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''' def _UpperCamelCase ( __A ) -> str: '''simple docstring''' return " ".join( "".join(word[::-1] ) if len(__A ) > 4 else word for word in sentence.split() ) if __name__ == "__main__": import doctest doctest.testmod() print(reverse_long_words('Hey wollef sroirraw'))
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import copy from typing import Any, Dict, List, Optional, Union import numpy as np import torch from ...audio_utils import mel_filter_bank, spectrogram, window_function from ...feature_extraction_sequence_utils import SequenceFeatureExtractor from ...feature_extraction_utils import BatchFeature from ...utils import TensorType, logging __A = logging.get_logger(__name__) class __lowerCAmelCase ( __magic_name__ ): """simple docstring""" snake_case_ = ['''input_features''', '''is_longer'''] def __init__( self , lowerCamelCase__=64 , lowerCamelCase__=48_000 , lowerCamelCase__=480 , lowerCamelCase__=10 , lowerCamelCase__=1_024 , lowerCamelCase__=0.0 , lowerCamelCase__=False , lowerCamelCase__ = 0 , lowerCamelCase__ = 14_000 , lowerCamelCase__ = None , lowerCamelCase__ = "fusion" , lowerCamelCase__ = "repeatpad" , **lowerCamelCase__ , ) -> Tuple: '''simple docstring''' super().__init__( feature_size=lowerCamelCase__ , sampling_rate=lowerCamelCase__ , padding_value=lowerCamelCase__ , return_attention_mask=lowerCamelCase__ , **lowerCamelCase__ , ) __lowerCamelCase = top_db __lowerCamelCase = truncation __lowerCamelCase = padding __lowerCamelCase = fft_window_size __lowerCamelCase = (fft_window_size >> 1) + 1 __lowerCamelCase = hop_length __lowerCamelCase = max_length_s __lowerCamelCase = max_length_s * sampling_rate __lowerCamelCase = sampling_rate __lowerCamelCase = frequency_min __lowerCamelCase = frequency_max __lowerCamelCase = mel_filter_bank( num_frequency_bins=self.nb_frequency_bins , num_mel_filters=lowerCamelCase__ , min_frequency=lowerCamelCase__ , max_frequency=lowerCamelCase__ , sampling_rate=lowerCamelCase__ , norm=lowerCamelCase__ , mel_scale='htk' , ) __lowerCamelCase = mel_filter_bank( num_frequency_bins=self.nb_frequency_bins , num_mel_filters=lowerCamelCase__ , min_frequency=lowerCamelCase__ , max_frequency=lowerCamelCase__ , sampling_rate=lowerCamelCase__ , norm='slaney' , mel_scale='slaney' , ) def lowercase_ ( self ) -> Dict[str, Any]: '''simple docstring''' __lowerCamelCase = copy.deepcopy(self.__dict__ ) __lowerCamelCase = self.__class__.__name__ if "mel_filters" in output: del output["mel_filters"] if "mel_filters_slaney" in output: del output["mel_filters_slaney"] return output def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ = None ) -> np.ndarray: '''simple docstring''' __lowerCamelCase = spectrogram( lowerCamelCase__ , window_function(self.fft_window_size , 'hann' ) , frame_length=self.fft_window_size , hop_length=self.hop_length , power=2.0 , mel_filters=lowerCamelCase__ , log_mel='dB' , ) return log_mel_spectrogram.T def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> int: '''simple docstring''' __lowerCamelCase = np.array_split(list(range(0 , total_frames - chunk_frames + 1 ) ) , 3 ) if len(ranges[1] ) == 0: # if the audio is too short, we just use the first chunk __lowerCamelCase = [0] if len(ranges[2] ) == 0: # if the audio is too short, we just use the first chunk __lowerCamelCase = [0] # randomly choose index for each part __lowerCamelCase = np.random.choice(ranges[0] ) __lowerCamelCase = np.random.choice(ranges[1] ) __lowerCamelCase = np.random.choice(ranges[2] ) __lowerCamelCase = mel[idx_front : idx_front + chunk_frames, :] __lowerCamelCase = mel[idx_middle : idx_middle + chunk_frames, :] __lowerCamelCase = mel[idx_back : idx_back + chunk_frames, :] __lowerCamelCase = torch.tensor(mel[None, None, :] ) __lowerCamelCase = torch.nn.functional.interpolate( lowerCamelCase__ , size=[chunk_frames, 64] , mode='bilinear' , align_corners=lowerCamelCase__ ) __lowerCamelCase = mel_shrink[0][0].numpy() __lowerCamelCase = np.stack([mel_shrink, mel_chunk_front, mel_chunk_middle, mel_chunk_back] , axis=0 ) return mel_fusion def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> np.array: '''simple docstring''' if waveform.shape[0] > max_length: if truncation == "rand_trunc": __lowerCamelCase = True # random crop to max_length (for compatibility) -> this should be handled by self.pad __lowerCamelCase = len(lowerCamelCase__ ) - max_length __lowerCamelCase = np.random.randint(0 , overflow + 1 ) __lowerCamelCase = waveform[idx : idx + max_length] __lowerCamelCase = self._np_extract_fbank_features(lowerCamelCase__ , self.mel_filters_slaney )[None, :] elif truncation == "fusion": __lowerCamelCase = self._np_extract_fbank_features(lowerCamelCase__ , self.mel_filters ) __lowerCamelCase = max_length // self.hop_length + 1 # the +1 related to how the spectrogram is computed __lowerCamelCase = mel.shape[0] if chunk_frames == total_frames: # there is a corner case where the audio length is larger than max_length but smaller than max_length+hop_length. # In this case, we just use the whole audio. __lowerCamelCase = np.stack([mel, mel, mel, mel] , axis=0 ) __lowerCamelCase = False else: __lowerCamelCase = self._random_mel_fusion(lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) __lowerCamelCase = True else: raise NotImplementedError(f"""data_truncating {truncation} not implemented""" ) else: __lowerCamelCase = False # only use repeat as a new possible value for padding. you repeat the audio before applying the usual max_length padding if waveform.shape[0] < max_length: if padding == "repeat": __lowerCamelCase = int(max_length / len(lowerCamelCase__ ) ) __lowerCamelCase = np.stack(np.tile(lowerCamelCase__ , n_repeat + 1 ) )[:max_length] if padding == "repeatpad": __lowerCamelCase = int(max_length / len(lowerCamelCase__ ) ) __lowerCamelCase = np.stack(np.tile(lowerCamelCase__ , lowerCamelCase__ ) ) __lowerCamelCase = np.pad(lowerCamelCase__ , (0, max_length - waveform.shape[0]) , mode='constant' , constant_values=0 ) if truncation == "fusion": __lowerCamelCase = self._np_extract_fbank_features(lowerCamelCase__ , self.mel_filters ) __lowerCamelCase = np.stack([input_mel, input_mel, input_mel, input_mel] , axis=0 ) else: __lowerCamelCase = self._np_extract_fbank_features(lowerCamelCase__ , self.mel_filters_slaney )[None, :] return input_mel, longer def __call__( self , lowerCamelCase__ , lowerCamelCase__ = None , lowerCamelCase__ = None , lowerCamelCase__ = None , lowerCamelCase__ = None , lowerCamelCase__ = None , **lowerCamelCase__ , ) -> BatchFeature: '''simple docstring''' __lowerCamelCase = truncation if truncation is not None else self.truncation __lowerCamelCase = padding if padding else self.padding if sampling_rate is not None: if sampling_rate != self.sampling_rate: raise ValueError( f"""The model corresponding to this feature extractor: {self.__class__.__name__} was trained using a""" f""" sampling rate of {self.sampling_rate}. Please make sure that the provided `raw_speech` input""" f""" was sampled with {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.' ) __lowerCamelCase = isinstance(lowerCamelCase__ , np.ndarray ) and len(raw_speech.shape ) > 1 if is_batched_numpy and len(raw_speech.shape ) > 2: raise ValueError(f"""Only mono-channel audio is supported for input to {self}""" ) __lowerCamelCase = is_batched_numpy or ( isinstance(lowerCamelCase__ , (list, tuple) ) and (isinstance(raw_speech[0] , (np.ndarray, tuple, list) )) ) if is_batched: __lowerCamelCase = [np.asarray(lowerCamelCase__ , dtype=np.floataa ) for speech in raw_speech] elif not is_batched and not isinstance(lowerCamelCase__ , np.ndarray ): __lowerCamelCase = np.asarray(lowerCamelCase__ , dtype=np.floataa ) elif isinstance(lowerCamelCase__ , np.ndarray ) and raw_speech.dtype is np.dtype(np.floataa ): __lowerCamelCase = raw_speech.astype(np.floataa ) # always return batch if not is_batched: __lowerCamelCase = [np.asarray(lowerCamelCase__ )] # convert to mel spectrogram, truncate and pad if needed. __lowerCamelCase = [ self._get_input_mel(lowerCamelCase__ , max_length if max_length else self.nb_max_samples , lowerCamelCase__ , lowerCamelCase__ ) for waveform in raw_speech ] __lowerCamelCase = [] __lowerCamelCase = [] for mel, longer in padded_inputs: input_mel.append(lowerCamelCase__ ) is_longer.append(lowerCamelCase__ ) if truncation == "fusion" and sum(lowerCamelCase__ ) == 0: # if no audio is longer than 10s, then randomly select one audio to be longer __lowerCamelCase = np.random.randint(0 , len(lowerCamelCase__ ) ) __lowerCamelCase = True if isinstance(input_mel[0] , lowerCamelCase__ ): __lowerCamelCase = [np.asarray(lowerCamelCase__ , dtype=np.floataa ) for feature in input_mel] # is_longer is a list of bool __lowerCamelCase = [[longer] for longer in is_longer] __lowerCamelCase = {'input_features': input_mel, 'is_longer': is_longer} __lowerCamelCase = BatchFeature(lowerCamelCase__ ) if return_tensors is not None: __lowerCamelCase = input_features.convert_to_tensors(lowerCamelCase__ ) return input_features
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"""simple docstring""" from argparse import ArgumentParser, Namespace from typing import Any, List, Optional from ..pipelines import Pipeline, get_supported_tasks, pipeline from ..utils import logging from . import BaseTransformersCLICommand try: from fastapi import Body, FastAPI, HTTPException from fastapi.routing import APIRoute from pydantic import BaseModel from starlette.responses import JSONResponse from uvicorn import run lowerCamelCase_ : str = True except (ImportError, AttributeError): lowerCamelCase_ : Optional[Any] = object def _A ( *lowercase , **lowercase ): """simple docstring""" pass lowerCamelCase_ : int = False lowerCamelCase_ : Dict = logging.get_logger("""transformers-cli/serving""") def _A ( lowercase ): """simple docstring""" a =pipeline( task=args.task , model=args.model if args.model else None , config=args.config , tokenizer=args.tokenizer , device=args.device , ) return ServeCommand(lowercase , args.host , args.port , args.workers ) class __A ( _SCREAMING_SNAKE_CASE ): """simple docstring""" __lowerCAmelCase = 42 class __A ( _SCREAMING_SNAKE_CASE ): """simple docstring""" __lowerCAmelCase = 42 __lowerCAmelCase = 42 class __A ( _SCREAMING_SNAKE_CASE ): """simple docstring""" __lowerCAmelCase = 42 class __A ( _SCREAMING_SNAKE_CASE ): """simple docstring""" __lowerCAmelCase = 42 class __A ( _SCREAMING_SNAKE_CASE ): """simple docstring""" @staticmethod def SCREAMING_SNAKE_CASE ( __A ) -> List[Any]: a =parser.add_parser( '''serve''' , help='''CLI tool to run inference requests through REST and GraphQL endpoints.''' ) serve_parser.add_argument( '''--task''' , type=__A , choices=get_supported_tasks() , help='''The task to run the pipeline on''' , ) serve_parser.add_argument('''--host''' , type=__A , default='''localhost''' , help='''Interface the server will listen on.''' ) serve_parser.add_argument('''--port''' , type=__A , default=8888 , help='''Port the serving will listen to.''' ) serve_parser.add_argument('''--workers''' , type=__A , default=1 , help='''Number of http workers''' ) serve_parser.add_argument('''--model''' , type=__A , help='''Model\'s name or path to stored model.''' ) serve_parser.add_argument('''--config''' , type=__A , help='''Model\'s config name or path to stored model.''' ) serve_parser.add_argument('''--tokenizer''' , type=__A , help='''Tokenizer name to use.''' ) serve_parser.add_argument( '''--device''' , type=__A , default=-1 , help='''Indicate the device to run onto, -1 indicates CPU, >= 0 indicates GPU (default: -1)''' , ) serve_parser.set_defaults(func=__A ) def __init__( self , __A , __A , __A , __A ) -> List[str]: a =pipeline a =host a =port a =workers if not _serve_dependencies_installed: raise RuntimeError( '''Using serve command requires FastAPI and uvicorn. ''' '''Please install transformers with [serving]: pip install "transformers[serving]".''' '''Or install FastAPI and uvicorn separately.''' ) else: logger.info(f'''Serving model over {host}:{port}''' ) a =FastAPI( routes=[ APIRoute( '''/''' , self.model_info , response_model=__A , response_class=__A , methods=['''GET'''] , ), APIRoute( '''/tokenize''' , self.tokenize , response_model=__A , response_class=__A , methods=['''POST'''] , ), APIRoute( '''/detokenize''' , self.detokenize , response_model=__A , response_class=__A , methods=['''POST'''] , ), APIRoute( '''/forward''' , self.forward , response_model=__A , response_class=__A , methods=['''POST'''] , ), ] , timeout=600 , ) def SCREAMING_SNAKE_CASE ( self ) -> Optional[int]: run(self._app , host=self.host , port=self.port , workers=self.workers ) def SCREAMING_SNAKE_CASE ( self ) -> List[str]: return ServeModelInfoResult(infos=vars(self._pipeline.model.config ) ) def SCREAMING_SNAKE_CASE ( self , __A = Body(__A , embed=__A ) , __A = Body(__A , embed=__A ) ) -> str: try: a =self._pipeline.tokenizer.tokenize(__A ) if return_ids: a =self._pipeline.tokenizer.convert_tokens_to_ids(__A ) return ServeTokenizeResult(tokens=__A , tokens_ids=__A ) else: return ServeTokenizeResult(tokens=__A ) except Exception as e: raise HTTPException(status_code=500 , detail={'''model''': '''''', '''error''': str(__A )} ) def SCREAMING_SNAKE_CASE ( self , __A = Body(__A , embed=__A ) , __A = Body(__A , embed=__A ) , __A = Body(__A , embed=__A ) , ) -> str: try: a =self._pipeline.tokenizer.decode(__A , __A , __A ) return ServeDeTokenizeResult(model='''''' , text=__A ) except Exception as e: raise HTTPException(status_code=500 , detail={'''model''': '''''', '''error''': str(__A )} ) async def SCREAMING_SNAKE_CASE ( self , __A=Body(__A , embed=__A ) ) -> Any: # Check we don't have empty string if len(__A ) == 0: return ServeForwardResult(output=[] , attention=[] ) try: # Forward through the model a =self._pipeline(__A ) return ServeForwardResult(output=__A ) except Exception as e: raise HTTPException(500 , {'''error''': str(__A )} )
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class __lowerCAmelCase : """simple docstring""" def __init__( self ) -> Any: '''simple docstring''' __lowerCamelCase = 0 __lowerCamelCase = 0 __lowerCamelCase = {} def lowercase_ ( self , lowerCamelCase__ ) -> Tuple: '''simple docstring''' if vertex not in self.adjacency: __lowerCamelCase = {} self.num_vertices += 1 def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> str: '''simple docstring''' self.add_vertex(lowerCamelCase__ ) self.add_vertex(lowerCamelCase__ ) if head == tail: return __lowerCamelCase = weight __lowerCamelCase = weight def lowercase_ ( self ) -> List[str]: '''simple docstring''' __lowerCamelCase = self.get_edges() for edge in edges: __lowerCamelCase , __lowerCamelCase , __lowerCamelCase = edge edges.remove((tail, head, weight) ) for i in range(len(lowerCamelCase__ ) ): __lowerCamelCase = list(edges[i] ) edges.sort(key=lambda lowerCamelCase__ : e[2] ) for i in range(len(lowerCamelCase__ ) - 1 ): if edges[i][2] >= edges[i + 1][2]: __lowerCamelCase = edges[i][2] + 1 for edge in edges: __lowerCamelCase , __lowerCamelCase , __lowerCamelCase = edge __lowerCamelCase = weight __lowerCamelCase = weight def __str__( self ) -> Union[str, Any]: '''simple docstring''' __lowerCamelCase = '' for tail in self.adjacency: for head in self.adjacency[tail]: __lowerCamelCase = self.adjacency[head][tail] string += f"""{head} -> {tail} == {weight}\n""" return string.rstrip('\n' ) def lowercase_ ( self ) -> Optional[Any]: '''simple docstring''' __lowerCamelCase = [] for tail in self.adjacency: for head in self.adjacency[tail]: output.append((tail, head, self.adjacency[head][tail]) ) return output def lowercase_ ( self ) -> List[Any]: '''simple docstring''' return self.adjacency.keys() @staticmethod def lowercase_ ( lowerCamelCase__=None , lowerCamelCase__=None ) -> str: '''simple docstring''' __lowerCamelCase = Graph() if vertices is None: __lowerCamelCase = [] if edges is None: __lowerCamelCase = [] for vertex in vertices: g.add_vertex(lowerCamelCase__ ) for edge in edges: g.add_edge(*lowerCamelCase__ ) return g class __lowerCAmelCase : """simple docstring""" def __init__( self ) -> Tuple: '''simple docstring''' __lowerCamelCase = {} __lowerCamelCase = {} def __len__( self ) -> Tuple: '''simple docstring''' return len(self.parent ) def lowercase_ ( self , lowerCamelCase__ ) -> List[Any]: '''simple docstring''' if item in self.parent: return self.find(lowerCamelCase__ ) __lowerCamelCase = item __lowerCamelCase = 0 return item def lowercase_ ( self , lowerCamelCase__ ) -> List[str]: '''simple docstring''' if item not in self.parent: return self.make_set(lowerCamelCase__ ) if item != self.parent[item]: __lowerCamelCase = self.find(self.parent[item] ) return self.parent[item] def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ ) -> int: '''simple docstring''' __lowerCamelCase = self.find(lowerCamelCase__ ) __lowerCamelCase = self.find(lowerCamelCase__ ) if roota == roota: return roota if self.rank[roota] > self.rank[roota]: __lowerCamelCase = roota return roota if self.rank[roota] < self.rank[roota]: __lowerCamelCase = roota return roota if self.rank[roota] == self.rank[roota]: self.rank[roota] += 1 __lowerCamelCase = roota return roota return None @staticmethod def lowercase_ ( lowerCamelCase__ ) -> str: '''simple docstring''' __lowerCamelCase = graph.num_vertices __lowerCamelCase = Graph.UnionFind() __lowerCamelCase = [] while num_components > 1: __lowerCamelCase = {} for vertex in graph.get_vertices(): __lowerCamelCase = -1 __lowerCamelCase = graph.get_edges() for edge in edges: __lowerCamelCase , __lowerCamelCase , __lowerCamelCase = edge edges.remove((tail, head, weight) ) for edge in edges: __lowerCamelCase , __lowerCamelCase , __lowerCamelCase = edge __lowerCamelCase = union_find.find(lowerCamelCase__ ) __lowerCamelCase = union_find.find(lowerCamelCase__ ) if seta != seta: if cheap_edge[seta] == -1 or cheap_edge[seta][2] > weight: __lowerCamelCase = [head, tail, weight] if cheap_edge[seta] == -1 or cheap_edge[seta][2] > weight: __lowerCamelCase = [head, tail, weight] for vertex in cheap_edge: if cheap_edge[vertex] != -1: __lowerCamelCase , __lowerCamelCase , __lowerCamelCase = cheap_edge[vertex] if union_find.find(lowerCamelCase__ ) != union_find.find(lowerCamelCase__ ): union_find.union(lowerCamelCase__ , lowerCamelCase__ ) mst_edges.append(cheap_edge[vertex] ) __lowerCamelCase = num_components - 1 __lowerCamelCase = Graph.build(edges=lowerCamelCase__ ) return mst
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def _UpperCAmelCase ( snake_case ): """simple docstring""" if not isinstance(snake_case , snake_case ): _lowerCAmelCase = F'Input value of [number={number}] must be an integer' raise TypeError(snake_case ) if number < 0: return False _lowerCAmelCase = number * number while number > 0: if number % 10 != number_square % 10: return False number //= 10 number_square //= 10 return True if __name__ == "__main__": import doctest doctest.testmod()
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from math import pi, sqrt, tan def lowerCamelCase_ ( UpperCamelCase__ : float ) -> float: """simple docstring""" if side_length < 0: raise ValueError('surface_area_cube() only accepts non-negative values' ) return 6 * side_length**2 def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if length < 0 or breadth < 0 or height < 0: raise ValueError('surface_area_cuboid() only accepts non-negative values' ) return 2 * ((length * breadth) + (breadth * height) + (length * height)) def lowerCamelCase_ ( UpperCamelCase__ : float ) -> float: """simple docstring""" if radius < 0: raise ValueError('surface_area_sphere() only accepts non-negative values' ) return 4 * pi * radius**2 def lowerCamelCase_ ( UpperCamelCase__ : float ) -> float: """simple docstring""" if radius < 0: raise ValueError('surface_area_hemisphere() only accepts non-negative values' ) return 3 * pi * radius**2 def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if radius < 0 or height < 0: raise ValueError('surface_area_cone() only accepts non-negative values' ) return pi * radius * (radius + (height**2 + radius**2) ** 0.5) def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if radius_a < 0 or radius_a < 0 or height < 0: raise ValueError( 'surface_area_conical_frustum() only accepts non-negative values' ) __lowerCamelCase = (height**2 + (radius_a - radius_a) ** 2) ** 0.5 return pi * ((slant_height * (radius_a + radius_a)) + radius_a**2 + radius_a**2) def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if radius < 0 or height < 0: raise ValueError('surface_area_cylinder() only accepts non-negative values' ) return 2 * pi * radius * (height + radius) def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if torus_radius < 0 or tube_radius < 0: raise ValueError('surface_area_torus() only accepts non-negative values' ) if torus_radius < tube_radius: raise ValueError( 'surface_area_torus() does not support spindle or self intersecting tori' ) return 4 * pow(UpperCamelCase__ , 2 ) * torus_radius * tube_radius def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if length < 0 or width < 0: raise ValueError('area_rectangle() only accepts non-negative values' ) return length * width def lowerCamelCase_ ( UpperCamelCase__ : float ) -> float: """simple docstring""" if side_length < 0: raise ValueError('area_square() only accepts non-negative values' ) return side_length**2 def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if base < 0 or height < 0: raise ValueError('area_triangle() only accepts non-negative values' ) return (base * height) / 2 def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if sidea < 0 or sidea < 0 or sidea < 0: raise ValueError('area_triangle_three_sides() only accepts non-negative values' ) elif sidea + sidea < sidea or sidea + sidea < sidea or sidea + sidea < sidea: raise ValueError('Given three sides do not form a triangle' ) __lowerCamelCase = (sidea + sidea + sidea) / 2 __lowerCamelCase = sqrt( semi_perimeter * (semi_perimeter - sidea) * (semi_perimeter - sidea) * (semi_perimeter - sidea) ) return area def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if base < 0 or height < 0: raise ValueError('area_parallelogram() only accepts non-negative values' ) return base * height def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if basea < 0 or basea < 0 or height < 0: raise ValueError('area_trapezium() only accepts non-negative values' ) return 1 / 2 * (basea + basea) * height def lowerCamelCase_ ( UpperCamelCase__ : float ) -> float: """simple docstring""" if radius < 0: raise ValueError('area_circle() only accepts non-negative values' ) return pi * radius**2 def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if radius_x < 0 or radius_y < 0: raise ValueError('area_ellipse() only accepts non-negative values' ) return pi * radius_x * radius_y def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if diagonal_a < 0 or diagonal_a < 0: raise ValueError('area_rhombus() only accepts non-negative values' ) return 1 / 2 * diagonal_a * diagonal_a def lowerCamelCase_ ( UpperCamelCase__ : int , UpperCamelCase__ : float ) -> float: """simple docstring""" if not isinstance(UpperCamelCase__ , UpperCamelCase__ ) or sides < 3: raise ValueError( 'area_reg_polygon() only accepts integers greater than or \ equal to three as number of sides' ) elif length < 0: raise ValueError( 'area_reg_polygon() only accepts non-negative values as \ length of a side' ) return (sides * length**2) / (4 * tan(pi / sides )) return (sides * length**2) / (4 * tan(pi / sides )) if __name__ == "__main__": import doctest doctest.testmod(verbose=True) # verbose so we can see methods missing tests print("[DEMO] Areas of various geometric shapes: \n") print(f'''Rectangle: {area_rectangle(10, 20) = }''') print(f'''Square: {area_square(10) = }''') print(f'''Triangle: {area_triangle(10, 10) = }''') print(f'''Triangle: {area_triangle_three_sides(5, 12, 13) = }''') print(f'''Parallelogram: {area_parallelogram(10, 20) = }''') print(f'''Rhombus: {area_rhombus(10, 20) = }''') print(f'''Trapezium: {area_trapezium(10, 20, 30) = }''') print(f'''Circle: {area_circle(20) = }''') print(f'''Ellipse: {area_ellipse(10, 20) = }''') print("\nSurface Areas of various geometric shapes: \n") print(f'''Cube: {surface_area_cube(20) = }''') print(f'''Cuboid: {surface_area_cuboid(10, 20, 30) = }''') print(f'''Sphere: {surface_area_sphere(20) = }''') print(f'''Hemisphere: {surface_area_hemisphere(20) = }''') print(f'''Cone: {surface_area_cone(10, 20) = }''') print(f'''Conical Frustum: {surface_area_conical_frustum(10, 20, 30) = }''') print(f'''Cylinder: {surface_area_cylinder(10, 20) = }''') print(f'''Torus: {surface_area_torus(20, 10) = }''') print(f'''Equilateral Triangle: {area_reg_polygon(3, 10) = }''') print(f'''Square: {area_reg_polygon(4, 10) = }''') print(f'''Reqular Pentagon: {area_reg_polygon(5, 10) = }''')
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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') snake_case_ : Any = logging.getLogger(__name__) @dataclass class lowercase__ : lowercase__ = field( metadata={"""help""": """Path to pretrained model or model identifier from huggingface.co/models"""} ) lowercase__ = field( default=lowercase , metadata={"""help""": """Pretrained config name or path if not the same as model_name"""} ) lowercase__ = field( default=lowercase , metadata={"""help""": """Pretrained tokenizer name or path if not the same as model_name"""} ) lowercase__ = field( default=lowercase , metadata={"""help""": """Where do you want to store the pretrained models downloaded from huggingface.co"""} , ) lowercase__ = field( default=lowercase , metadata={"""help""": """Whether to use one of the fast tokenizer (backed by the tokenizers library) or not."""} , ) lowercase__ = field( default="""main""" , metadata={"""help""": """The specific model version to use (can be a branch name, tag name or commit id)."""} , ) lowercase__ = field( default=lowercase , metadata={ """help""": ( """Will use the token generated when running `huggingface-cli login` (necessary to use this script """ """with private models).""" ) } , ) @dataclass class lowercase__ : lowercase__ = field(default=lowercase , metadata={"""help""": """The input training data file (a text file)."""} ) lowercase__ = field( default=lowercase , metadata={"""help""": """An optional input evaluation data file to evaluate the perplexity on (a text file)."""} , ) lowercase__ = field( default=lowercase , metadata={"""help""": """Overwrite the cached training and evaluation sets"""} ) lowercase__ = field( default=lowercase , metadata={"""help""": """The number of processes to use for the preprocessing."""} , ) lowercase__ = field( default=lowercase , metadata={ """help""": ( """The maximum total input sequence length after tokenization. If passed, sequences longer """ """than this will be truncated, sequences shorter will be padded.""" ) } , ) lowercase__ = field( default=lowercase , 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.""" ) } , ) lowercase__ = field( default=lowercase , metadata={ """help""": ( """For debugging purposes or quicker training, truncate the number of training examples to this """ """value if set.""" ) } , ) lowercase__ = field( default=lowercase , metadata={ """help""": ( """For debugging purposes or quicker training, truncate the number of evaluation examples to this """ """value if set.""" ) } , ) def UpperCamelCase_ ( self : str ): '''simple docstring''' if self.train_file is not None: _UpperCamelCase : List[Any] = 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: _UpperCamelCase : Union[str, Any] = self.validation_file.split('.' )[-1] assert extension in ["csv", "json"], "`validation_file` should be a csv or a json file." @dataclass class lowercase__ : lowercase__ = 42 lowercase__ = True lowercase__ = None lowercase__ = None def __call__( self : Optional[Any] ,lowerCamelCase__ : Dict ): '''simple docstring''' _UpperCamelCase : List[str] = 'label' if 'label' in features[0].keys() else 'labels' _UpperCamelCase : List[Any] = [feature.pop(lowerCamelCase__ ) for feature in features] _UpperCamelCase : Dict = len(lowerCamelCase__ ) _UpperCamelCase : List[str] = len(features[0]['input_ids'] ) _UpperCamelCase : List[Any] = [ [{k: v[i] for k, v in feature.items()} for i in range(lowerCamelCase__ )] for feature in features ] _UpperCamelCase : str = list(chain(*lowerCamelCase__ ) ) _UpperCamelCase : Tuple = self.tokenizer.pad( lowerCamelCase__ ,padding=self.padding ,max_length=self.max_length ,pad_to_multiple_of=self.pad_to_multiple_of ,return_tensors='pt' ,) # Un-flatten _UpperCamelCase : str = {k: v.view(lowerCamelCase__ ,lowerCamelCase__ ,-1 ) for k, v in batch.items()} # Add back labels _UpperCamelCase : Optional[int] = torch.tensor(lowerCamelCase__ ,dtype=torch.intaa ) return batch def A__ ( ): # See all possible arguments in src/transformers/training_args.py # or by passing the --help flag to this script. # We now keep distinct sets of args, for a cleaner separation of concerns. _UpperCamelCase : 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. _UpperCamelCase , _UpperCamelCase , _UpperCamelCase : Optional[int] = parser.parse_json_file(json_file=os.path.abspath(sys.argv[1] ) ) else: _UpperCamelCase , _UpperCamelCase , _UpperCamelCase : str = parser.parse_args_into_dataclasses() # Sending telemetry. Tracking the example usage helps us better allocate resources to maintain them. The # information sent is the one passed as arguments along with your Python/PyTorch versions. send_example_telemetry('run_swag' , UpperCAmelCase_ , UpperCAmelCase_ ) # 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() _UpperCamelCase : Optional[Any] = training_args.get_process_log_level() logger.setLevel(UpperCAmelCase_ ) datasets.utils.logging.set_verbosity(UpperCAmelCase_ ) transformers.utils.logging.set_verbosity(UpperCAmelCase_ ) 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. _UpperCamelCase : Union[str, Any] = None if os.path.isdir(training_args.output_dir ) and training_args.do_train and not training_args.overwrite_output_dir: _UpperCamelCase : List[str] = 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: _UpperCamelCase : Optional[int] = {} if data_args.train_file is not None: _UpperCamelCase : Tuple = data_args.train_file if data_args.validation_file is not None: _UpperCamelCase : Tuple = data_args.validation_file _UpperCamelCase : Any = data_args.train_file.split('.' )[-1] _UpperCamelCase : Union[str, Any] = load_dataset( UpperCAmelCase_ , data_files=UpperCAmelCase_ , 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. _UpperCamelCase : List[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. _UpperCamelCase : Union[str, Any] = 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 , ) _UpperCamelCase : int = 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 , ) _UpperCamelCase : Dict = AutoModelForMultipleChoice.from_pretrained( model_args.model_name_or_path , from_tf=bool('.ckpt' in model_args.model_name_or_path ) , config=UpperCAmelCase_ , 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. _UpperCamelCase : Any = [f'ending{i}' for i in range(4 )] _UpperCamelCase : int = 'sent1' _UpperCamelCase : List[str] = 'sent2' if data_args.max_seq_length is None: _UpperCamelCase : int = tokenizer.model_max_length if max_seq_length > 1_0_2_4: 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`.' ) _UpperCamelCase : int = 1_0_2_4 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}.' ) _UpperCamelCase : Optional[int] = min(data_args.max_seq_length , tokenizer.model_max_length ) # Preprocessing the datasets. def preprocess_function(UpperCAmelCase_ ): _UpperCamelCase : str = [[context] * 4 for context in examples[context_name]] _UpperCamelCase : Optional[Any] = examples[question_header_name] _UpperCamelCase : Tuple = [ [f'{header} {examples[end][i]}' for end in ending_names] for i, header in enumerate(UpperCAmelCase_ ) ] # Flatten out _UpperCamelCase : Optional[int] = list(chain(*UpperCAmelCase_ ) ) _UpperCamelCase : Optional[Any] = list(chain(*UpperCAmelCase_ ) ) # Tokenize _UpperCamelCase : Tuple = tokenizer( UpperCAmelCase_ , UpperCAmelCase_ , truncation=UpperCAmelCase_ , max_length=UpperCAmelCase_ , 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(UpperCAmelCase_ ) , 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' ) _UpperCamelCase : Optional[Any] = raw_datasets['train'] if data_args.max_train_samples is not None: _UpperCamelCase : Tuple = min(len(UpperCAmelCase_ ) , data_args.max_train_samples ) _UpperCamelCase : Tuple = train_dataset.select(range(UpperCAmelCase_ ) ) with training_args.main_process_first(desc='train dataset map pre-processing' ): _UpperCamelCase : Union[str, Any] = train_dataset.map( UpperCAmelCase_ , batched=UpperCAmelCase_ , 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' ) _UpperCamelCase : str = raw_datasets['validation'] if data_args.max_eval_samples is not None: _UpperCamelCase : Union[str, Any] = min(len(UpperCAmelCase_ ) , data_args.max_eval_samples ) _UpperCamelCase : str = eval_dataset.select(range(UpperCAmelCase_ ) ) with training_args.main_process_first(desc='validation dataset map pre-processing' ): _UpperCamelCase : Dict = eval_dataset.map( UpperCAmelCase_ , batched=UpperCAmelCase_ , num_proc=data_args.preprocessing_num_workers , load_from_cache_file=not data_args.overwrite_cache , ) # Data collator _UpperCamelCase : List[Any] = ( default_data_collator if data_args.pad_to_max_length else DataCollatorForMultipleChoice(tokenizer=UpperCAmelCase_ , pad_to_multiple_of=8 if training_args.fpaa else None ) ) # Metric def compute_metrics(UpperCAmelCase_ ): _UpperCamelCase , _UpperCamelCase : Union[str, Any] = eval_predictions _UpperCamelCase : List[str] = np.argmax(UpperCAmelCase_ , axis=1 ) return {"accuracy": (preds == label_ids).astype(np.floataa ).mean().item()} # Initialize our Trainer _UpperCamelCase : Optional[int] = Trainer( model=UpperCAmelCase_ , args=UpperCAmelCase_ , train_dataset=train_dataset if training_args.do_train else None , eval_dataset=eval_dataset if training_args.do_eval else None , tokenizer=UpperCAmelCase_ , data_collator=UpperCAmelCase_ , compute_metrics=UpperCAmelCase_ , ) # Training if training_args.do_train: _UpperCamelCase : Optional[int] = None if training_args.resume_from_checkpoint is not None: _UpperCamelCase : str = training_args.resume_from_checkpoint elif last_checkpoint is not None: _UpperCamelCase : int = last_checkpoint _UpperCamelCase : List[str] = trainer.train(resume_from_checkpoint=UpperCAmelCase_ ) trainer.save_model() # Saves the tokenizer too for easy upload _UpperCamelCase : Union[str, Any] = train_result.metrics _UpperCamelCase : Optional[Any] = ( data_args.max_train_samples if data_args.max_train_samples is not None else len(UpperCAmelCase_ ) ) _UpperCamelCase : Optional[Any] = min(UpperCAmelCase_ , len(UpperCAmelCase_ ) ) trainer.log_metrics('train' , UpperCAmelCase_ ) trainer.save_metrics('train' , UpperCAmelCase_ ) trainer.save_state() # Evaluation if training_args.do_eval: logger.info('*** Evaluate ***' ) _UpperCamelCase : List[Any] = trainer.evaluate() _UpperCamelCase : Dict = data_args.max_eval_samples if data_args.max_eval_samples is not None else len(UpperCAmelCase_ ) _UpperCamelCase : int = min(UpperCAmelCase_ , len(UpperCAmelCase_ ) ) trainer.log_metrics('eval' , UpperCAmelCase_ ) trainer.save_metrics('eval' , UpperCAmelCase_ ) _UpperCamelCase : Optional[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(**UpperCAmelCase_ ) else: trainer.create_model_card(**UpperCAmelCase_ ) def A__ ( UpperCAmelCase_ ): # For xla_spawn (TPUs) main() if __name__ == "__main__": main()
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import unittest from transformers import DebertaConfig, is_torch_available from transformers.testing_utils import require_sentencepiece, require_tokenizers, require_torch, slow, torch_device from ...test_configuration_common import ConfigTester from ...test_modeling_common import ModelTesterMixin, ids_tensor from ...test_pipeline_mixin import PipelineTesterMixin if is_torch_available(): import torch from transformers import ( DebertaForMaskedLM, DebertaForQuestionAnswering, DebertaForSequenceClassification, DebertaForTokenClassification, DebertaModel, ) from transformers.models.deberta.modeling_deberta import DEBERTA_PRETRAINED_MODEL_ARCHIVE_LIST class __lowerCAmelCase ( __magic_name__ ): """simple docstring""" def __init__( self , lowerCamelCase__ , lowerCamelCase__=13 , lowerCamelCase__=7 , lowerCamelCase__=True , lowerCamelCase__=True , lowerCamelCase__=True , lowerCamelCase__=True , lowerCamelCase__=99 , lowerCamelCase__=32 , lowerCamelCase__=5 , lowerCamelCase__=4 , lowerCamelCase__=37 , lowerCamelCase__="gelu" , lowerCamelCase__=0.1 , lowerCamelCase__=0.1 , lowerCamelCase__=512 , lowerCamelCase__=16 , lowerCamelCase__=2 , lowerCamelCase__=0.02 , lowerCamelCase__=False , lowerCamelCase__=True , lowerCamelCase__="None" , lowerCamelCase__=3 , lowerCamelCase__=4 , lowerCamelCase__=None , ) -> int: '''simple docstring''' __lowerCamelCase = parent __lowerCamelCase = batch_size __lowerCamelCase = seq_length __lowerCamelCase = is_training __lowerCamelCase = use_input_mask __lowerCamelCase = use_token_type_ids __lowerCamelCase = use_labels __lowerCamelCase = vocab_size __lowerCamelCase = hidden_size __lowerCamelCase = num_hidden_layers __lowerCamelCase = num_attention_heads __lowerCamelCase = intermediate_size __lowerCamelCase = hidden_act __lowerCamelCase = hidden_dropout_prob __lowerCamelCase = attention_probs_dropout_prob __lowerCamelCase = max_position_embeddings __lowerCamelCase = type_vocab_size __lowerCamelCase = type_sequence_label_size __lowerCamelCase = initializer_range __lowerCamelCase = num_labels __lowerCamelCase = num_choices __lowerCamelCase = relative_attention __lowerCamelCase = position_biased_input __lowerCamelCase = pos_att_type __lowerCamelCase = scope def lowercase_ ( self ) -> str: '''simple docstring''' __lowerCamelCase = ids_tensor([self.batch_size, self.seq_length] , self.vocab_size ) __lowerCamelCase = None if self.use_input_mask: __lowerCamelCase = ids_tensor([self.batch_size, self.seq_length] , vocab_size=2 ) __lowerCamelCase = None if self.use_token_type_ids: __lowerCamelCase = ids_tensor([self.batch_size, self.seq_length] , self.type_vocab_size ) __lowerCamelCase = None __lowerCamelCase = None __lowerCamelCase = None if self.use_labels: __lowerCamelCase = ids_tensor([self.batch_size] , self.type_sequence_label_size ) __lowerCamelCase = ids_tensor([self.batch_size, self.seq_length] , self.num_labels ) __lowerCamelCase = ids_tensor([self.batch_size] , self.num_choices ) __lowerCamelCase = self.get_config() return config, input_ids, token_type_ids, input_mask, sequence_labels, token_labels, choice_labels def lowercase_ ( self ) -> Optional[Any]: '''simple docstring''' return DebertaConfig( 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 , relative_attention=self.relative_attention , position_biased_input=self.position_biased_input , pos_att_type=self.pos_att_type , ) def lowercase_ ( self ) -> List[str]: '''simple docstring''' __lowerCamelCase = self.get_config() __lowerCamelCase = 300 return config def lowercase_ ( self , lowerCamelCase__ ) -> Optional[int]: '''simple docstring''' self.parent.assertListEqual(list(result.loss.size() ) , [] ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> Any: '''simple docstring''' __lowerCamelCase = DebertaModel(config=lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model(lowerCamelCase__ , attention_mask=lowerCamelCase__ , token_type_ids=lowerCamelCase__ )[0] __lowerCamelCase = model(lowerCamelCase__ , token_type_ids=lowerCamelCase__ )[0] __lowerCamelCase = model(lowerCamelCase__ )[0] self.parent.assertListEqual(list(sequence_output.size() ) , [self.batch_size, self.seq_length, self.hidden_size] ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> Tuple: '''simple docstring''' __lowerCamelCase = DebertaForMaskedLM(config=lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model(lowerCamelCase__ , attention_mask=lowerCamelCase__ , token_type_ids=lowerCamelCase__ , labels=lowerCamelCase__ ) self.parent.assertEqual(result.logits.shape , (self.batch_size, self.seq_length, self.vocab_size) ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> Union[str, Any]: '''simple docstring''' __lowerCamelCase = self.num_labels __lowerCamelCase = DebertaForSequenceClassification(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model(lowerCamelCase__ , attention_mask=lowerCamelCase__ , token_type_ids=lowerCamelCase__ , labels=lowerCamelCase__ ) self.parent.assertListEqual(list(result.logits.size() ) , [self.batch_size, self.num_labels] ) self.check_loss_output(lowerCamelCase__ ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> Optional[int]: '''simple docstring''' __lowerCamelCase = self.num_labels __lowerCamelCase = DebertaForTokenClassification(config=lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model(lowerCamelCase__ , attention_mask=lowerCamelCase__ , token_type_ids=lowerCamelCase__ , labels=lowerCamelCase__ ) self.parent.assertEqual(result.logits.shape , (self.batch_size, self.seq_length, self.num_labels) ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> Dict: '''simple docstring''' __lowerCamelCase = DebertaForQuestionAnswering(config=lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model( lowerCamelCase__ , attention_mask=lowerCamelCase__ , token_type_ids=lowerCamelCase__ , start_positions=lowerCamelCase__ , end_positions=lowerCamelCase__ , ) self.parent.assertEqual(result.start_logits.shape , (self.batch_size, self.seq_length) ) self.parent.assertEqual(result.end_logits.shape , (self.batch_size, self.seq_length) ) def lowercase_ ( self ) -> Union[str, Any]: '''simple docstring''' __lowerCamelCase = self.prepare_config_and_inputs() ( ( __lowerCamelCase ) , ( __lowerCamelCase ) , ( __lowerCamelCase ) , ( __lowerCamelCase ) , ( __lowerCamelCase ) , ( __lowerCamelCase ) , ( __lowerCamelCase ) , ) = config_and_inputs __lowerCamelCase = {'input_ids': input_ids, 'token_type_ids': token_type_ids, 'attention_mask': input_mask} return config, inputs_dict @require_torch class __lowerCAmelCase ( __magic_name__ , __magic_name__ , unittest.TestCase ): """simple docstring""" snake_case_ = ( ( DebertaModel, DebertaForMaskedLM, DebertaForSequenceClassification, DebertaForTokenClassification, DebertaForQuestionAnswering, ) if is_torch_available() else () ) snake_case_ = ( { '''feature-extraction''': DebertaModel, '''fill-mask''': DebertaForMaskedLM, '''question-answering''': DebertaForQuestionAnswering, '''text-classification''': DebertaForSequenceClassification, '''token-classification''': DebertaForTokenClassification, '''zero-shot''': DebertaForSequenceClassification, } if is_torch_available() else {} ) snake_case_ = True snake_case_ = False snake_case_ = False snake_case_ = False snake_case_ = False def lowercase_ ( self ) -> List[Any]: '''simple docstring''' __lowerCamelCase = DebertaModelTester(self ) __lowerCamelCase = ConfigTester(self , config_class=lowerCamelCase__ , hidden_size=37 ) def lowercase_ ( self ) -> Optional[int]: '''simple docstring''' self.config_tester.run_common_tests() def lowercase_ ( self ) -> List[str]: '''simple docstring''' __lowerCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_deberta_model(*lowerCamelCase__ ) def lowercase_ ( self ) -> Optional[int]: '''simple docstring''' __lowerCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_deberta_for_sequence_classification(*lowerCamelCase__ ) def lowercase_ ( self ) -> Dict: '''simple docstring''' __lowerCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_deberta_for_masked_lm(*lowerCamelCase__ ) def lowercase_ ( self ) -> Optional[Any]: '''simple docstring''' __lowerCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_deberta_for_question_answering(*lowerCamelCase__ ) def lowercase_ ( self ) -> str: '''simple docstring''' __lowerCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_deberta_for_token_classification(*lowerCamelCase__ ) @slow def lowercase_ ( self ) -> Optional[int]: '''simple docstring''' for model_name in DEBERTA_PRETRAINED_MODEL_ARCHIVE_LIST[:1]: __lowerCamelCase = DebertaModel.from_pretrained(lowerCamelCase__ ) self.assertIsNotNone(lowerCamelCase__ ) @require_torch @require_sentencepiece @require_tokenizers class __lowerCAmelCase ( unittest.TestCase ): """simple docstring""" @unittest.skip(reason='Model not available yet' ) def lowercase_ ( self ) -> Union[str, Any]: '''simple docstring''' pass @slow def lowercase_ ( self ) -> Tuple: '''simple docstring''' __lowerCamelCase = DebertaModel.from_pretrained('microsoft/deberta-base' ) __lowerCamelCase = torch.tensor([[0, 31_414, 232, 328, 740, 1_140, 12_695, 69, 46_078, 1_588, 2]] ) __lowerCamelCase = torch.tensor([[0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1]] ) with torch.no_grad(): __lowerCamelCase = model(lowerCamelCase__ , attention_mask=lowerCamelCase__ )[0] # compare the actual values for a slice. __lowerCamelCase = torch.tensor( [[[-0.59_86, -0.80_55, -0.84_62], [1.44_84, -0.93_48, -0.80_59], [0.31_23, 0.00_32, -1.41_31]]] ) self.assertTrue(torch.allclose(output[:, 1:4, 1:4] , lowerCamelCase__ , atol=1e-4 ) , f"""{output[:, 1:4, 1:4]}""" )
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"""simple docstring""" class _SCREAMING_SNAKE_CASE : def __init__( self ) -> int: lowerCAmelCase_ :List[str] = """""" lowerCAmelCase_ :List[Any] = """""" lowerCAmelCase_ :Union[str, Any] = [] def __lowerCAmelCase ( self , __A , __A ) -> int: if m == -1: return n + 1 elif n == -1: return m + 1 elif self.dp[m][n] > -1: return self.dp[m][n] else: if self.worda[m] == self.worda[n]: lowerCAmelCase_ :List[Any] = self.__min_dist_top_down_dp(m - 1 , n - 1 ) else: lowerCAmelCase_ :int = self.__min_dist_top_down_dp(__A , n - 1 ) lowerCAmelCase_ :Dict = self.__min_dist_top_down_dp(m - 1 , __A ) lowerCAmelCase_ :Optional[int] = self.__min_dist_top_down_dp(m - 1 , n - 1 ) lowerCAmelCase_ :Tuple = 1 + min(__A , __A , __A ) return self.dp[m][n] def __lowerCAmelCase ( self , __A , __A ) -> int: lowerCAmelCase_ :List[str] = worda lowerCAmelCase_ :int = worda lowerCAmelCase_ :int = [[-1 for _ in range(len(__A ) )] for _ in range(len(__A ) )] return self.__min_dist_top_down_dp(len(__A ) - 1 , len(__A ) - 1 ) def __lowerCAmelCase ( self , __A , __A ) -> int: lowerCAmelCase_ :Optional[Any] = worda lowerCAmelCase_ :Dict = worda lowerCAmelCase_ :str = len(__A ) lowerCAmelCase_ :Union[str, Any] = len(__A ) lowerCAmelCase_ :List[str] = [[0 for _ in range(n + 1 )] for _ in range(m + 1 )] for i in range(m + 1 ): for j in range(n + 1 ): if i == 0: # first string is empty lowerCAmelCase_ :int = j elif j == 0: # second string is empty lowerCAmelCase_ :int = i elif worda[i - 1] == worda[j - 1]: # last characters are equal lowerCAmelCase_ :Union[str, Any] = self.dp[i - 1][j - 1] else: lowerCAmelCase_ :Union[str, Any] = self.dp[i][j - 1] lowerCAmelCase_ :Tuple = self.dp[i - 1][j] lowerCAmelCase_ :Dict = self.dp[i - 1][j - 1] lowerCAmelCase_ :Tuple = 1 + min(__A , __A , __A ) return self.dp[m][n] if __name__ == "__main__": __UpperCAmelCase = EditDistance() print('****************** Testing Edit Distance DP Algorithm ******************') print() __UpperCAmelCase = input('Enter the first string: ').strip() __UpperCAmelCase = input('Enter the second string: ').strip() print() print(F"""The minimum edit distance is: {solver.min_dist_top_down(Sa, Sa)}""") print(F"""The minimum edit distance is: {solver.min_dist_bottom_up(Sa, Sa)}""") print() print('*************** End of Testing Edit Distance DP Algorithm ***************')
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from __future__ import annotations # This is the precision for this function which can be altered. # It is recommended for users to keep this number greater than or equal to 10. __A = 10 def lowerCamelCase_ ( UpperCamelCase__ : int , UpperCamelCase__ : int , UpperCamelCase__ : list[int] , UpperCamelCase__ : int ) -> int: """simple docstring""" for i in range(UpperCamelCase__ , UpperCamelCase__ ): if array[i] == target: return i return -1 def lowerCamelCase_ ( UpperCamelCase__ : list[int] , UpperCamelCase__ : int ) -> int: """simple docstring""" __lowerCamelCase = 0 __lowerCamelCase = len(UpperCamelCase__ ) while left <= right: if right - left < precision: return lin_search(UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ ) __lowerCamelCase = (left + right) // 3 + 1 __lowerCamelCase = 2 * (left + right) // 3 + 1 if array[one_third] == target: return one_third elif array[two_third] == target: return two_third elif target < array[one_third]: __lowerCamelCase = one_third - 1 elif array[two_third] < target: __lowerCamelCase = two_third + 1 else: __lowerCamelCase = one_third + 1 __lowerCamelCase = two_third - 1 else: return -1 def lowerCamelCase_ ( UpperCamelCase__ : int , UpperCamelCase__ : int , UpperCamelCase__ : list[int] , UpperCamelCase__ : int ) -> int: """simple docstring""" if left < right: if right - left < precision: return lin_search(UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ ) __lowerCamelCase = (left + right) // 3 + 1 __lowerCamelCase = 2 * (left + right) // 3 + 1 if array[one_third] == target: return one_third elif array[two_third] == target: return two_third elif target < array[one_third]: return rec_ternary_search(UpperCamelCase__ , one_third - 1 , UpperCamelCase__ , UpperCamelCase__ ) elif array[two_third] < target: return rec_ternary_search(two_third + 1 , UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ ) else: return rec_ternary_search(one_third + 1 , two_third - 1 , UpperCamelCase__ , UpperCamelCase__ ) else: return -1 if __name__ == "__main__": import doctest doctest.testmod() __A = input("Enter numbers separated by comma:\n").strip() __A = [int(item.strip()) for item in user_input.split(",")] assert collection == sorted(collection), f"List must be ordered.\n{collection}." __A = int(input("Enter the number to be found in the list:\n").strip()) __A = ite_ternary_search(collection, target) __A = rec_ternary_search(0, len(collection) - 1, collection, target) if resulta != -1: print(f'''Iterative search: {target} found at positions: {resulta}''') print(f'''Recursive search: {target} found at positions: {resulta}''') else: print("Not found")
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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 CLIPTokenizer, CLIPTokenizerFast from transformers.models.clip.tokenization_clip 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 CLIPImageProcessor, CLIPProcessor @require_vision class _snake_case ( unittest.TestCase ): def lowerCAmelCase__ ( self ) -> List[Any]: '''simple docstring''' snake_case_ = tempfile.mkdtemp() # fmt: off snake_case_ = ["l", "o", "w", "e", "r", "s", "t", "i", "d", "n", "lo", "l</w>", "w</w>", "r</w>", "t</w>", "low</w>", "er</w>", "lowest</w>", "newer</w>", "wider", "<unk>", "<|startoftext|>", "<|endoftext|>"] # fmt: on snake_case_ = dict(zip(a__ , range(len(a__ ) ) ) ) snake_case_ = ["#version: 0.2", "l o", "lo w</w>", "e r</w>", ""] snake_case_ = {"unk_token": "<unk>"} snake_case_ = os.path.join(self.tmpdirname , VOCAB_FILES_NAMES["vocab_file"] ) snake_case_ = os.path.join(self.tmpdirname , VOCAB_FILES_NAMES["merges_file"] ) with open(self.vocab_file , "w" , encoding="utf-8" ) as fp: fp.write(json.dumps(a__ ) + "\n" ) with open(self.merges_file , "w" , encoding="utf-8" ) as fp: fp.write("\n".join(a__ ) ) snake_case_ = { "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_ = os.path.join(self.tmpdirname , a__ ) with open(self.image_processor_file , "w" , encoding="utf-8" ) as fp: json.dump(a__ , a__ ) def lowerCAmelCase__ ( self , **a__ ) -> Dict: '''simple docstring''' return CLIPTokenizer.from_pretrained(self.tmpdirname , **a__ ) def lowerCAmelCase__ ( self , **a__ ) -> List[str]: '''simple docstring''' return CLIPTokenizerFast.from_pretrained(self.tmpdirname , **a__ ) def lowerCAmelCase__ ( self , **a__ ) -> Tuple: '''simple docstring''' return CLIPImageProcessor.from_pretrained(self.tmpdirname , **a__ ) def lowerCAmelCase__ ( self ) -> List[str]: '''simple docstring''' shutil.rmtree(self.tmpdirname ) def lowerCAmelCase__ ( self ) -> Dict: '''simple docstring''' snake_case_ = [np.random.randint(255 , size=(3, 30, 400) , dtype=np.uinta )] snake_case_ = [Image.fromarray(np.moveaxis(a__ , 0 , -1 ) ) for x in image_inputs] return image_inputs def lowerCAmelCase__ ( self ) -> Optional[int]: '''simple docstring''' snake_case_ = self.get_tokenizer() snake_case_ = self.get_rust_tokenizer() snake_case_ = self.get_image_processor() snake_case_ = CLIPProcessor(tokenizer=a__ , image_processor=a__ ) processor_slow.save_pretrained(self.tmpdirname ) snake_case_ = CLIPProcessor.from_pretrained(self.tmpdirname , use_fast=a__ ) snake_case_ = CLIPProcessor(tokenizer=a__ , image_processor=a__ ) processor_fast.save_pretrained(self.tmpdirname ) snake_case_ = CLIPProcessor.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 , a__ ) self.assertIsInstance(processor_fast.tokenizer , a__ ) 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 , a__ ) self.assertIsInstance(processor_fast.image_processor , a__ ) def lowerCAmelCase__ ( self ) -> Tuple: '''simple docstring''' snake_case_ = CLIPProcessor(tokenizer=self.get_tokenizer() , image_processor=self.get_image_processor() ) processor.save_pretrained(self.tmpdirname ) snake_case_ = self.get_tokenizer(bos_token="(BOS)" , eos_token="(EOS)" ) snake_case_ = self.get_image_processor(do_normalize=a__ , padding_value=1.0 ) snake_case_ = CLIPProcessor.from_pretrained( self.tmpdirname , bos_token="(BOS)" , eos_token="(EOS)" , do_normalize=a__ , padding_value=1.0 ) self.assertEqual(processor.tokenizer.get_vocab() , tokenizer_add_kwargs.get_vocab() ) self.assertIsInstance(processor.tokenizer , a__ ) self.assertEqual(processor.image_processor.to_json_string() , image_processor_add_kwargs.to_json_string() ) self.assertIsInstance(processor.image_processor , a__ ) def lowerCAmelCase__ ( self ) -> Dict: '''simple docstring''' snake_case_ = self.get_image_processor() snake_case_ = self.get_tokenizer() snake_case_ = CLIPProcessor(tokenizer=a__ , image_processor=a__ ) snake_case_ = self.prepare_image_inputs() snake_case_ = image_processor(a__ , return_tensors="np" ) snake_case_ = processor(images=a__ , 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 ) -> Dict: '''simple docstring''' snake_case_ = self.get_image_processor() snake_case_ = self.get_tokenizer() snake_case_ = CLIPProcessor(tokenizer=a__ , image_processor=a__ ) snake_case_ = "lower newer" snake_case_ = processor(text=a__ ) snake_case_ = tokenizer(a__ ) for key in encoded_tok.keys(): self.assertListEqual(encoded_tok[key] , encoded_processor[key] ) def lowerCAmelCase__ ( self ) -> Optional[int]: '''simple docstring''' snake_case_ = self.get_image_processor() snake_case_ = self.get_tokenizer() snake_case_ = CLIPProcessor(tokenizer=a__ , image_processor=a__ ) snake_case_ = "lower newer" snake_case_ = self.prepare_image_inputs() snake_case_ = processor(text=a__ , images=a__ ) self.assertListEqual(list(inputs.keys() ) , ["input_ids", "attention_mask", "pixel_values"] ) # test if it raises when no input is passed with pytest.raises(a__ ): processor() def lowerCAmelCase__ ( self ) -> Any: '''simple docstring''' snake_case_ = self.get_image_processor() snake_case_ = self.get_tokenizer() snake_case_ = CLIPProcessor(tokenizer=a__ , image_processor=a__ ) snake_case_ = [[1, 4, 5, 8, 1, 0, 8], [3, 4, 3, 1, 1, 8, 9]] snake_case_ = processor.batch_decode(a__ ) snake_case_ = tokenizer.batch_decode(a__ ) self.assertListEqual(a__ , a__ ) def lowerCAmelCase__ ( self ) -> str: '''simple docstring''' snake_case_ = self.get_image_processor() snake_case_ = self.get_tokenizer() snake_case_ = CLIPProcessor(tokenizer=a__ , image_processor=a__ ) snake_case_ = "lower newer" snake_case_ = self.prepare_image_inputs() snake_case_ = processor(text=a__ , images=a__ ) self.assertListEqual(list(inputs.keys() ) , processor.model_input_names )
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import string # frequency taken from https://en.wikipedia.org/wiki/Letter_frequency __A = { "E": 1_2.7_0, "T": 9.0_6, "A": 8.1_7, "O": 7.5_1, "I": 6.9_7, "N": 6.7_5, "S": 6.3_3, "H": 6.0_9, "R": 5.9_9, "D": 4.2_5, "L": 4.0_3, "C": 2.7_8, "U": 2.7_6, "M": 2.4_1, "W": 2.3_6, "F": 2.2_3, "G": 2.0_2, "Y": 1.9_7, "P": 1.9_3, "B": 1.2_9, "V": 0.9_8, "K": 0.7_7, "J": 0.1_5, "X": 0.1_5, "Q": 0.1_0, "Z": 0.0_7, } __A = "ETAOINSHRDLCUMWFGYPBVKJXQZ" __A = "ABCDEFGHIJKLMNOPQRSTUVWXYZ" def lowerCamelCase_ ( UpperCamelCase__ : str ) -> dict[str, int]: """simple docstring""" __lowerCamelCase = {letter: 0 for letter in string.ascii_uppercase} for letter in message.upper(): if letter in LETTERS: letter_count[letter] += 1 return letter_count def lowerCamelCase_ ( UpperCamelCase__ : tuple ) -> str: """simple docstring""" return x[0] def lowerCamelCase_ ( UpperCamelCase__ : str ) -> str: """simple docstring""" __lowerCamelCase = get_letter_count(UpperCamelCase__ ) __lowerCamelCase = { freq: [] for letter, freq in letter_to_freq.items() } for letter in LETTERS: freq_to_letter[letter_to_freq[letter]].append(UpperCamelCase__ ) __lowerCamelCase = {} for freq in freq_to_letter: freq_to_letter[freq].sort(key=ETAOIN.find , reverse=UpperCamelCase__ ) __lowerCamelCase = ''.join(freq_to_letter[freq] ) __lowerCamelCase = list(freq_to_letter_str.items() ) freq_pairs.sort(key=UpperCamelCase__ , reverse=UpperCamelCase__ ) __lowerCamelCase = [freq_pair[1] for freq_pair in freq_pairs] return "".join(UpperCamelCase__ ) def lowerCamelCase_ ( UpperCamelCase__ : str ) -> int: """simple docstring""" __lowerCamelCase = get_frequency_order(UpperCamelCase__ ) __lowerCamelCase = 0 for common_letter in ETAOIN[:6]: if common_letter in freq_order[:6]: match_score += 1 for uncommon_letter in ETAOIN[-6:]: if uncommon_letter in freq_order[-6:]: match_score += 1 return match_score if __name__ == "__main__": import doctest doctest.testmod()
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"""simple docstring""" import gc import unittest import numpy as np import torch from diffusers import AutoencoderKL, DDIMScheduler, DiTPipeline, DPMSolverMultistepScheduler, TransformeraDModel from diffusers.utils import is_xformers_available, load_numpy, slow, torch_device from diffusers.utils.testing_utils import enable_full_determinism, require_torch_gpu from ..pipeline_params import ( CLASS_CONDITIONED_IMAGE_GENERATION_BATCH_PARAMS, CLASS_CONDITIONED_IMAGE_GENERATION_PARAMS, ) from ..test_pipelines_common import PipelineTesterMixin enable_full_determinism() class A__ ( _lowerCamelCase , unittest.TestCase): A_ : Union[str, Any] = DiTPipeline A_ : Union[str, Any] = CLASS_CONDITIONED_IMAGE_GENERATION_PARAMS A_ : List[Any] = PipelineTesterMixin.required_optional_params - { 'latents', 'num_images_per_prompt', 'callback', 'callback_steps', } A_ : Optional[Any] = CLASS_CONDITIONED_IMAGE_GENERATION_BATCH_PARAMS A_ : Tuple = False def __lowerCamelCase ( self ): torch.manual_seed(0 ) __lowerCAmelCase : List[str] = TransformeraDModel( sample_size=16 , num_layers=2 , patch_size=4 , attention_head_dim=8 , num_attention_heads=2 , in_channels=4 , out_channels=8 , attention_bias=_SCREAMING_SNAKE_CASE , activation_fn='gelu-approximate' , num_embeds_ada_norm=10_00 , norm_type='ada_norm_zero' , norm_elementwise_affine=_SCREAMING_SNAKE_CASE , ) __lowerCAmelCase : str = AutoencoderKL() __lowerCAmelCase : Union[str, Any] = DDIMScheduler() __lowerCAmelCase : Dict = {'transformer': transformer.eval(), 'vae': vae.eval(), 'scheduler': scheduler} return components def __lowerCamelCase ( self , _SCREAMING_SNAKE_CASE , _SCREAMING_SNAKE_CASE=0 ): if str(_SCREAMING_SNAKE_CASE ).startswith('mps' ): __lowerCAmelCase : List[str] = torch.manual_seed(_SCREAMING_SNAKE_CASE ) else: __lowerCAmelCase : List[str] = torch.Generator(device=_SCREAMING_SNAKE_CASE ).manual_seed(_SCREAMING_SNAKE_CASE ) __lowerCAmelCase : Any = { 'class_labels': [1], 'generator': generator, 'num_inference_steps': 2, 'output_type': 'numpy', } return inputs def __lowerCamelCase ( self ): __lowerCAmelCase : List[str] = 'cpu' __lowerCAmelCase : Any = self.get_dummy_components() __lowerCAmelCase : Union[str, Any] = self.pipeline_class(**_SCREAMING_SNAKE_CASE ) pipe.to(_SCREAMING_SNAKE_CASE ) pipe.set_progress_bar_config(disable=_SCREAMING_SNAKE_CASE ) __lowerCAmelCase : Tuple = self.get_dummy_inputs(_SCREAMING_SNAKE_CASE ) __lowerCAmelCase : List[str] = pipe(**_SCREAMING_SNAKE_CASE ).images __lowerCAmelCase : List[str] = image[0, -3:, -3:, -1] self.assertEqual(image.shape , (1, 16, 16, 3) ) __lowerCAmelCase : Optional[int] = np.array([0.2946, 0.6601, 0.4329, 0.3296, 0.4144, 0.5319, 0.7273, 0.5013, 0.4457] ) __lowerCAmelCase : List[Any] = np.abs(image_slice.flatten() - expected_slice ).max() self.assertLessEqual(_SCREAMING_SNAKE_CASE , 1E-3 ) def __lowerCamelCase ( self ): self._test_inference_batch_single_identical(relax_max_difference=_SCREAMING_SNAKE_CASE , expected_max_diff=1E-3 ) @unittest.skipIf( torch_device != 'cuda' or not is_xformers_available() , reason='XFormers attention is only available with CUDA and `xformers` installed' , ) def __lowerCamelCase ( self ): self._test_xformers_attention_forwardGenerator_pass(expected_max_diff=1E-3 ) @require_torch_gpu @slow class A__ ( unittest.TestCase): def __lowerCamelCase ( self ): super().tearDown() gc.collect() torch.cuda.empty_cache() def __lowerCamelCase ( self ): __lowerCAmelCase : Dict = torch.manual_seed(0 ) __lowerCAmelCase : int = DiTPipeline.from_pretrained('facebook/DiT-XL-2-256' ) pipe.to('cuda' ) __lowerCAmelCase : Optional[Any] = ['vase', 'umbrella', 'white shark', 'white wolf'] __lowerCAmelCase : Optional[Any] = pipe.get_label_ids(_SCREAMING_SNAKE_CASE ) __lowerCAmelCase : Optional[Any] = pipe(_SCREAMING_SNAKE_CASE , generator=_SCREAMING_SNAKE_CASE , num_inference_steps=40 , output_type='np' ).images for word, image in zip(_SCREAMING_SNAKE_CASE , _SCREAMING_SNAKE_CASE ): __lowerCAmelCase : Tuple = load_numpy( f"https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main/dit/{word}.npy" ) assert np.abs((expected_image - image).max() ) < 1E-2 def __lowerCamelCase ( self ): __lowerCAmelCase : Any = DiTPipeline.from_pretrained('facebook/DiT-XL-2-512' ) __lowerCAmelCase : Union[str, Any] = DPMSolverMultistepScheduler.from_config(pipe.scheduler.config ) pipe.to('cuda' ) __lowerCAmelCase : Dict = ['vase', 'umbrella'] __lowerCAmelCase : List[str] = pipe.get_label_ids(_SCREAMING_SNAKE_CASE ) __lowerCAmelCase : Any = torch.manual_seed(0 ) __lowerCAmelCase : Optional[Any] = pipe(_SCREAMING_SNAKE_CASE , generator=_SCREAMING_SNAKE_CASE , num_inference_steps=25 , output_type='np' ).images for word, image in zip(_SCREAMING_SNAKE_CASE , _SCREAMING_SNAKE_CASE ): __lowerCAmelCase : Dict = load_numpy( 'https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main' f"/dit/{word}_512.npy" ) assert np.abs((expected_image - image).max() ) < 1E-1
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class __lowerCAmelCase : """simple docstring""" def __init__( self , lowerCamelCase__ ) -> Any: '''simple docstring''' __lowerCamelCase = n __lowerCamelCase = [None] * self.n __lowerCamelCase = 0 # index of the first element __lowerCamelCase = 0 __lowerCamelCase = 0 def __len__( self ) -> int: '''simple docstring''' return self.size def lowercase_ ( self ) -> bool: '''simple docstring''' return self.size == 0 def lowercase_ ( self ) -> str: '''simple docstring''' return False if self.is_empty() else self.array[self.front] def lowercase_ ( self , lowerCamelCase__ ) -> Optional[Any]: '''simple docstring''' if self.size >= self.n: raise Exception('QUEUE IS FULL' ) __lowerCamelCase = data __lowerCamelCase = (self.rear + 1) % self.n self.size += 1 return self def lowercase_ ( self ) -> Tuple: '''simple docstring''' if self.size == 0: raise Exception('UNDERFLOW' ) __lowerCamelCase = self.array[self.front] __lowerCamelCase = None __lowerCamelCase = (self.front + 1) % self.n self.size -= 1 return temp
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from ...configuration_utils import PretrainedConfig from ...utils import logging UpperCamelCase = logging.get_logger(__name__) UpperCamelCase = {'''ctrl''': '''https://huggingface.co/ctrl/resolve/main/config.json'''} class snake_case_ ( __A ): __A : str = "ctrl" __A : Tuple = ["past_key_values"] __A : Optional[int] = { "max_position_embeddings": "n_positions", "hidden_size": "n_embd", "num_attention_heads": "n_head", "num_hidden_layers": "n_layer", } def __init__( self : Dict , lowercase_ : Tuple=24_65_34 , lowercase_ : List[str]=2_56 , lowercase_ : Tuple=12_80 , lowercase_ : List[Any]=81_92 , lowercase_ : Union[str, Any]=48 , lowercase_ : Any=16 , lowercase_ : List[str]=0.1 , lowercase_ : Any=0.1 , lowercase_ : Optional[Any]=1E-6 , lowercase_ : Optional[Any]=0.02 , lowercase_ : Optional[int]=True , **lowercase_ : Optional[Any] , ) -> Optional[int]: lowercase__ : Union[str, Any] = vocab_size lowercase__ : Optional[Any] = n_positions lowercase__ : Optional[Any] = n_embd lowercase__ : Tuple = n_layer lowercase__ : List[str] = n_head lowercase__ : Union[str, Any] = dff lowercase__ : Dict = resid_pdrop lowercase__ : Any = embd_pdrop lowercase__ : List[str] = layer_norm_epsilon lowercase__ : int = initializer_range lowercase__ : Union[str, Any] = use_cache super().__init__(**lowercase_ )
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import unittest import numpy as np from transformers.testing_utils import require_flax, require_tf, require_torch from transformers.utils import ( expand_dims, flatten_dict, is_flax_available, is_tf_available, is_torch_available, reshape, squeeze, transpose, ) if is_flax_available(): import jax.numpy as jnp if is_tf_available(): import tensorflow as tf if is_torch_available(): import torch class __lowerCAmelCase ( unittest.TestCase ): """simple docstring""" def lowercase_ ( self ) -> Tuple: '''simple docstring''' __lowerCamelCase = { 'task_specific_params': { 'summarization': {'length_penalty': 1.0, 'max_length': 128, 'min_length': 12, 'num_beams': 4}, 'summarization_cnn': {'length_penalty': 2.0, 'max_length': 142, 'min_length': 56, 'num_beams': 4}, 'summarization_xsum': {'length_penalty': 1.0, 'max_length': 62, 'min_length': 11, 'num_beams': 6}, } } __lowerCamelCase = { 'task_specific_params.summarization.length_penalty': 1.0, 'task_specific_params.summarization.max_length': 128, 'task_specific_params.summarization.min_length': 12, 'task_specific_params.summarization.num_beams': 4, 'task_specific_params.summarization_cnn.length_penalty': 2.0, 'task_specific_params.summarization_cnn.max_length': 142, 'task_specific_params.summarization_cnn.min_length': 56, 'task_specific_params.summarization_cnn.num_beams': 4, 'task_specific_params.summarization_xsum.length_penalty': 1.0, 'task_specific_params.summarization_xsum.max_length': 62, 'task_specific_params.summarization_xsum.min_length': 11, 'task_specific_params.summarization_xsum.num_beams': 6, } self.assertEqual(flatten_dict(lowerCamelCase__ ) , lowerCamelCase__ ) def lowercase_ ( self ) -> Tuple: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) self.assertTrue(np.allclose(transpose(lowerCamelCase__ ) , x.transpose() ) ) __lowerCamelCase = np.random.randn(3 , 4 , 5 ) self.assertTrue(np.allclose(transpose(lowerCamelCase__ , axes=(1, 2, 0) ) , x.transpose((1, 2, 0) ) ) ) @require_torch def lowercase_ ( self ) -> int: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) __lowerCamelCase = torch.tensor(lowerCamelCase__ ) self.assertTrue(np.allclose(transpose(lowerCamelCase__ ) , transpose(lowerCamelCase__ ).numpy() ) ) __lowerCamelCase = np.random.randn(3 , 4 , 5 ) __lowerCamelCase = torch.tensor(lowerCamelCase__ ) self.assertTrue(np.allclose(transpose(lowerCamelCase__ , axes=(1, 2, 0) ) , transpose(lowerCamelCase__ , axes=(1, 2, 0) ).numpy() ) ) @require_tf def lowercase_ ( self ) -> Union[str, Any]: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) __lowerCamelCase = tf.constant(lowerCamelCase__ ) self.assertTrue(np.allclose(transpose(lowerCamelCase__ ) , transpose(lowerCamelCase__ ).numpy() ) ) __lowerCamelCase = np.random.randn(3 , 4 , 5 ) __lowerCamelCase = tf.constant(lowerCamelCase__ ) self.assertTrue(np.allclose(transpose(lowerCamelCase__ , axes=(1, 2, 0) ) , transpose(lowerCamelCase__ , axes=(1, 2, 0) ).numpy() ) ) @require_flax def lowercase_ ( self ) -> Optional[int]: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) __lowerCamelCase = jnp.array(lowerCamelCase__ ) self.assertTrue(np.allclose(transpose(lowerCamelCase__ ) , np.asarray(transpose(lowerCamelCase__ ) ) ) ) __lowerCamelCase = np.random.randn(3 , 4 , 5 ) __lowerCamelCase = jnp.array(lowerCamelCase__ ) self.assertTrue(np.allclose(transpose(lowerCamelCase__ , axes=(1, 2, 0) ) , np.asarray(transpose(lowerCamelCase__ , axes=(1, 2, 0) ) ) ) ) def lowercase_ ( self ) -> int: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) self.assertTrue(np.allclose(reshape(lowerCamelCase__ , (4, 3) ) , np.reshape(lowerCamelCase__ , (4, 3) ) ) ) __lowerCamelCase = np.random.randn(3 , 4 , 5 ) self.assertTrue(np.allclose(reshape(lowerCamelCase__ , (12, 5) ) , np.reshape(lowerCamelCase__ , (12, 5) ) ) ) @require_torch def lowercase_ ( self ) -> List[Any]: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) __lowerCamelCase = torch.tensor(lowerCamelCase__ ) self.assertTrue(np.allclose(reshape(lowerCamelCase__ , (4, 3) ) , reshape(lowerCamelCase__ , (4, 3) ).numpy() ) ) __lowerCamelCase = np.random.randn(3 , 4 , 5 ) __lowerCamelCase = torch.tensor(lowerCamelCase__ ) self.assertTrue(np.allclose(reshape(lowerCamelCase__ , (12, 5) ) , reshape(lowerCamelCase__ , (12, 5) ).numpy() ) ) @require_tf def lowercase_ ( self ) -> Optional[int]: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) __lowerCamelCase = tf.constant(lowerCamelCase__ ) self.assertTrue(np.allclose(reshape(lowerCamelCase__ , (4, 3) ) , reshape(lowerCamelCase__ , (4, 3) ).numpy() ) ) __lowerCamelCase = np.random.randn(3 , 4 , 5 ) __lowerCamelCase = tf.constant(lowerCamelCase__ ) self.assertTrue(np.allclose(reshape(lowerCamelCase__ , (12, 5) ) , reshape(lowerCamelCase__ , (12, 5) ).numpy() ) ) @require_flax def lowercase_ ( self ) -> Tuple: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) __lowerCamelCase = jnp.array(lowerCamelCase__ ) self.assertTrue(np.allclose(reshape(lowerCamelCase__ , (4, 3) ) , np.asarray(reshape(lowerCamelCase__ , (4, 3) ) ) ) ) __lowerCamelCase = np.random.randn(3 , 4 , 5 ) __lowerCamelCase = jnp.array(lowerCamelCase__ ) self.assertTrue(np.allclose(reshape(lowerCamelCase__ , (12, 5) ) , np.asarray(reshape(lowerCamelCase__ , (12, 5) ) ) ) ) def lowercase_ ( self ) -> int: '''simple docstring''' __lowerCamelCase = np.random.randn(1 , 3 , 4 ) self.assertTrue(np.allclose(squeeze(lowerCamelCase__ ) , np.squeeze(lowerCamelCase__ ) ) ) __lowerCamelCase = np.random.randn(1 , 4 , 1 , 5 ) self.assertTrue(np.allclose(squeeze(lowerCamelCase__ , axis=2 ) , np.squeeze(lowerCamelCase__ , axis=2 ) ) ) @require_torch def lowercase_ ( self ) -> int: '''simple docstring''' __lowerCamelCase = np.random.randn(1 , 3 , 4 ) __lowerCamelCase = torch.tensor(lowerCamelCase__ ) self.assertTrue(np.allclose(squeeze(lowerCamelCase__ ) , squeeze(lowerCamelCase__ ).numpy() ) ) __lowerCamelCase = np.random.randn(1 , 4 , 1 , 5 ) __lowerCamelCase = torch.tensor(lowerCamelCase__ ) self.assertTrue(np.allclose(squeeze(lowerCamelCase__ , axis=2 ) , squeeze(lowerCamelCase__ , axis=2 ).numpy() ) ) @require_tf def lowercase_ ( self ) -> Union[str, Any]: '''simple docstring''' __lowerCamelCase = np.random.randn(1 , 3 , 4 ) __lowerCamelCase = tf.constant(lowerCamelCase__ ) self.assertTrue(np.allclose(squeeze(lowerCamelCase__ ) , squeeze(lowerCamelCase__ ).numpy() ) ) __lowerCamelCase = np.random.randn(1 , 4 , 1 , 5 ) __lowerCamelCase = tf.constant(lowerCamelCase__ ) self.assertTrue(np.allclose(squeeze(lowerCamelCase__ , axis=2 ) , squeeze(lowerCamelCase__ , axis=2 ).numpy() ) ) @require_flax def lowercase_ ( self ) -> List[str]: '''simple docstring''' __lowerCamelCase = np.random.randn(1 , 3 , 4 ) __lowerCamelCase = jnp.array(lowerCamelCase__ ) self.assertTrue(np.allclose(squeeze(lowerCamelCase__ ) , np.asarray(squeeze(lowerCamelCase__ ) ) ) ) __lowerCamelCase = np.random.randn(1 , 4 , 1 , 5 ) __lowerCamelCase = jnp.array(lowerCamelCase__ ) self.assertTrue(np.allclose(squeeze(lowerCamelCase__ , axis=2 ) , np.asarray(squeeze(lowerCamelCase__ , axis=2 ) ) ) ) def lowercase_ ( self ) -> int: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) self.assertTrue(np.allclose(expand_dims(lowerCamelCase__ , axis=1 ) , np.expand_dims(lowerCamelCase__ , axis=1 ) ) ) @require_torch def lowercase_ ( self ) -> Any: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) __lowerCamelCase = torch.tensor(lowerCamelCase__ ) self.assertTrue(np.allclose(expand_dims(lowerCamelCase__ , axis=1 ) , expand_dims(lowerCamelCase__ , axis=1 ).numpy() ) ) @require_tf def lowercase_ ( self ) -> Any: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) __lowerCamelCase = tf.constant(lowerCamelCase__ ) self.assertTrue(np.allclose(expand_dims(lowerCamelCase__ , axis=1 ) , expand_dims(lowerCamelCase__ , axis=1 ).numpy() ) ) @require_flax def lowercase_ ( self ) -> List[Any]: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) __lowerCamelCase = jnp.array(lowerCamelCase__ ) self.assertTrue(np.allclose(expand_dims(lowerCamelCase__ , axis=1 ) , np.asarray(expand_dims(lowerCamelCase__ , axis=1 ) ) ) )
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import importlib import shutil import threading import warnings from typing import List import fsspec import fsspec.asyn from . import compression from .hffilesystem import HfFileSystem __lowerCAmelCase : Optional[Any] = importlib.util.find_spec('s3fs') is not None if _has_safs: from .safilesystem import SaFileSystem # noqa: F401 __lowerCAmelCase : List[compression.BaseCompressedFileFileSystem] = [ compression.BzaFileSystem, compression.GzipFileSystem, compression.LzaFileSystem, compression.XzFileSystem, compression.ZstdFileSystem, ] # Register custom filesystems for fs_class in COMPRESSION_FILESYSTEMS + [HfFileSystem]: if fs_class.protocol in fsspec.registry and fsspec.registry[fs_class.protocol] is not fs_class: warnings.warn(F'''A filesystem protocol was already set for {fs_class.protocol} and will be overwritten.''') fsspec.register_implementation(fs_class.protocol, fs_class, clobber=True) def a__ ( A_ ): '''simple docstring''' if "://" in dataset_path: __magic_name__ = dataset_path.split("""://""" )[1] return dataset_path def a__ ( A_ ): '''simple docstring''' if fs is not None and fs.protocol != "file": return True else: return False def a__ ( A_, A_, A_ ): '''simple docstring''' __magic_name__ = not is_remote_filesystem(A_ ) if is_local: # LocalFileSystem.mv does copy + rm, it is more efficient to simply move a local directory shutil.move(fs._strip_protocol(A_ ), fs._strip_protocol(A_ ) ) else: fs.mv(A_, A_, recursive=A_ ) def a__ ( ): '''simple docstring''' if hasattr(fsspec.asyn, """reset_lock""" ): # for future fsspec>2022.05.0 fsspec.asyn.reset_lock() else: __magic_name__ = None __magic_name__ = None __magic_name__ = threading.Lock()
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import copy import inspect import unittest import numpy as np from huggingface_hub import hf_hub_download from transformers import TimesformerConfig from transformers.models.auto import get_values 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, floats_tensor, ids_tensor from ...test_pipeline_mixin import PipelineTesterMixin if is_torch_available(): import torch from torch import nn from transformers import ( MODEL_FOR_VIDEO_CLASSIFICATION_MAPPING, TimesformerForVideoClassification, TimesformerModel, ) from transformers.models.timesformer.modeling_timesformer import TIMESFORMER_PRETRAINED_MODEL_ARCHIVE_LIST if is_vision_available(): from transformers import VideoMAEImageProcessor class __lowerCAmelCase : """simple docstring""" def __init__( self , lowerCamelCase__ , lowerCamelCase__=13 , lowerCamelCase__=10 , lowerCamelCase__=3 , lowerCamelCase__=2 , lowerCamelCase__=2 , lowerCamelCase__=True , lowerCamelCase__=True , lowerCamelCase__=32 , lowerCamelCase__=5 , lowerCamelCase__=4 , lowerCamelCase__=37 , lowerCamelCase__="gelu" , lowerCamelCase__=0.1 , lowerCamelCase__=0.1 , lowerCamelCase__=10 , lowerCamelCase__=0.02 , lowerCamelCase__="divided_space_time" , lowerCamelCase__=None , ) -> Any: '''simple docstring''' __lowerCamelCase = parent __lowerCamelCase = batch_size __lowerCamelCase = image_size __lowerCamelCase = num_channels __lowerCamelCase = patch_size __lowerCamelCase = num_frames __lowerCamelCase = is_training __lowerCamelCase = use_labels __lowerCamelCase = hidden_size __lowerCamelCase = num_hidden_layers __lowerCamelCase = num_attention_heads __lowerCamelCase = intermediate_size __lowerCamelCase = hidden_act __lowerCamelCase = hidden_dropout_prob __lowerCamelCase = attention_probs_dropout_prob __lowerCamelCase = attention_type __lowerCamelCase = initializer_range __lowerCamelCase = scope __lowerCamelCase = num_labels # in TimeSformer, the number of spatial tokens equals num_frames * num_patches per frame + 1 CLS token __lowerCamelCase = (image_size // patch_size) ** 2 __lowerCamelCase = (num_frames) * self.num_patches_per_frame + 1 def lowercase_ ( self ) -> Optional[int]: '''simple docstring''' __lowerCamelCase = floats_tensor( [self.batch_size, self.num_frames, self.num_channels, self.image_size, self.image_size] ) __lowerCamelCase = None if self.use_labels: __lowerCamelCase = ids_tensor([self.batch_size] , self.num_labels ) __lowerCamelCase = self.get_config() return config, pixel_values, labels def lowercase_ ( self ) -> Union[str, Any]: '''simple docstring''' __lowerCamelCase = TimesformerConfig( image_size=self.image_size , patch_size=self.patch_size , num_channels=self.num_channels , num_frames=self.num_frames , 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 , initializer_range=self.initializer_range , attention_type=self.attention_type , ) __lowerCamelCase = self.num_labels return config def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> Tuple: '''simple docstring''' __lowerCamelCase = TimesformerModel(config=lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model(lowerCamelCase__ ) self.parent.assertEqual(result.last_hidden_state.shape , (self.batch_size, self.seq_length, self.hidden_size) ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> Union[str, Any]: '''simple docstring''' __lowerCamelCase = TimesformerForVideoClassification(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model(lowerCamelCase__ ) # verify the logits shape __lowerCamelCase = torch.Size((self.batch_size, self.num_labels) ) self.parent.assertEqual(result.logits.shape , lowerCamelCase__ ) def lowercase_ ( self ) -> Tuple: '''simple docstring''' __lowerCamelCase = self.prepare_config_and_inputs() __lowerCamelCase , __lowerCamelCase , __lowerCamelCase = config_and_inputs __lowerCamelCase = {'pixel_values': pixel_values} return config, inputs_dict @require_torch class __lowerCAmelCase ( __magic_name__ , __magic_name__ , unittest.TestCase ): """simple docstring""" snake_case_ = (TimesformerModel, TimesformerForVideoClassification) if is_torch_available() else () snake_case_ = ( {'''feature-extraction''': TimesformerModel, '''video-classification''': TimesformerForVideoClassification} if is_torch_available() else {} ) snake_case_ = False snake_case_ = False snake_case_ = False snake_case_ = False def lowercase_ ( self ) -> List[str]: '''simple docstring''' __lowerCamelCase = TimesformerModelTester(self ) __lowerCamelCase = ConfigTester( self , config_class=lowerCamelCase__ , has_text_modality=lowerCamelCase__ , hidden_size=37 ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__=False ) -> int: '''simple docstring''' __lowerCamelCase = copy.deepcopy(lowerCamelCase__ ) if return_labels: if model_class in get_values(lowerCamelCase__ ): __lowerCamelCase = torch.zeros( self.model_tester.batch_size , dtype=torch.long , device=lowerCamelCase__ ) return inputs_dict def lowercase_ ( self ) -> Optional[int]: '''simple docstring''' self.config_tester.run_common_tests() @unittest.skip(reason='TimeSformer does not use inputs_embeds' ) def lowercase_ ( self ) -> List[str]: '''simple docstring''' pass def lowercase_ ( self ) -> Union[str, Any]: '''simple docstring''' __lowerCamelCase , __lowerCamelCase = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: __lowerCamelCase = model_class(lowerCamelCase__ ) self.assertIsInstance(model.get_input_embeddings() , (nn.Module) ) __lowerCamelCase = model.get_output_embeddings() self.assertTrue(x is None or isinstance(lowerCamelCase__ , nn.Linear ) ) def lowercase_ ( self ) -> List[str]: '''simple docstring''' __lowerCamelCase , __lowerCamelCase = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: __lowerCamelCase = model_class(lowerCamelCase__ ) __lowerCamelCase = inspect.signature(model.forward ) # signature.parameters is an OrderedDict => so arg_names order is deterministic __lowerCamelCase = [*signature.parameters.keys()] __lowerCamelCase = ['pixel_values'] self.assertListEqual(arg_names[:1] , lowerCamelCase__ ) def lowercase_ ( self ) -> Union[str, Any]: '''simple docstring''' __lowerCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_model(*lowerCamelCase__ ) def lowercase_ ( self ) -> str: '''simple docstring''' __lowerCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_for_video_classification(*lowerCamelCase__ ) @slow def lowercase_ ( self ) -> Dict: '''simple docstring''' for model_name in TIMESFORMER_PRETRAINED_MODEL_ARCHIVE_LIST[:1]: __lowerCamelCase = TimesformerModel.from_pretrained(lowerCamelCase__ ) self.assertIsNotNone(lowerCamelCase__ ) def lowercase_ ( self ) -> List[Any]: '''simple docstring''' if not self.has_attentions: pass else: __lowerCamelCase , __lowerCamelCase = self.model_tester.prepare_config_and_inputs_for_common() __lowerCamelCase = True for model_class in self.all_model_classes: __lowerCamelCase = self.model_tester.seq_length __lowerCamelCase = self.model_tester.num_frames __lowerCamelCase = True __lowerCamelCase = False __lowerCamelCase = True __lowerCamelCase = model_class(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() with torch.no_grad(): __lowerCamelCase = model(**self._prepare_for_class(lowerCamelCase__ , lowerCamelCase__ ) ) __lowerCamelCase = outputs.attentions self.assertEqual(len(lowerCamelCase__ ) , self.model_tester.num_hidden_layers ) # check that output_attentions also work using config del inputs_dict["output_attentions"] __lowerCamelCase = True __lowerCamelCase = model_class(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() with torch.no_grad(): __lowerCamelCase = model(**self._prepare_for_class(lowerCamelCase__ , lowerCamelCase__ ) ) __lowerCamelCase = outputs.attentions self.assertEqual(len(lowerCamelCase__ ) , self.model_tester.num_hidden_layers ) # attentions has shape (batch_size x num_frames) x num_heads x (num_patches per frame + 1) x (num_patches per frame + 1) self.assertListEqual( list(attentions[0].shape[-3:] ) , [self.model_tester.num_attention_heads, seq_len // num_frames + 1, seq_len // num_frames + 1] , ) __lowerCamelCase = len(lowerCamelCase__ ) # Check attention is always last and order is fine __lowerCamelCase = True __lowerCamelCase = True __lowerCamelCase = model_class(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() with torch.no_grad(): __lowerCamelCase = model(**self._prepare_for_class(lowerCamelCase__ , lowerCamelCase__ ) ) self.assertEqual(out_len + 1 , len(lowerCamelCase__ ) ) __lowerCamelCase = outputs.attentions self.assertEqual(len(lowerCamelCase__ ) , self.model_tester.num_hidden_layers ) # attentions has shape (batch_size x num_frames) x num_heads x (num_patches per frame + 1) x (num_patches per frame + 1) self.assertListEqual( list(self_attentions[0].shape[-3:] ) , [self.model_tester.num_attention_heads, seq_len // num_frames + 1, seq_len // num_frames + 1] , ) def lowercase_ ( self ) -> Tuple: '''simple docstring''' def check_hidden_states_output(lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ): __lowerCamelCase = model_class(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() with torch.no_grad(): __lowerCamelCase = model(**self._prepare_for_class(lowerCamelCase__ , lowerCamelCase__ ) ) __lowerCamelCase = outputs.hidden_states __lowerCamelCase = self.model_tester.num_hidden_layers + 1 self.assertEqual(len(lowerCamelCase__ ) , lowerCamelCase__ ) __lowerCamelCase = self.model_tester.seq_length self.assertListEqual( list(hidden_states[0].shape[-2:] ) , [seq_length, self.model_tester.hidden_size] , ) __lowerCamelCase , __lowerCamelCase = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: __lowerCamelCase = True check_hidden_states_output(lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) # check that output_hidden_states also work using config del inputs_dict["output_hidden_states"] __lowerCamelCase = True check_hidden_states_output(lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) def lowerCamelCase_ ( ) -> Any: """simple docstring""" __lowerCamelCase = hf_hub_download( repo_id='hf-internal-testing/spaghetti-video' , filename='eating_spaghetti.npy' , repo_type='dataset' ) __lowerCamelCase = np.load(UpperCamelCase__ ) return list(UpperCamelCase__ ) @require_torch @require_vision class __lowerCAmelCase ( unittest.TestCase ): """simple docstring""" @cached_property def lowercase_ ( self ) -> List[Any]: '''simple docstring''' # logits were tested with a different mean and std, so we use the same here return ( VideoMAEImageProcessor(image_mean=[0.5, 0.5, 0.5] , image_std=[0.5, 0.5, 0.5] ) if is_vision_available() else None ) @slow def lowercase_ ( self ) -> List[str]: '''simple docstring''' __lowerCamelCase = TimesformerForVideoClassification.from_pretrained('facebook/timesformer-base-finetuned-k400' ).to( lowerCamelCase__ ) __lowerCamelCase = self.default_image_processor __lowerCamelCase = prepare_video() __lowerCamelCase = image_processor(video[:8] , return_tensors='pt' ).to(lowerCamelCase__ ) # forward pass with torch.no_grad(): __lowerCamelCase = model(**lowerCamelCase__ ) # verify the logits __lowerCamelCase = torch.Size((1, 400) ) self.assertEqual(outputs.logits.shape , lowerCamelCase__ ) __lowerCamelCase = torch.tensor([-0.30_16, -0.77_13, -0.42_05] ).to(lowerCamelCase__ ) self.assertTrue(torch.allclose(outputs.logits[0, :3] , lowerCamelCase__ , atol=1e-4 ) )
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'''simple docstring''' import copy from ...configuration_utils import PretrainedConfig from ...utils import logging from ..auto.configuration_auto import CONFIG_MAPPING __lowerCAmelCase = logging.get_logger(__name__) class __magic_name__ ( _UpperCamelCase ): lowerCAmelCase : str = 'upernet' def __init__( self : List[Any] ,_UpperCAmelCase : str=None ,_UpperCAmelCase : List[Any]=512 ,_UpperCAmelCase : int=0.02 ,_UpperCAmelCase : int=[1, 2, 3, 6] ,_UpperCAmelCase : int=True ,_UpperCAmelCase : Dict=0.4 ,_UpperCAmelCase : Optional[int]=384 ,_UpperCAmelCase : Optional[Any]=256 ,_UpperCAmelCase : List[Any]=1 ,_UpperCAmelCase : List[Any]=False ,_UpperCAmelCase : Tuple=255 ,**_UpperCAmelCase : int ,): super().__init__(**_UpperCAmelCase ) if backbone_config is None: logger.info('`backbone_config` is `None`. Initializing the config with the default `ResNet` backbone.' ) _a : List[str] = CONFIG_MAPPING['resnet'](out_features=['stage1', 'stage2', 'stage3', 'stage4'] ) elif isinstance(_UpperCAmelCase ,_UpperCAmelCase ): _a : List[Any] = backbone_config.get('model_type' ) _a : List[str] = CONFIG_MAPPING[backbone_model_type] _a : Optional[int] = config_class.from_dict(_UpperCAmelCase ) _a : Optional[int] = backbone_config _a : Union[str, Any] = hidden_size _a : str = initializer_range _a : Any = pool_scales _a : str = use_auxiliary_head _a : Tuple = auxiliary_loss_weight _a : Optional[Any] = auxiliary_in_channels _a : Union[str, Any] = auxiliary_channels _a : List[str] = auxiliary_num_convs _a : List[str] = auxiliary_concat_input _a : Any = loss_ignore_index def __lowercase ( self : Optional[int] ): _a : int = copy.deepcopy(self.__dict__ ) _a : List[Any] = self.backbone_config.to_dict() _a : Dict = self.__class__.model_type return output
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import json from typing import TYPE_CHECKING, List, Optional, Tuple from tokenizers import pre_tokenizers from ...tokenization_utils_fast import PreTrainedTokenizerFast from ...utils import logging if TYPE_CHECKING: from transformers.pipelines.conversational import Conversation __A = logging.get_logger(__name__) __A = {"vocab_file": "vocab.json", "merges_file": "merges.txt", "tokenizer_file": "tokenizer.json"} __A = { "tokenizer_file": { "EleutherAI/gpt-neox-20b": "https://huggingface.co/EleutherAI/gpt-neox-20b/resolve/main/tokenizer.json", }, } __A = { "gpt-neox-20b": 20_48, } class __lowerCAmelCase ( __magic_name__ ): """simple docstring""" snake_case_ = VOCAB_FILES_NAMES snake_case_ = PRETRAINED_VOCAB_FILES_MAP snake_case_ = PRETRAINED_POSITIONAL_EMBEDDINGS_SIZES snake_case_ = ['''input_ids''', '''attention_mask'''] def __init__( self , lowerCamelCase__=None , lowerCamelCase__=None , lowerCamelCase__=None , lowerCamelCase__="<|endoftext|>" , lowerCamelCase__="<|endoftext|>" , lowerCamelCase__="<|endoftext|>" , lowerCamelCase__=False , **lowerCamelCase__ , ) -> int: '''simple docstring''' super().__init__( lowerCamelCase__ , lowerCamelCase__ , tokenizer_file=lowerCamelCase__ , unk_token=lowerCamelCase__ , bos_token=lowerCamelCase__ , eos_token=lowerCamelCase__ , add_prefix_space=lowerCamelCase__ , **lowerCamelCase__ , ) __lowerCamelCase = json.loads(self.backend_tokenizer.pre_tokenizer.__getstate__() ) if pre_tok_state.get('add_prefix_space' , lowerCamelCase__ ) != add_prefix_space: __lowerCamelCase = getattr(lowerCamelCase__ , pre_tok_state.pop('type' ) ) __lowerCamelCase = add_prefix_space __lowerCamelCase = pre_tok_class(**lowerCamelCase__ ) __lowerCamelCase = add_prefix_space def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ = None ) -> Tuple[str]: '''simple docstring''' __lowerCamelCase = self._tokenizer.model.save(lowerCamelCase__ , name=lowerCamelCase__ ) return tuple(lowerCamelCase__ ) def lowercase_ ( self , lowerCamelCase__ ) -> List[int]: '''simple docstring''' __lowerCamelCase = [] for is_user, text in conversation.iter_texts(): input_ids.extend(self.encode(lowerCamelCase__ , add_special_tokens=lowerCamelCase__ ) + [self.eos_token_id] ) if len(lowerCamelCase__ ) > self.model_max_length: __lowerCamelCase = input_ids[-self.model_max_length :] return input_ids
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"""simple docstring""" import tempfile import torch from diffusers import IPNDMScheduler from .test_schedulers import SchedulerCommonTest class lowerCAmelCase__ ( UpperCAmelCase__ ): '''simple docstring''' __UpperCamelCase = (IPNDMScheduler,) __UpperCamelCase = (("num_inference_steps", 5_0),) def _SCREAMING_SNAKE_CASE ( self : List[str] , **lowercase_ : str): '''simple docstring''' SCREAMING_SNAKE_CASE_ : Optional[int] = {'''num_train_timesteps''': 1000} config.update(**lowercase_) return config def _SCREAMING_SNAKE_CASE ( self : Optional[int] , lowercase_ : Any=0 , **lowercase_ : Any): '''simple docstring''' SCREAMING_SNAKE_CASE_ : List[str] = dict(self.forward_default_kwargs) SCREAMING_SNAKE_CASE_ : Tuple = kwargs.pop('''num_inference_steps''' , lowercase_) SCREAMING_SNAKE_CASE_ : List[str] = self.dummy_sample SCREAMING_SNAKE_CASE_ : List[str] = 0.1 * sample SCREAMING_SNAKE_CASE_ : Union[str, Any] = [residual + 0.2, residual + 0.15, residual + 0.1, residual + 0.05] for scheduler_class in self.scheduler_classes: SCREAMING_SNAKE_CASE_ : Optional[int] = self.get_scheduler_config(**lowercase_) SCREAMING_SNAKE_CASE_ : Union[str, Any] = scheduler_class(**lowercase_) scheduler.set_timesteps(lowercase_) # copy over dummy past residuals SCREAMING_SNAKE_CASE_ : Dict = dummy_past_residuals[:] if time_step is None: SCREAMING_SNAKE_CASE_ : str = scheduler.timesteps[len(scheduler.timesteps) // 2] with tempfile.TemporaryDirectory() as tmpdirname: scheduler.save_config(lowercase_) SCREAMING_SNAKE_CASE_ : List[str] = scheduler_class.from_pretrained(lowercase_) new_scheduler.set_timesteps(lowercase_) # copy over dummy past residuals SCREAMING_SNAKE_CASE_ : List[str] = dummy_past_residuals[:] SCREAMING_SNAKE_CASE_ : Optional[Any] = scheduler.step(lowercase_ , lowercase_ , lowercase_ , **lowercase_).prev_sample SCREAMING_SNAKE_CASE_ : str = new_scheduler.step(lowercase_ , lowercase_ , lowercase_ , **lowercase_).prev_sample assert torch.sum(torch.abs(output - new_output)) < 1e-5, "Scheduler outputs are not identical" SCREAMING_SNAKE_CASE_ : Optional[int] = scheduler.step(lowercase_ , lowercase_ , lowercase_ , **lowercase_).prev_sample SCREAMING_SNAKE_CASE_ : Tuple = new_scheduler.step(lowercase_ , lowercase_ , lowercase_ , **lowercase_).prev_sample assert torch.sum(torch.abs(output - new_output)) < 1e-5, "Scheduler outputs are not identical" def _SCREAMING_SNAKE_CASE ( self : Tuple): '''simple docstring''' pass def _SCREAMING_SNAKE_CASE ( self : Optional[Any] , lowercase_ : Optional[Any]=0 , **lowercase_ : List[Any]): '''simple docstring''' SCREAMING_SNAKE_CASE_ : Optional[int] = dict(self.forward_default_kwargs) SCREAMING_SNAKE_CASE_ : str = kwargs.pop('''num_inference_steps''' , lowercase_) SCREAMING_SNAKE_CASE_ : List[Any] = self.dummy_sample SCREAMING_SNAKE_CASE_ : Union[str, Any] = 0.1 * sample SCREAMING_SNAKE_CASE_ : Any = [residual + 0.2, residual + 0.15, residual + 0.1, residual + 0.05] for scheduler_class in self.scheduler_classes: SCREAMING_SNAKE_CASE_ : List[str] = self.get_scheduler_config() SCREAMING_SNAKE_CASE_ : Optional[Any] = scheduler_class(**lowercase_) scheduler.set_timesteps(lowercase_) # copy over dummy past residuals (must be after setting timesteps) SCREAMING_SNAKE_CASE_ : Optional[int] = dummy_past_residuals[:] if time_step is None: SCREAMING_SNAKE_CASE_ : str = scheduler.timesteps[len(scheduler.timesteps) // 2] with tempfile.TemporaryDirectory() as tmpdirname: scheduler.save_config(lowercase_) SCREAMING_SNAKE_CASE_ : Optional[Any] = scheduler_class.from_pretrained(lowercase_) # copy over dummy past residuals new_scheduler.set_timesteps(lowercase_) # copy over dummy past residual (must be after setting timesteps) SCREAMING_SNAKE_CASE_ : Optional[Any] = dummy_past_residuals[:] SCREAMING_SNAKE_CASE_ : str = scheduler.step(lowercase_ , lowercase_ , lowercase_ , **lowercase_).prev_sample SCREAMING_SNAKE_CASE_ : Any = new_scheduler.step(lowercase_ , lowercase_ , lowercase_ , **lowercase_).prev_sample assert torch.sum(torch.abs(output - new_output)) < 1e-5, "Scheduler outputs are not identical" SCREAMING_SNAKE_CASE_ : List[Any] = scheduler.step(lowercase_ , lowercase_ , lowercase_ , **lowercase_).prev_sample SCREAMING_SNAKE_CASE_ : List[Any] = new_scheduler.step(lowercase_ , lowercase_ , lowercase_ , **lowercase_).prev_sample assert torch.sum(torch.abs(output - new_output)) < 1e-5, "Scheduler outputs are not identical" def _SCREAMING_SNAKE_CASE ( self : Union[str, Any] , **lowercase_ : Tuple): '''simple docstring''' SCREAMING_SNAKE_CASE_ : str = self.scheduler_classes[0] SCREAMING_SNAKE_CASE_ : List[str] = self.get_scheduler_config(**lowercase_) SCREAMING_SNAKE_CASE_ : List[str] = scheduler_class(**lowercase_) SCREAMING_SNAKE_CASE_ : Tuple = 10 SCREAMING_SNAKE_CASE_ : Optional[Any] = self.dummy_model() SCREAMING_SNAKE_CASE_ : str = self.dummy_sample_deter scheduler.set_timesteps(lowercase_) for i, t in enumerate(scheduler.timesteps): SCREAMING_SNAKE_CASE_ : List[str] = model(lowercase_ , lowercase_) SCREAMING_SNAKE_CASE_ : Any = scheduler.step(lowercase_ , lowercase_ , lowercase_).prev_sample for i, t in enumerate(scheduler.timesteps): SCREAMING_SNAKE_CASE_ : List[Any] = model(lowercase_ , lowercase_) SCREAMING_SNAKE_CASE_ : Union[str, Any] = scheduler.step(lowercase_ , lowercase_ , lowercase_).prev_sample return sample def _SCREAMING_SNAKE_CASE ( self : Optional[Any]): '''simple docstring''' SCREAMING_SNAKE_CASE_ : int = dict(self.forward_default_kwargs) SCREAMING_SNAKE_CASE_ : int = kwargs.pop('''num_inference_steps''' , lowercase_) for scheduler_class in self.scheduler_classes: SCREAMING_SNAKE_CASE_ : Tuple = self.get_scheduler_config() SCREAMING_SNAKE_CASE_ : Tuple = scheduler_class(**lowercase_) SCREAMING_SNAKE_CASE_ : Union[str, Any] = self.dummy_sample SCREAMING_SNAKE_CASE_ : List[Any] = 0.1 * sample if num_inference_steps is not None and hasattr(lowercase_ , '''set_timesteps'''): scheduler.set_timesteps(lowercase_) elif num_inference_steps is not None and not hasattr(lowercase_ , '''set_timesteps'''): SCREAMING_SNAKE_CASE_ : List[Any] = num_inference_steps # copy over dummy past residuals (must be done after set_timesteps) SCREAMING_SNAKE_CASE_ : List[str] = [residual + 0.2, residual + 0.15, residual + 0.1, residual + 0.05] SCREAMING_SNAKE_CASE_ : List[str] = dummy_past_residuals[:] SCREAMING_SNAKE_CASE_ : List[str] = scheduler.timesteps[5] SCREAMING_SNAKE_CASE_ : Tuple = scheduler.timesteps[6] SCREAMING_SNAKE_CASE_ : int = scheduler.step(lowercase_ , lowercase_ , lowercase_ , **lowercase_).prev_sample SCREAMING_SNAKE_CASE_ : Dict = scheduler.step(lowercase_ , lowercase_ , lowercase_ , **lowercase_).prev_sample self.assertEqual(output_a.shape , sample.shape) self.assertEqual(output_a.shape , output_a.shape) SCREAMING_SNAKE_CASE_ : Optional[int] = scheduler.step(lowercase_ , lowercase_ , lowercase_ , **lowercase_).prev_sample SCREAMING_SNAKE_CASE_ : Tuple = scheduler.step(lowercase_ , lowercase_ , lowercase_ , **lowercase_).prev_sample self.assertEqual(output_a.shape , sample.shape) self.assertEqual(output_a.shape , output_a.shape) def _SCREAMING_SNAKE_CASE ( self : Optional[Any]): '''simple docstring''' for timesteps in [100, 1000]: self.check_over_configs(num_train_timesteps=lowercase_ , time_step=lowercase_) def _SCREAMING_SNAKE_CASE ( self : Optional[int]): '''simple docstring''' for t, num_inference_steps in zip([1, 5, 10] , [10, 50, 100]): self.check_over_forward(num_inference_steps=lowercase_ , time_step=lowercase_) def _SCREAMING_SNAKE_CASE ( self : str): '''simple docstring''' SCREAMING_SNAKE_CASE_ : Tuple = self.full_loop() SCREAMING_SNAKE_CASE_ : Tuple = torch.mean(torch.abs(lowercase_)) assert abs(result_mean.item() - 2540529) < 10
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from ..utils import DummyObject, requires_backends class __lowerCAmelCase ( metaclass=__magic_name__ ): """simple docstring""" snake_case_ = ['''onnx'''] def __init__( self , *lowerCamelCase__ , **lowerCamelCase__ ) -> Optional[Any]: '''simple docstring''' requires_backends(self , ['onnx'] ) @classmethod def lowercase_ ( cls , *lowerCamelCase__ , **lowerCamelCase__ ) -> Dict: '''simple docstring''' requires_backends(cls , ['onnx'] ) @classmethod def lowercase_ ( cls , *lowerCamelCase__ , **lowerCamelCase__ ) -> List[str]: '''simple docstring''' requires_backends(cls , ['onnx'] )
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import logging from pathlib import Path import numpy as np import pytorch_lightning as pl import torch from pytorch_lightning.callbacks import EarlyStopping, ModelCheckpoint from pytorch_lightning.utilities import rank_zero_only from utils_rag import save_json def _a ( SCREAMING_SNAKE_CASE_ : Union[str, Any] ): __lowerCAmelCase = filter(lambda SCREAMING_SNAKE_CASE_ : p.requires_grad , model.parameters() ) __lowerCAmelCase = sum([np.prod(p.size() ) for p in model_parameters] ) return params UpperCamelCase__ = logging.getLogger(__name__) def _a ( SCREAMING_SNAKE_CASE_ : List[Any] , SCREAMING_SNAKE_CASE_ : Any ): if metric == "rouge2": __lowerCAmelCase = "{val_avg_rouge2:.4f}-{step_count}" elif metric == "bleu": __lowerCAmelCase = "{val_avg_bleu:.4f}-{step_count}" elif metric == "em": __lowerCAmelCase = "{val_avg_em:.4f}-{step_count}" elif metric == "loss": __lowerCAmelCase = "{val_avg_loss:.4f}-{step_count}" else: raise NotImplementedError( F"""seq2seq callbacks only support rouge2 and bleu, got {metric}, You can make your own by adding to this""" " function." ) __lowerCAmelCase = ModelCheckpoint( dirpath=SCREAMING_SNAKE_CASE_ , filename=SCREAMING_SNAKE_CASE_ , monitor=F"""val_{metric}""" , mode="max" , save_top_k=1 , every_n_epochs=1 , ) return checkpoint_callback def _a ( SCREAMING_SNAKE_CASE_ : List[str] , SCREAMING_SNAKE_CASE_ : str ): return EarlyStopping( monitor=F"""val_{metric}""" , mode="min" if "loss" in metric else "max" , patience=SCREAMING_SNAKE_CASE_ , verbose=SCREAMING_SNAKE_CASE_ , ) class a__ ( pl.Callback ): def __SCREAMING_SNAKE_CASE( self , _A , _A ): """simple docstring""" __lowerCAmelCase = {f"""lr_group_{i}""": param["lr"] for i, param in enumerate(pl_module.trainer.optimizers[0].param_groups )} pl_module.logger.log_metrics(_A ) @rank_zero_only def __SCREAMING_SNAKE_CASE( self , _A , _A , _A , _A=True ): """simple docstring""" logger.info(f"""***** {type_path} results at step {trainer.global_step:05d} *****""" ) __lowerCAmelCase = trainer.callback_metrics trainer.logger.log_metrics({k: v for k, v in metrics.items() if k not in ["log", "progress_bar", "preds"]} ) # Log results __lowerCAmelCase = Path(pl_module.hparams.output_dir ) if type_path == "test": __lowerCAmelCase = od / "test_results.txt" __lowerCAmelCase = od / "test_generations.txt" else: # this never gets hit. I prefer not to save intermediate generations, and results are in metrics.json # If people want this it will be easy enough to add back. __lowerCAmelCase = od / f"""{type_path}_results/{trainer.global_step:05d}.txt""" __lowerCAmelCase = od / f"""{type_path}_generations/{trainer.global_step:05d}.txt""" results_file.parent.mkdir(exist_ok=_A ) generations_file.parent.mkdir(exist_ok=_A ) with open(_A , "a+" ) as writer: for key in sorted(_A ): if key in ["log", "progress_bar", "preds"]: continue __lowerCAmelCase = metrics[key] if isinstance(_A , torch.Tensor ): __lowerCAmelCase = val.item() __lowerCAmelCase = f"""{key}: {val:.6f}\n""" writer.write(_A ) if not save_generations: return if "preds" in metrics: __lowerCAmelCase = "\n".join(metrics["preds"] ) generations_file.open("w+" ).write(_A ) @rank_zero_only def __SCREAMING_SNAKE_CASE( self , _A , _A ): """simple docstring""" try: __lowerCAmelCase = pl_module.model.model.num_parameters() except AttributeError: __lowerCAmelCase = pl_module.model.num_parameters() __lowerCAmelCase = count_trainable_parameters(_A ) # mp stands for million parameters trainer.logger.log_metrics({"n_params": npars, "mp": npars / 1E6, "grad_mp": n_trainable_pars / 1E6} ) @rank_zero_only def __SCREAMING_SNAKE_CASE( self , _A , _A ): """simple docstring""" save_json(pl_module.metrics , pl_module.metrics_save_path ) return self._write_logs(_A , _A , "test" ) @rank_zero_only def __SCREAMING_SNAKE_CASE( self , _A , _A ): """simple docstring""" save_json(pl_module.metrics , pl_module.metrics_save_path ) # Uncommenting this will save val generations # return self._write_logs(trainer, pl_module, "valid")
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import itertools import os import random import tempfile import unittest import numpy as np from datasets import load_dataset from transformers import is_speech_available from transformers.testing_utils import check_json_file_has_correct_format, require_torch, require_torchaudio from transformers.utils.import_utils import is_torch_available from ...test_sequence_feature_extraction_common import SequenceFeatureExtractionTestMixin if is_speech_available(): from transformers import WhisperFeatureExtractor if is_torch_available(): import torch __A = random.Random() def lowerCamelCase_ ( UpperCamelCase__ : Optional[int] , UpperCamelCase__ : List[str]=1.0 , UpperCamelCase__ : Union[str, Any]=None , UpperCamelCase__ : Optional[int]=None ) -> Optional[Any]: """simple docstring""" if rng is None: __lowerCamelCase = global_rng __lowerCamelCase = [] for batch_idx in range(shape[0] ): values.append([] ) for _ in range(shape[1] ): values[-1].append(rng.random() * scale ) return values @require_torch @require_torchaudio class __lowerCAmelCase ( unittest.TestCase ): """simple docstring""" def __init__( self , lowerCamelCase__ , lowerCamelCase__=7 , lowerCamelCase__=400 , lowerCamelCase__=2_000 , lowerCamelCase__=10 , lowerCamelCase__=160 , lowerCamelCase__=8 , lowerCamelCase__=0.0 , lowerCamelCase__=4_000 , lowerCamelCase__=False , lowerCamelCase__=True , ) -> List[str]: '''simple docstring''' __lowerCamelCase = parent __lowerCamelCase = batch_size __lowerCamelCase = min_seq_length __lowerCamelCase = max_seq_length __lowerCamelCase = (self.max_seq_length - self.min_seq_length) // (self.batch_size - 1) __lowerCamelCase = padding_value __lowerCamelCase = sampling_rate __lowerCamelCase = return_attention_mask __lowerCamelCase = do_normalize __lowerCamelCase = feature_size __lowerCamelCase = chunk_length __lowerCamelCase = hop_length def lowercase_ ( self ) -> Any: '''simple docstring''' return { "feature_size": self.feature_size, "hop_length": self.hop_length, "chunk_length": self.chunk_length, "padding_value": self.padding_value, "sampling_rate": self.sampling_rate, "return_attention_mask": self.return_attention_mask, "do_normalize": self.do_normalize, } def lowercase_ ( self , lowerCamelCase__=False , lowerCamelCase__=False ) -> Optional[int]: '''simple docstring''' def _flatten(lowerCamelCase__ ): return list(itertools.chain(*lowerCamelCase__ ) ) if equal_length: __lowerCamelCase = [floats_list((self.max_seq_length, self.feature_size) ) for _ in range(self.batch_size )] else: # make sure that inputs increase in size __lowerCamelCase = [ floats_list((x, self.feature_size) ) for x in range(self.min_seq_length , self.max_seq_length , self.seq_length_diff ) ] if numpify: __lowerCamelCase = [np.asarray(lowerCamelCase__ ) for x in speech_inputs] return speech_inputs @require_torch @require_torchaudio class __lowerCAmelCase ( __magic_name__ , unittest.TestCase ): """simple docstring""" snake_case_ = WhisperFeatureExtractor if is_speech_available() else None def lowercase_ ( self ) -> Any: '''simple docstring''' __lowerCamelCase = WhisperFeatureExtractionTester(self ) def lowercase_ ( self ) -> List[str]: '''simple docstring''' __lowerCamelCase = self.feature_extraction_class(**self.feat_extract_dict ) with tempfile.TemporaryDirectory() as tmpdirname: __lowerCamelCase = feat_extract_first.save_pretrained(lowerCamelCase__ )[0] check_json_file_has_correct_format(lowerCamelCase__ ) __lowerCamelCase = self.feature_extraction_class.from_pretrained(lowerCamelCase__ ) __lowerCamelCase = feat_extract_first.to_dict() __lowerCamelCase = feat_extract_second.to_dict() __lowerCamelCase = feat_extract_first.mel_filters __lowerCamelCase = feat_extract_second.mel_filters self.assertTrue(np.allclose(lowerCamelCase__ , lowerCamelCase__ ) ) self.assertEqual(lowerCamelCase__ , lowerCamelCase__ ) def lowercase_ ( self ) -> Dict: '''simple docstring''' __lowerCamelCase = self.feature_extraction_class(**self.feat_extract_dict ) with tempfile.TemporaryDirectory() as tmpdirname: __lowerCamelCase = os.path.join(lowerCamelCase__ , 'feat_extract.json' ) feat_extract_first.to_json_file(lowerCamelCase__ ) __lowerCamelCase = self.feature_extraction_class.from_json_file(lowerCamelCase__ ) __lowerCamelCase = feat_extract_first.to_dict() __lowerCamelCase = feat_extract_second.to_dict() __lowerCamelCase = feat_extract_first.mel_filters __lowerCamelCase = feat_extract_second.mel_filters self.assertTrue(np.allclose(lowerCamelCase__ , lowerCamelCase__ ) ) self.assertEqual(lowerCamelCase__ , lowerCamelCase__ ) def lowercase_ ( self ) -> Dict: '''simple docstring''' # Tests that all call wrap to encode_plus and batch_encode_plus __lowerCamelCase = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) # create three inputs of length 800, 1000, and 1200 __lowerCamelCase = [floats_list((1, x) )[0] for x in range(800 , 1_400 , 200 )] __lowerCamelCase = [np.asarray(lowerCamelCase__ ) for speech_input in speech_inputs] # Test feature size __lowerCamelCase = feature_extractor(lowerCamelCase__ , padding='max_length' , return_tensors='np' ).input_features self.assertTrue(input_features.ndim == 3 ) self.assertTrue(input_features.shape[-1] == feature_extractor.nb_max_frames ) self.assertTrue(input_features.shape[-2] == feature_extractor.feature_size ) # Test not batched input __lowerCamelCase = feature_extractor(speech_inputs[0] , return_tensors='np' ).input_features __lowerCamelCase = feature_extractor(np_speech_inputs[0] , return_tensors='np' ).input_features self.assertTrue(np.allclose(lowerCamelCase__ , lowerCamelCase__ , atol=1e-3 ) ) # Test batched __lowerCamelCase = feature_extractor(lowerCamelCase__ , return_tensors='np' ).input_features __lowerCamelCase = feature_extractor(lowerCamelCase__ , return_tensors='np' ).input_features for enc_seq_a, enc_seq_a in zip(lowerCamelCase__ , lowerCamelCase__ ): self.assertTrue(np.allclose(lowerCamelCase__ , lowerCamelCase__ , atol=1e-3 ) ) # Test 2-D numpy arrays are batched. __lowerCamelCase = [floats_list((1, x) )[0] for x in (800, 800, 800)] __lowerCamelCase = np.asarray(lowerCamelCase__ ) __lowerCamelCase = feature_extractor(lowerCamelCase__ , return_tensors='np' ).input_features __lowerCamelCase = feature_extractor(lowerCamelCase__ , return_tensors='np' ).input_features for enc_seq_a, enc_seq_a in zip(lowerCamelCase__ , lowerCamelCase__ ): self.assertTrue(np.allclose(lowerCamelCase__ , lowerCamelCase__ , atol=1e-3 ) ) # Test truncation required __lowerCamelCase = [floats_list((1, x) )[0] for x in range(200 , (feature_extractor.n_samples + 500) , 200 )] __lowerCamelCase = [np.asarray(lowerCamelCase__ ) for speech_input in speech_inputs] __lowerCamelCase = [x[: feature_extractor.n_samples] for x in speech_inputs] __lowerCamelCase = [np.asarray(lowerCamelCase__ ) for speech_input in speech_inputs_truncated] __lowerCamelCase = feature_extractor(lowerCamelCase__ , return_tensors='np' ).input_features __lowerCamelCase = feature_extractor(lowerCamelCase__ , return_tensors='np' ).input_features for enc_seq_a, enc_seq_a in zip(lowerCamelCase__ , lowerCamelCase__ ): self.assertTrue(np.allclose(lowerCamelCase__ , lowerCamelCase__ , atol=1e-3 ) ) def lowercase_ ( self ) -> List[str]: '''simple docstring''' import torch __lowerCamelCase = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) __lowerCamelCase = np.random.rand(100 , 32 ).astype(np.floataa ) __lowerCamelCase = np_speech_inputs.tolist() for inputs in [py_speech_inputs, np_speech_inputs]: __lowerCamelCase = feature_extractor.pad([{'input_features': inputs}] , return_tensors='np' ) self.assertTrue(np_processed.input_features.dtype == np.floataa ) __lowerCamelCase = feature_extractor.pad([{'input_features': inputs}] , return_tensors='pt' ) self.assertTrue(pt_processed.input_features.dtype == torch.floataa ) def lowercase_ ( self , lowerCamelCase__ ) -> List[str]: '''simple docstring''' __lowerCamelCase = load_dataset('hf-internal-testing/librispeech_asr_dummy' , 'clean' , split='validation' ) # automatic decoding with librispeech __lowerCamelCase = ds.sort('id' ).select(range(lowerCamelCase__ ) )[:num_samples]['audio'] return [x["array"] for x in speech_samples] def lowercase_ ( self ) -> Tuple: '''simple docstring''' # fmt: off __lowerCamelCase = torch.tensor( [ 0.11_93, -0.09_46, -0.10_98, -0.01_96, 0.02_25, -0.06_90, -0.17_36, 0.09_51, 0.09_71, -0.08_17, -0.07_02, 0.01_62, 0.02_60, 0.00_17, -0.01_92, -0.16_78, 0.07_09, -0.18_67, -0.06_55, -0.02_74, -0.02_34, -0.18_84, -0.05_16, -0.05_54, -0.02_74, -0.14_25, -0.14_23, 0.08_37, 0.03_77, -0.08_54 ] ) # fmt: on __lowerCamelCase = self._load_datasamples(1 ) __lowerCamelCase = WhisperFeatureExtractor() __lowerCamelCase = feature_extractor(lowerCamelCase__ , return_tensors='pt' ).input_features self.assertEqual(input_features.shape , (1, 80, 3_000) ) self.assertTrue(torch.allclose(input_features[0, 0, :30] , lowerCamelCase__ , atol=1e-4 ) ) def lowercase_ ( self ) -> List[Any]: '''simple docstring''' __lowerCamelCase = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) __lowerCamelCase = self._load_datasamples(1 )[0] __lowerCamelCase = ((audio - audio.min()) / (audio.max() - audio.min())) * 65_535 # Rescale to [0, 65535] to show issue __lowerCamelCase = feat_extract.zero_mean_unit_var_norm([audio] , attention_mask=lowerCamelCase__ )[0] self.assertTrue(np.all(np.mean(lowerCamelCase__ ) < 1e-3 ) ) self.assertTrue(np.all(np.abs(np.var(lowerCamelCase__ ) - 1 ) < 1e-3 ) )
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'''simple docstring''' import importlib import inspect import json import os import re import shutil import sys from pathlib import Path from typing import Dict, Optional, Union from urllib import request from huggingface_hub import HfFolder, cached_download, hf_hub_download, model_info from packaging import version from .. import __version__ from . import DIFFUSERS_DYNAMIC_MODULE_NAME, HF_MODULES_CACHE, logging _lowercase : Optional[Any] = ( "https://raw.githubusercontent.com/huggingface/diffusers/{revision}/examples/community/{pipeline}.py" ) _lowercase : Tuple = logging.get_logger(__name__) # pylint: disable=invalid-name def snake_case_ ( ): """simple docstring""" lowercase_ : Tuple = '''https://pypi.org/pypi/diffusers/json''' lowercase_ : Tuple = json.loads(request.urlopen(__SCREAMING_SNAKE_CASE ).read() )['''releases'''].keys() return sorted(__SCREAMING_SNAKE_CASE , key=lambda __SCREAMING_SNAKE_CASE : version.Version(__SCREAMING_SNAKE_CASE ) ) def snake_case_ ( ): """simple docstring""" if HF_MODULES_CACHE in sys.path: return sys.path.append(__SCREAMING_SNAKE_CASE ) os.makedirs(__SCREAMING_SNAKE_CASE , exist_ok=__SCREAMING_SNAKE_CASE ) lowercase_ : List[Any] = Path(__SCREAMING_SNAKE_CASE ) / '''__init__.py''' if not init_path.exists(): init_path.touch() def snake_case_ ( __SCREAMING_SNAKE_CASE : Union[str, os.PathLike] ): """simple docstring""" init_hf_modules() lowercase_ : Optional[int] = Path(__SCREAMING_SNAKE_CASE ) / name # If the parent module does not exist yet, recursively create it. if not dynamic_module_path.parent.exists(): create_dynamic_module(dynamic_module_path.parent ) os.makedirs(__SCREAMING_SNAKE_CASE , exist_ok=__SCREAMING_SNAKE_CASE ) lowercase_ : str = dynamic_module_path / '''__init__.py''' if not init_path.exists(): init_path.touch() def snake_case_ ( __SCREAMING_SNAKE_CASE : List[str] ): """simple docstring""" with open(__SCREAMING_SNAKE_CASE , '''r''' , encoding='''utf-8''' ) as f: lowercase_ : int = f.read() # Imports of the form `import .xxx` lowercase_ : List[Any] = re.findall('''^\s*import\s+\.(\S+)\s*$''' , __SCREAMING_SNAKE_CASE , flags=re.MULTILINE ) # Imports of the form `from .xxx import yyy` relative_imports += re.findall('''^\s*from\s+\.(\S+)\s+import''' , __SCREAMING_SNAKE_CASE , flags=re.MULTILINE ) # Unique-ify return list(set(__SCREAMING_SNAKE_CASE ) ) def snake_case_ ( __SCREAMING_SNAKE_CASE : str ): """simple docstring""" lowercase_ : int = False lowercase_ : Any = [module_file] lowercase_ : Dict = [] # Let's recurse through all relative imports while not no_change: lowercase_ : Dict = [] for f in files_to_check: new_imports.extend(get_relative_imports(__SCREAMING_SNAKE_CASE ) ) lowercase_ : Union[str, Any] = Path(__SCREAMING_SNAKE_CASE ).parent lowercase_ : Optional[int] = [str(module_path / m ) for m in new_imports] lowercase_ : str = [f for f in new_import_files if f not in all_relative_imports] lowercase_ : int = [F'''{f}.py''' for f in new_import_files] lowercase_ : Optional[Any] = len(__SCREAMING_SNAKE_CASE ) == 0 all_relative_imports.extend(__SCREAMING_SNAKE_CASE ) return all_relative_imports def snake_case_ ( __SCREAMING_SNAKE_CASE : Any ): """simple docstring""" with open(__SCREAMING_SNAKE_CASE , '''r''' , encoding='''utf-8''' ) as f: lowercase_ : Union[str, Any] = f.read() # Imports of the form `import xxx` lowercase_ : Any = re.findall('''^\s*import\s+(\S+)\s*$''' , __SCREAMING_SNAKE_CASE , flags=re.MULTILINE ) # Imports of the form `from xxx import yyy` imports += re.findall('''^\s*from\s+(\S+)\s+import''' , __SCREAMING_SNAKE_CASE , flags=re.MULTILINE ) # Only keep the top-level module lowercase_ : List[str] = [imp.split('''.''' )[0] for imp in imports if not imp.startswith('''.''' )] # Unique-ify and test we got them all lowercase_ : Any = list(set(__SCREAMING_SNAKE_CASE ) ) lowercase_ : Optional[Any] = [] for imp in imports: try: importlib.import_module(__SCREAMING_SNAKE_CASE ) except ImportError: missing_packages.append(__SCREAMING_SNAKE_CASE ) if len(__SCREAMING_SNAKE_CASE ) > 0: raise ImportError( '''This modeling file requires the following packages that were not found in your environment: ''' F'''{', '.join(__SCREAMING_SNAKE_CASE )}. Run `pip install {' '.join(__SCREAMING_SNAKE_CASE )}`''' ) return get_relative_imports(__SCREAMING_SNAKE_CASE ) def snake_case_ ( __SCREAMING_SNAKE_CASE : List[Any] , __SCREAMING_SNAKE_CASE : Optional[Any] ): """simple docstring""" lowercase_ : List[Any] = module_path.replace(os.path.sep , '''.''' ) lowercase_ : Any = importlib.import_module(__SCREAMING_SNAKE_CASE ) if class_name is None: return find_pipeline_class(__SCREAMING_SNAKE_CASE ) return getattr(__SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE ) def snake_case_ ( __SCREAMING_SNAKE_CASE : Dict ): """simple docstring""" from ..pipelines import DiffusionPipeline lowercase_ : int = dict(inspect.getmembers(__SCREAMING_SNAKE_CASE , inspect.isclass ) ) lowercase_ : Optional[Any] = None for cls_name, cls in cls_members.items(): if ( cls_name != DiffusionPipeline.__name__ and issubclass(cls , __SCREAMING_SNAKE_CASE ) and cls.__module__.split('''.''' )[0] != "diffusers" ): if pipeline_class is not None: raise ValueError( F'''Multiple classes that inherit from {DiffusionPipeline.__name__} have been found:''' F''' {pipeline_class.__name__}, and {cls_name}. Please make sure to define only one in''' F''' {loaded_module}.''' ) lowercase_ : List[Any] = cls return pipeline_class def snake_case_ ( __SCREAMING_SNAKE_CASE : Union[str, os.PathLike] , __SCREAMING_SNAKE_CASE : str , __SCREAMING_SNAKE_CASE : Optional[Union[str, os.PathLike]] = None , __SCREAMING_SNAKE_CASE : bool = False , __SCREAMING_SNAKE_CASE : bool = False , __SCREAMING_SNAKE_CASE : Optional[Dict[str, str]] = None , __SCREAMING_SNAKE_CASE : Optional[Union[bool, str]] = None , __SCREAMING_SNAKE_CASE : Optional[str] = None , __SCREAMING_SNAKE_CASE : bool = False , ): """simple docstring""" lowercase_ : Dict = str(__SCREAMING_SNAKE_CASE ) lowercase_ : Tuple = os.path.join(__SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE ) if os.path.isfile(__SCREAMING_SNAKE_CASE ): lowercase_ : Dict = module_file_or_url lowercase_ : int = '''local''' elif pretrained_model_name_or_path.count('''/''' ) == 0: lowercase_ : Optional[int] = get_diffusers_versions() # cut ".dev0" lowercase_ : List[Any] = '''v''' + '''.'''.join(__version__.split('''.''' )[:3] ) # retrieve github version that matches if revision is None: lowercase_ : List[str] = latest_version if latest_version[1:] in available_versions else '''main''' logger.info(F'''Defaulting to latest_version: {revision}.''' ) elif revision in available_versions: lowercase_ : List[str] = F'''v{revision}''' elif revision == "main": lowercase_ : Optional[Any] = revision else: raise ValueError( F'''`custom_revision`: {revision} does not exist. Please make sure to choose one of''' F''' {', '.join(available_versions + ['main'] )}.''' ) # community pipeline on GitHub lowercase_ : Tuple = COMMUNITY_PIPELINES_URL.format(revision=__SCREAMING_SNAKE_CASE , pipeline=__SCREAMING_SNAKE_CASE ) try: lowercase_ : Optional[Any] = cached_download( __SCREAMING_SNAKE_CASE , cache_dir=__SCREAMING_SNAKE_CASE , force_download=__SCREAMING_SNAKE_CASE , proxies=__SCREAMING_SNAKE_CASE , resume_download=__SCREAMING_SNAKE_CASE , local_files_only=__SCREAMING_SNAKE_CASE , use_auth_token=__SCREAMING_SNAKE_CASE , ) lowercase_ : Tuple = '''git''' lowercase_ : Tuple = pretrained_model_name_or_path + '''.py''' except EnvironmentError: logger.error(F'''Could not locate the {module_file} inside {pretrained_model_name_or_path}.''' ) raise else: try: # Load from URL or cache if already cached lowercase_ : str = hf_hub_download( __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE , cache_dir=__SCREAMING_SNAKE_CASE , force_download=__SCREAMING_SNAKE_CASE , proxies=__SCREAMING_SNAKE_CASE , resume_download=__SCREAMING_SNAKE_CASE , local_files_only=__SCREAMING_SNAKE_CASE , use_auth_token=__SCREAMING_SNAKE_CASE , ) lowercase_ : Optional[Any] = os.path.join('''local''' , '''--'''.join(pretrained_model_name_or_path.split('''/''' ) ) ) except EnvironmentError: logger.error(F'''Could not locate the {module_file} inside {pretrained_model_name_or_path}.''' ) raise # Check we have all the requirements in our environment lowercase_ : Tuple = check_imports(__SCREAMING_SNAKE_CASE ) # Now we move the module inside our cached dynamic modules. lowercase_ : str = DIFFUSERS_DYNAMIC_MODULE_NAME + os.path.sep + submodule create_dynamic_module(__SCREAMING_SNAKE_CASE ) lowercase_ : Any = Path(__SCREAMING_SNAKE_CASE ) / full_submodule if submodule == "local" or submodule == "git": # We always copy local files (we could hash the file to see if there was a change, and give them the name of # that hash, to only copy when there is a modification but it seems overkill for now). # The only reason we do the copy is to avoid putting too many folders in sys.path. shutil.copy(__SCREAMING_SNAKE_CASE , submodule_path / module_file ) for module_needed in modules_needed: lowercase_ : Union[str, Any] = F'''{module_needed}.py''' shutil.copy(os.path.join(__SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE ) , submodule_path / module_needed ) else: # Get the commit hash # TODO: we will get this info in the etag soon, so retrieve it from there and not here. if isinstance(__SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE ): lowercase_ : Tuple = use_auth_token elif use_auth_token is True: lowercase_ : List[Any] = HfFolder.get_token() else: lowercase_ : Optional[Any] = None lowercase_ : Optional[int] = model_info(__SCREAMING_SNAKE_CASE , revision=__SCREAMING_SNAKE_CASE , token=__SCREAMING_SNAKE_CASE ).sha # The module file will end up being placed in a subfolder with the git hash of the repo. This way we get the # benefit of versioning. lowercase_ : int = submodule_path / commit_hash lowercase_ : Tuple = full_submodule + os.path.sep + commit_hash create_dynamic_module(__SCREAMING_SNAKE_CASE ) if not (submodule_path / module_file).exists(): shutil.copy(__SCREAMING_SNAKE_CASE , submodule_path / module_file ) # Make sure we also have every file with relative for module_needed in modules_needed: if not (submodule_path / module_needed).exists(): get_cached_module_file( __SCREAMING_SNAKE_CASE , F'''{module_needed}.py''' , cache_dir=__SCREAMING_SNAKE_CASE , force_download=__SCREAMING_SNAKE_CASE , resume_download=__SCREAMING_SNAKE_CASE , proxies=__SCREAMING_SNAKE_CASE , use_auth_token=__SCREAMING_SNAKE_CASE , revision=__SCREAMING_SNAKE_CASE , local_files_only=__SCREAMING_SNAKE_CASE , ) return os.path.join(__SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE ) def snake_case_ ( __SCREAMING_SNAKE_CASE : Union[str, os.PathLike] , __SCREAMING_SNAKE_CASE : str , __SCREAMING_SNAKE_CASE : Optional[str] = None , __SCREAMING_SNAKE_CASE : Optional[Union[str, os.PathLike]] = None , __SCREAMING_SNAKE_CASE : bool = False , __SCREAMING_SNAKE_CASE : bool = False , __SCREAMING_SNAKE_CASE : Optional[Dict[str, str]] = None , __SCREAMING_SNAKE_CASE : Optional[Union[bool, str]] = None , __SCREAMING_SNAKE_CASE : Optional[str] = None , __SCREAMING_SNAKE_CASE : bool = False , **__SCREAMING_SNAKE_CASE : Optional[Any] , ): """simple docstring""" lowercase_ : Optional[Any] = get_cached_module_file( __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE , cache_dir=__SCREAMING_SNAKE_CASE , force_download=__SCREAMING_SNAKE_CASE , resume_download=__SCREAMING_SNAKE_CASE , proxies=__SCREAMING_SNAKE_CASE , use_auth_token=__SCREAMING_SNAKE_CASE , revision=__SCREAMING_SNAKE_CASE , local_files_only=__SCREAMING_SNAKE_CASE , ) return get_class_in_module(__SCREAMING_SNAKE_CASE , final_module.replace('''.py''' , '''''' ) )
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from dataclasses import dataclass from typing import Tuple import numpy as np import torch @dataclass class __lowerCAmelCase : """simple docstring""" snake_case_ = 42 # [batch_size x 3] snake_case_ = 42 # [batch_size x 3] snake_case_ = 42 # [batch_size x 3] snake_case_ = 42 # [batch_size x 3] snake_case_ = 42 snake_case_ = 42 snake_case_ = 42 snake_case_ = 42 snake_case_ = 42 def lowercase_ ( self ) -> Union[str, Any]: '''simple docstring''' assert self.x.shape[0] == self.y.shape[0] == self.z.shape[0] == self.origin.shape[0] assert self.x.shape[1] == self.y.shape[1] == self.z.shape[1] == self.origin.shape[1] == 3 assert len(self.x.shape ) == len(self.y.shape ) == len(self.z.shape ) == len(self.origin.shape ) == 2 def lowercase_ ( self ) -> Optional[int]: '''simple docstring''' return torch.from_numpy(np.array([self.width, self.height] , dtype=np.floataa ) ) def lowercase_ ( self ) -> Optional[Any]: '''simple docstring''' return torch.from_numpy(np.array([self.x_fov, self.y_fov] , dtype=np.floataa ) ) def lowercase_ ( self ) -> torch.Tensor: '''simple docstring''' __lowerCamelCase = torch.arange(self.height * self.width ) __lowerCamelCase = torch.stack( [ pixel_indices % self.width, torch.div(lowerCamelCase__ , self.width , rounding_mode='trunc' ), ] , axis=1 , ) return coords @property def lowercase_ ( self ) -> int: '''simple docstring''' __lowerCamelCase , *__lowerCamelCase = self.shape __lowerCamelCase = int(np.prod(lowerCamelCase__ ) ) __lowerCamelCase = self.get_image_coords() __lowerCamelCase = torch.broadcast_to(coords.unsqueeze(0 ) , [batch_size * inner_batch_size, *coords.shape] ) __lowerCamelCase = self.get_camera_rays(lowerCamelCase__ ) __lowerCamelCase = rays.view(lowerCamelCase__ , inner_batch_size * self.height * self.width , 2 , 3 ) return rays def lowercase_ ( self , lowerCamelCase__ ) -> torch.Tensor: '''simple docstring''' __lowerCamelCase , *__lowerCamelCase , __lowerCamelCase = coords.shape assert n_coords == 2 assert batch_size == self.origin.shape[0] __lowerCamelCase = coords.view(lowerCamelCase__ , -1 , 2 ) __lowerCamelCase = self.resolution() __lowerCamelCase = self.fov() __lowerCamelCase = (flat.float() / (res - 1)) * 2 - 1 __lowerCamelCase = fracs * torch.tan(fov / 2 ) __lowerCamelCase = fracs.view(lowerCamelCase__ , -1 , 2 ) __lowerCamelCase = ( self.z.view(lowerCamelCase__ , 1 , 3 ) + self.x.view(lowerCamelCase__ , 1 , 3 ) * fracs[:, :, :1] + self.y.view(lowerCamelCase__ , 1 , 3 ) * fracs[:, :, 1:] ) __lowerCamelCase = directions / directions.norm(dim=-1 , keepdim=lowerCamelCase__ ) __lowerCamelCase = torch.stack( [ torch.broadcast_to(self.origin.view(lowerCamelCase__ , 1 , 3 ) , [batch_size, directions.shape[1], 3] ), directions, ] , dim=2 , ) return rays.view(lowerCamelCase__ , *lowerCamelCase__ , 2 , 3 ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ ) -> "DifferentiableProjectiveCamera": '''simple docstring''' assert width * self.height == height * self.width, "The aspect ratio should not change." return DifferentiableProjectiveCamera( origin=self.origin , x=self.x , y=self.y , z=self.z , width=lowerCamelCase__ , height=lowerCamelCase__ , x_fov=self.x_fov , y_fov=self.y_fov , ) def lowerCamelCase_ ( UpperCamelCase__ : int ) -> DifferentiableProjectiveCamera: """simple docstring""" __lowerCamelCase = [] __lowerCamelCase = [] __lowerCamelCase = [] __lowerCamelCase = [] for theta in np.linspace(0 , 2 * np.pi , num=20 ): __lowerCamelCase = np.array([np.sin(UpperCamelCase__ ), np.cos(UpperCamelCase__ ), -0.5] ) z /= np.sqrt(np.sum(z**2 ) ) __lowerCamelCase = -z * 4 __lowerCamelCase = np.array([np.cos(UpperCamelCase__ ), -np.sin(UpperCamelCase__ ), 0.0] ) __lowerCamelCase = np.cross(UpperCamelCase__ , UpperCamelCase__ ) origins.append(UpperCamelCase__ ) xs.append(UpperCamelCase__ ) ys.append(UpperCamelCase__ ) zs.append(UpperCamelCase__ ) return DifferentiableProjectiveCamera( origin=torch.from_numpy(np.stack(UpperCamelCase__ , axis=0 ) ).float() , x=torch.from_numpy(np.stack(UpperCamelCase__ , axis=0 ) ).float() , y=torch.from_numpy(np.stack(UpperCamelCase__ , axis=0 ) ).float() , z=torch.from_numpy(np.stack(UpperCamelCase__ , axis=0 ) ).float() , width=UpperCamelCase__ , height=UpperCamelCase__ , x_fov=0.7 , y_fov=0.7 , shape=(1, len(UpperCamelCase__ )) , )
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from unittest.mock import patch import pyspark from datasets.packaged_modules.spark.spark import ( Spark, SparkExamplesIterable, _generate_iterable_examples, ) from ..utils import ( require_dill_gt_0_3_2, require_not_windows, ) def __lowerCamelCase ( UpperCAmelCase_ : Optional[int] , UpperCAmelCase_ : Union[str, Any] ): """simple docstring""" a :Dict = [] for part_id in partition_order: a :str = df.where(F'''SPARK_PARTITION_ID() = {part_id}''' ).collect() for row_idx, row in enumerate(UpperCAmelCase_ ): expected_row_ids_and_row_dicts.append((F'''{part_id}_{row_idx}''', row.asDict()) ) return expected_row_ids_and_row_dicts @require_not_windows @require_dill_gt_0_3_2 def __lowerCamelCase ( ): """simple docstring""" a :Union[str, Any] = pyspark.sql.SparkSession.builder.master('''local[*]''' ).appName('''pyspark''' ).getOrCreate() a :List[Any] = spark.range(100 ).repartition(1 ) a :Any = Spark(UpperCAmelCase_ ) # The id ints will be converted to Pyarrow int64s, so each row will be 8 bytes. Setting a max_shard_size of 16 means # that each partition can hold 2 rows. spark_builder._repartition_df_if_needed(max_shard_size=16 ) # Given that the dataframe has 100 rows and each partition has 2 rows, we expect 50 partitions. assert spark_builder.df.rdd.getNumPartitions() == 50 @require_not_windows @require_dill_gt_0_3_2 def __lowerCamelCase ( ): """simple docstring""" a :int = pyspark.sql.SparkSession.builder.master('''local[*]''' ).appName('''pyspark''' ).getOrCreate() a :Tuple = spark.range(10 ).repartition(2 ) a :Optional[Any] = [1, 0] a :Any = _generate_iterable_examples(UpperCAmelCase_ , UpperCAmelCase_ ) # Reverse the partitions. a :int = _get_expected_row_ids_and_row_dicts_for_partition_order(UpperCAmelCase_ , UpperCAmelCase_ ) for i, (row_id, row_dict) in enumerate(generate_fn() ): a , a :int = expected_row_ids_and_row_dicts[i] assert row_id == expected_row_id assert row_dict == expected_row_dict @require_not_windows @require_dill_gt_0_3_2 def __lowerCamelCase ( ): """simple docstring""" a :int = pyspark.sql.SparkSession.builder.master('''local[*]''' ).appName('''pyspark''' ).getOrCreate() a :List[str] = spark.range(10 ).repartition(1 ) a :str = SparkExamplesIterable(UpperCAmelCase_ ) assert it.n_shards == 1 for i, (row_id, row_dict) in enumerate(UpperCAmelCase_ ): assert row_id == F'''0_{i}''' assert row_dict == {"id": i} @require_not_windows @require_dill_gt_0_3_2 def __lowerCamelCase ( ): """simple docstring""" a :List[Any] = pyspark.sql.SparkSession.builder.master('''local[*]''' ).appName('''pyspark''' ).getOrCreate() a :Dict = spark.range(30 ).repartition(3 ) # Mock the generator so that shuffle reverses the partition indices. with patch('''numpy.random.Generator''' ) as generator_mock: a :Optional[int] = lambda UpperCAmelCase_ : x.reverse() a :Tuple = _get_expected_row_ids_and_row_dicts_for_partition_order(UpperCAmelCase_ , [2, 1, 0] ) a :str = SparkExamplesIterable(UpperCAmelCase_ ).shuffle_data_sources(UpperCAmelCase_ ) assert shuffled_it.n_shards == 3 for i, (row_id, row_dict) in enumerate(UpperCAmelCase_ ): a , a :str = expected_row_ids_and_row_dicts[i] assert row_id == expected_row_id assert row_dict == expected_row_dict @require_not_windows @require_dill_gt_0_3_2 def __lowerCamelCase ( ): """simple docstring""" a :List[str] = pyspark.sql.SparkSession.builder.master('''local[*]''' ).appName('''pyspark''' ).getOrCreate() a :Optional[Any] = spark.range(20 ).repartition(4 ) # Partitions 0 and 2 a :Tuple = SparkExamplesIterable(UpperCAmelCase_ ).shard_data_sources(worker_id=0 , num_workers=2 ) assert shard_it_a.n_shards == 2 a :List[str] = _get_expected_row_ids_and_row_dicts_for_partition_order(UpperCAmelCase_ , [0, 2] ) for i, (row_id, row_dict) in enumerate(UpperCAmelCase_ ): a , a :List[Any] = expected_row_ids_and_row_dicts_a[i] assert row_id == expected_row_id assert row_dict == expected_row_dict # Partitions 1 and 3 a :Tuple = SparkExamplesIterable(UpperCAmelCase_ ).shard_data_sources(worker_id=1 , num_workers=2 ) assert shard_it_a.n_shards == 2 a :Optional[int] = _get_expected_row_ids_and_row_dicts_for_partition_order(UpperCAmelCase_ , [1, 3] ) for i, (row_id, row_dict) in enumerate(UpperCAmelCase_ ): a , a :Any = expected_row_ids_and_row_dicts_a[i] assert row_id == expected_row_id assert row_dict == expected_row_dict @require_not_windows @require_dill_gt_0_3_2 def __lowerCamelCase ( ): """simple docstring""" a :List[Any] = pyspark.sql.SparkSession.builder.master('''local[*]''' ).appName('''pyspark''' ).getOrCreate() a :Dict = spark.range(100 ).repartition(1 ) a :Dict = Spark(UpperCAmelCase_ ) # Choose a small max_shard_size for maximum partitioning. spark_builder._repartition_df_if_needed(max_shard_size=1 ) # The new number of partitions should not be greater than the number of rows. assert spark_builder.df.rdd.getNumPartitions() == 100
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import collections import inspect import unittest from transformers import FocalNetConfig 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_backbone_common import BackboneTesterMixin 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 ( FocalNetBackbone, FocalNetForImageClassification, FocalNetForMaskedImageModeling, FocalNetModel, ) from transformers.models.focalnet.modeling_focalnet import FOCALNET_PRETRAINED_MODEL_ARCHIVE_LIST if is_vision_available(): from PIL import Image from transformers import AutoImageProcessor class __lowerCAmelCase : """simple docstring""" def __init__( self , lowerCamelCase__ , lowerCamelCase__=13 , lowerCamelCase__=32 , lowerCamelCase__=2 , lowerCamelCase__=3 , lowerCamelCase__=16 , lowerCamelCase__=[32, 64, 128] , lowerCamelCase__=[1, 2, 1] , lowerCamelCase__=[2, 2, 4] , lowerCamelCase__=2 , lowerCamelCase__=2.0 , lowerCamelCase__=True , lowerCamelCase__=0.0 , lowerCamelCase__=0.0 , lowerCamelCase__=0.1 , lowerCamelCase__="gelu" , lowerCamelCase__=False , lowerCamelCase__=True , lowerCamelCase__=0.02 , lowerCamelCase__=1e-5 , lowerCamelCase__=True , lowerCamelCase__=None , lowerCamelCase__=True , lowerCamelCase__=10 , lowerCamelCase__=8 , lowerCamelCase__=["stage1", "stage2"] , lowerCamelCase__=[1, 2] , ) -> int: '''simple docstring''' __lowerCamelCase = parent __lowerCamelCase = batch_size __lowerCamelCase = image_size __lowerCamelCase = patch_size __lowerCamelCase = num_channels __lowerCamelCase = embed_dim __lowerCamelCase = hidden_sizes __lowerCamelCase = depths __lowerCamelCase = num_heads __lowerCamelCase = window_size __lowerCamelCase = mlp_ratio __lowerCamelCase = qkv_bias __lowerCamelCase = hidden_dropout_prob __lowerCamelCase = attention_probs_dropout_prob __lowerCamelCase = drop_path_rate __lowerCamelCase = hidden_act __lowerCamelCase = use_absolute_embeddings __lowerCamelCase = patch_norm __lowerCamelCase = layer_norm_eps __lowerCamelCase = initializer_range __lowerCamelCase = is_training __lowerCamelCase = scope __lowerCamelCase = use_labels __lowerCamelCase = type_sequence_label_size __lowerCamelCase = encoder_stride __lowerCamelCase = out_features __lowerCamelCase = out_indices def lowercase_ ( self ) -> List[Any]: '''simple docstring''' __lowerCamelCase = floats_tensor([self.batch_size, self.num_channels, self.image_size, self.image_size] ) __lowerCamelCase = None if self.use_labels: __lowerCamelCase = ids_tensor([self.batch_size] , self.type_sequence_label_size ) __lowerCamelCase = self.get_config() return config, pixel_values, labels def lowercase_ ( self ) -> List[str]: '''simple docstring''' return FocalNetConfig( image_size=self.image_size , patch_size=self.patch_size , num_channels=self.num_channels , embed_dim=self.embed_dim , hidden_sizes=self.hidden_sizes , 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 lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> int: '''simple docstring''' __lowerCamelCase = FocalNetModel(config=lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model(lowerCamelCase__ ) __lowerCamelCase = ((config.image_size // config.patch_size) ** 2) // (4 ** (len(config.depths ) - 1)) __lowerCamelCase = int(config.embed_dim * 2 ** (len(config.depths ) - 1) ) self.parent.assertEqual(result.last_hidden_state.shape , (self.batch_size, expected_seq_len, expected_dim) ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> List[Any]: '''simple docstring''' __lowerCamelCase = FocalNetBackbone(config=lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model(lowerCamelCase__ ) # verify feature maps self.parent.assertEqual(len(result.feature_maps ) , len(config.out_features ) ) self.parent.assertListEqual(list(result.feature_maps[0].shape ) , [self.batch_size, self.image_size, 8, 8] ) # verify channels self.parent.assertEqual(len(model.channels ) , len(config.out_features ) ) self.parent.assertListEqual(model.channels , config.hidden_sizes[:-1] ) # verify backbone works with out_features=None __lowerCamelCase = None __lowerCamelCase = FocalNetBackbone(config=lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model(lowerCamelCase__ ) # verify feature maps self.parent.assertEqual(len(result.feature_maps ) , 1 ) self.parent.assertListEqual(list(result.feature_maps[0].shape ) , [self.batch_size, self.image_size * 2, 4, 4] ) # verify channels self.parent.assertEqual(len(model.channels ) , 1 ) self.parent.assertListEqual(model.channels , [config.hidden_sizes[-1]] ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> int: '''simple docstring''' __lowerCamelCase = FocalNetForMaskedImageModeling(config=lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model(lowerCamelCase__ ) self.parent.assertEqual( result.reconstruction.shape , (self.batch_size, self.num_channels, self.image_size, self.image_size) ) # test greyscale images __lowerCamelCase = 1 __lowerCamelCase = FocalNetForMaskedImageModeling(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = floats_tensor([self.batch_size, 1, self.image_size, self.image_size] ) __lowerCamelCase = model(lowerCamelCase__ ) self.parent.assertEqual(result.reconstruction.shape , (self.batch_size, 1, self.image_size, self.image_size) ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> str: '''simple docstring''' __lowerCamelCase = self.type_sequence_label_size __lowerCamelCase = FocalNetForImageClassification(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model(lowerCamelCase__ , labels=lowerCamelCase__ ) self.parent.assertEqual(result.logits.shape , (self.batch_size, self.type_sequence_label_size) ) # test greyscale images __lowerCamelCase = 1 __lowerCamelCase = FocalNetForImageClassification(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = floats_tensor([self.batch_size, 1, self.image_size, self.image_size] ) __lowerCamelCase = model(lowerCamelCase__ ) self.parent.assertEqual(result.logits.shape , (self.batch_size, self.type_sequence_label_size) ) def lowercase_ ( self ) -> Tuple: '''simple docstring''' __lowerCamelCase = self.prepare_config_and_inputs() __lowerCamelCase , __lowerCamelCase , __lowerCamelCase = config_and_inputs __lowerCamelCase = {'pixel_values': pixel_values} return config, inputs_dict @require_torch class __lowerCAmelCase ( __magic_name__ , __magic_name__ , unittest.TestCase ): """simple docstring""" snake_case_ = ( ( FocalNetModel, FocalNetForImageClassification, FocalNetForMaskedImageModeling, FocalNetBackbone, ) if is_torch_available() else () ) snake_case_ = ( {'''feature-extraction''': FocalNetModel, '''image-classification''': FocalNetForImageClassification} if is_torch_available() else {} ) snake_case_ = False snake_case_ = False snake_case_ = False snake_case_ = False snake_case_ = False def lowercase_ ( self ) -> str: '''simple docstring''' __lowerCamelCase = FocalNetModelTester(self ) __lowerCamelCase = ConfigTester(self , config_class=lowerCamelCase__ , embed_dim=37 , has_text_modality=lowerCamelCase__ ) def lowercase_ ( self ) -> str: '''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 lowercase_ ( self ) -> str: '''simple docstring''' return def lowercase_ ( self ) -> List[Any]: '''simple docstring''' __lowerCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_model(*lowerCamelCase__ ) def lowercase_ ( self ) -> Optional[Any]: '''simple docstring''' __lowerCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_backbone(*lowerCamelCase__ ) def lowercase_ ( self ) -> str: '''simple docstring''' __lowerCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_for_masked_image_modeling(*lowerCamelCase__ ) def lowercase_ ( self ) -> Any: '''simple docstring''' __lowerCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_for_image_classification(*lowerCamelCase__ ) @unittest.skip(reason='FocalNet does not use inputs_embeds' ) def lowercase_ ( self ) -> Optional[int]: '''simple docstring''' pass @unittest.skip(reason='FocalNet does not use feedforward chunking' ) def lowercase_ ( self ) -> Union[str, Any]: '''simple docstring''' pass def lowercase_ ( self ) -> Dict: '''simple docstring''' __lowerCamelCase , __lowerCamelCase = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes[:-1]: __lowerCamelCase = model_class(lowerCamelCase__ ) self.assertIsInstance(model.get_input_embeddings() , (nn.Module) ) __lowerCamelCase = model.get_output_embeddings() self.assertTrue(x is None or isinstance(lowerCamelCase__ , nn.Linear ) ) def lowercase_ ( self ) -> str: '''simple docstring''' __lowerCamelCase , __lowerCamelCase = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes[:-1]: __lowerCamelCase = model_class(lowerCamelCase__ ) __lowerCamelCase = inspect.signature(model.forward ) # signature.parameters is an OrderedDict => so arg_names order is deterministic __lowerCamelCase = [*signature.parameters.keys()] __lowerCamelCase = ['pixel_values'] self.assertListEqual(arg_names[:1] , lowerCamelCase__ ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> int: '''simple docstring''' __lowerCamelCase = model_class(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() with torch.no_grad(): __lowerCamelCase = model(**self._prepare_for_class(lowerCamelCase__ , lowerCamelCase__ ) ) __lowerCamelCase = outputs.hidden_states __lowerCamelCase = getattr( self.model_tester , 'expected_num_hidden_layers' , len(self.model_tester.depths ) + 1 ) self.assertEqual(len(lowerCamelCase__ ) , lowerCamelCase__ ) # FocalNet has a different seq_length __lowerCamelCase = ( config.patch_size if isinstance(config.patch_size , collections.abc.Iterable ) else (config.patch_size, config.patch_size) ) __lowerCamelCase = (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] , ) __lowerCamelCase = outputs.reshaped_hidden_states self.assertEqual(len(lowerCamelCase__ ) , lowerCamelCase__ ) __lowerCamelCase , __lowerCamelCase , __lowerCamelCase , __lowerCamelCase = reshaped_hidden_states[0].shape __lowerCamelCase = ( reshaped_hidden_states[0].view(lowerCamelCase__ , lowerCamelCase__ , height * width ).permute(0 , 2 , 1 ) ) self.assertListEqual( list(reshaped_hidden_states.shape[-2:] ) , [num_patches, self.model_tester.embed_dim] , ) def lowercase_ ( self ) -> Dict: '''simple docstring''' __lowerCamelCase , __lowerCamelCase = self.model_tester.prepare_config_and_inputs_for_common() __lowerCamelCase = ( 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[:-1]: __lowerCamelCase = True self.check_hidden_states_output(lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) # check that output_hidden_states also work using config del inputs_dict["output_hidden_states"] __lowerCamelCase = True self.check_hidden_states_output(lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) def lowercase_ ( self ) -> Optional[Any]: '''simple docstring''' __lowerCamelCase , __lowerCamelCase = self.model_tester.prepare_config_and_inputs_for_common() __lowerCamelCase = 3 __lowerCamelCase = ( 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) ) __lowerCamelCase = ( config.patch_size if isinstance(config.patch_size , collections.abc.Iterable ) else (config.patch_size, config.patch_size) ) __lowerCamelCase = image_size[0] + patch_size[0] - (image_size[0] % patch_size[0]) __lowerCamelCase = image_size[1] + patch_size[1] - (image_size[1] % patch_size[1]) for model_class in self.all_model_classes[:-1]: __lowerCamelCase = True self.check_hidden_states_output(lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , (padded_height, padded_width) ) # check that output_hidden_states also work using config del inputs_dict["output_hidden_states"] __lowerCamelCase = True self.check_hidden_states_output(lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , (padded_height, padded_width) ) @slow def lowercase_ ( self ) -> str: '''simple docstring''' for model_name in FOCALNET_PRETRAINED_MODEL_ARCHIVE_LIST[:1]: __lowerCamelCase = FocalNetModel.from_pretrained(lowerCamelCase__ ) self.assertIsNotNone(lowerCamelCase__ ) def lowercase_ ( self ) -> Optional[int]: '''simple docstring''' __lowerCamelCase , __lowerCamelCase = self.model_tester.prepare_config_and_inputs_for_common() __lowerCamelCase = _config_zero_init(lowerCamelCase__ ) for model_class in self.all_model_classes: __lowerCamelCase = model_class(config=lowerCamelCase__ ) for name, param in model.named_parameters(): if "embeddings" 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 lowercase_ ( self ) -> List[str]: '''simple docstring''' # TODO update organization return AutoImageProcessor.from_pretrained('microsoft/focalnet-tiny' ) if is_vision_available() else None @slow def lowercase_ ( self ) -> List[Any]: '''simple docstring''' __lowerCamelCase = FocalNetForImageClassification.from_pretrained('microsoft/focalnet-tiny' ).to(lowerCamelCase__ ) __lowerCamelCase = self.default_image_processor __lowerCamelCase = Image.open('./tests/fixtures/tests_samples/COCO/000000039769.png' ) __lowerCamelCase = image_processor(images=lowerCamelCase__ , return_tensors='pt' ).to(lowerCamelCase__ ) # forward pass with torch.no_grad(): __lowerCamelCase = model(**lowerCamelCase__ ) # verify the logits __lowerCamelCase = torch.Size((1, 1_000) ) self.assertEqual(outputs.logits.shape , lowerCamelCase__ ) __lowerCamelCase = torch.tensor([0.21_66, -0.43_68, 0.21_91] ).to(lowerCamelCase__ ) self.assertTrue(torch.allclose(outputs.logits[0, :3] , lowerCamelCase__ , atol=1e-4 ) ) self.assertTrue(outputs.logits.argmax(dim=-1 ).item() , 281 ) @require_torch class __lowerCAmelCase ( __magic_name__ , unittest.TestCase ): """simple docstring""" snake_case_ = (FocalNetBackbone,) if is_torch_available() else () snake_case_ = FocalNetConfig snake_case_ = False def lowercase_ ( self ) -> Any: '''simple docstring''' __lowerCamelCase = FocalNetModelTester(self )
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def _A ( SCREAMING_SNAKE_CASE : str , SCREAMING_SNAKE_CASE : str ): """simple docstring""" a__ : int =len(SCREAMING_SNAKE_CASE ) a__ : int =len(SCREAMING_SNAKE_CASE ) a__ : int =( first_str_length if first_str_length > second_str_length else second_str_length ) a__ : list =[] for char_count in range(SCREAMING_SNAKE_CASE ): if char_count < first_str_length: output_list.append(first_str[char_count] ) if char_count < second_str_length: output_list.append(second_str[char_count] ) return "".join(SCREAMING_SNAKE_CASE ) if __name__ == "__main__": print(alternative_string_arrange("""AB""", """XYZ"""), end=""" """)
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from typing import TYPE_CHECKING from ...utils import OptionalDependencyNotAvailable, _LazyModule, is_speech_available, is_torch_available __A = { "configuration_audio_spectrogram_transformer": [ "AUDIO_SPECTROGRAM_TRANSFORMER_PRETRAINED_CONFIG_ARCHIVE_MAP", "ASTConfig", ] } try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __A = [ "AUDIO_SPECTROGRAM_TRANSFORMER_PRETRAINED_MODEL_ARCHIVE_LIST", "ASTForAudioClassification", "ASTModel", "ASTPreTrainedModel", ] try: if not is_speech_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __A = ["ASTFeatureExtractor"] if TYPE_CHECKING: from .configuration_audio_spectrogram_transformer import ( AUDIO_SPECTROGRAM_TRANSFORMER_PRETRAINED_CONFIG_ARCHIVE_MAP, ASTConfig, ) try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_audio_spectrogram_transformer import ( AUDIO_SPECTROGRAM_TRANSFORMER_PRETRAINED_MODEL_ARCHIVE_LIST, ASTForAudioClassification, ASTModel, ASTPreTrainedModel, ) try: if not is_speech_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .feature_extraction_audio_spectrogram_transformer import ASTFeatureExtractor else: import sys __A = _LazyModule(__name__, globals()["__file__"], _import_structure, module_spec=__spec__)
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"""simple docstring""" from .configuration_bert_masked import MaskedBertConfig from .modeling_bert_masked import ( MaskedBertForMultipleChoice, MaskedBertForQuestionAnswering, MaskedBertForSequenceClassification, MaskedBertForTokenClassification, MaskedBertModel, ) from .modules import *
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import argparse import os import pickle import sys import torch from transformers import TransfoXLConfig, TransfoXLLMHeadModel, load_tf_weights_in_transfo_xl from transformers.models.transfo_xl import tokenization_transfo_xl as data_utils from transformers.models.transfo_xl.tokenization_transfo_xl import CORPUS_NAME, VOCAB_FILES_NAMES from transformers.utils import CONFIG_NAME, WEIGHTS_NAME, logging logging.set_verbosity_info() # We do this to be able to load python 2 datasets pickles # See e.g. https://stackoverflow.com/questions/2121874/python-pickling-after-changing-a-modules-directory/2121918#2121918 __A = data_utils.TransfoXLTokenizer __A = data_utils.TransfoXLCorpus __A = data_utils __A = data_utils def lowerCamelCase_ ( UpperCamelCase__ : List[str] , UpperCamelCase__ : Optional[int] , UpperCamelCase__ : Union[str, Any] , UpperCamelCase__ : Optional[Any] ) -> Union[str, Any]: """simple docstring""" if transfo_xl_dataset_file: # Convert a pre-processed corpus (see original TensorFlow repo) with open(UpperCamelCase__ , 'rb' ) as fp: __lowerCamelCase = pickle.load(UpperCamelCase__ , encoding='latin1' ) # Save vocabulary and dataset cache as Dictionaries (should be better than pickles for the long-term) __lowerCamelCase = pytorch_dump_folder_path + '/' + VOCAB_FILES_NAMES['pretrained_vocab_file'] print(F"""Save vocabulary to {pytorch_vocab_dump_path}""" ) __lowerCamelCase = corpus.vocab.__dict__ torch.save(UpperCamelCase__ , UpperCamelCase__ ) __lowerCamelCase = corpus.__dict__ corpus_dict_no_vocab.pop('vocab' , UpperCamelCase__ ) __lowerCamelCase = pytorch_dump_folder_path + '/' + CORPUS_NAME print(F"""Save dataset to {pytorch_dataset_dump_path}""" ) torch.save(UpperCamelCase__ , UpperCamelCase__ ) if tf_checkpoint_path: # Convert a pre-trained TensorFlow model __lowerCamelCase = os.path.abspath(UpperCamelCase__ ) __lowerCamelCase = os.path.abspath(UpperCamelCase__ ) print(F"""Converting Transformer XL checkpoint from {tf_path} with config at {config_path}.""" ) # Initialise PyTorch model if transfo_xl_config_file == "": __lowerCamelCase = TransfoXLConfig() else: __lowerCamelCase = TransfoXLConfig.from_json_file(UpperCamelCase__ ) print(F"""Building PyTorch model from configuration: {config}""" ) __lowerCamelCase = TransfoXLLMHeadModel(UpperCamelCase__ ) __lowerCamelCase = load_tf_weights_in_transfo_xl(UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ ) # Save pytorch-model __lowerCamelCase = os.path.join(UpperCamelCase__ , UpperCamelCase__ ) __lowerCamelCase = os.path.join(UpperCamelCase__ , UpperCamelCase__ ) print(F"""Save PyTorch model to {os.path.abspath(UpperCamelCase__ )}""" ) torch.save(model.state_dict() , UpperCamelCase__ ) print(F"""Save configuration file to {os.path.abspath(UpperCamelCase__ )}""" ) with open(UpperCamelCase__ , 'w' , encoding='utf-8' ) as f: f.write(config.to_json_string() ) if __name__ == "__main__": __A = argparse.ArgumentParser() parser.add_argument( "--pytorch_dump_folder_path", default=None, type=str, required=True, help="Path to the folder to store the PyTorch model or dataset/vocab.", ) parser.add_argument( "--tf_checkpoint_path", default="", type=str, help="An optional path to a TensorFlow checkpoint path to be converted.", ) parser.add_argument( "--transfo_xl_config_file", default="", type=str, help=( "An optional config json file corresponding to the pre-trained BERT model. \n" "This specifies the model architecture." ), ) parser.add_argument( "--transfo_xl_dataset_file", default="", type=str, help="An optional dataset file to be converted in a vocabulary.", ) __A = parser.parse_args() convert_transfo_xl_checkpoint_to_pytorch( args.tf_checkpoint_path, args.transfo_xl_config_file, args.pytorch_dump_folder_path, args.transfo_xl_dataset_file, )
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'''simple docstring''' import os import tempfile import unittest import uuid from pathlib import Path from transformers.testing_utils import get_tests_dir, require_soundfile, require_torch, require_vision from transformers.tools.agent_types import AgentAudio, AgentImage, AgentText from transformers.utils import is_soundfile_availble, is_torch_available, is_vision_available if is_torch_available(): import torch if is_soundfile_availble(): import soundfile as sf if is_vision_available(): from PIL import Image def a ( __a="" ) -> str: '''simple docstring''' UpperCamelCase__ :Dict = tempfile.mkdtemp() return os.path.join(__a , str(uuid.uuida() ) + suffix ) @require_soundfile @require_torch class lowercase ( unittest.TestCase ): """simple docstring""" def lowerCAmelCase__ ( self ): '''simple docstring''' UpperCamelCase__ :List[Any] = torch.rand(12 , dtype=torch.floataa ) - 0.5 UpperCamelCase__ :str = AgentAudio(UpperCamelCase_ ) UpperCamelCase__ :Tuple = str(agent_type.to_string() ) # Ensure that the tensor and the agent_type's tensor are the same self.assertTrue(torch.allclose(UpperCamelCase_ , agent_type.to_raw() , atol=1e-4 ) ) del agent_type # Ensure the path remains even after the object deletion self.assertTrue(os.path.exists(UpperCamelCase_ ) ) # Ensure that the file contains the same value as the original tensor UpperCamelCase__ , UpperCamelCase__ :Union[str, Any] = sf.read(UpperCamelCase_ ) self.assertTrue(torch.allclose(UpperCamelCase_ , torch.tensor(UpperCamelCase_ ) , atol=1e-4 ) ) def lowerCAmelCase__ ( self ): '''simple docstring''' UpperCamelCase__ :Optional[int] = torch.rand(12 , dtype=torch.floataa ) - 0.5 UpperCamelCase__ :Optional[Any] = get_new_path(suffix='''.wav''' ) sf.write(UpperCamelCase_ , UpperCamelCase_ , 16000 ) UpperCamelCase__ :List[Any] = AgentAudio(UpperCamelCase_ ) self.assertTrue(torch.allclose(UpperCamelCase_ , agent_type.to_raw() , atol=1e-4 ) ) self.assertEqual(agent_type.to_string() , UpperCamelCase_ ) @require_vision @require_torch class lowercase ( unittest.TestCase ): """simple docstring""" def lowerCAmelCase__ ( self ): '''simple docstring''' UpperCamelCase__ :Optional[int] = torch.randint(0 , 256 , (64, 64, 3) ) UpperCamelCase__ :List[str] = AgentImage(UpperCamelCase_ ) UpperCamelCase__ :List[Any] = str(agent_type.to_string() ) # Ensure that the tensor and the agent_type's tensor are the same self.assertTrue(torch.allclose(UpperCamelCase_ , agent_type._tensor , atol=1e-4 ) ) self.assertIsInstance(agent_type.to_raw() , Image.Image ) # Ensure the path remains even after the object deletion del agent_type self.assertTrue(os.path.exists(UpperCamelCase_ ) ) def lowerCAmelCase__ ( self ): '''simple docstring''' UpperCamelCase__ :Tuple = Path(get_tests_dir('''fixtures/tests_samples/COCO''' ) ) / '''000000039769.png''' UpperCamelCase__ :str = Image.open(UpperCamelCase_ ) UpperCamelCase__ :int = AgentImage(UpperCamelCase_ ) self.assertTrue(path.samefile(agent_type.to_string() ) ) self.assertTrue(image == agent_type.to_raw() ) # Ensure the path remains even after the object deletion del agent_type self.assertTrue(os.path.exists(UpperCamelCase_ ) ) def lowerCAmelCase__ ( self ): '''simple docstring''' UpperCamelCase__ :Optional[Any] = Path(get_tests_dir('''fixtures/tests_samples/COCO''' ) ) / '''000000039769.png''' UpperCamelCase__ :List[Any] = Image.open(UpperCamelCase_ ) UpperCamelCase__ :Optional[Any] = AgentImage(UpperCamelCase_ ) self.assertFalse(path.samefile(agent_type.to_string() ) ) self.assertTrue(image == agent_type.to_raw() ) # Ensure the path remains even after the object deletion del agent_type self.assertTrue(os.path.exists(UpperCamelCase_ ) ) class lowercase ( unittest.TestCase ): """simple docstring""" def lowerCAmelCase__ ( self ): '''simple docstring''' UpperCamelCase__ :List[str] = '''Hey!''' UpperCamelCase__ :str = AgentText(UpperCamelCase_ ) self.assertEqual(UpperCamelCase_ , agent_type.to_string() ) self.assertEqual(UpperCamelCase_ , agent_type.to_raw() ) self.assertEqual(UpperCamelCase_ , UpperCamelCase_ )
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import argparse import shutil from pathlib import Path from tqdm import tqdm from transformers import AutoTokenizer def lowerCamelCase_ ( UpperCamelCase__ : List[Any] , UpperCamelCase__ : Optional[int] , UpperCamelCase__ : str , UpperCamelCase__ : Any=1024 ) -> Dict: """simple docstring""" __lowerCamelCase , __lowerCamelCase = [], [] __lowerCamelCase = list(zip(UpperCamelCase__ , UpperCamelCase__ ) ) __lowerCamelCase , __lowerCamelCase = sorted_examples[0] def is_too_big(UpperCamelCase__ : List[str] ): return tok(UpperCamelCase__ , return_tensors='pt' ).input_ids.shape[1] > max_tokens for src, tgt in tqdm(sorted_examples[1:] ): __lowerCamelCase = new_src + ' ' + src __lowerCamelCase = new_tgt + ' ' + tgt if is_too_big(UpperCamelCase__ ) or is_too_big(UpperCamelCase__ ): # cant fit, finalize example finished_src.append(UpperCamelCase__ ) finished_tgt.append(UpperCamelCase__ ) __lowerCamelCase , __lowerCamelCase = src, tgt else: # can fit, keep adding __lowerCamelCase , __lowerCamelCase = cand_src, cand_tgt # cleanup if new_src: assert new_tgt finished_src.append(UpperCamelCase__ ) finished_tgt.append(UpperCamelCase__ ) return finished_src, finished_tgt def lowerCamelCase_ ( UpperCamelCase__ : str , UpperCamelCase__ : Path , UpperCamelCase__ : Optional[int] , UpperCamelCase__ : str ) -> Optional[int]: """simple docstring""" __lowerCamelCase = Path(UpperCamelCase__ ) save_path.mkdir(exist_ok=UpperCamelCase__ ) for split in ["train"]: __lowerCamelCase , __lowerCamelCase = data_dir / F"""{split}.source""", data_dir / F"""{split}.target""" __lowerCamelCase = [x.rstrip() for x in Path(UpperCamelCase__ ).open().readlines()] __lowerCamelCase = [x.rstrip() for x in Path(UpperCamelCase__ ).open().readlines()] __lowerCamelCase , __lowerCamelCase = pack_examples(UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ ) print(F"""packed {split} split from {len(UpperCamelCase__ )} examples -> {len(UpperCamelCase__ )}.""" ) Path(save_path / F"""{split}.source""" ).open('w' ).write('\n'.join(UpperCamelCase__ ) ) Path(save_path / F"""{split}.target""" ).open('w' ).write('\n'.join(UpperCamelCase__ ) ) for split in ["val", "test"]: __lowerCamelCase , __lowerCamelCase = data_dir / F"""{split}.source""", data_dir / F"""{split}.target""" shutil.copyfile(UpperCamelCase__ , save_path / F"""{split}.source""" ) shutil.copyfile(UpperCamelCase__ , save_path / F"""{split}.target""" ) def lowerCamelCase_ ( ) -> List[str]: """simple docstring""" __lowerCamelCase = argparse.ArgumentParser() parser.add_argument('--tok_name' , type=UpperCamelCase__ , help='like facebook/bart-large-cnn,t5-base, etc.' ) parser.add_argument('--max_seq_len' , type=UpperCamelCase__ , default=128 ) parser.add_argument('--data_dir' , type=UpperCamelCase__ ) parser.add_argument('--save_path' , type=UpperCamelCase__ ) __lowerCamelCase = parser.parse_args() __lowerCamelCase = AutoTokenizer.from_pretrained(args.tok_name ) return pack_data_dir(UpperCamelCase__ , Path(args.data_dir ) , args.max_seq_len , args.save_path ) if __name__ == "__main__": packer_cli()
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"""simple docstring""" import hashlib import unittest from typing import Dict import numpy as np from transformers import ( MODEL_FOR_MASK_GENERATION_MAPPING, TF_MODEL_FOR_MASK_GENERATION_MAPPING, is_vision_available, pipeline, ) from transformers.pipelines import MaskGenerationPipeline from transformers.testing_utils import ( is_pipeline_test, nested_simplify, require_tf, require_torch, require_vision, slow, ) if is_vision_available(): from PIL import Image else: class snake_case : """simple docstring""" @staticmethod def __lowerCAmelCase ( *lowerCamelCase__ : List[Any] ,**lowerCamelCase__ : Union[str, Any] ): pass def a_ ( lowerCamelCase ): UpperCAmelCase__ = hashlib.mda(image.tobytes() ) return m.hexdigest()[:1_0] def a_ ( lowerCamelCase ): UpperCAmelCase__ = np.array(lowerCamelCase ) UpperCAmelCase__ = npimg.shape return {"hash": hashimage(lowerCamelCase ), "shape": shape} @is_pipeline_test @require_vision @require_torch class snake_case ( unittest.TestCase ): """simple docstring""" snake_case__ = dict( (list(MODEL_FOR_MASK_GENERATION_MAPPING.items() ) if MODEL_FOR_MASK_GENERATION_MAPPING else []) ) snake_case__ = dict( (list(TF_MODEL_FOR_MASK_GENERATION_MAPPING.items() ) if TF_MODEL_FOR_MASK_GENERATION_MAPPING else []) ) def __lowerCAmelCase ( self : List[Any] ,lowerCamelCase__ : Dict ,lowerCamelCase__ : Optional[int] ,lowerCamelCase__ : str ): UpperCAmelCase__ = MaskGenerationPipeline(model=lowerCamelCase__ ,image_processor=lowerCamelCase__ ) return image_segmenter, [ "./tests/fixtures/tests_samples/COCO/000000039769.png", "./tests/fixtures/tests_samples/COCO/000000039769.png", ] def __lowerCAmelCase ( self : Union[str, Any] ,lowerCamelCase__ : Tuple ,lowerCamelCase__ : str ): pass @require_tf @unittest.skip('Image segmentation not implemented in TF' ) def __lowerCAmelCase ( self : Optional[Any] ): pass @slow @require_torch def __lowerCAmelCase ( self : List[str] ): UpperCAmelCase__ = pipeline('mask-generation' ,model='facebook/sam-vit-huge' ) UpperCAmelCase__ = image_segmenter('http://images.cocodataset.org/val2017/000000039769.jpg' ,points_per_batch=256 ) # Shortening by hashing UpperCAmelCase__ = [] for i, o in enumerate(outputs['masks'] ): new_outupt += [{"mask": mask_to_test_readable(lowerCamelCase__ ), "scores": outputs["scores"][i]}] # fmt: off self.assertEqual( nested_simplify(lowerCamelCase__ ,decimals=4 ) ,[ {'mask': {'hash': '115ad19f5f', 'shape': (480, 640)}, 'scores': 1.0_4_4_4}, {'mask': {'hash': '6affa964c6', 'shape': (480, 640)}, 'scores': 1.0_2_1}, {'mask': {'hash': 'dfe28a0388', 'shape': (480, 640)}, 'scores': 1.0_1_6_7}, {'mask': {'hash': 'c0a5f4a318', 'shape': (480, 640)}, 'scores': 1.0_1_3_2}, {'mask': {'hash': 'fe8065c197', 'shape': (480, 640)}, 'scores': 1.0_0_5_3}, {'mask': {'hash': 'e2d0b7a0b7', 'shape': (480, 640)}, 'scores': 0.9_9_6_7}, {'mask': {'hash': '453c7844bd', 'shape': (480, 640)}, 'scores': 0.9_9_3}, {'mask': {'hash': '3d44f2926d', 'shape': (480, 640)}, 'scores': 0.9_9_0_9}, {'mask': {'hash': '64033ddc3f', 'shape': (480, 640)}, 'scores': 0.9_8_7_9}, {'mask': {'hash': '801064ff79', 'shape': (480, 640)}, 'scores': 0.9_8_3_4}, {'mask': {'hash': '6172f276ef', 'shape': (480, 640)}, 'scores': 0.9_7_1_6}, {'mask': {'hash': 'b49e60e084', 'shape': (480, 640)}, 'scores': 0.9_6_1_2}, {'mask': {'hash': 'a811e775fd', 'shape': (480, 640)}, 'scores': 0.9_5_9_9}, {'mask': {'hash': 'a6a8ebcf4b', 'shape': (480, 640)}, 'scores': 0.9_5_5_2}, {'mask': {'hash': '9d8257e080', 'shape': (480, 640)}, 'scores': 0.9_5_3_2}, {'mask': {'hash': '32de6454a8', 'shape': (480, 640)}, 'scores': 0.9_5_1_6}, {'mask': {'hash': 'af3d4af2c8', 'shape': (480, 640)}, 'scores': 0.9_4_9_9}, {'mask': {'hash': '3c6db475fb', 'shape': (480, 640)}, 'scores': 0.9_4_8_3}, {'mask': {'hash': 'c290813fb9', 'shape': (480, 640)}, 'scores': 0.9_4_6_4}, {'mask': {'hash': 'b6f0b8f606', 'shape': (480, 640)}, 'scores': 0.9_4_3}, {'mask': {'hash': '92ce16bfdf', 'shape': (480, 640)}, 'scores': 0.9_4_3}, {'mask': {'hash': 'c749b25868', 'shape': (480, 640)}, 'scores': 0.9_4_0_8}, {'mask': {'hash': 'efb6cab859', 'shape': (480, 640)}, 'scores': 0.9_3_3_5}, {'mask': {'hash': '1ff2eafb30', 'shape': (480, 640)}, 'scores': 0.9_3_2_6}, {'mask': {'hash': '788b798e24', 'shape': (480, 640)}, 'scores': 0.9_2_6_2}, {'mask': {'hash': 'abea804f0e', 'shape': (480, 640)}, 'scores': 0.8_9_9_9}, {'mask': {'hash': '7b9e8ddb73', 'shape': (480, 640)}, 'scores': 0.8_9_8_6}, {'mask': {'hash': 'cd24047c8a', 'shape': (480, 640)}, 'scores': 0.8_9_8_4}, {'mask': {'hash': '6943e6bcbd', 'shape': (480, 640)}, 'scores': 0.8_8_7_3}, {'mask': {'hash': 'b5f47c9191', 'shape': (480, 640)}, 'scores': 0.8_8_7_1} ] ,) # fmt: on @require_torch @slow def __lowerCAmelCase ( self : Optional[Any] ): UpperCAmelCase__ = 'facebook/sam-vit-huge' UpperCAmelCase__ = pipeline('mask-generation' ,model=lowerCamelCase__ ) UpperCAmelCase__ = image_segmenter( 'http://images.cocodataset.org/val2017/000000039769.jpg' ,pred_iou_thresh=1 ,points_per_batch=256 ) # Shortening by hashing UpperCAmelCase__ = [] for i, o in enumerate(outputs['masks'] ): new_outupt += [{"mask": mask_to_test_readable(lowerCamelCase__ ), "scores": outputs["scores"][i]}] self.assertEqual( nested_simplify(lowerCamelCase__ ,decimals=4 ) ,[ {'mask': {'hash': '115ad19f5f', 'shape': (480, 640)}, 'scores': 1.0_4_4_4}, {'mask': {'hash': '6affa964c6', 'shape': (480, 640)}, 'scores': 1.0_2_1_0}, {'mask': {'hash': 'dfe28a0388', 'shape': (480, 640)}, 'scores': 1.0_1_6_7}, {'mask': {'hash': 'c0a5f4a318', 'shape': (480, 640)}, 'scores': 1.0_1_3_2}, {'mask': {'hash': 'fe8065c197', 'shape': (480, 640)}, 'scores': 1.0_0_5_3}, ] ,)
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import argparse import fairseq import torch from torch import nn from transformers import ( MBartaaTokenizer, MBartConfig, MBartForCausalLM, SpeechEncoderDecoderConfig, SpeechEncoderDecoderModel, WavaVecaConfig, WavaVecaFeatureExtractor, WavaVecaModel, logging, ) logging.set_verbosity_info() __A = logging.get_logger(__name__) __A = { "post_extract_proj": "feature_projection.projection", "encoder.pos_conv.0": "encoder.pos_conv_embed.conv", "self_attn.k_proj": "encoder.layers.*.attention.k_proj", "self_attn.v_proj": "encoder.layers.*.attention.v_proj", "self_attn.q_proj": "encoder.layers.*.attention.q_proj", "self_attn.out_proj": "encoder.layers.*.attention.out_proj", "self_attn_layer_norm": "encoder.layers.*.layer_norm", "fc1": "encoder.layers.*.feed_forward.intermediate_dense", "fc2": "encoder.layers.*.feed_forward.output_dense", "final_layer_norm": "encoder.layers.*.final_layer_norm", "encoder.layer_norm": "encoder.layer_norm", "w2v_model.layer_norm": "feature_projection.layer_norm", "quantizer.weight_proj": "quantizer.weight_proj", "quantizer.vars": "quantizer.codevectors", "project_q": "project_q", "final_proj": "project_hid", "w2v_encoder.proj": "lm_head", "mask_emb": "masked_spec_embed", } __A = [ "lm_head", "quantizer.weight_proj", "quantizer.codevectors", "project_q", "project_hid", ] def lowerCamelCase_ ( UpperCamelCase__ : Any , UpperCamelCase__ : Any , UpperCamelCase__ : Optional[Any] , UpperCamelCase__ : Union[str, Any] , UpperCamelCase__ : Optional[int] ) -> Tuple: """simple docstring""" for attribute in key.split('.' ): __lowerCamelCase = getattr(UpperCamelCase__ , UpperCamelCase__ ) if weight_type is not None: __lowerCamelCase = getattr(UpperCamelCase__ , UpperCamelCase__ ).shape else: __lowerCamelCase = hf_pointer.shape assert hf_shape == value.shape, ( F"""Shape of hf {key + '.' + weight_type if weight_type is not None else ''} is {hf_shape}, but should be""" F""" {value.shape} for {full_name}""" ) if weight_type == "weight": __lowerCamelCase = value elif weight_type == "weight_g": __lowerCamelCase = value elif weight_type == "weight_v": __lowerCamelCase = value elif weight_type == "bias": __lowerCamelCase = value else: __lowerCamelCase = value logger.info(F"""{key + '.' + weight_type if weight_type is not None else ''} was initialized from {full_name}.""" ) def lowerCamelCase_ ( UpperCamelCase__ : Optional[Any] , UpperCamelCase__ : Tuple ) -> Optional[Any]: """simple docstring""" __lowerCamelCase = [] __lowerCamelCase = fairseq_model.state_dict() __lowerCamelCase = hf_model.feature_extractor __lowerCamelCase = hf_model.adapter for name, value in fairseq_dict.items(): __lowerCamelCase = False if "conv_layers" in name: load_conv_layer( UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ , hf_model.config.feat_extract_norm == 'group' , ) __lowerCamelCase = True elif any(x in name for x in ['adaptor', 'w2v_encoder.proj.', 'w2v_proj_ln.'] ): load_adapter(UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ ) __lowerCamelCase = True else: for key, mapped_key in MAPPING.items(): if key in name or key.split('w2v_model.' )[-1] == name.split('.' )[0]: __lowerCamelCase = True if "*" in mapped_key: __lowerCamelCase = name.split(UpperCamelCase__ )[0].split('.' )[-2] __lowerCamelCase = mapped_key.replace('*' , UpperCamelCase__ ) if "weight_g" in name: __lowerCamelCase = 'weight_g' elif "weight_v" in name: __lowerCamelCase = 'weight_v' elif "bias" in name: __lowerCamelCase = 'bias' elif "weight" in name: __lowerCamelCase = 'weight' else: __lowerCamelCase = None set_recursively(UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ ) continue if not is_used: unused_weights.append(UpperCamelCase__ ) logger.warning(F"""Unused weights: {unused_weights}""" ) def lowerCamelCase_ ( UpperCamelCase__ : Dict , UpperCamelCase__ : Any , UpperCamelCase__ : str , UpperCamelCase__ : Tuple , UpperCamelCase__ : Tuple ) -> int: """simple docstring""" __lowerCamelCase = full_name.split('conv_layers.' )[-1] __lowerCamelCase = name.split('.' ) __lowerCamelCase = int(items[0] ) __lowerCamelCase = int(items[1] ) if type_id == 0: if "bias" in name: assert value.shape == feature_extractor.conv_layers[layer_id].conv.bias.data.shape, ( F"""{full_name} has size {value.shape}, but""" F""" {feature_extractor.conv_layers[layer_id].conv.bias.data.shape} was found.""" ) __lowerCamelCase = value logger.info(F"""Feat extract conv layer {layer_id} was initialized from {full_name}.""" ) elif "weight" in name: assert value.shape == feature_extractor.conv_layers[layer_id].conv.weight.data.shape, ( F"""{full_name} has size {value.shape}, but""" F""" {feature_extractor.conv_layers[layer_id].conv.weight.data.shape} was found.""" ) __lowerCamelCase = value logger.info(F"""Feat extract conv layer {layer_id} was initialized from {full_name}.""" ) elif (type_id == 2 and not use_group_norm) or (type_id == 2 and layer_id == 0 and use_group_norm): if "bias" in name: assert value.shape == feature_extractor.conv_layers[layer_id].layer_norm.bias.data.shape, ( F"""{full_name} has size {value.shape}, but {feature_extractor[layer_id].layer_norm.bias.data.shape} was""" " found." ) __lowerCamelCase = value logger.info(F"""Feat extract layer norm weight of layer {layer_id} was initialized from {full_name}.""" ) elif "weight" in name: assert value.shape == feature_extractor.conv_layers[layer_id].layer_norm.weight.data.shape, ( F"""{full_name} has size {value.shape}, but""" F""" {feature_extractor[layer_id].layer_norm.weight.data.shape} was found.""" ) __lowerCamelCase = value logger.info(F"""Feat extract layer norm weight of layer {layer_id} was initialized from {full_name}.""" ) else: unused_weights.append(UpperCamelCase__ ) def lowerCamelCase_ ( UpperCamelCase__ : Tuple , UpperCamelCase__ : Optional[Any] , UpperCamelCase__ : Any , UpperCamelCase__ : int ) -> Union[str, Any]: """simple docstring""" __lowerCamelCase = full_name.split('adaptor.' )[-1] __lowerCamelCase = name.split('.' ) if items[1].isdigit(): __lowerCamelCase = int(items[1] ) else: __lowerCamelCase = None if "adaptor" not in full_name: if "proj_ln" in full_name: # has to be layer norm if "bias" in name: assert ( value.shape == adapter.proj_layer_norm.bias.data.shape ), F"""{full_name} has size {value.shape}, but {adapter.proj_layer_norm.bias.data.shape} was found.""" __lowerCamelCase = value logger.info(F"""Adapter proj layer norm bias was initialized from {full_name}.""" ) if "weight" in name: assert ( value.shape == adapter.proj_layer_norm.weight.data.shape ), F"""{full_name} has size {value.shape}, but {adapter.proj_layer_norm.weight.data.shape} was found.""" __lowerCamelCase = value else: # has to be projection layer if "bias" in name: assert ( value.shape == adapter.proj.bias.data.shape ), F"""{full_name} has size {value.shape}, but {adapter.proj.bias.data.shape} was found.""" __lowerCamelCase = value logger.info(F"""Adapter proj layer bias was initialized from {full_name}.""" ) if "weight" in name: assert ( value.shape == adapter.proj.weight.data.shape ), F"""{full_name} has size {value.shape}, but {adapter.proj.weight.data.shape} was found.""" __lowerCamelCase = value logger.info(F"""Adapter proj layer weight was initialized from {full_name}.""" ) elif isinstance(UpperCamelCase__ , UpperCamelCase__ ): if "bias" in name: assert ( value.shape == adapter.layers[layer_id].conv.bias.data.shape ), F"""{full_name} has size {value.shape}, but {adapter.layers[layer_id].conv.bias.data.shape} was found.""" __lowerCamelCase = value logger.info(F"""Adapter layer {layer_id} bias was initialized from {full_name}.""" ) elif "weight" in name: assert ( value.shape == adapter.layers[layer_id].conv.weight.data.shape ), F"""{full_name} has size {value.shape}, but {adapter.layers[layer_id].conv.weight.data.shape} was found.""" __lowerCamelCase = value logger.info(F"""Adapter layer {layer_id} bias was initialized from {full_name}.""" ) else: unused_weights.append(UpperCamelCase__ ) def lowerCamelCase_ ( UpperCamelCase__ : Tuple ) -> Tuple: """simple docstring""" __lowerCamelCase , __lowerCamelCase = emb.weight.shape __lowerCamelCase = nn.Linear(UpperCamelCase__ , UpperCamelCase__ , bias=UpperCamelCase__ ) __lowerCamelCase = emb.weight.data return lin_layer @torch.no_grad() def lowerCamelCase_ ( UpperCamelCase__ : List[str] , UpperCamelCase__ : List[Any] , UpperCamelCase__ : Union[str, Any] , UpperCamelCase__ : Dict , UpperCamelCase__ : List[str] , UpperCamelCase__ : Union[str, Any] , UpperCamelCase__ : Optional[int] , UpperCamelCase__ : Union[str, Any] , UpperCamelCase__ : Optional[Any] , UpperCamelCase__ : str , UpperCamelCase__ : Optional[Any] , ) -> str: """simple docstring""" __lowerCamelCase = WavaVecaConfig.from_pretrained( UpperCamelCase__ , add_adapter=UpperCamelCase__ , adapter_stride=UpperCamelCase__ , adapter_kernel_size=UpperCamelCase__ , use_auth_token=UpperCamelCase__ , output_hidden_size=UpperCamelCase__ , ) __lowerCamelCase = MBartConfig.from_pretrained(UpperCamelCase__ ) # load model __lowerCamelCase , __lowerCamelCase , __lowerCamelCase = fairseq.checkpoint_utils.load_model_ensemble_and_task( [checkpoint_path] , arg_overrides={ 'config_yaml': config_yaml_path, 'data': '/'.join(dict_path.split('/' )[:-1] ), 'w2v_path': checkpoint_path, 'load_pretrained_decoder_from': None, } , ) __lowerCamelCase = model[0].eval() # load feature extractor __lowerCamelCase = WavaVecaFeatureExtractor.from_pretrained(UpperCamelCase__ , use_auth_token=UpperCamelCase__ ) # set weights for wav2vec2 encoder __lowerCamelCase = WavaVecaModel(UpperCamelCase__ ) recursively_load_weights_wavaveca(model.encoder , UpperCamelCase__ ) # load decoder weights __lowerCamelCase = MBartForCausalLM(UpperCamelCase__ ) __lowerCamelCase , __lowerCamelCase = hf_decoder.model.decoder.load_state_dict(model.decoder.state_dict() , strict=UpperCamelCase__ ) logger.warning(F"""The following keys are missing when loading the decoder weights: {missing_keys}""" ) logger.warning(F"""The following keys are unexpected when loading the decoder weights: {unexpected_keys}""" ) __lowerCamelCase = SpeechEncoderDecoderModel(encoder=UpperCamelCase__ , decoder=UpperCamelCase__ ) __lowerCamelCase = False __lowerCamelCase = MBartaaTokenizer(UpperCamelCase__ ) tokenizer.save_pretrained(UpperCamelCase__ ) __lowerCamelCase = hf_wavavec.config.to_dict() __lowerCamelCase = tokenizer.pad_token_id __lowerCamelCase = tokenizer.bos_token_id __lowerCamelCase = tokenizer.eos_token_id __lowerCamelCase = 'mbart50' __lowerCamelCase = 'wav2vec2' __lowerCamelCase = tokenizer.eos_token_id __lowerCamelCase = 25_0004 __lowerCamelCase = tokenizer.eos_token_id __lowerCamelCase = SpeechEncoderDecoderConfig.from_dict(UpperCamelCase__ ) hf_wavavec.save_pretrained(UpperCamelCase__ ) feature_extractor.save_pretrained(UpperCamelCase__ ) 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 fairseq checkpoint") parser.add_argument("--dict_path", default=None, type=str, help="Path to dict of fine-tuned model") parser.add_argument("--config_yaml_path", default=None, type=str, help="Path to yaml file of fine-tuned model") parser.add_argument( "--encoder_config_path", default="facebook/wav2vec2-xls-r-1b", type=str, help="Path to hf encoder wav2vec2 checkpoint config", ) parser.add_argument( "--decoder_config_path", default="facebook/mbart-large-50-one-to-many-mmt", type=str, help="Path to hf decoder checkpoint config", ) parser.add_argument("--add_adapter", default=True, type=bool, help="whethere to add model adapter layers") parser.add_argument("--adapter_stride", default=2, type=int, help="stride of adapter layers") parser.add_argument("--adapter_kernel_size", default=3, type=int, help="kernel size of adapter layers") parser.add_argument("--encoder_output_dim", default=10_24, type=int, help="encoder output dim") parser.add_argument("--start_token_id", default=25_00_04, type=int, help="`decoder_start_token_id` of model config") __A = parser.parse_args() convert_wavaveca_checkpoint( args.checkpoint_path, args.pytorch_dump_folder_path, args.dict_path, args.config_yaml_path, encoder_config_path=args.encoder_config_path, decoder_config_path=args.decoder_config_path, add_adapter=args.add_adapter, adapter_kernel_size=args.adapter_kernel_size, adapter_stride=args.adapter_stride, decoder_start_token_id=args.start_token_id, encoder_output_dim=args.encoder_output_dim, )
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import 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 lowercase : List[Any] = """base_with_context""" def A_ ( A__ , A__ ) -> Any: a__ : str = nn.Parameter(torch.FloatTensor(weights['token_embedder']['embedding'] ) ) a__ : List[str] = nn.Parameter( torch.FloatTensor(weights['Embed_0']['embedding'] ) , requires_grad=A__ ) for lyr_num, lyr in enumerate(model.encoders ): a__ : Tuple = weights[F'layers_{lyr_num}'] a__ : Tuple = nn.Parameter( torch.FloatTensor(ly_weight['pre_attention_layer_norm']['scale'] ) ) a__ : Optional[int] = ly_weight['attention'] a__ : str = nn.Parameter(torch.FloatTensor(attention_weights['query']['kernel'].T ) ) a__ : Any = nn.Parameter(torch.FloatTensor(attention_weights['key']['kernel'].T ) ) a__ : Dict = nn.Parameter(torch.FloatTensor(attention_weights['value']['kernel'].T ) ) a__ : Tuple = nn.Parameter(torch.FloatTensor(attention_weights['out']['kernel'].T ) ) a__ : List[Any] = nn.Parameter(torch.FloatTensor(ly_weight['pre_mlp_layer_norm']['scale'] ) ) a__ : int = nn.Parameter(torch.FloatTensor(ly_weight['mlp']['wi_0']['kernel'].T ) ) a__ : Optional[Any] = nn.Parameter(torch.FloatTensor(ly_weight['mlp']['wi_1']['kernel'].T ) ) a__ : str = nn.Parameter(torch.FloatTensor(ly_weight['mlp']['wo']['kernel'].T ) ) a__ : Union[str, Any] = nn.Parameter(torch.FloatTensor(weights['encoder_norm']['scale'] ) ) return model def A_ ( A__ , A__ ) -> Tuple: a__ : Dict = nn.Parameter(torch.FloatTensor(weights['input_proj']['kernel'].T ) ) a__ : Optional[int] = nn.Parameter( torch.FloatTensor(weights['Embed_0']['embedding'] ) , requires_grad=A__ ) for lyr_num, lyr in enumerate(model.encoders ): a__ : Optional[Any] = weights[F'layers_{lyr_num}'] a__ : Tuple = ly_weight['attention'] a__ : Optional[int] = nn.Parameter(torch.FloatTensor(attention_weights['query']['kernel'].T ) ) a__ : Any = nn.Parameter(torch.FloatTensor(attention_weights['key']['kernel'].T ) ) a__ : Optional[int] = nn.Parameter(torch.FloatTensor(attention_weights['value']['kernel'].T ) ) a__ : List[str] = nn.Parameter(torch.FloatTensor(attention_weights['out']['kernel'].T ) ) a__ : int = nn.Parameter( torch.FloatTensor(ly_weight['pre_attention_layer_norm']['scale'] ) ) a__ : List[str] = nn.Parameter(torch.FloatTensor(ly_weight['mlp']['wi_0']['kernel'].T ) ) a__ : List[str] = nn.Parameter(torch.FloatTensor(ly_weight['mlp']['wi_1']['kernel'].T ) ) a__ : Any = nn.Parameter(torch.FloatTensor(ly_weight['mlp']['wo']['kernel'].T ) ) a__ : str = nn.Parameter(torch.FloatTensor(ly_weight['pre_mlp_layer_norm']['scale'] ) ) a__ : Optional[int] = nn.Parameter(torch.FloatTensor(weights['encoder_norm']['scale'] ) ) return model def A_ ( A__ , A__ ) -> str: a__ : List[Any] = nn.Parameter(torch.FloatTensor(weights['time_emb_dense0']['kernel'].T ) ) a__ : Optional[int] = nn.Parameter(torch.FloatTensor(weights['time_emb_dense1']['kernel'].T ) ) a__ : Tuple = nn.Parameter( torch.FloatTensor(weights['Embed_0']['embedding'] ) , requires_grad=A__ ) a__ : Optional[int] = nn.Parameter( torch.FloatTensor(weights['continuous_inputs_projection']['kernel'].T ) ) for lyr_num, lyr in enumerate(model.decoders ): a__ : int = weights[F'layers_{lyr_num}'] a__ : Union[str, Any] = nn.Parameter( torch.FloatTensor(ly_weight['pre_self_attention_layer_norm']['scale'] ) ) a__ : Optional[Any] = nn.Parameter( torch.FloatTensor(ly_weight['FiLMLayer_0']['DenseGeneral_0']['kernel'].T ) ) a__ : int = ly_weight['self_attention'] a__ : Tuple = nn.Parameter(torch.FloatTensor(attention_weights['query']['kernel'].T ) ) a__ : Union[str, Any] = nn.Parameter(torch.FloatTensor(attention_weights['key']['kernel'].T ) ) a__ : str = nn.Parameter(torch.FloatTensor(attention_weights['value']['kernel'].T ) ) a__ : Optional[Any] = nn.Parameter(torch.FloatTensor(attention_weights['out']['kernel'].T ) ) a__ : Tuple = ly_weight['MultiHeadDotProductAttention_0'] a__ : int = nn.Parameter(torch.FloatTensor(attention_weights['query']['kernel'].T ) ) a__ : Any = nn.Parameter(torch.FloatTensor(attention_weights['key']['kernel'].T ) ) a__ : List[str] = nn.Parameter(torch.FloatTensor(attention_weights['value']['kernel'].T ) ) a__ : int = nn.Parameter(torch.FloatTensor(attention_weights['out']['kernel'].T ) ) a__ : List[str] = nn.Parameter( torch.FloatTensor(ly_weight['pre_cross_attention_layer_norm']['scale'] ) ) a__ : Tuple = nn.Parameter(torch.FloatTensor(ly_weight['pre_mlp_layer_norm']['scale'] ) ) a__ : Optional[int] = nn.Parameter( torch.FloatTensor(ly_weight['FiLMLayer_1']['DenseGeneral_0']['kernel'].T ) ) a__ : int = nn.Parameter(torch.FloatTensor(ly_weight['mlp']['wi_0']['kernel'].T ) ) a__ : List[str] = nn.Parameter(torch.FloatTensor(ly_weight['mlp']['wi_1']['kernel'].T ) ) a__ : Dict = nn.Parameter(torch.FloatTensor(ly_weight['mlp']['wo']['kernel'].T ) ) a__ : int = nn.Parameter(torch.FloatTensor(weights['decoder_norm']['scale'] ) ) a__ : str = nn.Parameter(torch.FloatTensor(weights['spec_out_dense']['kernel'].T ) ) return model def A_ ( A__ ) -> Optional[int]: a__ : List[str] = checkpoints.load_tax_checkpoint(args.checkpoint_path ) a__ : Any = jnp.tree_util.tree_map(onp.array , A__ ) a__ : Optional[Any] = [ '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()', ] a__ : List[Any] = os.path.join(args.checkpoint_path , '..' , 'config.gin' ) a__ : Union[str, Any] = inference.parse_training_gin_file(A__ , A__ ) a__ : Dict = inference.InferenceModel(args.checkpoint_path , A__ ) a__ : Tuple = DDPMScheduler(beta_schedule='squaredcos_cap_v2' , variance_type='fixed_large' ) a__ : Optional[int] = 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' , ) a__ : Tuple = 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' , ) a__ : Any = 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 , ) a__ : str = load_notes_encoder(ta_checkpoint['target']['token_encoder'] , A__ ) a__ : Tuple = load_continuous_encoder(ta_checkpoint['target']['continuous_encoder'] , A__ ) a__ : Tuple = load_decoder(ta_checkpoint['target']['decoder'] , A__ ) a__ : int = OnnxRuntimeModel.from_pretrained('kashif/soundstream_mel_decoder' ) a__ : Optional[Any] = 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__": lowercase : Tuple = 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.""", ) lowercase : Optional[int] = parser.parse_args() main(args)
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def lowerCamelCase_ ( UpperCamelCase__ : int ) -> bool: """simple docstring""" return number & 1 == 0 if __name__ == "__main__": import doctest doctest.testmod()
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"""simple docstring""" def _lowerCAmelCase ( UpperCamelCase_ ): __SCREAMING_SNAKE_CASE = int(UpperCamelCase_ ) if decimal in (0, 1): # Exit cases for the recursion return str(UpperCamelCase_ ) __SCREAMING_SNAKE_CASE ,__SCREAMING_SNAKE_CASE = divmod(UpperCamelCase_ , 2 ) return binary_recursive(UpperCamelCase_ ) + str(UpperCamelCase_ ) def _lowerCAmelCase ( UpperCamelCase_ ): __SCREAMING_SNAKE_CASE = str(UpperCamelCase_ ).strip() if not number: raise ValueError("""No input value was provided""" ) __SCREAMING_SNAKE_CASE = """-""" if number.startswith("""-""" ) else """""" __SCREAMING_SNAKE_CASE = number.lstrip("""-""" ) if not number.isnumeric(): raise ValueError("""Input value is not an integer""" ) return f"{negative}0b{binary_recursive(int(UpperCamelCase_ ) )}" if __name__ == "__main__": from doctest import testmod testmod()
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from typing import List, Optional import numpy as np from ...processing_utils import ProcessorMixin from ...utils import to_numpy class __lowerCAmelCase ( __magic_name__ ): """simple docstring""" snake_case_ = '''EncodecFeatureExtractor''' snake_case_ = ('''T5Tokenizer''', '''T5TokenizerFast''') def __init__( self , lowerCamelCase__ , lowerCamelCase__ ) -> int: '''simple docstring''' super().__init__(lowerCamelCase__ , lowerCamelCase__ ) __lowerCamelCase = self.feature_extractor __lowerCamelCase = False def lowercase_ ( self , lowerCamelCase__=None , lowerCamelCase__=None , lowerCamelCase__=True ) -> List[Any]: '''simple docstring''' return self.tokenizer.get_decoder_prompt_ids(task=lowerCamelCase__ , language=lowerCamelCase__ , no_timestamps=lowerCamelCase__ ) def __call__( self , *lowerCamelCase__ , **lowerCamelCase__ ) -> Dict: '''simple docstring''' # For backward compatibility if self._in_target_context_manager: return self.current_processor(*lowerCamelCase__ , **lowerCamelCase__ ) __lowerCamelCase = kwargs.pop('audio' , lowerCamelCase__ ) __lowerCamelCase = kwargs.pop('sampling_rate' , lowerCamelCase__ ) __lowerCamelCase = kwargs.pop('text' , lowerCamelCase__ ) if len(lowerCamelCase__ ) > 0: __lowerCamelCase = args[0] __lowerCamelCase = args[1:] if audio is None and text is None: raise ValueError('You need to specify either an `audio` or `text` input to process.' ) if text is not None: __lowerCamelCase = self.tokenizer(lowerCamelCase__ , **lowerCamelCase__ ) if audio is not None: __lowerCamelCase = self.feature_extractor(lowerCamelCase__ , *lowerCamelCase__ , sampling_rate=lowerCamelCase__ , **lowerCamelCase__ ) if audio is None: return inputs elif text is None: return audio_inputs else: __lowerCamelCase = audio_inputs['input_values'] if "padding_mask" in audio_inputs: __lowerCamelCase = audio_inputs['padding_mask'] return inputs def lowercase_ ( self , *lowerCamelCase__ , **lowerCamelCase__ ) -> Union[str, Any]: '''simple docstring''' __lowerCamelCase = kwargs.pop('audio' , lowerCamelCase__ ) __lowerCamelCase = kwargs.pop('padding_mask' , lowerCamelCase__ ) if len(lowerCamelCase__ ) > 0: __lowerCamelCase = args[0] __lowerCamelCase = args[1:] if audio_values is not None: return self._decode_audio(lowerCamelCase__ , padding_mask=lowerCamelCase__ ) else: return self.tokenizer.batch_decode(*lowerCamelCase__ , **lowerCamelCase__ ) def lowercase_ ( self , *lowerCamelCase__ , **lowerCamelCase__ ) -> List[Any]: '''simple docstring''' return self.tokenizer.decode(*lowerCamelCase__ , **lowerCamelCase__ ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ = None ) -> List[np.ndarray]: '''simple docstring''' __lowerCamelCase = to_numpy(lowerCamelCase__ ) __lowerCamelCase , __lowerCamelCase , __lowerCamelCase = audio_values.shape if padding_mask is None: return list(lowerCamelCase__ ) __lowerCamelCase = to_numpy(lowerCamelCase__ ) # match the sequence length of the padding mask to the generated audio arrays by padding with the **non-padding** # token (so that the generated audio values are **not** treated as padded tokens) __lowerCamelCase = seq_len - padding_mask.shape[-1] __lowerCamelCase = 1 - self.feature_extractor.padding_value __lowerCamelCase = np.pad(lowerCamelCase__ , ((0, 0), (0, difference)) , 'constant' , constant_values=lowerCamelCase__ ) __lowerCamelCase = audio_values.tolist() for i in range(lowerCamelCase__ ): __lowerCamelCase = np.asarray(audio_values[i] )[ padding_mask[i][None, :] != self.feature_extractor.padding_value ] __lowerCamelCase = sliced_audio.reshape(lowerCamelCase__ , -1 ) return audio_values
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import tempfile import unittest from make_student import create_student_by_copying_alternating_layers from transformers import AutoConfig from transformers.file_utils import cached_property from transformers.testing_utils import require_torch lowercase__ :List[Any] = "sshleifer/bart-tiny-random" lowercase__ :Union[str, Any] = "patrickvonplaten/t5-tiny-random" @require_torch class lowercase ( unittest.TestCase ): @cached_property def A__ ( self): return AutoConfig.from_pretrained(A__) def A__ ( self): lowercase , *lowercase = create_student_by_copying_alternating_layers(A__ ,tempfile.mkdtemp() ,e=1 ,d=1) self.assertEqual(student.config.num_hidden_layers ,1) def A__ ( self): lowercase , *lowercase = create_student_by_copying_alternating_layers(A__ ,tempfile.mkdtemp() ,e=1 ,d=A__) def A__ ( self): lowercase , *lowercase = create_student_by_copying_alternating_layers(A__ ,tempfile.mkdtemp() ,e=1 ,d=A__) self.assertEqual(student.config.encoder_layers ,1) self.assertEqual(student.config.decoder_layers ,self.teacher_config.encoder_layers) def A__ ( self): lowercase , *lowercase = create_student_by_copying_alternating_layers(A__ ,tempfile.mkdtemp() ,e=1 ,d=1) self.assertEqual(student.config.encoder_layers ,1) self.assertEqual(student.config.decoder_layers ,1) def A__ ( self): with self.assertRaises(A__): create_student_by_copying_alternating_layers(A__ ,tempfile.mkdtemp() ,e=A__ ,d=A__)
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from math import sqrt def lowerCamelCase_ ( UpperCamelCase__ : int ) -> bool: """simple docstring""" if 1 < number < 4: # 2 and 3 are primes return True elif number < 2 or number % 2 == 0 or number % 3 == 0: # Negatives, 0, 1, all even numbers, all multiples of 3 are not primes return False # All primes number are in format of 6k +/- 1 for i in range(5 , int(sqrt(UpperCamelCase__ ) + 1 ) , 6 ): if number % i == 0 or number % (i + 2) == 0: return False return True def lowerCamelCase_ ( UpperCamelCase__ : int = 1_0001 ) -> int: """simple docstring""" __lowerCamelCase = 0 __lowerCamelCase = 1 while count != nth and number < 3: number += 1 if is_prime(UpperCamelCase__ ): count += 1 while count != nth: number += 2 if is_prime(UpperCamelCase__ ): count += 1 return number if __name__ == "__main__": print(f'''{solution() = }''')
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"""simple docstring""" def lowercase ( _snake_case : int , _snake_case : int ) ->str: """simple docstring""" if a < 0 or b < 0: raise ValueError('''the value of both inputs must be positive''' ) __snake_case : Tuple = str(bin(_snake_case ) )[2:] # remove the leading "0b" __snake_case : List[Any] = str(bin(_snake_case ) )[2:] __snake_case : Any = max(len(_snake_case ) , len(_snake_case ) ) return "0b" + "".join( str(int('''1''' in (char_a, char_b) ) ) for char_a, char_b in zip(a_binary.zfill(_snake_case ) , b_binary.zfill(_snake_case ) ) ) if __name__ == "__main__": import doctest doctest.testmod()
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import baseaa def lowerCamelCase_ ( UpperCamelCase__ : str ) -> bytes: """simple docstring""" return baseaa.aaaencode(string.encode('utf-8' ) ) def lowerCamelCase_ ( UpperCamelCase__ : bytes ) -> str: """simple docstring""" return baseaa.aaadecode(UpperCamelCase__ ).decode('utf-8' ) if __name__ == "__main__": import doctest doctest.testmod()
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import argparse import json import requests import torch from huggingface_hub import hf_hub_download from PIL import Image from transformers import ConvNextConfig, SegformerImageProcessor, UperNetConfig, UperNetForSemanticSegmentation def UpperCamelCase( __UpperCamelCase : Union[str, Any] ): lowerCAmelCase_ : Any = 384 if "tiny" in model_name: lowerCAmelCase_ : Tuple = [3, 3, 9, 3] lowerCAmelCase_ : List[str] = [96, 192, 384, 768] if "small" in model_name: lowerCAmelCase_ : List[Any] = [3, 3, 27, 3] lowerCAmelCase_ : List[str] = [96, 192, 384, 768] if "base" in model_name: lowerCAmelCase_ : Optional[int] = [3, 3, 27, 3] lowerCAmelCase_ : List[str] = [128, 256, 512, 1024] lowerCAmelCase_ : int = 512 if "large" in model_name: lowerCAmelCase_ : List[str] = [3, 3, 27, 3] lowerCAmelCase_ : int = [192, 384, 768, 1536] lowerCAmelCase_ : List[Any] = 768 if "xlarge" in model_name: lowerCAmelCase_ : Optional[Any] = [3, 3, 27, 3] lowerCAmelCase_ : Optional[int] = [256, 512, 1024, 2048] lowerCAmelCase_ : Optional[Any] = 1024 # set label information lowerCAmelCase_ : Tuple = 150 lowerCAmelCase_ : Optional[int] = '''huggingface/label-files''' lowerCAmelCase_ : str = '''ade20k-id2label.json''' lowerCAmelCase_ : List[str] = json.load(open(hf_hub_download(__UpperCamelCase ,__UpperCamelCase ,repo_type='''dataset''' ) ,'''r''' ) ) lowerCAmelCase_ : Any = {int(__UpperCamelCase ): v for k, v in idalabel.items()} lowerCAmelCase_ : Optional[int] = {v: k for k, v in idalabel.items()} lowerCAmelCase_ : Dict = ConvNextConfig( depths=__UpperCamelCase ,hidden_sizes=__UpperCamelCase ,out_features=['''stage1''', '''stage2''', '''stage3''', '''stage4'''] ) lowerCAmelCase_ : List[Any] = UperNetConfig( backbone_config=__UpperCamelCase ,auxiliary_in_channels=__UpperCamelCase ,num_labels=__UpperCamelCase ,idalabel=__UpperCamelCase ,labelaid=__UpperCamelCase ,) return config def UpperCamelCase( __UpperCamelCase : List[Any] ): lowerCAmelCase_ : List[str] = [] # fmt: off # stem rename_keys.append(('''backbone.downsample_layers.0.0.weight''', '''backbone.embeddings.patch_embeddings.weight''') ) rename_keys.append(('''backbone.downsample_layers.0.0.bias''', '''backbone.embeddings.patch_embeddings.bias''') ) rename_keys.append(('''backbone.downsample_layers.0.1.weight''', '''backbone.embeddings.layernorm.weight''') ) rename_keys.append(('''backbone.downsample_layers.0.1.bias''', '''backbone.embeddings.layernorm.bias''') ) # stages for i in range(len(config.backbone_config.depths ) ): for j in range(config.backbone_config.depths[i] ): rename_keys.append((f"""backbone.stages.{i}.{j}.gamma""", f"""backbone.encoder.stages.{i}.layers.{j}.layer_scale_parameter""") ) rename_keys.append((f"""backbone.stages.{i}.{j}.depthwise_conv.weight""", f"""backbone.encoder.stages.{i}.layers.{j}.dwconv.weight""") ) rename_keys.append((f"""backbone.stages.{i}.{j}.depthwise_conv.bias""", f"""backbone.encoder.stages.{i}.layers.{j}.dwconv.bias""") ) rename_keys.append((f"""backbone.stages.{i}.{j}.norm.weight""", f"""backbone.encoder.stages.{i}.layers.{j}.layernorm.weight""") ) rename_keys.append((f"""backbone.stages.{i}.{j}.norm.bias""", f"""backbone.encoder.stages.{i}.layers.{j}.layernorm.bias""") ) rename_keys.append((f"""backbone.stages.{i}.{j}.pointwise_conv1.weight""", f"""backbone.encoder.stages.{i}.layers.{j}.pwconv1.weight""") ) rename_keys.append((f"""backbone.stages.{i}.{j}.pointwise_conv1.bias""", f"""backbone.encoder.stages.{i}.layers.{j}.pwconv1.bias""") ) rename_keys.append((f"""backbone.stages.{i}.{j}.pointwise_conv2.weight""", f"""backbone.encoder.stages.{i}.layers.{j}.pwconv2.weight""") ) rename_keys.append((f"""backbone.stages.{i}.{j}.pointwise_conv2.bias""", f"""backbone.encoder.stages.{i}.layers.{j}.pwconv2.bias""") ) if i > 0: rename_keys.append((f"""backbone.downsample_layers.{i}.0.weight""", f"""backbone.encoder.stages.{i}.downsampling_layer.0.weight""") ) rename_keys.append((f"""backbone.downsample_layers.{i}.0.bias""", f"""backbone.encoder.stages.{i}.downsampling_layer.0.bias""") ) rename_keys.append((f"""backbone.downsample_layers.{i}.1.weight""", f"""backbone.encoder.stages.{i}.downsampling_layer.1.weight""") ) rename_keys.append((f"""backbone.downsample_layers.{i}.1.bias""", f"""backbone.encoder.stages.{i}.downsampling_layer.1.bias""") ) rename_keys.append((f"""backbone.norm{i}.weight""", f"""backbone.hidden_states_norms.stage{i+1}.weight""") ) rename_keys.append((f"""backbone.norm{i}.bias""", f"""backbone.hidden_states_norms.stage{i+1}.bias""") ) # decode head rename_keys.extend( [ ('''decode_head.conv_seg.weight''', '''decode_head.classifier.weight'''), ('''decode_head.conv_seg.bias''', '''decode_head.classifier.bias'''), ('''auxiliary_head.conv_seg.weight''', '''auxiliary_head.classifier.weight'''), ('''auxiliary_head.conv_seg.bias''', '''auxiliary_head.classifier.bias'''), ] ) # fmt: on return rename_keys def UpperCamelCase( __UpperCamelCase : int ,__UpperCamelCase : Optional[Any] ,__UpperCamelCase : Tuple ): lowerCAmelCase_ : Any = dct.pop(__UpperCamelCase ) lowerCAmelCase_ : Tuple = val def UpperCamelCase( __UpperCamelCase : Optional[int] ,__UpperCamelCase : int ,__UpperCamelCase : Dict ): lowerCAmelCase_ : List[Any] = { '''upernet-convnext-tiny''': '''https://download.openmmlab.com/mmsegmentation/v0.5/convnext/upernet_convnext_tiny_fp16_512x512_160k_ade20k/upernet_convnext_tiny_fp16_512x512_160k_ade20k_20220227_124553-cad485de.pth''', '''upernet-convnext-small''': '''https://download.openmmlab.com/mmsegmentation/v0.5/convnext/upernet_convnext_small_fp16_512x512_160k_ade20k/upernet_convnext_small_fp16_512x512_160k_ade20k_20220227_131208-1b1e394f.pth''', '''upernet-convnext-base''': '''https://download.openmmlab.com/mmsegmentation/v0.5/convnext/upernet_convnext_base_fp16_512x512_160k_ade20k/upernet_convnext_base_fp16_512x512_160k_ade20k_20220227_181227-02a24fc6.pth''', '''upernet-convnext-large''': '''https://download.openmmlab.com/mmsegmentation/v0.5/convnext/upernet_convnext_large_fp16_640x640_160k_ade20k/upernet_convnext_large_fp16_640x640_160k_ade20k_20220226_040532-e57aa54d.pth''', '''upernet-convnext-xlarge''': '''https://download.openmmlab.com/mmsegmentation/v0.5/convnext/upernet_convnext_xlarge_fp16_640x640_160k_ade20k/upernet_convnext_xlarge_fp16_640x640_160k_ade20k_20220226_080344-95fc38c2.pth''', } lowerCAmelCase_ : str = model_name_to_url[model_name] lowerCAmelCase_ : str = torch.hub.load_state_dict_from_url(__UpperCamelCase ,map_location='''cpu''' )['''state_dict'''] lowerCAmelCase_ : Optional[int] = get_upernet_config(__UpperCamelCase ) lowerCAmelCase_ : Any = UperNetForSemanticSegmentation(__UpperCamelCase ) model.eval() # replace "bn" => "batch_norm" for key in state_dict.copy().keys(): lowerCAmelCase_ : Dict = state_dict.pop(__UpperCamelCase ) if "bn" in key: lowerCAmelCase_ : List[str] = key.replace('''bn''' ,'''batch_norm''' ) lowerCAmelCase_ : Tuple = val # rename keys lowerCAmelCase_ : str = create_rename_keys(__UpperCamelCase ) for src, dest in rename_keys: rename_key(__UpperCamelCase ,__UpperCamelCase ,__UpperCamelCase ) model.load_state_dict(__UpperCamelCase ) # verify on image lowerCAmelCase_ : int = '''https://huggingface.co/datasets/hf-internal-testing/fixtures_ade20k/resolve/main/ADE_val_00000001.jpg''' lowerCAmelCase_ : Tuple = Image.open(requests.get(__UpperCamelCase ,stream=__UpperCamelCase ).raw ).convert('''RGB''' ) lowerCAmelCase_ : Dict = SegformerImageProcessor() lowerCAmelCase_ : Any = processor(__UpperCamelCase ,return_tensors='''pt''' ).pixel_values with torch.no_grad(): lowerCAmelCase_ : str = model(__UpperCamelCase ) if model_name == "upernet-convnext-tiny": lowerCAmelCase_ : List[str] = torch.tensor( [[-8.8_1_1_0, -8.8_1_1_0, -8.6_5_2_1], [-8.8_1_1_0, -8.8_1_1_0, -8.6_5_2_1], [-8.7_7_4_6, -8.7_7_4_6, -8.6_1_3_0]] ) elif model_name == "upernet-convnext-small": lowerCAmelCase_ : Union[str, Any] = torch.tensor( [[-8.8_2_3_6, -8.8_2_3_6, -8.6_7_7_1], [-8.8_2_3_6, -8.8_2_3_6, -8.6_7_7_1], [-8.7_6_3_8, -8.7_6_3_8, -8.6_2_4_0]] ) elif model_name == "upernet-convnext-base": lowerCAmelCase_ : Dict = torch.tensor( [[-8.8_5_5_8, -8.8_5_5_8, -8.6_9_0_5], [-8.8_5_5_8, -8.8_5_5_8, -8.6_9_0_5], [-8.7_6_6_9, -8.7_6_6_9, -8.6_0_2_1]] ) elif model_name == "upernet-convnext-large": lowerCAmelCase_ : Optional[Any] = torch.tensor( [[-8.6_6_6_0, -8.6_6_6_0, -8.6_2_1_0], [-8.6_6_6_0, -8.6_6_6_0, -8.6_2_1_0], [-8.6_3_1_0, -8.6_3_1_0, -8.5_9_6_4]] ) elif model_name == "upernet-convnext-xlarge": lowerCAmelCase_ : Dict = torch.tensor( [[-8.4_9_8_0, -8.4_9_8_0, -8.3_9_7_7], [-8.4_9_8_0, -8.4_9_8_0, -8.3_9_7_7], [-8.4_3_7_9, -8.4_3_7_9, -8.3_4_1_2]] ) print('''Logits:''' ,outputs.logits[0, 0, :3, :3] ) assert torch.allclose(outputs.logits[0, 0, :3, :3] ,__UpperCamelCase ,atol=1e-4 ) 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(__UpperCamelCase ) print(f"""Saving processor to {pytorch_dump_folder_path}""" ) processor.save_pretrained(__UpperCamelCase ) if push_to_hub: print(f"""Pushing model and processor for {model_name} to hub""" ) model.push_to_hub(f"""openmmlab/{model_name}""" ) processor.push_to_hub(f"""openmmlab/{model_name}""" ) if __name__ == "__main__": A__ : Optional[Any] = argparse.ArgumentParser() # Required parameters parser.add_argument( '''--model_name''', default='''upernet-convnext-tiny''', type=str, choices=[F'''upernet-convnext-{size}''' for size in ['''tiny''', '''small''', '''base''', '''large''', '''xlarge''']], help='''Name of the ConvNext UperNet 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.''' ) parser.add_argument( '''--push_to_hub''', action='''store_true''', help='''Whether or not to push the converted model to the 🤗 hub.''' ) A__ : int = parser.parse_args() convert_upernet_checkpoint(args.model_name, args.pytorch_dump_folder_path, args.push_to_hub)
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import copy from typing import Any, Dict, List, Optional, Union import numpy as np import torch from ...audio_utils import mel_filter_bank, spectrogram, window_function from ...feature_extraction_sequence_utils import SequenceFeatureExtractor from ...feature_extraction_utils import BatchFeature from ...utils import TensorType, logging __A = logging.get_logger(__name__) class __lowerCAmelCase ( __magic_name__ ): """simple docstring""" snake_case_ = ['''input_features''', '''is_longer'''] def __init__( self , lowerCamelCase__=64 , lowerCamelCase__=48_000 , lowerCamelCase__=480 , lowerCamelCase__=10 , lowerCamelCase__=1_024 , lowerCamelCase__=0.0 , lowerCamelCase__=False , lowerCamelCase__ = 0 , lowerCamelCase__ = 14_000 , lowerCamelCase__ = None , lowerCamelCase__ = "fusion" , lowerCamelCase__ = "repeatpad" , **lowerCamelCase__ , ) -> Tuple: '''simple docstring''' super().__init__( feature_size=lowerCamelCase__ , sampling_rate=lowerCamelCase__ , padding_value=lowerCamelCase__ , return_attention_mask=lowerCamelCase__ , **lowerCamelCase__ , ) __lowerCamelCase = top_db __lowerCamelCase = truncation __lowerCamelCase = padding __lowerCamelCase = fft_window_size __lowerCamelCase = (fft_window_size >> 1) + 1 __lowerCamelCase = hop_length __lowerCamelCase = max_length_s __lowerCamelCase = max_length_s * sampling_rate __lowerCamelCase = sampling_rate __lowerCamelCase = frequency_min __lowerCamelCase = frequency_max __lowerCamelCase = mel_filter_bank( num_frequency_bins=self.nb_frequency_bins , num_mel_filters=lowerCamelCase__ , min_frequency=lowerCamelCase__ , max_frequency=lowerCamelCase__ , sampling_rate=lowerCamelCase__ , norm=lowerCamelCase__ , mel_scale='htk' , ) __lowerCamelCase = mel_filter_bank( num_frequency_bins=self.nb_frequency_bins , num_mel_filters=lowerCamelCase__ , min_frequency=lowerCamelCase__ , max_frequency=lowerCamelCase__ , sampling_rate=lowerCamelCase__ , norm='slaney' , mel_scale='slaney' , ) def lowercase_ ( self ) -> Dict[str, Any]: '''simple docstring''' __lowerCamelCase = copy.deepcopy(self.__dict__ ) __lowerCamelCase = self.__class__.__name__ if "mel_filters" in output: del output["mel_filters"] if "mel_filters_slaney" in output: del output["mel_filters_slaney"] return output def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ = None ) -> np.ndarray: '''simple docstring''' __lowerCamelCase = spectrogram( lowerCamelCase__ , window_function(self.fft_window_size , 'hann' ) , frame_length=self.fft_window_size , hop_length=self.hop_length , power=2.0 , mel_filters=lowerCamelCase__ , log_mel='dB' , ) return log_mel_spectrogram.T def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> int: '''simple docstring''' __lowerCamelCase = np.array_split(list(range(0 , total_frames - chunk_frames + 1 ) ) , 3 ) if len(ranges[1] ) == 0: # if the audio is too short, we just use the first chunk __lowerCamelCase = [0] if len(ranges[2] ) == 0: # if the audio is too short, we just use the first chunk __lowerCamelCase = [0] # randomly choose index for each part __lowerCamelCase = np.random.choice(ranges[0] ) __lowerCamelCase = np.random.choice(ranges[1] ) __lowerCamelCase = np.random.choice(ranges[2] ) __lowerCamelCase = mel[idx_front : idx_front + chunk_frames, :] __lowerCamelCase = mel[idx_middle : idx_middle + chunk_frames, :] __lowerCamelCase = mel[idx_back : idx_back + chunk_frames, :] __lowerCamelCase = torch.tensor(mel[None, None, :] ) __lowerCamelCase = torch.nn.functional.interpolate( lowerCamelCase__ , size=[chunk_frames, 64] , mode='bilinear' , align_corners=lowerCamelCase__ ) __lowerCamelCase = mel_shrink[0][0].numpy() __lowerCamelCase = np.stack([mel_shrink, mel_chunk_front, mel_chunk_middle, mel_chunk_back] , axis=0 ) return mel_fusion def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> np.array: '''simple docstring''' if waveform.shape[0] > max_length: if truncation == "rand_trunc": __lowerCamelCase = True # random crop to max_length (for compatibility) -> this should be handled by self.pad __lowerCamelCase = len(lowerCamelCase__ ) - max_length __lowerCamelCase = np.random.randint(0 , overflow + 1 ) __lowerCamelCase = waveform[idx : idx + max_length] __lowerCamelCase = self._np_extract_fbank_features(lowerCamelCase__ , self.mel_filters_slaney )[None, :] elif truncation == "fusion": __lowerCamelCase = self._np_extract_fbank_features(lowerCamelCase__ , self.mel_filters ) __lowerCamelCase = max_length // self.hop_length + 1 # the +1 related to how the spectrogram is computed __lowerCamelCase = mel.shape[0] if chunk_frames == total_frames: # there is a corner case where the audio length is larger than max_length but smaller than max_length+hop_length. # In this case, we just use the whole audio. __lowerCamelCase = np.stack([mel, mel, mel, mel] , axis=0 ) __lowerCamelCase = False else: __lowerCamelCase = self._random_mel_fusion(lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) __lowerCamelCase = True else: raise NotImplementedError(f"""data_truncating {truncation} not implemented""" ) else: __lowerCamelCase = False # only use repeat as a new possible value for padding. you repeat the audio before applying the usual max_length padding if waveform.shape[0] < max_length: if padding == "repeat": __lowerCamelCase = int(max_length / len(lowerCamelCase__ ) ) __lowerCamelCase = np.stack(np.tile(lowerCamelCase__ , n_repeat + 1 ) )[:max_length] if padding == "repeatpad": __lowerCamelCase = int(max_length / len(lowerCamelCase__ ) ) __lowerCamelCase = np.stack(np.tile(lowerCamelCase__ , lowerCamelCase__ ) ) __lowerCamelCase = np.pad(lowerCamelCase__ , (0, max_length - waveform.shape[0]) , mode='constant' , constant_values=0 ) if truncation == "fusion": __lowerCamelCase = self._np_extract_fbank_features(lowerCamelCase__ , self.mel_filters ) __lowerCamelCase = np.stack([input_mel, input_mel, input_mel, input_mel] , axis=0 ) else: __lowerCamelCase = self._np_extract_fbank_features(lowerCamelCase__ , self.mel_filters_slaney )[None, :] return input_mel, longer def __call__( self , lowerCamelCase__ , lowerCamelCase__ = None , lowerCamelCase__ = None , lowerCamelCase__ = None , lowerCamelCase__ = None , lowerCamelCase__ = None , **lowerCamelCase__ , ) -> BatchFeature: '''simple docstring''' __lowerCamelCase = truncation if truncation is not None else self.truncation __lowerCamelCase = padding if padding else self.padding if sampling_rate is not None: if sampling_rate != self.sampling_rate: raise ValueError( f"""The model corresponding to this feature extractor: {self.__class__.__name__} was trained using a""" f""" sampling rate of {self.sampling_rate}. Please make sure that the provided `raw_speech` input""" f""" was sampled with {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.' ) __lowerCamelCase = isinstance(lowerCamelCase__ , np.ndarray ) and len(raw_speech.shape ) > 1 if is_batched_numpy and len(raw_speech.shape ) > 2: raise ValueError(f"""Only mono-channel audio is supported for input to {self}""" ) __lowerCamelCase = is_batched_numpy or ( isinstance(lowerCamelCase__ , (list, tuple) ) and (isinstance(raw_speech[0] , (np.ndarray, tuple, list) )) ) if is_batched: __lowerCamelCase = [np.asarray(lowerCamelCase__ , dtype=np.floataa ) for speech in raw_speech] elif not is_batched and not isinstance(lowerCamelCase__ , np.ndarray ): __lowerCamelCase = np.asarray(lowerCamelCase__ , dtype=np.floataa ) elif isinstance(lowerCamelCase__ , np.ndarray ) and raw_speech.dtype is np.dtype(np.floataa ): __lowerCamelCase = raw_speech.astype(np.floataa ) # always return batch if not is_batched: __lowerCamelCase = [np.asarray(lowerCamelCase__ )] # convert to mel spectrogram, truncate and pad if needed. __lowerCamelCase = [ self._get_input_mel(lowerCamelCase__ , max_length if max_length else self.nb_max_samples , lowerCamelCase__ , lowerCamelCase__ ) for waveform in raw_speech ] __lowerCamelCase = [] __lowerCamelCase = [] for mel, longer in padded_inputs: input_mel.append(lowerCamelCase__ ) is_longer.append(lowerCamelCase__ ) if truncation == "fusion" and sum(lowerCamelCase__ ) == 0: # if no audio is longer than 10s, then randomly select one audio to be longer __lowerCamelCase = np.random.randint(0 , len(lowerCamelCase__ ) ) __lowerCamelCase = True if isinstance(input_mel[0] , lowerCamelCase__ ): __lowerCamelCase = [np.asarray(lowerCamelCase__ , dtype=np.floataa ) for feature in input_mel] # is_longer is a list of bool __lowerCamelCase = [[longer] for longer in is_longer] __lowerCamelCase = {'input_features': input_mel, 'is_longer': is_longer} __lowerCamelCase = BatchFeature(lowerCamelCase__ ) if return_tensors is not None: __lowerCamelCase = input_features.convert_to_tensors(lowerCamelCase__ ) return input_features
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0
'''simple docstring''' from __future__ import annotations import time import numpy as np lowerCAmelCase__ = [8, 5, 9, 7] lowerCAmelCase__ = [ [2, 0, 1, 1], [0, 1, 2, 1], [4, 0, 0, 3], [0, 2, 1, 0], [1, 0, 3, 0], ] lowerCAmelCase__ = [ [3, 2, 1, 4], [0, 2, 5, 2], [5, 1, 0, 5], [1, 5, 3, 0], [3, 0, 3, 3], ] class lowercase_ : """simple docstring""" def __init__( self : Optional[Any] ,lowercase__ : list[int] ,lowercase__ : list[list[int]] ,lowercase__ : list[list[int]] ,): __lowercase = claim_vector __lowercase = allocated_resources_table __lowercase = maximum_claim_table def SCREAMING_SNAKE_CASE ( self : Tuple ): return [ sum(p_item[i] for p_item in self.__allocated_resources_table ) for i in range(len(self.__allocated_resources_table[0] ) ) ] def SCREAMING_SNAKE_CASE ( self : str ): return np.array(self.__claim_vector ) - np.array( self.__processes_resource_summation() ) def SCREAMING_SNAKE_CASE ( self : Union[str, Any] ): return [ list(np.array(self.__maximum_claim_table[i] ) - np.array(lowercase__ ) ) for i, allocated_resource in enumerate(self.__allocated_resources_table ) ] def SCREAMING_SNAKE_CASE ( self : Any ): return {self.__need().index(lowercase__ ): i for i in self.__need()} def SCREAMING_SNAKE_CASE ( self : List[str] ,**lowercase__ : List[Any] ): __lowercase = self.__need() __lowercase = self.__allocated_resources_table __lowercase = self.__available_resources() __lowercase = self.__need_index_manager() for kw, val in kwargs.items(): if kw and val is True: self.__pretty_data() print('''_''' * 5_0 + '''\n''' ) while need_list: __lowercase = False for each_need in need_list: __lowercase = True for index, need in enumerate(lowercase__ ): if need > available_resources[index]: __lowercase = False break if execution: __lowercase = True # get the original index of the process from ind_ctrl db for original_need_index, need_clone in need_index_manager.items(): if each_need == need_clone: __lowercase = original_need_index print(F"Process {process_number + 1} is executing." ) # remove the process run from stack need_list.remove(lowercase__ ) # update available/freed resources stack __lowercase = np.array(lowercase__ ) + np.array( alloc_resources_table[process_number] ) print( '''Updated available resource stack for processes: ''' + ''' '''.join([str(lowercase__ ) for x in available_resources] ) ) break if safe: print('''The process is in a safe state.\n''' ) else: print('''System in unsafe state. Aborting...\n''' ) break def SCREAMING_SNAKE_CASE ( self : Optional[int] ): print(''' ''' * 9 + '''Allocated Resource Table''' ) for item in self.__allocated_resources_table: print( F"P{self.__allocated_resources_table.index(lowercase__ ) + 1}" + ''' '''.join(F"{it:>8}" for it in item ) + '''\n''' ) print(''' ''' * 9 + '''System Resource Table''' ) for item in self.__maximum_claim_table: print( F"P{self.__maximum_claim_table.index(lowercase__ ) + 1}" + ''' '''.join(F"{it:>8}" for it in item ) + '''\n''' ) print( '''Current Usage by Active Processes: ''' + ''' '''.join(str(lowercase__ ) for x in self.__claim_vector ) ) print( '''Initial Available Resources: ''' + ''' '''.join(str(lowercase__ ) for x in self.__available_resources() ) ) time.sleep(1 ) if __name__ == "__main__": import doctest doctest.testmod()
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class __lowerCAmelCase : """simple docstring""" def __init__( self ) -> Any: '''simple docstring''' __lowerCamelCase = 0 __lowerCamelCase = 0 __lowerCamelCase = {} def lowercase_ ( self , lowerCamelCase__ ) -> Tuple: '''simple docstring''' if vertex not in self.adjacency: __lowerCamelCase = {} self.num_vertices += 1 def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> str: '''simple docstring''' self.add_vertex(lowerCamelCase__ ) self.add_vertex(lowerCamelCase__ ) if head == tail: return __lowerCamelCase = weight __lowerCamelCase = weight def lowercase_ ( self ) -> List[str]: '''simple docstring''' __lowerCamelCase = self.get_edges() for edge in edges: __lowerCamelCase , __lowerCamelCase , __lowerCamelCase = edge edges.remove((tail, head, weight) ) for i in range(len(lowerCamelCase__ ) ): __lowerCamelCase = list(edges[i] ) edges.sort(key=lambda lowerCamelCase__ : e[2] ) for i in range(len(lowerCamelCase__ ) - 1 ): if edges[i][2] >= edges[i + 1][2]: __lowerCamelCase = edges[i][2] + 1 for edge in edges: __lowerCamelCase , __lowerCamelCase , __lowerCamelCase = edge __lowerCamelCase = weight __lowerCamelCase = weight def __str__( self ) -> Union[str, Any]: '''simple docstring''' __lowerCamelCase = '' for tail in self.adjacency: for head in self.adjacency[tail]: __lowerCamelCase = self.adjacency[head][tail] string += f"""{head} -> {tail} == {weight}\n""" return string.rstrip('\n' ) def lowercase_ ( self ) -> Optional[Any]: '''simple docstring''' __lowerCamelCase = [] for tail in self.adjacency: for head in self.adjacency[tail]: output.append((tail, head, self.adjacency[head][tail]) ) return output def lowercase_ ( self ) -> List[Any]: '''simple docstring''' return self.adjacency.keys() @staticmethod def lowercase_ ( lowerCamelCase__=None , lowerCamelCase__=None ) -> str: '''simple docstring''' __lowerCamelCase = Graph() if vertices is None: __lowerCamelCase = [] if edges is None: __lowerCamelCase = [] for vertex in vertices: g.add_vertex(lowerCamelCase__ ) for edge in edges: g.add_edge(*lowerCamelCase__ ) return g class __lowerCAmelCase : """simple docstring""" def __init__( self ) -> Tuple: '''simple docstring''' __lowerCamelCase = {} __lowerCamelCase = {} def __len__( self ) -> Tuple: '''simple docstring''' return len(self.parent ) def lowercase_ ( self , lowerCamelCase__ ) -> List[Any]: '''simple docstring''' if item in self.parent: return self.find(lowerCamelCase__ ) __lowerCamelCase = item __lowerCamelCase = 0 return item def lowercase_ ( self , lowerCamelCase__ ) -> List[str]: '''simple docstring''' if item not in self.parent: return self.make_set(lowerCamelCase__ ) if item != self.parent[item]: __lowerCamelCase = self.find(self.parent[item] ) return self.parent[item] def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ ) -> int: '''simple docstring''' __lowerCamelCase = self.find(lowerCamelCase__ ) __lowerCamelCase = self.find(lowerCamelCase__ ) if roota == roota: return roota if self.rank[roota] > self.rank[roota]: __lowerCamelCase = roota return roota if self.rank[roota] < self.rank[roota]: __lowerCamelCase = roota return roota if self.rank[roota] == self.rank[roota]: self.rank[roota] += 1 __lowerCamelCase = roota return roota return None @staticmethod def lowercase_ ( lowerCamelCase__ ) -> str: '''simple docstring''' __lowerCamelCase = graph.num_vertices __lowerCamelCase = Graph.UnionFind() __lowerCamelCase = [] while num_components > 1: __lowerCamelCase = {} for vertex in graph.get_vertices(): __lowerCamelCase = -1 __lowerCamelCase = graph.get_edges() for edge in edges: __lowerCamelCase , __lowerCamelCase , __lowerCamelCase = edge edges.remove((tail, head, weight) ) for edge in edges: __lowerCamelCase , __lowerCamelCase , __lowerCamelCase = edge __lowerCamelCase = union_find.find(lowerCamelCase__ ) __lowerCamelCase = union_find.find(lowerCamelCase__ ) if seta != seta: if cheap_edge[seta] == -1 or cheap_edge[seta][2] > weight: __lowerCamelCase = [head, tail, weight] if cheap_edge[seta] == -1 or cheap_edge[seta][2] > weight: __lowerCamelCase = [head, tail, weight] for vertex in cheap_edge: if cheap_edge[vertex] != -1: __lowerCamelCase , __lowerCamelCase , __lowerCamelCase = cheap_edge[vertex] if union_find.find(lowerCamelCase__ ) != union_find.find(lowerCamelCase__ ): union_find.union(lowerCamelCase__ , lowerCamelCase__ ) mst_edges.append(cheap_edge[vertex] ) __lowerCamelCase = num_components - 1 __lowerCamelCase = Graph.build(edges=lowerCamelCase__ ) return mst
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"""simple docstring""" import json import os import unittest from transformers import DebertaTokenizer, DebertaTokenizerFast from transformers.models.deberta.tokenization_deberta import VOCAB_FILES_NAMES from transformers.testing_utils import slow from ...test_tokenization_common import TokenizerTesterMixin class __UpperCamelCase ( a__ , unittest.TestCase ): lowerCamelCase : Dict =DebertaTokenizer lowerCamelCase : Optional[Any] =True lowerCamelCase : List[Any] =DebertaTokenizerFast def __a ( self ) -> Optional[int]: super().setUp() # Adapted from Sennrich et al. 2015 and https://github.com/rsennrich/subword-nmt a : Optional[int] = [ "l", "o", "w", "e", "r", "s", "t", "i", "d", "n", "\u0120", "\u0120l", "\u0120n", "\u0120lo", "\u0120low", "er", "\u0120lowest", "\u0120newer", "\u0120wider", "[UNK]", ] a : str = dict(zip(lowerCAmelCase__ , range(len(lowerCAmelCase__ ) ) ) ) a : str = ["#version: 0.2", "\u0120 l", "\u0120l o", "\u0120lo w", "e r", ""] a : Dict = {"unk_token": "[UNK]"} a : Union[str, Any] = os.path.join(self.tmpdirname , VOCAB_FILES_NAMES["vocab_file"] ) a : str = os.path.join(self.tmpdirname , VOCAB_FILES_NAMES["merges_file"] ) with open(self.vocab_file , "w" , encoding="utf-8" ) as fp: fp.write(json.dumps(lowerCAmelCase__ ) + "\n" ) with open(self.merges_file , "w" , encoding="utf-8" ) as fp: fp.write("\n".join(lowerCAmelCase__ ) ) def __a ( self , **lowerCAmelCase__ ) -> str: kwargs.update(self.special_tokens_map ) return self.tokenizer_class.from_pretrained(self.tmpdirname , **lowerCAmelCase__ ) def __a ( self , lowerCAmelCase__ ) -> List[Any]: a : Dict = "lower newer" a : Dict = "lower newer" return input_text, output_text def __a ( self ) -> List[Any]: a : str = self.get_tokenizer() a : str = "lower newer" a : Union[str, Any] = ["l", "o", "w", "er", "\u0120", "n", "e", "w", "er"] a : Optional[int] = tokenizer.tokenize(lowerCAmelCase__ ) self.assertListEqual(lowerCAmelCase__ , lowerCAmelCase__ ) a : Tuple = tokens + [tokenizer.unk_token] a : Union[str, Any] = [0, 1, 2, 15, 10, 9, 3, 2, 15, 19] self.assertListEqual(tokenizer.convert_tokens_to_ids(lowerCAmelCase__ ) , lowerCAmelCase__ ) def __a ( self ) -> List[Any]: a : List[Any] = self.get_tokenizer() a : Optional[Any] = tokenizer("Hello" , "World" ) a : List[Any] = [0, 0, 0, 0, 0, 0, 0, 1, 1, 1, 1, 1, 1] self.assertListEqual(tokd["token_type_ids"] , lowerCAmelCase__ ) @slow def __a ( self ) -> Tuple: a : Tuple = self.tokenizer_class.from_pretrained("microsoft/deberta-base" ) a : Dict = tokenizer.encode("sequence builders" , add_special_tokens=lowerCAmelCase__ ) a : str = tokenizer.encode("multi-sequence build" , add_special_tokens=lowerCAmelCase__ ) a : Dict = tokenizer.encode( "sequence builders" , add_special_tokens=lowerCAmelCase__ , add_prefix_space=lowerCAmelCase__ ) a : Optional[int] = tokenizer.encode( "sequence builders" , "multi-sequence build" , add_special_tokens=lowerCAmelCase__ , add_prefix_space=lowerCAmelCase__ ) a : str = tokenizer.build_inputs_with_special_tokens(lowerCAmelCase__ ) a : List[str] = tokenizer.build_inputs_with_special_tokens(lowerCAmelCase__ , lowerCAmelCase__ ) assert encoded_sentence == encoded_text_from_decode assert encoded_pair == encoded_pair_from_decode @slow def __a ( self ) -> str: a : str = [self.tokenizer_class] if self.test_rust_tokenizer: tokenizer_classes.append(self.rust_tokenizer_class ) for tokenizer_class in tokenizer_classes: a : int = tokenizer_class.from_pretrained("microsoft/deberta-base" ) a : Optional[int] = [ "ALBERT: A Lite BERT for Self-supervised Learning of Language Representations", "ALBERT incorporates two parameter reduction techniques", "The first one is a factorized embedding parameterization. By decomposing the large vocabulary" " embedding matrix into two small matrices, we separate the size of the hidden layers from the size of" " vocabulary embedding.", ] a : Dict = tokenizer(lowerCAmelCase__ , padding=lowerCAmelCase__ ) a : Optional[Any] = [tokenizer.decode(lowerCAmelCase__ , skip_special_tokens=lowerCAmelCase__ ) for seq in encoding["input_ids"]] # fmt: off a : Optional[int] = { "input_ids": [ [1, 2118, 1_1126, 565, 35, 83, 2_5191, 163, 1_8854, 13, 1_2156, 12, 1_6101, 2_5376, 1_3807, 9, 2_2205, 2_7893, 1635, 2, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0], [1, 2118, 1_1126, 565, 2_4536, 80, 4_3797, 4878, 7373, 2, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0], [1, 133, 78, 65, 16, 10, 3724, 1538, 3_3183, 1_1303, 4_3797, 1938, 4, 870, 2_4165, 2_9105, 5, 739, 3_2644, 3_3183, 1_1303, 3_6173, 88, 80, 650, 7821, 4_5940, 6, 52, 2559, 5, 1836, 9, 5, 7397, 1_3171, 31, 5, 1836, 9, 3_2644, 3_3183, 1_1303, 4, 2] ], "token_type_ids": [ [0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0], [0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0], [0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0] ], "attention_mask": [ [1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0], [1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0], [1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1] ] } # fmt: on a : Union[str, Any] = [ "ALBERT: A Lite BERT for Self-supervised Learning of Language Representations", "ALBERT incorporates two parameter reduction techniques", "The first one is a factorized embedding parameterization. By decomposing the large vocabulary" " embedding matrix into two small matrices, we separate the size of the hidden layers from the size of" " vocabulary embedding.", ] self.assertDictEqual(encoding.data , lowerCAmelCase__ ) for expected, decoded in zip(lowerCAmelCase__ , lowerCAmelCase__ ): self.assertEqual(lowerCAmelCase__ , lowerCAmelCase__ )
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from math import pi, sqrt, tan def lowerCamelCase_ ( UpperCamelCase__ : float ) -> float: """simple docstring""" if side_length < 0: raise ValueError('surface_area_cube() only accepts non-negative values' ) return 6 * side_length**2 def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if length < 0 or breadth < 0 or height < 0: raise ValueError('surface_area_cuboid() only accepts non-negative values' ) return 2 * ((length * breadth) + (breadth * height) + (length * height)) def lowerCamelCase_ ( UpperCamelCase__ : float ) -> float: """simple docstring""" if radius < 0: raise ValueError('surface_area_sphere() only accepts non-negative values' ) return 4 * pi * radius**2 def lowerCamelCase_ ( UpperCamelCase__ : float ) -> float: """simple docstring""" if radius < 0: raise ValueError('surface_area_hemisphere() only accepts non-negative values' ) return 3 * pi * radius**2 def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if radius < 0 or height < 0: raise ValueError('surface_area_cone() only accepts non-negative values' ) return pi * radius * (radius + (height**2 + radius**2) ** 0.5) def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if radius_a < 0 or radius_a < 0 or height < 0: raise ValueError( 'surface_area_conical_frustum() only accepts non-negative values' ) __lowerCamelCase = (height**2 + (radius_a - radius_a) ** 2) ** 0.5 return pi * ((slant_height * (radius_a + radius_a)) + radius_a**2 + radius_a**2) def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if radius < 0 or height < 0: raise ValueError('surface_area_cylinder() only accepts non-negative values' ) return 2 * pi * radius * (height + radius) def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if torus_radius < 0 or tube_radius < 0: raise ValueError('surface_area_torus() only accepts non-negative values' ) if torus_radius < tube_radius: raise ValueError( 'surface_area_torus() does not support spindle or self intersecting tori' ) return 4 * pow(UpperCamelCase__ , 2 ) * torus_radius * tube_radius def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if length < 0 or width < 0: raise ValueError('area_rectangle() only accepts non-negative values' ) return length * width def lowerCamelCase_ ( UpperCamelCase__ : float ) -> float: """simple docstring""" if side_length < 0: raise ValueError('area_square() only accepts non-negative values' ) return side_length**2 def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if base < 0 or height < 0: raise ValueError('area_triangle() only accepts non-negative values' ) return (base * height) / 2 def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if sidea < 0 or sidea < 0 or sidea < 0: raise ValueError('area_triangle_three_sides() only accepts non-negative values' ) elif sidea + sidea < sidea or sidea + sidea < sidea or sidea + sidea < sidea: raise ValueError('Given three sides do not form a triangle' ) __lowerCamelCase = (sidea + sidea + sidea) / 2 __lowerCamelCase = sqrt( semi_perimeter * (semi_perimeter - sidea) * (semi_perimeter - sidea) * (semi_perimeter - sidea) ) return area def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if base < 0 or height < 0: raise ValueError('area_parallelogram() only accepts non-negative values' ) return base * height def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if basea < 0 or basea < 0 or height < 0: raise ValueError('area_trapezium() only accepts non-negative values' ) return 1 / 2 * (basea + basea) * height def lowerCamelCase_ ( UpperCamelCase__ : float ) -> float: """simple docstring""" if radius < 0: raise ValueError('area_circle() only accepts non-negative values' ) return pi * radius**2 def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if radius_x < 0 or radius_y < 0: raise ValueError('area_ellipse() only accepts non-negative values' ) return pi * radius_x * radius_y def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if diagonal_a < 0 or diagonal_a < 0: raise ValueError('area_rhombus() only accepts non-negative values' ) return 1 / 2 * diagonal_a * diagonal_a def lowerCamelCase_ ( UpperCamelCase__ : int , UpperCamelCase__ : float ) -> float: """simple docstring""" if not isinstance(UpperCamelCase__ , UpperCamelCase__ ) or sides < 3: raise ValueError( 'area_reg_polygon() only accepts integers greater than or \ equal to three as number of sides' ) elif length < 0: raise ValueError( 'area_reg_polygon() only accepts non-negative values as \ length of a side' ) return (sides * length**2) / (4 * tan(pi / sides )) return (sides * length**2) / (4 * tan(pi / sides )) if __name__ == "__main__": import doctest doctest.testmod(verbose=True) # verbose so we can see methods missing tests print("[DEMO] Areas of various geometric shapes: \n") print(f'''Rectangle: {area_rectangle(10, 20) = }''') print(f'''Square: {area_square(10) = }''') print(f'''Triangle: {area_triangle(10, 10) = }''') print(f'''Triangle: {area_triangle_three_sides(5, 12, 13) = }''') print(f'''Parallelogram: {area_parallelogram(10, 20) = }''') print(f'''Rhombus: {area_rhombus(10, 20) = }''') print(f'''Trapezium: {area_trapezium(10, 20, 30) = }''') print(f'''Circle: {area_circle(20) = }''') print(f'''Ellipse: {area_ellipse(10, 20) = }''') print("\nSurface Areas of various geometric shapes: \n") print(f'''Cube: {surface_area_cube(20) = }''') print(f'''Cuboid: {surface_area_cuboid(10, 20, 30) = }''') print(f'''Sphere: {surface_area_sphere(20) = }''') print(f'''Hemisphere: {surface_area_hemisphere(20) = }''') print(f'''Cone: {surface_area_cone(10, 20) = }''') print(f'''Conical Frustum: {surface_area_conical_frustum(10, 20, 30) = }''') print(f'''Cylinder: {surface_area_cylinder(10, 20) = }''') print(f'''Torus: {surface_area_torus(20, 10) = }''') print(f'''Equilateral Triangle: {area_reg_polygon(3, 10) = }''') print(f'''Square: {area_reg_polygon(4, 10) = }''') print(f'''Reqular Pentagon: {area_reg_polygon(5, 10) = }''')
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"""simple docstring""" import numpy as np def __SCREAMING_SNAKE_CASE ( A_ , A_ , A_ , A_ , A_ ): lowerCAmelCase__ : Any = int(np.ceil((x_end - xa) / h ) ) lowerCAmelCase__ : Any = np.zeros((n + 1,) ) lowerCAmelCase__ : List[str] = ya lowerCAmelCase__ : List[str] = xa for k in range(A_ ): lowerCAmelCase__ : Optional[int] = f(A_ , y[k] ) lowerCAmelCase__ : int = f(x + 0.5 * h , y[k] + 0.5 * h * ka ) lowerCAmelCase__ : List[str] = f(x + 0.5 * h , y[k] + 0.5 * h * ka ) lowerCAmelCase__ : Optional[int] = f(x + h , y[k] + h * ka ) lowerCAmelCase__ : Optional[Any] = y[k] + (1 / 6) * h * (ka + 2 * ka + 2 * ka + ka) x += h return y if __name__ == "__main__": import doctest doctest.testmod()
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import unittest from transformers import DebertaConfig, is_torch_available from transformers.testing_utils import require_sentencepiece, require_tokenizers, require_torch, slow, torch_device from ...test_configuration_common import ConfigTester from ...test_modeling_common import ModelTesterMixin, ids_tensor from ...test_pipeline_mixin import PipelineTesterMixin if is_torch_available(): import torch from transformers import ( DebertaForMaskedLM, DebertaForQuestionAnswering, DebertaForSequenceClassification, DebertaForTokenClassification, DebertaModel, ) from transformers.models.deberta.modeling_deberta import DEBERTA_PRETRAINED_MODEL_ARCHIVE_LIST class __lowerCAmelCase ( __magic_name__ ): """simple docstring""" def __init__( self , lowerCamelCase__ , lowerCamelCase__=13 , lowerCamelCase__=7 , lowerCamelCase__=True , lowerCamelCase__=True , lowerCamelCase__=True , lowerCamelCase__=True , lowerCamelCase__=99 , lowerCamelCase__=32 , lowerCamelCase__=5 , lowerCamelCase__=4 , lowerCamelCase__=37 , lowerCamelCase__="gelu" , lowerCamelCase__=0.1 , lowerCamelCase__=0.1 , lowerCamelCase__=512 , lowerCamelCase__=16 , lowerCamelCase__=2 , lowerCamelCase__=0.02 , lowerCamelCase__=False , lowerCamelCase__=True , lowerCamelCase__="None" , lowerCamelCase__=3 , lowerCamelCase__=4 , lowerCamelCase__=None , ) -> int: '''simple docstring''' __lowerCamelCase = parent __lowerCamelCase = batch_size __lowerCamelCase = seq_length __lowerCamelCase = is_training __lowerCamelCase = use_input_mask __lowerCamelCase = use_token_type_ids __lowerCamelCase = use_labels __lowerCamelCase = vocab_size __lowerCamelCase = hidden_size __lowerCamelCase = num_hidden_layers __lowerCamelCase = num_attention_heads __lowerCamelCase = intermediate_size __lowerCamelCase = hidden_act __lowerCamelCase = hidden_dropout_prob __lowerCamelCase = attention_probs_dropout_prob __lowerCamelCase = max_position_embeddings __lowerCamelCase = type_vocab_size __lowerCamelCase = type_sequence_label_size __lowerCamelCase = initializer_range __lowerCamelCase = num_labels __lowerCamelCase = num_choices __lowerCamelCase = relative_attention __lowerCamelCase = position_biased_input __lowerCamelCase = pos_att_type __lowerCamelCase = scope def lowercase_ ( self ) -> str: '''simple docstring''' __lowerCamelCase = ids_tensor([self.batch_size, self.seq_length] , self.vocab_size ) __lowerCamelCase = None if self.use_input_mask: __lowerCamelCase = ids_tensor([self.batch_size, self.seq_length] , vocab_size=2 ) __lowerCamelCase = None if self.use_token_type_ids: __lowerCamelCase = ids_tensor([self.batch_size, self.seq_length] , self.type_vocab_size ) __lowerCamelCase = None __lowerCamelCase = None __lowerCamelCase = None if self.use_labels: __lowerCamelCase = ids_tensor([self.batch_size] , self.type_sequence_label_size ) __lowerCamelCase = ids_tensor([self.batch_size, self.seq_length] , self.num_labels ) __lowerCamelCase = ids_tensor([self.batch_size] , self.num_choices ) __lowerCamelCase = self.get_config() return config, input_ids, token_type_ids, input_mask, sequence_labels, token_labels, choice_labels def lowercase_ ( self ) -> Optional[Any]: '''simple docstring''' return DebertaConfig( 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 , relative_attention=self.relative_attention , position_biased_input=self.position_biased_input , pos_att_type=self.pos_att_type , ) def lowercase_ ( self ) -> List[str]: '''simple docstring''' __lowerCamelCase = self.get_config() __lowerCamelCase = 300 return config def lowercase_ ( self , lowerCamelCase__ ) -> Optional[int]: '''simple docstring''' self.parent.assertListEqual(list(result.loss.size() ) , [] ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> Any: '''simple docstring''' __lowerCamelCase = DebertaModel(config=lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model(lowerCamelCase__ , attention_mask=lowerCamelCase__ , token_type_ids=lowerCamelCase__ )[0] __lowerCamelCase = model(lowerCamelCase__ , token_type_ids=lowerCamelCase__ )[0] __lowerCamelCase = model(lowerCamelCase__ )[0] self.parent.assertListEqual(list(sequence_output.size() ) , [self.batch_size, self.seq_length, self.hidden_size] ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> Tuple: '''simple docstring''' __lowerCamelCase = DebertaForMaskedLM(config=lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model(lowerCamelCase__ , attention_mask=lowerCamelCase__ , token_type_ids=lowerCamelCase__ , labels=lowerCamelCase__ ) self.parent.assertEqual(result.logits.shape , (self.batch_size, self.seq_length, self.vocab_size) ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> Union[str, Any]: '''simple docstring''' __lowerCamelCase = self.num_labels __lowerCamelCase = DebertaForSequenceClassification(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model(lowerCamelCase__ , attention_mask=lowerCamelCase__ , token_type_ids=lowerCamelCase__ , labels=lowerCamelCase__ ) self.parent.assertListEqual(list(result.logits.size() ) , [self.batch_size, self.num_labels] ) self.check_loss_output(lowerCamelCase__ ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> Optional[int]: '''simple docstring''' __lowerCamelCase = self.num_labels __lowerCamelCase = DebertaForTokenClassification(config=lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model(lowerCamelCase__ , attention_mask=lowerCamelCase__ , token_type_ids=lowerCamelCase__ , labels=lowerCamelCase__ ) self.parent.assertEqual(result.logits.shape , (self.batch_size, self.seq_length, self.num_labels) ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> Dict: '''simple docstring''' __lowerCamelCase = DebertaForQuestionAnswering(config=lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model( lowerCamelCase__ , attention_mask=lowerCamelCase__ , token_type_ids=lowerCamelCase__ , start_positions=lowerCamelCase__ , end_positions=lowerCamelCase__ , ) self.parent.assertEqual(result.start_logits.shape , (self.batch_size, self.seq_length) ) self.parent.assertEqual(result.end_logits.shape , (self.batch_size, self.seq_length) ) def lowercase_ ( self ) -> Union[str, Any]: '''simple docstring''' __lowerCamelCase = self.prepare_config_and_inputs() ( ( __lowerCamelCase ) , ( __lowerCamelCase ) , ( __lowerCamelCase ) , ( __lowerCamelCase ) , ( __lowerCamelCase ) , ( __lowerCamelCase ) , ( __lowerCamelCase ) , ) = config_and_inputs __lowerCamelCase = {'input_ids': input_ids, 'token_type_ids': token_type_ids, 'attention_mask': input_mask} return config, inputs_dict @require_torch class __lowerCAmelCase ( __magic_name__ , __magic_name__ , unittest.TestCase ): """simple docstring""" snake_case_ = ( ( DebertaModel, DebertaForMaskedLM, DebertaForSequenceClassification, DebertaForTokenClassification, DebertaForQuestionAnswering, ) if is_torch_available() else () ) snake_case_ = ( { '''feature-extraction''': DebertaModel, '''fill-mask''': DebertaForMaskedLM, '''question-answering''': DebertaForQuestionAnswering, '''text-classification''': DebertaForSequenceClassification, '''token-classification''': DebertaForTokenClassification, '''zero-shot''': DebertaForSequenceClassification, } if is_torch_available() else {} ) snake_case_ = True snake_case_ = False snake_case_ = False snake_case_ = False snake_case_ = False def lowercase_ ( self ) -> List[Any]: '''simple docstring''' __lowerCamelCase = DebertaModelTester(self ) __lowerCamelCase = ConfigTester(self , config_class=lowerCamelCase__ , hidden_size=37 ) def lowercase_ ( self ) -> Optional[int]: '''simple docstring''' self.config_tester.run_common_tests() def lowercase_ ( self ) -> List[str]: '''simple docstring''' __lowerCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_deberta_model(*lowerCamelCase__ ) def lowercase_ ( self ) -> Optional[int]: '''simple docstring''' __lowerCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_deberta_for_sequence_classification(*lowerCamelCase__ ) def lowercase_ ( self ) -> Dict: '''simple docstring''' __lowerCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_deberta_for_masked_lm(*lowerCamelCase__ ) def lowercase_ ( self ) -> Optional[Any]: '''simple docstring''' __lowerCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_deberta_for_question_answering(*lowerCamelCase__ ) def lowercase_ ( self ) -> str: '''simple docstring''' __lowerCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_deberta_for_token_classification(*lowerCamelCase__ ) @slow def lowercase_ ( self ) -> Optional[int]: '''simple docstring''' for model_name in DEBERTA_PRETRAINED_MODEL_ARCHIVE_LIST[:1]: __lowerCamelCase = DebertaModel.from_pretrained(lowerCamelCase__ ) self.assertIsNotNone(lowerCamelCase__ ) @require_torch @require_sentencepiece @require_tokenizers class __lowerCAmelCase ( unittest.TestCase ): """simple docstring""" @unittest.skip(reason='Model not available yet' ) def lowercase_ ( self ) -> Union[str, Any]: '''simple docstring''' pass @slow def lowercase_ ( self ) -> Tuple: '''simple docstring''' __lowerCamelCase = DebertaModel.from_pretrained('microsoft/deberta-base' ) __lowerCamelCase = torch.tensor([[0, 31_414, 232, 328, 740, 1_140, 12_695, 69, 46_078, 1_588, 2]] ) __lowerCamelCase = torch.tensor([[0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1]] ) with torch.no_grad(): __lowerCamelCase = model(lowerCamelCase__ , attention_mask=lowerCamelCase__ )[0] # compare the actual values for a slice. __lowerCamelCase = torch.tensor( [[[-0.59_86, -0.80_55, -0.84_62], [1.44_84, -0.93_48, -0.80_59], [0.31_23, 0.00_32, -1.41_31]]] ) self.assertTrue(torch.allclose(output[:, 1:4, 1:4] , lowerCamelCase__ , atol=1e-4 ) , f"""{output[:, 1:4, 1:4]}""" )
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import logging import torch from torch import nn from torch.nn import CrossEntropyLoss, MSELoss from transformers.file_utils import add_start_docstrings, add_start_docstrings_to_model_forward from transformers.models.bert.modeling_bert import ( BERT_INPUTS_DOCSTRING, BERT_START_DOCSTRING, BertEncoder, BertModel, BertPreTrainedModel, ) __lowerCAmelCase : List[Any] = logging.getLogger(__name__) class snake_case__ (_UpperCamelCase ): """simple docstring""" def __UpperCAmelCase ( self : Union[str, Any] , __lowerCamelCase : Any , __lowerCamelCase : str , __lowerCamelCase : Any=None , __lowerCamelCase : Optional[int]=None ) -> List[Any]: a = self.layer[current_layer](__lowerCamelCase , __lowerCamelCase , head_mask[current_layer] ) a = layer_outputs[0] return hidden_states @add_start_docstrings( """The bare Bert Model transformer with PABEE outputting raw hidden-states without any specific head on top.""" , _UpperCamelCase , ) class snake_case__ (_UpperCamelCase ): """simple docstring""" def __init__( self : str , __lowerCamelCase : Tuple ) -> str: super().__init__(__lowerCamelCase ) a = BertEncoderWithPabee(__lowerCamelCase ) self.init_weights() a = 0 a = 0 a = 0 a = 0 def __UpperCAmelCase ( self : Any , __lowerCamelCase : List[str] ) -> List[str]: a = threshold def __UpperCAmelCase ( self : int , __lowerCamelCase : Tuple ) -> Any: a = patience def __UpperCAmelCase ( self : List[Any] ) -> Union[str, Any]: a = 0 a = 0 def __UpperCAmelCase ( self : List[str] ) -> List[str]: a = self.inference_layers_num / self.inference_instances_num a = ( f"""*** Patience = {self.patience} Avg. Inference Layers = {avg_inf_layers:.2f} Speed Up =""" f""" {1 - avg_inf_layers / self.config.num_hidden_layers:.2f} ***""" ) print(__lowerCamelCase ) @add_start_docstrings_to_model_forward(__lowerCamelCase ) def __UpperCAmelCase ( self : int , __lowerCamelCase : int=None , __lowerCamelCase : int=None , __lowerCamelCase : Any=None , __lowerCamelCase : Optional[int]=None , __lowerCamelCase : str=None , __lowerCamelCase : Optional[int]=None , __lowerCamelCase : Tuple=None , __lowerCamelCase : int=None , __lowerCamelCase : List[str]=None , __lowerCamelCase : int=None , __lowerCamelCase : Any=False , ) -> Optional[Any]: if input_ids is not None and inputs_embeds is not None: raise ValueError("You cannot specify both input_ids and inputs_embeds at the same time" ) elif input_ids is not None: a = input_ids.size() elif inputs_embeds is not None: a = inputs_embeds.size()[:-1] else: raise ValueError("You have to specify either input_ids or inputs_embeds" ) a = input_ids.device if input_ids is not None else inputs_embeds.device if attention_mask is None: a = torch.ones(__lowerCamelCase , device=__lowerCamelCase ) if token_type_ids is None: a = torch.zeros(__lowerCamelCase , dtype=torch.long , device=__lowerCamelCase ) # We can provide a self-attention mask of dimensions [batch_size, from_seq_length, to_seq_length] # ourselves in which case we just need to make it broadcastable to all heads. a = self.get_extended_attention_mask(__lowerCamelCase , __lowerCamelCase , __lowerCamelCase ) # If a 2D ou 3D attention mask is provided for the cross-attention # we need to make broadcastable to [batch_size, num_heads, seq_length, seq_length] if self.config.is_decoder and encoder_hidden_states is not None: a , a , a = encoder_hidden_states.size() a = (encoder_batch_size, encoder_sequence_length) if encoder_attention_mask is None: a = torch.ones(__lowerCamelCase , device=__lowerCamelCase ) a = self.invert_attention_mask(__lowerCamelCase ) else: a = None # Prepare head mask if needed # 1.0 in head_mask indicate we keep the head # attention_probs has shape bsz x n_heads x N x N # input head_mask has shape [num_heads] or [num_hidden_layers x num_heads] # and head_mask is converted to shape [num_hidden_layers x batch x num_heads x seq_length x seq_length] a = self.get_head_mask(__lowerCamelCase , self.config.num_hidden_layers ) a = self.embeddings( input_ids=__lowerCamelCase , position_ids=__lowerCamelCase , token_type_ids=__lowerCamelCase , inputs_embeds=__lowerCamelCase ) a = embedding_output if self.training: a = [] for i in range(self.config.num_hidden_layers ): a = self.encoder.adaptive_forward( __lowerCamelCase , current_layer=__lowerCamelCase , attention_mask=__lowerCamelCase , head_mask=__lowerCamelCase ) a = self.pooler(__lowerCamelCase ) a = output_layers[i](output_dropout(__lowerCamelCase ) ) res.append(__lowerCamelCase ) elif self.patience == 0: # Use all layers for inference a = self.encoder( __lowerCamelCase , attention_mask=__lowerCamelCase , head_mask=__lowerCamelCase , encoder_hidden_states=__lowerCamelCase , encoder_attention_mask=__lowerCamelCase , ) a = self.pooler(encoder_outputs[0] ) a = [output_layers[self.config.num_hidden_layers - 1](__lowerCamelCase )] else: a = 0 a = None a = 0 for i in range(self.config.num_hidden_layers ): calculated_layer_num += 1 a = self.encoder.adaptive_forward( __lowerCamelCase , current_layer=__lowerCamelCase , attention_mask=__lowerCamelCase , head_mask=__lowerCamelCase ) a = self.pooler(__lowerCamelCase ) a = output_layers[i](__lowerCamelCase ) if regression: a = logits.detach() if patient_result is not None: a = patient_result.detach() if (patient_result is not None) and torch.abs(patient_result - labels ) < self.regression_threshold: patient_counter += 1 else: a = 0 else: a = logits.detach().argmax(dim=1 ) if patient_result is not None: a = patient_result.detach().argmax(dim=1 ) if (patient_result is not None) and torch.all(labels.eq(__lowerCamelCase ) ): patient_counter += 1 else: a = 0 a = logits if patient_counter == self.patience: break a = [patient_result] self.inference_layers_num += calculated_layer_num self.inference_instances_num += 1 return res @add_start_docstrings( """Bert Model transformer with PABEE and a sequence classification/regression head on top (a linear layer on top of the pooled output) e.g. for GLUE tasks. """ , _UpperCamelCase , ) class snake_case__ (_UpperCamelCase ): """simple docstring""" def __init__( self : str , __lowerCamelCase : Any ) -> Union[str, Any]: super().__init__(__lowerCamelCase ) a = config.num_labels a = BertModelWithPabee(__lowerCamelCase ) a = nn.Dropout(config.hidden_dropout_prob ) a = nn.ModuleList( [nn.Linear(config.hidden_size , self.config.num_labels ) for _ in range(config.num_hidden_layers )] ) self.init_weights() @add_start_docstrings_to_model_forward(__lowerCamelCase ) def __UpperCAmelCase ( self : Tuple , __lowerCamelCase : List[str]=None , __lowerCamelCase : Optional[int]=None , __lowerCamelCase : str=None , __lowerCamelCase : Dict=None , __lowerCamelCase : Any=None , __lowerCamelCase : Optional[int]=None , __lowerCamelCase : Any=None , ) -> Optional[int]: a = self.bert( input_ids=__lowerCamelCase , attention_mask=__lowerCamelCase , token_type_ids=__lowerCamelCase , position_ids=__lowerCamelCase , head_mask=__lowerCamelCase , inputs_embeds=__lowerCamelCase , output_dropout=self.dropout , output_layers=self.classifiers , regression=self.num_labels == 1 , ) a = (logits[-1],) if labels is not None: a = None a = 0 for ix, logits_item in enumerate(__lowerCamelCase ): if self.num_labels == 1: # We are doing regression a = MSELoss() a = loss_fct(logits_item.view(-1 ) , labels.view(-1 ) ) else: a = CrossEntropyLoss() a = loss_fct(logits_item.view(-1 , self.num_labels ) , labels.view(-1 ) ) if total_loss is None: a = loss else: total_loss += loss * (ix + 1) total_weights += ix + 1 a = (total_loss / total_weights,) + outputs return outputs
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from __future__ import annotations # This is the precision for this function which can be altered. # It is recommended for users to keep this number greater than or equal to 10. __A = 10 def lowerCamelCase_ ( UpperCamelCase__ : int , UpperCamelCase__ : int , UpperCamelCase__ : list[int] , UpperCamelCase__ : int ) -> int: """simple docstring""" for i in range(UpperCamelCase__ , UpperCamelCase__ ): if array[i] == target: return i return -1 def lowerCamelCase_ ( UpperCamelCase__ : list[int] , UpperCamelCase__ : int ) -> int: """simple docstring""" __lowerCamelCase = 0 __lowerCamelCase = len(UpperCamelCase__ ) while left <= right: if right - left < precision: return lin_search(UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ ) __lowerCamelCase = (left + right) // 3 + 1 __lowerCamelCase = 2 * (left + right) // 3 + 1 if array[one_third] == target: return one_third elif array[two_third] == target: return two_third elif target < array[one_third]: __lowerCamelCase = one_third - 1 elif array[two_third] < target: __lowerCamelCase = two_third + 1 else: __lowerCamelCase = one_third + 1 __lowerCamelCase = two_third - 1 else: return -1 def lowerCamelCase_ ( UpperCamelCase__ : int , UpperCamelCase__ : int , UpperCamelCase__ : list[int] , UpperCamelCase__ : int ) -> int: """simple docstring""" if left < right: if right - left < precision: return lin_search(UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ ) __lowerCamelCase = (left + right) // 3 + 1 __lowerCamelCase = 2 * (left + right) // 3 + 1 if array[one_third] == target: return one_third elif array[two_third] == target: return two_third elif target < array[one_third]: return rec_ternary_search(UpperCamelCase__ , one_third - 1 , UpperCamelCase__ , UpperCamelCase__ ) elif array[two_third] < target: return rec_ternary_search(two_third + 1 , UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ ) else: return rec_ternary_search(one_third + 1 , two_third - 1 , UpperCamelCase__ , UpperCamelCase__ ) else: return -1 if __name__ == "__main__": import doctest doctest.testmod() __A = input("Enter numbers separated by comma:\n").strip() __A = [int(item.strip()) for item in user_input.split(",")] assert collection == sorted(collection), f"List must be ordered.\n{collection}." __A = int(input("Enter the number to be found in the list:\n").strip()) __A = ite_ternary_search(collection, target) __A = rec_ternary_search(0, len(collection) - 1, collection, target) if resulta != -1: print(f'''Iterative search: {target} found at positions: {resulta}''') print(f'''Recursive search: {target} found at positions: {resulta}''') else: print("Not found")
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"""simple docstring""" import sys def a__ ( SCREAMING_SNAKE_CASE : Optional[Any] ): '''simple docstring''' lowerCAmelCase : Union[str, Any] = len(SCREAMING_SNAKE_CASE ) lowerCAmelCase : Any = [[0 for x in range(SCREAMING_SNAKE_CASE )] for x in range(SCREAMING_SNAKE_CASE )] lowerCAmelCase : Tuple = [[0 for x in range(SCREAMING_SNAKE_CASE )] for x in range(SCREAMING_SNAKE_CASE )] for chain_length in range(2 , SCREAMING_SNAKE_CASE ): for a in range(1 , n - chain_length + 1 ): lowerCAmelCase : List[Any] = a + chain_length - 1 lowerCAmelCase : List[Any] = sys.maxsize for c in range(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ): lowerCAmelCase : Union[str, Any] = ( matrix[a][c] + matrix[c + 1][b] + array[a - 1] * array[c] * array[b] ) if cost < matrix[a][b]: lowerCAmelCase : str = cost lowerCAmelCase : Optional[int] = c return matrix, sol def a__ ( SCREAMING_SNAKE_CASE : Optional[int] , SCREAMING_SNAKE_CASE : Union[str, Any] , SCREAMING_SNAKE_CASE : str ): '''simple docstring''' if i == j: print("A" + str(SCREAMING_SNAKE_CASE ) , end=" " ) else: print("(" , end=" " ) print_optiomal_solution(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , optimal_solution[i][j] ) print_optiomal_solution(SCREAMING_SNAKE_CASE , optimal_solution[i][j] + 1 , SCREAMING_SNAKE_CASE ) print(")" , end=" " ) def a__ ( ): '''simple docstring''' lowerCAmelCase : Optional[int] = [3_0, 3_5, 1_5, 5, 1_0, 2_0, 2_5] lowerCAmelCase : List[Any] = len(SCREAMING_SNAKE_CASE ) # Size of matrix created from above array will be # 30*35 35*15 15*5 5*10 10*20 20*25 lowerCAmelCase , lowerCAmelCase : List[Any] = matrix_chain_order(SCREAMING_SNAKE_CASE ) print("No. of Operation required: " + str(matrix[1][n - 1] ) ) print_optiomal_solution(SCREAMING_SNAKE_CASE , 1 , n - 1 ) if __name__ == "__main__": main()
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import string # frequency taken from https://en.wikipedia.org/wiki/Letter_frequency __A = { "E": 1_2.7_0, "T": 9.0_6, "A": 8.1_7, "O": 7.5_1, "I": 6.9_7, "N": 6.7_5, "S": 6.3_3, "H": 6.0_9, "R": 5.9_9, "D": 4.2_5, "L": 4.0_3, "C": 2.7_8, "U": 2.7_6, "M": 2.4_1, "W": 2.3_6, "F": 2.2_3, "G": 2.0_2, "Y": 1.9_7, "P": 1.9_3, "B": 1.2_9, "V": 0.9_8, "K": 0.7_7, "J": 0.1_5, "X": 0.1_5, "Q": 0.1_0, "Z": 0.0_7, } __A = "ETAOINSHRDLCUMWFGYPBVKJXQZ" __A = "ABCDEFGHIJKLMNOPQRSTUVWXYZ" def lowerCamelCase_ ( UpperCamelCase__ : str ) -> dict[str, int]: """simple docstring""" __lowerCamelCase = {letter: 0 for letter in string.ascii_uppercase} for letter in message.upper(): if letter in LETTERS: letter_count[letter] += 1 return letter_count def lowerCamelCase_ ( UpperCamelCase__ : tuple ) -> str: """simple docstring""" return x[0] def lowerCamelCase_ ( UpperCamelCase__ : str ) -> str: """simple docstring""" __lowerCamelCase = get_letter_count(UpperCamelCase__ ) __lowerCamelCase = { freq: [] for letter, freq in letter_to_freq.items() } for letter in LETTERS: freq_to_letter[letter_to_freq[letter]].append(UpperCamelCase__ ) __lowerCamelCase = {} for freq in freq_to_letter: freq_to_letter[freq].sort(key=ETAOIN.find , reverse=UpperCamelCase__ ) __lowerCamelCase = ''.join(freq_to_letter[freq] ) __lowerCamelCase = list(freq_to_letter_str.items() ) freq_pairs.sort(key=UpperCamelCase__ , reverse=UpperCamelCase__ ) __lowerCamelCase = [freq_pair[1] for freq_pair in freq_pairs] return "".join(UpperCamelCase__ ) def lowerCamelCase_ ( UpperCamelCase__ : str ) -> int: """simple docstring""" __lowerCamelCase = get_frequency_order(UpperCamelCase__ ) __lowerCamelCase = 0 for common_letter in ETAOIN[:6]: if common_letter in freq_order[:6]: match_score += 1 for uncommon_letter in ETAOIN[-6:]: if uncommon_letter in freq_order[-6:]: match_score += 1 return match_score if __name__ == "__main__": import doctest doctest.testmod()
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"""simple docstring""" from typing import 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 ....file_utils import PaddingStrategy, TensorType from ....utils import logging A: Any = logging.get_logger(__name__) class SCREAMING_SNAKE_CASE__ ( UpperCAmelCase__ ): __lowerCAmelCase : str = ['input_features', 'attention_mask'] def __init__( self , _SCREAMING_SNAKE_CASE=80 , _SCREAMING_SNAKE_CASE=16000 , _SCREAMING_SNAKE_CASE=0.0 , _SCREAMING_SNAKE_CASE=10 , _SCREAMING_SNAKE_CASE=25 , _SCREAMING_SNAKE_CASE="hamming_window" , _SCREAMING_SNAKE_CASE=3_2768.0 , _SCREAMING_SNAKE_CASE=0.97 , _SCREAMING_SNAKE_CASE=1.0 , _SCREAMING_SNAKE_CASE=True , _SCREAMING_SNAKE_CASE=True , _SCREAMING_SNAKE_CASE=False , **_SCREAMING_SNAKE_CASE , ) -> str: '''simple docstring''' super().__init__(feature_size=_SCREAMING_SNAKE_CASE , sampling_rate=_SCREAMING_SNAKE_CASE , padding_value=_SCREAMING_SNAKE_CASE , **_SCREAMING_SNAKE_CASE ) UpperCAmelCase : str = feature_size UpperCAmelCase : str = sampling_rate UpperCAmelCase : List[str] = padding_value UpperCAmelCase : Dict = hop_length UpperCAmelCase : str = win_length UpperCAmelCase : int = frame_signal_scale UpperCAmelCase : Tuple = preemphasis_coeff UpperCAmelCase : Any = mel_floor UpperCAmelCase : Optional[int] = normalize_means UpperCAmelCase : Union[str, Any] = normalize_vars UpperCAmelCase : Optional[int] = win_function UpperCAmelCase : Optional[int] = return_attention_mask UpperCAmelCase : Optional[Any] = win_length * sampling_rate // 1000 UpperCAmelCase : List[Any] = hop_length * sampling_rate // 1000 UpperCAmelCase : Optional[int] = optimal_fft_length(self.sample_size ) UpperCAmelCase : List[Any] = (self.n_fft // 2) + 1 def SCREAMING_SNAKE_CASE ( self , _SCREAMING_SNAKE_CASE ) -> np.ndarray: '''simple docstring''' if self.win_function == "hamming_window": UpperCAmelCase : str = window_function(window_length=self.sample_size , name=self.win_function , periodic=_SCREAMING_SNAKE_CASE ) else: UpperCAmelCase : Any = window_function(window_length=self.sample_size , name=self.win_function ) UpperCAmelCase : Optional[int] = mel_filter_bank( num_frequency_bins=self.n_freqs , num_mel_filters=self.feature_size , min_frequency=0.0 , max_frequency=self.sampling_rate / 2.0 , sampling_rate=self.sampling_rate , ) UpperCAmelCase : Optional[int] = spectrogram( one_waveform * self.frame_signal_scale , window=_SCREAMING_SNAKE_CASE , frame_length=self.sample_size , hop_length=self.sample_stride , fft_length=self.n_fft , center=_SCREAMING_SNAKE_CASE , preemphasis=self.preemphasis_coeff , mel_filters=_SCREAMING_SNAKE_CASE , mel_floor=self.mel_floor , log_mel="""log""" , ) return msfc_features.T def SCREAMING_SNAKE_CASE ( self , _SCREAMING_SNAKE_CASE , _SCREAMING_SNAKE_CASE , _SCREAMING_SNAKE_CASE ) -> Any: '''simple docstring''' if self.normalize_means: UpperCAmelCase : str = x[:input_length].mean(axis=0 ) UpperCAmelCase : Optional[int] = np.subtract(_SCREAMING_SNAKE_CASE , _SCREAMING_SNAKE_CASE ) if self.normalize_vars: UpperCAmelCase : Any = x[:input_length].std(axis=0 ) UpperCAmelCase : List[str] = np.divide(_SCREAMING_SNAKE_CASE , _SCREAMING_SNAKE_CASE ) if input_length < x.shape[0]: UpperCAmelCase : Dict = padding_value # make sure array is in float32 UpperCAmelCase : Dict = x.astype(np.floataa ) return x def SCREAMING_SNAKE_CASE ( self , _SCREAMING_SNAKE_CASE , _SCREAMING_SNAKE_CASE = None ) -> List[np.ndarray]: '''simple docstring''' UpperCAmelCase : List[Any] = attention_mask.sum(-1 ) if attention_mask is not None else [x.shape[0] for x in input_features] return [self._normalize_one(_SCREAMING_SNAKE_CASE , _SCREAMING_SNAKE_CASE , self.padding_value ) for x, n in zip(_SCREAMING_SNAKE_CASE , _SCREAMING_SNAKE_CASE )] def __call__( self , _SCREAMING_SNAKE_CASE , _SCREAMING_SNAKE_CASE = False , _SCREAMING_SNAKE_CASE = None , _SCREAMING_SNAKE_CASE = False , _SCREAMING_SNAKE_CASE = None , _SCREAMING_SNAKE_CASE = None , _SCREAMING_SNAKE_CASE = None , _SCREAMING_SNAKE_CASE = None , **_SCREAMING_SNAKE_CASE , ) -> BatchFeature: '''simple docstring''' 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 `raw_speech` 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.""" ) UpperCAmelCase : List[str] = isinstance(_SCREAMING_SNAKE_CASE , np.ndarray ) and len(raw_speech.shape ) > 1 if is_batched_numpy and len(raw_speech.shape ) > 2: raise ValueError(F"Only mono-channel audio is supported for input to {self}" ) UpperCAmelCase : Any = is_batched_numpy or ( isinstance(_SCREAMING_SNAKE_CASE , (list, tuple) ) and (isinstance(raw_speech[0] , (np.ndarray, tuple, list) )) ) if is_batched: UpperCAmelCase : str = [np.asarray(_SCREAMING_SNAKE_CASE , dtype=np.floataa ) for speech in raw_speech] elif not is_batched and not isinstance(_SCREAMING_SNAKE_CASE , np.ndarray ): UpperCAmelCase : List[Any] = np.asarray(_SCREAMING_SNAKE_CASE , dtype=np.floataa ) elif isinstance(_SCREAMING_SNAKE_CASE , np.ndarray ) and raw_speech.dtype is np.dtype(np.floataa ): UpperCAmelCase : List[Any] = raw_speech.astype(np.floataa ) # always return batch if not is_batched: UpperCAmelCase : Union[str, Any] = [raw_speech] # extract fbank features UpperCAmelCase : Optional[int] = [self._extract_mfsc_features(_SCREAMING_SNAKE_CASE ) for one_waveform in raw_speech] # convert into correct format for padding UpperCAmelCase : Optional[Any] = BatchFeature({"""input_features""": features} ) UpperCAmelCase : List[Any] = self.pad( _SCREAMING_SNAKE_CASE , padding=_SCREAMING_SNAKE_CASE , max_length=_SCREAMING_SNAKE_CASE , truncation=_SCREAMING_SNAKE_CASE , pad_to_multiple_of=_SCREAMING_SNAKE_CASE , return_attention_mask=_SCREAMING_SNAKE_CASE , **_SCREAMING_SNAKE_CASE , ) # make sure list is in array format UpperCAmelCase : Union[str, Any] = padded_inputs.get("""input_features""" ) if isinstance(input_features[0] , _SCREAMING_SNAKE_CASE ): UpperCAmelCase : Optional[Any] = [np.asarray(_SCREAMING_SNAKE_CASE , dtype=np.floataa ) for feature in input_features] UpperCAmelCase : Union[str, Any] = padded_inputs.get("""attention_mask""" ) if attention_mask is not None: UpperCAmelCase : Optional[Any] = [np.asarray(_SCREAMING_SNAKE_CASE , dtype=np.intaa ) for array in attention_mask] if self.normalize_means or self.normalize_vars: UpperCAmelCase : Union[str, Any] = ( np.array(_SCREAMING_SNAKE_CASE , dtype=np.intaa ) if self._get_padding_strategies(_SCREAMING_SNAKE_CASE , max_length=_SCREAMING_SNAKE_CASE ) is not PaddingStrategy.DO_NOT_PAD and padding else None ) UpperCAmelCase : Any = self.normalize( padded_inputs["""input_features"""] , attention_mask=_SCREAMING_SNAKE_CASE ) if return_tensors is not None: UpperCAmelCase : Optional[Any] = padded_inputs.convert_to_tensors(_SCREAMING_SNAKE_CASE ) return padded_inputs
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class __lowerCAmelCase : """simple docstring""" def __init__( self , lowerCamelCase__ ) -> Any: '''simple docstring''' __lowerCamelCase = n __lowerCamelCase = [None] * self.n __lowerCamelCase = 0 # index of the first element __lowerCamelCase = 0 __lowerCamelCase = 0 def __len__( self ) -> int: '''simple docstring''' return self.size def lowercase_ ( self ) -> bool: '''simple docstring''' return self.size == 0 def lowercase_ ( self ) -> str: '''simple docstring''' return False if self.is_empty() else self.array[self.front] def lowercase_ ( self , lowerCamelCase__ ) -> Optional[Any]: '''simple docstring''' if self.size >= self.n: raise Exception('QUEUE IS FULL' ) __lowerCamelCase = data __lowerCamelCase = (self.rear + 1) % self.n self.size += 1 return self def lowercase_ ( self ) -> Tuple: '''simple docstring''' if self.size == 0: raise Exception('UNDERFLOW' ) __lowerCamelCase = self.array[self.front] __lowerCamelCase = None __lowerCamelCase = (self.front + 1) % self.n self.size -= 1 return temp
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from __future__ import annotations import time from math import sqrt # 1 for manhattan, 0 for euclidean lowerCAmelCase = 0 lowerCAmelCase = [ [0, 0, 0, 0, 0, 0, 0], [0, 1, 0, 0, 0, 0, 0], # 0 are free path whereas 1's are obstacles [0, 0, 0, 0, 0, 0, 0], [0, 0, 1, 0, 0, 0, 0], [1, 0, 1, 0, 0, 0, 0], [0, 0, 0, 0, 0, 0, 0], [0, 0, 0, 0, 1, 0, 0], ] lowerCAmelCase = [[-1, 0], [0, -1], [1, 0], [0, 1]] # up, left, down, right lowerCAmelCase = tuple[int, int] class _a : def __init__( self: Optional[Any] , UpperCamelCase_: int , UpperCamelCase_: int , UpperCamelCase_: int , UpperCamelCase_: int , UpperCamelCase_: int , UpperCamelCase_: Node | None , ) -> None: """simple docstring""" lowercase__ = pos_x lowercase__ = pos_y lowercase__ = (pos_y, pos_x) lowercase__ = goal_x lowercase__ = goal_y lowercase__ = g_cost lowercase__ = parent lowercase__ = self.calculate_heuristic() lowercase__ = self.g_cost + self.h_cost def lowerCamelCase_ ( self: Union[str, Any] ) -> float: """simple docstring""" lowercase__ = self.pos_x - self.goal_x lowercase__ = self.pos_y - self.goal_y if HEURISTIC == 1: return abs(UpperCamelCase_ ) + abs(UpperCamelCase_ ) else: return sqrt(dy**2 + dx**2 ) def __lt__( self: Optional[Any] , UpperCamelCase_: Node ) -> bool: """simple docstring""" return self.f_cost < other.f_cost class _a : def __init__( self: List[Any] , UpperCamelCase_: TPosition , UpperCamelCase_: TPosition ) -> Dict: """simple docstring""" lowercase__ = Node(start[1] , start[0] , goal[1] , goal[0] , 0 , UpperCamelCase_ ) lowercase__ = Node(goal[1] , goal[0] , goal[1] , goal[0] , 99_999 , UpperCamelCase_ ) lowercase__ = [self.start] lowercase__ = [] lowercase__ = False def lowerCamelCase_ ( self: Any ) -> list[TPosition]: """simple docstring""" while self.open_nodes: # Open Nodes are sorted using __lt__ self.open_nodes.sort() lowercase__ = self.open_nodes.pop(0 ) if current_node.pos == self.target.pos: return self.retrace_path(UpperCamelCase_ ) self.closed_nodes.append(UpperCamelCase_ ) lowercase__ = self.get_successors(UpperCamelCase_ ) for child_node in successors: if child_node in self.closed_nodes: continue if child_node not in self.open_nodes: self.open_nodes.append(UpperCamelCase_ ) else: # retrieve the best current path lowercase__ = self.open_nodes.pop(self.open_nodes.index(UpperCamelCase_ ) ) if child_node.g_cost < better_node.g_cost: self.open_nodes.append(UpperCamelCase_ ) else: self.open_nodes.append(UpperCamelCase_ ) return [self.start.pos] def lowerCamelCase_ ( self: List[Any] , UpperCamelCase_: Node ) -> list[Node]: """simple docstring""" lowercase__ = [] for action in delta: lowercase__ = parent.pos_x + action[1] lowercase__ = parent.pos_y + action[0] if not (0 <= pos_x <= len(grid[0] ) - 1 and 0 <= pos_y <= len(UpperCamelCase_ ) - 1): continue if grid[pos_y][pos_x] != 0: continue successors.append( Node( UpperCamelCase_ , UpperCamelCase_ , self.target.pos_y , self.target.pos_x , parent.g_cost + 1 , UpperCamelCase_ , ) ) return successors def lowerCamelCase_ ( self: Optional[int] , UpperCamelCase_: Node | None ) -> list[TPosition]: """simple docstring""" lowercase__ = node lowercase__ = [] while current_node is not None: path.append((current_node.pos_y, current_node.pos_x) ) lowercase__ = current_node.parent path.reverse() return path class _a : def __init__( self: Optional[int] , UpperCamelCase_: TPosition , UpperCamelCase_: TPosition ) -> None: """simple docstring""" lowercase__ = AStar(UpperCamelCase_ , UpperCamelCase_ ) lowercase__ = AStar(UpperCamelCase_ , UpperCamelCase_ ) lowercase__ = False def lowerCamelCase_ ( self: int ) -> list[TPosition]: """simple docstring""" while self.fwd_astar.open_nodes or self.bwd_astar.open_nodes: self.fwd_astar.open_nodes.sort() self.bwd_astar.open_nodes.sort() lowercase__ = self.fwd_astar.open_nodes.pop(0 ) lowercase__ = self.bwd_astar.open_nodes.pop(0 ) if current_bwd_node.pos == current_fwd_node.pos: return self.retrace_bidirectional_path( UpperCamelCase_ , UpperCamelCase_ ) self.fwd_astar.closed_nodes.append(UpperCamelCase_ ) self.bwd_astar.closed_nodes.append(UpperCamelCase_ ) lowercase__ = current_bwd_node lowercase__ = current_fwd_node lowercase__ = { self.fwd_astar: self.fwd_astar.get_successors(UpperCamelCase_ ), self.bwd_astar: self.bwd_astar.get_successors(UpperCamelCase_ ), } for astar in [self.fwd_astar, self.bwd_astar]: for child_node in successors[astar]: if child_node in astar.closed_nodes: continue if child_node not in astar.open_nodes: astar.open_nodes.append(UpperCamelCase_ ) else: # retrieve the best current path lowercase__ = astar.open_nodes.pop( astar.open_nodes.index(UpperCamelCase_ ) ) if child_node.g_cost < better_node.g_cost: astar.open_nodes.append(UpperCamelCase_ ) else: astar.open_nodes.append(UpperCamelCase_ ) return [self.fwd_astar.start.pos] def lowerCamelCase_ ( self: Tuple , UpperCamelCase_: Node , UpperCamelCase_: Node ) -> list[TPosition]: """simple docstring""" lowercase__ = self.fwd_astar.retrace_path(UpperCamelCase_ ) lowercase__ = self.bwd_astar.retrace_path(UpperCamelCase_ ) bwd_path.pop() bwd_path.reverse() lowercase__ = fwd_path + bwd_path return path if __name__ == "__main__": # all coordinates are given in format [y,x] lowerCAmelCase = (0, 0) lowerCAmelCase = (len(grid) - 1, len(grid[0]) - 1) for elem in grid: print(elem) lowerCAmelCase = time.time() lowerCAmelCase = AStar(init, goal) lowerCAmelCase = a_star.search() lowerCAmelCase = time.time() - start_time print(f"""AStar execution time = {end_time:f} seconds""") lowerCAmelCase = time.time() lowerCAmelCase = BidirectionalAStar(init, goal) lowerCAmelCase = time.time() - bd_start_time print(f"""BidirectionalAStar execution time = {bd_end_time:f} seconds""")
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import unittest import numpy as np from transformers.testing_utils import require_flax, require_tf, require_torch from transformers.utils import ( expand_dims, flatten_dict, is_flax_available, is_tf_available, is_torch_available, reshape, squeeze, transpose, ) if is_flax_available(): import jax.numpy as jnp if is_tf_available(): import tensorflow as tf if is_torch_available(): import torch class __lowerCAmelCase ( unittest.TestCase ): """simple docstring""" def lowercase_ ( self ) -> Tuple: '''simple docstring''' __lowerCamelCase = { 'task_specific_params': { 'summarization': {'length_penalty': 1.0, 'max_length': 128, 'min_length': 12, 'num_beams': 4}, 'summarization_cnn': {'length_penalty': 2.0, 'max_length': 142, 'min_length': 56, 'num_beams': 4}, 'summarization_xsum': {'length_penalty': 1.0, 'max_length': 62, 'min_length': 11, 'num_beams': 6}, } } __lowerCamelCase = { 'task_specific_params.summarization.length_penalty': 1.0, 'task_specific_params.summarization.max_length': 128, 'task_specific_params.summarization.min_length': 12, 'task_specific_params.summarization.num_beams': 4, 'task_specific_params.summarization_cnn.length_penalty': 2.0, 'task_specific_params.summarization_cnn.max_length': 142, 'task_specific_params.summarization_cnn.min_length': 56, 'task_specific_params.summarization_cnn.num_beams': 4, 'task_specific_params.summarization_xsum.length_penalty': 1.0, 'task_specific_params.summarization_xsum.max_length': 62, 'task_specific_params.summarization_xsum.min_length': 11, 'task_specific_params.summarization_xsum.num_beams': 6, } self.assertEqual(flatten_dict(lowerCamelCase__ ) , lowerCamelCase__ ) def lowercase_ ( self ) -> Tuple: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) self.assertTrue(np.allclose(transpose(lowerCamelCase__ ) , x.transpose() ) ) __lowerCamelCase = np.random.randn(3 , 4 , 5 ) self.assertTrue(np.allclose(transpose(lowerCamelCase__ , axes=(1, 2, 0) ) , x.transpose((1, 2, 0) ) ) ) @require_torch def lowercase_ ( self ) -> int: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) __lowerCamelCase = torch.tensor(lowerCamelCase__ ) self.assertTrue(np.allclose(transpose(lowerCamelCase__ ) , transpose(lowerCamelCase__ ).numpy() ) ) __lowerCamelCase = np.random.randn(3 , 4 , 5 ) __lowerCamelCase = torch.tensor(lowerCamelCase__ ) self.assertTrue(np.allclose(transpose(lowerCamelCase__ , axes=(1, 2, 0) ) , transpose(lowerCamelCase__ , axes=(1, 2, 0) ).numpy() ) ) @require_tf def lowercase_ ( self ) -> Union[str, Any]: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) __lowerCamelCase = tf.constant(lowerCamelCase__ ) self.assertTrue(np.allclose(transpose(lowerCamelCase__ ) , transpose(lowerCamelCase__ ).numpy() ) ) __lowerCamelCase = np.random.randn(3 , 4 , 5 ) __lowerCamelCase = tf.constant(lowerCamelCase__ ) self.assertTrue(np.allclose(transpose(lowerCamelCase__ , axes=(1, 2, 0) ) , transpose(lowerCamelCase__ , axes=(1, 2, 0) ).numpy() ) ) @require_flax def lowercase_ ( self ) -> Optional[int]: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) __lowerCamelCase = jnp.array(lowerCamelCase__ ) self.assertTrue(np.allclose(transpose(lowerCamelCase__ ) , np.asarray(transpose(lowerCamelCase__ ) ) ) ) __lowerCamelCase = np.random.randn(3 , 4 , 5 ) __lowerCamelCase = jnp.array(lowerCamelCase__ ) self.assertTrue(np.allclose(transpose(lowerCamelCase__ , axes=(1, 2, 0) ) , np.asarray(transpose(lowerCamelCase__ , axes=(1, 2, 0) ) ) ) ) def lowercase_ ( self ) -> int: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) self.assertTrue(np.allclose(reshape(lowerCamelCase__ , (4, 3) ) , np.reshape(lowerCamelCase__ , (4, 3) ) ) ) __lowerCamelCase = np.random.randn(3 , 4 , 5 ) self.assertTrue(np.allclose(reshape(lowerCamelCase__ , (12, 5) ) , np.reshape(lowerCamelCase__ , (12, 5) ) ) ) @require_torch def lowercase_ ( self ) -> List[Any]: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) __lowerCamelCase = torch.tensor(lowerCamelCase__ ) self.assertTrue(np.allclose(reshape(lowerCamelCase__ , (4, 3) ) , reshape(lowerCamelCase__ , (4, 3) ).numpy() ) ) __lowerCamelCase = np.random.randn(3 , 4 , 5 ) __lowerCamelCase = torch.tensor(lowerCamelCase__ ) self.assertTrue(np.allclose(reshape(lowerCamelCase__ , (12, 5) ) , reshape(lowerCamelCase__ , (12, 5) ).numpy() ) ) @require_tf def lowercase_ ( self ) -> Optional[int]: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) __lowerCamelCase = tf.constant(lowerCamelCase__ ) self.assertTrue(np.allclose(reshape(lowerCamelCase__ , (4, 3) ) , reshape(lowerCamelCase__ , (4, 3) ).numpy() ) ) __lowerCamelCase = np.random.randn(3 , 4 , 5 ) __lowerCamelCase = tf.constant(lowerCamelCase__ ) self.assertTrue(np.allclose(reshape(lowerCamelCase__ , (12, 5) ) , reshape(lowerCamelCase__ , (12, 5) ).numpy() ) ) @require_flax def lowercase_ ( self ) -> Tuple: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) __lowerCamelCase = jnp.array(lowerCamelCase__ ) self.assertTrue(np.allclose(reshape(lowerCamelCase__ , (4, 3) ) , np.asarray(reshape(lowerCamelCase__ , (4, 3) ) ) ) ) __lowerCamelCase = np.random.randn(3 , 4 , 5 ) __lowerCamelCase = jnp.array(lowerCamelCase__ ) self.assertTrue(np.allclose(reshape(lowerCamelCase__ , (12, 5) ) , np.asarray(reshape(lowerCamelCase__ , (12, 5) ) ) ) ) def lowercase_ ( self ) -> int: '''simple docstring''' __lowerCamelCase = np.random.randn(1 , 3 , 4 ) self.assertTrue(np.allclose(squeeze(lowerCamelCase__ ) , np.squeeze(lowerCamelCase__ ) ) ) __lowerCamelCase = np.random.randn(1 , 4 , 1 , 5 ) self.assertTrue(np.allclose(squeeze(lowerCamelCase__ , axis=2 ) , np.squeeze(lowerCamelCase__ , axis=2 ) ) ) @require_torch def lowercase_ ( self ) -> int: '''simple docstring''' __lowerCamelCase = np.random.randn(1 , 3 , 4 ) __lowerCamelCase = torch.tensor(lowerCamelCase__ ) self.assertTrue(np.allclose(squeeze(lowerCamelCase__ ) , squeeze(lowerCamelCase__ ).numpy() ) ) __lowerCamelCase = np.random.randn(1 , 4 , 1 , 5 ) __lowerCamelCase = torch.tensor(lowerCamelCase__ ) self.assertTrue(np.allclose(squeeze(lowerCamelCase__ , axis=2 ) , squeeze(lowerCamelCase__ , axis=2 ).numpy() ) ) @require_tf def lowercase_ ( self ) -> Union[str, Any]: '''simple docstring''' __lowerCamelCase = np.random.randn(1 , 3 , 4 ) __lowerCamelCase = tf.constant(lowerCamelCase__ ) self.assertTrue(np.allclose(squeeze(lowerCamelCase__ ) , squeeze(lowerCamelCase__ ).numpy() ) ) __lowerCamelCase = np.random.randn(1 , 4 , 1 , 5 ) __lowerCamelCase = tf.constant(lowerCamelCase__ ) self.assertTrue(np.allclose(squeeze(lowerCamelCase__ , axis=2 ) , squeeze(lowerCamelCase__ , axis=2 ).numpy() ) ) @require_flax def lowercase_ ( self ) -> List[str]: '''simple docstring''' __lowerCamelCase = np.random.randn(1 , 3 , 4 ) __lowerCamelCase = jnp.array(lowerCamelCase__ ) self.assertTrue(np.allclose(squeeze(lowerCamelCase__ ) , np.asarray(squeeze(lowerCamelCase__ ) ) ) ) __lowerCamelCase = np.random.randn(1 , 4 , 1 , 5 ) __lowerCamelCase = jnp.array(lowerCamelCase__ ) self.assertTrue(np.allclose(squeeze(lowerCamelCase__ , axis=2 ) , np.asarray(squeeze(lowerCamelCase__ , axis=2 ) ) ) ) def lowercase_ ( self ) -> int: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) self.assertTrue(np.allclose(expand_dims(lowerCamelCase__ , axis=1 ) , np.expand_dims(lowerCamelCase__ , axis=1 ) ) ) @require_torch def lowercase_ ( self ) -> Any: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) __lowerCamelCase = torch.tensor(lowerCamelCase__ ) self.assertTrue(np.allclose(expand_dims(lowerCamelCase__ , axis=1 ) , expand_dims(lowerCamelCase__ , axis=1 ).numpy() ) ) @require_tf def lowercase_ ( self ) -> Any: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) __lowerCamelCase = tf.constant(lowerCamelCase__ ) self.assertTrue(np.allclose(expand_dims(lowerCamelCase__ , axis=1 ) , expand_dims(lowerCamelCase__ , axis=1 ).numpy() ) ) @require_flax def lowercase_ ( self ) -> List[Any]: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) __lowerCamelCase = jnp.array(lowerCamelCase__ ) self.assertTrue(np.allclose(expand_dims(lowerCamelCase__ , axis=1 ) , np.asarray(expand_dims(lowerCamelCase__ , axis=1 ) ) ) )
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import io import json import fsspec import pytest from datasets import Dataset, DatasetDict, Features, NamedSplit, Value from datasets.io.json import JsonDatasetReader, JsonDatasetWriter from ..utils import assert_arrow_memory_doesnt_increase, assert_arrow_memory_increases def UpperCAmelCase_ ( __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE ): assert isinstance(UpperCamelCase__ , UpperCamelCase__ ) assert dataset.num_rows == 4 assert dataset.num_columns == 3 assert dataset.column_names == ["col_1", "col_2", "col_3"] for feature, expected_dtype in expected_features.items(): assert dataset.features[feature].dtype == expected_dtype @pytest.mark.parametrize('keep_in_memory' , [False, True] ) def UpperCAmelCase_ ( __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE ): lowercase = tmp_path / 'cache' lowercase = {'col_1': 'string', 'col_2': 'int64', 'col_3': 'float64'} with assert_arrow_memory_increases() if keep_in_memory else assert_arrow_memory_doesnt_increase(): lowercase = JsonDatasetReader(UpperCamelCase__ , cache_dir=UpperCamelCase__ , keep_in_memory=UpperCamelCase__ ).read() _check_json_dataset(UpperCamelCase__ , UpperCamelCase__ ) @pytest.mark.parametrize( 'features' , [ None, {'col_1': 'string', 'col_2': 'int64', 'col_3': 'float64'}, {'col_1': 'string', 'col_2': 'string', 'col_3': 'string'}, {'col_1': 'int32', 'col_2': 'int32', 'col_3': 'int32'}, {'col_1': 'float32', 'col_2': 'float32', 'col_3': 'float32'}, ] , ) def UpperCAmelCase_ ( __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE ): lowercase = tmp_path / 'cache' lowercase = {'col_1': 'string', 'col_2': 'int64', 'col_3': 'float64'} lowercase = features.copy() if features else default_expected_features lowercase = ( Features({feature: Value(UpperCamelCase__ ) for feature, dtype in features.items()} ) if features is not None else None ) lowercase = JsonDatasetReader(UpperCamelCase__ , features=UpperCamelCase__ , cache_dir=UpperCamelCase__ ).read() _check_json_dataset(UpperCamelCase__ , UpperCamelCase__ ) @pytest.mark.parametrize( 'features' , [ None, {'col_3': 'float64', 'col_1': 'string', 'col_2': 'int64'}, ] , ) def UpperCAmelCase_ ( __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE ): lowercase = tmp_path / 'cache' lowercase = {'col_3': 'float64', 'col_1': 'string', 'col_2': 'int64'} lowercase = features.copy() if features else default_expected_features lowercase = ( Features({feature: Value(UpperCamelCase__ ) for feature, dtype in features.items()} ) if features is not None else None ) lowercase = JsonDatasetReader(UpperCamelCase__ , features=UpperCamelCase__ , cache_dir=UpperCamelCase__ ).read() assert isinstance(UpperCamelCase__ , UpperCamelCase__ ) assert dataset.num_rows == 2 assert dataset.num_columns == 3 assert dataset.column_names == ["col_3", "col_1", "col_2"] for feature, expected_dtype in expected_features.items(): assert dataset.features[feature].dtype == expected_dtype def UpperCAmelCase_ ( __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE ): lowercase = {'col_2': 'int64', 'col_3': 'float64', 'col_1': 'string'} lowercase = features.copy() lowercase = ( Features({feature: Value(UpperCamelCase__ ) for feature, dtype in features.items()} ) if features is not None else None ) lowercase = tmp_path / 'cache' lowercase = JsonDatasetReader(UpperCamelCase__ , features=UpperCamelCase__ , cache_dir=UpperCamelCase__ ).read() assert isinstance(UpperCamelCase__ , UpperCamelCase__ ) assert dataset.num_rows == 2 assert dataset.num_columns == 3 assert dataset.column_names == ["col_2", "col_3", "col_1"] for feature, expected_dtype in expected_features.items(): assert dataset.features[feature].dtype == expected_dtype @pytest.mark.parametrize('split' , [None, NamedSplit('train' ), 'train', 'test'] ) def UpperCAmelCase_ ( __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE ): lowercase = tmp_path / 'cache' lowercase = {'col_1': 'string', 'col_2': 'int64', 'col_3': 'float64'} lowercase = JsonDatasetReader(UpperCamelCase__ , cache_dir=UpperCamelCase__ , split=UpperCamelCase__ ).read() _check_json_dataset(UpperCamelCase__ , UpperCamelCase__ ) assert dataset.split == split if split else "train" @pytest.mark.parametrize('path_type' , [str, list] ) def UpperCAmelCase_ ( __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE ): if issubclass(UpperCamelCase__ , UpperCamelCase__ ): lowercase = jsonl_path elif issubclass(UpperCamelCase__ , UpperCamelCase__ ): lowercase = [jsonl_path] lowercase = tmp_path / 'cache' lowercase = {'col_1': 'string', 'col_2': 'int64', 'col_3': 'float64'} lowercase = JsonDatasetReader(UpperCamelCase__ , cache_dir=UpperCamelCase__ ).read() _check_json_dataset(UpperCamelCase__ , UpperCamelCase__ ) def UpperCAmelCase_ ( __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE=("train",) ): assert isinstance(UpperCamelCase__ , UpperCamelCase__ ) for split in splits: lowercase = dataset_dict[split] assert dataset.num_rows == 4 assert dataset.num_columns == 3 assert dataset.column_names == ["col_1", "col_2", "col_3"] for feature, expected_dtype in expected_features.items(): assert dataset.features[feature].dtype == expected_dtype @pytest.mark.parametrize('keep_in_memory' , [False, True] ) def UpperCAmelCase_ ( __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE ): lowercase = tmp_path / 'cache' lowercase = {'col_1': 'string', 'col_2': 'int64', 'col_3': 'float64'} with assert_arrow_memory_increases() if keep_in_memory else assert_arrow_memory_doesnt_increase(): lowercase = JsonDatasetReader({'train': jsonl_path} , cache_dir=UpperCamelCase__ , keep_in_memory=UpperCamelCase__ ).read() _check_json_datasetdict(UpperCamelCase__ , UpperCamelCase__ ) @pytest.mark.parametrize( 'features' , [ None, {'col_1': 'string', 'col_2': 'int64', 'col_3': 'float64'}, {'col_1': 'string', 'col_2': 'string', 'col_3': 'string'}, {'col_1': 'int32', 'col_2': 'int32', 'col_3': 'int32'}, {'col_1': 'float32', 'col_2': 'float32', 'col_3': 'float32'}, ] , ) def UpperCAmelCase_ ( __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE ): lowercase = tmp_path / 'cache' lowercase = {'col_1': 'string', 'col_2': 'int64', 'col_3': 'float64'} lowercase = features.copy() if features else default_expected_features lowercase = ( Features({feature: Value(UpperCamelCase__ ) for feature, dtype in features.items()} ) if features is not None else None ) lowercase = JsonDatasetReader({'train': jsonl_path} , features=UpperCamelCase__ , cache_dir=UpperCamelCase__ ).read() _check_json_datasetdict(UpperCamelCase__ , UpperCamelCase__ ) @pytest.mark.parametrize('split' , [None, NamedSplit('train' ), 'train', 'test'] ) def UpperCAmelCase_ ( __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE ): if split: lowercase = {split: jsonl_path} else: lowercase = 'train' lowercase = {'train': jsonl_path, 'test': jsonl_path} lowercase = tmp_path / 'cache' lowercase = {'col_1': 'string', 'col_2': 'int64', 'col_3': 'float64'} lowercase = JsonDatasetReader(UpperCamelCase__ , cache_dir=UpperCamelCase__ ).read() _check_json_datasetdict(UpperCamelCase__ , UpperCamelCase__ , splits=list(path.keys() ) ) assert all(dataset[split].split == split for split in path.keys() ) def UpperCAmelCase_ ( __SCREAMING_SNAKE_CASE ): return json.load(UpperCamelCase__ ) def UpperCAmelCase_ ( __SCREAMING_SNAKE_CASE ): return [json.loads(UpperCamelCase__ ) for line in buffer] class A_ : '''simple docstring''' @pytest.mark.parametrize('lines, load_json_function' , [(True, load_json_lines), (False, load_json)] ) def SCREAMING_SNAKE_CASE__ ( self , snake_case , snake_case , snake_case ): with io.BytesIO() as buffer: JsonDatasetWriter(lowerCamelCase__ , lowerCamelCase__ , lines=lowerCamelCase__ ).write() buffer.seek(0 ) lowercase = load_json_function(lowerCamelCase__ ) assert isinstance(lowerCamelCase__ , lowerCamelCase__ ) assert isinstance(exported_content[0] , lowerCamelCase__ ) assert len(lowerCamelCase__ ) == 10 @pytest.mark.parametrize( 'orient, container, keys, len_at' , [ ('records', list, {'tokens', 'labels', 'answers', 'id'}, None), ('split', dict, {'columns', 'data'}, 'data'), ('index', dict, set('0123456789' ), None), ('columns', dict, {'tokens', 'labels', 'answers', 'id'}, 'tokens'), ('values', list, None, None), ('table', dict, {'schema', 'data'}, 'data'), ] , ) def SCREAMING_SNAKE_CASE__ ( self , snake_case , snake_case , snake_case , snake_case , snake_case ): with io.BytesIO() as buffer: JsonDatasetWriter(lowerCamelCase__ , lowerCamelCase__ , lines=lowerCamelCase__ , orient=lowerCamelCase__ ).write() buffer.seek(0 ) lowercase = load_json(lowerCamelCase__ ) assert isinstance(lowerCamelCase__ , lowerCamelCase__ ) if keys: if container is dict: assert exported_content.keys() == keys else: assert exported_content[0].keys() == keys else: assert not hasattr(lowerCamelCase__ , 'keys' ) and not hasattr(exported_content[0] , 'keys' ) if len_at: assert len(exported_content[len_at] ) == 10 else: assert len(lowerCamelCase__ ) == 10 @pytest.mark.parametrize('lines, load_json_function' , [(True, load_json_lines), (False, load_json)] ) def SCREAMING_SNAKE_CASE__ ( self , snake_case , snake_case , snake_case ): with io.BytesIO() as buffer: JsonDatasetWriter(lowerCamelCase__ , lowerCamelCase__ , lines=lowerCamelCase__ , num_proc=2 ).write() buffer.seek(0 ) lowercase = load_json_function(lowerCamelCase__ ) assert isinstance(lowerCamelCase__ , lowerCamelCase__ ) assert isinstance(exported_content[0] , lowerCamelCase__ ) assert len(lowerCamelCase__ ) == 10 @pytest.mark.parametrize( 'orient, container, keys, len_at' , [ ('records', list, {'tokens', 'labels', 'answers', 'id'}, None), ('split', dict, {'columns', 'data'}, 'data'), ('index', dict, set('0123456789' ), None), ('columns', dict, {'tokens', 'labels', 'answers', 'id'}, 'tokens'), ('values', list, None, None), ('table', dict, {'schema', 'data'}, 'data'), ] , ) def SCREAMING_SNAKE_CASE__ ( self , snake_case , snake_case , snake_case , snake_case , snake_case ): with io.BytesIO() as buffer: JsonDatasetWriter(lowerCamelCase__ , lowerCamelCase__ , lines=lowerCamelCase__ , orient=lowerCamelCase__ , num_proc=2 ).write() buffer.seek(0 ) lowercase = load_json(lowerCamelCase__ ) assert isinstance(lowerCamelCase__ , lowerCamelCase__ ) if keys: if container is dict: assert exported_content.keys() == keys else: assert exported_content[0].keys() == keys else: assert not hasattr(lowerCamelCase__ , 'keys' ) and not hasattr(exported_content[0] , 'keys' ) if len_at: assert len(exported_content[len_at] ) == 10 else: assert len(lowerCamelCase__ ) == 10 def SCREAMING_SNAKE_CASE__ ( self , snake_case ): with pytest.raises(lowerCamelCase__ ): with io.BytesIO() as buffer: JsonDatasetWriter(lowerCamelCase__ , lowerCamelCase__ , num_proc=0 ) @pytest.mark.parametrize('compression, extension' , [('gzip', 'gz'), ('bz2', 'bz2'), ('xz', 'xz')] ) def SCREAMING_SNAKE_CASE__ ( self , snake_case , snake_case , snake_case , snake_case , snake_case ): lowercase = tmp_path_factory.mktemp('data' ) / F'''test.json.{extension}''' lowercase = str(shared_datadir / F'''test_file.json.{extension}''' ) JsonDatasetWriter(lowerCamelCase__ , lowerCamelCase__ , compression=lowerCamelCase__ ).write() with fsspec.open(lowerCamelCase__ , 'rb' , compression='infer' ) as f: lowercase = f.read() with fsspec.open(lowerCamelCase__ , 'rb' , compression='infer' ) as f: lowercase = f.read() assert exported_content == original_content
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import copy import inspect import unittest import numpy as np from huggingface_hub import hf_hub_download from transformers import TimesformerConfig from transformers.models.auto import get_values 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, floats_tensor, ids_tensor from ...test_pipeline_mixin import PipelineTesterMixin if is_torch_available(): import torch from torch import nn from transformers import ( MODEL_FOR_VIDEO_CLASSIFICATION_MAPPING, TimesformerForVideoClassification, TimesformerModel, ) from transformers.models.timesformer.modeling_timesformer import TIMESFORMER_PRETRAINED_MODEL_ARCHIVE_LIST if is_vision_available(): from transformers import VideoMAEImageProcessor class __lowerCAmelCase : """simple docstring""" def __init__( self , lowerCamelCase__ , lowerCamelCase__=13 , lowerCamelCase__=10 , lowerCamelCase__=3 , lowerCamelCase__=2 , lowerCamelCase__=2 , lowerCamelCase__=True , lowerCamelCase__=True , lowerCamelCase__=32 , lowerCamelCase__=5 , lowerCamelCase__=4 , lowerCamelCase__=37 , lowerCamelCase__="gelu" , lowerCamelCase__=0.1 , lowerCamelCase__=0.1 , lowerCamelCase__=10 , lowerCamelCase__=0.02 , lowerCamelCase__="divided_space_time" , lowerCamelCase__=None , ) -> Any: '''simple docstring''' __lowerCamelCase = parent __lowerCamelCase = batch_size __lowerCamelCase = image_size __lowerCamelCase = num_channels __lowerCamelCase = patch_size __lowerCamelCase = num_frames __lowerCamelCase = is_training __lowerCamelCase = use_labels __lowerCamelCase = hidden_size __lowerCamelCase = num_hidden_layers __lowerCamelCase = num_attention_heads __lowerCamelCase = intermediate_size __lowerCamelCase = hidden_act __lowerCamelCase = hidden_dropout_prob __lowerCamelCase = attention_probs_dropout_prob __lowerCamelCase = attention_type __lowerCamelCase = initializer_range __lowerCamelCase = scope __lowerCamelCase = num_labels # in TimeSformer, the number of spatial tokens equals num_frames * num_patches per frame + 1 CLS token __lowerCamelCase = (image_size // patch_size) ** 2 __lowerCamelCase = (num_frames) * self.num_patches_per_frame + 1 def lowercase_ ( self ) -> Optional[int]: '''simple docstring''' __lowerCamelCase = floats_tensor( [self.batch_size, self.num_frames, self.num_channels, self.image_size, self.image_size] ) __lowerCamelCase = None if self.use_labels: __lowerCamelCase = ids_tensor([self.batch_size] , self.num_labels ) __lowerCamelCase = self.get_config() return config, pixel_values, labels def lowercase_ ( self ) -> Union[str, Any]: '''simple docstring''' __lowerCamelCase = TimesformerConfig( image_size=self.image_size , patch_size=self.patch_size , num_channels=self.num_channels , num_frames=self.num_frames , 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 , initializer_range=self.initializer_range , attention_type=self.attention_type , ) __lowerCamelCase = self.num_labels return config def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> Tuple: '''simple docstring''' __lowerCamelCase = TimesformerModel(config=lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model(lowerCamelCase__ ) self.parent.assertEqual(result.last_hidden_state.shape , (self.batch_size, self.seq_length, self.hidden_size) ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> Union[str, Any]: '''simple docstring''' __lowerCamelCase = TimesformerForVideoClassification(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model(lowerCamelCase__ ) # verify the logits shape __lowerCamelCase = torch.Size((self.batch_size, self.num_labels) ) self.parent.assertEqual(result.logits.shape , lowerCamelCase__ ) def lowercase_ ( self ) -> Tuple: '''simple docstring''' __lowerCamelCase = self.prepare_config_and_inputs() __lowerCamelCase , __lowerCamelCase , __lowerCamelCase = config_and_inputs __lowerCamelCase = {'pixel_values': pixel_values} return config, inputs_dict @require_torch class __lowerCAmelCase ( __magic_name__ , __magic_name__ , unittest.TestCase ): """simple docstring""" snake_case_ = (TimesformerModel, TimesformerForVideoClassification) if is_torch_available() else () snake_case_ = ( {'''feature-extraction''': TimesformerModel, '''video-classification''': TimesformerForVideoClassification} if is_torch_available() else {} ) snake_case_ = False snake_case_ = False snake_case_ = False snake_case_ = False def lowercase_ ( self ) -> List[str]: '''simple docstring''' __lowerCamelCase = TimesformerModelTester(self ) __lowerCamelCase = ConfigTester( self , config_class=lowerCamelCase__ , has_text_modality=lowerCamelCase__ , hidden_size=37 ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__=False ) -> int: '''simple docstring''' __lowerCamelCase = copy.deepcopy(lowerCamelCase__ ) if return_labels: if model_class in get_values(lowerCamelCase__ ): __lowerCamelCase = torch.zeros( self.model_tester.batch_size , dtype=torch.long , device=lowerCamelCase__ ) return inputs_dict def lowercase_ ( self ) -> Optional[int]: '''simple docstring''' self.config_tester.run_common_tests() @unittest.skip(reason='TimeSformer does not use inputs_embeds' ) def lowercase_ ( self ) -> List[str]: '''simple docstring''' pass def lowercase_ ( self ) -> Union[str, Any]: '''simple docstring''' __lowerCamelCase , __lowerCamelCase = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: __lowerCamelCase = model_class(lowerCamelCase__ ) self.assertIsInstance(model.get_input_embeddings() , (nn.Module) ) __lowerCamelCase = model.get_output_embeddings() self.assertTrue(x is None or isinstance(lowerCamelCase__ , nn.Linear ) ) def lowercase_ ( self ) -> List[str]: '''simple docstring''' __lowerCamelCase , __lowerCamelCase = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: __lowerCamelCase = model_class(lowerCamelCase__ ) __lowerCamelCase = inspect.signature(model.forward ) # signature.parameters is an OrderedDict => so arg_names order is deterministic __lowerCamelCase = [*signature.parameters.keys()] __lowerCamelCase = ['pixel_values'] self.assertListEqual(arg_names[:1] , lowerCamelCase__ ) def lowercase_ ( self ) -> Union[str, Any]: '''simple docstring''' __lowerCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_model(*lowerCamelCase__ ) def lowercase_ ( self ) -> str: '''simple docstring''' __lowerCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_for_video_classification(*lowerCamelCase__ ) @slow def lowercase_ ( self ) -> Dict: '''simple docstring''' for model_name in TIMESFORMER_PRETRAINED_MODEL_ARCHIVE_LIST[:1]: __lowerCamelCase = TimesformerModel.from_pretrained(lowerCamelCase__ ) self.assertIsNotNone(lowerCamelCase__ ) def lowercase_ ( self ) -> List[Any]: '''simple docstring''' if not self.has_attentions: pass else: __lowerCamelCase , __lowerCamelCase = self.model_tester.prepare_config_and_inputs_for_common() __lowerCamelCase = True for model_class in self.all_model_classes: __lowerCamelCase = self.model_tester.seq_length __lowerCamelCase = self.model_tester.num_frames __lowerCamelCase = True __lowerCamelCase = False __lowerCamelCase = True __lowerCamelCase = model_class(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() with torch.no_grad(): __lowerCamelCase = model(**self._prepare_for_class(lowerCamelCase__ , lowerCamelCase__ ) ) __lowerCamelCase = outputs.attentions self.assertEqual(len(lowerCamelCase__ ) , self.model_tester.num_hidden_layers ) # check that output_attentions also work using config del inputs_dict["output_attentions"] __lowerCamelCase = True __lowerCamelCase = model_class(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() with torch.no_grad(): __lowerCamelCase = model(**self._prepare_for_class(lowerCamelCase__ , lowerCamelCase__ ) ) __lowerCamelCase = outputs.attentions self.assertEqual(len(lowerCamelCase__ ) , self.model_tester.num_hidden_layers ) # attentions has shape (batch_size x num_frames) x num_heads x (num_patches per frame + 1) x (num_patches per frame + 1) self.assertListEqual( list(attentions[0].shape[-3:] ) , [self.model_tester.num_attention_heads, seq_len // num_frames + 1, seq_len // num_frames + 1] , ) __lowerCamelCase = len(lowerCamelCase__ ) # Check attention is always last and order is fine __lowerCamelCase = True __lowerCamelCase = True __lowerCamelCase = model_class(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() with torch.no_grad(): __lowerCamelCase = model(**self._prepare_for_class(lowerCamelCase__ , lowerCamelCase__ ) ) self.assertEqual(out_len + 1 , len(lowerCamelCase__ ) ) __lowerCamelCase = outputs.attentions self.assertEqual(len(lowerCamelCase__ ) , self.model_tester.num_hidden_layers ) # attentions has shape (batch_size x num_frames) x num_heads x (num_patches per frame + 1) x (num_patches per frame + 1) self.assertListEqual( list(self_attentions[0].shape[-3:] ) , [self.model_tester.num_attention_heads, seq_len // num_frames + 1, seq_len // num_frames + 1] , ) def lowercase_ ( self ) -> Tuple: '''simple docstring''' def check_hidden_states_output(lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ): __lowerCamelCase = model_class(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() with torch.no_grad(): __lowerCamelCase = model(**self._prepare_for_class(lowerCamelCase__ , lowerCamelCase__ ) ) __lowerCamelCase = outputs.hidden_states __lowerCamelCase = self.model_tester.num_hidden_layers + 1 self.assertEqual(len(lowerCamelCase__ ) , lowerCamelCase__ ) __lowerCamelCase = self.model_tester.seq_length self.assertListEqual( list(hidden_states[0].shape[-2:] ) , [seq_length, self.model_tester.hidden_size] , ) __lowerCamelCase , __lowerCamelCase = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: __lowerCamelCase = True check_hidden_states_output(lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) # check that output_hidden_states also work using config del inputs_dict["output_hidden_states"] __lowerCamelCase = True check_hidden_states_output(lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) def lowerCamelCase_ ( ) -> Any: """simple docstring""" __lowerCamelCase = hf_hub_download( repo_id='hf-internal-testing/spaghetti-video' , filename='eating_spaghetti.npy' , repo_type='dataset' ) __lowerCamelCase = np.load(UpperCamelCase__ ) return list(UpperCamelCase__ ) @require_torch @require_vision class __lowerCAmelCase ( unittest.TestCase ): """simple docstring""" @cached_property def lowercase_ ( self ) -> List[Any]: '''simple docstring''' # logits were tested with a different mean and std, so we use the same here return ( VideoMAEImageProcessor(image_mean=[0.5, 0.5, 0.5] , image_std=[0.5, 0.5, 0.5] ) if is_vision_available() else None ) @slow def lowercase_ ( self ) -> List[str]: '''simple docstring''' __lowerCamelCase = TimesformerForVideoClassification.from_pretrained('facebook/timesformer-base-finetuned-k400' ).to( lowerCamelCase__ ) __lowerCamelCase = self.default_image_processor __lowerCamelCase = prepare_video() __lowerCamelCase = image_processor(video[:8] , return_tensors='pt' ).to(lowerCamelCase__ ) # forward pass with torch.no_grad(): __lowerCamelCase = model(**lowerCamelCase__ ) # verify the logits __lowerCamelCase = torch.Size((1, 400) ) self.assertEqual(outputs.logits.shape , lowerCamelCase__ ) __lowerCamelCase = torch.tensor([-0.30_16, -0.77_13, -0.42_05] ).to(lowerCamelCase__ ) self.assertTrue(torch.allclose(outputs.logits[0, :3] , lowerCamelCase__ , atol=1e-4 ) )
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import PIL.Image import PIL.ImageOps from packaging import version from PIL import Image if version.parse(version.parse(PIL.__version__).base_version) >= version.parse("9.1.0"): _lowerCAmelCase : str = { "linear": PIL.Image.Resampling.BILINEAR, "bilinear": PIL.Image.Resampling.BILINEAR, "bicubic": PIL.Image.Resampling.BICUBIC, "lanczos": PIL.Image.Resampling.LANCZOS, "nearest": PIL.Image.Resampling.NEAREST, } else: _lowerCAmelCase : Dict = { "linear": PIL.Image.LINEAR, "bilinear": PIL.Image.BILINEAR, "bicubic": PIL.Image.BICUBIC, "lanczos": PIL.Image.LANCZOS, "nearest": PIL.Image.NEAREST, } def UpperCamelCase_( _snake_case : Union[str, Any] ): """simple docstring""" __a =(images / 2 + 0.5).clamp(0 , 1 ) __a =images.cpu().permute(0 , 2 , 3 , 1 ).float().numpy() __a =numpy_to_pil(UpperCamelCase__ ) return images def UpperCamelCase_( _snake_case : Tuple ): """simple docstring""" if images.ndim == 3: __a =images[None, ...] __a =(images * 255).round().astype('uint8' ) if images.shape[-1] == 1: # special case for grayscale (single channel) images __a =[Image.fromarray(image.squeeze() , mode='L' ) for image in images] else: __a =[Image.fromarray(UpperCamelCase__ ) for image in images] return pil_images
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import json from typing import TYPE_CHECKING, List, Optional, Tuple from tokenizers import pre_tokenizers from ...tokenization_utils_fast import PreTrainedTokenizerFast from ...utils import logging if TYPE_CHECKING: from transformers.pipelines.conversational import Conversation __A = logging.get_logger(__name__) __A = {"vocab_file": "vocab.json", "merges_file": "merges.txt", "tokenizer_file": "tokenizer.json"} __A = { "tokenizer_file": { "EleutherAI/gpt-neox-20b": "https://huggingface.co/EleutherAI/gpt-neox-20b/resolve/main/tokenizer.json", }, } __A = { "gpt-neox-20b": 20_48, } class __lowerCAmelCase ( __magic_name__ ): """simple docstring""" snake_case_ = VOCAB_FILES_NAMES snake_case_ = PRETRAINED_VOCAB_FILES_MAP snake_case_ = PRETRAINED_POSITIONAL_EMBEDDINGS_SIZES snake_case_ = ['''input_ids''', '''attention_mask'''] def __init__( self , lowerCamelCase__=None , lowerCamelCase__=None , lowerCamelCase__=None , lowerCamelCase__="<|endoftext|>" , lowerCamelCase__="<|endoftext|>" , lowerCamelCase__="<|endoftext|>" , lowerCamelCase__=False , **lowerCamelCase__ , ) -> int: '''simple docstring''' super().__init__( lowerCamelCase__ , lowerCamelCase__ , tokenizer_file=lowerCamelCase__ , unk_token=lowerCamelCase__ , bos_token=lowerCamelCase__ , eos_token=lowerCamelCase__ , add_prefix_space=lowerCamelCase__ , **lowerCamelCase__ , ) __lowerCamelCase = json.loads(self.backend_tokenizer.pre_tokenizer.__getstate__() ) if pre_tok_state.get('add_prefix_space' , lowerCamelCase__ ) != add_prefix_space: __lowerCamelCase = getattr(lowerCamelCase__ , pre_tok_state.pop('type' ) ) __lowerCamelCase = add_prefix_space __lowerCamelCase = pre_tok_class(**lowerCamelCase__ ) __lowerCamelCase = add_prefix_space def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ = None ) -> Tuple[str]: '''simple docstring''' __lowerCamelCase = self._tokenizer.model.save(lowerCamelCase__ , name=lowerCamelCase__ ) return tuple(lowerCamelCase__ ) def lowercase_ ( self , lowerCamelCase__ ) -> List[int]: '''simple docstring''' __lowerCamelCase = [] for is_user, text in conversation.iter_texts(): input_ids.extend(self.encode(lowerCamelCase__ , add_special_tokens=lowerCamelCase__ ) + [self.eos_token_id] ) if len(lowerCamelCase__ ) > self.model_max_length: __lowerCamelCase = input_ids[-self.model_max_length :] return input_ids
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"""simple docstring""" from typing import Any import numpy as np def _A ( lowercase ): """simple docstring""" return np.array_equal(UpperCamelCase__ , matrix.conjugate().T ) def _A ( lowercase , lowercase ): """simple docstring""" a =v.conjugate().T a =v_star.dot(UpperCamelCase__ ) assert isinstance(UpperCamelCase__ , np.ndarray ) return (v_star_dot.dot(UpperCamelCase__ )) / (v_star.dot(UpperCamelCase__ )) def _A ( ): """simple docstring""" a =np.array([[2, 2 + 1J, 4], [2 - 1J, 3, 1J], [4, -1J, 1]] ) a =np.array([[1], [2], [3]] ) assert is_hermitian(UpperCamelCase__ ), f'''{a} is not hermitian.''' print(rayleigh_quotient(UpperCamelCase__ , UpperCamelCase__ ) ) a =np.array([[1, 2, 4], [2, 3, -1], [4, -1, 1]] ) assert is_hermitian(UpperCamelCase__ ), f'''{a} is not hermitian.''' assert rayleigh_quotient(UpperCamelCase__ , UpperCamelCase__ ) == float(3 ) if __name__ == "__main__": import doctest doctest.testmod() tests()
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from ..utils import DummyObject, requires_backends class __lowerCAmelCase ( metaclass=__magic_name__ ): """simple docstring""" snake_case_ = ['''onnx'''] def __init__( self , *lowerCamelCase__ , **lowerCamelCase__ ) -> Optional[Any]: '''simple docstring''' requires_backends(self , ['onnx'] ) @classmethod def lowercase_ ( cls , *lowerCamelCase__ , **lowerCamelCase__ ) -> Dict: '''simple docstring''' requires_backends(cls , ['onnx'] ) @classmethod def lowercase_ ( cls , *lowerCamelCase__ , **lowerCamelCase__ ) -> List[str]: '''simple docstring''' requires_backends(cls , ['onnx'] )
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import argparse import json from typing import List from ltp import LTP from transformers.models.bert.tokenization_bert import BertTokenizer def lowercase ( SCREAMING_SNAKE_CASE__ : List[str] ) -> int: if ( (cp >= 0X4_E_0_0 and cp <= 0X9_F_F_F) or (cp >= 0X3_4_0_0 and cp <= 0X4_D_B_F) # or (cp >= 0X2_0_0_0_0 and cp <= 0X2_A_6_D_F) # or (cp >= 0X2_A_7_0_0 and cp <= 0X2_B_7_3_F) # or (cp >= 0X2_B_7_4_0 and cp <= 0X2_B_8_1_F) # or (cp >= 0X2_B_8_2_0 and cp <= 0X2_C_E_A_F) # or (cp >= 0XF_9_0_0 and cp <= 0XF_A_F_F) or (cp >= 0X2_F_8_0_0 and cp <= 0X2_F_A_1_F) # ): # return True return False def lowercase ( SCREAMING_SNAKE_CASE__ : str ) -> List[Any]: for char in word: _snake_case : Optional[Any] = ord(UpperCamelCase__ ) if not _is_chinese_char(UpperCamelCase__ ): return 0 return 1 def lowercase ( SCREAMING_SNAKE_CASE__ : List[str] ) -> Dict: _snake_case : int = set() for token in tokens: _snake_case : List[str] = len(UpperCamelCase__ ) > 1 and is_chinese(UpperCamelCase__ ) if chinese_word: word_set.add(UpperCamelCase__ ) _snake_case : Union[str, Any] = list(UpperCamelCase__ ) return word_list def lowercase ( SCREAMING_SNAKE_CASE__ : List[str] , SCREAMING_SNAKE_CASE__ : set() ) -> str: if not chinese_word_set: return bert_tokens _snake_case : List[str] = max([len(UpperCamelCase__ ) for w in chinese_word_set] ) _snake_case : Optional[int] = bert_tokens _snake_case , _snake_case : Optional[int] = 0, len(UpperCamelCase__ ) while start < end: _snake_case : Optional[Any] = True if is_chinese(bert_word[start] ): _snake_case : Dict = min(end - start , UpperCamelCase__ ) for i in range(UpperCamelCase__ , 1 , -1 ): _snake_case : Any = """""".join(bert_word[start : start + i] ) if whole_word in chinese_word_set: for j in range(start + 1 , start + i ): _snake_case : Dict = """##""" + bert_word[j] _snake_case : Union[str, Any] = start + i _snake_case : Tuple = False break if single_word: start += 1 return bert_word def lowercase ( SCREAMING_SNAKE_CASE__ : List[str] , SCREAMING_SNAKE_CASE__ : LTP , SCREAMING_SNAKE_CASE__ : BertTokenizer ) -> int: _snake_case : Tuple = [] for i in range(0 , len(UpperCamelCase__ ) , 100 ): _snake_case : Optional[int] = ltp_tokenizer.pipeline(lines[i : i + 100] , tasks=["""cws"""] ).cws _snake_case : List[str] = [get_chinese_word(UpperCamelCase__ ) for r in res] ltp_res.extend(UpperCamelCase__ ) assert len(UpperCamelCase__ ) == len(UpperCamelCase__ ) _snake_case : Union[str, Any] = [] for i in range(0 , len(UpperCamelCase__ ) , 100 ): _snake_case : Optional[int] = bert_tokenizer(lines[i : i + 100] , add_special_tokens=UpperCamelCase__ , truncation=UpperCamelCase__ , max_length=512 ) bert_res.extend(res["""input_ids"""] ) assert len(UpperCamelCase__ ) == len(UpperCamelCase__ ) _snake_case : Optional[int] = [] for input_ids, chinese_word in zip(UpperCamelCase__ , UpperCamelCase__ ): _snake_case : Tuple = [] for id in input_ids: _snake_case : List[str] = bert_tokenizer._convert_id_to_token(UpperCamelCase__ ) input_tokens.append(UpperCamelCase__ ) _snake_case : List[str] = add_sub_symbol(UpperCamelCase__ , UpperCamelCase__ ) _snake_case : List[str] = [] # We only save pos of chinese subwords start with ##, which mean is part of a whole word. for i, token in enumerate(UpperCamelCase__ ): if token[:2] == "##": _snake_case : List[Any] = token[2:] # save chinese tokens' pos if len(UpperCamelCase__ ) == 1 and _is_chinese_char(ord(UpperCamelCase__ ) ): ref_id.append(UpperCamelCase__ ) ref_ids.append(UpperCamelCase__ ) assert len(UpperCamelCase__ ) == len(UpperCamelCase__ ) return ref_ids def lowercase ( SCREAMING_SNAKE_CASE__ : List[Any] ) -> Optional[Any]: with open(args.file_name , """r""" , encoding="""utf-8""" ) as f: _snake_case : Optional[int] = f.readlines() _snake_case : Any = [line.strip() for line in data if len(UpperCamelCase__ ) > 0 and not line.isspace()] # avoid delimiter like '\u2029' _snake_case : int = LTP(args.ltp ) # faster in GPU device _snake_case : Any = BertTokenizer.from_pretrained(args.bert ) _snake_case : Dict = prepare_ref(UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ ) with open(args.save_path , """w""" , encoding="""utf-8""" ) as f: _snake_case : int = [json.dumps(UpperCamelCase__ ) + """\n""" for ref in ref_ids] f.writelines(UpperCamelCase__ ) if __name__ == "__main__": a__ = argparse.ArgumentParser(description="""prepare_chinese_ref""") parser.add_argument( """--file_name""", required=False, type=str, default="""./resources/chinese-demo.txt""", help="""file need process, same as training data in lm""", ) parser.add_argument( """--ltp""", required=False, type=str, default="""./resources/ltp""", help="""resources for LTP tokenizer, usually a path""", ) parser.add_argument( """--bert""", required=False, type=str, default="""./resources/robert""", help="""resources for Bert tokenizer""", ) parser.add_argument( """--save_path""", required=False, type=str, default="""./resources/ref.txt""", help="""path to save res""", ) a__ = parser.parse_args() main(args)
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import itertools import os import random import tempfile import unittest import numpy as np from datasets import load_dataset from transformers import is_speech_available from transformers.testing_utils import check_json_file_has_correct_format, require_torch, require_torchaudio from transformers.utils.import_utils import is_torch_available from ...test_sequence_feature_extraction_common import SequenceFeatureExtractionTestMixin if is_speech_available(): from transformers import WhisperFeatureExtractor if is_torch_available(): import torch __A = random.Random() def lowerCamelCase_ ( UpperCamelCase__ : Optional[int] , UpperCamelCase__ : List[str]=1.0 , UpperCamelCase__ : Union[str, Any]=None , UpperCamelCase__ : Optional[int]=None ) -> Optional[Any]: """simple docstring""" if rng is None: __lowerCamelCase = global_rng __lowerCamelCase = [] for batch_idx in range(shape[0] ): values.append([] ) for _ in range(shape[1] ): values[-1].append(rng.random() * scale ) return values @require_torch @require_torchaudio class __lowerCAmelCase ( unittest.TestCase ): """simple docstring""" def __init__( self , lowerCamelCase__ , lowerCamelCase__=7 , lowerCamelCase__=400 , lowerCamelCase__=2_000 , lowerCamelCase__=10 , lowerCamelCase__=160 , lowerCamelCase__=8 , lowerCamelCase__=0.0 , lowerCamelCase__=4_000 , lowerCamelCase__=False , lowerCamelCase__=True , ) -> List[str]: '''simple docstring''' __lowerCamelCase = parent __lowerCamelCase = batch_size __lowerCamelCase = min_seq_length __lowerCamelCase = max_seq_length __lowerCamelCase = (self.max_seq_length - self.min_seq_length) // (self.batch_size - 1) __lowerCamelCase = padding_value __lowerCamelCase = sampling_rate __lowerCamelCase = return_attention_mask __lowerCamelCase = do_normalize __lowerCamelCase = feature_size __lowerCamelCase = chunk_length __lowerCamelCase = hop_length def lowercase_ ( self ) -> Any: '''simple docstring''' return { "feature_size": self.feature_size, "hop_length": self.hop_length, "chunk_length": self.chunk_length, "padding_value": self.padding_value, "sampling_rate": self.sampling_rate, "return_attention_mask": self.return_attention_mask, "do_normalize": self.do_normalize, } def lowercase_ ( self , lowerCamelCase__=False , lowerCamelCase__=False ) -> Optional[int]: '''simple docstring''' def _flatten(lowerCamelCase__ ): return list(itertools.chain(*lowerCamelCase__ ) ) if equal_length: __lowerCamelCase = [floats_list((self.max_seq_length, self.feature_size) ) for _ in range(self.batch_size )] else: # make sure that inputs increase in size __lowerCamelCase = [ floats_list((x, self.feature_size) ) for x in range(self.min_seq_length , self.max_seq_length , self.seq_length_diff ) ] if numpify: __lowerCamelCase = [np.asarray(lowerCamelCase__ ) for x in speech_inputs] return speech_inputs @require_torch @require_torchaudio class __lowerCAmelCase ( __magic_name__ , unittest.TestCase ): """simple docstring""" snake_case_ = WhisperFeatureExtractor if is_speech_available() else None def lowercase_ ( self ) -> Any: '''simple docstring''' __lowerCamelCase = WhisperFeatureExtractionTester(self ) def lowercase_ ( self ) -> List[str]: '''simple docstring''' __lowerCamelCase = self.feature_extraction_class(**self.feat_extract_dict ) with tempfile.TemporaryDirectory() as tmpdirname: __lowerCamelCase = feat_extract_first.save_pretrained(lowerCamelCase__ )[0] check_json_file_has_correct_format(lowerCamelCase__ ) __lowerCamelCase = self.feature_extraction_class.from_pretrained(lowerCamelCase__ ) __lowerCamelCase = feat_extract_first.to_dict() __lowerCamelCase = feat_extract_second.to_dict() __lowerCamelCase = feat_extract_first.mel_filters __lowerCamelCase = feat_extract_second.mel_filters self.assertTrue(np.allclose(lowerCamelCase__ , lowerCamelCase__ ) ) self.assertEqual(lowerCamelCase__ , lowerCamelCase__ ) def lowercase_ ( self ) -> Dict: '''simple docstring''' __lowerCamelCase = self.feature_extraction_class(**self.feat_extract_dict ) with tempfile.TemporaryDirectory() as tmpdirname: __lowerCamelCase = os.path.join(lowerCamelCase__ , 'feat_extract.json' ) feat_extract_first.to_json_file(lowerCamelCase__ ) __lowerCamelCase = self.feature_extraction_class.from_json_file(lowerCamelCase__ ) __lowerCamelCase = feat_extract_first.to_dict() __lowerCamelCase = feat_extract_second.to_dict() __lowerCamelCase = feat_extract_first.mel_filters __lowerCamelCase = feat_extract_second.mel_filters self.assertTrue(np.allclose(lowerCamelCase__ , lowerCamelCase__ ) ) self.assertEqual(lowerCamelCase__ , lowerCamelCase__ ) def lowercase_ ( self ) -> Dict: '''simple docstring''' # Tests that all call wrap to encode_plus and batch_encode_plus __lowerCamelCase = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) # create three inputs of length 800, 1000, and 1200 __lowerCamelCase = [floats_list((1, x) )[0] for x in range(800 , 1_400 , 200 )] __lowerCamelCase = [np.asarray(lowerCamelCase__ ) for speech_input in speech_inputs] # Test feature size __lowerCamelCase = feature_extractor(lowerCamelCase__ , padding='max_length' , return_tensors='np' ).input_features self.assertTrue(input_features.ndim == 3 ) self.assertTrue(input_features.shape[-1] == feature_extractor.nb_max_frames ) self.assertTrue(input_features.shape[-2] == feature_extractor.feature_size ) # Test not batched input __lowerCamelCase = feature_extractor(speech_inputs[0] , return_tensors='np' ).input_features __lowerCamelCase = feature_extractor(np_speech_inputs[0] , return_tensors='np' ).input_features self.assertTrue(np.allclose(lowerCamelCase__ , lowerCamelCase__ , atol=1e-3 ) ) # Test batched __lowerCamelCase = feature_extractor(lowerCamelCase__ , return_tensors='np' ).input_features __lowerCamelCase = feature_extractor(lowerCamelCase__ , return_tensors='np' ).input_features for enc_seq_a, enc_seq_a in zip(lowerCamelCase__ , lowerCamelCase__ ): self.assertTrue(np.allclose(lowerCamelCase__ , lowerCamelCase__ , atol=1e-3 ) ) # Test 2-D numpy arrays are batched. __lowerCamelCase = [floats_list((1, x) )[0] for x in (800, 800, 800)] __lowerCamelCase = np.asarray(lowerCamelCase__ ) __lowerCamelCase = feature_extractor(lowerCamelCase__ , return_tensors='np' ).input_features __lowerCamelCase = feature_extractor(lowerCamelCase__ , return_tensors='np' ).input_features for enc_seq_a, enc_seq_a in zip(lowerCamelCase__ , lowerCamelCase__ ): self.assertTrue(np.allclose(lowerCamelCase__ , lowerCamelCase__ , atol=1e-3 ) ) # Test truncation required __lowerCamelCase = [floats_list((1, x) )[0] for x in range(200 , (feature_extractor.n_samples + 500) , 200 )] __lowerCamelCase = [np.asarray(lowerCamelCase__ ) for speech_input in speech_inputs] __lowerCamelCase = [x[: feature_extractor.n_samples] for x in speech_inputs] __lowerCamelCase = [np.asarray(lowerCamelCase__ ) for speech_input in speech_inputs_truncated] __lowerCamelCase = feature_extractor(lowerCamelCase__ , return_tensors='np' ).input_features __lowerCamelCase = feature_extractor(lowerCamelCase__ , return_tensors='np' ).input_features for enc_seq_a, enc_seq_a in zip(lowerCamelCase__ , lowerCamelCase__ ): self.assertTrue(np.allclose(lowerCamelCase__ , lowerCamelCase__ , atol=1e-3 ) ) def lowercase_ ( self ) -> List[str]: '''simple docstring''' import torch __lowerCamelCase = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) __lowerCamelCase = np.random.rand(100 , 32 ).astype(np.floataa ) __lowerCamelCase = np_speech_inputs.tolist() for inputs in [py_speech_inputs, np_speech_inputs]: __lowerCamelCase = feature_extractor.pad([{'input_features': inputs}] , return_tensors='np' ) self.assertTrue(np_processed.input_features.dtype == np.floataa ) __lowerCamelCase = feature_extractor.pad([{'input_features': inputs}] , return_tensors='pt' ) self.assertTrue(pt_processed.input_features.dtype == torch.floataa ) def lowercase_ ( self , lowerCamelCase__ ) -> List[str]: '''simple docstring''' __lowerCamelCase = load_dataset('hf-internal-testing/librispeech_asr_dummy' , 'clean' , split='validation' ) # automatic decoding with librispeech __lowerCamelCase = ds.sort('id' ).select(range(lowerCamelCase__ ) )[:num_samples]['audio'] return [x["array"] for x in speech_samples] def lowercase_ ( self ) -> Tuple: '''simple docstring''' # fmt: off __lowerCamelCase = torch.tensor( [ 0.11_93, -0.09_46, -0.10_98, -0.01_96, 0.02_25, -0.06_90, -0.17_36, 0.09_51, 0.09_71, -0.08_17, -0.07_02, 0.01_62, 0.02_60, 0.00_17, -0.01_92, -0.16_78, 0.07_09, -0.18_67, -0.06_55, -0.02_74, -0.02_34, -0.18_84, -0.05_16, -0.05_54, -0.02_74, -0.14_25, -0.14_23, 0.08_37, 0.03_77, -0.08_54 ] ) # fmt: on __lowerCamelCase = self._load_datasamples(1 ) __lowerCamelCase = WhisperFeatureExtractor() __lowerCamelCase = feature_extractor(lowerCamelCase__ , return_tensors='pt' ).input_features self.assertEqual(input_features.shape , (1, 80, 3_000) ) self.assertTrue(torch.allclose(input_features[0, 0, :30] , lowerCamelCase__ , atol=1e-4 ) ) def lowercase_ ( self ) -> List[Any]: '''simple docstring''' __lowerCamelCase = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) __lowerCamelCase = self._load_datasamples(1 )[0] __lowerCamelCase = ((audio - audio.min()) / (audio.max() - audio.min())) * 65_535 # Rescale to [0, 65535] to show issue __lowerCamelCase = feat_extract.zero_mean_unit_var_norm([audio] , attention_mask=lowerCamelCase__ )[0] self.assertTrue(np.all(np.mean(lowerCamelCase__ ) < 1e-3 ) ) self.assertTrue(np.all(np.abs(np.var(lowerCamelCase__ ) - 1 ) < 1e-3 ) )
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"""simple docstring""" import unittest import numpy as np from transformers import is_flax_available from transformers.testing_utils import require_flax from ..test_modeling_flax_common import ids_tensor if is_flax_available(): import jax import jax.numpy as jnp from transformers.generation import ( FlaxForcedBOSTokenLogitsProcessor, FlaxForcedEOSTokenLogitsProcessor, FlaxLogitsProcessorList, FlaxMinLengthLogitsProcessor, FlaxTemperatureLogitsWarper, FlaxTopKLogitsWarper, FlaxTopPLogitsWarper, ) @require_flax class SCREAMING_SNAKE_CASE__ ( unittest.TestCase ): def _UpperCAmelCase ( self : Union[str, Any] , lowerCAmelCase_ : str , lowerCAmelCase_ : Dict): """simple docstring""" lowercase_ = jnp.ones((batch_size, length)) / length return scores def _UpperCAmelCase ( self : Union[str, Any]): """simple docstring""" lowercase_ = None lowercase_ = 2_0 lowercase_ = self._get_uniform_logits(batch_size=2 , length=lowerCamelCase__) # tweak scores to not be uniform anymore lowercase_ = scores.at[1, 5].set((1 / length) + 0.1) # peak, 1st batch lowercase_ = scores.at[1, 1_0].set((1 / length) - 0.4) # valley, 1st batch # compute softmax lowercase_ = jax.nn.softmax(lowerCamelCase__ , axis=-1) lowercase_ = FlaxTemperatureLogitsWarper(temperature=0.5) lowercase_ = FlaxTemperatureLogitsWarper(temperature=1.3) lowercase_ = jax.nn.softmax(temp_dist_warper_sharper(lowerCamelCase__ , scores.copy() , cur_len=lowerCamelCase__) , axis=-1) lowercase_ = jax.nn.softmax(temp_dist_warper_smoother(lowerCamelCase__ , scores.copy() , cur_len=lowerCamelCase__) , axis=-1) # uniform distribution stays uniform self.assertTrue(jnp.allclose(probs[0, :] , warped_prob_sharp[0, :] , atol=1E-3)) self.assertTrue(jnp.allclose(probs[0, :] , warped_prob_smooth[0, :] , atol=1E-3)) # sharp peaks get higher, valleys get lower self.assertLess(probs[1, :].max() , warped_prob_sharp[1, :].max()) self.assertGreater(probs[1, :].min() , warped_prob_sharp[1, :].min()) # smooth peaks get lower, valleys get higher self.assertGreater(probs[1, :].max() , warped_prob_smooth[1, :].max()) self.assertLess(probs[1, :].min() , warped_prob_smooth[1, :].min()) def _UpperCAmelCase ( self : Optional[int]): """simple docstring""" lowercase_ = None lowercase_ = 1_0 lowercase_ = 2 # create ramp distribution lowercase_ = np.broadcast_to(np.arange(lowerCamelCase__)[None, :] , (batch_size, vocab_size)).copy() lowercase_ = ramp_logits[1:, : vocab_size // 2] + vocab_size lowercase_ = FlaxTopKLogitsWarper(3) lowercase_ = top_k_warp(lowerCamelCase__ , lowerCamelCase__ , cur_len=lowerCamelCase__) # check that correct tokens are filtered self.assertListEqual(jnp.isinf(scores[0]).tolist() , 7 * [True] + 3 * [False]) self.assertListEqual(jnp.isinf(scores[1]).tolist() , 2 * [True] + 3 * [False] + 5 * [True]) # check special case lowercase_ = 5 lowercase_ = FlaxTopKLogitsWarper(top_k=1 , filter_value=0.0 , min_tokens_to_keep=3) lowercase_ = np.broadcast_to(np.arange(lowerCamelCase__)[None, :] , (batch_size, length)).copy() lowercase_ = top_k_warp_safety_check(lowerCamelCase__ , lowerCamelCase__ , cur_len=lowerCamelCase__) # min_tokens overwrites k: 3 tokens are kept => 2 tokens are nullified self.assertListEqual((scores == 0.0).sum(axis=-1).tolist() , [2, 2]) def _UpperCAmelCase ( self : str): """simple docstring""" lowercase_ = None lowercase_ = 1_0 lowercase_ = 2 # create distribution and take log (inverse to Softmax as taken in TopPLogitsWarper) lowercase_ = np.log(np.array([[0.3, 0.1, 0.1, 0.5], [0.15, 0.3, 0.3, 0.25]])) lowercase_ = FlaxTopPLogitsWarper(0.8) lowercase_ = np.exp(top_p_warp(lowerCamelCase__ , lowerCamelCase__ , cur_len=lowerCamelCase__)) # dist should be filtered to keep min num values so that sum is >= top_p # exp (-inf) => 0 lowercase_ = np.array([[0.3, 0.0, 0.0, 0.5], [0.0, 0.3, 0.3, 0.25]]) self.assertTrue(np.allclose(lowerCamelCase__ , lowerCamelCase__ , atol=1E-3)) # check edge cases with negative and extreme logits lowercase_ = np.broadcast_to(np.arange(lowerCamelCase__)[None, :] , (batch_size, vocab_size)).copy() - ( vocab_size // 2 ) # make ramp_logits more extreme lowercase_ = ramp_logits[1] * 1_0_0.0 # make sure at least 2 tokens are kept lowercase_ = FlaxTopPLogitsWarper(0.9 , min_tokens_to_keep=2 , filter_value=0.0) lowercase_ = top_p_warp(lowerCamelCase__ , lowerCamelCase__ , cur_len=lowerCamelCase__) # first batch should keep three tokens, second batch would keep only 1, but due to `min_tokens_to_keep=2` keeps 2. self.assertListEqual((filtered_dist != 0.0).sum(axis=-1).tolist() , [3, 2]) def _UpperCAmelCase ( self : Union[str, Any]): """simple docstring""" lowercase_ = 2_0 lowercase_ = 4 lowercase_ = 0 lowercase_ = FlaxMinLengthLogitsProcessor(min_length=1_0 , eos_token_id=lowerCamelCase__) # check that min length is applied at length 5 lowercase_ = ids_tensor((batch_size, 2_0) , vocab_size=2_0) lowercase_ = 5 lowercase_ = self._get_uniform_logits(lowerCamelCase__ , lowerCamelCase__) lowercase_ = min_dist_processor(lowerCamelCase__ , lowerCamelCase__ , cur_len=lowerCamelCase__) self.assertListEqual(scores_before_min_length[:, eos_token_id].tolist() , 4 * [-float("""inf""")]) # check that min length is not applied anymore at length 15 lowercase_ = self._get_uniform_logits(lowerCamelCase__ , lowerCamelCase__) lowercase_ = 1_5 lowercase_ = min_dist_processor(lowerCamelCase__ , lowerCamelCase__ , cur_len=lowerCamelCase__) self.assertFalse(jnp.isinf(lowerCamelCase__).any()) def _UpperCAmelCase ( self : str): """simple docstring""" lowercase_ = 2_0 lowercase_ = 4 lowercase_ = 0 lowercase_ = FlaxForcedBOSTokenLogitsProcessor(bos_token_id=lowerCamelCase__) # check that all scores are -inf except the bos_token_id score lowercase_ = ids_tensor((batch_size, 1) , vocab_size=2_0) lowercase_ = 1 lowercase_ = self._get_uniform_logits(lowerCamelCase__ , lowerCamelCase__) lowercase_ = logits_processor(lowerCamelCase__ , lowerCamelCase__ , cur_len=lowerCamelCase__) self.assertTrue(jnp.isneginf(scores[:, bos_token_id + 1 :]).all()) self.assertListEqual(scores[:, bos_token_id].tolist() , 4 * [0]) # score for bos_token_id shold be zero # check that bos_token_id is not forced if current length is greater than 1 lowercase_ = 3 lowercase_ = self._get_uniform_logits(lowerCamelCase__ , lowerCamelCase__) lowercase_ = logits_processor(lowerCamelCase__ , lowerCamelCase__ , cur_len=lowerCamelCase__) self.assertFalse(jnp.isinf(lowerCamelCase__).any()) def _UpperCAmelCase ( self : int): """simple docstring""" lowercase_ = 2_0 lowercase_ = 4 lowercase_ = 0 lowercase_ = 5 lowercase_ = FlaxForcedEOSTokenLogitsProcessor(max_length=lowerCamelCase__ , eos_token_id=lowerCamelCase__) # check that all scores are -inf except the eos_token_id when max_length is reached lowercase_ = ids_tensor((batch_size, 4) , vocab_size=2_0) lowercase_ = 4 lowercase_ = self._get_uniform_logits(lowerCamelCase__ , lowerCamelCase__) lowercase_ = logits_processor(lowerCamelCase__ , lowerCamelCase__ , cur_len=lowerCamelCase__) self.assertTrue(jnp.isneginf(scores[:, eos_token_id + 1 :]).all()) self.assertListEqual(scores[:, eos_token_id].tolist() , 4 * [0]) # score for eos_token_id should be zero # check that eos_token_id is not forced if max_length is not reached lowercase_ = 3 lowercase_ = self._get_uniform_logits(lowerCamelCase__ , lowerCamelCase__) lowercase_ = logits_processor(lowerCamelCase__ , lowerCamelCase__ , cur_len=lowerCamelCase__) self.assertFalse(jnp.isinf(lowerCamelCase__).any()) def _UpperCAmelCase ( self : Optional[int]): """simple docstring""" lowercase_ = 4 lowercase_ = 1_0 lowercase_ = 1_5 lowercase_ = 2 lowercase_ = 1 lowercase_ = 1_5 # dummy input_ids and scores lowercase_ = ids_tensor((batch_size, sequence_length) , lowerCamelCase__) lowercase_ = input_ids.copy() lowercase_ = self._get_uniform_logits(lowerCamelCase__ , lowerCamelCase__) lowercase_ = scores.copy() # instantiate all dist processors lowercase_ = FlaxTemperatureLogitsWarper(temperature=0.5) lowercase_ = FlaxTopKLogitsWarper(3) lowercase_ = FlaxTopPLogitsWarper(0.8) # instantiate all logits processors lowercase_ = FlaxMinLengthLogitsProcessor(min_length=1_0 , eos_token_id=lowerCamelCase__) lowercase_ = FlaxForcedBOSTokenLogitsProcessor(bos_token_id=lowerCamelCase__) lowercase_ = FlaxForcedEOSTokenLogitsProcessor(max_length=lowerCamelCase__ , eos_token_id=lowerCamelCase__) lowercase_ = 1_0 # no processor list lowercase_ = temp_dist_warp(lowerCamelCase__ , lowerCamelCase__ , cur_len=lowerCamelCase__) lowercase_ = top_k_warp(lowerCamelCase__ , lowerCamelCase__ , cur_len=lowerCamelCase__) lowercase_ = top_p_warp(lowerCamelCase__ , lowerCamelCase__ , cur_len=lowerCamelCase__) lowercase_ = min_dist_proc(lowerCamelCase__ , lowerCamelCase__ , cur_len=lowerCamelCase__) lowercase_ = bos_dist_proc(lowerCamelCase__ , lowerCamelCase__ , cur_len=lowerCamelCase__) lowercase_ = eos_dist_proc(lowerCamelCase__ , lowerCamelCase__ , cur_len=lowerCamelCase__) # with processor list lowercase_ = FlaxLogitsProcessorList( [temp_dist_warp, top_k_warp, top_p_warp, min_dist_proc, bos_dist_proc, eos_dist_proc]) lowercase_ = processor(lowerCamelCase__ , lowerCamelCase__ , cur_len=lowerCamelCase__) # scores should be equal self.assertTrue(jnp.allclose(lowerCamelCase__ , lowerCamelCase__ , atol=1E-3)) # input_ids should never be changed self.assertListEqual(input_ids.tolist() , input_ids_comp.tolist()) def _UpperCAmelCase ( self : Optional[Any]): """simple docstring""" lowercase_ = 4 lowercase_ = 1_0 lowercase_ = 1_5 lowercase_ = 2 lowercase_ = 1 lowercase_ = 1_5 # dummy input_ids and scores lowercase_ = ids_tensor((batch_size, sequence_length) , lowerCamelCase__) lowercase_ = input_ids.copy() lowercase_ = self._get_uniform_logits(lowerCamelCase__ , lowerCamelCase__) lowercase_ = scores.copy() # instantiate all dist processors lowercase_ = FlaxTemperatureLogitsWarper(temperature=0.5) lowercase_ = FlaxTopKLogitsWarper(3) lowercase_ = FlaxTopPLogitsWarper(0.8) # instantiate all logits processors lowercase_ = FlaxMinLengthLogitsProcessor(min_length=1_0 , eos_token_id=lowerCamelCase__) lowercase_ = FlaxForcedBOSTokenLogitsProcessor(bos_token_id=lowerCamelCase__) lowercase_ = FlaxForcedEOSTokenLogitsProcessor(max_length=lowerCamelCase__ , eos_token_id=lowerCamelCase__) lowercase_ = 1_0 # no processor list def run_no_processor_list(lowerCAmelCase_ : Optional[Any] , lowerCAmelCase_ : str , lowerCAmelCase_ : int): lowercase_ = temp_dist_warp(lowerCamelCase__ , lowerCamelCase__ , cur_len=lowerCamelCase__) lowercase_ = top_k_warp(lowerCamelCase__ , lowerCamelCase__ , cur_len=lowerCamelCase__) lowercase_ = top_p_warp(lowerCamelCase__ , lowerCamelCase__ , cur_len=lowerCamelCase__) lowercase_ = min_dist_proc(lowerCamelCase__ , lowerCamelCase__ , cur_len=lowerCamelCase__) lowercase_ = bos_dist_proc(lowerCamelCase__ , lowerCamelCase__ , cur_len=lowerCamelCase__) lowercase_ = eos_dist_proc(lowerCamelCase__ , lowerCamelCase__ , cur_len=lowerCamelCase__) return scores # with processor list def run_processor_list(lowerCAmelCase_ : Dict , lowerCAmelCase_ : List[str] , lowerCAmelCase_ : Optional[int]): lowercase_ = FlaxLogitsProcessorList( [temp_dist_warp, top_k_warp, top_p_warp, min_dist_proc, bos_dist_proc, eos_dist_proc]) lowercase_ = processor(lowerCamelCase__ , lowerCamelCase__ , cur_len=lowerCamelCase__) return scores lowercase_ = jax.jit(lowerCamelCase__) lowercase_ = jax.jit(lowerCamelCase__) lowercase_ = jitted_run_no_processor_list(lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__) lowercase_ = jitted_run_processor_list(lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__) # scores should be equal self.assertTrue(jnp.allclose(lowerCamelCase__ , lowerCamelCase__ , atol=1E-3)) # input_ids should never be changed self.assertListEqual(input_ids.tolist() , input_ids_comp.tolist())
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from dataclasses import dataclass from typing import Tuple import numpy as np import torch @dataclass class __lowerCAmelCase : """simple docstring""" snake_case_ = 42 # [batch_size x 3] snake_case_ = 42 # [batch_size x 3] snake_case_ = 42 # [batch_size x 3] snake_case_ = 42 # [batch_size x 3] snake_case_ = 42 snake_case_ = 42 snake_case_ = 42 snake_case_ = 42 snake_case_ = 42 def lowercase_ ( self ) -> Union[str, Any]: '''simple docstring''' assert self.x.shape[0] == self.y.shape[0] == self.z.shape[0] == self.origin.shape[0] assert self.x.shape[1] == self.y.shape[1] == self.z.shape[1] == self.origin.shape[1] == 3 assert len(self.x.shape ) == len(self.y.shape ) == len(self.z.shape ) == len(self.origin.shape ) == 2 def lowercase_ ( self ) -> Optional[int]: '''simple docstring''' return torch.from_numpy(np.array([self.width, self.height] , dtype=np.floataa ) ) def lowercase_ ( self ) -> Optional[Any]: '''simple docstring''' return torch.from_numpy(np.array([self.x_fov, self.y_fov] , dtype=np.floataa ) ) def lowercase_ ( self ) -> torch.Tensor: '''simple docstring''' __lowerCamelCase = torch.arange(self.height * self.width ) __lowerCamelCase = torch.stack( [ pixel_indices % self.width, torch.div(lowerCamelCase__ , self.width , rounding_mode='trunc' ), ] , axis=1 , ) return coords @property def lowercase_ ( self ) -> int: '''simple docstring''' __lowerCamelCase , *__lowerCamelCase = self.shape __lowerCamelCase = int(np.prod(lowerCamelCase__ ) ) __lowerCamelCase = self.get_image_coords() __lowerCamelCase = torch.broadcast_to(coords.unsqueeze(0 ) , [batch_size * inner_batch_size, *coords.shape] ) __lowerCamelCase = self.get_camera_rays(lowerCamelCase__ ) __lowerCamelCase = rays.view(lowerCamelCase__ , inner_batch_size * self.height * self.width , 2 , 3 ) return rays def lowercase_ ( self , lowerCamelCase__ ) -> torch.Tensor: '''simple docstring''' __lowerCamelCase , *__lowerCamelCase , __lowerCamelCase = coords.shape assert n_coords == 2 assert batch_size == self.origin.shape[0] __lowerCamelCase = coords.view(lowerCamelCase__ , -1 , 2 ) __lowerCamelCase = self.resolution() __lowerCamelCase = self.fov() __lowerCamelCase = (flat.float() / (res - 1)) * 2 - 1 __lowerCamelCase = fracs * torch.tan(fov / 2 ) __lowerCamelCase = fracs.view(lowerCamelCase__ , -1 , 2 ) __lowerCamelCase = ( self.z.view(lowerCamelCase__ , 1 , 3 ) + self.x.view(lowerCamelCase__ , 1 , 3 ) * fracs[:, :, :1] + self.y.view(lowerCamelCase__ , 1 , 3 ) * fracs[:, :, 1:] ) __lowerCamelCase = directions / directions.norm(dim=-1 , keepdim=lowerCamelCase__ ) __lowerCamelCase = torch.stack( [ torch.broadcast_to(self.origin.view(lowerCamelCase__ , 1 , 3 ) , [batch_size, directions.shape[1], 3] ), directions, ] , dim=2 , ) return rays.view(lowerCamelCase__ , *lowerCamelCase__ , 2 , 3 ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ ) -> "DifferentiableProjectiveCamera": '''simple docstring''' assert width * self.height == height * self.width, "The aspect ratio should not change." return DifferentiableProjectiveCamera( origin=self.origin , x=self.x , y=self.y , z=self.z , width=lowerCamelCase__ , height=lowerCamelCase__ , x_fov=self.x_fov , y_fov=self.y_fov , ) def lowerCamelCase_ ( UpperCamelCase__ : int ) -> DifferentiableProjectiveCamera: """simple docstring""" __lowerCamelCase = [] __lowerCamelCase = [] __lowerCamelCase = [] __lowerCamelCase = [] for theta in np.linspace(0 , 2 * np.pi , num=20 ): __lowerCamelCase = np.array([np.sin(UpperCamelCase__ ), np.cos(UpperCamelCase__ ), -0.5] ) z /= np.sqrt(np.sum(z**2 ) ) __lowerCamelCase = -z * 4 __lowerCamelCase = np.array([np.cos(UpperCamelCase__ ), -np.sin(UpperCamelCase__ ), 0.0] ) __lowerCamelCase = np.cross(UpperCamelCase__ , UpperCamelCase__ ) origins.append(UpperCamelCase__ ) xs.append(UpperCamelCase__ ) ys.append(UpperCamelCase__ ) zs.append(UpperCamelCase__ ) return DifferentiableProjectiveCamera( origin=torch.from_numpy(np.stack(UpperCamelCase__ , axis=0 ) ).float() , x=torch.from_numpy(np.stack(UpperCamelCase__ , axis=0 ) ).float() , y=torch.from_numpy(np.stack(UpperCamelCase__ , axis=0 ) ).float() , z=torch.from_numpy(np.stack(UpperCamelCase__ , axis=0 ) ).float() , width=UpperCamelCase__ , height=UpperCamelCase__ , x_fov=0.7 , y_fov=0.7 , shape=(1, len(UpperCamelCase__ )) , )
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0
'''simple docstring''' import os try: from .build_directory_md import good_file_paths except ImportError: from build_directory_md import good_file_paths # type: ignore lowercase_ = list(good_file_paths()) assert filepaths, "good_file_paths() failed!" lowercase_ = [file for file in filepaths if file != file.lower()] if upper_files: print(f"""{len(upper_files)} files contain uppercase characters:""") print("""\n""".join(upper_files) + """\n""") lowercase_ = [file for file in filepaths if """ """ in file] if space_files: print(f"""{len(space_files)} files contain space characters:""") print("""\n""".join(space_files) + """\n""") lowercase_ = [file for file in filepaths if """-""" in file] if hyphen_files: print(f"""{len(hyphen_files)} files contain hyphen characters:""") print("""\n""".join(hyphen_files) + """\n""") lowercase_ = [file for file in filepaths if os.sep not in file] if nodir_files: print(f"""{len(nodir_files)} files are not in a directory:""") print("""\n""".join(nodir_files) + """\n""") lowercase_ = len(upper_files + space_files + hyphen_files + nodir_files) if bad_files: import sys sys.exit(bad_files)
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import collections import inspect import unittest from transformers import FocalNetConfig 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_backbone_common import BackboneTesterMixin 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 ( FocalNetBackbone, FocalNetForImageClassification, FocalNetForMaskedImageModeling, FocalNetModel, ) from transformers.models.focalnet.modeling_focalnet import FOCALNET_PRETRAINED_MODEL_ARCHIVE_LIST if is_vision_available(): from PIL import Image from transformers import AutoImageProcessor class __lowerCAmelCase : """simple docstring""" def __init__( self , lowerCamelCase__ , lowerCamelCase__=13 , lowerCamelCase__=32 , lowerCamelCase__=2 , lowerCamelCase__=3 , lowerCamelCase__=16 , lowerCamelCase__=[32, 64, 128] , lowerCamelCase__=[1, 2, 1] , lowerCamelCase__=[2, 2, 4] , lowerCamelCase__=2 , lowerCamelCase__=2.0 , lowerCamelCase__=True , lowerCamelCase__=0.0 , lowerCamelCase__=0.0 , lowerCamelCase__=0.1 , lowerCamelCase__="gelu" , lowerCamelCase__=False , lowerCamelCase__=True , lowerCamelCase__=0.02 , lowerCamelCase__=1e-5 , lowerCamelCase__=True , lowerCamelCase__=None , lowerCamelCase__=True , lowerCamelCase__=10 , lowerCamelCase__=8 , lowerCamelCase__=["stage1", "stage2"] , lowerCamelCase__=[1, 2] , ) -> int: '''simple docstring''' __lowerCamelCase = parent __lowerCamelCase = batch_size __lowerCamelCase = image_size __lowerCamelCase = patch_size __lowerCamelCase = num_channels __lowerCamelCase = embed_dim __lowerCamelCase = hidden_sizes __lowerCamelCase = depths __lowerCamelCase = num_heads __lowerCamelCase = window_size __lowerCamelCase = mlp_ratio __lowerCamelCase = qkv_bias __lowerCamelCase = hidden_dropout_prob __lowerCamelCase = attention_probs_dropout_prob __lowerCamelCase = drop_path_rate __lowerCamelCase = hidden_act __lowerCamelCase = use_absolute_embeddings __lowerCamelCase = patch_norm __lowerCamelCase = layer_norm_eps __lowerCamelCase = initializer_range __lowerCamelCase = is_training __lowerCamelCase = scope __lowerCamelCase = use_labels __lowerCamelCase = type_sequence_label_size __lowerCamelCase = encoder_stride __lowerCamelCase = out_features __lowerCamelCase = out_indices def lowercase_ ( self ) -> List[Any]: '''simple docstring''' __lowerCamelCase = floats_tensor([self.batch_size, self.num_channels, self.image_size, self.image_size] ) __lowerCamelCase = None if self.use_labels: __lowerCamelCase = ids_tensor([self.batch_size] , self.type_sequence_label_size ) __lowerCamelCase = self.get_config() return config, pixel_values, labels def lowercase_ ( self ) -> List[str]: '''simple docstring''' return FocalNetConfig( image_size=self.image_size , patch_size=self.patch_size , num_channels=self.num_channels , embed_dim=self.embed_dim , hidden_sizes=self.hidden_sizes , 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 lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> int: '''simple docstring''' __lowerCamelCase = FocalNetModel(config=lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model(lowerCamelCase__ ) __lowerCamelCase = ((config.image_size // config.patch_size) ** 2) // (4 ** (len(config.depths ) - 1)) __lowerCamelCase = int(config.embed_dim * 2 ** (len(config.depths ) - 1) ) self.parent.assertEqual(result.last_hidden_state.shape , (self.batch_size, expected_seq_len, expected_dim) ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> List[Any]: '''simple docstring''' __lowerCamelCase = FocalNetBackbone(config=lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model(lowerCamelCase__ ) # verify feature maps self.parent.assertEqual(len(result.feature_maps ) , len(config.out_features ) ) self.parent.assertListEqual(list(result.feature_maps[0].shape ) , [self.batch_size, self.image_size, 8, 8] ) # verify channels self.parent.assertEqual(len(model.channels ) , len(config.out_features ) ) self.parent.assertListEqual(model.channels , config.hidden_sizes[:-1] ) # verify backbone works with out_features=None __lowerCamelCase = None __lowerCamelCase = FocalNetBackbone(config=lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model(lowerCamelCase__ ) # verify feature maps self.parent.assertEqual(len(result.feature_maps ) , 1 ) self.parent.assertListEqual(list(result.feature_maps[0].shape ) , [self.batch_size, self.image_size * 2, 4, 4] ) # verify channels self.parent.assertEqual(len(model.channels ) , 1 ) self.parent.assertListEqual(model.channels , [config.hidden_sizes[-1]] ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> int: '''simple docstring''' __lowerCamelCase = FocalNetForMaskedImageModeling(config=lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model(lowerCamelCase__ ) self.parent.assertEqual( result.reconstruction.shape , (self.batch_size, self.num_channels, self.image_size, self.image_size) ) # test greyscale images __lowerCamelCase = 1 __lowerCamelCase = FocalNetForMaskedImageModeling(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = floats_tensor([self.batch_size, 1, self.image_size, self.image_size] ) __lowerCamelCase = model(lowerCamelCase__ ) self.parent.assertEqual(result.reconstruction.shape , (self.batch_size, 1, self.image_size, self.image_size) ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> str: '''simple docstring''' __lowerCamelCase = self.type_sequence_label_size __lowerCamelCase = FocalNetForImageClassification(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model(lowerCamelCase__ , labels=lowerCamelCase__ ) self.parent.assertEqual(result.logits.shape , (self.batch_size, self.type_sequence_label_size) ) # test greyscale images __lowerCamelCase = 1 __lowerCamelCase = FocalNetForImageClassification(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = floats_tensor([self.batch_size, 1, self.image_size, self.image_size] ) __lowerCamelCase = model(lowerCamelCase__ ) self.parent.assertEqual(result.logits.shape , (self.batch_size, self.type_sequence_label_size) ) def lowercase_ ( self ) -> Tuple: '''simple docstring''' __lowerCamelCase = self.prepare_config_and_inputs() __lowerCamelCase , __lowerCamelCase , __lowerCamelCase = config_and_inputs __lowerCamelCase = {'pixel_values': pixel_values} return config, inputs_dict @require_torch class __lowerCAmelCase ( __magic_name__ , __magic_name__ , unittest.TestCase ): """simple docstring""" snake_case_ = ( ( FocalNetModel, FocalNetForImageClassification, FocalNetForMaskedImageModeling, FocalNetBackbone, ) if is_torch_available() else () ) snake_case_ = ( {'''feature-extraction''': FocalNetModel, '''image-classification''': FocalNetForImageClassification} if is_torch_available() else {} ) snake_case_ = False snake_case_ = False snake_case_ = False snake_case_ = False snake_case_ = False def lowercase_ ( self ) -> str: '''simple docstring''' __lowerCamelCase = FocalNetModelTester(self ) __lowerCamelCase = ConfigTester(self , config_class=lowerCamelCase__ , embed_dim=37 , has_text_modality=lowerCamelCase__ ) def lowercase_ ( self ) -> str: '''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 lowercase_ ( self ) -> str: '''simple docstring''' return def lowercase_ ( self ) -> List[Any]: '''simple docstring''' __lowerCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_model(*lowerCamelCase__ ) def lowercase_ ( self ) -> Optional[Any]: '''simple docstring''' __lowerCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_backbone(*lowerCamelCase__ ) def lowercase_ ( self ) -> str: '''simple docstring''' __lowerCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_for_masked_image_modeling(*lowerCamelCase__ ) def lowercase_ ( self ) -> Any: '''simple docstring''' __lowerCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_for_image_classification(*lowerCamelCase__ ) @unittest.skip(reason='FocalNet does not use inputs_embeds' ) def lowercase_ ( self ) -> Optional[int]: '''simple docstring''' pass @unittest.skip(reason='FocalNet does not use feedforward chunking' ) def lowercase_ ( self ) -> Union[str, Any]: '''simple docstring''' pass def lowercase_ ( self ) -> Dict: '''simple docstring''' __lowerCamelCase , __lowerCamelCase = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes[:-1]: __lowerCamelCase = model_class(lowerCamelCase__ ) self.assertIsInstance(model.get_input_embeddings() , (nn.Module) ) __lowerCamelCase = model.get_output_embeddings() self.assertTrue(x is None or isinstance(lowerCamelCase__ , nn.Linear ) ) def lowercase_ ( self ) -> str: '''simple docstring''' __lowerCamelCase , __lowerCamelCase = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes[:-1]: __lowerCamelCase = model_class(lowerCamelCase__ ) __lowerCamelCase = inspect.signature(model.forward ) # signature.parameters is an OrderedDict => so arg_names order is deterministic __lowerCamelCase = [*signature.parameters.keys()] __lowerCamelCase = ['pixel_values'] self.assertListEqual(arg_names[:1] , lowerCamelCase__ ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> int: '''simple docstring''' __lowerCamelCase = model_class(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() with torch.no_grad(): __lowerCamelCase = model(**self._prepare_for_class(lowerCamelCase__ , lowerCamelCase__ ) ) __lowerCamelCase = outputs.hidden_states __lowerCamelCase = getattr( self.model_tester , 'expected_num_hidden_layers' , len(self.model_tester.depths ) + 1 ) self.assertEqual(len(lowerCamelCase__ ) , lowerCamelCase__ ) # FocalNet has a different seq_length __lowerCamelCase = ( config.patch_size if isinstance(config.patch_size , collections.abc.Iterable ) else (config.patch_size, config.patch_size) ) __lowerCamelCase = (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] , ) __lowerCamelCase = outputs.reshaped_hidden_states self.assertEqual(len(lowerCamelCase__ ) , lowerCamelCase__ ) __lowerCamelCase , __lowerCamelCase , __lowerCamelCase , __lowerCamelCase = reshaped_hidden_states[0].shape __lowerCamelCase = ( reshaped_hidden_states[0].view(lowerCamelCase__ , lowerCamelCase__ , height * width ).permute(0 , 2 , 1 ) ) self.assertListEqual( list(reshaped_hidden_states.shape[-2:] ) , [num_patches, self.model_tester.embed_dim] , ) def lowercase_ ( self ) -> Dict: '''simple docstring''' __lowerCamelCase , __lowerCamelCase = self.model_tester.prepare_config_and_inputs_for_common() __lowerCamelCase = ( 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[:-1]: __lowerCamelCase = True self.check_hidden_states_output(lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) # check that output_hidden_states also work using config del inputs_dict["output_hidden_states"] __lowerCamelCase = True self.check_hidden_states_output(lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) def lowercase_ ( self ) -> Optional[Any]: '''simple docstring''' __lowerCamelCase , __lowerCamelCase = self.model_tester.prepare_config_and_inputs_for_common() __lowerCamelCase = 3 __lowerCamelCase = ( 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) ) __lowerCamelCase = ( config.patch_size if isinstance(config.patch_size , collections.abc.Iterable ) else (config.patch_size, config.patch_size) ) __lowerCamelCase = image_size[0] + patch_size[0] - (image_size[0] % patch_size[0]) __lowerCamelCase = image_size[1] + patch_size[1] - (image_size[1] % patch_size[1]) for model_class in self.all_model_classes[:-1]: __lowerCamelCase = True self.check_hidden_states_output(lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , (padded_height, padded_width) ) # check that output_hidden_states also work using config del inputs_dict["output_hidden_states"] __lowerCamelCase = True self.check_hidden_states_output(lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , (padded_height, padded_width) ) @slow def lowercase_ ( self ) -> str: '''simple docstring''' for model_name in FOCALNET_PRETRAINED_MODEL_ARCHIVE_LIST[:1]: __lowerCamelCase = FocalNetModel.from_pretrained(lowerCamelCase__ ) self.assertIsNotNone(lowerCamelCase__ ) def lowercase_ ( self ) -> Optional[int]: '''simple docstring''' __lowerCamelCase , __lowerCamelCase = self.model_tester.prepare_config_and_inputs_for_common() __lowerCamelCase = _config_zero_init(lowerCamelCase__ ) for model_class in self.all_model_classes: __lowerCamelCase = model_class(config=lowerCamelCase__ ) for name, param in model.named_parameters(): if "embeddings" 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 lowercase_ ( self ) -> List[str]: '''simple docstring''' # TODO update organization return AutoImageProcessor.from_pretrained('microsoft/focalnet-tiny' ) if is_vision_available() else None @slow def lowercase_ ( self ) -> List[Any]: '''simple docstring''' __lowerCamelCase = FocalNetForImageClassification.from_pretrained('microsoft/focalnet-tiny' ).to(lowerCamelCase__ ) __lowerCamelCase = self.default_image_processor __lowerCamelCase = Image.open('./tests/fixtures/tests_samples/COCO/000000039769.png' ) __lowerCamelCase = image_processor(images=lowerCamelCase__ , return_tensors='pt' ).to(lowerCamelCase__ ) # forward pass with torch.no_grad(): __lowerCamelCase = model(**lowerCamelCase__ ) # verify the logits __lowerCamelCase = torch.Size((1, 1_000) ) self.assertEqual(outputs.logits.shape , lowerCamelCase__ ) __lowerCamelCase = torch.tensor([0.21_66, -0.43_68, 0.21_91] ).to(lowerCamelCase__ ) self.assertTrue(torch.allclose(outputs.logits[0, :3] , lowerCamelCase__ , atol=1e-4 ) ) self.assertTrue(outputs.logits.argmax(dim=-1 ).item() , 281 ) @require_torch class __lowerCAmelCase ( __magic_name__ , unittest.TestCase ): """simple docstring""" snake_case_ = (FocalNetBackbone,) if is_torch_available() else () snake_case_ = FocalNetConfig snake_case_ = False def lowercase_ ( self ) -> Any: '''simple docstring''' __lowerCamelCase = FocalNetModelTester(self )
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def _a ( a :int = 10 , a :int = 1_000 , a :bool = True ) -> int: assert ( isinstance(UpperCamelCase__ , UpperCamelCase__ ) and isinstance(UpperCamelCase__ , UpperCamelCase__ ) and isinstance(UpperCamelCase__ , UpperCamelCase__ ) ), "Invalid type of value(s) specified to function!" if min_val > max_val: raise ValueError('''Invalid value for min_val or max_val (min_value < max_value)''' ) return min_val if option else max_val def _a ( a :int , a :int ) -> int: return int((number_a + number_a) / 2 ) def _a ( a :int , a :int , a :int ) -> None: assert ( isinstance(UpperCamelCase__ , UpperCamelCase__ ) and isinstance(UpperCamelCase__ , UpperCamelCase__ ) and isinstance(UpperCamelCase__ , UpperCamelCase__ ) ), 'argument values must be type of "int"' if lower > higher: raise ValueError('''argument value for lower and higher must be(lower > higher)''' ) if not lower < to_guess < higher: raise ValueError( '''guess value must be within the range of lower and higher value''' ) def answer(a :int ) -> str: if number > to_guess: return "high" elif number < to_guess: return "low" else: return "same" print('''started...''' ) a = lower a = higher a = [] while True: a = get_avg(UpperCamelCase__ , UpperCamelCase__ ) last_numbers.append(UpperCamelCase__ ) if answer(UpperCamelCase__ ) == "low": a = number elif answer(UpperCamelCase__ ) == "high": a = number else: break print(F"""guess the number : {last_numbers[-1]}""" ) print(F"""details : {last_numbers!s}""" ) def _a ( ) -> None: a = int(input('''Enter lower value : ''' ).strip() ) a = int(input('''Enter high value : ''' ).strip() ) a = int(input('''Enter value to guess : ''' ).strip() ) guess_the_number(UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ ) if __name__ == "__main__": main()
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from typing import TYPE_CHECKING from ...utils import OptionalDependencyNotAvailable, _LazyModule, is_speech_available, is_torch_available __A = { "configuration_audio_spectrogram_transformer": [ "AUDIO_SPECTROGRAM_TRANSFORMER_PRETRAINED_CONFIG_ARCHIVE_MAP", "ASTConfig", ] } try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __A = [ "AUDIO_SPECTROGRAM_TRANSFORMER_PRETRAINED_MODEL_ARCHIVE_LIST", "ASTForAudioClassification", "ASTModel", "ASTPreTrainedModel", ] try: if not is_speech_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __A = ["ASTFeatureExtractor"] if TYPE_CHECKING: from .configuration_audio_spectrogram_transformer import ( AUDIO_SPECTROGRAM_TRANSFORMER_PRETRAINED_CONFIG_ARCHIVE_MAP, ASTConfig, ) try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_audio_spectrogram_transformer import ( AUDIO_SPECTROGRAM_TRANSFORMER_PRETRAINED_MODEL_ARCHIVE_LIST, ASTForAudioClassification, ASTModel, ASTPreTrainedModel, ) try: if not is_speech_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .feature_extraction_audio_spectrogram_transformer import ASTFeatureExtractor else: import sys __A = _LazyModule(__name__, globals()["__file__"], _import_structure, module_spec=__spec__)
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lowercase__ : Optional[int] = { '''Pillow''': '''Pillow<10.0.0''', '''accelerate''': '''accelerate>=0.20.3''', '''av''': '''av==9.2.0''', '''beautifulsoup4''': '''beautifulsoup4''', '''black''': '''black~=23.1''', '''codecarbon''': '''codecarbon==1.2.0''', '''cookiecutter''': '''cookiecutter==1.7.3''', '''dataclasses''': '''dataclasses''', '''datasets''': '''datasets!=2.5.0''', '''decord''': '''decord==0.6.0''', '''deepspeed''': '''deepspeed>=0.9.3''', '''diffusers''': '''diffusers''', '''dill''': '''dill<0.3.5''', '''evaluate''': '''evaluate>=0.2.0''', '''fairscale''': '''fairscale>0.3''', '''faiss-cpu''': '''faiss-cpu''', '''fastapi''': '''fastapi''', '''filelock''': '''filelock''', '''flax''': '''flax>=0.4.1,<=0.7.0''', '''ftfy''': '''ftfy''', '''fugashi''': '''fugashi>=1.0''', '''GitPython''': '''GitPython<3.1.19''', '''hf-doc-builder''': '''hf-doc-builder>=0.3.0''', '''huggingface-hub''': '''huggingface-hub>=0.14.1,<1.0''', '''importlib_metadata''': '''importlib_metadata''', '''ipadic''': '''ipadic>=1.0.0,<2.0''', '''isort''': '''isort>=5.5.4''', '''jax''': '''jax>=0.2.8,!=0.3.2,<=0.4.13''', '''jaxlib''': '''jaxlib>=0.1.65,<=0.4.13''', '''jieba''': '''jieba''', '''kenlm''': '''kenlm''', '''keras-nlp''': '''keras-nlp>=0.3.1''', '''librosa''': '''librosa''', '''nltk''': '''nltk''', '''natten''': '''natten>=0.14.6''', '''numpy''': '''numpy>=1.17''', '''onnxconverter-common''': '''onnxconverter-common''', '''onnxruntime-tools''': '''onnxruntime-tools>=1.4.2''', '''onnxruntime''': '''onnxruntime>=1.4.0''', '''opencv-python''': '''opencv-python''', '''optuna''': '''optuna''', '''optax''': '''optax>=0.0.8,<=0.1.4''', '''packaging''': '''packaging>=20.0''', '''parameterized''': '''parameterized''', '''phonemizer''': '''phonemizer''', '''protobuf''': '''protobuf''', '''psutil''': '''psutil''', '''pyyaml''': '''pyyaml>=5.1''', '''pydantic''': '''pydantic<2''', '''pytest''': '''pytest>=7.2.0''', '''pytest-timeout''': '''pytest-timeout''', '''pytest-xdist''': '''pytest-xdist''', '''python''': '''python>=3.8.0''', '''ray[tune]''': '''ray[tune]''', '''regex''': '''regex!=2019.12.17''', '''requests''': '''requests''', '''rhoknp''': '''rhoknp>=1.1.0,<1.3.1''', '''rjieba''': '''rjieba''', '''rouge-score''': '''rouge-score!=0.0.7,!=0.0.8,!=0.1,!=0.1.1''', '''ruff''': '''ruff>=0.0.241,<=0.0.259''', '''sacrebleu''': '''sacrebleu>=1.4.12,<2.0.0''', '''sacremoses''': '''sacremoses''', '''safetensors''': '''safetensors>=0.3.1''', '''sagemaker''': '''sagemaker>=2.31.0''', '''scikit-learn''': '''scikit-learn''', '''sentencepiece''': '''sentencepiece>=0.1.91,!=0.1.92''', '''sigopt''': '''sigopt''', '''starlette''': '''starlette''', '''sudachipy''': '''sudachipy>=0.6.6''', '''sudachidict_core''': '''sudachidict_core>=20220729''', '''tensorflow-cpu''': '''tensorflow-cpu>=2.6,<2.14''', '''tensorflow''': '''tensorflow>=2.6,<2.14''', '''tensorflow-text''': '''tensorflow-text<2.14''', '''tf2onnx''': '''tf2onnx''', '''timeout-decorator''': '''timeout-decorator''', '''timm''': '''timm''', '''tokenizers''': '''tokenizers>=0.11.1,!=0.11.3,<0.14''', '''torch''': '''torch>=1.9,!=1.12.0''', '''torchaudio''': '''torchaudio''', '''torchvision''': '''torchvision''', '''pyctcdecode''': '''pyctcdecode>=0.4.0''', '''tqdm''': '''tqdm>=4.27''', '''unidic''': '''unidic>=1.0.2''', '''unidic_lite''': '''unidic_lite>=1.0.7''', '''urllib3''': '''urllib3<2.0.0''', '''uvicorn''': '''uvicorn''', }
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import argparse import os import pickle import sys import torch from transformers import TransfoXLConfig, TransfoXLLMHeadModel, load_tf_weights_in_transfo_xl from transformers.models.transfo_xl import tokenization_transfo_xl as data_utils from transformers.models.transfo_xl.tokenization_transfo_xl import CORPUS_NAME, VOCAB_FILES_NAMES from transformers.utils import CONFIG_NAME, WEIGHTS_NAME, logging logging.set_verbosity_info() # We do this to be able to load python 2 datasets pickles # See e.g. https://stackoverflow.com/questions/2121874/python-pickling-after-changing-a-modules-directory/2121918#2121918 __A = data_utils.TransfoXLTokenizer __A = data_utils.TransfoXLCorpus __A = data_utils __A = data_utils def lowerCamelCase_ ( UpperCamelCase__ : List[str] , UpperCamelCase__ : Optional[int] , UpperCamelCase__ : Union[str, Any] , UpperCamelCase__ : Optional[Any] ) -> Union[str, Any]: """simple docstring""" if transfo_xl_dataset_file: # Convert a pre-processed corpus (see original TensorFlow repo) with open(UpperCamelCase__ , 'rb' ) as fp: __lowerCamelCase = pickle.load(UpperCamelCase__ , encoding='latin1' ) # Save vocabulary and dataset cache as Dictionaries (should be better than pickles for the long-term) __lowerCamelCase = pytorch_dump_folder_path + '/' + VOCAB_FILES_NAMES['pretrained_vocab_file'] print(F"""Save vocabulary to {pytorch_vocab_dump_path}""" ) __lowerCamelCase = corpus.vocab.__dict__ torch.save(UpperCamelCase__ , UpperCamelCase__ ) __lowerCamelCase = corpus.__dict__ corpus_dict_no_vocab.pop('vocab' , UpperCamelCase__ ) __lowerCamelCase = pytorch_dump_folder_path + '/' + CORPUS_NAME print(F"""Save dataset to {pytorch_dataset_dump_path}""" ) torch.save(UpperCamelCase__ , UpperCamelCase__ ) if tf_checkpoint_path: # Convert a pre-trained TensorFlow model __lowerCamelCase = os.path.abspath(UpperCamelCase__ ) __lowerCamelCase = os.path.abspath(UpperCamelCase__ ) print(F"""Converting Transformer XL checkpoint from {tf_path} with config at {config_path}.""" ) # Initialise PyTorch model if transfo_xl_config_file == "": __lowerCamelCase = TransfoXLConfig() else: __lowerCamelCase = TransfoXLConfig.from_json_file(UpperCamelCase__ ) print(F"""Building PyTorch model from configuration: {config}""" ) __lowerCamelCase = TransfoXLLMHeadModel(UpperCamelCase__ ) __lowerCamelCase = load_tf_weights_in_transfo_xl(UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ ) # Save pytorch-model __lowerCamelCase = os.path.join(UpperCamelCase__ , UpperCamelCase__ ) __lowerCamelCase = os.path.join(UpperCamelCase__ , UpperCamelCase__ ) print(F"""Save PyTorch model to {os.path.abspath(UpperCamelCase__ )}""" ) torch.save(model.state_dict() , UpperCamelCase__ ) print(F"""Save configuration file to {os.path.abspath(UpperCamelCase__ )}""" ) with open(UpperCamelCase__ , 'w' , encoding='utf-8' ) as f: f.write(config.to_json_string() ) if __name__ == "__main__": __A = argparse.ArgumentParser() parser.add_argument( "--pytorch_dump_folder_path", default=None, type=str, required=True, help="Path to the folder to store the PyTorch model or dataset/vocab.", ) parser.add_argument( "--tf_checkpoint_path", default="", type=str, help="An optional path to a TensorFlow checkpoint path to be converted.", ) parser.add_argument( "--transfo_xl_config_file", default="", type=str, help=( "An optional config json file corresponding to the pre-trained BERT model. \n" "This specifies the model architecture." ), ) parser.add_argument( "--transfo_xl_dataset_file", default="", type=str, help="An optional dataset file to be converted in a vocabulary.", ) __A = parser.parse_args() convert_transfo_xl_checkpoint_to_pytorch( args.tf_checkpoint_path, args.transfo_xl_config_file, args.pytorch_dump_folder_path, args.transfo_xl_dataset_file, )
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"""simple docstring""" from collections import UserDict from typing import List, Union from ..utils import ( add_end_docstrings, is_tf_available, is_torch_available, is_vision_available, logging, requires_backends, ) from .base import PIPELINE_INIT_ARGS, Pipeline if is_vision_available(): from PIL import Image from ..image_utils import load_image if is_torch_available(): from ..models.auto.modeling_auto import MODEL_FOR_ZERO_SHOT_IMAGE_CLASSIFICATION_MAPPING if is_tf_available(): from ..models.auto.modeling_tf_auto import TF_MODEL_FOR_ZERO_SHOT_IMAGE_CLASSIFICATION_MAPPING from ..tf_utils import stable_softmax lowercase__ = logging.get_logger(__name__) @add_end_docstrings(__lowerCAmelCase ) class __snake_case ( __lowerCAmelCase ): def __init__( self , **lowercase) -> List[str]: '''simple docstring''' super().__init__(**lowerCamelCase__) requires_backends(self , 'vision') self.check_model_type( TF_MODEL_FOR_ZERO_SHOT_IMAGE_CLASSIFICATION_MAPPING if self.framework == 'tf' else MODEL_FOR_ZERO_SHOT_IMAGE_CLASSIFICATION_MAPPING) def __call__( self , lowercase , **lowercase) -> Dict: '''simple docstring''' return super().__call__(lowerCamelCase__ , **lowerCamelCase__) def lowerCamelCase_ ( self , **lowercase) -> List[str]: '''simple docstring''' a__: str = {} if "candidate_labels" in kwargs: a__: Optional[Any] = kwargs['candidate_labels'] if "hypothesis_template" in kwargs: a__: Tuple = kwargs['hypothesis_template'] return preprocess_params, {}, {} def lowerCamelCase_ ( self , lowercase , lowercase=None , lowercase="This is a photo of {}.") -> List[Any]: '''simple docstring''' a__: Optional[int] = load_image(lowerCamelCase__) a__: str = self.image_processor(images=[image] , return_tensors=self.framework) a__: List[str] = candidate_labels a__: Optional[Any] = [hypothesis_template.format(lowerCamelCase__) for x in candidate_labels] a__: Dict = self.tokenizer(lowerCamelCase__ , return_tensors=self.framework , padding=lowerCamelCase__) a__: Tuple = [text_inputs] return inputs def lowerCamelCase_ ( self , lowercase) -> List[Any]: '''simple docstring''' a__: List[str] = model_inputs.pop('candidate_labels') a__: Union[str, Any] = model_inputs.pop('text_inputs') if isinstance(text_inputs[0] , lowerCamelCase__): a__: List[str] = text_inputs[0] else: # Batching case. a__: int = text_inputs[0][0] a__: List[str] = self.model(**lowerCamelCase__ , **lowerCamelCase__) a__: Union[str, Any] = { 'candidate_labels': candidate_labels, 'logits': outputs.logits_per_image, } return model_outputs def lowerCamelCase_ ( self , lowercase) -> List[Any]: '''simple docstring''' a__: str = model_outputs.pop('candidate_labels') a__: List[Any] = model_outputs['logits'][0] if self.framework == "pt": a__: Dict = logits.softmax(dim=-1).squeeze(-1) a__: Optional[int] = probs.tolist() if not isinstance(lowerCamelCase__ , lowerCamelCase__): a__: List[Any] = [scores] elif self.framework == "tf": a__: Union[str, Any] = stable_softmax(lowerCamelCase__ , axis=-1) a__: Dict = probs.numpy().tolist() else: raise ValueError(f'Unsupported framework: {self.framework}') a__: str = [ {'score': score, 'label': candidate_label} for score, candidate_label in sorted(zip(lowerCamelCase__ , lowerCamelCase__) , key=lambda lowercase: -x[0]) ] return result
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import argparse import shutil from pathlib import Path from tqdm import tqdm from transformers import AutoTokenizer def lowerCamelCase_ ( UpperCamelCase__ : List[Any] , UpperCamelCase__ : Optional[int] , UpperCamelCase__ : str , UpperCamelCase__ : Any=1024 ) -> Dict: """simple docstring""" __lowerCamelCase , __lowerCamelCase = [], [] __lowerCamelCase = list(zip(UpperCamelCase__ , UpperCamelCase__ ) ) __lowerCamelCase , __lowerCamelCase = sorted_examples[0] def is_too_big(UpperCamelCase__ : List[str] ): return tok(UpperCamelCase__ , return_tensors='pt' ).input_ids.shape[1] > max_tokens for src, tgt in tqdm(sorted_examples[1:] ): __lowerCamelCase = new_src + ' ' + src __lowerCamelCase = new_tgt + ' ' + tgt if is_too_big(UpperCamelCase__ ) or is_too_big(UpperCamelCase__ ): # cant fit, finalize example finished_src.append(UpperCamelCase__ ) finished_tgt.append(UpperCamelCase__ ) __lowerCamelCase , __lowerCamelCase = src, tgt else: # can fit, keep adding __lowerCamelCase , __lowerCamelCase = cand_src, cand_tgt # cleanup if new_src: assert new_tgt finished_src.append(UpperCamelCase__ ) finished_tgt.append(UpperCamelCase__ ) return finished_src, finished_tgt def lowerCamelCase_ ( UpperCamelCase__ : str , UpperCamelCase__ : Path , UpperCamelCase__ : Optional[int] , UpperCamelCase__ : str ) -> Optional[int]: """simple docstring""" __lowerCamelCase = Path(UpperCamelCase__ ) save_path.mkdir(exist_ok=UpperCamelCase__ ) for split in ["train"]: __lowerCamelCase , __lowerCamelCase = data_dir / F"""{split}.source""", data_dir / F"""{split}.target""" __lowerCamelCase = [x.rstrip() for x in Path(UpperCamelCase__ ).open().readlines()] __lowerCamelCase = [x.rstrip() for x in Path(UpperCamelCase__ ).open().readlines()] __lowerCamelCase , __lowerCamelCase = pack_examples(UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ ) print(F"""packed {split} split from {len(UpperCamelCase__ )} examples -> {len(UpperCamelCase__ )}.""" ) Path(save_path / F"""{split}.source""" ).open('w' ).write('\n'.join(UpperCamelCase__ ) ) Path(save_path / F"""{split}.target""" ).open('w' ).write('\n'.join(UpperCamelCase__ ) ) for split in ["val", "test"]: __lowerCamelCase , __lowerCamelCase = data_dir / F"""{split}.source""", data_dir / F"""{split}.target""" shutil.copyfile(UpperCamelCase__ , save_path / F"""{split}.source""" ) shutil.copyfile(UpperCamelCase__ , save_path / F"""{split}.target""" ) def lowerCamelCase_ ( ) -> List[str]: """simple docstring""" __lowerCamelCase = argparse.ArgumentParser() parser.add_argument('--tok_name' , type=UpperCamelCase__ , help='like facebook/bart-large-cnn,t5-base, etc.' ) parser.add_argument('--max_seq_len' , type=UpperCamelCase__ , default=128 ) parser.add_argument('--data_dir' , type=UpperCamelCase__ ) parser.add_argument('--save_path' , type=UpperCamelCase__ ) __lowerCamelCase = parser.parse_args() __lowerCamelCase = AutoTokenizer.from_pretrained(args.tok_name ) return pack_data_dir(UpperCamelCase__ , Path(args.data_dir ) , args.max_seq_len , args.save_path ) if __name__ == "__main__": packer_cli()
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"""simple docstring""" import gzip import hashlib import json import multiprocessing import os import re import shutil import time from pathlib import Path import numpy as np from arguments import PreprocessingArguments from datasets import load_dataset from minhash_deduplication import deduplicate_dataset from transformers import AutoTokenizer, HfArgumentParser _lowercase : List[str] = re.compile(r'\s+') def lowercase__ ( snake_case_ :Optional[int] ): return {"hash": hashlib.mda(re.sub(UpperCamelCase__ , '''''' , example['''content'''] ).encode('''utf-8''' ) ).hexdigest()} def lowercase__ ( snake_case_ :List[Any] ): __UpperCAmelCase = [len(UpperCamelCase__ ) for line in example['''content'''].splitlines()] return {"line_mean": np.mean(UpperCamelCase__ ), "line_max": max(UpperCamelCase__ )} def lowercase__ ( snake_case_ :Optional[Any] ): __UpperCAmelCase = np.mean([c.isalnum() for c in example['''content''']] ) return {"alpha_frac": alpha_frac} def lowercase__ ( snake_case_ :List[str] , snake_case_ :Tuple ): if example["hash"] in uniques: uniques.remove(example['''hash'''] ) return True else: return False def lowercase__ ( snake_case_ :Tuple , snake_case_ :Dict=5 ): __UpperCAmelCase = ['''auto-generated''', '''autogenerated''', '''automatically generated'''] __UpperCAmelCase = example['''content'''].splitlines() for _, line in zip(range(UpperCamelCase__ ) , UpperCamelCase__ ): for keyword in keywords: if keyword in line.lower(): return {"autogenerated": True} else: return {"autogenerated": False} def lowercase__ ( snake_case_ :str , snake_case_ :Any=5 , snake_case_ :List[str]=0.05 ): __UpperCAmelCase = ['''unit tests''', '''test file''', '''configuration file'''] __UpperCAmelCase = example['''content'''].splitlines() __UpperCAmelCase = 0 __UpperCAmelCase = 0 # first test for _, line in zip(range(UpperCamelCase__ ) , UpperCamelCase__ ): for keyword in keywords: if keyword in line.lower(): return {"config_or_test": True} # second test __UpperCAmelCase = example['''content'''].count('''\n''' ) __UpperCAmelCase = int(coeff * nlines ) for line in lines: count_config += line.lower().count('''config''' ) count_test += line.lower().count('''test''' ) if count_config > threshold or count_test > threshold: return {"config_or_test": True} return {"config_or_test": False} def lowercase__ ( snake_case_ :List[str] ): __UpperCAmelCase = ['''def ''', '''class ''', '''for ''', '''while '''] __UpperCAmelCase = example['''content'''].splitlines() for line in lines: for keyword in keywords: if keyword in line.lower(): return {"has_no_keywords": False} return {"has_no_keywords": True} def lowercase__ ( snake_case_ :Optional[Any] , snake_case_ :List[Any]=4 ): __UpperCAmelCase = example['''content'''].splitlines() __UpperCAmelCase = 0 for line in lines: counter += line.lower().count('''=''' ) if counter > minimum: return {"has_few_assignments": False} return {"has_few_assignments": True} def lowercase__ ( snake_case_ :Optional[int] ): __UpperCAmelCase = tokenizer(example['''content'''] , truncation=UpperCamelCase__ )['''input_ids'''] __UpperCAmelCase = len(example['''content'''] ) / len(UpperCamelCase__ ) return {"ratio": ratio} def lowercase__ ( snake_case_ :Dict ): __UpperCAmelCase = {} results.update(get_hash(UpperCamelCase__ ) ) results.update(line_stats(UpperCamelCase__ ) ) results.update(alpha_stats(UpperCamelCase__ ) ) results.update(char_token_ratio(UpperCamelCase__ ) ) results.update(is_autogenerated(UpperCamelCase__ ) ) results.update(is_config_or_test(UpperCamelCase__ ) ) results.update(has_no_keywords(UpperCamelCase__ ) ) results.update(has_few_assignments(UpperCamelCase__ ) ) return results def lowercase__ ( snake_case_ :List[str] , snake_case_ :str , snake_case_ :Optional[Any] ): if not check_uniques(UpperCamelCase__ , UpperCamelCase__ ): return False elif example["autogenerated"]: return False elif example["line_max"] > args.line_max: return False elif example["line_mean"] > args.line_mean: return False elif example["alpha_frac"] < args.alpha_frac: return False elif example["ratio"] < args.min_token_ratio: return False elif example["config_or_test"] and np.random.rand() <= args.filter_proba: return False elif example["has_no_keywords"] and np.random.rand() <= args.filter_proba: return False elif example["has_few_assignments"]: return False else: return True def lowercase__ ( snake_case_ :int ): with open(UpperCamelCase__ , '''rb''' ) as f_in: with gzip.open(str(UpperCamelCase__ ) + '''.gz''' , '''wb''' , compresslevel=6 ) as f_out: shutil.copyfileobj(UpperCamelCase__ , UpperCamelCase__ ) os.unlink(UpperCamelCase__ ) # Settings _lowercase : List[Any] = HfArgumentParser(PreprocessingArguments) _lowercase : Any = parser.parse_args() if args.num_workers is None: _lowercase : Tuple = multiprocessing.cpu_count() _lowercase : Optional[int] = AutoTokenizer.from_pretrained(args.tokenizer_dir) # Load dataset _lowercase : Tuple = time.time() _lowercase : Union[str, Any] = load_dataset(args.dataset_name, split='train') print(f"""Time to load dataset: {time.time()-t_start:.2f}""") # Run preprocessing _lowercase : Optional[Any] = time.time() _lowercase : Dict = ds.map(preprocess, num_proc=args.num_workers) print(f"""Time to preprocess dataset: {time.time()-t_start:.2f}""") # Deduplicate hashes _lowercase : int = set(ds.unique('hash')) _lowercase : Optional[Any] = len(uniques) / len(ds) print(f"""Fraction of duplicates: {1-frac:.2%}""") # Deduplicate data and apply heuristics _lowercase : int = time.time() _lowercase : Tuple = ds.filter(filter, fn_kwargs={'uniques': uniques, 'args': args}) print(f"""Time to filter dataset: {time.time()-t_start:.2f}""") print(f"""Size of filtered dataset: {len(ds_filter)}""") # Deduplicate with minhash and jaccard similarity if args.near_deduplication: _lowercase : Tuple = time.time() _lowercase ,_lowercase : List[str] = deduplicate_dataset(ds_filter, args.jaccard_threshold) print(f"""Time to deduplicate dataset: {time.time()-t_start:.2f}""") print(f"""Size of deduplicate dataset: {len(ds_filter)}""") # Save data in batches of samples_per_file _lowercase : Tuple = Path(args.output_dir) output_dir.mkdir(exist_ok=True) # save duplicate_clusters in the output_dir as artifacts # not sure it is the right place the save it if args.near_deduplication: with open(output_dir / 'duplicate_clusters.json', 'w') as f: json.dump(duplicate_clusters, f) _lowercase : int = output_dir / 'data' data_dir.mkdir(exist_ok=True) _lowercase : Optional[int] = time.time() for file_number, index in enumerate(range(0, len(ds_filter), args.samples_per_file)): _lowercase : Dict = str(data_dir / f"""file-{file_number+1:012}.json""") _lowercase : Any = min(len(ds_filter), index + args.samples_per_file) ds_filter.select(list(range(index, end_index))).to_json(file_path) compress_file(file_path) print(f"""Time to save dataset: {time.time()-t_start:.2f}""")
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import argparse import fairseq import torch from torch import nn from transformers import ( MBartaaTokenizer, MBartConfig, MBartForCausalLM, SpeechEncoderDecoderConfig, SpeechEncoderDecoderModel, WavaVecaConfig, WavaVecaFeatureExtractor, WavaVecaModel, logging, ) logging.set_verbosity_info() __A = logging.get_logger(__name__) __A = { "post_extract_proj": "feature_projection.projection", "encoder.pos_conv.0": "encoder.pos_conv_embed.conv", "self_attn.k_proj": "encoder.layers.*.attention.k_proj", "self_attn.v_proj": "encoder.layers.*.attention.v_proj", "self_attn.q_proj": "encoder.layers.*.attention.q_proj", "self_attn.out_proj": "encoder.layers.*.attention.out_proj", "self_attn_layer_norm": "encoder.layers.*.layer_norm", "fc1": "encoder.layers.*.feed_forward.intermediate_dense", "fc2": "encoder.layers.*.feed_forward.output_dense", "final_layer_norm": "encoder.layers.*.final_layer_norm", "encoder.layer_norm": "encoder.layer_norm", "w2v_model.layer_norm": "feature_projection.layer_norm", "quantizer.weight_proj": "quantizer.weight_proj", "quantizer.vars": "quantizer.codevectors", "project_q": "project_q", "final_proj": "project_hid", "w2v_encoder.proj": "lm_head", "mask_emb": "masked_spec_embed", } __A = [ "lm_head", "quantizer.weight_proj", "quantizer.codevectors", "project_q", "project_hid", ] def lowerCamelCase_ ( UpperCamelCase__ : Any , UpperCamelCase__ : Any , UpperCamelCase__ : Optional[Any] , UpperCamelCase__ : Union[str, Any] , UpperCamelCase__ : Optional[int] ) -> Tuple: """simple docstring""" for attribute in key.split('.' ): __lowerCamelCase = getattr(UpperCamelCase__ , UpperCamelCase__ ) if weight_type is not None: __lowerCamelCase = getattr(UpperCamelCase__ , UpperCamelCase__ ).shape else: __lowerCamelCase = hf_pointer.shape assert hf_shape == value.shape, ( F"""Shape of hf {key + '.' + weight_type if weight_type is not None else ''} is {hf_shape}, but should be""" F""" {value.shape} for {full_name}""" ) if weight_type == "weight": __lowerCamelCase = value elif weight_type == "weight_g": __lowerCamelCase = value elif weight_type == "weight_v": __lowerCamelCase = value elif weight_type == "bias": __lowerCamelCase = value else: __lowerCamelCase = value logger.info(F"""{key + '.' + weight_type if weight_type is not None else ''} was initialized from {full_name}.""" ) def lowerCamelCase_ ( UpperCamelCase__ : Optional[Any] , UpperCamelCase__ : Tuple ) -> Optional[Any]: """simple docstring""" __lowerCamelCase = [] __lowerCamelCase = fairseq_model.state_dict() __lowerCamelCase = hf_model.feature_extractor __lowerCamelCase = hf_model.adapter for name, value in fairseq_dict.items(): __lowerCamelCase = False if "conv_layers" in name: load_conv_layer( UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ , hf_model.config.feat_extract_norm == 'group' , ) __lowerCamelCase = True elif any(x in name for x in ['adaptor', 'w2v_encoder.proj.', 'w2v_proj_ln.'] ): load_adapter(UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ ) __lowerCamelCase = True else: for key, mapped_key in MAPPING.items(): if key in name or key.split('w2v_model.' )[-1] == name.split('.' )[0]: __lowerCamelCase = True if "*" in mapped_key: __lowerCamelCase = name.split(UpperCamelCase__ )[0].split('.' )[-2] __lowerCamelCase = mapped_key.replace('*' , UpperCamelCase__ ) if "weight_g" in name: __lowerCamelCase = 'weight_g' elif "weight_v" in name: __lowerCamelCase = 'weight_v' elif "bias" in name: __lowerCamelCase = 'bias' elif "weight" in name: __lowerCamelCase = 'weight' else: __lowerCamelCase = None set_recursively(UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ ) continue if not is_used: unused_weights.append(UpperCamelCase__ ) logger.warning(F"""Unused weights: {unused_weights}""" ) def lowerCamelCase_ ( UpperCamelCase__ : Dict , UpperCamelCase__ : Any , UpperCamelCase__ : str , UpperCamelCase__ : Tuple , UpperCamelCase__ : Tuple ) -> int: """simple docstring""" __lowerCamelCase = full_name.split('conv_layers.' )[-1] __lowerCamelCase = name.split('.' ) __lowerCamelCase = int(items[0] ) __lowerCamelCase = int(items[1] ) if type_id == 0: if "bias" in name: assert value.shape == feature_extractor.conv_layers[layer_id].conv.bias.data.shape, ( F"""{full_name} has size {value.shape}, but""" F""" {feature_extractor.conv_layers[layer_id].conv.bias.data.shape} was found.""" ) __lowerCamelCase = value logger.info(F"""Feat extract conv layer {layer_id} was initialized from {full_name}.""" ) elif "weight" in name: assert value.shape == feature_extractor.conv_layers[layer_id].conv.weight.data.shape, ( F"""{full_name} has size {value.shape}, but""" F""" {feature_extractor.conv_layers[layer_id].conv.weight.data.shape} was found.""" ) __lowerCamelCase = value logger.info(F"""Feat extract conv layer {layer_id} was initialized from {full_name}.""" ) elif (type_id == 2 and not use_group_norm) or (type_id == 2 and layer_id == 0 and use_group_norm): if "bias" in name: assert value.shape == feature_extractor.conv_layers[layer_id].layer_norm.bias.data.shape, ( F"""{full_name} has size {value.shape}, but {feature_extractor[layer_id].layer_norm.bias.data.shape} was""" " found." ) __lowerCamelCase = value logger.info(F"""Feat extract layer norm weight of layer {layer_id} was initialized from {full_name}.""" ) elif "weight" in name: assert value.shape == feature_extractor.conv_layers[layer_id].layer_norm.weight.data.shape, ( F"""{full_name} has size {value.shape}, but""" F""" {feature_extractor[layer_id].layer_norm.weight.data.shape} was found.""" ) __lowerCamelCase = value logger.info(F"""Feat extract layer norm weight of layer {layer_id} was initialized from {full_name}.""" ) else: unused_weights.append(UpperCamelCase__ ) def lowerCamelCase_ ( UpperCamelCase__ : Tuple , UpperCamelCase__ : Optional[Any] , UpperCamelCase__ : Any , UpperCamelCase__ : int ) -> Union[str, Any]: """simple docstring""" __lowerCamelCase = full_name.split('adaptor.' )[-1] __lowerCamelCase = name.split('.' ) if items[1].isdigit(): __lowerCamelCase = int(items[1] ) else: __lowerCamelCase = None if "adaptor" not in full_name: if "proj_ln" in full_name: # has to be layer norm if "bias" in name: assert ( value.shape == adapter.proj_layer_norm.bias.data.shape ), F"""{full_name} has size {value.shape}, but {adapter.proj_layer_norm.bias.data.shape} was found.""" __lowerCamelCase = value logger.info(F"""Adapter proj layer norm bias was initialized from {full_name}.""" ) if "weight" in name: assert ( value.shape == adapter.proj_layer_norm.weight.data.shape ), F"""{full_name} has size {value.shape}, but {adapter.proj_layer_norm.weight.data.shape} was found.""" __lowerCamelCase = value else: # has to be projection layer if "bias" in name: assert ( value.shape == adapter.proj.bias.data.shape ), F"""{full_name} has size {value.shape}, but {adapter.proj.bias.data.shape} was found.""" __lowerCamelCase = value logger.info(F"""Adapter proj layer bias was initialized from {full_name}.""" ) if "weight" in name: assert ( value.shape == adapter.proj.weight.data.shape ), F"""{full_name} has size {value.shape}, but {adapter.proj.weight.data.shape} was found.""" __lowerCamelCase = value logger.info(F"""Adapter proj layer weight was initialized from {full_name}.""" ) elif isinstance(UpperCamelCase__ , UpperCamelCase__ ): if "bias" in name: assert ( value.shape == adapter.layers[layer_id].conv.bias.data.shape ), F"""{full_name} has size {value.shape}, but {adapter.layers[layer_id].conv.bias.data.shape} was found.""" __lowerCamelCase = value logger.info(F"""Adapter layer {layer_id} bias was initialized from {full_name}.""" ) elif "weight" in name: assert ( value.shape == adapter.layers[layer_id].conv.weight.data.shape ), F"""{full_name} has size {value.shape}, but {adapter.layers[layer_id].conv.weight.data.shape} was found.""" __lowerCamelCase = value logger.info(F"""Adapter layer {layer_id} bias was initialized from {full_name}.""" ) else: unused_weights.append(UpperCamelCase__ ) def lowerCamelCase_ ( UpperCamelCase__ : Tuple ) -> Tuple: """simple docstring""" __lowerCamelCase , __lowerCamelCase = emb.weight.shape __lowerCamelCase = nn.Linear(UpperCamelCase__ , UpperCamelCase__ , bias=UpperCamelCase__ ) __lowerCamelCase = emb.weight.data return lin_layer @torch.no_grad() def lowerCamelCase_ ( UpperCamelCase__ : List[str] , UpperCamelCase__ : List[Any] , UpperCamelCase__ : Union[str, Any] , UpperCamelCase__ : Dict , UpperCamelCase__ : List[str] , UpperCamelCase__ : Union[str, Any] , UpperCamelCase__ : Optional[int] , UpperCamelCase__ : Union[str, Any] , UpperCamelCase__ : Optional[Any] , UpperCamelCase__ : str , UpperCamelCase__ : Optional[Any] , ) -> str: """simple docstring""" __lowerCamelCase = WavaVecaConfig.from_pretrained( UpperCamelCase__ , add_adapter=UpperCamelCase__ , adapter_stride=UpperCamelCase__ , adapter_kernel_size=UpperCamelCase__ , use_auth_token=UpperCamelCase__ , output_hidden_size=UpperCamelCase__ , ) __lowerCamelCase = MBartConfig.from_pretrained(UpperCamelCase__ ) # load model __lowerCamelCase , __lowerCamelCase , __lowerCamelCase = fairseq.checkpoint_utils.load_model_ensemble_and_task( [checkpoint_path] , arg_overrides={ 'config_yaml': config_yaml_path, 'data': '/'.join(dict_path.split('/' )[:-1] ), 'w2v_path': checkpoint_path, 'load_pretrained_decoder_from': None, } , ) __lowerCamelCase = model[0].eval() # load feature extractor __lowerCamelCase = WavaVecaFeatureExtractor.from_pretrained(UpperCamelCase__ , use_auth_token=UpperCamelCase__ ) # set weights for wav2vec2 encoder __lowerCamelCase = WavaVecaModel(UpperCamelCase__ ) recursively_load_weights_wavaveca(model.encoder , UpperCamelCase__ ) # load decoder weights __lowerCamelCase = MBartForCausalLM(UpperCamelCase__ ) __lowerCamelCase , __lowerCamelCase = hf_decoder.model.decoder.load_state_dict(model.decoder.state_dict() , strict=UpperCamelCase__ ) logger.warning(F"""The following keys are missing when loading the decoder weights: {missing_keys}""" ) logger.warning(F"""The following keys are unexpected when loading the decoder weights: {unexpected_keys}""" ) __lowerCamelCase = SpeechEncoderDecoderModel(encoder=UpperCamelCase__ , decoder=UpperCamelCase__ ) __lowerCamelCase = False __lowerCamelCase = MBartaaTokenizer(UpperCamelCase__ ) tokenizer.save_pretrained(UpperCamelCase__ ) __lowerCamelCase = hf_wavavec.config.to_dict() __lowerCamelCase = tokenizer.pad_token_id __lowerCamelCase = tokenizer.bos_token_id __lowerCamelCase = tokenizer.eos_token_id __lowerCamelCase = 'mbart50' __lowerCamelCase = 'wav2vec2' __lowerCamelCase = tokenizer.eos_token_id __lowerCamelCase = 25_0004 __lowerCamelCase = tokenizer.eos_token_id __lowerCamelCase = SpeechEncoderDecoderConfig.from_dict(UpperCamelCase__ ) hf_wavavec.save_pretrained(UpperCamelCase__ ) feature_extractor.save_pretrained(UpperCamelCase__ ) 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 fairseq checkpoint") parser.add_argument("--dict_path", default=None, type=str, help="Path to dict of fine-tuned model") parser.add_argument("--config_yaml_path", default=None, type=str, help="Path to yaml file of fine-tuned model") parser.add_argument( "--encoder_config_path", default="facebook/wav2vec2-xls-r-1b", type=str, help="Path to hf encoder wav2vec2 checkpoint config", ) parser.add_argument( "--decoder_config_path", default="facebook/mbart-large-50-one-to-many-mmt", type=str, help="Path to hf decoder checkpoint config", ) parser.add_argument("--add_adapter", default=True, type=bool, help="whethere to add model adapter layers") parser.add_argument("--adapter_stride", default=2, type=int, help="stride of adapter layers") parser.add_argument("--adapter_kernel_size", default=3, type=int, help="kernel size of adapter layers") parser.add_argument("--encoder_output_dim", default=10_24, type=int, help="encoder output dim") parser.add_argument("--start_token_id", default=25_00_04, type=int, help="`decoder_start_token_id` of model config") __A = parser.parse_args() convert_wavaveca_checkpoint( args.checkpoint_path, args.pytorch_dump_folder_path, args.dict_path, args.config_yaml_path, encoder_config_path=args.encoder_config_path, decoder_config_path=args.decoder_config_path, add_adapter=args.add_adapter, adapter_kernel_size=args.adapter_kernel_size, adapter_stride=args.adapter_stride, decoder_start_token_id=args.start_token_id, encoder_output_dim=args.encoder_output_dim, )
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'''simple docstring''' # Copyright 2023 The HuggingFace Team. All rights reserved. # # Licensed under the Apache License, Version 2.0 (the "License"); # you may not use this file except in compliance with the License. # You may obtain a copy of the License at # # http://www.apache.org/licenses/LICENSE-2.0 # # Unless required by applicable law or agreed to in writing, software # distributed under the License is distributed on an "AS IS" BASIS, # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. # See the License for the specific language governing permissions and # limitations under the License. from typing import TYPE_CHECKING # rely on isort to merge the imports from ...utils import OptionalDependencyNotAvailable, _LazyModule, is_torch_available, is_vision_available __lowerCAmelCase = { """configuration_efficientnet""": [ """EFFICIENTNET_PRETRAINED_CONFIG_ARCHIVE_MAP""", """EfficientNetConfig""", """EfficientNetOnnxConfig""", ] } try: if not is_vision_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __lowerCAmelCase = ["""EfficientNetImageProcessor"""] try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __lowerCAmelCase = [ """EFFICIENTNET_PRETRAINED_MODEL_ARCHIVE_LIST""", """EfficientNetForImageClassification""", """EfficientNetModel""", """EfficientNetPreTrainedModel""", ] if TYPE_CHECKING: from .configuration_efficientnet import ( EFFICIENTNET_PRETRAINED_CONFIG_ARCHIVE_MAP, EfficientNetConfig, EfficientNetOnnxConfig, ) try: if not is_vision_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .image_processing_efficientnet import EfficientNetImageProcessor try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_efficientnet import ( EFFICIENTNET_PRETRAINED_MODEL_ARCHIVE_LIST, EfficientNetForImageClassification, EfficientNetModel, EfficientNetPreTrainedModel, ) else: import sys __lowerCAmelCase = _LazyModule(__name__, globals()["""__file__"""], _import_structure)
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def lowerCamelCase_ ( UpperCamelCase__ : int ) -> bool: """simple docstring""" return number & 1 == 0 if __name__ == "__main__": import doctest doctest.testmod()
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from typing import Dict, List, Optional, Union import numpy as np from ...image_processing_utils import BaseImageProcessor, BatchFeature, get_size_dict from ...image_transforms import ( center_crop, convert_to_rgb, get_resize_output_image_size, normalize, rescale, resize, to_channel_dimension_format, ) from ...image_utils import ( OPENAI_CLIP_MEAN, OPENAI_CLIP_STD, ChannelDimension, ImageInput, PILImageResampling, make_list_of_images, to_numpy_array, valid_images, ) from ...utils import TensorType, is_vision_available, logging UpperCAmelCase = logging.get_logger(__name__) if is_vision_available(): import PIL class A_ ( __lowerCamelCase ): '''simple docstring''' _UpperCamelCase : int = ["""pixel_values"""] def __init__( self , snake_case = True , snake_case = None , snake_case = PILImageResampling.BICUBIC , snake_case = True , snake_case = None , snake_case = True , snake_case = 1 / 255 , snake_case = True , snake_case = None , snake_case = None , snake_case = True , **snake_case , ): super().__init__(**lowerCamelCase__ ) lowercase = size if size is not None else {'shortest_edge': 224} lowercase = get_size_dict(lowerCamelCase__ , default_to_square=lowerCamelCase__ ) lowercase = crop_size if crop_size is not None else {'height': 224, 'width': 224} lowercase = get_size_dict(lowerCamelCase__ , default_to_square=lowerCamelCase__ , param_name='crop_size' ) lowercase = do_resize lowercase = size lowercase = resample lowercase = do_center_crop lowercase = crop_size lowercase = do_rescale lowercase = rescale_factor lowercase = do_normalize lowercase = image_mean if image_mean is not None else OPENAI_CLIP_MEAN lowercase = image_std if image_std is not None else OPENAI_CLIP_STD lowercase = do_convert_rgb def SCREAMING_SNAKE_CASE__ ( self , snake_case , snake_case , snake_case = PILImageResampling.BICUBIC , snake_case = None , **snake_case , ): lowercase = get_size_dict(lowerCamelCase__ , default_to_square=lowerCamelCase__ ) if "shortest_edge" not in size: raise ValueError(F'''The `size` parameter must contain the key `shortest_edge`. Got {size.keys()}''' ) lowercase = get_resize_output_image_size(lowerCamelCase__ , size=size['shortest_edge'] , default_to_square=lowerCamelCase__ ) return resize(lowerCamelCase__ , size=lowerCamelCase__ , resample=lowerCamelCase__ , data_format=lowerCamelCase__ , **lowerCamelCase__ ) def SCREAMING_SNAKE_CASE__ ( self , snake_case , snake_case , snake_case = None , **snake_case , ): lowercase = get_size_dict(lowerCamelCase__ ) if "height" not in size or "width" not in size: raise ValueError(F'''The `size` parameter must contain the keys (height, width). Got {size.keys()}''' ) return center_crop(lowerCamelCase__ , size=(size['height'], size['width']) , data_format=lowerCamelCase__ , **lowerCamelCase__ ) def SCREAMING_SNAKE_CASE__ ( self , snake_case , snake_case , snake_case = None , **snake_case , ): return rescale(lowerCamelCase__ , scale=lowerCamelCase__ , data_format=lowerCamelCase__ , **lowerCamelCase__ ) def SCREAMING_SNAKE_CASE__ ( self , snake_case , snake_case , snake_case , snake_case = None , **snake_case , ): return normalize(lowerCamelCase__ , mean=lowerCamelCase__ , std=lowerCamelCase__ , data_format=lowerCamelCase__ , **lowerCamelCase__ ) def SCREAMING_SNAKE_CASE__ ( self , snake_case , snake_case = None , snake_case = None , snake_case = None , snake_case = None , snake_case = None , snake_case = None , snake_case = None , snake_case = None , snake_case = None , snake_case = None , snake_case = None , snake_case = None , snake_case = ChannelDimension.FIRST , **snake_case , ): lowercase = do_resize if do_resize is not None else self.do_resize lowercase = size if size is not None else self.size lowercase = get_size_dict(lowerCamelCase__ , param_name='size' , default_to_square=lowerCamelCase__ ) lowercase = resample if resample is not None else self.resample lowercase = do_center_crop if do_center_crop is not None else self.do_center_crop lowercase = crop_size if crop_size is not None else self.crop_size lowercase = get_size_dict(lowerCamelCase__ , param_name='crop_size' , default_to_square=lowerCamelCase__ ) lowercase = do_rescale if do_rescale is not None else self.do_rescale lowercase = rescale_factor if rescale_factor is not None else self.rescale_factor lowercase = do_normalize if do_normalize is not None else self.do_normalize lowercase = image_mean if image_mean is not None else self.image_mean lowercase = image_std if image_std is not None else self.image_std lowercase = do_convert_rgb if do_convert_rgb is not None else self.do_convert_rgb lowercase = make_list_of_images(lowerCamelCase__ ) if not valid_images(lowerCamelCase__ ): raise ValueError( 'Invalid image type. Must be of type PIL.Image.Image, numpy.ndarray, ' 'torch.Tensor, tf.Tensor or jax.ndarray.' ) if do_resize and size is None: raise ValueError('Size must be specified if do_resize is True.' ) if do_center_crop and crop_size is None: raise ValueError('Crop size must be specified if do_center_crop is True.' ) if do_rescale and rescale_factor is None: raise ValueError('Rescale factor must be specified if do_rescale is True.' ) if do_normalize and (image_mean is None or image_std is None): raise ValueError('Image mean and std must be specified if do_normalize is True.' ) # PIL RGBA images are converted to RGB if do_convert_rgb: lowercase = [convert_to_rgb(lowerCamelCase__ ) for image in images] # All transformations expect numpy arrays. lowercase = [to_numpy_array(lowerCamelCase__ ) for image in images] if do_resize: lowercase = [self.resize(image=lowerCamelCase__ , size=lowerCamelCase__ , resample=lowerCamelCase__ ) for image in images] if do_center_crop: lowercase = [self.center_crop(image=lowerCamelCase__ , size=lowerCamelCase__ ) for image in images] if do_rescale: lowercase = [self.rescale(image=lowerCamelCase__ , scale=lowerCamelCase__ ) for image in images] if do_normalize: lowercase = [self.normalize(image=lowerCamelCase__ , mean=lowerCamelCase__ , std=lowerCamelCase__ ) for image in images] lowercase = [to_channel_dimension_format(lowerCamelCase__ , lowerCamelCase__ ) for image in images] lowercase = {'pixel_values': images} return BatchFeature(data=lowerCamelCase__ , tensor_type=lowerCamelCase__ )
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from typing import List, Optional import numpy as np from ...processing_utils import ProcessorMixin from ...utils import to_numpy class __lowerCAmelCase ( __magic_name__ ): """simple docstring""" snake_case_ = '''EncodecFeatureExtractor''' snake_case_ = ('''T5Tokenizer''', '''T5TokenizerFast''') def __init__( self , lowerCamelCase__ , lowerCamelCase__ ) -> int: '''simple docstring''' super().__init__(lowerCamelCase__ , lowerCamelCase__ ) __lowerCamelCase = self.feature_extractor __lowerCamelCase = False def lowercase_ ( self , lowerCamelCase__=None , lowerCamelCase__=None , lowerCamelCase__=True ) -> List[Any]: '''simple docstring''' return self.tokenizer.get_decoder_prompt_ids(task=lowerCamelCase__ , language=lowerCamelCase__ , no_timestamps=lowerCamelCase__ ) def __call__( self , *lowerCamelCase__ , **lowerCamelCase__ ) -> Dict: '''simple docstring''' # For backward compatibility if self._in_target_context_manager: return self.current_processor(*lowerCamelCase__ , **lowerCamelCase__ ) __lowerCamelCase = kwargs.pop('audio' , lowerCamelCase__ ) __lowerCamelCase = kwargs.pop('sampling_rate' , lowerCamelCase__ ) __lowerCamelCase = kwargs.pop('text' , lowerCamelCase__ ) if len(lowerCamelCase__ ) > 0: __lowerCamelCase = args[0] __lowerCamelCase = args[1:] if audio is None and text is None: raise ValueError('You need to specify either an `audio` or `text` input to process.' ) if text is not None: __lowerCamelCase = self.tokenizer(lowerCamelCase__ , **lowerCamelCase__ ) if audio is not None: __lowerCamelCase = self.feature_extractor(lowerCamelCase__ , *lowerCamelCase__ , sampling_rate=lowerCamelCase__ , **lowerCamelCase__ ) if audio is None: return inputs elif text is None: return audio_inputs else: __lowerCamelCase = audio_inputs['input_values'] if "padding_mask" in audio_inputs: __lowerCamelCase = audio_inputs['padding_mask'] return inputs def lowercase_ ( self , *lowerCamelCase__ , **lowerCamelCase__ ) -> Union[str, Any]: '''simple docstring''' __lowerCamelCase = kwargs.pop('audio' , lowerCamelCase__ ) __lowerCamelCase = kwargs.pop('padding_mask' , lowerCamelCase__ ) if len(lowerCamelCase__ ) > 0: __lowerCamelCase = args[0] __lowerCamelCase = args[1:] if audio_values is not None: return self._decode_audio(lowerCamelCase__ , padding_mask=lowerCamelCase__ ) else: return self.tokenizer.batch_decode(*lowerCamelCase__ , **lowerCamelCase__ ) def lowercase_ ( self , *lowerCamelCase__ , **lowerCamelCase__ ) -> List[Any]: '''simple docstring''' return self.tokenizer.decode(*lowerCamelCase__ , **lowerCamelCase__ ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ = None ) -> List[np.ndarray]: '''simple docstring''' __lowerCamelCase = to_numpy(lowerCamelCase__ ) __lowerCamelCase , __lowerCamelCase , __lowerCamelCase = audio_values.shape if padding_mask is None: return list(lowerCamelCase__ ) __lowerCamelCase = to_numpy(lowerCamelCase__ ) # match the sequence length of the padding mask to the generated audio arrays by padding with the **non-padding** # token (so that the generated audio values are **not** treated as padded tokens) __lowerCamelCase = seq_len - padding_mask.shape[-1] __lowerCamelCase = 1 - self.feature_extractor.padding_value __lowerCamelCase = np.pad(lowerCamelCase__ , ((0, 0), (0, difference)) , 'constant' , constant_values=lowerCamelCase__ ) __lowerCamelCase = audio_values.tolist() for i in range(lowerCamelCase__ ): __lowerCamelCase = np.asarray(audio_values[i] )[ padding_mask[i][None, :] != self.feature_extractor.padding_value ] __lowerCamelCase = sliced_audio.reshape(lowerCamelCase__ , -1 ) return audio_values
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import copy import inspect import unittest import numpy as np from huggingface_hub import hf_hub_download from transformers import TimesformerConfig from transformers.models.auto import get_values 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, floats_tensor, ids_tensor from ...test_pipeline_mixin import PipelineTesterMixin if is_torch_available(): import torch from torch import nn from transformers import ( MODEL_FOR_VIDEO_CLASSIFICATION_MAPPING, TimesformerForVideoClassification, TimesformerModel, ) from transformers.models.timesformer.modeling_timesformer import TIMESFORMER_PRETRAINED_MODEL_ARCHIVE_LIST if is_vision_available(): from transformers import VideoMAEImageProcessor class __magic_name__ : def __init__( self , __snake_case , __snake_case=13 , __snake_case=10 , __snake_case=3 , __snake_case=2 , __snake_case=2 , __snake_case=True , __snake_case=True , __snake_case=32 , __snake_case=5 , __snake_case=4 , __snake_case=37 , __snake_case="gelu" , __snake_case=0.1 , __snake_case=0.1 , __snake_case=10 , __snake_case=0.02 , __snake_case="divided_space_time" , __snake_case=None , ) -> Any: '''simple docstring''' __a =parent __a =batch_size __a =image_size __a =num_channels __a =patch_size __a =num_frames __a =is_training __a =use_labels __a =hidden_size __a =num_hidden_layers __a =num_attention_heads __a =intermediate_size __a =hidden_act __a =hidden_dropout_prob __a =attention_probs_dropout_prob __a =attention_type __a =initializer_range __a =scope __a =num_labels # in TimeSformer, the number of spatial tokens equals num_frames * num_patches per frame + 1 CLS token __a =(image_size // patch_size) ** 2 __a =(num_frames) * self.num_patches_per_frame + 1 def __magic_name__ ( self ) -> Optional[int]: '''simple docstring''' __a =floats_tensor( [self.batch_size, self.num_frames, self.num_channels, self.image_size, self.image_size] ) __a =None if self.use_labels: __a =ids_tensor([self.batch_size] , self.num_labels ) __a =self.get_config() return config, pixel_values, labels def __magic_name__ ( self ) -> Union[str, Any]: '''simple docstring''' __a =TimesformerConfig( image_size=self.image_size , patch_size=self.patch_size , num_channels=self.num_channels , num_frames=self.num_frames , 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 , initializer_range=self.initializer_range , attention_type=self.attention_type , ) __a =self.num_labels return config def __magic_name__ ( self , __snake_case , __snake_case , __snake_case ) -> Tuple: '''simple docstring''' __a =TimesformerModel(config=lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __a =model(lowerCamelCase__ ) self.parent.assertEqual(result.last_hidden_state.shape , (self.batch_size, self.seq_length, self.hidden_size) ) def __magic_name__ ( self , __snake_case , __snake_case , __snake_case ) -> Union[str, Any]: '''simple docstring''' __a =TimesformerForVideoClassification(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __a =model(lowerCamelCase__ ) # verify the logits shape __a =torch.Size((self.batch_size, self.num_labels) ) self.parent.assertEqual(result.logits.shape , lowerCamelCase__ ) def __magic_name__ ( self ) -> Tuple: '''simple docstring''' __a =self.prepare_config_and_inputs() __a , __a , __a =config_and_inputs __a ={'pixel_values': pixel_values} return config, inputs_dict @require_torch class __magic_name__ ( lowerCAmelCase_ , lowerCAmelCase_ , unittest.TestCase ): SCREAMING_SNAKE_CASE = (TimesformerModel, TimesformerForVideoClassification) if is_torch_available() else () SCREAMING_SNAKE_CASE = ( {'feature-extraction': TimesformerModel, 'video-classification': TimesformerForVideoClassification} if is_torch_available() else {} ) SCREAMING_SNAKE_CASE = False SCREAMING_SNAKE_CASE = False SCREAMING_SNAKE_CASE = False SCREAMING_SNAKE_CASE = False def __magic_name__ ( self ) -> List[str]: '''simple docstring''' __a =TimesformerModelTester(self ) __a =ConfigTester( self , config_class=lowerCamelCase__ , has_text_modality=lowerCamelCase__ , hidden_size=37 ) def __magic_name__ ( self , __snake_case , __snake_case , __snake_case=False ) -> int: '''simple docstring''' __a =copy.deepcopy(lowerCamelCase__ ) if return_labels: if model_class in get_values(lowerCamelCase__ ): __a =torch.zeros( self.model_tester.batch_size , dtype=torch.long , device=lowerCamelCase__ ) return inputs_dict def __magic_name__ ( self ) -> Optional[int]: '''simple docstring''' self.config_tester.run_common_tests() @unittest.skip(reason='TimeSformer does not use inputs_embeds' ) def __magic_name__ ( self ) -> List[str]: '''simple docstring''' pass def __magic_name__ ( self ) -> Union[str, Any]: '''simple docstring''' __a , __a =self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: __a =model_class(lowerCamelCase__ ) self.assertIsInstance(model.get_input_embeddings() , (nn.Module) ) __a =model.get_output_embeddings() self.assertTrue(x is None or isinstance(lowerCamelCase__ , nn.Linear ) ) def __magic_name__ ( self ) -> List[str]: '''simple docstring''' __a , __a =self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: __a =model_class(lowerCamelCase__ ) __a =inspect.signature(model.forward ) # signature.parameters is an OrderedDict => so arg_names order is deterministic __a =[*signature.parameters.keys()] __a =['pixel_values'] self.assertListEqual(arg_names[:1] , lowerCamelCase__ ) def __magic_name__ ( self ) -> Union[str, Any]: '''simple docstring''' __a =self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_model(*lowerCamelCase__ ) def __magic_name__ ( self ) -> str: '''simple docstring''' __a =self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_for_video_classification(*lowerCamelCase__ ) @slow def __magic_name__ ( self ) -> Dict: '''simple docstring''' for model_name in TIMESFORMER_PRETRAINED_MODEL_ARCHIVE_LIST[:1]: __a =TimesformerModel.from_pretrained(lowerCamelCase__ ) self.assertIsNotNone(lowerCamelCase__ ) def __magic_name__ ( self ) -> List[Any]: '''simple docstring''' if not self.has_attentions: pass else: __a , __a =self.model_tester.prepare_config_and_inputs_for_common() __a =True for model_class in self.all_model_classes: __a =self.model_tester.seq_length __a =self.model_tester.num_frames __a =True __a =False __a =True __a =model_class(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() with torch.no_grad(): __a =model(**self._prepare_for_class(lowerCamelCase__ , lowerCamelCase__ ) ) __a =outputs.attentions self.assertEqual(len(lowerCamelCase__ ) , self.model_tester.num_hidden_layers ) # check that output_attentions also work using config del inputs_dict["output_attentions"] __a =True __a =model_class(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() with torch.no_grad(): __a =model(**self._prepare_for_class(lowerCamelCase__ , lowerCamelCase__ ) ) __a =outputs.attentions self.assertEqual(len(lowerCamelCase__ ) , self.model_tester.num_hidden_layers ) # attentions has shape (batch_size x num_frames) x num_heads x (num_patches per frame + 1) x (num_patches per frame + 1) self.assertListEqual( list(attentions[0].shape[-3:] ) , [self.model_tester.num_attention_heads, seq_len // num_frames + 1, seq_len // num_frames + 1] , ) __a =len(lowerCamelCase__ ) # Check attention is always last and order is fine __a =True __a =True __a =model_class(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() with torch.no_grad(): __a =model(**self._prepare_for_class(lowerCamelCase__ , lowerCamelCase__ ) ) self.assertEqual(out_len + 1 , len(lowerCamelCase__ ) ) __a =outputs.attentions self.assertEqual(len(lowerCamelCase__ ) , self.model_tester.num_hidden_layers ) # attentions has shape (batch_size x num_frames) x num_heads x (num_patches per frame + 1) x (num_patches per frame + 1) self.assertListEqual( list(self_attentions[0].shape[-3:] ) , [self.model_tester.num_attention_heads, seq_len // num_frames + 1, seq_len // num_frames + 1] , ) def __magic_name__ ( self ) -> Tuple: '''simple docstring''' def check_hidden_states_output(__snake_case , __snake_case , __snake_case ): __a =model_class(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() with torch.no_grad(): __a =model(**self._prepare_for_class(lowerCamelCase__ , lowerCamelCase__ ) ) __a =outputs.hidden_states __a =self.model_tester.num_hidden_layers + 1 self.assertEqual(len(lowerCamelCase__ ) , lowerCamelCase__ ) __a =self.model_tester.seq_length self.assertListEqual( list(hidden_states[0].shape[-2:] ) , [seq_length, self.model_tester.hidden_size] , ) __a , __a =self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: __a =True check_hidden_states_output(lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) # check that output_hidden_states also work using config del inputs_dict["output_hidden_states"] __a =True check_hidden_states_output(lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) def UpperCamelCase_( ): """simple docstring""" __a =hf_hub_download( repo_id='hf-internal-testing/spaghetti-video' , filename='eating_spaghetti.npy' , repo_type='dataset' ) __a =np.load(UpperCamelCase__ ) return list(UpperCamelCase__ ) @require_torch @require_vision class __magic_name__ ( unittest.TestCase ): @cached_property def __magic_name__ ( self ) -> List[Any]: '''simple docstring''' return ( VideoMAEImageProcessor(image_mean=[0.5, 0.5, 0.5] , image_std=[0.5, 0.5, 0.5] ) if is_vision_available() else None ) @slow def __magic_name__ ( self ) -> List[str]: '''simple docstring''' __a =TimesformerForVideoClassification.from_pretrained('facebook/timesformer-base-finetuned-k400' ).to( lowerCamelCase__ ) __a =self.default_image_processor __a =prepare_video() __a =image_processor(video[:8] , return_tensors='pt' ).to(lowerCamelCase__ ) # forward pass with torch.no_grad(): __a =model(**lowerCamelCase__ ) # verify the logits __a =torch.Size((1, 400) ) self.assertEqual(outputs.logits.shape , lowerCamelCase__ ) __a =torch.tensor([-0.3016, -0.7713, -0.4205] ).to(lowerCamelCase__ ) self.assertTrue(torch.allclose(outputs.logits[0, :3] , lowerCamelCase__ , atol=1e-4 ) )
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from math import sqrt def lowerCamelCase_ ( UpperCamelCase__ : int ) -> bool: """simple docstring""" if 1 < number < 4: # 2 and 3 are primes return True elif number < 2 or number % 2 == 0 or number % 3 == 0: # Negatives, 0, 1, all even numbers, all multiples of 3 are not primes return False # All primes number are in format of 6k +/- 1 for i in range(5 , int(sqrt(UpperCamelCase__ ) + 1 ) , 6 ): if number % i == 0 or number % (i + 2) == 0: return False return True def lowerCamelCase_ ( UpperCamelCase__ : int = 1_0001 ) -> int: """simple docstring""" __lowerCamelCase = 0 __lowerCamelCase = 1 while count != nth and number < 3: number += 1 if is_prime(UpperCamelCase__ ): count += 1 while count != nth: number += 2 if is_prime(UpperCamelCase__ ): count += 1 return number if __name__ == "__main__": print(f'''{solution() = }''')
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0
"""simple docstring""" from ...utils import is_torch_available, is_transformers_available if is_transformers_available() and is_torch_available(): from .pipeline_vq_diffusion import LearnedClassifierFreeSamplingEmbeddings, VQDiffusionPipeline
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import baseaa def lowerCamelCase_ ( UpperCamelCase__ : str ) -> bytes: """simple docstring""" return baseaa.aaaencode(string.encode('utf-8' ) ) def lowerCamelCase_ ( UpperCamelCase__ : bytes ) -> str: """simple docstring""" return baseaa.aaadecode(UpperCamelCase__ ).decode('utf-8' ) if __name__ == "__main__": import doctest doctest.testmod()
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0
import gc import unittest import numpy as np import torch from transformers import CLIPTextConfig, CLIPTextModelWithProjection, CLIPTokenizer from diffusers import HeunDiscreteScheduler, PriorTransformer, ShapEPipeline from diffusers.pipelines.shap_e import ShapERenderer from diffusers.utils import load_numpy, slow from diffusers.utils.testing_utils import require_torch_gpu, torch_device from ..test_pipelines_common import PipelineTesterMixin, assert_mean_pixel_difference class snake_case ( SCREAMING_SNAKE_CASE_ ,unittest.TestCase ): '''simple docstring''' snake_case_ : Dict = ShapEPipeline snake_case_ : int = ["""prompt"""] snake_case_ : Optional[Any] = ["""prompt"""] snake_case_ : Any = [ """num_images_per_prompt""", """num_inference_steps""", """generator""", """latents""", """guidance_scale""", """frame_size""", """output_type""", """return_dict""", ] snake_case_ : str = False @property def UpperCamelCase_ ( self : Tuple) -> Dict: """simple docstring""" return 32 @property def UpperCamelCase_ ( self : str) -> Optional[Any]: """simple docstring""" return 32 @property def UpperCamelCase_ ( self : Any) -> int: """simple docstring""" return self.time_input_dim * 4 @property def UpperCamelCase_ ( self : Dict) -> str: """simple docstring""" return 8 @property def UpperCamelCase_ ( self : Union[str, Any]) -> List[str]: """simple docstring""" _snake_case : Optional[int] = CLIPTokenizer.from_pretrained("""hf-internal-testing/tiny-random-clip""") return tokenizer @property def UpperCamelCase_ ( self : str) -> Any: """simple docstring""" torch.manual_seed(0) _snake_case : Any = CLIPTextConfig( bos_token_id=0 , eos_token_id=2 , hidden_size=self.text_embedder_hidden_size , projection_dim=self.text_embedder_hidden_size , intermediate_size=37 , layer_norm_eps=1E-05 , num_attention_heads=4 , num_hidden_layers=5 , pad_token_id=1 , vocab_size=1000 , ) return CLIPTextModelWithProjection(lowerCamelCase__) @property def UpperCamelCase_ ( self : Optional[Any]) -> Optional[Any]: """simple docstring""" torch.manual_seed(0) _snake_case : Dict = { """num_attention_heads""": 2, """attention_head_dim""": 16, """embedding_dim""": self.time_input_dim, """num_embeddings""": 32, """embedding_proj_dim""": self.text_embedder_hidden_size, """time_embed_dim""": self.time_embed_dim, """num_layers""": 1, """clip_embed_dim""": self.time_input_dim * 2, """additional_embeddings""": 0, """time_embed_act_fn""": """gelu""", """norm_in_type""": """layer""", """encoder_hid_proj_type""": None, """added_emb_type""": None, } _snake_case : int = PriorTransformer(**lowerCamelCase__) return model @property def UpperCamelCase_ ( self : Dict) -> Dict: """simple docstring""" torch.manual_seed(0) _snake_case : Tuple = { """param_shapes""": ( (self.renderer_dim, 93), (self.renderer_dim, 8), (self.renderer_dim, 8), (self.renderer_dim, 8), ), """d_latent""": self.time_input_dim, """d_hidden""": self.renderer_dim, """n_output""": 12, """background""": ( 0.1, 0.1, 0.1, ), } _snake_case : Union[str, Any] = ShapERenderer(**lowerCamelCase__) return model def UpperCamelCase_ ( self : Optional[Any]) -> Optional[Any]: """simple docstring""" _snake_case : Tuple = self.dummy_prior _snake_case : str = self.dummy_text_encoder _snake_case : Dict = self.dummy_tokenizer _snake_case : Tuple = self.dummy_renderer _snake_case : Union[str, Any] = HeunDiscreteScheduler( beta_schedule="""exp""" , num_train_timesteps=1024 , prediction_type="""sample""" , use_karras_sigmas=lowerCamelCase__ , clip_sample=lowerCamelCase__ , clip_sample_range=1.0 , ) _snake_case : List[str] = { """prior""": prior, """text_encoder""": text_encoder, """tokenizer""": tokenizer, """renderer""": renderer, """scheduler""": scheduler, } return components def UpperCamelCase_ ( self : Optional[Any] , lowerCAmelCase : List[Any] , lowerCAmelCase : str=0) -> Optional[Any]: """simple docstring""" if str(lowerCamelCase__).startswith("""mps"""): _snake_case : List[Any] = torch.manual_seed(lowerCamelCase__) else: _snake_case : Union[str, Any] = torch.Generator(device=lowerCamelCase__).manual_seed(lowerCamelCase__) _snake_case : Tuple = { """prompt""": """horse""", """generator""": generator, """num_inference_steps""": 1, """frame_size""": 32, """output_type""": """np""", } return inputs def UpperCamelCase_ ( self : int) -> int: """simple docstring""" _snake_case : List[Any] = """cpu""" _snake_case : Optional[int] = self.get_dummy_components() _snake_case : List[str] = self.pipeline_class(**lowerCamelCase__) _snake_case : Any = pipe.to(lowerCamelCase__) pipe.set_progress_bar_config(disable=lowerCamelCase__) _snake_case : str = pipe(**self.get_dummy_inputs(lowerCamelCase__)) _snake_case : Optional[Any] = output.images[0] _snake_case : str = image[0, -3:, -3:, -1] assert image.shape == (20, 32, 32, 3) _snake_case : str = np.array( [ 0.00_039_216, 0.00_039_216, 0.00_039_216, 0.00_039_216, 0.00_039_216, 0.00_039_216, 0.00_039_216, 0.00_039_216, 0.00_039_216, ]) assert np.abs(image_slice.flatten() - expected_slice).max() < 1E-2 def UpperCamelCase_ ( self : List[str]) -> Optional[Any]: """simple docstring""" self._test_inference_batch_consistent(batch_sizes=[1, 2]) def UpperCamelCase_ ( self : Any) -> Tuple: """simple docstring""" _snake_case : List[Any] = torch_device == """cpu""" _snake_case : int = True self._test_inference_batch_single_identical( batch_size=2 , test_max_difference=lowerCamelCase__ , relax_max_difference=lowerCamelCase__ , ) def UpperCamelCase_ ( self : List[str]) -> Union[str, Any]: """simple docstring""" _snake_case : Dict = self.get_dummy_components() _snake_case : str = self.pipeline_class(**lowerCamelCase__) _snake_case : Tuple = pipe.to(lowerCamelCase__) pipe.set_progress_bar_config(disable=lowerCamelCase__) _snake_case : List[str] = 1 _snake_case : str = 2 _snake_case : str = self.get_dummy_inputs(lowerCamelCase__) for key in inputs.keys(): if key in self.batch_params: _snake_case : Any = batch_size * [inputs[key]] _snake_case : int = pipe(**lowerCamelCase__ , num_images_per_prompt=lowerCamelCase__)[0] assert images.shape[0] == batch_size * num_images_per_prompt @slow @require_torch_gpu class snake_case ( unittest.TestCase ): '''simple docstring''' def UpperCamelCase_ ( self : str) -> int: """simple docstring""" super().tearDown() gc.collect() torch.cuda.empty_cache() def UpperCamelCase_ ( self : Dict) -> List[Any]: """simple docstring""" _snake_case : Optional[Any] = load_numpy( """https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main""" """/shap_e/test_shap_e_np_out.npy""") _snake_case : List[str] = ShapEPipeline.from_pretrained("""openai/shap-e""") _snake_case : Union[str, Any] = pipe.to(lowerCamelCase__) pipe.set_progress_bar_config(disable=lowerCamelCase__) _snake_case : Dict = torch.Generator(device=lowerCamelCase__).manual_seed(0) _snake_case : Union[str, Any] = pipe( """a shark""" , generator=lowerCamelCase__ , guidance_scale=15.0 , num_inference_steps=64 , frame_size=64 , output_type="""np""" , ).images[0] assert images.shape == (20, 64, 64, 3) assert_mean_pixel_difference(lowerCamelCase__ , lowerCamelCase__)
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import copy from typing import Any, Dict, List, Optional, Union import numpy as np import torch from ...audio_utils import mel_filter_bank, spectrogram, window_function from ...feature_extraction_sequence_utils import SequenceFeatureExtractor from ...feature_extraction_utils import BatchFeature from ...utils import TensorType, logging __A = logging.get_logger(__name__) class __lowerCAmelCase ( __magic_name__ ): """simple docstring""" snake_case_ = ['''input_features''', '''is_longer'''] def __init__( self , lowerCamelCase__=64 , lowerCamelCase__=48_000 , lowerCamelCase__=480 , lowerCamelCase__=10 , lowerCamelCase__=1_024 , lowerCamelCase__=0.0 , lowerCamelCase__=False , lowerCamelCase__ = 0 , lowerCamelCase__ = 14_000 , lowerCamelCase__ = None , lowerCamelCase__ = "fusion" , lowerCamelCase__ = "repeatpad" , **lowerCamelCase__ , ) -> Tuple: '''simple docstring''' super().__init__( feature_size=lowerCamelCase__ , sampling_rate=lowerCamelCase__ , padding_value=lowerCamelCase__ , return_attention_mask=lowerCamelCase__ , **lowerCamelCase__ , ) __lowerCamelCase = top_db __lowerCamelCase = truncation __lowerCamelCase = padding __lowerCamelCase = fft_window_size __lowerCamelCase = (fft_window_size >> 1) + 1 __lowerCamelCase = hop_length __lowerCamelCase = max_length_s __lowerCamelCase = max_length_s * sampling_rate __lowerCamelCase = sampling_rate __lowerCamelCase = frequency_min __lowerCamelCase = frequency_max __lowerCamelCase = mel_filter_bank( num_frequency_bins=self.nb_frequency_bins , num_mel_filters=lowerCamelCase__ , min_frequency=lowerCamelCase__ , max_frequency=lowerCamelCase__ , sampling_rate=lowerCamelCase__ , norm=lowerCamelCase__ , mel_scale='htk' , ) __lowerCamelCase = mel_filter_bank( num_frequency_bins=self.nb_frequency_bins , num_mel_filters=lowerCamelCase__ , min_frequency=lowerCamelCase__ , max_frequency=lowerCamelCase__ , sampling_rate=lowerCamelCase__ , norm='slaney' , mel_scale='slaney' , ) def lowercase_ ( self ) -> Dict[str, Any]: '''simple docstring''' __lowerCamelCase = copy.deepcopy(self.__dict__ ) __lowerCamelCase = self.__class__.__name__ if "mel_filters" in output: del output["mel_filters"] if "mel_filters_slaney" in output: del output["mel_filters_slaney"] return output def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ = None ) -> np.ndarray: '''simple docstring''' __lowerCamelCase = spectrogram( lowerCamelCase__ , window_function(self.fft_window_size , 'hann' ) , frame_length=self.fft_window_size , hop_length=self.hop_length , power=2.0 , mel_filters=lowerCamelCase__ , log_mel='dB' , ) return log_mel_spectrogram.T def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> int: '''simple docstring''' __lowerCamelCase = np.array_split(list(range(0 , total_frames - chunk_frames + 1 ) ) , 3 ) if len(ranges[1] ) == 0: # if the audio is too short, we just use the first chunk __lowerCamelCase = [0] if len(ranges[2] ) == 0: # if the audio is too short, we just use the first chunk __lowerCamelCase = [0] # randomly choose index for each part __lowerCamelCase = np.random.choice(ranges[0] ) __lowerCamelCase = np.random.choice(ranges[1] ) __lowerCamelCase = np.random.choice(ranges[2] ) __lowerCamelCase = mel[idx_front : idx_front + chunk_frames, :] __lowerCamelCase = mel[idx_middle : idx_middle + chunk_frames, :] __lowerCamelCase = mel[idx_back : idx_back + chunk_frames, :] __lowerCamelCase = torch.tensor(mel[None, None, :] ) __lowerCamelCase = torch.nn.functional.interpolate( lowerCamelCase__ , size=[chunk_frames, 64] , mode='bilinear' , align_corners=lowerCamelCase__ ) __lowerCamelCase = mel_shrink[0][0].numpy() __lowerCamelCase = np.stack([mel_shrink, mel_chunk_front, mel_chunk_middle, mel_chunk_back] , axis=0 ) return mel_fusion def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> np.array: '''simple docstring''' if waveform.shape[0] > max_length: if truncation == "rand_trunc": __lowerCamelCase = True # random crop to max_length (for compatibility) -> this should be handled by self.pad __lowerCamelCase = len(lowerCamelCase__ ) - max_length __lowerCamelCase = np.random.randint(0 , overflow + 1 ) __lowerCamelCase = waveform[idx : idx + max_length] __lowerCamelCase = self._np_extract_fbank_features(lowerCamelCase__ , self.mel_filters_slaney )[None, :] elif truncation == "fusion": __lowerCamelCase = self._np_extract_fbank_features(lowerCamelCase__ , self.mel_filters ) __lowerCamelCase = max_length // self.hop_length + 1 # the +1 related to how the spectrogram is computed __lowerCamelCase = mel.shape[0] if chunk_frames == total_frames: # there is a corner case where the audio length is larger than max_length but smaller than max_length+hop_length. # In this case, we just use the whole audio. __lowerCamelCase = np.stack([mel, mel, mel, mel] , axis=0 ) __lowerCamelCase = False else: __lowerCamelCase = self._random_mel_fusion(lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) __lowerCamelCase = True else: raise NotImplementedError(f"""data_truncating {truncation} not implemented""" ) else: __lowerCamelCase = False # only use repeat as a new possible value for padding. you repeat the audio before applying the usual max_length padding if waveform.shape[0] < max_length: if padding == "repeat": __lowerCamelCase = int(max_length / len(lowerCamelCase__ ) ) __lowerCamelCase = np.stack(np.tile(lowerCamelCase__ , n_repeat + 1 ) )[:max_length] if padding == "repeatpad": __lowerCamelCase = int(max_length / len(lowerCamelCase__ ) ) __lowerCamelCase = np.stack(np.tile(lowerCamelCase__ , lowerCamelCase__ ) ) __lowerCamelCase = np.pad(lowerCamelCase__ , (0, max_length - waveform.shape[0]) , mode='constant' , constant_values=0 ) if truncation == "fusion": __lowerCamelCase = self._np_extract_fbank_features(lowerCamelCase__ , self.mel_filters ) __lowerCamelCase = np.stack([input_mel, input_mel, input_mel, input_mel] , axis=0 ) else: __lowerCamelCase = self._np_extract_fbank_features(lowerCamelCase__ , self.mel_filters_slaney )[None, :] return input_mel, longer def __call__( self , lowerCamelCase__ , lowerCamelCase__ = None , lowerCamelCase__ = None , lowerCamelCase__ = None , lowerCamelCase__ = None , lowerCamelCase__ = None , **lowerCamelCase__ , ) -> BatchFeature: '''simple docstring''' __lowerCamelCase = truncation if truncation is not None else self.truncation __lowerCamelCase = padding if padding else self.padding if sampling_rate is not None: if sampling_rate != self.sampling_rate: raise ValueError( f"""The model corresponding to this feature extractor: {self.__class__.__name__} was trained using a""" f""" sampling rate of {self.sampling_rate}. Please make sure that the provided `raw_speech` input""" f""" was sampled with {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.' ) __lowerCamelCase = isinstance(lowerCamelCase__ , np.ndarray ) and len(raw_speech.shape ) > 1 if is_batched_numpy and len(raw_speech.shape ) > 2: raise ValueError(f"""Only mono-channel audio is supported for input to {self}""" ) __lowerCamelCase = is_batched_numpy or ( isinstance(lowerCamelCase__ , (list, tuple) ) and (isinstance(raw_speech[0] , (np.ndarray, tuple, list) )) ) if is_batched: __lowerCamelCase = [np.asarray(lowerCamelCase__ , dtype=np.floataa ) for speech in raw_speech] elif not is_batched and not isinstance(lowerCamelCase__ , np.ndarray ): __lowerCamelCase = np.asarray(lowerCamelCase__ , dtype=np.floataa ) elif isinstance(lowerCamelCase__ , np.ndarray ) and raw_speech.dtype is np.dtype(np.floataa ): __lowerCamelCase = raw_speech.astype(np.floataa ) # always return batch if not is_batched: __lowerCamelCase = [np.asarray(lowerCamelCase__ )] # convert to mel spectrogram, truncate and pad if needed. __lowerCamelCase = [ self._get_input_mel(lowerCamelCase__ , max_length if max_length else self.nb_max_samples , lowerCamelCase__ , lowerCamelCase__ ) for waveform in raw_speech ] __lowerCamelCase = [] __lowerCamelCase = [] for mel, longer in padded_inputs: input_mel.append(lowerCamelCase__ ) is_longer.append(lowerCamelCase__ ) if truncation == "fusion" and sum(lowerCamelCase__ ) == 0: # if no audio is longer than 10s, then randomly select one audio to be longer __lowerCamelCase = np.random.randint(0 , len(lowerCamelCase__ ) ) __lowerCamelCase = True if isinstance(input_mel[0] , lowerCamelCase__ ): __lowerCamelCase = [np.asarray(lowerCamelCase__ , dtype=np.floataa ) for feature in input_mel] # is_longer is a list of bool __lowerCamelCase = [[longer] for longer in is_longer] __lowerCamelCase = {'input_features': input_mel, 'is_longer': is_longer} __lowerCamelCase = BatchFeature(lowerCamelCase__ ) if return_tensors is not None: __lowerCamelCase = input_features.convert_to_tensors(lowerCamelCase__ ) return input_features
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"""simple docstring""" from __future__ import annotations def _SCREAMING_SNAKE_CASE (__lowerCAmelCase ) -> list[int]: '''simple docstring''' if len(UpperCamelCase__ ) == 0: return array lowercase_ , lowercase_ = min(UpperCamelCase__ ), max(UpperCamelCase__ ) # Compute the variables lowercase_ = _max - _min + 1 lowercase_ , lowercase_ = [0] * holes_range, [0] * holes_range # Make the sorting. for i in array: lowercase_ = i - _min lowercase_ = i holes_repeat[index] += 1 # Makes the array back by replacing the numbers. lowercase_ = 0 for i in range(UpperCamelCase__ ): while holes_repeat[i] > 0: lowercase_ = holes[i] index += 1 holes_repeat[i] -= 1 # Returns the sorted array. return array if __name__ == "__main__": import doctest doctest.testmod() UpperCAmelCase : Union[str, Any] = input("Enter numbers separated by comma:\n") UpperCAmelCase : Union[str, Any] = [int(x) for x in user_input.split(",")] print(pigeon_sort(unsorted))
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class __lowerCAmelCase : """simple docstring""" def __init__( self ) -> Any: '''simple docstring''' __lowerCamelCase = 0 __lowerCamelCase = 0 __lowerCamelCase = {} def lowercase_ ( self , lowerCamelCase__ ) -> Tuple: '''simple docstring''' if vertex not in self.adjacency: __lowerCamelCase = {} self.num_vertices += 1 def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> str: '''simple docstring''' self.add_vertex(lowerCamelCase__ ) self.add_vertex(lowerCamelCase__ ) if head == tail: return __lowerCamelCase = weight __lowerCamelCase = weight def lowercase_ ( self ) -> List[str]: '''simple docstring''' __lowerCamelCase = self.get_edges() for edge in edges: __lowerCamelCase , __lowerCamelCase , __lowerCamelCase = edge edges.remove((tail, head, weight) ) for i in range(len(lowerCamelCase__ ) ): __lowerCamelCase = list(edges[i] ) edges.sort(key=lambda lowerCamelCase__ : e[2] ) for i in range(len(lowerCamelCase__ ) - 1 ): if edges[i][2] >= edges[i + 1][2]: __lowerCamelCase = edges[i][2] + 1 for edge in edges: __lowerCamelCase , __lowerCamelCase , __lowerCamelCase = edge __lowerCamelCase = weight __lowerCamelCase = weight def __str__( self ) -> Union[str, Any]: '''simple docstring''' __lowerCamelCase = '' for tail in self.adjacency: for head in self.adjacency[tail]: __lowerCamelCase = self.adjacency[head][tail] string += f"""{head} -> {tail} == {weight}\n""" return string.rstrip('\n' ) def lowercase_ ( self ) -> Optional[Any]: '''simple docstring''' __lowerCamelCase = [] for tail in self.adjacency: for head in self.adjacency[tail]: output.append((tail, head, self.adjacency[head][tail]) ) return output def lowercase_ ( self ) -> List[Any]: '''simple docstring''' return self.adjacency.keys() @staticmethod def lowercase_ ( lowerCamelCase__=None , lowerCamelCase__=None ) -> str: '''simple docstring''' __lowerCamelCase = Graph() if vertices is None: __lowerCamelCase = [] if edges is None: __lowerCamelCase = [] for vertex in vertices: g.add_vertex(lowerCamelCase__ ) for edge in edges: g.add_edge(*lowerCamelCase__ ) return g class __lowerCAmelCase : """simple docstring""" def __init__( self ) -> Tuple: '''simple docstring''' __lowerCamelCase = {} __lowerCamelCase = {} def __len__( self ) -> Tuple: '''simple docstring''' return len(self.parent ) def lowercase_ ( self , lowerCamelCase__ ) -> List[Any]: '''simple docstring''' if item in self.parent: return self.find(lowerCamelCase__ ) __lowerCamelCase = item __lowerCamelCase = 0 return item def lowercase_ ( self , lowerCamelCase__ ) -> List[str]: '''simple docstring''' if item not in self.parent: return self.make_set(lowerCamelCase__ ) if item != self.parent[item]: __lowerCamelCase = self.find(self.parent[item] ) return self.parent[item] def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ ) -> int: '''simple docstring''' __lowerCamelCase = self.find(lowerCamelCase__ ) __lowerCamelCase = self.find(lowerCamelCase__ ) if roota == roota: return roota if self.rank[roota] > self.rank[roota]: __lowerCamelCase = roota return roota if self.rank[roota] < self.rank[roota]: __lowerCamelCase = roota return roota if self.rank[roota] == self.rank[roota]: self.rank[roota] += 1 __lowerCamelCase = roota return roota return None @staticmethod def lowercase_ ( lowerCamelCase__ ) -> str: '''simple docstring''' __lowerCamelCase = graph.num_vertices __lowerCamelCase = Graph.UnionFind() __lowerCamelCase = [] while num_components > 1: __lowerCamelCase = {} for vertex in graph.get_vertices(): __lowerCamelCase = -1 __lowerCamelCase = graph.get_edges() for edge in edges: __lowerCamelCase , __lowerCamelCase , __lowerCamelCase = edge edges.remove((tail, head, weight) ) for edge in edges: __lowerCamelCase , __lowerCamelCase , __lowerCamelCase = edge __lowerCamelCase = union_find.find(lowerCamelCase__ ) __lowerCamelCase = union_find.find(lowerCamelCase__ ) if seta != seta: if cheap_edge[seta] == -1 or cheap_edge[seta][2] > weight: __lowerCamelCase = [head, tail, weight] if cheap_edge[seta] == -1 or cheap_edge[seta][2] > weight: __lowerCamelCase = [head, tail, weight] for vertex in cheap_edge: if cheap_edge[vertex] != -1: __lowerCamelCase , __lowerCamelCase , __lowerCamelCase = cheap_edge[vertex] if union_find.find(lowerCamelCase__ ) != union_find.find(lowerCamelCase__ ): union_find.union(lowerCamelCase__ , lowerCamelCase__ ) mst_edges.append(cheap_edge[vertex] ) __lowerCamelCase = num_components - 1 __lowerCamelCase = Graph.build(edges=lowerCamelCase__ ) return mst
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'''simple docstring''' import argparse import os import gluonnlp as nlp import mxnet as mx import numpy as np import torch from gluonnlp.base import get_home_dir from gluonnlp.model.bert import BERTEncoder from gluonnlp.model.utils import _load_vocab from gluonnlp.vocab import Vocab from packaging import version from torch import nn from transformers import BertConfig, BertForMaskedLM, BertModel, RobertaTokenizer from transformers.models.bert.modeling_bert import ( BertIntermediate, BertLayer, BertOutput, BertSelfAttention, BertSelfOutput, ) from transformers.utils import logging if version.parse(nlp.__version__) != version.parse("""0.8.3"""): raise Exception("""requires gluonnlp == 0.8.3""") if version.parse(mx.__version__) != version.parse("""1.5.0"""): raise Exception("""requires mxnet == 1.5.0""") logging.set_verbosity_info() lowercase_ = logging.get_logger(__name__) lowercase_ = """The Nymphenburg Palace is a beautiful palace in Munich!""" def lowerCamelCase ( __lowerCamelCase : str , __lowerCamelCase : str ) ->List[str]: _SCREAMING_SNAKE_CASE = { """attention_cell""": """multi_head""", """num_layers""": 4, """units""": 1024, """hidden_size""": 768, """max_length""": 512, """num_heads""": 8, """scaled""": True, """dropout""": 0.1, """use_residual""": True, """embed_size""": 1024, """embed_dropout""": 0.1, """word_embed""": None, """layer_norm_eps""": 1e-5, """token_type_vocab_size""": 2, } _SCREAMING_SNAKE_CASE = bort_4_8_768_1024_hparams # Let's construct the original Bort model here # Taken from official BERT implementation, see: # https://github.com/alexa/bort/blob/master/bort/bort.py _SCREAMING_SNAKE_CASE = BERTEncoder( attention_cell=predefined_args["""attention_cell"""] , num_layers=predefined_args["""num_layers"""] , units=predefined_args["""units"""] , hidden_size=predefined_args["""hidden_size"""] , max_length=predefined_args["""max_length"""] , num_heads=predefined_args["""num_heads"""] , scaled=predefined_args["""scaled"""] , dropout=predefined_args["""dropout"""] , output_attention=UpperCamelCase__ , output_all_encodings=UpperCamelCase__ , use_residual=predefined_args["""use_residual"""] , activation=predefined_args.get("""activation""" , """gelu""" ) , layer_norm_eps=predefined_args.get("""layer_norm_eps""" , UpperCamelCase__ ) , ) # Vocab information needs to be fetched first # It's the same as RoBERTa, so RobertaTokenizer can be used later _SCREAMING_SNAKE_CASE = """openwebtext_ccnews_stories_books_cased""" # Specify download folder to Gluonnlp's vocab _SCREAMING_SNAKE_CASE = os.path.join(get_home_dir() , """models""" ) _SCREAMING_SNAKE_CASE = _load_vocab(UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ , cls=UpperCamelCase__ ) _SCREAMING_SNAKE_CASE = nlp.model.BERTModel( UpperCamelCase__ , len(UpperCamelCase__ ) , units=predefined_args["""units"""] , embed_size=predefined_args["""embed_size"""] , embed_dropout=predefined_args["""embed_dropout"""] , word_embed=predefined_args["""word_embed"""] , use_pooler=UpperCamelCase__ , use_token_type_embed=UpperCamelCase__ , token_type_vocab_size=predefined_args["""token_type_vocab_size"""] , use_classifier=UpperCamelCase__ , use_decoder=UpperCamelCase__ , ) original_bort.load_parameters(UpperCamelCase__ , cast_dtype=UpperCamelCase__ , ignore_extra=UpperCamelCase__ ) _SCREAMING_SNAKE_CASE = original_bort._collect_params_with_prefix() # Build our config 🤗 _SCREAMING_SNAKE_CASE = { """architectures""": ["""BertForMaskedLM"""], """attention_probs_dropout_prob""": predefined_args["""dropout"""], """hidden_act""": """gelu""", """hidden_dropout_prob""": predefined_args["""dropout"""], """hidden_size""": predefined_args["""embed_size"""], """initializer_range""": 0.02, """intermediate_size""": predefined_args["""hidden_size"""], """layer_norm_eps""": predefined_args["""layer_norm_eps"""], """max_position_embeddings""": predefined_args["""max_length"""], """model_type""": """bort""", """num_attention_heads""": predefined_args["""num_heads"""], """num_hidden_layers""": predefined_args["""num_layers"""], """pad_token_id""": 1, # 2 = BERT, 1 = RoBERTa """type_vocab_size""": 1, # 2 = BERT, 1 = RoBERTa """vocab_size""": len(UpperCamelCase__ ), } _SCREAMING_SNAKE_CASE = BertConfig.from_dict(UpperCamelCase__ ) _SCREAMING_SNAKE_CASE = BertForMaskedLM(UpperCamelCase__ ) hf_bort_model.eval() # Parameter mapping table (Gluonnlp to Transformers) # * denotes layer index # # | Gluon Parameter | Transformers Parameter # | -------------------------------------------------------------- | ---------------------- # | `encoder.layer_norm.beta` | `bert.embeddings.LayerNorm.bias` # | `encoder.layer_norm.gamma` | `bert.embeddings.LayerNorm.weight` # | `encoder.position_weight` | `bert.embeddings.position_embeddings.weight` # | `word_embed.0.weight` | `bert.embeddings.word_embeddings.weight` # | `encoder.transformer_cells.*.attention_cell.proj_key.bias` | `bert.encoder.layer.*.attention.self.key.bias` # | `encoder.transformer_cells.*.attention_cell.proj_key.weight` | `bert.encoder.layer.*.attention.self.key.weight` # | `encoder.transformer_cells.*.attention_cell.proj_query.bias` | `bert.encoder.layer.*.attention.self.query.bias` # | `encoder.transformer_cells.*.attention_cell.proj_query.weight` | `bert.encoder.layer.*.attention.self.query.weight` # | `encoder.transformer_cells.*.attention_cell.proj_value.bias` | `bert.encoder.layer.*.attention.self.value.bias` # | `encoder.transformer_cells.*.attention_cell.proj_value.weight` | `bert.encoder.layer.*.attention.self.value.weight` # | `encoder.transformer_cells.*.ffn.ffn_2.bias` | `bert.encoder.layer.*.attention.output.dense.bias` # | `encoder.transformer_cells.*.ffn.ffn_2.weight` | `bert.encoder.layer.*.attention.output.dense.weight` # | `encoder.transformer_cells.*.layer_norm.beta` | `bert.encoder.layer.*.attention.output.LayerNorm.bias` # | `encoder.transformer_cells.*.layer_norm.gamma` | `bert.encoder.layer.*.attention.output.LayerNorm.weight` # | `encoder.transformer_cells.*.ffn.ffn_1.bias` | `bert.encoder.layer.*.intermediate.dense.bias` # | `encoder.transformer_cells.*.ffn.ffn_1.weight` | `bert.encoder.layer.*.intermediate.dense.weight` # | `encoder.transformer_cells.*.ffn.layer_norm.beta` | `bert.encoder.layer.*.output.LayerNorm.bias` # | `encoder.transformer_cells.*.ffn.layer_norm.gamma` | `bert.encoder.layer.*.output.LayerNorm.weight` # | `encoder.transformer_cells.*.proj.bias` | `bert.encoder.layer.*.output.dense.bias` # | `encoder.transformer_cells.*.proj.weight` | `bert.encoder.layer.*.output.dense.weight` # Helper function to convert MXNET Arrays to PyTorch def to_torch(__lowerCamelCase : int ) -> nn.Parameter: return nn.Parameter(torch.FloatTensor(mx_array.data().asnumpy() ) ) # Check param shapes and map new HF param back def check_and_map_params(__lowerCamelCase : Union[str, Any] , __lowerCamelCase : Dict ): _SCREAMING_SNAKE_CASE = hf_param.shape _SCREAMING_SNAKE_CASE = to_torch(params[gluon_param] ) _SCREAMING_SNAKE_CASE = gluon_param.shape assert ( shape_hf == shape_gluon ), F'The gluon parameter {gluon_param} has shape {shape_gluon}, but expects shape {shape_hf} for Transformers' return gluon_param _SCREAMING_SNAKE_CASE = check_and_map_params( hf_bort_model.bert.embeddings.word_embeddings.weight , """word_embed.0.weight""" ) _SCREAMING_SNAKE_CASE = check_and_map_params( hf_bort_model.bert.embeddings.position_embeddings.weight , """encoder.position_weight""" ) _SCREAMING_SNAKE_CASE = check_and_map_params( hf_bort_model.bert.embeddings.LayerNorm.bias , """encoder.layer_norm.beta""" ) _SCREAMING_SNAKE_CASE = check_and_map_params( hf_bort_model.bert.embeddings.LayerNorm.weight , """encoder.layer_norm.gamma""" ) # Inspired by RoBERTa conversion script, we just zero them out (Bort does not use them) _SCREAMING_SNAKE_CASE = torch.zeros_like( hf_bort_model.bert.embeddings.token_type_embeddings.weight.data ) for i in range(hf_bort_config.num_hidden_layers ): _SCREAMING_SNAKE_CASE = hf_bort_model.bert.encoder.layer[i] # self attention _SCREAMING_SNAKE_CASE = layer.attention.self _SCREAMING_SNAKE_CASE = check_and_map_params( self_attn.key.bias.data , F'encoder.transformer_cells.{i}.attention_cell.proj_key.bias' ) _SCREAMING_SNAKE_CASE = check_and_map_params( self_attn.key.weight.data , F'encoder.transformer_cells.{i}.attention_cell.proj_key.weight' ) _SCREAMING_SNAKE_CASE = check_and_map_params( self_attn.query.bias.data , F'encoder.transformer_cells.{i}.attention_cell.proj_query.bias' ) _SCREAMING_SNAKE_CASE = check_and_map_params( self_attn.query.weight.data , F'encoder.transformer_cells.{i}.attention_cell.proj_query.weight' ) _SCREAMING_SNAKE_CASE = check_and_map_params( self_attn.value.bias.data , F'encoder.transformer_cells.{i}.attention_cell.proj_value.bias' ) _SCREAMING_SNAKE_CASE = check_and_map_params( self_attn.value.weight.data , F'encoder.transformer_cells.{i}.attention_cell.proj_value.weight' ) # self attention output _SCREAMING_SNAKE_CASE = layer.attention.output _SCREAMING_SNAKE_CASE = check_and_map_params( self_output.dense.bias , F'encoder.transformer_cells.{i}.proj.bias' ) _SCREAMING_SNAKE_CASE = check_and_map_params( self_output.dense.weight , F'encoder.transformer_cells.{i}.proj.weight' ) _SCREAMING_SNAKE_CASE = check_and_map_params( self_output.LayerNorm.bias , F'encoder.transformer_cells.{i}.layer_norm.beta' ) _SCREAMING_SNAKE_CASE = check_and_map_params( self_output.LayerNorm.weight , F'encoder.transformer_cells.{i}.layer_norm.gamma' ) # intermediate _SCREAMING_SNAKE_CASE = layer.intermediate _SCREAMING_SNAKE_CASE = check_and_map_params( intermediate.dense.bias , F'encoder.transformer_cells.{i}.ffn.ffn_1.bias' ) _SCREAMING_SNAKE_CASE = check_and_map_params( intermediate.dense.weight , F'encoder.transformer_cells.{i}.ffn.ffn_1.weight' ) # output _SCREAMING_SNAKE_CASE = layer.output _SCREAMING_SNAKE_CASE = check_and_map_params( bert_output.dense.bias , F'encoder.transformer_cells.{i}.ffn.ffn_2.bias' ) _SCREAMING_SNAKE_CASE = check_and_map_params( bert_output.dense.weight , F'encoder.transformer_cells.{i}.ffn.ffn_2.weight' ) _SCREAMING_SNAKE_CASE = check_and_map_params( bert_output.LayerNorm.bias , F'encoder.transformer_cells.{i}.ffn.layer_norm.beta' ) _SCREAMING_SNAKE_CASE = check_and_map_params( bert_output.LayerNorm.weight , F'encoder.transformer_cells.{i}.ffn.layer_norm.gamma' ) # Save space and energy 🎄 hf_bort_model.half() # Compare output of both models _SCREAMING_SNAKE_CASE = RobertaTokenizer.from_pretrained("""roberta-base""" ) _SCREAMING_SNAKE_CASE = tokenizer.encode_plus(UpperCamelCase__ )["""input_ids"""] # Get gluon output _SCREAMING_SNAKE_CASE = mx.nd.array([input_ids] ) _SCREAMING_SNAKE_CASE = original_bort(inputs=UpperCamelCase__ , token_types=[] ) # Get Transformer output (save and reload model again) hf_bort_model.save_pretrained(UpperCamelCase__ ) _SCREAMING_SNAKE_CASE = BertModel.from_pretrained(UpperCamelCase__ ) hf_bort_model.eval() _SCREAMING_SNAKE_CASE = tokenizer.encode_plus(UpperCamelCase__ , return_tensors="""pt""" ) _SCREAMING_SNAKE_CASE = hf_bort_model(**UpperCamelCase__ )[0] _SCREAMING_SNAKE_CASE = output_gluon[0].asnumpy() _SCREAMING_SNAKE_CASE = output_hf[0].detach().numpy() _SCREAMING_SNAKE_CASE = np.max(np.abs(hf_layer - gluon_layer ) ).item() _SCREAMING_SNAKE_CASE = np.allclose(UpperCamelCase__ , UpperCamelCase__ , atol=1e-3 ) if success: print("""✔️ Both model do output the same tensors""" ) else: print("""❌ Both model do **NOT** output the same tensors""" ) print("""Absolute difference is:""" , UpperCamelCase__ ) if __name__ == "__main__": lowercase_ = argparse.ArgumentParser() # Required parameters parser.add_argument( """--bort_checkpoint_path""", default=None, type=str, required=True, help="""Path the official Bort params file.""" ) parser.add_argument( """--pytorch_dump_folder_path""", default=None, type=str, required=True, help="""Path to the output PyTorch model.""" ) lowercase_ = parser.parse_args() convert_bort_checkpoint_to_pytorch(args.bort_checkpoint_path, args.pytorch_dump_folder_path)
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from math import pi, sqrt, tan def lowerCamelCase_ ( UpperCamelCase__ : float ) -> float: """simple docstring""" if side_length < 0: raise ValueError('surface_area_cube() only accepts non-negative values' ) return 6 * side_length**2 def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if length < 0 or breadth < 0 or height < 0: raise ValueError('surface_area_cuboid() only accepts non-negative values' ) return 2 * ((length * breadth) + (breadth * height) + (length * height)) def lowerCamelCase_ ( UpperCamelCase__ : float ) -> float: """simple docstring""" if radius < 0: raise ValueError('surface_area_sphere() only accepts non-negative values' ) return 4 * pi * radius**2 def lowerCamelCase_ ( UpperCamelCase__ : float ) -> float: """simple docstring""" if radius < 0: raise ValueError('surface_area_hemisphere() only accepts non-negative values' ) return 3 * pi * radius**2 def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if radius < 0 or height < 0: raise ValueError('surface_area_cone() only accepts non-negative values' ) return pi * radius * (radius + (height**2 + radius**2) ** 0.5) def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if radius_a < 0 or radius_a < 0 or height < 0: raise ValueError( 'surface_area_conical_frustum() only accepts non-negative values' ) __lowerCamelCase = (height**2 + (radius_a - radius_a) ** 2) ** 0.5 return pi * ((slant_height * (radius_a + radius_a)) + radius_a**2 + radius_a**2) def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if radius < 0 or height < 0: raise ValueError('surface_area_cylinder() only accepts non-negative values' ) return 2 * pi * radius * (height + radius) def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if torus_radius < 0 or tube_radius < 0: raise ValueError('surface_area_torus() only accepts non-negative values' ) if torus_radius < tube_radius: raise ValueError( 'surface_area_torus() does not support spindle or self intersecting tori' ) return 4 * pow(UpperCamelCase__ , 2 ) * torus_radius * tube_radius def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if length < 0 or width < 0: raise ValueError('area_rectangle() only accepts non-negative values' ) return length * width def lowerCamelCase_ ( UpperCamelCase__ : float ) -> float: """simple docstring""" if side_length < 0: raise ValueError('area_square() only accepts non-negative values' ) return side_length**2 def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if base < 0 or height < 0: raise ValueError('area_triangle() only accepts non-negative values' ) return (base * height) / 2 def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if sidea < 0 or sidea < 0 or sidea < 0: raise ValueError('area_triangle_three_sides() only accepts non-negative values' ) elif sidea + sidea < sidea or sidea + sidea < sidea or sidea + sidea < sidea: raise ValueError('Given three sides do not form a triangle' ) __lowerCamelCase = (sidea + sidea + sidea) / 2 __lowerCamelCase = sqrt( semi_perimeter * (semi_perimeter - sidea) * (semi_perimeter - sidea) * (semi_perimeter - sidea) ) return area def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if base < 0 or height < 0: raise ValueError('area_parallelogram() only accepts non-negative values' ) return base * height def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if basea < 0 or basea < 0 or height < 0: raise ValueError('area_trapezium() only accepts non-negative values' ) return 1 / 2 * (basea + basea) * height def lowerCamelCase_ ( UpperCamelCase__ : float ) -> float: """simple docstring""" if radius < 0: raise ValueError('area_circle() only accepts non-negative values' ) return pi * radius**2 def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if radius_x < 0 or radius_y < 0: raise ValueError('area_ellipse() only accepts non-negative values' ) return pi * radius_x * radius_y def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if diagonal_a < 0 or diagonal_a < 0: raise ValueError('area_rhombus() only accepts non-negative values' ) return 1 / 2 * diagonal_a * diagonal_a def lowerCamelCase_ ( UpperCamelCase__ : int , UpperCamelCase__ : float ) -> float: """simple docstring""" if not isinstance(UpperCamelCase__ , UpperCamelCase__ ) or sides < 3: raise ValueError( 'area_reg_polygon() only accepts integers greater than or \ equal to three as number of sides' ) elif length < 0: raise ValueError( 'area_reg_polygon() only accepts non-negative values as \ length of a side' ) return (sides * length**2) / (4 * tan(pi / sides )) return (sides * length**2) / (4 * tan(pi / sides )) if __name__ == "__main__": import doctest doctest.testmod(verbose=True) # verbose so we can see methods missing tests print("[DEMO] Areas of various geometric shapes: \n") print(f'''Rectangle: {area_rectangle(10, 20) = }''') print(f'''Square: {area_square(10) = }''') print(f'''Triangle: {area_triangle(10, 10) = }''') print(f'''Triangle: {area_triangle_three_sides(5, 12, 13) = }''') print(f'''Parallelogram: {area_parallelogram(10, 20) = }''') print(f'''Rhombus: {area_rhombus(10, 20) = }''') print(f'''Trapezium: {area_trapezium(10, 20, 30) = }''') print(f'''Circle: {area_circle(20) = }''') print(f'''Ellipse: {area_ellipse(10, 20) = }''') print("\nSurface Areas of various geometric shapes: \n") print(f'''Cube: {surface_area_cube(20) = }''') print(f'''Cuboid: {surface_area_cuboid(10, 20, 30) = }''') print(f'''Sphere: {surface_area_sphere(20) = }''') print(f'''Hemisphere: {surface_area_hemisphere(20) = }''') print(f'''Cone: {surface_area_cone(10, 20) = }''') print(f'''Conical Frustum: {surface_area_conical_frustum(10, 20, 30) = }''') print(f'''Cylinder: {surface_area_cylinder(10, 20) = }''') print(f'''Torus: {surface_area_torus(20, 10) = }''') print(f'''Equilateral Triangle: {area_reg_polygon(3, 10) = }''') print(f'''Square: {area_reg_polygon(4, 10) = }''') print(f'''Reqular Pentagon: {area_reg_polygon(5, 10) = }''')
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def _a ( a :list ) -> list: if len(UpperCamelCase__ ) <= 1: return [tuple(UpperCamelCase__ )] a = [] def generate(a :int , a :list ): if k == 1: res.append(tuple(arr[:] ) ) return generate(k - 1 , UpperCamelCase__ ) for i in range(k - 1 ): if k % 2 == 0: # k is even a , a = arr[k - 1], arr[i] else: # k is odd a , a = arr[k - 1], arr[0] generate(k - 1 , UpperCamelCase__ ) generate(len(UpperCamelCase__ ) , UpperCamelCase__ ) return res if __name__ == "__main__": UpperCAmelCase__ = input("Enter numbers separated by a comma:\n").strip() UpperCAmelCase__ = [int(item) for item in user_input.split(",")] print(heaps(arr))
0
import unittest from transformers import DebertaConfig, is_torch_available from transformers.testing_utils import require_sentencepiece, require_tokenizers, require_torch, slow, torch_device from ...test_configuration_common import ConfigTester from ...test_modeling_common import ModelTesterMixin, ids_tensor from ...test_pipeline_mixin import PipelineTesterMixin if is_torch_available(): import torch from transformers import ( DebertaForMaskedLM, DebertaForQuestionAnswering, DebertaForSequenceClassification, DebertaForTokenClassification, DebertaModel, ) from transformers.models.deberta.modeling_deberta import DEBERTA_PRETRAINED_MODEL_ARCHIVE_LIST class __lowerCAmelCase ( __magic_name__ ): """simple docstring""" def __init__( self , lowerCamelCase__ , lowerCamelCase__=13 , lowerCamelCase__=7 , lowerCamelCase__=True , lowerCamelCase__=True , lowerCamelCase__=True , lowerCamelCase__=True , lowerCamelCase__=99 , lowerCamelCase__=32 , lowerCamelCase__=5 , lowerCamelCase__=4 , lowerCamelCase__=37 , lowerCamelCase__="gelu" , lowerCamelCase__=0.1 , lowerCamelCase__=0.1 , lowerCamelCase__=512 , lowerCamelCase__=16 , lowerCamelCase__=2 , lowerCamelCase__=0.02 , lowerCamelCase__=False , lowerCamelCase__=True , lowerCamelCase__="None" , lowerCamelCase__=3 , lowerCamelCase__=4 , lowerCamelCase__=None , ) -> int: '''simple docstring''' __lowerCamelCase = parent __lowerCamelCase = batch_size __lowerCamelCase = seq_length __lowerCamelCase = is_training __lowerCamelCase = use_input_mask __lowerCamelCase = use_token_type_ids __lowerCamelCase = use_labels __lowerCamelCase = vocab_size __lowerCamelCase = hidden_size __lowerCamelCase = num_hidden_layers __lowerCamelCase = num_attention_heads __lowerCamelCase = intermediate_size __lowerCamelCase = hidden_act __lowerCamelCase = hidden_dropout_prob __lowerCamelCase = attention_probs_dropout_prob __lowerCamelCase = max_position_embeddings __lowerCamelCase = type_vocab_size __lowerCamelCase = type_sequence_label_size __lowerCamelCase = initializer_range __lowerCamelCase = num_labels __lowerCamelCase = num_choices __lowerCamelCase = relative_attention __lowerCamelCase = position_biased_input __lowerCamelCase = pos_att_type __lowerCamelCase = scope def lowercase_ ( self ) -> str: '''simple docstring''' __lowerCamelCase = ids_tensor([self.batch_size, self.seq_length] , self.vocab_size ) __lowerCamelCase = None if self.use_input_mask: __lowerCamelCase = ids_tensor([self.batch_size, self.seq_length] , vocab_size=2 ) __lowerCamelCase = None if self.use_token_type_ids: __lowerCamelCase = ids_tensor([self.batch_size, self.seq_length] , self.type_vocab_size ) __lowerCamelCase = None __lowerCamelCase = None __lowerCamelCase = None if self.use_labels: __lowerCamelCase = ids_tensor([self.batch_size] , self.type_sequence_label_size ) __lowerCamelCase = ids_tensor([self.batch_size, self.seq_length] , self.num_labels ) __lowerCamelCase = ids_tensor([self.batch_size] , self.num_choices ) __lowerCamelCase = self.get_config() return config, input_ids, token_type_ids, input_mask, sequence_labels, token_labels, choice_labels def lowercase_ ( self ) -> Optional[Any]: '''simple docstring''' return DebertaConfig( 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 , relative_attention=self.relative_attention , position_biased_input=self.position_biased_input , pos_att_type=self.pos_att_type , ) def lowercase_ ( self ) -> List[str]: '''simple docstring''' __lowerCamelCase = self.get_config() __lowerCamelCase = 300 return config def lowercase_ ( self , lowerCamelCase__ ) -> Optional[int]: '''simple docstring''' self.parent.assertListEqual(list(result.loss.size() ) , [] ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> Any: '''simple docstring''' __lowerCamelCase = DebertaModel(config=lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model(lowerCamelCase__ , attention_mask=lowerCamelCase__ , token_type_ids=lowerCamelCase__ )[0] __lowerCamelCase = model(lowerCamelCase__ , token_type_ids=lowerCamelCase__ )[0] __lowerCamelCase = model(lowerCamelCase__ )[0] self.parent.assertListEqual(list(sequence_output.size() ) , [self.batch_size, self.seq_length, self.hidden_size] ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> Tuple: '''simple docstring''' __lowerCamelCase = DebertaForMaskedLM(config=lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model(lowerCamelCase__ , attention_mask=lowerCamelCase__ , token_type_ids=lowerCamelCase__ , labels=lowerCamelCase__ ) self.parent.assertEqual(result.logits.shape , (self.batch_size, self.seq_length, self.vocab_size) ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> Union[str, Any]: '''simple docstring''' __lowerCamelCase = self.num_labels __lowerCamelCase = DebertaForSequenceClassification(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model(lowerCamelCase__ , attention_mask=lowerCamelCase__ , token_type_ids=lowerCamelCase__ , labels=lowerCamelCase__ ) self.parent.assertListEqual(list(result.logits.size() ) , [self.batch_size, self.num_labels] ) self.check_loss_output(lowerCamelCase__ ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> Optional[int]: '''simple docstring''' __lowerCamelCase = self.num_labels __lowerCamelCase = DebertaForTokenClassification(config=lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model(lowerCamelCase__ , attention_mask=lowerCamelCase__ , token_type_ids=lowerCamelCase__ , labels=lowerCamelCase__ ) self.parent.assertEqual(result.logits.shape , (self.batch_size, self.seq_length, self.num_labels) ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> Dict: '''simple docstring''' __lowerCamelCase = DebertaForQuestionAnswering(config=lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model( lowerCamelCase__ , attention_mask=lowerCamelCase__ , token_type_ids=lowerCamelCase__ , start_positions=lowerCamelCase__ , end_positions=lowerCamelCase__ , ) self.parent.assertEqual(result.start_logits.shape , (self.batch_size, self.seq_length) ) self.parent.assertEqual(result.end_logits.shape , (self.batch_size, self.seq_length) ) def lowercase_ ( self ) -> Union[str, Any]: '''simple docstring''' __lowerCamelCase = self.prepare_config_and_inputs() ( ( __lowerCamelCase ) , ( __lowerCamelCase ) , ( __lowerCamelCase ) , ( __lowerCamelCase ) , ( __lowerCamelCase ) , ( __lowerCamelCase ) , ( __lowerCamelCase ) , ) = config_and_inputs __lowerCamelCase = {'input_ids': input_ids, 'token_type_ids': token_type_ids, 'attention_mask': input_mask} return config, inputs_dict @require_torch class __lowerCAmelCase ( __magic_name__ , __magic_name__ , unittest.TestCase ): """simple docstring""" snake_case_ = ( ( DebertaModel, DebertaForMaskedLM, DebertaForSequenceClassification, DebertaForTokenClassification, DebertaForQuestionAnswering, ) if is_torch_available() else () ) snake_case_ = ( { '''feature-extraction''': DebertaModel, '''fill-mask''': DebertaForMaskedLM, '''question-answering''': DebertaForQuestionAnswering, '''text-classification''': DebertaForSequenceClassification, '''token-classification''': DebertaForTokenClassification, '''zero-shot''': DebertaForSequenceClassification, } if is_torch_available() else {} ) snake_case_ = True snake_case_ = False snake_case_ = False snake_case_ = False snake_case_ = False def lowercase_ ( self ) -> List[Any]: '''simple docstring''' __lowerCamelCase = DebertaModelTester(self ) __lowerCamelCase = ConfigTester(self , config_class=lowerCamelCase__ , hidden_size=37 ) def lowercase_ ( self ) -> Optional[int]: '''simple docstring''' self.config_tester.run_common_tests() def lowercase_ ( self ) -> List[str]: '''simple docstring''' __lowerCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_deberta_model(*lowerCamelCase__ ) def lowercase_ ( self ) -> Optional[int]: '''simple docstring''' __lowerCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_deberta_for_sequence_classification(*lowerCamelCase__ ) def lowercase_ ( self ) -> Dict: '''simple docstring''' __lowerCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_deberta_for_masked_lm(*lowerCamelCase__ ) def lowercase_ ( self ) -> Optional[Any]: '''simple docstring''' __lowerCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_deberta_for_question_answering(*lowerCamelCase__ ) def lowercase_ ( self ) -> str: '''simple docstring''' __lowerCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_deberta_for_token_classification(*lowerCamelCase__ ) @slow def lowercase_ ( self ) -> Optional[int]: '''simple docstring''' for model_name in DEBERTA_PRETRAINED_MODEL_ARCHIVE_LIST[:1]: __lowerCamelCase = DebertaModel.from_pretrained(lowerCamelCase__ ) self.assertIsNotNone(lowerCamelCase__ ) @require_torch @require_sentencepiece @require_tokenizers class __lowerCAmelCase ( unittest.TestCase ): """simple docstring""" @unittest.skip(reason='Model not available yet' ) def lowercase_ ( self ) -> Union[str, Any]: '''simple docstring''' pass @slow def lowercase_ ( self ) -> Tuple: '''simple docstring''' __lowerCamelCase = DebertaModel.from_pretrained('microsoft/deberta-base' ) __lowerCamelCase = torch.tensor([[0, 31_414, 232, 328, 740, 1_140, 12_695, 69, 46_078, 1_588, 2]] ) __lowerCamelCase = torch.tensor([[0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1]] ) with torch.no_grad(): __lowerCamelCase = model(lowerCamelCase__ , attention_mask=lowerCamelCase__ )[0] # compare the actual values for a slice. __lowerCamelCase = torch.tensor( [[[-0.59_86, -0.80_55, -0.84_62], [1.44_84, -0.93_48, -0.80_59], [0.31_23, 0.00_32, -1.41_31]]] ) self.assertTrue(torch.allclose(output[:, 1:4, 1:4] , lowerCamelCase__ , atol=1e-4 ) , f"""{output[:, 1:4, 1:4]}""" )
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import unittest from datasets import load_dataset from transformers import BloomTokenizerFast from transformers.testing_utils import require_tokenizers from ...test_tokenization_common import TokenizerTesterMixin @require_tokenizers class lowercase_ ( UpperCamelCase_ , unittest.TestCase ): """simple docstring""" UpperCAmelCase_ : Optional[Any] = None UpperCAmelCase_ : Union[str, Any] = BloomTokenizerFast UpperCAmelCase_ : int = BloomTokenizerFast UpperCAmelCase_ : str = True UpperCAmelCase_ : Any = False UpperCAmelCase_ : Optional[Any] = """tokenizer_file""" UpperCAmelCase_ : Dict = {"""bos_token""": """<s>""", """eos_token""": """</s>""", """unk_token""": """<unk>""", """pad_token""": """<pad>"""} def SCREAMING_SNAKE_CASE_ ( self ) ->str: super().setUp() lowerCAmelCase = BloomTokenizerFast.from_pretrained('''bigscience/tokenizer''' ) tokenizer.save_pretrained(self.tmpdirname ) def SCREAMING_SNAKE_CASE_ ( self , **__SCREAMING_SNAKE_CASE ) ->Optional[int]: kwargs.update(self.special_tokens_map ) return BloomTokenizerFast.from_pretrained(self.tmpdirname , **lowerCamelCase__ ) def SCREAMING_SNAKE_CASE_ ( self ) ->Union[str, Any]: lowerCAmelCase = self.get_rust_tokenizer() lowerCAmelCase = ['''The quick brown fox</s>''', '''jumps over the lazy dog</s>'''] lowerCAmelCase = [[2175, 23714, 73173, 144252, 2], [77, 132619, 3478, 368, 109586, 35433, 2]] lowerCAmelCase = tokenizer.batch_encode_plus(lowerCamelCase__ )['''input_ids'''] self.assertListEqual(lowerCamelCase__ , lowerCamelCase__ ) lowerCAmelCase = tokenizer.batch_decode(lowerCamelCase__ ) self.assertListEqual(lowerCamelCase__ , lowerCamelCase__ ) def SCREAMING_SNAKE_CASE_ ( self , __SCREAMING_SNAKE_CASE=6 ) ->Optional[int]: for tokenizer, pretrained_name, kwargs in self.tokenizers_list: with self.subTest(F"{tokenizer.__class__.__name__} ({pretrained_name})" ): lowerCAmelCase = self.rust_tokenizer_class.from_pretrained(lowerCamelCase__ , **lowerCamelCase__ ) # tokenizer_r.pad_token = None # Hotfixing padding = None # Simple input lowerCAmelCase = '''This is a simple input''' lowerCAmelCase = ['''This is a simple input 1''', '''This is a simple input 2'''] lowerCAmelCase = ('''This is a simple input''', '''This is a pair''') lowerCAmelCase = [ ('''This is a simple input 1''', '''This is a simple input 2'''), ('''This is a simple pair 1''', '''This is a simple pair 2'''), ] # Simple input tests try: tokenizer_r.encode(lowerCamelCase__ , max_length=lowerCamelCase__ ) tokenizer_r.encode_plus(lowerCamelCase__ , max_length=lowerCamelCase__ ) tokenizer_r.batch_encode_plus(lowerCamelCase__ , max_length=lowerCamelCase__ ) tokenizer_r.encode(lowerCamelCase__ , max_length=lowerCamelCase__ ) tokenizer_r.batch_encode_plus(lowerCamelCase__ , max_length=lowerCamelCase__ ) except ValueError: self.fail('''Bloom Tokenizer should be able to deal with padding''' ) lowerCAmelCase = None # Hotfixing padding = None self.assertRaises(lowerCamelCase__ , tokenizer_r.encode , lowerCamelCase__ , max_length=lowerCamelCase__ , padding='''max_length''' ) # Simple input self.assertRaises(lowerCamelCase__ , tokenizer_r.encode_plus , lowerCamelCase__ , max_length=lowerCamelCase__ , padding='''max_length''' ) # Simple input self.assertRaises( lowerCamelCase__ , tokenizer_r.batch_encode_plus , lowerCamelCase__ , max_length=lowerCamelCase__ , padding='''max_length''' , ) # Pair input self.assertRaises(lowerCamelCase__ , tokenizer_r.encode , lowerCamelCase__ , max_length=lowerCamelCase__ , padding='''max_length''' ) # Pair input self.assertRaises(lowerCamelCase__ , tokenizer_r.encode_plus , lowerCamelCase__ , max_length=lowerCamelCase__ , padding='''max_length''' ) # Pair input self.assertRaises( lowerCamelCase__ , tokenizer_r.batch_encode_plus , lowerCamelCase__ , max_length=lowerCamelCase__ , padding='''max_length''' , ) def SCREAMING_SNAKE_CASE_ ( self ) ->Tuple: lowerCAmelCase = self.get_rust_tokenizer() lowerCAmelCase = load_dataset('''xnli''' , '''all_languages''' , split='''test''' , streaming=lowerCamelCase__ ) lowerCAmelCase = next(iter(lowerCamelCase__ ) )['''premise'''] # pick up one data lowerCAmelCase = list(sample_data.values() ) lowerCAmelCase = list(map(tokenizer.encode , lowerCamelCase__ ) ) lowerCAmelCase = [tokenizer.decode(lowerCamelCase__ , clean_up_tokenization_spaces=lowerCamelCase__ ) for x in output_tokens] self.assertListEqual(lowerCamelCase__ , lowerCamelCase__ ) def SCREAMING_SNAKE_CASE_ ( self ) ->str: self.assertGreaterEqual(len(self.tokenizer_class.pretrained_vocab_files_map ) , 1 ) self.assertGreaterEqual(len(list(self.tokenizer_class.pretrained_vocab_files_map.values() )[0] ) , 1 )
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from __future__ import annotations # This is the precision for this function which can be altered. # It is recommended for users to keep this number greater than or equal to 10. __A = 10 def lowerCamelCase_ ( UpperCamelCase__ : int , UpperCamelCase__ : int , UpperCamelCase__ : list[int] , UpperCamelCase__ : int ) -> int: """simple docstring""" for i in range(UpperCamelCase__ , UpperCamelCase__ ): if array[i] == target: return i return -1 def lowerCamelCase_ ( UpperCamelCase__ : list[int] , UpperCamelCase__ : int ) -> int: """simple docstring""" __lowerCamelCase = 0 __lowerCamelCase = len(UpperCamelCase__ ) while left <= right: if right - left < precision: return lin_search(UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ ) __lowerCamelCase = (left + right) // 3 + 1 __lowerCamelCase = 2 * (left + right) // 3 + 1 if array[one_third] == target: return one_third elif array[two_third] == target: return two_third elif target < array[one_third]: __lowerCamelCase = one_third - 1 elif array[two_third] < target: __lowerCamelCase = two_third + 1 else: __lowerCamelCase = one_third + 1 __lowerCamelCase = two_third - 1 else: return -1 def lowerCamelCase_ ( UpperCamelCase__ : int , UpperCamelCase__ : int , UpperCamelCase__ : list[int] , UpperCamelCase__ : int ) -> int: """simple docstring""" if left < right: if right - left < precision: return lin_search(UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ ) __lowerCamelCase = (left + right) // 3 + 1 __lowerCamelCase = 2 * (left + right) // 3 + 1 if array[one_third] == target: return one_third elif array[two_third] == target: return two_third elif target < array[one_third]: return rec_ternary_search(UpperCamelCase__ , one_third - 1 , UpperCamelCase__ , UpperCamelCase__ ) elif array[two_third] < target: return rec_ternary_search(two_third + 1 , UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ ) else: return rec_ternary_search(one_third + 1 , two_third - 1 , UpperCamelCase__ , UpperCamelCase__ ) else: return -1 if __name__ == "__main__": import doctest doctest.testmod() __A = input("Enter numbers separated by comma:\n").strip() __A = [int(item.strip()) for item in user_input.split(",")] assert collection == sorted(collection), f"List must be ordered.\n{collection}." __A = int(input("Enter the number to be found in the list:\n").strip()) __A = ite_ternary_search(collection, target) __A = rec_ternary_search(0, len(collection) - 1, collection, target) if resulta != -1: print(f'''Iterative search: {target} found at positions: {resulta}''') print(f'''Recursive search: {target} found at positions: {resulta}''') else: print("Not found")
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"""simple docstring""" import multiprocessing from typing import TYPE_CHECKING, Optional, Union from .. import Dataset, Features, config from ..formatting import query_table from ..packaged_modules.sql.sql import Sql from ..utils import logging from .abc import AbstractDatasetInputStream if TYPE_CHECKING: import sqlitea import sqlalchemy class __snake_case ( __lowerCAmelCase ): def __init__( self , lowercase , lowercase , lowercase = None , lowercase = None , lowercase = False , **lowercase , ) -> str: '''simple docstring''' super().__init__(features=lowerCamelCase__ , cache_dir=lowerCamelCase__ , keep_in_memory=lowerCamelCase__ , **lowerCamelCase__) a__: Tuple = Sql( cache_dir=lowerCamelCase__ , features=lowerCamelCase__ , sql=lowerCamelCase__ , con=lowerCamelCase__ , **lowerCamelCase__ , ) def lowerCamelCase_ ( self) -> int: '''simple docstring''' a__: Tuple = None a__: int = None a__: Union[str, Any] = None a__: Optional[int] = None self.builder.download_and_prepare( download_config=lowerCamelCase__ , download_mode=lowerCamelCase__ , verification_mode=lowerCamelCase__ , base_path=lowerCamelCase__ , ) # Build dataset for splits a__: Any = self.builder.as_dataset( split='train' , verification_mode=lowerCamelCase__ , in_memory=self.keep_in_memory) return dataset class __snake_case : def __init__( self , lowercase , lowercase , lowercase , lowercase = None , lowercase = None , **lowercase , ) -> List[str]: '''simple docstring''' if num_proc is not None and num_proc <= 0: raise ValueError(f'num_proc {num_proc} must be an integer > 0.') a__: Dict = dataset a__: str = name a__: List[Any] = con a__: str = batch_size if batch_size else config.DEFAULT_MAX_BATCH_SIZE a__: int = num_proc a__: Optional[int] = to_sql_kwargs def lowerCamelCase_ ( self) -> int: '''simple docstring''' a__: List[str] = self.to_sql_kwargs.pop('sql' , lowerCamelCase__) a__: List[str] = self.to_sql_kwargs.pop('con' , lowerCamelCase__) a__: str = self.to_sql_kwargs.pop('index' , lowerCamelCase__) a__: Optional[int] = self._write(index=lowerCamelCase__ , **self.to_sql_kwargs) return written def lowerCamelCase_ ( self , lowercase) -> Union[str, Any]: '''simple docstring''' a__ , a__ , a__: Optional[int] = args a__: Tuple = {**to_sql_kwargs, 'if_exists': 'append'} if offset > 0 else to_sql_kwargs a__: List[Any] = query_table( table=self.dataset.data , key=slice(lowerCamelCase__ , offset + self.batch_size) , indices=self.dataset._indices , ) a__: int = batch.to_pandas() a__: List[str] = df.to_sql(self.name , self.con , index=lowerCamelCase__ , **lowerCamelCase__) return num_rows or len(lowerCamelCase__) def lowerCamelCase_ ( self , lowercase , **lowercase) -> int: '''simple docstring''' a__: Dict = 0 if self.num_proc is None or self.num_proc == 1: for offset in logging.tqdm( range(0 , len(self.dataset) , self.batch_size) , unit='ba' , disable=not logging.is_progress_bar_enabled() , desc='Creating SQL from Arrow format' , ): written += self._batch_sql((offset, index, to_sql_kwargs)) else: a__ , a__: Union[str, Any] = len(self.dataset), self.batch_size with multiprocessing.Pool(self.num_proc) as pool: for num_rows in logging.tqdm( pool.imap( self._batch_sql , [(offset, index, to_sql_kwargs) for offset in range(0 , lowerCamelCase__ , lowerCamelCase__)] , ) , total=(num_rows // batch_size) + 1 if num_rows % batch_size else num_rows // batch_size , unit='ba' , disable=not logging.is_progress_bar_enabled() , desc='Creating SQL from Arrow format' , ): written += num_rows return written
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import string # frequency taken from https://en.wikipedia.org/wiki/Letter_frequency __A = { "E": 1_2.7_0, "T": 9.0_6, "A": 8.1_7, "O": 7.5_1, "I": 6.9_7, "N": 6.7_5, "S": 6.3_3, "H": 6.0_9, "R": 5.9_9, "D": 4.2_5, "L": 4.0_3, "C": 2.7_8, "U": 2.7_6, "M": 2.4_1, "W": 2.3_6, "F": 2.2_3, "G": 2.0_2, "Y": 1.9_7, "P": 1.9_3, "B": 1.2_9, "V": 0.9_8, "K": 0.7_7, "J": 0.1_5, "X": 0.1_5, "Q": 0.1_0, "Z": 0.0_7, } __A = "ETAOINSHRDLCUMWFGYPBVKJXQZ" __A = "ABCDEFGHIJKLMNOPQRSTUVWXYZ" def lowerCamelCase_ ( UpperCamelCase__ : str ) -> dict[str, int]: """simple docstring""" __lowerCamelCase = {letter: 0 for letter in string.ascii_uppercase} for letter in message.upper(): if letter in LETTERS: letter_count[letter] += 1 return letter_count def lowerCamelCase_ ( UpperCamelCase__ : tuple ) -> str: """simple docstring""" return x[0] def lowerCamelCase_ ( UpperCamelCase__ : str ) -> str: """simple docstring""" __lowerCamelCase = get_letter_count(UpperCamelCase__ ) __lowerCamelCase = { freq: [] for letter, freq in letter_to_freq.items() } for letter in LETTERS: freq_to_letter[letter_to_freq[letter]].append(UpperCamelCase__ ) __lowerCamelCase = {} for freq in freq_to_letter: freq_to_letter[freq].sort(key=ETAOIN.find , reverse=UpperCamelCase__ ) __lowerCamelCase = ''.join(freq_to_letter[freq] ) __lowerCamelCase = list(freq_to_letter_str.items() ) freq_pairs.sort(key=UpperCamelCase__ , reverse=UpperCamelCase__ ) __lowerCamelCase = [freq_pair[1] for freq_pair in freq_pairs] return "".join(UpperCamelCase__ ) def lowerCamelCase_ ( UpperCamelCase__ : str ) -> int: """simple docstring""" __lowerCamelCase = get_frequency_order(UpperCamelCase__ ) __lowerCamelCase = 0 for common_letter in ETAOIN[:6]: if common_letter in freq_order[:6]: match_score += 1 for uncommon_letter in ETAOIN[-6:]: if uncommon_letter in freq_order[-6:]: match_score += 1 return match_score if __name__ == "__main__": import doctest doctest.testmod()
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"""simple docstring""" import copy import inspect import unittest from transformers import PretrainedConfig, SwiftFormerConfig 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, floats_tensor, ids_tensor from ...test_pipeline_mixin import PipelineTesterMixin if is_torch_available(): import torch from torch import nn from transformers import SwiftFormerForImageClassification, SwiftFormerModel from transformers.models.swiftformer.modeling_swiftformer import SWIFTFORMER_PRETRAINED_MODEL_ARCHIVE_LIST if is_vision_available(): from PIL import Image from transformers import ViTImageProcessor class _UpperCAmelCase : def __init__( self : List[Any] , _lowercase : int , _lowercase : Dict=13 , _lowercase : List[Any]=3 , _lowercase : List[Any]=True , _lowercase : List[str]=True , _lowercase : Dict=0.1 , _lowercase : Any=0.1 , _lowercase : str=2_24 , _lowercase : Union[str, Any]=10_00 , _lowercase : Union[str, Any]=[3, 3, 6, 4] , _lowercase : str=[48, 56, 1_12, 2_20] , ): __UpperCAmelCase = parent __UpperCAmelCase = batch_size __UpperCAmelCase = num_channels __UpperCAmelCase = is_training __UpperCAmelCase = use_labels __UpperCAmelCase = hidden_dropout_prob __UpperCAmelCase = attention_probs_dropout_prob __UpperCAmelCase = num_labels __UpperCAmelCase = image_size __UpperCAmelCase = layer_depths __UpperCAmelCase = embed_dims def a ( self : Tuple ): __UpperCAmelCase = floats_tensor([self.batch_size, self.num_channels, self.image_size, self.image_size] ) __UpperCAmelCase = None if self.use_labels: __UpperCAmelCase = ids_tensor([self.batch_size] , self.num_labels ) __UpperCAmelCase = self.get_config() return config, pixel_values, labels def a ( self : Optional[int] ): return SwiftFormerConfig( depths=self.layer_depths , embed_dims=self.embed_dims , mlp_ratio=4 , downsamples=[True, True, True, True] , hidden_act='''gelu''' , num_labels=self.num_labels , down_patch_size=3 , down_stride=2 , down_pad=1 , drop_rate=0.0 , drop_path_rate=0.0 , use_layer_scale=lowerCamelCase__ , layer_scale_init_value=1E-5 , ) def a ( self : int , _lowercase : Any , _lowercase : str , _lowercase : List[Any] ): __UpperCAmelCase = SwiftFormerModel(config=lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __UpperCAmelCase = model(lowerCamelCase__ ) self.parent.assertEqual(result.last_hidden_state.shape , (self.batch_size, self.embed_dims[-1], 7, 7) ) def a ( self : str , _lowercase : Optional[Any] , _lowercase : Any , _lowercase : int ): __UpperCAmelCase = self.num_labels __UpperCAmelCase = SwiftFormerForImageClassification(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __UpperCAmelCase = model(lowerCamelCase__ , labels=lowerCamelCase__ ) self.parent.assertEqual(result.logits.shape , (self.batch_size, self.num_labels) ) __UpperCAmelCase = SwiftFormerForImageClassification(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __UpperCAmelCase = floats_tensor([self.batch_size, self.num_channels, self.image_size, self.image_size] ) __UpperCAmelCase = model(lowerCamelCase__ ) self.parent.assertEqual(result.logits.shape , (self.batch_size, self.num_labels) ) def a ( self : Tuple ): ((__UpperCAmelCase) , (__UpperCAmelCase) , (__UpperCAmelCase)) = self.prepare_config_and_inputs() __UpperCAmelCase = {'''pixel_values''': pixel_values} return config, inputs_dict @require_torch class _UpperCAmelCase ( _lowerCAmelCase , _lowerCAmelCase , unittest.TestCase ): a__ : Dict = (SwiftFormerModel, SwiftFormerForImageClassification) if is_torch_available() else () a__ : List[str] = ( {"feature-extraction": SwiftFormerModel, "image-classification": SwiftFormerForImageClassification} if is_torch_available() else {} ) a__ : Union[str, Any] = False a__ : Union[str, Any] = False a__ : Tuple = False a__ : List[Any] = False a__ : Any = False def a ( self : str ): __UpperCAmelCase = SwiftFormerModelTester(self ) __UpperCAmelCase = ConfigTester( self , config_class=lowerCamelCase__ , has_text_modality=lowerCamelCase__ , hidden_size=37 , num_attention_heads=12 , num_hidden_layers=12 , ) def a ( self : Tuple ): self.config_tester.run_common_tests() @unittest.skip(reason='''SwiftFormer does not use inputs_embeds''' ) def a ( self : List[Any] ): pass def a ( self : Dict ): __UpperCAmelCase , __UpperCAmelCase = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: __UpperCAmelCase = model_class(lowerCamelCase__ ) __UpperCAmelCase = model.get_output_embeddings() self.assertTrue(x is None or isinstance(lowerCamelCase__ , nn.Linear ) ) def a ( self : Optional[int] ): __UpperCAmelCase , __UpperCAmelCase = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: __UpperCAmelCase = model_class(lowerCamelCase__ ) __UpperCAmelCase = inspect.signature(model.forward ) # signature.parameters is an OrderedDict => so arg_names order is deterministic __UpperCAmelCase = [*signature.parameters.keys()] __UpperCAmelCase = ['''pixel_values'''] self.assertListEqual(arg_names[:1] , lowerCamelCase__ ) def a ( self : List[Any] ): __UpperCAmelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_model(*lowerCamelCase__ ) def a ( self : Optional[int] ): __UpperCAmelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_for_image_classification(*lowerCamelCase__ ) @slow def a ( self : Optional[Any] ): for model_name in SWIFTFORMER_PRETRAINED_MODEL_ARCHIVE_LIST[:1]: __UpperCAmelCase = SwiftFormerModel.from_pretrained(lowerCamelCase__ ) self.assertIsNotNone(lowerCamelCase__ ) @unittest.skip(reason='''SwiftFormer does not output attentions''' ) def a ( self : Optional[int] ): pass def a ( self : Dict ): def check_hidden_states_output(_lowercase : Tuple , _lowercase : int , _lowercase : int ): __UpperCAmelCase = model_class(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() with torch.no_grad(): __UpperCAmelCase = model(**self._prepare_for_class(lowerCamelCase__ , lowerCamelCase__ ) ) __UpperCAmelCase = outputs.hidden_states __UpperCAmelCase = 8 self.assertEqual(len(lowerCamelCase__ ) , lowerCamelCase__ ) # TODO # SwiftFormer's feature maps are of shape (batch_size, embed_dims, height, width) # with the width and height being successively divided by 2, after every 2 blocks for i in range(len(lowerCamelCase__ ) ): self.assertEqual( hidden_states[i].shape , torch.Size( [ self.model_tester.batch_size, self.model_tester.embed_dims[i // 2], (self.model_tester.image_size // 4) // 2 ** (i // 2), (self.model_tester.image_size // 4) // 2 ** (i // 2), ] ) , ) __UpperCAmelCase , __UpperCAmelCase = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: __UpperCAmelCase = True check_hidden_states_output(lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) # check that output_hidden_states also work using config del inputs_dict["output_hidden_states"] __UpperCAmelCase = True check_hidden_states_output(lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) def a ( self : List[str] ): def _config_zero_init(_lowercase : Optional[Any] ): __UpperCAmelCase = copy.deepcopy(lowerCamelCase__ ) for key in configs_no_init.__dict__.keys(): if "_range" in key or "_std" in key or "initializer_factor" in key or "layer_scale" in key: setattr(lowerCamelCase__ , lowerCamelCase__ , 1E-10 ) if isinstance(getattr(lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) , lowerCamelCase__ ): __UpperCAmelCase = _config_zero_init(getattr(lowerCamelCase__ , lowerCamelCase__ ) ) setattr(lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) return configs_no_init __UpperCAmelCase , __UpperCAmelCase = self.model_tester.prepare_config_and_inputs_for_common() __UpperCAmelCase = _config_zero_init(lowerCamelCase__ ) for model_class in self.all_model_classes: __UpperCAmelCase = model_class(config=lowerCamelCase__ ) for name, param in model.named_parameters(): if param.requires_grad: self.assertIn( ((param.data.mean() * 1E9) / 1E9).round().item() , [0.0, 1.0] , msg=F'''Parameter {name} of model {model_class} seems not properly initialized''' , ) @unittest.skip('''Will be fixed soon by reducing the size of the model used for common tests.''' ) def a ( self : Optional[int] ): pass def lowercase__ ( ): __UpperCAmelCase = Image.open('''./tests/fixtures/tests_samples/COCO/000000039769.png''' ) return image @require_torch @require_vision class _UpperCAmelCase ( unittest.TestCase ): @cached_property def a ( self : int ): return ViTImageProcessor.from_pretrained('''MBZUAI/swiftformer-xs''' ) if is_vision_available() else None @slow def a ( self : List[Any] ): __UpperCAmelCase = SwiftFormerForImageClassification.from_pretrained('''MBZUAI/swiftformer-xs''' ).to(lowerCamelCase__ ) __UpperCAmelCase = self.default_image_processor __UpperCAmelCase = prepare_img() __UpperCAmelCase = image_processor(images=lowerCamelCase__ , return_tensors='''pt''' ).to(lowerCamelCase__ ) # forward pass with torch.no_grad(): __UpperCAmelCase = model(**lowerCamelCase__ ) # verify the logits __UpperCAmelCase = torch.Size((1, 10_00) ) self.assertEqual(outputs.logits.shape , lowerCamelCase__ ) __UpperCAmelCase = torch.tensor([[-2.1703E00, 2.1107E00, -2.0811E00]] ).to(lowerCamelCase__ ) self.assertTrue(torch.allclose(outputs.logits[0, :3] , lowerCamelCase__ , atol=1E-4 ) )
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class __lowerCAmelCase : """simple docstring""" def __init__( self , lowerCamelCase__ ) -> Any: '''simple docstring''' __lowerCamelCase = n __lowerCamelCase = [None] * self.n __lowerCamelCase = 0 # index of the first element __lowerCamelCase = 0 __lowerCamelCase = 0 def __len__( self ) -> int: '''simple docstring''' return self.size def lowercase_ ( self ) -> bool: '''simple docstring''' return self.size == 0 def lowercase_ ( self ) -> str: '''simple docstring''' return False if self.is_empty() else self.array[self.front] def lowercase_ ( self , lowerCamelCase__ ) -> Optional[Any]: '''simple docstring''' if self.size >= self.n: raise Exception('QUEUE IS FULL' ) __lowerCamelCase = data __lowerCamelCase = (self.rear + 1) % self.n self.size += 1 return self def lowercase_ ( self ) -> Tuple: '''simple docstring''' if self.size == 0: raise Exception('UNDERFLOW' ) __lowerCamelCase = self.array[self.front] __lowerCamelCase = None __lowerCamelCase = (self.front + 1) % self.n self.size -= 1 return temp
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'''simple docstring''' from typing import List, Optional, Union import numpy as np import PIL.Image from ...image_processing_utils import BaseImageProcessor, BatchFeature from ...image_transforms import rescale, resize, to_channel_dimension_format from ...image_utils import ( ChannelDimension, PILImageResampling, get_image_size, make_list_of_images, to_numpy_array, valid_images, ) from ...utils import TensorType, logging __lowerCAmelCase = logging.get_logger(__name__) class UpperCAmelCase__ ( lowercase__ ): """simple docstring""" __UpperCAmelCase : Union[str, Any] = ['''pixel_values'''] def __init__( self : Optional[Any] ,_a : List[str] = True ,_a : List[Any] = 32 ,_a : Optional[int]=PILImageResampling.BILINEAR ,_a : Optional[int] = True ,**_a : List[str] ,): '''simple docstring''' _a : Optional[int] = do_resize _a : Optional[int] = do_rescale _a : List[Any] = size_divisor _a : Optional[int] = resample super().__init__(**lowerCamelCase__ ) def __lowercase ( self : Dict ,_a : Any ,_a : List[Any] ,_a : Union[str, Any] ,_a : Optional[Any] = None ,**_a : int ): '''simple docstring''' _a, _a : int = get_image_size(lowerCamelCase__ ) # Rounds the height and width down to the closest multiple of size_divisor _a : Optional[Any] = height // size_divisor * size_divisor _a : Optional[int] = width // size_divisor * size_divisor _a : Union[str, Any] = resize(lowerCamelCase__ ,(new_h, new_w) ,resample=lowerCamelCase__ ,data_format=lowerCamelCase__ ,**lowerCamelCase__ ) return image def __lowercase ( self : Dict ,_a : int ,_a : Optional[Any] ,_a : Optional[Any] = None ,**_a : Optional[int] ): '''simple docstring''' return rescale(image=lowerCamelCase__ ,scale=lowerCamelCase__ ,data_format=lowerCamelCase__ ,**lowerCamelCase__ ) def __lowercase ( self : Tuple ,_a : List[Any] ,_a : Dict = None ,_a : Tuple = None ,_a : Optional[int]=None ,_a : Any = None ,_a : Tuple = None ,_a : Dict = ChannelDimension.FIRST ,**_a : str ,): '''simple docstring''' _a : int = do_resize if do_resize is not None else self.do_resize _a : Optional[Any] = do_rescale if do_rescale is not None else self.do_rescale _a : Any = size_divisor if size_divisor is not None else self.size_divisor _a : str = resample if resample is not None else self.resample if do_resize and size_divisor is None: raise ValueError('size_divisor is required for resizing' ) _a : Optional[Any] = make_list_of_images(lowerCamelCase__ ) if not valid_images(lowerCamelCase__ ): raise ValueError('Invalid image(s)' ) # All transformations expect numpy arrays. _a : Optional[Any] = [to_numpy_array(lowerCamelCase__ ) for img in images] if do_resize: _a : str = [self.resize(lowerCamelCase__ ,size_divisor=lowerCamelCase__ ,resample=lowerCamelCase__ ) for image in images] if do_rescale: _a : List[Any] = [self.rescale(lowerCamelCase__ ,scale=1 / 255 ) for image in images] _a : Optional[Any] = [to_channel_dimension_format(lowerCamelCase__ ,lowerCamelCase__ ) for image in images] _a : str = {'pixel_values': images} return BatchFeature(data=lowerCamelCase__ ,tensor_type=lowerCamelCase__ )
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import unittest import numpy as np from transformers.testing_utils import require_flax, require_tf, require_torch from transformers.utils import ( expand_dims, flatten_dict, is_flax_available, is_tf_available, is_torch_available, reshape, squeeze, transpose, ) if is_flax_available(): import jax.numpy as jnp if is_tf_available(): import tensorflow as tf if is_torch_available(): import torch class __lowerCAmelCase ( unittest.TestCase ): """simple docstring""" def lowercase_ ( self ) -> Tuple: '''simple docstring''' __lowerCamelCase = { 'task_specific_params': { 'summarization': {'length_penalty': 1.0, 'max_length': 128, 'min_length': 12, 'num_beams': 4}, 'summarization_cnn': {'length_penalty': 2.0, 'max_length': 142, 'min_length': 56, 'num_beams': 4}, 'summarization_xsum': {'length_penalty': 1.0, 'max_length': 62, 'min_length': 11, 'num_beams': 6}, } } __lowerCamelCase = { 'task_specific_params.summarization.length_penalty': 1.0, 'task_specific_params.summarization.max_length': 128, 'task_specific_params.summarization.min_length': 12, 'task_specific_params.summarization.num_beams': 4, 'task_specific_params.summarization_cnn.length_penalty': 2.0, 'task_specific_params.summarization_cnn.max_length': 142, 'task_specific_params.summarization_cnn.min_length': 56, 'task_specific_params.summarization_cnn.num_beams': 4, 'task_specific_params.summarization_xsum.length_penalty': 1.0, 'task_specific_params.summarization_xsum.max_length': 62, 'task_specific_params.summarization_xsum.min_length': 11, 'task_specific_params.summarization_xsum.num_beams': 6, } self.assertEqual(flatten_dict(lowerCamelCase__ ) , lowerCamelCase__ ) def lowercase_ ( self ) -> Tuple: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) self.assertTrue(np.allclose(transpose(lowerCamelCase__ ) , x.transpose() ) ) __lowerCamelCase = np.random.randn(3 , 4 , 5 ) self.assertTrue(np.allclose(transpose(lowerCamelCase__ , axes=(1, 2, 0) ) , x.transpose((1, 2, 0) ) ) ) @require_torch def lowercase_ ( self ) -> int: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) __lowerCamelCase = torch.tensor(lowerCamelCase__ ) self.assertTrue(np.allclose(transpose(lowerCamelCase__ ) , transpose(lowerCamelCase__ ).numpy() ) ) __lowerCamelCase = np.random.randn(3 , 4 , 5 ) __lowerCamelCase = torch.tensor(lowerCamelCase__ ) self.assertTrue(np.allclose(transpose(lowerCamelCase__ , axes=(1, 2, 0) ) , transpose(lowerCamelCase__ , axes=(1, 2, 0) ).numpy() ) ) @require_tf def lowercase_ ( self ) -> Union[str, Any]: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) __lowerCamelCase = tf.constant(lowerCamelCase__ ) self.assertTrue(np.allclose(transpose(lowerCamelCase__ ) , transpose(lowerCamelCase__ ).numpy() ) ) __lowerCamelCase = np.random.randn(3 , 4 , 5 ) __lowerCamelCase = tf.constant(lowerCamelCase__ ) self.assertTrue(np.allclose(transpose(lowerCamelCase__ , axes=(1, 2, 0) ) , transpose(lowerCamelCase__ , axes=(1, 2, 0) ).numpy() ) ) @require_flax def lowercase_ ( self ) -> Optional[int]: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) __lowerCamelCase = jnp.array(lowerCamelCase__ ) self.assertTrue(np.allclose(transpose(lowerCamelCase__ ) , np.asarray(transpose(lowerCamelCase__ ) ) ) ) __lowerCamelCase = np.random.randn(3 , 4 , 5 ) __lowerCamelCase = jnp.array(lowerCamelCase__ ) self.assertTrue(np.allclose(transpose(lowerCamelCase__ , axes=(1, 2, 0) ) , np.asarray(transpose(lowerCamelCase__ , axes=(1, 2, 0) ) ) ) ) def lowercase_ ( self ) -> int: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) self.assertTrue(np.allclose(reshape(lowerCamelCase__ , (4, 3) ) , np.reshape(lowerCamelCase__ , (4, 3) ) ) ) __lowerCamelCase = np.random.randn(3 , 4 , 5 ) self.assertTrue(np.allclose(reshape(lowerCamelCase__ , (12, 5) ) , np.reshape(lowerCamelCase__ , (12, 5) ) ) ) @require_torch def lowercase_ ( self ) -> List[Any]: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) __lowerCamelCase = torch.tensor(lowerCamelCase__ ) self.assertTrue(np.allclose(reshape(lowerCamelCase__ , (4, 3) ) , reshape(lowerCamelCase__ , (4, 3) ).numpy() ) ) __lowerCamelCase = np.random.randn(3 , 4 , 5 ) __lowerCamelCase = torch.tensor(lowerCamelCase__ ) self.assertTrue(np.allclose(reshape(lowerCamelCase__ , (12, 5) ) , reshape(lowerCamelCase__ , (12, 5) ).numpy() ) ) @require_tf def lowercase_ ( self ) -> Optional[int]: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) __lowerCamelCase = tf.constant(lowerCamelCase__ ) self.assertTrue(np.allclose(reshape(lowerCamelCase__ , (4, 3) ) , reshape(lowerCamelCase__ , (4, 3) ).numpy() ) ) __lowerCamelCase = np.random.randn(3 , 4 , 5 ) __lowerCamelCase = tf.constant(lowerCamelCase__ ) self.assertTrue(np.allclose(reshape(lowerCamelCase__ , (12, 5) ) , reshape(lowerCamelCase__ , (12, 5) ).numpy() ) ) @require_flax def lowercase_ ( self ) -> Tuple: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) __lowerCamelCase = jnp.array(lowerCamelCase__ ) self.assertTrue(np.allclose(reshape(lowerCamelCase__ , (4, 3) ) , np.asarray(reshape(lowerCamelCase__ , (4, 3) ) ) ) ) __lowerCamelCase = np.random.randn(3 , 4 , 5 ) __lowerCamelCase = jnp.array(lowerCamelCase__ ) self.assertTrue(np.allclose(reshape(lowerCamelCase__ , (12, 5) ) , np.asarray(reshape(lowerCamelCase__ , (12, 5) ) ) ) ) def lowercase_ ( self ) -> int: '''simple docstring''' __lowerCamelCase = np.random.randn(1 , 3 , 4 ) self.assertTrue(np.allclose(squeeze(lowerCamelCase__ ) , np.squeeze(lowerCamelCase__ ) ) ) __lowerCamelCase = np.random.randn(1 , 4 , 1 , 5 ) self.assertTrue(np.allclose(squeeze(lowerCamelCase__ , axis=2 ) , np.squeeze(lowerCamelCase__ , axis=2 ) ) ) @require_torch def lowercase_ ( self ) -> int: '''simple docstring''' __lowerCamelCase = np.random.randn(1 , 3 , 4 ) __lowerCamelCase = torch.tensor(lowerCamelCase__ ) self.assertTrue(np.allclose(squeeze(lowerCamelCase__ ) , squeeze(lowerCamelCase__ ).numpy() ) ) __lowerCamelCase = np.random.randn(1 , 4 , 1 , 5 ) __lowerCamelCase = torch.tensor(lowerCamelCase__ ) self.assertTrue(np.allclose(squeeze(lowerCamelCase__ , axis=2 ) , squeeze(lowerCamelCase__ , axis=2 ).numpy() ) ) @require_tf def lowercase_ ( self ) -> Union[str, Any]: '''simple docstring''' __lowerCamelCase = np.random.randn(1 , 3 , 4 ) __lowerCamelCase = tf.constant(lowerCamelCase__ ) self.assertTrue(np.allclose(squeeze(lowerCamelCase__ ) , squeeze(lowerCamelCase__ ).numpy() ) ) __lowerCamelCase = np.random.randn(1 , 4 , 1 , 5 ) __lowerCamelCase = tf.constant(lowerCamelCase__ ) self.assertTrue(np.allclose(squeeze(lowerCamelCase__ , axis=2 ) , squeeze(lowerCamelCase__ , axis=2 ).numpy() ) ) @require_flax def lowercase_ ( self ) -> List[str]: '''simple docstring''' __lowerCamelCase = np.random.randn(1 , 3 , 4 ) __lowerCamelCase = jnp.array(lowerCamelCase__ ) self.assertTrue(np.allclose(squeeze(lowerCamelCase__ ) , np.asarray(squeeze(lowerCamelCase__ ) ) ) ) __lowerCamelCase = np.random.randn(1 , 4 , 1 , 5 ) __lowerCamelCase = jnp.array(lowerCamelCase__ ) self.assertTrue(np.allclose(squeeze(lowerCamelCase__ , axis=2 ) , np.asarray(squeeze(lowerCamelCase__ , axis=2 ) ) ) ) def lowercase_ ( self ) -> int: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) self.assertTrue(np.allclose(expand_dims(lowerCamelCase__ , axis=1 ) , np.expand_dims(lowerCamelCase__ , axis=1 ) ) ) @require_torch def lowercase_ ( self ) -> Any: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) __lowerCamelCase = torch.tensor(lowerCamelCase__ ) self.assertTrue(np.allclose(expand_dims(lowerCamelCase__ , axis=1 ) , expand_dims(lowerCamelCase__ , axis=1 ).numpy() ) ) @require_tf def lowercase_ ( self ) -> Any: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) __lowerCamelCase = tf.constant(lowerCamelCase__ ) self.assertTrue(np.allclose(expand_dims(lowerCamelCase__ , axis=1 ) , expand_dims(lowerCamelCase__ , axis=1 ).numpy() ) ) @require_flax def lowercase_ ( self ) -> List[Any]: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) __lowerCamelCase = jnp.array(lowerCamelCase__ ) self.assertTrue(np.allclose(expand_dims(lowerCamelCase__ , axis=1 ) , np.asarray(expand_dims(lowerCamelCase__ , axis=1 ) ) ) )
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from __future__ import annotations import random # Maximum size of the population. Bigger could be faster but is more memory expensive. UpperCAmelCase = 200 # Number of elements selected in every generation of evolution. The selection takes # place from best to worst of that generation and must be smaller than N_POPULATION. UpperCAmelCase = 50 # Probability that an element of a generation can mutate, changing one of its genes. # This will guarantee that all genes will be used during evolution. UpperCAmelCase = 0.4 # Just a seed to improve randomness required by the algorithm. random.seed(random.randint(0, 1000)) def UpperCAmelCase_ ( __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE ): lowercase = len([g for position, g in enumerate(UpperCamelCase__ ) if g == main_target[position]] ) return (item, float(UpperCamelCase__ )) def UpperCAmelCase_ ( __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE ): lowercase = random.randint(0 , len(UpperCamelCase__ ) - 1 ) lowercase = parent_a[:random_slice] + parent_a[random_slice:] lowercase = parent_a[:random_slice] + parent_a[random_slice:] return (child_a, child_a) def UpperCAmelCase_ ( __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE ): lowercase = list(UpperCamelCase__ ) if random.uniform(0 , 1 ) < MUTATION_PROBABILITY: lowercase = random.choice(UpperCamelCase__ ) return "".join(UpperCamelCase__ ) def UpperCAmelCase_ ( __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE , ): lowercase = [] # Generate more children proportionally to the fitness score. lowercase = int(parent_a[1] * 100 ) + 1 lowercase = 10 if child_n >= 10 else child_n for _ in range(UpperCamelCase__ ): lowercase = population_score[random.randint(0 , UpperCamelCase__ )][0] lowercase , lowercase = crossover(parent_a[0] , UpperCamelCase__ ) # Append new string to the population list. pop.append(mutate(UpperCamelCase__ , UpperCamelCase__ ) ) pop.append(mutate(UpperCamelCase__ , UpperCamelCase__ ) ) return pop def UpperCAmelCase_ ( __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE = True ): if N_POPULATION < N_SELECTED: lowercase = F'''{N_POPULATION} must be bigger than {N_SELECTED}''' raise ValueError(UpperCamelCase__ ) # Verify that the target contains no genes besides the ones inside genes variable. lowercase = sorted({c for c in target if c not in genes} ) if not_in_genes_list: lowercase = F'''{not_in_genes_list} is not in genes list, evolution cannot converge''' raise ValueError(UpperCamelCase__ ) # Generate random starting population. lowercase = [] for _ in range(UpperCamelCase__ ): population.append(''.join([random.choice(UpperCamelCase__ ) for i in range(len(UpperCamelCase__ ) )] ) ) # Just some logs to know what the algorithms is doing. lowercase , lowercase = 0, 0 # This loop will end when we find a perfect match for our target. while True: generation += 1 total_population += len(UpperCamelCase__ ) # Random population created. Now it's time to evaluate. # Adding a bit of concurrency can make everything faster, # # import concurrent.futures # population_score: list[tuple[str, float]] = [] # with concurrent.futures.ThreadPoolExecutor( # max_workers=NUM_WORKERS) as executor: # futures = {executor.submit(evaluate, item) for item in population} # concurrent.futures.wait(futures) # population_score = [item.result() for item in futures] # # but with a simple algorithm like this, it will probably be slower. # We just need to call evaluate for every item inside the population. lowercase = [evaluate(UpperCamelCase__ , UpperCamelCase__ ) for item in population] # Check if there is a matching evolution. lowercase = sorted(UpperCamelCase__ , key=lambda __SCREAMING_SNAKE_CASE : x[1] , reverse=UpperCamelCase__ ) if population_score[0][0] == target: return (generation, total_population, population_score[0][0]) # Print the best result every 10 generation. # Just to know that the algorithm is working. if debug and generation % 10 == 0: print( F'''\nGeneration: {generation}''' F'''\nTotal Population:{total_population}''' F'''\nBest score: {population_score[0][1]}''' F'''\nBest string: {population_score[0][0]}''' ) # Flush the old population, keeping some of the best evolutions. # Keeping this avoid regression of evolution. lowercase = population[: int(N_POPULATION / 3 )] population.clear() population.extend(UpperCamelCase__ ) # Normalize population score to be between 0 and 1. lowercase = [ (item, score / len(UpperCamelCase__ )) for item, score in population_score ] # This is selection for i in range(UpperCamelCase__ ): population.extend(select(population_score[int(UpperCamelCase__ )] , UpperCamelCase__ , UpperCamelCase__ ) ) # Check if the population has already reached the maximum value and if so, # break the cycle. If this check is disabled, the algorithm will take # forever to compute large strings, but will also calculate small strings in # a far fewer generations. if len(UpperCamelCase__ ) > N_POPULATION: break if __name__ == "__main__": UpperCAmelCase = ( '''This is a genetic algorithm to evaluate, combine, evolve, and mutate a string!''' ) UpperCAmelCase = list( ''' ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklm''' '''nopqrstuvwxyz.,;!?+-*#@^\'èéòà€ù=)(&%$£/\\''' ) UpperCAmelCase , UpperCAmelCase , UpperCAmelCase = basic(target_str, genes_list) print( F"""\nGeneration: {generation}\nTotal Population: {population}\nTarget: {target}""" )
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import copy import inspect import unittest import numpy as np from huggingface_hub import hf_hub_download from transformers import TimesformerConfig from transformers.models.auto import get_values 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, floats_tensor, ids_tensor from ...test_pipeline_mixin import PipelineTesterMixin if is_torch_available(): import torch from torch import nn from transformers import ( MODEL_FOR_VIDEO_CLASSIFICATION_MAPPING, TimesformerForVideoClassification, TimesformerModel, ) from transformers.models.timesformer.modeling_timesformer import TIMESFORMER_PRETRAINED_MODEL_ARCHIVE_LIST if is_vision_available(): from transformers import VideoMAEImageProcessor class __lowerCAmelCase : """simple docstring""" def __init__( self , lowerCamelCase__ , lowerCamelCase__=13 , lowerCamelCase__=10 , lowerCamelCase__=3 , lowerCamelCase__=2 , lowerCamelCase__=2 , lowerCamelCase__=True , lowerCamelCase__=True , lowerCamelCase__=32 , lowerCamelCase__=5 , lowerCamelCase__=4 , lowerCamelCase__=37 , lowerCamelCase__="gelu" , lowerCamelCase__=0.1 , lowerCamelCase__=0.1 , lowerCamelCase__=10 , lowerCamelCase__=0.02 , lowerCamelCase__="divided_space_time" , lowerCamelCase__=None , ) -> Any: '''simple docstring''' __lowerCamelCase = parent __lowerCamelCase = batch_size __lowerCamelCase = image_size __lowerCamelCase = num_channels __lowerCamelCase = patch_size __lowerCamelCase = num_frames __lowerCamelCase = is_training __lowerCamelCase = use_labels __lowerCamelCase = hidden_size __lowerCamelCase = num_hidden_layers __lowerCamelCase = num_attention_heads __lowerCamelCase = intermediate_size __lowerCamelCase = hidden_act __lowerCamelCase = hidden_dropout_prob __lowerCamelCase = attention_probs_dropout_prob __lowerCamelCase = attention_type __lowerCamelCase = initializer_range __lowerCamelCase = scope __lowerCamelCase = num_labels # in TimeSformer, the number of spatial tokens equals num_frames * num_patches per frame + 1 CLS token __lowerCamelCase = (image_size // patch_size) ** 2 __lowerCamelCase = (num_frames) * self.num_patches_per_frame + 1 def lowercase_ ( self ) -> Optional[int]: '''simple docstring''' __lowerCamelCase = floats_tensor( [self.batch_size, self.num_frames, self.num_channels, self.image_size, self.image_size] ) __lowerCamelCase = None if self.use_labels: __lowerCamelCase = ids_tensor([self.batch_size] , self.num_labels ) __lowerCamelCase = self.get_config() return config, pixel_values, labels def lowercase_ ( self ) -> Union[str, Any]: '''simple docstring''' __lowerCamelCase = TimesformerConfig( image_size=self.image_size , patch_size=self.patch_size , num_channels=self.num_channels , num_frames=self.num_frames , 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 , initializer_range=self.initializer_range , attention_type=self.attention_type , ) __lowerCamelCase = self.num_labels return config def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> Tuple: '''simple docstring''' __lowerCamelCase = TimesformerModel(config=lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model(lowerCamelCase__ ) self.parent.assertEqual(result.last_hidden_state.shape , (self.batch_size, self.seq_length, self.hidden_size) ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> Union[str, Any]: '''simple docstring''' __lowerCamelCase = TimesformerForVideoClassification(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model(lowerCamelCase__ ) # verify the logits shape __lowerCamelCase = torch.Size((self.batch_size, self.num_labels) ) self.parent.assertEqual(result.logits.shape , lowerCamelCase__ ) def lowercase_ ( self ) -> Tuple: '''simple docstring''' __lowerCamelCase = self.prepare_config_and_inputs() __lowerCamelCase , __lowerCamelCase , __lowerCamelCase = config_and_inputs __lowerCamelCase = {'pixel_values': pixel_values} return config, inputs_dict @require_torch class __lowerCAmelCase ( __magic_name__ , __magic_name__ , unittest.TestCase ): """simple docstring""" snake_case_ = (TimesformerModel, TimesformerForVideoClassification) if is_torch_available() else () snake_case_ = ( {'''feature-extraction''': TimesformerModel, '''video-classification''': TimesformerForVideoClassification} if is_torch_available() else {} ) snake_case_ = False snake_case_ = False snake_case_ = False snake_case_ = False def lowercase_ ( self ) -> List[str]: '''simple docstring''' __lowerCamelCase = TimesformerModelTester(self ) __lowerCamelCase = ConfigTester( self , config_class=lowerCamelCase__ , has_text_modality=lowerCamelCase__ , hidden_size=37 ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__=False ) -> int: '''simple docstring''' __lowerCamelCase = copy.deepcopy(lowerCamelCase__ ) if return_labels: if model_class in get_values(lowerCamelCase__ ): __lowerCamelCase = torch.zeros( self.model_tester.batch_size , dtype=torch.long , device=lowerCamelCase__ ) return inputs_dict def lowercase_ ( self ) -> Optional[int]: '''simple docstring''' self.config_tester.run_common_tests() @unittest.skip(reason='TimeSformer does not use inputs_embeds' ) def lowercase_ ( self ) -> List[str]: '''simple docstring''' pass def lowercase_ ( self ) -> Union[str, Any]: '''simple docstring''' __lowerCamelCase , __lowerCamelCase = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: __lowerCamelCase = model_class(lowerCamelCase__ ) self.assertIsInstance(model.get_input_embeddings() , (nn.Module) ) __lowerCamelCase = model.get_output_embeddings() self.assertTrue(x is None or isinstance(lowerCamelCase__ , nn.Linear ) ) def lowercase_ ( self ) -> List[str]: '''simple docstring''' __lowerCamelCase , __lowerCamelCase = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: __lowerCamelCase = model_class(lowerCamelCase__ ) __lowerCamelCase = inspect.signature(model.forward ) # signature.parameters is an OrderedDict => so arg_names order is deterministic __lowerCamelCase = [*signature.parameters.keys()] __lowerCamelCase = ['pixel_values'] self.assertListEqual(arg_names[:1] , lowerCamelCase__ ) def lowercase_ ( self ) -> Union[str, Any]: '''simple docstring''' __lowerCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_model(*lowerCamelCase__ ) def lowercase_ ( self ) -> str: '''simple docstring''' __lowerCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_for_video_classification(*lowerCamelCase__ ) @slow def lowercase_ ( self ) -> Dict: '''simple docstring''' for model_name in TIMESFORMER_PRETRAINED_MODEL_ARCHIVE_LIST[:1]: __lowerCamelCase = TimesformerModel.from_pretrained(lowerCamelCase__ ) self.assertIsNotNone(lowerCamelCase__ ) def lowercase_ ( self ) -> List[Any]: '''simple docstring''' if not self.has_attentions: pass else: __lowerCamelCase , __lowerCamelCase = self.model_tester.prepare_config_and_inputs_for_common() __lowerCamelCase = True for model_class in self.all_model_classes: __lowerCamelCase = self.model_tester.seq_length __lowerCamelCase = self.model_tester.num_frames __lowerCamelCase = True __lowerCamelCase = False __lowerCamelCase = True __lowerCamelCase = model_class(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() with torch.no_grad(): __lowerCamelCase = model(**self._prepare_for_class(lowerCamelCase__ , lowerCamelCase__ ) ) __lowerCamelCase = outputs.attentions self.assertEqual(len(lowerCamelCase__ ) , self.model_tester.num_hidden_layers ) # check that output_attentions also work using config del inputs_dict["output_attentions"] __lowerCamelCase = True __lowerCamelCase = model_class(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() with torch.no_grad(): __lowerCamelCase = model(**self._prepare_for_class(lowerCamelCase__ , lowerCamelCase__ ) ) __lowerCamelCase = outputs.attentions self.assertEqual(len(lowerCamelCase__ ) , self.model_tester.num_hidden_layers ) # attentions has shape (batch_size x num_frames) x num_heads x (num_patches per frame + 1) x (num_patches per frame + 1) self.assertListEqual( list(attentions[0].shape[-3:] ) , [self.model_tester.num_attention_heads, seq_len // num_frames + 1, seq_len // num_frames + 1] , ) __lowerCamelCase = len(lowerCamelCase__ ) # Check attention is always last and order is fine __lowerCamelCase = True __lowerCamelCase = True __lowerCamelCase = model_class(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() with torch.no_grad(): __lowerCamelCase = model(**self._prepare_for_class(lowerCamelCase__ , lowerCamelCase__ ) ) self.assertEqual(out_len + 1 , len(lowerCamelCase__ ) ) __lowerCamelCase = outputs.attentions self.assertEqual(len(lowerCamelCase__ ) , self.model_tester.num_hidden_layers ) # attentions has shape (batch_size x num_frames) x num_heads x (num_patches per frame + 1) x (num_patches per frame + 1) self.assertListEqual( list(self_attentions[0].shape[-3:] ) , [self.model_tester.num_attention_heads, seq_len // num_frames + 1, seq_len // num_frames + 1] , ) def lowercase_ ( self ) -> Tuple: '''simple docstring''' def check_hidden_states_output(lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ): __lowerCamelCase = model_class(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() with torch.no_grad(): __lowerCamelCase = model(**self._prepare_for_class(lowerCamelCase__ , lowerCamelCase__ ) ) __lowerCamelCase = outputs.hidden_states __lowerCamelCase = self.model_tester.num_hidden_layers + 1 self.assertEqual(len(lowerCamelCase__ ) , lowerCamelCase__ ) __lowerCamelCase = self.model_tester.seq_length self.assertListEqual( list(hidden_states[0].shape[-2:] ) , [seq_length, self.model_tester.hidden_size] , ) __lowerCamelCase , __lowerCamelCase = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: __lowerCamelCase = True check_hidden_states_output(lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) # check that output_hidden_states also work using config del inputs_dict["output_hidden_states"] __lowerCamelCase = True check_hidden_states_output(lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) def lowerCamelCase_ ( ) -> Any: """simple docstring""" __lowerCamelCase = hf_hub_download( repo_id='hf-internal-testing/spaghetti-video' , filename='eating_spaghetti.npy' , repo_type='dataset' ) __lowerCamelCase = np.load(UpperCamelCase__ ) return list(UpperCamelCase__ ) @require_torch @require_vision class __lowerCAmelCase ( unittest.TestCase ): """simple docstring""" @cached_property def lowercase_ ( self ) -> List[Any]: '''simple docstring''' # logits were tested with a different mean and std, so we use the same here return ( VideoMAEImageProcessor(image_mean=[0.5, 0.5, 0.5] , image_std=[0.5, 0.5, 0.5] ) if is_vision_available() else None ) @slow def lowercase_ ( self ) -> List[str]: '''simple docstring''' __lowerCamelCase = TimesformerForVideoClassification.from_pretrained('facebook/timesformer-base-finetuned-k400' ).to( lowerCamelCase__ ) __lowerCamelCase = self.default_image_processor __lowerCamelCase = prepare_video() __lowerCamelCase = image_processor(video[:8] , return_tensors='pt' ).to(lowerCamelCase__ ) # forward pass with torch.no_grad(): __lowerCamelCase = model(**lowerCamelCase__ ) # verify the logits __lowerCamelCase = torch.Size((1, 400) ) self.assertEqual(outputs.logits.shape , lowerCamelCase__ ) __lowerCamelCase = torch.tensor([-0.30_16, -0.77_13, -0.42_05] ).to(lowerCamelCase__ ) self.assertTrue(torch.allclose(outputs.logits[0, :3] , lowerCamelCase__ , atol=1e-4 ) )
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import json import os import tempfile from transformers.testing_utils import check_json_file_has_correct_format class __magic_name__ : SCREAMING_SNAKE_CASE = None def __magic_name__ ( self ) -> Any: '''simple docstring''' __a =self.feature_extraction_class(**self.feat_extract_dict ) __a =json.loads(feat_extract.to_json_string() ) for key, value in self.feat_extract_dict.items(): self.assertEqual(obj[key] , lowerCamelCase__ ) def __magic_name__ ( self ) -> List[Any]: '''simple docstring''' __a =self.feature_extraction_class(**self.feat_extract_dict ) with tempfile.TemporaryDirectory() as tmpdirname: __a =os.path.join(lowerCamelCase__ , 'feat_extract.json' ) feat_extract_first.to_json_file(lowerCamelCase__ ) __a =self.feature_extraction_class.from_json_file(lowerCamelCase__ ) self.assertEqual(feat_extract_second.to_dict() , feat_extract_first.to_dict() ) def __magic_name__ ( self ) -> str: '''simple docstring''' __a =self.feature_extraction_class(**self.feat_extract_dict ) with tempfile.TemporaryDirectory() as tmpdirname: __a =feat_extract_first.save_pretrained(lowerCamelCase__ )[0] check_json_file_has_correct_format(lowerCamelCase__ ) __a =self.feature_extraction_class.from_pretrained(lowerCamelCase__ ) self.assertEqual(feat_extract_second.to_dict() , feat_extract_first.to_dict() ) def __magic_name__ ( self ) -> Optional[int]: '''simple docstring''' __a =self.feature_extraction_class() self.assertIsNotNone(lowerCamelCase__ )
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import json from typing import TYPE_CHECKING, List, Optional, Tuple from tokenizers import pre_tokenizers from ...tokenization_utils_fast import PreTrainedTokenizerFast from ...utils import logging if TYPE_CHECKING: from transformers.pipelines.conversational import Conversation __A = logging.get_logger(__name__) __A = {"vocab_file": "vocab.json", "merges_file": "merges.txt", "tokenizer_file": "tokenizer.json"} __A = { "tokenizer_file": { "EleutherAI/gpt-neox-20b": "https://huggingface.co/EleutherAI/gpt-neox-20b/resolve/main/tokenizer.json", }, } __A = { "gpt-neox-20b": 20_48, } class __lowerCAmelCase ( __magic_name__ ): """simple docstring""" snake_case_ = VOCAB_FILES_NAMES snake_case_ = PRETRAINED_VOCAB_FILES_MAP snake_case_ = PRETRAINED_POSITIONAL_EMBEDDINGS_SIZES snake_case_ = ['''input_ids''', '''attention_mask'''] def __init__( self , lowerCamelCase__=None , lowerCamelCase__=None , lowerCamelCase__=None , lowerCamelCase__="<|endoftext|>" , lowerCamelCase__="<|endoftext|>" , lowerCamelCase__="<|endoftext|>" , lowerCamelCase__=False , **lowerCamelCase__ , ) -> int: '''simple docstring''' super().__init__( lowerCamelCase__ , lowerCamelCase__ , tokenizer_file=lowerCamelCase__ , unk_token=lowerCamelCase__ , bos_token=lowerCamelCase__ , eos_token=lowerCamelCase__ , add_prefix_space=lowerCamelCase__ , **lowerCamelCase__ , ) __lowerCamelCase = json.loads(self.backend_tokenizer.pre_tokenizer.__getstate__() ) if pre_tok_state.get('add_prefix_space' , lowerCamelCase__ ) != add_prefix_space: __lowerCamelCase = getattr(lowerCamelCase__ , pre_tok_state.pop('type' ) ) __lowerCamelCase = add_prefix_space __lowerCamelCase = pre_tok_class(**lowerCamelCase__ ) __lowerCamelCase = add_prefix_space def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ = None ) -> Tuple[str]: '''simple docstring''' __lowerCamelCase = self._tokenizer.model.save(lowerCamelCase__ , name=lowerCamelCase__ ) return tuple(lowerCamelCase__ ) def lowercase_ ( self , lowerCamelCase__ ) -> List[int]: '''simple docstring''' __lowerCamelCase = [] for is_user, text in conversation.iter_texts(): input_ids.extend(self.encode(lowerCamelCase__ , add_special_tokens=lowerCamelCase__ ) + [self.eos_token_id] ) if len(lowerCamelCase__ ) > self.model_max_length: __lowerCamelCase = input_ids[-self.model_max_length :] return input_ids
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"""simple docstring""" import json import os import unittest from typing import Tuple from transformers import WavaVecaPhonemeCTCTokenizer from transformers.models.wavaveca.tokenization_wavaveca import VOCAB_FILES_NAMES from transformers.models.wavaveca_phoneme.tokenization_wavaveca_phoneme import WavaVecaPhonemeCTCTokenizerOutput from transformers.testing_utils import require_phonemizer from ...test_tokenization_common import TokenizerTesterMixin @require_phonemizer class __A ( _SCREAMING_SNAKE_CASE, unittest.TestCase ): """simple docstring""" __lowerCAmelCase = WavaVecaPhonemeCTCTokenizer __lowerCAmelCase = False def SCREAMING_SNAKE_CASE ( self ) -> Dict: super().setUp() a =( '''<s> <pad> </s> <unk> n s t ə l a i k d m ɛ ɾ e ɪ p o ɐ z ð f j v b ɹ ʁ ʊ iː r w ʌ u ɡ æ aɪ ʃ h ɔ ɑː ''' '''ŋ ɚ eɪ β uː y ɑ̃ oʊ ᵻ eː θ aʊ ts oː ɔ̃ ɣ ɜ ɑ dʒ əl x ɜː ç ʒ tʃ ɔː ɑːɹ ɛ̃ ʎ ɔːɹ ʋ aː ɕ œ ø oːɹ ɲ yː ''' '''ʔ iə i5 s. tɕ ?? nʲ ɛː œ̃ ɭ ɔø ʑ tʲ ɨ ɛɹ ts. rʲ ɪɹ ɭʲ i.5 ɔɪ q sʲ u5 ʊɹ iɜ a5 iɛ5 øː ʕ ja əɜ th ɑ5 ''' '''oɪ dʲ ə5 tɕh ts.h mʲ ɯ dʑ vʲ e̞ tʃʲ ei5 o5 onɡ5 ɑu5 iɑ5 ai5 aɪɚ kh ə1 ʐ i2 ʉ ħ t[ aɪə ʲ ju ə2 u2 oɜ ''' '''pː iɛɜ ou5 y5 uɜ tː uo5 d[ uoɜ tsh ɑɜ ɵ i̪5 uei5 ɟ aɜ ɑɨ i.ɜ eʊ o2 ɐ̃ ä pʲ kʲ n̩ ɒ ph ɑu2 uɨ əɪ ɫ ɬ ''' '''yɜ bʲ ɑ2 s̪ aiɜ χ ɐ̃ʊ̃ 1 ə4 yæɜ a2 ɨː t̪ iouɜ ũ onɡɜ aɨ iɛ2 ɔɨ ɑuɜ o̞ ei2 iou2 c kː y2 ɖ oe dˤ yɛɜ ''' '''əʊ S ɡʲ onɡ2 u" eiɜ ʈ ɯᵝ iou5 dZ r̝̊ i.2 tS s^ ʝ yə5 iɑɜ uə5 pf ɨu iɑ2 ou2 ər2 fʲ ai2 r̝ uəɜ ɳ əɨ ''' '''ua5 uɪ ɽ bː yu5 uo2 yɛ5 l̩ ɻ ərɜ ʂ i̪2 ouɜ uaɜ a. a.ː yæ5 dː r̩ ee ɪu ər5 i̪ ɜ æi u: i.ː t^ o1 ɪ^ ''' '''ai ueiɜ æː ɛɪ eə i. ɴ ie ua2 ɑ1 o4 tʃː o: ɑ: u1 N i̪1 au yæ2 u. qː yəɜ y: kʰ tʃʰ iʊ sx õ uo tʰ ''' '''uai5 bʰ u.ː uə2 ʊə d^ s̪ː yiɜ dʰ r. oe: i1 ɟː yu2 nʲʲ i̪4 uei2 tsʲ ɸ ĩ ɑ4 t̪ː eɑ u4 e: tsː ʈʰ ɡʰ ''' '''ɯɯ dʒʲ ʂʲ X ɵː uaiɜ tɕʲ ã t^ː ẽː yɛ2 cː i.1 ɛʊ dˤdˤ dʒː i4 ɡː yi ɕʲ ɟʰ pʰ dʑʲ yuɜ ua1 ua4 æiː ɐɐ ''' '''ui iou1 ʊː a1 iou4 cʰ iɛ1 yə2 ɖʰ ẽ ʒʲ ää ər4 iːː ɪː iɑ1 ər1 œː øi ɪuː cʰcʰ əː1 iː1 ũ kʰː o̞o̞ xʲ ''' '''ou1 iɛ4 e̞e̞ y1 dzː dʲʲ dʰː ɯᵝɯᵝ lː uo1 i.4 i: yɛ5ʲ a4''' ).split(''' ''' ) a =dict(zip(lowerCamelCase__ , range(len(lowerCamelCase__ ) ) ) ) a ={'''pad_token''': '''<pad>''', '''unk_token''': '''<unk>''', '''bos_token''': '''<s>''', '''eos_token''': '''</s>'''} a =os.path.join(self.tmpdirname , VOCAB_FILES_NAMES['''vocab_file'''] ) with open(self.vocab_file , '''w''' , encoding='''utf-8''' ) as fp: fp.write(json.dumps(lowerCamelCase__ ) + '''\n''' ) def SCREAMING_SNAKE_CASE ( self , __A , __A=False , __A=20 , __A=5 ) -> Tuple[str, list]: a =[(i, tokenizer.decode([i] , clean_up_tokenization_spaces=lowerCamelCase__ )) for i in range(len(lowerCamelCase__ ) )] a =list(filter(lambda __A : [t[0]] == tokenizer.encode(t[1] , do_phonemize=lowerCamelCase__ ) , lowerCamelCase__ ) ) if max_length is not None and len(lowerCamelCase__ ) > max_length: a =toks[:max_length] if min_length is not None and len(lowerCamelCase__ ) < min_length and len(lowerCamelCase__ ) > 0: while len(lowerCamelCase__ ) < min_length: a =toks + toks # toks_str = [t[1] for t in toks] a =[t[0] for t in toks] # Ensure consistency a =tokenizer.decode(lowerCamelCase__ , clean_up_tokenization_spaces=lowerCamelCase__ ) if " " not in output_txt and len(lowerCamelCase__ ) > 1: a =( tokenizer.decode([toks_ids[0]] , clean_up_tokenization_spaces=lowerCamelCase__ ) + ''' ''' + tokenizer.decode(toks_ids[1:] , clean_up_tokenization_spaces=lowerCamelCase__ ) ) if with_prefix_space: a =''' ''' + output_txt a =tokenizer.encode(lowerCamelCase__ , add_special_tokens=lowerCamelCase__ ) return output_txt, output_ids def SCREAMING_SNAKE_CASE ( self , **__A ) -> Any: kwargs.update(self.special_tokens_map ) return WavaVecaPhonemeCTCTokenizer.from_pretrained(self.tmpdirname , **lowerCamelCase__ ) def SCREAMING_SNAKE_CASE ( self ) -> Tuple: a =self.tokenizer_class.from_pretrained('''facebook/wav2vec2-lv-60-espeak-cv-ft''' ) # check adding a single token tokenizer.add_tokens('''xxx''' ) a =tokenizer('''m xxx ɪ''' , do_phonemize=lowerCamelCase__ ).input_ids self.assertEqual(lowerCamelCase__ , [13, 392, 17] ) # xxx should be last token tokenizer.add_tokens(['''aaa''', '''bbb''', '''ccc'''] ) a =tokenizer('''m aaa ɪ ccc''' , do_phonemize=lowerCamelCase__ ).input_ids self.assertEqual(lowerCamelCase__ , [13, 393, 17, 395] ) # aaa and ccc should be after xxx and 2 after aaa a =tokenizer('''maɪ c''' , do_phonemize=lowerCamelCase__ ).input_ids self.assertEqual(lowerCamelCase__ , [3, 200] ) # mai should be <unk> (=3) def SCREAMING_SNAKE_CASE ( self ) -> List[str]: a =self.tokenizer_class.from_pretrained('''facebook/wav2vec2-lv-60-espeak-cv-ft''' ) a ='''Hello how are you''' a =tokenizer.phonemize(lowerCamelCase__ , phonemizer_lang='''en-us''' ) self.assertEqual(lowerCamelCase__ , '''h ə l oʊ h aʊ ɑːɹ j uː''' ) def SCREAMING_SNAKE_CASE ( self ) -> int: a =self.tokenizer_class.from_pretrained('''facebook/wav2vec2-lv-60-espeak-cv-ft''' ) a ='''Hello how are you''' a =tokenizer.phonemize(lowerCamelCase__ , phonemizer_lang='''en-us''' ) self.assertEqual(tokenizer(lowerCamelCase__ ).input_ids , tokenizer(lowerCamelCase__ , do_phonemize=lowerCamelCase__ ).input_ids ) def SCREAMING_SNAKE_CASE ( self ) -> int: a =self.tokenizer_class.from_pretrained('''facebook/wav2vec2-lv-60-espeak-cv-ft''' ) a ='''Hello how are you''' a =tokenizer.phonemize(lowerCamelCase__ , phonemizer_lang='''en-us''' ) a =tokenizer.decode(tokenizer(lowerCamelCase__ ).input_ids ) self.assertEqual(lowerCamelCase__ , lowerCamelCase__ ) def SCREAMING_SNAKE_CASE ( self ) -> List[Any]: a =self.tokenizer_class.from_pretrained('''facebook/wav2vec2-lv-60-espeak-cv-ft''' ) a =[ [11, 5, 15, tokenizer.pad_token_id, 15, 8, 98], [24, 22, 5, 24, 22, 5, 77], ] a =tokenizer.decode(sample_ids[0] ) a =tokenizer.batch_decode(lowerCamelCase__ ) self.assertEqual(lowerCamelCase__ , batch_tokens[0] ) self.assertEqual(lowerCamelCase__ , ['''k s ɾ ɾ l ɭʲ''', '''j ð s j ð s oːɹ'''] ) def SCREAMING_SNAKE_CASE ( self ) -> Tuple: a =self.tokenizer_class.from_pretrained( '''facebook/wav2vec2-lv-60-espeak-cv-ft''' , word_delimiter_token='''|''' ) tokenizer.add_tokens('''|''' ) a ='''Hello how are you''' a =tokenizer.phonemize(lowerCamelCase__ , phonemizer_lang='''en-us''' ) self.assertEqual(lowerCamelCase__ , '''h ə l oʊ | h aʊ | ɑːɹ | j uː |''' ) def SCREAMING_SNAKE_CASE ( self ) -> Optional[Any]: a =self.tokenizer_class.from_pretrained( '''facebook/wav2vec2-lv-60-espeak-cv-ft''' , word_delimiter_token='''|''' ) tokenizer.add_tokens('''|''' ) a ='''Hello how are you''' a =tokenizer.phonemize(lowerCamelCase__ , phonemizer_lang='''en-us''' ) self.assertEqual(tokenizer(lowerCamelCase__ ).input_ids , tokenizer(lowerCamelCase__ , do_phonemize=lowerCamelCase__ ).input_ids ) def SCREAMING_SNAKE_CASE ( self ) -> List[str]: a =self.tokenizer_class.from_pretrained( '''facebook/wav2vec2-lv-60-espeak-cv-ft''' , word_delimiter_token='''|''' ) tokenizer.add_tokens('''|''' ) # fmt: off a =[ [11, 5, 15, tokenizer.pad_token_id, tokenizer.word_delimiter_token_id, 15, 8, tokenizer.word_delimiter_token_id, 98], [tokenizer.word_delimiter_token_id, 24, 22, tokenizer.word_delimiter_token_id, 5, 24, 22, 5, 77], ] # fmt: on # decode with word_del_token filter a =tokenizer.decode(sample_ids[0] ) a =tokenizer.batch_decode(lowerCamelCase__ ) self.assertEqual(lowerCamelCase__ , batch_tokens[0] ) self.assertEqual(lowerCamelCase__ , ['''k s ɾ ɾ l ɭʲ''', '''j ð s j ð s oːɹ'''] ) # decode with no word_del_token filter a =tokenizer.decode(sample_ids[0] , filter_word_delimiter_token=lowerCamelCase__ ) a =tokenizer.batch_decode(lowerCamelCase__ , filter_word_delimiter_token=lowerCamelCase__ ) self.assertEqual(lowerCamelCase__ , batch_tokens[0] ) self.assertEqual(lowerCamelCase__ , ['''k s ɾ | ɾ l | ɭʲ''', '''| j ð | s j ð s oːɹ'''] ) def SCREAMING_SNAKE_CASE ( self ) -> Any: a =self.tokenizer_class.from_pretrained( '''facebook/wav2vec2-lv-60-espeak-cv-ft''' , word_delimiter_token='''|''' ) tokenizer.add_tokens('''|''' ) a ='''Hello how are you''' a =tokenizer.phonemize(lowerCamelCase__ , phonemizer_lang='''en-us''' ) a =tokenizer.decode(tokenizer(lowerCamelCase__ ).input_ids , filter_word_delimiter_token=lowerCamelCase__ ) self.assertEqual(lowerCamelCase__ , lowerCamelCase__ ) def SCREAMING_SNAKE_CASE ( self ) -> List[str]: a =self.tokenizer_class.from_pretrained( '''facebook/wav2vec2-lv-60-espeak-cv-ft''' , word_delimiter_token='''|''' ) tokenizer.add_tokens('''|''' ) a ='''Hello how are you''' a =tokenizer.phonemize(lowerCamelCase__ , phonemizer_lang='''en-us''' ) a =tokenizer.decode(tokenizer(lowerCamelCase__ ).input_ids , filter_word_delimiter_token=lowerCamelCase__ ) self.assertEqual(''' '''.join([p.strip() for p in phonemes.split(''' |''' )] ).strip() , lowerCamelCase__ ) def SCREAMING_SNAKE_CASE ( self ) -> Any: a =self.tokenizer_class.from_pretrained( '''facebook/wav2vec2-lv-60-espeak-cv-ft''' , word_delimiter_token=lowerCamelCase__ ) a ='''Hello how are you''' a =tokenizer(lowerCamelCase__ , phonemizer_lang='''en-us''' ).input_ids a =tokenizer(lowerCamelCase__ , phonemizer_lang='''fr-fr''' ).input_ids self.assertNotEqual(lowerCamelCase__ , lowerCamelCase__ ) a =tokenizer.decode(lowerCamelCase__ ) a =tokenizer.decode(lowerCamelCase__ ) self.assertEqual(lowerCamelCase__ , '''h ə l oʊ h aʊ ɑːɹ j uː''' ) self.assertEqual(lowerCamelCase__ , '''ɛ l o h aʊ a ʁ j u''' ) def SCREAMING_SNAKE_CASE ( self ) -> int: a =self.tokenizer_class.from_pretrained('''facebook/wav2vec2-lv-60-espeak-cv-ft''' ) a ='''Hello how Are you''' a ='''hello how are you''' a =tokenizer(lowerCamelCase__ ).input_ids a =tokenizer(lowerCamelCase__ ).input_ids self.assertEqual(lowerCamelCase__ , lowerCamelCase__ ) def SCREAMING_SNAKE_CASE ( self ) -> Tuple: a =self.tokenizer_class.from_pretrained('''facebook/wav2vec2-lv-60-espeak-cv-ft''' ) tokenizer.add_tokens(['''!''', '''?'''] ) tokenizer.add_special_tokens({'''cls_token''': '''$$$'''} ) # fmt: off a =[ [11, 5, 15, tokenizer.pad_token_id, 15, 8, 98, 392, 392, 393, 392, 392, 393, 394, 394], [24, 22, 5, 24, 22, 5, 77, tokenizer.pad_token_id, 394, 394], ] # fmt: on a =tokenizer.batch_decode(lowerCamelCase__ ) self.assertEqual(lowerCamelCase__ , ['''k s ɾ ɾ l ɭʲ!?!? $$$''', '''j ð s j ð s oːɹ $$$'''] ) @staticmethod def SCREAMING_SNAKE_CASE ( __A , __A ) -> str: a =[d[key] for d in offsets] return retrieved_list def SCREAMING_SNAKE_CASE ( self ) -> List[Any]: a =self.get_tokenizer(word_delimiter_token='''|''' ) tokenizer.add_tokens('''|''' ) # fmt: off # ksssɾɾ|ɾɾ<pad>ɾɾ|<pad>ɾlll|ɭʲ -> k s ɾ ɾ | ɾ l | ɭʲ" a =[11, 5, 5, 5, 15, 15, tokenizer.pad_token_id, 15, 15, tokenizer.word_delimiter_token_id, tokenizer.pad_token_id, 15, 8, 8, 8, tokenizer.word_delimiter_token_id, 98] # fmt: on a =tokenizer.decode(lowerCamelCase__ , output_char_offsets=lowerCamelCase__ , filter_word_delimiter_token=lowerCamelCase__ ) # check Wav2Vec2CTCTokenizerOutput keys for char self.assertEqual(len(outputs.keys() ) , 2 ) self.assertTrue('''text''' in outputs ) self.assertTrue('''char_offsets''' in outputs ) self.assertTrue(isinstance(lowerCamelCase__ , lowerCamelCase__ ) ) # check that order of chars is correct and identical for both outputs self.assertEqual(''' '''.join(self.get_from_offsets(outputs['''char_offsets'''] , '''char''' ) ) , outputs.text ) self.assertListEqual( self.get_from_offsets(outputs['''char_offsets'''] , '''char''' ) , ['''k''', '''s''', '''ɾ''', '''ɾ''', '''|''', '''ɾ''', '''l''', '''|''', '''ɭʲ'''] ) # check that offsets are actually correct for char # 0-1 is 11, 1-4 is 5, 4-6 is first 15, 6-7 is <pad> (thus not shown), 7-9 is second 15, 9-10 is word_delimiter_token, # 10-11 is <pad> (thus not shown), 11-12 is third 15, 12-15 is 8, 15-16 is word_delimiter_token, 16-17 is 98 self.assertListEqual( self.get_from_offsets(outputs['''char_offsets'''] , '''start_offset''' ) , [0, 1, 4, 7, 9, 11, 12, 15, 16] ) self.assertListEqual( self.get_from_offsets(outputs['''char_offsets'''] , '''end_offset''' ) , [1, 4, 6, 9, 10, 12, 15, 16, 17] ) def SCREAMING_SNAKE_CASE ( self ) -> List[Any]: a =self.get_tokenizer(word_delimiter_token='''|''' ) def check_list_tuples_equal(__A , __A ): self.assertTrue(isinstance(lowerCamelCase__ , lowerCamelCase__ ) ) self.assertTrue(isinstance(outputs_list[0] , lowerCamelCase__ ) ) # transform list to ModelOutput a =WavaVecaPhonemeCTCTokenizerOutput( {k: [d[k] for d in outputs_list] for k in outputs_list[0]} ) self.assertListEqual(outputs_batch['''text'''] , outputs_batch_a['''text'''] ) def recursive_check(__A , __A ): if isinstance(lowerCamelCase__ , lowerCamelCase__ ): [recursive_check(lowerCamelCase__ , lowerCamelCase__ ) for la, la in zip(lowerCamelCase__ , lowerCamelCase__ )] self.assertEqual(lowerCamelCase__ , lowerCamelCase__ ) if "char_offsets" in outputs_batch: recursive_check(outputs_batch['''char_offsets'''] , outputs_batch_a['''char_offsets'''] ) # fmt: off a =[ [11, 5, 15, tokenizer.pad_token_id, 15, 4, 8, 98, 32, 32, 32, 32, 4, 33, tokenizer.word_delimiter_token_id, 32, 32, 33, 34, 34], [24, 22, 5, tokenizer.word_delimiter_token_id, tokenizer.word_delimiter_token_id, 24, 22, 22, 22, 4, 5, 77, tokenizer.pad_token_id, 22, 22, 4, 34, 34, 34, 34], ] # fmt: on # We assume that `decode` works as expected. All we will check now is # the output type is correct and the output is identical to `decode` # char a =tokenizer.batch_decode(lowerCamelCase__ , output_char_offsets=lowerCamelCase__ ) a =[tokenizer.decode(lowerCamelCase__ , output_char_offsets=lowerCamelCase__ ) for ids in sample_ids] check_list_tuples_equal(lowerCamelCase__ , lowerCamelCase__ ) @unittest.skip('''Wav2Vec2PhonemeTokenizer always lower cases letters to correctly map to phonemes''' ) def SCREAMING_SNAKE_CASE ( self ) -> Tuple: pass @unittest.skip('''Wav2Vec2PhonemeTokenizer always puts spaces between phonemes''' ) def SCREAMING_SNAKE_CASE ( self ) -> str: pass @unittest.skip('''encodes to text to ids, but decodes ids to phonemes -> not possible to have internal consistency''' ) def SCREAMING_SNAKE_CASE ( self ) -> Optional[Any]: pass @unittest.skip('''Wav2Vec2PhonemeModel has no max model length => no testing''' ) def SCREAMING_SNAKE_CASE ( self ) -> str: pass def SCREAMING_SNAKE_CASE ( self ) -> Any: a =self.get_tokenizers(do_lower_case=lowerCamelCase__ ) for tokenizer in tokenizers: with self.subTest(f'''{tokenizer.__class__.__name__}''' ): a =tokenizer.vocab_size a =len(lowerCamelCase__ ) self.assertNotEqual(lowerCamelCase__ , 0 ) # We usually have added tokens from the start in tests because our vocab fixtures are # smaller than the original vocabs - let's not assert this # self.assertEqual(vocab_size, all_size) a =['''aaaaa bbbbbb''', '''cccccccccdddddddd'''] a =tokenizer.add_tokens(lowerCamelCase__ ) a =tokenizer.vocab_size a =len(lowerCamelCase__ ) self.assertNotEqual(lowerCamelCase__ , 0 ) self.assertEqual(lowerCamelCase__ , lowerCamelCase__ ) self.assertEqual(lowerCamelCase__ , len(lowerCamelCase__ ) ) self.assertEqual(lowerCamelCase__ , all_size + len(lowerCamelCase__ ) ) a =tokenizer.encode('''aaaaa bbbbbb low cccccccccdddddddd l''' , add_special_tokens=lowerCamelCase__ ) self.assertGreaterEqual(len(lowerCamelCase__ ) , 4 ) self.assertGreater(tokens[0] , tokenizer.vocab_size - 1 ) self.assertGreater(tokens[-3] , tokenizer.vocab_size - 1 ) a ={'''eos_token''': '''>>>>|||<||<<|<<''', '''pad_token''': '''<<<<<|||>|>>>>|>'''} a =tokenizer.add_special_tokens(lowerCamelCase__ ) a =tokenizer.vocab_size a =len(lowerCamelCase__ ) self.assertNotEqual(lowerCamelCase__ , 0 ) self.assertEqual(lowerCamelCase__ , lowerCamelCase__ ) self.assertEqual(lowerCamelCase__ , len(lowerCamelCase__ ) ) self.assertEqual(lowerCamelCase__ , all_size_a + len(lowerCamelCase__ ) ) a =tokenizer.encode( '''>>>>|||<||<<|<< aaaaabbbbbb low cccccccccdddddddd <<<<<|||>|>>>>|> l''' , add_special_tokens=lowerCamelCase__ ) self.assertGreaterEqual(len(lowerCamelCase__ ) , 6 ) self.assertGreater(tokens[0] , tokenizer.vocab_size - 1 ) self.assertGreater(tokens[0] , tokens[1] ) self.assertGreater(tokens[-3] , tokenizer.vocab_size - 1 ) self.assertGreater(tokens[-3] , tokens[-4] ) self.assertEqual(tokens[0] , tokenizer.eos_token_id ) self.assertEqual(tokens[-3] , tokenizer.pad_token_id ) @unittest.skip('''The tokenizer shouldn\'t be used to encode input IDs (except for labels), only to decode.''' ) def SCREAMING_SNAKE_CASE ( self ) -> Tuple: pass @unittest.skip('''The tokenizer shouldn\'t be used to encode input IDs (except for labels), only to decode.''' ) def SCREAMING_SNAKE_CASE ( self ) -> Union[str, Any]: pass def SCREAMING_SNAKE_CASE ( self ) -> int: a =self.get_tokenizers(fast=lowerCamelCase__ , do_lower_case=lowerCamelCase__ ) for tokenizer in tokenizers: with self.subTest(f'''{tokenizer.__class__.__name__}''' ): a =['''ð''', '''ɪ''', '''s''', '''ɪ''', '''z''', '''ɐ''', '''t''', '''ɛ''', '''k''', '''s''', '''t'''] a =tokenizer.convert_tokens_to_string(lowerCamelCase__ ) self.assertIsInstance(output['''text'''] , lowerCamelCase__ )
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from ..utils import DummyObject, requires_backends class __lowerCAmelCase ( metaclass=__magic_name__ ): """simple docstring""" snake_case_ = ['''onnx'''] def __init__( self , *lowerCamelCase__ , **lowerCamelCase__ ) -> Optional[Any]: '''simple docstring''' requires_backends(self , ['onnx'] ) @classmethod def lowercase_ ( cls , *lowerCamelCase__ , **lowerCamelCase__ ) -> Dict: '''simple docstring''' requires_backends(cls , ['onnx'] ) @classmethod def lowercase_ ( cls , *lowerCamelCase__ , **lowerCamelCase__ ) -> List[str]: '''simple docstring''' requires_backends(cls , ['onnx'] )
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0
from typing import TYPE_CHECKING from ...utils import ( OptionalDependencyNotAvailable, _LazyModule, is_sentencepiece_available, is_tf_available, is_tokenizers_available, is_torch_available, ) a__ = { """configuration_rembert""": ["""REMBERT_PRETRAINED_CONFIG_ARCHIVE_MAP""", """RemBertConfig""", """RemBertOnnxConfig"""] } try: if not is_sentencepiece_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: a__ = ["""RemBertTokenizer"""] try: if not is_tokenizers_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: a__ = ["""RemBertTokenizerFast"""] try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: a__ = [ """REMBERT_PRETRAINED_MODEL_ARCHIVE_LIST""", """RemBertForCausalLM""", """RemBertForMaskedLM""", """RemBertForMultipleChoice""", """RemBertForQuestionAnswering""", """RemBertForSequenceClassification""", """RemBertForTokenClassification""", """RemBertLayer""", """RemBertModel""", """RemBertPreTrainedModel""", """load_tf_weights_in_rembert""", ] try: if not is_tf_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: a__ = [ """TF_REMBERT_PRETRAINED_MODEL_ARCHIVE_LIST""", """TFRemBertForCausalLM""", """TFRemBertForMaskedLM""", """TFRemBertForMultipleChoice""", """TFRemBertForQuestionAnswering""", """TFRemBertForSequenceClassification""", """TFRemBertForTokenClassification""", """TFRemBertLayer""", """TFRemBertModel""", """TFRemBertPreTrainedModel""", ] if TYPE_CHECKING: from .configuration_rembert import REMBERT_PRETRAINED_CONFIG_ARCHIVE_MAP, RemBertConfig, RemBertOnnxConfig try: if not is_sentencepiece_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .tokenization_rembert import RemBertTokenizer try: if not is_tokenizers_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .tokenization_rembert_fast import RemBertTokenizerFast try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_rembert import ( REMBERT_PRETRAINED_MODEL_ARCHIVE_LIST, RemBertForCausalLM, RemBertForMaskedLM, RemBertForMultipleChoice, RemBertForQuestionAnswering, RemBertForSequenceClassification, RemBertForTokenClassification, RemBertLayer, RemBertModel, RemBertPreTrainedModel, load_tf_weights_in_rembert, ) try: if not is_tf_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_tf_rembert import ( TF_REMBERT_PRETRAINED_MODEL_ARCHIVE_LIST, TFRemBertForCausalLM, TFRemBertForMaskedLM, TFRemBertForMultipleChoice, TFRemBertForQuestionAnswering, TFRemBertForSequenceClassification, TFRemBertForTokenClassification, TFRemBertLayer, TFRemBertModel, TFRemBertPreTrainedModel, ) else: import sys a__ = _LazyModule(__name__, globals()["""__file__"""], _import_structure, module_spec=__spec__)
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import itertools import os import random import tempfile import unittest import numpy as np from datasets import load_dataset from transformers import is_speech_available from transformers.testing_utils import check_json_file_has_correct_format, require_torch, require_torchaudio from transformers.utils.import_utils import is_torch_available from ...test_sequence_feature_extraction_common import SequenceFeatureExtractionTestMixin if is_speech_available(): from transformers import WhisperFeatureExtractor if is_torch_available(): import torch __A = random.Random() def lowerCamelCase_ ( UpperCamelCase__ : Optional[int] , UpperCamelCase__ : List[str]=1.0 , UpperCamelCase__ : Union[str, Any]=None , UpperCamelCase__ : Optional[int]=None ) -> Optional[Any]: """simple docstring""" if rng is None: __lowerCamelCase = global_rng __lowerCamelCase = [] for batch_idx in range(shape[0] ): values.append([] ) for _ in range(shape[1] ): values[-1].append(rng.random() * scale ) return values @require_torch @require_torchaudio class __lowerCAmelCase ( unittest.TestCase ): """simple docstring""" def __init__( self , lowerCamelCase__ , lowerCamelCase__=7 , lowerCamelCase__=400 , lowerCamelCase__=2_000 , lowerCamelCase__=10 , lowerCamelCase__=160 , lowerCamelCase__=8 , lowerCamelCase__=0.0 , lowerCamelCase__=4_000 , lowerCamelCase__=False , lowerCamelCase__=True , ) -> List[str]: '''simple docstring''' __lowerCamelCase = parent __lowerCamelCase = batch_size __lowerCamelCase = min_seq_length __lowerCamelCase = max_seq_length __lowerCamelCase = (self.max_seq_length - self.min_seq_length) // (self.batch_size - 1) __lowerCamelCase = padding_value __lowerCamelCase = sampling_rate __lowerCamelCase = return_attention_mask __lowerCamelCase = do_normalize __lowerCamelCase = feature_size __lowerCamelCase = chunk_length __lowerCamelCase = hop_length def lowercase_ ( self ) -> Any: '''simple docstring''' return { "feature_size": self.feature_size, "hop_length": self.hop_length, "chunk_length": self.chunk_length, "padding_value": self.padding_value, "sampling_rate": self.sampling_rate, "return_attention_mask": self.return_attention_mask, "do_normalize": self.do_normalize, } def lowercase_ ( self , lowerCamelCase__=False , lowerCamelCase__=False ) -> Optional[int]: '''simple docstring''' def _flatten(lowerCamelCase__ ): return list(itertools.chain(*lowerCamelCase__ ) ) if equal_length: __lowerCamelCase = [floats_list((self.max_seq_length, self.feature_size) ) for _ in range(self.batch_size )] else: # make sure that inputs increase in size __lowerCamelCase = [ floats_list((x, self.feature_size) ) for x in range(self.min_seq_length , self.max_seq_length , self.seq_length_diff ) ] if numpify: __lowerCamelCase = [np.asarray(lowerCamelCase__ ) for x in speech_inputs] return speech_inputs @require_torch @require_torchaudio class __lowerCAmelCase ( __magic_name__ , unittest.TestCase ): """simple docstring""" snake_case_ = WhisperFeatureExtractor if is_speech_available() else None def lowercase_ ( self ) -> Any: '''simple docstring''' __lowerCamelCase = WhisperFeatureExtractionTester(self ) def lowercase_ ( self ) -> List[str]: '''simple docstring''' __lowerCamelCase = self.feature_extraction_class(**self.feat_extract_dict ) with tempfile.TemporaryDirectory() as tmpdirname: __lowerCamelCase = feat_extract_first.save_pretrained(lowerCamelCase__ )[0] check_json_file_has_correct_format(lowerCamelCase__ ) __lowerCamelCase = self.feature_extraction_class.from_pretrained(lowerCamelCase__ ) __lowerCamelCase = feat_extract_first.to_dict() __lowerCamelCase = feat_extract_second.to_dict() __lowerCamelCase = feat_extract_first.mel_filters __lowerCamelCase = feat_extract_second.mel_filters self.assertTrue(np.allclose(lowerCamelCase__ , lowerCamelCase__ ) ) self.assertEqual(lowerCamelCase__ , lowerCamelCase__ ) def lowercase_ ( self ) -> Dict: '''simple docstring''' __lowerCamelCase = self.feature_extraction_class(**self.feat_extract_dict ) with tempfile.TemporaryDirectory() as tmpdirname: __lowerCamelCase = os.path.join(lowerCamelCase__ , 'feat_extract.json' ) feat_extract_first.to_json_file(lowerCamelCase__ ) __lowerCamelCase = self.feature_extraction_class.from_json_file(lowerCamelCase__ ) __lowerCamelCase = feat_extract_first.to_dict() __lowerCamelCase = feat_extract_second.to_dict() __lowerCamelCase = feat_extract_first.mel_filters __lowerCamelCase = feat_extract_second.mel_filters self.assertTrue(np.allclose(lowerCamelCase__ , lowerCamelCase__ ) ) self.assertEqual(lowerCamelCase__ , lowerCamelCase__ ) def lowercase_ ( self ) -> Dict: '''simple docstring''' # Tests that all call wrap to encode_plus and batch_encode_plus __lowerCamelCase = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) # create three inputs of length 800, 1000, and 1200 __lowerCamelCase = [floats_list((1, x) )[0] for x in range(800 , 1_400 , 200 )] __lowerCamelCase = [np.asarray(lowerCamelCase__ ) for speech_input in speech_inputs] # Test feature size __lowerCamelCase = feature_extractor(lowerCamelCase__ , padding='max_length' , return_tensors='np' ).input_features self.assertTrue(input_features.ndim == 3 ) self.assertTrue(input_features.shape[-1] == feature_extractor.nb_max_frames ) self.assertTrue(input_features.shape[-2] == feature_extractor.feature_size ) # Test not batched input __lowerCamelCase = feature_extractor(speech_inputs[0] , return_tensors='np' ).input_features __lowerCamelCase = feature_extractor(np_speech_inputs[0] , return_tensors='np' ).input_features self.assertTrue(np.allclose(lowerCamelCase__ , lowerCamelCase__ , atol=1e-3 ) ) # Test batched __lowerCamelCase = feature_extractor(lowerCamelCase__ , return_tensors='np' ).input_features __lowerCamelCase = feature_extractor(lowerCamelCase__ , return_tensors='np' ).input_features for enc_seq_a, enc_seq_a in zip(lowerCamelCase__ , lowerCamelCase__ ): self.assertTrue(np.allclose(lowerCamelCase__ , lowerCamelCase__ , atol=1e-3 ) ) # Test 2-D numpy arrays are batched. __lowerCamelCase = [floats_list((1, x) )[0] for x in (800, 800, 800)] __lowerCamelCase = np.asarray(lowerCamelCase__ ) __lowerCamelCase = feature_extractor(lowerCamelCase__ , return_tensors='np' ).input_features __lowerCamelCase = feature_extractor(lowerCamelCase__ , return_tensors='np' ).input_features for enc_seq_a, enc_seq_a in zip(lowerCamelCase__ , lowerCamelCase__ ): self.assertTrue(np.allclose(lowerCamelCase__ , lowerCamelCase__ , atol=1e-3 ) ) # Test truncation required __lowerCamelCase = [floats_list((1, x) )[0] for x in range(200 , (feature_extractor.n_samples + 500) , 200 )] __lowerCamelCase = [np.asarray(lowerCamelCase__ ) for speech_input in speech_inputs] __lowerCamelCase = [x[: feature_extractor.n_samples] for x in speech_inputs] __lowerCamelCase = [np.asarray(lowerCamelCase__ ) for speech_input in speech_inputs_truncated] __lowerCamelCase = feature_extractor(lowerCamelCase__ , return_tensors='np' ).input_features __lowerCamelCase = feature_extractor(lowerCamelCase__ , return_tensors='np' ).input_features for enc_seq_a, enc_seq_a in zip(lowerCamelCase__ , lowerCamelCase__ ): self.assertTrue(np.allclose(lowerCamelCase__ , lowerCamelCase__ , atol=1e-3 ) ) def lowercase_ ( self ) -> List[str]: '''simple docstring''' import torch __lowerCamelCase = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) __lowerCamelCase = np.random.rand(100 , 32 ).astype(np.floataa ) __lowerCamelCase = np_speech_inputs.tolist() for inputs in [py_speech_inputs, np_speech_inputs]: __lowerCamelCase = feature_extractor.pad([{'input_features': inputs}] , return_tensors='np' ) self.assertTrue(np_processed.input_features.dtype == np.floataa ) __lowerCamelCase = feature_extractor.pad([{'input_features': inputs}] , return_tensors='pt' ) self.assertTrue(pt_processed.input_features.dtype == torch.floataa ) def lowercase_ ( self , lowerCamelCase__ ) -> List[str]: '''simple docstring''' __lowerCamelCase = load_dataset('hf-internal-testing/librispeech_asr_dummy' , 'clean' , split='validation' ) # automatic decoding with librispeech __lowerCamelCase = ds.sort('id' ).select(range(lowerCamelCase__ ) )[:num_samples]['audio'] return [x["array"] for x in speech_samples] def lowercase_ ( self ) -> Tuple: '''simple docstring''' # fmt: off __lowerCamelCase = torch.tensor( [ 0.11_93, -0.09_46, -0.10_98, -0.01_96, 0.02_25, -0.06_90, -0.17_36, 0.09_51, 0.09_71, -0.08_17, -0.07_02, 0.01_62, 0.02_60, 0.00_17, -0.01_92, -0.16_78, 0.07_09, -0.18_67, -0.06_55, -0.02_74, -0.02_34, -0.18_84, -0.05_16, -0.05_54, -0.02_74, -0.14_25, -0.14_23, 0.08_37, 0.03_77, -0.08_54 ] ) # fmt: on __lowerCamelCase = self._load_datasamples(1 ) __lowerCamelCase = WhisperFeatureExtractor() __lowerCamelCase = feature_extractor(lowerCamelCase__ , return_tensors='pt' ).input_features self.assertEqual(input_features.shape , (1, 80, 3_000) ) self.assertTrue(torch.allclose(input_features[0, 0, :30] , lowerCamelCase__ , atol=1e-4 ) ) def lowercase_ ( self ) -> List[Any]: '''simple docstring''' __lowerCamelCase = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) __lowerCamelCase = self._load_datasamples(1 )[0] __lowerCamelCase = ((audio - audio.min()) / (audio.max() - audio.min())) * 65_535 # Rescale to [0, 65535] to show issue __lowerCamelCase = feat_extract.zero_mean_unit_var_norm([audio] , attention_mask=lowerCamelCase__ )[0] self.assertTrue(np.all(np.mean(lowerCamelCase__ ) < 1e-3 ) ) self.assertTrue(np.all(np.abs(np.var(lowerCamelCase__ ) - 1 ) < 1e-3 ) )
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"""simple docstring""" import logging import os from dataclasses import dataclass, field from functools import partial from pathlib import Path from tempfile import TemporaryDirectory from typing import List, Optional import faiss import torch from datasets import Features, Sequence, Value, load_dataset from transformers import DPRContextEncoder, DPRContextEncoderTokenizerFast, HfArgumentParser UpperCAmelCase : Tuple = logging.getLogger(__name__) torch.set_grad_enabled(False) UpperCAmelCase : Dict = "cuda" if torch.cuda.is_available() else "cpu" def _SCREAMING_SNAKE_CASE (__lowerCAmelCase , __lowerCAmelCase=1_00 , __lowerCAmelCase=" " ) -> List[str]: '''simple docstring''' lowercase_ = text.split(UpperCamelCase__ ) return [character.join(text[i : i + n] ).strip() for i in range(0 , len(UpperCamelCase__ ) , UpperCamelCase__ )] def _SCREAMING_SNAKE_CASE (__lowerCAmelCase ) -> dict: '''simple docstring''' lowercase_ , lowercase_ = [], [] for title, text in zip(documents["""title"""] , documents["""text"""] ): if text is not None: for passage in split_text(UpperCamelCase__ ): titles.append(title if title is not None else """""" ) texts.append(UpperCamelCase__ ) return {"title": titles, "text": texts} def _SCREAMING_SNAKE_CASE (__lowerCAmelCase , __lowerCAmelCase , __lowerCAmelCase ) -> dict: '''simple docstring''' lowercase_ = ctx_tokenizer( documents["""title"""] , documents["""text"""] , truncation=UpperCamelCase__ , padding="""longest""" , return_tensors="""pt""" )["""input_ids"""] lowercase_ = ctx_encoder(input_ids.to(device=UpperCamelCase__ ) , return_dict=UpperCamelCase__ ).pooler_output return {"embeddings": embeddings.detach().cpu().numpy()} def _SCREAMING_SNAKE_CASE (__lowerCAmelCase , __lowerCAmelCase , __lowerCAmelCase , ) -> Union[str, Any]: '''simple docstring''' logger.info("""Step 1 - Create the dataset""" ) ###################################### # The dataset needed for RAG must have three columns: # - title (string): title of the document # - text (string): text of a passage of the document # - embeddings (array of dimension d): DPR representation of the passage # Let's say you have documents in tab-separated csv files with columns "title" and "text" assert os.path.isfile(rag_example_args.csv_path ), "Please provide a valid path to a csv file" # You can load a Dataset object this way lowercase_ = load_dataset( """csv""" , data_files=[rag_example_args.csv_path] , split="""train""" , delimiter="""\t""" , column_names=["""title""", """text"""] ) # More info about loading csv files in the documentation: https://huggingface.co/docs/datasets/loading_datasets.html?highlight=csv#csv-files # Then split the documents into passages of 100 words lowercase_ = dataset.map(UpperCamelCase__ , batched=UpperCamelCase__ , num_proc=processing_args.num_proc ) # And compute the embeddings lowercase_ = DPRContextEncoder.from_pretrained(rag_example_args.dpr_ctx_encoder_model_name ).to(device=UpperCamelCase__ ) lowercase_ = DPRContextEncoderTokenizerFast.from_pretrained(rag_example_args.dpr_ctx_encoder_model_name ) lowercase_ = Features( {"""text""": Value("""string""" ), """title""": Value("""string""" ), """embeddings""": Sequence(Value("""float32""" ) )} ) # optional, save as float32 instead of float64 to save space lowercase_ = dataset.map( partial(UpperCamelCase__ , ctx_encoder=UpperCamelCase__ , ctx_tokenizer=UpperCamelCase__ ) , batched=UpperCamelCase__ , batch_size=processing_args.batch_size , features=UpperCamelCase__ , ) # And finally save your dataset lowercase_ = os.path.join(rag_example_args.output_dir , """my_knowledge_dataset""" ) dataset.save_to_disk(UpperCamelCase__ ) # from datasets import load_from_disk # dataset = load_from_disk(passages_path) # to reload the dataset ###################################### logger.info("""Step 2 - Index the dataset""" ) ###################################### # Let's use the Faiss implementation of HNSW for fast approximate nearest neighbor search lowercase_ = faiss.IndexHNSWFlat(index_hnsw_args.d , index_hnsw_args.m , faiss.METRIC_INNER_PRODUCT ) dataset.add_faiss_index("""embeddings""" , custom_index=UpperCamelCase__ ) # And save the index lowercase_ = os.path.join(rag_example_args.output_dir , """my_knowledge_dataset_hnsw_index.faiss""" ) dataset.get_index("""embeddings""" ).save(UpperCamelCase__ ) # dataset.load_faiss_index("embeddings", index_path) # to reload the index @dataclass class SCREAMING_SNAKE_CASE__ : lowercase__ = field( default=str(Path(__UpperCAmelCase ).parent / "test_run" / "dummy-kb" / "my_knowledge_dataset.csv" ) , metadata={"help": "Path to a tab-separated csv file with columns \'title\' and \'text\'"} , ) lowercase__ = field( default=__UpperCAmelCase , metadata={"help": "Question that is passed as input to RAG. Default is \'What does Moses\' rod turn into ?\'."} , ) lowercase__ = field( default="facebook/rag-sequence-nq" , metadata={"help": "The RAG model to use. Either \'facebook/rag-sequence-nq\' or \'facebook/rag-token-nq\'"} , ) lowercase__ = field( default="facebook/dpr-ctx_encoder-multiset-base" , metadata={ "help": ( "The DPR context encoder model to use. Either \'facebook/dpr-ctx_encoder-single-nq-base\' or" " \'facebook/dpr-ctx_encoder-multiset-base\'" ) } , ) lowercase__ = field( default=str(Path(__UpperCAmelCase ).parent / "test_run" / "dummy-kb" ) , metadata={"help": "Path to a directory where the dataset passages and the index will be saved"} , ) @dataclass class SCREAMING_SNAKE_CASE__ : lowercase__ = field( default=__UpperCAmelCase , metadata={ "help": "The number of processes to use to split the documents into passages. Default is single process." } , ) lowercase__ = field( default=16 , metadata={ "help": "The batch size to use when computing the passages embeddings using the DPR context encoder." } , ) @dataclass class SCREAMING_SNAKE_CASE__ : lowercase__ = field( default=768 , metadata={"help": "The dimension of the embeddings to pass to the HNSW Faiss index."} , ) lowercase__ = field( default=128 , metadata={ "help": ( "The number of bi-directional links created for every new element during the HNSW index construction." ) } , ) if __name__ == "__main__": logging.basicConfig(level=logging.WARNING) logger.setLevel(logging.INFO) UpperCAmelCase : Dict = HfArgumentParser((RagExampleArguments, ProcessingArguments, IndexHnswArguments)) UpperCAmelCase , UpperCAmelCase , UpperCAmelCase : str = parser.parse_args_into_dataclasses() with TemporaryDirectory() as tmp_dir: UpperCAmelCase : List[Any] = rag_example_args.output_dir or tmp_dir main(rag_example_args, processing_args, index_hnsw_args)
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from dataclasses import dataclass from typing import Tuple import numpy as np import torch @dataclass class __lowerCAmelCase : """simple docstring""" snake_case_ = 42 # [batch_size x 3] snake_case_ = 42 # [batch_size x 3] snake_case_ = 42 # [batch_size x 3] snake_case_ = 42 # [batch_size x 3] snake_case_ = 42 snake_case_ = 42 snake_case_ = 42 snake_case_ = 42 snake_case_ = 42 def lowercase_ ( self ) -> Union[str, Any]: '''simple docstring''' assert self.x.shape[0] == self.y.shape[0] == self.z.shape[0] == self.origin.shape[0] assert self.x.shape[1] == self.y.shape[1] == self.z.shape[1] == self.origin.shape[1] == 3 assert len(self.x.shape ) == len(self.y.shape ) == len(self.z.shape ) == len(self.origin.shape ) == 2 def lowercase_ ( self ) -> Optional[int]: '''simple docstring''' return torch.from_numpy(np.array([self.width, self.height] , dtype=np.floataa ) ) def lowercase_ ( self ) -> Optional[Any]: '''simple docstring''' return torch.from_numpy(np.array([self.x_fov, self.y_fov] , dtype=np.floataa ) ) def lowercase_ ( self ) -> torch.Tensor: '''simple docstring''' __lowerCamelCase = torch.arange(self.height * self.width ) __lowerCamelCase = torch.stack( [ pixel_indices % self.width, torch.div(lowerCamelCase__ , self.width , rounding_mode='trunc' ), ] , axis=1 , ) return coords @property def lowercase_ ( self ) -> int: '''simple docstring''' __lowerCamelCase , *__lowerCamelCase = self.shape __lowerCamelCase = int(np.prod(lowerCamelCase__ ) ) __lowerCamelCase = self.get_image_coords() __lowerCamelCase = torch.broadcast_to(coords.unsqueeze(0 ) , [batch_size * inner_batch_size, *coords.shape] ) __lowerCamelCase = self.get_camera_rays(lowerCamelCase__ ) __lowerCamelCase = rays.view(lowerCamelCase__ , inner_batch_size * self.height * self.width , 2 , 3 ) return rays def lowercase_ ( self , lowerCamelCase__ ) -> torch.Tensor: '''simple docstring''' __lowerCamelCase , *__lowerCamelCase , __lowerCamelCase = coords.shape assert n_coords == 2 assert batch_size == self.origin.shape[0] __lowerCamelCase = coords.view(lowerCamelCase__ , -1 , 2 ) __lowerCamelCase = self.resolution() __lowerCamelCase = self.fov() __lowerCamelCase = (flat.float() / (res - 1)) * 2 - 1 __lowerCamelCase = fracs * torch.tan(fov / 2 ) __lowerCamelCase = fracs.view(lowerCamelCase__ , -1 , 2 ) __lowerCamelCase = ( self.z.view(lowerCamelCase__ , 1 , 3 ) + self.x.view(lowerCamelCase__ , 1 , 3 ) * fracs[:, :, :1] + self.y.view(lowerCamelCase__ , 1 , 3 ) * fracs[:, :, 1:] ) __lowerCamelCase = directions / directions.norm(dim=-1 , keepdim=lowerCamelCase__ ) __lowerCamelCase = torch.stack( [ torch.broadcast_to(self.origin.view(lowerCamelCase__ , 1 , 3 ) , [batch_size, directions.shape[1], 3] ), directions, ] , dim=2 , ) return rays.view(lowerCamelCase__ , *lowerCamelCase__ , 2 , 3 ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ ) -> "DifferentiableProjectiveCamera": '''simple docstring''' assert width * self.height == height * self.width, "The aspect ratio should not change." return DifferentiableProjectiveCamera( origin=self.origin , x=self.x , y=self.y , z=self.z , width=lowerCamelCase__ , height=lowerCamelCase__ , x_fov=self.x_fov , y_fov=self.y_fov , ) def lowerCamelCase_ ( UpperCamelCase__ : int ) -> DifferentiableProjectiveCamera: """simple docstring""" __lowerCamelCase = [] __lowerCamelCase = [] __lowerCamelCase = [] __lowerCamelCase = [] for theta in np.linspace(0 , 2 * np.pi , num=20 ): __lowerCamelCase = np.array([np.sin(UpperCamelCase__ ), np.cos(UpperCamelCase__ ), -0.5] ) z /= np.sqrt(np.sum(z**2 ) ) __lowerCamelCase = -z * 4 __lowerCamelCase = np.array([np.cos(UpperCamelCase__ ), -np.sin(UpperCamelCase__ ), 0.0] ) __lowerCamelCase = np.cross(UpperCamelCase__ , UpperCamelCase__ ) origins.append(UpperCamelCase__ ) xs.append(UpperCamelCase__ ) ys.append(UpperCamelCase__ ) zs.append(UpperCamelCase__ ) return DifferentiableProjectiveCamera( origin=torch.from_numpy(np.stack(UpperCamelCase__ , axis=0 ) ).float() , x=torch.from_numpy(np.stack(UpperCamelCase__ , axis=0 ) ).float() , y=torch.from_numpy(np.stack(UpperCamelCase__ , axis=0 ) ).float() , z=torch.from_numpy(np.stack(UpperCamelCase__ , axis=0 ) ).float() , width=UpperCamelCase__ , height=UpperCamelCase__ , x_fov=0.7 , y_fov=0.7 , shape=(1, len(UpperCamelCase__ )) , )
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'''simple docstring''' from dataclasses import dataclass, field from typing import Tuple from ..utils import cached_property, is_tf_available, logging, requires_backends from .benchmark_args_utils import BenchmarkArguments if is_tf_available(): import tensorflow as tf lowercase_ = logging.get_logger(__name__) @dataclass class a_ ( snake_case_ ): '''simple docstring''' UpperCamelCase = [ '''no_inference''', '''no_cuda''', '''no_tpu''', '''no_speed''', '''no_memory''', '''no_env_print''', '''no_multi_process''', ] def __init__( self , **A ) -> int: for deprecated_arg in self.deprecated_args: if deprecated_arg in kwargs: _SCREAMING_SNAKE_CASE = deprecated_arg[3:] _SCREAMING_SNAKE_CASE = not kwargs.pop(lowerCamelCase__ ) logger.warning( f'{deprecated_arg} is depreciated. Please use --no-{positive_arg} or' f' {positive_arg}={kwargs[positive_arg]}' ) _SCREAMING_SNAKE_CASE = kwargs.pop("""tpu_name""" , self.tpu_name ) _SCREAMING_SNAKE_CASE = kwargs.pop("""device_idx""" , self.device_idx ) _SCREAMING_SNAKE_CASE = kwargs.pop("""eager_mode""" , self.eager_mode ) _SCREAMING_SNAKE_CASE = kwargs.pop("""use_xla""" , self.use_xla ) super().__init__(**lowerCamelCase__ ) UpperCamelCase = field( default=snake_case_ , metadata={'''help''': '''Name of TPU'''} , ) UpperCamelCase = field( default=0 , metadata={'''help''': '''CPU / GPU device index. Defaults to 0.'''} , ) UpperCamelCase = field(default=snake_case_ , metadata={'''help''': '''Benchmark models in eager model.'''} ) UpperCamelCase = field( default=snake_case_ , metadata={ '''help''': '''Benchmark models using XLA JIT compilation. Note that `eager_model` has to be set to `False`.''' } , ) @cached_property def snake_case_( self ) -> Tuple["tf.distribute.cluster_resolver.TPUClusterResolver"]: requires_backends(self , ["""tf"""] ) _SCREAMING_SNAKE_CASE = None if self.tpu: try: if self.tpu_name: _SCREAMING_SNAKE_CASE = tf.distribute.cluster_resolver.TPUClusterResolver(self.tpu_name ) else: _SCREAMING_SNAKE_CASE = tf.distribute.cluster_resolver.TPUClusterResolver() except ValueError: _SCREAMING_SNAKE_CASE = None return tpu @cached_property def snake_case_( self ) -> Tuple["tf.distribute.Strategy", "tf.distribute.cluster_resolver.TPUClusterResolver"]: requires_backends(self , ["""tf"""] ) if self.is_tpu: tf.config.experimental_connect_to_cluster(self._setup_tpu ) tf.tpu.experimental.initialize_tpu_system(self._setup_tpu ) _SCREAMING_SNAKE_CASE = tf.distribute.TPUStrategy(self._setup_tpu ) else: # currently no multi gpu is allowed if self.is_gpu: # TODO: Currently only single GPU is supported tf.config.set_visible_devices(self.gpu_list[self.device_idx] , """GPU""" ) _SCREAMING_SNAKE_CASE = tf.distribute.OneDeviceStrategy(device=f'/gpu:{self.device_idx}' ) else: tf.config.set_visible_devices([] , """GPU""" ) # disable GPU _SCREAMING_SNAKE_CASE = tf.distribute.OneDeviceStrategy(device=f'/cpu:{self.device_idx}' ) return strategy @property def snake_case_( self ) -> bool: requires_backends(self , ["""tf"""] ) return self._setup_tpu is not None @property def snake_case_( self ) -> "tf.distribute.Strategy": requires_backends(self , ["""tf"""] ) return self._setup_strategy @property def snake_case_( self ) -> Any: requires_backends(self , ["""tf"""] ) return tf.config.list_physical_devices("""GPU""" ) @property def snake_case_( self ) -> int: requires_backends(self , ["""tf"""] ) if self.cuda: return len(self.gpu_list ) return 0 @property def snake_case_( self ) -> bool: return self.n_gpu > 0
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import collections import inspect import unittest from transformers import FocalNetConfig 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_backbone_common import BackboneTesterMixin 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 ( FocalNetBackbone, FocalNetForImageClassification, FocalNetForMaskedImageModeling, FocalNetModel, ) from transformers.models.focalnet.modeling_focalnet import FOCALNET_PRETRAINED_MODEL_ARCHIVE_LIST if is_vision_available(): from PIL import Image from transformers import AutoImageProcessor class __lowerCAmelCase : """simple docstring""" def __init__( self , lowerCamelCase__ , lowerCamelCase__=13 , lowerCamelCase__=32 , lowerCamelCase__=2 , lowerCamelCase__=3 , lowerCamelCase__=16 , lowerCamelCase__=[32, 64, 128] , lowerCamelCase__=[1, 2, 1] , lowerCamelCase__=[2, 2, 4] , lowerCamelCase__=2 , lowerCamelCase__=2.0 , lowerCamelCase__=True , lowerCamelCase__=0.0 , lowerCamelCase__=0.0 , lowerCamelCase__=0.1 , lowerCamelCase__="gelu" , lowerCamelCase__=False , lowerCamelCase__=True , lowerCamelCase__=0.02 , lowerCamelCase__=1e-5 , lowerCamelCase__=True , lowerCamelCase__=None , lowerCamelCase__=True , lowerCamelCase__=10 , lowerCamelCase__=8 , lowerCamelCase__=["stage1", "stage2"] , lowerCamelCase__=[1, 2] , ) -> int: '''simple docstring''' __lowerCamelCase = parent __lowerCamelCase = batch_size __lowerCamelCase = image_size __lowerCamelCase = patch_size __lowerCamelCase = num_channels __lowerCamelCase = embed_dim __lowerCamelCase = hidden_sizes __lowerCamelCase = depths __lowerCamelCase = num_heads __lowerCamelCase = window_size __lowerCamelCase = mlp_ratio __lowerCamelCase = qkv_bias __lowerCamelCase = hidden_dropout_prob __lowerCamelCase = attention_probs_dropout_prob __lowerCamelCase = drop_path_rate __lowerCamelCase = hidden_act __lowerCamelCase = use_absolute_embeddings __lowerCamelCase = patch_norm __lowerCamelCase = layer_norm_eps __lowerCamelCase = initializer_range __lowerCamelCase = is_training __lowerCamelCase = scope __lowerCamelCase = use_labels __lowerCamelCase = type_sequence_label_size __lowerCamelCase = encoder_stride __lowerCamelCase = out_features __lowerCamelCase = out_indices def lowercase_ ( self ) -> List[Any]: '''simple docstring''' __lowerCamelCase = floats_tensor([self.batch_size, self.num_channels, self.image_size, self.image_size] ) __lowerCamelCase = None if self.use_labels: __lowerCamelCase = ids_tensor([self.batch_size] , self.type_sequence_label_size ) __lowerCamelCase = self.get_config() return config, pixel_values, labels def lowercase_ ( self ) -> List[str]: '''simple docstring''' return FocalNetConfig( image_size=self.image_size , patch_size=self.patch_size , num_channels=self.num_channels , embed_dim=self.embed_dim , hidden_sizes=self.hidden_sizes , 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 lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> int: '''simple docstring''' __lowerCamelCase = FocalNetModel(config=lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model(lowerCamelCase__ ) __lowerCamelCase = ((config.image_size // config.patch_size) ** 2) // (4 ** (len(config.depths ) - 1)) __lowerCamelCase = int(config.embed_dim * 2 ** (len(config.depths ) - 1) ) self.parent.assertEqual(result.last_hidden_state.shape , (self.batch_size, expected_seq_len, expected_dim) ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> List[Any]: '''simple docstring''' __lowerCamelCase = FocalNetBackbone(config=lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model(lowerCamelCase__ ) # verify feature maps self.parent.assertEqual(len(result.feature_maps ) , len(config.out_features ) ) self.parent.assertListEqual(list(result.feature_maps[0].shape ) , [self.batch_size, self.image_size, 8, 8] ) # verify channels self.parent.assertEqual(len(model.channels ) , len(config.out_features ) ) self.parent.assertListEqual(model.channels , config.hidden_sizes[:-1] ) # verify backbone works with out_features=None __lowerCamelCase = None __lowerCamelCase = FocalNetBackbone(config=lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model(lowerCamelCase__ ) # verify feature maps self.parent.assertEqual(len(result.feature_maps ) , 1 ) self.parent.assertListEqual(list(result.feature_maps[0].shape ) , [self.batch_size, self.image_size * 2, 4, 4] ) # verify channels self.parent.assertEqual(len(model.channels ) , 1 ) self.parent.assertListEqual(model.channels , [config.hidden_sizes[-1]] ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> int: '''simple docstring''' __lowerCamelCase = FocalNetForMaskedImageModeling(config=lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model(lowerCamelCase__ ) self.parent.assertEqual( result.reconstruction.shape , (self.batch_size, self.num_channels, self.image_size, self.image_size) ) # test greyscale images __lowerCamelCase = 1 __lowerCamelCase = FocalNetForMaskedImageModeling(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = floats_tensor([self.batch_size, 1, self.image_size, self.image_size] ) __lowerCamelCase = model(lowerCamelCase__ ) self.parent.assertEqual(result.reconstruction.shape , (self.batch_size, 1, self.image_size, self.image_size) ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> str: '''simple docstring''' __lowerCamelCase = self.type_sequence_label_size __lowerCamelCase = FocalNetForImageClassification(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model(lowerCamelCase__ , labels=lowerCamelCase__ ) self.parent.assertEqual(result.logits.shape , (self.batch_size, self.type_sequence_label_size) ) # test greyscale images __lowerCamelCase = 1 __lowerCamelCase = FocalNetForImageClassification(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = floats_tensor([self.batch_size, 1, self.image_size, self.image_size] ) __lowerCamelCase = model(lowerCamelCase__ ) self.parent.assertEqual(result.logits.shape , (self.batch_size, self.type_sequence_label_size) ) def lowercase_ ( self ) -> Tuple: '''simple docstring''' __lowerCamelCase = self.prepare_config_and_inputs() __lowerCamelCase , __lowerCamelCase , __lowerCamelCase = config_and_inputs __lowerCamelCase = {'pixel_values': pixel_values} return config, inputs_dict @require_torch class __lowerCAmelCase ( __magic_name__ , __magic_name__ , unittest.TestCase ): """simple docstring""" snake_case_ = ( ( FocalNetModel, FocalNetForImageClassification, FocalNetForMaskedImageModeling, FocalNetBackbone, ) if is_torch_available() else () ) snake_case_ = ( {'''feature-extraction''': FocalNetModel, '''image-classification''': FocalNetForImageClassification} if is_torch_available() else {} ) snake_case_ = False snake_case_ = False snake_case_ = False snake_case_ = False snake_case_ = False def lowercase_ ( self ) -> str: '''simple docstring''' __lowerCamelCase = FocalNetModelTester(self ) __lowerCamelCase = ConfigTester(self , config_class=lowerCamelCase__ , embed_dim=37 , has_text_modality=lowerCamelCase__ ) def lowercase_ ( self ) -> str: '''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 lowercase_ ( self ) -> str: '''simple docstring''' return def lowercase_ ( self ) -> List[Any]: '''simple docstring''' __lowerCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_model(*lowerCamelCase__ ) def lowercase_ ( self ) -> Optional[Any]: '''simple docstring''' __lowerCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_backbone(*lowerCamelCase__ ) def lowercase_ ( self ) -> str: '''simple docstring''' __lowerCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_for_masked_image_modeling(*lowerCamelCase__ ) def lowercase_ ( self ) -> Any: '''simple docstring''' __lowerCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_for_image_classification(*lowerCamelCase__ ) @unittest.skip(reason='FocalNet does not use inputs_embeds' ) def lowercase_ ( self ) -> Optional[int]: '''simple docstring''' pass @unittest.skip(reason='FocalNet does not use feedforward chunking' ) def lowercase_ ( self ) -> Union[str, Any]: '''simple docstring''' pass def lowercase_ ( self ) -> Dict: '''simple docstring''' __lowerCamelCase , __lowerCamelCase = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes[:-1]: __lowerCamelCase = model_class(lowerCamelCase__ ) self.assertIsInstance(model.get_input_embeddings() , (nn.Module) ) __lowerCamelCase = model.get_output_embeddings() self.assertTrue(x is None or isinstance(lowerCamelCase__ , nn.Linear ) ) def lowercase_ ( self ) -> str: '''simple docstring''' __lowerCamelCase , __lowerCamelCase = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes[:-1]: __lowerCamelCase = model_class(lowerCamelCase__ ) __lowerCamelCase = inspect.signature(model.forward ) # signature.parameters is an OrderedDict => so arg_names order is deterministic __lowerCamelCase = [*signature.parameters.keys()] __lowerCamelCase = ['pixel_values'] self.assertListEqual(arg_names[:1] , lowerCamelCase__ ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> int: '''simple docstring''' __lowerCamelCase = model_class(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() with torch.no_grad(): __lowerCamelCase = model(**self._prepare_for_class(lowerCamelCase__ , lowerCamelCase__ ) ) __lowerCamelCase = outputs.hidden_states __lowerCamelCase = getattr( self.model_tester , 'expected_num_hidden_layers' , len(self.model_tester.depths ) + 1 ) self.assertEqual(len(lowerCamelCase__ ) , lowerCamelCase__ ) # FocalNet has a different seq_length __lowerCamelCase = ( config.patch_size if isinstance(config.patch_size , collections.abc.Iterable ) else (config.patch_size, config.patch_size) ) __lowerCamelCase = (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] , ) __lowerCamelCase = outputs.reshaped_hidden_states self.assertEqual(len(lowerCamelCase__ ) , lowerCamelCase__ ) __lowerCamelCase , __lowerCamelCase , __lowerCamelCase , __lowerCamelCase = reshaped_hidden_states[0].shape __lowerCamelCase = ( reshaped_hidden_states[0].view(lowerCamelCase__ , lowerCamelCase__ , height * width ).permute(0 , 2 , 1 ) ) self.assertListEqual( list(reshaped_hidden_states.shape[-2:] ) , [num_patches, self.model_tester.embed_dim] , ) def lowercase_ ( self ) -> Dict: '''simple docstring''' __lowerCamelCase , __lowerCamelCase = self.model_tester.prepare_config_and_inputs_for_common() __lowerCamelCase = ( 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[:-1]: __lowerCamelCase = True self.check_hidden_states_output(lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) # check that output_hidden_states also work using config del inputs_dict["output_hidden_states"] __lowerCamelCase = True self.check_hidden_states_output(lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) def lowercase_ ( self ) -> Optional[Any]: '''simple docstring''' __lowerCamelCase , __lowerCamelCase = self.model_tester.prepare_config_and_inputs_for_common() __lowerCamelCase = 3 __lowerCamelCase = ( 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) ) __lowerCamelCase = ( config.patch_size if isinstance(config.patch_size , collections.abc.Iterable ) else (config.patch_size, config.patch_size) ) __lowerCamelCase = image_size[0] + patch_size[0] - (image_size[0] % patch_size[0]) __lowerCamelCase = image_size[1] + patch_size[1] - (image_size[1] % patch_size[1]) for model_class in self.all_model_classes[:-1]: __lowerCamelCase = True self.check_hidden_states_output(lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , (padded_height, padded_width) ) # check that output_hidden_states also work using config del inputs_dict["output_hidden_states"] __lowerCamelCase = True self.check_hidden_states_output(lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , (padded_height, padded_width) ) @slow def lowercase_ ( self ) -> str: '''simple docstring''' for model_name in FOCALNET_PRETRAINED_MODEL_ARCHIVE_LIST[:1]: __lowerCamelCase = FocalNetModel.from_pretrained(lowerCamelCase__ ) self.assertIsNotNone(lowerCamelCase__ ) def lowercase_ ( self ) -> Optional[int]: '''simple docstring''' __lowerCamelCase , __lowerCamelCase = self.model_tester.prepare_config_and_inputs_for_common() __lowerCamelCase = _config_zero_init(lowerCamelCase__ ) for model_class in self.all_model_classes: __lowerCamelCase = model_class(config=lowerCamelCase__ ) for name, param in model.named_parameters(): if "embeddings" 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 lowercase_ ( self ) -> List[str]: '''simple docstring''' # TODO update organization return AutoImageProcessor.from_pretrained('microsoft/focalnet-tiny' ) if is_vision_available() else None @slow def lowercase_ ( self ) -> List[Any]: '''simple docstring''' __lowerCamelCase = FocalNetForImageClassification.from_pretrained('microsoft/focalnet-tiny' ).to(lowerCamelCase__ ) __lowerCamelCase = self.default_image_processor __lowerCamelCase = Image.open('./tests/fixtures/tests_samples/COCO/000000039769.png' ) __lowerCamelCase = image_processor(images=lowerCamelCase__ , return_tensors='pt' ).to(lowerCamelCase__ ) # forward pass with torch.no_grad(): __lowerCamelCase = model(**lowerCamelCase__ ) # verify the logits __lowerCamelCase = torch.Size((1, 1_000) ) self.assertEqual(outputs.logits.shape , lowerCamelCase__ ) __lowerCamelCase = torch.tensor([0.21_66, -0.43_68, 0.21_91] ).to(lowerCamelCase__ ) self.assertTrue(torch.allclose(outputs.logits[0, :3] , lowerCamelCase__ , atol=1e-4 ) ) self.assertTrue(outputs.logits.argmax(dim=-1 ).item() , 281 ) @require_torch class __lowerCAmelCase ( __magic_name__ , unittest.TestCase ): """simple docstring""" snake_case_ = (FocalNetBackbone,) if is_torch_available() else () snake_case_ = FocalNetConfig snake_case_ = False def lowercase_ ( self ) -> Any: '''simple docstring''' __lowerCamelCase = FocalNetModelTester(self )
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import json import os import unittest from transformers.models.ctrl.tokenization_ctrl import VOCAB_FILES_NAMES, CTRLTokenizer from ...test_tokenization_common import TokenizerTesterMixin class lowercase_ ( lowercase , unittest.TestCase ): '''simple docstring''' __snake_case = CTRLTokenizer __snake_case = False __snake_case = False def __lowerCAmelCase ( self : Tuple ) ->Any: """simple docstring""" super().setUp() # Adapted from Sennrich et al. 2015 and https://github.com/rsennrich/subword-nmt a = ['''adapt''', '''re@@''', '''a@@''', '''apt''', '''c@@''', '''t''', '''<unk>'''] a = dict(zip(lowerCamelCase__ , range(len(lowerCamelCase__ ) ) ) ) a = ['''#version: 0.2''', '''a p''', '''ap t</w>''', '''r e''', '''a d''', '''ad apt</w>''', ''''''] a = {'''unk_token''': '''<unk>'''} a = os.path.join(self.tmpdirname , VOCAB_FILES_NAMES['''vocab_file'''] ) a = os.path.join(self.tmpdirname , VOCAB_FILES_NAMES['''merges_file'''] ) with open(self.vocab_file , '''w''' , encoding='''utf-8''' ) as fp: fp.write(json.dumps(lowerCamelCase__ ) + '''\n''' ) with open(self.merges_file , '''w''' , encoding='''utf-8''' ) as fp: fp.write('''\n'''.join(lowerCamelCase__ ) ) def __lowerCAmelCase ( self : Tuple , **__UpperCAmelCase : Optional[int] ) ->Tuple: """simple docstring""" kwargs.update(self.special_tokens_map ) return CTRLTokenizer.from_pretrained(self.tmpdirname , **lowerCamelCase__ ) def __lowerCAmelCase ( self : Dict , __UpperCAmelCase : Optional[Any] ) ->int: """simple docstring""" a = '''adapt react readapt apt''' a = '''adapt react readapt apt''' return input_text, output_text def __lowerCAmelCase ( self : List[str] ) ->List[Any]: """simple docstring""" a = CTRLTokenizer(self.vocab_file , self.merges_file , **self.special_tokens_map ) a = '''adapt react readapt apt''' a = '''adapt re@@ a@@ c@@ t re@@ adapt apt'''.split() a = tokenizer.tokenize(lowerCamelCase__ ) self.assertListEqual(lowerCamelCase__ , lowerCamelCase__ ) a = tokens + [tokenizer.unk_token] a = [0, 1, 2, 4, 5, 1, 0, 3, 6] self.assertListEqual(tokenizer.convert_tokens_to_ids(lowerCamelCase__ ) , lowerCamelCase__ )
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from typing import TYPE_CHECKING from ...utils import OptionalDependencyNotAvailable, _LazyModule, is_speech_available, is_torch_available __A = { "configuration_audio_spectrogram_transformer": [ "AUDIO_SPECTROGRAM_TRANSFORMER_PRETRAINED_CONFIG_ARCHIVE_MAP", "ASTConfig", ] } try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __A = [ "AUDIO_SPECTROGRAM_TRANSFORMER_PRETRAINED_MODEL_ARCHIVE_LIST", "ASTForAudioClassification", "ASTModel", "ASTPreTrainedModel", ] try: if not is_speech_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __A = ["ASTFeatureExtractor"] if TYPE_CHECKING: from .configuration_audio_spectrogram_transformer import ( AUDIO_SPECTROGRAM_TRANSFORMER_PRETRAINED_CONFIG_ARCHIVE_MAP, ASTConfig, ) try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_audio_spectrogram_transformer import ( AUDIO_SPECTROGRAM_TRANSFORMER_PRETRAINED_MODEL_ARCHIVE_LIST, ASTForAudioClassification, ASTModel, ASTPreTrainedModel, ) try: if not is_speech_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .feature_extraction_audio_spectrogram_transformer import ASTFeatureExtractor else: import sys __A = _LazyModule(__name__, globals()["__file__"], _import_structure, module_spec=__spec__)
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from .glue import GlueDataset, GlueDataTrainingArguments from .language_modeling import ( LineByLineTextDataset, LineByLineWithRefDataset, LineByLineWithSOPTextDataset, TextDataset, TextDatasetForNextSentencePrediction, ) from .squad import SquadDataset, SquadDataTrainingArguments
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import argparse import os import pickle import sys import torch from transformers import TransfoXLConfig, TransfoXLLMHeadModel, load_tf_weights_in_transfo_xl from transformers.models.transfo_xl import tokenization_transfo_xl as data_utils from transformers.models.transfo_xl.tokenization_transfo_xl import CORPUS_NAME, VOCAB_FILES_NAMES from transformers.utils import CONFIG_NAME, WEIGHTS_NAME, logging logging.set_verbosity_info() # We do this to be able to load python 2 datasets pickles # See e.g. https://stackoverflow.com/questions/2121874/python-pickling-after-changing-a-modules-directory/2121918#2121918 __A = data_utils.TransfoXLTokenizer __A = data_utils.TransfoXLCorpus __A = data_utils __A = data_utils def lowerCamelCase_ ( UpperCamelCase__ : List[str] , UpperCamelCase__ : Optional[int] , UpperCamelCase__ : Union[str, Any] , UpperCamelCase__ : Optional[Any] ) -> Union[str, Any]: """simple docstring""" if transfo_xl_dataset_file: # Convert a pre-processed corpus (see original TensorFlow repo) with open(UpperCamelCase__ , 'rb' ) as fp: __lowerCamelCase = pickle.load(UpperCamelCase__ , encoding='latin1' ) # Save vocabulary and dataset cache as Dictionaries (should be better than pickles for the long-term) __lowerCamelCase = pytorch_dump_folder_path + '/' + VOCAB_FILES_NAMES['pretrained_vocab_file'] print(F"""Save vocabulary to {pytorch_vocab_dump_path}""" ) __lowerCamelCase = corpus.vocab.__dict__ torch.save(UpperCamelCase__ , UpperCamelCase__ ) __lowerCamelCase = corpus.__dict__ corpus_dict_no_vocab.pop('vocab' , UpperCamelCase__ ) __lowerCamelCase = pytorch_dump_folder_path + '/' + CORPUS_NAME print(F"""Save dataset to {pytorch_dataset_dump_path}""" ) torch.save(UpperCamelCase__ , UpperCamelCase__ ) if tf_checkpoint_path: # Convert a pre-trained TensorFlow model __lowerCamelCase = os.path.abspath(UpperCamelCase__ ) __lowerCamelCase = os.path.abspath(UpperCamelCase__ ) print(F"""Converting Transformer XL checkpoint from {tf_path} with config at {config_path}.""" ) # Initialise PyTorch model if transfo_xl_config_file == "": __lowerCamelCase = TransfoXLConfig() else: __lowerCamelCase = TransfoXLConfig.from_json_file(UpperCamelCase__ ) print(F"""Building PyTorch model from configuration: {config}""" ) __lowerCamelCase = TransfoXLLMHeadModel(UpperCamelCase__ ) __lowerCamelCase = load_tf_weights_in_transfo_xl(UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ ) # Save pytorch-model __lowerCamelCase = os.path.join(UpperCamelCase__ , UpperCamelCase__ ) __lowerCamelCase = os.path.join(UpperCamelCase__ , UpperCamelCase__ ) print(F"""Save PyTorch model to {os.path.abspath(UpperCamelCase__ )}""" ) torch.save(model.state_dict() , UpperCamelCase__ ) print(F"""Save configuration file to {os.path.abspath(UpperCamelCase__ )}""" ) with open(UpperCamelCase__ , 'w' , encoding='utf-8' ) as f: f.write(config.to_json_string() ) if __name__ == "__main__": __A = argparse.ArgumentParser() parser.add_argument( "--pytorch_dump_folder_path", default=None, type=str, required=True, help="Path to the folder to store the PyTorch model or dataset/vocab.", ) parser.add_argument( "--tf_checkpoint_path", default="", type=str, help="An optional path to a TensorFlow checkpoint path to be converted.", ) parser.add_argument( "--transfo_xl_config_file", default="", type=str, help=( "An optional config json file corresponding to the pre-trained BERT model. \n" "This specifies the model architecture." ), ) parser.add_argument( "--transfo_xl_dataset_file", default="", type=str, help="An optional dataset file to be converted in a vocabulary.", ) __A = parser.parse_args() convert_transfo_xl_checkpoint_to_pytorch( args.tf_checkpoint_path, args.transfo_xl_config_file, args.pytorch_dump_folder_path, args.transfo_xl_dataset_file, )
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"""simple docstring""" from typing import List, Optional, Union from ...configuration_utils import PretrainedConfig from ...utils import logging lowercase__ = logging.get_logger(__name__) lowercase__ = { 'huggingface/informer-tourism-monthly': ( 'https://huggingface.co/huggingface/informer-tourism-monthly/resolve/main/config.json' ), # See all Informer models at https://huggingface.co/models?filter=informer } class __snake_case ( __lowerCAmelCase ): a__ = """informer""" a__ = { """hidden_size""": """d_model""", """num_attention_heads""": """encoder_attention_heads""", """num_hidden_layers""": """encoder_layers""", } def __init__( self , lowercase = None , lowercase = None , lowercase = "student_t" , lowercase = "nll" , lowercase = 1 , lowercase = None , lowercase = "mean" , lowercase = 0 , lowercase = 0 , lowercase = 0 , lowercase = 0 , lowercase = None , lowercase = None , lowercase = 64 , lowercase = 32 , lowercase = 32 , lowercase = 2 , lowercase = 2 , lowercase = 2 , lowercase = 2 , lowercase = True , lowercase = "gelu" , lowercase = 0.05 , lowercase = 0.1 , lowercase = 0.1 , lowercase = 0.1 , lowercase = 0.1 , lowercase = 1_00 , lowercase = 0.02 , lowercase=True , lowercase = "prob" , lowercase = 5 , lowercase = True , **lowercase , ) -> Any: '''simple docstring''' a__: List[str] = prediction_length a__: int = context_length or prediction_length a__: Optional[int] = distribution_output a__: int = loss a__: Dict = input_size a__: Any = num_time_features a__: Dict = lags_sequence if lags_sequence is not None else [1, 2, 3, 4, 5, 6, 7] a__: Union[str, Any] = scaling a__: List[Any] = num_dynamic_real_features a__: Any = num_static_real_features a__: Tuple = num_static_categorical_features # set cardinality if cardinality and num_static_categorical_features > 0: if len(lowerCamelCase__) != num_static_categorical_features: raise ValueError( 'The cardinality should be a list of the same length as `num_static_categorical_features`') a__: int = cardinality else: a__: List[Any] = [0] # set embedding_dimension if embedding_dimension and num_static_categorical_features > 0: if len(lowerCamelCase__) != num_static_categorical_features: raise ValueError( 'The embedding dimension should be a list of the same length as `num_static_categorical_features`') a__: Dict = embedding_dimension else: a__: Union[str, Any] = [min(50 , (cat + 1) // 2) for cat in self.cardinality] a__: List[Any] = num_parallel_samples # Transformer architecture configuration a__: Optional[int] = input_size * len(self.lags_sequence) + self._number_of_features a__: Dict = d_model a__: List[str] = encoder_attention_heads a__: int = decoder_attention_heads a__: Optional[int] = encoder_ffn_dim a__: Union[str, Any] = decoder_ffn_dim a__: List[Any] = encoder_layers a__: Dict = decoder_layers a__: Optional[Any] = dropout a__: Union[str, Any] = attention_dropout a__: Union[str, Any] = activation_dropout a__: Union[str, Any] = encoder_layerdrop a__: int = decoder_layerdrop a__: Optional[int] = activation_function a__: List[Any] = init_std a__: Any = use_cache # Informer a__: Any = attention_type a__: Any = sampling_factor a__: Optional[int] = distil super().__init__(is_encoder_decoder=lowerCamelCase__ , **lowerCamelCase__) @property def lowerCamelCase_ ( self) -> int: '''simple docstring''' return ( sum(self.embedding_dimension) + self.num_dynamic_real_features + self.num_time_features + self.num_static_real_features + self.input_size * 2 # the log1p(abs(loc)) and log(scale) features )
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import argparse import shutil from pathlib import Path from tqdm import tqdm from transformers import AutoTokenizer def lowerCamelCase_ ( UpperCamelCase__ : List[Any] , UpperCamelCase__ : Optional[int] , UpperCamelCase__ : str , UpperCamelCase__ : Any=1024 ) -> Dict: """simple docstring""" __lowerCamelCase , __lowerCamelCase = [], [] __lowerCamelCase = list(zip(UpperCamelCase__ , UpperCamelCase__ ) ) __lowerCamelCase , __lowerCamelCase = sorted_examples[0] def is_too_big(UpperCamelCase__ : List[str] ): return tok(UpperCamelCase__ , return_tensors='pt' ).input_ids.shape[1] > max_tokens for src, tgt in tqdm(sorted_examples[1:] ): __lowerCamelCase = new_src + ' ' + src __lowerCamelCase = new_tgt + ' ' + tgt if is_too_big(UpperCamelCase__ ) or is_too_big(UpperCamelCase__ ): # cant fit, finalize example finished_src.append(UpperCamelCase__ ) finished_tgt.append(UpperCamelCase__ ) __lowerCamelCase , __lowerCamelCase = src, tgt else: # can fit, keep adding __lowerCamelCase , __lowerCamelCase = cand_src, cand_tgt # cleanup if new_src: assert new_tgt finished_src.append(UpperCamelCase__ ) finished_tgt.append(UpperCamelCase__ ) return finished_src, finished_tgt def lowerCamelCase_ ( UpperCamelCase__ : str , UpperCamelCase__ : Path , UpperCamelCase__ : Optional[int] , UpperCamelCase__ : str ) -> Optional[int]: """simple docstring""" __lowerCamelCase = Path(UpperCamelCase__ ) save_path.mkdir(exist_ok=UpperCamelCase__ ) for split in ["train"]: __lowerCamelCase , __lowerCamelCase = data_dir / F"""{split}.source""", data_dir / F"""{split}.target""" __lowerCamelCase = [x.rstrip() for x in Path(UpperCamelCase__ ).open().readlines()] __lowerCamelCase = [x.rstrip() for x in Path(UpperCamelCase__ ).open().readlines()] __lowerCamelCase , __lowerCamelCase = pack_examples(UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ ) print(F"""packed {split} split from {len(UpperCamelCase__ )} examples -> {len(UpperCamelCase__ )}.""" ) Path(save_path / F"""{split}.source""" ).open('w' ).write('\n'.join(UpperCamelCase__ ) ) Path(save_path / F"""{split}.target""" ).open('w' ).write('\n'.join(UpperCamelCase__ ) ) for split in ["val", "test"]: __lowerCamelCase , __lowerCamelCase = data_dir / F"""{split}.source""", data_dir / F"""{split}.target""" shutil.copyfile(UpperCamelCase__ , save_path / F"""{split}.source""" ) shutil.copyfile(UpperCamelCase__ , save_path / F"""{split}.target""" ) def lowerCamelCase_ ( ) -> List[str]: """simple docstring""" __lowerCamelCase = argparse.ArgumentParser() parser.add_argument('--tok_name' , type=UpperCamelCase__ , help='like facebook/bart-large-cnn,t5-base, etc.' ) parser.add_argument('--max_seq_len' , type=UpperCamelCase__ , default=128 ) parser.add_argument('--data_dir' , type=UpperCamelCase__ ) parser.add_argument('--save_path' , type=UpperCamelCase__ ) __lowerCamelCase = parser.parse_args() __lowerCamelCase = AutoTokenizer.from_pretrained(args.tok_name ) return pack_data_dir(UpperCamelCase__ , Path(args.data_dir ) , args.max_seq_len , args.save_path ) if __name__ == "__main__": packer_cli()
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"""simple docstring""" import colorsys from PIL import Image # type: ignore def lowercase__ ( snake_case_ :float , snake_case_ :float , snake_case_ :int ): __UpperCAmelCase = x __UpperCAmelCase = y for step in range(UpperCamelCase__ ): # noqa: B007 __UpperCAmelCase = a * a - b * b + x __UpperCAmelCase = 2 * a * b + y __UpperCAmelCase = a_new # divergence happens for all complex number with an absolute value # greater than 4 if a * a + b * b > 4: break return step / (max_step - 1) def lowercase__ ( snake_case_ :float ): if distance == 1: return (0, 0, 0) else: return (255, 255, 255) def lowercase__ ( snake_case_ :float ): if distance == 1: return (0, 0, 0) else: return tuple(round(i * 255 ) for i in colorsys.hsv_to_rgb(UpperCamelCase__ , 1 , 1 ) ) def lowercase__ ( snake_case_ :int = 800 , snake_case_ :int = 600 , snake_case_ :float = -0.6 , snake_case_ :float = 0 , snake_case_ :float = 3.2 , snake_case_ :int = 50 , snake_case_ :bool = True , ): __UpperCAmelCase = Image.new('''RGB''' , (image_width, image_height) ) __UpperCAmelCase = img.load() # loop through the image-coordinates for image_x in range(UpperCamelCase__ ): for image_y in range(UpperCamelCase__ ): # determine the figure-coordinates based on the image-coordinates __UpperCAmelCase = figure_width / image_width * image_height __UpperCAmelCase = figure_center_x + (image_x / image_width - 0.5) * figure_width __UpperCAmelCase = figure_center_y + (image_y / image_height - 0.5) * figure_height __UpperCAmelCase = get_distance(UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ ) # color the corresponding pixel based on the selected coloring-function if use_distance_color_coding: __UpperCAmelCase = get_color_coded_rgb(UpperCamelCase__ ) else: __UpperCAmelCase = get_black_and_white_rgb(UpperCamelCase__ ) return img if __name__ == "__main__": import doctest doctest.testmod() # colored version, full figure _lowercase : List[str] = get_image() # uncomment for colored version, different section, zoomed in # img = get_image(figure_center_x = -0.6, figure_center_y = -0.4, # figure_width = 0.8) # uncomment for black and white version, full figure # img = get_image(use_distance_color_coding = False) # uncomment to save the image # img.save("mandelbrot.png") img.show()
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import argparse import fairseq import torch from torch import nn from transformers import ( MBartaaTokenizer, MBartConfig, MBartForCausalLM, SpeechEncoderDecoderConfig, SpeechEncoderDecoderModel, WavaVecaConfig, WavaVecaFeatureExtractor, WavaVecaModel, logging, ) logging.set_verbosity_info() __A = logging.get_logger(__name__) __A = { "post_extract_proj": "feature_projection.projection", "encoder.pos_conv.0": "encoder.pos_conv_embed.conv", "self_attn.k_proj": "encoder.layers.*.attention.k_proj", "self_attn.v_proj": "encoder.layers.*.attention.v_proj", "self_attn.q_proj": "encoder.layers.*.attention.q_proj", "self_attn.out_proj": "encoder.layers.*.attention.out_proj", "self_attn_layer_norm": "encoder.layers.*.layer_norm", "fc1": "encoder.layers.*.feed_forward.intermediate_dense", "fc2": "encoder.layers.*.feed_forward.output_dense", "final_layer_norm": "encoder.layers.*.final_layer_norm", "encoder.layer_norm": "encoder.layer_norm", "w2v_model.layer_norm": "feature_projection.layer_norm", "quantizer.weight_proj": "quantizer.weight_proj", "quantizer.vars": "quantizer.codevectors", "project_q": "project_q", "final_proj": "project_hid", "w2v_encoder.proj": "lm_head", "mask_emb": "masked_spec_embed", } __A = [ "lm_head", "quantizer.weight_proj", "quantizer.codevectors", "project_q", "project_hid", ] def lowerCamelCase_ ( UpperCamelCase__ : Any , UpperCamelCase__ : Any , UpperCamelCase__ : Optional[Any] , UpperCamelCase__ : Union[str, Any] , UpperCamelCase__ : Optional[int] ) -> Tuple: """simple docstring""" for attribute in key.split('.' ): __lowerCamelCase = getattr(UpperCamelCase__ , UpperCamelCase__ ) if weight_type is not None: __lowerCamelCase = getattr(UpperCamelCase__ , UpperCamelCase__ ).shape else: __lowerCamelCase = hf_pointer.shape assert hf_shape == value.shape, ( F"""Shape of hf {key + '.' + weight_type if weight_type is not None else ''} is {hf_shape}, but should be""" F""" {value.shape} for {full_name}""" ) if weight_type == "weight": __lowerCamelCase = value elif weight_type == "weight_g": __lowerCamelCase = value elif weight_type == "weight_v": __lowerCamelCase = value elif weight_type == "bias": __lowerCamelCase = value else: __lowerCamelCase = value logger.info(F"""{key + '.' + weight_type if weight_type is not None else ''} was initialized from {full_name}.""" ) def lowerCamelCase_ ( UpperCamelCase__ : Optional[Any] , UpperCamelCase__ : Tuple ) -> Optional[Any]: """simple docstring""" __lowerCamelCase = [] __lowerCamelCase = fairseq_model.state_dict() __lowerCamelCase = hf_model.feature_extractor __lowerCamelCase = hf_model.adapter for name, value in fairseq_dict.items(): __lowerCamelCase = False if "conv_layers" in name: load_conv_layer( UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ , hf_model.config.feat_extract_norm == 'group' , ) __lowerCamelCase = True elif any(x in name for x in ['adaptor', 'w2v_encoder.proj.', 'w2v_proj_ln.'] ): load_adapter(UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ ) __lowerCamelCase = True else: for key, mapped_key in MAPPING.items(): if key in name or key.split('w2v_model.' )[-1] == name.split('.' )[0]: __lowerCamelCase = True if "*" in mapped_key: __lowerCamelCase = name.split(UpperCamelCase__ )[0].split('.' )[-2] __lowerCamelCase = mapped_key.replace('*' , UpperCamelCase__ ) if "weight_g" in name: __lowerCamelCase = 'weight_g' elif "weight_v" in name: __lowerCamelCase = 'weight_v' elif "bias" in name: __lowerCamelCase = 'bias' elif "weight" in name: __lowerCamelCase = 'weight' else: __lowerCamelCase = None set_recursively(UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ ) continue if not is_used: unused_weights.append(UpperCamelCase__ ) logger.warning(F"""Unused weights: {unused_weights}""" ) def lowerCamelCase_ ( UpperCamelCase__ : Dict , UpperCamelCase__ : Any , UpperCamelCase__ : str , UpperCamelCase__ : Tuple , UpperCamelCase__ : Tuple ) -> int: """simple docstring""" __lowerCamelCase = full_name.split('conv_layers.' )[-1] __lowerCamelCase = name.split('.' ) __lowerCamelCase = int(items[0] ) __lowerCamelCase = int(items[1] ) if type_id == 0: if "bias" in name: assert value.shape == feature_extractor.conv_layers[layer_id].conv.bias.data.shape, ( F"""{full_name} has size {value.shape}, but""" F""" {feature_extractor.conv_layers[layer_id].conv.bias.data.shape} was found.""" ) __lowerCamelCase = value logger.info(F"""Feat extract conv layer {layer_id} was initialized from {full_name}.""" ) elif "weight" in name: assert value.shape == feature_extractor.conv_layers[layer_id].conv.weight.data.shape, ( F"""{full_name} has size {value.shape}, but""" F""" {feature_extractor.conv_layers[layer_id].conv.weight.data.shape} was found.""" ) __lowerCamelCase = value logger.info(F"""Feat extract conv layer {layer_id} was initialized from {full_name}.""" ) elif (type_id == 2 and not use_group_norm) or (type_id == 2 and layer_id == 0 and use_group_norm): if "bias" in name: assert value.shape == feature_extractor.conv_layers[layer_id].layer_norm.bias.data.shape, ( F"""{full_name} has size {value.shape}, but {feature_extractor[layer_id].layer_norm.bias.data.shape} was""" " found." ) __lowerCamelCase = value logger.info(F"""Feat extract layer norm weight of layer {layer_id} was initialized from {full_name}.""" ) elif "weight" in name: assert value.shape == feature_extractor.conv_layers[layer_id].layer_norm.weight.data.shape, ( F"""{full_name} has size {value.shape}, but""" F""" {feature_extractor[layer_id].layer_norm.weight.data.shape} was found.""" ) __lowerCamelCase = value logger.info(F"""Feat extract layer norm weight of layer {layer_id} was initialized from {full_name}.""" ) else: unused_weights.append(UpperCamelCase__ ) def lowerCamelCase_ ( UpperCamelCase__ : Tuple , UpperCamelCase__ : Optional[Any] , UpperCamelCase__ : Any , UpperCamelCase__ : int ) -> Union[str, Any]: """simple docstring""" __lowerCamelCase = full_name.split('adaptor.' )[-1] __lowerCamelCase = name.split('.' ) if items[1].isdigit(): __lowerCamelCase = int(items[1] ) else: __lowerCamelCase = None if "adaptor" not in full_name: if "proj_ln" in full_name: # has to be layer norm if "bias" in name: assert ( value.shape == adapter.proj_layer_norm.bias.data.shape ), F"""{full_name} has size {value.shape}, but {adapter.proj_layer_norm.bias.data.shape} was found.""" __lowerCamelCase = value logger.info(F"""Adapter proj layer norm bias was initialized from {full_name}.""" ) if "weight" in name: assert ( value.shape == adapter.proj_layer_norm.weight.data.shape ), F"""{full_name} has size {value.shape}, but {adapter.proj_layer_norm.weight.data.shape} was found.""" __lowerCamelCase = value else: # has to be projection layer if "bias" in name: assert ( value.shape == adapter.proj.bias.data.shape ), F"""{full_name} has size {value.shape}, but {adapter.proj.bias.data.shape} was found.""" __lowerCamelCase = value logger.info(F"""Adapter proj layer bias was initialized from {full_name}.""" ) if "weight" in name: assert ( value.shape == adapter.proj.weight.data.shape ), F"""{full_name} has size {value.shape}, but {adapter.proj.weight.data.shape} was found.""" __lowerCamelCase = value logger.info(F"""Adapter proj layer weight was initialized from {full_name}.""" ) elif isinstance(UpperCamelCase__ , UpperCamelCase__ ): if "bias" in name: assert ( value.shape == adapter.layers[layer_id].conv.bias.data.shape ), F"""{full_name} has size {value.shape}, but {adapter.layers[layer_id].conv.bias.data.shape} was found.""" __lowerCamelCase = value logger.info(F"""Adapter layer {layer_id} bias was initialized from {full_name}.""" ) elif "weight" in name: assert ( value.shape == adapter.layers[layer_id].conv.weight.data.shape ), F"""{full_name} has size {value.shape}, but {adapter.layers[layer_id].conv.weight.data.shape} was found.""" __lowerCamelCase = value logger.info(F"""Adapter layer {layer_id} bias was initialized from {full_name}.""" ) else: unused_weights.append(UpperCamelCase__ ) def lowerCamelCase_ ( UpperCamelCase__ : Tuple ) -> Tuple: """simple docstring""" __lowerCamelCase , __lowerCamelCase = emb.weight.shape __lowerCamelCase = nn.Linear(UpperCamelCase__ , UpperCamelCase__ , bias=UpperCamelCase__ ) __lowerCamelCase = emb.weight.data return lin_layer @torch.no_grad() def lowerCamelCase_ ( UpperCamelCase__ : List[str] , UpperCamelCase__ : List[Any] , UpperCamelCase__ : Union[str, Any] , UpperCamelCase__ : Dict , UpperCamelCase__ : List[str] , UpperCamelCase__ : Union[str, Any] , UpperCamelCase__ : Optional[int] , UpperCamelCase__ : Union[str, Any] , UpperCamelCase__ : Optional[Any] , UpperCamelCase__ : str , UpperCamelCase__ : Optional[Any] , ) -> str: """simple docstring""" __lowerCamelCase = WavaVecaConfig.from_pretrained( UpperCamelCase__ , add_adapter=UpperCamelCase__ , adapter_stride=UpperCamelCase__ , adapter_kernel_size=UpperCamelCase__ , use_auth_token=UpperCamelCase__ , output_hidden_size=UpperCamelCase__ , ) __lowerCamelCase = MBartConfig.from_pretrained(UpperCamelCase__ ) # load model __lowerCamelCase , __lowerCamelCase , __lowerCamelCase = fairseq.checkpoint_utils.load_model_ensemble_and_task( [checkpoint_path] , arg_overrides={ 'config_yaml': config_yaml_path, 'data': '/'.join(dict_path.split('/' )[:-1] ), 'w2v_path': checkpoint_path, 'load_pretrained_decoder_from': None, } , ) __lowerCamelCase = model[0].eval() # load feature extractor __lowerCamelCase = WavaVecaFeatureExtractor.from_pretrained(UpperCamelCase__ , use_auth_token=UpperCamelCase__ ) # set weights for wav2vec2 encoder __lowerCamelCase = WavaVecaModel(UpperCamelCase__ ) recursively_load_weights_wavaveca(model.encoder , UpperCamelCase__ ) # load decoder weights __lowerCamelCase = MBartForCausalLM(UpperCamelCase__ ) __lowerCamelCase , __lowerCamelCase = hf_decoder.model.decoder.load_state_dict(model.decoder.state_dict() , strict=UpperCamelCase__ ) logger.warning(F"""The following keys are missing when loading the decoder weights: {missing_keys}""" ) logger.warning(F"""The following keys are unexpected when loading the decoder weights: {unexpected_keys}""" ) __lowerCamelCase = SpeechEncoderDecoderModel(encoder=UpperCamelCase__ , decoder=UpperCamelCase__ ) __lowerCamelCase = False __lowerCamelCase = MBartaaTokenizer(UpperCamelCase__ ) tokenizer.save_pretrained(UpperCamelCase__ ) __lowerCamelCase = hf_wavavec.config.to_dict() __lowerCamelCase = tokenizer.pad_token_id __lowerCamelCase = tokenizer.bos_token_id __lowerCamelCase = tokenizer.eos_token_id __lowerCamelCase = 'mbart50' __lowerCamelCase = 'wav2vec2' __lowerCamelCase = tokenizer.eos_token_id __lowerCamelCase = 25_0004 __lowerCamelCase = tokenizer.eos_token_id __lowerCamelCase = SpeechEncoderDecoderConfig.from_dict(UpperCamelCase__ ) hf_wavavec.save_pretrained(UpperCamelCase__ ) feature_extractor.save_pretrained(UpperCamelCase__ ) 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 fairseq checkpoint") parser.add_argument("--dict_path", default=None, type=str, help="Path to dict of fine-tuned model") parser.add_argument("--config_yaml_path", default=None, type=str, help="Path to yaml file of fine-tuned model") parser.add_argument( "--encoder_config_path", default="facebook/wav2vec2-xls-r-1b", type=str, help="Path to hf encoder wav2vec2 checkpoint config", ) parser.add_argument( "--decoder_config_path", default="facebook/mbart-large-50-one-to-many-mmt", type=str, help="Path to hf decoder checkpoint config", ) parser.add_argument("--add_adapter", default=True, type=bool, help="whethere to add model adapter layers") parser.add_argument("--adapter_stride", default=2, type=int, help="stride of adapter layers") parser.add_argument("--adapter_kernel_size", default=3, type=int, help="kernel size of adapter layers") parser.add_argument("--encoder_output_dim", default=10_24, type=int, help="encoder output dim") parser.add_argument("--start_token_id", default=25_00_04, type=int, help="`decoder_start_token_id` of model config") __A = parser.parse_args() convert_wavaveca_checkpoint( args.checkpoint_path, args.pytorch_dump_folder_path, args.dict_path, args.config_yaml_path, encoder_config_path=args.encoder_config_path, decoder_config_path=args.decoder_config_path, add_adapter=args.add_adapter, adapter_kernel_size=args.adapter_kernel_size, adapter_stride=args.adapter_stride, decoder_start_token_id=args.start_token_id, encoder_output_dim=args.encoder_output_dim, )
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'''simple docstring''' from typing import TYPE_CHECKING from ...utils import ( OptionalDependencyNotAvailable, _LazyModule, is_sentencepiece_available, is_tokenizers_available, is_torch_available, ) __lowerCAmelCase = {"""configuration_fnet""": ["""FNET_PRETRAINED_CONFIG_ARCHIVE_MAP""", """FNetConfig"""]} try: if not is_sentencepiece_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __lowerCAmelCase = ["""FNetTokenizer"""] try: if not is_tokenizers_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __lowerCAmelCase = ["""FNetTokenizerFast"""] try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __lowerCAmelCase = [ """FNET_PRETRAINED_MODEL_ARCHIVE_LIST""", """FNetForMaskedLM""", """FNetForMultipleChoice""", """FNetForNextSentencePrediction""", """FNetForPreTraining""", """FNetForQuestionAnswering""", """FNetForSequenceClassification""", """FNetForTokenClassification""", """FNetLayer""", """FNetModel""", """FNetPreTrainedModel""", ] if TYPE_CHECKING: from .configuration_fnet import FNET_PRETRAINED_CONFIG_ARCHIVE_MAP, FNetConfig try: if not is_sentencepiece_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .tokenization_fnet import FNetTokenizer try: if not is_tokenizers_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .tokenization_fnet_fast import FNetTokenizerFast try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_fnet import ( FNET_PRETRAINED_MODEL_ARCHIVE_LIST, FNetForMaskedLM, FNetForMultipleChoice, FNetForNextSentencePrediction, FNetForPreTraining, FNetForQuestionAnswering, FNetForSequenceClassification, FNetForTokenClassification, FNetLayer, FNetModel, FNetPreTrainedModel, ) else: import sys __lowerCAmelCase = _LazyModule(__name__, globals()["""__file__"""], _import_structure, module_spec=__spec__)
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def lowerCamelCase_ ( UpperCamelCase__ : int ) -> bool: """simple docstring""" return number & 1 == 0 if __name__ == "__main__": import doctest doctest.testmod()
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from __future__ import annotations # This is the precision for this function which can be altered. # It is recommended for users to keep this number greater than or equal to 10. UpperCAmelCase = 10 def UpperCAmelCase_ ( __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE ): for i in range(UpperCamelCase__ , UpperCamelCase__ ): if array[i] == target: return i return -1 def UpperCAmelCase_ ( __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE ): lowercase = 0 lowercase = len(UpperCamelCase__ ) while left <= right: if right - left < precision: return lin_search(UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ ) lowercase = (left + right) // 3 + 1 lowercase = 2 * (left + right) // 3 + 1 if array[one_third] == target: return one_third elif array[two_third] == target: return two_third elif target < array[one_third]: lowercase = one_third - 1 elif array[two_third] < target: lowercase = two_third + 1 else: lowercase = one_third + 1 lowercase = two_third - 1 else: return -1 def UpperCAmelCase_ ( __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE ): if left < right: if right - left < precision: return lin_search(UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ ) lowercase = (left + right) // 3 + 1 lowercase = 2 * (left + right) // 3 + 1 if array[one_third] == target: return one_third elif array[two_third] == target: return two_third elif target < array[one_third]: return rec_ternary_search(UpperCamelCase__ , one_third - 1 , UpperCamelCase__ , UpperCamelCase__ ) elif array[two_third] < target: return rec_ternary_search(two_third + 1 , UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ ) else: return rec_ternary_search(one_third + 1 , two_third - 1 , UpperCamelCase__ , UpperCamelCase__ ) else: return -1 if __name__ == "__main__": import doctest doctest.testmod() UpperCAmelCase = input('''Enter numbers separated by comma:\n''').strip() UpperCAmelCase = [int(item.strip()) for item in user_input.split(''',''')] assert collection == sorted(collection), F"List must be ordered.\n{collection}." UpperCAmelCase = int(input('''Enter the number to be found in the list:\n''').strip()) UpperCAmelCase = ite_ternary_search(collection, target) UpperCAmelCase = rec_ternary_search(0, len(collection) - 1, collection, target) if resulta != -1: print(F"""Iterative search: {target} found at positions: {resulta}""") print(F"""Recursive search: {target} found at positions: {resulta}""") else: print('''Not found''')
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from typing import List, Optional import numpy as np from ...processing_utils import ProcessorMixin from ...utils import to_numpy class __lowerCAmelCase ( __magic_name__ ): """simple docstring""" snake_case_ = '''EncodecFeatureExtractor''' snake_case_ = ('''T5Tokenizer''', '''T5TokenizerFast''') def __init__( self , lowerCamelCase__ , lowerCamelCase__ ) -> int: '''simple docstring''' super().__init__(lowerCamelCase__ , lowerCamelCase__ ) __lowerCamelCase = self.feature_extractor __lowerCamelCase = False def lowercase_ ( self , lowerCamelCase__=None , lowerCamelCase__=None , lowerCamelCase__=True ) -> List[Any]: '''simple docstring''' return self.tokenizer.get_decoder_prompt_ids(task=lowerCamelCase__ , language=lowerCamelCase__ , no_timestamps=lowerCamelCase__ ) def __call__( self , *lowerCamelCase__ , **lowerCamelCase__ ) -> Dict: '''simple docstring''' # For backward compatibility if self._in_target_context_manager: return self.current_processor(*lowerCamelCase__ , **lowerCamelCase__ ) __lowerCamelCase = kwargs.pop('audio' , lowerCamelCase__ ) __lowerCamelCase = kwargs.pop('sampling_rate' , lowerCamelCase__ ) __lowerCamelCase = kwargs.pop('text' , lowerCamelCase__ ) if len(lowerCamelCase__ ) > 0: __lowerCamelCase = args[0] __lowerCamelCase = args[1:] if audio is None and text is None: raise ValueError('You need to specify either an `audio` or `text` input to process.' ) if text is not None: __lowerCamelCase = self.tokenizer(lowerCamelCase__ , **lowerCamelCase__ ) if audio is not None: __lowerCamelCase = self.feature_extractor(lowerCamelCase__ , *lowerCamelCase__ , sampling_rate=lowerCamelCase__ , **lowerCamelCase__ ) if audio is None: return inputs elif text is None: return audio_inputs else: __lowerCamelCase = audio_inputs['input_values'] if "padding_mask" in audio_inputs: __lowerCamelCase = audio_inputs['padding_mask'] return inputs def lowercase_ ( self , *lowerCamelCase__ , **lowerCamelCase__ ) -> Union[str, Any]: '''simple docstring''' __lowerCamelCase = kwargs.pop('audio' , lowerCamelCase__ ) __lowerCamelCase = kwargs.pop('padding_mask' , lowerCamelCase__ ) if len(lowerCamelCase__ ) > 0: __lowerCamelCase = args[0] __lowerCamelCase = args[1:] if audio_values is not None: return self._decode_audio(lowerCamelCase__ , padding_mask=lowerCamelCase__ ) else: return self.tokenizer.batch_decode(*lowerCamelCase__ , **lowerCamelCase__ ) def lowercase_ ( self , *lowerCamelCase__ , **lowerCamelCase__ ) -> List[Any]: '''simple docstring''' return self.tokenizer.decode(*lowerCamelCase__ , **lowerCamelCase__ ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ = None ) -> List[np.ndarray]: '''simple docstring''' __lowerCamelCase = to_numpy(lowerCamelCase__ ) __lowerCamelCase , __lowerCamelCase , __lowerCamelCase = audio_values.shape if padding_mask is None: return list(lowerCamelCase__ ) __lowerCamelCase = to_numpy(lowerCamelCase__ ) # match the sequence length of the padding mask to the generated audio arrays by padding with the **non-padding** # token (so that the generated audio values are **not** treated as padded tokens) __lowerCamelCase = seq_len - padding_mask.shape[-1] __lowerCamelCase = 1 - self.feature_extractor.padding_value __lowerCamelCase = np.pad(lowerCamelCase__ , ((0, 0), (0, difference)) , 'constant' , constant_values=lowerCamelCase__ ) __lowerCamelCase = audio_values.tolist() for i in range(lowerCamelCase__ ): __lowerCamelCase = np.asarray(audio_values[i] )[ padding_mask[i][None, :] != self.feature_extractor.padding_value ] __lowerCamelCase = sliced_audio.reshape(lowerCamelCase__ , -1 ) return audio_values
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from __future__ import annotations def UpperCamelCase_( _snake_case : str , _snake_case : list[str] | None = None , _snake_case : dict[str, float] | None = None , _snake_case : bool = False , ): """simple docstring""" __a =cipher_alphabet or [chr(UpperCamelCase__ ) for i in range(97 , 123 )] # If the argument is None or the user provided an empty dictionary if not frequencies_dict: # Frequencies of letters in the english language (how much they show up) __a ={ 'a': 0.08_497, 'b': 0.01_492, 'c': 0.02_202, 'd': 0.04_253, 'e': 0.11_162, 'f': 0.02_228, 'g': 0.02_015, 'h': 0.06_094, 'i': 0.07_546, 'j': 0.00_153, 'k': 0.01_292, 'l': 0.04_025, 'm': 0.02_406, 'n': 0.06_749, 'o': 0.07_507, 'p': 0.01_929, 'q': 0.00_095, 'r': 0.07_587, 's': 0.06_327, 't': 0.09_356, 'u': 0.02_758, 'v': 0.00_978, 'w': 0.02_560, 'x': 0.00_150, 'y': 0.01_994, 'z': 0.00_077, } else: # Custom frequencies dictionary __a =frequencies_dict if not case_sensitive: __a =ciphertext.lower() # Chi squared statistic values __a ={} # cycle through all of the shifts for shift in range(len(UpperCamelCase__ ) ): __a ='' # decrypt the message with the shift for letter in ciphertext: try: # Try to index the letter in the alphabet __a =(alphabet_letters.index(letter.lower() ) - shift) % len( UpperCamelCase__ ) decrypted_with_shift += ( alphabet_letters[new_key].upper() if case_sensitive and letter.isupper() else alphabet_letters[new_key] ) except ValueError: # Append the character if it isn't in the alphabet decrypted_with_shift += letter __a =0.0 # Loop through each letter in the decoded message with the shift for letter in decrypted_with_shift: if case_sensitive: __a =letter.lower() if letter in frequencies: # Get the amount of times the letter occurs in the message __a =decrypted_with_shift.lower().count(UpperCamelCase__ ) # Get the excepcted amount of times the letter should appear based # on letter frequencies __a =frequencies[letter] * occurrences # Complete the chi squared statistic formula __a =((occurrences - expected) ** 2) / expected # Add the margin of error to the total chi squared statistic chi_squared_statistic += chi_letter_value else: if letter.lower() in frequencies: # Get the amount of times the letter occurs in the message __a =decrypted_with_shift.count(UpperCamelCase__ ) # Get the excepcted amount of times the letter should appear based # on letter frequencies __a =frequencies[letter] * occurrences # Complete the chi squared statistic formula __a =((occurrences - expected) ** 2) / expected # Add the margin of error to the total chi squared statistic chi_squared_statistic += chi_letter_value # Add the data to the chi_squared_statistic_values dictionary __a =( chi_squared_statistic, decrypted_with_shift, ) # Get the most likely cipher by finding the cipher with the smallest chi squared # statistic def chi_squared_statistic_values_sorting_key(_snake_case : int ) -> tuple[float, str]: return chi_squared_statistic_values[key] __a =min( UpperCamelCase__ , key=UpperCamelCase__ , ) # Get all the data from the most likely cipher (key, decoded message) ( ( __a ) , ( __a ) , ) =chi_squared_statistic_values[most_likely_cipher] # Return the data on the most likely shift return ( most_likely_cipher, most_likely_cipher_chi_squared_value, decoded_most_likely_cipher, )
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from math import sqrt def lowerCamelCase_ ( UpperCamelCase__ : int ) -> bool: """simple docstring""" if 1 < number < 4: # 2 and 3 are primes return True elif number < 2 or number % 2 == 0 or number % 3 == 0: # Negatives, 0, 1, all even numbers, all multiples of 3 are not primes return False # All primes number are in format of 6k +/- 1 for i in range(5 , int(sqrt(UpperCamelCase__ ) + 1 ) , 6 ): if number % i == 0 or number % (i + 2) == 0: return False return True def lowerCamelCase_ ( UpperCamelCase__ : int = 1_0001 ) -> int: """simple docstring""" __lowerCamelCase = 0 __lowerCamelCase = 1 while count != nth and number < 3: number += 1 if is_prime(UpperCamelCase__ ): count += 1 while count != nth: number += 2 if is_prime(UpperCamelCase__ ): count += 1 return number if __name__ == "__main__": print(f'''{solution() = }''')
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"""simple docstring""" import argparse import logging import sys from unittest.mock import patch import run_glue_deebert from transformers.testing_utils import TestCasePlus, get_gpu_count, require_torch_non_multi_gpu, slow logging.basicConfig(level=logging.DEBUG) lowerCamelCase_ : Tuple = logging.getLogger() def _A ( ): """simple docstring""" a =argparse.ArgumentParser() parser.add_argument('''-f''' ) a =parser.parse_args() return args.f class __A ( _SCREAMING_SNAKE_CASE ): """simple docstring""" def SCREAMING_SNAKE_CASE ( self ) -> None: a =logging.StreamHandler(sys.stdout ) logger.addHandler(lowerCamelCase__ ) def SCREAMING_SNAKE_CASE ( self , __A ) -> Dict: a =get_gpu_count() if n_gpu > 1: pass # XXX: doesn't quite work with n_gpu > 1 https://github.com/huggingface/transformers/issues/10560 # script = f"{self.examples_dir_str}/research_projects/deebert/run_glue_deebert.py" # distributed_args = f"-m torch.distributed.launch --nproc_per_node={n_gpu} {script}".split() # cmd = [sys.executable] + distributed_args + args # execute_subprocess_async(cmd, env=self.get_env()) # XXX: test the results - need to save them first into .json file else: args.insert(0 , '''run_glue_deebert.py''' ) with patch.object(lowerCamelCase__ , '''argv''' , lowerCamelCase__ ): a =run_glue_deebert.main() for value in result.values(): self.assertGreaterEqual(lowerCamelCase__ , 0.666 ) @slow @require_torch_non_multi_gpu def SCREAMING_SNAKE_CASE ( self ) -> Dict: a ='''\n --model_type roberta\n --model_name_or_path roberta-base\n --task_name MRPC\n --do_train\n --do_eval\n --do_lower_case\n --data_dir ./tests/fixtures/tests_samples/MRPC/\n --max_seq_length 128\n --per_gpu_eval_batch_size=1\n --per_gpu_train_batch_size=8\n --learning_rate 2e-4\n --num_train_epochs 3\n --overwrite_output_dir\n --seed 42\n --output_dir ./examples/deebert/saved_models/roberta-base/MRPC/two_stage\n --plot_data_dir ./examples/deebert/results/\n --save_steps 0\n --overwrite_cache\n --eval_after_first_stage\n '''.split() self.run_and_check(lowerCamelCase__ ) a ='''\n --model_type roberta\n --model_name_or_path ./examples/deebert/saved_models/roberta-base/MRPC/two_stage\n --task_name MRPC\n --do_eval\n --do_lower_case\n --data_dir ./tests/fixtures/tests_samples/MRPC/\n --output_dir ./examples/deebert/saved_models/roberta-base/MRPC/two_stage\n --plot_data_dir ./examples/deebert/results/\n --max_seq_length 128\n --eval_each_highway\n --eval_highway\n --overwrite_cache\n --per_gpu_eval_batch_size=1\n '''.split() self.run_and_check(lowerCamelCase__ ) a ='''\n --model_type roberta\n --model_name_or_path ./examples/deebert/saved_models/roberta-base/MRPC/two_stage\n --task_name MRPC\n --do_eval\n --do_lower_case\n --data_dir ./tests/fixtures/tests_samples/MRPC/\n --output_dir ./examples/deebert/saved_models/roberta-base/MRPC/two_stage\n --plot_data_dir ./examples/deebert/results/\n --max_seq_length 128\n --early_exit_entropy 0.1\n --eval_highway\n --overwrite_cache\n --per_gpu_eval_batch_size=1\n '''.split() self.run_and_check(lowerCamelCase__ )
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import baseaa def lowerCamelCase_ ( UpperCamelCase__ : str ) -> bytes: """simple docstring""" return baseaa.aaaencode(string.encode('utf-8' ) ) def lowerCamelCase_ ( UpperCamelCase__ : bytes ) -> str: """simple docstring""" return baseaa.aaadecode(UpperCamelCase__ ).decode('utf-8' ) if __name__ == "__main__": import doctest doctest.testmod()
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from collections import defaultdict def lowercase ( SCREAMING_SNAKE_CASE__ : str , SCREAMING_SNAKE_CASE__ : str ) -> bool: _snake_case : List[str] = first_str.lower().strip() _snake_case : Tuple = second_str.lower().strip() # Remove whitespace _snake_case : Optional[int] = first_str.replace(""" """ , """""" ) _snake_case : int = second_str.replace(""" """ , """""" ) # Strings of different lengths are not anagrams if len(UpperCamelCase__ ) != len(UpperCamelCase__ ): return False # Default values for count should be 0 _snake_case : List[str] = defaultdict(UpperCamelCase__ ) # For each character in input strings, # increment count in the corresponding for i in range(len(UpperCamelCase__ ) ): count[first_str[i]] += 1 count[second_str[i]] -= 1 return all(_count == 0 for _count in count.values() ) if __name__ == "__main__": from doctest import testmod testmod() a__ = input("""Enter the first string """).strip() a__ = input("""Enter the second string """).strip() a__ = check_anagrams(input_a, input_b) print(F'''{input_a} and {input_b} are {'' if status else 'not '}anagrams.''')
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import copy from typing import Any, Dict, List, Optional, Union import numpy as np import torch from ...audio_utils import mel_filter_bank, spectrogram, window_function from ...feature_extraction_sequence_utils import SequenceFeatureExtractor from ...feature_extraction_utils import BatchFeature from ...utils import TensorType, logging __A = logging.get_logger(__name__) class __lowerCAmelCase ( __magic_name__ ): """simple docstring""" snake_case_ = ['''input_features''', '''is_longer'''] def __init__( self , lowerCamelCase__=64 , lowerCamelCase__=48_000 , lowerCamelCase__=480 , lowerCamelCase__=10 , lowerCamelCase__=1_024 , lowerCamelCase__=0.0 , lowerCamelCase__=False , lowerCamelCase__ = 0 , lowerCamelCase__ = 14_000 , lowerCamelCase__ = None , lowerCamelCase__ = "fusion" , lowerCamelCase__ = "repeatpad" , **lowerCamelCase__ , ) -> Tuple: '''simple docstring''' super().__init__( feature_size=lowerCamelCase__ , sampling_rate=lowerCamelCase__ , padding_value=lowerCamelCase__ , return_attention_mask=lowerCamelCase__ , **lowerCamelCase__ , ) __lowerCamelCase = top_db __lowerCamelCase = truncation __lowerCamelCase = padding __lowerCamelCase = fft_window_size __lowerCamelCase = (fft_window_size >> 1) + 1 __lowerCamelCase = hop_length __lowerCamelCase = max_length_s __lowerCamelCase = max_length_s * sampling_rate __lowerCamelCase = sampling_rate __lowerCamelCase = frequency_min __lowerCamelCase = frequency_max __lowerCamelCase = mel_filter_bank( num_frequency_bins=self.nb_frequency_bins , num_mel_filters=lowerCamelCase__ , min_frequency=lowerCamelCase__ , max_frequency=lowerCamelCase__ , sampling_rate=lowerCamelCase__ , norm=lowerCamelCase__ , mel_scale='htk' , ) __lowerCamelCase = mel_filter_bank( num_frequency_bins=self.nb_frequency_bins , num_mel_filters=lowerCamelCase__ , min_frequency=lowerCamelCase__ , max_frequency=lowerCamelCase__ , sampling_rate=lowerCamelCase__ , norm='slaney' , mel_scale='slaney' , ) def lowercase_ ( self ) -> Dict[str, Any]: '''simple docstring''' __lowerCamelCase = copy.deepcopy(self.__dict__ ) __lowerCamelCase = self.__class__.__name__ if "mel_filters" in output: del output["mel_filters"] if "mel_filters_slaney" in output: del output["mel_filters_slaney"] return output def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ = None ) -> np.ndarray: '''simple docstring''' __lowerCamelCase = spectrogram( lowerCamelCase__ , window_function(self.fft_window_size , 'hann' ) , frame_length=self.fft_window_size , hop_length=self.hop_length , power=2.0 , mel_filters=lowerCamelCase__ , log_mel='dB' , ) return log_mel_spectrogram.T def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> int: '''simple docstring''' __lowerCamelCase = np.array_split(list(range(0 , total_frames - chunk_frames + 1 ) ) , 3 ) if len(ranges[1] ) == 0: # if the audio is too short, we just use the first chunk __lowerCamelCase = [0] if len(ranges[2] ) == 0: # if the audio is too short, we just use the first chunk __lowerCamelCase = [0] # randomly choose index for each part __lowerCamelCase = np.random.choice(ranges[0] ) __lowerCamelCase = np.random.choice(ranges[1] ) __lowerCamelCase = np.random.choice(ranges[2] ) __lowerCamelCase = mel[idx_front : idx_front + chunk_frames, :] __lowerCamelCase = mel[idx_middle : idx_middle + chunk_frames, :] __lowerCamelCase = mel[idx_back : idx_back + chunk_frames, :] __lowerCamelCase = torch.tensor(mel[None, None, :] ) __lowerCamelCase = torch.nn.functional.interpolate( lowerCamelCase__ , size=[chunk_frames, 64] , mode='bilinear' , align_corners=lowerCamelCase__ ) __lowerCamelCase = mel_shrink[0][0].numpy() __lowerCamelCase = np.stack([mel_shrink, mel_chunk_front, mel_chunk_middle, mel_chunk_back] , axis=0 ) return mel_fusion def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> np.array: '''simple docstring''' if waveform.shape[0] > max_length: if truncation == "rand_trunc": __lowerCamelCase = True # random crop to max_length (for compatibility) -> this should be handled by self.pad __lowerCamelCase = len(lowerCamelCase__ ) - max_length __lowerCamelCase = np.random.randint(0 , overflow + 1 ) __lowerCamelCase = waveform[idx : idx + max_length] __lowerCamelCase = self._np_extract_fbank_features(lowerCamelCase__ , self.mel_filters_slaney )[None, :] elif truncation == "fusion": __lowerCamelCase = self._np_extract_fbank_features(lowerCamelCase__ , self.mel_filters ) __lowerCamelCase = max_length // self.hop_length + 1 # the +1 related to how the spectrogram is computed __lowerCamelCase = mel.shape[0] if chunk_frames == total_frames: # there is a corner case where the audio length is larger than max_length but smaller than max_length+hop_length. # In this case, we just use the whole audio. __lowerCamelCase = np.stack([mel, mel, mel, mel] , axis=0 ) __lowerCamelCase = False else: __lowerCamelCase = self._random_mel_fusion(lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) __lowerCamelCase = True else: raise NotImplementedError(f"""data_truncating {truncation} not implemented""" ) else: __lowerCamelCase = False # only use repeat as a new possible value for padding. you repeat the audio before applying the usual max_length padding if waveform.shape[0] < max_length: if padding == "repeat": __lowerCamelCase = int(max_length / len(lowerCamelCase__ ) ) __lowerCamelCase = np.stack(np.tile(lowerCamelCase__ , n_repeat + 1 ) )[:max_length] if padding == "repeatpad": __lowerCamelCase = int(max_length / len(lowerCamelCase__ ) ) __lowerCamelCase = np.stack(np.tile(lowerCamelCase__ , lowerCamelCase__ ) ) __lowerCamelCase = np.pad(lowerCamelCase__ , (0, max_length - waveform.shape[0]) , mode='constant' , constant_values=0 ) if truncation == "fusion": __lowerCamelCase = self._np_extract_fbank_features(lowerCamelCase__ , self.mel_filters ) __lowerCamelCase = np.stack([input_mel, input_mel, input_mel, input_mel] , axis=0 ) else: __lowerCamelCase = self._np_extract_fbank_features(lowerCamelCase__ , self.mel_filters_slaney )[None, :] return input_mel, longer def __call__( self , lowerCamelCase__ , lowerCamelCase__ = None , lowerCamelCase__ = None , lowerCamelCase__ = None , lowerCamelCase__ = None , lowerCamelCase__ = None , **lowerCamelCase__ , ) -> BatchFeature: '''simple docstring''' __lowerCamelCase = truncation if truncation is not None else self.truncation __lowerCamelCase = padding if padding else self.padding if sampling_rate is not None: if sampling_rate != self.sampling_rate: raise ValueError( f"""The model corresponding to this feature extractor: {self.__class__.__name__} was trained using a""" f""" sampling rate of {self.sampling_rate}. Please make sure that the provided `raw_speech` input""" f""" was sampled with {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.' ) __lowerCamelCase = isinstance(lowerCamelCase__ , np.ndarray ) and len(raw_speech.shape ) > 1 if is_batched_numpy and len(raw_speech.shape ) > 2: raise ValueError(f"""Only mono-channel audio is supported for input to {self}""" ) __lowerCamelCase = is_batched_numpy or ( isinstance(lowerCamelCase__ , (list, tuple) ) and (isinstance(raw_speech[0] , (np.ndarray, tuple, list) )) ) if is_batched: __lowerCamelCase = [np.asarray(lowerCamelCase__ , dtype=np.floataa ) for speech in raw_speech] elif not is_batched and not isinstance(lowerCamelCase__ , np.ndarray ): __lowerCamelCase = np.asarray(lowerCamelCase__ , dtype=np.floataa ) elif isinstance(lowerCamelCase__ , np.ndarray ) and raw_speech.dtype is np.dtype(np.floataa ): __lowerCamelCase = raw_speech.astype(np.floataa ) # always return batch if not is_batched: __lowerCamelCase = [np.asarray(lowerCamelCase__ )] # convert to mel spectrogram, truncate and pad if needed. __lowerCamelCase = [ self._get_input_mel(lowerCamelCase__ , max_length if max_length else self.nb_max_samples , lowerCamelCase__ , lowerCamelCase__ ) for waveform in raw_speech ] __lowerCamelCase = [] __lowerCamelCase = [] for mel, longer in padded_inputs: input_mel.append(lowerCamelCase__ ) is_longer.append(lowerCamelCase__ ) if truncation == "fusion" and sum(lowerCamelCase__ ) == 0: # if no audio is longer than 10s, then randomly select one audio to be longer __lowerCamelCase = np.random.randint(0 , len(lowerCamelCase__ ) ) __lowerCamelCase = True if isinstance(input_mel[0] , lowerCamelCase__ ): __lowerCamelCase = [np.asarray(lowerCamelCase__ , dtype=np.floataa ) for feature in input_mel] # is_longer is a list of bool __lowerCamelCase = [[longer] for longer in is_longer] __lowerCamelCase = {'input_features': input_mel, 'is_longer': is_longer} __lowerCamelCase = BatchFeature(lowerCamelCase__ ) if return_tensors is not None: __lowerCamelCase = input_features.convert_to_tensors(lowerCamelCase__ ) return input_features
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"""simple docstring""" from math import factorial def _SCREAMING_SNAKE_CASE (__lowerCAmelCase = 1_00 ) -> int: '''simple docstring''' return sum(int(UpperCamelCase__ ) for x in str(factorial(UpperCamelCase__ ) ) ) if __name__ == "__main__": print(solution(int(input("Enter the Number: ").strip())))
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class __lowerCAmelCase : """simple docstring""" def __init__( self ) -> Any: '''simple docstring''' __lowerCamelCase = 0 __lowerCamelCase = 0 __lowerCamelCase = {} def lowercase_ ( self , lowerCamelCase__ ) -> Tuple: '''simple docstring''' if vertex not in self.adjacency: __lowerCamelCase = {} self.num_vertices += 1 def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> str: '''simple docstring''' self.add_vertex(lowerCamelCase__ ) self.add_vertex(lowerCamelCase__ ) if head == tail: return __lowerCamelCase = weight __lowerCamelCase = weight def lowercase_ ( self ) -> List[str]: '''simple docstring''' __lowerCamelCase = self.get_edges() for edge in edges: __lowerCamelCase , __lowerCamelCase , __lowerCamelCase = edge edges.remove((tail, head, weight) ) for i in range(len(lowerCamelCase__ ) ): __lowerCamelCase = list(edges[i] ) edges.sort(key=lambda lowerCamelCase__ : e[2] ) for i in range(len(lowerCamelCase__ ) - 1 ): if edges[i][2] >= edges[i + 1][2]: __lowerCamelCase = edges[i][2] + 1 for edge in edges: __lowerCamelCase , __lowerCamelCase , __lowerCamelCase = edge __lowerCamelCase = weight __lowerCamelCase = weight def __str__( self ) -> Union[str, Any]: '''simple docstring''' __lowerCamelCase = '' for tail in self.adjacency: for head in self.adjacency[tail]: __lowerCamelCase = self.adjacency[head][tail] string += f"""{head} -> {tail} == {weight}\n""" return string.rstrip('\n' ) def lowercase_ ( self ) -> Optional[Any]: '''simple docstring''' __lowerCamelCase = [] for tail in self.adjacency: for head in self.adjacency[tail]: output.append((tail, head, self.adjacency[head][tail]) ) return output def lowercase_ ( self ) -> List[Any]: '''simple docstring''' return self.adjacency.keys() @staticmethod def lowercase_ ( lowerCamelCase__=None , lowerCamelCase__=None ) -> str: '''simple docstring''' __lowerCamelCase = Graph() if vertices is None: __lowerCamelCase = [] if edges is None: __lowerCamelCase = [] for vertex in vertices: g.add_vertex(lowerCamelCase__ ) for edge in edges: g.add_edge(*lowerCamelCase__ ) return g class __lowerCAmelCase : """simple docstring""" def __init__( self ) -> Tuple: '''simple docstring''' __lowerCamelCase = {} __lowerCamelCase = {} def __len__( self ) -> Tuple: '''simple docstring''' return len(self.parent ) def lowercase_ ( self , lowerCamelCase__ ) -> List[Any]: '''simple docstring''' if item in self.parent: return self.find(lowerCamelCase__ ) __lowerCamelCase = item __lowerCamelCase = 0 return item def lowercase_ ( self , lowerCamelCase__ ) -> List[str]: '''simple docstring''' if item not in self.parent: return self.make_set(lowerCamelCase__ ) if item != self.parent[item]: __lowerCamelCase = self.find(self.parent[item] ) return self.parent[item] def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ ) -> int: '''simple docstring''' __lowerCamelCase = self.find(lowerCamelCase__ ) __lowerCamelCase = self.find(lowerCamelCase__ ) if roota == roota: return roota if self.rank[roota] > self.rank[roota]: __lowerCamelCase = roota return roota if self.rank[roota] < self.rank[roota]: __lowerCamelCase = roota return roota if self.rank[roota] == self.rank[roota]: self.rank[roota] += 1 __lowerCamelCase = roota return roota return None @staticmethod def lowercase_ ( lowerCamelCase__ ) -> str: '''simple docstring''' __lowerCamelCase = graph.num_vertices __lowerCamelCase = Graph.UnionFind() __lowerCamelCase = [] while num_components > 1: __lowerCamelCase = {} for vertex in graph.get_vertices(): __lowerCamelCase = -1 __lowerCamelCase = graph.get_edges() for edge in edges: __lowerCamelCase , __lowerCamelCase , __lowerCamelCase = edge edges.remove((tail, head, weight) ) for edge in edges: __lowerCamelCase , __lowerCamelCase , __lowerCamelCase = edge __lowerCamelCase = union_find.find(lowerCamelCase__ ) __lowerCamelCase = union_find.find(lowerCamelCase__ ) if seta != seta: if cheap_edge[seta] == -1 or cheap_edge[seta][2] > weight: __lowerCamelCase = [head, tail, weight] if cheap_edge[seta] == -1 or cheap_edge[seta][2] > weight: __lowerCamelCase = [head, tail, weight] for vertex in cheap_edge: if cheap_edge[vertex] != -1: __lowerCamelCase , __lowerCamelCase , __lowerCamelCase = cheap_edge[vertex] if union_find.find(lowerCamelCase__ ) != union_find.find(lowerCamelCase__ ): union_find.union(lowerCamelCase__ , lowerCamelCase__ ) mst_edges.append(cheap_edge[vertex] ) __lowerCamelCase = num_components - 1 __lowerCamelCase = Graph.build(edges=lowerCamelCase__ ) return mst
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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_ = logging.getLogger(__name__) def lowerCamelCase ( ) ->List[str]: _SCREAMING_SNAKE_CASE = argparse.ArgumentParser( description="""Preprocess the data to avoid re-doing it several times by (tokenization + token_to_ids).""" ) parser.add_argument("""--file_path""" , type=UpperCamelCase__ , default="""data/dump.txt""" , help="""The path to the data.""" ) parser.add_argument("""--tokenizer_type""" , type=UpperCamelCase__ , default="""bert""" , choices=["""bert""", """roberta""", """gpt2"""] ) parser.add_argument("""--tokenizer_name""" , type=UpperCamelCase__ , default="""bert-base-uncased""" , help="""The tokenizer to use.""" ) parser.add_argument("""--dump_file""" , type=UpperCamelCase__ , default="""data/dump""" , help="""The dump file prefix.""" ) _SCREAMING_SNAKE_CASE = parser.parse_args() logger.info(F'Loading Tokenizer ({args.tokenizer_name})' ) if args.tokenizer_type == "bert": _SCREAMING_SNAKE_CASE = BertTokenizer.from_pretrained(args.tokenizer_name ) _SCREAMING_SNAKE_CASE = tokenizer.special_tokens_map["""cls_token"""] # `[CLS]` _SCREAMING_SNAKE_CASE = tokenizer.special_tokens_map["""sep_token"""] # `[SEP]` elif args.tokenizer_type == "roberta": _SCREAMING_SNAKE_CASE = RobertaTokenizer.from_pretrained(args.tokenizer_name ) _SCREAMING_SNAKE_CASE = tokenizer.special_tokens_map["""cls_token"""] # `<s>` _SCREAMING_SNAKE_CASE = tokenizer.special_tokens_map["""sep_token"""] # `</s>` elif args.tokenizer_type == "gpt2": _SCREAMING_SNAKE_CASE = GPTaTokenizer.from_pretrained(args.tokenizer_name ) _SCREAMING_SNAKE_CASE = tokenizer.special_tokens_map["""bos_token"""] # `<|endoftext|>` _SCREAMING_SNAKE_CASE = 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: _SCREAMING_SNAKE_CASE = fp.readlines() logger.info("""Start encoding""" ) logger.info(F'{len(UpperCamelCase__ )} examples to process.' ) _SCREAMING_SNAKE_CASE = [] _SCREAMING_SNAKE_CASE = 0 _SCREAMING_SNAKE_CASE = 1_0000 _SCREAMING_SNAKE_CASE = time.time() for text in data: _SCREAMING_SNAKE_CASE = F'{bos} {text.strip()} {sep}' _SCREAMING_SNAKE_CASE = tokenizer.encode(UpperCamelCase__ , add_special_tokens=UpperCamelCase__ ) rslt.append(UpperCamelCase__ ) iter += 1 if iter % interval == 0: _SCREAMING_SNAKE_CASE = time.time() logger.info(F'{iter} examples processed. - {(end-start):.2f}s/{interval}expl' ) _SCREAMING_SNAKE_CASE = time.time() logger.info("""Finished binarization""" ) logger.info(F'{len(UpperCamelCase__ )} examples processed.' ) _SCREAMING_SNAKE_CASE = F'{args.dump_file}.{args.tokenizer_name}.pickle' _SCREAMING_SNAKE_CASE = tokenizer.vocab_size if vocab_size < (1 << 16): _SCREAMING_SNAKE_CASE = [np.uintaa(UpperCamelCase__ ) for d in rslt] else: _SCREAMING_SNAKE_CASE = [np.intaa(UpperCamelCase__ ) for d in rslt] random.shuffle(rslt_ ) logger.info(F'Dump to {dp_file}' ) with open(UpperCamelCase__ , """wb""" ) as handle: pickle.dump(rslt_ , UpperCamelCase__ , protocol=pickle.HIGHEST_PROTOCOL ) if __name__ == "__main__": main()
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from math import pi, sqrt, tan def lowerCamelCase_ ( UpperCamelCase__ : float ) -> float: """simple docstring""" if side_length < 0: raise ValueError('surface_area_cube() only accepts non-negative values' ) return 6 * side_length**2 def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if length < 0 or breadth < 0 or height < 0: raise ValueError('surface_area_cuboid() only accepts non-negative values' ) return 2 * ((length * breadth) + (breadth * height) + (length * height)) def lowerCamelCase_ ( UpperCamelCase__ : float ) -> float: """simple docstring""" if radius < 0: raise ValueError('surface_area_sphere() only accepts non-negative values' ) return 4 * pi * radius**2 def lowerCamelCase_ ( UpperCamelCase__ : float ) -> float: """simple docstring""" if radius < 0: raise ValueError('surface_area_hemisphere() only accepts non-negative values' ) return 3 * pi * radius**2 def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if radius < 0 or height < 0: raise ValueError('surface_area_cone() only accepts non-negative values' ) return pi * radius * (radius + (height**2 + radius**2) ** 0.5) def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if radius_a < 0 or radius_a < 0 or height < 0: raise ValueError( 'surface_area_conical_frustum() only accepts non-negative values' ) __lowerCamelCase = (height**2 + (radius_a - radius_a) ** 2) ** 0.5 return pi * ((slant_height * (radius_a + radius_a)) + radius_a**2 + radius_a**2) def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if radius < 0 or height < 0: raise ValueError('surface_area_cylinder() only accepts non-negative values' ) return 2 * pi * radius * (height + radius) def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if torus_radius < 0 or tube_radius < 0: raise ValueError('surface_area_torus() only accepts non-negative values' ) if torus_radius < tube_radius: raise ValueError( 'surface_area_torus() does not support spindle or self intersecting tori' ) return 4 * pow(UpperCamelCase__ , 2 ) * torus_radius * tube_radius def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if length < 0 or width < 0: raise ValueError('area_rectangle() only accepts non-negative values' ) return length * width def lowerCamelCase_ ( UpperCamelCase__ : float ) -> float: """simple docstring""" if side_length < 0: raise ValueError('area_square() only accepts non-negative values' ) return side_length**2 def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if base < 0 or height < 0: raise ValueError('area_triangle() only accepts non-negative values' ) return (base * height) / 2 def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if sidea < 0 or sidea < 0 or sidea < 0: raise ValueError('area_triangle_three_sides() only accepts non-negative values' ) elif sidea + sidea < sidea or sidea + sidea < sidea or sidea + sidea < sidea: raise ValueError('Given three sides do not form a triangle' ) __lowerCamelCase = (sidea + sidea + sidea) / 2 __lowerCamelCase = sqrt( semi_perimeter * (semi_perimeter - sidea) * (semi_perimeter - sidea) * (semi_perimeter - sidea) ) return area def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if base < 0 or height < 0: raise ValueError('area_parallelogram() only accepts non-negative values' ) return base * height def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if basea < 0 or basea < 0 or height < 0: raise ValueError('area_trapezium() only accepts non-negative values' ) return 1 / 2 * (basea + basea) * height def lowerCamelCase_ ( UpperCamelCase__ : float ) -> float: """simple docstring""" if radius < 0: raise ValueError('area_circle() only accepts non-negative values' ) return pi * radius**2 def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if radius_x < 0 or radius_y < 0: raise ValueError('area_ellipse() only accepts non-negative values' ) return pi * radius_x * radius_y def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if diagonal_a < 0 or diagonal_a < 0: raise ValueError('area_rhombus() only accepts non-negative values' ) return 1 / 2 * diagonal_a * diagonal_a def lowerCamelCase_ ( UpperCamelCase__ : int , UpperCamelCase__ : float ) -> float: """simple docstring""" if not isinstance(UpperCamelCase__ , UpperCamelCase__ ) or sides < 3: raise ValueError( 'area_reg_polygon() only accepts integers greater than or \ equal to three as number of sides' ) elif length < 0: raise ValueError( 'area_reg_polygon() only accepts non-negative values as \ length of a side' ) return (sides * length**2) / (4 * tan(pi / sides )) return (sides * length**2) / (4 * tan(pi / sides )) if __name__ == "__main__": import doctest doctest.testmod(verbose=True) # verbose so we can see methods missing tests print("[DEMO] Areas of various geometric shapes: \n") print(f'''Rectangle: {area_rectangle(10, 20) = }''') print(f'''Square: {area_square(10) = }''') print(f'''Triangle: {area_triangle(10, 10) = }''') print(f'''Triangle: {area_triangle_three_sides(5, 12, 13) = }''') print(f'''Parallelogram: {area_parallelogram(10, 20) = }''') print(f'''Rhombus: {area_rhombus(10, 20) = }''') print(f'''Trapezium: {area_trapezium(10, 20, 30) = }''') print(f'''Circle: {area_circle(20) = }''') print(f'''Ellipse: {area_ellipse(10, 20) = }''') print("\nSurface Areas of various geometric shapes: \n") print(f'''Cube: {surface_area_cube(20) = }''') print(f'''Cuboid: {surface_area_cuboid(10, 20, 30) = }''') print(f'''Sphere: {surface_area_sphere(20) = }''') print(f'''Hemisphere: {surface_area_hemisphere(20) = }''') print(f'''Cone: {surface_area_cone(10, 20) = }''') print(f'''Conical Frustum: {surface_area_conical_frustum(10, 20, 30) = }''') print(f'''Cylinder: {surface_area_cylinder(10, 20) = }''') print(f'''Torus: {surface_area_torus(20, 10) = }''') print(f'''Equilateral Triangle: {area_reg_polygon(3, 10) = }''') print(f'''Square: {area_reg_polygon(4, 10) = }''') print(f'''Reqular Pentagon: {area_reg_polygon(5, 10) = }''')
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from typing import TYPE_CHECKING from ...utils import OptionalDependencyNotAvailable, _LazyModule, is_torch_available UpperCAmelCase__ = {"configuration_vit_msn": ["VIT_MSN_PRETRAINED_CONFIG_ARCHIVE_MAP", "ViTMSNConfig"]} try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: UpperCAmelCase__ = [ "VIT_MSN_PRETRAINED_MODEL_ARCHIVE_LIST", "ViTMSNModel", "ViTMSNForImageClassification", "ViTMSNPreTrainedModel", ] if TYPE_CHECKING: from .configuration_vit_msn import VIT_MSN_PRETRAINED_CONFIG_ARCHIVE_MAP, ViTMSNConfig try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_vit_msn import ( VIT_MSN_PRETRAINED_MODEL_ARCHIVE_LIST, ViTMSNForImageClassification, ViTMSNModel, ViTMSNPreTrainedModel, ) else: import sys UpperCAmelCase__ = _LazyModule(__name__, globals()["__file__"], _import_structure, module_spec=__spec__)
0
import unittest from transformers import DebertaConfig, is_torch_available from transformers.testing_utils import require_sentencepiece, require_tokenizers, require_torch, slow, torch_device from ...test_configuration_common import ConfigTester from ...test_modeling_common import ModelTesterMixin, ids_tensor from ...test_pipeline_mixin import PipelineTesterMixin if is_torch_available(): import torch from transformers import ( DebertaForMaskedLM, DebertaForQuestionAnswering, DebertaForSequenceClassification, DebertaForTokenClassification, DebertaModel, ) from transformers.models.deberta.modeling_deberta import DEBERTA_PRETRAINED_MODEL_ARCHIVE_LIST class __lowerCAmelCase ( __magic_name__ ): """simple docstring""" def __init__( self , lowerCamelCase__ , lowerCamelCase__=13 , lowerCamelCase__=7 , lowerCamelCase__=True , lowerCamelCase__=True , lowerCamelCase__=True , lowerCamelCase__=True , lowerCamelCase__=99 , lowerCamelCase__=32 , lowerCamelCase__=5 , lowerCamelCase__=4 , lowerCamelCase__=37 , lowerCamelCase__="gelu" , lowerCamelCase__=0.1 , lowerCamelCase__=0.1 , lowerCamelCase__=512 , lowerCamelCase__=16 , lowerCamelCase__=2 , lowerCamelCase__=0.02 , lowerCamelCase__=False , lowerCamelCase__=True , lowerCamelCase__="None" , lowerCamelCase__=3 , lowerCamelCase__=4 , lowerCamelCase__=None , ) -> int: '''simple docstring''' __lowerCamelCase = parent __lowerCamelCase = batch_size __lowerCamelCase = seq_length __lowerCamelCase = is_training __lowerCamelCase = use_input_mask __lowerCamelCase = use_token_type_ids __lowerCamelCase = use_labels __lowerCamelCase = vocab_size __lowerCamelCase = hidden_size __lowerCamelCase = num_hidden_layers __lowerCamelCase = num_attention_heads __lowerCamelCase = intermediate_size __lowerCamelCase = hidden_act __lowerCamelCase = hidden_dropout_prob __lowerCamelCase = attention_probs_dropout_prob __lowerCamelCase = max_position_embeddings __lowerCamelCase = type_vocab_size __lowerCamelCase = type_sequence_label_size __lowerCamelCase = initializer_range __lowerCamelCase = num_labels __lowerCamelCase = num_choices __lowerCamelCase = relative_attention __lowerCamelCase = position_biased_input __lowerCamelCase = pos_att_type __lowerCamelCase = scope def lowercase_ ( self ) -> str: '''simple docstring''' __lowerCamelCase = ids_tensor([self.batch_size, self.seq_length] , self.vocab_size ) __lowerCamelCase = None if self.use_input_mask: __lowerCamelCase = ids_tensor([self.batch_size, self.seq_length] , vocab_size=2 ) __lowerCamelCase = None if self.use_token_type_ids: __lowerCamelCase = ids_tensor([self.batch_size, self.seq_length] , self.type_vocab_size ) __lowerCamelCase = None __lowerCamelCase = None __lowerCamelCase = None if self.use_labels: __lowerCamelCase = ids_tensor([self.batch_size] , self.type_sequence_label_size ) __lowerCamelCase = ids_tensor([self.batch_size, self.seq_length] , self.num_labels ) __lowerCamelCase = ids_tensor([self.batch_size] , self.num_choices ) __lowerCamelCase = self.get_config() return config, input_ids, token_type_ids, input_mask, sequence_labels, token_labels, choice_labels def lowercase_ ( self ) -> Optional[Any]: '''simple docstring''' return DebertaConfig( 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 , relative_attention=self.relative_attention , position_biased_input=self.position_biased_input , pos_att_type=self.pos_att_type , ) def lowercase_ ( self ) -> List[str]: '''simple docstring''' __lowerCamelCase = self.get_config() __lowerCamelCase = 300 return config def lowercase_ ( self , lowerCamelCase__ ) -> Optional[int]: '''simple docstring''' self.parent.assertListEqual(list(result.loss.size() ) , [] ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> Any: '''simple docstring''' __lowerCamelCase = DebertaModel(config=lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model(lowerCamelCase__ , attention_mask=lowerCamelCase__ , token_type_ids=lowerCamelCase__ )[0] __lowerCamelCase = model(lowerCamelCase__ , token_type_ids=lowerCamelCase__ )[0] __lowerCamelCase = model(lowerCamelCase__ )[0] self.parent.assertListEqual(list(sequence_output.size() ) , [self.batch_size, self.seq_length, self.hidden_size] ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> Tuple: '''simple docstring''' __lowerCamelCase = DebertaForMaskedLM(config=lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model(lowerCamelCase__ , attention_mask=lowerCamelCase__ , token_type_ids=lowerCamelCase__ , labels=lowerCamelCase__ ) self.parent.assertEqual(result.logits.shape , (self.batch_size, self.seq_length, self.vocab_size) ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> Union[str, Any]: '''simple docstring''' __lowerCamelCase = self.num_labels __lowerCamelCase = DebertaForSequenceClassification(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model(lowerCamelCase__ , attention_mask=lowerCamelCase__ , token_type_ids=lowerCamelCase__ , labels=lowerCamelCase__ ) self.parent.assertListEqual(list(result.logits.size() ) , [self.batch_size, self.num_labels] ) self.check_loss_output(lowerCamelCase__ ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> Optional[int]: '''simple docstring''' __lowerCamelCase = self.num_labels __lowerCamelCase = DebertaForTokenClassification(config=lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model(lowerCamelCase__ , attention_mask=lowerCamelCase__ , token_type_ids=lowerCamelCase__ , labels=lowerCamelCase__ ) self.parent.assertEqual(result.logits.shape , (self.batch_size, self.seq_length, self.num_labels) ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> Dict: '''simple docstring''' __lowerCamelCase = DebertaForQuestionAnswering(config=lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model( lowerCamelCase__ , attention_mask=lowerCamelCase__ , token_type_ids=lowerCamelCase__ , start_positions=lowerCamelCase__ , end_positions=lowerCamelCase__ , ) self.parent.assertEqual(result.start_logits.shape , (self.batch_size, self.seq_length) ) self.parent.assertEqual(result.end_logits.shape , (self.batch_size, self.seq_length) ) def lowercase_ ( self ) -> Union[str, Any]: '''simple docstring''' __lowerCamelCase = self.prepare_config_and_inputs() ( ( __lowerCamelCase ) , ( __lowerCamelCase ) , ( __lowerCamelCase ) , ( __lowerCamelCase ) , ( __lowerCamelCase ) , ( __lowerCamelCase ) , ( __lowerCamelCase ) , ) = config_and_inputs __lowerCamelCase = {'input_ids': input_ids, 'token_type_ids': token_type_ids, 'attention_mask': input_mask} return config, inputs_dict @require_torch class __lowerCAmelCase ( __magic_name__ , __magic_name__ , unittest.TestCase ): """simple docstring""" snake_case_ = ( ( DebertaModel, DebertaForMaskedLM, DebertaForSequenceClassification, DebertaForTokenClassification, DebertaForQuestionAnswering, ) if is_torch_available() else () ) snake_case_ = ( { '''feature-extraction''': DebertaModel, '''fill-mask''': DebertaForMaskedLM, '''question-answering''': DebertaForQuestionAnswering, '''text-classification''': DebertaForSequenceClassification, '''token-classification''': DebertaForTokenClassification, '''zero-shot''': DebertaForSequenceClassification, } if is_torch_available() else {} ) snake_case_ = True snake_case_ = False snake_case_ = False snake_case_ = False snake_case_ = False def lowercase_ ( self ) -> List[Any]: '''simple docstring''' __lowerCamelCase = DebertaModelTester(self ) __lowerCamelCase = ConfigTester(self , config_class=lowerCamelCase__ , hidden_size=37 ) def lowercase_ ( self ) -> Optional[int]: '''simple docstring''' self.config_tester.run_common_tests() def lowercase_ ( self ) -> List[str]: '''simple docstring''' __lowerCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_deberta_model(*lowerCamelCase__ ) def lowercase_ ( self ) -> Optional[int]: '''simple docstring''' __lowerCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_deberta_for_sequence_classification(*lowerCamelCase__ ) def lowercase_ ( self ) -> Dict: '''simple docstring''' __lowerCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_deberta_for_masked_lm(*lowerCamelCase__ ) def lowercase_ ( self ) -> Optional[Any]: '''simple docstring''' __lowerCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_deberta_for_question_answering(*lowerCamelCase__ ) def lowercase_ ( self ) -> str: '''simple docstring''' __lowerCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_deberta_for_token_classification(*lowerCamelCase__ ) @slow def lowercase_ ( self ) -> Optional[int]: '''simple docstring''' for model_name in DEBERTA_PRETRAINED_MODEL_ARCHIVE_LIST[:1]: __lowerCamelCase = DebertaModel.from_pretrained(lowerCamelCase__ ) self.assertIsNotNone(lowerCamelCase__ ) @require_torch @require_sentencepiece @require_tokenizers class __lowerCAmelCase ( unittest.TestCase ): """simple docstring""" @unittest.skip(reason='Model not available yet' ) def lowercase_ ( self ) -> Union[str, Any]: '''simple docstring''' pass @slow def lowercase_ ( self ) -> Tuple: '''simple docstring''' __lowerCamelCase = DebertaModel.from_pretrained('microsoft/deberta-base' ) __lowerCamelCase = torch.tensor([[0, 31_414, 232, 328, 740, 1_140, 12_695, 69, 46_078, 1_588, 2]] ) __lowerCamelCase = torch.tensor([[0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1]] ) with torch.no_grad(): __lowerCamelCase = model(lowerCamelCase__ , attention_mask=lowerCamelCase__ )[0] # compare the actual values for a slice. __lowerCamelCase = torch.tensor( [[[-0.59_86, -0.80_55, -0.84_62], [1.44_84, -0.93_48, -0.80_59], [0.31_23, 0.00_32, -1.41_31]]] ) self.assertTrue(torch.allclose(output[:, 1:4, 1:4] , lowerCamelCase__ , atol=1e-4 ) , f"""{output[:, 1:4, 1:4]}""" )
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from typing import TYPE_CHECKING from ...utils import OptionalDependencyNotAvailable, _LazyModule, is_speech_available, is_torch_available lowercase__ : List[Any] = { '''configuration_audio_spectrogram_transformer''': [ '''AUDIO_SPECTROGRAM_TRANSFORMER_PRETRAINED_CONFIG_ARCHIVE_MAP''', '''ASTConfig''', ] } try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: lowercase__ : List[str] = [ '''AUDIO_SPECTROGRAM_TRANSFORMER_PRETRAINED_MODEL_ARCHIVE_LIST''', '''ASTForAudioClassification''', '''ASTModel''', '''ASTPreTrainedModel''', ] try: if not is_speech_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: lowercase__ : Tuple = ['''ASTFeatureExtractor'''] if TYPE_CHECKING: from .configuration_audio_spectrogram_transformer import ( AUDIO_SPECTROGRAM_TRANSFORMER_PRETRAINED_CONFIG_ARCHIVE_MAP, ASTConfig, ) try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_audio_spectrogram_transformer import ( AUDIO_SPECTROGRAM_TRANSFORMER_PRETRAINED_MODEL_ARCHIVE_LIST, ASTForAudioClassification, ASTModel, ASTPreTrainedModel, ) try: if not is_speech_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .feature_extraction_audio_spectrogram_transformer import ASTFeatureExtractor else: import sys lowercase__ : Optional[Any] = _LazyModule(__name__, globals()['''__file__'''], _import_structure, module_spec=__spec__)
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from __future__ import annotations # This is the precision for this function which can be altered. # It is recommended for users to keep this number greater than or equal to 10. __A = 10 def lowerCamelCase_ ( UpperCamelCase__ : int , UpperCamelCase__ : int , UpperCamelCase__ : list[int] , UpperCamelCase__ : int ) -> int: """simple docstring""" for i in range(UpperCamelCase__ , UpperCamelCase__ ): if array[i] == target: return i return -1 def lowerCamelCase_ ( UpperCamelCase__ : list[int] , UpperCamelCase__ : int ) -> int: """simple docstring""" __lowerCamelCase = 0 __lowerCamelCase = len(UpperCamelCase__ ) while left <= right: if right - left < precision: return lin_search(UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ ) __lowerCamelCase = (left + right) // 3 + 1 __lowerCamelCase = 2 * (left + right) // 3 + 1 if array[one_third] == target: return one_third elif array[two_third] == target: return two_third elif target < array[one_third]: __lowerCamelCase = one_third - 1 elif array[two_third] < target: __lowerCamelCase = two_third + 1 else: __lowerCamelCase = one_third + 1 __lowerCamelCase = two_third - 1 else: return -1 def lowerCamelCase_ ( UpperCamelCase__ : int , UpperCamelCase__ : int , UpperCamelCase__ : list[int] , UpperCamelCase__ : int ) -> int: """simple docstring""" if left < right: if right - left < precision: return lin_search(UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ ) __lowerCamelCase = (left + right) // 3 + 1 __lowerCamelCase = 2 * (left + right) // 3 + 1 if array[one_third] == target: return one_third elif array[two_third] == target: return two_third elif target < array[one_third]: return rec_ternary_search(UpperCamelCase__ , one_third - 1 , UpperCamelCase__ , UpperCamelCase__ ) elif array[two_third] < target: return rec_ternary_search(two_third + 1 , UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ ) else: return rec_ternary_search(one_third + 1 , two_third - 1 , UpperCamelCase__ , UpperCamelCase__ ) else: return -1 if __name__ == "__main__": import doctest doctest.testmod() __A = input("Enter numbers separated by comma:\n").strip() __A = [int(item.strip()) for item in user_input.split(",")] assert collection == sorted(collection), f"List must be ordered.\n{collection}." __A = int(input("Enter the number to be found in the list:\n").strip()) __A = ite_ternary_search(collection, target) __A = rec_ternary_search(0, len(collection) - 1, collection, target) if resulta != -1: print(f'''Iterative search: {target} found at positions: {resulta}''') print(f'''Recursive search: {target} found at positions: {resulta}''') else: print("Not found")
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"""simple docstring""" from manim import * class __snake_case ( __lowerCAmelCase ): def lowerCamelCase_ ( self) -> Any: '''simple docstring''' a__: Tuple = Rectangle(height=0.5 , width=0.5) a__: Tuple = Rectangle(height=0.46 , width=0.46).set_stroke(width=0) a__: List[str] = Rectangle(height=0.25 , width=0.25) a__: List[Any] = [mem.copy() for i in range(6)] a__: List[str] = [mem.copy() for i in range(6)] a__: List[str] = VGroup(*lowerCamelCase__).arrange(lowerCamelCase__ , buff=0) a__: Dict = VGroup(*lowerCamelCase__).arrange(lowerCamelCase__ , buff=0) a__: Optional[int] = VGroup(lowerCamelCase__ , lowerCamelCase__).arrange(lowerCamelCase__ , buff=0) a__: Optional[Any] = Text('CPU' , font_size=24) a__: Tuple = Group(lowerCamelCase__ , lowerCamelCase__).arrange(lowerCamelCase__ , buff=0.5 , aligned_edge=lowerCamelCase__) cpu.move_to([-2.5, -0.5, 0]) self.add(lowerCamelCase__) a__: Optional[int] = [mem.copy() for i in range(4)] a__: List[Any] = VGroup(*lowerCamelCase__).arrange(lowerCamelCase__ , buff=0) a__: Tuple = Text('GPU' , font_size=24) a__: Tuple = Group(lowerCamelCase__ , lowerCamelCase__).arrange(lowerCamelCase__ , buff=0.5 , aligned_edge=lowerCamelCase__) gpu.move_to([-1, -1, 0]) self.add(lowerCamelCase__) a__: int = [mem.copy() for i in range(6)] a__: str = VGroup(*lowerCamelCase__).arrange(lowerCamelCase__ , buff=0) a__: Union[str, Any] = Text('Model' , font_size=24) a__: Tuple = Group(lowerCamelCase__ , lowerCamelCase__).arrange(lowerCamelCase__ , buff=0.5 , aligned_edge=lowerCamelCase__) model.move_to([3, -1.0, 0]) self.add(lowerCamelCase__) a__: List[str] = [] a__: int = [] for i, rect in enumerate(lowerCamelCase__): a__: List[str] = fill.copy().set_fill(lowerCamelCase__ , opacity=0.8) target.move_to(lowerCamelCase__) model_arr.append(lowerCamelCase__) a__: Tuple = Rectangle(height=0.46 , width=0.46).set_stroke(width=0.0).set_fill(lowerCamelCase__ , opacity=0.8) cpu_target.move_to(cpu_left_col_base[i]) model_cpu_arr.append(lowerCamelCase__) self.add(*lowerCamelCase__ , *lowerCamelCase__) a__: int = [meta_mem.copy() for i in range(6)] a__: Tuple = [meta_mem.copy() for i in range(6)] a__: Tuple = VGroup(*lowerCamelCase__).arrange(lowerCamelCase__ , buff=0) a__: Optional[Any] = VGroup(*lowerCamelCase__).arrange(lowerCamelCase__ , buff=0) a__: Any = VGroup(lowerCamelCase__ , lowerCamelCase__).arrange(lowerCamelCase__ , buff=0) a__: Dict = Text('Disk' , font_size=24) a__: List[str] = Group(lowerCamelCase__ , lowerCamelCase__).arrange(lowerCamelCase__ , buff=0.5 , aligned_edge=lowerCamelCase__) disk.move_to([-4, -1.25, 0]) self.add(lowerCamelCase__ , lowerCamelCase__) a__: Dict = Square(side_length=2.2) key.move_to([-5, 2, 0]) a__: Union[str, Any] = MarkupText( f'<b>Key:</b>\n\n<span fgcolor=\'{YELLOW}\'>●</span> Empty Model' , font_size=18 , ) key_text.move_to([-5, 2.4, 0]) self.add(lowerCamelCase__ , lowerCamelCase__) a__: List[str] = MarkupText( f'<span fgcolor=\'{BLUE}\'>●</span> Checkpoint' , font_size=18 , ) blue_text.next_to(lowerCamelCase__ , DOWN * 2.4 , aligned_edge=key_text.get_left()) self.add(lowerCamelCase__) a__: Tuple = MarkupText( f'Now watch as an input is passed through the model\nand how the memory is utilized and handled.' , font_size=24 , ) step_a.move_to([2, 2, 0]) self.play(Write(lowerCamelCase__)) a__: Tuple = Square(0.3) input.set_fill(lowerCamelCase__ , opacity=1.0) input.set_stroke(width=0.0) input.next_to(model_base[0] , lowerCamelCase__ , buff=0.5) self.play(Write(lowerCamelCase__)) input.generate_target() input.target.next_to(model_arr[0] , direction=lowerCamelCase__ , buff=0.02) self.play(MoveToTarget(lowerCamelCase__)) self.play(FadeOut(lowerCamelCase__)) a__: Any = Arrow(start=lowerCamelCase__ , end=lowerCamelCase__ , color=lowerCamelCase__ , buff=0.5) a.next_to(model_arr[0].get_left() , lowerCamelCase__ , buff=0.2) model_cpu_arr[0].generate_target() model_cpu_arr[0].target.move_to(gpu_rect[0]) a__: int = 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=24 , ) step_a.move_to([2, 2, 0]) self.play(Write(lowerCamelCase__ , run_time=3)) a__: List[str] = {'run_time': 1, 'fade_in': True, 'fade_out': True, 'buff': 0.02} self.play( Write(lowerCamelCase__) , Circumscribe(model_arr[0] , color=lowerCamelCase__ , **lowerCamelCase__) , Circumscribe(model_cpu_arr[0] , color=lowerCamelCase__ , **lowerCamelCase__) , Circumscribe(gpu_rect[0] , color=lowerCamelCase__ , **lowerCamelCase__) , ) self.play(MoveToTarget(model_cpu_arr[0])) a__: int = a.copy() for i in range(6): a_c.next_to(model_arr[i].get_right() + 0.02 , lowerCamelCase__ , buff=0.2) input.generate_target() input.target.move_to(model_arr[i].get_right() + 0.02) a__: str = AnimationGroup( FadeOut(lowerCamelCase__ , run_time=0.5) , MoveToTarget(lowerCamelCase__ , run_time=0.5) , FadeIn(lowerCamelCase__ , run_time=0.5) , lag_ratio=0.2) self.play(lowerCamelCase__) 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: a__: int = 0.7 self.play( Circumscribe(model_arr[i] , **lowerCamelCase__) , Circumscribe(cpu_left_col_base[i] , **lowerCamelCase__) , Circumscribe(cpu_left_col_base[i + 1] , color=lowerCamelCase__ , **lowerCamelCase__) , Circumscribe(gpu_rect[0] , color=lowerCamelCase__ , **lowerCamelCase__) , Circumscribe(model_arr[i + 1] , color=lowerCamelCase__ , **lowerCamelCase__) , ) 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=lowerCamelCase__ , **lowerCamelCase__) , Circumscribe(cpu_left_col_base[-1] , color=lowerCamelCase__ , **lowerCamelCase__) , Circumscribe(gpu_rect[0] , color=lowerCamelCase__ , **lowerCamelCase__) , ) self.play(MoveToTarget(model_cpu_arr[i])) a__: int = a_c a__: Optional[int] = a_c.copy() input.generate_target() input.target.next_to(model_base[-1] , RIGHT + 0.02 , buff=0.5) self.play( FadeOut(lowerCamelCase__) , FadeOut(lowerCamelCase__ , run_time=0.5) , ) a__: List[Any] = MarkupText(f'Inference on a model too large for GPU memory\nis successfully completed.' , font_size=24) step_a.move_to([2, 2, 0]) self.play(Write(lowerCamelCase__ , run_time=3) , MoveToTarget(lowerCamelCase__)) self.wait()
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import string # frequency taken from https://en.wikipedia.org/wiki/Letter_frequency __A = { "E": 1_2.7_0, "T": 9.0_6, "A": 8.1_7, "O": 7.5_1, "I": 6.9_7, "N": 6.7_5, "S": 6.3_3, "H": 6.0_9, "R": 5.9_9, "D": 4.2_5, "L": 4.0_3, "C": 2.7_8, "U": 2.7_6, "M": 2.4_1, "W": 2.3_6, "F": 2.2_3, "G": 2.0_2, "Y": 1.9_7, "P": 1.9_3, "B": 1.2_9, "V": 0.9_8, "K": 0.7_7, "J": 0.1_5, "X": 0.1_5, "Q": 0.1_0, "Z": 0.0_7, } __A = "ETAOINSHRDLCUMWFGYPBVKJXQZ" __A = "ABCDEFGHIJKLMNOPQRSTUVWXYZ" def lowerCamelCase_ ( UpperCamelCase__ : str ) -> dict[str, int]: """simple docstring""" __lowerCamelCase = {letter: 0 for letter in string.ascii_uppercase} for letter in message.upper(): if letter in LETTERS: letter_count[letter] += 1 return letter_count def lowerCamelCase_ ( UpperCamelCase__ : tuple ) -> str: """simple docstring""" return x[0] def lowerCamelCase_ ( UpperCamelCase__ : str ) -> str: """simple docstring""" __lowerCamelCase = get_letter_count(UpperCamelCase__ ) __lowerCamelCase = { freq: [] for letter, freq in letter_to_freq.items() } for letter in LETTERS: freq_to_letter[letter_to_freq[letter]].append(UpperCamelCase__ ) __lowerCamelCase = {} for freq in freq_to_letter: freq_to_letter[freq].sort(key=ETAOIN.find , reverse=UpperCamelCase__ ) __lowerCamelCase = ''.join(freq_to_letter[freq] ) __lowerCamelCase = list(freq_to_letter_str.items() ) freq_pairs.sort(key=UpperCamelCase__ , reverse=UpperCamelCase__ ) __lowerCamelCase = [freq_pair[1] for freq_pair in freq_pairs] return "".join(UpperCamelCase__ ) def lowerCamelCase_ ( UpperCamelCase__ : str ) -> int: """simple docstring""" __lowerCamelCase = get_frequency_order(UpperCamelCase__ ) __lowerCamelCase = 0 for common_letter in ETAOIN[:6]: if common_letter in freq_order[:6]: match_score += 1 for uncommon_letter in ETAOIN[-6:]: if uncommon_letter in freq_order[-6:]: match_score += 1 return match_score if __name__ == "__main__": import doctest doctest.testmod()
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"""simple docstring""" import argparse import os from io import BytesIO from pathlib import Path import requests from clip_retrieval.clip_client import ClipClient from PIL import Image from tqdm import tqdm def lowercase__ ( snake_case_ :Any , snake_case_ :Union[str, Any] , snake_case_ :str ): __UpperCAmelCase = 1.5 __UpperCAmelCase = int(factor * num_class_images ) __UpperCAmelCase = ClipClient( url='''https://knn.laion.ai/knn-service''' , indice_name='''laion_400m''' , num_images=UpperCamelCase__ , aesthetic_weight=0.1 ) os.makedirs(F'''{class_data_dir}/images''' , exist_ok=UpperCamelCase__ ) if len(list(Path(F'''{class_data_dir}/images''' ).iterdir() ) ) >= num_class_images: return while True: __UpperCAmelCase = client.query(text=UpperCamelCase__ ) if len(UpperCamelCase__ ) >= factor * num_class_images or num_images > 1E4: break else: __UpperCAmelCase = int(factor * num_images ) __UpperCAmelCase = ClipClient( url='''https://knn.laion.ai/knn-service''' , indice_name='''laion_400m''' , num_images=UpperCamelCase__ , aesthetic_weight=0.1 , ) __UpperCAmelCase = 0 __UpperCAmelCase = 0 __UpperCAmelCase = tqdm(desc='''downloading real regularization images''' , total=UpperCamelCase__ ) with open(F'''{class_data_dir}/caption.txt''' , '''w''' ) as fa, open(F'''{class_data_dir}/urls.txt''' , '''w''' ) as fa, open( F'''{class_data_dir}/images.txt''' , '''w''' ) as fa: while total < num_class_images: __UpperCAmelCase = class_images[count] count += 1 try: __UpperCAmelCase = requests.get(images['''url'''] ) if img.status_code == 200: __UpperCAmelCase = Image.open(BytesIO(img.content ) ) with open(F'''{class_data_dir}/images/{total}.jpg''' , '''wb''' ) as f: f.write(img.content ) fa.write(images['''caption'''] + '''\n''' ) fa.write(images['''url'''] + '''\n''' ) fa.write(F'''{class_data_dir}/images/{total}.jpg''' + '''\n''' ) total += 1 pbar.update(1 ) else: continue except Exception: continue return def lowercase__ ( ): __UpperCAmelCase = argparse.ArgumentParser('''''' , add_help=UpperCamelCase__ ) parser.add_argument('''--class_prompt''' , help='''text prompt to retrieve images''' , required=UpperCamelCase__ , type=UpperCamelCase__ ) parser.add_argument('''--class_data_dir''' , help='''path to save images''' , required=UpperCamelCase__ , type=UpperCamelCase__ ) parser.add_argument('''--num_class_images''' , help='''number of images to download''' , default=200 , type=UpperCamelCase__ ) return parser.parse_args() if __name__ == "__main__": _lowercase : Tuple = parse_args() retrieve(args.class_prompt, args.class_data_dir, args.num_class_images)
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class __lowerCAmelCase : """simple docstring""" def __init__( self , lowerCamelCase__ ) -> Any: '''simple docstring''' __lowerCamelCase = n __lowerCamelCase = [None] * self.n __lowerCamelCase = 0 # index of the first element __lowerCamelCase = 0 __lowerCamelCase = 0 def __len__( self ) -> int: '''simple docstring''' return self.size def lowercase_ ( self ) -> bool: '''simple docstring''' return self.size == 0 def lowercase_ ( self ) -> str: '''simple docstring''' return False if self.is_empty() else self.array[self.front] def lowercase_ ( self , lowerCamelCase__ ) -> Optional[Any]: '''simple docstring''' if self.size >= self.n: raise Exception('QUEUE IS FULL' ) __lowerCamelCase = data __lowerCamelCase = (self.rear + 1) % self.n self.size += 1 return self def lowercase_ ( self ) -> Tuple: '''simple docstring''' if self.size == 0: raise Exception('UNDERFLOW' ) __lowerCamelCase = self.array[self.front] __lowerCamelCase = None __lowerCamelCase = (self.front + 1) % self.n self.size -= 1 return temp
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'''simple docstring''' from __future__ import annotations import unittest from transformers import MobileBertConfig, is_tf_available from transformers.models.auto import get_values 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 ( TF_MODEL_FOR_PRETRAINING_MAPPING, TFMobileBertForMaskedLM, TFMobileBertForMultipleChoice, TFMobileBertForNextSentencePrediction, TFMobileBertForPreTraining, TFMobileBertForQuestionAnswering, TFMobileBertForSequenceClassification, TFMobileBertForTokenClassification, TFMobileBertModel, ) @require_tf class UpperCAmelCase__ ( lowercase__ , lowercase__ , unittest.TestCase ): """simple docstring""" __UpperCAmelCase : Tuple = ( ( TFMobileBertModel, TFMobileBertForMaskedLM, TFMobileBertForNextSentencePrediction, TFMobileBertForPreTraining, TFMobileBertForQuestionAnswering, TFMobileBertForSequenceClassification, TFMobileBertForTokenClassification, TFMobileBertForMultipleChoice, ) if is_tf_available() else () ) __UpperCAmelCase : Dict = ( { '''feature-extraction''': TFMobileBertModel, '''fill-mask''': TFMobileBertForMaskedLM, '''question-answering''': TFMobileBertForQuestionAnswering, '''text-classification''': TFMobileBertForSequenceClassification, '''token-classification''': TFMobileBertForTokenClassification, '''zero-shot''': TFMobileBertForSequenceClassification, } if is_tf_available() else {} ) __UpperCAmelCase : Dict = False __UpperCAmelCase : Tuple = False def __lowercase ( self : Dict ,_a : List[Any] ,_a : Any ,_a : int=False ): '''simple docstring''' _a : Dict = super()._prepare_for_class(lowerCamelCase__ ,lowerCamelCase__ ,return_labels=lowerCamelCase__ ) if return_labels: if model_class in get_values(lowerCamelCase__ ): _a : List[Any] = tf.zeros(self.model_tester.batch_size ,dtype=tf.intaa ) return inputs_dict class UpperCAmelCase__ ( lowercase__ ): """simple docstring""" def __init__( self : Union[str, Any] ,_a : int ,_a : int=13 ,_a : List[str]=7 ,_a : Tuple=True ,_a : Optional[int]=True ,_a : List[str]=True ,_a : List[str]=True ,_a : Union[str, Any]=99 ,_a : Dict=32 ,_a : Optional[int]=32 ,_a : int=2 ,_a : Tuple=4 ,_a : int=37 ,_a : Tuple="gelu" ,_a : int=0.1 ,_a : Tuple=0.1 ,_a : Union[str, Any]=512 ,_a : Union[str, Any]=16 ,_a : Any=2 ,_a : Optional[Any]=0.02 ,_a : Dict=3 ,_a : Dict=4 ,_a : List[Any]=None ,): '''simple docstring''' _a : Tuple = parent _a : Any = batch_size _a : Dict = seq_length _a : Optional[Any] = is_training _a : Optional[Any] = use_input_mask _a : Dict = use_token_type_ids _a : Union[str, Any] = use_labels _a : str = vocab_size _a : Union[str, Any] = hidden_size _a : Optional[int] = num_hidden_layers _a : Dict = num_attention_heads _a : Tuple = intermediate_size _a : Any = hidden_act _a : Any = hidden_dropout_prob _a : Union[str, Any] = attention_probs_dropout_prob _a : Dict = max_position_embeddings _a : Union[str, Any] = type_vocab_size _a : Tuple = type_sequence_label_size _a : Tuple = initializer_range _a : Any = num_labels _a : int = num_choices _a : int = scope _a : str = embedding_size def __lowercase ( self : Optional[Any] ): '''simple docstring''' _a : Optional[Any] = ids_tensor([self.batch_size, self.seq_length] ,self.vocab_size ) _a : List[str] = None if self.use_input_mask: _a : Union[str, Any] = random_attention_mask([self.batch_size, self.seq_length] ) _a : Tuple = None if self.use_token_type_ids: _a : List[str] = ids_tensor([self.batch_size, self.seq_length] ,self.type_vocab_size ) _a : List[str] = None _a : Optional[Any] = None _a : Any = None if self.use_labels: _a : List[Any] = ids_tensor([self.batch_size] ,self.type_sequence_label_size ) _a : Tuple = ids_tensor([self.batch_size, self.seq_length] ,self.num_labels ) _a : List[Any] = ids_tensor([self.batch_size] ,self.num_choices ) _a : List[Any] = MobileBertConfig( 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 ,embedding_size=self.embedding_size ,) return config, input_ids, token_type_ids, input_mask, sequence_labels, token_labels, choice_labels def __lowercase ( self : Optional[int] ,_a : str ,_a : Optional[Any] ,_a : Union[str, Any] ,_a : List[Any] ,_a : Tuple ,_a : List[Any] ,_a : Optional[int] ): '''simple docstring''' _a : List[Any] = TFMobileBertModel(config=lowerCamelCase__ ) _a : List[str] = {'input_ids': input_ids, 'attention_mask': input_mask, 'token_type_ids': token_type_ids} _a : List[str] = model(lowerCamelCase__ ) _a : Dict = [input_ids, input_mask] _a : Optional[int] = model(lowerCamelCase__ ) _a : Optional[Any] = model(lowerCamelCase__ ) self.parent.assertEqual( result.last_hidden_state.shape ,(self.batch_size, self.seq_length, self.hidden_size) ) self.parent.assertEqual(result.pooler_output.shape ,(self.batch_size, self.hidden_size) ) def __lowercase ( self : List[str] ,_a : Optional[int] ,_a : Optional[Any] ,_a : int ,_a : Dict ,_a : Optional[Any] ,_a : Optional[int] ,_a : Optional[Any] ): '''simple docstring''' _a : List[Any] = TFMobileBertForMaskedLM(config=lowerCamelCase__ ) _a : Optional[Any] = {'input_ids': input_ids, 'attention_mask': input_mask, 'token_type_ids': token_type_ids} _a : Optional[Any] = model(lowerCamelCase__ ) self.parent.assertEqual(result.logits.shape ,(self.batch_size, self.seq_length, self.vocab_size) ) def __lowercase ( self : Any ,_a : List[str] ,_a : Any ,_a : Dict ,_a : str ,_a : List[str] ,_a : Optional[Any] ,_a : str ): '''simple docstring''' _a : int = TFMobileBertForNextSentencePrediction(config=lowerCamelCase__ ) _a : List[Any] = {'input_ids': input_ids, 'attention_mask': input_mask, 'token_type_ids': token_type_ids} _a : str = model(lowerCamelCase__ ) self.parent.assertEqual(result.logits.shape ,(self.batch_size, 2) ) def __lowercase ( self : int ,_a : List[Any] ,_a : Optional[int] ,_a : Optional[Any] ,_a : Optional[int] ,_a : Optional[int] ,_a : List[str] ,_a : str ): '''simple docstring''' _a : Tuple = TFMobileBertForPreTraining(config=lowerCamelCase__ ) _a : Optional[int] = {'input_ids': input_ids, 'attention_mask': input_mask, 'token_type_ids': token_type_ids} _a : Tuple = model(lowerCamelCase__ ) self.parent.assertEqual( result.prediction_logits.shape ,(self.batch_size, self.seq_length, self.vocab_size) ) self.parent.assertEqual(result.seq_relationship_logits.shape ,(self.batch_size, 2) ) def __lowercase ( self : Dict ,_a : List[Any] ,_a : Optional[int] ,_a : Any ,_a : int ,_a : Optional[Any] ,_a : Union[str, Any] ,_a : Tuple ): '''simple docstring''' _a : Union[str, Any] = self.num_labels _a : Optional[int] = TFMobileBertForSequenceClassification(config=lowerCamelCase__ ) _a : str = {'input_ids': input_ids, 'attention_mask': input_mask, 'token_type_ids': token_type_ids} _a : Optional[Any] = model(lowerCamelCase__ ) self.parent.assertEqual(result.logits.shape ,(self.batch_size, self.num_labels) ) def __lowercase ( self : Any ,_a : List[str] ,_a : Union[str, Any] ,_a : List[str] ,_a : List[str] ,_a : List[str] ,_a : str ,_a : Tuple ): '''simple docstring''' _a : Optional[Any] = self.num_choices _a : Tuple = TFMobileBertForMultipleChoice(config=lowerCamelCase__ ) _a : Optional[Any] = tf.tile(tf.expand_dims(lowerCamelCase__ ,1 ) ,(1, self.num_choices, 1) ) _a : str = tf.tile(tf.expand_dims(lowerCamelCase__ ,1 ) ,(1, self.num_choices, 1) ) _a : Optional[int] = tf.tile(tf.expand_dims(lowerCamelCase__ ,1 ) ,(1, self.num_choices, 1) ) _a : str = { 'input_ids': multiple_choice_inputs_ids, 'attention_mask': multiple_choice_input_mask, 'token_type_ids': multiple_choice_token_type_ids, } _a : Union[str, Any] = model(lowerCamelCase__ ) self.parent.assertEqual(result.logits.shape ,(self.batch_size, self.num_choices) ) def __lowercase ( self : Optional[Any] ,_a : List[Any] ,_a : str ,_a : Any ,_a : Optional[int] ,_a : Optional[Any] ,_a : List[Any] ,_a : Any ): '''simple docstring''' _a : Optional[int] = self.num_labels _a : Optional[int] = TFMobileBertForTokenClassification(config=lowerCamelCase__ ) _a : Optional[Any] = {'input_ids': input_ids, 'attention_mask': input_mask, 'token_type_ids': token_type_ids} _a : List[str] = model(lowerCamelCase__ ) self.parent.assertEqual(result.logits.shape ,(self.batch_size, self.seq_length, self.num_labels) ) def __lowercase ( self : Any ,_a : Tuple ,_a : Any ,_a : List[Any] ,_a : List[str] ,_a : Optional[int] ,_a : Optional[int] ,_a : Optional[int] ): '''simple docstring''' _a : int = TFMobileBertForQuestionAnswering(config=lowerCamelCase__ ) _a : List[Any] = {'input_ids': input_ids, 'attention_mask': input_mask, 'token_type_ids': token_type_ids} _a : Tuple = model(lowerCamelCase__ ) self.parent.assertEqual(result.start_logits.shape ,(self.batch_size, self.seq_length) ) self.parent.assertEqual(result.end_logits.shape ,(self.batch_size, self.seq_length) ) def __lowercase ( self : Optional[int] ): '''simple docstring''' _a : Optional[Any] = self.prepare_config_and_inputs() ( ( _a ), ( _a ), ( _a ), ( _a ), ( _a ), ( _a ), ( _a ), ) : Any = config_and_inputs _a : str = {'input_ids': input_ids, 'token_type_ids': token_type_ids, 'attention_mask': input_mask} return config, inputs_dict def __lowercase ( self : str ): '''simple docstring''' _a : int = TFMobileBertModelTest.TFMobileBertModelTester(self ) _a : Tuple = ConfigTester(self ,config_class=lowerCamelCase__ ,hidden_size=37 ) def __lowercase ( self : Dict ): '''simple docstring''' self.config_tester.run_common_tests() def __lowercase ( self : int ): '''simple docstring''' _a : Union[str, Any] = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_mobilebert_model(*lowerCamelCase__ ) def __lowercase ( self : int ): '''simple docstring''' _a : Union[str, Any] = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_mobilebert_for_masked_lm(*lowerCamelCase__ ) def __lowercase ( self : str ): '''simple docstring''' _a : int = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_mobilebert_for_multiple_choice(*lowerCamelCase__ ) def __lowercase ( self : str ): '''simple docstring''' _a : List[Any] = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_mobilebert_for_next_sequence_prediction(*lowerCamelCase__ ) def __lowercase ( self : Optional[Any] ): '''simple docstring''' _a : int = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_mobilebert_for_pretraining(*lowerCamelCase__ ) def __lowercase ( self : Any ): '''simple docstring''' _a : Dict = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_mobilebert_for_question_answering(*lowerCamelCase__ ) def __lowercase ( self : List[str] ): '''simple docstring''' _a : Optional[int] = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_mobilebert_for_sequence_classification(*lowerCamelCase__ ) def __lowercase ( self : Any ): '''simple docstring''' _a : str = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_mobilebert_for_token_classification(*lowerCamelCase__ ) @slow def __lowercase ( self : str ): '''simple docstring''' for model_name in ["google/mobilebert-uncased"]: _a : Dict = TFMobileBertModel.from_pretrained(lowerCamelCase__ ) self.assertIsNotNone(lowerCamelCase__ ) @require_tf class UpperCAmelCase__ ( unittest.TestCase ): """simple docstring""" @slow def __lowercase ( self : Dict ): '''simple docstring''' _a : Any = TFMobileBertForPreTraining.from_pretrained('google/mobilebert-uncased' ) _a : Optional[int] = tf.constant([[0, 1, 2, 3, 4, 5]] ) _a : Dict = model(lowerCamelCase__ )[0] _a : str = [1, 6, 3_0522] self.assertEqual(output.shape ,lowerCamelCase__ ) _a : List[str] = tf.constant( [ [ [-4.591_9547, -9.24_8295, -9.64_5256], [-6.730_6175, -6.44_0284, -6.605_2837], [-7.274_3506, -6.784_7915, -6.02_4673], ] ] ) tf.debugging.assert_near(output[:, :3, :3] ,lowerCamelCase__ ,atol=1E-4 )
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import unittest import numpy as np from transformers.testing_utils import require_flax, require_tf, require_torch from transformers.utils import ( expand_dims, flatten_dict, is_flax_available, is_tf_available, is_torch_available, reshape, squeeze, transpose, ) if is_flax_available(): import jax.numpy as jnp if is_tf_available(): import tensorflow as tf if is_torch_available(): import torch class __lowerCAmelCase ( unittest.TestCase ): """simple docstring""" def lowercase_ ( self ) -> Tuple: '''simple docstring''' __lowerCamelCase = { 'task_specific_params': { 'summarization': {'length_penalty': 1.0, 'max_length': 128, 'min_length': 12, 'num_beams': 4}, 'summarization_cnn': {'length_penalty': 2.0, 'max_length': 142, 'min_length': 56, 'num_beams': 4}, 'summarization_xsum': {'length_penalty': 1.0, 'max_length': 62, 'min_length': 11, 'num_beams': 6}, } } __lowerCamelCase = { 'task_specific_params.summarization.length_penalty': 1.0, 'task_specific_params.summarization.max_length': 128, 'task_specific_params.summarization.min_length': 12, 'task_specific_params.summarization.num_beams': 4, 'task_specific_params.summarization_cnn.length_penalty': 2.0, 'task_specific_params.summarization_cnn.max_length': 142, 'task_specific_params.summarization_cnn.min_length': 56, 'task_specific_params.summarization_cnn.num_beams': 4, 'task_specific_params.summarization_xsum.length_penalty': 1.0, 'task_specific_params.summarization_xsum.max_length': 62, 'task_specific_params.summarization_xsum.min_length': 11, 'task_specific_params.summarization_xsum.num_beams': 6, } self.assertEqual(flatten_dict(lowerCamelCase__ ) , lowerCamelCase__ ) def lowercase_ ( self ) -> Tuple: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) self.assertTrue(np.allclose(transpose(lowerCamelCase__ ) , x.transpose() ) ) __lowerCamelCase = np.random.randn(3 , 4 , 5 ) self.assertTrue(np.allclose(transpose(lowerCamelCase__ , axes=(1, 2, 0) ) , x.transpose((1, 2, 0) ) ) ) @require_torch def lowercase_ ( self ) -> int: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) __lowerCamelCase = torch.tensor(lowerCamelCase__ ) self.assertTrue(np.allclose(transpose(lowerCamelCase__ ) , transpose(lowerCamelCase__ ).numpy() ) ) __lowerCamelCase = np.random.randn(3 , 4 , 5 ) __lowerCamelCase = torch.tensor(lowerCamelCase__ ) self.assertTrue(np.allclose(transpose(lowerCamelCase__ , axes=(1, 2, 0) ) , transpose(lowerCamelCase__ , axes=(1, 2, 0) ).numpy() ) ) @require_tf def lowercase_ ( self ) -> Union[str, Any]: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) __lowerCamelCase = tf.constant(lowerCamelCase__ ) self.assertTrue(np.allclose(transpose(lowerCamelCase__ ) , transpose(lowerCamelCase__ ).numpy() ) ) __lowerCamelCase = np.random.randn(3 , 4 , 5 ) __lowerCamelCase = tf.constant(lowerCamelCase__ ) self.assertTrue(np.allclose(transpose(lowerCamelCase__ , axes=(1, 2, 0) ) , transpose(lowerCamelCase__ , axes=(1, 2, 0) ).numpy() ) ) @require_flax def lowercase_ ( self ) -> Optional[int]: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) __lowerCamelCase = jnp.array(lowerCamelCase__ ) self.assertTrue(np.allclose(transpose(lowerCamelCase__ ) , np.asarray(transpose(lowerCamelCase__ ) ) ) ) __lowerCamelCase = np.random.randn(3 , 4 , 5 ) __lowerCamelCase = jnp.array(lowerCamelCase__ ) self.assertTrue(np.allclose(transpose(lowerCamelCase__ , axes=(1, 2, 0) ) , np.asarray(transpose(lowerCamelCase__ , axes=(1, 2, 0) ) ) ) ) def lowercase_ ( self ) -> int: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) self.assertTrue(np.allclose(reshape(lowerCamelCase__ , (4, 3) ) , np.reshape(lowerCamelCase__ , (4, 3) ) ) ) __lowerCamelCase = np.random.randn(3 , 4 , 5 ) self.assertTrue(np.allclose(reshape(lowerCamelCase__ , (12, 5) ) , np.reshape(lowerCamelCase__ , (12, 5) ) ) ) @require_torch def lowercase_ ( self ) -> List[Any]: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) __lowerCamelCase = torch.tensor(lowerCamelCase__ ) self.assertTrue(np.allclose(reshape(lowerCamelCase__ , (4, 3) ) , reshape(lowerCamelCase__ , (4, 3) ).numpy() ) ) __lowerCamelCase = np.random.randn(3 , 4 , 5 ) __lowerCamelCase = torch.tensor(lowerCamelCase__ ) self.assertTrue(np.allclose(reshape(lowerCamelCase__ , (12, 5) ) , reshape(lowerCamelCase__ , (12, 5) ).numpy() ) ) @require_tf def lowercase_ ( self ) -> Optional[int]: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) __lowerCamelCase = tf.constant(lowerCamelCase__ ) self.assertTrue(np.allclose(reshape(lowerCamelCase__ , (4, 3) ) , reshape(lowerCamelCase__ , (4, 3) ).numpy() ) ) __lowerCamelCase = np.random.randn(3 , 4 , 5 ) __lowerCamelCase = tf.constant(lowerCamelCase__ ) self.assertTrue(np.allclose(reshape(lowerCamelCase__ , (12, 5) ) , reshape(lowerCamelCase__ , (12, 5) ).numpy() ) ) @require_flax def lowercase_ ( self ) -> Tuple: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) __lowerCamelCase = jnp.array(lowerCamelCase__ ) self.assertTrue(np.allclose(reshape(lowerCamelCase__ , (4, 3) ) , np.asarray(reshape(lowerCamelCase__ , (4, 3) ) ) ) ) __lowerCamelCase = np.random.randn(3 , 4 , 5 ) __lowerCamelCase = jnp.array(lowerCamelCase__ ) self.assertTrue(np.allclose(reshape(lowerCamelCase__ , (12, 5) ) , np.asarray(reshape(lowerCamelCase__ , (12, 5) ) ) ) ) def lowercase_ ( self ) -> int: '''simple docstring''' __lowerCamelCase = np.random.randn(1 , 3 , 4 ) self.assertTrue(np.allclose(squeeze(lowerCamelCase__ ) , np.squeeze(lowerCamelCase__ ) ) ) __lowerCamelCase = np.random.randn(1 , 4 , 1 , 5 ) self.assertTrue(np.allclose(squeeze(lowerCamelCase__ , axis=2 ) , np.squeeze(lowerCamelCase__ , axis=2 ) ) ) @require_torch def lowercase_ ( self ) -> int: '''simple docstring''' __lowerCamelCase = np.random.randn(1 , 3 , 4 ) __lowerCamelCase = torch.tensor(lowerCamelCase__ ) self.assertTrue(np.allclose(squeeze(lowerCamelCase__ ) , squeeze(lowerCamelCase__ ).numpy() ) ) __lowerCamelCase = np.random.randn(1 , 4 , 1 , 5 ) __lowerCamelCase = torch.tensor(lowerCamelCase__ ) self.assertTrue(np.allclose(squeeze(lowerCamelCase__ , axis=2 ) , squeeze(lowerCamelCase__ , axis=2 ).numpy() ) ) @require_tf def lowercase_ ( self ) -> Union[str, Any]: '''simple docstring''' __lowerCamelCase = np.random.randn(1 , 3 , 4 ) __lowerCamelCase = tf.constant(lowerCamelCase__ ) self.assertTrue(np.allclose(squeeze(lowerCamelCase__ ) , squeeze(lowerCamelCase__ ).numpy() ) ) __lowerCamelCase = np.random.randn(1 , 4 , 1 , 5 ) __lowerCamelCase = tf.constant(lowerCamelCase__ ) self.assertTrue(np.allclose(squeeze(lowerCamelCase__ , axis=2 ) , squeeze(lowerCamelCase__ , axis=2 ).numpy() ) ) @require_flax def lowercase_ ( self ) -> List[str]: '''simple docstring''' __lowerCamelCase = np.random.randn(1 , 3 , 4 ) __lowerCamelCase = jnp.array(lowerCamelCase__ ) self.assertTrue(np.allclose(squeeze(lowerCamelCase__ ) , np.asarray(squeeze(lowerCamelCase__ ) ) ) ) __lowerCamelCase = np.random.randn(1 , 4 , 1 , 5 ) __lowerCamelCase = jnp.array(lowerCamelCase__ ) self.assertTrue(np.allclose(squeeze(lowerCamelCase__ , axis=2 ) , np.asarray(squeeze(lowerCamelCase__ , axis=2 ) ) ) ) def lowercase_ ( self ) -> int: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) self.assertTrue(np.allclose(expand_dims(lowerCamelCase__ , axis=1 ) , np.expand_dims(lowerCamelCase__ , axis=1 ) ) ) @require_torch def lowercase_ ( self ) -> Any: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) __lowerCamelCase = torch.tensor(lowerCamelCase__ ) self.assertTrue(np.allclose(expand_dims(lowerCamelCase__ , axis=1 ) , expand_dims(lowerCamelCase__ , axis=1 ).numpy() ) ) @require_tf def lowercase_ ( self ) -> Any: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) __lowerCamelCase = tf.constant(lowerCamelCase__ ) self.assertTrue(np.allclose(expand_dims(lowerCamelCase__ , axis=1 ) , expand_dims(lowerCamelCase__ , axis=1 ).numpy() ) ) @require_flax def lowercase_ ( self ) -> List[Any]: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) __lowerCamelCase = jnp.array(lowerCamelCase__ ) self.assertTrue(np.allclose(expand_dims(lowerCamelCase__ , axis=1 ) , np.asarray(expand_dims(lowerCamelCase__ , axis=1 ) ) ) )
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import json import os from pathlib import Path from shutil import copyfile from typing import Any, Dict, List, Optional, Tuple, Union import sentencepiece from ...tokenization_utils import PreTrainedTokenizer from ...utils import logging UpperCAmelCase = logging.get_logger(__name__) UpperCAmelCase = '''▁''' UpperCAmelCase = { '''vocab_file''': '''vocab.json''', '''spm_file''': '''sentencepiece.bpe.model''', } UpperCAmelCase = { '''vocab_file''': { '''facebook/s2t-small-librispeech-asr''': ( '''https://huggingface.co/facebook/s2t-small-librispeech-asr/resolve/main/vocab.json''' ), }, '''spm_file''': { '''facebook/s2t-small-librispeech-asr''': ( '''https://huggingface.co/facebook/s2t-small-librispeech-asr/resolve/main/sentencepiece.bpe.model''' ) }, } UpperCAmelCase = { '''facebook/s2t-small-librispeech-asr''': 1024, } UpperCAmelCase = ['''pt''', '''fr''', '''ru''', '''nl''', '''ro''', '''it''', '''es''', '''de'''] UpperCAmelCase = {'''mustc''': MUSTC_LANGS} class A_ ( __lowerCamelCase ): '''simple docstring''' _UpperCamelCase : Dict = VOCAB_FILES_NAMES _UpperCamelCase : Union[str, Any] = PRETRAINED_VOCAB_FILES_MAP _UpperCamelCase : Optional[int] = MAX_MODEL_INPUT_SIZES _UpperCamelCase : str = ["""input_ids""", """attention_mask"""] _UpperCamelCase : str = [] def __init__( self , snake_case , snake_case , snake_case="<s>" , snake_case="</s>" , snake_case="<pad>" , snake_case="<unk>" , snake_case=False , snake_case=False , snake_case=None , snake_case=None , snake_case = None , **snake_case , ): lowercase = {} if sp_model_kwargs is None else sp_model_kwargs super().__init__( bos_token=lowerCamelCase__ , eos_token=lowerCamelCase__ , unk_token=lowerCamelCase__ , pad_token=lowerCamelCase__ , do_upper_case=lowerCamelCase__ , do_lower_case=lowerCamelCase__ , tgt_lang=lowerCamelCase__ , lang_codes=lowerCamelCase__ , sp_model_kwargs=self.sp_model_kwargs , **lowerCamelCase__ , ) lowercase = do_upper_case lowercase = do_lower_case lowercase = load_json(lowerCamelCase__ ) lowercase = {v: k for k, v in self.encoder.items()} lowercase = spm_file lowercase = load_spm(lowerCamelCase__ , self.sp_model_kwargs ) if lang_codes is not None: lowercase = lang_codes lowercase = LANGUAGES[lang_codes] lowercase = [F'''<lang:{lang}>''' for lang in self.langs] lowercase = {lang: self.sp_model.PieceToId(F'''<lang:{lang}>''' ) for lang in self.langs} lowercase = self.lang_tokens lowercase = tgt_lang if tgt_lang is not None else self.langs[0] self.set_tgt_lang_special_tokens(self._tgt_lang ) else: lowercase = {} @property def SCREAMING_SNAKE_CASE__ ( self ): return len(self.encoder ) @property def SCREAMING_SNAKE_CASE__ ( self ): return self._tgt_lang @tgt_lang.setter def SCREAMING_SNAKE_CASE__ ( self , snake_case ): lowercase = new_tgt_lang self.set_tgt_lang_special_tokens(lowerCamelCase__ ) def SCREAMING_SNAKE_CASE__ ( self , snake_case ): lowercase = self.lang_code_to_id[tgt_lang] lowercase = [lang_code_id] def SCREAMING_SNAKE_CASE__ ( self , snake_case ): return self.sp_model.encode(lowerCamelCase__ , out_type=lowerCamelCase__ ) def SCREAMING_SNAKE_CASE__ ( self , snake_case ): return self.encoder.get(lowerCamelCase__ , self.encoder[self.unk_token] ) def SCREAMING_SNAKE_CASE__ ( self , snake_case ): return self.decoder.get(lowerCamelCase__ , self.unk_token ) def SCREAMING_SNAKE_CASE__ ( self , snake_case ): lowercase = [] lowercase = '' for token in tokens: # make sure that special tokens are not decoded using sentencepiece model if token in self.all_special_tokens: lowercase = self.sp_model.decode(lowerCamelCase__ ) out_string += (decoded.upper() if self.do_upper_case else decoded) + token + " " lowercase = [] else: current_sub_tokens.append(lowerCamelCase__ ) lowercase = self.sp_model.decode(lowerCamelCase__ ) out_string += decoded.upper() if self.do_upper_case else decoded return out_string.strip() def SCREAMING_SNAKE_CASE__ ( self , snake_case , snake_case=None ): if token_ids_a is None: return self.prefix_tokens + token_ids_a + [self.eos_token_id] # We don't expect to process pairs, but leave the pair logic for API consistency return self.prefix_tokens + token_ids_a + token_ids_a + [self.eos_token_id] def SCREAMING_SNAKE_CASE__ ( self , snake_case , snake_case = None , snake_case = False ): if already_has_special_tokens: return super().get_special_tokens_mask( token_ids_a=lowerCamelCase__ , token_ids_a=lowerCamelCase__ , already_has_special_tokens=lowerCamelCase__ ) lowercase = [1] * len(self.prefix_tokens ) lowercase = [1] if token_ids_a is None: return prefix_ones + ([0] * len(lowerCamelCase__ )) + suffix_ones return prefix_ones + ([0] * len(lowerCamelCase__ )) + ([0] * len(lowerCamelCase__ )) + suffix_ones def SCREAMING_SNAKE_CASE__ ( self ): lowercase = self.encoder.copy() vocab.update(self.added_tokens_encoder ) return vocab def __getstate__( self ): lowercase = self.__dict__.copy() lowercase = None return state def __setstate__( self , snake_case ): lowercase = d # for backward compatibility if not hasattr(self , 'sp_model_kwargs' ): lowercase = {} lowercase = load_spm(self.spm_file , self.sp_model_kwargs ) def SCREAMING_SNAKE_CASE__ ( self , snake_case , snake_case = None ): lowercase = Path(lowerCamelCase__ ) assert save_dir.is_dir(), F'''{save_directory} should be a directory''' lowercase = save_dir / ( (filename_prefix + '-' if filename_prefix else '') + self.vocab_files_names['vocab_file'] ) lowercase = save_dir / ( (filename_prefix + '-' if filename_prefix else '') + self.vocab_files_names['spm_file'] ) save_json(self.encoder , lowerCamelCase__ ) if os.path.abspath(self.spm_file ) != os.path.abspath(lowerCamelCase__ ) and os.path.isfile(self.spm_file ): copyfile(self.spm_file , lowerCamelCase__ ) elif not os.path.isfile(self.spm_file ): with open(lowerCamelCase__ , 'wb' ) as fi: lowercase = self.sp_model.serialized_model_proto() fi.write(lowerCamelCase__ ) return (str(lowerCamelCase__ ), str(lowerCamelCase__ )) def UpperCAmelCase_ ( __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE ): lowercase = sentencepiece.SentencePieceProcessor(**UpperCamelCase__ ) spm.Load(str(UpperCamelCase__ ) ) return spm def UpperCAmelCase_ ( __SCREAMING_SNAKE_CASE ): with open(UpperCamelCase__ , 'r' ) as f: return json.load(UpperCamelCase__ ) def UpperCAmelCase_ ( __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE ): with open(UpperCamelCase__ , 'w' ) as f: json.dump(UpperCamelCase__ , UpperCamelCase__ , indent=2 )
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import copy import inspect import unittest import numpy as np from huggingface_hub import hf_hub_download from transformers import TimesformerConfig from transformers.models.auto import get_values 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, floats_tensor, ids_tensor from ...test_pipeline_mixin import PipelineTesterMixin if is_torch_available(): import torch from torch import nn from transformers import ( MODEL_FOR_VIDEO_CLASSIFICATION_MAPPING, TimesformerForVideoClassification, TimesformerModel, ) from transformers.models.timesformer.modeling_timesformer import TIMESFORMER_PRETRAINED_MODEL_ARCHIVE_LIST if is_vision_available(): from transformers import VideoMAEImageProcessor class __lowerCAmelCase : """simple docstring""" def __init__( self , lowerCamelCase__ , lowerCamelCase__=13 , lowerCamelCase__=10 , lowerCamelCase__=3 , lowerCamelCase__=2 , lowerCamelCase__=2 , lowerCamelCase__=True , lowerCamelCase__=True , lowerCamelCase__=32 , lowerCamelCase__=5 , lowerCamelCase__=4 , lowerCamelCase__=37 , lowerCamelCase__="gelu" , lowerCamelCase__=0.1 , lowerCamelCase__=0.1 , lowerCamelCase__=10 , lowerCamelCase__=0.02 , lowerCamelCase__="divided_space_time" , lowerCamelCase__=None , ) -> Any: '''simple docstring''' __lowerCamelCase = parent __lowerCamelCase = batch_size __lowerCamelCase = image_size __lowerCamelCase = num_channels __lowerCamelCase = patch_size __lowerCamelCase = num_frames __lowerCamelCase = is_training __lowerCamelCase = use_labels __lowerCamelCase = hidden_size __lowerCamelCase = num_hidden_layers __lowerCamelCase = num_attention_heads __lowerCamelCase = intermediate_size __lowerCamelCase = hidden_act __lowerCamelCase = hidden_dropout_prob __lowerCamelCase = attention_probs_dropout_prob __lowerCamelCase = attention_type __lowerCamelCase = initializer_range __lowerCamelCase = scope __lowerCamelCase = num_labels # in TimeSformer, the number of spatial tokens equals num_frames * num_patches per frame + 1 CLS token __lowerCamelCase = (image_size // patch_size) ** 2 __lowerCamelCase = (num_frames) * self.num_patches_per_frame + 1 def lowercase_ ( self ) -> Optional[int]: '''simple docstring''' __lowerCamelCase = floats_tensor( [self.batch_size, self.num_frames, self.num_channels, self.image_size, self.image_size] ) __lowerCamelCase = None if self.use_labels: __lowerCamelCase = ids_tensor([self.batch_size] , self.num_labels ) __lowerCamelCase = self.get_config() return config, pixel_values, labels def lowercase_ ( self ) -> Union[str, Any]: '''simple docstring''' __lowerCamelCase = TimesformerConfig( image_size=self.image_size , patch_size=self.patch_size , num_channels=self.num_channels , num_frames=self.num_frames , 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 , initializer_range=self.initializer_range , attention_type=self.attention_type , ) __lowerCamelCase = self.num_labels return config def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> Tuple: '''simple docstring''' __lowerCamelCase = TimesformerModel(config=lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model(lowerCamelCase__ ) self.parent.assertEqual(result.last_hidden_state.shape , (self.batch_size, self.seq_length, self.hidden_size) ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> Union[str, Any]: '''simple docstring''' __lowerCamelCase = TimesformerForVideoClassification(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model(lowerCamelCase__ ) # verify the logits shape __lowerCamelCase = torch.Size((self.batch_size, self.num_labels) ) self.parent.assertEqual(result.logits.shape , lowerCamelCase__ ) def lowercase_ ( self ) -> Tuple: '''simple docstring''' __lowerCamelCase = self.prepare_config_and_inputs() __lowerCamelCase , __lowerCamelCase , __lowerCamelCase = config_and_inputs __lowerCamelCase = {'pixel_values': pixel_values} return config, inputs_dict @require_torch class __lowerCAmelCase ( __magic_name__ , __magic_name__ , unittest.TestCase ): """simple docstring""" snake_case_ = (TimesformerModel, TimesformerForVideoClassification) if is_torch_available() else () snake_case_ = ( {'''feature-extraction''': TimesformerModel, '''video-classification''': TimesformerForVideoClassification} if is_torch_available() else {} ) snake_case_ = False snake_case_ = False snake_case_ = False snake_case_ = False def lowercase_ ( self ) -> List[str]: '''simple docstring''' __lowerCamelCase = TimesformerModelTester(self ) __lowerCamelCase = ConfigTester( self , config_class=lowerCamelCase__ , has_text_modality=lowerCamelCase__ , hidden_size=37 ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__=False ) -> int: '''simple docstring''' __lowerCamelCase = copy.deepcopy(lowerCamelCase__ ) if return_labels: if model_class in get_values(lowerCamelCase__ ): __lowerCamelCase = torch.zeros( self.model_tester.batch_size , dtype=torch.long , device=lowerCamelCase__ ) return inputs_dict def lowercase_ ( self ) -> Optional[int]: '''simple docstring''' self.config_tester.run_common_tests() @unittest.skip(reason='TimeSformer does not use inputs_embeds' ) def lowercase_ ( self ) -> List[str]: '''simple docstring''' pass def lowercase_ ( self ) -> Union[str, Any]: '''simple docstring''' __lowerCamelCase , __lowerCamelCase = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: __lowerCamelCase = model_class(lowerCamelCase__ ) self.assertIsInstance(model.get_input_embeddings() , (nn.Module) ) __lowerCamelCase = model.get_output_embeddings() self.assertTrue(x is None or isinstance(lowerCamelCase__ , nn.Linear ) ) def lowercase_ ( self ) -> List[str]: '''simple docstring''' __lowerCamelCase , __lowerCamelCase = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: __lowerCamelCase = model_class(lowerCamelCase__ ) __lowerCamelCase = inspect.signature(model.forward ) # signature.parameters is an OrderedDict => so arg_names order is deterministic __lowerCamelCase = [*signature.parameters.keys()] __lowerCamelCase = ['pixel_values'] self.assertListEqual(arg_names[:1] , lowerCamelCase__ ) def lowercase_ ( self ) -> Union[str, Any]: '''simple docstring''' __lowerCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_model(*lowerCamelCase__ ) def lowercase_ ( self ) -> str: '''simple docstring''' __lowerCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_for_video_classification(*lowerCamelCase__ ) @slow def lowercase_ ( self ) -> Dict: '''simple docstring''' for model_name in TIMESFORMER_PRETRAINED_MODEL_ARCHIVE_LIST[:1]: __lowerCamelCase = TimesformerModel.from_pretrained(lowerCamelCase__ ) self.assertIsNotNone(lowerCamelCase__ ) def lowercase_ ( self ) -> List[Any]: '''simple docstring''' if not self.has_attentions: pass else: __lowerCamelCase , __lowerCamelCase = self.model_tester.prepare_config_and_inputs_for_common() __lowerCamelCase = True for model_class in self.all_model_classes: __lowerCamelCase = self.model_tester.seq_length __lowerCamelCase = self.model_tester.num_frames __lowerCamelCase = True __lowerCamelCase = False __lowerCamelCase = True __lowerCamelCase = model_class(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() with torch.no_grad(): __lowerCamelCase = model(**self._prepare_for_class(lowerCamelCase__ , lowerCamelCase__ ) ) __lowerCamelCase = outputs.attentions self.assertEqual(len(lowerCamelCase__ ) , self.model_tester.num_hidden_layers ) # check that output_attentions also work using config del inputs_dict["output_attentions"] __lowerCamelCase = True __lowerCamelCase = model_class(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() with torch.no_grad(): __lowerCamelCase = model(**self._prepare_for_class(lowerCamelCase__ , lowerCamelCase__ ) ) __lowerCamelCase = outputs.attentions self.assertEqual(len(lowerCamelCase__ ) , self.model_tester.num_hidden_layers ) # attentions has shape (batch_size x num_frames) x num_heads x (num_patches per frame + 1) x (num_patches per frame + 1) self.assertListEqual( list(attentions[0].shape[-3:] ) , [self.model_tester.num_attention_heads, seq_len // num_frames + 1, seq_len // num_frames + 1] , ) __lowerCamelCase = len(lowerCamelCase__ ) # Check attention is always last and order is fine __lowerCamelCase = True __lowerCamelCase = True __lowerCamelCase = model_class(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() with torch.no_grad(): __lowerCamelCase = model(**self._prepare_for_class(lowerCamelCase__ , lowerCamelCase__ ) ) self.assertEqual(out_len + 1 , len(lowerCamelCase__ ) ) __lowerCamelCase = outputs.attentions self.assertEqual(len(lowerCamelCase__ ) , self.model_tester.num_hidden_layers ) # attentions has shape (batch_size x num_frames) x num_heads x (num_patches per frame + 1) x (num_patches per frame + 1) self.assertListEqual( list(self_attentions[0].shape[-3:] ) , [self.model_tester.num_attention_heads, seq_len // num_frames + 1, seq_len // num_frames + 1] , ) def lowercase_ ( self ) -> Tuple: '''simple docstring''' def check_hidden_states_output(lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ): __lowerCamelCase = model_class(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() with torch.no_grad(): __lowerCamelCase = model(**self._prepare_for_class(lowerCamelCase__ , lowerCamelCase__ ) ) __lowerCamelCase = outputs.hidden_states __lowerCamelCase = self.model_tester.num_hidden_layers + 1 self.assertEqual(len(lowerCamelCase__ ) , lowerCamelCase__ ) __lowerCamelCase = self.model_tester.seq_length self.assertListEqual( list(hidden_states[0].shape[-2:] ) , [seq_length, self.model_tester.hidden_size] , ) __lowerCamelCase , __lowerCamelCase = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: __lowerCamelCase = True check_hidden_states_output(lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) # check that output_hidden_states also work using config del inputs_dict["output_hidden_states"] __lowerCamelCase = True check_hidden_states_output(lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) def lowerCamelCase_ ( ) -> Any: """simple docstring""" __lowerCamelCase = hf_hub_download( repo_id='hf-internal-testing/spaghetti-video' , filename='eating_spaghetti.npy' , repo_type='dataset' ) __lowerCamelCase = np.load(UpperCamelCase__ ) return list(UpperCamelCase__ ) @require_torch @require_vision class __lowerCAmelCase ( unittest.TestCase ): """simple docstring""" @cached_property def lowercase_ ( self ) -> List[Any]: '''simple docstring''' # logits were tested with a different mean and std, so we use the same here return ( VideoMAEImageProcessor(image_mean=[0.5, 0.5, 0.5] , image_std=[0.5, 0.5, 0.5] ) if is_vision_available() else None ) @slow def lowercase_ ( self ) -> List[str]: '''simple docstring''' __lowerCamelCase = TimesformerForVideoClassification.from_pretrained('facebook/timesformer-base-finetuned-k400' ).to( lowerCamelCase__ ) __lowerCamelCase = self.default_image_processor __lowerCamelCase = prepare_video() __lowerCamelCase = image_processor(video[:8] , return_tensors='pt' ).to(lowerCamelCase__ ) # forward pass with torch.no_grad(): __lowerCamelCase = model(**lowerCamelCase__ ) # verify the logits __lowerCamelCase = torch.Size((1, 400) ) self.assertEqual(outputs.logits.shape , lowerCamelCase__ ) __lowerCamelCase = torch.tensor([-0.30_16, -0.77_13, -0.42_05] ).to(lowerCamelCase__ ) self.assertTrue(torch.allclose(outputs.logits[0, :3] , lowerCamelCase__ , atol=1e-4 ) )
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import datasets from .nmt_bleu import compute_bleu # From: https://github.com/tensorflow/nmt/blob/master/nmt/scripts/bleu.py _lowerCAmelCase : Optional[Any] = "\\n@INPROCEEDINGS{Papineni02bleu:a,\n author = {Kishore Papineni and Salim Roukos and Todd Ward and Wei-jing Zhu},\n title = {BLEU: a Method for Automatic Evaluation of Machine Translation},\n booktitle = {},\n year = {2002},\n pages = {311--318}\n}\n@inproceedings{lin-och-2004-orange,\n title = \"{ORANGE}: a Method for Evaluating Automatic Evaluation Metrics for Machine Translation\",\n author = \"Lin, Chin-Yew and\n Och, Franz Josef\",\n booktitle = \"{COLING} 2004: Proceedings of the 20th International Conference on Computational Linguistics\",\n month = \"aug 23{--}aug 27\",\n year = \"2004\",\n address = \"Geneva, Switzerland\",\n publisher = \"COLING\",\n url = \"https://www.aclweb.org/anthology/C04-1072\",\n pages = \"501--507\",\n}\n" _lowerCAmelCase : Optional[Any] = "\\nBLEU (bilingual evaluation understudy) is an algorithm for evaluating the quality of text which has been machine-translated from one natural language to another.\nQuality is considered to be the correspondence between a machine's output and that of a human: \"the closer a machine translation is to a professional human translation,\nthe better it is\" – this is the central idea behind BLEU. BLEU was one of the first metrics to claim a high correlation with human judgements of quality, and\nremains one of the most popular automated and inexpensive metrics.\n\nScores are calculated for individual translated segments—generally sentences—by comparing them with a set of good quality reference translations.\nThose scores are then averaged over the whole corpus to reach an estimate of the translation's overall quality. Intelligibility or grammatical correctness\nare not taken into account[citation needed].\n\nBLEU's output is always a number between 0 and 1. This value indicates how similar the candidate text is to the reference texts, with values closer to 1\nrepresenting more similar texts. Few human translations will attain a score of 1, since this would indicate that the candidate is identical to one of the\nreference translations. For this reason, it is not necessary to attain a score of 1. Because there are more opportunities to match, adding additional\nreference translations will increase the BLEU score.\n" _lowerCAmelCase : Optional[Any] = "\nComputes BLEU score of translated segments against one or more references.\nArgs:\n predictions: list of translations to score.\n Each translation should be tokenized into a list of tokens.\n references: list of lists of references for each translation.\n Each reference should be tokenized into a list of tokens.\n max_order: Maximum n-gram order to use when computing BLEU score.\n smooth: Whether or not to apply Lin et al. 2004 smoothing.\nReturns:\n 'bleu': bleu score,\n 'precisions': geometric mean of n-gram precisions,\n 'brevity_penalty': brevity penalty,\n 'length_ratio': ratio of lengths,\n 'translation_length': translation_length,\n 'reference_length': reference_length\nExamples:\n\n >>> predictions = [\n ... [\"hello\", \"there\", \"general\", \"kenobi\"], # tokenized prediction of the first sample\n ... [\"foo\", \"bar\", \"foobar\"] # tokenized prediction of the second sample\n ... ]\n >>> references = [\n ... [[\"hello\", \"there\", \"general\", \"kenobi\"], [\"hello\", \"there\", \"!\"]], # tokenized references for the first sample (2 references)\n ... [[\"foo\", \"bar\", \"foobar\"]] # tokenized references for the second sample (1 reference)\n ... ]\n >>> bleu = datasets.load_metric(\"bleu\")\n >>> results = bleu.compute(predictions=predictions, references=references)\n >>> print(results[\"bleu\"])\n 1.0\n" @datasets.utils.file_utils.add_start_docstrings(_DESCRIPTION , _KWARGS_DESCRIPTION ) class __magic_name__ ( datasets.Metric ): def __magic_name__ ( self ) -> List[Any]: '''simple docstring''' return datasets.MetricInfo( description=_DESCRIPTION , citation=_CITATION , inputs_description=_KWARGS_DESCRIPTION , features=datasets.Features( { 'predictions': datasets.Sequence(datasets.Value('string' , id='token' ) , id='sequence' ), 'references': datasets.Sequence( datasets.Sequence(datasets.Value('string' , id='token' ) , id='sequence' ) , id='references' ), } ) , codebase_urls=['https://github.com/tensorflow/nmt/blob/master/nmt/scripts/bleu.py'] , reference_urls=[ 'https://en.wikipedia.org/wiki/BLEU', 'https://towardsdatascience.com/evaluating-text-output-in-nlp-bleu-at-your-own-risk-e8609665a213', ] , ) def __magic_name__ ( self , __snake_case , __snake_case , __snake_case=4 , __snake_case=False ) -> Any: '''simple docstring''' __a =compute_bleu( reference_corpus=lowerCamelCase__ , translation_corpus=lowerCamelCase__ , max_order=lowerCamelCase__ , smooth=lowerCamelCase__ ) ((__a) , (__a) , (__a) , (__a) , (__a) , (__a)) =score return { "bleu": bleu, "precisions": precisions, "brevity_penalty": bp, "length_ratio": ratio, "translation_length": translation_length, "reference_length": reference_length, }
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import json from typing import TYPE_CHECKING, List, Optional, Tuple from tokenizers import pre_tokenizers from ...tokenization_utils_fast import PreTrainedTokenizerFast from ...utils import logging if TYPE_CHECKING: from transformers.pipelines.conversational import Conversation __A = logging.get_logger(__name__) __A = {"vocab_file": "vocab.json", "merges_file": "merges.txt", "tokenizer_file": "tokenizer.json"} __A = { "tokenizer_file": { "EleutherAI/gpt-neox-20b": "https://huggingface.co/EleutherAI/gpt-neox-20b/resolve/main/tokenizer.json", }, } __A = { "gpt-neox-20b": 20_48, } class __lowerCAmelCase ( __magic_name__ ): """simple docstring""" snake_case_ = VOCAB_FILES_NAMES snake_case_ = PRETRAINED_VOCAB_FILES_MAP snake_case_ = PRETRAINED_POSITIONAL_EMBEDDINGS_SIZES snake_case_ = ['''input_ids''', '''attention_mask'''] def __init__( self , lowerCamelCase__=None , lowerCamelCase__=None , lowerCamelCase__=None , lowerCamelCase__="<|endoftext|>" , lowerCamelCase__="<|endoftext|>" , lowerCamelCase__="<|endoftext|>" , lowerCamelCase__=False , **lowerCamelCase__ , ) -> int: '''simple docstring''' super().__init__( lowerCamelCase__ , lowerCamelCase__ , tokenizer_file=lowerCamelCase__ , unk_token=lowerCamelCase__ , bos_token=lowerCamelCase__ , eos_token=lowerCamelCase__ , add_prefix_space=lowerCamelCase__ , **lowerCamelCase__ , ) __lowerCamelCase = json.loads(self.backend_tokenizer.pre_tokenizer.__getstate__() ) if pre_tok_state.get('add_prefix_space' , lowerCamelCase__ ) != add_prefix_space: __lowerCamelCase = getattr(lowerCamelCase__ , pre_tok_state.pop('type' ) ) __lowerCamelCase = add_prefix_space __lowerCamelCase = pre_tok_class(**lowerCamelCase__ ) __lowerCamelCase = add_prefix_space def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ = None ) -> Tuple[str]: '''simple docstring''' __lowerCamelCase = self._tokenizer.model.save(lowerCamelCase__ , name=lowerCamelCase__ ) return tuple(lowerCamelCase__ ) def lowercase_ ( self , lowerCamelCase__ ) -> List[int]: '''simple docstring''' __lowerCamelCase = [] for is_user, text in conversation.iter_texts(): input_ids.extend(self.encode(lowerCamelCase__ , add_special_tokens=lowerCamelCase__ ) + [self.eos_token_id] ) if len(lowerCamelCase__ ) > self.model_max_length: __lowerCamelCase = input_ids[-self.model_max_length :] return input_ids
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"""simple docstring""" import baseaa def _A ( lowercase ): """simple docstring""" return baseaa.aaaencode(string.encode('''utf-8''' ) ) def _A ( lowercase ): """simple docstring""" return baseaa.aaadecode(UpperCamelCase__ ).decode('''utf-8''' ) if __name__ == "__main__": import doctest doctest.testmod()
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from ..utils import DummyObject, requires_backends class __lowerCAmelCase ( metaclass=__magic_name__ ): """simple docstring""" snake_case_ = ['''onnx'''] def __init__( self , *lowerCamelCase__ , **lowerCamelCase__ ) -> Optional[Any]: '''simple docstring''' requires_backends(self , ['onnx'] ) @classmethod def lowercase_ ( cls , *lowerCamelCase__ , **lowerCamelCase__ ) -> Dict: '''simple docstring''' requires_backends(cls , ['onnx'] ) @classmethod def lowercase_ ( cls , *lowerCamelCase__ , **lowerCamelCase__ ) -> List[str]: '''simple docstring''' requires_backends(cls , ['onnx'] )
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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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import itertools import os import random import tempfile import unittest import numpy as np from datasets import load_dataset from transformers import is_speech_available from transformers.testing_utils import check_json_file_has_correct_format, require_torch, require_torchaudio from transformers.utils.import_utils import is_torch_available from ...test_sequence_feature_extraction_common import SequenceFeatureExtractionTestMixin if is_speech_available(): from transformers import WhisperFeatureExtractor if is_torch_available(): import torch __A = random.Random() def lowerCamelCase_ ( UpperCamelCase__ : Optional[int] , UpperCamelCase__ : List[str]=1.0 , UpperCamelCase__ : Union[str, Any]=None , UpperCamelCase__ : Optional[int]=None ) -> Optional[Any]: """simple docstring""" if rng is None: __lowerCamelCase = global_rng __lowerCamelCase = [] for batch_idx in range(shape[0] ): values.append([] ) for _ in range(shape[1] ): values[-1].append(rng.random() * scale ) return values @require_torch @require_torchaudio class __lowerCAmelCase ( unittest.TestCase ): """simple docstring""" def __init__( self , lowerCamelCase__ , lowerCamelCase__=7 , lowerCamelCase__=400 , lowerCamelCase__=2_000 , lowerCamelCase__=10 , lowerCamelCase__=160 , lowerCamelCase__=8 , lowerCamelCase__=0.0 , lowerCamelCase__=4_000 , lowerCamelCase__=False , lowerCamelCase__=True , ) -> List[str]: '''simple docstring''' __lowerCamelCase = parent __lowerCamelCase = batch_size __lowerCamelCase = min_seq_length __lowerCamelCase = max_seq_length __lowerCamelCase = (self.max_seq_length - self.min_seq_length) // (self.batch_size - 1) __lowerCamelCase = padding_value __lowerCamelCase = sampling_rate __lowerCamelCase = return_attention_mask __lowerCamelCase = do_normalize __lowerCamelCase = feature_size __lowerCamelCase = chunk_length __lowerCamelCase = hop_length def lowercase_ ( self ) -> Any: '''simple docstring''' return { "feature_size": self.feature_size, "hop_length": self.hop_length, "chunk_length": self.chunk_length, "padding_value": self.padding_value, "sampling_rate": self.sampling_rate, "return_attention_mask": self.return_attention_mask, "do_normalize": self.do_normalize, } def lowercase_ ( self , lowerCamelCase__=False , lowerCamelCase__=False ) -> Optional[int]: '''simple docstring''' def _flatten(lowerCamelCase__ ): return list(itertools.chain(*lowerCamelCase__ ) ) if equal_length: __lowerCamelCase = [floats_list((self.max_seq_length, self.feature_size) ) for _ in range(self.batch_size )] else: # make sure that inputs increase in size __lowerCamelCase = [ floats_list((x, self.feature_size) ) for x in range(self.min_seq_length , self.max_seq_length , self.seq_length_diff ) ] if numpify: __lowerCamelCase = [np.asarray(lowerCamelCase__ ) for x in speech_inputs] return speech_inputs @require_torch @require_torchaudio class __lowerCAmelCase ( __magic_name__ , unittest.TestCase ): """simple docstring""" snake_case_ = WhisperFeatureExtractor if is_speech_available() else None def lowercase_ ( self ) -> Any: '''simple docstring''' __lowerCamelCase = WhisperFeatureExtractionTester(self ) def lowercase_ ( self ) -> List[str]: '''simple docstring''' __lowerCamelCase = self.feature_extraction_class(**self.feat_extract_dict ) with tempfile.TemporaryDirectory() as tmpdirname: __lowerCamelCase = feat_extract_first.save_pretrained(lowerCamelCase__ )[0] check_json_file_has_correct_format(lowerCamelCase__ ) __lowerCamelCase = self.feature_extraction_class.from_pretrained(lowerCamelCase__ ) __lowerCamelCase = feat_extract_first.to_dict() __lowerCamelCase = feat_extract_second.to_dict() __lowerCamelCase = feat_extract_first.mel_filters __lowerCamelCase = feat_extract_second.mel_filters self.assertTrue(np.allclose(lowerCamelCase__ , lowerCamelCase__ ) ) self.assertEqual(lowerCamelCase__ , lowerCamelCase__ ) def lowercase_ ( self ) -> Dict: '''simple docstring''' __lowerCamelCase = self.feature_extraction_class(**self.feat_extract_dict ) with tempfile.TemporaryDirectory() as tmpdirname: __lowerCamelCase = os.path.join(lowerCamelCase__ , 'feat_extract.json' ) feat_extract_first.to_json_file(lowerCamelCase__ ) __lowerCamelCase = self.feature_extraction_class.from_json_file(lowerCamelCase__ ) __lowerCamelCase = feat_extract_first.to_dict() __lowerCamelCase = feat_extract_second.to_dict() __lowerCamelCase = feat_extract_first.mel_filters __lowerCamelCase = feat_extract_second.mel_filters self.assertTrue(np.allclose(lowerCamelCase__ , lowerCamelCase__ ) ) self.assertEqual(lowerCamelCase__ , lowerCamelCase__ ) def lowercase_ ( self ) -> Dict: '''simple docstring''' # Tests that all call wrap to encode_plus and batch_encode_plus __lowerCamelCase = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) # create three inputs of length 800, 1000, and 1200 __lowerCamelCase = [floats_list((1, x) )[0] for x in range(800 , 1_400 , 200 )] __lowerCamelCase = [np.asarray(lowerCamelCase__ ) for speech_input in speech_inputs] # Test feature size __lowerCamelCase = feature_extractor(lowerCamelCase__ , padding='max_length' , return_tensors='np' ).input_features self.assertTrue(input_features.ndim == 3 ) self.assertTrue(input_features.shape[-1] == feature_extractor.nb_max_frames ) self.assertTrue(input_features.shape[-2] == feature_extractor.feature_size ) # Test not batched input __lowerCamelCase = feature_extractor(speech_inputs[0] , return_tensors='np' ).input_features __lowerCamelCase = feature_extractor(np_speech_inputs[0] , return_tensors='np' ).input_features self.assertTrue(np.allclose(lowerCamelCase__ , lowerCamelCase__ , atol=1e-3 ) ) # Test batched __lowerCamelCase = feature_extractor(lowerCamelCase__ , return_tensors='np' ).input_features __lowerCamelCase = feature_extractor(lowerCamelCase__ , return_tensors='np' ).input_features for enc_seq_a, enc_seq_a in zip(lowerCamelCase__ , lowerCamelCase__ ): self.assertTrue(np.allclose(lowerCamelCase__ , lowerCamelCase__ , atol=1e-3 ) ) # Test 2-D numpy arrays are batched. __lowerCamelCase = [floats_list((1, x) )[0] for x in (800, 800, 800)] __lowerCamelCase = np.asarray(lowerCamelCase__ ) __lowerCamelCase = feature_extractor(lowerCamelCase__ , return_tensors='np' ).input_features __lowerCamelCase = feature_extractor(lowerCamelCase__ , return_tensors='np' ).input_features for enc_seq_a, enc_seq_a in zip(lowerCamelCase__ , lowerCamelCase__ ): self.assertTrue(np.allclose(lowerCamelCase__ , lowerCamelCase__ , atol=1e-3 ) ) # Test truncation required __lowerCamelCase = [floats_list((1, x) )[0] for x in range(200 , (feature_extractor.n_samples + 500) , 200 )] __lowerCamelCase = [np.asarray(lowerCamelCase__ ) for speech_input in speech_inputs] __lowerCamelCase = [x[: feature_extractor.n_samples] for x in speech_inputs] __lowerCamelCase = [np.asarray(lowerCamelCase__ ) for speech_input in speech_inputs_truncated] __lowerCamelCase = feature_extractor(lowerCamelCase__ , return_tensors='np' ).input_features __lowerCamelCase = feature_extractor(lowerCamelCase__ , return_tensors='np' ).input_features for enc_seq_a, enc_seq_a in zip(lowerCamelCase__ , lowerCamelCase__ ): self.assertTrue(np.allclose(lowerCamelCase__ , lowerCamelCase__ , atol=1e-3 ) ) def lowercase_ ( self ) -> List[str]: '''simple docstring''' import torch __lowerCamelCase = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) __lowerCamelCase = np.random.rand(100 , 32 ).astype(np.floataa ) __lowerCamelCase = np_speech_inputs.tolist() for inputs in [py_speech_inputs, np_speech_inputs]: __lowerCamelCase = feature_extractor.pad([{'input_features': inputs}] , return_tensors='np' ) self.assertTrue(np_processed.input_features.dtype == np.floataa ) __lowerCamelCase = feature_extractor.pad([{'input_features': inputs}] , return_tensors='pt' ) self.assertTrue(pt_processed.input_features.dtype == torch.floataa ) def lowercase_ ( self , lowerCamelCase__ ) -> List[str]: '''simple docstring''' __lowerCamelCase = load_dataset('hf-internal-testing/librispeech_asr_dummy' , 'clean' , split='validation' ) # automatic decoding with librispeech __lowerCamelCase = ds.sort('id' ).select(range(lowerCamelCase__ ) )[:num_samples]['audio'] return [x["array"] for x in speech_samples] def lowercase_ ( self ) -> Tuple: '''simple docstring''' # fmt: off __lowerCamelCase = torch.tensor( [ 0.11_93, -0.09_46, -0.10_98, -0.01_96, 0.02_25, -0.06_90, -0.17_36, 0.09_51, 0.09_71, -0.08_17, -0.07_02, 0.01_62, 0.02_60, 0.00_17, -0.01_92, -0.16_78, 0.07_09, -0.18_67, -0.06_55, -0.02_74, -0.02_34, -0.18_84, -0.05_16, -0.05_54, -0.02_74, -0.14_25, -0.14_23, 0.08_37, 0.03_77, -0.08_54 ] ) # fmt: on __lowerCamelCase = self._load_datasamples(1 ) __lowerCamelCase = WhisperFeatureExtractor() __lowerCamelCase = feature_extractor(lowerCamelCase__ , return_tensors='pt' ).input_features self.assertEqual(input_features.shape , (1, 80, 3_000) ) self.assertTrue(torch.allclose(input_features[0, 0, :30] , lowerCamelCase__ , atol=1e-4 ) ) def lowercase_ ( self ) -> List[Any]: '''simple docstring''' __lowerCamelCase = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) __lowerCamelCase = self._load_datasamples(1 )[0] __lowerCamelCase = ((audio - audio.min()) / (audio.max() - audio.min())) * 65_535 # Rescale to [0, 65535] to show issue __lowerCamelCase = feat_extract.zero_mean_unit_var_norm([audio] , attention_mask=lowerCamelCase__ )[0] self.assertTrue(np.all(np.mean(lowerCamelCase__ ) < 1e-3 ) ) self.assertTrue(np.all(np.abs(np.var(lowerCamelCase__ ) - 1 ) < 1e-3 ) )
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"""simple docstring""" import logging import os from dataclasses import dataclass, field from typing import Dict, Optional import datasets import numpy as np import tensorflow as tf from transformers import ( AutoConfig, AutoTokenizer, EvalPrediction, HfArgumentParser, PreTrainedTokenizer, TFAutoModelForSequenceClassification, TFTrainer, TFTrainingArguments, ) from transformers.utils import logging as hf_logging hf_logging.set_verbosity_info() hf_logging.enable_default_handler() hf_logging.enable_explicit_format() def _SCREAMING_SNAKE_CASE (__lowerCAmelCase , __lowerCAmelCase , __lowerCAmelCase , __lowerCAmelCase , __lowerCAmelCase , __lowerCAmelCase = None , ) -> Union[str, Any]: '''simple docstring''' lowercase_ = {} if train_file is not None: lowercase_ = [train_file] if eval_file is not None: lowercase_ = [eval_file] if test_file is not None: lowercase_ = [test_file] lowercase_ = datasets.load_dataset("""csv""" , data_files=UpperCamelCase__ ) lowercase_ = list(ds[list(files.keys() )[0]].features.keys() ) lowercase_ = features_name.pop(UpperCamelCase__ ) lowercase_ = list(set(ds[list(files.keys() )[0]][label_name] ) ) lowercase_ = {label: i for i, label in enumerate(UpperCamelCase__ )} lowercase_ = tokenizer.model_input_names lowercase_ = {} if len(UpperCamelCase__ ) == 1: for k in files.keys(): lowercase_ = ds[k].map( lambda __lowerCAmelCase : tokenizer.batch_encode_plus( example[features_name[0]] , truncation=UpperCamelCase__ , max_length=UpperCamelCase__ , padding="""max_length""" ) , batched=UpperCamelCase__ , ) elif len(UpperCamelCase__ ) == 2: for k in files.keys(): lowercase_ = ds[k].map( lambda __lowerCAmelCase : tokenizer.batch_encode_plus( (example[features_name[0]], example[features_name[1]]) , truncation=UpperCamelCase__ , max_length=UpperCamelCase__ , padding="""max_length""" , ) , batched=UpperCamelCase__ , ) def gen_train(): for ex in transformed_ds[datasets.Split.TRAIN]: lowercase_ = {k: v for k, v in ex.items() if k in input_names} lowercase_ = labelaid[ex[label_name]] yield (d, label) def gen_val(): for ex in transformed_ds[datasets.Split.VALIDATION]: lowercase_ = {k: v for k, v in ex.items() if k in input_names} lowercase_ = labelaid[ex[label_name]] yield (d, label) def gen_test(): for ex in transformed_ds[datasets.Split.TEST]: lowercase_ = {k: v for k, v in ex.items() if k in input_names} lowercase_ = labelaid[ex[label_name]] yield (d, label) lowercase_ = ( tf.data.Dataset.from_generator( UpperCamelCase__ , ({k: tf.intaa for k in input_names}, tf.intaa) , ({k: tf.TensorShape([None] ) for k in input_names}, tf.TensorShape([] )) , ) if datasets.Split.TRAIN in transformed_ds else None ) if train_ds is not None: lowercase_ = train_ds.apply(tf.data.experimental.assert_cardinality(len(ds[datasets.Split.TRAIN] ) ) ) lowercase_ = ( tf.data.Dataset.from_generator( UpperCamelCase__ , ({k: tf.intaa for k in input_names}, tf.intaa) , ({k: tf.TensorShape([None] ) for k in input_names}, tf.TensorShape([] )) , ) if datasets.Split.VALIDATION in transformed_ds else None ) if val_ds is not None: lowercase_ = val_ds.apply(tf.data.experimental.assert_cardinality(len(ds[datasets.Split.VALIDATION] ) ) ) lowercase_ = ( tf.data.Dataset.from_generator( UpperCamelCase__ , ({k: tf.intaa for k in input_names}, tf.intaa) , ({k: tf.TensorShape([None] ) for k in input_names}, tf.TensorShape([] )) , ) if datasets.Split.TEST in transformed_ds else None ) if test_ds is not None: lowercase_ = test_ds.apply(tf.data.experimental.assert_cardinality(len(ds[datasets.Split.TEST] ) ) ) return train_ds, val_ds, test_ds, labelaid UpperCAmelCase : List[Any] = logging.getLogger(__name__) @dataclass class SCREAMING_SNAKE_CASE__ : lowercase__ = field(metadata={"help": "Which column contains the label"} ) lowercase__ = field(default=__UpperCAmelCase , metadata={"help": "The path of the training file"} ) lowercase__ = field(default=__UpperCAmelCase , metadata={"help": "The path of the development file"} ) lowercase__ = field(default=__UpperCAmelCase , metadata={"help": "The path of the test file"} ) lowercase__ = field( default=128 , metadata={ "help": ( "The maximum total input sequence length after tokenization. Sequences longer " "than this will be truncated, sequences shorter will be padded." ) } , ) lowercase__ = field( default=__UpperCAmelCase , metadata={"help": "Overwrite the cached training and evaluation sets"} ) @dataclass class SCREAMING_SNAKE_CASE__ : lowercase__ = field( metadata={"help": "Path to pretrained model or model identifier from huggingface.co/models"} ) lowercase__ = field( default=__UpperCAmelCase , metadata={"help": "Pretrained config name or path if not the same as model_name"} ) lowercase__ = field( default=__UpperCAmelCase , metadata={"help": "Pretrained tokenizer name or path if not the same as model_name"} ) lowercase__ = field(default=__UpperCAmelCase , metadata={"help": "Set this flag to use fast tokenization."} ) # If you want to tweak more attributes on your tokenizer, you should do it in a distinct script, # or just modify its tokenizer_config.json. lowercase__ = field( default=__UpperCAmelCase , metadata={"help": "Where do you want to store the pretrained models downloaded from huggingface.co"} , ) def _SCREAMING_SNAKE_CASE () -> int: '''simple docstring''' lowercase_ = HfArgumentParser((ModelArguments, DataTrainingArguments, TFTrainingArguments) ) lowercase_ , lowercase_ , lowercase_ = 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 , ) logger.info( F'''n_replicas: {training_args.n_replicas}, distributed training: {bool(training_args.n_replicas > 1 )}, ''' F'''16-bits training: {training_args.fpaa}''' ) logger.info(F'''Training/evaluation parameters {training_args}''' ) # Load pretrained model and tokenizer # # Distributed training: # The .from_pretrained methods guarantee that only one local process can concurrently # download model & vocab. lowercase_ = 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 , ) lowercase_ , lowercase_ , lowercase_ , lowercase_ = get_tfds( train_file=data_args.train_file , eval_file=data_args.dev_file , test_file=data_args.test_file , tokenizer=UpperCamelCase__ , label_column_id=data_args.label_column_id , max_seq_length=data_args.max_seq_length , ) lowercase_ = AutoConfig.from_pretrained( model_args.config_name if model_args.config_name else model_args.model_name_or_path , num_labels=len(UpperCamelCase__ ) , labelaid=UpperCamelCase__ , idalabel={id: label for label, id in labelaid.items()} , finetuning_task="""text-classification""" , cache_dir=model_args.cache_dir , ) with training_args.strategy.scope(): lowercase_ = TFAutoModelForSequenceClassification.from_pretrained( model_args.model_name_or_path , from_pt=bool(""".bin""" in model_args.model_name_or_path ) , config=UpperCamelCase__ , cache_dir=model_args.cache_dir , ) def compute_metrics(__lowerCAmelCase ) -> Dict: lowercase_ = np.argmax(p.predictions , axis=1 ) return {"acc": (preds == p.label_ids).mean()} # Initialize our Trainer lowercase_ = TFTrainer( model=UpperCamelCase__ , args=UpperCamelCase__ , train_dataset=UpperCamelCase__ , eval_dataset=UpperCamelCase__ , compute_metrics=UpperCamelCase__ , ) # Training if training_args.do_train: trainer.train() trainer.save_model() tokenizer.save_pretrained(training_args.output_dir ) # Evaluation lowercase_ = {} if training_args.do_eval: logger.info("""*** Evaluate ***""" ) lowercase_ = trainer.evaluate() lowercase_ = os.path.join(training_args.output_dir , """eval_results.txt""" ) with open(UpperCamelCase__ , """w""" ) as writer: logger.info("""***** Eval results *****""" ) for key, value in result.items(): logger.info(F''' {key} = {value}''' ) writer.write(F'''{key} = {value}\n''' ) results.update(UpperCamelCase__ ) return results if __name__ == "__main__": main()
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from dataclasses import dataclass from typing import Tuple import numpy as np import torch @dataclass class __lowerCAmelCase : """simple docstring""" snake_case_ = 42 # [batch_size x 3] snake_case_ = 42 # [batch_size x 3] snake_case_ = 42 # [batch_size x 3] snake_case_ = 42 # [batch_size x 3] snake_case_ = 42 snake_case_ = 42 snake_case_ = 42 snake_case_ = 42 snake_case_ = 42 def lowercase_ ( self ) -> Union[str, Any]: '''simple docstring''' assert self.x.shape[0] == self.y.shape[0] == self.z.shape[0] == self.origin.shape[0] assert self.x.shape[1] == self.y.shape[1] == self.z.shape[1] == self.origin.shape[1] == 3 assert len(self.x.shape ) == len(self.y.shape ) == len(self.z.shape ) == len(self.origin.shape ) == 2 def lowercase_ ( self ) -> Optional[int]: '''simple docstring''' return torch.from_numpy(np.array([self.width, self.height] , dtype=np.floataa ) ) def lowercase_ ( self ) -> Optional[Any]: '''simple docstring''' return torch.from_numpy(np.array([self.x_fov, self.y_fov] , dtype=np.floataa ) ) def lowercase_ ( self ) -> torch.Tensor: '''simple docstring''' __lowerCamelCase = torch.arange(self.height * self.width ) __lowerCamelCase = torch.stack( [ pixel_indices % self.width, torch.div(lowerCamelCase__ , self.width , rounding_mode='trunc' ), ] , axis=1 , ) return coords @property def lowercase_ ( self ) -> int: '''simple docstring''' __lowerCamelCase , *__lowerCamelCase = self.shape __lowerCamelCase = int(np.prod(lowerCamelCase__ ) ) __lowerCamelCase = self.get_image_coords() __lowerCamelCase = torch.broadcast_to(coords.unsqueeze(0 ) , [batch_size * inner_batch_size, *coords.shape] ) __lowerCamelCase = self.get_camera_rays(lowerCamelCase__ ) __lowerCamelCase = rays.view(lowerCamelCase__ , inner_batch_size * self.height * self.width , 2 , 3 ) return rays def lowercase_ ( self , lowerCamelCase__ ) -> torch.Tensor: '''simple docstring''' __lowerCamelCase , *__lowerCamelCase , __lowerCamelCase = coords.shape assert n_coords == 2 assert batch_size == self.origin.shape[0] __lowerCamelCase = coords.view(lowerCamelCase__ , -1 , 2 ) __lowerCamelCase = self.resolution() __lowerCamelCase = self.fov() __lowerCamelCase = (flat.float() / (res - 1)) * 2 - 1 __lowerCamelCase = fracs * torch.tan(fov / 2 ) __lowerCamelCase = fracs.view(lowerCamelCase__ , -1 , 2 ) __lowerCamelCase = ( self.z.view(lowerCamelCase__ , 1 , 3 ) + self.x.view(lowerCamelCase__ , 1 , 3 ) * fracs[:, :, :1] + self.y.view(lowerCamelCase__ , 1 , 3 ) * fracs[:, :, 1:] ) __lowerCamelCase = directions / directions.norm(dim=-1 , keepdim=lowerCamelCase__ ) __lowerCamelCase = torch.stack( [ torch.broadcast_to(self.origin.view(lowerCamelCase__ , 1 , 3 ) , [batch_size, directions.shape[1], 3] ), directions, ] , dim=2 , ) return rays.view(lowerCamelCase__ , *lowerCamelCase__ , 2 , 3 ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ ) -> "DifferentiableProjectiveCamera": '''simple docstring''' assert width * self.height == height * self.width, "The aspect ratio should not change." return DifferentiableProjectiveCamera( origin=self.origin , x=self.x , y=self.y , z=self.z , width=lowerCamelCase__ , height=lowerCamelCase__ , x_fov=self.x_fov , y_fov=self.y_fov , ) def lowerCamelCase_ ( UpperCamelCase__ : int ) -> DifferentiableProjectiveCamera: """simple docstring""" __lowerCamelCase = [] __lowerCamelCase = [] __lowerCamelCase = [] __lowerCamelCase = [] for theta in np.linspace(0 , 2 * np.pi , num=20 ): __lowerCamelCase = np.array([np.sin(UpperCamelCase__ ), np.cos(UpperCamelCase__ ), -0.5] ) z /= np.sqrt(np.sum(z**2 ) ) __lowerCamelCase = -z * 4 __lowerCamelCase = np.array([np.cos(UpperCamelCase__ ), -np.sin(UpperCamelCase__ ), 0.0] ) __lowerCamelCase = np.cross(UpperCamelCase__ , UpperCamelCase__ ) origins.append(UpperCamelCase__ ) xs.append(UpperCamelCase__ ) ys.append(UpperCamelCase__ ) zs.append(UpperCamelCase__ ) return DifferentiableProjectiveCamera( origin=torch.from_numpy(np.stack(UpperCamelCase__ , axis=0 ) ).float() , x=torch.from_numpy(np.stack(UpperCamelCase__ , axis=0 ) ).float() , y=torch.from_numpy(np.stack(UpperCamelCase__ , axis=0 ) ).float() , z=torch.from_numpy(np.stack(UpperCamelCase__ , axis=0 ) ).float() , width=UpperCamelCase__ , height=UpperCamelCase__ , x_fov=0.7 , y_fov=0.7 , shape=(1, len(UpperCamelCase__ )) , )
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0
'''simple docstring''' import warnings from typing import List, Optional, Union from ...processing_utils import ProcessorMixin from ...tokenization_utils_base import BatchEncoding, PaddingStrategy, PreTokenizedInput, TextInput, TruncationStrategy from ...utils import TensorType class a_ ( snake_case_ ): '''simple docstring''' UpperCamelCase = ['''image_processor''', '''tokenizer'''] UpperCamelCase = '''LayoutLMv2ImageProcessor''' UpperCamelCase = ('''LayoutXLMTokenizer''', '''LayoutXLMTokenizerFast''') def __init__( self , A=None , A=None , **A ) -> Union[str, Any]: if "feature_extractor" in kwargs: warnings.warn( """The `feature_extractor` argument is deprecated and will be removed in v5, use `image_processor`""" """ instead.""" , lowerCamelCase__ , ) _SCREAMING_SNAKE_CASE = kwargs.pop("""feature_extractor""" ) _SCREAMING_SNAKE_CASE = image_processor if image_processor is not None else feature_extractor if image_processor is None: raise ValueError("""You need to specify an `image_processor`.""" ) if tokenizer is None: raise ValueError("""You need to specify a `tokenizer`.""" ) super().__init__(lowerCamelCase__ , lowerCamelCase__ ) def __call__( self , A , A = None , A = None , A = None , A = None , A = True , A = False , A = None , A = None , A = 0 , A = None , A = None , A = None , A = False , A = False , A = False , A = False , A = True , A = None , **A , ) -> BatchEncoding: # verify input if self.image_processor.apply_ocr and (boxes is not None): raise ValueError( """You cannot provide bounding boxes """ """if you initialized the image processor with apply_ocr set to True.""" ) if self.image_processor.apply_ocr and (word_labels is not None): raise ValueError( """You cannot provide word labels if you initialized the image processor with apply_ocr set to True.""" ) if return_overflowing_tokens is True and return_offsets_mapping is False: raise ValueError("""You cannot return overflowing tokens without returning the offsets mapping.""" ) # first, apply the image processor _SCREAMING_SNAKE_CASE = self.image_processor(images=lowerCamelCase__ , return_tensors=lowerCamelCase__ ) # second, apply the tokenizer if text is not None and self.image_processor.apply_ocr and text_pair is None: if isinstance(lowerCamelCase__ , lowerCamelCase__ ): _SCREAMING_SNAKE_CASE = [text] # add batch dimension (as the image processor always adds a batch dimension) _SCREAMING_SNAKE_CASE = features["""words"""] _SCREAMING_SNAKE_CASE = self.tokenizer( text=text if text is not None else features["""words"""] , text_pair=text_pair if text_pair is not None else None , boxes=boxes if boxes is not None else features["""boxes"""] , word_labels=lowerCamelCase__ , add_special_tokens=lowerCamelCase__ , padding=lowerCamelCase__ , truncation=lowerCamelCase__ , max_length=lowerCamelCase__ , stride=lowerCamelCase__ , pad_to_multiple_of=lowerCamelCase__ , return_token_type_ids=lowerCamelCase__ , return_attention_mask=lowerCamelCase__ , return_overflowing_tokens=lowerCamelCase__ , return_special_tokens_mask=lowerCamelCase__ , return_offsets_mapping=lowerCamelCase__ , return_length=lowerCamelCase__ , verbose=lowerCamelCase__ , return_tensors=lowerCamelCase__ , **lowerCamelCase__ , ) # add pixel values _SCREAMING_SNAKE_CASE = features.pop("""pixel_values""" ) if return_overflowing_tokens is True: _SCREAMING_SNAKE_CASE = self.get_overflowing_images(lowerCamelCase__ , encoded_inputs["""overflow_to_sample_mapping"""] ) _SCREAMING_SNAKE_CASE = images return encoded_inputs def snake_case_( self , A , A ) -> Optional[int]: _SCREAMING_SNAKE_CASE = [] for sample_idx in overflow_to_sample_mapping: images_with_overflow.append(images[sample_idx] ) if len(lowerCamelCase__ ) != len(lowerCamelCase__ ): raise ValueError( """Expected length of images to be the same as the length of `overflow_to_sample_mapping`, but got""" f' {len(lowerCamelCase__ )} and {len(lowerCamelCase__ )}' ) return images_with_overflow def snake_case_( self , *A , **A ) -> List[Any]: return self.tokenizer.batch_decode(*lowerCamelCase__ , **lowerCamelCase__ ) def snake_case_( self , *A , **A ) -> List[Any]: return self.tokenizer.decode(*lowerCamelCase__ , **lowerCamelCase__ ) @property def snake_case_( self ) -> int: return ["input_ids", "bbox", "attention_mask", "image"] @property def snake_case_( self ) -> List[str]: warnings.warn( """`feature_extractor_class` is deprecated and will be removed in v5. Use `image_processor_class` instead.""" , lowerCamelCase__ , ) return self.image_processor_class @property def snake_case_( self ) -> List[Any]: warnings.warn( """`feature_extractor` is deprecated and will be removed in v5. Use `image_processor` instead.""" , lowerCamelCase__ , ) return self.image_processor
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import collections import inspect import unittest from transformers import FocalNetConfig 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_backbone_common import BackboneTesterMixin 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 ( FocalNetBackbone, FocalNetForImageClassification, FocalNetForMaskedImageModeling, FocalNetModel, ) from transformers.models.focalnet.modeling_focalnet import FOCALNET_PRETRAINED_MODEL_ARCHIVE_LIST if is_vision_available(): from PIL import Image from transformers import AutoImageProcessor class __lowerCAmelCase : """simple docstring""" def __init__( self , lowerCamelCase__ , lowerCamelCase__=13 , lowerCamelCase__=32 , lowerCamelCase__=2 , lowerCamelCase__=3 , lowerCamelCase__=16 , lowerCamelCase__=[32, 64, 128] , lowerCamelCase__=[1, 2, 1] , lowerCamelCase__=[2, 2, 4] , lowerCamelCase__=2 , lowerCamelCase__=2.0 , lowerCamelCase__=True , lowerCamelCase__=0.0 , lowerCamelCase__=0.0 , lowerCamelCase__=0.1 , lowerCamelCase__="gelu" , lowerCamelCase__=False , lowerCamelCase__=True , lowerCamelCase__=0.02 , lowerCamelCase__=1e-5 , lowerCamelCase__=True , lowerCamelCase__=None , lowerCamelCase__=True , lowerCamelCase__=10 , lowerCamelCase__=8 , lowerCamelCase__=["stage1", "stage2"] , lowerCamelCase__=[1, 2] , ) -> int: '''simple docstring''' __lowerCamelCase = parent __lowerCamelCase = batch_size __lowerCamelCase = image_size __lowerCamelCase = patch_size __lowerCamelCase = num_channels __lowerCamelCase = embed_dim __lowerCamelCase = hidden_sizes __lowerCamelCase = depths __lowerCamelCase = num_heads __lowerCamelCase = window_size __lowerCamelCase = mlp_ratio __lowerCamelCase = qkv_bias __lowerCamelCase = hidden_dropout_prob __lowerCamelCase = attention_probs_dropout_prob __lowerCamelCase = drop_path_rate __lowerCamelCase = hidden_act __lowerCamelCase = use_absolute_embeddings __lowerCamelCase = patch_norm __lowerCamelCase = layer_norm_eps __lowerCamelCase = initializer_range __lowerCamelCase = is_training __lowerCamelCase = scope __lowerCamelCase = use_labels __lowerCamelCase = type_sequence_label_size __lowerCamelCase = encoder_stride __lowerCamelCase = out_features __lowerCamelCase = out_indices def lowercase_ ( self ) -> List[Any]: '''simple docstring''' __lowerCamelCase = floats_tensor([self.batch_size, self.num_channels, self.image_size, self.image_size] ) __lowerCamelCase = None if self.use_labels: __lowerCamelCase = ids_tensor([self.batch_size] , self.type_sequence_label_size ) __lowerCamelCase = self.get_config() return config, pixel_values, labels def lowercase_ ( self ) -> List[str]: '''simple docstring''' return FocalNetConfig( image_size=self.image_size , patch_size=self.patch_size , num_channels=self.num_channels , embed_dim=self.embed_dim , hidden_sizes=self.hidden_sizes , 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 lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> int: '''simple docstring''' __lowerCamelCase = FocalNetModel(config=lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model(lowerCamelCase__ ) __lowerCamelCase = ((config.image_size // config.patch_size) ** 2) // (4 ** (len(config.depths ) - 1)) __lowerCamelCase = int(config.embed_dim * 2 ** (len(config.depths ) - 1) ) self.parent.assertEqual(result.last_hidden_state.shape , (self.batch_size, expected_seq_len, expected_dim) ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> List[Any]: '''simple docstring''' __lowerCamelCase = FocalNetBackbone(config=lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model(lowerCamelCase__ ) # verify feature maps self.parent.assertEqual(len(result.feature_maps ) , len(config.out_features ) ) self.parent.assertListEqual(list(result.feature_maps[0].shape ) , [self.batch_size, self.image_size, 8, 8] ) # verify channels self.parent.assertEqual(len(model.channels ) , len(config.out_features ) ) self.parent.assertListEqual(model.channels , config.hidden_sizes[:-1] ) # verify backbone works with out_features=None __lowerCamelCase = None __lowerCamelCase = FocalNetBackbone(config=lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model(lowerCamelCase__ ) # verify feature maps self.parent.assertEqual(len(result.feature_maps ) , 1 ) self.parent.assertListEqual(list(result.feature_maps[0].shape ) , [self.batch_size, self.image_size * 2, 4, 4] ) # verify channels self.parent.assertEqual(len(model.channels ) , 1 ) self.parent.assertListEqual(model.channels , [config.hidden_sizes[-1]] ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> int: '''simple docstring''' __lowerCamelCase = FocalNetForMaskedImageModeling(config=lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model(lowerCamelCase__ ) self.parent.assertEqual( result.reconstruction.shape , (self.batch_size, self.num_channels, self.image_size, self.image_size) ) # test greyscale images __lowerCamelCase = 1 __lowerCamelCase = FocalNetForMaskedImageModeling(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = floats_tensor([self.batch_size, 1, self.image_size, self.image_size] ) __lowerCamelCase = model(lowerCamelCase__ ) self.parent.assertEqual(result.reconstruction.shape , (self.batch_size, 1, self.image_size, self.image_size) ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> str: '''simple docstring''' __lowerCamelCase = self.type_sequence_label_size __lowerCamelCase = FocalNetForImageClassification(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model(lowerCamelCase__ , labels=lowerCamelCase__ ) self.parent.assertEqual(result.logits.shape , (self.batch_size, self.type_sequence_label_size) ) # test greyscale images __lowerCamelCase = 1 __lowerCamelCase = FocalNetForImageClassification(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = floats_tensor([self.batch_size, 1, self.image_size, self.image_size] ) __lowerCamelCase = model(lowerCamelCase__ ) self.parent.assertEqual(result.logits.shape , (self.batch_size, self.type_sequence_label_size) ) def lowercase_ ( self ) -> Tuple: '''simple docstring''' __lowerCamelCase = self.prepare_config_and_inputs() __lowerCamelCase , __lowerCamelCase , __lowerCamelCase = config_and_inputs __lowerCamelCase = {'pixel_values': pixel_values} return config, inputs_dict @require_torch class __lowerCAmelCase ( __magic_name__ , __magic_name__ , unittest.TestCase ): """simple docstring""" snake_case_ = ( ( FocalNetModel, FocalNetForImageClassification, FocalNetForMaskedImageModeling, FocalNetBackbone, ) if is_torch_available() else () ) snake_case_ = ( {'''feature-extraction''': FocalNetModel, '''image-classification''': FocalNetForImageClassification} if is_torch_available() else {} ) snake_case_ = False snake_case_ = False snake_case_ = False snake_case_ = False snake_case_ = False def lowercase_ ( self ) -> str: '''simple docstring''' __lowerCamelCase = FocalNetModelTester(self ) __lowerCamelCase = ConfigTester(self , config_class=lowerCamelCase__ , embed_dim=37 , has_text_modality=lowerCamelCase__ ) def lowercase_ ( self ) -> str: '''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 lowercase_ ( self ) -> str: '''simple docstring''' return def lowercase_ ( self ) -> List[Any]: '''simple docstring''' __lowerCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_model(*lowerCamelCase__ ) def lowercase_ ( self ) -> Optional[Any]: '''simple docstring''' __lowerCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_backbone(*lowerCamelCase__ ) def lowercase_ ( self ) -> str: '''simple docstring''' __lowerCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_for_masked_image_modeling(*lowerCamelCase__ ) def lowercase_ ( self ) -> Any: '''simple docstring''' __lowerCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_for_image_classification(*lowerCamelCase__ ) @unittest.skip(reason='FocalNet does not use inputs_embeds' ) def lowercase_ ( self ) -> Optional[int]: '''simple docstring''' pass @unittest.skip(reason='FocalNet does not use feedforward chunking' ) def lowercase_ ( self ) -> Union[str, Any]: '''simple docstring''' pass def lowercase_ ( self ) -> Dict: '''simple docstring''' __lowerCamelCase , __lowerCamelCase = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes[:-1]: __lowerCamelCase = model_class(lowerCamelCase__ ) self.assertIsInstance(model.get_input_embeddings() , (nn.Module) ) __lowerCamelCase = model.get_output_embeddings() self.assertTrue(x is None or isinstance(lowerCamelCase__ , nn.Linear ) ) def lowercase_ ( self ) -> str: '''simple docstring''' __lowerCamelCase , __lowerCamelCase = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes[:-1]: __lowerCamelCase = model_class(lowerCamelCase__ ) __lowerCamelCase = inspect.signature(model.forward ) # signature.parameters is an OrderedDict => so arg_names order is deterministic __lowerCamelCase = [*signature.parameters.keys()] __lowerCamelCase = ['pixel_values'] self.assertListEqual(arg_names[:1] , lowerCamelCase__ ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> int: '''simple docstring''' __lowerCamelCase = model_class(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() with torch.no_grad(): __lowerCamelCase = model(**self._prepare_for_class(lowerCamelCase__ , lowerCamelCase__ ) ) __lowerCamelCase = outputs.hidden_states __lowerCamelCase = getattr( self.model_tester , 'expected_num_hidden_layers' , len(self.model_tester.depths ) + 1 ) self.assertEqual(len(lowerCamelCase__ ) , lowerCamelCase__ ) # FocalNet has a different seq_length __lowerCamelCase = ( config.patch_size if isinstance(config.patch_size , collections.abc.Iterable ) else (config.patch_size, config.patch_size) ) __lowerCamelCase = (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] , ) __lowerCamelCase = outputs.reshaped_hidden_states self.assertEqual(len(lowerCamelCase__ ) , lowerCamelCase__ ) __lowerCamelCase , __lowerCamelCase , __lowerCamelCase , __lowerCamelCase = reshaped_hidden_states[0].shape __lowerCamelCase = ( reshaped_hidden_states[0].view(lowerCamelCase__ , lowerCamelCase__ , height * width ).permute(0 , 2 , 1 ) ) self.assertListEqual( list(reshaped_hidden_states.shape[-2:] ) , [num_patches, self.model_tester.embed_dim] , ) def lowercase_ ( self ) -> Dict: '''simple docstring''' __lowerCamelCase , __lowerCamelCase = self.model_tester.prepare_config_and_inputs_for_common() __lowerCamelCase = ( 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[:-1]: __lowerCamelCase = True self.check_hidden_states_output(lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) # check that output_hidden_states also work using config del inputs_dict["output_hidden_states"] __lowerCamelCase = True self.check_hidden_states_output(lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) def lowercase_ ( self ) -> Optional[Any]: '''simple docstring''' __lowerCamelCase , __lowerCamelCase = self.model_tester.prepare_config_and_inputs_for_common() __lowerCamelCase = 3 __lowerCamelCase = ( 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) ) __lowerCamelCase = ( config.patch_size if isinstance(config.patch_size , collections.abc.Iterable ) else (config.patch_size, config.patch_size) ) __lowerCamelCase = image_size[0] + patch_size[0] - (image_size[0] % patch_size[0]) __lowerCamelCase = image_size[1] + patch_size[1] - (image_size[1] % patch_size[1]) for model_class in self.all_model_classes[:-1]: __lowerCamelCase = True self.check_hidden_states_output(lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , (padded_height, padded_width) ) # check that output_hidden_states also work using config del inputs_dict["output_hidden_states"] __lowerCamelCase = True self.check_hidden_states_output(lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , (padded_height, padded_width) ) @slow def lowercase_ ( self ) -> str: '''simple docstring''' for model_name in FOCALNET_PRETRAINED_MODEL_ARCHIVE_LIST[:1]: __lowerCamelCase = FocalNetModel.from_pretrained(lowerCamelCase__ ) self.assertIsNotNone(lowerCamelCase__ ) def lowercase_ ( self ) -> Optional[int]: '''simple docstring''' __lowerCamelCase , __lowerCamelCase = self.model_tester.prepare_config_and_inputs_for_common() __lowerCamelCase = _config_zero_init(lowerCamelCase__ ) for model_class in self.all_model_classes: __lowerCamelCase = model_class(config=lowerCamelCase__ ) for name, param in model.named_parameters(): if "embeddings" 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 lowercase_ ( self ) -> List[str]: '''simple docstring''' # TODO update organization return AutoImageProcessor.from_pretrained('microsoft/focalnet-tiny' ) if is_vision_available() else None @slow def lowercase_ ( self ) -> List[Any]: '''simple docstring''' __lowerCamelCase = FocalNetForImageClassification.from_pretrained('microsoft/focalnet-tiny' ).to(lowerCamelCase__ ) __lowerCamelCase = self.default_image_processor __lowerCamelCase = Image.open('./tests/fixtures/tests_samples/COCO/000000039769.png' ) __lowerCamelCase = image_processor(images=lowerCamelCase__ , return_tensors='pt' ).to(lowerCamelCase__ ) # forward pass with torch.no_grad(): __lowerCamelCase = model(**lowerCamelCase__ ) # verify the logits __lowerCamelCase = torch.Size((1, 1_000) ) self.assertEqual(outputs.logits.shape , lowerCamelCase__ ) __lowerCamelCase = torch.tensor([0.21_66, -0.43_68, 0.21_91] ).to(lowerCamelCase__ ) self.assertTrue(torch.allclose(outputs.logits[0, :3] , lowerCamelCase__ , atol=1e-4 ) ) self.assertTrue(outputs.logits.argmax(dim=-1 ).item() , 281 ) @require_torch class __lowerCAmelCase ( __magic_name__ , unittest.TestCase ): """simple docstring""" snake_case_ = (FocalNetBackbone,) if is_torch_available() else () snake_case_ = FocalNetConfig snake_case_ = False def lowercase_ ( self ) -> Any: '''simple docstring''' __lowerCamelCase = FocalNetModelTester(self )
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def _a ( a :list[list[int | float]] ) -> int: a = len(UpperCamelCase__ ) a = len(matrix[0] ) a = min(UpperCamelCase__ , UpperCamelCase__ ) for row in range(UpperCamelCase__ ): # Check if diagonal element is not zero if matrix[row][row] != 0: # Eliminate all the elements below the diagonal for col in range(row + 1 , UpperCamelCase__ ): a = matrix[col][row] / matrix[row][row] for i in range(UpperCamelCase__ , UpperCamelCase__ ): matrix[col][i] -= multiplier * matrix[row][i] else: # Find a non-zero diagonal element to swap rows a = True for i in range(row + 1 , UpperCamelCase__ ): if matrix[i][row] != 0: a , a = matrix[i], matrix[row] a = False break if reduce: rank -= 1 for i in range(UpperCamelCase__ ): a = matrix[i][rank] # Reduce the row pointer by one to stay on the same row row -= 1 return rank if __name__ == "__main__": import doctest doctest.testmod()
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from typing import TYPE_CHECKING from ...utils import OptionalDependencyNotAvailable, _LazyModule, is_speech_available, is_torch_available __A = { "configuration_audio_spectrogram_transformer": [ "AUDIO_SPECTROGRAM_TRANSFORMER_PRETRAINED_CONFIG_ARCHIVE_MAP", "ASTConfig", ] } try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __A = [ "AUDIO_SPECTROGRAM_TRANSFORMER_PRETRAINED_MODEL_ARCHIVE_LIST", "ASTForAudioClassification", "ASTModel", "ASTPreTrainedModel", ] try: if not is_speech_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __A = ["ASTFeatureExtractor"] if TYPE_CHECKING: from .configuration_audio_spectrogram_transformer import ( AUDIO_SPECTROGRAM_TRANSFORMER_PRETRAINED_CONFIG_ARCHIVE_MAP, ASTConfig, ) try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_audio_spectrogram_transformer import ( AUDIO_SPECTROGRAM_TRANSFORMER_PRETRAINED_MODEL_ARCHIVE_LIST, ASTForAudioClassification, ASTModel, ASTPreTrainedModel, ) try: if not is_speech_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .feature_extraction_audio_spectrogram_transformer import ASTFeatureExtractor else: import sys __A = _LazyModule(__name__, globals()["__file__"], _import_structure, module_spec=__spec__)
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from .glue import glue_convert_examples_to_features, glue_output_modes, glue_processors, glue_tasks_num_labels from .squad import SquadExample, SquadFeatures, SquadVaProcessor, SquadVaProcessor, squad_convert_examples_to_features from .utils import DataProcessor, InputExample, InputFeatures, SingleSentenceClassificationProcessor from .xnli import xnli_output_modes, xnli_processors, xnli_tasks_num_labels
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import argparse import os import pickle import sys import torch from transformers import TransfoXLConfig, TransfoXLLMHeadModel, load_tf_weights_in_transfo_xl from transformers.models.transfo_xl import tokenization_transfo_xl as data_utils from transformers.models.transfo_xl.tokenization_transfo_xl import CORPUS_NAME, VOCAB_FILES_NAMES from transformers.utils import CONFIG_NAME, WEIGHTS_NAME, logging logging.set_verbosity_info() # We do this to be able to load python 2 datasets pickles # See e.g. https://stackoverflow.com/questions/2121874/python-pickling-after-changing-a-modules-directory/2121918#2121918 __A = data_utils.TransfoXLTokenizer __A = data_utils.TransfoXLCorpus __A = data_utils __A = data_utils def lowerCamelCase_ ( UpperCamelCase__ : List[str] , UpperCamelCase__ : Optional[int] , UpperCamelCase__ : Union[str, Any] , UpperCamelCase__ : Optional[Any] ) -> Union[str, Any]: """simple docstring""" if transfo_xl_dataset_file: # Convert a pre-processed corpus (see original TensorFlow repo) with open(UpperCamelCase__ , 'rb' ) as fp: __lowerCamelCase = pickle.load(UpperCamelCase__ , encoding='latin1' ) # Save vocabulary and dataset cache as Dictionaries (should be better than pickles for the long-term) __lowerCamelCase = pytorch_dump_folder_path + '/' + VOCAB_FILES_NAMES['pretrained_vocab_file'] print(F"""Save vocabulary to {pytorch_vocab_dump_path}""" ) __lowerCamelCase = corpus.vocab.__dict__ torch.save(UpperCamelCase__ , UpperCamelCase__ ) __lowerCamelCase = corpus.__dict__ corpus_dict_no_vocab.pop('vocab' , UpperCamelCase__ ) __lowerCamelCase = pytorch_dump_folder_path + '/' + CORPUS_NAME print(F"""Save dataset to {pytorch_dataset_dump_path}""" ) torch.save(UpperCamelCase__ , UpperCamelCase__ ) if tf_checkpoint_path: # Convert a pre-trained TensorFlow model __lowerCamelCase = os.path.abspath(UpperCamelCase__ ) __lowerCamelCase = os.path.abspath(UpperCamelCase__ ) print(F"""Converting Transformer XL checkpoint from {tf_path} with config at {config_path}.""" ) # Initialise PyTorch model if transfo_xl_config_file == "": __lowerCamelCase = TransfoXLConfig() else: __lowerCamelCase = TransfoXLConfig.from_json_file(UpperCamelCase__ ) print(F"""Building PyTorch model from configuration: {config}""" ) __lowerCamelCase = TransfoXLLMHeadModel(UpperCamelCase__ ) __lowerCamelCase = load_tf_weights_in_transfo_xl(UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ ) # Save pytorch-model __lowerCamelCase = os.path.join(UpperCamelCase__ , UpperCamelCase__ ) __lowerCamelCase = os.path.join(UpperCamelCase__ , UpperCamelCase__ ) print(F"""Save PyTorch model to {os.path.abspath(UpperCamelCase__ )}""" ) torch.save(model.state_dict() , UpperCamelCase__ ) print(F"""Save configuration file to {os.path.abspath(UpperCamelCase__ )}""" ) with open(UpperCamelCase__ , 'w' , encoding='utf-8' ) as f: f.write(config.to_json_string() ) if __name__ == "__main__": __A = argparse.ArgumentParser() parser.add_argument( "--pytorch_dump_folder_path", default=None, type=str, required=True, help="Path to the folder to store the PyTorch model or dataset/vocab.", ) parser.add_argument( "--tf_checkpoint_path", default="", type=str, help="An optional path to a TensorFlow checkpoint path to be converted.", ) parser.add_argument( "--transfo_xl_config_file", default="", type=str, help=( "An optional config json file corresponding to the pre-trained BERT model. \n" "This specifies the model architecture." ), ) parser.add_argument( "--transfo_xl_dataset_file", default="", type=str, help="An optional dataset file to be converted in a vocabulary.", ) __A = parser.parse_args() convert_transfo_xl_checkpoint_to_pytorch( args.tf_checkpoint_path, args.transfo_xl_config_file, args.pytorch_dump_folder_path, args.transfo_xl_dataset_file, )
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"""simple docstring""" import gc import random import unittest import numpy as np import torch from diffusers import ( DDIMScheduler, KandinskyVaaControlnetPipeline, KandinskyVaaPriorPipeline, UNetaDConditionModel, VQModel, ) from diffusers.utils import floats_tensor, load_image, load_numpy, slow, torch_device from diffusers.utils.testing_utils import enable_full_determinism, require_torch_gpu from ..test_pipelines_common import PipelineTesterMixin, assert_mean_pixel_difference enable_full_determinism() class __snake_case ( __lowerCAmelCase , unittest.TestCase ): a__ = KandinskyVaaControlnetPipeline a__ = ["""image_embeds""", """negative_image_embeds""", """hint"""] a__ = ["""image_embeds""", """negative_image_embeds""", """hint"""] a__ = [ """generator""", """height""", """width""", """latents""", """guidance_scale""", """num_inference_steps""", """return_dict""", """guidance_scale""", """num_images_per_prompt""", """output_type""", """return_dict""", ] a__ = False @property def lowerCamelCase_ ( self) -> str: '''simple docstring''' return 32 @property def lowerCamelCase_ ( self) -> Tuple: '''simple docstring''' return 32 @property def lowerCamelCase_ ( self) -> Tuple: '''simple docstring''' return self.time_input_dim @property def lowerCamelCase_ ( self) -> str: '''simple docstring''' return self.time_input_dim * 4 @property def lowerCamelCase_ ( self) -> List[Any]: '''simple docstring''' return 1_00 @property def lowerCamelCase_ ( self) -> Any: '''simple docstring''' torch.manual_seed(0) a__: Optional[int] = { 'in_channels': 8, # Out channels is double in channels because predicts mean and variance 'out_channels': 8, 'addition_embed_type': 'image_hint', 'down_block_types': ('ResnetDownsampleBlock2D', 'SimpleCrossAttnDownBlock2D'), 'up_block_types': ('SimpleCrossAttnUpBlock2D', 'ResnetUpsampleBlock2D'), 'mid_block_type': 'UNetMidBlock2DSimpleCrossAttn', 'block_out_channels': (self.block_out_channels_a, self.block_out_channels_a * 2), 'layers_per_block': 1, 'encoder_hid_dim': self.text_embedder_hidden_size, 'encoder_hid_dim_type': 'image_proj', 'cross_attention_dim': self.cross_attention_dim, 'attention_head_dim': 4, 'resnet_time_scale_shift': 'scale_shift', 'class_embed_type': None, } a__: Any = UNetaDConditionModel(**lowerCamelCase__) return model @property def lowerCamelCase_ ( self) -> Union[str, Any]: '''simple docstring''' return { "block_out_channels": [32, 32, 64, 64], "down_block_types": [ "DownEncoderBlock2D", "DownEncoderBlock2D", "DownEncoderBlock2D", "AttnDownEncoderBlock2D", ], "in_channels": 3, "latent_channels": 4, "layers_per_block": 1, "norm_num_groups": 8, "norm_type": "spatial", "num_vq_embeddings": 12, "out_channels": 3, "up_block_types": ["AttnUpDecoderBlock2D", "UpDecoderBlock2D", "UpDecoderBlock2D", "UpDecoderBlock2D"], "vq_embed_dim": 4, } @property def lowerCamelCase_ ( self) -> List[str]: '''simple docstring''' torch.manual_seed(0) a__: Dict = VQModel(**self.dummy_movq_kwargs) return model def lowerCamelCase_ ( self) -> Optional[int]: '''simple docstring''' a__: List[Any] = self.dummy_unet a__: Tuple = self.dummy_movq a__: Tuple = DDIMScheduler( num_train_timesteps=10_00 , beta_schedule='linear' , beta_start=0.00085 , beta_end=0.012 , clip_sample=lowerCamelCase__ , set_alpha_to_one=lowerCamelCase__ , steps_offset=1 , prediction_type='epsilon' , thresholding=lowerCamelCase__ , ) a__: Any = { 'unet': unet, 'scheduler': scheduler, 'movq': movq, } return components def lowerCamelCase_ ( self , lowercase , lowercase=0) -> Union[str, Any]: '''simple docstring''' a__: Dict = floats_tensor((1, self.text_embedder_hidden_size) , rng=random.Random(lowerCamelCase__)).to(lowerCamelCase__) a__: Dict = floats_tensor((1, self.text_embedder_hidden_size) , rng=random.Random(seed + 1)).to( lowerCamelCase__) # create hint a__: List[str] = floats_tensor((1, 3, 64, 64) , rng=random.Random(lowerCamelCase__)).to(lowerCamelCase__) if str(lowerCamelCase__).startswith('mps'): a__: List[str] = torch.manual_seed(lowerCamelCase__) else: a__: str = torch.Generator(device=lowerCamelCase__).manual_seed(lowerCamelCase__) a__: int = { 'image_embeds': image_embeds, 'negative_image_embeds': negative_image_embeds, 'hint': hint, 'generator': generator, 'height': 64, 'width': 64, 'guidance_scale': 4.0, 'num_inference_steps': 2, 'output_type': 'np', } return inputs def lowerCamelCase_ ( self) -> str: '''simple docstring''' a__: int = 'cpu' a__: str = self.get_dummy_components() a__: int = self.pipeline_class(**lowerCamelCase__) a__: Optional[Any] = pipe.to(lowerCamelCase__) pipe.set_progress_bar_config(disable=lowerCamelCase__) a__: List[str] = pipe(**self.get_dummy_inputs(lowerCamelCase__)) a__: Dict = output.images a__: Optional[Any] = pipe( **self.get_dummy_inputs(lowerCamelCase__) , return_dict=lowerCamelCase__ , )[0] a__: List[Any] = image[0, -3:, -3:, -1] a__: Tuple = image_from_tuple[0, -3:, -3:, -1] assert image.shape == (1, 64, 64, 3) a__: List[Any] = np.array( [0.6959826, 0.868279, 0.7558092, 0.68769467, 0.85805804, 0.65977496, 0.44885302, 0.5959111, 0.4251595]) assert ( np.abs(image_slice.flatten() - expected_slice).max() < 1e-2 ), f' expected_slice {expected_slice}, but got {image_slice.flatten()}' assert ( np.abs(image_from_tuple_slice.flatten() - expected_slice).max() < 1e-2 ), f' expected_slice {expected_slice}, but got {image_from_tuple_slice.flatten()}' @slow @require_torch_gpu class __snake_case ( unittest.TestCase ): def lowerCamelCase_ ( self) -> List[Any]: '''simple docstring''' super().tearDown() gc.collect() torch.cuda.empty_cache() def lowerCamelCase_ ( self) -> Any: '''simple docstring''' a__: Dict = load_numpy( 'https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main' '/kandinskyv22/kandinskyv22_controlnet_robotcat_fp16.npy') a__: Any = load_image( 'https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main' '/kandinskyv22/hint_image_cat.png') a__: Any = torch.from_numpy(np.array(lowerCamelCase__)).float() / 2_55.0 a__: Dict = hint.permute(2 , 0 , 1).unsqueeze(0) a__: Optional[int] = KandinskyVaaPriorPipeline.from_pretrained( 'kandinsky-community/kandinsky-2-2-prior' , torch_dtype=torch.floataa) pipe_prior.to(lowerCamelCase__) a__: Any = KandinskyVaaControlnetPipeline.from_pretrained( 'kandinsky-community/kandinsky-2-2-controlnet-depth' , torch_dtype=torch.floataa) a__: Optional[Any] = pipeline.to(lowerCamelCase__) pipeline.set_progress_bar_config(disable=lowerCamelCase__) a__: Tuple = 'A robot, 4k photo' a__: Optional[int] = torch.Generator(device='cuda').manual_seed(0) a__ , a__: Optional[int] = pipe_prior( lowerCamelCase__ , generator=lowerCamelCase__ , num_inference_steps=5 , negative_prompt='' , ).to_tuple() a__: Union[str, Any] = torch.Generator(device='cuda').manual_seed(0) a__: Optional[int] = pipeline( image_embeds=lowerCamelCase__ , negative_image_embeds=lowerCamelCase__ , hint=lowerCamelCase__ , generator=lowerCamelCase__ , num_inference_steps=1_00 , output_type='np' , ) a__: List[str] = output.images[0] assert image.shape == (5_12, 5_12, 3) assert_mean_pixel_difference(lowerCamelCase__ , lowerCamelCase__)
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import argparse import shutil from pathlib import Path from tqdm import tqdm from transformers import AutoTokenizer def lowerCamelCase_ ( UpperCamelCase__ : List[Any] , UpperCamelCase__ : Optional[int] , UpperCamelCase__ : str , UpperCamelCase__ : Any=1024 ) -> Dict: """simple docstring""" __lowerCamelCase , __lowerCamelCase = [], [] __lowerCamelCase = list(zip(UpperCamelCase__ , UpperCamelCase__ ) ) __lowerCamelCase , __lowerCamelCase = sorted_examples[0] def is_too_big(UpperCamelCase__ : List[str] ): return tok(UpperCamelCase__ , return_tensors='pt' ).input_ids.shape[1] > max_tokens for src, tgt in tqdm(sorted_examples[1:] ): __lowerCamelCase = new_src + ' ' + src __lowerCamelCase = new_tgt + ' ' + tgt if is_too_big(UpperCamelCase__ ) or is_too_big(UpperCamelCase__ ): # cant fit, finalize example finished_src.append(UpperCamelCase__ ) finished_tgt.append(UpperCamelCase__ ) __lowerCamelCase , __lowerCamelCase = src, tgt else: # can fit, keep adding __lowerCamelCase , __lowerCamelCase = cand_src, cand_tgt # cleanup if new_src: assert new_tgt finished_src.append(UpperCamelCase__ ) finished_tgt.append(UpperCamelCase__ ) return finished_src, finished_tgt def lowerCamelCase_ ( UpperCamelCase__ : str , UpperCamelCase__ : Path , UpperCamelCase__ : Optional[int] , UpperCamelCase__ : str ) -> Optional[int]: """simple docstring""" __lowerCamelCase = Path(UpperCamelCase__ ) save_path.mkdir(exist_ok=UpperCamelCase__ ) for split in ["train"]: __lowerCamelCase , __lowerCamelCase = data_dir / F"""{split}.source""", data_dir / F"""{split}.target""" __lowerCamelCase = [x.rstrip() for x in Path(UpperCamelCase__ ).open().readlines()] __lowerCamelCase = [x.rstrip() for x in Path(UpperCamelCase__ ).open().readlines()] __lowerCamelCase , __lowerCamelCase = pack_examples(UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ ) print(F"""packed {split} split from {len(UpperCamelCase__ )} examples -> {len(UpperCamelCase__ )}.""" ) Path(save_path / F"""{split}.source""" ).open('w' ).write('\n'.join(UpperCamelCase__ ) ) Path(save_path / F"""{split}.target""" ).open('w' ).write('\n'.join(UpperCamelCase__ ) ) for split in ["val", "test"]: __lowerCamelCase , __lowerCamelCase = data_dir / F"""{split}.source""", data_dir / F"""{split}.target""" shutil.copyfile(UpperCamelCase__ , save_path / F"""{split}.source""" ) shutil.copyfile(UpperCamelCase__ , save_path / F"""{split}.target""" ) def lowerCamelCase_ ( ) -> List[str]: """simple docstring""" __lowerCamelCase = argparse.ArgumentParser() parser.add_argument('--tok_name' , type=UpperCamelCase__ , help='like facebook/bart-large-cnn,t5-base, etc.' ) parser.add_argument('--max_seq_len' , type=UpperCamelCase__ , default=128 ) parser.add_argument('--data_dir' , type=UpperCamelCase__ ) parser.add_argument('--save_path' , type=UpperCamelCase__ ) __lowerCamelCase = parser.parse_args() __lowerCamelCase = AutoTokenizer.from_pretrained(args.tok_name ) return pack_data_dir(UpperCamelCase__ , Path(args.data_dir ) , args.max_seq_len , args.save_path ) if __name__ == "__main__": packer_cli()
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"""simple docstring""" import argparse import glob import importlib.util import os import re import black from doc_builder.style_doc import style_docstrings_in_code # All paths are set with the intent you should run this script from the root of the repo with the command # python utils/check_copies.py _lowercase : Dict = 'src/diffusers' _lowercase : Any = '.' # This is to make sure the diffusers module imported is the one in the repo. _lowercase : List[Any] = importlib.util.spec_from_file_location( 'diffusers', os.path.join(DIFFUSERS_PATH, '__init__.py'), submodule_search_locations=[DIFFUSERS_PATH], ) _lowercase : int = spec.loader.load_module() def lowercase__ ( snake_case_ :Optional[Any] , snake_case_ :Optional[Any] ): return line.startswith(UpperCamelCase__ ) or len(UpperCamelCase__ ) <= 1 or re.search(r'''^\s*\)(\s*->.*:|:)\s*$''' , UpperCamelCase__ ) is not None def lowercase__ ( snake_case_ :Tuple ): __UpperCAmelCase = object_name.split('''.''' ) __UpperCAmelCase = 0 # First let's find the module where our object lives. __UpperCAmelCase = parts[i] while i < len(UpperCamelCase__ ) and not os.path.isfile(os.path.join(UpperCamelCase__ , F'''{module}.py''' ) ): i += 1 if i < len(UpperCamelCase__ ): __UpperCAmelCase = os.path.join(UpperCamelCase__ , parts[i] ) if i >= len(UpperCamelCase__ ): raise ValueError(F'''`object_name` should begin with the name of a module of diffusers but got {object_name}.''' ) with open(os.path.join(UpperCamelCase__ , F'''{module}.py''' ) , '''r''' , encoding='''utf-8''' , newline='''\n''' ) as f: __UpperCAmelCase = f.readlines() # Now let's find the class / func in the code! __UpperCAmelCase = '''''' __UpperCAmelCase = 0 for name in parts[i + 1 :]: while ( line_index < len(UpperCamelCase__ ) and re.search(rF'''^{indent}(class|def)\s+{name}(\(|\:)''' , lines[line_index] ) is None ): line_index += 1 indent += " " line_index += 1 if line_index >= len(UpperCamelCase__ ): raise ValueError(F''' {object_name} does not match any function or class in {module}.''' ) # We found the beginning of the class / func, now let's find the end (when the indent diminishes). __UpperCAmelCase = line_index while line_index < len(UpperCamelCase__ ) and _should_continue(lines[line_index] , UpperCamelCase__ ): line_index += 1 # Clean up empty lines at the end (if any). while len(lines[line_index - 1] ) <= 1: line_index -= 1 __UpperCAmelCase = lines[start_index:line_index] return "".join(UpperCamelCase__ ) _lowercase : List[str] = re.compile(r'^(\s*)#\s*Copied from\s+diffusers\.(\S+\.\S+)\s*($|\S.*$)') _lowercase : List[Any] = re.compile(r'^\s*(\S+)->(\S+)(\s+.*|$)') _lowercase : List[Any] = re.compile(r'<FILL\s+[^>]*>') def lowercase__ ( snake_case_ :int ): __UpperCAmelCase = code.split('''\n''' ) __UpperCAmelCase = 0 while idx < len(UpperCamelCase__ ) and len(lines[idx] ) == 0: idx += 1 if idx < len(UpperCamelCase__ ): return re.search(r'''^(\s*)\S''' , lines[idx] ).groups()[0] return "" def lowercase__ ( snake_case_ :Tuple ): __UpperCAmelCase = len(get_indent(UpperCamelCase__ ) ) > 0 if has_indent: __UpperCAmelCase = F'''class Bla:\n{code}''' __UpperCAmelCase = black.Mode(target_versions={black.TargetVersion.PYaa} , line_length=119 , preview=UpperCamelCase__ ) __UpperCAmelCase = black.format_str(UpperCamelCase__ , mode=UpperCamelCase__ ) __UpperCAmelCase , __UpperCAmelCase = style_docstrings_in_code(UpperCamelCase__ ) return result[len('''class Bla:\n''' ) :] if has_indent else result def lowercase__ ( snake_case_ :Optional[Any] , snake_case_ :Tuple=False ): with open(UpperCamelCase__ , '''r''' , encoding='''utf-8''' , newline='''\n''' ) as f: __UpperCAmelCase = f.readlines() __UpperCAmelCase = [] __UpperCAmelCase = 0 # Not a for loop cause `lines` is going to change (if `overwrite=True`). while line_index < len(UpperCamelCase__ ): __UpperCAmelCase = _re_copy_warning.search(lines[line_index] ) if search is None: line_index += 1 continue # There is some copied code here, let's retrieve the original. __UpperCAmelCase , __UpperCAmelCase , __UpperCAmelCase = search.groups() __UpperCAmelCase = find_code_in_diffusers(UpperCamelCase__ ) __UpperCAmelCase = get_indent(UpperCamelCase__ ) __UpperCAmelCase = line_index + 1 if indent == theoretical_indent else line_index + 2 __UpperCAmelCase = theoretical_indent __UpperCAmelCase = start_index # Loop to check the observed code, stop when indentation diminishes or if we see a End copy comment. __UpperCAmelCase = True while line_index < len(UpperCamelCase__ ) and should_continue: line_index += 1 if line_index >= len(UpperCamelCase__ ): break __UpperCAmelCase = lines[line_index] __UpperCAmelCase = _should_continue(UpperCamelCase__ , UpperCamelCase__ ) and re.search(F'''^{indent}# End copy''' , UpperCamelCase__ ) is None # Clean up empty lines at the end (if any). while len(lines[line_index - 1] ) <= 1: line_index -= 1 __UpperCAmelCase = lines[start_index:line_index] __UpperCAmelCase = ''''''.join(UpperCamelCase__ ) # Remove any nested `Copied from` comments to avoid circular copies __UpperCAmelCase = [line for line in theoretical_code.split('''\n''' ) if _re_copy_warning.search(UpperCamelCase__ ) is None] __UpperCAmelCase = '''\n'''.join(UpperCamelCase__ ) # Before comparing, use the `replace_pattern` on the original code. if len(UpperCamelCase__ ) > 0: __UpperCAmelCase = replace_pattern.replace('''with''' , '''''' ).split(''',''' ) __UpperCAmelCase = [_re_replace_pattern.search(UpperCamelCase__ ) for p in patterns] for pattern in patterns: if pattern is None: continue __UpperCAmelCase , __UpperCAmelCase , __UpperCAmelCase = pattern.groups() __UpperCAmelCase = re.sub(UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ ) if option.strip() == "all-casing": __UpperCAmelCase = re.sub(obja.lower() , obja.lower() , UpperCamelCase__ ) __UpperCAmelCase = re.sub(obja.upper() , obja.upper() , UpperCamelCase__ ) # Blackify after replacement. To be able to do that, we need the header (class or function definition) # from the previous line __UpperCAmelCase = blackify(lines[start_index - 1] + theoretical_code ) __UpperCAmelCase = theoretical_code[len(lines[start_index - 1] ) :] # Test for a diff and act accordingly. if observed_code != theoretical_code: diffs.append([object_name, start_index] ) if overwrite: __UpperCAmelCase = lines[:start_index] + [theoretical_code] + lines[line_index:] __UpperCAmelCase = start_index + 1 if overwrite and len(UpperCamelCase__ ) > 0: # Warn the user a file has been modified. print(F'''Detected changes, rewriting {filename}.''' ) with open(UpperCamelCase__ , '''w''' , encoding='''utf-8''' , newline='''\n''' ) as f: f.writelines(UpperCamelCase__ ) return diffs def lowercase__ ( snake_case_ :bool = False ): __UpperCAmelCase = glob.glob(os.path.join(UpperCamelCase__ , '''**/*.py''' ) , recursive=UpperCamelCase__ ) __UpperCAmelCase = [] for filename in all_files: __UpperCAmelCase = is_copy_consistent(UpperCamelCase__ , UpperCamelCase__ ) diffs += [F'''- {filename}: copy does not match {d[0]} at line {d[1]}''' for d in new_diffs] if not overwrite and len(UpperCamelCase__ ) > 0: __UpperCAmelCase = '''\n'''.join(UpperCamelCase__ ) raise Exception( '''Found the following copy inconsistencies:\n''' + diff + '''\nRun `make fix-copies` or `python utils/check_copies.py --fix_and_overwrite` to fix them.''' ) if __name__ == "__main__": _lowercase : Any = argparse.ArgumentParser() parser.add_argument('--fix_and_overwrite', action='store_true', help='Whether to fix inconsistencies.') _lowercase : Union[str, Any] = parser.parse_args() check_copies(args.fix_and_overwrite)
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import argparse import fairseq import torch from torch import nn from transformers import ( MBartaaTokenizer, MBartConfig, MBartForCausalLM, SpeechEncoderDecoderConfig, SpeechEncoderDecoderModel, WavaVecaConfig, WavaVecaFeatureExtractor, WavaVecaModel, logging, ) logging.set_verbosity_info() __A = logging.get_logger(__name__) __A = { "post_extract_proj": "feature_projection.projection", "encoder.pos_conv.0": "encoder.pos_conv_embed.conv", "self_attn.k_proj": "encoder.layers.*.attention.k_proj", "self_attn.v_proj": "encoder.layers.*.attention.v_proj", "self_attn.q_proj": "encoder.layers.*.attention.q_proj", "self_attn.out_proj": "encoder.layers.*.attention.out_proj", "self_attn_layer_norm": "encoder.layers.*.layer_norm", "fc1": "encoder.layers.*.feed_forward.intermediate_dense", "fc2": "encoder.layers.*.feed_forward.output_dense", "final_layer_norm": "encoder.layers.*.final_layer_norm", "encoder.layer_norm": "encoder.layer_norm", "w2v_model.layer_norm": "feature_projection.layer_norm", "quantizer.weight_proj": "quantizer.weight_proj", "quantizer.vars": "quantizer.codevectors", "project_q": "project_q", "final_proj": "project_hid", "w2v_encoder.proj": "lm_head", "mask_emb": "masked_spec_embed", } __A = [ "lm_head", "quantizer.weight_proj", "quantizer.codevectors", "project_q", "project_hid", ] def lowerCamelCase_ ( UpperCamelCase__ : Any , UpperCamelCase__ : Any , UpperCamelCase__ : Optional[Any] , UpperCamelCase__ : Union[str, Any] , UpperCamelCase__ : Optional[int] ) -> Tuple: """simple docstring""" for attribute in key.split('.' ): __lowerCamelCase = getattr(UpperCamelCase__ , UpperCamelCase__ ) if weight_type is not None: __lowerCamelCase = getattr(UpperCamelCase__ , UpperCamelCase__ ).shape else: __lowerCamelCase = hf_pointer.shape assert hf_shape == value.shape, ( F"""Shape of hf {key + '.' + weight_type if weight_type is not None else ''} is {hf_shape}, but should be""" F""" {value.shape} for {full_name}""" ) if weight_type == "weight": __lowerCamelCase = value elif weight_type == "weight_g": __lowerCamelCase = value elif weight_type == "weight_v": __lowerCamelCase = value elif weight_type == "bias": __lowerCamelCase = value else: __lowerCamelCase = value logger.info(F"""{key + '.' + weight_type if weight_type is not None else ''} was initialized from {full_name}.""" ) def lowerCamelCase_ ( UpperCamelCase__ : Optional[Any] , UpperCamelCase__ : Tuple ) -> Optional[Any]: """simple docstring""" __lowerCamelCase = [] __lowerCamelCase = fairseq_model.state_dict() __lowerCamelCase = hf_model.feature_extractor __lowerCamelCase = hf_model.adapter for name, value in fairseq_dict.items(): __lowerCamelCase = False if "conv_layers" in name: load_conv_layer( UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ , hf_model.config.feat_extract_norm == 'group' , ) __lowerCamelCase = True elif any(x in name for x in ['adaptor', 'w2v_encoder.proj.', 'w2v_proj_ln.'] ): load_adapter(UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ ) __lowerCamelCase = True else: for key, mapped_key in MAPPING.items(): if key in name or key.split('w2v_model.' )[-1] == name.split('.' )[0]: __lowerCamelCase = True if "*" in mapped_key: __lowerCamelCase = name.split(UpperCamelCase__ )[0].split('.' )[-2] __lowerCamelCase = mapped_key.replace('*' , UpperCamelCase__ ) if "weight_g" in name: __lowerCamelCase = 'weight_g' elif "weight_v" in name: __lowerCamelCase = 'weight_v' elif "bias" in name: __lowerCamelCase = 'bias' elif "weight" in name: __lowerCamelCase = 'weight' else: __lowerCamelCase = None set_recursively(UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ ) continue if not is_used: unused_weights.append(UpperCamelCase__ ) logger.warning(F"""Unused weights: {unused_weights}""" ) def lowerCamelCase_ ( UpperCamelCase__ : Dict , UpperCamelCase__ : Any , UpperCamelCase__ : str , UpperCamelCase__ : Tuple , UpperCamelCase__ : Tuple ) -> int: """simple docstring""" __lowerCamelCase = full_name.split('conv_layers.' )[-1] __lowerCamelCase = name.split('.' ) __lowerCamelCase = int(items[0] ) __lowerCamelCase = int(items[1] ) if type_id == 0: if "bias" in name: assert value.shape == feature_extractor.conv_layers[layer_id].conv.bias.data.shape, ( F"""{full_name} has size {value.shape}, but""" F""" {feature_extractor.conv_layers[layer_id].conv.bias.data.shape} was found.""" ) __lowerCamelCase = value logger.info(F"""Feat extract conv layer {layer_id} was initialized from {full_name}.""" ) elif "weight" in name: assert value.shape == feature_extractor.conv_layers[layer_id].conv.weight.data.shape, ( F"""{full_name} has size {value.shape}, but""" F""" {feature_extractor.conv_layers[layer_id].conv.weight.data.shape} was found.""" ) __lowerCamelCase = value logger.info(F"""Feat extract conv layer {layer_id} was initialized from {full_name}.""" ) elif (type_id == 2 and not use_group_norm) or (type_id == 2 and layer_id == 0 and use_group_norm): if "bias" in name: assert value.shape == feature_extractor.conv_layers[layer_id].layer_norm.bias.data.shape, ( F"""{full_name} has size {value.shape}, but {feature_extractor[layer_id].layer_norm.bias.data.shape} was""" " found." ) __lowerCamelCase = value logger.info(F"""Feat extract layer norm weight of layer {layer_id} was initialized from {full_name}.""" ) elif "weight" in name: assert value.shape == feature_extractor.conv_layers[layer_id].layer_norm.weight.data.shape, ( F"""{full_name} has size {value.shape}, but""" F""" {feature_extractor[layer_id].layer_norm.weight.data.shape} was found.""" ) __lowerCamelCase = value logger.info(F"""Feat extract layer norm weight of layer {layer_id} was initialized from {full_name}.""" ) else: unused_weights.append(UpperCamelCase__ ) def lowerCamelCase_ ( UpperCamelCase__ : Tuple , UpperCamelCase__ : Optional[Any] , UpperCamelCase__ : Any , UpperCamelCase__ : int ) -> Union[str, Any]: """simple docstring""" __lowerCamelCase = full_name.split('adaptor.' )[-1] __lowerCamelCase = name.split('.' ) if items[1].isdigit(): __lowerCamelCase = int(items[1] ) else: __lowerCamelCase = None if "adaptor" not in full_name: if "proj_ln" in full_name: # has to be layer norm if "bias" in name: assert ( value.shape == adapter.proj_layer_norm.bias.data.shape ), F"""{full_name} has size {value.shape}, but {adapter.proj_layer_norm.bias.data.shape} was found.""" __lowerCamelCase = value logger.info(F"""Adapter proj layer norm bias was initialized from {full_name}.""" ) if "weight" in name: assert ( value.shape == adapter.proj_layer_norm.weight.data.shape ), F"""{full_name} has size {value.shape}, but {adapter.proj_layer_norm.weight.data.shape} was found.""" __lowerCamelCase = value else: # has to be projection layer if "bias" in name: assert ( value.shape == adapter.proj.bias.data.shape ), F"""{full_name} has size {value.shape}, but {adapter.proj.bias.data.shape} was found.""" __lowerCamelCase = value logger.info(F"""Adapter proj layer bias was initialized from {full_name}.""" ) if "weight" in name: assert ( value.shape == adapter.proj.weight.data.shape ), F"""{full_name} has size {value.shape}, but {adapter.proj.weight.data.shape} was found.""" __lowerCamelCase = value logger.info(F"""Adapter proj layer weight was initialized from {full_name}.""" ) elif isinstance(UpperCamelCase__ , UpperCamelCase__ ): if "bias" in name: assert ( value.shape == adapter.layers[layer_id].conv.bias.data.shape ), F"""{full_name} has size {value.shape}, but {adapter.layers[layer_id].conv.bias.data.shape} was found.""" __lowerCamelCase = value logger.info(F"""Adapter layer {layer_id} bias was initialized from {full_name}.""" ) elif "weight" in name: assert ( value.shape == adapter.layers[layer_id].conv.weight.data.shape ), F"""{full_name} has size {value.shape}, but {adapter.layers[layer_id].conv.weight.data.shape} was found.""" __lowerCamelCase = value logger.info(F"""Adapter layer {layer_id} bias was initialized from {full_name}.""" ) else: unused_weights.append(UpperCamelCase__ ) def lowerCamelCase_ ( UpperCamelCase__ : Tuple ) -> Tuple: """simple docstring""" __lowerCamelCase , __lowerCamelCase = emb.weight.shape __lowerCamelCase = nn.Linear(UpperCamelCase__ , UpperCamelCase__ , bias=UpperCamelCase__ ) __lowerCamelCase = emb.weight.data return lin_layer @torch.no_grad() def lowerCamelCase_ ( UpperCamelCase__ : List[str] , UpperCamelCase__ : List[Any] , UpperCamelCase__ : Union[str, Any] , UpperCamelCase__ : Dict , UpperCamelCase__ : List[str] , UpperCamelCase__ : Union[str, Any] , UpperCamelCase__ : Optional[int] , UpperCamelCase__ : Union[str, Any] , UpperCamelCase__ : Optional[Any] , UpperCamelCase__ : str , UpperCamelCase__ : Optional[Any] , ) -> str: """simple docstring""" __lowerCamelCase = WavaVecaConfig.from_pretrained( UpperCamelCase__ , add_adapter=UpperCamelCase__ , adapter_stride=UpperCamelCase__ , adapter_kernel_size=UpperCamelCase__ , use_auth_token=UpperCamelCase__ , output_hidden_size=UpperCamelCase__ , ) __lowerCamelCase = MBartConfig.from_pretrained(UpperCamelCase__ ) # load model __lowerCamelCase , __lowerCamelCase , __lowerCamelCase = fairseq.checkpoint_utils.load_model_ensemble_and_task( [checkpoint_path] , arg_overrides={ 'config_yaml': config_yaml_path, 'data': '/'.join(dict_path.split('/' )[:-1] ), 'w2v_path': checkpoint_path, 'load_pretrained_decoder_from': None, } , ) __lowerCamelCase = model[0].eval() # load feature extractor __lowerCamelCase = WavaVecaFeatureExtractor.from_pretrained(UpperCamelCase__ , use_auth_token=UpperCamelCase__ ) # set weights for wav2vec2 encoder __lowerCamelCase = WavaVecaModel(UpperCamelCase__ ) recursively_load_weights_wavaveca(model.encoder , UpperCamelCase__ ) # load decoder weights __lowerCamelCase = MBartForCausalLM(UpperCamelCase__ ) __lowerCamelCase , __lowerCamelCase = hf_decoder.model.decoder.load_state_dict(model.decoder.state_dict() , strict=UpperCamelCase__ ) logger.warning(F"""The following keys are missing when loading the decoder weights: {missing_keys}""" ) logger.warning(F"""The following keys are unexpected when loading the decoder weights: {unexpected_keys}""" ) __lowerCamelCase = SpeechEncoderDecoderModel(encoder=UpperCamelCase__ , decoder=UpperCamelCase__ ) __lowerCamelCase = False __lowerCamelCase = MBartaaTokenizer(UpperCamelCase__ ) tokenizer.save_pretrained(UpperCamelCase__ ) __lowerCamelCase = hf_wavavec.config.to_dict() __lowerCamelCase = tokenizer.pad_token_id __lowerCamelCase = tokenizer.bos_token_id __lowerCamelCase = tokenizer.eos_token_id __lowerCamelCase = 'mbart50' __lowerCamelCase = 'wav2vec2' __lowerCamelCase = tokenizer.eos_token_id __lowerCamelCase = 25_0004 __lowerCamelCase = tokenizer.eos_token_id __lowerCamelCase = SpeechEncoderDecoderConfig.from_dict(UpperCamelCase__ ) hf_wavavec.save_pretrained(UpperCamelCase__ ) feature_extractor.save_pretrained(UpperCamelCase__ ) 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 fairseq checkpoint") parser.add_argument("--dict_path", default=None, type=str, help="Path to dict of fine-tuned model") parser.add_argument("--config_yaml_path", default=None, type=str, help="Path to yaml file of fine-tuned model") parser.add_argument( "--encoder_config_path", default="facebook/wav2vec2-xls-r-1b", type=str, help="Path to hf encoder wav2vec2 checkpoint config", ) parser.add_argument( "--decoder_config_path", default="facebook/mbart-large-50-one-to-many-mmt", type=str, help="Path to hf decoder checkpoint config", ) parser.add_argument("--add_adapter", default=True, type=bool, help="whethere to add model adapter layers") parser.add_argument("--adapter_stride", default=2, type=int, help="stride of adapter layers") parser.add_argument("--adapter_kernel_size", default=3, type=int, help="kernel size of adapter layers") parser.add_argument("--encoder_output_dim", default=10_24, type=int, help="encoder output dim") parser.add_argument("--start_token_id", default=25_00_04, type=int, help="`decoder_start_token_id` of model config") __A = parser.parse_args() convert_wavaveca_checkpoint( args.checkpoint_path, args.pytorch_dump_folder_path, args.dict_path, args.config_yaml_path, encoder_config_path=args.encoder_config_path, decoder_config_path=args.decoder_config_path, add_adapter=args.add_adapter, adapter_kernel_size=args.adapter_kernel_size, adapter_stride=args.adapter_stride, decoder_start_token_id=args.start_token_id, encoder_output_dim=args.encoder_output_dim, )
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'''simple docstring''' import argparse import shutil from pathlib import Path from tqdm import tqdm from transformers import AutoTokenizer def UpperCAmelCase_ (__a : List[Any] , __a : Optional[int] , __a : str , __a : Any=1_0_2_4 ): """simple docstring""" _a, _a : Any = [], [] _a : List[str] = list(zip(UpperCamelCase__ , UpperCamelCase__ ) ) _a, _a : Optional[Any] = sorted_examples[0] def is_too_big(__a : List[str] ): return tok(UpperCamelCase__ , return_tensors='pt' ).input_ids.shape[1] > max_tokens for src, tgt in tqdm(sorted_examples[1:] ): _a : List[Any] = new_src + ' ' + src _a : Optional[int] = new_tgt + ' ' + tgt if is_too_big(UpperCamelCase__ ) or is_too_big(UpperCamelCase__ ): # cant fit, finalize example finished_src.append(UpperCamelCase__ ) finished_tgt.append(UpperCamelCase__ ) _a, _a : Dict = src, tgt else: # can fit, keep adding _a, _a : List[str] = cand_src, cand_tgt # cleanup if new_src: assert new_tgt finished_src.append(UpperCamelCase__ ) finished_tgt.append(UpperCamelCase__ ) return finished_src, finished_tgt def UpperCAmelCase_ (__a : str , __a : Path , __a : Optional[int] , __a : str ): """simple docstring""" _a : Dict = Path(UpperCamelCase__ ) save_path.mkdir(exist_ok=UpperCamelCase__ ) for split in ["train"]: _a, _a : List[str] = data_dir / f"""{split}.source""", data_dir / f"""{split}.target""" _a : Tuple = [x.rstrip() for x in Path(UpperCamelCase__ ).open().readlines()] _a : Union[str, Any] = [x.rstrip() for x in Path(UpperCamelCase__ ).open().readlines()] _a, _a : Optional[int] = pack_examples(UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ ) print(f"""packed {split} split from {len(UpperCamelCase__ )} examples -> {len(UpperCamelCase__ )}.""" ) Path(save_path / f"""{split}.source""" ).open('w' ).write('\n'.join(UpperCamelCase__ ) ) Path(save_path / f"""{split}.target""" ).open('w' ).write('\n'.join(UpperCamelCase__ ) ) for split in ["val", "test"]: _a, _a : Union[str, Any] = data_dir / f"""{split}.source""", data_dir / f"""{split}.target""" shutil.copyfile(UpperCamelCase__ , save_path / f"""{split}.source""" ) shutil.copyfile(UpperCamelCase__ , save_path / f"""{split}.target""" ) def UpperCAmelCase_ (): """simple docstring""" _a : Any = argparse.ArgumentParser() parser.add_argument('--tok_name' , type=UpperCamelCase__ , help='like facebook/bart-large-cnn,t5-base, etc.' ) parser.add_argument('--max_seq_len' , type=UpperCamelCase__ , default=1_2_8 ) parser.add_argument('--data_dir' , type=UpperCamelCase__ ) parser.add_argument('--save_path' , type=UpperCamelCase__ ) _a : Optional[int] = parser.parse_args() _a : Optional[Any] = AutoTokenizer.from_pretrained(args.tok_name ) return pack_data_dir(UpperCamelCase__ , Path(args.data_dir ) , args.max_seq_len , args.save_path ) if __name__ == "__main__": packer_cli()
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def lowerCamelCase_ ( UpperCamelCase__ : int ) -> bool: """simple docstring""" return number & 1 == 0 if __name__ == "__main__": import doctest doctest.testmod()
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def UpperCAmelCase_ ( __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE ): lowercase = [0 for i in range(r + 1 )] # nc0 = 1 lowercase = 1 for i in range(1 , n + 1 ): # to compute current row from previous row. lowercase = min(UpperCamelCase__ , UpperCamelCase__ ) while j > 0: c[j] += c[j - 1] j -= 1 return c[r] print(binomial_coefficient(n=10, r=5))
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from typing import List, Optional import numpy as np from ...processing_utils import ProcessorMixin from ...utils import to_numpy class __lowerCAmelCase ( __magic_name__ ): """simple docstring""" snake_case_ = '''EncodecFeatureExtractor''' snake_case_ = ('''T5Tokenizer''', '''T5TokenizerFast''') def __init__( self , lowerCamelCase__ , lowerCamelCase__ ) -> int: '''simple docstring''' super().__init__(lowerCamelCase__ , lowerCamelCase__ ) __lowerCamelCase = self.feature_extractor __lowerCamelCase = False def lowercase_ ( self , lowerCamelCase__=None , lowerCamelCase__=None , lowerCamelCase__=True ) -> List[Any]: '''simple docstring''' return self.tokenizer.get_decoder_prompt_ids(task=lowerCamelCase__ , language=lowerCamelCase__ , no_timestamps=lowerCamelCase__ ) def __call__( self , *lowerCamelCase__ , **lowerCamelCase__ ) -> Dict: '''simple docstring''' # For backward compatibility if self._in_target_context_manager: return self.current_processor(*lowerCamelCase__ , **lowerCamelCase__ ) __lowerCamelCase = kwargs.pop('audio' , lowerCamelCase__ ) __lowerCamelCase = kwargs.pop('sampling_rate' , lowerCamelCase__ ) __lowerCamelCase = kwargs.pop('text' , lowerCamelCase__ ) if len(lowerCamelCase__ ) > 0: __lowerCamelCase = args[0] __lowerCamelCase = args[1:] if audio is None and text is None: raise ValueError('You need to specify either an `audio` or `text` input to process.' ) if text is not None: __lowerCamelCase = self.tokenizer(lowerCamelCase__ , **lowerCamelCase__ ) if audio is not None: __lowerCamelCase = self.feature_extractor(lowerCamelCase__ , *lowerCamelCase__ , sampling_rate=lowerCamelCase__ , **lowerCamelCase__ ) if audio is None: return inputs elif text is None: return audio_inputs else: __lowerCamelCase = audio_inputs['input_values'] if "padding_mask" in audio_inputs: __lowerCamelCase = audio_inputs['padding_mask'] return inputs def lowercase_ ( self , *lowerCamelCase__ , **lowerCamelCase__ ) -> Union[str, Any]: '''simple docstring''' __lowerCamelCase = kwargs.pop('audio' , lowerCamelCase__ ) __lowerCamelCase = kwargs.pop('padding_mask' , lowerCamelCase__ ) if len(lowerCamelCase__ ) > 0: __lowerCamelCase = args[0] __lowerCamelCase = args[1:] if audio_values is not None: return self._decode_audio(lowerCamelCase__ , padding_mask=lowerCamelCase__ ) else: return self.tokenizer.batch_decode(*lowerCamelCase__ , **lowerCamelCase__ ) def lowercase_ ( self , *lowerCamelCase__ , **lowerCamelCase__ ) -> List[Any]: '''simple docstring''' return self.tokenizer.decode(*lowerCamelCase__ , **lowerCamelCase__ ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ = None ) -> List[np.ndarray]: '''simple docstring''' __lowerCamelCase = to_numpy(lowerCamelCase__ ) __lowerCamelCase , __lowerCamelCase , __lowerCamelCase = audio_values.shape if padding_mask is None: return list(lowerCamelCase__ ) __lowerCamelCase = to_numpy(lowerCamelCase__ ) # match the sequence length of the padding mask to the generated audio arrays by padding with the **non-padding** # token (so that the generated audio values are **not** treated as padded tokens) __lowerCamelCase = seq_len - padding_mask.shape[-1] __lowerCamelCase = 1 - self.feature_extractor.padding_value __lowerCamelCase = np.pad(lowerCamelCase__ , ((0, 0), (0, difference)) , 'constant' , constant_values=lowerCamelCase__ ) __lowerCamelCase = audio_values.tolist() for i in range(lowerCamelCase__ ): __lowerCamelCase = np.asarray(audio_values[i] )[ padding_mask[i][None, :] != self.feature_extractor.padding_value ] __lowerCamelCase = sliced_audio.reshape(lowerCamelCase__ , -1 ) return audio_values
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import math import os import unittest from transformers import MegatronBertConfig, is_torch_available from transformers.models.auto import get_values from transformers.testing_utils import require_sentencepiece, require_tokenizers, require_torch, slow, torch_device from ...test_configuration_common import ConfigTester from ...test_modeling_common import ModelTesterMixin, ids_tensor, random_attention_mask from ...test_pipeline_mixin import PipelineTesterMixin if is_torch_available(): import torch from transformers import ( MODEL_FOR_PRETRAINING_MAPPING, MegatronBertForCausalLM, MegatronBertForMaskedLM, MegatronBertForMultipleChoice, MegatronBertForNextSentencePrediction, MegatronBertForPreTraining, MegatronBertForQuestionAnswering, MegatronBertForSequenceClassification, MegatronBertForTokenClassification, MegatronBertModel, ) class __magic_name__ : def __init__( self , __snake_case , __snake_case=13 , __snake_case=7 , __snake_case=True , __snake_case=True , __snake_case=True , __snake_case=True , __snake_case=99 , __snake_case=64 , __snake_case=32 , __snake_case=5 , __snake_case=4 , __snake_case=37 , __snake_case="gelu" , __snake_case=0.1 , __snake_case=0.1 , __snake_case=512 , __snake_case=16 , __snake_case=2 , __snake_case=0.02 , __snake_case=3 , __snake_case=4 , __snake_case=None , ) -> str: '''simple docstring''' __a =parent __a =batch_size __a =seq_length __a =is_training __a =use_input_mask __a =use_token_type_ids __a =use_labels __a =vocab_size __a =hidden_size __a =embedding_size __a =num_hidden_layers __a =num_attention_heads __a =intermediate_size __a =hidden_act __a =hidden_dropout_prob __a =attention_probs_dropout_prob __a =max_position_embeddings __a =type_vocab_size __a =type_sequence_label_size __a =initializer_range __a =num_labels __a =num_choices __a =scope def __magic_name__ ( self ) -> Tuple: '''simple docstring''' __a =ids_tensor([self.batch_size, self.seq_length] , self.vocab_size ) __a =None if self.use_input_mask: __a =random_attention_mask([self.batch_size, self.seq_length] ) __a =None if self.use_token_type_ids: __a =ids_tensor([self.batch_size, self.seq_length] , self.type_vocab_size ) __a =None __a =None __a =None if self.use_labels: __a =ids_tensor([self.batch_size] , self.type_sequence_label_size ) __a =ids_tensor([self.batch_size, self.seq_length] , self.num_labels ) __a =ids_tensor([self.batch_size] , self.num_choices ) __a =self.get_config() return config, input_ids, token_type_ids, input_mask, sequence_labels, token_labels, choice_labels def __magic_name__ ( self ) -> Optional[int]: '''simple docstring''' return MegatronBertConfig( 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 , embedding_size=self.embedding_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=lowerCamelCase__ , initializer_range=self.initializer_range , ) def __magic_name__ ( self , __snake_case , __snake_case , __snake_case , __snake_case , __snake_case , __snake_case , __snake_case ) -> List[Any]: '''simple docstring''' __a =MegatronBertModel(config=lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __a =model(lowerCamelCase__ , attention_mask=lowerCamelCase__ , token_type_ids=lowerCamelCase__ ) __a =model(lowerCamelCase__ , token_type_ids=lowerCamelCase__ ) __a =model(lowerCamelCase__ ) self.parent.assertEqual(result.last_hidden_state.shape , (self.batch_size, self.seq_length, self.hidden_size) ) self.parent.assertEqual(result.pooler_output.shape , (self.batch_size, self.hidden_size) ) def __magic_name__ ( self , __snake_case , __snake_case , __snake_case , __snake_case , __snake_case , __snake_case , __snake_case ) -> List[str]: '''simple docstring''' __a =MegatronBertForMaskedLM(config=lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __a =model(lowerCamelCase__ , attention_mask=lowerCamelCase__ , token_type_ids=lowerCamelCase__ , labels=lowerCamelCase__ ) self.parent.assertEqual(result.logits.shape , (self.batch_size, self.seq_length, self.vocab_size) ) def __magic_name__ ( self , __snake_case , __snake_case , __snake_case , __snake_case , __snake_case , __snake_case , __snake_case ) -> Optional[Any]: '''simple docstring''' __a =MegatronBertForCausalLM(config=lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __a =model(lowerCamelCase__ , attention_mask=lowerCamelCase__ , token_type_ids=lowerCamelCase__ , labels=lowerCamelCase__ ) self.parent.assertEqual(result.logits.shape , (self.batch_size, self.seq_length, self.vocab_size) ) def __magic_name__ ( self , __snake_case , __snake_case , __snake_case , __snake_case , __snake_case , __snake_case , __snake_case ) -> List[str]: '''simple docstring''' __a =MegatronBertForNextSentencePrediction(config=lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __a =model( lowerCamelCase__ , attention_mask=lowerCamelCase__ , token_type_ids=lowerCamelCase__ , labels=lowerCamelCase__ , ) self.parent.assertEqual(result.logits.shape , (self.batch_size, 2) ) def __magic_name__ ( self , __snake_case , __snake_case , __snake_case , __snake_case , __snake_case , __snake_case , __snake_case ) -> Optional[int]: '''simple docstring''' __a =MegatronBertForPreTraining(config=lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __a =model( lowerCamelCase__ , attention_mask=lowerCamelCase__ , token_type_ids=lowerCamelCase__ , labels=lowerCamelCase__ , next_sentence_label=lowerCamelCase__ , ) self.parent.assertEqual(result.prediction_logits.shape , (self.batch_size, self.seq_length, self.vocab_size) ) self.parent.assertEqual(result.seq_relationship_logits.shape , (self.batch_size, 2) ) def __magic_name__ ( self , __snake_case , __snake_case , __snake_case , __snake_case , __snake_case , __snake_case , __snake_case ) -> Optional[int]: '''simple docstring''' __a =MegatronBertForQuestionAnswering(config=lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __a =model( lowerCamelCase__ , attention_mask=lowerCamelCase__ , token_type_ids=lowerCamelCase__ , start_positions=lowerCamelCase__ , end_positions=lowerCamelCase__ , ) 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 , __snake_case , __snake_case , __snake_case , __snake_case , __snake_case , __snake_case , __snake_case ) -> str: '''simple docstring''' __a =self.num_labels __a =MegatronBertForSequenceClassification(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __a =model(lowerCamelCase__ , attention_mask=lowerCamelCase__ , token_type_ids=lowerCamelCase__ , labels=lowerCamelCase__ ) self.parent.assertEqual(result.logits.shape , (self.batch_size, self.num_labels) ) def __magic_name__ ( self , __snake_case , __snake_case , __snake_case , __snake_case , __snake_case , __snake_case , __snake_case ) -> str: '''simple docstring''' __a =self.num_labels __a =MegatronBertForTokenClassification(config=lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __a =model(lowerCamelCase__ , attention_mask=lowerCamelCase__ , token_type_ids=lowerCamelCase__ , labels=lowerCamelCase__ ) self.parent.assertEqual(result.logits.shape , (self.batch_size, self.seq_length, self.num_labels) ) def __magic_name__ ( self , __snake_case , __snake_case , __snake_case , __snake_case , __snake_case , __snake_case , __snake_case ) -> str: '''simple docstring''' __a =self.num_choices __a =MegatronBertForMultipleChoice(config=lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __a =input_ids.unsqueeze(1 ).expand(-1 , self.num_choices , -1 ).contiguous() __a =token_type_ids.unsqueeze(1 ).expand(-1 , self.num_choices , -1 ).contiguous() __a =input_mask.unsqueeze(1 ).expand(-1 , self.num_choices , -1 ).contiguous() __a =model( lowerCamelCase__ , attention_mask=lowerCamelCase__ , token_type_ids=lowerCamelCase__ , labels=lowerCamelCase__ , ) self.parent.assertEqual(result.logits.shape , (self.batch_size, self.num_choices) ) def __magic_name__ ( self ) -> List[str]: '''simple docstring''' __a =self.prepare_config_and_inputs() ( ( __a ) , ( __a ) , ( __a ) , ( __a ) , ( __a ) , ( __a ) , ( __a ) , ) =config_and_inputs __a ={'input_ids': input_ids, 'token_type_ids': token_type_ids, 'attention_mask': input_mask} return config, inputs_dict @require_torch class __magic_name__ ( lowerCAmelCase_ , lowerCAmelCase_ , unittest.TestCase ): SCREAMING_SNAKE_CASE = ( ( MegatronBertModel, MegatronBertForMaskedLM, MegatronBertForCausalLM, MegatronBertForMultipleChoice, MegatronBertForNextSentencePrediction, MegatronBertForPreTraining, MegatronBertForQuestionAnswering, MegatronBertForSequenceClassification, MegatronBertForTokenClassification, ) if is_torch_available() else () ) SCREAMING_SNAKE_CASE = ( { 'feature-extraction': MegatronBertModel, 'fill-mask': MegatronBertForMaskedLM, 'question-answering': MegatronBertForQuestionAnswering, 'text-classification': MegatronBertForSequenceClassification, 'text-generation': MegatronBertForCausalLM, 'token-classification': MegatronBertForTokenClassification, 'zero-shot': MegatronBertForSequenceClassification, } if is_torch_available() else {} ) SCREAMING_SNAKE_CASE = True # test_resize_embeddings = False SCREAMING_SNAKE_CASE = False def __magic_name__ ( self , __snake_case , __snake_case , __snake_case=False ) -> Dict: '''simple docstring''' __a =super()._prepare_for_class(lowerCamelCase__ , lowerCamelCase__ , return_labels=lowerCamelCase__ ) if return_labels: if model_class in get_values(lowerCamelCase__ ): __a =torch.zeros( (self.model_tester.batch_size, self.model_tester.seq_length) , dtype=torch.long , device=lowerCamelCase__ ) __a =torch.zeros( self.model_tester.batch_size , dtype=torch.long , device=lowerCamelCase__ ) return inputs_dict def __magic_name__ ( self ) -> Union[str, Any]: '''simple docstring''' __a =MegatronBertModelTester(self ) __a =ConfigTester(self , config_class=lowerCamelCase__ , hidden_size=37 ) def __magic_name__ ( self ) -> Dict: '''simple docstring''' self.config_tester.run_common_tests() def __magic_name__ ( self ) -> Tuple: '''simple docstring''' __a =self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_megatron_bert_model(*lowerCamelCase__ ) def __magic_name__ ( self ) -> Tuple: '''simple docstring''' __a =self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_megatron_bert_for_masked_lm(*lowerCamelCase__ ) def __magic_name__ ( self ) -> Union[str, Any]: '''simple docstring''' __a =self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_megatron_bert_for_multiple_choice(*lowerCamelCase__ ) def __magic_name__ ( self ) -> int: '''simple docstring''' __a =self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_megatron_bert_for_next_sequence_prediction(*lowerCamelCase__ ) def __magic_name__ ( self ) -> Union[str, Any]: '''simple docstring''' __a =self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_megatron_bert_for_pretraining(*lowerCamelCase__ ) def __magic_name__ ( self ) -> List[Any]: '''simple docstring''' __a =self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_megatron_bert_for_question_answering(*lowerCamelCase__ ) def __magic_name__ ( self ) -> List[str]: '''simple docstring''' __a =self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_megatron_bert_for_sequence_classification(*lowerCamelCase__ ) def __magic_name__ ( self ) -> Dict: '''simple docstring''' __a =self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_megatron_bert_for_token_classification(*lowerCamelCase__ ) def UpperCamelCase_( _snake_case : int ): """simple docstring""" return torch.tensor( UpperCamelCase__ , dtype=torch.long , device=UpperCamelCase__ , ) _lowerCAmelCase : Dict = 1E-4 @require_torch @require_sentencepiece @require_tokenizers class __magic_name__ ( unittest.TestCase ): @slow @unittest.skip('Model is not available.' ) def __magic_name__ ( self ) -> Any: '''simple docstring''' __a ='nvidia/megatron-bert-uncased-345m' if "MYDIR" in os.environ: __a =os.path.join(os.environ['MYDIR'] , lowerCamelCase__ ) __a =MegatronBertModel.from_pretrained(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.half() __a =_long_tensor([[101, 7110, 1005, 1056, 2023, 1_1333, 1_7413, 1029, 102]] ) with torch.no_grad(): __a =model(lowerCamelCase__ )[0] __a =torch.Size((1, 9, 1024) ) self.assertEqual(output.shape , lowerCamelCase__ ) __a =[-0.6040, -0.2517, -0.1025, 0.3420, -0.6758, -0.0017, -0.1089, -0.1990, 0.5728] for ii in range(3 ): for jj in range(3 ): __a =output[0, ii, jj] __a =expected[3 * ii + jj] __a ='ii={} jj={} a={} b={}'.format(lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) self.assertTrue(math.isclose(lowerCamelCase__ , lowerCamelCase__ , rel_tol=lowerCamelCase__ , abs_tol=lowerCamelCase__ ) , msg=lowerCamelCase__ )
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from math import sqrt def lowerCamelCase_ ( UpperCamelCase__ : int ) -> bool: """simple docstring""" if 1 < number < 4: # 2 and 3 are primes return True elif number < 2 or number % 2 == 0 or number % 3 == 0: # Negatives, 0, 1, all even numbers, all multiples of 3 are not primes return False # All primes number are in format of 6k +/- 1 for i in range(5 , int(sqrt(UpperCamelCase__ ) + 1 ) , 6 ): if number % i == 0 or number % (i + 2) == 0: return False return True def lowerCamelCase_ ( UpperCamelCase__ : int = 1_0001 ) -> int: """simple docstring""" __lowerCamelCase = 0 __lowerCamelCase = 1 while count != nth and number < 3: number += 1 if is_prime(UpperCamelCase__ ): count += 1 while count != nth: number += 2 if is_prime(UpperCamelCase__ ): count += 1 return number if __name__ == "__main__": print(f'''{solution() = }''')
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"""simple docstring""" import argparse import os import re import packaging.version lowerCamelCase_ : str = """examples/""" lowerCamelCase_ : Tuple = { """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"""), } lowerCamelCase_ : List[Any] = { """init""": """src/diffusers/__init__.py""", """setup""": """setup.py""", } lowerCamelCase_ : Tuple = """README.md""" def _A ( lowercase , lowercase , lowercase ): """simple docstring""" with open(UpperCamelCase__ , '''r''' , encoding='''utf-8''' , newline='''\n''' ) as f: a =f.read() a , a =REPLACE_PATTERNS[pattern] a =replace.replace('''VERSION''' , UpperCamelCase__ ) a =re_pattern.sub(UpperCamelCase__ , UpperCamelCase__ ) with open(UpperCamelCase__ , '''w''' , encoding='''utf-8''' , newline='''\n''' ) as f: f.write(UpperCamelCase__ ) def _A ( lowercase ): """simple docstring""" for folder, directories, fnames in os.walk(UpperCamelCase__ ): # 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(UpperCamelCase__ , UpperCamelCase__ ) , UpperCamelCase__ , pattern='''examples''' ) def _A ( lowercase , lowercase=False ): """simple docstring""" for pattern, fname in REPLACE_FILES.items(): update_version_in_file(UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ ) if not patch: update_version_in_examples(UpperCamelCase__ ) def _A ( ): """simple docstring""" a ='''🤗 Transformers currently provides the following architectures''' a ='''1. Want to contribute a new model?''' with open(UpperCamelCase__ , '''r''' , encoding='''utf-8''' , newline='''\n''' ) as f: a =f.readlines() # Find the start of the list. a =0 while not lines[start_index].startswith(_start_prompt ): start_index += 1 start_index += 1 a =start_index # Update the lines in the model list. while not lines[index].startswith(_end_prompt ): if lines[index].startswith('''1.''' ): a =lines[index].replace( '''https://huggingface.co/docs/diffusers/main/model_doc''' , '''https://huggingface.co/docs/diffusers/model_doc''' , ) index += 1 with open(UpperCamelCase__ , '''w''' , encoding='''utf-8''' , newline='''\n''' ) as f: f.writelines(UpperCamelCase__ ) def _A ( ): """simple docstring""" with open(REPLACE_FILES['''init'''] , '''r''' ) as f: a =f.read() a =REPLACE_PATTERNS['''init'''][0].search(UpperCamelCase__ ).groups()[0] return packaging.version.parse(UpperCamelCase__ ) def _A ( lowercase=False ): """simple docstring""" a =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: a =default_version.base_version elif patch: a =f'''{default_version.major}.{default_version.minor}.{default_version.micro + 1}''' else: a =f'''{default_version.major}.{default_version.minor + 1}.0''' # Now let's ask nicely if that's the right one. a =input(f'''Which version are you releasing? [{default_version}]''' ) if len(UpperCamelCase__ ) == 0: a =default_version print(f'''Updating version to {version}.''' ) global_version_update(UpperCamelCase__ , patch=UpperCamelCase__ ) def _A ( ): """simple docstring""" a =get_version() a =f'''{current_version.major}.{current_version.minor + 1}.0.dev0''' a =current_version.base_version # Check with the user we got that right. a =input(f'''Which version are we developing now? [{dev_version}]''' ) if len(UpperCamelCase__ ) == 0: a =dev_version print(f'''Updating version to {version}.''' ) global_version_update(UpperCamelCase__ ) # print("Cleaning main README, don't forget to run `make fix-copies`.") # clean_main_ref_in_model_list() if __name__ == "__main__": lowerCamelCase_ : int = 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.""") lowerCamelCase_ : Dict = 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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import baseaa def lowerCamelCase_ ( UpperCamelCase__ : str ) -> bytes: """simple docstring""" return baseaa.aaaencode(string.encode('utf-8' ) ) def lowerCamelCase_ ( UpperCamelCase__ : bytes ) -> str: """simple docstring""" return baseaa.aaadecode(UpperCamelCase__ ).decode('utf-8' ) if __name__ == "__main__": import doctest doctest.testmod()
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import pickle import unittest import torch from accelerate import Accelerator from accelerate.state import AcceleratorState from accelerate.test_utils import require_cpu @require_cpu class snake_case ( unittest.TestCase ): '''simple docstring''' def UpperCamelCase_ ( self : Any) -> Dict: """simple docstring""" _snake_case : Any = torch.nn.Linear(10 , 10) _snake_case : Dict = torch.optim.SGD(model.parameters() , 0.1) _snake_case : str = Accelerator() _snake_case : Any = accelerator.prepare(lowerCamelCase__) try: pickle.loads(pickle.dumps(lowerCamelCase__)) except Exception as e: self.fail(F'''Accelerated optimizer pickling failed with {e}''') AcceleratorState._reset_state()
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import copy from typing import Any, Dict, List, Optional, Union import numpy as np import torch from ...audio_utils import mel_filter_bank, spectrogram, window_function from ...feature_extraction_sequence_utils import SequenceFeatureExtractor from ...feature_extraction_utils import BatchFeature from ...utils import TensorType, logging __A = logging.get_logger(__name__) class __lowerCAmelCase ( __magic_name__ ): """simple docstring""" snake_case_ = ['''input_features''', '''is_longer'''] def __init__( self , lowerCamelCase__=64 , lowerCamelCase__=48_000 , lowerCamelCase__=480 , lowerCamelCase__=10 , lowerCamelCase__=1_024 , lowerCamelCase__=0.0 , lowerCamelCase__=False , lowerCamelCase__ = 0 , lowerCamelCase__ = 14_000 , lowerCamelCase__ = None , lowerCamelCase__ = "fusion" , lowerCamelCase__ = "repeatpad" , **lowerCamelCase__ , ) -> Tuple: '''simple docstring''' super().__init__( feature_size=lowerCamelCase__ , sampling_rate=lowerCamelCase__ , padding_value=lowerCamelCase__ , return_attention_mask=lowerCamelCase__ , **lowerCamelCase__ , ) __lowerCamelCase = top_db __lowerCamelCase = truncation __lowerCamelCase = padding __lowerCamelCase = fft_window_size __lowerCamelCase = (fft_window_size >> 1) + 1 __lowerCamelCase = hop_length __lowerCamelCase = max_length_s __lowerCamelCase = max_length_s * sampling_rate __lowerCamelCase = sampling_rate __lowerCamelCase = frequency_min __lowerCamelCase = frequency_max __lowerCamelCase = mel_filter_bank( num_frequency_bins=self.nb_frequency_bins , num_mel_filters=lowerCamelCase__ , min_frequency=lowerCamelCase__ , max_frequency=lowerCamelCase__ , sampling_rate=lowerCamelCase__ , norm=lowerCamelCase__ , mel_scale='htk' , ) __lowerCamelCase = mel_filter_bank( num_frequency_bins=self.nb_frequency_bins , num_mel_filters=lowerCamelCase__ , min_frequency=lowerCamelCase__ , max_frequency=lowerCamelCase__ , sampling_rate=lowerCamelCase__ , norm='slaney' , mel_scale='slaney' , ) def lowercase_ ( self ) -> Dict[str, Any]: '''simple docstring''' __lowerCamelCase = copy.deepcopy(self.__dict__ ) __lowerCamelCase = self.__class__.__name__ if "mel_filters" in output: del output["mel_filters"] if "mel_filters_slaney" in output: del output["mel_filters_slaney"] return output def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ = None ) -> np.ndarray: '''simple docstring''' __lowerCamelCase = spectrogram( lowerCamelCase__ , window_function(self.fft_window_size , 'hann' ) , frame_length=self.fft_window_size , hop_length=self.hop_length , power=2.0 , mel_filters=lowerCamelCase__ , log_mel='dB' , ) return log_mel_spectrogram.T def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> int: '''simple docstring''' __lowerCamelCase = np.array_split(list(range(0 , total_frames - chunk_frames + 1 ) ) , 3 ) if len(ranges[1] ) == 0: # if the audio is too short, we just use the first chunk __lowerCamelCase = [0] if len(ranges[2] ) == 0: # if the audio is too short, we just use the first chunk __lowerCamelCase = [0] # randomly choose index for each part __lowerCamelCase = np.random.choice(ranges[0] ) __lowerCamelCase = np.random.choice(ranges[1] ) __lowerCamelCase = np.random.choice(ranges[2] ) __lowerCamelCase = mel[idx_front : idx_front + chunk_frames, :] __lowerCamelCase = mel[idx_middle : idx_middle + chunk_frames, :] __lowerCamelCase = mel[idx_back : idx_back + chunk_frames, :] __lowerCamelCase = torch.tensor(mel[None, None, :] ) __lowerCamelCase = torch.nn.functional.interpolate( lowerCamelCase__ , size=[chunk_frames, 64] , mode='bilinear' , align_corners=lowerCamelCase__ ) __lowerCamelCase = mel_shrink[0][0].numpy() __lowerCamelCase = np.stack([mel_shrink, mel_chunk_front, mel_chunk_middle, mel_chunk_back] , axis=0 ) return mel_fusion def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> np.array: '''simple docstring''' if waveform.shape[0] > max_length: if truncation == "rand_trunc": __lowerCamelCase = True # random crop to max_length (for compatibility) -> this should be handled by self.pad __lowerCamelCase = len(lowerCamelCase__ ) - max_length __lowerCamelCase = np.random.randint(0 , overflow + 1 ) __lowerCamelCase = waveform[idx : idx + max_length] __lowerCamelCase = self._np_extract_fbank_features(lowerCamelCase__ , self.mel_filters_slaney )[None, :] elif truncation == "fusion": __lowerCamelCase = self._np_extract_fbank_features(lowerCamelCase__ , self.mel_filters ) __lowerCamelCase = max_length // self.hop_length + 1 # the +1 related to how the spectrogram is computed __lowerCamelCase = mel.shape[0] if chunk_frames == total_frames: # there is a corner case where the audio length is larger than max_length but smaller than max_length+hop_length. # In this case, we just use the whole audio. __lowerCamelCase = np.stack([mel, mel, mel, mel] , axis=0 ) __lowerCamelCase = False else: __lowerCamelCase = self._random_mel_fusion(lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) __lowerCamelCase = True else: raise NotImplementedError(f"""data_truncating {truncation} not implemented""" ) else: __lowerCamelCase = False # only use repeat as a new possible value for padding. you repeat the audio before applying the usual max_length padding if waveform.shape[0] < max_length: if padding == "repeat": __lowerCamelCase = int(max_length / len(lowerCamelCase__ ) ) __lowerCamelCase = np.stack(np.tile(lowerCamelCase__ , n_repeat + 1 ) )[:max_length] if padding == "repeatpad": __lowerCamelCase = int(max_length / len(lowerCamelCase__ ) ) __lowerCamelCase = np.stack(np.tile(lowerCamelCase__ , lowerCamelCase__ ) ) __lowerCamelCase = np.pad(lowerCamelCase__ , (0, max_length - waveform.shape[0]) , mode='constant' , constant_values=0 ) if truncation == "fusion": __lowerCamelCase = self._np_extract_fbank_features(lowerCamelCase__ , self.mel_filters ) __lowerCamelCase = np.stack([input_mel, input_mel, input_mel, input_mel] , axis=0 ) else: __lowerCamelCase = self._np_extract_fbank_features(lowerCamelCase__ , self.mel_filters_slaney )[None, :] return input_mel, longer def __call__( self , lowerCamelCase__ , lowerCamelCase__ = None , lowerCamelCase__ = None , lowerCamelCase__ = None , lowerCamelCase__ = None , lowerCamelCase__ = None , **lowerCamelCase__ , ) -> BatchFeature: '''simple docstring''' __lowerCamelCase = truncation if truncation is not None else self.truncation __lowerCamelCase = padding if padding else self.padding if sampling_rate is not None: if sampling_rate != self.sampling_rate: raise ValueError( f"""The model corresponding to this feature extractor: {self.__class__.__name__} was trained using a""" f""" sampling rate of {self.sampling_rate}. Please make sure that the provided `raw_speech` input""" f""" was sampled with {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.' ) __lowerCamelCase = isinstance(lowerCamelCase__ , np.ndarray ) and len(raw_speech.shape ) > 1 if is_batched_numpy and len(raw_speech.shape ) > 2: raise ValueError(f"""Only mono-channel audio is supported for input to {self}""" ) __lowerCamelCase = is_batched_numpy or ( isinstance(lowerCamelCase__ , (list, tuple) ) and (isinstance(raw_speech[0] , (np.ndarray, tuple, list) )) ) if is_batched: __lowerCamelCase = [np.asarray(lowerCamelCase__ , dtype=np.floataa ) for speech in raw_speech] elif not is_batched and not isinstance(lowerCamelCase__ , np.ndarray ): __lowerCamelCase = np.asarray(lowerCamelCase__ , dtype=np.floataa ) elif isinstance(lowerCamelCase__ , np.ndarray ) and raw_speech.dtype is np.dtype(np.floataa ): __lowerCamelCase = raw_speech.astype(np.floataa ) # always return batch if not is_batched: __lowerCamelCase = [np.asarray(lowerCamelCase__ )] # convert to mel spectrogram, truncate and pad if needed. __lowerCamelCase = [ self._get_input_mel(lowerCamelCase__ , max_length if max_length else self.nb_max_samples , lowerCamelCase__ , lowerCamelCase__ ) for waveform in raw_speech ] __lowerCamelCase = [] __lowerCamelCase = [] for mel, longer in padded_inputs: input_mel.append(lowerCamelCase__ ) is_longer.append(lowerCamelCase__ ) if truncation == "fusion" and sum(lowerCamelCase__ ) == 0: # if no audio is longer than 10s, then randomly select one audio to be longer __lowerCamelCase = np.random.randint(0 , len(lowerCamelCase__ ) ) __lowerCamelCase = True if isinstance(input_mel[0] , lowerCamelCase__ ): __lowerCamelCase = [np.asarray(lowerCamelCase__ , dtype=np.floataa ) for feature in input_mel] # is_longer is a list of bool __lowerCamelCase = [[longer] for longer in is_longer] __lowerCamelCase = {'input_features': input_mel, 'is_longer': is_longer} __lowerCamelCase = BatchFeature(lowerCamelCase__ ) if return_tensors is not None: __lowerCamelCase = input_features.convert_to_tensors(lowerCamelCase__ ) return input_features
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"""simple docstring""" def _SCREAMING_SNAKE_CASE (__lowerCAmelCase ) -> List[Any]: '''simple docstring''' lowercase_ = len(UpperCamelCase__ ) while cur > 1: # Find the maximum number in arr lowercase_ = arr.index(max(arr[0:cur] ) ) # Reverse from 0 to mi lowercase_ = arr[mi::-1] + arr[mi + 1 : len(UpperCamelCase__ )] # Reverse whole list lowercase_ = arr[cur - 1 :: -1] + arr[cur : len(UpperCamelCase__ )] cur -= 1 return arr if __name__ == "__main__": UpperCAmelCase : Dict = input("Enter numbers separated by a comma:\n").strip() UpperCAmelCase : Dict = [int(item) for item in user_input.split(",")] print(pancake_sort(unsorted))
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class __lowerCAmelCase : """simple docstring""" def __init__( self ) -> Any: '''simple docstring''' __lowerCamelCase = 0 __lowerCamelCase = 0 __lowerCamelCase = {} def lowercase_ ( self , lowerCamelCase__ ) -> Tuple: '''simple docstring''' if vertex not in self.adjacency: __lowerCamelCase = {} self.num_vertices += 1 def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> str: '''simple docstring''' self.add_vertex(lowerCamelCase__ ) self.add_vertex(lowerCamelCase__ ) if head == tail: return __lowerCamelCase = weight __lowerCamelCase = weight def lowercase_ ( self ) -> List[str]: '''simple docstring''' __lowerCamelCase = self.get_edges() for edge in edges: __lowerCamelCase , __lowerCamelCase , __lowerCamelCase = edge edges.remove((tail, head, weight) ) for i in range(len(lowerCamelCase__ ) ): __lowerCamelCase = list(edges[i] ) edges.sort(key=lambda lowerCamelCase__ : e[2] ) for i in range(len(lowerCamelCase__ ) - 1 ): if edges[i][2] >= edges[i + 1][2]: __lowerCamelCase = edges[i][2] + 1 for edge in edges: __lowerCamelCase , __lowerCamelCase , __lowerCamelCase = edge __lowerCamelCase = weight __lowerCamelCase = weight def __str__( self ) -> Union[str, Any]: '''simple docstring''' __lowerCamelCase = '' for tail in self.adjacency: for head in self.adjacency[tail]: __lowerCamelCase = self.adjacency[head][tail] string += f"""{head} -> {tail} == {weight}\n""" return string.rstrip('\n' ) def lowercase_ ( self ) -> Optional[Any]: '''simple docstring''' __lowerCamelCase = [] for tail in self.adjacency: for head in self.adjacency[tail]: output.append((tail, head, self.adjacency[head][tail]) ) return output def lowercase_ ( self ) -> List[Any]: '''simple docstring''' return self.adjacency.keys() @staticmethod def lowercase_ ( lowerCamelCase__=None , lowerCamelCase__=None ) -> str: '''simple docstring''' __lowerCamelCase = Graph() if vertices is None: __lowerCamelCase = [] if edges is None: __lowerCamelCase = [] for vertex in vertices: g.add_vertex(lowerCamelCase__ ) for edge in edges: g.add_edge(*lowerCamelCase__ ) return g class __lowerCAmelCase : """simple docstring""" def __init__( self ) -> Tuple: '''simple docstring''' __lowerCamelCase = {} __lowerCamelCase = {} def __len__( self ) -> Tuple: '''simple docstring''' return len(self.parent ) def lowercase_ ( self , lowerCamelCase__ ) -> List[Any]: '''simple docstring''' if item in self.parent: return self.find(lowerCamelCase__ ) __lowerCamelCase = item __lowerCamelCase = 0 return item def lowercase_ ( self , lowerCamelCase__ ) -> List[str]: '''simple docstring''' if item not in self.parent: return self.make_set(lowerCamelCase__ ) if item != self.parent[item]: __lowerCamelCase = self.find(self.parent[item] ) return self.parent[item] def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ ) -> int: '''simple docstring''' __lowerCamelCase = self.find(lowerCamelCase__ ) __lowerCamelCase = self.find(lowerCamelCase__ ) if roota == roota: return roota if self.rank[roota] > self.rank[roota]: __lowerCamelCase = roota return roota if self.rank[roota] < self.rank[roota]: __lowerCamelCase = roota return roota if self.rank[roota] == self.rank[roota]: self.rank[roota] += 1 __lowerCamelCase = roota return roota return None @staticmethod def lowercase_ ( lowerCamelCase__ ) -> str: '''simple docstring''' __lowerCamelCase = graph.num_vertices __lowerCamelCase = Graph.UnionFind() __lowerCamelCase = [] while num_components > 1: __lowerCamelCase = {} for vertex in graph.get_vertices(): __lowerCamelCase = -1 __lowerCamelCase = graph.get_edges() for edge in edges: __lowerCamelCase , __lowerCamelCase , __lowerCamelCase = edge edges.remove((tail, head, weight) ) for edge in edges: __lowerCamelCase , __lowerCamelCase , __lowerCamelCase = edge __lowerCamelCase = union_find.find(lowerCamelCase__ ) __lowerCamelCase = union_find.find(lowerCamelCase__ ) if seta != seta: if cheap_edge[seta] == -1 or cheap_edge[seta][2] > weight: __lowerCamelCase = [head, tail, weight] if cheap_edge[seta] == -1 or cheap_edge[seta][2] > weight: __lowerCamelCase = [head, tail, weight] for vertex in cheap_edge: if cheap_edge[vertex] != -1: __lowerCamelCase , __lowerCamelCase , __lowerCamelCase = cheap_edge[vertex] if union_find.find(lowerCamelCase__ ) != union_find.find(lowerCamelCase__ ): union_find.union(lowerCamelCase__ , lowerCamelCase__ ) mst_edges.append(cheap_edge[vertex] ) __lowerCamelCase = num_components - 1 __lowerCamelCase = Graph.build(edges=lowerCamelCase__ ) return mst
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'''simple docstring''' from typing import List, Optional, Union import numpy as np from ...feature_extraction_sequence_utils import SequenceFeatureExtractor from ...feature_extraction_utils import BatchFeature from ...utils import PaddingStrategy, TensorType, logging lowercase_ = logging.get_logger(__name__) class a_ ( snake_case_ ): '''simple docstring''' UpperCamelCase = ['''input_values''', '''padding_mask'''] def __init__( self , A = 1 , A = 2_4000 , A = 0.0 , A = None , A = None , **A , ) -> Union[str, Any]: super().__init__(feature_size=lowerCamelCase__ , sampling_rate=lowerCamelCase__ , padding_value=lowerCamelCase__ , **lowerCamelCase__ ) _SCREAMING_SNAKE_CASE = chunk_length_s _SCREAMING_SNAKE_CASE = overlap @property def snake_case_( self ) -> Optional[int]: if self.chunk_length_s is None: return None else: return int(self.chunk_length_s * self.sampling_rate ) @property def snake_case_( self ) -> Optional[int]: if self.chunk_length_s is None or self.overlap is None: return None else: return max(1 , int((1.0 - self.overlap) * self.chunk_length ) ) def __call__( self , A , A = None , A = False , A = None , A = None , A = None , ) -> BatchFeature: 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 padding and truncation: raise ValueError("""Both padding and truncation were set. Make sure you only set one.""" ) elif padding is None: # by default let's pad the inputs _SCREAMING_SNAKE_CASE = True _SCREAMING_SNAKE_CASE = bool( isinstance(lowerCamelCase__ , (list, tuple) ) and (isinstance(raw_audio[0] , (np.ndarray, tuple, list) )) ) if is_batched: _SCREAMING_SNAKE_CASE = [np.asarray(lowerCamelCase__ , dtype=np.floataa ).T for audio in raw_audio] elif not is_batched and not isinstance(lowerCamelCase__ , np.ndarray ): _SCREAMING_SNAKE_CASE = np.asarray(lowerCamelCase__ , dtype=np.floataa ) elif isinstance(lowerCamelCase__ , np.ndarray ) and raw_audio.dtype is np.dtype(np.floataa ): _SCREAMING_SNAKE_CASE = raw_audio.astype(np.floataa ) # always return batch if not is_batched: _SCREAMING_SNAKE_CASE = [np.asarray(lowerCamelCase__ ).T] # verify inputs are valid for idx, example in enumerate(lowerCamelCase__ ): if example.ndim > 2: raise ValueError(f'Expected input shape (channels, length) but got shape {example.shape}' ) if self.feature_size == 1 and example.ndim != 1: raise ValueError(f'Expected mono audio but example has {example.shape[-1]} channels' ) if self.feature_size == 2 and example.shape[-1] != 2: raise ValueError(f'Expected stereo audio but example has {example.shape[-1]} channels' ) _SCREAMING_SNAKE_CASE = None _SCREAMING_SNAKE_CASE = BatchFeature({"""input_values""": raw_audio} ) if self.chunk_stride is not None and self.chunk_length is not None and max_length is None: if truncation: _SCREAMING_SNAKE_CASE = min(array.shape[0] for array in raw_audio ) _SCREAMING_SNAKE_CASE = int(np.floor(max_length / self.chunk_stride ) ) _SCREAMING_SNAKE_CASE = (nb_step - 1) * self.chunk_stride + self.chunk_length elif padding: _SCREAMING_SNAKE_CASE = max(array.shape[0] for array in raw_audio ) _SCREAMING_SNAKE_CASE = int(np.ceil(max_length / self.chunk_stride ) ) _SCREAMING_SNAKE_CASE = (nb_step - 1) * self.chunk_stride + self.chunk_length _SCREAMING_SNAKE_CASE = """max_length""" else: _SCREAMING_SNAKE_CASE = input_values # normal padding on batch if padded_inputs is None: _SCREAMING_SNAKE_CASE = self.pad( lowerCamelCase__ , max_length=lowerCamelCase__ , truncation=lowerCamelCase__ , padding=lowerCamelCase__ , return_attention_mask=lowerCamelCase__ , ) if padding: _SCREAMING_SNAKE_CASE = padded_inputs.pop("""attention_mask""" ) _SCREAMING_SNAKE_CASE = [] for example in padded_inputs.pop("""input_values""" ): if self.feature_size == 1: _SCREAMING_SNAKE_CASE = example[..., None] input_values.append(example.T ) _SCREAMING_SNAKE_CASE = input_values if return_tensors is not None: _SCREAMING_SNAKE_CASE = padded_inputs.convert_to_tensors(lowerCamelCase__ ) return padded_inputs
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from math import pi, sqrt, tan def lowerCamelCase_ ( UpperCamelCase__ : float ) -> float: """simple docstring""" if side_length < 0: raise ValueError('surface_area_cube() only accepts non-negative values' ) return 6 * side_length**2 def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if length < 0 or breadth < 0 or height < 0: raise ValueError('surface_area_cuboid() only accepts non-negative values' ) return 2 * ((length * breadth) + (breadth * height) + (length * height)) def lowerCamelCase_ ( UpperCamelCase__ : float ) -> float: """simple docstring""" if radius < 0: raise ValueError('surface_area_sphere() only accepts non-negative values' ) return 4 * pi * radius**2 def lowerCamelCase_ ( UpperCamelCase__ : float ) -> float: """simple docstring""" if radius < 0: raise ValueError('surface_area_hemisphere() only accepts non-negative values' ) return 3 * pi * radius**2 def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if radius < 0 or height < 0: raise ValueError('surface_area_cone() only accepts non-negative values' ) return pi * radius * (radius + (height**2 + radius**2) ** 0.5) def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if radius_a < 0 or radius_a < 0 or height < 0: raise ValueError( 'surface_area_conical_frustum() only accepts non-negative values' ) __lowerCamelCase = (height**2 + (radius_a - radius_a) ** 2) ** 0.5 return pi * ((slant_height * (radius_a + radius_a)) + radius_a**2 + radius_a**2) def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if radius < 0 or height < 0: raise ValueError('surface_area_cylinder() only accepts non-negative values' ) return 2 * pi * radius * (height + radius) def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if torus_radius < 0 or tube_radius < 0: raise ValueError('surface_area_torus() only accepts non-negative values' ) if torus_radius < tube_radius: raise ValueError( 'surface_area_torus() does not support spindle or self intersecting tori' ) return 4 * pow(UpperCamelCase__ , 2 ) * torus_radius * tube_radius def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if length < 0 or width < 0: raise ValueError('area_rectangle() only accepts non-negative values' ) return length * width def lowerCamelCase_ ( UpperCamelCase__ : float ) -> float: """simple docstring""" if side_length < 0: raise ValueError('area_square() only accepts non-negative values' ) return side_length**2 def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if base < 0 or height < 0: raise ValueError('area_triangle() only accepts non-negative values' ) return (base * height) / 2 def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if sidea < 0 or sidea < 0 or sidea < 0: raise ValueError('area_triangle_three_sides() only accepts non-negative values' ) elif sidea + sidea < sidea or sidea + sidea < sidea or sidea + sidea < sidea: raise ValueError('Given three sides do not form a triangle' ) __lowerCamelCase = (sidea + sidea + sidea) / 2 __lowerCamelCase = sqrt( semi_perimeter * (semi_perimeter - sidea) * (semi_perimeter - sidea) * (semi_perimeter - sidea) ) return area def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if base < 0 or height < 0: raise ValueError('area_parallelogram() only accepts non-negative values' ) return base * height def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if basea < 0 or basea < 0 or height < 0: raise ValueError('area_trapezium() only accepts non-negative values' ) return 1 / 2 * (basea + basea) * height def lowerCamelCase_ ( UpperCamelCase__ : float ) -> float: """simple docstring""" if radius < 0: raise ValueError('area_circle() only accepts non-negative values' ) return pi * radius**2 def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if radius_x < 0 or radius_y < 0: raise ValueError('area_ellipse() only accepts non-negative values' ) return pi * radius_x * radius_y def lowerCamelCase_ ( UpperCamelCase__ : float , UpperCamelCase__ : float ) -> float: """simple docstring""" if diagonal_a < 0 or diagonal_a < 0: raise ValueError('area_rhombus() only accepts non-negative values' ) return 1 / 2 * diagonal_a * diagonal_a def lowerCamelCase_ ( UpperCamelCase__ : int , UpperCamelCase__ : float ) -> float: """simple docstring""" if not isinstance(UpperCamelCase__ , UpperCamelCase__ ) or sides < 3: raise ValueError( 'area_reg_polygon() only accepts integers greater than or \ equal to three as number of sides' ) elif length < 0: raise ValueError( 'area_reg_polygon() only accepts non-negative values as \ length of a side' ) return (sides * length**2) / (4 * tan(pi / sides )) return (sides * length**2) / (4 * tan(pi / sides )) if __name__ == "__main__": import doctest doctest.testmod(verbose=True) # verbose so we can see methods missing tests print("[DEMO] Areas of various geometric shapes: \n") print(f'''Rectangle: {area_rectangle(10, 20) = }''') print(f'''Square: {area_square(10) = }''') print(f'''Triangle: {area_triangle(10, 10) = }''') print(f'''Triangle: {area_triangle_three_sides(5, 12, 13) = }''') print(f'''Parallelogram: {area_parallelogram(10, 20) = }''') print(f'''Rhombus: {area_rhombus(10, 20) = }''') print(f'''Trapezium: {area_trapezium(10, 20, 30) = }''') print(f'''Circle: {area_circle(20) = }''') print(f'''Ellipse: {area_ellipse(10, 20) = }''') print("\nSurface Areas of various geometric shapes: \n") print(f'''Cube: {surface_area_cube(20) = }''') print(f'''Cuboid: {surface_area_cuboid(10, 20, 30) = }''') print(f'''Sphere: {surface_area_sphere(20) = }''') print(f'''Hemisphere: {surface_area_hemisphere(20) = }''') print(f'''Cone: {surface_area_cone(10, 20) = }''') print(f'''Conical Frustum: {surface_area_conical_frustum(10, 20, 30) = }''') print(f'''Cylinder: {surface_area_cylinder(10, 20) = }''') print(f'''Torus: {surface_area_torus(20, 10) = }''') print(f'''Equilateral Triangle: {area_reg_polygon(3, 10) = }''') print(f'''Square: {area_reg_polygon(4, 10) = }''') print(f'''Reqular Pentagon: {area_reg_polygon(5, 10) = }''')
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import sys from collections import defaultdict class lowercase_ : '''simple docstring''' def __init__( self : Dict ) ->Tuple: """simple docstring""" a = [] def __lowerCAmelCase ( self : Optional[int] , __UpperCAmelCase : str ) ->Dict: """simple docstring""" return self.node_position[vertex] def __lowerCAmelCase ( self : List[str] , __UpperCAmelCase : Union[str, Any] , __UpperCAmelCase : Optional[Any] ) ->Tuple: """simple docstring""" a = pos def __lowerCAmelCase ( self : int , __UpperCAmelCase : int , __UpperCAmelCase : str , __UpperCAmelCase : List[Any] , __UpperCAmelCase : Union[str, Any] ) ->List[str]: """simple docstring""" if start > size // 2 - 1: return else: if 2 * start + 2 >= size: a = 2 * start + 1 else: if heap[2 * start + 1] < heap[2 * start + 2]: a = 2 * start + 1 else: a = 2 * start + 2 if heap[smallest_child] < heap[start]: a , a = heap[smallest_child], positions[smallest_child] a , a = ( heap[start], positions[start], ) a , a = temp, tempa a = self.get_position(positions[smallest_child] ) self.set_position( positions[smallest_child] , self.get_position(positions[start] ) ) self.set_position(positions[start] , lowerCamelCase__ ) self.top_to_bottom(lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) def __lowerCAmelCase ( self : Any , __UpperCAmelCase : str , __UpperCAmelCase : Union[str, Any] , __UpperCAmelCase : Tuple , __UpperCAmelCase : str ) ->Union[str, Any]: """simple docstring""" a = position[index] while index != 0: a = int((index - 2) / 2 ) if index % 2 == 0 else int((index - 1) / 2 ) if val < heap[parent]: a = heap[parent] a = position[parent] self.set_position(position[parent] , lowerCamelCase__ ) else: a = val a = temp self.set_position(lowerCamelCase__ , lowerCamelCase__ ) break a = parent else: a = val a = temp self.set_position(lowerCamelCase__ , 0 ) def __lowerCAmelCase ( self : Any , __UpperCAmelCase : int , __UpperCAmelCase : Optional[int] ) ->List[Any]: """simple docstring""" a = len(lowerCamelCase__ ) // 2 - 1 for i in range(lowerCamelCase__ , -1 , -1 ): self.top_to_bottom(lowerCamelCase__ , lowerCamelCase__ , len(lowerCamelCase__ ) , lowerCamelCase__ ) def __lowerCAmelCase ( self : Tuple , __UpperCAmelCase : Optional[Any] , __UpperCAmelCase : Any ) ->Any: """simple docstring""" a = positions[0] a = sys.maxsize self.top_to_bottom(lowerCamelCase__ , 0 , len(lowerCamelCase__ ) , lowerCamelCase__ ) return temp def _a ( a :str ) -> List[str]: a = Heap() a = [0] * len(UpperCamelCase__ ) a = [-1] * len(UpperCamelCase__ ) # Neighboring Tree Vertex of selected vertex # Minimum Distance of explored vertex with neighboring vertex of partial tree # formed in graph a = [] # Heap of Distance of vertices from their neighboring vertex a = [] for vertex in range(len(UpperCamelCase__ ) ): distance_tv.append(sys.maxsize ) positions.append(UpperCamelCase__ ) heap.node_position.append(UpperCamelCase__ ) a = [] a = 1 a = sys.maxsize for neighbor, distance in adjacency_list[0]: a = 0 a = distance heap.heapify(UpperCamelCase__ , UpperCamelCase__ ) for _ in range(1 , len(UpperCamelCase__ ) ): a = heap.delete_minimum(UpperCamelCase__ , UpperCamelCase__ ) if visited[vertex] == 0: tree_edges.append((nbr_tv[vertex], vertex) ) a = 1 for neighbor, distance in adjacency_list[vertex]: if ( visited[neighbor] == 0 and distance < distance_tv[heap.get_position(UpperCamelCase__ )] ): a = distance heap.bottom_to_top( UpperCamelCase__ , heap.get_position(UpperCamelCase__ ) , UpperCamelCase__ , UpperCamelCase__ ) a = vertex return tree_edges if __name__ == "__main__": # pragma: no cover # < --------- Prims Algorithm --------- > UpperCAmelCase__ = int(input("Enter number of edges: ").strip()) UpperCAmelCase__ = defaultdict(list) for _ in range(edges_number): UpperCAmelCase__ = [int(x) for x in input().strip().split()] adjacency_list[edge[0]].append([edge[1], edge[2]]) adjacency_list[edge[1]].append([edge[0], edge[2]]) print(prisms_algorithm(adjacency_list))
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import unittest from transformers import DebertaConfig, is_torch_available from transformers.testing_utils import require_sentencepiece, require_tokenizers, require_torch, slow, torch_device from ...test_configuration_common import ConfigTester from ...test_modeling_common import ModelTesterMixin, ids_tensor from ...test_pipeline_mixin import PipelineTesterMixin if is_torch_available(): import torch from transformers import ( DebertaForMaskedLM, DebertaForQuestionAnswering, DebertaForSequenceClassification, DebertaForTokenClassification, DebertaModel, ) from transformers.models.deberta.modeling_deberta import DEBERTA_PRETRAINED_MODEL_ARCHIVE_LIST class __lowerCAmelCase ( __magic_name__ ): """simple docstring""" def __init__( self , lowerCamelCase__ , lowerCamelCase__=13 , lowerCamelCase__=7 , lowerCamelCase__=True , lowerCamelCase__=True , lowerCamelCase__=True , lowerCamelCase__=True , lowerCamelCase__=99 , lowerCamelCase__=32 , lowerCamelCase__=5 , lowerCamelCase__=4 , lowerCamelCase__=37 , lowerCamelCase__="gelu" , lowerCamelCase__=0.1 , lowerCamelCase__=0.1 , lowerCamelCase__=512 , lowerCamelCase__=16 , lowerCamelCase__=2 , lowerCamelCase__=0.02 , lowerCamelCase__=False , lowerCamelCase__=True , lowerCamelCase__="None" , lowerCamelCase__=3 , lowerCamelCase__=4 , lowerCamelCase__=None , ) -> int: '''simple docstring''' __lowerCamelCase = parent __lowerCamelCase = batch_size __lowerCamelCase = seq_length __lowerCamelCase = is_training __lowerCamelCase = use_input_mask __lowerCamelCase = use_token_type_ids __lowerCamelCase = use_labels __lowerCamelCase = vocab_size __lowerCamelCase = hidden_size __lowerCamelCase = num_hidden_layers __lowerCamelCase = num_attention_heads __lowerCamelCase = intermediate_size __lowerCamelCase = hidden_act __lowerCamelCase = hidden_dropout_prob __lowerCamelCase = attention_probs_dropout_prob __lowerCamelCase = max_position_embeddings __lowerCamelCase = type_vocab_size __lowerCamelCase = type_sequence_label_size __lowerCamelCase = initializer_range __lowerCamelCase = num_labels __lowerCamelCase = num_choices __lowerCamelCase = relative_attention __lowerCamelCase = position_biased_input __lowerCamelCase = pos_att_type __lowerCamelCase = scope def lowercase_ ( self ) -> str: '''simple docstring''' __lowerCamelCase = ids_tensor([self.batch_size, self.seq_length] , self.vocab_size ) __lowerCamelCase = None if self.use_input_mask: __lowerCamelCase = ids_tensor([self.batch_size, self.seq_length] , vocab_size=2 ) __lowerCamelCase = None if self.use_token_type_ids: __lowerCamelCase = ids_tensor([self.batch_size, self.seq_length] , self.type_vocab_size ) __lowerCamelCase = None __lowerCamelCase = None __lowerCamelCase = None if self.use_labels: __lowerCamelCase = ids_tensor([self.batch_size] , self.type_sequence_label_size ) __lowerCamelCase = ids_tensor([self.batch_size, self.seq_length] , self.num_labels ) __lowerCamelCase = ids_tensor([self.batch_size] , self.num_choices ) __lowerCamelCase = self.get_config() return config, input_ids, token_type_ids, input_mask, sequence_labels, token_labels, choice_labels def lowercase_ ( self ) -> Optional[Any]: '''simple docstring''' return DebertaConfig( 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 , relative_attention=self.relative_attention , position_biased_input=self.position_biased_input , pos_att_type=self.pos_att_type , ) def lowercase_ ( self ) -> List[str]: '''simple docstring''' __lowerCamelCase = self.get_config() __lowerCamelCase = 300 return config def lowercase_ ( self , lowerCamelCase__ ) -> Optional[int]: '''simple docstring''' self.parent.assertListEqual(list(result.loss.size() ) , [] ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> Any: '''simple docstring''' __lowerCamelCase = DebertaModel(config=lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model(lowerCamelCase__ , attention_mask=lowerCamelCase__ , token_type_ids=lowerCamelCase__ )[0] __lowerCamelCase = model(lowerCamelCase__ , token_type_ids=lowerCamelCase__ )[0] __lowerCamelCase = model(lowerCamelCase__ )[0] self.parent.assertListEqual(list(sequence_output.size() ) , [self.batch_size, self.seq_length, self.hidden_size] ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> Tuple: '''simple docstring''' __lowerCamelCase = DebertaForMaskedLM(config=lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model(lowerCamelCase__ , attention_mask=lowerCamelCase__ , token_type_ids=lowerCamelCase__ , labels=lowerCamelCase__ ) self.parent.assertEqual(result.logits.shape , (self.batch_size, self.seq_length, self.vocab_size) ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> Union[str, Any]: '''simple docstring''' __lowerCamelCase = self.num_labels __lowerCamelCase = DebertaForSequenceClassification(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model(lowerCamelCase__ , attention_mask=lowerCamelCase__ , token_type_ids=lowerCamelCase__ , labels=lowerCamelCase__ ) self.parent.assertListEqual(list(result.logits.size() ) , [self.batch_size, self.num_labels] ) self.check_loss_output(lowerCamelCase__ ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> Optional[int]: '''simple docstring''' __lowerCamelCase = self.num_labels __lowerCamelCase = DebertaForTokenClassification(config=lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model(lowerCamelCase__ , attention_mask=lowerCamelCase__ , token_type_ids=lowerCamelCase__ , labels=lowerCamelCase__ ) self.parent.assertEqual(result.logits.shape , (self.batch_size, self.seq_length, self.num_labels) ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> Dict: '''simple docstring''' __lowerCamelCase = DebertaForQuestionAnswering(config=lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model( lowerCamelCase__ , attention_mask=lowerCamelCase__ , token_type_ids=lowerCamelCase__ , start_positions=lowerCamelCase__ , end_positions=lowerCamelCase__ , ) self.parent.assertEqual(result.start_logits.shape , (self.batch_size, self.seq_length) ) self.parent.assertEqual(result.end_logits.shape , (self.batch_size, self.seq_length) ) def lowercase_ ( self ) -> Union[str, Any]: '''simple docstring''' __lowerCamelCase = self.prepare_config_and_inputs() ( ( __lowerCamelCase ) , ( __lowerCamelCase ) , ( __lowerCamelCase ) , ( __lowerCamelCase ) , ( __lowerCamelCase ) , ( __lowerCamelCase ) , ( __lowerCamelCase ) , ) = config_and_inputs __lowerCamelCase = {'input_ids': input_ids, 'token_type_ids': token_type_ids, 'attention_mask': input_mask} return config, inputs_dict @require_torch class __lowerCAmelCase ( __magic_name__ , __magic_name__ , unittest.TestCase ): """simple docstring""" snake_case_ = ( ( DebertaModel, DebertaForMaskedLM, DebertaForSequenceClassification, DebertaForTokenClassification, DebertaForQuestionAnswering, ) if is_torch_available() else () ) snake_case_ = ( { '''feature-extraction''': DebertaModel, '''fill-mask''': DebertaForMaskedLM, '''question-answering''': DebertaForQuestionAnswering, '''text-classification''': DebertaForSequenceClassification, '''token-classification''': DebertaForTokenClassification, '''zero-shot''': DebertaForSequenceClassification, } if is_torch_available() else {} ) snake_case_ = True snake_case_ = False snake_case_ = False snake_case_ = False snake_case_ = False def lowercase_ ( self ) -> List[Any]: '''simple docstring''' __lowerCamelCase = DebertaModelTester(self ) __lowerCamelCase = ConfigTester(self , config_class=lowerCamelCase__ , hidden_size=37 ) def lowercase_ ( self ) -> Optional[int]: '''simple docstring''' self.config_tester.run_common_tests() def lowercase_ ( self ) -> List[str]: '''simple docstring''' __lowerCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_deberta_model(*lowerCamelCase__ ) def lowercase_ ( self ) -> Optional[int]: '''simple docstring''' __lowerCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_deberta_for_sequence_classification(*lowerCamelCase__ ) def lowercase_ ( self ) -> Dict: '''simple docstring''' __lowerCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_deberta_for_masked_lm(*lowerCamelCase__ ) def lowercase_ ( self ) -> Optional[Any]: '''simple docstring''' __lowerCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_deberta_for_question_answering(*lowerCamelCase__ ) def lowercase_ ( self ) -> str: '''simple docstring''' __lowerCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_deberta_for_token_classification(*lowerCamelCase__ ) @slow def lowercase_ ( self ) -> Optional[int]: '''simple docstring''' for model_name in DEBERTA_PRETRAINED_MODEL_ARCHIVE_LIST[:1]: __lowerCamelCase = DebertaModel.from_pretrained(lowerCamelCase__ ) self.assertIsNotNone(lowerCamelCase__ ) @require_torch @require_sentencepiece @require_tokenizers class __lowerCAmelCase ( unittest.TestCase ): """simple docstring""" @unittest.skip(reason='Model not available yet' ) def lowercase_ ( self ) -> Union[str, Any]: '''simple docstring''' pass @slow def lowercase_ ( self ) -> Tuple: '''simple docstring''' __lowerCamelCase = DebertaModel.from_pretrained('microsoft/deberta-base' ) __lowerCamelCase = torch.tensor([[0, 31_414, 232, 328, 740, 1_140, 12_695, 69, 46_078, 1_588, 2]] ) __lowerCamelCase = torch.tensor([[0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1]] ) with torch.no_grad(): __lowerCamelCase = model(lowerCamelCase__ , attention_mask=lowerCamelCase__ )[0] # compare the actual values for a slice. __lowerCamelCase = torch.tensor( [[[-0.59_86, -0.80_55, -0.84_62], [1.44_84, -0.93_48, -0.80_59], [0.31_23, 0.00_32, -1.41_31]]] ) self.assertTrue(torch.allclose(output[:, 1:4, 1:4] , lowerCamelCase__ , atol=1e-4 ) , f"""{output[:, 1:4, 1:4]}""" )
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# DISCLAIMER: This file is strongly influenced by https://github.com/ermongroup/ddim from dataclasses import dataclass from typing import Optional, Tuple, Union import flax import jax import jax.numpy as jnp from ..configuration_utils import ConfigMixin, register_to_config from .scheduling_utils_flax import ( CommonSchedulerState, FlaxKarrasDiffusionSchedulers, FlaxSchedulerMixin, FlaxSchedulerOutput, add_noise_common, get_velocity_common, ) @flax.struct.dataclass class lowercase_ : """simple docstring""" UpperCAmelCase_ : Any = 42 # setable values UpperCAmelCase_ : Any = 42 UpperCAmelCase_ : Optional[int] = 42 UpperCAmelCase_ : List[Any] = None @classmethod def SCREAMING_SNAKE_CASE_ ( cls , __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE ) ->str: return cls(common=lowerCamelCase__ , init_noise_sigma=lowerCamelCase__ , timesteps=lowerCamelCase__ ) @dataclass class lowercase_ ( UpperCamelCase_ ): """simple docstring""" UpperCAmelCase_ : str = 42 class lowercase_ ( UpperCamelCase_ , UpperCamelCase_ ): """simple docstring""" UpperCAmelCase_ : Dict = [e.name for e in FlaxKarrasDiffusionSchedulers] UpperCAmelCase_ : int = 42 @property def SCREAMING_SNAKE_CASE_ ( self ) ->Tuple: return True @register_to_config def __init__( self , __SCREAMING_SNAKE_CASE = 1000 , __SCREAMING_SNAKE_CASE = 0.0_0_0_1 , __SCREAMING_SNAKE_CASE = 0.0_2 , __SCREAMING_SNAKE_CASE = "linear" , __SCREAMING_SNAKE_CASE = None , __SCREAMING_SNAKE_CASE = "fixed_small" , __SCREAMING_SNAKE_CASE = True , __SCREAMING_SNAKE_CASE = "epsilon" , __SCREAMING_SNAKE_CASE = jnp.floataa , ) ->List[Any]: lowerCAmelCase = dtype def SCREAMING_SNAKE_CASE_ ( self , __SCREAMING_SNAKE_CASE = None ) ->DDPMSchedulerState: if common is None: lowerCAmelCase = CommonSchedulerState.create(self ) # standard deviation of the initial noise distribution lowerCAmelCase = jnp.array(1.0 , dtype=self.dtype ) lowerCAmelCase = jnp.arange(0 , self.config.num_train_timesteps ).round()[::-1] return DDPMSchedulerState.create( common=lowerCamelCase__ , init_noise_sigma=lowerCamelCase__ , timesteps=lowerCamelCase__ , ) def SCREAMING_SNAKE_CASE_ ( self , __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE = None ) ->jnp.ndarray: return sample def SCREAMING_SNAKE_CASE_ ( self , __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE = () ) ->DDPMSchedulerState: lowerCAmelCase = self.config.num_train_timesteps // num_inference_steps # creates integer timesteps by multiplying by ratio # rounding to avoid issues when num_inference_step is power of 3 lowerCAmelCase = (jnp.arange(0 , lowerCamelCase__ ) * step_ratio).round()[::-1] return state.replace( num_inference_steps=lowerCamelCase__ , timesteps=lowerCamelCase__ , ) def SCREAMING_SNAKE_CASE_ ( self , __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE=None , __SCREAMING_SNAKE_CASE=None ) ->Optional[int]: lowerCAmelCase = state.common.alphas_cumprod[t] lowerCAmelCase = jnp.where(t > 0 , state.common.alphas_cumprod[t - 1] , jnp.array(1.0 , dtype=self.dtype ) ) # 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 lowerCAmelCase = (1 - alpha_prod_t_prev) / (1 - alpha_prod_t) * state.common.betas[t] if variance_type is None: lowerCAmelCase = self.config.variance_type # hacks - were probably added for training stability if variance_type == "fixed_small": lowerCAmelCase = jnp.clip(lowerCamelCase__ , a_min=1e-20 ) # for rl-diffuser https://arxiv.org/abs/2205.09991 elif variance_type == "fixed_small_log": lowerCAmelCase = jnp.log(jnp.clip(lowerCamelCase__ , a_min=1e-20 ) ) elif variance_type == "fixed_large": lowerCAmelCase = state.common.betas[t] elif variance_type == "fixed_large_log": # Glide max_log lowerCAmelCase = jnp.log(state.common.betas[t] ) elif variance_type == "learned": return predicted_variance elif variance_type == "learned_range": lowerCAmelCase = variance lowerCAmelCase = state.common.betas[t] lowerCAmelCase = (predicted_variance + 1) / 2 lowerCAmelCase = frac * max_log + (1 - frac) * min_log return variance def SCREAMING_SNAKE_CASE_ ( self , __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE = None , __SCREAMING_SNAKE_CASE = True , ) ->Union[FlaxDDPMSchedulerOutput, Tuple]: lowerCAmelCase = timestep if key is None: lowerCAmelCase = jax.random.PRNGKey(0 ) if model_output.shape[1] == sample.shape[1] * 2 and self.config.variance_type in ["learned", "learned_range"]: lowerCAmelCase , lowerCAmelCase = jnp.split(lowerCamelCase__ , sample.shape[1] , axis=1 ) else: lowerCAmelCase = None # 1. compute alphas, betas lowerCAmelCase = state.common.alphas_cumprod[t] lowerCAmelCase = jnp.where(t > 0 , state.common.alphas_cumprod[t - 1] , jnp.array(1.0 , dtype=self.dtype ) ) lowerCAmelCase = 1 - alpha_prod_t lowerCAmelCase = 1 - alpha_prod_t_prev # 2. compute predicted original sample from predicted noise also called # "predicted x_0" of formula (15) from https://arxiv.org/pdf/2006.11239.pdf if self.config.prediction_type == "epsilon": lowerCAmelCase = (sample - beta_prod_t ** 0.5 * model_output) / alpha_prod_t ** 0.5 elif self.config.prediction_type == "sample": lowerCAmelCase = model_output elif self.config.prediction_type == "v_prediction": lowerCAmelCase = (alpha_prod_t**0.5) * sample - (beta_prod_t**0.5) * model_output else: raise ValueError( F"prediction_type given as {self.config.prediction_type} must be one of `epsilon`, `sample` " ''' for the FlaxDDPMScheduler.''' ) # 3. Clip "predicted x_0" if self.config.clip_sample: lowerCAmelCase = jnp.clip(lowerCamelCase__ , -1 , 1 ) # 4. Compute coefficients for pred_original_sample x_0 and current sample x_t # See formula (7) from https://arxiv.org/pdf/2006.11239.pdf lowerCAmelCase = (alpha_prod_t_prev ** 0.5 * state.common.betas[t]) / beta_prod_t lowerCAmelCase = state.common.alphas[t] ** 0.5 * beta_prod_t_prev / beta_prod_t # 5. Compute predicted previous sample µ_t # See formula (7) from https://arxiv.org/pdf/2006.11239.pdf lowerCAmelCase = pred_original_sample_coeff * pred_original_sample + current_sample_coeff * sample # 6. Add noise def random_variance(): lowerCAmelCase = jax.random.split(lowerCamelCase__ , num=1 ) lowerCAmelCase = jax.random.normal(lowerCamelCase__ , shape=model_output.shape , dtype=self.dtype ) return (self._get_variance(lowerCamelCase__ , lowerCamelCase__ , predicted_variance=lowerCamelCase__ ) ** 0.5) * noise lowerCAmelCase = jnp.where(t > 0 , random_variance() , jnp.zeros(model_output.shape , dtype=self.dtype ) ) lowerCAmelCase = pred_prev_sample + variance if not return_dict: return (pred_prev_sample, state) return FlaxDDPMSchedulerOutput(prev_sample=lowerCamelCase__ , state=lowerCamelCase__ ) def SCREAMING_SNAKE_CASE_ ( self , __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE , ) ->jnp.ndarray: return add_noise_common(state.common , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) def SCREAMING_SNAKE_CASE_ ( self , __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE , ) ->jnp.ndarray: return get_velocity_common(state.common , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) def __len__( self ) ->List[str]: return self.config.num_train_timesteps
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from __future__ import annotations # This is the precision for this function which can be altered. # It is recommended for users to keep this number greater than or equal to 10. __A = 10 def lowerCamelCase_ ( UpperCamelCase__ : int , UpperCamelCase__ : int , UpperCamelCase__ : list[int] , UpperCamelCase__ : int ) -> int: """simple docstring""" for i in range(UpperCamelCase__ , UpperCamelCase__ ): if array[i] == target: return i return -1 def lowerCamelCase_ ( UpperCamelCase__ : list[int] , UpperCamelCase__ : int ) -> int: """simple docstring""" __lowerCamelCase = 0 __lowerCamelCase = len(UpperCamelCase__ ) while left <= right: if right - left < precision: return lin_search(UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ ) __lowerCamelCase = (left + right) // 3 + 1 __lowerCamelCase = 2 * (left + right) // 3 + 1 if array[one_third] == target: return one_third elif array[two_third] == target: return two_third elif target < array[one_third]: __lowerCamelCase = one_third - 1 elif array[two_third] < target: __lowerCamelCase = two_third + 1 else: __lowerCamelCase = one_third + 1 __lowerCamelCase = two_third - 1 else: return -1 def lowerCamelCase_ ( UpperCamelCase__ : int , UpperCamelCase__ : int , UpperCamelCase__ : list[int] , UpperCamelCase__ : int ) -> int: """simple docstring""" if left < right: if right - left < precision: return lin_search(UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ ) __lowerCamelCase = (left + right) // 3 + 1 __lowerCamelCase = 2 * (left + right) // 3 + 1 if array[one_third] == target: return one_third elif array[two_third] == target: return two_third elif target < array[one_third]: return rec_ternary_search(UpperCamelCase__ , one_third - 1 , UpperCamelCase__ , UpperCamelCase__ ) elif array[two_third] < target: return rec_ternary_search(two_third + 1 , UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ ) else: return rec_ternary_search(one_third + 1 , two_third - 1 , UpperCamelCase__ , UpperCamelCase__ ) else: return -1 if __name__ == "__main__": import doctest doctest.testmod() __A = input("Enter numbers separated by comma:\n").strip() __A = [int(item.strip()) for item in user_input.split(",")] assert collection == sorted(collection), f"List must be ordered.\n{collection}." __A = int(input("Enter the number to be found in the list:\n").strip()) __A = ite_ternary_search(collection, target) __A = rec_ternary_search(0, len(collection) - 1, collection, target) if resulta != -1: print(f'''Iterative search: {target} found at positions: {resulta}''') print(f'''Recursive search: {target} found at positions: {resulta}''') else: print("Not found")
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"""simple docstring""" import math import unittest from transformers import BioGptConfig, is_torch_available from transformers.testing_utils import require_torch, slow, torch_device from ...generation.test_utils import GenerationTesterMixin from ...test_configuration_common import ConfigTester from ...test_modeling_common import ModelTesterMixin, ids_tensor, random_attention_mask from ...test_pipeline_mixin import PipelineTesterMixin if is_torch_available(): import torch from transformers import ( BioGptForCausalLM, BioGptForSequenceClassification, BioGptForTokenClassification, BioGptModel, BioGptTokenizer, ) from transformers.models.biogpt.modeling_biogpt import BIOGPT_PRETRAINED_MODEL_ARCHIVE_LIST class __snake_case : def __init__( self , lowercase , lowercase=13 , lowercase=7 , lowercase=True , lowercase=True , lowercase=False , lowercase=True , lowercase=99 , lowercase=32 , lowercase=5 , lowercase=4 , lowercase=37 , lowercase="gelu" , lowercase=0.1 , lowercase=0.1 , lowercase=5_12 , lowercase=16 , lowercase=2 , lowercase=0.02 , lowercase=3 , lowercase=4 , lowercase=None , ) -> Any: '''simple docstring''' a__: Optional[Any] = parent a__: int = batch_size a__: Optional[Any] = seq_length a__: int = is_training a__: Optional[int] = use_input_mask a__: str = use_token_type_ids a__: int = use_labels a__: Any = vocab_size a__: Optional[Any] = hidden_size a__: str = num_hidden_layers a__: str = num_attention_heads a__: List[Any] = intermediate_size a__: List[str] = hidden_act a__: Dict = hidden_dropout_prob a__: str = attention_probs_dropout_prob a__: Any = max_position_embeddings a__: Dict = type_vocab_size a__: Any = type_sequence_label_size a__: List[Any] = initializer_range a__: Union[str, Any] = num_labels a__: Tuple = num_choices a__: Any = scope def lowerCamelCase_ ( self) -> List[Any]: '''simple docstring''' a__: Optional[Any] = ids_tensor([self.batch_size, self.seq_length] , self.vocab_size) a__: Dict = None if self.use_input_mask: a__: str = random_attention_mask([self.batch_size, self.seq_length]) a__: Dict = None if self.use_token_type_ids: a__: List[Any] = ids_tensor([self.batch_size, self.seq_length] , self.type_vocab_size) a__: Optional[int] = None a__: Any = None a__: Optional[Any] = None if self.use_labels: a__: Dict = ids_tensor([self.batch_size] , self.type_sequence_label_size) a__: List[Any] = ids_tensor([self.batch_size, self.seq_length] , self.num_labels) a__: Optional[Any] = ids_tensor([self.batch_size] , self.num_choices) a__: Union[str, Any] = self.get_config() return config, input_ids, token_type_ids, input_mask, sequence_labels, token_labels, choice_labels def lowerCamelCase_ ( self) -> int: '''simple docstring''' return BioGptConfig( 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=lowerCamelCase__ , initializer_range=self.initializer_range , ) def lowerCamelCase_ ( self , lowercase , lowercase , lowercase , lowercase , lowercase , lowercase , lowercase) -> int: '''simple docstring''' a__: Any = BioGptModel(config=lowerCamelCase__) model.to(lowerCamelCase__) model.eval() a__: List[Any] = model(lowerCamelCase__ , attention_mask=lowerCamelCase__) a__: Union[str, Any] = model(lowerCamelCase__) self.parent.assertEqual(result.last_hidden_state.shape , (self.batch_size, self.seq_length, self.hidden_size)) def lowerCamelCase_ ( self , lowercase , lowercase , lowercase , lowercase , lowercase , lowercase , lowercase , lowercase , lowercase , ) -> str: '''simple docstring''' a__: str = BioGptForCausalLM(config=lowerCamelCase__) model.to(lowerCamelCase__) model.eval() a__: int = model(lowerCamelCase__ , attention_mask=lowerCamelCase__ , token_type_ids=lowerCamelCase__ , labels=lowerCamelCase__) self.parent.assertEqual(result.logits.shape , (self.batch_size, self.seq_length, self.vocab_size)) def lowerCamelCase_ ( self , lowercase , lowercase , lowercase , lowercase , lowercase , *lowercase) -> str: '''simple docstring''' a__: Tuple = BioGptModel(config=lowerCamelCase__) model.to(lowerCamelCase__) model.eval() # create attention mask a__: List[Any] = torch.ones(input_ids.shape , dtype=torch.long , device=lowerCamelCase__) a__: Dict = self.seq_length // 2 a__: Dict = 0 # first forward pass a__ , a__: Dict = model(lowerCamelCase__ , attention_mask=lowerCamelCase__).to_tuple() # create hypothetical next token and extent to next_input_ids a__: Dict = ids_tensor((self.batch_size, 1) , config.vocab_size) # change a random masked slice from input_ids a__: Union[str, Any] = ids_tensor((1,) , lowerCamelCase__).item() + 1 a__: Optional[Any] = ids_tensor((self.batch_size, 1) , config.vocab_size).squeeze(-1) a__: str = random_other_next_tokens # append to next input_ids and attn_mask a__: int = torch.cat([input_ids, next_tokens] , dim=-1) a__: Optional[int] = torch.cat( [attn_mask, torch.ones((attn_mask.shape[0], 1) , dtype=torch.long , device=lowerCamelCase__)] , dim=1 , ) # get two different outputs a__: Optional[Any] = model(lowerCamelCase__ , attention_mask=lowerCamelCase__)['last_hidden_state'] a__: Optional[Any] = model(lowerCamelCase__ , past_key_values=lowerCamelCase__ , attention_mask=lowerCamelCase__)['last_hidden_state'] # select random slice a__: List[Any] = ids_tensor((1,) , output_from_past.shape[-1]).item() a__: List[str] = output_from_no_past[:, -1, random_slice_idx].detach() a__: Tuple = output_from_past[:, 0, random_slice_idx].detach() # test that outputs are equal for slice self.parent.assertTrue(torch.allclose(lowerCamelCase__ , lowerCamelCase__ , atol=1e-3)) def lowerCamelCase_ ( self , lowercase , lowercase , lowercase , lowercase , lowercase , *lowercase) -> List[Any]: '''simple docstring''' a__: Any = BioGptModel(config=lowerCamelCase__).to(lowerCamelCase__).eval() a__: Optional[Any] = torch.ones(input_ids.shape , dtype=torch.long , device=lowerCamelCase__) # first forward pass a__: int = model(lowerCamelCase__ , attention_mask=lowerCamelCase__ , use_cache=lowerCamelCase__) a__ , a__: List[str] = outputs.to_tuple() # create hypothetical multiple next token and extent to next_input_ids a__: List[str] = ids_tensor((self.batch_size, 3) , config.vocab_size) a__: Any = ids_tensor((self.batch_size, 3) , 2) # append to next input_ids and a__: str = torch.cat([input_ids, next_tokens] , dim=-1) a__: Dict = torch.cat([attention_mask, next_attn_mask] , dim=-1) a__: int = model(lowerCamelCase__ , attention_mask=lowerCamelCase__)['last_hidden_state'] a__: Tuple = model(lowerCamelCase__ , attention_mask=lowerCamelCase__ , past_key_values=lowerCamelCase__)[ 'last_hidden_state' ] # select random slice a__: List[str] = ids_tensor((1,) , output_from_past.shape[-1]).item() a__: Tuple = output_from_no_past[:, -3:, random_slice_idx].detach() a__: str = 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(lowerCamelCase__ , lowerCamelCase__ , atol=1e-3)) def lowerCamelCase_ ( self , lowercase , lowercase , lowercase , lowercase , lowercase , *lowercase , lowercase=False) -> Union[str, Any]: '''simple docstring''' a__: int = BioGptForCausalLM(lowerCamelCase__) model.to(lowerCamelCase__) if gradient_checkpointing: model.gradient_checkpointing_enable() a__: str = model(lowerCamelCase__ , labels=lowerCamelCase__) self.parent.assertEqual(result.loss.shape , ()) self.parent.assertEqual(result.logits.shape , (self.batch_size, self.seq_length, self.vocab_size)) result.loss.backward() def lowerCamelCase_ ( self , lowercase , *lowercase) -> List[Any]: '''simple docstring''' a__: Any = BioGptModel(lowerCamelCase__) a__: List[str] = model.config.initializer_range / math.sqrt(2 * model.config.num_hidden_layers) for key in model.state_dict().keys(): if "c_proj" in key and "weight" in key: self.parent.assertLessEqual(abs(torch.std(model.state_dict()[key]) - model_std) , 0.001) self.parent.assertLessEqual(abs(torch.mean(model.state_dict()[key]) - 0.0) , 0.01) def lowerCamelCase_ ( self , lowercase , lowercase , lowercase , lowercase , lowercase , *lowercase) -> Tuple: '''simple docstring''' a__: Union[str, Any] = self.num_labels a__: Optional[Any] = BioGptForTokenClassification(lowerCamelCase__) model.to(lowerCamelCase__) model.eval() a__: int = model(lowerCamelCase__ , attention_mask=lowerCamelCase__ , token_type_ids=lowerCamelCase__) self.parent.assertEqual(result.logits.shape , (self.batch_size, self.seq_length, self.num_labels)) def lowerCamelCase_ ( self) -> str: '''simple docstring''' a__: Tuple = self.prepare_config_and_inputs() ( ( a__ ) , ( a__ ) , ( a__ ) , ( a__ ) , ( a__ ) , ( a__ ) , ( a__ ) , ): Any = config_and_inputs a__: Optional[int] = {'input_ids': input_ids, 'attention_mask': input_mask} return config, inputs_dict @require_torch class __snake_case ( __lowerCAmelCase , __lowerCAmelCase , __lowerCAmelCase , unittest.TestCase ): a__ = ( (BioGptModel, BioGptForCausalLM, BioGptForSequenceClassification, BioGptForTokenClassification) if is_torch_available() else () ) a__ = (BioGptForCausalLM,) if is_torch_available() else () a__ = ( { """feature-extraction""": BioGptModel, """text-classification""": BioGptForSequenceClassification, """text-generation""": BioGptForCausalLM, """token-classification""": BioGptForTokenClassification, """zero-shot""": BioGptForSequenceClassification, } if is_torch_available() else {} ) a__ = False def lowerCamelCase_ ( self) -> Optional[int]: '''simple docstring''' a__: int = BioGptModelTester(self) a__: Tuple = ConfigTester(self , config_class=lowerCamelCase__ , hidden_size=37) def lowerCamelCase_ ( self) -> Optional[int]: '''simple docstring''' self.config_tester.run_common_tests() def lowerCamelCase_ ( self) -> Any: '''simple docstring''' a__: Dict = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_model(*lowerCamelCase__) def lowerCamelCase_ ( self) -> Any: '''simple docstring''' a__: List[Any] = self.model_tester.prepare_config_and_inputs() for type in ["absolute", "relative_key", "relative_key_query"]: a__: str = type self.model_tester.create_and_check_model(*lowerCamelCase__) def lowerCamelCase_ ( self) -> Optional[Any]: '''simple docstring''' a__: Optional[Any] = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_biogpt_model_attention_mask_past(*lowerCamelCase__) def lowerCamelCase_ ( self) -> Tuple: '''simple docstring''' a__: Optional[Any] = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_forward_and_backwards(*lowerCamelCase__ , gradient_checkpointing=lowerCamelCase__) def lowerCamelCase_ ( self) -> str: '''simple docstring''' a__: Any = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_biogpt_model_past_large_inputs(*lowerCamelCase__) def lowerCamelCase_ ( self) -> str: '''simple docstring''' a__: Any = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_biogpt_weight_initialization(*lowerCamelCase__) def lowerCamelCase_ ( self) -> Optional[int]: '''simple docstring''' a__: Union[str, Any] = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_biogpt_for_token_classification(*lowerCamelCase__) @slow def lowerCamelCase_ ( self) -> Tuple: '''simple docstring''' a__: Any = BioGptForCausalLM.from_pretrained('microsoft/biogpt') model.to(lowerCamelCase__) a__: Tuple = BioGptTokenizer.from_pretrained('microsoft/biogpt') a__: List[Any] = 'left' # Define PAD Token = EOS Token = 50256 a__: str = tokenizer.eos_token a__: str = model.config.eos_token_id # use different length sentences to test batching a__: Optional[int] = [ 'Hello, my dog is a little', 'Today, I', ] a__: Tuple = tokenizer(lowerCamelCase__ , return_tensors='pt' , padding=lowerCamelCase__) a__: int = inputs['input_ids'].to(lowerCamelCase__) a__: Tuple = model.generate( input_ids=lowerCamelCase__ , attention_mask=inputs['attention_mask'].to(lowerCamelCase__) , ) a__: Any = tokenizer(sentences[0] , return_tensors='pt').input_ids.to(lowerCamelCase__) a__: str = model.generate(input_ids=lowerCamelCase__) a__: Optional[int] = inputs_non_padded.shape[-1] - inputs['attention_mask'][-1].long().sum().cpu().item() a__: Tuple = tokenizer(sentences[1] , return_tensors='pt').input_ids.to(lowerCamelCase__) a__: List[str] = model.generate(input_ids=lowerCamelCase__ , max_length=model.config.max_length - num_paddings) a__: List[Any] = tokenizer.batch_decode(lowerCamelCase__ , skip_special_tokens=lowerCamelCase__) a__: Optional[int] = tokenizer.decode(output_non_padded[0] , skip_special_tokens=lowerCamelCase__) a__: Union[str, Any] = tokenizer.decode(output_padded[0] , skip_special_tokens=lowerCamelCase__) a__: str = [ 'Hello, my dog is a little bit bigger than a little bit.', 'Today, I have a good idea of how to use the information', ] self.assertListEqual(lowerCamelCase__ , lowerCamelCase__) self.assertListEqual(lowerCamelCase__ , [non_padded_sentence, padded_sentence]) @slow def lowerCamelCase_ ( self) -> Union[str, Any]: '''simple docstring''' for model_name in BIOGPT_PRETRAINED_MODEL_ARCHIVE_LIST[:1]: a__: List[Any] = BioGptModel.from_pretrained(lowerCamelCase__) self.assertIsNotNone(lowerCamelCase__) def lowerCamelCase_ ( self) -> Union[str, Any]: '''simple docstring''' a__ , a__: int = self.model_tester.prepare_config_and_inputs_for_common() a__: Optional[int] = 3 a__: Any = input_dict['input_ids'] a__: Any = input_ids.ne(1).to(lowerCamelCase__) a__: str = ids_tensor([self.model_tester.batch_size] , self.model_tester.type_sequence_label_size) a__: List[Any] = BioGptForSequenceClassification(lowerCamelCase__) model.to(lowerCamelCase__) model.eval() a__: Union[str, Any] = model(lowerCamelCase__ , attention_mask=lowerCamelCase__ , labels=lowerCamelCase__) self.assertEqual(result.logits.shape , (self.model_tester.batch_size, self.model_tester.num_labels)) def lowerCamelCase_ ( self) -> Any: '''simple docstring''' a__ , a__: str = self.model_tester.prepare_config_and_inputs_for_common() a__: Any = 3 a__: str = 'multi_label_classification' a__: Optional[int] = input_dict['input_ids'] a__: Any = input_ids.ne(1).to(lowerCamelCase__) a__: Tuple = ids_tensor( [self.model_tester.batch_size, config.num_labels] , self.model_tester.type_sequence_label_size).to(torch.float) a__: Union[str, Any] = BioGptForSequenceClassification(lowerCamelCase__) model.to(lowerCamelCase__) model.eval() a__: Optional[Any] = model(lowerCamelCase__ , attention_mask=lowerCamelCase__ , labels=lowerCamelCase__) self.assertEqual(result.logits.shape , (self.model_tester.batch_size, self.model_tester.num_labels)) @require_torch class __snake_case ( unittest.TestCase ): @slow def lowerCamelCase_ ( self) -> str: '''simple docstring''' a__: Tuple = BioGptForCausalLM.from_pretrained('microsoft/biogpt') a__: List[Any] = torch.tensor([[2, 48_05, 9, 6_56, 21]]) a__: str = model(lowerCamelCase__)[0] a__: str = 4_23_84 a__: Optional[Any] = torch.Size((1, 5, vocab_size)) self.assertEqual(output.shape , lowerCamelCase__) a__: Optional[Any] = torch.tensor( [[[-9.5236, -9.8918, 10.4557], [-11.0469, -9.6423, 8.1022], [-8.8664, -7.8826, 5.5325]]]) self.assertTrue(torch.allclose(output[:, :3, :3] , lowerCamelCase__ , atol=1e-4)) @slow def lowerCamelCase_ ( self) -> Optional[int]: '''simple docstring''' a__: Tuple = BioGptTokenizer.from_pretrained('microsoft/biogpt') a__: Tuple = BioGptForCausalLM.from_pretrained('microsoft/biogpt') model.to(lowerCamelCase__) torch.manual_seed(0) a__: str = tokenizer('COVID-19 is' , return_tensors='pt').to(lowerCamelCase__) a__: Union[str, Any] = model.generate( **lowerCamelCase__ , min_length=1_00 , max_length=10_24 , num_beams=5 , early_stopping=lowerCamelCase__ , ) a__: Tuple = tokenizer.decode(output_ids[0] , skip_special_tokens=lowerCamelCase__) a__: Dict = ( 'COVID-19 is a global pandemic caused by severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), the' ' causative agent of coronavirus disease 2019 (COVID-19), which has spread to more than 200 countries and' ' territories, including the United States (US), Canada, Australia, New Zealand, the United Kingdom (UK),' ' and the United States of America (USA), as of March 11, 2020, with more than 800,000 confirmed cases and' ' more than 800,000 deaths.' ) self.assertEqual(lowerCamelCase__ , lowerCamelCase__)
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import string # frequency taken from https://en.wikipedia.org/wiki/Letter_frequency __A = { "E": 1_2.7_0, "T": 9.0_6, "A": 8.1_7, "O": 7.5_1, "I": 6.9_7, "N": 6.7_5, "S": 6.3_3, "H": 6.0_9, "R": 5.9_9, "D": 4.2_5, "L": 4.0_3, "C": 2.7_8, "U": 2.7_6, "M": 2.4_1, "W": 2.3_6, "F": 2.2_3, "G": 2.0_2, "Y": 1.9_7, "P": 1.9_3, "B": 1.2_9, "V": 0.9_8, "K": 0.7_7, "J": 0.1_5, "X": 0.1_5, "Q": 0.1_0, "Z": 0.0_7, } __A = "ETAOINSHRDLCUMWFGYPBVKJXQZ" __A = "ABCDEFGHIJKLMNOPQRSTUVWXYZ" def lowerCamelCase_ ( UpperCamelCase__ : str ) -> dict[str, int]: """simple docstring""" __lowerCamelCase = {letter: 0 for letter in string.ascii_uppercase} for letter in message.upper(): if letter in LETTERS: letter_count[letter] += 1 return letter_count def lowerCamelCase_ ( UpperCamelCase__ : tuple ) -> str: """simple docstring""" return x[0] def lowerCamelCase_ ( UpperCamelCase__ : str ) -> str: """simple docstring""" __lowerCamelCase = get_letter_count(UpperCamelCase__ ) __lowerCamelCase = { freq: [] for letter, freq in letter_to_freq.items() } for letter in LETTERS: freq_to_letter[letter_to_freq[letter]].append(UpperCamelCase__ ) __lowerCamelCase = {} for freq in freq_to_letter: freq_to_letter[freq].sort(key=ETAOIN.find , reverse=UpperCamelCase__ ) __lowerCamelCase = ''.join(freq_to_letter[freq] ) __lowerCamelCase = list(freq_to_letter_str.items() ) freq_pairs.sort(key=UpperCamelCase__ , reverse=UpperCamelCase__ ) __lowerCamelCase = [freq_pair[1] for freq_pair in freq_pairs] return "".join(UpperCamelCase__ ) def lowerCamelCase_ ( UpperCamelCase__ : str ) -> int: """simple docstring""" __lowerCamelCase = get_frequency_order(UpperCamelCase__ ) __lowerCamelCase = 0 for common_letter in ETAOIN[:6]: if common_letter in freq_order[:6]: match_score += 1 for uncommon_letter in ETAOIN[-6:]: if uncommon_letter in freq_order[-6:]: match_score += 1 return match_score if __name__ == "__main__": import doctest doctest.testmod()
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"""simple docstring""" def lowercase__ ( snake_case_ :int = 600_851_475_143 ): try: __UpperCAmelCase = int(UpperCamelCase__ ) except (TypeError, ValueError): raise TypeError('''Parameter n must be int or castable to int.''' ) if n <= 0: raise ValueError('''Parameter n must be greater than or equal to one.''' ) __UpperCAmelCase = 2 __UpperCAmelCase = 0 if n == 2: return 2 while n > 2: while n % i != 0: i += 1 __UpperCAmelCase = i while n % i == 0: __UpperCAmelCase = n // i i += 1 return int(UpperCamelCase__ ) if __name__ == "__main__": print(f"""{solution() = }""")
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class __lowerCAmelCase : """simple docstring""" def __init__( self , lowerCamelCase__ ) -> Any: '''simple docstring''' __lowerCamelCase = n __lowerCamelCase = [None] * self.n __lowerCamelCase = 0 # index of the first element __lowerCamelCase = 0 __lowerCamelCase = 0 def __len__( self ) -> int: '''simple docstring''' return self.size def lowercase_ ( self ) -> bool: '''simple docstring''' return self.size == 0 def lowercase_ ( self ) -> str: '''simple docstring''' return False if self.is_empty() else self.array[self.front] def lowercase_ ( self , lowerCamelCase__ ) -> Optional[Any]: '''simple docstring''' if self.size >= self.n: raise Exception('QUEUE IS FULL' ) __lowerCamelCase = data __lowerCamelCase = (self.rear + 1) % self.n self.size += 1 return self def lowercase_ ( self ) -> Tuple: '''simple docstring''' if self.size == 0: raise Exception('UNDERFLOW' ) __lowerCamelCase = self.array[self.front] __lowerCamelCase = None __lowerCamelCase = (self.front + 1) % self.n self.size -= 1 return temp
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'''simple docstring''' import unittest from transformers import is_torch_available from transformers.testing_utils import require_torch, slow, torch_device from ...generation.test_utils import GenerationTesterMixin from ...test_configuration_common import ConfigTester from ...test_modeling_common import ModelTesterMixin, ids_tensor from ...test_pipeline_mixin import PipelineTesterMixin if is_torch_available(): import torch from transformers import ( OPENAI_GPT_PRETRAINED_MODEL_ARCHIVE_LIST, OpenAIGPTConfig, OpenAIGPTDoubleHeadsModel, OpenAIGPTForSequenceClassification, OpenAIGPTLMHeadModel, OpenAIGPTModel, ) class UpperCAmelCase__ : """simple docstring""" def __init__( self : List[Any] ,_a : Optional[int] ,_a : int=13 ,_a : str=7 ,_a : int=True ,_a : Tuple=True ,_a : Tuple=True ,_a : Dict=99 ,_a : Union[str, Any]=32 ,_a : Tuple=5 ,_a : List[str]=4 ,_a : str=37 ,_a : Optional[Any]="gelu" ,_a : int=0.1 ,_a : List[Any]=0.1 ,_a : Tuple=512 ,_a : Dict=16 ,_a : Dict=2 ,_a : Optional[int]=0.02 ,_a : str=3 ,_a : Optional[Any]=4 ,_a : List[str]=None ,): '''simple docstring''' _a : Optional[Any] = parent _a : Tuple = batch_size _a : Any = seq_length _a : Union[str, Any] = is_training _a : Any = use_token_type_ids _a : List[Any] = use_labels _a : List[Any] = vocab_size _a : Dict = hidden_size _a : Union[str, Any] = num_hidden_layers _a : int = num_attention_heads _a : List[str] = intermediate_size _a : Dict = hidden_act _a : str = hidden_dropout_prob _a : Tuple = attention_probs_dropout_prob _a : Dict = max_position_embeddings _a : Dict = type_vocab_size _a : Union[str, Any] = type_sequence_label_size _a : Tuple = initializer_range _a : Tuple = num_labels _a : str = num_choices _a : List[str] = scope _a : Union[str, Any] = self.vocab_size - 1 def __lowercase ( self : Dict ): '''simple docstring''' _a : Optional[Any] = ids_tensor([self.batch_size, self.seq_length] ,self.vocab_size ) _a : List[str] = None if self.use_token_type_ids: _a : Optional[int] = ids_tensor([self.batch_size, self.seq_length] ,self.type_vocab_size ) _a : Optional[int] = None _a : str = None _a : int = None if self.use_labels: _a : Tuple = ids_tensor([self.batch_size] ,self.type_sequence_label_size ) _a : int = ids_tensor([self.batch_size, self.seq_length] ,self.num_labels ) _a : Optional[Any] = ids_tensor([self.batch_size] ,self.num_choices ) _a : Union[str, Any] = OpenAIGPTConfig( vocab_size=self.vocab_size ,n_embd=self.hidden_size ,n_layer=self.num_hidden_layers ,n_head=self.num_attention_heads ,n_positions=self.max_position_embeddings ,pad_token_id=self.pad_token_id ,) _a : Union[str, Any] = ids_tensor([self.num_hidden_layers, self.num_attention_heads] ,2 ) return ( config, input_ids, head_mask, token_type_ids, sequence_labels, token_labels, choice_labels, ) def __lowercase ( self : Any ,_a : int ,_a : List[Any] ,_a : str ,_a : Optional[int] ,*_a : Union[str, Any] ): '''simple docstring''' _a : Optional[int] = OpenAIGPTModel(config=lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() _a : int = model(lowerCamelCase__ ,token_type_ids=lowerCamelCase__ ,head_mask=lowerCamelCase__ ) _a : Dict = model(lowerCamelCase__ ,token_type_ids=lowerCamelCase__ ) _a : List[str] = model(lowerCamelCase__ ) self.parent.assertEqual(result.last_hidden_state.shape ,(self.batch_size, self.seq_length, self.hidden_size) ) def __lowercase ( self : List[Any] ,_a : Any ,_a : int ,_a : Optional[Any] ,_a : int ,*_a : Union[str, Any] ): '''simple docstring''' _a : Any = OpenAIGPTLMHeadModel(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() _a : Optional[int] = model(lowerCamelCase__ ,token_type_ids=lowerCamelCase__ ,labels=lowerCamelCase__ ) self.parent.assertEqual(result.loss.shape ,() ) self.parent.assertEqual(result.logits.shape ,(self.batch_size, self.seq_length, self.vocab_size) ) def __lowercase ( self : Tuple ,_a : str ,_a : Any ,_a : str ,_a : List[Any] ,*_a : List[Any] ): '''simple docstring''' _a : Optional[Any] = OpenAIGPTDoubleHeadsModel(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() _a : List[str] = model(lowerCamelCase__ ,token_type_ids=lowerCamelCase__ ,labels=lowerCamelCase__ ) self.parent.assertEqual(result.loss.shape ,() ) self.parent.assertEqual(result.logits.shape ,(self.batch_size, self.seq_length, self.vocab_size) ) def __lowercase ( self : str ,_a : Any ,_a : Optional[Any] ,_a : List[Any] ,_a : int ,*_a : int ): '''simple docstring''' _a : List[Any] = self.num_labels _a : Optional[int] = OpenAIGPTForSequenceClassification(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() _a : str = ids_tensor([self.batch_size] ,self.type_sequence_label_size ) _a : List[str] = model(lowerCamelCase__ ,token_type_ids=lowerCamelCase__ ,labels=lowerCamelCase__ ) self.parent.assertEqual(result.logits.shape ,(self.batch_size, self.num_labels) ) def __lowercase ( self : str ): '''simple docstring''' _a : Dict = self.prepare_config_and_inputs() ( ( _a ), ( _a ), ( _a ), ( _a ), ( _a ), ( _a ), ( _a ), ) : List[Any] = config_and_inputs _a : int = { 'input_ids': input_ids, 'token_type_ids': token_type_ids, 'head_mask': head_mask, } return config, inputs_dict @require_torch class UpperCAmelCase__ ( lowercase__ , lowercase__ , lowercase__ , unittest.TestCase ): """simple docstring""" __UpperCAmelCase : Dict = ( (OpenAIGPTModel, OpenAIGPTLMHeadModel, OpenAIGPTDoubleHeadsModel, OpenAIGPTForSequenceClassification) if is_torch_available() else () ) __UpperCAmelCase : Optional[Any] = ( (OpenAIGPTLMHeadModel,) if is_torch_available() else () ) # TODO (PVP): Add Double HeadsModel when generate() function is changed accordingly __UpperCAmelCase : Any = ( { '''feature-extraction''': OpenAIGPTModel, '''text-classification''': OpenAIGPTForSequenceClassification, '''text-generation''': OpenAIGPTLMHeadModel, '''zero-shot''': OpenAIGPTForSequenceClassification, } if is_torch_available() else {} ) def __lowercase ( self : int ,_a : int ,_a : Dict ,_a : Union[str, Any] ,_a : Optional[Any] ,_a : List[Any] ): '''simple docstring''' if pipeline_test_casse_name == "ZeroShotClassificationPipelineTests": # Get `tokenizer does not have a padding token` error for both fast/slow tokenizers. # `OpenAIGPTConfig` was never used in pipeline tests, either because of a missing checkpoint or because a # tiny config could not be created. return True return False def __lowercase ( self : Optional[int] ,_a : str ,_a : Optional[Any] ,_a : int=False ): '''simple docstring''' _a : List[Any] = super()._prepare_for_class(lowerCamelCase__ ,lowerCamelCase__ ,return_labels=lowerCamelCase__ ) if return_labels: if model_class.__name__ == "OpenAIGPTDoubleHeadsModel": _a : Tuple = torch.zeros( (self.model_tester.batch_size, self.model_tester.num_choices, self.model_tester.seq_length) ,dtype=torch.long ,device=lowerCamelCase__ ,) _a : Optional[int] = inputs_dict['labels'] _a : Dict = inputs_dict['labels'] _a : List[str] = torch.zeros( (self.model_tester.batch_size, self.model_tester.num_choices) ,dtype=torch.long ,device=lowerCamelCase__ ,) _a : Optional[int] = torch.zeros( self.model_tester.batch_size ,dtype=torch.long ,device=lowerCamelCase__ ) return inputs_dict def __lowercase ( self : Any ): '''simple docstring''' _a : str = OpenAIGPTModelTester(self ) _a : List[str] = ConfigTester(self ,config_class=lowerCamelCase__ ,n_embd=37 ) def __lowercase ( self : Optional[Any] ): '''simple docstring''' self.config_tester.run_common_tests() def __lowercase ( self : List[str] ): '''simple docstring''' _a : Union[str, Any] = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_openai_gpt_model(*lowerCamelCase__ ) def __lowercase ( self : Tuple ): '''simple docstring''' _a : List[str] = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_lm_head_model(*lowerCamelCase__ ) def __lowercase ( self : List[Any] ): '''simple docstring''' _a : List[str] = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_double_lm_head_model(*lowerCamelCase__ ) def __lowercase ( self : List[Any] ): '''simple docstring''' _a : Any = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_openai_gpt_for_sequence_classification(*lowerCamelCase__ ) @slow def __lowercase ( self : Union[str, Any] ): '''simple docstring''' for model_name in OPENAI_GPT_PRETRAINED_MODEL_ARCHIVE_LIST[:1]: _a : int = OpenAIGPTModel.from_pretrained(lowerCamelCase__ ) self.assertIsNotNone(lowerCamelCase__ ) @require_torch class UpperCAmelCase__ ( unittest.TestCase ): """simple docstring""" @slow def __lowercase ( self : List[str] ): '''simple docstring''' _a : str = OpenAIGPTLMHeadModel.from_pretrained('openai-gpt' ) model.to(lowerCamelCase__ ) _a : List[str] = torch.tensor([[481, 4735, 544]] ,dtype=torch.long ,device=lowerCamelCase__ ) # the president is _a : List[str] = [ 481, 4735, 544, 246, 963, 870, 762, 239, 244, 4_0477, 244, 249, 719, 881, 487, 544, 240, 244, 603, 481, ] # the president is a very good man. " \n " i\'m sure he is, " said the _a : Optional[int] = model.generate(lowerCamelCase__ ,do_sample=lowerCamelCase__ ) self.assertListEqual(output_ids[0].tolist() ,lowerCamelCase__ )
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import unittest import numpy as np from transformers.testing_utils import require_flax, require_tf, require_torch from transformers.utils import ( expand_dims, flatten_dict, is_flax_available, is_tf_available, is_torch_available, reshape, squeeze, transpose, ) if is_flax_available(): import jax.numpy as jnp if is_tf_available(): import tensorflow as tf if is_torch_available(): import torch class __lowerCAmelCase ( unittest.TestCase ): """simple docstring""" def lowercase_ ( self ) -> Tuple: '''simple docstring''' __lowerCamelCase = { 'task_specific_params': { 'summarization': {'length_penalty': 1.0, 'max_length': 128, 'min_length': 12, 'num_beams': 4}, 'summarization_cnn': {'length_penalty': 2.0, 'max_length': 142, 'min_length': 56, 'num_beams': 4}, 'summarization_xsum': {'length_penalty': 1.0, 'max_length': 62, 'min_length': 11, 'num_beams': 6}, } } __lowerCamelCase = { 'task_specific_params.summarization.length_penalty': 1.0, 'task_specific_params.summarization.max_length': 128, 'task_specific_params.summarization.min_length': 12, 'task_specific_params.summarization.num_beams': 4, 'task_specific_params.summarization_cnn.length_penalty': 2.0, 'task_specific_params.summarization_cnn.max_length': 142, 'task_specific_params.summarization_cnn.min_length': 56, 'task_specific_params.summarization_cnn.num_beams': 4, 'task_specific_params.summarization_xsum.length_penalty': 1.0, 'task_specific_params.summarization_xsum.max_length': 62, 'task_specific_params.summarization_xsum.min_length': 11, 'task_specific_params.summarization_xsum.num_beams': 6, } self.assertEqual(flatten_dict(lowerCamelCase__ ) , lowerCamelCase__ ) def lowercase_ ( self ) -> Tuple: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) self.assertTrue(np.allclose(transpose(lowerCamelCase__ ) , x.transpose() ) ) __lowerCamelCase = np.random.randn(3 , 4 , 5 ) self.assertTrue(np.allclose(transpose(lowerCamelCase__ , axes=(1, 2, 0) ) , x.transpose((1, 2, 0) ) ) ) @require_torch def lowercase_ ( self ) -> int: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) __lowerCamelCase = torch.tensor(lowerCamelCase__ ) self.assertTrue(np.allclose(transpose(lowerCamelCase__ ) , transpose(lowerCamelCase__ ).numpy() ) ) __lowerCamelCase = np.random.randn(3 , 4 , 5 ) __lowerCamelCase = torch.tensor(lowerCamelCase__ ) self.assertTrue(np.allclose(transpose(lowerCamelCase__ , axes=(1, 2, 0) ) , transpose(lowerCamelCase__ , axes=(1, 2, 0) ).numpy() ) ) @require_tf def lowercase_ ( self ) -> Union[str, Any]: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) __lowerCamelCase = tf.constant(lowerCamelCase__ ) self.assertTrue(np.allclose(transpose(lowerCamelCase__ ) , transpose(lowerCamelCase__ ).numpy() ) ) __lowerCamelCase = np.random.randn(3 , 4 , 5 ) __lowerCamelCase = tf.constant(lowerCamelCase__ ) self.assertTrue(np.allclose(transpose(lowerCamelCase__ , axes=(1, 2, 0) ) , transpose(lowerCamelCase__ , axes=(1, 2, 0) ).numpy() ) ) @require_flax def lowercase_ ( self ) -> Optional[int]: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) __lowerCamelCase = jnp.array(lowerCamelCase__ ) self.assertTrue(np.allclose(transpose(lowerCamelCase__ ) , np.asarray(transpose(lowerCamelCase__ ) ) ) ) __lowerCamelCase = np.random.randn(3 , 4 , 5 ) __lowerCamelCase = jnp.array(lowerCamelCase__ ) self.assertTrue(np.allclose(transpose(lowerCamelCase__ , axes=(1, 2, 0) ) , np.asarray(transpose(lowerCamelCase__ , axes=(1, 2, 0) ) ) ) ) def lowercase_ ( self ) -> int: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) self.assertTrue(np.allclose(reshape(lowerCamelCase__ , (4, 3) ) , np.reshape(lowerCamelCase__ , (4, 3) ) ) ) __lowerCamelCase = np.random.randn(3 , 4 , 5 ) self.assertTrue(np.allclose(reshape(lowerCamelCase__ , (12, 5) ) , np.reshape(lowerCamelCase__ , (12, 5) ) ) ) @require_torch def lowercase_ ( self ) -> List[Any]: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) __lowerCamelCase = torch.tensor(lowerCamelCase__ ) self.assertTrue(np.allclose(reshape(lowerCamelCase__ , (4, 3) ) , reshape(lowerCamelCase__ , (4, 3) ).numpy() ) ) __lowerCamelCase = np.random.randn(3 , 4 , 5 ) __lowerCamelCase = torch.tensor(lowerCamelCase__ ) self.assertTrue(np.allclose(reshape(lowerCamelCase__ , (12, 5) ) , reshape(lowerCamelCase__ , (12, 5) ).numpy() ) ) @require_tf def lowercase_ ( self ) -> Optional[int]: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) __lowerCamelCase = tf.constant(lowerCamelCase__ ) self.assertTrue(np.allclose(reshape(lowerCamelCase__ , (4, 3) ) , reshape(lowerCamelCase__ , (4, 3) ).numpy() ) ) __lowerCamelCase = np.random.randn(3 , 4 , 5 ) __lowerCamelCase = tf.constant(lowerCamelCase__ ) self.assertTrue(np.allclose(reshape(lowerCamelCase__ , (12, 5) ) , reshape(lowerCamelCase__ , (12, 5) ).numpy() ) ) @require_flax def lowercase_ ( self ) -> Tuple: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) __lowerCamelCase = jnp.array(lowerCamelCase__ ) self.assertTrue(np.allclose(reshape(lowerCamelCase__ , (4, 3) ) , np.asarray(reshape(lowerCamelCase__ , (4, 3) ) ) ) ) __lowerCamelCase = np.random.randn(3 , 4 , 5 ) __lowerCamelCase = jnp.array(lowerCamelCase__ ) self.assertTrue(np.allclose(reshape(lowerCamelCase__ , (12, 5) ) , np.asarray(reshape(lowerCamelCase__ , (12, 5) ) ) ) ) def lowercase_ ( self ) -> int: '''simple docstring''' __lowerCamelCase = np.random.randn(1 , 3 , 4 ) self.assertTrue(np.allclose(squeeze(lowerCamelCase__ ) , np.squeeze(lowerCamelCase__ ) ) ) __lowerCamelCase = np.random.randn(1 , 4 , 1 , 5 ) self.assertTrue(np.allclose(squeeze(lowerCamelCase__ , axis=2 ) , np.squeeze(lowerCamelCase__ , axis=2 ) ) ) @require_torch def lowercase_ ( self ) -> int: '''simple docstring''' __lowerCamelCase = np.random.randn(1 , 3 , 4 ) __lowerCamelCase = torch.tensor(lowerCamelCase__ ) self.assertTrue(np.allclose(squeeze(lowerCamelCase__ ) , squeeze(lowerCamelCase__ ).numpy() ) ) __lowerCamelCase = np.random.randn(1 , 4 , 1 , 5 ) __lowerCamelCase = torch.tensor(lowerCamelCase__ ) self.assertTrue(np.allclose(squeeze(lowerCamelCase__ , axis=2 ) , squeeze(lowerCamelCase__ , axis=2 ).numpy() ) ) @require_tf def lowercase_ ( self ) -> Union[str, Any]: '''simple docstring''' __lowerCamelCase = np.random.randn(1 , 3 , 4 ) __lowerCamelCase = tf.constant(lowerCamelCase__ ) self.assertTrue(np.allclose(squeeze(lowerCamelCase__ ) , squeeze(lowerCamelCase__ ).numpy() ) ) __lowerCamelCase = np.random.randn(1 , 4 , 1 , 5 ) __lowerCamelCase = tf.constant(lowerCamelCase__ ) self.assertTrue(np.allclose(squeeze(lowerCamelCase__ , axis=2 ) , squeeze(lowerCamelCase__ , axis=2 ).numpy() ) ) @require_flax def lowercase_ ( self ) -> List[str]: '''simple docstring''' __lowerCamelCase = np.random.randn(1 , 3 , 4 ) __lowerCamelCase = jnp.array(lowerCamelCase__ ) self.assertTrue(np.allclose(squeeze(lowerCamelCase__ ) , np.asarray(squeeze(lowerCamelCase__ ) ) ) ) __lowerCamelCase = np.random.randn(1 , 4 , 1 , 5 ) __lowerCamelCase = jnp.array(lowerCamelCase__ ) self.assertTrue(np.allclose(squeeze(lowerCamelCase__ , axis=2 ) , np.asarray(squeeze(lowerCamelCase__ , axis=2 ) ) ) ) def lowercase_ ( self ) -> int: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) self.assertTrue(np.allclose(expand_dims(lowerCamelCase__ , axis=1 ) , np.expand_dims(lowerCamelCase__ , axis=1 ) ) ) @require_torch def lowercase_ ( self ) -> Any: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) __lowerCamelCase = torch.tensor(lowerCamelCase__ ) self.assertTrue(np.allclose(expand_dims(lowerCamelCase__ , axis=1 ) , expand_dims(lowerCamelCase__ , axis=1 ).numpy() ) ) @require_tf def lowercase_ ( self ) -> Any: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) __lowerCamelCase = tf.constant(lowerCamelCase__ ) self.assertTrue(np.allclose(expand_dims(lowerCamelCase__ , axis=1 ) , expand_dims(lowerCamelCase__ , axis=1 ).numpy() ) ) @require_flax def lowercase_ ( self ) -> List[Any]: '''simple docstring''' __lowerCamelCase = np.random.randn(3 , 4 ) __lowerCamelCase = jnp.array(lowerCamelCase__ ) self.assertTrue(np.allclose(expand_dims(lowerCamelCase__ , axis=1 ) , np.asarray(expand_dims(lowerCamelCase__ , axis=1 ) ) ) )
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import argparse import requests import torch # pip3 install salesforce-lavis # I'm actually installing a slightly modified version: pip3 install git+https://github.com/nielsrogge/LAVIS.git@fix_lavis_float32 (there's also the fix_lavis branch) # also note: to convert Vicuna checkpoints, we had to include /home/niels/python_projects/checkpoints/FastChat/vicuna-7b in lavis/configs/models/blip2/blip2_instruct_vicuna7b.yaml # same for Vicuna-13b from lavis.models import load_model_and_preprocess from PIL import Image from transformers import ( AutoTokenizer, BlipImageProcessor, InstructBlipConfig, InstructBlipForConditionalGeneration, InstructBlipProcessor, InstructBlipQFormerConfig, InstructBlipVisionConfig, LlamaConfig, LlamaTokenizerFast, TaConfig, TaTokenizerFast, ) from transformers.utils.constants import OPENAI_CLIP_MEAN, OPENAI_CLIP_STD def UpperCAmelCase_ ( ): lowercase = 'https://raw.githubusercontent.com/salesforce/LAVIS/main/docs/_static/Confusing-Pictures.jpg' lowercase = Image.open(requests.get(UpperCamelCase__ , stream=UpperCamelCase__ ).raw ).convert('RGB' ) return image def UpperCAmelCase_ ( __SCREAMING_SNAKE_CASE ): lowercase = [] # fmt: off # vision encoder rename_keys.append(('visual_encoder.cls_token', 'vision_model.embeddings.class_embedding') ) rename_keys.append(('visual_encoder.pos_embed', 'vision_model.embeddings.position_embedding') ) rename_keys.append(('visual_encoder.patch_embed.proj.weight', 'vision_model.embeddings.patch_embedding.weight') ) rename_keys.append(('visual_encoder.patch_embed.proj.bias', 'vision_model.embeddings.patch_embedding.bias') ) rename_keys.append(('ln_vision.weight', 'vision_model.post_layernorm.weight') ) rename_keys.append(('ln_vision.bias', 'vision_model.post_layernorm.bias') ) for i in range(config.vision_config.num_hidden_layers ): rename_keys.append((F'''visual_encoder.blocks.{i}.norm1.weight''', F'''vision_model.encoder.layers.{i}.layer_norm1.weight''') ) rename_keys.append((F'''visual_encoder.blocks.{i}.norm1.bias''', F'''vision_model.encoder.layers.{i}.layer_norm1.bias''') ) rename_keys.append((F'''visual_encoder.blocks.{i}.norm2.weight''', F'''vision_model.encoder.layers.{i}.layer_norm2.weight''') ) rename_keys.append((F'''visual_encoder.blocks.{i}.norm2.bias''', F'''vision_model.encoder.layers.{i}.layer_norm2.bias''') ) rename_keys.append((F'''visual_encoder.blocks.{i}.attn.qkv.weight''', F'''vision_model.encoder.layers.{i}.self_attn.qkv.weight''') ) rename_keys.append((F'''visual_encoder.blocks.{i}.attn.proj.weight''', F'''vision_model.encoder.layers.{i}.self_attn.projection.weight''',) ) rename_keys.append((F'''visual_encoder.blocks.{i}.attn.proj.bias''', F'''vision_model.encoder.layers.{i}.self_attn.projection.bias''') ) rename_keys.append((F'''visual_encoder.blocks.{i}.mlp.fc1.weight''', F'''vision_model.encoder.layers.{i}.mlp.fc1.weight''') ) rename_keys.append((F'''visual_encoder.blocks.{i}.mlp.fc1.bias''', F'''vision_model.encoder.layers.{i}.mlp.fc1.bias''') ) rename_keys.append((F'''visual_encoder.blocks.{i}.mlp.fc2.weight''', F'''vision_model.encoder.layers.{i}.mlp.fc2.weight''') ) rename_keys.append((F'''visual_encoder.blocks.{i}.mlp.fc2.bias''', F'''vision_model.encoder.layers.{i}.mlp.fc2.bias''') ) # QFormer rename_keys.append(('Qformer.bert.embeddings.LayerNorm.weight', 'qformer.embeddings.layernorm.weight') ) rename_keys.append(('Qformer.bert.embeddings.LayerNorm.bias', 'qformer.embeddings.layernorm.bias') ) # fmt: on return rename_keys def UpperCAmelCase_ ( __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE ): lowercase = dct.pop(UpperCamelCase__ ) lowercase = val def UpperCAmelCase_ ( __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE ): for i in range(config.vision_config.num_hidden_layers ): # read in original q and v biases lowercase = state_dict.pop(F'''visual_encoder.blocks.{i}.attn.q_bias''' ) lowercase = state_dict.pop(F'''visual_encoder.blocks.{i}.attn.v_bias''' ) # next, set bias in the state dict lowercase = torch.cat((q_bias, torch.zeros_like(UpperCamelCase__ , requires_grad=UpperCamelCase__ ), v_bias) ) lowercase = qkv_bias def UpperCAmelCase_ ( __SCREAMING_SNAKE_CASE ): lowercase = 364 if 'coco' in model_name else 224 lowercase = InstructBlipVisionConfig(image_size=UpperCamelCase__ ).to_dict() # make sure the models have proper bos_token_id and eos_token_id set (important for generation) # seems like flan-T5 models don't have bos_token_id properly set? if "t5-xl" in model_name: lowercase = TaConfig.from_pretrained('google/flan-t5-xl' , dense_act_fn='gelu' , bos_token_id=1 ).to_dict() elif "t5-xxl" in model_name: lowercase = TaConfig.from_pretrained('google/flan-t5-xxl' , dense_act_fn='gelu' , bos_token_id=1 ).to_dict() elif "vicuna-7b" in model_name: lowercase = LlamaConfig.from_pretrained('decapoda-research/llama-7b-hf' , vocab_size=3_2001 ).to_dict() elif "vicuna-13b" in model_name: lowercase = LlamaConfig.from_pretrained('decapoda-research/llama-13b-hf' , vocab_size=3_2001 ).to_dict() else: raise ValueError('Model name not supported' ) # the authors add one special "[DEC]" token to the vocab of Q-Former, hence vocab size = 30522 + 1 lowercase = InstructBlipQFormerConfig(vocab_size=3_0523 ).to_dict() lowercase = InstructBlipConfig(vision_config=UpperCamelCase__ , text_config=UpperCamelCase__ , qformer_config=UpperCamelCase__ ) return config, image_size @torch.no_grad() def UpperCAmelCase_ ( __SCREAMING_SNAKE_CASE , __SCREAMING_SNAKE_CASE=None , __SCREAMING_SNAKE_CASE=False ): lowercase = AutoTokenizer.from_pretrained('bert-base-uncased' , truncation_side='left' ) qformer_tokenizer.add_special_tokens({'bos_token': '[DEC]'} ) if "t5" in model_name: lowercase = TaTokenizerFast.from_pretrained('google/flan-t5-xl' , truncation_side='left' ) elif "vicuna" in model_name: # the following was used in the original implementation: # tokenizer = LlamaTokenizer.from_pretrained("huggyllama/llama-7b", use_fast=False, truncation_side="left") # tokenizer.add_special_tokens({"pad_token": "[PAD]"}) # tokenizer.add_special_tokens({"bos_token": "</s>"}) # tokenizer.add_special_tokens({"eos_token": "</s>"}) # tokenizer.add_special_tokens({"unk_token": "</s>"}) lowercase = LlamaTokenizerFast.from_pretrained( 'huggyllama/llama-7b' , truncation_side='left' , bos_token='</s>' , unk_token='</s>' ) tokenizer.add_special_tokens({'pad_token': '[PAD]'} ) lowercase , lowercase = get_blipa_config(UpperCamelCase__ ) lowercase = InstructBlipForConditionalGeneration(UpperCamelCase__ ).eval() lowercase = { 'instructblip-vicuna-7b': ('blip2_vicuna_instruct', 'vicuna7b'), 'instructblip-vicuna-13b': ('blip2_vicuna_instruct', 'vicuna13b'), 'instructblip-flan-t5-xl': ('blip2_t5_instruct', 'flant5xl'), 'instructblip-flan-t5-xxl': ('blip2_t5_instruct', 'flant5xxl'), } lowercase , lowercase = model_name_to_original[model_name] # load original model print('Loading original model...' ) lowercase = 'cuda:1' if torch.cuda.is_available() else 'cpu' lowercase = 'cuda:2' if torch.cuda.is_available() else 'cpu' lowercase , lowercase , lowercase = load_model_and_preprocess( name=UpperCamelCase__ , model_type=UpperCamelCase__ , is_eval=UpperCamelCase__ , device=UpperCamelCase__ ) original_model.eval() print('Done!' ) # update state dict keys lowercase = original_model.state_dict() lowercase = create_rename_keys(UpperCamelCase__ ) for src, dest in rename_keys: rename_key(UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ ) # some keys can be renamed efficiently for key, val in state_dict.copy().items(): lowercase = state_dict.pop(UpperCamelCase__ ) if key.startswith('Qformer.bert' ): lowercase = key.replace('Qformer.bert' , 'qformer' ) if "attention.self" in key: lowercase = key.replace('self' , 'attention' ) if "llm_proj" in key: lowercase = key.replace('llm_proj' , 'language_projection' ) if "t5_proj" in key: lowercase = key.replace('t5_proj' , 'language_projection' ) if key.startswith('llm_model' ): lowercase = key.replace('llm_model' , 'language_model' ) if key.startswith('t5' ): lowercase = key.replace('t5' , 'language' ) lowercase = val # read in qv biases read_in_q_v_bias(UpperCamelCase__ , UpperCamelCase__ ) # note: weights get loaded in torch.float32 by default hf_model.load_state_dict(UpperCamelCase__ , strict=UpperCamelCase__ ) lowercase = load_demo_image() lowercase = 'What is unusual about this image?' # create processor lowercase = BlipImageProcessor( size={'height': image_size, 'width': image_size} , image_mean=UpperCamelCase__ , image_std=UpperCamelCase__ ) lowercase = InstructBlipProcessor( image_processor=UpperCamelCase__ , tokenizer=UpperCamelCase__ , qformer_tokenizer=UpperCamelCase__ , ) lowercase = processor(images=UpperCamelCase__ , text=UpperCamelCase__ , return_tensors='pt' ).to(UpperCamelCase__ ) # make sure processor creates exact same pixel values lowercase = vis_processors['eval'](UpperCamelCase__ ).unsqueeze(0 ).to(UpperCamelCase__ ) lowercase = inputs.pixel_values assert torch.allclose(original_pixel_values.to(pixel_values.device ) , UpperCamelCase__ ) original_model.to(UpperCamelCase__ ) hf_model.to(UpperCamelCase__ ) with torch.no_grad(): if "vicuna" in model_name: lowercase = original_model({'image': original_pixel_values, 'text_input': [prompt]} ).logits lowercase = hf_model(**UpperCamelCase__ ).logits else: lowercase = original_model( {'image': original_pixel_values, 'text_input': [prompt], 'text_output': ['\n']} ).logits lowercase = tokenizer('\n' , return_tensors='pt' ).input_ids.to(UpperCamelCase__ ) lowercase = label_input_ids.masked_fill(label_input_ids == tokenizer.pad_token_id , -100 ) lowercase = hf_model(**UpperCamelCase__ , labels=UpperCamelCase__ ).logits print('First values of original logits:' , original_logits[0, :3, :3] ) print('First values of HF logits:' , logits[0, :3, :3] ) # assert values assert original_logits.shape == logits.shape lowercase = 1e-4 if 'vicuna' in model_name else 1e-5 assert torch.allclose(original_logits.to(logits.device ) , UpperCamelCase__ , atol=UpperCamelCase__ ) print('Looks ok!' ) print('Generating with original model...' ) lowercase = original_model.generate({'image': original_pixel_values, 'prompt': prompt} , num_beams=5 ) # important: we need to cast the weights of the HF model to the appropriate type print('Generating with HF model...' ) lowercase = hf_model.generate( **UpperCamelCase__ , do_sample=UpperCamelCase__ , num_beams=5 , max_length=256 , min_length=1 , top_p=0.9 , repetition_penalty=1.5 , length_penalty=1.0 , temperature=1 , ) if "vicuna" in model_name: # convert output id 0 to 2 (eos_token_id) # TODO add this in the generate method? lowercase = 2 print('Original generation:' , UpperCamelCase__ ) lowercase = processor.batch_decode(UpperCamelCase__ , skip_special_tokens=UpperCamelCase__ ) lowercase = [text.strip() for text in output_text] print('HF generation:' , UpperCamelCase__ ) if pytorch_dump_folder_path is not None: processor.save_pretrained(UpperCamelCase__ ) hf_model.save_pretrained(UpperCamelCase__ ) if push_to_hub: processor.push_to_hub(F'''Salesforce/{model_name}''' ) hf_model.push_to_hub(F'''Salesforce/{model_name}''' ) if __name__ == "__main__": UpperCAmelCase = argparse.ArgumentParser() UpperCAmelCase = [ '''instructblip-vicuna-7b''', '''instructblip-vicuna-13b''', '''instructblip-flan-t5-xl''', '''instructblip-flan-t5-xxl''', ] parser.add_argument( '''--model_name''', default='''instructblip-flan-t5-xl''', choices=choices, type=str, help='''Path to hf config.json of model to convert''', ) parser.add_argument('''--pytorch_dump_folder_path''', default=None, type=str, help='''Path to the output PyTorch model.''') parser.add_argument( '''--push_to_hub''', action='''store_true''', help='''Whether to push the model and processor to the hub after converting''', ) UpperCAmelCase = parser.parse_args() convert_blipa_checkpoint(args.model_name, args.pytorch_dump_folder_path, args.push_to_hub)
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import copy import inspect import unittest import numpy as np from huggingface_hub import hf_hub_download from transformers import TimesformerConfig from transformers.models.auto import get_values 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, floats_tensor, ids_tensor from ...test_pipeline_mixin import PipelineTesterMixin if is_torch_available(): import torch from torch import nn from transformers import ( MODEL_FOR_VIDEO_CLASSIFICATION_MAPPING, TimesformerForVideoClassification, TimesformerModel, ) from transformers.models.timesformer.modeling_timesformer import TIMESFORMER_PRETRAINED_MODEL_ARCHIVE_LIST if is_vision_available(): from transformers import VideoMAEImageProcessor class __lowerCAmelCase : """simple docstring""" def __init__( self , lowerCamelCase__ , lowerCamelCase__=13 , lowerCamelCase__=10 , lowerCamelCase__=3 , lowerCamelCase__=2 , lowerCamelCase__=2 , lowerCamelCase__=True , lowerCamelCase__=True , lowerCamelCase__=32 , lowerCamelCase__=5 , lowerCamelCase__=4 , lowerCamelCase__=37 , lowerCamelCase__="gelu" , lowerCamelCase__=0.1 , lowerCamelCase__=0.1 , lowerCamelCase__=10 , lowerCamelCase__=0.02 , lowerCamelCase__="divided_space_time" , lowerCamelCase__=None , ) -> Any: '''simple docstring''' __lowerCamelCase = parent __lowerCamelCase = batch_size __lowerCamelCase = image_size __lowerCamelCase = num_channels __lowerCamelCase = patch_size __lowerCamelCase = num_frames __lowerCamelCase = is_training __lowerCamelCase = use_labels __lowerCamelCase = hidden_size __lowerCamelCase = num_hidden_layers __lowerCamelCase = num_attention_heads __lowerCamelCase = intermediate_size __lowerCamelCase = hidden_act __lowerCamelCase = hidden_dropout_prob __lowerCamelCase = attention_probs_dropout_prob __lowerCamelCase = attention_type __lowerCamelCase = initializer_range __lowerCamelCase = scope __lowerCamelCase = num_labels # in TimeSformer, the number of spatial tokens equals num_frames * num_patches per frame + 1 CLS token __lowerCamelCase = (image_size // patch_size) ** 2 __lowerCamelCase = (num_frames) * self.num_patches_per_frame + 1 def lowercase_ ( self ) -> Optional[int]: '''simple docstring''' __lowerCamelCase = floats_tensor( [self.batch_size, self.num_frames, self.num_channels, self.image_size, self.image_size] ) __lowerCamelCase = None if self.use_labels: __lowerCamelCase = ids_tensor([self.batch_size] , self.num_labels ) __lowerCamelCase = self.get_config() return config, pixel_values, labels def lowercase_ ( self ) -> Union[str, Any]: '''simple docstring''' __lowerCamelCase = TimesformerConfig( image_size=self.image_size , patch_size=self.patch_size , num_channels=self.num_channels , num_frames=self.num_frames , 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 , initializer_range=self.initializer_range , attention_type=self.attention_type , ) __lowerCamelCase = self.num_labels return config def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> Tuple: '''simple docstring''' __lowerCamelCase = TimesformerModel(config=lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model(lowerCamelCase__ ) self.parent.assertEqual(result.last_hidden_state.shape , (self.batch_size, self.seq_length, self.hidden_size) ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) -> Union[str, Any]: '''simple docstring''' __lowerCamelCase = TimesformerForVideoClassification(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() __lowerCamelCase = model(lowerCamelCase__ ) # verify the logits shape __lowerCamelCase = torch.Size((self.batch_size, self.num_labels) ) self.parent.assertEqual(result.logits.shape , lowerCamelCase__ ) def lowercase_ ( self ) -> Tuple: '''simple docstring''' __lowerCamelCase = self.prepare_config_and_inputs() __lowerCamelCase , __lowerCamelCase , __lowerCamelCase = config_and_inputs __lowerCamelCase = {'pixel_values': pixel_values} return config, inputs_dict @require_torch class __lowerCAmelCase ( __magic_name__ , __magic_name__ , unittest.TestCase ): """simple docstring""" snake_case_ = (TimesformerModel, TimesformerForVideoClassification) if is_torch_available() else () snake_case_ = ( {'''feature-extraction''': TimesformerModel, '''video-classification''': TimesformerForVideoClassification} if is_torch_available() else {} ) snake_case_ = False snake_case_ = False snake_case_ = False snake_case_ = False def lowercase_ ( self ) -> List[str]: '''simple docstring''' __lowerCamelCase = TimesformerModelTester(self ) __lowerCamelCase = ConfigTester( self , config_class=lowerCamelCase__ , has_text_modality=lowerCamelCase__ , hidden_size=37 ) def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__=False ) -> int: '''simple docstring''' __lowerCamelCase = copy.deepcopy(lowerCamelCase__ ) if return_labels: if model_class in get_values(lowerCamelCase__ ): __lowerCamelCase = torch.zeros( self.model_tester.batch_size , dtype=torch.long , device=lowerCamelCase__ ) return inputs_dict def lowercase_ ( self ) -> Optional[int]: '''simple docstring''' self.config_tester.run_common_tests() @unittest.skip(reason='TimeSformer does not use inputs_embeds' ) def lowercase_ ( self ) -> List[str]: '''simple docstring''' pass def lowercase_ ( self ) -> Union[str, Any]: '''simple docstring''' __lowerCamelCase , __lowerCamelCase = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: __lowerCamelCase = model_class(lowerCamelCase__ ) self.assertIsInstance(model.get_input_embeddings() , (nn.Module) ) __lowerCamelCase = model.get_output_embeddings() self.assertTrue(x is None or isinstance(lowerCamelCase__ , nn.Linear ) ) def lowercase_ ( self ) -> List[str]: '''simple docstring''' __lowerCamelCase , __lowerCamelCase = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: __lowerCamelCase = model_class(lowerCamelCase__ ) __lowerCamelCase = inspect.signature(model.forward ) # signature.parameters is an OrderedDict => so arg_names order is deterministic __lowerCamelCase = [*signature.parameters.keys()] __lowerCamelCase = ['pixel_values'] self.assertListEqual(arg_names[:1] , lowerCamelCase__ ) def lowercase_ ( self ) -> Union[str, Any]: '''simple docstring''' __lowerCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_model(*lowerCamelCase__ ) def lowercase_ ( self ) -> str: '''simple docstring''' __lowerCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_for_video_classification(*lowerCamelCase__ ) @slow def lowercase_ ( self ) -> Dict: '''simple docstring''' for model_name in TIMESFORMER_PRETRAINED_MODEL_ARCHIVE_LIST[:1]: __lowerCamelCase = TimesformerModel.from_pretrained(lowerCamelCase__ ) self.assertIsNotNone(lowerCamelCase__ ) def lowercase_ ( self ) -> List[Any]: '''simple docstring''' if not self.has_attentions: pass else: __lowerCamelCase , __lowerCamelCase = self.model_tester.prepare_config_and_inputs_for_common() __lowerCamelCase = True for model_class in self.all_model_classes: __lowerCamelCase = self.model_tester.seq_length __lowerCamelCase = self.model_tester.num_frames __lowerCamelCase = True __lowerCamelCase = False __lowerCamelCase = True __lowerCamelCase = model_class(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() with torch.no_grad(): __lowerCamelCase = model(**self._prepare_for_class(lowerCamelCase__ , lowerCamelCase__ ) ) __lowerCamelCase = outputs.attentions self.assertEqual(len(lowerCamelCase__ ) , self.model_tester.num_hidden_layers ) # check that output_attentions also work using config del inputs_dict["output_attentions"] __lowerCamelCase = True __lowerCamelCase = model_class(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() with torch.no_grad(): __lowerCamelCase = model(**self._prepare_for_class(lowerCamelCase__ , lowerCamelCase__ ) ) __lowerCamelCase = outputs.attentions self.assertEqual(len(lowerCamelCase__ ) , self.model_tester.num_hidden_layers ) # attentions has shape (batch_size x num_frames) x num_heads x (num_patches per frame + 1) x (num_patches per frame + 1) self.assertListEqual( list(attentions[0].shape[-3:] ) , [self.model_tester.num_attention_heads, seq_len // num_frames + 1, seq_len // num_frames + 1] , ) __lowerCamelCase = len(lowerCamelCase__ ) # Check attention is always last and order is fine __lowerCamelCase = True __lowerCamelCase = True __lowerCamelCase = model_class(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() with torch.no_grad(): __lowerCamelCase = model(**self._prepare_for_class(lowerCamelCase__ , lowerCamelCase__ ) ) self.assertEqual(out_len + 1 , len(lowerCamelCase__ ) ) __lowerCamelCase = outputs.attentions self.assertEqual(len(lowerCamelCase__ ) , self.model_tester.num_hidden_layers ) # attentions has shape (batch_size x num_frames) x num_heads x (num_patches per frame + 1) x (num_patches per frame + 1) self.assertListEqual( list(self_attentions[0].shape[-3:] ) , [self.model_tester.num_attention_heads, seq_len // num_frames + 1, seq_len // num_frames + 1] , ) def lowercase_ ( self ) -> Tuple: '''simple docstring''' def check_hidden_states_output(lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ): __lowerCamelCase = model_class(lowerCamelCase__ ) model.to(lowerCamelCase__ ) model.eval() with torch.no_grad(): __lowerCamelCase = model(**self._prepare_for_class(lowerCamelCase__ , lowerCamelCase__ ) ) __lowerCamelCase = outputs.hidden_states __lowerCamelCase = self.model_tester.num_hidden_layers + 1 self.assertEqual(len(lowerCamelCase__ ) , lowerCamelCase__ ) __lowerCamelCase = self.model_tester.seq_length self.assertListEqual( list(hidden_states[0].shape[-2:] ) , [seq_length, self.model_tester.hidden_size] , ) __lowerCamelCase , __lowerCamelCase = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: __lowerCamelCase = True check_hidden_states_output(lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) # check that output_hidden_states also work using config del inputs_dict["output_hidden_states"] __lowerCamelCase = True check_hidden_states_output(lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ ) def lowerCamelCase_ ( ) -> Any: """simple docstring""" __lowerCamelCase = hf_hub_download( repo_id='hf-internal-testing/spaghetti-video' , filename='eating_spaghetti.npy' , repo_type='dataset' ) __lowerCamelCase = np.load(UpperCamelCase__ ) return list(UpperCamelCase__ ) @require_torch @require_vision class __lowerCAmelCase ( unittest.TestCase ): """simple docstring""" @cached_property def lowercase_ ( self ) -> List[Any]: '''simple docstring''' # logits were tested with a different mean and std, so we use the same here return ( VideoMAEImageProcessor(image_mean=[0.5, 0.5, 0.5] , image_std=[0.5, 0.5, 0.5] ) if is_vision_available() else None ) @slow def lowercase_ ( self ) -> List[str]: '''simple docstring''' __lowerCamelCase = TimesformerForVideoClassification.from_pretrained('facebook/timesformer-base-finetuned-k400' ).to( lowerCamelCase__ ) __lowerCamelCase = self.default_image_processor __lowerCamelCase = prepare_video() __lowerCamelCase = image_processor(video[:8] , return_tensors='pt' ).to(lowerCamelCase__ ) # forward pass with torch.no_grad(): __lowerCamelCase = model(**lowerCamelCase__ ) # verify the logits __lowerCamelCase = torch.Size((1, 400) ) self.assertEqual(outputs.logits.shape , lowerCamelCase__ ) __lowerCamelCase = torch.tensor([-0.30_16, -0.77_13, -0.42_05] ).to(lowerCamelCase__ ) self.assertTrue(torch.allclose(outputs.logits[0, :3] , lowerCamelCase__ , atol=1e-4 ) )
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def UpperCamelCase_( _snake_case : int ): """simple docstring""" if number > 0: raise ValueError('input must be a negative integer' ) __a =len(bin(UpperCamelCase__ )[3:] ) __a =bin(abs(UpperCamelCase__ ) - (1 << binary_number_length) )[3:] __a =( ( '1' + '0' * (binary_number_length - len(UpperCamelCase__ )) + twos_complement_number ) if number < 0 else '0' ) return "0b" + twos_complement_number if __name__ == "__main__": import doctest doctest.testmod()
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import json from typing import TYPE_CHECKING, List, Optional, Tuple from tokenizers import pre_tokenizers from ...tokenization_utils_fast import PreTrainedTokenizerFast from ...utils import logging if TYPE_CHECKING: from transformers.pipelines.conversational import Conversation __A = logging.get_logger(__name__) __A = {"vocab_file": "vocab.json", "merges_file": "merges.txt", "tokenizer_file": "tokenizer.json"} __A = { "tokenizer_file": { "EleutherAI/gpt-neox-20b": "https://huggingface.co/EleutherAI/gpt-neox-20b/resolve/main/tokenizer.json", }, } __A = { "gpt-neox-20b": 20_48, } class __lowerCAmelCase ( __magic_name__ ): """simple docstring""" snake_case_ = VOCAB_FILES_NAMES snake_case_ = PRETRAINED_VOCAB_FILES_MAP snake_case_ = PRETRAINED_POSITIONAL_EMBEDDINGS_SIZES snake_case_ = ['''input_ids''', '''attention_mask'''] def __init__( self , lowerCamelCase__=None , lowerCamelCase__=None , lowerCamelCase__=None , lowerCamelCase__="<|endoftext|>" , lowerCamelCase__="<|endoftext|>" , lowerCamelCase__="<|endoftext|>" , lowerCamelCase__=False , **lowerCamelCase__ , ) -> int: '''simple docstring''' super().__init__( lowerCamelCase__ , lowerCamelCase__ , tokenizer_file=lowerCamelCase__ , unk_token=lowerCamelCase__ , bos_token=lowerCamelCase__ , eos_token=lowerCamelCase__ , add_prefix_space=lowerCamelCase__ , **lowerCamelCase__ , ) __lowerCamelCase = json.loads(self.backend_tokenizer.pre_tokenizer.__getstate__() ) if pre_tok_state.get('add_prefix_space' , lowerCamelCase__ ) != add_prefix_space: __lowerCamelCase = getattr(lowerCamelCase__ , pre_tok_state.pop('type' ) ) __lowerCamelCase = add_prefix_space __lowerCamelCase = pre_tok_class(**lowerCamelCase__ ) __lowerCamelCase = add_prefix_space def lowercase_ ( self , lowerCamelCase__ , lowerCamelCase__ = None ) -> Tuple[str]: '''simple docstring''' __lowerCamelCase = self._tokenizer.model.save(lowerCamelCase__ , name=lowerCamelCase__ ) return tuple(lowerCamelCase__ ) def lowercase_ ( self , lowerCamelCase__ ) -> List[int]: '''simple docstring''' __lowerCamelCase = [] for is_user, text in conversation.iter_texts(): input_ids.extend(self.encode(lowerCamelCase__ , add_special_tokens=lowerCamelCase__ ) + [self.eos_token_id] ) if len(lowerCamelCase__ ) > self.model_max_length: __lowerCamelCase = input_ids[-self.model_max_length :] return input_ids
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"""simple docstring""" import argparse import ast import logging import os import sys import pandas as pd import torch from tqdm import tqdm from transformers import BartForConditionalGeneration, RagRetriever, RagSequenceForGeneration, RagTokenForGeneration from transformers import logging as transformers_logging sys.path.append(os.path.join(os.getcwd())) # noqa: E402 # isort:skip from utils_rag import exact_match_score, fa_score # noqa: E402 # isort:skip lowerCamelCase_ : List[Any] = logging.getLogger(__name__) logging.basicConfig(level=logging.INFO) transformers_logging.set_verbosity_info() def _A ( lowercase ): """simple docstring""" if "token" in model_name_or_path: return "rag_token" if "sequence" in model_name_or_path: return "rag_sequence" if "bart" in model_name_or_path: return "bart" return None def _A ( lowercase , lowercase , lowercase ): """simple docstring""" return max(metric_fn(UpperCamelCase__ , UpperCamelCase__ ) for gt in ground_truths ) def _A ( lowercase , lowercase , lowercase ): """simple docstring""" a =[line.strip() for line in open(UpperCamelCase__ , '''r''' ).readlines()] a =[] if args.gold_data_mode == "qa": a =pd.read_csv(UpperCamelCase__ , sep='''\t''' , header=UpperCamelCase__ ) for answer_list in data[1]: a =ast.literal_eval(UpperCamelCase__ ) answers.append(UpperCamelCase__ ) else: a =[line.strip() for line in open(UpperCamelCase__ , '''r''' ).readlines()] a =[[reference] for reference in references] a =a =a =0 for prediction, ground_truths in zip(UpperCamelCase__ , UpperCamelCase__ ): total += 1 em += metric_max_over_ground_truths(UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ ) fa += metric_max_over_ground_truths(UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ ) a =1_00.0 * em / total a =1_00.0 * fa / total logger.info(f'''F1: {fa:.2f}''' ) logger.info(f'''EM: {em:.2f}''' ) def _A ( lowercase , lowercase , lowercase ): """simple docstring""" a =args.k a =[line.strip() for line in open(UpperCamelCase__ , '''r''' ).readlines()] a =[line.strip() for line in open(UpperCamelCase__ , '''r''' ).readlines()] a =a =0 for hypo, reference in zip(UpperCamelCase__ , UpperCamelCase__ ): a =set(hypo.split('''\t''' )[:k] ) a =set(reference.split('''\t''' ) ) total += 1 em += len(hypo_provenance & ref_provenance ) / k a =1_00.0 * em / total logger.info(f'''Precision@{k}: {em: .2f}''' ) def _A ( lowercase , lowercase , lowercase ): """simple docstring""" def strip_title(lowercase ): if title.startswith('''"''' ): a =title[1:] if title.endswith('''"''' ): a =title[:-1] return title a =rag_model.retriever.question_encoder_tokenizer.batch_encode_plus( UpperCamelCase__ , return_tensors='''pt''' , padding=UpperCamelCase__ , truncation=UpperCamelCase__ , )['''input_ids'''].to(args.device ) a =rag_model.rag.question_encoder(UpperCamelCase__ ) a =question_enc_outputs[0] a =rag_model.retriever( UpperCamelCase__ , question_enc_pool_output.cpu().detach().to(torch.floataa ).numpy() , prefix=rag_model.rag.generator.config.prefix , n_docs=rag_model.config.n_docs , return_tensors='''pt''' , ) a =rag_model.retriever.index.get_doc_dicts(result.doc_ids ) a =[] for docs in all_docs: a =[strip_title(UpperCamelCase__ ) for title in docs['''title''']] provenance_strings.append('''\t'''.join(UpperCamelCase__ ) ) return provenance_strings def _A ( lowercase , lowercase , lowercase ): """simple docstring""" with torch.no_grad(): a =rag_model.retriever.question_encoder_tokenizer.batch_encode_plus( UpperCamelCase__ , return_tensors='''pt''' , padding=UpperCamelCase__ , truncation=UpperCamelCase__ ) a =inputs_dict.input_ids.to(args.device ) a =inputs_dict.attention_mask.to(args.device ) a =rag_model.generate( # rag_model overwrites generate UpperCamelCase__ , attention_mask=UpperCamelCase__ , num_beams=args.num_beams , min_length=args.min_length , max_length=args.max_length , early_stopping=UpperCamelCase__ , num_return_sequences=1 , bad_words_ids=[[0, 0]] , ) a =rag_model.retriever.generator_tokenizer.batch_decode(UpperCamelCase__ , skip_special_tokens=UpperCamelCase__ ) if args.print_predictions: for q, a in zip(UpperCamelCase__ , UpperCamelCase__ ): logger.info('''Q: {} - A: {}'''.format(UpperCamelCase__ , UpperCamelCase__ ) ) return answers def _A ( ): """simple docstring""" a =argparse.ArgumentParser() parser.add_argument( '''--model_type''' , choices=['''rag_sequence''', '''rag_token''', '''bart'''] , type=UpperCamelCase__ , help=( '''RAG model type: rag_sequence, rag_token or bart, if none specified, the type is inferred from the''' ''' model_name_or_path''' ) , ) parser.add_argument( '''--index_name''' , default=UpperCamelCase__ , choices=['''exact''', '''compressed''', '''legacy'''] , type=UpperCamelCase__ , help='''RAG model retriever type''' , ) parser.add_argument( '''--index_path''' , default=UpperCamelCase__ , type=UpperCamelCase__ , help='''Path to the retrieval index''' , ) parser.add_argument('''--n_docs''' , default=5 , type=UpperCamelCase__ , help='''Number of retrieved docs''' ) parser.add_argument( '''--model_name_or_path''' , default=UpperCamelCase__ , type=UpperCamelCase__ , required=UpperCamelCase__ , help='''Path to pretrained checkpoints or model identifier from huggingface.co/models''' , ) parser.add_argument( '''--eval_mode''' , choices=['''e2e''', '''retrieval'''] , default='''e2e''' , type=UpperCamelCase__ , help=( '''Evaluation mode, e2e calculates exact match and F1 of the downstream task, retrieval calculates''' ''' precision@k.''' ) , ) parser.add_argument('''--k''' , default=1 , type=UpperCamelCase__ , help='''k for the precision@k calculation''' ) parser.add_argument( '''--evaluation_set''' , default=UpperCamelCase__ , type=UpperCamelCase__ , required=UpperCamelCase__ , help='''Path to a file containing evaluation samples''' , ) parser.add_argument( '''--gold_data_path''' , default=UpperCamelCase__ , type=UpperCamelCase__ , required=UpperCamelCase__ , help='''Path to a tab-separated file with gold samples''' , ) parser.add_argument( '''--gold_data_mode''' , default='''qa''' , type=UpperCamelCase__ , choices=['''qa''', '''ans'''] , help=( '''Format of the gold data file''' '''qa - a single line in the following format: question [tab] answer_list''' '''ans - a single line of the gold file contains the expected answer string''' ) , ) parser.add_argument( '''--predictions_path''' , type=UpperCamelCase__ , default='''predictions.txt''' , help='''Name of the predictions file, to be stored in the checkpoints directory''' , ) parser.add_argument( '''--eval_all_checkpoints''' , action='''store_true''' , help='''Evaluate all checkpoints starting with the same prefix as model_name ending and ending with step number''' , ) parser.add_argument( '''--eval_batch_size''' , default=8 , type=UpperCamelCase__ , help='''Batch size per GPU/CPU for evaluation.''' , ) parser.add_argument( '''--recalculate''' , help='''Recalculate predictions even if the prediction file exists''' , action='''store_true''' , ) parser.add_argument( '''--num_beams''' , default=4 , type=UpperCamelCase__ , help='''Number of beams to be used when generating answers''' , ) parser.add_argument('''--min_length''' , default=1 , type=UpperCamelCase__ , help='''Min length of the generated answers''' ) parser.add_argument('''--max_length''' , default=50 , type=UpperCamelCase__ , help='''Max length of the generated answers''' ) parser.add_argument( '''--print_predictions''' , action='''store_true''' , help='''If True, prints predictions while evaluating.''' , ) parser.add_argument( '''--print_docs''' , action='''store_true''' , help='''If True, prints docs retried while generating.''' , ) a =parser.parse_args() a =torch.device('''cuda''' if torch.cuda.is_available() else '''cpu''' ) return args def _A ( lowercase ): """simple docstring""" a ={} if args.model_type is None: a =infer_model_type(args.model_name_or_path ) assert args.model_type is not None if args.model_type.startswith('''rag''' ): a =RagTokenForGeneration if args.model_type == '''rag_token''' else RagSequenceForGeneration a =args.n_docs if args.index_name is not None: a =args.index_name if args.index_path is not None: a =args.index_path else: a =BartForConditionalGeneration a =( [f.path for f in os.scandir(args.model_name_or_path ) if f.is_dir()] if args.eval_all_checkpoints else [args.model_name_or_path] ) logger.info('''Evaluate the following checkpoints: %s''' , UpperCamelCase__ ) a =get_scores if args.eval_mode == '''e2e''' else get_precision_at_k a =evaluate_batch_eae if args.eval_mode == '''e2e''' else evaluate_batch_retrieval for checkpoint in checkpoints: if os.path.exists(args.predictions_path ) and (not args.recalculate): logger.info('''Calculating metrics based on an existing predictions file: {}'''.format(args.predictions_path ) ) score_fn(UpperCamelCase__ , args.predictions_path , args.gold_data_path ) continue logger.info('''***** Running evaluation for {} *****'''.format(UpperCamelCase__ ) ) logger.info(''' Batch size = %d''' , args.eval_batch_size ) logger.info(''' Predictions will be stored under {}'''.format(args.predictions_path ) ) if args.model_type.startswith('''rag''' ): a =RagRetriever.from_pretrained(UpperCamelCase__ , **UpperCamelCase__ ) a =model_class.from_pretrained(UpperCamelCase__ , retriever=UpperCamelCase__ , **UpperCamelCase__ ) model.retriever.init_retrieval() else: a =model_class.from_pretrained(UpperCamelCase__ , **UpperCamelCase__ ) model.to(args.device ) with open(args.evaluation_set , '''r''' ) as eval_file, open(args.predictions_path , '''w''' ) as preds_file: a =[] for line in tqdm(UpperCamelCase__ ): questions.append(line.strip() ) if len(UpperCamelCase__ ) == args.eval_batch_size: a =evaluate_batch_fn(UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ ) preds_file.write('''\n'''.join(UpperCamelCase__ ) + '''\n''' ) preds_file.flush() a =[] if len(UpperCamelCase__ ) > 0: a =evaluate_batch_fn(UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ ) preds_file.write('''\n'''.join(UpperCamelCase__ ) ) preds_file.flush() score_fn(UpperCamelCase__ , args.predictions_path , args.gold_data_path ) if __name__ == "__main__": lowerCamelCase_ : Any = get_args() main(args)
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from ..utils import DummyObject, requires_backends class __lowerCAmelCase ( metaclass=__magic_name__ ): """simple docstring""" snake_case_ = ['''onnx'''] def __init__( self , *lowerCamelCase__ , **lowerCamelCase__ ) -> Optional[Any]: '''simple docstring''' requires_backends(self , ['onnx'] ) @classmethod def lowercase_ ( cls , *lowerCamelCase__ , **lowerCamelCase__ ) -> Dict: '''simple docstring''' requires_backends(cls , ['onnx'] ) @classmethod def lowercase_ ( cls , *lowerCamelCase__ , **lowerCamelCase__ ) -> List[str]: '''simple docstring''' requires_backends(cls , ['onnx'] )
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import warnings from contextlib import contextmanager from ....processing_utils import ProcessorMixin class snake_case ( SCREAMING_SNAKE_CASE_ ): '''simple docstring''' snake_case_ : str = """MCTCTFeatureExtractor""" snake_case_ : Optional[Any] = """AutoTokenizer""" def __init__( self : Optional[Any] , lowerCAmelCase : Tuple , lowerCAmelCase : List[Any]) -> Dict: """simple docstring""" super().__init__(lowerCamelCase__ , lowerCamelCase__) _snake_case : int = self.feature_extractor _snake_case : List[str] = False def __call__( self : List[Any] , *lowerCAmelCase : List[Any] , **lowerCAmelCase : Union[str, Any]) -> Any: """simple docstring""" if self._in_target_context_manager: return self.current_processor(*lowerCamelCase__ , **lowerCamelCase__) if "raw_speech" in kwargs: warnings.warn("""Using `raw_speech` as a keyword argument is deprecated. Use `audio` instead.""") _snake_case : List[str] = kwargs.pop("""raw_speech""") else: _snake_case : Dict = kwargs.pop("""audio""" , lowerCamelCase__) _snake_case : Optional[Any] = kwargs.pop("""sampling_rate""" , lowerCamelCase__) _snake_case : Optional[Any] = kwargs.pop("""text""" , lowerCamelCase__) if len(lowerCamelCase__) > 0: _snake_case : Union[str, Any] = args[0] _snake_case : Union[str, Any] = args[1:] if audio is None and text is None: raise ValueError("""You need to specify either an `audio` or `text` input to process.""") if audio is not None: _snake_case : Dict = self.feature_extractor(lowerCamelCase__ , *lowerCamelCase__ , sampling_rate=lowerCamelCase__ , **lowerCamelCase__) if text is not None: _snake_case : Tuple = self.tokenizer(lowerCamelCase__ , **lowerCamelCase__) if text is None: return inputs elif audio is None: return encodings else: _snake_case : Union[str, Any] = encodings["""input_ids"""] return inputs def UpperCamelCase_ ( self : Tuple , *lowerCAmelCase : Any , **lowerCAmelCase : Union[str, Any]) -> int: """simple docstring""" return self.tokenizer.batch_decode(*lowerCamelCase__ , **lowerCamelCase__) def UpperCamelCase_ ( self : Optional[int] , *lowerCAmelCase : int , **lowerCAmelCase : Any) -> str: """simple docstring""" if self._in_target_context_manager: return self.current_processor.pad(*lowerCamelCase__ , **lowerCamelCase__) _snake_case : Tuple = kwargs.pop("""input_features""" , lowerCamelCase__) _snake_case : int = kwargs.pop("""labels""" , lowerCamelCase__) if len(lowerCamelCase__) > 0: _snake_case : Union[str, Any] = args[0] _snake_case : Dict = args[1:] if input_features is not None: _snake_case : Dict = self.feature_extractor.pad(lowerCamelCase__ , *lowerCamelCase__ , **lowerCamelCase__) if labels is not None: _snake_case : Optional[Any] = self.tokenizer.pad(lowerCamelCase__ , **lowerCamelCase__) if labels is None: return input_features elif input_features is None: return labels else: _snake_case : str = labels["""input_ids"""] return input_features def UpperCamelCase_ ( self : str , *lowerCAmelCase : Tuple , **lowerCAmelCase : Optional[int]) -> List[Any]: """simple docstring""" return self.tokenizer.decode(*lowerCamelCase__ , **lowerCamelCase__) @contextmanager def UpperCamelCase_ ( self : Tuple) -> List[str]: """simple docstring""" warnings.warn( """`as_target_processor` is deprecated and will be removed in v5 of Transformers. You can process your """ """labels by using the argument `text` of the regular `__call__` method (either in the same call as """ """your audio inputs, or in a separate call.""") _snake_case : Tuple = True _snake_case : str = self.tokenizer yield _snake_case : Optional[Any] = self.feature_extractor _snake_case : Tuple = False
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import itertools import os import random import tempfile import unittest import numpy as np from datasets import load_dataset from transformers import is_speech_available from transformers.testing_utils import check_json_file_has_correct_format, require_torch, require_torchaudio from transformers.utils.import_utils import is_torch_available from ...test_sequence_feature_extraction_common import SequenceFeatureExtractionTestMixin if is_speech_available(): from transformers import WhisperFeatureExtractor if is_torch_available(): import torch __A = random.Random() def lowerCamelCase_ ( UpperCamelCase__ : Optional[int] , UpperCamelCase__ : List[str]=1.0 , UpperCamelCase__ : Union[str, Any]=None , UpperCamelCase__ : Optional[int]=None ) -> Optional[Any]: """simple docstring""" if rng is None: __lowerCamelCase = global_rng __lowerCamelCase = [] for batch_idx in range(shape[0] ): values.append([] ) for _ in range(shape[1] ): values[-1].append(rng.random() * scale ) return values @require_torch @require_torchaudio class __lowerCAmelCase ( unittest.TestCase ): """simple docstring""" def __init__( self , lowerCamelCase__ , lowerCamelCase__=7 , lowerCamelCase__=400 , lowerCamelCase__=2_000 , lowerCamelCase__=10 , lowerCamelCase__=160 , lowerCamelCase__=8 , lowerCamelCase__=0.0 , lowerCamelCase__=4_000 , lowerCamelCase__=False , lowerCamelCase__=True , ) -> List[str]: '''simple docstring''' __lowerCamelCase = parent __lowerCamelCase = batch_size __lowerCamelCase = min_seq_length __lowerCamelCase = max_seq_length __lowerCamelCase = (self.max_seq_length - self.min_seq_length) // (self.batch_size - 1) __lowerCamelCase = padding_value __lowerCamelCase = sampling_rate __lowerCamelCase = return_attention_mask __lowerCamelCase = do_normalize __lowerCamelCase = feature_size __lowerCamelCase = chunk_length __lowerCamelCase = hop_length def lowercase_ ( self ) -> Any: '''simple docstring''' return { "feature_size": self.feature_size, "hop_length": self.hop_length, "chunk_length": self.chunk_length, "padding_value": self.padding_value, "sampling_rate": self.sampling_rate, "return_attention_mask": self.return_attention_mask, "do_normalize": self.do_normalize, } def lowercase_ ( self , lowerCamelCase__=False , lowerCamelCase__=False ) -> Optional[int]: '''simple docstring''' def _flatten(lowerCamelCase__ ): return list(itertools.chain(*lowerCamelCase__ ) ) if equal_length: __lowerCamelCase = [floats_list((self.max_seq_length, self.feature_size) ) for _ in range(self.batch_size )] else: # make sure that inputs increase in size __lowerCamelCase = [ floats_list((x, self.feature_size) ) for x in range(self.min_seq_length , self.max_seq_length , self.seq_length_diff ) ] if numpify: __lowerCamelCase = [np.asarray(lowerCamelCase__ ) for x in speech_inputs] return speech_inputs @require_torch @require_torchaudio class __lowerCAmelCase ( __magic_name__ , unittest.TestCase ): """simple docstring""" snake_case_ = WhisperFeatureExtractor if is_speech_available() else None def lowercase_ ( self ) -> Any: '''simple docstring''' __lowerCamelCase = WhisperFeatureExtractionTester(self ) def lowercase_ ( self ) -> List[str]: '''simple docstring''' __lowerCamelCase = self.feature_extraction_class(**self.feat_extract_dict ) with tempfile.TemporaryDirectory() as tmpdirname: __lowerCamelCase = feat_extract_first.save_pretrained(lowerCamelCase__ )[0] check_json_file_has_correct_format(lowerCamelCase__ ) __lowerCamelCase = self.feature_extraction_class.from_pretrained(lowerCamelCase__ ) __lowerCamelCase = feat_extract_first.to_dict() __lowerCamelCase = feat_extract_second.to_dict() __lowerCamelCase = feat_extract_first.mel_filters __lowerCamelCase = feat_extract_second.mel_filters self.assertTrue(np.allclose(lowerCamelCase__ , lowerCamelCase__ ) ) self.assertEqual(lowerCamelCase__ , lowerCamelCase__ ) def lowercase_ ( self ) -> Dict: '''simple docstring''' __lowerCamelCase = self.feature_extraction_class(**self.feat_extract_dict ) with tempfile.TemporaryDirectory() as tmpdirname: __lowerCamelCase = os.path.join(lowerCamelCase__ , 'feat_extract.json' ) feat_extract_first.to_json_file(lowerCamelCase__ ) __lowerCamelCase = self.feature_extraction_class.from_json_file(lowerCamelCase__ ) __lowerCamelCase = feat_extract_first.to_dict() __lowerCamelCase = feat_extract_second.to_dict() __lowerCamelCase = feat_extract_first.mel_filters __lowerCamelCase = feat_extract_second.mel_filters self.assertTrue(np.allclose(lowerCamelCase__ , lowerCamelCase__ ) ) self.assertEqual(lowerCamelCase__ , lowerCamelCase__ ) def lowercase_ ( self ) -> Dict: '''simple docstring''' # Tests that all call wrap to encode_plus and batch_encode_plus __lowerCamelCase = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) # create three inputs of length 800, 1000, and 1200 __lowerCamelCase = [floats_list((1, x) )[0] for x in range(800 , 1_400 , 200 )] __lowerCamelCase = [np.asarray(lowerCamelCase__ ) for speech_input in speech_inputs] # Test feature size __lowerCamelCase = feature_extractor(lowerCamelCase__ , padding='max_length' , return_tensors='np' ).input_features self.assertTrue(input_features.ndim == 3 ) self.assertTrue(input_features.shape[-1] == feature_extractor.nb_max_frames ) self.assertTrue(input_features.shape[-2] == feature_extractor.feature_size ) # Test not batched input __lowerCamelCase = feature_extractor(speech_inputs[0] , return_tensors='np' ).input_features __lowerCamelCase = feature_extractor(np_speech_inputs[0] , return_tensors='np' ).input_features self.assertTrue(np.allclose(lowerCamelCase__ , lowerCamelCase__ , atol=1e-3 ) ) # Test batched __lowerCamelCase = feature_extractor(lowerCamelCase__ , return_tensors='np' ).input_features __lowerCamelCase = feature_extractor(lowerCamelCase__ , return_tensors='np' ).input_features for enc_seq_a, enc_seq_a in zip(lowerCamelCase__ , lowerCamelCase__ ): self.assertTrue(np.allclose(lowerCamelCase__ , lowerCamelCase__ , atol=1e-3 ) ) # Test 2-D numpy arrays are batched. __lowerCamelCase = [floats_list((1, x) )[0] for x in (800, 800, 800)] __lowerCamelCase = np.asarray(lowerCamelCase__ ) __lowerCamelCase = feature_extractor(lowerCamelCase__ , return_tensors='np' ).input_features __lowerCamelCase = feature_extractor(lowerCamelCase__ , return_tensors='np' ).input_features for enc_seq_a, enc_seq_a in zip(lowerCamelCase__ , lowerCamelCase__ ): self.assertTrue(np.allclose(lowerCamelCase__ , lowerCamelCase__ , atol=1e-3 ) ) # Test truncation required __lowerCamelCase = [floats_list((1, x) )[0] for x in range(200 , (feature_extractor.n_samples + 500) , 200 )] __lowerCamelCase = [np.asarray(lowerCamelCase__ ) for speech_input in speech_inputs] __lowerCamelCase = [x[: feature_extractor.n_samples] for x in speech_inputs] __lowerCamelCase = [np.asarray(lowerCamelCase__ ) for speech_input in speech_inputs_truncated] __lowerCamelCase = feature_extractor(lowerCamelCase__ , return_tensors='np' ).input_features __lowerCamelCase = feature_extractor(lowerCamelCase__ , return_tensors='np' ).input_features for enc_seq_a, enc_seq_a in zip(lowerCamelCase__ , lowerCamelCase__ ): self.assertTrue(np.allclose(lowerCamelCase__ , lowerCamelCase__ , atol=1e-3 ) ) def lowercase_ ( self ) -> List[str]: '''simple docstring''' import torch __lowerCamelCase = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) __lowerCamelCase = np.random.rand(100 , 32 ).astype(np.floataa ) __lowerCamelCase = np_speech_inputs.tolist() for inputs in [py_speech_inputs, np_speech_inputs]: __lowerCamelCase = feature_extractor.pad([{'input_features': inputs}] , return_tensors='np' ) self.assertTrue(np_processed.input_features.dtype == np.floataa ) __lowerCamelCase = feature_extractor.pad([{'input_features': inputs}] , return_tensors='pt' ) self.assertTrue(pt_processed.input_features.dtype == torch.floataa ) def lowercase_ ( self , lowerCamelCase__ ) -> List[str]: '''simple docstring''' __lowerCamelCase = load_dataset('hf-internal-testing/librispeech_asr_dummy' , 'clean' , split='validation' ) # automatic decoding with librispeech __lowerCamelCase = ds.sort('id' ).select(range(lowerCamelCase__ ) )[:num_samples]['audio'] return [x["array"] for x in speech_samples] def lowercase_ ( self ) -> Tuple: '''simple docstring''' # fmt: off __lowerCamelCase = torch.tensor( [ 0.11_93, -0.09_46, -0.10_98, -0.01_96, 0.02_25, -0.06_90, -0.17_36, 0.09_51, 0.09_71, -0.08_17, -0.07_02, 0.01_62, 0.02_60, 0.00_17, -0.01_92, -0.16_78, 0.07_09, -0.18_67, -0.06_55, -0.02_74, -0.02_34, -0.18_84, -0.05_16, -0.05_54, -0.02_74, -0.14_25, -0.14_23, 0.08_37, 0.03_77, -0.08_54 ] ) # fmt: on __lowerCamelCase = self._load_datasamples(1 ) __lowerCamelCase = WhisperFeatureExtractor() __lowerCamelCase = feature_extractor(lowerCamelCase__ , return_tensors='pt' ).input_features self.assertEqual(input_features.shape , (1, 80, 3_000) ) self.assertTrue(torch.allclose(input_features[0, 0, :30] , lowerCamelCase__ , atol=1e-4 ) ) def lowercase_ ( self ) -> List[Any]: '''simple docstring''' __lowerCamelCase = self.feature_extraction_class(**self.feat_extract_tester.prepare_feat_extract_dict() ) __lowerCamelCase = self._load_datasamples(1 )[0] __lowerCamelCase = ((audio - audio.min()) / (audio.max() - audio.min())) * 65_535 # Rescale to [0, 65535] to show issue __lowerCamelCase = feat_extract.zero_mean_unit_var_norm([audio] , attention_mask=lowerCamelCase__ )[0] self.assertTrue(np.all(np.mean(lowerCamelCase__ ) < 1e-3 ) ) self.assertTrue(np.all(np.abs(np.var(lowerCamelCase__ ) - 1 ) < 1e-3 ) )
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