ ( self: Any ) -> Any: snake_case_, snake_case_ :List[Any] = self.model_tester.prepare_config_and_inputs_for_common() 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) ) for model_class in self.all_model_classes: snake_case_ :Union[str, Any] = 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_ :List[str] = True self.check_hidden_states_output(snake_case , snake_case , snake_case , snake_case ) def lowerCAmelCase_ ( self: Tuple ) -> Any: snake_case_, snake_case_ :Union[str, Any] = self.model_tester.prepare_config_and_inputs_for_common() snake_case_ :Optional[int] = 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_ :Any = image_size[0] + patch_size[0] - (image_size[0] % patch_size[0]) snake_case_ :int = image_size[1] + patch_size[1] - (image_size[1] % patch_size[1]) for model_class in self.all_model_classes: snake_case_ :str = 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_ :Tuple = True self.check_hidden_states_output(snake_case , snake_case , snake_case , (padded_height, padded_width) ) def lowerCAmelCase_ ( self: Any ) -> Tuple: snake_case_ :int = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_for_masked_image_modeling(*snake_case ) def lowerCAmelCase_ ( self: Optional[int] ) -> Dict: snake_case_ :Any = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_for_image_classification(*snake_case ) @slow def lowerCAmelCase_ ( self: List[Any] ) -> Dict: for model_name in SWINV2_PRETRAINED_MODEL_ARCHIVE_LIST[:1]: snake_case_ :List[str] = SwinvaModel.from_pretrained(snake_case ) self.assertIsNotNone(snake_case ) def lowerCAmelCase_ ( self: Optional[int] ) -> List[Any]: snake_case_, snake_case_ :str = self.model_tester.prepare_config_and_inputs_for_common() snake_case_ :Optional[int] = _config_zero_init(snake_case ) for model_class in self.all_model_classes: snake_case_ :Tuple = 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 ): '''simple docstring''' @cached_property def lowerCAmelCase_ ( self: Optional[int] ) -> List[Any]: return ( AutoImageProcessor.from_pretrained("""microsoft/swinv2-tiny-patch4-window8-256""" ) if is_vision_available() else None ) @slow def lowerCAmelCase_ ( self: List[str] ) -> List[str]: snake_case_ :Tuple = SwinvaForImageClassification.from_pretrained("""microsoft/swinv2-tiny-patch4-window8-256""" ).to( snake_case ) snake_case_ :str = self.default_image_processor snake_case_ :List[Any] = Image.open("""./tests/fixtures/tests_samples/COCO/000000039769.png""" ) snake_case_ :str = image_processor(images=snake_case , return_tensors="""pt""" ).to(snake_case ) # forward pass with torch.no_grad(): snake_case_ :Tuple = model(**snake_case ) # verify the logits snake_case_ :Dict = torch.Size((1, 1_000) ) self.assertEqual(outputs.logits.shape , snake_case ) snake_case_ :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 string import numpy def A_ ( _lowercase, _lowercase ): '''simple docstring''' return b if a == 0 else greatest_common_divisor(b % a, _lowercase ) class lowerCamelCase : '''simple docstring''' _A : int = string.ascii_uppercase + string.digits # This cipher takes alphanumerics into account # i.e. a total of 36 characters # take x and return x % len(key_string) _A : Union[str, Any] = numpy.vectorize(lambda _lowerCAmelCase : x % 3_6 ) _A : List[Any] = numpy.vectorize(_lowerCAmelCase ) def __init__( self: Optional[int] , snake_case: numpy.ndarray ) -> None: snake_case_ :Optional[int] = self.modulus(snake_case ) # mod36 calc's on the encrypt key self.check_determinant() # validate the determinant of the encryption key snake_case_ :Union[str, Any] = encrypt_key.shape[0] def lowerCAmelCase_ ( self: Tuple , snake_case: str ) -> int: return self.key_string.index(snake_case ) def lowerCAmelCase_ ( self: Tuple , snake_case: int ) -> str: return self.key_string[round(snake_case )] def lowerCAmelCase_ ( self: int ) -> None: snake_case_ :Optional[Any] = round(numpy.linalg.det(self.encrypt_key ) ) if det < 0: snake_case_ :Any = det % len(self.key_string ) snake_case_ :Union[str, Any] = len(self.key_string ) if greatest_common_divisor(snake_case , len(self.key_string ) ) != 1: snake_case_ :str = ( f"""determinant modular {req_l} of encryption key({det}) """ f"""is not co prime w.r.t {req_l}.\nTry another key.""" ) raise ValueError(snake_case ) def lowerCAmelCase_ ( self: Optional[int] , snake_case: str ) -> str: snake_case_ :Union[str, Any] = [char for char in text.upper() if char in self.key_string] snake_case_ :Union[str, Any] = chars[-1] while len(snake_case ) % self.break_key != 0: chars.append(snake_case ) return "".join(snake_case ) def lowerCAmelCase_ ( self: Dict , snake_case: str ) -> str: snake_case_ :List[str] = self.process_text(text.upper() ) snake_case_ :List[Any] = """""" for i in range(0 , len(snake_case ) - self.break_key + 1 , self.break_key ): snake_case_ :int = text[i : i + self.break_key] snake_case_ :int = [self.replace_letters(snake_case ) for char in batch] snake_case_ :Optional[int] = numpy.array([vec] ).T snake_case_ :Any = self.modulus(self.encrypt_key.dot(snake_case ) ).T.tolist()[ 0 ] snake_case_ :Optional[Any] = """""".join( self.replace_digits(snake_case ) for num in batch_encrypted ) encrypted += encrypted_batch return encrypted def lowerCAmelCase_ ( self: Union[str, Any] ) -> numpy.ndarray: snake_case_ :Dict = round(numpy.linalg.det(self.encrypt_key ) ) if det < 0: snake_case_ :List[Any] = det % len(self.key_string ) snake_case_ :Optional[int] = None for i in range(len(self.key_string ) ): if (det * i) % len(self.key_string ) == 1: snake_case_ :Dict = i break snake_case_ :Optional[int] = ( det_inv * numpy.linalg.det(self.encrypt_key ) * numpy.linalg.inv(self.encrypt_key ) ) return self.to_int(self.modulus(snake_case ) ) def lowerCAmelCase_ ( self: Optional[Any] , snake_case: str ) -> str: snake_case_ :Dict = self.make_decrypt_key() snake_case_ :Tuple = self.process_text(text.upper() ) snake_case_ :Optional[int] = """""" for i in range(0 , len(snake_case ) - self.break_key + 1 , self.break_key ): snake_case_ :Tuple = text[i : i + self.break_key] snake_case_ :Dict = [self.replace_letters(snake_case ) for char in batch] snake_case_ :List[str] = numpy.array([vec] ).T snake_case_ :Optional[Any] = self.modulus(decrypt_key.dot(snake_case ) ).T.tolist()[0] snake_case_ :int = """""".join( self.replace_digits(snake_case ) for num in batch_decrypted ) decrypted += decrypted_batch return decrypted def A_ ( ): '''simple docstring''' snake_case_ :Dict = int(input("""Enter the order of the encryption key: """ ) ) snake_case_ :Union[str, Any] = [] print("""Enter each row of the encryption key with space separated integers""" ) for _ in range(_lowercase ): snake_case_ :Union[str, Any] = [int(_lowercase ) for x in input().split()] hill_matrix.append(_lowercase ) snake_case_ :List[Any] = HillCipher(numpy.array(_lowercase ) ) print("""Would you like to encrypt or decrypt some text? (1 or 2)""" ) snake_case_ :int = input("""\n1. Encrypt\n2. Decrypt\n""" ) if option == "1": snake_case_ :Optional[Any] = input("""What text would you like to encrypt?: """ ) print("""Your encrypted text is:""" ) print(hc.encrypt(_lowercase ) ) elif option == "2": snake_case_ :Dict = input("""What text would you like to decrypt?: """ ) print("""Your decrypted text is:""" ) print(hc.decrypt(_lowercase ) ) if __name__ == "__main__": import doctest doctest.testmod() main()
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"""simple docstring""" import re def A_ ( _lowercase ): '''simple docstring''' snake_case_ :Optional[int] = re.compile( r"""^(?:0|94|\+94|0{2}94)""" r"""7(0|1|2|4|5|6|7|8)""" r"""(-| |)""" r"""\d{7}$""" ) return bool(re.search(_lowercase, _lowercase ) ) if __name__ == "__main__": __a = "0094702343221" print(is_sri_lankan_phone_number(phone))
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"""simple docstring""" import argparse import os import torch from transformers import FlavaConfig, FlavaForPreTraining from transformers.models.flava.convert_dalle_to_flava_codebook import convert_dalle_checkpoint def A_ ( _lowercase ): '''simple docstring''' return sum(param.float().sum() if """encoder.embeddings""" not in key else 0 for key, param in state_dict.items() ) def A_ ( _lowercase, _lowercase ): '''simple docstring''' snake_case_ :Union[str, Any] = {} for key, value in state_dict.items(): if "text_encoder.embeddings" in key or "image_encoder.embeddings" in key: continue snake_case_ :Union[str, Any] = key.replace("""heads.cmd.mim_head.cls.predictions""", """mmm_image_head""" ) snake_case_ :str = key.replace("""heads.cmd.mlm_head.cls.predictions""", """mmm_text_head""" ) snake_case_ :Optional[Any] = key.replace("""heads.cmd.itm_head.cls""", """itm_head""" ) snake_case_ :Tuple = key.replace("""heads.cmd.itm_head.pooler""", """itm_head.pooler""" ) snake_case_ :int = key.replace("""heads.cmd.clip_head.logit_scale""", """flava.logit_scale""" ) snake_case_ :str = key.replace("""heads.fairseq_mlm.cls.predictions""", """mlm_head""" ) snake_case_ :Tuple = key.replace("""heads.imagenet.mim_head.cls.predictions""", """mim_head""" ) snake_case_ :Optional[int] = key.replace("""mm_text_projection""", """flava.text_to_mm_projection""" ) snake_case_ :List[str] = key.replace("""mm_image_projection""", """flava.image_to_mm_projection""" ) snake_case_ :str = key.replace("""image_encoder.module""", """flava.image_model""" ) snake_case_ :List[Any] = key.replace("""text_encoder.module""", """flava.text_model""" ) snake_case_ :str = key.replace("""mm_encoder.module.encoder.cls_token""", """flava.multimodal_model.cls_token""" ) snake_case_ :Any = key.replace("""mm_encoder.module""", """flava.multimodal_model""" ) snake_case_ :List[str] = key.replace("""text_projection""", """flava.text_projection""" ) snake_case_ :List[str] = key.replace("""image_projection""", """flava.image_projection""" ) snake_case_ :str = value.float() for key, value in codebook_state_dict.items(): snake_case_ :Optional[int] = value return upgrade @torch.no_grad() def A_ ( _lowercase, _lowercase, _lowercase, _lowercase=None ): '''simple docstring''' if config_path is not None: snake_case_ :int = FlavaConfig.from_pretrained(_lowercase ) else: snake_case_ :int = FlavaConfig() snake_case_ :Optional[Any] = FlavaForPreTraining(_lowercase ).eval() snake_case_ :Any = convert_dalle_checkpoint(_lowercase, _lowercase, save_checkpoint=_lowercase ) if os.path.exists(_lowercase ): snake_case_ :List[str] = torch.load(_lowercase, map_location="""cpu""" ) else: snake_case_ :Optional[int] = torch.hub.load_state_dict_from_url(_lowercase, map_location="""cpu""" ) snake_case_ :List[Any] = upgrade_state_dict(_lowercase, _lowercase ) hf_model.load_state_dict(_lowercase ) snake_case_ :Optional[int] = hf_model.state_dict() snake_case_ :int = count_parameters(_lowercase ) snake_case_ :Optional[Any] = count_parameters(_lowercase ) + count_parameters(_lowercase ) assert torch.allclose(_lowercase, _lowercase, atol=1e-3 ) hf_model.save_pretrained(_lowercase ) if __name__ == "__main__": __a = 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 flava checkpoint") parser.add_argument("--codebook_path", default=None, type=str, help="Path to flava codebook checkpoint") parser.add_argument("--config_path", default=None, type=str, help="Path to hf config.json of model to convert") __a = parser.parse_args() convert_flava_checkpoint(args.checkpoint_path, args.codebook_path, args.pytorch_dump_folder_path, args.config_path)
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"""simple docstring""" import argparse import json import os import pickle import shutil import numpy as np import torch from distiller import Distiller from lm_seqs_dataset import LmSeqsDataset from transformers import ( BertConfig, BertForMaskedLM, BertTokenizer, DistilBertConfig, DistilBertForMaskedLM, DistilBertTokenizer, GPTaConfig, GPTaLMHeadModel, GPTaTokenizer, RobertaConfig, RobertaForMaskedLM, RobertaTokenizer, ) from utils import git_log, init_gpu_params, logger, set_seed __a = { "distilbert": (DistilBertConfig, DistilBertForMaskedLM, DistilBertTokenizer), "roberta": (RobertaConfig, RobertaForMaskedLM, RobertaTokenizer), "bert": (BertConfig, BertForMaskedLM, BertTokenizer), "gpt2": (GPTaConfig, GPTaLMHeadModel, GPTaTokenizer), } def A_ ( _lowercase ): '''simple docstring''' assert (args.mlm and args.alpha_mlm > 0.0) or (not args.mlm and args.alpha_mlm == 0.0) assert (args.alpha_mlm > 0.0 and args.alpha_clm == 0.0) or (args.alpha_mlm == 0.0 and args.alpha_clm > 0.0) if args.mlm: assert os.path.isfile(args.token_counts ) assert (args.student_type in ["roberta", "distilbert"]) and (args.teacher_type in ["roberta", "bert"]) else: assert (args.student_type in ["gpt2"]) and (args.teacher_type in ["gpt2"]) assert args.teacher_type == args.student_type or ( args.student_type == "distilbert" and args.teacher_type == "bert" ) assert os.path.isfile(args.student_config ) if args.student_pretrained_weights is not None: assert os.path.isfile(args.student_pretrained_weights ) if args.freeze_token_type_embds: assert args.student_type in ["roberta"] assert args.alpha_ce >= 0.0 assert args.alpha_mlm >= 0.0 assert args.alpha_clm >= 0.0 assert args.alpha_mse >= 0.0 assert args.alpha_cos >= 0.0 assert args.alpha_ce + args.alpha_mlm + args.alpha_clm + args.alpha_mse + args.alpha_cos > 0.0 def A_ ( _lowercase, _lowercase ): '''simple docstring''' if args.student_type == "roberta": snake_case_ :Tuple = False elif args.student_type == "gpt2": snake_case_ :Union[str, Any] = False def A_ ( _lowercase, _lowercase ): '''simple docstring''' if args.student_type == "roberta": snake_case_ :List[str] = False def A_ ( ): '''simple docstring''' snake_case_ :Union[str, Any] = argparse.ArgumentParser(description="""Training""" ) parser.add_argument("""--force""", action="""store_true""", help="""Overwrite dump_path if it already exists.""" ) parser.add_argument( """--dump_path""", type=_lowercase, required=_lowercase, help="""The output directory (log, checkpoints, parameters, etc.)""" ) parser.add_argument( """--data_file""", type=_lowercase, required=_lowercase, help="""The binarized file (tokenized + tokens_to_ids) and grouped by sequence.""", ) parser.add_argument( """--student_type""", type=_lowercase, choices=["""distilbert""", """roberta""", """gpt2"""], required=_lowercase, help="""The student type (DistilBERT, RoBERTa).""", ) parser.add_argument("""--student_config""", type=_lowercase, required=_lowercase, help="""Path to the student configuration.""" ) parser.add_argument( """--student_pretrained_weights""", default=_lowercase, type=_lowercase, help="""Load student initialization checkpoint.""" ) parser.add_argument( """--teacher_type""", choices=["""bert""", """roberta""", """gpt2"""], required=_lowercase, help="""Teacher type (BERT, RoBERTa).""" ) parser.add_argument("""--teacher_name""", type=_lowercase, required=_lowercase, help="""The teacher model.""" ) parser.add_argument("""--temperature""", default=2.0, type=_lowercase, help="""Temperature for the softmax temperature.""" ) parser.add_argument( """--alpha_ce""", default=0.5, type=_lowercase, help="""Linear weight for the distillation loss. Must be >=0.""" ) parser.add_argument( """--alpha_mlm""", default=0.0, type=_lowercase, help="""Linear weight for the MLM loss. Must be >=0. Should be used in conjunction with `mlm` flag.""", ) parser.add_argument("""--alpha_clm""", default=0.5, type=_lowercase, help="""Linear weight for the CLM loss. Must be >=0.""" ) parser.add_argument("""--alpha_mse""", default=0.0, type=_lowercase, help="""Linear weight of the MSE loss. Must be >=0.""" ) parser.add_argument( """--alpha_cos""", default=0.0, type=_lowercase, help="""Linear weight of the cosine embedding loss. Must be >=0.""" ) parser.add_argument( """--mlm""", action="""store_true""", help="""The LM step: MLM or CLM. If `mlm` is True, the MLM is used over CLM.""" ) parser.add_argument( """--mlm_mask_prop""", default=0.15, type=_lowercase, help="""Proportion of tokens for which we need to make a prediction.""", ) parser.add_argument("""--word_mask""", default=0.8, type=_lowercase, help="""Proportion of tokens to mask out.""" ) parser.add_argument("""--word_keep""", default=0.1, type=_lowercase, help="""Proportion of tokens to keep.""" ) parser.add_argument("""--word_rand""", default=0.1, type=_lowercase, help="""Proportion of tokens to randomly replace.""" ) parser.add_argument( """--mlm_smoothing""", default=0.7, type=_lowercase, help="""Smoothing parameter to emphasize more rare tokens (see XLM, similar to word2vec).""", ) parser.add_argument("""--token_counts""", type=_lowercase, help="""The token counts in the data_file for MLM.""" ) parser.add_argument( """--restrict_ce_to_mask""", action="""store_true""", help="""If true, compute the distillation loss only the [MLM] prediction distribution.""", ) parser.add_argument( """--freeze_pos_embs""", action="""store_true""", help="""Freeze positional embeddings during distillation. For student_type in ['roberta', 'gpt2'] only.""", ) parser.add_argument( """--freeze_token_type_embds""", action="""store_true""", help="""Freeze token type embeddings during distillation if existent. For student_type in ['roberta'] only.""", ) parser.add_argument("""--n_epoch""", type=_lowercase, default=3, help="""Number of pass on the whole dataset.""" ) parser.add_argument("""--batch_size""", type=_lowercase, default=5, help="""Batch size (for each process).""" ) parser.add_argument( """--group_by_size""", action="""store_false""", help="""If true, group sequences that have similar length into the same batch. Default is true.""", ) parser.add_argument( """--gradient_accumulation_steps""", type=_lowercase, default=50, help="""Gradient accumulation for larger training batches.""", ) parser.add_argument("""--warmup_prop""", default=0.05, type=_lowercase, help="""Linear warmup proportion.""" ) parser.add_argument("""--weight_decay""", default=0.0, type=_lowercase, help="""Weight decay if we apply some.""" ) parser.add_argument("""--learning_rate""", default=5e-4, type=_lowercase, help="""The initial learning rate for Adam.""" ) parser.add_argument("""--adam_epsilon""", default=1e-6, type=_lowercase, help="""Epsilon for Adam optimizer.""" ) parser.add_argument("""--max_grad_norm""", default=5.0, type=_lowercase, help="""Max gradient norm.""" ) parser.add_argument("""--initializer_range""", default=0.02, type=_lowercase, help="""Random initialization range.""" ) parser.add_argument( """--fp16""", action="""store_true""", help="""Whether to use 16-bit (mixed) precision (through NVIDIA apex) instead of 32-bit""", ) parser.add_argument( """--fp16_opt_level""", type=_lowercase, default="""O1""", help=( """For fp16: Apex AMP optimization level selected in ['O0', 'O1', 'O2', and 'O3'].""" """See details at https://nvidia.github.io/apex/amp.html""" ), ) parser.add_argument("""--n_gpu""", type=_lowercase, default=1, help="""Number of GPUs in the node.""" ) parser.add_argument("""--local_rank""", type=_lowercase, default=-1, help="""Distributed training - Local rank""" ) parser.add_argument("""--seed""", type=_lowercase, default=56, help="""Random seed""" ) parser.add_argument("""--log_interval""", type=_lowercase, default=500, help="""Tensorboard logging interval.""" ) parser.add_argument("""--checkpoint_interval""", type=_lowercase, default=4000, help="""Checkpoint interval.""" ) snake_case_ :Tuple = parser.parse_args() sanity_checks(_lowercase ) # ARGS # init_gpu_params(_lowercase ) set_seed(_lowercase ) if args.is_master: if os.path.exists(args.dump_path ): if not args.force: raise ValueError( f"""Serialization dir {args.dump_path} already exists, but you have not precised wheter to overwrite""" """ itUse `--force` if you want to overwrite it""" ) else: shutil.rmtree(args.dump_path ) if not os.path.exists(args.dump_path ): os.makedirs(args.dump_path ) logger.info(f"""Experiment will be dumped and logged in {args.dump_path}""" ) # SAVE PARAMS # logger.info(f"""Param: {args}""" ) with open(os.path.join(args.dump_path, """parameters.json""" ), """w""" ) as f: json.dump(vars(_lowercase ), _lowercase, indent=4 ) git_log(args.dump_path ) snake_case_, snake_case_, snake_case_ :Any = MODEL_CLASSES[args.student_type] snake_case_, snake_case_, snake_case_ :int = MODEL_CLASSES[args.teacher_type] # TOKENIZER # snake_case_ :Any = teacher_tokenizer_class.from_pretrained(args.teacher_name ) snake_case_ :Optional[Any] = {} for tok_name, tok_symbol in tokenizer.special_tokens_map.items(): snake_case_ :Union[str, Any] = tokenizer.all_special_tokens.index(_lowercase ) snake_case_ :Union[str, Any] = tokenizer.all_special_ids[idx] logger.info(f"""Special tokens {special_tok_ids}""" ) snake_case_ :str = special_tok_ids snake_case_ :Any = tokenizer.max_model_input_sizes[args.teacher_name] # DATA LOADER # logger.info(f"""Loading data from {args.data_file}""" ) with open(args.data_file, """rb""" ) as fp: snake_case_ :str = pickle.load(_lowercase ) if args.mlm: logger.info(f"""Loading token counts from {args.token_counts} (already pre-computed)""" ) with open(args.token_counts, """rb""" ) as fp: snake_case_ :Optional[Any] = pickle.load(_lowercase ) snake_case_ :Tuple = np.maximum(_lowercase, 1 ) ** -args.mlm_smoothing for idx in special_tok_ids.values(): snake_case_ :Optional[int] = 0.0 # do not predict special tokens snake_case_ :int = torch.from_numpy(_lowercase ) else: snake_case_ :List[str] = None snake_case_ :Optional[int] = LmSeqsDataset(params=_lowercase, data=_lowercase ) logger.info("""Data loader created.""" ) # STUDENT # logger.info(f"""Loading student config from {args.student_config}""" ) snake_case_ :List[Any] = student_config_class.from_pretrained(args.student_config ) snake_case_ :Union[str, Any] = True if args.student_pretrained_weights is not None: logger.info(f"""Loading pretrained weights from {args.student_pretrained_weights}""" ) snake_case_ :List[str] = student_model_class.from_pretrained(args.student_pretrained_weights, config=_lowercase ) else: snake_case_ :Optional[int] = student_model_class(_lowercase ) if args.n_gpu > 0: student.to(f"""cuda:{args.local_rank}""" ) logger.info("""Student loaded.""" ) # TEACHER # snake_case_ :Dict = teacher_model_class.from_pretrained(args.teacher_name, output_hidden_states=_lowercase ) if args.n_gpu > 0: teacher.to(f"""cuda:{args.local_rank}""" ) logger.info(f"""Teacher loaded from {args.teacher_name}.""" ) # FREEZING # if args.freeze_pos_embs: freeze_pos_embeddings(_lowercase, _lowercase ) if args.freeze_token_type_embds: freeze_token_type_embeddings(_lowercase, _lowercase ) # SANITY CHECKS # assert student.config.vocab_size == teacher.config.vocab_size assert student.config.hidden_size == teacher.config.hidden_size assert student.config.max_position_embeddings == teacher.config.max_position_embeddings if args.mlm: assert token_probs.size(0 ) == stu_architecture_config.vocab_size # DISTILLER # torch.cuda.empty_cache() snake_case_ :Optional[int] = Distiller( params=_lowercase, dataset=_lowercase, token_probs=_lowercase, student=_lowercase, teacher=_lowercase ) distiller.train() logger.info("""Let's go get some drinks.""" ) if __name__ == "__main__": main()
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"""simple docstring""" import logging import os import sys from dataclasses import dataclass, field from itertools import chain from typing import Optional, Union import datasets import numpy as np import torch from datasets import load_dataset import transformers from transformers import ( AutoConfig, AutoModelForMultipleChoice, AutoTokenizer, HfArgumentParser, Trainer, TrainingArguments, default_data_collator, set_seed, ) from transformers.tokenization_utils_base import PreTrainedTokenizerBase from transformers.trainer_utils import get_last_checkpoint from transformers.utils import PaddingStrategy, check_min_version, send_example_telemetry # Will error if the minimal version of Transformers is not installed. Remove at your own risks. check_min_version("4.31.0") __a = logging.getLogger(__name__) @dataclass class lowerCamelCase : '''simple docstring''' _A : str = field( metadata={"""help""": """Path to pretrained model or model identifier from huggingface.co/models"""} ) _A : Optional[str] = field( default=_lowerCAmelCase , metadata={"""help""": """Pretrained config name or path if not the same as model_name"""} ) _A : Optional[str] = field( default=_lowerCAmelCase , metadata={"""help""": """Pretrained tokenizer name or path if not the same as model_name"""} ) _A : Optional[str] = field( default=_lowerCAmelCase , metadata={"""help""": """Where do you want to store the pretrained models downloaded from huggingface.co"""} , ) _A : bool = field( default=_lowerCAmelCase , metadata={"""help""": """Whether to use one of the fast tokenizer (backed by the tokenizers library) or not."""} , ) _A : str = field( default="""main""" , metadata={"""help""": """The specific model version to use (can be a branch name, tag name or commit id)."""} , ) _A : bool = field( default=_lowerCAmelCase , metadata={ """help""": ( """Will use the token generated when running `huggingface-cli login` (necessary to use this script """ """with private models).""" ) } , ) @dataclass class lowerCamelCase : '''simple docstring''' _A : Optional[str] = field(default=_lowerCAmelCase , metadata={"""help""": """The input training data file (a text file)."""} ) _A : Optional[str] = field( default=_lowerCAmelCase , metadata={"""help""": """An optional input evaluation data file to evaluate the perplexity on (a text file)."""} , ) _A : bool = field( default=_lowerCAmelCase , metadata={"""help""": """Overwrite the cached training and evaluation sets"""} ) _A : Optional[int] = field( default=_lowerCAmelCase , metadata={"""help""": """The number of processes to use for the preprocessing."""} , ) _A : Optional[int] = field( default=_lowerCAmelCase , metadata={ """help""": ( """The maximum total input sequence length after tokenization. If passed, sequences longer """ """than this will be truncated, sequences shorter will be padded.""" ) } , ) _A : bool = field( default=_lowerCAmelCase , metadata={ """help""": ( """Whether to pad all samples to the maximum sentence length. """ """If False, will pad the samples dynamically when batching to the maximum length in the batch. More """ """efficient on GPU but very bad for TPU.""" ) } , ) _A : Optional[int] = field( default=_lowerCAmelCase , metadata={ """help""": ( """For debugging purposes or quicker training, truncate the number of training examples to this """ """value if set.""" ) } , ) _A : Optional[int] = field( default=_lowerCAmelCase , metadata={ """help""": ( """For debugging purposes or quicker training, truncate the number of evaluation examples to this """ """value if set.""" ) } , ) def lowerCAmelCase_ ( self: List[str] ) -> Tuple: if self.train_file is not None: snake_case_ :Optional[int] = self.train_file.split(""".""" )[-1] assert extension in ["csv", "json"], "`train_file` should be a csv or a json file." if self.validation_file is not None: snake_case_ :Tuple = self.validation_file.split(""".""" )[-1] assert extension in ["csv", "json"], "`validation_file` should be a csv or a json file." @dataclass class lowerCamelCase : '''simple docstring''' _A : PreTrainedTokenizerBase _A : Union[bool, str, PaddingStrategy] = True _A : Optional[int] = None _A : Optional[int] = None def __call__( self: Dict , snake_case: Union[str, Any] ) -> Dict: snake_case_ :Dict = """label""" if """label""" in features[0].keys() else """labels""" snake_case_ :Union[str, Any] = [feature.pop(snake_case ) for feature in features] snake_case_ :List[Any] = len(snake_case ) snake_case_ :Dict = len(features[0]["""input_ids"""] ) snake_case_ :Any = [ [{k: v[i] for k, v in feature.items()} for i in range(snake_case )] for feature in features ] snake_case_ :Union[str, Any] = list(chain(*snake_case ) ) snake_case_ :Optional[Any] = self.tokenizer.pad( snake_case , padding=self.padding , max_length=self.max_length , pad_to_multiple_of=self.pad_to_multiple_of , return_tensors="""pt""" , ) # Un-flatten snake_case_ :Optional[Any] = {k: v.view(snake_case , snake_case , -1 ) for k, v in batch.items()} # Add back labels snake_case_ :Dict = torch.tensor(snake_case , dtype=torch.intaa ) return batch def A_ ( ): '''simple docstring''' snake_case_ :str = 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. snake_case_, snake_case_, snake_case_ :Any = parser.parse_json_file(json_file=os.path.abspath(sys.argv[1] ) ) else: snake_case_, snake_case_, snake_case_ :List[Any] = 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_swag""", _lowercase, _lowercase ) # 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() snake_case_ :int = training_args.get_process_log_level() logger.setLevel(_lowercase ) datasets.utils.logging.set_verbosity(_lowercase ) transformers.utils.logging.set_verbosity(_lowercase ) 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}""" ) # Detecting last checkpoint. snake_case_ :List[Any] = None if os.path.isdir(training_args.output_dir ) and training_args.do_train and not training_args.overwrite_output_dir: snake_case_ :Dict = 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 overcome.""" ) 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.""" ) # Set seed before initializing model. set_seed(training_args.seed ) # Get the datasets: you can either provide your own CSV/JSON/TXT training and evaluation files (see below) # or just provide the name of one of the public datasets available on the hub at https://huggingface.co/datasets/ # (the dataset will be downloaded automatically from the datasets Hub). # For CSV/JSON files, this script will use the column called 'text' or the first column if no column called # 'text' is found. You can easily tweak this behavior (see below). # In distributed training, the load_dataset function guarantee that only one local process can concurrently # download the dataset. if data_args.train_file is not None or data_args.validation_file is not None: snake_case_ :int = {} if data_args.train_file is not None: snake_case_ :Dict = data_args.train_file if data_args.validation_file is not None: snake_case_ :Optional[Any] = data_args.validation_file snake_case_ :str = data_args.train_file.split(""".""" )[-1] snake_case_ :Any = load_dataset( _lowercase, data_files=_lowercase, cache_dir=model_args.cache_dir, use_auth_token=True if model_args.use_auth_token else None, ) else: # Downloading and loading the swag dataset from the hub. snake_case_ :str = load_dataset( """swag""", """regular""", cache_dir=model_args.cache_dir, use_auth_token=True if model_args.use_auth_token else None, ) # See more about loading any type of standard or custom dataset (from files, python dict, pandas DataFrame, etc) at # https://huggingface.co/docs/datasets/loading_datasets.html. # Load pretrained model and tokenizer # Distributed training: # The .from_pretrained methods guarantee that only one local process can concurrently # download model & vocab. snake_case_ :List[str] = AutoConfig.from_pretrained( model_args.config_name if model_args.config_name else model_args.model_name_or_path, cache_dir=model_args.cache_dir, revision=model_args.model_revision, use_auth_token=True if model_args.use_auth_token else None, ) snake_case_ :str = AutoTokenizer.from_pretrained( model_args.tokenizer_name if model_args.tokenizer_name else model_args.model_name_or_path, cache_dir=model_args.cache_dir, use_fast=model_args.use_fast_tokenizer, revision=model_args.model_revision, use_auth_token=True if model_args.use_auth_token else None, ) snake_case_ :int = AutoModelForMultipleChoice.from_pretrained( model_args.model_name_or_path, from_tf=bool(""".ckpt""" in model_args.model_name_or_path ), config=_lowercase, cache_dir=model_args.cache_dir, revision=model_args.model_revision, use_auth_token=True if model_args.use_auth_token else None, ) # When using your own dataset or a different dataset from swag, you will probably need to change this. snake_case_ :Optional[int] = [f"""ending{i}""" for i in range(4 )] snake_case_ :int = """sent1""" snake_case_ :int = """sent2""" if data_args.max_seq_length is None: snake_case_ :int = tokenizer.model_max_length if max_seq_length > 1024: logger.warning( """The chosen tokenizer supports a `model_max_length` that is longer than the default `block_size` value""" """ of 1024. If you would like to use a longer `block_size` up to `tokenizer.model_max_length` you can""" """ override this default with `--block_size xxx`.""" ) snake_case_ :Optional[int] = 1024 else: if data_args.max_seq_length > tokenizer.model_max_length: logger.warning( f"""The max_seq_length passed ({data_args.max_seq_length}) is larger than the maximum length for the""" f"""model ({tokenizer.model_max_length}). Using max_seq_length={tokenizer.model_max_length}.""" ) snake_case_ :Any = min(data_args.max_seq_length, tokenizer.model_max_length ) # Preprocessing the datasets. def preprocess_function(_lowercase ): snake_case_ :Dict = [[context] * 4 for context in examples[context_name]] snake_case_ :Optional[Any] = examples[question_header_name] snake_case_ :Optional[int] = [ [f"""{header} {examples[end][i]}""" for end in ending_names] for i, header in enumerate(_lowercase ) ] # Flatten out snake_case_ :Optional[int] = list(chain(*_lowercase ) ) snake_case_ :Optional[int] = list(chain(*_lowercase ) ) # Tokenize snake_case_ :Any = tokenizer( _lowercase, _lowercase, truncation=_lowercase, max_length=_lowercase, padding="""max_length""" if data_args.pad_to_max_length else False, ) # Un-flatten return {k: [v[i : i + 4] for i in range(0, len(_lowercase ), 4 )] for k, v in tokenized_examples.items()} if training_args.do_train: if "train" not in raw_datasets: raise ValueError("""--do_train requires a train dataset""" ) snake_case_ :Dict = raw_datasets["""train"""] if data_args.max_train_samples is not None: snake_case_ :Optional[int] = min(len(_lowercase ), data_args.max_train_samples ) snake_case_ :Tuple = train_dataset.select(range(_lowercase ) ) with training_args.main_process_first(desc="""train dataset map pre-processing""" ): snake_case_ :int = train_dataset.map( _lowercase, batched=_lowercase, num_proc=data_args.preprocessing_num_workers, load_from_cache_file=not data_args.overwrite_cache, ) if training_args.do_eval: if "validation" not in raw_datasets: raise ValueError("""--do_eval requires a validation dataset""" ) snake_case_ :str = raw_datasets["""validation"""] if data_args.max_eval_samples is not None: snake_case_ :Any = min(len(_lowercase ), data_args.max_eval_samples ) snake_case_ :Optional[Any] = eval_dataset.select(range(_lowercase ) ) with training_args.main_process_first(desc="""validation dataset map pre-processing""" ): snake_case_ :List[Any] = eval_dataset.map( _lowercase, batched=_lowercase, num_proc=data_args.preprocessing_num_workers, load_from_cache_file=not data_args.overwrite_cache, ) # Data collator snake_case_ :List[str] = ( default_data_collator if data_args.pad_to_max_length else DataCollatorForMultipleChoice(tokenizer=_lowercase, pad_to_multiple_of=8 if training_args.fpaa else None ) ) # Metric def compute_metrics(_lowercase ): snake_case_, snake_case_ :Dict = eval_predictions snake_case_ :Tuple = np.argmax(_lowercase, axis=1 ) return {"accuracy": (preds == label_ids).astype(np.floataa ).mean().item()} # Initialize our Trainer snake_case_ :int = Trainer( model=_lowercase, args=_lowercase, train_dataset=train_dataset if training_args.do_train else None, eval_dataset=eval_dataset if training_args.do_eval else None, tokenizer=_lowercase, data_collator=_lowercase, compute_metrics=_lowercase, ) # Training if training_args.do_train: snake_case_ :Tuple = None if training_args.resume_from_checkpoint is not None: snake_case_ :List[Any] = training_args.resume_from_checkpoint elif last_checkpoint is not None: snake_case_ :List[Any] = last_checkpoint snake_case_ :Any = trainer.train(resume_from_checkpoint=_lowercase ) trainer.save_model() # Saves the tokenizer too for easy upload snake_case_ :Tuple = train_result.metrics snake_case_ :List[Any] = ( data_args.max_train_samples if data_args.max_train_samples is not None else len(_lowercase ) ) snake_case_ :Optional[Any] = min(_lowercase, len(_lowercase ) ) trainer.log_metrics("""train""", _lowercase ) trainer.save_metrics("""train""", _lowercase ) trainer.save_state() # Evaluation if training_args.do_eval: logger.info("""*** Evaluate ***""" ) snake_case_ :List[Any] = trainer.evaluate() snake_case_ :List[Any] = data_args.max_eval_samples if data_args.max_eval_samples is not None else len(_lowercase ) snake_case_ :Union[str, Any] = min(_lowercase, len(_lowercase ) ) trainer.log_metrics("""eval""", _lowercase ) trainer.save_metrics("""eval""", _lowercase ) snake_case_ :int = { """finetuned_from""": model_args.model_name_or_path, """tasks""": """multiple-choice""", """dataset_tags""": """swag""", """dataset_args""": """regular""", """dataset""": """SWAG""", """language""": """en""", } if training_args.push_to_hub: trainer.push_to_hub(**_lowercase ) else: trainer.create_model_card(**_lowercase ) def A_ ( _lowercase ): '''simple docstring''' main() if __name__ == "__main__": main()
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"""simple docstring""" import json import os import subprocess import unittest from ast import literal_eval import pytest from parameterized import parameterized, parameterized_class from . import is_sagemaker_available if is_sagemaker_available(): from sagemaker import Session, TrainingJobAnalytics from sagemaker.huggingface import HuggingFace @pytest.mark.skipif( literal_eval(os.getenv("""TEST_SAGEMAKER""" , """False""" ) ) is not True , reason="""Skipping test because should only be run when releasing minor transformers version""" , ) @pytest.mark.usefixtures("""sm_env""" ) @parameterized_class( [ { """framework""": """pytorch""", """script""": """run_glue_model_parallelism.py""", """model_name_or_path""": """roberta-large""", """instance_type""": """ml.p3dn.24xlarge""", """results""": {"""train_runtime""": 1_6_0_0, """eval_accuracy""": 0.3, """eval_loss""": 1.2}, }, { """framework""": """pytorch""", """script""": """run_glue.py""", """model_name_or_path""": """roberta-large""", """instance_type""": """ml.p3dn.24xlarge""", """results""": {"""train_runtime""": 1_6_0_0, """eval_accuracy""": 0.3, """eval_loss""": 1.2}, }, ] ) class lowerCamelCase ( unittest.TestCase ): '''simple docstring''' def lowerCAmelCase_ ( self: Any ) -> str: if self.framework == "pytorch": subprocess.run( f"""cp ./examples/pytorch/text-classification/run_glue.py {self.env.test_path}/run_glue.py""".split() , encoding="""utf-8""" , check=snake_case , ) assert hasattr(self , """env""" ) def lowerCAmelCase_ ( self: int , snake_case: Dict ) -> List[Any]: # configuration for running training on smdistributed Model Parallel snake_case_ :Tuple = { """enabled""": True, """processes_per_host""": 8, } snake_case_ :List[Any] = { """enabled""": True, """parameters""": { """microbatches""": 4, """placement_strategy""": """spread""", """pipeline""": """interleaved""", """optimize""": """speed""", """partitions""": 4, """ddp""": True, }, } snake_case_ :Tuple = {"""smdistributed""": {"""modelparallel""": smp_options}, """mpi""": mpi_options} snake_case_ :Any = """trainer""" if self.script == """run_glue.py""" else """smtrainer""" # creates estimator return HuggingFace( entry_point=self.script , source_dir=self.env.test_path , role=self.env.role , image_uri=self.env.image_uri , base_job_name=f"""{self.env.base_job_name}-{instance_count}-smp-{name_extension}""" , instance_count=snake_case , instance_type=self.instance_type , debugger_hook_config=snake_case , hyperparameters={ **self.env.hyperparameters, """model_name_or_path""": self.model_name_or_path, """max_steps""": 500, } , metric_definitions=self.env.metric_definitions , distribution=snake_case , py_version="""py36""" , ) def lowerCAmelCase_ ( self: Any , snake_case: Tuple ) -> List[str]: TrainingJobAnalytics(snake_case ).export_csv(f"""{self.env.test_path}/{job_name}_metrics.csv""" ) @parameterized.expand([(1,)] ) def lowerCAmelCase_ ( self: Dict , snake_case: Dict ) -> List[Any]: # create estimator snake_case_ :List[Any] = self.create_estimator(snake_case ) # run training estimator.fit() # result dataframe snake_case_ :Any = TrainingJobAnalytics(estimator.latest_training_job.name ).dataframe() # extract kpis snake_case_ :Tuple = list(result_metrics_df[result_metrics_df.metric_name == """eval_accuracy"""]["""value"""] ) snake_case_ :Dict = list(result_metrics_df[result_metrics_df.metric_name == """eval_loss"""]["""value"""] ) # get train time from SageMaker job, this includes starting, preprocessing, stopping snake_case_ :int = ( Session().describe_training_job(estimator.latest_training_job.name ).get("""TrainingTimeInSeconds""" , 999_999 ) ) # assert kpis assert train_runtime <= self.results["train_runtime"] assert all(t >= self.results["""eval_accuracy"""] for t in eval_accuracy ) assert all(t <= self.results["""eval_loss"""] for t in eval_loss ) # dump tests result into json file to share in PR with open(f"""{estimator.latest_training_job.name}.json""" , """w""" ) as outfile: json.dump({"""train_time""": train_runtime, """eval_accuracy""": eval_accuracy, """eval_loss""": eval_loss} , snake_case )
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"""simple docstring""" import json import os from functools import lru_cache from typing import Dict, List, Optional, Tuple, Union import regex as re from ...tokenization_utils import AddedToken, PreTrainedTokenizer from ...tokenization_utils_base import BatchEncoding, EncodedInput from ...utils import PaddingStrategy, logging __a = logging.get_logger(__name__) __a = {"vocab_file": "vocab.json", "merges_file": "merges.txt"} # See all LED models at https://huggingface.co/models?filter=LED __a = { "vocab_file": { "allenai/led-base-16384": "https://huggingface.co/allenai/led-base-16384/resolve/main/vocab.json", }, "merges_file": { "allenai/led-base-16384": "https://huggingface.co/allenai/led-base-16384/resolve/main/merges.txt", }, "tokenizer_file": { "allenai/led-base-16384": "https://huggingface.co/allenai/led-base-16384/resolve/main/tokenizer.json", }, } __a = { "allenai/led-base-16384": 1_63_84, } @lru_cache() # Copied from transformers.models.bart.tokenization_bart.bytes_to_unicode def A_ ( ): '''simple docstring''' snake_case_ :Tuple = ( list(range(ord("""!""" ), ord("""~""" ) + 1 ) ) + list(range(ord("""¡""" ), ord("""¬""" ) + 1 ) ) + list(range(ord("""®""" ), ord("""ÿ""" ) + 1 ) ) ) snake_case_ :List[Any] = bs[:] snake_case_ :int = 0 for b in range(2**8 ): if b not in bs: bs.append(_lowercase ) cs.append(2**8 + n ) n += 1 snake_case_ :List[Any] = [chr(_lowercase ) for n in cs] return dict(zip(_lowercase, _lowercase ) ) def A_ ( _lowercase ): '''simple docstring''' snake_case_ :Any = set() snake_case_ :int = word[0] for char in word[1:]: pairs.add((prev_char, char) ) snake_case_ :Optional[int] = char return pairs class lowerCamelCase ( _lowerCAmelCase ): '''simple docstring''' _A : Dict = VOCAB_FILES_NAMES _A : Tuple = PRETRAINED_VOCAB_FILES_MAP _A : int = PRETRAINED_POSITIONAL_EMBEDDINGS_SIZES _A : List[str] = ["""input_ids""", """attention_mask"""] def __init__( self: List[str] , snake_case: Tuple , snake_case: Optional[int] , snake_case: Optional[Any]="replace" , snake_case: Optional[Any]="<s>" , snake_case: Any="</s>" , snake_case: int="</s>" , snake_case: Optional[int]="<s>" , snake_case: int="<unk>" , snake_case: Any="<pad>" , snake_case: str="<mask>" , snake_case: Optional[int]=False , **snake_case: str , ) -> List[Any]: snake_case_ :int = AddedToken(snake_case , lstrip=snake_case , rstrip=snake_case ) if isinstance(snake_case , snake_case ) else bos_token snake_case_ :Union[str, Any] = AddedToken(snake_case , lstrip=snake_case , rstrip=snake_case ) if isinstance(snake_case , snake_case ) else eos_token snake_case_ :Union[str, Any] = AddedToken(snake_case , lstrip=snake_case , rstrip=snake_case ) if isinstance(snake_case , snake_case ) else sep_token snake_case_ :int = AddedToken(snake_case , lstrip=snake_case , rstrip=snake_case ) if isinstance(snake_case , snake_case ) else cls_token snake_case_ :List[str] = AddedToken(snake_case , lstrip=snake_case , rstrip=snake_case ) if isinstance(snake_case , snake_case ) else unk_token snake_case_ :List[str] = AddedToken(snake_case , lstrip=snake_case , rstrip=snake_case ) if isinstance(snake_case , snake_case ) else pad_token # Mask token behave like a normal word, i.e. include the space before it snake_case_ :str = AddedToken(snake_case , lstrip=snake_case , rstrip=snake_case ) if isinstance(snake_case , snake_case ) else mask_token super().__init__( errors=snake_case , bos_token=snake_case , eos_token=snake_case , unk_token=snake_case , sep_token=snake_case , cls_token=snake_case , pad_token=snake_case , mask_token=snake_case , add_prefix_space=snake_case , **snake_case , ) with open(snake_case , encoding="""utf-8""" ) as vocab_handle: snake_case_ :int = json.load(snake_case ) snake_case_ :str = {v: k for k, v in self.encoder.items()} snake_case_ :Dict = errors # how to handle errors in decoding snake_case_ :Any = bytes_to_unicode() snake_case_ :List[str] = {v: k for k, v in self.byte_encoder.items()} with open(snake_case , encoding="""utf-8""" ) as merges_handle: snake_case_ :List[str] = merges_handle.read().split("""\n""" )[1:-1] snake_case_ :str = [tuple(merge.split() ) for merge in bpe_merges] snake_case_ :Optional[int] = dict(zip(snake_case , range(len(snake_case ) ) ) ) snake_case_ :int = {} snake_case_ :Union[str, Any] = add_prefix_space # Should have added re.IGNORECASE so BPE merges can happen for capitalized versions of contractions snake_case_ :Union[str, Any] = re.compile(r"""'s|'t|'re|'ve|'m|'ll|'d| ?\p{L}+| ?\p{N}+| ?[^\s\p{L}\p{N}]+|\s+(?!\S)|\s+""" ) @property # Copied from transformers.models.bart.tokenization_bart.BartTokenizer.vocab_size def lowerCAmelCase_ ( self: str ) -> List[str]: return len(self.encoder ) def lowerCAmelCase_ ( self: Optional[int] ) -> int: return dict(self.encoder , **self.added_tokens_encoder ) def lowerCAmelCase_ ( self: Tuple , snake_case: Optional[Any] ) -> Union[str, Any]: if token in self.cache: return self.cache[token] snake_case_ :Optional[Any] = tuple(snake_case ) snake_case_ :Any = get_pairs(snake_case ) if not pairs: return token while True: snake_case_ :Union[str, Any] = min(snake_case , key=lambda snake_case : self.bpe_ranks.get(snake_case , float("""inf""" ) ) ) if bigram not in self.bpe_ranks: break snake_case_, snake_case_ :int = bigram snake_case_ :int = [] snake_case_ :str = 0 while i < len(snake_case ): try: snake_case_ :Any = word.index(snake_case , snake_case ) except ValueError: new_word.extend(word[i:] ) break else: new_word.extend(word[i:j] ) snake_case_ :Any = j if word[i] == first and i < len(snake_case ) - 1 and word[i + 1] == second: new_word.append(first + second ) i += 2 else: new_word.append(word[i] ) i += 1 snake_case_ :Dict = tuple(snake_case ) snake_case_ :Optional[Any] = new_word if len(snake_case ) == 1: break else: snake_case_ :Optional[int] = get_pairs(snake_case ) snake_case_ :Optional[int] = """ """.join(snake_case ) snake_case_ :Optional[int] = word return word def lowerCAmelCase_ ( self: Optional[int] , snake_case: List[str] ) -> str: snake_case_ :List[str] = [] for token in re.findall(self.pat , snake_case ): snake_case_ :str = """""".join( self.byte_encoder[b] for b in token.encode("""utf-8""" ) ) # Maps all our bytes to unicode strings, avoiding control tokens of the BPE (spaces in our case) bpe_tokens.extend(bpe_token for bpe_token in self.bpe(snake_case ).split(""" """ ) ) return bpe_tokens def lowerCAmelCase_ ( self: List[Any] , snake_case: Tuple ) -> Optional[int]: return self.encoder.get(snake_case , self.encoder.get(self.unk_token ) ) def lowerCAmelCase_ ( self: int , snake_case: List[str] ) -> Tuple: return self.decoder.get(snake_case ) def lowerCAmelCase_ ( self: Dict , snake_case: Dict ) -> str: snake_case_ :Optional[Any] = """""".join(snake_case ) snake_case_ :Dict = bytearray([self.byte_decoder[c] for c in text] ).decode("""utf-8""" , errors=self.errors ) return text def lowerCAmelCase_ ( self: str , snake_case: str , 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 snake_case_ :Dict = os.path.join( snake_case , (filename_prefix + """-""" if filename_prefix else """""") + VOCAB_FILES_NAMES["""vocab_file"""] ) snake_case_ :Dict = os.path.join( snake_case , (filename_prefix + """-""" if filename_prefix else """""") + VOCAB_FILES_NAMES["""merges_file"""] ) with open(snake_case , """w""" , encoding="""utf-8""" ) as f: f.write(json.dumps(self.encoder , indent=2 , sort_keys=snake_case , ensure_ascii=snake_case ) + """\n""" ) snake_case_ :Optional[Any] = 0 with open(snake_case , """w""" , encoding="""utf-8""" ) as writer: writer.write("""#version: 0.2\n""" ) for bpe_tokens, token_index in sorted(self.bpe_ranks.items() , key=lambda snake_case : kv[1] ): if index != token_index: logger.warning( f"""Saving vocabulary to {merge_file}: BPE merge indices are not consecutive.""" """ Please check that the tokenizer is not corrupted!""" ) snake_case_ :Optional[int] = token_index writer.write(""" """.join(snake_case ) + """\n""" ) index += 1 return vocab_file, merge_file def lowerCAmelCase_ ( self: Optional[int] , snake_case: List[int] , snake_case: Optional[List[int]] = None ) -> List[int]: if token_ids_a is None: return [self.cls_token_id] + token_ids_a + [self.sep_token_id] snake_case_ :List[str] = [self.cls_token_id] snake_case_ :List[str] = [self.sep_token_id] return cls + token_ids_a + sep + sep + token_ids_a + sep def lowerCAmelCase_ ( self: List[Any] , snake_case: List[int] , snake_case: Optional[List[int]] = None , snake_case: bool = False ) -> List[int]: 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 ) if token_ids_a is None: return [1] + ([0] * len(snake_case )) + [1] return [1] + ([0] * len(snake_case )) + [1, 1] + ([0] * len(snake_case )) + [1] def lowerCAmelCase_ ( self: Optional[Any] , snake_case: List[int] , snake_case: Optional[List[int]] = None ) -> List[int]: snake_case_ :Optional[Any] = [self.sep_token_id] snake_case_ :Dict = [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] def lowerCAmelCase_ ( self: List[Any] , snake_case: Tuple , snake_case: Optional[int]=False , **snake_case: List[Any] ) -> Dict: snake_case_ :List[Any] = kwargs.pop("""add_prefix_space""" , self.add_prefix_space ) if (is_split_into_words or add_prefix_space) and (len(snake_case ) > 0 and not text[0].isspace()): snake_case_ :Any = """ """ + text return (text, kwargs) def lowerCAmelCase_ ( self: List[str] , snake_case: Union[Dict[str, EncodedInput], BatchEncoding] , snake_case: Optional[int] = None , snake_case: PaddingStrategy = PaddingStrategy.DO_NOT_PAD , snake_case: Optional[int] = None , snake_case: Optional[bool] = None , ) -> dict: snake_case_ :Any = super()._pad( encoded_inputs=snake_case , max_length=snake_case , padding_strategy=snake_case , pad_to_multiple_of=snake_case , return_attention_mask=snake_case , ) # Load from model defaults if return_attention_mask is None: snake_case_ :List[str] = """attention_mask""" in self.model_input_names if return_attention_mask and "global_attention_mask" in encoded_inputs: snake_case_ :str = encoded_inputs[self.model_input_names[0]] # `global_attention_mask` need to have the same length as other (sequential) inputs. snake_case_ :Tuple = len(encoded_inputs["""global_attention_mask"""] ) != len(snake_case ) if needs_to_be_padded: snake_case_ :Tuple = len(snake_case ) - len(encoded_inputs["""global_attention_mask"""] ) if self.padding_side == "right": # Use `-1` since `0` in `global_attention_mask` means `local attention` instead of `not to attend` snake_case_ :Union[str, Any] = ( encoded_inputs["""global_attention_mask"""] + [-1] * difference ) elif self.padding_side == "left": snake_case_ :Optional[int] = [-1] * difference + encoded_inputs[ """global_attention_mask""" ] else: raise ValueError("""Invalid padding strategy:""" + str(self.padding_side ) ) return encoded_inputs
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"""simple docstring""" import collections import inspect import unittest from typing import Dict, List, Tuple from transformers import MaskFormerSwinConfig from transformers.testing_utils import require_torch, require_torch_multi_gpu, torch_device from transformers.utils import is_torch_available from ...test_backbone_common import BackboneTesterMixin from ...test_configuration_common import ConfigTester from ...test_modeling_common import ModelTesterMixin, floats_tensor, ids_tensor from ...test_pipeline_mixin import PipelineTesterMixin if is_torch_available(): import torch from torch import nn from transformers import MaskFormerSwinBackbone from transformers.models.maskformer import MaskFormerSwinModel class lowerCamelCase : '''simple docstring''' def __init__( self: Dict , snake_case: Optional[Any] , snake_case: Tuple=13 , snake_case: Any=32 , snake_case: Union[str, Any]=2 , snake_case: Tuple=3 , snake_case: Union[str, Any]=16 , snake_case: Union[str, Any]=[1, 2, 1] , snake_case: Optional[Any]=[2, 2, 4] , snake_case: str=2 , snake_case: List[str]=2.0 , snake_case: Optional[int]=True , snake_case: Union[str, Any]=0.0 , snake_case: Optional[int]=0.0 , snake_case: Optional[Any]=0.1 , snake_case: List[str]="gelu" , snake_case: Any=False , snake_case: Optional[Any]=True , snake_case: Optional[int]=0.0_2 , snake_case: Any=1E-5 , snake_case: Optional[int]=True , snake_case: int=None , snake_case: Any=True , snake_case: str=10 , snake_case: Optional[Any]=8 , snake_case: Union[str, Any]=["stage1", "stage2", "stage3"] , snake_case: Tuple=[1, 2, 3] , ) -> Dict: snake_case_ :Dict = parent snake_case_ :List[Any] = batch_size snake_case_ :Dict = image_size snake_case_ :Dict = patch_size snake_case_ :Tuple = num_channels snake_case_ :List[Any] = embed_dim snake_case_ :List[str] = depths snake_case_ :str = num_heads snake_case_ :Tuple = window_size snake_case_ :Tuple = mlp_ratio snake_case_ :int = qkv_bias snake_case_ :Tuple = hidden_dropout_prob snake_case_ :Optional[Any] = attention_probs_dropout_prob snake_case_ :Dict = drop_path_rate snake_case_ :Any = hidden_act snake_case_ :Any = use_absolute_embeddings snake_case_ :int = patch_norm snake_case_ :List[Any] = layer_norm_eps snake_case_ :Tuple = initializer_range snake_case_ :str = is_training snake_case_ :int = scope snake_case_ :Tuple = use_labels snake_case_ :Tuple = type_sequence_label_size snake_case_ :str = encoder_stride snake_case_ :List[Any] = out_features snake_case_ :str = out_indices def lowerCAmelCase_ ( self: Tuple ) -> Dict: snake_case_ :Optional[int] = floats_tensor([self.batch_size, self.num_channels, self.image_size, self.image_size] ) snake_case_ :str = None if self.use_labels: snake_case_ :Optional[int] = ids_tensor([self.batch_size] , self.type_sequence_label_size ) snake_case_ :Union[str, Any] = self.get_config() return config, pixel_values, labels def lowerCAmelCase_ ( self: int ) -> Optional[Any]: return MaskFormerSwinConfig( 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 , out_features=self.out_features , out_indices=self.out_indices , ) def lowerCAmelCase_ ( self: List[Any] , snake_case: str , snake_case: int , snake_case: List[str] ) -> Any: snake_case_ :Dict = MaskFormerSwinModel(config=snake_case ) model.to(snake_case ) model.eval() snake_case_ :Tuple = model(snake_case ) snake_case_ :Dict = ((config.image_size // config.patch_size) ** 2) // (4 ** (len(config.depths ) - 1)) snake_case_ :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 lowerCAmelCase_ ( self: Optional[Any] , snake_case: int , snake_case: List[str] , snake_case: Tuple ) -> Union[str, Any]: snake_case_ :Any = MaskFormerSwinBackbone(config=snake_case ) model.to(snake_case ) model.eval() snake_case_ :Optional[Any] = model(snake_case ) # verify feature maps self.parent.assertEqual(len(result.feature_maps ) , len(config.out_features ) ) self.parent.assertListEqual(list(result.feature_maps[0].shape ) , [13, 16, 16, 16] ) # verify channels self.parent.assertEqual(len(model.channels ) , len(config.out_features ) ) self.parent.assertListEqual(model.channels , [16, 32, 64] ) # verify ValueError with self.parent.assertRaises(snake_case ): snake_case_ :Optional[Any] = ["""stem"""] snake_case_ :str = MaskFormerSwinBackbone(config=snake_case ) def lowerCAmelCase_ ( self: List[str] ) -> Optional[Any]: snake_case_ :Optional[int] = self.prepare_config_and_inputs() snake_case_, snake_case_, snake_case_ :str = config_and_inputs snake_case_ :Tuple = {"""pixel_values""": pixel_values} return config, inputs_dict @require_torch class lowerCamelCase ( _lowerCAmelCase , _lowerCAmelCase , unittest.TestCase ): '''simple docstring''' _A : Union[str, Any] = ( ( MaskFormerSwinModel, MaskFormerSwinBackbone, ) if is_torch_available() else () ) _A : str = {"""feature-extraction""": MaskFormerSwinModel} if is_torch_available() else {} _A : List[str] = False _A : Any = False _A : Dict = False _A : List[Any] = False _A : Optional[int] = False def lowerCAmelCase_ ( self: Dict ) -> Any: snake_case_ :str = MaskFormerSwinModelTester(self ) snake_case_ :Optional[Any] = ConfigTester(self , config_class=snake_case , embed_dim=37 ) @require_torch_multi_gpu @unittest.skip( reason=( """`MaskFormerSwinModel` outputs `hidden_states_spatial_dimensions` which doesn't work well with""" """ `nn.DataParallel`""" ) ) def lowerCAmelCase_ ( self: List[str] ) -> Optional[int]: pass def lowerCAmelCase_ ( self: Union[str, Any] ) -> Dict: self.create_and_test_config_common_properties() 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 lowerCAmelCase_ ( self: Any ) -> Tuple: return def lowerCAmelCase_ ( self: Any ) -> Any: snake_case_ :List[Any] = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_model(*snake_case ) def lowerCAmelCase_ ( self: Union[str, Any] ) -> int: snake_case_ :Any = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_backbone(*snake_case ) @unittest.skip("""Swin does not use inputs_embeds""" ) def lowerCAmelCase_ ( self: str ) -> List[str]: pass @unittest.skip("""Swin does not support feedforward chunking""" ) def lowerCAmelCase_ ( self: int ) -> Optional[int]: pass def lowerCAmelCase_ ( self: List[str] ) -> List[Any]: snake_case_, snake_case_ :List[Any] = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: snake_case_ :str = model_class(snake_case ) self.assertIsInstance(model.get_input_embeddings() , (nn.Module) ) snake_case_ :Dict = model.get_output_embeddings() self.assertTrue(x is None or isinstance(snake_case , nn.Linear ) ) def lowerCAmelCase_ ( self: Tuple ) -> Dict: snake_case_, snake_case_ :int = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: snake_case_ :Optional[int] = model_class(snake_case ) snake_case_ :str = inspect.signature(model.forward ) # signature.parameters is an OrderedDict => so arg_names order is deterministic snake_case_ :str = [*signature.parameters.keys()] snake_case_ :str = ["""pixel_values"""] self.assertListEqual(arg_names[:1] , snake_case ) @unittest.skip(reason="""MaskFormerSwin is only used as backbone and doesn't support output_attentions""" ) def lowerCAmelCase_ ( self: List[Any] ) -> List[Any]: pass @unittest.skip(reason="""MaskFormerSwin is only used as an internal backbone""" ) def lowerCAmelCase_ ( self: Dict ) -> List[Any]: pass def lowerCAmelCase_ ( self: Union[str, Any] , snake_case: Union[str, Any] , snake_case: int , snake_case: Any , snake_case: List[str] ) -> str: snake_case_ :List[str] = 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_ :Any = outputs.hidden_states snake_case_ :Optional[int] = getattr( self.model_tester , """expected_num_hidden_layers""" , len(self.model_tester.depths ) + 1 ) self.assertEqual(len(snake_case ) , snake_case ) # Swin has a different seq_length snake_case_ :str = ( config.patch_size if isinstance(config.patch_size , collections.abc.Iterable ) else (config.patch_size, config.patch_size) ) snake_case_ :int = (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] , ) def lowerCAmelCase_ ( self: List[Any] ) -> Optional[int]: 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_ :Tuple = 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_ :List[Any] = True self.check_hidden_states_output(snake_case , snake_case , snake_case , snake_case ) def lowerCAmelCase_ ( self: Optional[Any] ) -> Tuple: snake_case_, snake_case_ :int = self.model_tester.prepare_config_and_inputs_for_common() snake_case_ :List[Any] = 3 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) ) snake_case_ :Any = ( 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_ :List[str] = image_size[1] + patch_size[1] - (image_size[1] % patch_size[1]) for model_class in self.all_model_classes: snake_case_ :str = 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_ :Any = True self.check_hidden_states_output(snake_case , snake_case , snake_case , (padded_height, padded_width) ) @unittest.skip(reason="""MaskFormerSwin doesn't have pretrained checkpoints""" ) def lowerCAmelCase_ ( self: Union[str, Any] ) -> List[str]: pass @unittest.skip(reason="""This will be fixed once MaskFormerSwin is replaced by native Swin""" ) def lowerCAmelCase_ ( self: List[str] ) -> str: pass @unittest.skip(reason="""This will be fixed once MaskFormerSwin is replaced by native Swin""" ) def lowerCAmelCase_ ( self: str ) -> List[Any]: pass def lowerCAmelCase_ ( self: Union[str, Any] ) -> Optional[Any]: snake_case_, snake_case_ :Dict = self.model_tester.prepare_config_and_inputs_for_common() def set_nan_tensor_to_zero(snake_case: str ): snake_case_ :Optional[int] = 0 return t def check_equivalence(snake_case: List[Any] , snake_case: Union[str, Any] , snake_case: int , snake_case: Tuple={} ): with torch.no_grad(): snake_case_ :List[Any] = model(**snake_case , return_dict=snake_case , **snake_case ) snake_case_ :Any = model(**snake_case , return_dict=snake_case , **snake_case ).to_tuple() def recursive_check(snake_case: List[Any] , snake_case: int ): if isinstance(snake_case , (List, Tuple) ): for tuple_iterable_value, dict_iterable_value in zip(snake_case , snake_case ): recursive_check(snake_case , snake_case ) elif isinstance(snake_case , snake_case ): for tuple_iterable_value, dict_iterable_value in zip( tuple_object.values() , dict_object.values() ): recursive_check(snake_case , snake_case ) elif tuple_object is None: return else: self.assertTrue( torch.allclose( set_nan_tensor_to_zero(snake_case ) , set_nan_tensor_to_zero(snake_case ) , atol=1E-5 ) , msg=( """Tuple and dict output are not equal. Difference:""" f""" {torch.max(torch.abs(tuple_object - dict_object ) )}. Tuple has `nan`:""" f""" {torch.isnan(snake_case ).any()} and `inf`: {torch.isinf(snake_case )}. Dict has""" f""" `nan`: {torch.isnan(snake_case ).any()} and `inf`: {torch.isinf(snake_case )}.""" ) , ) recursive_check(snake_case , snake_case ) for model_class in self.all_model_classes: snake_case_ :int = model_class(snake_case ) model.to(snake_case ) model.eval() snake_case_ :Any = self._prepare_for_class(snake_case , snake_case ) snake_case_ :List[Any] = self._prepare_for_class(snake_case , snake_case ) check_equivalence(snake_case , snake_case , snake_case ) snake_case_ :Tuple = self._prepare_for_class(snake_case , snake_case , return_labels=snake_case ) snake_case_ :Dict = self._prepare_for_class(snake_case , snake_case , return_labels=snake_case ) check_equivalence(snake_case , snake_case , snake_case ) snake_case_ :Tuple = self._prepare_for_class(snake_case , snake_case ) snake_case_ :Any = self._prepare_for_class(snake_case , snake_case ) check_equivalence(snake_case , snake_case , snake_case , {"""output_hidden_states""": True} ) snake_case_ :Dict = self._prepare_for_class(snake_case , snake_case , return_labels=snake_case ) snake_case_ :List[str] = self._prepare_for_class(snake_case , snake_case , return_labels=snake_case ) check_equivalence(snake_case , snake_case , snake_case , {"""output_hidden_states""": True} ) @require_torch class lowerCamelCase ( unittest.TestCase , _lowerCAmelCase ): '''simple docstring''' _A : int = (MaskFormerSwinBackbone,) if is_torch_available() else () _A : Tuple = MaskFormerSwinConfig def lowerCAmelCase_ ( self: List[str] ) -> Optional[int]: snake_case_ :Optional[Any] = MaskFormerSwinModelTester(self ) def lowerCAmelCase_ ( self: int ) -> Optional[int]: snake_case_, snake_case_ :Any = self.model_tester.prepare_config_and_inputs_for_common() snake_case_ :Tuple = inputs_dict["""pixel_values"""].shape[0] for backbone_class in self.all_model_classes: snake_case_ :List[str] = backbone_class(snake_case ) backbone.to(snake_case ) backbone.eval() snake_case_ :List[Any] = backbone(**snake_case ) # Test default outputs and verify feature maps self.assertIsInstance(outputs.feature_maps , snake_case ) self.assertTrue(len(outputs.feature_maps ) == len(backbone.channels ) ) for feature_map, n_channels in zip(outputs.feature_maps , backbone.channels ): self.assertTrue(feature_map.shape[:2] , (batch_size, n_channels) ) self.assertIsNone(outputs.hidden_states ) self.assertIsNone(outputs.attentions ) # Test output_hidden_states=True snake_case_ :Union[str, Any] = backbone(**snake_case , output_hidden_states=snake_case ) self.assertIsNotNone(outputs.hidden_states ) self.assertTrue(len(outputs.hidden_states ) , len(backbone.stage_names ) ) # We skip the stem layer for hidden_states, n_channels in zip(outputs.hidden_states[1:] , backbone.channels ): for hidden_state in hidden_states: # Hidden states are in the format (batch_size, (height * width), n_channels) snake_case_, snake_case_, snake_case_ :List[Any] = hidden_state.shape self.assertTrue((h_batch_size, h_n_channels) , (batch_size, n_channels) ) # Test output_attentions=True if self.has_attentions: snake_case_ :List[Any] = backbone(**snake_case , output_attentions=snake_case ) self.assertIsNotNone(outputs.attentions )
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1
"""simple docstring""" import argparse import torch from transformers import MobileBertConfig, MobileBertForPreTraining, load_tf_weights_in_mobilebert from transformers.utils import logging logging.set_verbosity_info() def A_ ( _lowercase, _lowercase, _lowercase ): '''simple docstring''' snake_case_ :Union[str, Any] = MobileBertConfig.from_json_file(_lowercase ) print(f"""Building PyTorch model from configuration: {config}""" ) snake_case_ :Optional[int] = MobileBertForPreTraining(_lowercase ) # Load weights from tf checkpoint snake_case_ :Union[str, Any] = load_tf_weights_in_mobilebert(_lowercase, _lowercase, _lowercase ) # Save pytorch-model print(f"""Save PyTorch model to {pytorch_dump_path}""" ) torch.save(model.state_dict(), _lowercase ) if __name__ == "__main__": __a = 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( "--mobilebert_config_file", default=None, type=str, required=True, help=( "The config json file corresponding to the pre-trained MobileBERT model. \n" "This specifies the model architecture." ), ) parser.add_argument( "--pytorch_dump_path", default=None, type=str, required=True, help="Path to the output PyTorch model." ) __a = parser.parse_args() convert_tf_checkpoint_to_pytorch(args.tf_checkpoint_path, args.mobilebert_config_file, args.pytorch_dump_path)
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"""simple docstring""" import gc import math import unittest import torch from diffusers import UNetaDModel from diffusers.utils import floats_tensor, logging, slow, torch_all_close, torch_device from diffusers.utils.testing_utils import enable_full_determinism from .test_modeling_common import ModelTesterMixin, UNetTesterMixin __a = logging.get_logger(__name__) enable_full_determinism() class lowerCamelCase ( _lowerCAmelCase , _lowerCAmelCase , unittest.TestCase ): '''simple docstring''' _A : List[Any] = UNetaDModel _A : Union[str, Any] = """sample""" @property def lowerCAmelCase_ ( self: str ) -> Tuple: snake_case_ :List[str] = 4 snake_case_ :Tuple = 3 snake_case_ :Optional[Any] = (32, 32) snake_case_ :str = floats_tensor((batch_size, num_channels) + sizes ).to(snake_case ) snake_case_ :Union[str, Any] = torch.tensor([10] ).to(snake_case ) return {"sample": noise, "timestep": time_step} @property def lowerCAmelCase_ ( self: List[str] ) -> Dict: return (3, 32, 32) @property def lowerCAmelCase_ ( self: Optional[int] ) -> Optional[int]: return (3, 32, 32) def lowerCAmelCase_ ( self: Optional[int] ) -> Dict: snake_case_ :Any = { """block_out_channels""": (32, 64), """down_block_types""": ("""DownBlock2D""", """AttnDownBlock2D"""), """up_block_types""": ("""AttnUpBlock2D""", """UpBlock2D"""), """attention_head_dim""": 3, """out_channels""": 3, """in_channels""": 3, """layers_per_block""": 2, """sample_size""": 32, } snake_case_ :Tuple = self.dummy_input return init_dict, inputs_dict class lowerCamelCase ( _lowerCAmelCase , _lowerCAmelCase , unittest.TestCase ): '''simple docstring''' _A : List[str] = UNetaDModel _A : Union[str, Any] = """sample""" @property def lowerCAmelCase_ ( self: str ) -> str: snake_case_ :List[str] = 4 snake_case_ :Optional[int] = 4 snake_case_ :int = (32, 32) snake_case_ :Any = floats_tensor((batch_size, num_channels) + sizes ).to(snake_case ) snake_case_ :List[Any] = torch.tensor([10] ).to(snake_case ) return {"sample": noise, "timestep": time_step} @property def lowerCAmelCase_ ( self: Optional[int] ) -> Optional[int]: return (4, 32, 32) @property def lowerCAmelCase_ ( self: List[Any] ) -> int: return (4, 32, 32) def lowerCAmelCase_ ( self: Union[str, Any] ) -> List[Any]: snake_case_ :Dict = { """sample_size""": 32, """in_channels""": 4, """out_channels""": 4, """layers_per_block""": 2, """block_out_channels""": (32, 64), """attention_head_dim""": 32, """down_block_types""": ("""DownBlock2D""", """DownBlock2D"""), """up_block_types""": ("""UpBlock2D""", """UpBlock2D"""), } snake_case_ :List[str] = self.dummy_input return init_dict, inputs_dict def lowerCAmelCase_ ( self: Optional[int] ) -> Optional[Any]: snake_case_, snake_case_ :List[str] = UNetaDModel.from_pretrained("""fusing/unet-ldm-dummy-update""" , output_loading_info=snake_case ) self.assertIsNotNone(snake_case ) self.assertEqual(len(loading_info["""missing_keys"""] ) , 0 ) model.to(snake_case ) snake_case_ :List[str] = model(**self.dummy_input ).sample assert image is not None, "Make sure output is not None" @unittest.skipIf(torch_device != """cuda""" , """This test is supposed to run on GPU""" ) def lowerCAmelCase_ ( self: Tuple ) -> Dict: snake_case_, snake_case_ :Union[str, Any] = UNetaDModel.from_pretrained("""fusing/unet-ldm-dummy-update""" , output_loading_info=snake_case ) model.to(snake_case ) snake_case_ :Union[str, Any] = model(**self.dummy_input ).sample assert image is not None, "Make sure output is not None" @unittest.skipIf(torch_device != """cuda""" , """This test is supposed to run on GPU""" ) def lowerCAmelCase_ ( self: str ) -> Any: # by defautl model loading will use accelerate as `low_cpu_mem_usage=True` snake_case_, snake_case_ :List[str] = UNetaDModel.from_pretrained("""fusing/unet-ldm-dummy-update""" , output_loading_info=snake_case ) model_accelerate.to(snake_case ) model_accelerate.eval() snake_case_ :List[Any] = torch.randn( 1 , model_accelerate.config.in_channels , model_accelerate.config.sample_size , model_accelerate.config.sample_size , generator=torch.manual_seed(0 ) , ) snake_case_ :int = noise.to(snake_case ) snake_case_ :str = torch.tensor([10] * noise.shape[0] ).to(snake_case ) snake_case_ :Optional[int] = model_accelerate(snake_case , snake_case )["""sample"""] # two models don't need to stay in the device at the same time del model_accelerate torch.cuda.empty_cache() gc.collect() snake_case_, snake_case_ :str = UNetaDModel.from_pretrained( """fusing/unet-ldm-dummy-update""" , output_loading_info=snake_case , low_cpu_mem_usage=snake_case ) model_normal_load.to(snake_case ) model_normal_load.eval() snake_case_ :int = model_normal_load(snake_case , snake_case )["""sample"""] assert torch_all_close(snake_case , snake_case , rtol=1E-3 ) def lowerCAmelCase_ ( self: Tuple ) -> Any: snake_case_ :Tuple = UNetaDModel.from_pretrained("""fusing/unet-ldm-dummy-update""" ) model.eval() model.to(snake_case ) snake_case_ :Optional[int] = torch.randn( 1 , model.config.in_channels , model.config.sample_size , model.config.sample_size , generator=torch.manual_seed(0 ) , ) snake_case_ :int = noise.to(snake_case ) snake_case_ :List[Any] = torch.tensor([10] * noise.shape[0] ).to(snake_case ) with torch.no_grad(): snake_case_ :Union[str, Any] = model(snake_case , snake_case ).sample snake_case_ :Optional[int] = output[0, -1, -3:, -3:].flatten().cpu() # fmt: off snake_case_ :Dict = torch.tensor([-1_3.3_2_5_8, -2_0.1_1_0_0, -1_5.9_8_7_3, -1_7.6_6_1_7, -2_3.0_5_9_6, -1_7.9_4_1_9, -1_3.3_6_7_5, -1_6.1_8_8_9, -1_2.3_8_0_0] ) # fmt: on self.assertTrue(torch_all_close(snake_case , snake_case , rtol=1E-3 ) ) class lowerCamelCase ( _lowerCAmelCase , _lowerCAmelCase , unittest.TestCase ): '''simple docstring''' _A : List[Any] = UNetaDModel _A : List[Any] = """sample""" @property def lowerCAmelCase_ ( self: Union[str, Any] , snake_case: int=(32, 32) ) -> Tuple: snake_case_ :Union[str, Any] = 4 snake_case_ :Any = 3 snake_case_ :int = floats_tensor((batch_size, num_channels) + sizes ).to(snake_case ) snake_case_ :Any = torch.tensor(batch_size * [10] ).to(dtype=torch.intaa , device=snake_case ) return {"sample": noise, "timestep": time_step} @property def lowerCAmelCase_ ( self: Union[str, Any] ) -> Any: return (3, 32, 32) @property def lowerCAmelCase_ ( self: int ) -> Tuple: return (3, 32, 32) def lowerCAmelCase_ ( self: List[str] ) -> Tuple: snake_case_ :List[Any] = { """block_out_channels""": [32, 64, 64, 64], """in_channels""": 3, """layers_per_block""": 1, """out_channels""": 3, """time_embedding_type""": """fourier""", """norm_eps""": 1E-6, """mid_block_scale_factor""": math.sqrt(2.0 ), """norm_num_groups""": None, """down_block_types""": [ """SkipDownBlock2D""", """AttnSkipDownBlock2D""", """SkipDownBlock2D""", """SkipDownBlock2D""", ], """up_block_types""": [ """SkipUpBlock2D""", """SkipUpBlock2D""", """AttnSkipUpBlock2D""", """SkipUpBlock2D""", ], } snake_case_ :int = self.dummy_input return init_dict, inputs_dict @slow def lowerCAmelCase_ ( self: Optional[Any] ) -> List[Any]: snake_case_, snake_case_ :List[Any] = UNetaDModel.from_pretrained("""google/ncsnpp-celebahq-256""" , output_loading_info=snake_case ) self.assertIsNotNone(snake_case ) self.assertEqual(len(loading_info["""missing_keys"""] ) , 0 ) model.to(snake_case ) snake_case_ :Any = self.dummy_input snake_case_ :int = floats_tensor((4, 3) + (256, 256) ).to(snake_case ) snake_case_ :int = noise snake_case_ :int = model(**snake_case ) assert image is not None, "Make sure output is not None" @slow def lowerCAmelCase_ ( self: str ) -> Dict: snake_case_ :Dict = UNetaDModel.from_pretrained("""google/ncsnpp-celebahq-256""" ) model.to(snake_case ) snake_case_ :List[str] = 4 snake_case_ :Optional[int] = 3 snake_case_ :List[str] = (256, 256) snake_case_ :Tuple = torch.ones((batch_size, num_channels) + sizes ).to(snake_case ) snake_case_ :str = torch.tensor(batch_size * [1E-4] ).to(snake_case ) with torch.no_grad(): snake_case_ :Dict = model(snake_case , snake_case ).sample snake_case_ :int = output[0, -3:, -3:, -1].flatten().cpu() # fmt: off snake_case_ :Optional[Any] = torch.tensor([-4_8_4_2.8_6_9_1, -6_4_9_9.6_6_3_1, -3_8_0_0.1_9_5_3, -7_9_7_8.2_6_8_6, -1_0_9_8_0.7_1_2_9, -2_0_0_2_8.8_5_3_5, 8_1_4_8.2_8_2_2, 2_3_4_2.2_9_0_5, 5_6_7.7_6_0_8] ) # fmt: on self.assertTrue(torch_all_close(snake_case , snake_case , rtol=1E-2 ) ) def lowerCAmelCase_ ( self: List[str] ) -> List[Any]: snake_case_ :Optional[Any] = UNetaDModel.from_pretrained("""fusing/ncsnpp-ffhq-ve-dummy-update""" ) model.to(snake_case ) snake_case_ :Optional[int] = 4 snake_case_ :Optional[Any] = 3 snake_case_ :Optional[Any] = (32, 32) snake_case_ :Dict = torch.ones((batch_size, num_channels) + sizes ).to(snake_case ) snake_case_ :Any = torch.tensor(batch_size * [1E-4] ).to(snake_case ) with torch.no_grad(): snake_case_ :str = model(snake_case , snake_case ).sample snake_case_ :int = output[0, -3:, -3:, -1].flatten().cpu() # fmt: off snake_case_ :int = torch.tensor([-0.0_3_2_5, -0.0_9_0_0, -0.0_8_6_9, -0.0_3_3_2, -0.0_7_2_5, -0.0_2_7_0, -0.0_1_0_1, 0.0_2_2_7, 0.0_2_5_6] ) # fmt: on self.assertTrue(torch_all_close(snake_case , snake_case , rtol=1E-2 ) ) def lowerCAmelCase_ ( self: Dict ) -> Optional[Any]: # not required for this model pass
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"""simple docstring""" import unittest import numpy as np from transformers import BertConfig, is_flax_available from transformers.testing_utils import require_flax, slow from ...test_modeling_flax_common import FlaxModelTesterMixin, floats_tensor, ids_tensor, random_attention_mask if is_flax_available(): from transformers.models.bert.modeling_flax_bert import ( FlaxBertForMaskedLM, FlaxBertForMultipleChoice, FlaxBertForNextSentencePrediction, FlaxBertForPreTraining, FlaxBertForQuestionAnswering, FlaxBertForSequenceClassification, FlaxBertForTokenClassification, FlaxBertModel, ) class lowerCamelCase ( unittest.TestCase ): '''simple docstring''' def __init__( self: List[Any] , snake_case: List[str] , snake_case: Optional[Any]=13 , snake_case: List[str]=7 , snake_case: Dict=True , snake_case: List[str]=True , snake_case: Optional[int]=True , snake_case: Any=True , snake_case: Optional[Any]=99 , snake_case: Tuple=32 , snake_case: Tuple=5 , snake_case: Dict=4 , snake_case: Optional[Any]=37 , snake_case: Union[str, Any]="gelu" , snake_case: Tuple=0.1 , snake_case: List[Any]=0.1 , snake_case: List[str]=512 , snake_case: Optional[int]=16 , snake_case: int=2 , snake_case: List[Any]=0.0_2 , snake_case: Union[str, Any]=4 , ) -> List[str]: snake_case_ :Dict = parent snake_case_ :Any = batch_size snake_case_ :Any = seq_length snake_case_ :List[str] = is_training snake_case_ :Optional[Any] = use_attention_mask snake_case_ :Dict = use_token_type_ids snake_case_ :Union[str, Any] = use_labels snake_case_ :str = vocab_size snake_case_ :int = hidden_size snake_case_ :List[str] = num_hidden_layers snake_case_ :Dict = num_attention_heads snake_case_ :Any = intermediate_size snake_case_ :Tuple = hidden_act snake_case_ :int = hidden_dropout_prob snake_case_ :Optional[Any] = attention_probs_dropout_prob snake_case_ :Any = max_position_embeddings snake_case_ :Union[str, Any] = type_vocab_size snake_case_ :Optional[int] = type_sequence_label_size snake_case_ :Union[str, Any] = initializer_range snake_case_ :Tuple = num_choices def lowerCAmelCase_ ( self: Tuple ) -> str: snake_case_ :Optional[Any] = ids_tensor([self.batch_size, self.seq_length] , self.vocab_size ) snake_case_ :Union[str, Any] = None if self.use_attention_mask: snake_case_ :str = random_attention_mask([self.batch_size, self.seq_length] ) snake_case_ :Any = None if self.use_token_type_ids: snake_case_ :List[str] = ids_tensor([self.batch_size, self.seq_length] , self.type_vocab_size ) snake_case_ :int = BertConfig( 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 , ) return config, input_ids, token_type_ids, attention_mask def lowerCAmelCase_ ( self: Optional[int] ) -> int: snake_case_ :str = self.prepare_config_and_inputs() snake_case_, snake_case_, snake_case_, snake_case_ :Optional[int] = config_and_inputs snake_case_ :Union[str, Any] = {"""input_ids""": input_ids, """token_type_ids""": token_type_ids, """attention_mask""": attention_mask} return config, inputs_dict def lowerCAmelCase_ ( self: Optional[Any] ) -> Any: snake_case_ :int = self.prepare_config_and_inputs() snake_case_, snake_case_, snake_case_, snake_case_ :Dict = config_and_inputs snake_case_ :Union[str, Any] = True snake_case_ :Optional[int] = floats_tensor([self.batch_size, self.seq_length, self.hidden_size] ) snake_case_ :Tuple = ids_tensor([self.batch_size, self.seq_length] , vocab_size=2 ) return ( config, input_ids, attention_mask, encoder_hidden_states, encoder_attention_mask, ) @require_flax class lowerCamelCase ( _lowerCAmelCase , unittest.TestCase ): '''simple docstring''' _A : List[str] = True _A : Dict = ( ( FlaxBertModel, FlaxBertForPreTraining, FlaxBertForMaskedLM, FlaxBertForMultipleChoice, FlaxBertForQuestionAnswering, FlaxBertForNextSentencePrediction, FlaxBertForSequenceClassification, FlaxBertForTokenClassification, FlaxBertForQuestionAnswering, ) if is_flax_available() else () ) def lowerCAmelCase_ ( self: int ) -> List[str]: snake_case_ :Any = FlaxBertModelTester(self ) @slow def lowerCAmelCase_ ( self: List[str] ) -> Dict: # Only check this for base model, not necessary for all model classes. # This will also help speed-up tests. snake_case_ :Dict = FlaxBertModel.from_pretrained("""bert-base-cased""" ) snake_case_ :Dict = model(np.ones((1, 1) ) ) self.assertIsNotNone(snake_case )
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"""simple docstring""" from typing import TYPE_CHECKING from ...utils import OptionalDependencyNotAvailable, _LazyModule, is_torch_available, is_vision_available __a = { "configuration_mask2former": [ "MASK2FORMER_PRETRAINED_CONFIG_ARCHIVE_MAP", "Mask2FormerConfig", ], } try: if not is_vision_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __a = ["Mask2FormerImageProcessor"] try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __a = [ "MASK2FORMER_PRETRAINED_MODEL_ARCHIVE_LIST", "Mask2FormerForUniversalSegmentation", "Mask2FormerModel", "Mask2FormerPreTrainedModel", ] if TYPE_CHECKING: from .configuration_maskaformer import MASK2FORMER_PRETRAINED_CONFIG_ARCHIVE_MAP, MaskaFormerConfig try: if not is_vision_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .image_processing_maskaformer import MaskaFormerImageProcessor try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_maskaformer import ( MASK2FORMER_PRETRAINED_MODEL_ARCHIVE_LIST, MaskaFormerForUniversalSegmentation, MaskaFormerModel, MaskaFormerPreTrainedModel, ) else: import sys __a = _LazyModule(__name__, globals()["__file__"], _import_structure)
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"""simple docstring""" def A_ ( _lowercase ): '''simple docstring''' if not isinstance(_lowercase, _lowercase ): raise TypeError("""Input value must be an 'int' type""" ) snake_case_ :Any = 0 while number: position += 1 number >>= 1 return position if __name__ == "__main__": import doctest doctest.testmod()
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"""simple docstring""" import gc import unittest import numpy as np import torch from transformers import CLIPTextConfig, CLIPTextModel, CLIPTokenizer from diffusers import ( AutoencoderKL, DDIMScheduler, StableDiffusionSAGPipeline, UNetaDConditionModel, ) from diffusers.utils import slow, torch_device from diffusers.utils.testing_utils import enable_full_determinism, require_torch_gpu 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() class lowerCamelCase ( _lowerCAmelCase , _lowerCAmelCase , unittest.TestCase ): '''simple docstring''' _A : str = StableDiffusionSAGPipeline _A : Optional[Any] = TEXT_TO_IMAGE_PARAMS _A : Any = TEXT_TO_IMAGE_BATCH_PARAMS _A : Tuple = TEXT_TO_IMAGE_IMAGE_PARAMS _A : Tuple = TEXT_TO_IMAGE_IMAGE_PARAMS _A : List[str] = False def lowerCAmelCase_ ( self: Optional[Any] ) -> str: torch.manual_seed(0 ) snake_case_ :Any = UNetaDConditionModel( block_out_channels=(32, 64) , layers_per_block=2 , sample_size=32 , in_channels=4 , out_channels=4 , down_block_types=("""DownBlock2D""", """CrossAttnDownBlock2D""") , up_block_types=("""CrossAttnUpBlock2D""", """UpBlock2D""") , cross_attention_dim=32 , ) snake_case_ :Any = DDIMScheduler( beta_start=0.0_0_0_8_5 , beta_end=0.0_1_2 , beta_schedule="""scaled_linear""" , clip_sample=snake_case , set_alpha_to_one=snake_case , ) torch.manual_seed(0 ) snake_case_ :Optional[int] = AutoencoderKL( block_out_channels=[32, 64] , in_channels=3 , out_channels=3 , down_block_types=["""DownEncoderBlock2D""", """DownEncoderBlock2D"""] , up_block_types=["""UpDecoderBlock2D""", """UpDecoderBlock2D"""] , latent_channels=4 , ) torch.manual_seed(0 ) snake_case_ :Union[str, Any] = CLIPTextConfig( bos_token_id=0 , eos_token_id=2 , hidden_size=32 , intermediate_size=37 , layer_norm_eps=1E-05 , num_attention_heads=4 , num_hidden_layers=5 , pad_token_id=1 , vocab_size=1_000 , ) snake_case_ :Tuple = CLIPTextModel(snake_case ) snake_case_ :str = CLIPTokenizer.from_pretrained("""hf-internal-testing/tiny-random-clip""" ) snake_case_ :Dict = { """unet""": unet, """scheduler""": scheduler, """vae""": vae, """text_encoder""": text_encoder, """tokenizer""": tokenizer, """safety_checker""": None, """feature_extractor""": None, } return components def lowerCAmelCase_ ( self: List[str] , snake_case: Tuple , snake_case: List[str]=0 ) -> str: if str(snake_case ).startswith("""mps""" ): snake_case_ :Tuple = torch.manual_seed(snake_case ) else: snake_case_ :Optional[int] = torch.Generator(device=snake_case ).manual_seed(snake_case ) snake_case_ :Any = { """prompt""": """.""", """generator""": generator, """num_inference_steps""": 2, """guidance_scale""": 1.0, """sag_scale""": 1.0, """output_type""": """numpy""", } return inputs def lowerCAmelCase_ ( self: Optional[int] ) -> str: super().test_inference_batch_single_identical(expected_max_diff=3E-3 ) @slow @require_torch_gpu class lowerCamelCase ( unittest.TestCase ): '''simple docstring''' def lowerCAmelCase_ ( self: int ) -> str: # clean up the VRAM after each test super().tearDown() gc.collect() torch.cuda.empty_cache() def lowerCAmelCase_ ( self: int ) -> List[str]: snake_case_ :Any = StableDiffusionSAGPipeline.from_pretrained("""CompVis/stable-diffusion-v1-4""" ) snake_case_ :int = sag_pipe.to(snake_case ) sag_pipe.set_progress_bar_config(disable=snake_case ) snake_case_ :Union[str, Any] = """.""" snake_case_ :str = torch.manual_seed(0 ) snake_case_ :str = sag_pipe( [prompt] , generator=snake_case , guidance_scale=7.5 , sag_scale=1.0 , num_inference_steps=20 , output_type="""np""" ) snake_case_ :List[Any] = output.images snake_case_ :Tuple = image[0, -3:, -3:, -1] assert image.shape == (1, 512, 512, 3) snake_case_ :List[Any] = np.array([0.1_5_6_8, 0.1_7_3_8, 0.1_6_9_5, 0.1_6_9_3, 0.1_5_0_7, 0.1_7_0_5, 0.1_5_4_7, 0.1_7_5_1, 0.1_9_4_9] ) assert np.abs(image_slice.flatten() - expected_slice ).max() < 5E-2 def lowerCAmelCase_ ( self: Dict ) -> str: snake_case_ :Tuple = StableDiffusionSAGPipeline.from_pretrained("""stabilityai/stable-diffusion-2-1-base""" ) snake_case_ :Optional[int] = sag_pipe.to(snake_case ) sag_pipe.set_progress_bar_config(disable=snake_case ) snake_case_ :Tuple = """.""" snake_case_ :Union[str, Any] = torch.manual_seed(0 ) snake_case_ :Tuple = sag_pipe( [prompt] , generator=snake_case , guidance_scale=7.5 , sag_scale=1.0 , num_inference_steps=20 , output_type="""np""" ) snake_case_ :Optional[int] = output.images snake_case_ :Optional[Any] = image[0, -3:, -3:, -1] assert image.shape == (1, 512, 512, 3) snake_case_ :Tuple = np.array([0.3_4_5_9, 0.2_8_7_6, 0.2_5_3_7, 0.3_0_0_2, 0.2_6_7_1, 0.2_1_6_0, 0.3_0_2_6, 0.2_2_6_2, 0.2_3_7_1] ) assert np.abs(image_slice.flatten() - expected_slice ).max() < 5E-2 def lowerCAmelCase_ ( self: List[str] ) -> List[str]: snake_case_ :Optional[int] = StableDiffusionSAGPipeline.from_pretrained("""stabilityai/stable-diffusion-2-1-base""" ) snake_case_ :int = sag_pipe.to(snake_case ) sag_pipe.set_progress_bar_config(disable=snake_case ) snake_case_ :Tuple = """.""" snake_case_ :Optional[int] = torch.manual_seed(0 ) snake_case_ :List[str] = sag_pipe( [prompt] , width=768 , height=512 , generator=snake_case , guidance_scale=7.5 , sag_scale=1.0 , num_inference_steps=20 , output_type="""np""" , ) snake_case_ :Optional[Any] = output.images assert image.shape == (1, 512, 768, 3)
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"""simple docstring""" import json from typing import List, Optional, Tuple from tokenizers import normalizers from ...tokenization_utils_fast import PreTrainedTokenizerFast from ...utils import logging from .tokenization_distilbert import DistilBertTokenizer __a = logging.get_logger(__name__) __a = {"vocab_file": "vocab.txt", "tokenizer_file": "tokenizer.json"} __a = { "vocab_file": { "distilbert-base-uncased": "https://huggingface.co/distilbert-base-uncased/resolve/main/vocab.txt", "distilbert-base-uncased-distilled-squad": ( "https://huggingface.co/distilbert-base-uncased-distilled-squad/resolve/main/vocab.txt" ), "distilbert-base-cased": "https://huggingface.co/distilbert-base-cased/resolve/main/vocab.txt", "distilbert-base-cased-distilled-squad": ( "https://huggingface.co/distilbert-base-cased-distilled-squad/resolve/main/vocab.txt" ), "distilbert-base-german-cased": "https://huggingface.co/distilbert-base-german-cased/resolve/main/vocab.txt", "distilbert-base-multilingual-cased": ( "https://huggingface.co/distilbert-base-multilingual-cased/resolve/main/vocab.txt" ), }, "tokenizer_file": { "distilbert-base-uncased": "https://huggingface.co/distilbert-base-uncased/resolve/main/tokenizer.json", "distilbert-base-uncased-distilled-squad": ( "https://huggingface.co/distilbert-base-uncased-distilled-squad/resolve/main/tokenizer.json" ), "distilbert-base-cased": "https://huggingface.co/distilbert-base-cased/resolve/main/tokenizer.json", "distilbert-base-cased-distilled-squad": ( "https://huggingface.co/distilbert-base-cased-distilled-squad/resolve/main/tokenizer.json" ), "distilbert-base-german-cased": ( "https://huggingface.co/distilbert-base-german-cased/resolve/main/tokenizer.json" ), "distilbert-base-multilingual-cased": ( "https://huggingface.co/distilbert-base-multilingual-cased/resolve/main/tokenizer.json" ), }, } __a = { "distilbert-base-uncased": 5_12, "distilbert-base-uncased-distilled-squad": 5_12, "distilbert-base-cased": 5_12, "distilbert-base-cased-distilled-squad": 5_12, "distilbert-base-german-cased": 5_12, "distilbert-base-multilingual-cased": 5_12, } __a = { "distilbert-base-uncased": {"do_lower_case": True}, "distilbert-base-uncased-distilled-squad": {"do_lower_case": True}, "distilbert-base-cased": {"do_lower_case": False}, "distilbert-base-cased-distilled-squad": {"do_lower_case": False}, "distilbert-base-german-cased": {"do_lower_case": False}, "distilbert-base-multilingual-cased": {"do_lower_case": False}, } class lowerCamelCase ( _lowerCAmelCase ): '''simple docstring''' _A : int = VOCAB_FILES_NAMES _A : List[Any] = PRETRAINED_VOCAB_FILES_MAP _A : Dict = PRETRAINED_POSITIONAL_EMBEDDINGS_SIZES _A : List[Any] = PRETRAINED_INIT_CONFIGURATION _A : int = ["""input_ids""", """attention_mask"""] _A : str = DistilBertTokenizer def __init__( self: List[Any] , snake_case: Dict=None , snake_case: Tuple=None , snake_case: List[str]=True , snake_case: int="[UNK]" , snake_case: List[str]="[SEP]" , snake_case: Any="[PAD]" , snake_case: List[Any]="[CLS]" , snake_case: int="[MASK]" , snake_case: Optional[Any]=True , snake_case: Dict=None , **snake_case: List[str] , ) -> Optional[int]: super().__init__( snake_case , tokenizer_file=snake_case , do_lower_case=snake_case , unk_token=snake_case , sep_token=snake_case , pad_token=snake_case , cls_token=snake_case , mask_token=snake_case , tokenize_chinese_chars=snake_case , strip_accents=snake_case , **snake_case , ) snake_case_ :str = json.loads(self.backend_tokenizer.normalizer.__getstate__() ) if ( normalizer_state.get("""lowercase""" , snake_case ) != do_lower_case or normalizer_state.get("""strip_accents""" , snake_case ) != strip_accents or normalizer_state.get("""handle_chinese_chars""" , snake_case ) != tokenize_chinese_chars ): snake_case_ :Optional[Any] = getattr(snake_case , normalizer_state.pop("""type""" ) ) snake_case_ :Any = do_lower_case snake_case_ :Optional[int] = strip_accents snake_case_ :Optional[Any] = tokenize_chinese_chars snake_case_ :Dict = normalizer_class(**snake_case ) snake_case_ :Optional[Any] = do_lower_case def lowerCAmelCase_ ( self: Dict , snake_case: Union[str, Any] , snake_case: Union[str, Any]=None ) -> int: snake_case_ :Union[str, Any] = [self.cls_token_id] + token_ids_a + [self.sep_token_id] if token_ids_a: output += token_ids_a + [self.sep_token_id] return output def lowerCAmelCase_ ( self: Any , snake_case: List[int] , snake_case: Optional[List[int]] = None ) -> List[int]: snake_case_ :List[Any] = [self.sep_token_id] snake_case_ :List[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 ) * [0] + len(token_ids_a + sep ) * [1] def lowerCAmelCase_ ( self: str , snake_case: str , snake_case: Optional[str] = None ) -> Tuple[str]: snake_case_ :Any = self._tokenizer.model.save(snake_case , name=snake_case ) return tuple(snake_case )
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"""simple docstring""" from __future__ import annotations from collections import Counter from random import random class lowerCamelCase : '''simple docstring''' def __init__( self: Tuple ) -> Optional[Any]: snake_case_ :Optional[int] = {} def lowerCAmelCase_ ( self: Dict , snake_case: str ) -> None: snake_case_ :str = {} def lowerCAmelCase_ ( self: Optional[int] , snake_case: str , snake_case: str , snake_case: float ) -> None: if nodea not in self.connections: self.add_node(snake_case ) if nodea not in self.connections: self.add_node(snake_case ) snake_case_ :Dict = probability def lowerCAmelCase_ ( self: List[Any] ) -> list[str]: return list(self.connections ) def lowerCAmelCase_ ( self: Any , snake_case: str ) -> str: snake_case_ :Optional[Any] = 0 snake_case_ :List[str] = random() for dest in self.connections[node]: current_probability += self.connections[node][dest] if current_probability > random_value: return dest return "" def A_ ( _lowercase, _lowercase, _lowercase ): '''simple docstring''' snake_case_ :List[str] = MarkovChainGraphUndirectedUnweighted() for nodea, nodea, probability in transitions: graph.add_transition_probability(_lowercase, _lowercase, _lowercase ) snake_case_ :int = Counter(graph.get_nodes() ) snake_case_ :Optional[Any] = start for _ in range(_lowercase ): snake_case_ :Tuple = graph.transition(_lowercase ) visited[node] += 1 return visited if __name__ == "__main__": import doctest doctest.testmod()
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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 LevitImageProcessor class lowerCamelCase ( unittest.TestCase ): '''simple docstring''' def __init__( self: int , snake_case: int , snake_case: Tuple=7 , snake_case: Optional[int]=3 , snake_case: List[Any]=18 , snake_case: Dict=30 , snake_case: Optional[int]=400 , snake_case: int=True , snake_case: Dict=None , snake_case: Dict=True , snake_case: Tuple=None , snake_case: Optional[Any]=True , snake_case: Dict=[0.5, 0.5, 0.5] , snake_case: Union[str, Any]=[0.5, 0.5, 0.5] , ) -> int: snake_case_ :Tuple = size if size is not None else {"""shortest_edge""": 18} snake_case_ :Dict = crop_size if crop_size is not None else {"""height""": 18, """width""": 18} snake_case_ :str = parent snake_case_ :int = batch_size snake_case_ :Tuple = num_channels snake_case_ :Any = image_size snake_case_ :int = min_resolution snake_case_ :Dict = max_resolution snake_case_ :Any = do_resize snake_case_ :Optional[int] = size snake_case_ :Optional[int] = do_center_crop snake_case_ :Dict = crop_size snake_case_ :int = do_normalize snake_case_ :Optional[Any] = image_mean snake_case_ :Optional[Any] = image_std def lowerCAmelCase_ ( self: List[Any] ) -> 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 lowerCamelCase ( _lowerCAmelCase , unittest.TestCase ): '''simple docstring''' _A : List[str] = LevitImageProcessor if is_vision_available() else None def lowerCAmelCase_ ( self: List[Any] ) -> str: snake_case_ :List[str] = LevitImageProcessingTester(self ) @property def lowerCAmelCase_ ( self: str ) -> Dict: return self.image_processor_tester.prepare_image_processor_dict() def lowerCAmelCase_ ( self: List[Any] ) -> Any: snake_case_ :Any = 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 lowerCAmelCase_ ( self: Dict ) -> List[str]: snake_case_ :List[Any] = 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_ :Tuple = 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 lowerCAmelCase_ ( self: Optional[int] ) -> List[str]: pass def lowerCAmelCase_ ( self: int ) -> Optional[Any]: # Initialize image_processing snake_case_ :str = 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_ :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_ :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"""], ) , ) def lowerCAmelCase_ ( self: List[Any] ) -> List[Any]: # Initialize image_processing snake_case_ :List[str] = self.image_processing_class(**self.image_processor_dict ) # create random numpy tensors snake_case_ :Union[str, Any] = 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_ :Union[str, Any] = 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[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 lowerCAmelCase_ ( self: List[str] ) -> int: # Initialize image_processing snake_case_ :Optional[int] = self.image_processing_class(**self.image_processor_dict ) # create random PyTorch tensors snake_case_ :Any = 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_ :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_ :Optional[int] = 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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"""simple docstring""" import argparse import collections import os import re import tempfile import pandas as pd from datasets import Dataset from huggingface_hub import hf_hub_download, upload_folder from transformers.utils import direct_transformers_import # All paths are set with the intent you should run this script from the root of the repo with the command # python utils/update_metadata.py __a = "src/transformers" # This is to make sure the transformers module imported is the one in the repo. __a = direct_transformers_import(TRANSFORMERS_PATH) # Regexes that match TF/Flax/PT model names. __a = re.compile(r"TF(.*)(?:Model|Encoder|Decoder|ForConditionalGeneration)") __a = re.compile(r"Flax(.*)(?:Model|Encoder|Decoder|ForConditionalGeneration)") # Will match any TF or Flax model too so need to be in an else branch afterthe two previous regexes. __a = re.compile(r"(.*)(?:Model|Encoder|Decoder|ForConditionalGeneration)") # Fill this with tuples (pipeline_tag, model_mapping, auto_model) __a = [ ("pretraining", "MODEL_FOR_PRETRAINING_MAPPING_NAMES", "AutoModelForPreTraining"), ("feature-extraction", "MODEL_MAPPING_NAMES", "AutoModel"), ("audio-classification", "MODEL_FOR_AUDIO_CLASSIFICATION_MAPPING_NAMES", "AutoModelForAudioClassification"), ("text-generation", "MODEL_FOR_CAUSAL_LM_MAPPING_NAMES", "AutoModelForCausalLM"), ("automatic-speech-recognition", "MODEL_FOR_CTC_MAPPING_NAMES", "AutoModelForCTC"), ("image-classification", "MODEL_FOR_IMAGE_CLASSIFICATION_MAPPING_NAMES", "AutoModelForImageClassification"), ("image-segmentation", "MODEL_FOR_IMAGE_SEGMENTATION_MAPPING_NAMES", "AutoModelForImageSegmentation"), ("fill-mask", "MODEL_FOR_MASKED_LM_MAPPING_NAMES", "AutoModelForMaskedLM"), ("object-detection", "MODEL_FOR_OBJECT_DETECTION_MAPPING_NAMES", "AutoModelForObjectDetection"), ( "zero-shot-object-detection", "MODEL_FOR_ZERO_SHOT_OBJECT_DETECTION_MAPPING_NAMES", "AutoModelForZeroShotObjectDetection", ), ("question-answering", "MODEL_FOR_QUESTION_ANSWERING_MAPPING_NAMES", "AutoModelForQuestionAnswering"), ("text2text-generation", "MODEL_FOR_SEQ_TO_SEQ_CAUSAL_LM_MAPPING_NAMES", "AutoModelForSeq2SeqLM"), ("text-classification", "MODEL_FOR_SEQUENCE_CLASSIFICATION_MAPPING_NAMES", "AutoModelForSequenceClassification"), ("automatic-speech-recognition", "MODEL_FOR_SPEECH_SEQ_2_SEQ_MAPPING_NAMES", "AutoModelForSpeechSeq2Seq"), ( "table-question-answering", "MODEL_FOR_TABLE_QUESTION_ANSWERING_MAPPING_NAMES", "AutoModelForTableQuestionAnswering", ), ("token-classification", "MODEL_FOR_TOKEN_CLASSIFICATION_MAPPING_NAMES", "AutoModelForTokenClassification"), ("multiple-choice", "MODEL_FOR_MULTIPLE_CHOICE_MAPPING_NAMES", "AutoModelForMultipleChoice"), ( "next-sentence-prediction", "MODEL_FOR_NEXT_SENTENCE_PREDICTION_MAPPING_NAMES", "AutoModelForNextSentencePrediction", ), ( "audio-frame-classification", "MODEL_FOR_AUDIO_FRAME_CLASSIFICATION_MAPPING_NAMES", "AutoModelForAudioFrameClassification", ), ("audio-xvector", "MODEL_FOR_AUDIO_XVECTOR_MAPPING_NAMES", "AutoModelForAudioXVector"), ( "document-question-answering", "MODEL_FOR_DOCUMENT_QUESTION_ANSWERING_MAPPING_NAMES", "AutoModelForDocumentQuestionAnswering", ), ( "visual-question-answering", "MODEL_FOR_VISUAL_QUESTION_ANSWERING_MAPPING_NAMES", "AutoModelForVisualQuestionAnswering", ), ("image-to-text", "MODEL_FOR_FOR_VISION_2_SEQ_MAPPING_NAMES", "AutoModelForVision2Seq"), ( "zero-shot-image-classification", "MODEL_FOR_ZERO_SHOT_IMAGE_CLASSIFICATION_MAPPING_NAMES", "AutoModelForZeroShotImageClassification", ), ("depth-estimation", "MODEL_FOR_DEPTH_ESTIMATION_MAPPING_NAMES", "AutoModelForDepthEstimation"), ("video-classification", "MODEL_FOR_VIDEO_CLASSIFICATION_MAPPING_NAMES", "AutoModelForVideoClassification"), ("mask-generation", "MODEL_FOR_MASK_GENERATION_MAPPING_NAMES", "AutoModelForMaskGeneration"), ] def A_ ( _lowercase ): '''simple docstring''' snake_case_ :Any = re.finditer(""".+?(?:(?<=[a-z])(?=[A-Z])|(?<=[A-Z])(?=[A-Z][a-z])|$)""", _lowercase ) return [m.group(0 ) for m in matches] def A_ ( ): '''simple docstring''' snake_case_ :int = transformers_module.models.auto.configuration_auto.CONFIG_MAPPING_NAMES snake_case_ :Dict = { config.replace("""Config""", """""" ): model_type for model_type, config in config_maping_names.items() } # Dictionaries flagging if each model prefix has a backend in PT/TF/Flax. snake_case_ :Optional[Any] = collections.defaultdict(_lowercase ) snake_case_ :int = collections.defaultdict(_lowercase ) snake_case_ :List[str] = collections.defaultdict(_lowercase ) # Let's lookup through all transformers object (once) and find if models are supported by a given backend. for attr_name in dir(_lowercase ): snake_case_ :int = None if _re_tf_models.match(_lowercase ) is not None: snake_case_ :int = tf_models snake_case_ :List[str] = _re_tf_models.match(_lowercase ).groups()[0] elif _re_flax_models.match(_lowercase ) is not None: snake_case_ :List[Any] = flax_models snake_case_ :Any = _re_flax_models.match(_lowercase ).groups()[0] elif _re_pt_models.match(_lowercase ) is not None: snake_case_ :Optional[Any] = pt_models snake_case_ :int = _re_pt_models.match(_lowercase ).groups()[0] if lookup_dict is not None: while len(_lowercase ) > 0: if attr_name in model_prefix_to_model_type: snake_case_ :Optional[int] = True break # Try again after removing the last word in the name snake_case_ :Optional[Any] = """""".join(camel_case_split(_lowercase )[:-1] ) snake_case_ :Optional[int] = set(list(pt_models.keys() ) + list(tf_models.keys() ) + list(flax_models.keys() ) ) snake_case_ :Optional[Any] = list(_lowercase ) all_models.sort() snake_case_ :Optional[int] = {"""model_type""": all_models} snake_case_ :Optional[int] = [pt_models[t] for t in all_models] snake_case_ :Any = [tf_models[t] for t in all_models] snake_case_ :Dict = [flax_models[t] for t in all_models] # Now let's use the auto-mapping names to make sure snake_case_ :Dict = {} for t in all_models: if t in transformers_module.models.auto.processing_auto.PROCESSOR_MAPPING_NAMES: snake_case_ :Optional[Any] = """AutoProcessor""" elif t in transformers_module.models.auto.tokenization_auto.TOKENIZER_MAPPING_NAMES: snake_case_ :Tuple = """AutoTokenizer""" elif t in transformers_module.models.auto.feature_extraction_auto.FEATURE_EXTRACTOR_MAPPING_NAMES: snake_case_ :Tuple = """AutoFeatureExtractor""" else: # Default to AutoTokenizer if a model has nothing, for backward compatibility. snake_case_ :str = """AutoTokenizer""" snake_case_ :int = [processors[t] for t in all_models] return pd.DataFrame(_lowercase ) def A_ ( _lowercase ): '''simple docstring''' snake_case_ :List[Any] = [ transformers_module.models.auto.modeling_auto, transformers_module.models.auto.modeling_tf_auto, transformers_module.models.auto.modeling_flax_auto, ] for pipeline_tag, model_mapping, auto_class in PIPELINE_TAGS_AND_AUTO_MODELS: snake_case_ :Optional[int] = [model_mapping, f"""TF_{model_mapping}""", f"""FLAX_{model_mapping}"""] snake_case_ :List[str] = [auto_class, f"""TF_{auto_class}""", f"""Flax_{auto_class}"""] # Loop through all three frameworks for module, cls, mapping in zip(_lowercase, _lowercase, _lowercase ): # The type of pipeline may not exist in this framework if not hasattr(_lowercase, _lowercase ): continue # First extract all model_names snake_case_ :Tuple = [] for name in getattr(_lowercase, _lowercase ).values(): if isinstance(_lowercase, _lowercase ): model_names.append(_lowercase ) else: model_names.extend(list(_lowercase ) ) # Add pipeline tag and auto model class for those models table.update({model_name: (pipeline_tag, cls) for model_name in model_names} ) return table def A_ ( _lowercase, _lowercase ): '''simple docstring''' snake_case_ :List[Any] = get_frameworks_table() snake_case_ :str = Dataset.from_pandas(_lowercase ) snake_case_ :List[Any] = hf_hub_download( """huggingface/transformers-metadata""", """pipeline_tags.json""", repo_type="""dataset""", token=_lowercase ) snake_case_ :List[str] = Dataset.from_json(_lowercase ) snake_case_ :int = { tags_dataset[i]["""model_class"""]: (tags_dataset[i]["""pipeline_tag"""], tags_dataset[i]["""auto_class"""]) for i in range(len(_lowercase ) ) } snake_case_ :Optional[int] = update_pipeline_and_auto_class_table(_lowercase ) # Sort the model classes to avoid some nondeterministic updates to create false update commits. snake_case_ :Tuple = sorted(table.keys() ) snake_case_ :Tuple = pd.DataFrame( { """model_class""": model_classes, """pipeline_tag""": [table[m][0] for m in model_classes], """auto_class""": [table[m][1] for m in model_classes], } ) snake_case_ :Union[str, Any] = Dataset.from_pandas(_lowercase ) with tempfile.TemporaryDirectory() as tmp_dir: frameworks_dataset.to_json(os.path.join(_lowercase, """frameworks.json""" ) ) tags_dataset.to_json(os.path.join(_lowercase, """pipeline_tags.json""" ) ) if commit_sha is not None: snake_case_ :Union[str, Any] = ( f"""Update with commit {commit_sha}\n\nSee: """ f"""https://github.com/huggingface/transformers/commit/{commit_sha}""" ) else: snake_case_ :List[Any] = """Update""" upload_folder( repo_id="""huggingface/transformers-metadata""", folder_path=_lowercase, repo_type="""dataset""", token=_lowercase, commit_message=_lowercase, ) def A_ ( ): '''simple docstring''' snake_case_ :List[Any] = {tag: cls for tag, _, cls in PIPELINE_TAGS_AND_AUTO_MODELS} snake_case_ :Dict = transformers_module.pipelines.SUPPORTED_TASKS snake_case_ :List[str] = [] for key in pipeline_tasks: if key not in in_table: snake_case_ :int = pipeline_tasks[key]["""pt"""] if isinstance(_lowercase, (list, tuple) ): snake_case_ :Any = model[0] snake_case_ :str = model.__name__ if model not in in_table.values(): missing.append(_lowercase ) if len(_lowercase ) > 0: snake_case_ :Optional[int] = """, """.join(_lowercase ) raise ValueError( """The following pipeline tags are not present in the `PIPELINE_TAGS_AND_AUTO_MODELS` constant inside """ f"""`utils/update_metadata.py`: {msg}. Please add them!""" ) if __name__ == "__main__": __a = argparse.ArgumentParser() parser.add_argument("--token", type=str, help="The token to use to push to the transformers-metadata dataset.") parser.add_argument("--commit_sha", type=str, help="The sha of the commit going with this update.") parser.add_argument("--check-only", action="store_true", help="Activate to just check all pipelines are present.") __a = parser.parse_args() if args.check_only: check_pipeline_tags() else: update_metadata(args.token, args.commit_sha)
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"""simple docstring""" import unittest from transformers import BertGenerationConfig, 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, floats_tensor, ids_tensor, random_attention_mask from ...test_pipeline_mixin import PipelineTesterMixin if is_torch_available(): import torch from transformers import BertGenerationDecoder, BertGenerationEncoder class lowerCamelCase : '''simple docstring''' def __init__( self: str , snake_case: List[Any] , snake_case: Dict=13 , snake_case: Union[str, Any]=7 , snake_case: List[Any]=True , snake_case: Any=True , snake_case: Optional[int]=99 , snake_case: str=32 , snake_case: Optional[int]=5 , snake_case: List[Any]=4 , snake_case: str=37 , snake_case: List[Any]="gelu" , snake_case: Optional[int]=0.1 , snake_case: List[Any]=0.1 , snake_case: str=50 , snake_case: str=0.0_2 , snake_case: Optional[Any]=True , snake_case: Any=None , ) -> int: snake_case_ :Union[str, Any] = parent snake_case_ :Optional[int] = batch_size snake_case_ :Any = seq_length snake_case_ :str = is_training snake_case_ :int = use_input_mask snake_case_ :Optional[int] = vocab_size snake_case_ :int = hidden_size snake_case_ :Optional[Any] = num_hidden_layers snake_case_ :List[str] = num_attention_heads snake_case_ :Optional[Any] = intermediate_size snake_case_ :Optional[int] = hidden_act snake_case_ :int = hidden_dropout_prob snake_case_ :Optional[int] = attention_probs_dropout_prob snake_case_ :List[Any] = max_position_embeddings snake_case_ :str = initializer_range snake_case_ :List[str] = use_labels snake_case_ :List[str] = scope def lowerCAmelCase_ ( self: str ) -> Dict: snake_case_ :Union[str, Any] = ids_tensor([self.batch_size, self.seq_length] , self.vocab_size ) snake_case_ :Any = None if self.use_input_mask: snake_case_ :List[Any] = random_attention_mask([self.batch_size, self.seq_length] ) if self.use_labels: snake_case_ :List[Any] = ids_tensor([self.batch_size, self.seq_length] , self.vocab_size ) snake_case_ :List[Any] = self.get_config() return config, input_ids, input_mask, token_labels def lowerCAmelCase_ ( self: Tuple ) -> str: return BertGenerationConfig( 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 , is_decoder=snake_case , initializer_range=self.initializer_range , ) def lowerCAmelCase_ ( self: Optional[Any] ) -> Union[str, Any]: ( ( snake_case_ ), ( snake_case_ ), ( snake_case_ ), ( snake_case_ ), ) :List[str] = self.prepare_config_and_inputs() snake_case_ :List[str] = True snake_case_ :Dict = floats_tensor([self.batch_size, self.seq_length, self.hidden_size] ) snake_case_ :Any = ids_tensor([self.batch_size, self.seq_length] , vocab_size=2 ) return ( config, input_ids, input_mask, token_labels, encoder_hidden_states, encoder_attention_mask, ) def lowerCAmelCase_ ( self: Tuple , snake_case: List[Any] , snake_case: int , snake_case: Tuple , snake_case: List[str] , **snake_case: Any , ) -> List[Any]: snake_case_ :List[Any] = BertGenerationEncoder(config=snake_case ) model.to(snake_case ) model.eval() snake_case_ :List[str] = model(snake_case , attention_mask=snake_case ) snake_case_ :Union[str, Any] = model(snake_case ) self.parent.assertEqual(result.last_hidden_state.shape , (self.batch_size, self.seq_length, self.hidden_size) ) def lowerCAmelCase_ ( self: List[Any] , snake_case: List[Any] , snake_case: Dict , snake_case: int , snake_case: Optional[int] , snake_case: Optional[Any] , snake_case: List[Any] , **snake_case: Tuple , ) -> List[Any]: snake_case_ :Dict = True snake_case_ :List[str] = BertGenerationEncoder(config=snake_case ) model.to(snake_case ) model.eval() snake_case_ :Tuple = model( snake_case , attention_mask=snake_case , encoder_hidden_states=snake_case , encoder_attention_mask=snake_case , ) snake_case_ :int = model( snake_case , attention_mask=snake_case , encoder_hidden_states=snake_case , ) self.parent.assertEqual(result.last_hidden_state.shape , (self.batch_size, self.seq_length, self.hidden_size) ) def lowerCAmelCase_ ( self: List[str] , snake_case: Union[str, Any] , snake_case: Optional[Any] , snake_case: str , snake_case: int , snake_case: Optional[Any] , snake_case: Any , **snake_case: Any , ) -> List[str]: snake_case_ :Optional[Any] = True snake_case_ :Any = True snake_case_ :Any = BertGenerationDecoder(config=snake_case ).to(snake_case ).eval() # first forward pass snake_case_ :int = model( snake_case , attention_mask=snake_case , encoder_hidden_states=snake_case , encoder_attention_mask=snake_case , use_cache=snake_case , ) snake_case_ :Any = outputs.past_key_values # create hypothetical multiple next token and extent to next_input_ids snake_case_ :Any = ids_tensor((self.batch_size, 3) , config.vocab_size ) snake_case_ :Optional[Any] = ids_tensor((self.batch_size, 3) , vocab_size=2 ) # append to next input_ids and snake_case_ :Dict = torch.cat([input_ids, next_tokens] , dim=-1 ) snake_case_ :Union[str, Any] = torch.cat([input_mask, next_mask] , dim=-1 ) snake_case_ :Dict = model( snake_case , attention_mask=snake_case , encoder_hidden_states=snake_case , encoder_attention_mask=snake_case , output_hidden_states=snake_case , )["""hidden_states"""][0] snake_case_ :Any = model( snake_case , attention_mask=snake_case , encoder_hidden_states=snake_case , encoder_attention_mask=snake_case , past_key_values=snake_case , output_hidden_states=snake_case , )["""hidden_states"""][0] # select random slice snake_case_ :Any = ids_tensor((1,) , output_from_past.shape[-1] ).item() snake_case_ :Any = output_from_no_past[:, -3:, random_slice_idx].detach() snake_case_ :Dict = 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 lowerCAmelCase_ ( self: List[Any] , snake_case: Dict , snake_case: int , snake_case: Tuple , snake_case: Dict , *snake_case: Tuple , ) -> str: snake_case_ :Optional[Any] = BertGenerationDecoder(snake_case ) model.to(snake_case ) model.eval() snake_case_ :int = 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 lowerCAmelCase_ ( self: Dict ) -> Tuple: snake_case_, snake_case_, snake_case_, snake_case_ :List[str] = self.prepare_config_and_inputs() snake_case_ :Optional[Any] = {"""input_ids""": input_ids, """attention_mask""": input_mask} return config, inputs_dict @require_torch class lowerCamelCase ( _lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase , unittest.TestCase ): '''simple docstring''' _A : Any = (BertGenerationEncoder, BertGenerationDecoder) if is_torch_available() else () _A : Union[str, Any] = (BertGenerationDecoder,) if is_torch_available() else () _A : Any = ( {"""feature-extraction""": BertGenerationEncoder, """text-generation""": BertGenerationDecoder} if is_torch_available() else {} ) def lowerCAmelCase_ ( self: int ) -> Dict: snake_case_ :Optional[Any] = BertGenerationEncoderTester(self ) snake_case_ :List[str] = ConfigTester(self , config_class=snake_case , hidden_size=37 ) def lowerCAmelCase_ ( self: Dict ) -> List[Any]: self.config_tester.run_common_tests() def lowerCAmelCase_ ( self: List[str] ) -> Dict: snake_case_ :Optional[Any] = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_model(*snake_case ) def lowerCAmelCase_ ( self: List[str] ) -> Tuple: snake_case_, snake_case_, snake_case_, snake_case_ :Tuple = self.model_tester.prepare_config_and_inputs() snake_case_ :Dict = """bert""" self.model_tester.create_and_check_model(snake_case , snake_case , snake_case , snake_case ) def lowerCAmelCase_ ( self: str ) -> Dict: snake_case_ :Union[str, Any] = self.model_tester.prepare_config_and_inputs_for_decoder() self.model_tester.create_and_check_model_as_decoder(*snake_case ) def lowerCAmelCase_ ( self: List[Any] ) -> List[str]: snake_case_ :Union[str, Any] = self.model_tester.prepare_config_and_inputs_for_decoder() self.model_tester.create_and_check_decoder_model_past_large_inputs(*snake_case ) def lowerCAmelCase_ ( self: List[Any] ) -> List[Any]: # This regression test was failing with PyTorch < 1.3 ( ( snake_case_ ), ( snake_case_ ), ( snake_case_ ), ( snake_case_ ), ( snake_case_ ), ( snake_case_ ), ) :Tuple = self.model_tester.prepare_config_and_inputs_for_decoder() snake_case_ :Union[str, Any] = None self.model_tester.create_and_check_model_as_decoder( snake_case , snake_case , snake_case , snake_case , snake_case , snake_case , ) def lowerCAmelCase_ ( self: Dict ) -> Optional[int]: snake_case_ :Union[str, Any] = self.model_tester.prepare_config_and_inputs_for_decoder() self.model_tester.create_and_check_for_causal_lm(*snake_case ) @slow def lowerCAmelCase_ ( self: int ) -> str: snake_case_ :int = BertGenerationEncoder.from_pretrained("""google/bert_for_seq_generation_L-24_bbc_encoder""" ) self.assertIsNotNone(snake_case ) @require_torch class lowerCamelCase ( unittest.TestCase ): '''simple docstring''' @slow def lowerCAmelCase_ ( self: List[str] ) -> str: snake_case_ :Optional[Any] = BertGenerationEncoder.from_pretrained("""google/bert_for_seq_generation_L-24_bbc_encoder""" ) snake_case_ :Any = torch.tensor([[101, 7_592, 1_010, 2_026, 3_899, 2_003, 10_140, 102]] ) with torch.no_grad(): snake_case_ :Optional[int] = model(snake_case )[0] snake_case_ :int = torch.Size([1, 8, 1_024] ) self.assertEqual(output.shape , snake_case ) snake_case_ :List[str] = torch.tensor( [[[0.1_7_7_5, 0.0_0_8_3, -0.0_3_2_1], [1.6_0_0_2, 0.1_2_8_7, 0.3_9_1_2], [2.1_4_7_3, 0.5_7_9_1, 0.6_0_6_6]]] ) self.assertTrue(torch.allclose(output[:, :3, :3] , snake_case , atol=1E-4 ) ) @require_torch class lowerCamelCase ( unittest.TestCase ): '''simple docstring''' @slow def lowerCAmelCase_ ( self: Any ) -> List[Any]: snake_case_ :Tuple = BertGenerationDecoder.from_pretrained("""google/bert_for_seq_generation_L-24_bbc_encoder""" ) snake_case_ :List[str] = torch.tensor([[101, 7_592, 1_010, 2_026, 3_899, 2_003, 10_140, 102]] ) with torch.no_grad(): snake_case_ :Optional[int] = model(snake_case )[0] snake_case_ :Optional[Any] = torch.Size([1, 8, 50_358] ) self.assertEqual(output.shape , snake_case ) snake_case_ :Any = torch.tensor( [[[-0.5_7_8_8, -2.5_9_9_4, -3.7_0_5_4], [0.0_4_3_8, 4.7_9_9_7, 1.8_7_9_5], [1.5_8_6_2, 6.6_4_0_9, 4.4_6_3_8]]] ) self.assertTrue(torch.allclose(output[:, :3, :3] , snake_case , atol=1E-4 ) )
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"""simple docstring""" import argparse import glob import logging import os from argparse import Namespace from importlib import import_module import numpy as np import torch from lightning_base import BaseTransformer, add_generic_args, generic_train from seqeval.metrics import accuracy_score, fa_score, precision_score, recall_score from torch.nn import CrossEntropyLoss from torch.utils.data import DataLoader, TensorDataset from utils_ner import TokenClassificationTask __a = logging.getLogger(__name__) class lowerCamelCase ( _lowerCAmelCase ): '''simple docstring''' _A : Union[str, Any] = """token-classification""" def __init__( self: Any , snake_case: Tuple ) -> List[Any]: if type(snake_case ) == dict: snake_case_ :Optional[int] = Namespace(**snake_case ) snake_case_ :Optional[int] = import_module("""tasks""" ) try: snake_case_ :Any = getattr(snake_case , hparams.task_type ) snake_case_ :TokenClassificationTask = token_classification_task_clazz() except AttributeError: raise ValueError( f"""Task {hparams.task_type} needs to be defined as a TokenClassificationTask subclass in {module}. """ f"""Available tasks classes are: {TokenClassificationTask.__subclasses__()}""" ) snake_case_ :Any = self.token_classification_task.get_labels(hparams.labels ) snake_case_ :str = CrossEntropyLoss().ignore_index super().__init__(snake_case , len(self.labels ) , self.mode ) def lowerCAmelCase_ ( self: Dict , **snake_case: List[Any] ) -> Any: return self.model(**snake_case ) def lowerCAmelCase_ ( self: str , snake_case: Tuple , snake_case: List[Any] ) -> Optional[int]: snake_case_ :List[str] = {"""input_ids""": batch[0], """attention_mask""": batch[1], """labels""": batch[3]} if self.config.model_type != "distilbert": snake_case_ :List[str] = ( batch[2] if self.config.model_type in ["""bert""", """xlnet"""] else None ) # XLM and RoBERTa don"t use token_type_ids snake_case_ :Optional[Any] = self(**snake_case ) snake_case_ :List[str] = outputs[0] # tensorboard_logs = {"loss": loss, "rate": self.lr_scheduler.get_last_lr()[-1]} return {"loss": loss} def lowerCAmelCase_ ( self: int ) -> Dict: snake_case_ :List[Any] = self.hparams for mode in ["train", "dev", "test"]: snake_case_ :Optional[int] = self._feature_file(snake_case ) if os.path.exists(snake_case ) and not args.overwrite_cache: logger.info("""Loading features from cached file %s""" , snake_case ) snake_case_ :Optional[int] = torch.load(snake_case ) else: logger.info("""Creating features from dataset file at %s""" , args.data_dir ) snake_case_ :Optional[int] = self.token_classification_task.read_examples_from_file(args.data_dir , snake_case ) snake_case_ :Any = self.token_classification_task.convert_examples_to_features( snake_case , self.labels , args.max_seq_length , self.tokenizer , cls_token_at_end=bool(self.config.model_type in ["""xlnet"""] ) , cls_token=self.tokenizer.cls_token , cls_token_segment_id=2 if self.config.model_type in ["""xlnet"""] else 0 , sep_token=self.tokenizer.sep_token , sep_token_extra=snake_case , pad_on_left=bool(self.config.model_type in ["""xlnet"""] ) , pad_token=self.tokenizer.pad_token_id , pad_token_segment_id=self.tokenizer.pad_token_type_id , pad_token_label_id=self.pad_token_label_id , ) logger.info("""Saving features into cached file %s""" , snake_case ) torch.save(snake_case , snake_case ) def lowerCAmelCase_ ( self: Optional[int] , snake_case: int , snake_case: int , snake_case: bool = False ) -> DataLoader: snake_case_ :int = self._feature_file(snake_case ) logger.info("""Loading features from cached file %s""" , snake_case ) snake_case_ :str = torch.load(snake_case ) snake_case_ :Dict = torch.tensor([f.input_ids for f in features] , dtype=torch.long ) snake_case_ :str = torch.tensor([f.attention_mask for f in features] , dtype=torch.long ) if features[0].token_type_ids is not None: snake_case_ :List[Any] = torch.tensor([f.token_type_ids for f in features] , dtype=torch.long ) else: snake_case_ :List[str] = torch.tensor([0 for f in features] , dtype=torch.long ) # HACK(we will not use this anymore soon) snake_case_ :Any = torch.tensor([f.label_ids for f in features] , dtype=torch.long ) return DataLoader( TensorDataset(snake_case , snake_case , snake_case , snake_case ) , batch_size=snake_case ) def lowerCAmelCase_ ( self: List[str] , snake_case: Dict , snake_case: Union[str, Any] ) -> List[str]: """Compute validation""" "" snake_case_ :List[str] = {"""input_ids""": batch[0], """attention_mask""": batch[1], """labels""": batch[3]} if self.config.model_type != "distilbert": snake_case_ :Dict = ( batch[2] if self.config.model_type in ["""bert""", """xlnet"""] else None ) # XLM and RoBERTa don"t use token_type_ids snake_case_ :Dict = self(**snake_case ) snake_case_, snake_case_ :Dict = outputs[:2] snake_case_ :Union[str, Any] = logits.detach().cpu().numpy() snake_case_ :List[Any] = inputs["""labels"""].detach().cpu().numpy() return {"val_loss": tmp_eval_loss.detach().cpu(), "pred": preds, "target": out_label_ids} def lowerCAmelCase_ ( self: List[Any] , snake_case: int ) -> Tuple: snake_case_ :Union[str, Any] = torch.stack([x["""val_loss"""] for x in outputs] ).mean() snake_case_ :Tuple = np.concatenate([x["""pred"""] for x in outputs] , axis=0 ) snake_case_ :Tuple = np.argmax(snake_case , axis=2 ) snake_case_ :List[str] = np.concatenate([x["""target"""] for x in outputs] , axis=0 ) snake_case_ :Optional[Any] = dict(enumerate(self.labels ) ) snake_case_ :Dict = [[] for _ in range(out_label_ids.shape[0] )] snake_case_ :Dict = [[] for _ in range(out_label_ids.shape[0] )] for i in range(out_label_ids.shape[0] ): for j in range(out_label_ids.shape[1] ): if out_label_ids[i, j] != self.pad_token_label_id: out_label_list[i].append(label_map[out_label_ids[i][j]] ) preds_list[i].append(label_map[preds[i][j]] ) snake_case_ :str = { """val_loss""": val_loss_mean, """accuracy_score""": accuracy_score(snake_case , snake_case ), """precision""": precision_score(snake_case , snake_case ), """recall""": recall_score(snake_case , snake_case ), """f1""": fa_score(snake_case , snake_case ), } snake_case_ :List[Any] = dict(results.items() ) snake_case_ :Union[str, Any] = results return ret, preds_list, out_label_list def lowerCAmelCase_ ( self: Optional[Any] , snake_case: Dict ) -> Optional[Any]: # when stable snake_case_, snake_case_, snake_case_ :Tuple = self._eval_end(snake_case ) snake_case_ :str = ret["""log"""] return {"val_loss": logs["val_loss"], "log": logs, "progress_bar": logs} def lowerCAmelCase_ ( self: Tuple , snake_case: Optional[int] ) -> Any: # updating to test_epoch_end instead of deprecated test_end snake_case_, snake_case_, snake_case_ :Any = self._eval_end(snake_case ) # Converting to the dict required by pl # https://github.com/PyTorchLightning/pytorch-lightning/blob/master/\ # pytorch_lightning/trainer/logging.py#L139 snake_case_ :Optional[int] = ret["""log"""] # `val_loss` is the key returned by `self._eval_end()` but actually refers to `test_loss` return {"avg_test_loss": logs["val_loss"], "log": logs, "progress_bar": logs} @staticmethod def lowerCAmelCase_ ( snake_case: Any , snake_case: int ) -> Dict: # Add NER specific options BaseTransformer.add_model_specific_args(snake_case , snake_case ) parser.add_argument( """--task_type""" , default="""NER""" , type=snake_case , help="""Task type to fine tune in training (e.g. NER, POS, etc)""" ) parser.add_argument( """--max_seq_length""" , default=128 , type=snake_case , help=( """The maximum total input sequence length after tokenization. Sequences longer """ """than this will be truncated, sequences shorter will be padded.""" ) , ) parser.add_argument( """--labels""" , default="""""" , type=snake_case , help="""Path to a file containing all labels. If not specified, CoNLL-2003 labels are used.""" , ) parser.add_argument( """--gpus""" , default=0 , type=snake_case , help="""The number of GPUs allocated for this, it is by default 0 meaning none""" , ) parser.add_argument( """--overwrite_cache""" , action="""store_true""" , help="""Overwrite the cached training and evaluation sets""" ) return parser if __name__ == "__main__": __a = argparse.ArgumentParser() add_generic_args(parser, os.getcwd()) __a = NERTransformer.add_model_specific_args(parser, os.getcwd()) __a = parser.parse_args() __a = NERTransformer(args) __a = generic_train(model, args) if args.do_predict: # See https://github.com/huggingface/transformers/issues/3159 # pl use this default format to create a checkpoint: # https://github.com/PyTorchLightning/pytorch-lightning/blob/master\ # /pytorch_lightning/callbacks/model_checkpoint.py#L322 __a = sorted(glob.glob(os.path.join(args.output_dir, "checkpoint-epoch=*.ckpt"), recursive=True)) __a = model.load_from_checkpoint(checkpoints[-1]) trainer.test(model)
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"""simple docstring""" import numpy as np import pandas as pd from sklearn.preprocessing import MinMaxScaler from tensorflow.keras.layers import LSTM, Dense from tensorflow.keras.models import Sequential if __name__ == "__main__": __a = pd.read_csv("sample_data.csv", header=None) __a = df.shape[:1][0] # If you're using some other dataset input the target column __a = df.iloc[:, 1:2] __a = actual_data.values.reshape(len_data, 1) __a = MinMaxScaler().fit_transform(actual_data) __a = 10 __a = 5 __a = 20 __a = len_data - periods * look_back __a = actual_data[:division] __a = actual_data[division - look_back :] __a , __a = [], [] __a , __a = [], [] for i in range(0, len(train_data) - forward_days - look_back + 1): train_x.append(train_data[i : i + look_back]) train_y.append(train_data[i + look_back : i + look_back + forward_days]) for i in range(0, len(test_data) - forward_days - look_back + 1): test_x.append(test_data[i : i + look_back]) test_y.append(test_data[i + look_back : i + look_back + forward_days]) __a = np.array(train_x) __a = np.array(test_x) __a = np.array([list(i.ravel()) for i in train_y]) __a = np.array([list(i.ravel()) for i in test_y]) __a = Sequential() model.add(LSTM(1_28, input_shape=(look_back, 1), return_sequences=True)) model.add(LSTM(64, input_shape=(1_28, 1))) model.add(Dense(forward_days)) model.compile(loss="mean_squared_error", optimizer="adam") __a = model.fit( x_train, y_train, epochs=1_50, verbose=1, shuffle=True, batch_size=4 ) __a = model.predict(x_test)
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"""simple docstring""" from math import factorial class lowerCamelCase : '''simple docstring''' def __init__( self: Optional[int] , snake_case: Dict , snake_case: int ) -> Tuple: snake_case_ :List[Any] = real if isinstance(snake_case , snake_case ): snake_case_ :Tuple = [1] * rank else: snake_case_ :Optional[Any] = rank def __repr__( self: List[str] ) -> Tuple: return ( f"""{self.real}+""" f"""{'+'.join(str(snake_case )+'E'+str(n+1 )for n,dual in enumerate(self.duals ) )}""" ) def lowerCAmelCase_ ( self: Optional[int] ) -> Optional[int]: snake_case_ :Any = self.duals.copy() while cur[-1] == 0: cur.pop(-1 ) return Dual(self.real , snake_case ) def __add__( self: Optional[int] , snake_case: Dict ) -> List[str]: if not isinstance(snake_case , snake_case ): return Dual(self.real + other , self.duals ) snake_case_ :List[Any] = self.duals.copy() snake_case_ :Tuple = other.duals.copy() if len(snake_case ) > len(snake_case ): o_dual.extend([1] * (len(snake_case ) - len(snake_case )) ) elif len(snake_case ) < len(snake_case ): s_dual.extend([1] * (len(snake_case ) - len(snake_case )) ) snake_case_ :Dict = [] for i in range(len(snake_case ) ): new_duals.append(s_dual[i] + o_dual[i] ) return Dual(self.real + other.real , snake_case ) _A : str = __add__ def __sub__( self: Tuple , snake_case: Union[str, Any] ) -> Tuple: return self + other * -1 def __mul__( self: str , snake_case: Tuple ) -> Optional[Any]: if not isinstance(snake_case , snake_case ): snake_case_ :Dict = [] for i in self.duals: new_duals.append(i * other ) return Dual(self.real * other , snake_case ) snake_case_ :int = [0] * (len(self.duals ) + len(other.duals ) + 1) for i, item in enumerate(self.duals ): for j, jtem in enumerate(other.duals ): new_duals[i + j + 1] += item * jtem for k in range(len(self.duals ) ): new_duals[k] += self.duals[k] * other.real for index in range(len(other.duals ) ): new_duals[index] += other.duals[index] * self.real return Dual(self.real * other.real , snake_case ) _A : int = __mul__ def __truediv__( self: List[str] , snake_case: List[str] ) -> List[str]: if not isinstance(snake_case , snake_case ): snake_case_ :Optional[Any] = [] for i in self.duals: new_duals.append(i / other ) return Dual(self.real / other , snake_case ) raise ValueError def __floordiv__( self: int , snake_case: List[Any] ) -> Any: if not isinstance(snake_case , snake_case ): snake_case_ :Optional[int] = [] for i in self.duals: new_duals.append(i // other ) return Dual(self.real // other , snake_case ) raise ValueError def __pow__( self: Optional[Any] , snake_case: Optional[int] ) -> List[Any]: if n < 0 or isinstance(snake_case , snake_case ): raise ValueError("""power must be a positive integer""" ) if n == 0: return 1 if n == 1: return self snake_case_ :str = self for _ in range(n - 1 ): x *= self return x def A_ ( _lowercase, _lowercase, _lowercase ): '''simple docstring''' if not callable(_lowercase ): raise ValueError("""differentiate() requires a function as input for func""" ) if not isinstance(_lowercase, (float, int) ): raise ValueError("""differentiate() requires a float as input for position""" ) if not isinstance(_lowercase, _lowercase ): raise ValueError("""differentiate() requires an int as input for order""" ) snake_case_ :Optional[Any] = Dual(_lowercase, 1 ) snake_case_ :List[Any] = func(_lowercase ) if order == 0: return result.real return result.duals[order - 1] * factorial(_lowercase ) if __name__ == "__main__": import doctest doctest.testmod() def A_ ( _lowercase ): '''simple docstring''' return y**2 * y**4 print(differentiate(f, 9, 2))
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"""simple docstring""" import logging import os from dataclasses import dataclass, field from typing import Dict, Optional import numpy as np from utils_multiple_choice import MultipleChoiceDataset, Split, processors import transformers from transformers import ( AutoConfig, AutoModelForMultipleChoice, AutoTokenizer, DataCollatorWithPadding, EvalPrediction, HfArgumentParser, Trainer, TrainingArguments, set_seed, ) from transformers.trainer_utils import is_main_process __a = logging.getLogger(__name__) def A_ ( _lowercase, _lowercase ): '''simple docstring''' return (preds == labels).mean() @dataclass class lowerCamelCase : '''simple docstring''' _A : str = field( metadata={"""help""": """Path to pretrained model or model identifier from huggingface.co/models"""} ) _A : Optional[str] = field( default=_lowerCAmelCase , metadata={"""help""": """Pretrained config name or path if not the same as model_name"""} ) _A : Optional[str] = field( default=_lowerCAmelCase , metadata={"""help""": """Pretrained tokenizer name or path if not the same as model_name"""} ) _A : Optional[str] = field( default=_lowerCAmelCase , metadata={"""help""": """Where do you want to store the pretrained models downloaded from huggingface.co"""} , ) @dataclass class lowerCamelCase : '''simple docstring''' _A : str = field(metadata={"""help""": """The name of the task to train on: """ + """, """.join(processors.keys() )} ) _A : str = field(metadata={"""help""": """Should contain the data files for the task."""} ) _A : int = field( default=1_2_8 , metadata={ """help""": ( """The maximum total input sequence length after tokenization. Sequences longer """ """than this will be truncated, sequences shorter will be padded.""" ) } , ) _A : bool = field( default=_lowerCAmelCase , metadata={"""help""": """Overwrite the cached training and evaluation sets"""} ) def A_ ( ): '''simple docstring''' snake_case_ :List[str] = HfArgumentParser((ModelArguments, DataTrainingArguments, TrainingArguments) ) snake_case_, snake_case_, snake_case_ :List[Any] = parser.parse_args_into_dataclasses() if ( os.path.exists(training_args.output_dir ) and os.listdir(training_args.output_dir ) and training_args.do_train and not training_args.overwrite_output_dir ): raise ValueError( f"""Output directory ({training_args.output_dir}) already exists and is not empty. Use""" """ --overwrite_output_dir to overcome.""" ) # Setup logging logging.basicConfig( format="""%(asctime)s - %(levelname)s - %(name)s - %(message)s""", datefmt="""%m/%d/%Y %H:%M:%S""", level=logging.INFO if training_args.local_rank in [-1, 0] else logging.WARN, ) logger.warning( """Process rank: %s, device: %s, n_gpu: %s, distributed training: %s, 16-bits training: %s""", training_args.local_rank, training_args.device, training_args.n_gpu, bool(training_args.local_rank != -1 ), training_args.fpaa, ) # Set the verbosity to info of the Transformers logger (on main process only): if is_main_process(training_args.local_rank ): transformers.utils.logging.set_verbosity_info() transformers.utils.logging.enable_default_handler() transformers.utils.logging.enable_explicit_format() logger.info("""Training/evaluation parameters %s""", _lowercase ) # Set seed set_seed(training_args.seed ) try: snake_case_ :Optional[Any] = processors[data_args.task_name]() snake_case_ :Tuple = processor.get_labels() snake_case_ :int = len(_lowercase ) except KeyError: raise ValueError("""Task not found: %s""" % (data_args.task_name) ) # Load pretrained model and tokenizer # # Distributed training: # The .from_pretrained methods guarantee that only one local process can concurrently # download model & vocab. snake_case_ :List[str] = AutoConfig.from_pretrained( model_args.config_name if model_args.config_name else model_args.model_name_or_path, num_labels=_lowercase, finetuning_task=data_args.task_name, cache_dir=model_args.cache_dir, ) snake_case_ :Union[str, Any] = AutoTokenizer.from_pretrained( model_args.tokenizer_name if model_args.tokenizer_name else model_args.model_name_or_path, cache_dir=model_args.cache_dir, ) snake_case_ :Union[str, Any] = AutoModelForMultipleChoice.from_pretrained( model_args.model_name_or_path, from_tf=bool(""".ckpt""" in model_args.model_name_or_path ), config=_lowercase, cache_dir=model_args.cache_dir, ) # Get datasets snake_case_ :List[str] = ( MultipleChoiceDataset( data_dir=data_args.data_dir, tokenizer=_lowercase, task=data_args.task_name, max_seq_length=data_args.max_seq_length, overwrite_cache=data_args.overwrite_cache, mode=Split.train, ) if training_args.do_train else None ) snake_case_ :Optional[Any] = ( MultipleChoiceDataset( data_dir=data_args.data_dir, tokenizer=_lowercase, task=data_args.task_name, max_seq_length=data_args.max_seq_length, overwrite_cache=data_args.overwrite_cache, mode=Split.dev, ) if training_args.do_eval else None ) def compute_metrics(_lowercase ) -> Dict: snake_case_ :Union[str, Any] = np.argmax(p.predictions, axis=1 ) return {"acc": simple_accuracy(_lowercase, p.label_ids )} # Data collator snake_case_ :List[str] = DataCollatorWithPadding(_lowercase, pad_to_multiple_of=8 ) if training_args.fpaa else None # Initialize our Trainer snake_case_ :Optional[Any] = Trainer( model=_lowercase, args=_lowercase, train_dataset=_lowercase, eval_dataset=_lowercase, compute_metrics=_lowercase, data_collator=_lowercase, ) # Training if training_args.do_train: trainer.train( model_path=model_args.model_name_or_path if os.path.isdir(model_args.model_name_or_path ) else None ) trainer.save_model() # For convenience, we also re-save the tokenizer to the same directory, # so that you can share your model easily on huggingface.co/models =) if trainer.is_world_master(): tokenizer.save_pretrained(training_args.output_dir ) # Evaluation snake_case_ :Optional[int] = {} if training_args.do_eval: logger.info("""*** Evaluate ***""" ) snake_case_ :List[str] = trainer.evaluate() snake_case_ :Union[str, Any] = os.path.join(training_args.output_dir, """eval_results.txt""" ) if trainer.is_world_master(): with open(_lowercase, """w""" ) as writer: logger.info("""***** Eval results *****""" ) for key, value in result.items(): logger.info(""" %s = %s""", _lowercase, _lowercase ) writer.write("""%s = %s\n""" % (key, value) ) results.update(_lowercase ) return results def A_ ( _lowercase ): '''simple docstring''' main() if __name__ == "__main__": main()
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"""simple docstring""" from __future__ import annotations __a = 10 def A_ ( _lowercase ): '''simple docstring''' snake_case_ :Union[str, Any] = 1 snake_case_ :List[str] = max(_lowercase ) while placement <= max_digit: # declare and initialize empty buckets snake_case_ :list[list] = [[] for _ in range(_lowercase )] # split list_of_ints between the buckets for i in list_of_ints: snake_case_ :Any = int((i / placement) % RADIX ) buckets[tmp].append(_lowercase ) # put each buckets' contents into list_of_ints snake_case_ :Optional[Any] = 0 for b in range(_lowercase ): for i in buckets[b]: snake_case_ :Union[str, Any] = i a += 1 # move to next placement *= RADIX return list_of_ints if __name__ == "__main__": import doctest doctest.testmod()
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"""simple docstring""" import tempfile import torch from diffusers import IPNDMScheduler from .test_schedulers import SchedulerCommonTest class lowerCamelCase ( _lowerCAmelCase ): '''simple docstring''' _A : Dict = (IPNDMScheduler,) _A : Any = (("""num_inference_steps""", 5_0),) def lowerCAmelCase_ ( self: Union[str, Any] , **snake_case: str ) -> Optional[int]: snake_case_ :Tuple = {"""num_train_timesteps""": 1_000} config.update(**snake_case ) return config def lowerCAmelCase_ ( self: List[str] , snake_case: int=0 , **snake_case: str ) -> Optional[Any]: snake_case_ :List[Any] = dict(self.forward_default_kwargs ) snake_case_ :str = kwargs.pop("""num_inference_steps""" , snake_case ) snake_case_ :Optional[int] = self.dummy_sample snake_case_ :Tuple = 0.1 * sample snake_case_ :str = [residual + 0.2, residual + 0.1_5, residual + 0.1, residual + 0.0_5] for scheduler_class in self.scheduler_classes: snake_case_ :int = self.get_scheduler_config(**snake_case ) snake_case_ :str = scheduler_class(**snake_case ) scheduler.set_timesteps(snake_case ) # copy over dummy past residuals snake_case_ :str = dummy_past_residuals[:] if time_step is None: snake_case_ :Optional[Any] = scheduler.timesteps[len(scheduler.timesteps ) // 2] with tempfile.TemporaryDirectory() as tmpdirname: scheduler.save_config(snake_case ) snake_case_ :List[str] = scheduler_class.from_pretrained(snake_case ) new_scheduler.set_timesteps(snake_case ) # copy over dummy past residuals snake_case_ :str = dummy_past_residuals[:] snake_case_ :int = scheduler.step(snake_case , snake_case , snake_case , **snake_case ).prev_sample snake_case_ :Optional[int] = new_scheduler.step(snake_case , snake_case , snake_case , **snake_case ).prev_sample assert torch.sum(torch.abs(output - new_output ) ) < 1E-5, "Scheduler outputs are not identical" snake_case_ :Optional[int] = scheduler.step(snake_case , snake_case , snake_case , **snake_case ).prev_sample snake_case_ :Tuple = new_scheduler.step(snake_case , snake_case , snake_case , **snake_case ).prev_sample assert torch.sum(torch.abs(output - new_output ) ) < 1E-5, "Scheduler outputs are not identical" def lowerCAmelCase_ ( self: str ) -> List[str]: pass def lowerCAmelCase_ ( self: Union[str, Any] , snake_case: str=0 , **snake_case: Dict ) -> Tuple: snake_case_ :List[str] = dict(self.forward_default_kwargs ) snake_case_ :Optional[int] = kwargs.pop("""num_inference_steps""" , snake_case ) snake_case_ :Dict = self.dummy_sample snake_case_ :Optional[Any] = 0.1 * sample snake_case_ :Dict = [residual + 0.2, residual + 0.1_5, residual + 0.1, residual + 0.0_5] for scheduler_class in self.scheduler_classes: snake_case_ :Tuple = self.get_scheduler_config() snake_case_ :List[str] = scheduler_class(**snake_case ) scheduler.set_timesteps(snake_case ) # copy over dummy past residuals (must be after setting timesteps) snake_case_ :Any = dummy_past_residuals[:] if time_step is None: snake_case_ :Dict = scheduler.timesteps[len(scheduler.timesteps ) // 2] with tempfile.TemporaryDirectory() as tmpdirname: scheduler.save_config(snake_case ) snake_case_ :int = scheduler_class.from_pretrained(snake_case ) # copy over dummy past residuals new_scheduler.set_timesteps(snake_case ) # copy over dummy past residual (must be after setting timesteps) snake_case_ :Union[str, Any] = dummy_past_residuals[:] snake_case_ :List[Any] = scheduler.step(snake_case , snake_case , snake_case , **snake_case ).prev_sample snake_case_ :Union[str, Any] = new_scheduler.step(snake_case , snake_case , snake_case , **snake_case ).prev_sample assert torch.sum(torch.abs(output - new_output ) ) < 1E-5, "Scheduler outputs are not identical" snake_case_ :Tuple = scheduler.step(snake_case , snake_case , snake_case , **snake_case ).prev_sample snake_case_ :List[str] = new_scheduler.step(snake_case , snake_case , snake_case , **snake_case ).prev_sample assert torch.sum(torch.abs(output - new_output ) ) < 1E-5, "Scheduler outputs are not identical" def lowerCAmelCase_ ( self: Optional[int] , **snake_case: Tuple ) -> str: snake_case_ :int = self.scheduler_classes[0] snake_case_ :List[Any] = self.get_scheduler_config(**snake_case ) snake_case_ :int = scheduler_class(**snake_case ) snake_case_ :str = 10 snake_case_ :Optional[Any] = self.dummy_model() snake_case_ :int = self.dummy_sample_deter scheduler.set_timesteps(snake_case ) for i, t in enumerate(scheduler.timesteps ): snake_case_ :Tuple = model(snake_case , snake_case ) snake_case_ :Dict = scheduler.step(snake_case , snake_case , snake_case ).prev_sample for i, t in enumerate(scheduler.timesteps ): snake_case_ :Optional[int] = model(snake_case , snake_case ) snake_case_ :Any = scheduler.step(snake_case , snake_case , snake_case ).prev_sample return sample def lowerCAmelCase_ ( self: str ) -> List[str]: snake_case_ :str = dict(self.forward_default_kwargs ) snake_case_ :int = kwargs.pop("""num_inference_steps""" , snake_case ) for scheduler_class in self.scheduler_classes: snake_case_ :List[str] = self.get_scheduler_config() snake_case_ :Any = scheduler_class(**snake_case ) snake_case_ :List[str] = self.dummy_sample snake_case_ :Dict = 0.1 * sample if num_inference_steps is not None and hasattr(snake_case , """set_timesteps""" ): scheduler.set_timesteps(snake_case ) elif num_inference_steps is not None and not hasattr(snake_case , """set_timesteps""" ): snake_case_ :str = num_inference_steps # copy over dummy past residuals (must be done after set_timesteps) snake_case_ :Union[str, Any] = [residual + 0.2, residual + 0.1_5, residual + 0.1, residual + 0.0_5] snake_case_ :Optional[int] = dummy_past_residuals[:] snake_case_ :Optional[int] = scheduler.timesteps[5] snake_case_ :str = scheduler.timesteps[6] snake_case_ :int = scheduler.step(snake_case , snake_case , snake_case , **snake_case ).prev_sample snake_case_ :List[str] = scheduler.step(snake_case , snake_case , snake_case , **snake_case ).prev_sample self.assertEqual(output_a.shape , sample.shape ) self.assertEqual(output_a.shape , output_a.shape ) snake_case_ :str = scheduler.step(snake_case , snake_case , snake_case , **snake_case ).prev_sample snake_case_ :Optional[int] = scheduler.step(snake_case , snake_case , snake_case , **snake_case ).prev_sample self.assertEqual(output_a.shape , sample.shape ) self.assertEqual(output_a.shape , output_a.shape ) def lowerCAmelCase_ ( self: Tuple ) -> Dict: for timesteps in [100, 1_000]: self.check_over_configs(num_train_timesteps=snake_case , time_step=snake_case ) def lowerCAmelCase_ ( self: int ) -> Optional[int]: for t, num_inference_steps in zip([1, 5, 10] , [10, 50, 100] ): self.check_over_forward(num_inference_steps=snake_case , time_step=snake_case ) def lowerCAmelCase_ ( self: Optional[Any] ) -> Optional[Any]: snake_case_ :List[Any] = self.full_loop() snake_case_ :str = torch.mean(torch.abs(snake_case ) ) assert abs(result_mean.item() - 2_540_529 ) < 10
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"""simple docstring""" from typing import TYPE_CHECKING from ...utils import ( OptionalDependencyNotAvailable, _LazyModule, is_sentencepiece_available, is_tokenizers_available, is_torch_available, ) __a = {"configuration_reformer": ["REFORMER_PRETRAINED_CONFIG_ARCHIVE_MAP", "ReformerConfig"]} try: if not is_sentencepiece_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __a = ["ReformerTokenizer"] try: if not is_tokenizers_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __a = ["ReformerTokenizerFast"] try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __a = [ "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 = _LazyModule(__name__, globals()["__file__"], _import_structure, module_spec=__spec__)
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"""simple docstring""" from timeit import timeit __a = { "MALAYALAM": True, "String": False, "rotor": True, "level": True, "A": True, "BB": True, "ABC": False, "amanaplanacanalpanama": True, # "a man a plan a canal panama" } # Ensure our test data is valid assert all((key == key[::-1]) is value for key, value in test_data.items()) def A_ ( _lowercase ): '''simple docstring''' snake_case_ :Dict = 0 snake_case_ :Tuple = len(_lowercase ) - 1 while start_i < end_i: if s[start_i] == s[end_i]: start_i += 1 end_i -= 1 else: return False return True def A_ ( _lowercase ): '''simple docstring''' snake_case_ :List[Any] = len(_lowercase ) // 2 snake_case_ :Dict = len(_lowercase ) # We need to traverse till half of the length of string # as we can get access of the i'th last element from # i'th index. # eg: [0,1,2,3,4,5] => 4th index can be accessed # with the help of 1st index (i==n-i-1) # where n is length of string return all(s[i] == s[n - i - 1] for i in range(_lowercase ) ) def A_ ( _lowercase ): '''simple docstring''' if len(_lowercase ) <= 2: return True if s[0] == s[len(_lowercase ) - 1]: return is_palindrome_recursive(s[1:-1] ) else: return False def A_ ( _lowercase ): '''simple docstring''' return s == s[::-1] def A_ ( _lowercase ): '''simple docstring''' snake_case_ :Optional[int] = f"""all({name}(key) is value for key, value in test_data.items())""" snake_case_ :int = f"""from __main__ import test_data, {name}""" snake_case_ :Any = 500000 snake_case_ :Union[str, Any] = timeit(stmt=_lowercase, setup=_lowercase, number=_lowercase ) print(f"""{name:<35} finished {number:,} runs in {result:.5f} seconds""" ) if __name__ == "__main__": for key, value in test_data.items(): assert is_palindrome(key) is is_palindrome_recursive(key) assert is_palindrome(key) is is_palindrome_slice(key) print(F"""{key:21} {value}""") print("a man a plan a canal panama") # finished 500,000 runs in 0.46793 seconds benchmark_function("is_palindrome_slice") # finished 500,000 runs in 0.85234 seconds benchmark_function("is_palindrome") # finished 500,000 runs in 1.32028 seconds benchmark_function("is_palindrome_recursive") # finished 500,000 runs in 2.08679 seconds benchmark_function("is_palindrome_traversal")
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"""simple docstring""" import gc import unittest from diffusers import FlaxControlNetModel, FlaxStableDiffusionControlNetPipeline from diffusers.utils import is_flax_available, load_image, slow from diffusers.utils.testing_utils import require_flax if is_flax_available(): import jax import jax.numpy as jnp from flax.jax_utils import replicate from flax.training.common_utils import shard @slow @require_flax class lowerCamelCase ( unittest.TestCase ): '''simple docstring''' def lowerCAmelCase_ ( self: List[Any] ) -> Any: # clean up the VRAM after each test super().tearDown() gc.collect() def lowerCAmelCase_ ( self: Tuple ) -> Any: snake_case_, snake_case_ :List[str] = FlaxControlNetModel.from_pretrained( """lllyasviel/sd-controlnet-canny""" , from_pt=snake_case , dtype=jnp.bfloataa ) snake_case_, snake_case_ :Union[str, Any] = FlaxStableDiffusionControlNetPipeline.from_pretrained( """runwayml/stable-diffusion-v1-5""" , controlnet=snake_case , from_pt=snake_case , dtype=jnp.bfloataa ) snake_case_ :Union[str, Any] = controlnet_params snake_case_ :Union[str, Any] = """bird""" snake_case_ :List[Any] = jax.device_count() snake_case_ :List[Any] = pipe.prepare_text_inputs([prompts] * num_samples ) snake_case_ :List[str] = load_image( """https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main/sd_controlnet/bird_canny.png""" ) snake_case_ :List[str] = pipe.prepare_image_inputs([canny_image] * num_samples ) snake_case_ :Any = jax.random.PRNGKey(0 ) snake_case_ :List[str] = jax.random.split(snake_case , jax.device_count() ) snake_case_ :List[Any] = replicate(snake_case ) snake_case_ :List[str] = shard(snake_case ) snake_case_ :str = shard(snake_case ) snake_case_ :Dict = pipe( prompt_ids=snake_case , image=snake_case , params=snake_case , prng_seed=snake_case , num_inference_steps=50 , jit=snake_case , ).images assert images.shape == (jax.device_count(), 1, 768, 512, 3) snake_case_ :str = images.reshape((images.shape[0] * images.shape[1],) + images.shape[-3:] ) snake_case_ :Union[str, Any] = images[0, 253:256, 253:256, -1] snake_case_ :str = jnp.asarray(jax.device_get(image_slice.flatten() ) ) snake_case_ :Dict = jnp.array( [0.1_6_7_9_6_9, 0.1_1_6_6_9_9, 0.0_8_1_5_4_3, 0.1_5_4_2_9_7, 0.1_3_2_8_1_2, 0.1_0_8_8_8_7, 0.1_6_9_9_2_2, 0.1_6_9_9_2_2, 0.2_0_5_0_7_8] ) print(f"""output_slice: {output_slice}""" ) assert jnp.abs(output_slice - expected_slice ).max() < 1E-2 def lowerCAmelCase_ ( self: int ) -> Dict: snake_case_, snake_case_ :List[Any] = FlaxControlNetModel.from_pretrained( """lllyasviel/sd-controlnet-openpose""" , from_pt=snake_case , dtype=jnp.bfloataa ) snake_case_, snake_case_ :int = FlaxStableDiffusionControlNetPipeline.from_pretrained( """runwayml/stable-diffusion-v1-5""" , controlnet=snake_case , from_pt=snake_case , dtype=jnp.bfloataa ) snake_case_ :str = controlnet_params snake_case_ :Optional[int] = """Chef in the kitchen""" snake_case_ :Union[str, Any] = jax.device_count() snake_case_ :Any = pipe.prepare_text_inputs([prompts] * num_samples ) snake_case_ :str = load_image( """https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main/sd_controlnet/pose.png""" ) snake_case_ :Optional[Any] = pipe.prepare_image_inputs([pose_image] * num_samples ) snake_case_ :str = jax.random.PRNGKey(0 ) snake_case_ :str = jax.random.split(snake_case , jax.device_count() ) snake_case_ :Tuple = replicate(snake_case ) snake_case_ :str = shard(snake_case ) snake_case_ :int = shard(snake_case ) snake_case_ :List[str] = pipe( prompt_ids=snake_case , image=snake_case , params=snake_case , prng_seed=snake_case , num_inference_steps=50 , jit=snake_case , ).images assert images.shape == (jax.device_count(), 1, 768, 512, 3) snake_case_ :str = images.reshape((images.shape[0] * images.shape[1],) + images.shape[-3:] ) snake_case_ :int = images[0, 253:256, 253:256, -1] snake_case_ :Dict = jnp.asarray(jax.device_get(image_slice.flatten() ) ) snake_case_ :Optional[int] = jnp.array( [[0.2_7_1_4_8_4, 0.2_6_1_7_1_9, 0.2_7_5_3_9_1, 0.2_7_7_3_4_4, 0.2_7_9_2_9_7, 0.2_9_1_0_1_6, 0.2_9_4_9_2_2, 0.3_0_2_7_3_4, 0.3_0_2_7_3_4]] ) print(f"""output_slice: {output_slice}""" ) assert jnp.abs(output_slice - expected_slice ).max() < 1E-2
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1
"""simple docstring""" from sklearn.metrics import fa_score, matthews_corrcoef import datasets from .record_evaluation import evaluate as evaluate_record __a = "\\n@article{wang2019superglue,\n title={SuperGLUE: A Stickier Benchmark for General-Purpose Language Understanding Systems},\n author={Wang, Alex and Pruksachatkun, Yada and Nangia, Nikita and Singh, Amanpreet and Michael, Julian and Hill, Felix and Levy, Omer and Bowman, Samuel R},\n journal={arXiv preprint arXiv:1905.00537},\n year={2019}\n}\n" __a = "\\nSuperGLUE (https://super.gluebenchmark.com/) is a new benchmark styled after\nGLUE with a new set of more difficult language understanding tasks, improved\nresources, and a new public leaderboard.\n" __a = "\nCompute SuperGLUE evaluation metric associated to each SuperGLUE dataset.\nArgs:\n predictions: list of predictions to score. Depending on the SuperGlUE subset:\n - for 'record': list of question-answer dictionaries with the following keys:\n - 'idx': index of the question as specified by the dataset\n - 'prediction_text': the predicted answer text\n - for 'multirc': list of question-answer dictionaries with the following keys:\n - 'idx': index of the question-answer pair as specified by the dataset\n - 'prediction': the predicted answer label\n - otherwise: list of predicted labels\n references: list of reference labels. Depending on the SuperGLUE subset:\n - for 'record': list of question-answers dictionaries with the following keys:\n - 'idx': index of the question as specified by the dataset\n - 'answers': list of possible answers\n - otherwise: list of reference labels\nReturns: depending on the SuperGLUE subset:\n - for 'record':\n - 'exact_match': Exact match between answer and gold answer\n - 'f1': F1 score\n - for 'multirc':\n - 'exact_match': Exact match between answer and gold answer\n - 'f1_m': Per-question macro-F1 score\n - 'f1_a': Average F1 score over all answers\n - for 'axb':\n 'matthews_correlation': Matthew Correlation\n - for 'cb':\n - 'accuracy': Accuracy\n - 'f1': F1 score\n - for all others:\n - 'accuracy': Accuracy\nExamples:\n\n >>> super_glue_metric = datasets.load_metric('super_glue', 'copa') # any of [\"copa\", \"rte\", \"wic\", \"wsc\", \"wsc.fixed\", \"boolq\", \"axg\"]\n >>> predictions = [0, 1]\n >>> references = [0, 1]\n >>> results = super_glue_metric.compute(predictions=predictions, references=references)\n >>> print(results)\n {'accuracy': 1.0}\n\n >>> super_glue_metric = datasets.load_metric('super_glue', 'cb')\n >>> predictions = [0, 1]\n >>> references = [0, 1]\n >>> results = super_glue_metric.compute(predictions=predictions, references=references)\n >>> print(results)\n {'accuracy': 1.0, 'f1': 1.0}\n\n >>> super_glue_metric = datasets.load_metric('super_glue', 'record')\n >>> predictions = [{'idx': {'passage': 0, 'query': 0}, 'prediction_text': 'answer'}]\n >>> references = [{'idx': {'passage': 0, 'query': 0}, 'answers': ['answer', 'another_answer']}]\n >>> results = super_glue_metric.compute(predictions=predictions, references=references)\n >>> print(results)\n {'exact_match': 1.0, 'f1': 1.0}\n\n >>> super_glue_metric = datasets.load_metric('super_glue', 'multirc')\n >>> predictions = [{'idx': {'answer': 0, 'paragraph': 0, 'question': 0}, 'prediction': 0}, {'idx': {'answer': 1, 'paragraph': 2, 'question': 3}, 'prediction': 1}]\n >>> references = [0, 1]\n >>> results = super_glue_metric.compute(predictions=predictions, references=references)\n >>> print(results)\n {'exact_match': 1.0, 'f1_m': 1.0, 'f1_a': 1.0}\n\n >>> super_glue_metric = datasets.load_metric('super_glue', 'axb')\n >>> references = [0, 1]\n >>> predictions = [0, 1]\n >>> results = super_glue_metric.compute(predictions=predictions, references=references)\n >>> print(results)\n {'matthews_correlation': 1.0}\n" def A_ ( _lowercase, _lowercase ): '''simple docstring''' return float((preds == labels).mean() ) def A_ ( _lowercase, _lowercase, _lowercase="binary" ): '''simple docstring''' snake_case_ :Union[str, Any] = simple_accuracy(_lowercase, _lowercase ) snake_case_ :Tuple = float(fa_score(y_true=_lowercase, y_pred=_lowercase, average=_lowercase ) ) return { "accuracy": acc, "f1": fa, } def A_ ( _lowercase, _lowercase ): '''simple docstring''' snake_case_ :Any = {} for id_pred, label in zip(_lowercase, _lowercase ): snake_case_ :List[Any] = f"""{id_pred['idx']['paragraph']}-{id_pred['idx']['question']}""" snake_case_ :Dict = id_pred["""prediction"""] if question_id in question_map: question_map[question_id].append((pred, label) ) else: snake_case_ :Optional[int] = [(pred, label)] snake_case_, snake_case_ :List[Any] = [], [] for question, preds_labels in question_map.items(): snake_case_, snake_case_ :Union[str, Any] = zip(*_lowercase ) snake_case_ :Any = fa_score(y_true=_lowercase, y_pred=_lowercase, average="""macro""" ) fas.append(_lowercase ) snake_case_ :Tuple = int(sum(pred == label for pred, label in preds_labels ) == len(_lowercase ) ) ems.append(_lowercase ) snake_case_ :Optional[Any] = float(sum(_lowercase ) / len(_lowercase ) ) snake_case_ :List[Any] = sum(_lowercase ) / len(_lowercase ) snake_case_ :Dict = float(fa_score(y_true=_lowercase, y_pred=[id_pred["""prediction"""] for id_pred in ids_preds] ) ) return {"exact_match": em, "f1_m": fa_m, "f1_a": fa_a} @datasets.utils.file_utils.add_start_docstrings(_DESCRIPTION , _KWARGS_DESCRIPTION ) class lowerCamelCase ( datasets.Metric ): '''simple docstring''' def lowerCAmelCase_ ( self: Optional[Any] ) -> Union[str, Any]: if self.config_name not in [ "boolq", "cb", "copa", "multirc", "record", "rte", "wic", "wsc", "wsc.fixed", "axb", "axg", ]: raise KeyError( """You should supply a configuration name selected in """ """[\"boolq\", \"cb\", \"copa\", \"multirc\", \"record\", \"rte\", \"wic\", \"wsc\", \"wsc.fixed\", \"axb\", \"axg\",]""" ) return datasets.MetricInfo( description=_DESCRIPTION , citation=_CITATION , inputs_description=_KWARGS_DESCRIPTION , features=datasets.Features(self._get_feature_types() ) , codebase_urls=[] , reference_urls=[] , format="""numpy""" if not self.config_name == """record""" and not self.config_name == """multirc""" else None , ) def lowerCAmelCase_ ( self: Optional[Any] ) -> Any: if self.config_name == "record": return { "predictions": { "idx": { "passage": datasets.Value("""int64""" ), "query": datasets.Value("""int64""" ), }, "prediction_text": datasets.Value("""string""" ), }, "references": { "idx": { "passage": datasets.Value("""int64""" ), "query": datasets.Value("""int64""" ), }, "answers": datasets.Sequence(datasets.Value("""string""" ) ), }, } elif self.config_name == "multirc": return { "predictions": { "idx": { "answer": datasets.Value("""int64""" ), "paragraph": datasets.Value("""int64""" ), "question": datasets.Value("""int64""" ), }, "prediction": datasets.Value("""int64""" ), }, "references": datasets.Value("""int64""" ), } else: return { "predictions": datasets.Value("""int64""" ), "references": datasets.Value("""int64""" ), } def lowerCAmelCase_ ( self: Optional[int] , snake_case: Union[str, Any] , snake_case: Optional[Any] ) -> Optional[Any]: if self.config_name == "axb": return {"matthews_correlation": matthews_corrcoef(snake_case , snake_case )} elif self.config_name == "cb": return acc_and_fa(snake_case , snake_case , fa_avg="""macro""" ) elif self.config_name == "record": snake_case_ :List[str] = [ { """qas""": [ {"""id""": ref["""idx"""]["""query"""], """answers""": [{"""text""": ans} for ans in ref["""answers"""]]} for ref in references ] } ] snake_case_ :List[str] = {pred["""idx"""]["""query"""]: pred["""prediction_text"""] for pred in predictions} return evaluate_record(snake_case , snake_case )[0] elif self.config_name == "multirc": return evaluate_multirc(snake_case , snake_case ) elif self.config_name in ["copa", "rte", "wic", "wsc", "wsc.fixed", "boolq", "axg"]: return {"accuracy": simple_accuracy(snake_case , snake_case )} else: raise KeyError( """You should supply a configuration name selected in """ """[\"boolq\", \"cb\", \"copa\", \"multirc\", \"record\", \"rte\", \"wic\", \"wsc\", \"wsc.fixed\", \"axb\", \"axg\",]""" )
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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, ) __a = { "configuration_mobilebert": [ "MOBILEBERT_PRETRAINED_CONFIG_ARCHIVE_MAP", "MobileBertConfig", "MobileBertOnnxConfig", ], "tokenization_mobilebert": ["MobileBertTokenizer"], } try: if not is_tokenizers_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __a = ["MobileBertTokenizerFast"] try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __a = [ "MOBILEBERT_PRETRAINED_MODEL_ARCHIVE_LIST", "MobileBertForMaskedLM", "MobileBertForMultipleChoice", "MobileBertForNextSentencePrediction", "MobileBertForPreTraining", "MobileBertForQuestionAnswering", "MobileBertForSequenceClassification", "MobileBertForTokenClassification", "MobileBertLayer", "MobileBertModel", "MobileBertPreTrainedModel", "load_tf_weights_in_mobilebert", ] try: if not is_tf_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __a = [ "TF_MOBILEBERT_PRETRAINED_MODEL_ARCHIVE_LIST", "TFMobileBertForMaskedLM", "TFMobileBertForMultipleChoice", "TFMobileBertForNextSentencePrediction", "TFMobileBertForPreTraining", "TFMobileBertForQuestionAnswering", "TFMobileBertForSequenceClassification", "TFMobileBertForTokenClassification", "TFMobileBertMainLayer", "TFMobileBertModel", "TFMobileBertPreTrainedModel", ] if TYPE_CHECKING: from .configuration_mobilebert import ( MOBILEBERT_PRETRAINED_CONFIG_ARCHIVE_MAP, MobileBertConfig, MobileBertOnnxConfig, ) from .tokenization_mobilebert import MobileBertTokenizer try: if not is_tokenizers_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .tokenization_mobilebert_fast import MobileBertTokenizerFast try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_mobilebert import ( MOBILEBERT_PRETRAINED_MODEL_ARCHIVE_LIST, MobileBertForMaskedLM, MobileBertForMultipleChoice, MobileBertForNextSentencePrediction, MobileBertForPreTraining, MobileBertForQuestionAnswering, MobileBertForSequenceClassification, MobileBertForTokenClassification, MobileBertLayer, MobileBertModel, MobileBertPreTrainedModel, load_tf_weights_in_mobilebert, ) try: if not is_tf_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_tf_mobilebert import ( TF_MOBILEBERT_PRETRAINED_MODEL_ARCHIVE_LIST, TFMobileBertForMaskedLM, TFMobileBertForMultipleChoice, TFMobileBertForNextSentencePrediction, TFMobileBertForPreTraining, TFMobileBertForQuestionAnswering, TFMobileBertForSequenceClassification, TFMobileBertForTokenClassification, TFMobileBertMainLayer, TFMobileBertModel, TFMobileBertPreTrainedModel, ) else: import sys __a = _LazyModule(__name__, globals()["__file__"], _import_structure, module_spec=__spec__)
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1
"""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_camembert import CamembertTokenizer else: __a = None __a = logging.get_logger(__name__) __a = {"vocab_file": "sentencepiece.bpe.model", "tokenizer_file": "tokenizer.json"} __a = { "vocab_file": { "camembert-base": "https://huggingface.co/camembert-base/resolve/main/sentencepiece.bpe.model", }, "tokenizer_file": { "camembert-base": "https://huggingface.co/camembert-base/resolve/main/tokenizer.json", }, } __a = { "camembert-base": 5_12, } __a = "▁" class lowerCamelCase ( _lowerCAmelCase ): '''simple docstring''' _A : str = VOCAB_FILES_NAMES _A : str = PRETRAINED_VOCAB_FILES_MAP _A : List[Any] = PRETRAINED_POSITIONAL_EMBEDDINGS_SIZES _A : Dict = ["""input_ids""", """attention_mask"""] _A : Dict = CamembertTokenizer def __init__( self: int , snake_case: Union[str, Any]=None , snake_case: int=None , snake_case: Optional[int]="<s>" , snake_case: Optional[Any]="</s>" , snake_case: Dict="</s>" , snake_case: int="<s>" , snake_case: Tuple="<unk>" , snake_case: List[Any]="<pad>" , snake_case: List[str]="<mask>" , snake_case: int=["<s>NOTUSED", "</s>NOTUSED"] , **snake_case: str , ) -> List[str]: # Mask token behave like a normal word, i.e. include the space before it snake_case_ :List[str] = AddedToken(snake_case , lstrip=snake_case , rstrip=snake_case ) if isinstance(snake_case , snake_case ) else mask_token super().__init__( snake_case , tokenizer_file=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 , additional_special_tokens=snake_case , **snake_case , ) snake_case_ :List[str] = vocab_file snake_case_ :str = False if not self.vocab_file else True def lowerCAmelCase_ ( self: Union[str, Any] , snake_case: List[int] , snake_case: Optional[List[int]] = None ) -> List[int]: if token_ids_a is None: return [self.cls_token_id] + token_ids_a + [self.sep_token_id] snake_case_ :Tuple = [self.cls_token_id] snake_case_ :Dict = [self.sep_token_id] return cls + token_ids_a + sep + sep + token_ids_a + sep def lowerCAmelCase_ ( self: Union[str, Any] , snake_case: List[int] , snake_case: Optional[List[int]] = None ) -> List[int]: snake_case_ :Dict = [self.sep_token_id] snake_case_ :Dict = [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] def lowerCAmelCase_ ( self: Dict , snake_case: str , snake_case: Optional[str] = None ) -> Tuple[str]: if not self.can_save_slow_tokenizer: raise ValueError( """Your fast tokenizer does not have the necessary information to save the vocabulary for a slow """ """tokenizer.""" ) if not os.path.isdir(snake_case ): logger.error(f"""Vocabulary path ({save_directory}) should be a directory""" ) return snake_case_ :Union[str, Any] = 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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"""simple docstring""" import argparse import json import os from collections import OrderedDict import numpy as np import tensorflow as tf import torch def A_ ( _lowercase ): '''simple docstring''' snake_case_ :Union[str, Any] = os.path.join(args.tf_model_dir, """parameters.json""" ) snake_case_ :Any = json.loads(open(_lowercase ).read() ) if not params: raise ValueError( f"""It seems that the json file at {parameter_file} is empty. Make sure you have a correct json file.""" ) if not args.output.endswith(""".pt""" ): snake_case_ :Optional[int] = args.output + """.pt""" snake_case_ :List[str] = OrderedDict() with tf.device("""/CPU:0""" ): snake_case_ :Dict = tf.train.load_checkpoint(args.tf_model_dir ) snake_case_ :str = reader.get_variable_to_shape_map() for key_name in shapes.keys(): snake_case_ :List[Any] = reader.get_tensor(_lowercase ).astype(np.floataa ) if key_name.endswith("""/adam_m""" ) or key_name.endswith("""/adam_v""" ): continue if key_name.startswith("""pasts/""" ): if key_name.startswith("""pasts/mlp""" ): snake_case_ :Any = int(key_name[9] ) elif key_name.startswith("""pasts/out""" ): snake_case_ :Optional[int] = 8 snake_case_ :List[str] = """model.sqout.%d.weight""" % (player * 2) # enter to nn.Sequencial with Tanh, so 2 at a time snake_case_ :Optional[Any] = vnp.transpose([1, 0] ).copy() # Mesh-Tensorflow is a diagonal matrix snake_case_ :List[str] = torch.tensor(_lowercase ) elif key_name.startswith("""model/moe""" ): snake_case_ :Tuple = int(key_name[9:].split("""/""" )[0] ) if key_name.endswith("""/switch_gating/kernel""" ): snake_case_ :Union[str, Any] = """model.blocks.%d.feed_forward.mlp.router.classifier.weight""" % player snake_case_ :Optional[Any] = vnp.transpose([1, 0] ).copy() # Mesh-Tensorflow is a diagonal matrix snake_case_ :Optional[Any] = torch.tensor(_lowercase ) elif key_name.endswith("""/softmlp/kernel""" ): snake_case_ :List[Any] = """model.blocks.%d.feed_forward.soft_bypass_mlp.weight""" % player snake_case_ :Optional[int] = vnp.transpose([1, 0] ).copy() # Mesh-Tensorflow is a diagonal matrix snake_case_ :Optional[Any] = torch.tensor(_lowercase ) elif key_name.endswith("""/wo/kernel""" ) or key_name.endswith("""/wi/kernel""" ): snake_case_ :Dict = key_name[-9:-7] for i in range(16 ): snake_case_ :str = """model.blocks.%d.feed_forward.mlp.experts.expert_%d.%s.weight""" % (player, i, nlayer) snake_case_ :Tuple = ( vnp[i].transpose([1, 0] ).copy() ) # In Mesh-Tensorflow, it is one array, so it is divided snake_case_ :Optional[int] = torch.tensor(_lowercase ) elif key_name.startswith("""model/mlp""" ): snake_case_ :Optional[int] = int(key_name[9:].split("""/""" )[0] ) if key_name.endswith("""/p1/kernel""" ): snake_case_ :Union[str, Any] = """model.blocks.%d.feed_forward.mlp.wi.weight""" % player snake_case_ :Dict = vnp.transpose([1, 0] ).copy() # Mesh-Tensorflow is a diagonal matrix snake_case_ :Optional[Any] = torch.tensor(_lowercase ) elif key_name.endswith("""/p1/bias""" ): snake_case_ :List[Any] = """model.blocks.%d.feed_forward.mlp.wi.bias""" % player snake_case_ :str = vnp.copy() # same because it is one dimensional snake_case_ :Optional[Any] = torch.tensor(_lowercase ) elif key_name.endswith("""/p2/kernel""" ): snake_case_ :Union[str, Any] = """model.blocks.%d.feed_forward.mlp.wo.weight""" % player snake_case_ :Dict = vnp.transpose([1, 0] ).copy() # Mesh-Tensorflow is a diagonal matrix snake_case_ :Tuple = torch.tensor(_lowercase ) elif key_name.endswith("""/p2/bias""" ): snake_case_ :Dict = """model.blocks.%d.feed_forward.mlp.wo.bias""" % player snake_case_ :Any = vnp.copy() # same because it is one dimensional snake_case_ :Optional[int] = torch.tensor(_lowercase ) elif key_name.startswith("""model/ln""" ): snake_case_ :Union[str, Any] = int(key_name[8:].split("""/""" )[0] ) if key_name.endswith("""/b""" ): snake_case_ :str = """model.blocks.%d.feed_forward.norm.bias""" % player snake_case_ :Dict = vnp.copy() # same because it is one dimensional snake_case_ :int = torch.tensor(_lowercase ) elif key_name.endswith("""/g""" ): snake_case_ :Dict = """model.blocks.%d.feed_forward.norm.weight""" % player snake_case_ :Dict = vnp.copy() # same because it is one dimensional snake_case_ :Tuple = torch.tensor(_lowercase ) elif key_name.startswith("""model/att""" ): snake_case_ :List[str] = int(key_name[9:].split("""/""" )[0] ) if key_name.endswith("""/qkv/kernel""" ): snake_case_ :Optional[int] = vnp.copy() # Compute same dimension as Mesh-tensorflow using einsum snake_case_ :Dict = state[:, 0, :, :] snake_case_ :int = state[:, 1, :, :] snake_case_ :List[str] = state[:, 2, :, :] snake_case_ :str = ( state_q.reshape([state_q.shape[0], state_q.shape[1] * state_q.shape[2]] ) .transpose([1, 0] ) .copy() ) # Mesh-Tensorflow is a diagonal matrix snake_case_ :Any = ( state_k.reshape([state_k.shape[0], state_k.shape[1] * state_k.shape[2]] ) .transpose([1, 0] ) .copy() ) # Mesh-Tensorflow is a diagonal matrix snake_case_ :Optional[int] = ( state_v.reshape([state_v.shape[0], state_v.shape[1] * state_v.shape[2]] ) .transpose([1, 0] ) .copy() ) # Mesh-Tensorflow is a diagonal matrix snake_case_ :int = """model.blocks.%d.self_attn.self_attn.q_proj.weight""" % player snake_case_ :int = torch.tensor(_lowercase ) snake_case_ :Optional[Any] = """model.blocks.%d.self_attn.self_attn.k_proj.weight""" % player snake_case_ :Dict = torch.tensor(_lowercase ) snake_case_ :Dict = """model.blocks.%d.self_attn.self_attn.v_proj.weight""" % player snake_case_ :Optional[Any] = torch.tensor(_lowercase ) elif key_name.endswith("""/o/kernel""" ): snake_case_ :str = """model.blocks.%d.self_attn.self_attn.out_proj.weight""" % player snake_case_ :str = ( vnp.reshape([vnp.shape[0] * vnp.shape[1], vnp.shape[2]] ).transpose([1, 0] ).copy() ) # Mesh-Tensorflow is a diagonal matrix snake_case_ :Any = torch.tensor(_lowercase ) elif key_name.startswith("""model/an""" ): snake_case_ :Optional[int] = int(key_name[8:].split("""/""" )[0] ) if key_name.endswith("""/b""" ): snake_case_ :Any = """model.blocks.%d.self_attn.norm.bias""" % player snake_case_ :Optional[int] = vnp.copy() # same because it is one dimensional snake_case_ :Tuple = torch.tensor(_lowercase ) elif key_name.endswith("""/g""" ): snake_case_ :Union[str, Any] = """model.blocks.%d.self_attn.norm.weight""" % player snake_case_ :Dict = vnp.copy() # same because it is one dimensional snake_case_ :Optional[int] = torch.tensor(_lowercase ) elif ( key_name.startswith("""model/wte""" ) or key_name.startswith("""model/wpe""" ) or key_name.startswith("""model/ete""" ) ): snake_case_ :List[Any] = {"""wte""": """embed_tokens""", """wpe""": """position_embeddings""", """ete""": """extra_position_embeddings"""}[ key_name[-3:] ] snake_case_ :Optional[Any] = """model.%s.weight""" % nlayer snake_case_ :Any = vnp.copy() # same in embedded snake_case_ :List[Any] = torch.tensor(_lowercase ) if key_name.startswith("""model/wte""" ): snake_case_ :Tuple = """lm_head.weight""" snake_case_ :List[str] = vnp.copy() # same in embedded snake_case_ :List[Any] = torch.tensor(_lowercase ) elif key_name.startswith("""model/wob""" ): snake_case_ :str = """final_logits_bias""" snake_case_ :Any = vnp.copy() # same in embedded snake_case_ :List[Any] = state.reshape((1, -1) ) snake_case_ :Union[str, Any] = torch.tensor(_lowercase ) elif key_name == "model/dense/kernel": snake_case_ :str = """model.last_project.weight""" snake_case_ :Dict = vnp.transpose([1, 0] ).copy() # Mesh-Tensorflow is a diagonal matrix snake_case_ :int = torch.tensor(_lowercase ) elif key_name == "model/dense_1/bias": snake_case_ :Optional[int] = """model.last_project.bias""" snake_case_ :Tuple = vnp.copy() # same because it is one dimensional snake_case_ :Any = torch.tensor(_lowercase ) torch.save(_lowercase, args.output ) if __name__ == "__main__": __a = argparse.ArgumentParser( description="model converter.", formatter_class=argparse.ArgumentDefaultsHelpFormatter ) parser.add_argument("--tf_model_dir", metavar="PATH", type=str, required=True, help="import model") parser.add_argument("--output", metavar="PATH", type=str, required=True, help="output model") __a = parser.parse_args() convert_tf_gptsan_to_pt(args)
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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: Union[str, Any] , snake_case: Optional[Any] , snake_case: List[str]=7 , snake_case: List[str]=3 , snake_case: Tuple=18 , snake_case: Optional[int]=30 , snake_case: Optional[Any]=400 , snake_case: Tuple=True , snake_case: int=None , snake_case: Optional[int]=True , snake_case: int=None , ) -> Dict: snake_case_ :Optional[Any] = size if size is not None else {"""shortest_edge""": 20} snake_case_ :int = crop_size if crop_size is not None else {"""height""": 18, """width""": 18} snake_case_ :List[Any] = parent snake_case_ :Any = batch_size snake_case_ :List[Any] = num_channels snake_case_ :Any = image_size snake_case_ :Tuple = min_resolution snake_case_ :Optional[Any] = max_resolution snake_case_ :Tuple = do_resize snake_case_ :Any = size snake_case_ :List[str] = do_center_crop snake_case_ :Dict = crop_size def lowerCAmelCase_ ( self: Union[str, Any] ) -> List[str]: 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''' _A : Any = MobileNetVaImageProcessor if is_vision_available() else None def lowerCAmelCase_ ( self: str ) -> Dict: snake_case_ :Any = MobileNetVaImageProcessingTester(self ) @property def lowerCAmelCase_ ( self: Dict ) -> str: return self.image_processor_tester.prepare_image_processor_dict() def lowerCAmelCase_ ( self: List[str] ) -> List[Any]: snake_case_ :Tuple = 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 lowerCAmelCase_ ( self: Dict ) -> Tuple: snake_case_ :Optional[int] = 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} ) snake_case_ :Union[str, Any] = 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 lowerCAmelCase_ ( self: Tuple ) -> Tuple: pass def lowerCAmelCase_ ( self: Tuple ) -> List[Any]: # Initialize image_processing snake_case_ :str = self.image_processing_class(**self.image_processor_dict ) # create random PIL images snake_case_ :int = 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_ :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_ :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 lowerCAmelCase_ ( self: Any ) -> Tuple: # Initialize image_processing snake_case_ :List[str] = self.image_processing_class(**self.image_processor_dict ) # create random numpy tensors snake_case_ :Tuple = 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_ :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_ :int = 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 lowerCAmelCase_ ( self: str ) -> List[str]: # Initialize image_processing snake_case_ :Union[str, Any] = self.image_processing_class(**self.image_processor_dict ) # create random PyTorch tensors snake_case_ :Optional[int] = 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_ :List[Any] = 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_ :int = 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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"""simple docstring""" import numpy as np import pandas as pd from sklearn.preprocessing import MinMaxScaler from tensorflow.keras.layers import LSTM, Dense from tensorflow.keras.models import Sequential if __name__ == "__main__": __a = pd.read_csv("sample_data.csv", header=None) __a = df.shape[:1][0] # If you're using some other dataset input the target column __a = df.iloc[:, 1:2] __a = actual_data.values.reshape(len_data, 1) __a = MinMaxScaler().fit_transform(actual_data) __a = 10 __a = 5 __a = 20 __a = len_data - periods * look_back __a = actual_data[:division] __a = actual_data[division - look_back :] __a , __a = [], [] __a , __a = [], [] for i in range(0, len(train_data) - forward_days - look_back + 1): train_x.append(train_data[i : i + look_back]) train_y.append(train_data[i + look_back : i + look_back + forward_days]) for i in range(0, len(test_data) - forward_days - look_back + 1): test_x.append(test_data[i : i + look_back]) test_y.append(test_data[i + look_back : i + look_back + forward_days]) __a = np.array(train_x) __a = np.array(test_x) __a = np.array([list(i.ravel()) for i in train_y]) __a = np.array([list(i.ravel()) for i in test_y]) __a = Sequential() model.add(LSTM(1_28, input_shape=(look_back, 1), return_sequences=True)) model.add(LSTM(64, input_shape=(1_28, 1))) model.add(Dense(forward_days)) model.compile(loss="mean_squared_error", optimizer="adam") __a = model.fit( x_train, y_train, epochs=1_50, verbose=1, shuffle=True, batch_size=4 ) __a = model.predict(x_test)
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"""simple docstring""" import warnings from typing import Any, Dict, List, Optional, Union import numpy as np from ...audio_utils import mel_filter_bank, optimal_fft_length, spectrogram, window_function from ...feature_extraction_sequence_utils import SequenceFeatureExtractor from ...feature_extraction_utils import BatchFeature from ...utils import PaddingStrategy, TensorType, logging __a = logging.get_logger(__name__) class lowerCamelCase ( _lowerCAmelCase ): '''simple docstring''' _A : Union[str, Any] = ["""input_values""", """attention_mask"""] def __init__( self: Optional[int] , snake_case: int = 1 , snake_case: int = 16_000 , snake_case: float = 0.0 , snake_case: bool = False , snake_case: int = 80 , snake_case: int = 16 , snake_case: int = 64 , snake_case: str = "hann_window" , snake_case: float = 1.0 , snake_case: float = 80 , snake_case: float = 7_600 , snake_case: float = 1E-10 , snake_case: int = 2 , snake_case: bool = True , **snake_case: Tuple , ) -> Union[str, Any]: super().__init__(feature_size=snake_case , sampling_rate=snake_case , padding_value=snake_case , **snake_case ) snake_case_ :Optional[int] = do_normalize snake_case_ :Optional[int] = return_attention_mask snake_case_ :str = num_mel_bins snake_case_ :Tuple = hop_length snake_case_ :Optional[Any] = win_length snake_case_ :Optional[Any] = win_function snake_case_ :Any = frame_signal_scale snake_case_ :int = fmin snake_case_ :Any = fmax snake_case_ :Optional[Any] = mel_floor snake_case_ :str = reduction_factor snake_case_ :int = win_length * sampling_rate // 1_000 snake_case_ :List[Any] = hop_length * sampling_rate // 1_000 snake_case_ :str = optimal_fft_length(self.sample_size ) snake_case_ :Optional[Any] = (self.n_fft // 2) + 1 snake_case_ :Any = window_function(window_length=self.sample_size , name=self.win_function , periodic=snake_case ) snake_case_ :int = mel_filter_bank( num_frequency_bins=self.n_freqs , num_mel_filters=self.num_mel_bins , min_frequency=self.fmin , max_frequency=self.fmax , sampling_rate=self.sampling_rate , norm="""slaney""" , mel_scale="""slaney""" , ) if frame_signal_scale != 1.0: warnings.warn( """The argument `frame_signal_scale` is deprecated and will be removed in version 4.30.0 of Transformers""" , snake_case , ) if reduction_factor != 2.0: warnings.warn( """The argument `reduction_factor` is deprecated and will be removed in version 4.30.0 of Transformers""" , snake_case , ) @staticmethod # Copied from transformers.models.wav2vec2.feature_extraction_wav2vec2.Wav2Vec2FeatureExtractor.zero_mean_unit_var_norm def lowerCAmelCase_ ( snake_case: List[np.ndarray] , snake_case: List[np.ndarray] , snake_case: float = 0.0 ) -> List[np.ndarray]: if attention_mask is not None: snake_case_ :Tuple = np.array(snake_case , np.intaa ) snake_case_ :Tuple = [] for vector, length in zip(snake_case , attention_mask.sum(-1 ) ): snake_case_ :List[Any] = (vector - vector[:length].mean()) / np.sqrt(vector[:length].var() + 1E-7 ) if length < normed_slice.shape[0]: snake_case_ :Optional[Any] = padding_value normed_input_values.append(snake_case ) else: snake_case_ :Union[str, Any] = [(x - x.mean()) / np.sqrt(x.var() + 1E-7 ) for x in input_values] return normed_input_values def lowerCAmelCase_ ( self: Optional[int] , snake_case: np.ndarray , ) -> np.ndarray: snake_case_ :List[str] = spectrogram( snake_case , window=self.window , frame_length=self.sample_size , hop_length=self.sample_stride , fft_length=self.n_fft , mel_filters=self.mel_filters , mel_floor=self.mel_floor , log_mel="""log10""" , ) return log_mel_spec.T def __call__( self: Dict , snake_case: Optional[Union[np.ndarray, List[float], List[np.ndarray], List[List[float]]]] = None , snake_case: Optional[Union[np.ndarray, List[float], List[np.ndarray], List[List[float]]]] = None , snake_case: Union[bool, str, PaddingStrategy] = False , snake_case: Optional[int] = None , snake_case: bool = False , snake_case: Optional[int] = None , snake_case: Optional[bool] = None , snake_case: Optional[Union[str, TensorType]] = None , snake_case: Optional[int] = None , **snake_case: Union[str, Any] , ) -> BatchFeature: if audio is None and audio_target is None: raise ValueError("""You must provide either `audio` or `audio_target` values.""" ) if sampling_rate is not None: if sampling_rate != self.sampling_rate: raise ValueError( f"""The model corresponding to this feature extractor: {self} was trained using a sampling rate of""" f""" {self.sampling_rate}. Please make sure that the provided audio input was sampled with""" f""" {self.sampling_rate} and not {sampling_rate}.""" ) else: logger.warning( """It is strongly recommended to pass the ``sampling_rate`` argument to this function. """ """Failing to do so can result in silent errors that might be hard to debug.""" ) if audio is not None: snake_case_ :str = self._process_audio( snake_case , snake_case , snake_case , snake_case , snake_case , snake_case , snake_case , snake_case , **snake_case , ) else: snake_case_ :Optional[Any] = None if audio_target is not None: snake_case_ :Optional[Any] = self._process_audio( snake_case , snake_case , snake_case , snake_case , snake_case , snake_case , snake_case , snake_case , **snake_case , ) if inputs is None: return inputs_target else: snake_case_ :Optional[Any] = inputs_target["""input_values"""] snake_case_ :Union[str, Any] = inputs_target.get("""attention_mask""" ) if decoder_attention_mask is not None: snake_case_ :str = decoder_attention_mask return inputs def lowerCAmelCase_ ( self: Optional[Any] , snake_case: Union[np.ndarray, List[float], List[np.ndarray], List[List[float]]] , snake_case: bool = False , snake_case: Union[bool, str, PaddingStrategy] = False , snake_case: Optional[int] = None , snake_case: bool = False , snake_case: Optional[int] = None , snake_case: Optional[bool] = None , snake_case: Optional[Union[str, TensorType]] = None , **snake_case: int , ) -> BatchFeature: snake_case_ :str = isinstance(snake_case , np.ndarray ) and len(speech.shape ) > 1 if is_batched_numpy and len(speech.shape ) > 2: raise ValueError(f"""Only mono-channel audio is supported for input to {self}""" ) snake_case_ :str = is_batched_numpy or ( isinstance(snake_case , (list, tuple) ) and (isinstance(speech[0] , (np.ndarray, tuple, list) )) ) if is_batched: snake_case_ :Dict = [np.asarray(snake_case , dtype=np.floataa ) for speech in speech] elif not is_batched and not isinstance(snake_case , np.ndarray ): snake_case_ :str = np.asarray(snake_case , dtype=np.floataa ) elif isinstance(snake_case , np.ndarray ) and speech.dtype is np.dtype(np.floataa ): snake_case_ :Any = speech.astype(np.floataa ) # always return batch if not is_batched: snake_case_ :List[str] = [speech] # needed to make pad() work on spectrogram inputs snake_case_ :Optional[int] = self.feature_size # convert into correct format for padding if is_target: snake_case_ :str = [self._extract_mel_features(snake_case ) for waveform in speech] snake_case_ :str = BatchFeature({"""input_values""": features} ) snake_case_ :List[Any] = self.num_mel_bins else: snake_case_ :Optional[Any] = BatchFeature({"""input_values""": speech} ) snake_case_ :Any = self.pad( snake_case , padding=snake_case , max_length=snake_case , truncation=snake_case , pad_to_multiple_of=snake_case , return_attention_mask=snake_case , **snake_case , ) snake_case_ :Dict = feature_size_hack # convert input values to correct format snake_case_ :Dict = padded_inputs["""input_values"""] if not isinstance(input_values[0] , np.ndarray ): snake_case_ :Union[str, Any] = [np.asarray(snake_case , dtype=np.floataa ) for array in input_values] elif ( not isinstance(snake_case , np.ndarray ) and isinstance(input_values[0] , np.ndarray ) and input_values[0].dtype is np.dtype(np.floataa ) ): snake_case_ :Union[str, Any] = [array.astype(np.floataa ) for array in input_values] elif isinstance(snake_case , np.ndarray ) and input_values.dtype is np.dtype(np.floataa ): snake_case_ :str = input_values.astype(np.floataa ) # convert attention_mask to correct format snake_case_ :Union[str, Any] = padded_inputs.get("""attention_mask""" ) if attention_mask is not None: snake_case_ :Optional[int] = [np.asarray(snake_case , dtype=np.intaa ) for array in attention_mask] # zero-mean and unit-variance normalization if not is_target and self.do_normalize: snake_case_ :Optional[Any] = ( attention_mask if self._get_padding_strategies(snake_case , max_length=snake_case ) is not PaddingStrategy.DO_NOT_PAD else None ) snake_case_ :Optional[Any] = self.zero_mean_unit_var_norm( padded_inputs["""input_values"""] , attention_mask=snake_case , padding_value=self.padding_value ) if return_tensors is not None: snake_case_ :Union[str, Any] = padded_inputs.convert_to_tensors(snake_case ) return padded_inputs def lowerCAmelCase_ ( self: Dict ) -> Dict[str, Any]: snake_case_ :Optional[int] = super().to_dict() # Don't serialize these as they are derived from the other properties. snake_case_ :Optional[int] = ["""window""", """mel_filters""", """sample_size""", """sample_stride""", """n_fft""", """n_freqs"""] for name in names: if name in output: del output[name] return output
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"""simple docstring""" from typing import TYPE_CHECKING from ...utils import OptionalDependencyNotAvailable, _LazyModule, is_tokenizers_available, is_torch_available __a = { "configuration_altclip": [ "ALTCLIP_PRETRAINED_CONFIG_ARCHIVE_MAP", "AltCLIPConfig", "AltCLIPTextConfig", "AltCLIPVisionConfig", ], "processing_altclip": ["AltCLIPProcessor"], } try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __a = [ "ALTCLIP_PRETRAINED_MODEL_ARCHIVE_LIST", "AltCLIPPreTrainedModel", "AltCLIPModel", "AltCLIPTextModel", "AltCLIPVisionModel", ] if TYPE_CHECKING: from .configuration_altclip import ( ALTCLIP_PRETRAINED_CONFIG_ARCHIVE_MAP, AltCLIPConfig, AltCLIPTextConfig, AltCLIPVisionConfig, ) from .processing_altclip import AltCLIPProcessor try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_altclip import ( ALTCLIP_PRETRAINED_MODEL_ARCHIVE_LIST, AltCLIPModel, AltCLIPPreTrainedModel, AltCLIPTextModel, AltCLIPVisionModel, ) else: import sys __a = _LazyModule(__name__, globals()["__file__"], _import_structure, module_spec=__spec__)
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"""simple docstring""" from typing import TYPE_CHECKING from ...utils import ( OptionalDependencyNotAvailable, _LazyModule, is_torch_available, ) __a = { "configuration_swiftformer": [ "SWIFTFORMER_PRETRAINED_CONFIG_ARCHIVE_MAP", "SwiftFormerConfig", "SwiftFormerOnnxConfig", ] } try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __a = [ "SWIFTFORMER_PRETRAINED_MODEL_ARCHIVE_LIST", "SwiftFormerForImageClassification", "SwiftFormerModel", "SwiftFormerPreTrainedModel", ] if TYPE_CHECKING: from .configuration_swiftformer import ( SWIFTFORMER_PRETRAINED_CONFIG_ARCHIVE_MAP, SwiftFormerConfig, SwiftFormerOnnxConfig, ) try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_swiftformer import ( SWIFTFORMER_PRETRAINED_MODEL_ARCHIVE_LIST, SwiftFormerForImageClassification, SwiftFormerModel, SwiftFormerPreTrainedModel, ) else: import sys __a = _LazyModule(__name__, globals()["__file__"], _import_structure, module_spec=__spec__)
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"""simple docstring""" import argparse import gdown import numpy as np import torch from huggingface_hub import hf_hub_download from transformers import ( CLIPTokenizer, CLIPTokenizerFast, VideoMAEImageProcessor, XCLIPConfig, XCLIPModel, XCLIPProcessor, XCLIPTextConfig, XCLIPVisionConfig, ) def A_ ( _lowercase, _lowercase ): '''simple docstring''' snake_case_ :int = XCLIPTextConfig() # derive patch size from model name snake_case_ :Union[str, Any] = model_name.find("""patch""" ) snake_case_ :List[str] = int(model_name[start_idx + len("""patch""" ) : start_idx + len("""patch""" ) + 2] ) snake_case_ :Any = XCLIPVisionConfig(patch_size=_lowercase, num_frames=_lowercase ) if "large" in model_name: snake_case_ :Optional[Any] = 768 snake_case_ :Union[str, Any] = 3072 snake_case_ :Any = 12 snake_case_ :Any = 1024 snake_case_ :str = 4096 snake_case_ :Union[str, Any] = 16 snake_case_ :Union[str, Any] = 24 snake_case_ :Tuple = 768 snake_case_ :Any = 3072 if model_name == "xclip-large-patch14-16-frames": snake_case_ :Any = 336 snake_case_ :Any = XCLIPConfig.from_text_vision_configs(_lowercase, _lowercase ) if "large" in model_name: snake_case_ :List[Any] = 768 return config def A_ ( _lowercase ): '''simple docstring''' if name == "token_embedding.weight": snake_case_ :Optional[Any] = name.replace("""token_embedding.weight""", """text_model.embeddings.token_embedding.weight""" ) if name == "positional_embedding": snake_case_ :Tuple = name.replace("""positional_embedding""", """text_model.embeddings.position_embedding.weight""" ) if "ln_1" in name: snake_case_ :Dict = name.replace("""ln_1""", """layer_norm1""" ) if "ln_2" in name: snake_case_ :str = name.replace("""ln_2""", """layer_norm2""" ) if "c_fc" in name: snake_case_ :str = name.replace("""c_fc""", """fc1""" ) if "c_proj" in name: snake_case_ :int = name.replace("""c_proj""", """fc2""" ) if name.startswith("""transformer.resblocks""" ): snake_case_ :Union[str, Any] = name.replace("""transformer.resblocks""", """text_model.encoder.layers""" ) if "attn.out_proj" in name and "message" not in name: snake_case_ :Union[str, Any] = name.replace("""attn.out_proj""", """self_attn.out_proj""" ) if "ln_final" in name: snake_case_ :Union[str, Any] = name.replace("""ln_final""", """text_model.final_layer_norm""" ) # visual encoder if name == "visual.class_embedding": snake_case_ :Any = name.replace("""visual.class_embedding""", """vision_model.embeddings.class_embedding""" ) if name == "visual.positional_embedding": snake_case_ :Optional[int] = name.replace("""visual.positional_embedding""", """vision_model.embeddings.position_embedding.weight""" ) if name.startswith("""visual.transformer.resblocks""" ): snake_case_ :Union[str, Any] = name.replace("""visual.transformer.resblocks""", """vision_model.encoder.layers""" ) if "visual.conv1" in name: snake_case_ :int = name.replace("""visual.conv1""", """vision_model.embeddings.patch_embedding""" ) if "visual.ln_pre" in name: snake_case_ :Any = name.replace("""visual.ln_pre""", """vision_model.pre_layernorm""" ) if "visual.ln_post" in name: snake_case_ :str = name.replace("""visual.ln_post""", """vision_model.post_layernorm""" ) if "visual.proj" in name: snake_case_ :Union[str, Any] = name.replace("""visual.proj""", """visual_projection.weight""" ) if "text_projection" in name: snake_case_ :Dict = name.replace("""text_projection""", """text_projection.weight""" ) # things on top if "prompts_visual_proj" in name: snake_case_ :List[str] = name.replace("""prompts_visual_proj""", """prompts_visual_projection""" ) if "prompts_visual_ln" in name: snake_case_ :Dict = name.replace("""prompts_visual_ln""", """prompts_visual_layernorm""" ) # mit if name == "mit.positional_embedding": snake_case_ :str = name.replace("""positional""", """position""" ) if name.startswith("""mit.resblocks""" ): snake_case_ :Dict = name.replace("""mit.resblocks""", """mit.encoder.layers""" ) # prompts generator if name.startswith("""prompts_generator.norm""" ): snake_case_ :Union[str, Any] = name.replace("""prompts_generator.norm""", """prompts_generator.layernorm""" ) return name def A_ ( _lowercase, _lowercase ): '''simple docstring''' for key in orig_state_dict.copy().keys(): snake_case_ :Dict = orig_state_dict.pop(_lowercase ) if "attn.in_proj" in key: snake_case_ :Optional[Any] = key.split(""".""" ) if key.startswith("""visual""" ): snake_case_ :Any = key_split[3] snake_case_ :Optional[Any] = config.vision_config.hidden_size if "message_attn" in key: if "weight" in key: snake_case_ :str = val[ :dim, : ] snake_case_ :Optional[int] = val[ dim : dim * 2, : ] snake_case_ :Union[str, Any] = val[ -dim:, : ] else: snake_case_ :Dict = val[ :dim ] snake_case_ :Optional[int] = val[ dim : dim * 2 ] snake_case_ :Optional[int] = val[ -dim: ] else: if "weight" in key: snake_case_ :Optional[Any] = val[ :dim, : ] snake_case_ :List[str] = val[ dim : dim * 2, : ] snake_case_ :Dict = val[ -dim:, : ] else: snake_case_ :Union[str, Any] = val[:dim] snake_case_ :Union[str, Any] = val[ dim : dim * 2 ] snake_case_ :Union[str, Any] = val[-dim:] elif key.startswith("""mit""" ): snake_case_ :Tuple = key_split[2] snake_case_ :Union[str, Any] = config.vision_config.mit_hidden_size if "weight" in key: snake_case_ :Optional[int] = val[:dim, :] snake_case_ :Optional[int] = val[dim : dim * 2, :] snake_case_ :str = val[-dim:, :] else: snake_case_ :str = val[:dim] snake_case_ :Any = val[dim : dim * 2] snake_case_ :int = val[-dim:] else: snake_case_ :Tuple = key_split[2] snake_case_ :Any = config.text_config.hidden_size if "weight" in key: snake_case_ :Dict = val[:dim, :] snake_case_ :Dict = val[ dim : dim * 2, : ] snake_case_ :List[str] = val[-dim:, :] else: snake_case_ :Any = val[:dim] snake_case_ :Tuple = val[ dim : dim * 2 ] snake_case_ :List[str] = val[-dim:] else: snake_case_ :Optional[int] = rename_key(_lowercase ) if new_key_name in ["visual_projection.weight", "text_projection.weight"]: snake_case_ :Optional[Any] = val.T snake_case_ :Tuple = val return orig_state_dict def A_ ( _lowercase ): '''simple docstring''' if num_frames == 8: snake_case_ :str = """eating_spaghetti_8_frames.npy""" elif num_frames == 16: snake_case_ :int = """eating_spaghetti.npy""" elif num_frames == 32: snake_case_ :List[str] = """eating_spaghetti_32_frames.npy""" snake_case_ :int = hf_hub_download( repo_id="""hf-internal-testing/spaghetti-video""", filename=_lowercase, repo_type="""dataset""", ) snake_case_ :Union[str, Any] = np.load(_lowercase ) return list(_lowercase ) def A_ ( _lowercase, _lowercase=None, _lowercase=False ): '''simple docstring''' snake_case_ :List[Any] = { # fully supervised kinetics-400 checkpoints """xclip-base-patch32""": """https://github.com/nbl97/X-CLIP_Model_Zoo/releases/download/v1.0/k400_32_8.pth""", """xclip-base-patch32-16-frames""": ( """https://github.com/nbl97/X-CLIP_Model_Zoo/releases/download/v1.0/k400_32_16.pth""" ), """xclip-base-patch16""": """https://github.com/nbl97/X-CLIP_Model_Zoo/releases/download/v1.0/k400_16_8.pth""", """xclip-base-patch16-16-frames""": ( """https://github.com/nbl97/X-CLIP_Model_Zoo/releases/download/v1.0/k400_16_16.pth""" ), """xclip-large-patch14""": """https://drive.google.com/u/0/uc?id=1NUOImq0o5DlQTST17iIP3vG7DgmHQuCx&amp;export=download&amp;confirm=t&amp;uuid=b26caedc-88e2-473e-830a-9d158b653cdb""", """xclip-large-patch14-16-frames""": """https://drive.google.com/u/0/uc?id=1FOYgnJc097OJ4lGwtRCCydQyVPJEOH7d&amp;export=download&amp;confirm=t&amp;uuid=538fa810-e671-4050-b385-9a623f89804f""", # fully supervised kinetics-600 checkpoints """xclip-base-patch16-kinetics-600""": ( """https://github.com/nbl97/X-CLIP_Model_Zoo/releases/download/v1.0/k600_16_8.pth""" ), """xclip-base-patch16-kinetics-600-16-frames""": ( """https://github.com/nbl97/X-CLIP_Model_Zoo/releases/download/v1.0/k600_16_16.pth""" ), """xclip-large-patch14-kinetics-600""": """https://drive.google.com/u/0/uc?id=1FV8C1INuM91sLAN4ImjzePLIlpMSihwV&amp;export=download&amp;confirm=t&amp;uuid=141d4977-4a65-44ae-864f-4b0c19f838be""", # few shot """xclip-base-patch16-hmdb-2-shot""": ( """https://github.com/nbl97/X-CLIP_Model_Zoo/releases/download/v1.0/few_hmdb_2.pth""" ), """xclip-base-patch16-hmdb-4-shot""": ( """https://github.com/nbl97/X-CLIP_Model_Zoo/releases/download/v1.0/few_hmdb_4.pth""" ), """xclip-base-patch16-hmdb-8-shot""": ( """https://github.com/nbl97/X-CLIP_Model_Zoo/releases/download/v1.0/few_hmdb_8.pth""" ), """xclip-base-patch16-hmdb-16-shot""": ( """https://github.com/nbl97/X-CLIP_Model_Zoo/releases/download/v1.0/few_hmdb_16.pth""" ), """xclip-base-patch16-ucf-2-shot""": ( """https://github.com/nbl97/X-CLIP_Model_Zoo/releases/download/v1.0/few_ucf_2.pth""" ), """xclip-base-patch16-ucf-4-shot""": ( """https://github.com/nbl97/X-CLIP_Model_Zoo/releases/download/v1.0/few_ucf_4.pth""" ), """xclip-base-patch16-ucf-8-shot""": ( """https://github.com/nbl97/X-CLIP_Model_Zoo/releases/download/v1.0/few_ucf_8.pth""" ), """xclip-base-patch16-ucf-16-shot""": ( """https://github.com/nbl97/X-CLIP_Model_Zoo/releases/download/v1.0/few_ucf_16.pth""" ), # zero shot """xclip-base-patch16-zero-shot""": """https://github.com/nbl97/X-CLIP_Model_Zoo/releases/download/v1.0/zero.pth""", } snake_case_ :Optional[int] = model_to_url[model_name] snake_case_ :int = 8 if "16-frames" in model_name: snake_case_ :List[Any] = 16 elif "shot" in model_name: snake_case_ :Dict = 32 snake_case_ :Optional[int] = get_xclip_config(_lowercase, _lowercase ) snake_case_ :Optional[Any] = XCLIPModel(_lowercase ) model.eval() if "drive" in checkpoint_url: snake_case_ :List[str] = """pytorch_model.bin""" gdown.cached_download(_lowercase, _lowercase, quiet=_lowercase ) snake_case_ :List[Any] = torch.load(_lowercase, map_location="""cpu""" )["""model"""] else: snake_case_ :Tuple = torch.hub.load_state_dict_from_url(_lowercase )["""model"""] snake_case_ :Union[str, Any] = convert_state_dict(_lowercase, _lowercase ) snake_case_ :str = XCLIPModel(_lowercase ) snake_case_, snake_case_ :Optional[int] = model.load_state_dict(_lowercase, strict=_lowercase ) assert missing_keys == ["text_model.embeddings.position_ids", "vision_model.embeddings.position_ids"] model.eval() snake_case_ :List[str] = 336 if model_name == """xclip-large-patch14-16-frames""" else 224 snake_case_ :List[Any] = VideoMAEImageProcessor(size=_lowercase ) snake_case_ :Any = CLIPTokenizer.from_pretrained("""openai/clip-vit-base-patch32""" ) snake_case_ :str = CLIPTokenizerFast.from_pretrained("""openai/clip-vit-base-patch32""" ) snake_case_ :Optional[Any] = XCLIPProcessor(image_processor=_lowercase, tokenizer=_lowercase ) snake_case_ :Optional[int] = prepare_video(_lowercase ) snake_case_ :Optional[Any] = processor( text=["""playing sports""", """eating spaghetti""", """go shopping"""], videos=_lowercase, return_tensors="""pt""", padding=_lowercase ) print("""Shape of pixel values:""", inputs.pixel_values.shape ) with torch.no_grad(): snake_case_ :List[Any] = model(**_lowercase ) # Verify outputs snake_case_ :List[Any] = outputs.logits_per_video snake_case_ :Any = logits_per_video.softmax(dim=1 ) print("""Probs:""", _lowercase ) # kinetics-400 if model_name == "xclip-base-patch32": snake_case_ :Union[str, Any] = torch.tensor([[0.0019, 0.9951, 0.0030]] ) elif model_name == "xclip-base-patch32-16-frames": snake_case_ :str = torch.tensor([[7.09_99e-04, 9.98_83e-01, 4.55_80e-04]] ) elif model_name == "xclip-base-patch16": snake_case_ :Tuple = torch.tensor([[0.0083, 0.9681, 0.0236]] ) elif model_name == "xclip-base-patch16-16-frames": snake_case_ :Any = torch.tensor([[7.69_37e-04, 9.97_28e-01, 1.94_73e-03]] ) elif model_name == "xclip-large-patch14": snake_case_ :str = torch.tensor([[0.0062, 0.9864, 0.0075]] ) elif model_name == "xclip-large-patch14-16-frames": snake_case_ :Tuple = torch.tensor([[3.38_77e-04, 9.99_37e-01, 2.88_88e-04]] ) # kinetics-600 elif model_name == "xclip-base-patch16-kinetics-600": snake_case_ :List[Any] = torch.tensor([[0.0555, 0.8914, 0.0531]] ) elif model_name == "xclip-base-patch16-kinetics-600-16-frames": snake_case_ :Union[str, Any] = torch.tensor([[3.85_54e-04, 9.99_29e-01, 3.27_54e-04]] ) elif model_name == "xclip-large-patch14-kinetics-600": snake_case_ :List[Any] = torch.tensor([[0.0036, 0.9920, 0.0045]] ) # few shot elif model_name == "xclip-base-patch16-hmdb-2-shot": snake_case_ :Dict = torch.tensor([[7.18_90e-06, 9.99_94e-01, 5.65_59e-05]] ) elif model_name == "xclip-base-patch16-hmdb-4-shot": snake_case_ :Union[str, Any] = torch.tensor([[1.03_20e-05, 9.99_93e-01, 6.24_35e-05]] ) elif model_name == "xclip-base-patch16-hmdb-8-shot": snake_case_ :str = torch.tensor([[4.13_77e-06, 9.99_90e-01, 9.83_86e-05]] ) elif model_name == "xclip-base-patch16-hmdb-16-shot": snake_case_ :str = torch.tensor([[4.13_47e-05, 9.99_62e-01, 3.34_11e-04]] ) elif model_name == "xclip-base-patch16-ucf-2-shot": snake_case_ :int = torch.tensor([[8.58_57e-05, 9.99_28e-01, 6.32_91e-04]] ) elif model_name == "xclip-base-patch16-ucf-4-shot": snake_case_ :Optional[int] = torch.tensor([[8.58_57e-05, 9.99_28e-01, 6.32_91e-04]] ) elif model_name == "xclip-base-patch16-ucf-8-shot": snake_case_ :Any = torch.tensor([[0.0027, 0.9904, 0.0070]] ) elif model_name == "xclip-base-patch16-ucf-16-shot": snake_case_ :Tuple = torch.tensor([[9.82_19e-04, 9.95_93e-01, 3.08_63e-03]] ) # zero shot elif model_name == "xclip-base-patch16-zero-shot": snake_case_ :Union[str, Any] = torch.tensor([[3.50_82e-04, 9.97_85e-01, 1.79_66e-03]] ) else: raise ValueError(f"""Model name {model_name} not supported""" ) assert torch.allclose(_lowercase, _lowercase, atol=1e-3 ) print("""Looks ok!""" ) if pytorch_dump_folder_path is not None: print(f"""Saving model {model_name} to {pytorch_dump_folder_path}""" ) model.save_pretrained(_lowercase ) if push_to_hub: print("""Pushing model, processor and slow tokenizer files to the hub...""" ) model.push_to_hub(_lowercase, organization="""nielsr""" ) processor.push_to_hub(_lowercase, organization="""nielsr""" ) slow_tokenizer.push_to_hub(_lowercase, organization="""nielsr""" ) if __name__ == "__main__": __a = argparse.ArgumentParser() # Required parameters parser.add_argument( "--model_name", default="xclip-base-patch32", type=str, help="Name of the model.", ) 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 = parser.parse_args() convert_xclip_checkpoint(args.model_name, args.pytorch_dump_folder_path, args.push_to_hub)
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"""simple docstring""" import os import time import pytest from datasets.utils.filelock import FileLock, Timeout def A_ ( _lowercase ): '''simple docstring''' snake_case_ :Optional[int] = FileLock(str(tmpdir / """foo.lock""" ) ) snake_case_ :Tuple = FileLock(str(tmpdir / """foo.lock""" ) ) snake_case_ :List[Any] = 0.01 with locka.acquire(): with pytest.raises(_lowercase ): snake_case_ :Optional[Any] = time.time() locka.acquire(_lowercase ) assert time.time() - _start > timeout def A_ ( _lowercase ): '''simple docstring''' snake_case_ :int = """a""" * 1000 + """.lock""" snake_case_ :Tuple = FileLock(str(tmpdir / filename ) ) assert locka._lock_file.endswith(""".lock""" ) assert not locka._lock_file.endswith(_lowercase ) assert len(os.path.basename(locka._lock_file ) ) <= 255 snake_case_ :List[str] = FileLock(tmpdir / filename ) with locka.acquire(): with pytest.raises(_lowercase ): locka.acquire(0 )
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"""simple docstring""" import unittest import numpy as np from transformers import BertConfig, is_flax_available from transformers.testing_utils import require_flax, slow from ...test_modeling_flax_common import FlaxModelTesterMixin, floats_tensor, ids_tensor, random_attention_mask if is_flax_available(): from transformers.models.bert.modeling_flax_bert import ( FlaxBertForMaskedLM, FlaxBertForMultipleChoice, FlaxBertForNextSentencePrediction, FlaxBertForPreTraining, FlaxBertForQuestionAnswering, FlaxBertForSequenceClassification, FlaxBertForTokenClassification, FlaxBertModel, ) class lowerCamelCase ( unittest.TestCase ): '''simple docstring''' def __init__( self: List[Any] , snake_case: List[str] , snake_case: Optional[Any]=13 , snake_case: List[str]=7 , snake_case: Dict=True , snake_case: List[str]=True , snake_case: Optional[int]=True , snake_case: Any=True , snake_case: Optional[Any]=99 , snake_case: Tuple=32 , snake_case: Tuple=5 , snake_case: Dict=4 , snake_case: Optional[Any]=37 , snake_case: Union[str, Any]="gelu" , snake_case: Tuple=0.1 , snake_case: List[Any]=0.1 , snake_case: List[str]=512 , snake_case: Optional[int]=16 , snake_case: int=2 , snake_case: List[Any]=0.0_2 , snake_case: Union[str, Any]=4 , ) -> List[str]: snake_case_ :Dict = parent snake_case_ :Any = batch_size snake_case_ :Any = seq_length snake_case_ :List[str] = is_training snake_case_ :Optional[Any] = use_attention_mask snake_case_ :Dict = use_token_type_ids snake_case_ :Union[str, Any] = use_labels snake_case_ :str = vocab_size snake_case_ :int = hidden_size snake_case_ :List[str] = num_hidden_layers snake_case_ :Dict = num_attention_heads snake_case_ :Any = intermediate_size snake_case_ :Tuple = hidden_act snake_case_ :int = hidden_dropout_prob snake_case_ :Optional[Any] = attention_probs_dropout_prob snake_case_ :Any = max_position_embeddings snake_case_ :Union[str, Any] = type_vocab_size snake_case_ :Optional[int] = type_sequence_label_size snake_case_ :Union[str, Any] = initializer_range snake_case_ :Tuple = num_choices def lowerCAmelCase_ ( self: Tuple ) -> str: snake_case_ :Optional[Any] = ids_tensor([self.batch_size, self.seq_length] , self.vocab_size ) snake_case_ :Union[str, Any] = None if self.use_attention_mask: snake_case_ :str = random_attention_mask([self.batch_size, self.seq_length] ) snake_case_ :Any = None if self.use_token_type_ids: snake_case_ :List[str] = ids_tensor([self.batch_size, self.seq_length] , self.type_vocab_size ) snake_case_ :int = BertConfig( 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 , ) return config, input_ids, token_type_ids, attention_mask def lowerCAmelCase_ ( self: Optional[int] ) -> int: snake_case_ :str = self.prepare_config_and_inputs() snake_case_, snake_case_, snake_case_, snake_case_ :Optional[int] = config_and_inputs snake_case_ :Union[str, Any] = {"""input_ids""": input_ids, """token_type_ids""": token_type_ids, """attention_mask""": attention_mask} return config, inputs_dict def lowerCAmelCase_ ( self: Optional[Any] ) -> Any: snake_case_ :int = self.prepare_config_and_inputs() snake_case_, snake_case_, snake_case_, snake_case_ :Dict = config_and_inputs snake_case_ :Union[str, Any] = True snake_case_ :Optional[int] = floats_tensor([self.batch_size, self.seq_length, self.hidden_size] ) snake_case_ :Tuple = ids_tensor([self.batch_size, self.seq_length] , vocab_size=2 ) return ( config, input_ids, attention_mask, encoder_hidden_states, encoder_attention_mask, ) @require_flax class lowerCamelCase ( _lowerCAmelCase , unittest.TestCase ): '''simple docstring''' _A : List[str] = True _A : Dict = ( ( FlaxBertModel, FlaxBertForPreTraining, FlaxBertForMaskedLM, FlaxBertForMultipleChoice, FlaxBertForQuestionAnswering, FlaxBertForNextSentencePrediction, FlaxBertForSequenceClassification, FlaxBertForTokenClassification, FlaxBertForQuestionAnswering, ) if is_flax_available() else () ) def lowerCAmelCase_ ( self: int ) -> List[str]: snake_case_ :Any = FlaxBertModelTester(self ) @slow def lowerCAmelCase_ ( self: List[str] ) -> Dict: # Only check this for base model, not necessary for all model classes. # This will also help speed-up tests. snake_case_ :Dict = FlaxBertModel.from_pretrained("""bert-base-cased""" ) snake_case_ :Dict = model(np.ones((1, 1) ) ) self.assertIsNotNone(snake_case )
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1
"""simple docstring""" from __future__ import annotations def A_ ( _lowercase, _lowercase ): '''simple docstring''' snake_case_ :list[list[int]] = [] snake_case_ :list[int] = [] snake_case_ :Any = 0 snake_case_ :List[str] = sum(_lowercase ) create_state_space_tree(_lowercase, _lowercase, _lowercase, _lowercase, _lowercase, _lowercase ) return result def A_ ( _lowercase, _lowercase, _lowercase, _lowercase, _lowercase, _lowercase, ): '''simple docstring''' if sum(_lowercase ) > max_sum or (remaining_nums_sum + sum(_lowercase )) < max_sum: return if sum(_lowercase ) == max_sum: result.append(_lowercase ) return for index in range(_lowercase, len(_lowercase ) ): create_state_space_tree( _lowercase, _lowercase, index + 1, [*path, nums[index]], _lowercase, remaining_nums_sum - nums[index], ) __a = [3, 34, 4, 12, 5, 2] __a = 9 __a = generate_sum_of_subsets_soln(nums, max_sum) print(*result)
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"""simple docstring""" import math class lowerCamelCase : '''simple docstring''' def lowerCAmelCase_ ( self: Tuple , snake_case: list[list[float]] , snake_case: list[int] ) -> int: snake_case_ :Any = 0.0 snake_case_ :Tuple = 0.0 for i in range(len(snake_case ) ): da += math.pow((sample[i] - weights[0][i]) , 2 ) da += math.pow((sample[i] - weights[1][i]) , 2 ) return 0 if da > da else 1 return 0 def lowerCAmelCase_ ( self: Optional[int] , snake_case: list[list[int | float]] , snake_case: list[int] , snake_case: int , snake_case: float ) -> list[list[int | float]]: for i in range(len(snake_case ) ): weights[j][i] += alpha * (sample[i] - weights[j][i]) return weights def A_ ( ): '''simple docstring''' snake_case_ :Dict = [[1, 1, 0, 0], [0, 0, 0, 1], [1, 0, 0, 0], [0, 0, 1, 1]] # weight initialization ( n, C ) snake_case_ :List[Any] = [[0.2, 0.6, 0.5, 0.9], [0.8, 0.4, 0.7, 0.3]] # training snake_case_ :Optional[Any] = SelfOrganizingMap() snake_case_ :Dict = 3 snake_case_ :Dict = 0.5 for _ in range(_lowercase ): for j in range(len(_lowercase ) ): # training sample snake_case_ :List[Any] = training_samples[j] # Compute the winning vector snake_case_ :Optional[int] = self_organizing_map.get_winner(_lowercase, _lowercase ) # Update the winning vector snake_case_ :List[str] = self_organizing_map.update(_lowercase, _lowercase, _lowercase, _lowercase ) # classify test sample snake_case_ :str = [0, 0, 0, 1] snake_case_ :List[Any] = self_organizing_map.get_winner(_lowercase, _lowercase ) # results print(f"""Clusters that the test sample belongs to : {winner}""" ) print(f"""Weights that have been trained : {weights}""" ) # running the main() function if __name__ == "__main__": main()
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1
"""simple docstring""" # Lint as: python3 # pylint: enable=line-too-long # pylint: disable=g-import-not-at-top,g-bad-import-order,wrong-import-position __a = "2.13.1" import platform import pyarrow from packaging import version if version.parse(platform.python_version()) < version.parse("3.7"): raise ImportWarning( "To use `datasets`, Python>=3.7 is required, and the current version of Python doesn't match this condition." ) if version.parse(pyarrow.__version__).major < 8: raise ImportWarning( "To use `datasets`, the module `pyarrow>=8.0.0` is required, and the current version of `pyarrow` doesn't match this condition.\n" "If you are running this in a Google Colab, you should probably just restart the runtime to use the right version of `pyarrow`." ) del platform del pyarrow del version from .arrow_dataset import Dataset from .arrow_reader import ReadInstruction from .builder import ArrowBasedBuilder, BeamBasedBuilder, BuilderConfig, DatasetBuilder, GeneratorBasedBuilder from .combine import concatenate_datasets, interleave_datasets from .dataset_dict import DatasetDict, IterableDatasetDict from .download import * from .features import * from .fingerprint import disable_caching, enable_caching, is_caching_enabled, set_caching_enabled from .info import DatasetInfo, MetricInfo from .inspect import ( get_dataset_config_info, get_dataset_config_names, get_dataset_infos, get_dataset_split_names, inspect_dataset, inspect_metric, list_datasets, list_metrics, ) from .iterable_dataset import IterableDataset from .load import load_dataset, load_dataset_builder, load_from_disk, load_metric from .metric import Metric from .splits import ( NamedSplit, NamedSplitAll, Split, SplitBase, SplitDict, SplitGenerator, SplitInfo, SubSplitInfo, percent, ) from .tasks import * from .utils import * from .utils import logging # deprecated modules from datasets import arrow_dataset as _arrow_dataset # isort:skip from datasets import utils as _utils # isort:skip from datasets.utils import download_manager as _deprecated_download_manager # isort:skip __a = concatenate_datasets __a = DownloadConfig __a = DownloadManager __a = DownloadMode __a = DownloadConfig __a = DownloadMode __a = DownloadManager del _arrow_dataset, _utils, _deprecated_download_manager
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"""simple docstring""" 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 : '''simple docstring''' def __init__( self: Optional[int] , snake_case: Any , snake_case: Optional[Any]=13 , snake_case: Tuple=32 , snake_case: Optional[int]=2 , snake_case: Tuple=3 , snake_case: Tuple=16 , snake_case: Optional[Any]=[1, 2, 1] , snake_case: Optional[int]=[2, 2, 4] , snake_case: Optional[int]=2 , snake_case: int=2.0 , snake_case: Union[str, Any]=True , snake_case: List[str]=0.0 , snake_case: List[Any]=0.0 , snake_case: Optional[Any]=0.1 , snake_case: List[Any]="gelu" , snake_case: Optional[int]=False , snake_case: Union[str, Any]=True , snake_case: Union[str, Any]=0.0_2 , snake_case: Optional[int]=1E-5 , snake_case: Optional[Any]=True , snake_case: List[Any]=None , snake_case: List[Any]=True , snake_case: Optional[Any]=10 , snake_case: str=8 , ) -> Tuple: snake_case_ :Dict = parent snake_case_ :Any = batch_size snake_case_ :List[Any] = image_size snake_case_ :List[Any] = patch_size snake_case_ :int = num_channels snake_case_ :Tuple = embed_dim snake_case_ :str = depths snake_case_ :str = num_heads snake_case_ :Optional[int] = window_size snake_case_ :Tuple = mlp_ratio snake_case_ :Any = qkv_bias snake_case_ :List[Any] = hidden_dropout_prob snake_case_ :Optional[Any] = attention_probs_dropout_prob snake_case_ :Union[str, Any] = drop_path_rate snake_case_ :Any = hidden_act snake_case_ :Optional[Any] = use_absolute_embeddings snake_case_ :Union[str, Any] = patch_norm snake_case_ :Dict = layer_norm_eps snake_case_ :str = initializer_range snake_case_ :Tuple = is_training snake_case_ :Tuple = scope snake_case_ :Union[str, Any] = use_labels snake_case_ :Optional[Any] = type_sequence_label_size snake_case_ :Dict = encoder_stride def lowerCAmelCase_ ( self: int ) -> int: snake_case_ :List[str] = floats_tensor([self.batch_size, self.num_channels, self.image_size, self.image_size] ) snake_case_ :Any = None if self.use_labels: snake_case_ :str = ids_tensor([self.batch_size] , self.type_sequence_label_size ) snake_case_ :int = self.get_config() return config, pixel_values, labels def lowerCAmelCase_ ( self: str ) -> Union[str, Any]: 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 lowerCAmelCase_ ( self: str , snake_case: Optional[int] , snake_case: Dict , snake_case: str ) -> List[Any]: snake_case_ :Union[str, Any] = SwinvaModel(config=snake_case ) model.to(snake_case ) model.eval() snake_case_ :Optional[int] = model(snake_case ) snake_case_ :Optional[Any] = ((config.image_size // config.patch_size) ** 2) // (4 ** (len(config.depths ) - 1)) snake_case_ :int = 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 lowerCAmelCase_ ( self: int , snake_case: List[str] , snake_case: Tuple , snake_case: int ) -> Any: snake_case_ :Dict = SwinvaForMaskedImageModeling(config=snake_case ) model.to(snake_case ) model.eval() snake_case_ :Tuple = 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_ :List[Any] = 1 snake_case_ :int = SwinvaForMaskedImageModeling(snake_case ) model.to(snake_case ) model.eval() snake_case_ :Union[str, Any] = floats_tensor([self.batch_size, 1, self.image_size, self.image_size] ) snake_case_ :int = model(snake_case ) self.parent.assertEqual(result.logits.shape , (self.batch_size, 1, self.image_size, self.image_size) ) def lowerCAmelCase_ ( self: List[Any] , snake_case: Any , snake_case: List[str] , snake_case: Union[str, Any] ) -> Tuple: snake_case_ :int = self.type_sequence_label_size snake_case_ :List[Any] = SwinvaForImageClassification(snake_case ) model.to(snake_case ) model.eval() snake_case_ :Dict = model(snake_case , labels=snake_case ) self.parent.assertEqual(result.logits.shape , (self.batch_size, self.type_sequence_label_size) ) def lowerCAmelCase_ ( self: int ) -> str: snake_case_ :Any = self.prepare_config_and_inputs() snake_case_, snake_case_, snake_case_ :List[str] = config_and_inputs snake_case_ :List[Any] = {"""pixel_values""": pixel_values} return config, inputs_dict @require_torch class lowerCamelCase ( _lowerCAmelCase , _lowerCAmelCase , unittest.TestCase ): '''simple docstring''' _A : Optional[Any] = ( (SwinvaModel, SwinvaForImageClassification, SwinvaForMaskedImageModeling) if is_torch_available() else () ) _A : Any = ( {"""feature-extraction""": SwinvaModel, """image-classification""": SwinvaForImageClassification} if is_torch_available() else {} ) _A : List[Any] = False _A : List[str] = False _A : Tuple = False _A : List[str] = False def lowerCAmelCase_ ( self: Dict ) -> List[Any]: snake_case_ :Optional[int] = SwinvaModelTester(self ) snake_case_ :List[str] = ConfigTester(self , config_class=snake_case , embed_dim=37 ) def lowerCAmelCase_ ( self: Union[str, Any] ) -> List[Any]: 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 lowerCAmelCase_ ( self: Union[str, Any] ) -> Tuple: snake_case_ :List[str] = 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 lowerCAmelCase_ ( self: Union[str, Any] ) -> str: pass @unittest.skip(reason="""Swinv2 does not use inputs_embeds""" ) def lowerCAmelCase_ ( self: int ) -> Dict: pass def lowerCAmelCase_ ( self: List[str] ) -> Union[str, Any]: snake_case_, snake_case_ :List[str] = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: snake_case_ :Optional[int] = model_class(snake_case ) self.assertIsInstance(model.get_input_embeddings() , (nn.Module) ) snake_case_ :List[Any] = model.get_output_embeddings() self.assertTrue(x is None or isinstance(snake_case , nn.Linear ) ) def lowerCAmelCase_ ( self: Dict ) -> Optional[int]: snake_case_, snake_case_ :Union[str, Any] = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: snake_case_ :Optional[int] = model_class(snake_case ) snake_case_ :List[Any] = inspect.signature(model.forward ) # signature.parameters is an OrderedDict => so arg_names order is deterministic snake_case_ :int = [*signature.parameters.keys()] snake_case_ :List[Any] = ["""pixel_values"""] self.assertListEqual(arg_names[:1] , snake_case ) def lowerCAmelCase_ ( self: List[str] ) -> Optional[Any]: snake_case_, snake_case_ :List[str] = self.model_tester.prepare_config_and_inputs_for_common() snake_case_ :List[str] = True for model_class in self.all_model_classes: snake_case_ :List[Any] = True snake_case_ :Any = False snake_case_ :Optional[int] = True snake_case_ :Tuple = model_class(snake_case ) model.to(snake_case ) model.eval() with torch.no_grad(): snake_case_ :Any = model(**self._prepare_for_class(snake_case , snake_case ) ) snake_case_ :str = outputs.attentions snake_case_ :Dict = 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_ :Union[str, Any] = True snake_case_ :Tuple = config.window_size**2 snake_case_ :Any = model_class(snake_case ) model.to(snake_case ) model.eval() with torch.no_grad(): snake_case_ :Union[str, Any] = model(**self._prepare_for_class(snake_case , snake_case ) ) snake_case_ :int = 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_ :Any = len(snake_case ) # Check attention is always last and order is fine snake_case_ :int = True snake_case_ :Dict = True snake_case_ :Optional[int] = model_class(snake_case ) model.to(snake_case ) model.eval() with torch.no_grad(): snake_case_ :Dict = model(**self._prepare_for_class(snake_case , snake_case ) ) if hasattr(self.model_tester , """num_hidden_states_types""" ): snake_case_ :Any = self.model_tester.num_hidden_states_types else: # also another +1 for reshaped_hidden_states snake_case_ :int = 2 self.assertEqual(out_len + added_hidden_states , len(snake_case ) ) snake_case_ :str = 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 lowerCAmelCase_ ( self: int , snake_case: Dict , snake_case: Dict , snake_case: Optional[Any] , snake_case: Dict ) -> List[str]: snake_case_ :Dict = 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_ :str = outputs.hidden_states snake_case_ :List[Any] = 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_ :List[Any] = ( config.patch_size if isinstance(config.patch_size , collections.abc.Iterable ) else (config.patch_size, config.patch_size) ) snake_case_ :Optional[int] = (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_ :str = outputs.reshaped_hidden_states self.assertEqual(len(snake_case ) , snake_case ) snake_case_, snake_case_, snake_case_, snake_case_ :Any = reshaped_hidden_states[0].shape snake_case_ :int = ( 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 lowerCAmelCase_ ( self: Any ) -> Any: snake_case_, snake_case_ :List[Any] = self.model_tester.prepare_config_and_inputs_for_common() 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) ) for model_class in self.all_model_classes: snake_case_ :Union[str, Any] = 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_ :List[str] = True self.check_hidden_states_output(snake_case , snake_case , snake_case , snake_case ) def lowerCAmelCase_ ( self: Tuple ) -> Any: snake_case_, snake_case_ :Union[str, Any] = self.model_tester.prepare_config_and_inputs_for_common() snake_case_ :Optional[int] = 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_ :Any = image_size[0] + patch_size[0] - (image_size[0] % patch_size[0]) snake_case_ :int = image_size[1] + patch_size[1] - (image_size[1] % patch_size[1]) for model_class in self.all_model_classes: snake_case_ :str = 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_ :Tuple = True self.check_hidden_states_output(snake_case , snake_case , snake_case , (padded_height, padded_width) ) def lowerCAmelCase_ ( self: Any ) -> Tuple: snake_case_ :int = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_for_masked_image_modeling(*snake_case ) def lowerCAmelCase_ ( self: Optional[int] ) -> Dict: snake_case_ :Any = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_for_image_classification(*snake_case ) @slow def lowerCAmelCase_ ( self: List[Any] ) -> Dict: for model_name in SWINV2_PRETRAINED_MODEL_ARCHIVE_LIST[:1]: snake_case_ :List[str] = SwinvaModel.from_pretrained(snake_case ) self.assertIsNotNone(snake_case ) def lowerCAmelCase_ ( self: Optional[int] ) -> List[Any]: snake_case_, snake_case_ :str = self.model_tester.prepare_config_and_inputs_for_common() snake_case_ :Optional[int] = _config_zero_init(snake_case ) for model_class in self.all_model_classes: snake_case_ :Tuple = 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 ): '''simple docstring''' @cached_property def lowerCAmelCase_ ( self: Optional[int] ) -> List[Any]: return ( AutoImageProcessor.from_pretrained("""microsoft/swinv2-tiny-patch4-window8-256""" ) if is_vision_available() else None ) @slow def lowerCAmelCase_ ( self: List[str] ) -> List[str]: snake_case_ :Tuple = SwinvaForImageClassification.from_pretrained("""microsoft/swinv2-tiny-patch4-window8-256""" ).to( snake_case ) snake_case_ :str = self.default_image_processor snake_case_ :List[Any] = Image.open("""./tests/fixtures/tests_samples/COCO/000000039769.png""" ) snake_case_ :str = image_processor(images=snake_case , return_tensors="""pt""" ).to(snake_case ) # forward pass with torch.no_grad(): snake_case_ :Tuple = model(**snake_case ) # verify the logits snake_case_ :Dict = torch.Size((1, 1_000) ) self.assertEqual(outputs.logits.shape , snake_case ) snake_case_ :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 json import os import shutil import tempfile import unittest import numpy as np import pytest from transformers import BertTokenizer, BertTokenizerFast from transformers.models.bert.tokenization_bert import VOCAB_FILES_NAMES from transformers.testing_utils import require_vision from transformers.utils import IMAGE_PROCESSOR_NAME, is_vision_available if is_vision_available(): from PIL import Image from transformers import AlignProcessor, EfficientNetImageProcessor @require_vision class lowerCamelCase ( unittest.TestCase ): '''simple docstring''' def lowerCAmelCase_ ( self: str ) -> str: snake_case_ :Tuple = tempfile.mkdtemp() snake_case_ :Optional[Any] = [ """[UNK]""", """[CLS]""", """[SEP]""", """[PAD]""", """[MASK]""", """want""", """##want""", """##ed""", """wa""", """un""", """runn""", """##ing""", """,""", """low""", """lowest""", ] snake_case_ :int = 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] ) ) snake_case_ :List[str] = { """do_resize""": True, """size""": 20, """do_center_crop""": True, """crop_size""": 18, """do_normalize""": True, """image_mean""": [0.4_8_1_4_5_4_6_6, 0.4_5_7_8_2_7_5, 0.4_0_8_2_1_0_7_3], """image_std""": [0.2_6_8_6_2_9_5_4, 0.2_6_1_3_0_2_5_8, 0.2_7_5_7_7_7_1_1], } snake_case_ :List[str] = os.path.join(self.tmpdirname , snake_case ) with open(self.image_processor_file , """w""" , encoding="""utf-8""" ) as fp: json.dump(snake_case , snake_case ) def lowerCAmelCase_ ( self: Dict , **snake_case: Any ) -> List[Any]: return BertTokenizer.from_pretrained(self.tmpdirname , **snake_case ) def lowerCAmelCase_ ( self: Optional[Any] , **snake_case: List[str] ) -> Union[str, Any]: return BertTokenizerFast.from_pretrained(self.tmpdirname , **snake_case ) def lowerCAmelCase_ ( self: Optional[Any] , **snake_case: Dict ) -> Any: return EfficientNetImageProcessor.from_pretrained(self.tmpdirname , **snake_case ) def lowerCAmelCase_ ( self: List[Any] ) -> Optional[Any]: shutil.rmtree(self.tmpdirname ) def lowerCAmelCase_ ( self: List[Any] ) -> int: snake_case_ :Tuple = [np.random.randint(255 , size=(3, 30, 400) , dtype=np.uinta )] snake_case_ :Dict = [Image.fromarray(np.moveaxis(snake_case , 0 , -1 ) ) for x in image_inputs] return image_inputs def lowerCAmelCase_ ( self: List[Any] ) -> Any: snake_case_ :Optional[Any] = self.get_tokenizer() snake_case_ :Tuple = self.get_rust_tokenizer() snake_case_ :Optional[int] = self.get_image_processor() snake_case_ :List[Any] = AlignProcessor(tokenizer=snake_case , image_processor=snake_case ) processor_slow.save_pretrained(self.tmpdirname ) snake_case_ :Union[str, Any] = AlignProcessor.from_pretrained(self.tmpdirname , use_fast=snake_case ) snake_case_ :int = AlignProcessor(tokenizer=snake_case , image_processor=snake_case ) processor_fast.save_pretrained(self.tmpdirname ) snake_case_ :int = AlignProcessor.from_pretrained(self.tmpdirname ) self.assertEqual(processor_slow.tokenizer.get_vocab() , tokenizer_slow.get_vocab() ) self.assertEqual(processor_fast.tokenizer.get_vocab() , tokenizer_fast.get_vocab() ) self.assertEqual(tokenizer_slow.get_vocab() , tokenizer_fast.get_vocab() ) self.assertIsInstance(processor_slow.tokenizer , snake_case ) self.assertIsInstance(processor_fast.tokenizer , snake_case ) self.assertEqual(processor_slow.image_processor.to_json_string() , image_processor.to_json_string() ) self.assertEqual(processor_fast.image_processor.to_json_string() , image_processor.to_json_string() ) self.assertIsInstance(processor_slow.image_processor , snake_case ) self.assertIsInstance(processor_fast.image_processor , snake_case ) def lowerCAmelCase_ ( self: str ) -> int: snake_case_ :List[str] = AlignProcessor(tokenizer=self.get_tokenizer() , image_processor=self.get_image_processor() ) processor.save_pretrained(self.tmpdirname ) snake_case_ :List[str] = self.get_tokenizer(bos_token="""(BOS)""" , eos_token="""(EOS)""" ) snake_case_ :Optional[Any] = self.get_image_processor(do_normalize=snake_case , padding_value=1.0 ) snake_case_ :int = AlignProcessor.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 lowerCAmelCase_ ( self: Optional[Any] ) -> str: snake_case_ :Tuple = self.get_image_processor() snake_case_ :List[str] = self.get_tokenizer() snake_case_ :int = AlignProcessor(tokenizer=snake_case , image_processor=snake_case ) snake_case_ :Optional[Any] = self.prepare_image_inputs() snake_case_ :Optional[int] = image_processor(snake_case , return_tensors="""np""" ) snake_case_ :Optional[Any] = processor(images=snake_case , return_tensors="""np""" ) for key in input_image_proc.keys(): self.assertAlmostEqual(input_image_proc[key].sum() , input_processor[key].sum() , delta=1E-2 ) def lowerCAmelCase_ ( self: Optional[int] ) -> List[Any]: snake_case_ :List[str] = self.get_image_processor() snake_case_ :List[Any] = self.get_tokenizer() snake_case_ :Dict = AlignProcessor(tokenizer=snake_case , image_processor=snake_case ) snake_case_ :Optional[Any] = """lower newer""" snake_case_ :int = processor(text=snake_case ) snake_case_ :Optional[Any] = tokenizer(snake_case , padding="""max_length""" , max_length=64 ) for key in encoded_tok.keys(): self.assertListEqual(encoded_tok[key] , encoded_processor[key] ) def lowerCAmelCase_ ( self: Dict ) -> Union[str, Any]: snake_case_ :Any = self.get_image_processor() snake_case_ :Optional[int] = self.get_tokenizer() snake_case_ :Union[str, Any] = AlignProcessor(tokenizer=snake_case , image_processor=snake_case ) snake_case_ :Dict = """lower newer""" snake_case_ :Dict = self.prepare_image_inputs() snake_case_ :Dict = processor(text=snake_case , images=snake_case ) self.assertListEqual(list(inputs.keys() ) , ["""input_ids""", """token_type_ids""", """attention_mask""", """pixel_values"""] ) # test if it raises when no input is passed with pytest.raises(snake_case ): processor() def lowerCAmelCase_ ( self: Union[str, Any] ) -> Optional[Any]: snake_case_ :Optional[Any] = self.get_image_processor() snake_case_ :Optional[Any] = self.get_tokenizer() snake_case_ :str = AlignProcessor(tokenizer=snake_case , image_processor=snake_case ) snake_case_ :Optional[int] = [[1, 4, 5, 8, 1, 0, 8], [3, 4, 3, 1, 1, 8, 9]] snake_case_ :int = processor.batch_decode(snake_case ) snake_case_ :List[str] = tokenizer.batch_decode(snake_case ) self.assertListEqual(snake_case , snake_case ) def lowerCAmelCase_ ( self: List[Any] ) -> List[str]: snake_case_ :List[Any] = self.get_image_processor() snake_case_ :str = self.get_tokenizer() snake_case_ :Optional[Any] = AlignProcessor(tokenizer=snake_case , image_processor=snake_case ) snake_case_ :List[Any] = """lower newer""" snake_case_ :Dict = self.prepare_image_inputs() snake_case_ :int = processor(text=snake_case , images=snake_case ) self.assertListEqual(list(inputs.keys() ) , processor.model_input_names )
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"""simple docstring""" import re def A_ ( _lowercase ): '''simple docstring''' snake_case_ :Optional[int] = re.compile( r"""^(?:0|94|\+94|0{2}94)""" r"""7(0|1|2|4|5|6|7|8)""" r"""(-| |)""" r"""\d{7}$""" ) return bool(re.search(_lowercase, _lowercase ) ) if __name__ == "__main__": __a = "0094702343221" print(is_sri_lankan_phone_number(phone))
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"""simple docstring""" import argparse import json import requests import timm import torch from huggingface_hub import hf_hub_download from PIL import Image from transformers import AutoImageProcessor, SwinConfig, SwinForImageClassification def A_ ( _lowercase ): '''simple docstring''' snake_case_ :Any = SwinConfig() snake_case_ :List[str] = swin_name.split("""_""" ) snake_case_ :Optional[Any] = name_split[1] snake_case_ :Union[str, Any] = int(name_split[4] ) snake_case_ :List[Any] = int(name_split[3][-1] ) if model_size == "tiny": snake_case_ :Union[str, Any] = 96 snake_case_ :Dict = (2, 2, 6, 2) snake_case_ :List[str] = (3, 6, 12, 24) elif model_size == "small": snake_case_ :str = 96 snake_case_ :List[str] = (2, 2, 18, 2) snake_case_ :Optional[Any] = (3, 6, 12, 24) elif model_size == "base": snake_case_ :str = 128 snake_case_ :List[Any] = (2, 2, 18, 2) snake_case_ :Union[str, Any] = (4, 8, 16, 32) else: snake_case_ :str = 192 snake_case_ :Union[str, Any] = (2, 2, 18, 2) snake_case_ :Optional[int] = (6, 12, 24, 48) if "in22k" in swin_name: snake_case_ :Union[str, Any] = 21841 else: snake_case_ :List[Any] = 1000 snake_case_ :Any = """huggingface/label-files""" snake_case_ :Dict = """imagenet-1k-id2label.json""" snake_case_ :List[Any] = json.load(open(hf_hub_download(_lowercase, _lowercase, repo_type="""dataset""" ), """r""" ) ) snake_case_ :Optional[int] = {int(_lowercase ): v for k, v in idalabel.items()} snake_case_ :List[Any] = idalabel snake_case_ :Any = {v: k for k, v in idalabel.items()} snake_case_ :List[str] = img_size snake_case_ :Optional[Any] = num_classes snake_case_ :List[Any] = embed_dim snake_case_ :Dict = depths snake_case_ :List[Any] = num_heads snake_case_ :List[str] = window_size return config def A_ ( _lowercase ): '''simple docstring''' if "patch_embed.proj" in name: snake_case_ :Union[str, Any] = name.replace("""patch_embed.proj""", """embeddings.patch_embeddings.projection""" ) if "patch_embed.norm" in name: snake_case_ :Tuple = name.replace("""patch_embed.norm""", """embeddings.norm""" ) if "layers" in name: snake_case_ :List[Any] = """encoder.""" + name if "attn.proj" in name: snake_case_ :Dict = name.replace("""attn.proj""", """attention.output.dense""" ) if "attn" in name: snake_case_ :int = name.replace("""attn""", """attention.self""" ) if "norm1" in name: snake_case_ :Dict = name.replace("""norm1""", """layernorm_before""" ) if "norm2" in name: snake_case_ :Optional[int] = name.replace("""norm2""", """layernorm_after""" ) if "mlp.fc1" in name: snake_case_ :Any = name.replace("""mlp.fc1""", """intermediate.dense""" ) if "mlp.fc2" in name: snake_case_ :List[str] = name.replace("""mlp.fc2""", """output.dense""" ) if name == "norm.weight": snake_case_ :List[str] = """layernorm.weight""" if name == "norm.bias": snake_case_ :Union[str, Any] = """layernorm.bias""" if "head" in name: snake_case_ :Dict = name.replace("""head""", """classifier""" ) else: snake_case_ :Dict = """swin.""" + name return name def A_ ( _lowercase, _lowercase ): '''simple docstring''' for key in orig_state_dict.copy().keys(): snake_case_ :List[Any] = orig_state_dict.pop(_lowercase ) if "mask" in key: continue elif "qkv" in key: snake_case_ :Any = key.split(""".""" ) snake_case_ :int = int(key_split[1] ) snake_case_ :str = int(key_split[3] ) snake_case_ :Dict = model.swin.encoder.layers[layer_num].blocks[block_num].attention.self.all_head_size if "weight" in key: snake_case_ :int = val[:dim, :] snake_case_ :Any = val[ dim : dim * 2, : ] snake_case_ :List[Any] = val[-dim:, :] else: snake_case_ :Any = val[ :dim ] snake_case_ :str = val[ dim : dim * 2 ] snake_case_ :Any = val[ -dim: ] else: snake_case_ :Optional[Any] = val return orig_state_dict def A_ ( _lowercase, _lowercase ): '''simple docstring''' snake_case_ :Optional[int] = timm.create_model(_lowercase, pretrained=_lowercase ) timm_model.eval() snake_case_ :int = get_swin_config(_lowercase ) snake_case_ :Union[str, Any] = SwinForImageClassification(_lowercase ) model.eval() snake_case_ :List[str] = convert_state_dict(timm_model.state_dict(), _lowercase ) model.load_state_dict(_lowercase ) snake_case_ :Tuple = """http://images.cocodataset.org/val2017/000000039769.jpg""" snake_case_ :List[str] = AutoImageProcessor.from_pretrained("""microsoft/{}""".format(swin_name.replace("""_""", """-""" ) ) ) snake_case_ :str = Image.open(requests.get(_lowercase, stream=_lowercase ).raw ) snake_case_ :Optional[int] = image_processor(images=_lowercase, return_tensors="""pt""" ) snake_case_ :List[Any] = timm_model(inputs["""pixel_values"""] ) snake_case_ :List[Any] = model(**_lowercase ).logits assert torch.allclose(_lowercase, _lowercase, atol=1e-3 ) print(f"""Saving model {swin_name} to {pytorch_dump_folder_path}""" ) model.save_pretrained(_lowercase ) print(f"""Saving image processor to {pytorch_dump_folder_path}""" ) image_processor.save_pretrained(_lowercase ) if __name__ == "__main__": __a = argparse.ArgumentParser() # Required parameters parser.add_argument( "--swin_name", default="swin_tiny_patch4_window7_224", type=str, help="Name of the Swin timm model you'd like to convert.", ) parser.add_argument( "--pytorch_dump_folder_path", default=None, type=str, help="Path to the output PyTorch model directory." ) __a = parser.parse_args() convert_swin_checkpoint(args.swin_name, args.pytorch_dump_folder_path)
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"""simple docstring""" import argparse import json import os import pickle import shutil import numpy as np import torch from distiller import Distiller from lm_seqs_dataset import LmSeqsDataset from transformers import ( BertConfig, BertForMaskedLM, BertTokenizer, DistilBertConfig, DistilBertForMaskedLM, DistilBertTokenizer, GPTaConfig, GPTaLMHeadModel, GPTaTokenizer, RobertaConfig, RobertaForMaskedLM, RobertaTokenizer, ) from utils import git_log, init_gpu_params, logger, set_seed __a = { "distilbert": (DistilBertConfig, DistilBertForMaskedLM, DistilBertTokenizer), "roberta": (RobertaConfig, RobertaForMaskedLM, RobertaTokenizer), "bert": (BertConfig, BertForMaskedLM, BertTokenizer), "gpt2": (GPTaConfig, GPTaLMHeadModel, GPTaTokenizer), } def A_ ( _lowercase ): '''simple docstring''' assert (args.mlm and args.alpha_mlm > 0.0) or (not args.mlm and args.alpha_mlm == 0.0) assert (args.alpha_mlm > 0.0 and args.alpha_clm == 0.0) or (args.alpha_mlm == 0.0 and args.alpha_clm > 0.0) if args.mlm: assert os.path.isfile(args.token_counts ) assert (args.student_type in ["roberta", "distilbert"]) and (args.teacher_type in ["roberta", "bert"]) else: assert (args.student_type in ["gpt2"]) and (args.teacher_type in ["gpt2"]) assert args.teacher_type == args.student_type or ( args.student_type == "distilbert" and args.teacher_type == "bert" ) assert os.path.isfile(args.student_config ) if args.student_pretrained_weights is not None: assert os.path.isfile(args.student_pretrained_weights ) if args.freeze_token_type_embds: assert args.student_type in ["roberta"] assert args.alpha_ce >= 0.0 assert args.alpha_mlm >= 0.0 assert args.alpha_clm >= 0.0 assert args.alpha_mse >= 0.0 assert args.alpha_cos >= 0.0 assert args.alpha_ce + args.alpha_mlm + args.alpha_clm + args.alpha_mse + args.alpha_cos > 0.0 def A_ ( _lowercase, _lowercase ): '''simple docstring''' if args.student_type == "roberta": snake_case_ :Tuple = False elif args.student_type == "gpt2": snake_case_ :Union[str, Any] = False def A_ ( _lowercase, _lowercase ): '''simple docstring''' if args.student_type == "roberta": snake_case_ :List[str] = False def A_ ( ): '''simple docstring''' snake_case_ :Union[str, Any] = argparse.ArgumentParser(description="""Training""" ) parser.add_argument("""--force""", action="""store_true""", help="""Overwrite dump_path if it already exists.""" ) parser.add_argument( """--dump_path""", type=_lowercase, required=_lowercase, help="""The output directory (log, checkpoints, parameters, etc.)""" ) parser.add_argument( """--data_file""", type=_lowercase, required=_lowercase, help="""The binarized file (tokenized + tokens_to_ids) and grouped by sequence.""", ) parser.add_argument( """--student_type""", type=_lowercase, choices=["""distilbert""", """roberta""", """gpt2"""], required=_lowercase, help="""The student type (DistilBERT, RoBERTa).""", ) parser.add_argument("""--student_config""", type=_lowercase, required=_lowercase, help="""Path to the student configuration.""" ) parser.add_argument( """--student_pretrained_weights""", default=_lowercase, type=_lowercase, help="""Load student initialization checkpoint.""" ) parser.add_argument( """--teacher_type""", choices=["""bert""", """roberta""", """gpt2"""], required=_lowercase, help="""Teacher type (BERT, RoBERTa).""" ) parser.add_argument("""--teacher_name""", type=_lowercase, required=_lowercase, help="""The teacher model.""" ) parser.add_argument("""--temperature""", default=2.0, type=_lowercase, help="""Temperature for the softmax temperature.""" ) parser.add_argument( """--alpha_ce""", default=0.5, type=_lowercase, help="""Linear weight for the distillation loss. Must be >=0.""" ) parser.add_argument( """--alpha_mlm""", default=0.0, type=_lowercase, help="""Linear weight for the MLM loss. Must be >=0. Should be used in conjunction with `mlm` flag.""", ) parser.add_argument("""--alpha_clm""", default=0.5, type=_lowercase, help="""Linear weight for the CLM loss. Must be >=0.""" ) parser.add_argument("""--alpha_mse""", default=0.0, type=_lowercase, help="""Linear weight of the MSE loss. Must be >=0.""" ) parser.add_argument( """--alpha_cos""", default=0.0, type=_lowercase, help="""Linear weight of the cosine embedding loss. Must be >=0.""" ) parser.add_argument( """--mlm""", action="""store_true""", help="""The LM step: MLM or CLM. If `mlm` is True, the MLM is used over CLM.""" ) parser.add_argument( """--mlm_mask_prop""", default=0.15, type=_lowercase, help="""Proportion of tokens for which we need to make a prediction.""", ) parser.add_argument("""--word_mask""", default=0.8, type=_lowercase, help="""Proportion of tokens to mask out.""" ) parser.add_argument("""--word_keep""", default=0.1, type=_lowercase, help="""Proportion of tokens to keep.""" ) parser.add_argument("""--word_rand""", default=0.1, type=_lowercase, help="""Proportion of tokens to randomly replace.""" ) parser.add_argument( """--mlm_smoothing""", default=0.7, type=_lowercase, help="""Smoothing parameter to emphasize more rare tokens (see XLM, similar to word2vec).""", ) parser.add_argument("""--token_counts""", type=_lowercase, help="""The token counts in the data_file for MLM.""" ) parser.add_argument( """--restrict_ce_to_mask""", action="""store_true""", help="""If true, compute the distillation loss only the [MLM] prediction distribution.""", ) parser.add_argument( """--freeze_pos_embs""", action="""store_true""", help="""Freeze positional embeddings during distillation. For student_type in ['roberta', 'gpt2'] only.""", ) parser.add_argument( """--freeze_token_type_embds""", action="""store_true""", help="""Freeze token type embeddings during distillation if existent. For student_type in ['roberta'] only.""", ) parser.add_argument("""--n_epoch""", type=_lowercase, default=3, help="""Number of pass on the whole dataset.""" ) parser.add_argument("""--batch_size""", type=_lowercase, default=5, help="""Batch size (for each process).""" ) parser.add_argument( """--group_by_size""", action="""store_false""", help="""If true, group sequences that have similar length into the same batch. Default is true.""", ) parser.add_argument( """--gradient_accumulation_steps""", type=_lowercase, default=50, help="""Gradient accumulation for larger training batches.""", ) parser.add_argument("""--warmup_prop""", default=0.05, type=_lowercase, help="""Linear warmup proportion.""" ) parser.add_argument("""--weight_decay""", default=0.0, type=_lowercase, help="""Weight decay if we apply some.""" ) parser.add_argument("""--learning_rate""", default=5e-4, type=_lowercase, help="""The initial learning rate for Adam.""" ) parser.add_argument("""--adam_epsilon""", default=1e-6, type=_lowercase, help="""Epsilon for Adam optimizer.""" ) parser.add_argument("""--max_grad_norm""", default=5.0, type=_lowercase, help="""Max gradient norm.""" ) parser.add_argument("""--initializer_range""", default=0.02, type=_lowercase, help="""Random initialization range.""" ) parser.add_argument( """--fp16""", action="""store_true""", help="""Whether to use 16-bit (mixed) precision (through NVIDIA apex) instead of 32-bit""", ) parser.add_argument( """--fp16_opt_level""", type=_lowercase, default="""O1""", help=( """For fp16: Apex AMP optimization level selected in ['O0', 'O1', 'O2', and 'O3'].""" """See details at https://nvidia.github.io/apex/amp.html""" ), ) parser.add_argument("""--n_gpu""", type=_lowercase, default=1, help="""Number of GPUs in the node.""" ) parser.add_argument("""--local_rank""", type=_lowercase, default=-1, help="""Distributed training - Local rank""" ) parser.add_argument("""--seed""", type=_lowercase, default=56, help="""Random seed""" ) parser.add_argument("""--log_interval""", type=_lowercase, default=500, help="""Tensorboard logging interval.""" ) parser.add_argument("""--checkpoint_interval""", type=_lowercase, default=4000, help="""Checkpoint interval.""" ) snake_case_ :Tuple = parser.parse_args() sanity_checks(_lowercase ) # ARGS # init_gpu_params(_lowercase ) set_seed(_lowercase ) if args.is_master: if os.path.exists(args.dump_path ): if not args.force: raise ValueError( f"""Serialization dir {args.dump_path} already exists, but you have not precised wheter to overwrite""" """ itUse `--force` if you want to overwrite it""" ) else: shutil.rmtree(args.dump_path ) if not os.path.exists(args.dump_path ): os.makedirs(args.dump_path ) logger.info(f"""Experiment will be dumped and logged in {args.dump_path}""" ) # SAVE PARAMS # logger.info(f"""Param: {args}""" ) with open(os.path.join(args.dump_path, """parameters.json""" ), """w""" ) as f: json.dump(vars(_lowercase ), _lowercase, indent=4 ) git_log(args.dump_path ) snake_case_, snake_case_, snake_case_ :Any = MODEL_CLASSES[args.student_type] snake_case_, snake_case_, snake_case_ :int = MODEL_CLASSES[args.teacher_type] # TOKENIZER # snake_case_ :Any = teacher_tokenizer_class.from_pretrained(args.teacher_name ) snake_case_ :Optional[Any] = {} for tok_name, tok_symbol in tokenizer.special_tokens_map.items(): snake_case_ :Union[str, Any] = tokenizer.all_special_tokens.index(_lowercase ) snake_case_ :Union[str, Any] = tokenizer.all_special_ids[idx] logger.info(f"""Special tokens {special_tok_ids}""" ) snake_case_ :str = special_tok_ids snake_case_ :Any = tokenizer.max_model_input_sizes[args.teacher_name] # DATA LOADER # logger.info(f"""Loading data from {args.data_file}""" ) with open(args.data_file, """rb""" ) as fp: snake_case_ :str = pickle.load(_lowercase ) if args.mlm: logger.info(f"""Loading token counts from {args.token_counts} (already pre-computed)""" ) with open(args.token_counts, """rb""" ) as fp: snake_case_ :Optional[Any] = pickle.load(_lowercase ) snake_case_ :Tuple = np.maximum(_lowercase, 1 ) ** -args.mlm_smoothing for idx in special_tok_ids.values(): snake_case_ :Optional[int] = 0.0 # do not predict special tokens snake_case_ :int = torch.from_numpy(_lowercase ) else: snake_case_ :List[str] = None snake_case_ :Optional[int] = LmSeqsDataset(params=_lowercase, data=_lowercase ) logger.info("""Data loader created.""" ) # STUDENT # logger.info(f"""Loading student config from {args.student_config}""" ) snake_case_ :List[Any] = student_config_class.from_pretrained(args.student_config ) snake_case_ :Union[str, Any] = True if args.student_pretrained_weights is not None: logger.info(f"""Loading pretrained weights from {args.student_pretrained_weights}""" ) snake_case_ :List[str] = student_model_class.from_pretrained(args.student_pretrained_weights, config=_lowercase ) else: snake_case_ :Optional[int] = student_model_class(_lowercase ) if args.n_gpu > 0: student.to(f"""cuda:{args.local_rank}""" ) logger.info("""Student loaded.""" ) # TEACHER # snake_case_ :Dict = teacher_model_class.from_pretrained(args.teacher_name, output_hidden_states=_lowercase ) if args.n_gpu > 0: teacher.to(f"""cuda:{args.local_rank}""" ) logger.info(f"""Teacher loaded from {args.teacher_name}.""" ) # FREEZING # if args.freeze_pos_embs: freeze_pos_embeddings(_lowercase, _lowercase ) if args.freeze_token_type_embds: freeze_token_type_embeddings(_lowercase, _lowercase ) # SANITY CHECKS # assert student.config.vocab_size == teacher.config.vocab_size assert student.config.hidden_size == teacher.config.hidden_size assert student.config.max_position_embeddings == teacher.config.max_position_embeddings if args.mlm: assert token_probs.size(0 ) == stu_architecture_config.vocab_size # DISTILLER # torch.cuda.empty_cache() snake_case_ :Optional[int] = Distiller( params=_lowercase, dataset=_lowercase, token_probs=_lowercase, student=_lowercase, teacher=_lowercase ) distiller.train() logger.info("""Let's go get some drinks.""" ) if __name__ == "__main__": main()
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1
"""simple docstring""" from typing import TYPE_CHECKING from ...utils import ( OptionalDependencyNotAvailable, _LazyModule, is_flax_available, is_tensorflow_text_available, is_tf_available, is_tokenizers_available, is_torch_available, ) __a = { "configuration_bert": ["BERT_PRETRAINED_CONFIG_ARCHIVE_MAP", "BertConfig", "BertOnnxConfig"], "tokenization_bert": ["BasicTokenizer", "BertTokenizer", "WordpieceTokenizer"], } try: if not is_tokenizers_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __a = ["BertTokenizerFast"] try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __a = [ "BERT_PRETRAINED_MODEL_ARCHIVE_LIST", "BertForMaskedLM", "BertForMultipleChoice", "BertForNextSentencePrediction", "BertForPreTraining", "BertForQuestionAnswering", "BertForSequenceClassification", "BertForTokenClassification", "BertLayer", "BertLMHeadModel", "BertModel", "BertPreTrainedModel", "load_tf_weights_in_bert", ] try: if not is_tf_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __a = [ "TF_BERT_PRETRAINED_MODEL_ARCHIVE_LIST", "TFBertEmbeddings", "TFBertForMaskedLM", "TFBertForMultipleChoice", "TFBertForNextSentencePrediction", "TFBertForPreTraining", "TFBertForQuestionAnswering", "TFBertForSequenceClassification", "TFBertForTokenClassification", "TFBertLMHeadModel", "TFBertMainLayer", "TFBertModel", "TFBertPreTrainedModel", ] try: if not is_tensorflow_text_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __a = ["TFBertTokenizer"] try: if not is_flax_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __a = [ "FlaxBertForCausalLM", "FlaxBertForMaskedLM", "FlaxBertForMultipleChoice", "FlaxBertForNextSentencePrediction", "FlaxBertForPreTraining", "FlaxBertForQuestionAnswering", "FlaxBertForSequenceClassification", "FlaxBertForTokenClassification", "FlaxBertModel", "FlaxBertPreTrainedModel", ] if TYPE_CHECKING: from .configuration_bert import BERT_PRETRAINED_CONFIG_ARCHIVE_MAP, BertConfig, BertOnnxConfig from .tokenization_bert import BasicTokenizer, BertTokenizer, WordpieceTokenizer try: if not is_tokenizers_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .tokenization_bert_fast import BertTokenizerFast try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_bert import ( BERT_PRETRAINED_MODEL_ARCHIVE_LIST, BertForMaskedLM, BertForMultipleChoice, BertForNextSentencePrediction, BertForPreTraining, BertForQuestionAnswering, BertForSequenceClassification, BertForTokenClassification, BertLayer, BertLMHeadModel, BertModel, BertPreTrainedModel, load_tf_weights_in_bert, ) try: if not is_tf_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_tf_bert import ( TF_BERT_PRETRAINED_MODEL_ARCHIVE_LIST, TFBertEmbeddings, TFBertForMaskedLM, TFBertForMultipleChoice, TFBertForNextSentencePrediction, TFBertForPreTraining, TFBertForQuestionAnswering, TFBertForSequenceClassification, TFBertForTokenClassification, TFBertLMHeadModel, TFBertMainLayer, TFBertModel, TFBertPreTrainedModel, ) try: if not is_tensorflow_text_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .tokenization_bert_tf import TFBertTokenizer try: if not is_flax_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_flax_bert import ( FlaxBertForCausalLM, FlaxBertForMaskedLM, FlaxBertForMultipleChoice, FlaxBertForNextSentencePrediction, FlaxBertForPreTraining, FlaxBertForQuestionAnswering, FlaxBertForSequenceClassification, FlaxBertForTokenClassification, FlaxBertModel, FlaxBertPreTrainedModel, ) else: import sys __a = _LazyModule(__name__, globals()["__file__"], _import_structure, module_spec=__spec__)
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"""simple docstring""" import json import os import subprocess import unittest from ast import literal_eval import pytest from parameterized import parameterized, parameterized_class from . import is_sagemaker_available if is_sagemaker_available(): from sagemaker import Session, TrainingJobAnalytics from sagemaker.huggingface import HuggingFace @pytest.mark.skipif( literal_eval(os.getenv("""TEST_SAGEMAKER""" , """False""" ) ) is not True , reason="""Skipping test because should only be run when releasing minor transformers version""" , ) @pytest.mark.usefixtures("""sm_env""" ) @parameterized_class( [ { """framework""": """pytorch""", """script""": """run_glue_model_parallelism.py""", """model_name_or_path""": """roberta-large""", """instance_type""": """ml.p3dn.24xlarge""", """results""": {"""train_runtime""": 1_6_0_0, """eval_accuracy""": 0.3, """eval_loss""": 1.2}, }, { """framework""": """pytorch""", """script""": """run_glue.py""", """model_name_or_path""": """roberta-large""", """instance_type""": """ml.p3dn.24xlarge""", """results""": {"""train_runtime""": 1_6_0_0, """eval_accuracy""": 0.3, """eval_loss""": 1.2}, }, ] ) class lowerCamelCase ( unittest.TestCase ): '''simple docstring''' def lowerCAmelCase_ ( self: Any ) -> str: if self.framework == "pytorch": subprocess.run( f"""cp ./examples/pytorch/text-classification/run_glue.py {self.env.test_path}/run_glue.py""".split() , encoding="""utf-8""" , check=snake_case , ) assert hasattr(self , """env""" ) def lowerCAmelCase_ ( self: int , snake_case: Dict ) -> List[Any]: # configuration for running training on smdistributed Model Parallel snake_case_ :Tuple = { """enabled""": True, """processes_per_host""": 8, } snake_case_ :List[Any] = { """enabled""": True, """parameters""": { """microbatches""": 4, """placement_strategy""": """spread""", """pipeline""": """interleaved""", """optimize""": """speed""", """partitions""": 4, """ddp""": True, }, } snake_case_ :Tuple = {"""smdistributed""": {"""modelparallel""": smp_options}, """mpi""": mpi_options} snake_case_ :Any = """trainer""" if self.script == """run_glue.py""" else """smtrainer""" # creates estimator return HuggingFace( entry_point=self.script , source_dir=self.env.test_path , role=self.env.role , image_uri=self.env.image_uri , base_job_name=f"""{self.env.base_job_name}-{instance_count}-smp-{name_extension}""" , instance_count=snake_case , instance_type=self.instance_type , debugger_hook_config=snake_case , hyperparameters={ **self.env.hyperparameters, """model_name_or_path""": self.model_name_or_path, """max_steps""": 500, } , metric_definitions=self.env.metric_definitions , distribution=snake_case , py_version="""py36""" , ) def lowerCAmelCase_ ( self: Any , snake_case: Tuple ) -> List[str]: TrainingJobAnalytics(snake_case ).export_csv(f"""{self.env.test_path}/{job_name}_metrics.csv""" ) @parameterized.expand([(1,)] ) def lowerCAmelCase_ ( self: Dict , snake_case: Dict ) -> List[Any]: # create estimator snake_case_ :List[Any] = self.create_estimator(snake_case ) # run training estimator.fit() # result dataframe snake_case_ :Any = TrainingJobAnalytics(estimator.latest_training_job.name ).dataframe() # extract kpis snake_case_ :Tuple = list(result_metrics_df[result_metrics_df.metric_name == """eval_accuracy"""]["""value"""] ) snake_case_ :Dict = list(result_metrics_df[result_metrics_df.metric_name == """eval_loss"""]["""value"""] ) # get train time from SageMaker job, this includes starting, preprocessing, stopping snake_case_ :int = ( Session().describe_training_job(estimator.latest_training_job.name ).get("""TrainingTimeInSeconds""" , 999_999 ) ) # assert kpis assert train_runtime <= self.results["train_runtime"] assert all(t >= self.results["""eval_accuracy"""] for t in eval_accuracy ) assert all(t <= self.results["""eval_loss"""] for t in eval_loss ) # dump tests result into json file to share in PR with open(f"""{estimator.latest_training_job.name}.json""" , """w""" ) as outfile: json.dump({"""train_time""": train_runtime, """eval_accuracy""": eval_accuracy, """eval_loss""": eval_loss} , snake_case )
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1
"""simple docstring""" import argparse import os from pathlib import Path from typing import Dict import tensorflow as tf import torch from tqdm import tqdm from transformers import PegasusConfig, PegasusForConditionalGeneration, PegasusTokenizer from transformers.models.pegasus.configuration_pegasus import DEFAULTS, task_specific_params __a = [ # replace left string with right string to get the relevant state_dict key (identical state dict to bart) ["memory_attention", "encoder_attn"], ["attention", "attn"], ["/", "."], [".LayerNorm.gamma", "_layer_norm.weight"], [".LayerNorm.beta", "_layer_norm.bias"], ["r.layer_", "r.layers."], ["output_proj", "out_proj"], ["ffn.dense_1.", "fc2."], ["ffn.dense.", "fc1."], ["ffn_layer_norm", "final_layer_norm"], ["kernel", "weight"], ["encoder_layer_norm.", "encoder.layer_norm."], ["decoder_layer_norm.", "decoder.layer_norm."], ["embeddings.weights", "shared.weight"], ] def A_ ( _lowercase ): '''simple docstring''' for pegasus_name, hf_name in PATTERNS: snake_case_ :Any = k.replace(_lowercase, _lowercase ) return k def A_ ( _lowercase, _lowercase ): '''simple docstring''' snake_case_ :int = DEFAULTS.copy() cfg_kwargs.update(_lowercase ) snake_case_ :Union[str, Any] = PegasusConfig(**_lowercase ) snake_case_ :List[Any] = PegasusForConditionalGeneration(_lowercase ) snake_case_ :Optional[Any] = torch_model.model.state_dict() snake_case_ :Tuple = {} for k, v in tf_weights.items(): snake_case_ :Optional[Any] = rename_state_dict_key(_lowercase ) if new_k not in sd: raise ValueError(f"""could not find new key {new_k} in state dict. (converted from {k})""" ) if "dense" in k or "proj" in new_k: snake_case_ :int = v.T snake_case_ :Dict = torch.tensor(_lowercase, dtype=sd[new_k].dtype ) assert v.shape == sd[new_k].shape, f"""{new_k}, {k}, {v.shape}, {sd[new_k].shape}""" # make sure embedding.padding_idx is respected snake_case_ :Optional[Any] = torch.zeros_like(mapping["""shared.weight"""][cfg.pad_token_id + 1] ) snake_case_ :Optional[Any] = mapping["""shared.weight"""] snake_case_ :List[str] = mapping["""shared.weight"""] snake_case_ :List[Any] = {k: torch.zeros_like(_lowercase ) for k, v in sd.items() if k.endswith("""bias""" ) and k not in mapping} mapping.update(**_lowercase ) snake_case_, snake_case_ :Optional[int] = torch_model.model.load_state_dict(_lowercase, strict=_lowercase ) snake_case_ :str = [ k for k in missing if k not in ["""encoder.embed_positions.weight""", """decoder.embed_positions.weight"""] ] assert unexpected_missing == [], f"""no matches found for the following torch keys {unexpected_missing}""" assert extra == [], f"""no matches found for the following tf keys {extra}""" return torch_model def A_ ( _lowercase="./ckpt/aeslc/model.ckpt-32000" ): '''simple docstring''' snake_case_ :List[str] = tf.train.list_variables(_lowercase ) snake_case_ :int = {} snake_case_ :Any = ["""Adafactor""", """global_step"""] for name, shape in tqdm(_lowercase, desc="""converting tf checkpoint to dict""" ): snake_case_ :List[Any] = any(pat in name for pat in ignore_name ) if skip_key: continue snake_case_ :Optional[Any] = tf.train.load_variable(_lowercase, _lowercase ) snake_case_ :List[str] = array return tf_weights def A_ ( _lowercase, _lowercase ): '''simple docstring''' snake_case_ :str = Path(_lowercase ).parent.name snake_case_ :int = task_specific_params[f"""summarization_{dataset}"""]["""max_position_embeddings"""] snake_case_ :Optional[int] = PegasusTokenizer.from_pretrained("""sshleifer/pegasus""", model_max_length=_lowercase ) assert tok.model_max_length == desired_max_model_length tok.save_pretrained(_lowercase ) # convert model snake_case_ :List[str] = get_tf_weights_as_numpy(_lowercase ) snake_case_ :Optional[int] = task_specific_params[f"""summarization_{dataset}"""] if dataset == "large": snake_case_ :str = task_specific_params snake_case_ :Dict = convert_pegasus(_lowercase, _lowercase ) torch_model.save_pretrained(_lowercase ) snake_case_ :Optional[int] = torch_model.state_dict() sd.pop("""model.decoder.embed_positions.weight""" ) sd.pop("""model.encoder.embed_positions.weight""" ) torch.save(_lowercase, Path(_lowercase ) / """pytorch_model.bin""" ) if __name__ == "__main__": __a = argparse.ArgumentParser() # Required parameters parser.add_argument("tf_ckpt_path", type=str, help="passed to tf.train.list_variables") parser.add_argument("save_dir", default=None, type=str, help="Path to the output PyTorch model.") __a = parser.parse_args() if args.save_dir is None: __a = Path(args.tf_ckpt_path).parent.name __a = os.path.join("pegasus", dataset) convert_pegasus_ckpt_to_pytorch(args.tf_ckpt_path, args.save_dir)
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"""simple docstring""" import collections import inspect import unittest from typing import Dict, List, Tuple from transformers import MaskFormerSwinConfig from transformers.testing_utils import require_torch, require_torch_multi_gpu, torch_device from transformers.utils import is_torch_available from ...test_backbone_common import BackboneTesterMixin from ...test_configuration_common import ConfigTester from ...test_modeling_common import ModelTesterMixin, floats_tensor, ids_tensor from ...test_pipeline_mixin import PipelineTesterMixin if is_torch_available(): import torch from torch import nn from transformers import MaskFormerSwinBackbone from transformers.models.maskformer import MaskFormerSwinModel class lowerCamelCase : '''simple docstring''' def __init__( self: Dict , snake_case: Optional[Any] , snake_case: Tuple=13 , snake_case: Any=32 , snake_case: Union[str, Any]=2 , snake_case: Tuple=3 , snake_case: Union[str, Any]=16 , snake_case: Union[str, Any]=[1, 2, 1] , snake_case: Optional[Any]=[2, 2, 4] , snake_case: str=2 , snake_case: List[str]=2.0 , snake_case: Optional[int]=True , snake_case: Union[str, Any]=0.0 , snake_case: Optional[int]=0.0 , snake_case: Optional[Any]=0.1 , snake_case: List[str]="gelu" , snake_case: Any=False , snake_case: Optional[Any]=True , snake_case: Optional[int]=0.0_2 , snake_case: Any=1E-5 , snake_case: Optional[int]=True , snake_case: int=None , snake_case: Any=True , snake_case: str=10 , snake_case: Optional[Any]=8 , snake_case: Union[str, Any]=["stage1", "stage2", "stage3"] , snake_case: Tuple=[1, 2, 3] , ) -> Dict: snake_case_ :Dict = parent snake_case_ :List[Any] = batch_size snake_case_ :Dict = image_size snake_case_ :Dict = patch_size snake_case_ :Tuple = num_channels snake_case_ :List[Any] = embed_dim snake_case_ :List[str] = depths snake_case_ :str = num_heads snake_case_ :Tuple = window_size snake_case_ :Tuple = mlp_ratio snake_case_ :int = qkv_bias snake_case_ :Tuple = hidden_dropout_prob snake_case_ :Optional[Any] = attention_probs_dropout_prob snake_case_ :Dict = drop_path_rate snake_case_ :Any = hidden_act snake_case_ :Any = use_absolute_embeddings snake_case_ :int = patch_norm snake_case_ :List[Any] = layer_norm_eps snake_case_ :Tuple = initializer_range snake_case_ :str = is_training snake_case_ :int = scope snake_case_ :Tuple = use_labels snake_case_ :Tuple = type_sequence_label_size snake_case_ :str = encoder_stride snake_case_ :List[Any] = out_features snake_case_ :str = out_indices def lowerCAmelCase_ ( self: Tuple ) -> Dict: snake_case_ :Optional[int] = floats_tensor([self.batch_size, self.num_channels, self.image_size, self.image_size] ) snake_case_ :str = None if self.use_labels: snake_case_ :Optional[int] = ids_tensor([self.batch_size] , self.type_sequence_label_size ) snake_case_ :Union[str, Any] = self.get_config() return config, pixel_values, labels def lowerCAmelCase_ ( self: int ) -> Optional[Any]: return MaskFormerSwinConfig( 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 , out_features=self.out_features , out_indices=self.out_indices , ) def lowerCAmelCase_ ( self: List[Any] , snake_case: str , snake_case: int , snake_case: List[str] ) -> Any: snake_case_ :Dict = MaskFormerSwinModel(config=snake_case ) model.to(snake_case ) model.eval() snake_case_ :Tuple = model(snake_case ) snake_case_ :Dict = ((config.image_size // config.patch_size) ** 2) // (4 ** (len(config.depths ) - 1)) snake_case_ :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 lowerCAmelCase_ ( self: Optional[Any] , snake_case: int , snake_case: List[str] , snake_case: Tuple ) -> Union[str, Any]: snake_case_ :Any = MaskFormerSwinBackbone(config=snake_case ) model.to(snake_case ) model.eval() snake_case_ :Optional[Any] = model(snake_case ) # verify feature maps self.parent.assertEqual(len(result.feature_maps ) , len(config.out_features ) ) self.parent.assertListEqual(list(result.feature_maps[0].shape ) , [13, 16, 16, 16] ) # verify channels self.parent.assertEqual(len(model.channels ) , len(config.out_features ) ) self.parent.assertListEqual(model.channels , [16, 32, 64] ) # verify ValueError with self.parent.assertRaises(snake_case ): snake_case_ :Optional[Any] = ["""stem"""] snake_case_ :str = MaskFormerSwinBackbone(config=snake_case ) def lowerCAmelCase_ ( self: List[str] ) -> Optional[Any]: snake_case_ :Optional[int] = self.prepare_config_and_inputs() snake_case_, snake_case_, snake_case_ :str = config_and_inputs snake_case_ :Tuple = {"""pixel_values""": pixel_values} return config, inputs_dict @require_torch class lowerCamelCase ( _lowerCAmelCase , _lowerCAmelCase , unittest.TestCase ): '''simple docstring''' _A : Union[str, Any] = ( ( MaskFormerSwinModel, MaskFormerSwinBackbone, ) if is_torch_available() else () ) _A : str = {"""feature-extraction""": MaskFormerSwinModel} if is_torch_available() else {} _A : List[str] = False _A : Any = False _A : Dict = False _A : List[Any] = False _A : Optional[int] = False def lowerCAmelCase_ ( self: Dict ) -> Any: snake_case_ :str = MaskFormerSwinModelTester(self ) snake_case_ :Optional[Any] = ConfigTester(self , config_class=snake_case , embed_dim=37 ) @require_torch_multi_gpu @unittest.skip( reason=( """`MaskFormerSwinModel` outputs `hidden_states_spatial_dimensions` which doesn't work well with""" """ `nn.DataParallel`""" ) ) def lowerCAmelCase_ ( self: List[str] ) -> Optional[int]: pass def lowerCAmelCase_ ( self: Union[str, Any] ) -> Dict: self.create_and_test_config_common_properties() 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 lowerCAmelCase_ ( self: Any ) -> Tuple: return def lowerCAmelCase_ ( self: Any ) -> Any: snake_case_ :List[Any] = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_model(*snake_case ) def lowerCAmelCase_ ( self: Union[str, Any] ) -> int: snake_case_ :Any = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_backbone(*snake_case ) @unittest.skip("""Swin does not use inputs_embeds""" ) def lowerCAmelCase_ ( self: str ) -> List[str]: pass @unittest.skip("""Swin does not support feedforward chunking""" ) def lowerCAmelCase_ ( self: int ) -> Optional[int]: pass def lowerCAmelCase_ ( self: List[str] ) -> List[Any]: snake_case_, snake_case_ :List[Any] = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: snake_case_ :str = model_class(snake_case ) self.assertIsInstance(model.get_input_embeddings() , (nn.Module) ) snake_case_ :Dict = model.get_output_embeddings() self.assertTrue(x is None or isinstance(snake_case , nn.Linear ) ) def lowerCAmelCase_ ( self: Tuple ) -> Dict: snake_case_, snake_case_ :int = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: snake_case_ :Optional[int] = model_class(snake_case ) snake_case_ :str = inspect.signature(model.forward ) # signature.parameters is an OrderedDict => so arg_names order is deterministic snake_case_ :str = [*signature.parameters.keys()] snake_case_ :str = ["""pixel_values"""] self.assertListEqual(arg_names[:1] , snake_case ) @unittest.skip(reason="""MaskFormerSwin is only used as backbone and doesn't support output_attentions""" ) def lowerCAmelCase_ ( self: List[Any] ) -> List[Any]: pass @unittest.skip(reason="""MaskFormerSwin is only used as an internal backbone""" ) def lowerCAmelCase_ ( self: Dict ) -> List[Any]: pass def lowerCAmelCase_ ( self: Union[str, Any] , snake_case: Union[str, Any] , snake_case: int , snake_case: Any , snake_case: List[str] ) -> str: snake_case_ :List[str] = 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_ :Any = outputs.hidden_states snake_case_ :Optional[int] = getattr( self.model_tester , """expected_num_hidden_layers""" , len(self.model_tester.depths ) + 1 ) self.assertEqual(len(snake_case ) , snake_case ) # Swin has a different seq_length snake_case_ :str = ( config.patch_size if isinstance(config.patch_size , collections.abc.Iterable ) else (config.patch_size, config.patch_size) ) snake_case_ :int = (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] , ) def lowerCAmelCase_ ( self: List[Any] ) -> Optional[int]: 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_ :Tuple = 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_ :List[Any] = True self.check_hidden_states_output(snake_case , snake_case , snake_case , snake_case ) def lowerCAmelCase_ ( self: Optional[Any] ) -> Tuple: snake_case_, snake_case_ :int = self.model_tester.prepare_config_and_inputs_for_common() snake_case_ :List[Any] = 3 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) ) snake_case_ :Any = ( 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_ :List[str] = image_size[1] + patch_size[1] - (image_size[1] % patch_size[1]) for model_class in self.all_model_classes: snake_case_ :str = 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_ :Any = True self.check_hidden_states_output(snake_case , snake_case , snake_case , (padded_height, padded_width) ) @unittest.skip(reason="""MaskFormerSwin doesn't have pretrained checkpoints""" ) def lowerCAmelCase_ ( self: Union[str, Any] ) -> List[str]: pass @unittest.skip(reason="""This will be fixed once MaskFormerSwin is replaced by native Swin""" ) def lowerCAmelCase_ ( self: List[str] ) -> str: pass @unittest.skip(reason="""This will be fixed once MaskFormerSwin is replaced by native Swin""" ) def lowerCAmelCase_ ( self: str ) -> List[Any]: pass def lowerCAmelCase_ ( self: Union[str, Any] ) -> Optional[Any]: snake_case_, snake_case_ :Dict = self.model_tester.prepare_config_and_inputs_for_common() def set_nan_tensor_to_zero(snake_case: str ): snake_case_ :Optional[int] = 0 return t def check_equivalence(snake_case: List[Any] , snake_case: Union[str, Any] , snake_case: int , snake_case: Tuple={} ): with torch.no_grad(): snake_case_ :List[Any] = model(**snake_case , return_dict=snake_case , **snake_case ) snake_case_ :Any = model(**snake_case , return_dict=snake_case , **snake_case ).to_tuple() def recursive_check(snake_case: List[Any] , snake_case: int ): if isinstance(snake_case , (List, Tuple) ): for tuple_iterable_value, dict_iterable_value in zip(snake_case , snake_case ): recursive_check(snake_case , snake_case ) elif isinstance(snake_case , snake_case ): for tuple_iterable_value, dict_iterable_value in zip( tuple_object.values() , dict_object.values() ): recursive_check(snake_case , snake_case ) elif tuple_object is None: return else: self.assertTrue( torch.allclose( set_nan_tensor_to_zero(snake_case ) , set_nan_tensor_to_zero(snake_case ) , atol=1E-5 ) , msg=( """Tuple and dict output are not equal. Difference:""" f""" {torch.max(torch.abs(tuple_object - dict_object ) )}. Tuple has `nan`:""" f""" {torch.isnan(snake_case ).any()} and `inf`: {torch.isinf(snake_case )}. Dict has""" f""" `nan`: {torch.isnan(snake_case ).any()} and `inf`: {torch.isinf(snake_case )}.""" ) , ) recursive_check(snake_case , snake_case ) for model_class in self.all_model_classes: snake_case_ :int = model_class(snake_case ) model.to(snake_case ) model.eval() snake_case_ :Any = self._prepare_for_class(snake_case , snake_case ) snake_case_ :List[Any] = self._prepare_for_class(snake_case , snake_case ) check_equivalence(snake_case , snake_case , snake_case ) snake_case_ :Tuple = self._prepare_for_class(snake_case , snake_case , return_labels=snake_case ) snake_case_ :Dict = self._prepare_for_class(snake_case , snake_case , return_labels=snake_case ) check_equivalence(snake_case , snake_case , snake_case ) snake_case_ :Tuple = self._prepare_for_class(snake_case , snake_case ) snake_case_ :Any = self._prepare_for_class(snake_case , snake_case ) check_equivalence(snake_case , snake_case , snake_case , {"""output_hidden_states""": True} ) snake_case_ :Dict = self._prepare_for_class(snake_case , snake_case , return_labels=snake_case ) snake_case_ :List[str] = self._prepare_for_class(snake_case , snake_case , return_labels=snake_case ) check_equivalence(snake_case , snake_case , snake_case , {"""output_hidden_states""": True} ) @require_torch class lowerCamelCase ( unittest.TestCase , _lowerCAmelCase ): '''simple docstring''' _A : int = (MaskFormerSwinBackbone,) if is_torch_available() else () _A : Tuple = MaskFormerSwinConfig def lowerCAmelCase_ ( self: List[str] ) -> Optional[int]: snake_case_ :Optional[Any] = MaskFormerSwinModelTester(self ) def lowerCAmelCase_ ( self: int ) -> Optional[int]: snake_case_, snake_case_ :Any = self.model_tester.prepare_config_and_inputs_for_common() snake_case_ :Tuple = inputs_dict["""pixel_values"""].shape[0] for backbone_class in self.all_model_classes: snake_case_ :List[str] = backbone_class(snake_case ) backbone.to(snake_case ) backbone.eval() snake_case_ :List[Any] = backbone(**snake_case ) # Test default outputs and verify feature maps self.assertIsInstance(outputs.feature_maps , snake_case ) self.assertTrue(len(outputs.feature_maps ) == len(backbone.channels ) ) for feature_map, n_channels in zip(outputs.feature_maps , backbone.channels ): self.assertTrue(feature_map.shape[:2] , (batch_size, n_channels) ) self.assertIsNone(outputs.hidden_states ) self.assertIsNone(outputs.attentions ) # Test output_hidden_states=True snake_case_ :Union[str, Any] = backbone(**snake_case , output_hidden_states=snake_case ) self.assertIsNotNone(outputs.hidden_states ) self.assertTrue(len(outputs.hidden_states ) , len(backbone.stage_names ) ) # We skip the stem layer for hidden_states, n_channels in zip(outputs.hidden_states[1:] , backbone.channels ): for hidden_state in hidden_states: # Hidden states are in the format (batch_size, (height * width), n_channels) snake_case_, snake_case_, snake_case_ :List[Any] = hidden_state.shape self.assertTrue((h_batch_size, h_n_channels) , (batch_size, n_channels) ) # Test output_attentions=True if self.has_attentions: snake_case_ :List[Any] = backbone(**snake_case , output_attentions=snake_case ) self.assertIsNotNone(outputs.attentions )
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"""simple docstring""" 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 : '''simple docstring''' def __init__( self: Optional[int] , snake_case: Any , snake_case: Optional[Any]=13 , snake_case: Tuple=32 , snake_case: Optional[int]=2 , snake_case: Tuple=3 , snake_case: Tuple=16 , snake_case: Optional[Any]=[1, 2, 1] , snake_case: Optional[int]=[2, 2, 4] , snake_case: Optional[int]=2 , snake_case: int=2.0 , snake_case: Union[str, Any]=True , snake_case: List[str]=0.0 , snake_case: List[Any]=0.0 , snake_case: Optional[Any]=0.1 , snake_case: List[Any]="gelu" , snake_case: Optional[int]=False , snake_case: Union[str, Any]=True , snake_case: Union[str, Any]=0.0_2 , snake_case: Optional[int]=1E-5 , snake_case: Optional[Any]=True , snake_case: List[Any]=None , snake_case: List[Any]=True , snake_case: Optional[Any]=10 , snake_case: str=8 , ) -> Tuple: snake_case_ :Dict = parent snake_case_ :Any = batch_size snake_case_ :List[Any] = image_size snake_case_ :List[Any] = patch_size snake_case_ :int = num_channels snake_case_ :Tuple = embed_dim snake_case_ :str = depths snake_case_ :str = num_heads snake_case_ :Optional[int] = window_size snake_case_ :Tuple = mlp_ratio snake_case_ :Any = qkv_bias snake_case_ :List[Any] = hidden_dropout_prob snake_case_ :Optional[Any] = attention_probs_dropout_prob snake_case_ :Union[str, Any] = drop_path_rate snake_case_ :Any = hidden_act snake_case_ :Optional[Any] = use_absolute_embeddings snake_case_ :Union[str, Any] = patch_norm snake_case_ :Dict = layer_norm_eps snake_case_ :str = initializer_range snake_case_ :Tuple = is_training snake_case_ :Tuple = scope snake_case_ :Union[str, Any] = use_labels snake_case_ :Optional[Any] = type_sequence_label_size snake_case_ :Dict = encoder_stride def lowerCAmelCase_ ( self: int ) -> int: snake_case_ :List[str] = floats_tensor([self.batch_size, self.num_channels, self.image_size, self.image_size] ) snake_case_ :Any = None if self.use_labels: snake_case_ :str = ids_tensor([self.batch_size] , self.type_sequence_label_size ) snake_case_ :int = self.get_config() return config, pixel_values, labels def lowerCAmelCase_ ( self: str ) -> Union[str, Any]: 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 lowerCAmelCase_ ( self: str , snake_case: Optional[int] , snake_case: Dict , snake_case: str ) -> List[Any]: snake_case_ :Union[str, Any] = SwinvaModel(config=snake_case ) model.to(snake_case ) model.eval() snake_case_ :Optional[int] = model(snake_case ) snake_case_ :Optional[Any] = ((config.image_size // config.patch_size) ** 2) // (4 ** (len(config.depths ) - 1)) snake_case_ :int = 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 lowerCAmelCase_ ( self: int , snake_case: List[str] , snake_case: Tuple , snake_case: int ) -> Any: snake_case_ :Dict = SwinvaForMaskedImageModeling(config=snake_case ) model.to(snake_case ) model.eval() snake_case_ :Tuple = 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_ :List[Any] = 1 snake_case_ :int = SwinvaForMaskedImageModeling(snake_case ) model.to(snake_case ) model.eval() snake_case_ :Union[str, Any] = floats_tensor([self.batch_size, 1, self.image_size, self.image_size] ) snake_case_ :int = model(snake_case ) self.parent.assertEqual(result.logits.shape , (self.batch_size, 1, self.image_size, self.image_size) ) def lowerCAmelCase_ ( self: List[Any] , snake_case: Any , snake_case: List[str] , snake_case: Union[str, Any] ) -> Tuple: snake_case_ :int = self.type_sequence_label_size snake_case_ :List[Any] = SwinvaForImageClassification(snake_case ) model.to(snake_case ) model.eval() snake_case_ :Dict = model(snake_case , labels=snake_case ) self.parent.assertEqual(result.logits.shape , (self.batch_size, self.type_sequence_label_size) ) def lowerCAmelCase_ ( self: int ) -> str: snake_case_ :Any = self.prepare_config_and_inputs() snake_case_, snake_case_, snake_case_ :List[str] = config_and_inputs snake_case_ :List[Any] = {"""pixel_values""": pixel_values} return config, inputs_dict @require_torch class lowerCamelCase ( _lowerCAmelCase , _lowerCAmelCase , unittest.TestCase ): '''simple docstring''' _A : Optional[Any] = ( (SwinvaModel, SwinvaForImageClassification, SwinvaForMaskedImageModeling) if is_torch_available() else () ) _A : Any = ( {"""feature-extraction""": SwinvaModel, """image-classification""": SwinvaForImageClassification} if is_torch_available() else {} ) _A : List[Any] = False _A : List[str] = False _A : Tuple = False _A : List[str] = False def lowerCAmelCase_ ( self: Dict ) -> List[Any]: snake_case_ :Optional[int] = SwinvaModelTester(self ) snake_case_ :List[str] = ConfigTester(self , config_class=snake_case , embed_dim=37 ) def lowerCAmelCase_ ( self: Union[str, Any] ) -> List[Any]: 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 lowerCAmelCase_ ( self: Union[str, Any] ) -> Tuple: snake_case_ :List[str] = 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 lowerCAmelCase_ ( self: Union[str, Any] ) -> str: pass @unittest.skip(reason="""Swinv2 does not use inputs_embeds""" ) def lowerCAmelCase_ ( self: int ) -> Dict: pass def lowerCAmelCase_ ( self: List[str] ) -> Union[str, Any]: snake_case_, snake_case_ :List[str] = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: snake_case_ :Optional[int] = model_class(snake_case ) self.assertIsInstance(model.get_input_embeddings() , (nn.Module) ) snake_case_ :List[Any] = model.get_output_embeddings() self.assertTrue(x is None or isinstance(snake_case , nn.Linear ) ) def lowerCAmelCase_ ( self: Dict ) -> Optional[int]: snake_case_, snake_case_ :Union[str, Any] = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: snake_case_ :Optional[int] = model_class(snake_case ) snake_case_ :List[Any] = inspect.signature(model.forward ) # signature.parameters is an OrderedDict => so arg_names order is deterministic snake_case_ :int = [*signature.parameters.keys()] snake_case_ :List[Any] = ["""pixel_values"""] self.assertListEqual(arg_names[:1] , snake_case ) def lowerCAmelCase_ ( self: List[str] ) -> Optional[Any]: snake_case_, snake_case_ :List[str] = self.model_tester.prepare_config_and_inputs_for_common() snake_case_ :List[str] = True for model_class in self.all_model_classes: snake_case_ :List[Any] = True snake_case_ :Any = False snake_case_ :Optional[int] = True snake_case_ :Tuple = model_class(snake_case ) model.to(snake_case ) model.eval() with torch.no_grad(): snake_case_ :Any = model(**self._prepare_for_class(snake_case , snake_case ) ) snake_case_ :str = outputs.attentions snake_case_ :Dict = 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_ :Union[str, Any] = True snake_case_ :Tuple = config.window_size**2 snake_case_ :Any = model_class(snake_case ) model.to(snake_case ) model.eval() with torch.no_grad(): snake_case_ :Union[str, Any] = model(**self._prepare_for_class(snake_case , snake_case ) ) snake_case_ :int = 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_ :Any = len(snake_case ) # Check attention is always last and order is fine snake_case_ :int = True snake_case_ :Dict = True snake_case_ :Optional[int] = model_class(snake_case ) model.to(snake_case ) model.eval() with torch.no_grad(): snake_case_ :Dict = model(**self._prepare_for_class(snake_case , snake_case ) ) if hasattr(self.model_tester , """num_hidden_states_types""" ): snake_case_ :Any = self.model_tester.num_hidden_states_types else: # also another +1 for reshaped_hidden_states snake_case_ :int = 2 self.assertEqual(out_len + added_hidden_states , len(snake_case ) ) snake_case_ :str = 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 lowerCAmelCase_ ( self: int , snake_case: Dict , snake_case: Dict , snake_case: Optional[Any] , snake_case: Dict ) -> List[str]: snake_case_ :Dict = 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_ :str = outputs.hidden_states snake_case_ :List[Any] = 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_ :List[Any] = ( config.patch_size if isinstance(config.patch_size , collections.abc.Iterable ) else (config.patch_size, config.patch_size) ) snake_case_ :Optional[int] = (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_ :str = outputs.reshaped_hidden_states self.assertEqual(len(snake_case ) , snake_case ) snake_case_, snake_case_, snake_case_, snake_case_ :Any = reshaped_hidden_states[0].shape snake_case_ :int = ( 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 lowerCAmelCase_ ( self: Any ) -> Any: snake_case_, snake_case_ :List[Any] = self.model_tester.prepare_config_and_inputs_for_common() 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) ) for model_class in self.all_model_classes: snake_case_ :Union[str, Any] = 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_ :List[str] = True self.check_hidden_states_output(snake_case , snake_case , snake_case , snake_case ) def lowerCAmelCase_ ( self: Tuple ) -> Any: snake_case_, snake_case_ :Union[str, Any] = self.model_tester.prepare_config_and_inputs_for_common() snake_case_ :Optional[int] = 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_ :Any = image_size[0] + patch_size[0] - (image_size[0] % patch_size[0]) snake_case_ :int = image_size[1] + patch_size[1] - (image_size[1] % patch_size[1]) for model_class in self.all_model_classes: snake_case_ :str = 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_ :Tuple = True self.check_hidden_states_output(snake_case , snake_case , snake_case , (padded_height, padded_width) ) def lowerCAmelCase_ ( self: Any ) -> Tuple: snake_case_ :int = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_for_masked_image_modeling(*snake_case ) def lowerCAmelCase_ ( self: Optional[int] ) -> Dict: snake_case_ :Any = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_for_image_classification(*snake_case ) @slow def lowerCAmelCase_ ( self: List[Any] ) -> Dict: for model_name in SWINV2_PRETRAINED_MODEL_ARCHIVE_LIST[:1]: snake_case_ :List[str] = SwinvaModel.from_pretrained(snake_case ) self.assertIsNotNone(snake_case ) def lowerCAmelCase_ ( self: Optional[int] ) -> List[Any]: snake_case_, snake_case_ :str = self.model_tester.prepare_config_and_inputs_for_common() snake_case_ :Optional[int] = _config_zero_init(snake_case ) for model_class in self.all_model_classes: snake_case_ :Tuple = 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 ): '''simple docstring''' @cached_property def lowerCAmelCase_ ( self: Optional[int] ) -> List[Any]: return ( AutoImageProcessor.from_pretrained("""microsoft/swinv2-tiny-patch4-window8-256""" ) if is_vision_available() else None ) @slow def lowerCAmelCase_ ( self: List[str] ) -> List[str]: snake_case_ :Tuple = SwinvaForImageClassification.from_pretrained("""microsoft/swinv2-tiny-patch4-window8-256""" ).to( snake_case ) snake_case_ :str = self.default_image_processor snake_case_ :List[Any] = Image.open("""./tests/fixtures/tests_samples/COCO/000000039769.png""" ) snake_case_ :str = image_processor(images=snake_case , return_tensors="""pt""" ).to(snake_case ) # forward pass with torch.no_grad(): snake_case_ :Tuple = model(**snake_case ) # verify the logits snake_case_ :Dict = torch.Size((1, 1_000) ) self.assertEqual(outputs.logits.shape , snake_case ) snake_case_ :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 ) )
66
"""simple docstring""" import gc import math import unittest import torch from diffusers import UNetaDModel from diffusers.utils import floats_tensor, logging, slow, torch_all_close, torch_device from diffusers.utils.testing_utils import enable_full_determinism from .test_modeling_common import ModelTesterMixin, UNetTesterMixin __a = logging.get_logger(__name__) enable_full_determinism() class lowerCamelCase ( _lowerCAmelCase , _lowerCAmelCase , unittest.TestCase ): '''simple docstring''' _A : List[Any] = UNetaDModel _A : Union[str, Any] = """sample""" @property def lowerCAmelCase_ ( self: str ) -> Tuple: snake_case_ :List[str] = 4 snake_case_ :Tuple = 3 snake_case_ :Optional[Any] = (32, 32) snake_case_ :str = floats_tensor((batch_size, num_channels) + sizes ).to(snake_case ) snake_case_ :Union[str, Any] = torch.tensor([10] ).to(snake_case ) return {"sample": noise, "timestep": time_step} @property def lowerCAmelCase_ ( self: List[str] ) -> Dict: return (3, 32, 32) @property def lowerCAmelCase_ ( self: Optional[int] ) -> Optional[int]: return (3, 32, 32) def lowerCAmelCase_ ( self: Optional[int] ) -> Dict: snake_case_ :Any = { """block_out_channels""": (32, 64), """down_block_types""": ("""DownBlock2D""", """AttnDownBlock2D"""), """up_block_types""": ("""AttnUpBlock2D""", """UpBlock2D"""), """attention_head_dim""": 3, """out_channels""": 3, """in_channels""": 3, """layers_per_block""": 2, """sample_size""": 32, } snake_case_ :Tuple = self.dummy_input return init_dict, inputs_dict class lowerCamelCase ( _lowerCAmelCase , _lowerCAmelCase , unittest.TestCase ): '''simple docstring''' _A : List[str] = UNetaDModel _A : Union[str, Any] = """sample""" @property def lowerCAmelCase_ ( self: str ) -> str: snake_case_ :List[str] = 4 snake_case_ :Optional[int] = 4 snake_case_ :int = (32, 32) snake_case_ :Any = floats_tensor((batch_size, num_channels) + sizes ).to(snake_case ) snake_case_ :List[Any] = torch.tensor([10] ).to(snake_case ) return {"sample": noise, "timestep": time_step} @property def lowerCAmelCase_ ( self: Optional[int] ) -> Optional[int]: return (4, 32, 32) @property def lowerCAmelCase_ ( self: List[Any] ) -> int: return (4, 32, 32) def lowerCAmelCase_ ( self: Union[str, Any] ) -> List[Any]: snake_case_ :Dict = { """sample_size""": 32, """in_channels""": 4, """out_channels""": 4, """layers_per_block""": 2, """block_out_channels""": (32, 64), """attention_head_dim""": 32, """down_block_types""": ("""DownBlock2D""", """DownBlock2D"""), """up_block_types""": ("""UpBlock2D""", """UpBlock2D"""), } snake_case_ :List[str] = self.dummy_input return init_dict, inputs_dict def lowerCAmelCase_ ( self: Optional[int] ) -> Optional[Any]: snake_case_, snake_case_ :List[str] = UNetaDModel.from_pretrained("""fusing/unet-ldm-dummy-update""" , output_loading_info=snake_case ) self.assertIsNotNone(snake_case ) self.assertEqual(len(loading_info["""missing_keys"""] ) , 0 ) model.to(snake_case ) snake_case_ :List[str] = model(**self.dummy_input ).sample assert image is not None, "Make sure output is not None" @unittest.skipIf(torch_device != """cuda""" , """This test is supposed to run on GPU""" ) def lowerCAmelCase_ ( self: Tuple ) -> Dict: snake_case_, snake_case_ :Union[str, Any] = UNetaDModel.from_pretrained("""fusing/unet-ldm-dummy-update""" , output_loading_info=snake_case ) model.to(snake_case ) snake_case_ :Union[str, Any] = model(**self.dummy_input ).sample assert image is not None, "Make sure output is not None" @unittest.skipIf(torch_device != """cuda""" , """This test is supposed to run on GPU""" ) def lowerCAmelCase_ ( self: str ) -> Any: # by defautl model loading will use accelerate as `low_cpu_mem_usage=True` snake_case_, snake_case_ :List[str] = UNetaDModel.from_pretrained("""fusing/unet-ldm-dummy-update""" , output_loading_info=snake_case ) model_accelerate.to(snake_case ) model_accelerate.eval() snake_case_ :List[Any] = torch.randn( 1 , model_accelerate.config.in_channels , model_accelerate.config.sample_size , model_accelerate.config.sample_size , generator=torch.manual_seed(0 ) , ) snake_case_ :int = noise.to(snake_case ) snake_case_ :str = torch.tensor([10] * noise.shape[0] ).to(snake_case ) snake_case_ :Optional[int] = model_accelerate(snake_case , snake_case )["""sample"""] # two models don't need to stay in the device at the same time del model_accelerate torch.cuda.empty_cache() gc.collect() snake_case_, snake_case_ :str = UNetaDModel.from_pretrained( """fusing/unet-ldm-dummy-update""" , output_loading_info=snake_case , low_cpu_mem_usage=snake_case ) model_normal_load.to(snake_case ) model_normal_load.eval() snake_case_ :int = model_normal_load(snake_case , snake_case )["""sample"""] assert torch_all_close(snake_case , snake_case , rtol=1E-3 ) def lowerCAmelCase_ ( self: Tuple ) -> Any: snake_case_ :Tuple = UNetaDModel.from_pretrained("""fusing/unet-ldm-dummy-update""" ) model.eval() model.to(snake_case ) snake_case_ :Optional[int] = torch.randn( 1 , model.config.in_channels , model.config.sample_size , model.config.sample_size , generator=torch.manual_seed(0 ) , ) snake_case_ :int = noise.to(snake_case ) snake_case_ :List[Any] = torch.tensor([10] * noise.shape[0] ).to(snake_case ) with torch.no_grad(): snake_case_ :Union[str, Any] = model(snake_case , snake_case ).sample snake_case_ :Optional[int] = output[0, -1, -3:, -3:].flatten().cpu() # fmt: off snake_case_ :Dict = torch.tensor([-1_3.3_2_5_8, -2_0.1_1_0_0, -1_5.9_8_7_3, -1_7.6_6_1_7, -2_3.0_5_9_6, -1_7.9_4_1_9, -1_3.3_6_7_5, -1_6.1_8_8_9, -1_2.3_8_0_0] ) # fmt: on self.assertTrue(torch_all_close(snake_case , snake_case , rtol=1E-3 ) ) class lowerCamelCase ( _lowerCAmelCase , _lowerCAmelCase , unittest.TestCase ): '''simple docstring''' _A : List[Any] = UNetaDModel _A : List[Any] = """sample""" @property def lowerCAmelCase_ ( self: Union[str, Any] , snake_case: int=(32, 32) ) -> Tuple: snake_case_ :Union[str, Any] = 4 snake_case_ :Any = 3 snake_case_ :int = floats_tensor((batch_size, num_channels) + sizes ).to(snake_case ) snake_case_ :Any = torch.tensor(batch_size * [10] ).to(dtype=torch.intaa , device=snake_case ) return {"sample": noise, "timestep": time_step} @property def lowerCAmelCase_ ( self: Union[str, Any] ) -> Any: return (3, 32, 32) @property def lowerCAmelCase_ ( self: int ) -> Tuple: return (3, 32, 32) def lowerCAmelCase_ ( self: List[str] ) -> Tuple: snake_case_ :List[Any] = { """block_out_channels""": [32, 64, 64, 64], """in_channels""": 3, """layers_per_block""": 1, """out_channels""": 3, """time_embedding_type""": """fourier""", """norm_eps""": 1E-6, """mid_block_scale_factor""": math.sqrt(2.0 ), """norm_num_groups""": None, """down_block_types""": [ """SkipDownBlock2D""", """AttnSkipDownBlock2D""", """SkipDownBlock2D""", """SkipDownBlock2D""", ], """up_block_types""": [ """SkipUpBlock2D""", """SkipUpBlock2D""", """AttnSkipUpBlock2D""", """SkipUpBlock2D""", ], } snake_case_ :int = self.dummy_input return init_dict, inputs_dict @slow def lowerCAmelCase_ ( self: Optional[Any] ) -> List[Any]: snake_case_, snake_case_ :List[Any] = UNetaDModel.from_pretrained("""google/ncsnpp-celebahq-256""" , output_loading_info=snake_case ) self.assertIsNotNone(snake_case ) self.assertEqual(len(loading_info["""missing_keys"""] ) , 0 ) model.to(snake_case ) snake_case_ :Any = self.dummy_input snake_case_ :int = floats_tensor((4, 3) + (256, 256) ).to(snake_case ) snake_case_ :int = noise snake_case_ :int = model(**snake_case ) assert image is not None, "Make sure output is not None" @slow def lowerCAmelCase_ ( self: str ) -> Dict: snake_case_ :Dict = UNetaDModel.from_pretrained("""google/ncsnpp-celebahq-256""" ) model.to(snake_case ) snake_case_ :List[str] = 4 snake_case_ :Optional[int] = 3 snake_case_ :List[str] = (256, 256) snake_case_ :Tuple = torch.ones((batch_size, num_channels) + sizes ).to(snake_case ) snake_case_ :str = torch.tensor(batch_size * [1E-4] ).to(snake_case ) with torch.no_grad(): snake_case_ :Dict = model(snake_case , snake_case ).sample snake_case_ :int = output[0, -3:, -3:, -1].flatten().cpu() # fmt: off snake_case_ :Optional[Any] = torch.tensor([-4_8_4_2.8_6_9_1, -6_4_9_9.6_6_3_1, -3_8_0_0.1_9_5_3, -7_9_7_8.2_6_8_6, -1_0_9_8_0.7_1_2_9, -2_0_0_2_8.8_5_3_5, 8_1_4_8.2_8_2_2, 2_3_4_2.2_9_0_5, 5_6_7.7_6_0_8] ) # fmt: on self.assertTrue(torch_all_close(snake_case , snake_case , rtol=1E-2 ) ) def lowerCAmelCase_ ( self: List[str] ) -> List[Any]: snake_case_ :Optional[Any] = UNetaDModel.from_pretrained("""fusing/ncsnpp-ffhq-ve-dummy-update""" ) model.to(snake_case ) snake_case_ :Optional[int] = 4 snake_case_ :Optional[Any] = 3 snake_case_ :Optional[Any] = (32, 32) snake_case_ :Dict = torch.ones((batch_size, num_channels) + sizes ).to(snake_case ) snake_case_ :Any = torch.tensor(batch_size * [1E-4] ).to(snake_case ) with torch.no_grad(): snake_case_ :str = model(snake_case , snake_case ).sample snake_case_ :int = output[0, -3:, -3:, -1].flatten().cpu() # fmt: off snake_case_ :int = torch.tensor([-0.0_3_2_5, -0.0_9_0_0, -0.0_8_6_9, -0.0_3_3_2, -0.0_7_2_5, -0.0_2_7_0, -0.0_1_0_1, 0.0_2_2_7, 0.0_2_5_6] ) # fmt: on self.assertTrue(torch_all_close(snake_case , snake_case , rtol=1E-2 ) ) def lowerCAmelCase_ ( self: Dict ) -> Optional[Any]: # not required for this model pass
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"""simple docstring""" 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 __a = logging.get_logger(__name__) # pylint: disable=invalid-name class lowerCamelCase ( _lowerCAmelCase ): '''simple docstring''' def __init__( self: Tuple , snake_case: WhisperForConditionalGeneration , snake_case: WhisperProcessor , snake_case: AutoencoderKL , snake_case: CLIPTextModel , snake_case: CLIPTokenizer , snake_case: UNetaDConditionModel , snake_case: Union[DDIMScheduler, PNDMScheduler, LMSDiscreteScheduler] , snake_case: StableDiffusionSafetyChecker , snake_case: CLIPImageProcessor , ) -> List[Any]: 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 lowerCAmelCase_ ( self: Dict , snake_case: Optional[Union[str, int]] = "auto" ) -> Any: if slice_size == "auto": snake_case_ :Optional[int] = self.unet.config.attention_head_dim // 2 self.unet.set_attention_slice(snake_case ) def lowerCAmelCase_ ( self: Any ) -> Union[str, Any]: self.enable_attention_slicing(snake_case ) @torch.no_grad() def __call__( self: List[str] , snake_case: Dict , snake_case: Tuple=16_000 , snake_case: int = 512 , snake_case: int = 512 , snake_case: int = 50 , snake_case: float = 7.5 , snake_case: Optional[Union[str, List[str]]] = None , snake_case: Optional[int] = 1 , snake_case: float = 0.0 , snake_case: Optional[torch.Generator] = None , snake_case: Optional[torch.FloatTensor] = None , snake_case: Optional[str] = "pil" , snake_case: bool = True , snake_case: Optional[Callable[[int, int, torch.FloatTensor], None]] = None , snake_case: int = 1 , **snake_case: str , ) -> Tuple: snake_case_ :List[Any] = self.speech_processor.feature_extractor( snake_case , return_tensors="""pt""" , sampling_rate=snake_case ).input_features.to(self.device ) snake_case_ :Dict = self.speech_model.generate(snake_case , max_length=480_000 ) snake_case_ :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 ): snake_case_ :Any = 1 elif isinstance(snake_case , snake_case ): snake_case_ :Optional[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 snake_case_ :str = self.tokenizer( snake_case , padding="""max_length""" , max_length=self.tokenizer.model_max_length , return_tensors="""pt""" , ) snake_case_ :int = text_inputs.input_ids if text_input_ids.shape[-1] > self.tokenizer.model_max_length: snake_case_ :str = 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}""" ) snake_case_ :Any = text_input_ids[:, : self.tokenizer.model_max_length] snake_case_ :int = self.text_encoder(text_input_ids.to(self.device ) )[0] # duplicate text embeddings for each generation per prompt, using mps friendly method snake_case_, snake_case_, snake_case_ :Any = text_embeddings.shape snake_case_ :Dict = text_embeddings.repeat(1 , snake_case , 1 ) snake_case_ :int = 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. snake_case_ :Union[str, Any] = guidance_scale > 1.0 # get unconditional embeddings for classifier free guidance if do_classifier_free_guidance: snake_case_ :List[str] if negative_prompt is None: snake_case_ :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 ): snake_case_ :Any = [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: snake_case_ :List[Any] = negative_prompt snake_case_ :List[str] = text_input_ids.shape[-1] snake_case_ :Any = self.tokenizer( snake_case , padding="""max_length""" , max_length=snake_case , truncation=snake_case , return_tensors="""pt""" , ) snake_case_ :int = self.text_encoder(uncond_input.input_ids.to(self.device ) )[0] # duplicate unconditional embeddings for each generation per prompt, using mps friendly method snake_case_ :int = uncond_embeddings.shape[1] snake_case_ :str = uncond_embeddings.repeat(1 , snake_case , 1 ) snake_case_ :Optional[int] = 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 snake_case_ :List[Any] = 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`. snake_case_ :str = (batch_size * num_images_per_prompt, self.unet.config.in_channels, height // 8, width // 8) snake_case_ :Dict = text_embeddings.dtype if latents is None: if self.device.type == "mps": # randn does not exist on mps snake_case_ :str = torch.randn(snake_case , generator=snake_case , device="""cpu""" , dtype=snake_case ).to( self.device ) else: snake_case_ :Union[str, Any] = 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}""" ) snake_case_ :Any = 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 snake_case_ :int = self.scheduler.timesteps.to(self.device ) # scale the initial noise by the standard deviation required by the scheduler snake_case_ :str = 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] snake_case_ :List[str] = """eta""" in set(inspect.signature(self.scheduler.step ).parameters.keys() ) snake_case_ :Union[str, Any] = {} if accepts_eta: snake_case_ :Dict = eta for i, t in enumerate(self.progress_bar(snake_case ) ): # expand the latents if we are doing classifier free guidance snake_case_ :Optional[int] = torch.cat([latents] * 2 ) if do_classifier_free_guidance else latents snake_case_ :List[Any] = self.scheduler.scale_model_input(snake_case , snake_case ) # predict the noise residual snake_case_ :str = self.unet(snake_case , snake_case , encoder_hidden_states=snake_case ).sample # perform guidance if do_classifier_free_guidance: snake_case_, snake_case_ :str = noise_pred.chunk(2 ) snake_case_ :Any = noise_pred_uncond + guidance_scale * (noise_pred_text - noise_pred_uncond) # compute the previous noisy sample x_t -> x_t-1 snake_case_ :Optional[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 ) snake_case_ :Tuple = 1 / 0.1_8_2_1_5 * latents snake_case_ :int = self.vae.decode(snake_case ).sample snake_case_ :Optional[int] = (image / 2 + 0.5).clamp(0 , 1 ) # we always cast to float32 as this does not cause significant overhead and is compatible with bfloat16 snake_case_ :List[Any] = image.cpu().permute(0 , 2 , 3 , 1 ).float().numpy() if output_type == "pil": snake_case_ :Optional[int] = 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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"""simple docstring""" from typing import TYPE_CHECKING from ...utils import OptionalDependencyNotAvailable, _LazyModule, is_torch_available, is_vision_available __a = { "configuration_mask2former": [ "MASK2FORMER_PRETRAINED_CONFIG_ARCHIVE_MAP", "Mask2FormerConfig", ], } try: if not is_vision_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __a = ["Mask2FormerImageProcessor"] try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __a = [ "MASK2FORMER_PRETRAINED_MODEL_ARCHIVE_LIST", "Mask2FormerForUniversalSegmentation", "Mask2FormerModel", "Mask2FormerPreTrainedModel", ] if TYPE_CHECKING: from .configuration_maskaformer import MASK2FORMER_PRETRAINED_CONFIG_ARCHIVE_MAP, MaskaFormerConfig try: if not is_vision_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .image_processing_maskaformer import MaskaFormerImageProcessor try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_maskaformer import ( MASK2FORMER_PRETRAINED_MODEL_ARCHIVE_LIST, MaskaFormerForUniversalSegmentation, MaskaFormerModel, MaskaFormerPreTrainedModel, ) else: import sys __a = _LazyModule(__name__, globals()["__file__"], _import_structure)
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"""simple docstring""" import json import os import tempfile import unittest import unittest.mock as mock from pathlib import Path from requests.exceptions import HTTPError from transformers.utils import ( CONFIG_NAME, FLAX_WEIGHTS_NAME, TF2_WEIGHTS_NAME, TRANSFORMERS_CACHE, WEIGHTS_NAME, cached_file, get_file_from_repo, has_file, ) __a = "hf-internal-testing/tiny-random-bert" __a = os.path.join(TRANSFORMERS_CACHE, "models--hf-internal-testing--tiny-random-bert") __a = "9b8c223d42b2188cb49d29af482996f9d0f3e5a6" class lowerCamelCase ( unittest.TestCase ): '''simple docstring''' def lowerCAmelCase_ ( self: Optional[int] ) -> Tuple: snake_case_ :Tuple = cached_file(snake_case , snake_case ) # Should have downloaded the file in here self.assertTrue(os.path.isdir(snake_case ) ) # Cache should contain at least those three subfolders: for subfolder in ["blobs", "refs", "snapshots"]: self.assertTrue(os.path.isdir(os.path.join(snake_case , snake_case ) ) ) with open(os.path.join(snake_case , """refs""" , """main""" ) ) as f: snake_case_ :List[str] = f.read() self.assertEqual(snake_case , os.path.join(snake_case , """snapshots""" , snake_case , snake_case ) ) self.assertTrue(os.path.isfile(snake_case ) ) # File is cached at the same place the second time. snake_case_ :Tuple = cached_file(snake_case , snake_case ) self.assertEqual(snake_case , snake_case ) # Using a specific revision to test the full commit hash. snake_case_ :List[str] = cached_file(snake_case , snake_case , revision="""9b8c223""" ) self.assertEqual(snake_case , os.path.join(snake_case , """snapshots""" , snake_case , snake_case ) ) def lowerCAmelCase_ ( self: List[str] ) -> List[Any]: with self.assertRaisesRegex(snake_case , """is not a valid model identifier""" ): snake_case_ :int = cached_file("""tiny-random-bert""" , snake_case ) with self.assertRaisesRegex(snake_case , """is not a valid git identifier""" ): snake_case_ :str = cached_file(snake_case , snake_case , revision="""aaaa""" ) with self.assertRaisesRegex(snake_case , """does not appear to have a file named""" ): snake_case_ :Tuple = cached_file(snake_case , """conf""" ) def lowerCAmelCase_ ( self: int ) -> List[str]: with self.assertRaisesRegex(snake_case , """does not appear to have a file named""" ): snake_case_ :Any = cached_file(snake_case , """conf""" ) with open(os.path.join(snake_case , """refs""" , """main""" ) ) as f: snake_case_ :Optional[Any] = f.read() self.assertTrue(os.path.isfile(os.path.join(snake_case , """.no_exist""" , snake_case , """conf""" ) ) ) snake_case_ :List[str] = cached_file(snake_case , """conf""" , _raise_exceptions_for_missing_entries=snake_case ) self.assertIsNone(snake_case ) snake_case_ :int = cached_file(snake_case , """conf""" , local_files_only=snake_case , _raise_exceptions_for_missing_entries=snake_case ) self.assertIsNone(snake_case ) snake_case_ :Optional[int] = mock.Mock() snake_case_ :List[Any] = 500 snake_case_ :List[str] = {} snake_case_ :Dict = HTTPError snake_case_ :Optional[Any] = {} # Under the mock environment we get a 500 error when trying to reach the tokenizer. with mock.patch("""requests.Session.request""" , return_value=snake_case ) as mock_head: snake_case_ :Tuple = cached_file(snake_case , """conf""" , _raise_exceptions_for_connection_errors=snake_case ) self.assertIsNone(snake_case ) # This check we did call the fake head request mock_head.assert_called() def lowerCAmelCase_ ( self: str ) -> Tuple: self.assertTrue(has_file("""hf-internal-testing/tiny-bert-pt-only""" , snake_case ) ) self.assertFalse(has_file("""hf-internal-testing/tiny-bert-pt-only""" , snake_case ) ) self.assertFalse(has_file("""hf-internal-testing/tiny-bert-pt-only""" , snake_case ) ) def lowerCAmelCase_ ( self: List[Any] ) -> List[str]: # `get_file_from_repo` returns None if the file does not exist self.assertIsNone(get_file_from_repo("""bert-base-cased""" , """ahah.txt""" ) ) # The function raises if the repository does not exist. with self.assertRaisesRegex(snake_case , """is not a valid model identifier""" ): get_file_from_repo("""bert-base-case""" , snake_case ) # The function raises if the revision does not exist. with self.assertRaisesRegex(snake_case , """is not a valid git identifier""" ): get_file_from_repo("""bert-base-cased""" , snake_case , revision="""ahaha""" ) snake_case_ :Optional[Any] = get_file_from_repo("""bert-base-cased""" , snake_case ) # The name is the cached name which is not very easy to test, so instead we load the content. snake_case_ :int = json.loads(open(snake_case , """r""" ).read() ) self.assertEqual(config["""hidden_size"""] , 768 ) def lowerCAmelCase_ ( self: List[Any] ) -> str: with tempfile.TemporaryDirectory() as tmp_dir: snake_case_ :Union[str, Any] = Path(snake_case ) / """a.txt""" filename.touch() self.assertEqual(get_file_from_repo(snake_case , """a.txt""" ) , str(snake_case ) ) self.assertIsNone(get_file_from_repo(snake_case , """b.txt""" ) )
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"""simple docstring""" import gc import unittest import numpy as np import torch from transformers import CLIPTextConfig, CLIPTextModel, CLIPTokenizer from diffusers import ( AutoencoderKL, DDIMScheduler, StableDiffusionSAGPipeline, UNetaDConditionModel, ) from diffusers.utils import slow, torch_device from diffusers.utils.testing_utils import enable_full_determinism, require_torch_gpu 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() class lowerCamelCase ( _lowerCAmelCase , _lowerCAmelCase , unittest.TestCase ): '''simple docstring''' _A : str = StableDiffusionSAGPipeline _A : Optional[Any] = TEXT_TO_IMAGE_PARAMS _A : Any = TEXT_TO_IMAGE_BATCH_PARAMS _A : Tuple = TEXT_TO_IMAGE_IMAGE_PARAMS _A : Tuple = TEXT_TO_IMAGE_IMAGE_PARAMS _A : List[str] = False def lowerCAmelCase_ ( self: Optional[Any] ) -> str: torch.manual_seed(0 ) snake_case_ :Any = UNetaDConditionModel( block_out_channels=(32, 64) , layers_per_block=2 , sample_size=32 , in_channels=4 , out_channels=4 , down_block_types=("""DownBlock2D""", """CrossAttnDownBlock2D""") , up_block_types=("""CrossAttnUpBlock2D""", """UpBlock2D""") , cross_attention_dim=32 , ) snake_case_ :Any = DDIMScheduler( beta_start=0.0_0_0_8_5 , beta_end=0.0_1_2 , beta_schedule="""scaled_linear""" , clip_sample=snake_case , set_alpha_to_one=snake_case , ) torch.manual_seed(0 ) snake_case_ :Optional[int] = AutoencoderKL( block_out_channels=[32, 64] , in_channels=3 , out_channels=3 , down_block_types=["""DownEncoderBlock2D""", """DownEncoderBlock2D"""] , up_block_types=["""UpDecoderBlock2D""", """UpDecoderBlock2D"""] , latent_channels=4 , ) torch.manual_seed(0 ) snake_case_ :Union[str, Any] = CLIPTextConfig( bos_token_id=0 , eos_token_id=2 , hidden_size=32 , intermediate_size=37 , layer_norm_eps=1E-05 , num_attention_heads=4 , num_hidden_layers=5 , pad_token_id=1 , vocab_size=1_000 , ) snake_case_ :Tuple = CLIPTextModel(snake_case ) snake_case_ :str = CLIPTokenizer.from_pretrained("""hf-internal-testing/tiny-random-clip""" ) snake_case_ :Dict = { """unet""": unet, """scheduler""": scheduler, """vae""": vae, """text_encoder""": text_encoder, """tokenizer""": tokenizer, """safety_checker""": None, """feature_extractor""": None, } return components def lowerCAmelCase_ ( self: List[str] , snake_case: Tuple , snake_case: List[str]=0 ) -> str: if str(snake_case ).startswith("""mps""" ): snake_case_ :Tuple = torch.manual_seed(snake_case ) else: snake_case_ :Optional[int] = torch.Generator(device=snake_case ).manual_seed(snake_case ) snake_case_ :Any = { """prompt""": """.""", """generator""": generator, """num_inference_steps""": 2, """guidance_scale""": 1.0, """sag_scale""": 1.0, """output_type""": """numpy""", } return inputs def lowerCAmelCase_ ( self: Optional[int] ) -> str: super().test_inference_batch_single_identical(expected_max_diff=3E-3 ) @slow @require_torch_gpu class lowerCamelCase ( unittest.TestCase ): '''simple docstring''' def lowerCAmelCase_ ( self: int ) -> str: # clean up the VRAM after each test super().tearDown() gc.collect() torch.cuda.empty_cache() def lowerCAmelCase_ ( self: int ) -> List[str]: snake_case_ :Any = StableDiffusionSAGPipeline.from_pretrained("""CompVis/stable-diffusion-v1-4""" ) snake_case_ :int = sag_pipe.to(snake_case ) sag_pipe.set_progress_bar_config(disable=snake_case ) snake_case_ :Union[str, Any] = """.""" snake_case_ :str = torch.manual_seed(0 ) snake_case_ :str = sag_pipe( [prompt] , generator=snake_case , guidance_scale=7.5 , sag_scale=1.0 , num_inference_steps=20 , output_type="""np""" ) snake_case_ :List[Any] = output.images snake_case_ :Tuple = image[0, -3:, -3:, -1] assert image.shape == (1, 512, 512, 3) snake_case_ :List[Any] = np.array([0.1_5_6_8, 0.1_7_3_8, 0.1_6_9_5, 0.1_6_9_3, 0.1_5_0_7, 0.1_7_0_5, 0.1_5_4_7, 0.1_7_5_1, 0.1_9_4_9] ) assert np.abs(image_slice.flatten() - expected_slice ).max() < 5E-2 def lowerCAmelCase_ ( self: Dict ) -> str: snake_case_ :Tuple = StableDiffusionSAGPipeline.from_pretrained("""stabilityai/stable-diffusion-2-1-base""" ) snake_case_ :Optional[int] = sag_pipe.to(snake_case ) sag_pipe.set_progress_bar_config(disable=snake_case ) snake_case_ :Tuple = """.""" snake_case_ :Union[str, Any] = torch.manual_seed(0 ) snake_case_ :Tuple = sag_pipe( [prompt] , generator=snake_case , guidance_scale=7.5 , sag_scale=1.0 , num_inference_steps=20 , output_type="""np""" ) snake_case_ :Optional[int] = output.images snake_case_ :Optional[Any] = image[0, -3:, -3:, -1] assert image.shape == (1, 512, 512, 3) snake_case_ :Tuple = np.array([0.3_4_5_9, 0.2_8_7_6, 0.2_5_3_7, 0.3_0_0_2, 0.2_6_7_1, 0.2_1_6_0, 0.3_0_2_6, 0.2_2_6_2, 0.2_3_7_1] ) assert np.abs(image_slice.flatten() - expected_slice ).max() < 5E-2 def lowerCAmelCase_ ( self: List[str] ) -> List[str]: snake_case_ :Optional[int] = StableDiffusionSAGPipeline.from_pretrained("""stabilityai/stable-diffusion-2-1-base""" ) snake_case_ :int = sag_pipe.to(snake_case ) sag_pipe.set_progress_bar_config(disable=snake_case ) snake_case_ :Tuple = """.""" snake_case_ :Optional[int] = torch.manual_seed(0 ) snake_case_ :List[str] = sag_pipe( [prompt] , width=768 , height=512 , generator=snake_case , guidance_scale=7.5 , sag_scale=1.0 , num_inference_steps=20 , output_type="""np""" , ) snake_case_ :Optional[Any] = output.images assert image.shape == (1, 512, 768, 3)
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1
"""simple docstring""" from ...configuration_utils import PretrainedConfig from ...utils import logging __a = logging.get_logger(__name__) __a = { "google/realm-cc-news-pretrained-embedder": ( "https://huggingface.co/google/realm-cc-news-pretrained-embedder/resolve/main/config.json" ), "google/realm-cc-news-pretrained-encoder": ( "https://huggingface.co/google/realm-cc-news-pretrained-encoder/resolve/main/config.json" ), "google/realm-cc-news-pretrained-scorer": ( "https://huggingface.co/google/realm-cc-news-pretrained-scorer/resolve/main/config.json" ), "google/realm-cc-news-pretrained-openqa": ( "https://huggingface.co/google/realm-cc-news-pretrained-openqa/aresolve/main/config.json" ), "google/realm-orqa-nq-openqa": "https://huggingface.co/google/realm-orqa-nq-openqa/resolve/main/config.json", "google/realm-orqa-nq-reader": "https://huggingface.co/google/realm-orqa-nq-reader/resolve/main/config.json", "google/realm-orqa-wq-openqa": "https://huggingface.co/google/realm-orqa-wq-openqa/resolve/main/config.json", "google/realm-orqa-wq-reader": "https://huggingface.co/google/realm-orqa-wq-reader/resolve/main/config.json", # See all REALM models at https://huggingface.co/models?filter=realm } class lowerCamelCase ( _lowerCAmelCase ): '''simple docstring''' _A : str = """realm""" def __init__( self: List[Any] , snake_case: Dict=30_522 , snake_case: Dict=768 , snake_case: Dict=128 , snake_case: int=12 , snake_case: Dict=12 , snake_case: int=8 , snake_case: Union[str, Any]=3_072 , snake_case: List[str]="gelu_new" , snake_case: Optional[int]=0.1 , snake_case: List[str]=0.1 , snake_case: List[str]=512 , snake_case: Optional[Any]=2 , snake_case: Dict=0.0_2 , snake_case: Optional[Any]=1E-12 , snake_case: List[str]=256 , snake_case: int=10 , snake_case: List[Any]=1E-3 , snake_case: Union[str, Any]=5 , snake_case: Tuple=320 , snake_case: int=13_353_718 , snake_case: Tuple=5_000 , snake_case: Optional[int]=1 , snake_case: List[str]=0 , snake_case: Optional[int]=2 , **snake_case: List[Any] , ) -> Any: super().__init__(pad_token_id=snake_case , bos_token_id=snake_case , eos_token_id=snake_case , **snake_case ) # Common config snake_case_ :List[Any] = vocab_size snake_case_ :Tuple = max_position_embeddings snake_case_ :List[str] = hidden_size snake_case_ :Union[str, Any] = retriever_proj_size snake_case_ :Union[str, Any] = num_hidden_layers snake_case_ :Union[str, Any] = num_attention_heads snake_case_ :Optional[Any] = num_candidates snake_case_ :Any = intermediate_size snake_case_ :Union[str, Any] = hidden_act snake_case_ :Optional[int] = hidden_dropout_prob snake_case_ :Dict = attention_probs_dropout_prob snake_case_ :Optional[Any] = initializer_range snake_case_ :Any = type_vocab_size snake_case_ :Dict = layer_norm_eps # Reader config snake_case_ :Optional[Any] = span_hidden_size snake_case_ :Optional[int] = max_span_width snake_case_ :List[str] = reader_layer_norm_eps snake_case_ :List[Any] = reader_beam_size snake_case_ :Union[str, Any] = reader_seq_len # Retrieval config snake_case_ :List[str] = num_block_records snake_case_ :List[Any] = searcher_beam_size
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"""simple docstring""" from __future__ import annotations from collections import Counter from random import random class lowerCamelCase : '''simple docstring''' def __init__( self: Tuple ) -> Optional[Any]: snake_case_ :Optional[int] = {} def lowerCAmelCase_ ( self: Dict , snake_case: str ) -> None: snake_case_ :str = {} def lowerCAmelCase_ ( self: Optional[int] , snake_case: str , snake_case: str , snake_case: float ) -> None: if nodea not in self.connections: self.add_node(snake_case ) if nodea not in self.connections: self.add_node(snake_case ) snake_case_ :Dict = probability def lowerCAmelCase_ ( self: List[Any] ) -> list[str]: return list(self.connections ) def lowerCAmelCase_ ( self: Any , snake_case: str ) -> str: snake_case_ :Optional[Any] = 0 snake_case_ :List[str] = random() for dest in self.connections[node]: current_probability += self.connections[node][dest] if current_probability > random_value: return dest return "" def A_ ( _lowercase, _lowercase, _lowercase ): '''simple docstring''' snake_case_ :List[str] = MarkovChainGraphUndirectedUnweighted() for nodea, nodea, probability in transitions: graph.add_transition_probability(_lowercase, _lowercase, _lowercase ) snake_case_ :int = Counter(graph.get_nodes() ) snake_case_ :Optional[Any] = start for _ in range(_lowercase ): snake_case_ :Tuple = graph.transition(_lowercase ) visited[node] += 1 return visited if __name__ == "__main__": import doctest doctest.testmod()
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1
"""simple docstring""" class lowerCamelCase : '''simple docstring''' def __init__( self: Tuple , snake_case: str = "" , snake_case: bool = False ) -> None: # Mapping from the first character of the prefix of the node snake_case_ :dict[str, RadixNode] = {} # A node will be a leaf if the tree contains its word snake_case_ :Union[str, Any] = is_leaf snake_case_ :Dict = prefix def lowerCAmelCase_ ( self: Dict , snake_case: str ) -> tuple[str, str, str]: snake_case_ :int = 0 for q, w in zip(self.prefix , snake_case ): if q != w: break x += 1 return self.prefix[:x], self.prefix[x:], word[x:] def lowerCAmelCase_ ( self: Optional[Any] , snake_case: list[str] ) -> None: for word in words: self.insert(snake_case ) def lowerCAmelCase_ ( self: List[Any] , snake_case: str ) -> None: # Case 1: If the word is the prefix of the node # Solution: We set the current node as leaf if self.prefix == word: snake_case_ :int = True # Case 2: The node has no edges that have a prefix to the word # Solution: We create an edge from the current node to a new one # containing the word elif word[0] not in self.nodes: snake_case_ :List[Any] = RadixNode(prefix=snake_case , is_leaf=snake_case ) else: snake_case_ :Dict = self.nodes[word[0]] snake_case_, snake_case_, snake_case_ :Optional[int] = incoming_node.match( snake_case ) # Case 3: The node prefix is equal to the matching # Solution: We insert remaining word on the next node if remaining_prefix == "": self.nodes[matching_string[0]].insert(snake_case ) # Case 4: The word is greater equal to the matching # Solution: Create a node in between both nodes, change # prefixes and add the new node for the remaining word else: snake_case_ :Union[str, Any] = remaining_prefix snake_case_ :List[str] = self.nodes[matching_string[0]] snake_case_ :Optional[int] = RadixNode(snake_case , snake_case ) snake_case_ :str = aux_node if remaining_word == "": snake_case_ :Optional[int] = True else: self.nodes[matching_string[0]].insert(snake_case ) def lowerCAmelCase_ ( self: Optional[int] , snake_case: str ) -> bool: snake_case_ :Union[str, Any] = self.nodes.get(word[0] , snake_case ) if not incoming_node: return False else: snake_case_, snake_case_, snake_case_ :int = incoming_node.match( snake_case ) # If there is remaining prefix, the word can't be on the tree if remaining_prefix != "": return False # This applies when the word and the prefix are equal elif remaining_word == "": return incoming_node.is_leaf # We have word remaining so we check the next node else: return incoming_node.find(snake_case ) def lowerCAmelCase_ ( self: int , snake_case: str ) -> bool: snake_case_ :List[str] = self.nodes.get(word[0] , snake_case ) if not incoming_node: return False else: snake_case_, snake_case_, snake_case_ :Any = incoming_node.match( snake_case ) # If there is remaining prefix, the word can't be on the tree if remaining_prefix != "": return False # We have word remaining so we check the next node elif remaining_word != "": return incoming_node.delete(snake_case ) else: # If it is not a leaf, we don't have to delete if not incoming_node.is_leaf: return False else: # We delete the nodes if no edges go from it if len(incoming_node.nodes ) == 0: del self.nodes[word[0]] # We merge the current node with its only child if len(self.nodes ) == 1 and not self.is_leaf: snake_case_ :List[str] = list(self.nodes.values() )[0] snake_case_ :Optional[Any] = merging_node.is_leaf self.prefix += merging_node.prefix snake_case_ :Dict = merging_node.nodes # If there is more than 1 edge, we just mark it as non-leaf elif len(incoming_node.nodes ) > 1: snake_case_ :List[str] = False # If there is 1 edge, we merge it with its child else: snake_case_ :Optional[Any] = list(incoming_node.nodes.values() )[0] snake_case_ :Optional[Any] = merging_node.is_leaf incoming_node.prefix += merging_node.prefix snake_case_ :List[str] = merging_node.nodes return True def lowerCAmelCase_ ( self: str , snake_case: int = 0 ) -> None: if self.prefix != "": print("""-""" * height , self.prefix , """ (leaf)""" if self.is_leaf else """""" ) for value in self.nodes.values(): value.print_tree(height + 1 ) def A_ ( ): '''simple docstring''' snake_case_ :Any = """banana bananas bandana band apple all beast""".split() snake_case_ :List[Any] = RadixNode() root.insert_many(_lowercase ) assert all(root.find(_lowercase ) for word in words ) assert not root.find("""bandanas""" ) assert not root.find("""apps""" ) root.delete("""all""" ) assert not root.find("""all""" ) root.delete("""banana""" ) assert not root.find("""banana""" ) assert root.find("""bananas""" ) return True def A_ ( ): '''simple docstring''' assert test_trie() def A_ ( ): '''simple docstring''' snake_case_ :Dict = RadixNode() snake_case_ :Dict = """banana bananas bandanas bandana band apple all beast""".split() root.insert_many(_lowercase ) print("""Words:""", _lowercase ) print("""Tree:""" ) root.print_tree() if __name__ == "__main__": main()
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"""simple docstring""" import argparse import collections import os import re import tempfile import pandas as pd from datasets import Dataset from huggingface_hub import hf_hub_download, upload_folder from transformers.utils import direct_transformers_import # All paths are set with the intent you should run this script from the root of the repo with the command # python utils/update_metadata.py __a = "src/transformers" # This is to make sure the transformers module imported is the one in the repo. __a = direct_transformers_import(TRANSFORMERS_PATH) # Regexes that match TF/Flax/PT model names. __a = re.compile(r"TF(.*)(?:Model|Encoder|Decoder|ForConditionalGeneration)") __a = re.compile(r"Flax(.*)(?:Model|Encoder|Decoder|ForConditionalGeneration)") # Will match any TF or Flax model too so need to be in an else branch afterthe two previous regexes. __a = re.compile(r"(.*)(?:Model|Encoder|Decoder|ForConditionalGeneration)") # Fill this with tuples (pipeline_tag, model_mapping, auto_model) __a = [ ("pretraining", "MODEL_FOR_PRETRAINING_MAPPING_NAMES", "AutoModelForPreTraining"), ("feature-extraction", "MODEL_MAPPING_NAMES", "AutoModel"), ("audio-classification", "MODEL_FOR_AUDIO_CLASSIFICATION_MAPPING_NAMES", "AutoModelForAudioClassification"), ("text-generation", "MODEL_FOR_CAUSAL_LM_MAPPING_NAMES", "AutoModelForCausalLM"), ("automatic-speech-recognition", "MODEL_FOR_CTC_MAPPING_NAMES", "AutoModelForCTC"), ("image-classification", "MODEL_FOR_IMAGE_CLASSIFICATION_MAPPING_NAMES", "AutoModelForImageClassification"), ("image-segmentation", "MODEL_FOR_IMAGE_SEGMENTATION_MAPPING_NAMES", "AutoModelForImageSegmentation"), ("fill-mask", "MODEL_FOR_MASKED_LM_MAPPING_NAMES", "AutoModelForMaskedLM"), ("object-detection", "MODEL_FOR_OBJECT_DETECTION_MAPPING_NAMES", "AutoModelForObjectDetection"), ( "zero-shot-object-detection", "MODEL_FOR_ZERO_SHOT_OBJECT_DETECTION_MAPPING_NAMES", "AutoModelForZeroShotObjectDetection", ), ("question-answering", "MODEL_FOR_QUESTION_ANSWERING_MAPPING_NAMES", "AutoModelForQuestionAnswering"), ("text2text-generation", "MODEL_FOR_SEQ_TO_SEQ_CAUSAL_LM_MAPPING_NAMES", "AutoModelForSeq2SeqLM"), ("text-classification", "MODEL_FOR_SEQUENCE_CLASSIFICATION_MAPPING_NAMES", "AutoModelForSequenceClassification"), ("automatic-speech-recognition", "MODEL_FOR_SPEECH_SEQ_2_SEQ_MAPPING_NAMES", "AutoModelForSpeechSeq2Seq"), ( "table-question-answering", "MODEL_FOR_TABLE_QUESTION_ANSWERING_MAPPING_NAMES", "AutoModelForTableQuestionAnswering", ), ("token-classification", "MODEL_FOR_TOKEN_CLASSIFICATION_MAPPING_NAMES", "AutoModelForTokenClassification"), ("multiple-choice", "MODEL_FOR_MULTIPLE_CHOICE_MAPPING_NAMES", "AutoModelForMultipleChoice"), ( "next-sentence-prediction", "MODEL_FOR_NEXT_SENTENCE_PREDICTION_MAPPING_NAMES", "AutoModelForNextSentencePrediction", ), ( "audio-frame-classification", "MODEL_FOR_AUDIO_FRAME_CLASSIFICATION_MAPPING_NAMES", "AutoModelForAudioFrameClassification", ), ("audio-xvector", "MODEL_FOR_AUDIO_XVECTOR_MAPPING_NAMES", "AutoModelForAudioXVector"), ( "document-question-answering", "MODEL_FOR_DOCUMENT_QUESTION_ANSWERING_MAPPING_NAMES", "AutoModelForDocumentQuestionAnswering", ), ( "visual-question-answering", "MODEL_FOR_VISUAL_QUESTION_ANSWERING_MAPPING_NAMES", "AutoModelForVisualQuestionAnswering", ), ("image-to-text", "MODEL_FOR_FOR_VISION_2_SEQ_MAPPING_NAMES", "AutoModelForVision2Seq"), ( "zero-shot-image-classification", "MODEL_FOR_ZERO_SHOT_IMAGE_CLASSIFICATION_MAPPING_NAMES", "AutoModelForZeroShotImageClassification", ), ("depth-estimation", "MODEL_FOR_DEPTH_ESTIMATION_MAPPING_NAMES", "AutoModelForDepthEstimation"), ("video-classification", "MODEL_FOR_VIDEO_CLASSIFICATION_MAPPING_NAMES", "AutoModelForVideoClassification"), ("mask-generation", "MODEL_FOR_MASK_GENERATION_MAPPING_NAMES", "AutoModelForMaskGeneration"), ] def A_ ( _lowercase ): '''simple docstring''' snake_case_ :Any = re.finditer(""".+?(?:(?<=[a-z])(?=[A-Z])|(?<=[A-Z])(?=[A-Z][a-z])|$)""", _lowercase ) return [m.group(0 ) for m in matches] def A_ ( ): '''simple docstring''' snake_case_ :int = transformers_module.models.auto.configuration_auto.CONFIG_MAPPING_NAMES snake_case_ :Dict = { config.replace("""Config""", """""" ): model_type for model_type, config in config_maping_names.items() } # Dictionaries flagging if each model prefix has a backend in PT/TF/Flax. snake_case_ :Optional[Any] = collections.defaultdict(_lowercase ) snake_case_ :int = collections.defaultdict(_lowercase ) snake_case_ :List[str] = collections.defaultdict(_lowercase ) # Let's lookup through all transformers object (once) and find if models are supported by a given backend. for attr_name in dir(_lowercase ): snake_case_ :int = None if _re_tf_models.match(_lowercase ) is not None: snake_case_ :int = tf_models snake_case_ :List[str] = _re_tf_models.match(_lowercase ).groups()[0] elif _re_flax_models.match(_lowercase ) is not None: snake_case_ :List[Any] = flax_models snake_case_ :Any = _re_flax_models.match(_lowercase ).groups()[0] elif _re_pt_models.match(_lowercase ) is not None: snake_case_ :Optional[Any] = pt_models snake_case_ :int = _re_pt_models.match(_lowercase ).groups()[0] if lookup_dict is not None: while len(_lowercase ) > 0: if attr_name in model_prefix_to_model_type: snake_case_ :Optional[int] = True break # Try again after removing the last word in the name snake_case_ :Optional[Any] = """""".join(camel_case_split(_lowercase )[:-1] ) snake_case_ :Optional[int] = set(list(pt_models.keys() ) + list(tf_models.keys() ) + list(flax_models.keys() ) ) snake_case_ :Optional[Any] = list(_lowercase ) all_models.sort() snake_case_ :Optional[int] = {"""model_type""": all_models} snake_case_ :Optional[int] = [pt_models[t] for t in all_models] snake_case_ :Any = [tf_models[t] for t in all_models] snake_case_ :Dict = [flax_models[t] for t in all_models] # Now let's use the auto-mapping names to make sure snake_case_ :Dict = {} for t in all_models: if t in transformers_module.models.auto.processing_auto.PROCESSOR_MAPPING_NAMES: snake_case_ :Optional[Any] = """AutoProcessor""" elif t in transformers_module.models.auto.tokenization_auto.TOKENIZER_MAPPING_NAMES: snake_case_ :Tuple = """AutoTokenizer""" elif t in transformers_module.models.auto.feature_extraction_auto.FEATURE_EXTRACTOR_MAPPING_NAMES: snake_case_ :Tuple = """AutoFeatureExtractor""" else: # Default to AutoTokenizer if a model has nothing, for backward compatibility. snake_case_ :str = """AutoTokenizer""" snake_case_ :int = [processors[t] for t in all_models] return pd.DataFrame(_lowercase ) def A_ ( _lowercase ): '''simple docstring''' snake_case_ :List[Any] = [ transformers_module.models.auto.modeling_auto, transformers_module.models.auto.modeling_tf_auto, transformers_module.models.auto.modeling_flax_auto, ] for pipeline_tag, model_mapping, auto_class in PIPELINE_TAGS_AND_AUTO_MODELS: snake_case_ :Optional[int] = [model_mapping, f"""TF_{model_mapping}""", f"""FLAX_{model_mapping}"""] snake_case_ :List[str] = [auto_class, f"""TF_{auto_class}""", f"""Flax_{auto_class}"""] # Loop through all three frameworks for module, cls, mapping in zip(_lowercase, _lowercase, _lowercase ): # The type of pipeline may not exist in this framework if not hasattr(_lowercase, _lowercase ): continue # First extract all model_names snake_case_ :Tuple = [] for name in getattr(_lowercase, _lowercase ).values(): if isinstance(_lowercase, _lowercase ): model_names.append(_lowercase ) else: model_names.extend(list(_lowercase ) ) # Add pipeline tag and auto model class for those models table.update({model_name: (pipeline_tag, cls) for model_name in model_names} ) return table def A_ ( _lowercase, _lowercase ): '''simple docstring''' snake_case_ :List[Any] = get_frameworks_table() snake_case_ :str = Dataset.from_pandas(_lowercase ) snake_case_ :List[Any] = hf_hub_download( """huggingface/transformers-metadata""", """pipeline_tags.json""", repo_type="""dataset""", token=_lowercase ) snake_case_ :List[str] = Dataset.from_json(_lowercase ) snake_case_ :int = { tags_dataset[i]["""model_class"""]: (tags_dataset[i]["""pipeline_tag"""], tags_dataset[i]["""auto_class"""]) for i in range(len(_lowercase ) ) } snake_case_ :Optional[int] = update_pipeline_and_auto_class_table(_lowercase ) # Sort the model classes to avoid some nondeterministic updates to create false update commits. snake_case_ :Tuple = sorted(table.keys() ) snake_case_ :Tuple = pd.DataFrame( { """model_class""": model_classes, """pipeline_tag""": [table[m][0] for m in model_classes], """auto_class""": [table[m][1] for m in model_classes], } ) snake_case_ :Union[str, Any] = Dataset.from_pandas(_lowercase ) with tempfile.TemporaryDirectory() as tmp_dir: frameworks_dataset.to_json(os.path.join(_lowercase, """frameworks.json""" ) ) tags_dataset.to_json(os.path.join(_lowercase, """pipeline_tags.json""" ) ) if commit_sha is not None: snake_case_ :Union[str, Any] = ( f"""Update with commit {commit_sha}\n\nSee: """ f"""https://github.com/huggingface/transformers/commit/{commit_sha}""" ) else: snake_case_ :List[Any] = """Update""" upload_folder( repo_id="""huggingface/transformers-metadata""", folder_path=_lowercase, repo_type="""dataset""", token=_lowercase, commit_message=_lowercase, ) def A_ ( ): '''simple docstring''' snake_case_ :List[Any] = {tag: cls for tag, _, cls in PIPELINE_TAGS_AND_AUTO_MODELS} snake_case_ :Dict = transformers_module.pipelines.SUPPORTED_TASKS snake_case_ :List[str] = [] for key in pipeline_tasks: if key not in in_table: snake_case_ :int = pipeline_tasks[key]["""pt"""] if isinstance(_lowercase, (list, tuple) ): snake_case_ :Any = model[0] snake_case_ :str = model.__name__ if model not in in_table.values(): missing.append(_lowercase ) if len(_lowercase ) > 0: snake_case_ :Optional[int] = """, """.join(_lowercase ) raise ValueError( """The following pipeline tags are not present in the `PIPELINE_TAGS_AND_AUTO_MODELS` constant inside """ f"""`utils/update_metadata.py`: {msg}. Please add them!""" ) if __name__ == "__main__": __a = argparse.ArgumentParser() parser.add_argument("--token", type=str, help="The token to use to push to the transformers-metadata dataset.") parser.add_argument("--commit_sha", type=str, help="The sha of the commit going with this update.") parser.add_argument("--check-only", action="store_true", help="Activate to just check all pipelines are present.") __a = parser.parse_args() if args.check_only: check_pipeline_tags() else: update_metadata(args.token, args.commit_sha)
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"""simple docstring""" from typing import TYPE_CHECKING from ...utils import OptionalDependencyNotAvailable, _LazyModule, is_flax_available, is_torch_available __a = { "configuration_longt5": ["LONGT5_PRETRAINED_CONFIG_ARCHIVE_MAP", "LongT5Config", "LongT5OnnxConfig"], } try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __a = [ "LONGT5_PRETRAINED_MODEL_ARCHIVE_LIST", "LongT5EncoderModel", "LongT5ForConditionalGeneration", "LongT5Model", "LongT5PreTrainedModel", ] try: if not is_flax_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __a = [ "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 = _LazyModule(__name__, globals()["__file__"], _import_structure, module_spec=__spec__)
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"""simple docstring""" import argparse import glob import logging import os from argparse import Namespace from importlib import import_module import numpy as np import torch from lightning_base import BaseTransformer, add_generic_args, generic_train from seqeval.metrics import accuracy_score, fa_score, precision_score, recall_score from torch.nn import CrossEntropyLoss from torch.utils.data import DataLoader, TensorDataset from utils_ner import TokenClassificationTask __a = logging.getLogger(__name__) class lowerCamelCase ( _lowerCAmelCase ): '''simple docstring''' _A : Union[str, Any] = """token-classification""" def __init__( self: Any , snake_case: Tuple ) -> List[Any]: if type(snake_case ) == dict: snake_case_ :Optional[int] = Namespace(**snake_case ) snake_case_ :Optional[int] = import_module("""tasks""" ) try: snake_case_ :Any = getattr(snake_case , hparams.task_type ) snake_case_ :TokenClassificationTask = token_classification_task_clazz() except AttributeError: raise ValueError( f"""Task {hparams.task_type} needs to be defined as a TokenClassificationTask subclass in {module}. """ f"""Available tasks classes are: {TokenClassificationTask.__subclasses__()}""" ) snake_case_ :Any = self.token_classification_task.get_labels(hparams.labels ) snake_case_ :str = CrossEntropyLoss().ignore_index super().__init__(snake_case , len(self.labels ) , self.mode ) def lowerCAmelCase_ ( self: Dict , **snake_case: List[Any] ) -> Any: return self.model(**snake_case ) def lowerCAmelCase_ ( self: str , snake_case: Tuple , snake_case: List[Any] ) -> Optional[int]: snake_case_ :List[str] = {"""input_ids""": batch[0], """attention_mask""": batch[1], """labels""": batch[3]} if self.config.model_type != "distilbert": snake_case_ :List[str] = ( batch[2] if self.config.model_type in ["""bert""", """xlnet"""] else None ) # XLM and RoBERTa don"t use token_type_ids snake_case_ :Optional[Any] = self(**snake_case ) snake_case_ :List[str] = outputs[0] # tensorboard_logs = {"loss": loss, "rate": self.lr_scheduler.get_last_lr()[-1]} return {"loss": loss} def lowerCAmelCase_ ( self: int ) -> Dict: snake_case_ :List[Any] = self.hparams for mode in ["train", "dev", "test"]: snake_case_ :Optional[int] = self._feature_file(snake_case ) if os.path.exists(snake_case ) and not args.overwrite_cache: logger.info("""Loading features from cached file %s""" , snake_case ) snake_case_ :Optional[int] = torch.load(snake_case ) else: logger.info("""Creating features from dataset file at %s""" , args.data_dir ) snake_case_ :Optional[int] = self.token_classification_task.read_examples_from_file(args.data_dir , snake_case ) snake_case_ :Any = self.token_classification_task.convert_examples_to_features( snake_case , self.labels , args.max_seq_length , self.tokenizer , cls_token_at_end=bool(self.config.model_type in ["""xlnet"""] ) , cls_token=self.tokenizer.cls_token , cls_token_segment_id=2 if self.config.model_type in ["""xlnet"""] else 0 , sep_token=self.tokenizer.sep_token , sep_token_extra=snake_case , pad_on_left=bool(self.config.model_type in ["""xlnet"""] ) , pad_token=self.tokenizer.pad_token_id , pad_token_segment_id=self.tokenizer.pad_token_type_id , pad_token_label_id=self.pad_token_label_id , ) logger.info("""Saving features into cached file %s""" , snake_case ) torch.save(snake_case , snake_case ) def lowerCAmelCase_ ( self: Optional[int] , snake_case: int , snake_case: int , snake_case: bool = False ) -> DataLoader: snake_case_ :int = self._feature_file(snake_case ) logger.info("""Loading features from cached file %s""" , snake_case ) snake_case_ :str = torch.load(snake_case ) snake_case_ :Dict = torch.tensor([f.input_ids for f in features] , dtype=torch.long ) snake_case_ :str = torch.tensor([f.attention_mask for f in features] , dtype=torch.long ) if features[0].token_type_ids is not None: snake_case_ :List[Any] = torch.tensor([f.token_type_ids for f in features] , dtype=torch.long ) else: snake_case_ :List[str] = torch.tensor([0 for f in features] , dtype=torch.long ) # HACK(we will not use this anymore soon) snake_case_ :Any = torch.tensor([f.label_ids for f in features] , dtype=torch.long ) return DataLoader( TensorDataset(snake_case , snake_case , snake_case , snake_case ) , batch_size=snake_case ) def lowerCAmelCase_ ( self: List[str] , snake_case: Dict , snake_case: Union[str, Any] ) -> List[str]: """Compute validation""" "" snake_case_ :List[str] = {"""input_ids""": batch[0], """attention_mask""": batch[1], """labels""": batch[3]} if self.config.model_type != "distilbert": snake_case_ :Dict = ( batch[2] if self.config.model_type in ["""bert""", """xlnet"""] else None ) # XLM and RoBERTa don"t use token_type_ids snake_case_ :Dict = self(**snake_case ) snake_case_, snake_case_ :Dict = outputs[:2] snake_case_ :Union[str, Any] = logits.detach().cpu().numpy() snake_case_ :List[Any] = inputs["""labels"""].detach().cpu().numpy() return {"val_loss": tmp_eval_loss.detach().cpu(), "pred": preds, "target": out_label_ids} def lowerCAmelCase_ ( self: List[Any] , snake_case: int ) -> Tuple: snake_case_ :Union[str, Any] = torch.stack([x["""val_loss"""] for x in outputs] ).mean() snake_case_ :Tuple = np.concatenate([x["""pred"""] for x in outputs] , axis=0 ) snake_case_ :Tuple = np.argmax(snake_case , axis=2 ) snake_case_ :List[str] = np.concatenate([x["""target"""] for x in outputs] , axis=0 ) snake_case_ :Optional[Any] = dict(enumerate(self.labels ) ) snake_case_ :Dict = [[] for _ in range(out_label_ids.shape[0] )] snake_case_ :Dict = [[] for _ in range(out_label_ids.shape[0] )] for i in range(out_label_ids.shape[0] ): for j in range(out_label_ids.shape[1] ): if out_label_ids[i, j] != self.pad_token_label_id: out_label_list[i].append(label_map[out_label_ids[i][j]] ) preds_list[i].append(label_map[preds[i][j]] ) snake_case_ :str = { """val_loss""": val_loss_mean, """accuracy_score""": accuracy_score(snake_case , snake_case ), """precision""": precision_score(snake_case , snake_case ), """recall""": recall_score(snake_case , snake_case ), """f1""": fa_score(snake_case , snake_case ), } snake_case_ :List[Any] = dict(results.items() ) snake_case_ :Union[str, Any] = results return ret, preds_list, out_label_list def lowerCAmelCase_ ( self: Optional[Any] , snake_case: Dict ) -> Optional[Any]: # when stable snake_case_, snake_case_, snake_case_ :Tuple = self._eval_end(snake_case ) snake_case_ :str = ret["""log"""] return {"val_loss": logs["val_loss"], "log": logs, "progress_bar": logs} def lowerCAmelCase_ ( self: Tuple , snake_case: Optional[int] ) -> Any: # updating to test_epoch_end instead of deprecated test_end snake_case_, snake_case_, snake_case_ :Any = self._eval_end(snake_case ) # Converting to the dict required by pl # https://github.com/PyTorchLightning/pytorch-lightning/blob/master/\ # pytorch_lightning/trainer/logging.py#L139 snake_case_ :Optional[int] = ret["""log"""] # `val_loss` is the key returned by `self._eval_end()` but actually refers to `test_loss` return {"avg_test_loss": logs["val_loss"], "log": logs, "progress_bar": logs} @staticmethod def lowerCAmelCase_ ( snake_case: Any , snake_case: int ) -> Dict: # Add NER specific options BaseTransformer.add_model_specific_args(snake_case , snake_case ) parser.add_argument( """--task_type""" , default="""NER""" , type=snake_case , help="""Task type to fine tune in training (e.g. NER, POS, etc)""" ) parser.add_argument( """--max_seq_length""" , default=128 , type=snake_case , help=( """The maximum total input sequence length after tokenization. Sequences longer """ """than this will be truncated, sequences shorter will be padded.""" ) , ) parser.add_argument( """--labels""" , default="""""" , type=snake_case , help="""Path to a file containing all labels. If not specified, CoNLL-2003 labels are used.""" , ) parser.add_argument( """--gpus""" , default=0 , type=snake_case , help="""The number of GPUs allocated for this, it is by default 0 meaning none""" , ) parser.add_argument( """--overwrite_cache""" , action="""store_true""" , help="""Overwrite the cached training and evaluation sets""" ) return parser if __name__ == "__main__": __a = argparse.ArgumentParser() add_generic_args(parser, os.getcwd()) __a = NERTransformer.add_model_specific_args(parser, os.getcwd()) __a = parser.parse_args() __a = NERTransformer(args) __a = generic_train(model, args) if args.do_predict: # See https://github.com/huggingface/transformers/issues/3159 # pl use this default format to create a checkpoint: # https://github.com/PyTorchLightning/pytorch-lightning/blob/master\ # /pytorch_lightning/callbacks/model_checkpoint.py#L322 __a = sorted(glob.glob(os.path.join(args.output_dir, "checkpoint-epoch=*.ckpt"), recursive=True)) __a = model.load_from_checkpoint(checkpoints[-1]) trainer.test(model)
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