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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)
| 43
|
import glob
import os
import random
from string import ascii_lowercase, digits
import cva
import numpy as np
# Parrameters
__lowercase = (720, 1280) # Height, Width
__lowercase = (0.4, 0.6) # if height or width lower than this scale, drop it.
__lowercase = 1 / 100
__lowercase = ''''''
__lowercase = ''''''
__lowercase = ''''''
__lowercase = 250
def lowerCamelCase ( ):
'''simple docstring'''
__UpperCamelCase , __UpperCamelCase :List[Any] = get_dataset(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
for index in range(SCREAMING_SNAKE_CASE ):
__UpperCamelCase :Optional[Any] = random.sample(range(len(SCREAMING_SNAKE_CASE ) ) , 4 )
__UpperCamelCase , __UpperCamelCase , __UpperCamelCase :str = update_image_and_anno(
SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , filter_scale=SCREAMING_SNAKE_CASE , )
# Get random string code: '7b7ad245cdff75241935e4dd860f3bad'
__UpperCamelCase :List[Any] = random_chars(32 )
__UpperCamelCase :List[str] = path.split(os.sep )[-1].rsplit('''.''' , 1 )[0]
__UpperCamelCase :Tuple = f"""{OUTPUT_DIR}/{file_name}_MOSAIC_{letter_code}"""
cva.imwrite(f"""{file_root}.jpg""" , SCREAMING_SNAKE_CASE , [cva.IMWRITE_JPEG_QUALITY, 85] )
print(f"""Succeeded {index+1}/{NUMBER_IMAGES} with {file_name}""" )
__UpperCamelCase :Optional[Any] = []
for anno in new_annos:
__UpperCamelCase :int = anno[3] - anno[1]
__UpperCamelCase :Optional[int] = anno[4] - anno[2]
__UpperCamelCase :int = anno[1] + width / 2
__UpperCamelCase :List[str] = anno[2] + height / 2
__UpperCamelCase :str = f"""{anno[0]} {x_center} {y_center} {width} {height}"""
annos_list.append(SCREAMING_SNAKE_CASE )
with open(f"""{file_root}.txt""" , '''w''' ) as outfile:
outfile.write('''\n'''.join(line for line in annos_list ) )
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :str = []
__UpperCamelCase :str = []
for label_file in glob.glob(os.path.join(SCREAMING_SNAKE_CASE , '''*.txt''' ) ):
__UpperCamelCase :Any = label_file.split(os.sep )[-1].rsplit('''.''' , 1 )[0]
with open(SCREAMING_SNAKE_CASE ) as in_file:
__UpperCamelCase :str = in_file.readlines()
__UpperCamelCase :Optional[int] = os.path.join(SCREAMING_SNAKE_CASE , f"""{label_name}.jpg""" )
__UpperCamelCase :int = []
for obj_list in obj_lists:
__UpperCamelCase :Optional[int] = obj_list.rstrip('''\n''' ).split(''' ''' )
__UpperCamelCase :Any = float(obj[1] ) - float(obj[3] ) / 2
__UpperCamelCase :List[str] = float(obj[2] ) - float(obj[4] ) / 2
__UpperCamelCase :Dict = float(obj[1] ) + float(obj[3] ) / 2
__UpperCamelCase :List[str] = float(obj[2] ) + float(obj[4] ) / 2
boxes.append([int(obj[0] ), xmin, ymin, xmax, ymax] )
if not boxes:
continue
img_paths.append(SCREAMING_SNAKE_CASE )
labels.append(SCREAMING_SNAKE_CASE )
return img_paths, labels
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE = 0.0 , ):
'''simple docstring'''
__UpperCamelCase :List[str] = np.zeros([output_size[0], output_size[1], 3] , dtype=np.uinta )
__UpperCamelCase :List[Any] = scale_range[0] + random.random() * (scale_range[1] - scale_range[0])
__UpperCamelCase :int = scale_range[0] + random.random() * (scale_range[1] - scale_range[0])
__UpperCamelCase :Optional[int] = int(scale_x * output_size[1] )
__UpperCamelCase :Any = int(scale_y * output_size[0] )
__UpperCamelCase :List[str] = []
__UpperCamelCase :Dict = []
for i, index in enumerate(SCREAMING_SNAKE_CASE ):
__UpperCamelCase :Any = all_img_list[index]
path_list.append(SCREAMING_SNAKE_CASE )
__UpperCamelCase :Any = all_annos[index]
__UpperCamelCase :Union[str, Any] = cva.imread(SCREAMING_SNAKE_CASE )
if i == 0: # top-left
__UpperCamelCase :str = cva.resize(SCREAMING_SNAKE_CASE , (divid_point_x, divid_point_y) )
__UpperCamelCase :Union[str, Any] = img
for bbox in img_annos:
__UpperCamelCase :Union[str, Any] = bbox[1] * scale_x
__UpperCamelCase :Optional[Any] = bbox[2] * scale_y
__UpperCamelCase :int = bbox[3] * scale_x
__UpperCamelCase :Union[str, Any] = bbox[4] * scale_y
new_anno.append([bbox[0], xmin, ymin, xmax, ymax] )
elif i == 1: # top-right
__UpperCamelCase :str = cva.resize(SCREAMING_SNAKE_CASE , (output_size[1] - divid_point_x, divid_point_y) )
__UpperCamelCase :List[str] = img
for bbox in img_annos:
__UpperCamelCase :str = scale_x + bbox[1] * (1 - scale_x)
__UpperCamelCase :Dict = bbox[2] * scale_y
__UpperCamelCase :Optional[Any] = scale_x + bbox[3] * (1 - scale_x)
__UpperCamelCase :List[Any] = bbox[4] * scale_y
new_anno.append([bbox[0], xmin, ymin, xmax, ymax] )
elif i == 2: # bottom-left
__UpperCamelCase :str = cva.resize(SCREAMING_SNAKE_CASE , (divid_point_x, output_size[0] - divid_point_y) )
__UpperCamelCase :Optional[int] = img
for bbox in img_annos:
__UpperCamelCase :Tuple = bbox[1] * scale_x
__UpperCamelCase :Optional[Any] = scale_y + bbox[2] * (1 - scale_y)
__UpperCamelCase :Tuple = bbox[3] * scale_x
__UpperCamelCase :Dict = scale_y + bbox[4] * (1 - scale_y)
new_anno.append([bbox[0], xmin, ymin, xmax, ymax] )
else: # bottom-right
__UpperCamelCase :Optional[int] = cva.resize(
SCREAMING_SNAKE_CASE , (output_size[1] - divid_point_x, output_size[0] - divid_point_y) )
__UpperCamelCase :Optional[int] = img
for bbox in img_annos:
__UpperCamelCase :Optional[Any] = scale_x + bbox[1] * (1 - scale_x)
__UpperCamelCase :Optional[int] = scale_y + bbox[2] * (1 - scale_y)
__UpperCamelCase :Optional[Any] = scale_x + bbox[3] * (1 - scale_x)
__UpperCamelCase :int = scale_y + bbox[4] * (1 - scale_y)
new_anno.append([bbox[0], xmin, ymin, xmax, ymax] )
# Remove bounding box small than scale of filter
if filter_scale > 0:
__UpperCamelCase :List[Any] = [
anno
for anno in new_anno
if filter_scale < (anno[3] - anno[1]) and filter_scale < (anno[4] - anno[2])
]
return output_img, new_anno, path_list[0]
def lowerCamelCase ( SCREAMING_SNAKE_CASE ):
'''simple docstring'''
assert number_char > 1, "The number of character should greater than 1"
__UpperCamelCase :Optional[Any] = ascii_lowercase + digits
return "".join(random.choice(SCREAMING_SNAKE_CASE ) for _ in range(SCREAMING_SNAKE_CASE ) )
if __name__ == "__main__":
main()
print('''DONE ✅''')
| 43
| 1
|
from __future__ import annotations
import random
# Maximum size of the population. Bigger could be faster but is more memory expensive.
__lowercase = 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.
__lowercase = 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.
__lowercase = 0.4
# Just a seed to improve randomness required by the algorithm.
random.seed(random.randint(0, 1000))
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Any = len([g for position, g in enumerate(SCREAMING_SNAKE_CASE ) if g == main_target[position]] )
return (item, float(SCREAMING_SNAKE_CASE ))
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Optional[Any] = random.randint(0 , len(SCREAMING_SNAKE_CASE ) - 1 )
__UpperCamelCase :Tuple = parent_a[:random_slice] + parent_a[random_slice:]
__UpperCamelCase :Union[str, Any] = parent_a[:random_slice] + parent_a[random_slice:]
return (child_a, child_a)
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :int = list(SCREAMING_SNAKE_CASE )
if random.uniform(0 , 1 ) < MUTATION_PROBABILITY:
__UpperCamelCase :str = random.choice(SCREAMING_SNAKE_CASE )
return "".join(SCREAMING_SNAKE_CASE )
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , ):
'''simple docstring'''
__UpperCamelCase :int = []
# Generate more children proportionally to the fitness score.
__UpperCamelCase :int = int(parent_a[1] * 100 ) + 1
__UpperCamelCase :List[str] = 10 if child_n >= 10 else child_n
for _ in range(SCREAMING_SNAKE_CASE ):
__UpperCamelCase :Optional[Any] = population_score[random.randint(0 , SCREAMING_SNAKE_CASE )][0]
__UpperCamelCase , __UpperCamelCase :Any = crossover(parent_a[0] , SCREAMING_SNAKE_CASE )
# Append new string to the population list.
pop.append(mutate(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ) )
pop.append(mutate(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ) )
return pop
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE = True ):
'''simple docstring'''
if N_POPULATION < N_SELECTED:
__UpperCamelCase :List[Any] = f"""{N_POPULATION} must be bigger than {N_SELECTED}"""
raise ValueError(SCREAMING_SNAKE_CASE )
# Verify that the target contains no genes besides the ones inside genes variable.
__UpperCamelCase :List[str] = sorted({c for c in target if c not in genes} )
if not_in_genes_list:
__UpperCamelCase :Optional[int] = f"""{not_in_genes_list} is not in genes list, evolution cannot converge"""
raise ValueError(SCREAMING_SNAKE_CASE )
# Generate random starting population.
__UpperCamelCase :int = []
for _ in range(SCREAMING_SNAKE_CASE ):
population.append(''''''.join([random.choice(SCREAMING_SNAKE_CASE ) for i in range(len(SCREAMING_SNAKE_CASE ) )] ) )
# Just some logs to know what the algorithms is doing.
__UpperCamelCase , __UpperCamelCase :List[Any] = 0, 0
# This loop will end when we find a perfect match for our target.
while True:
generation += 1
total_population += len(SCREAMING_SNAKE_CASE )
# 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.
__UpperCamelCase :Tuple = [evaluate(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ) for item in population]
# Check if there is a matching evolution.
__UpperCamelCase :Tuple = sorted(SCREAMING_SNAKE_CASE , key=lambda SCREAMING_SNAKE_CASE : x[1] , reverse=SCREAMING_SNAKE_CASE )
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.
__UpperCamelCase :str = population[: int(N_POPULATION / 3 )]
population.clear()
population.extend(SCREAMING_SNAKE_CASE )
# Normalize population score to be between 0 and 1.
__UpperCamelCase :Union[str, Any] = [
(item, score / len(SCREAMING_SNAKE_CASE )) for item, score in population_score
]
# This is selection
for i in range(SCREAMING_SNAKE_CASE ):
population.extend(select(population_score[int(SCREAMING_SNAKE_CASE )] , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ) )
# 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(SCREAMING_SNAKE_CASE ) > N_POPULATION:
break
if __name__ == "__main__":
__lowercase = (
'''This is a genetic algorithm to evaluate, combine, evolve, and mutate a string!'''
)
__lowercase = list(
''' ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklm'''
'''nopqrstuvwxyz.,;!?+-*#@^\'èéòà€ù=)(&%$£/\\'''
)
__lowercase , __lowercase , __lowercase = basic(target_str, genes_list)
print(
F'\nGeneration: {generation}\nTotal Population: {population}\nTarget: {target}'
)
| 43
|
import functools
import operator
from ...configuration_utils import PretrainedConfig
from ...utils import logging
__lowercase = logging.get_logger(__name__)
__lowercase = {
'''facebook/wav2vec2-base-960h''': '''https://huggingface.co/facebook/wav2vec2-base-960h/resolve/main/config.json''',
# See all Wav2Vec2 models at https://huggingface.co/models?filter=wav2vec2
}
class lowerCamelCase_ ( UpperCAmelCase_ ):
'''simple docstring'''
a__ : Union[str, Any] = """wav2vec2"""
def __init__( self , __lowercase=32 , __lowercase=768 , __lowercase=12 , __lowercase=12 , __lowercase=3_072 , __lowercase="gelu" , __lowercase=0.1 , __lowercase=0.1 , __lowercase=0.1 , __lowercase=0.0 , __lowercase=0.0 , __lowercase=0.1 , __lowercase=0.1 , __lowercase=0.02 , __lowercase=1E-5 , __lowercase="group" , __lowercase="gelu" , __lowercase=(512, 512, 512, 512, 512, 512, 512) , __lowercase=(5, 2, 2, 2, 2, 2, 2) , __lowercase=(10, 3, 3, 3, 3, 2, 2) , __lowercase=False , __lowercase=128 , __lowercase=16 , __lowercase=False , __lowercase=True , __lowercase=0.05 , __lowercase=10 , __lowercase=2 , __lowercase=0.0 , __lowercase=10 , __lowercase=0 , __lowercase=320 , __lowercase=2 , __lowercase=0.1 , __lowercase=100 , __lowercase=256 , __lowercase=256 , __lowercase=0.1 , __lowercase="sum" , __lowercase=False , __lowercase=False , __lowercase=256 , __lowercase=(512, 512, 512, 512, 1_500) , __lowercase=(5, 3, 3, 1, 1) , __lowercase=(1, 2, 3, 1, 1) , __lowercase=512 , __lowercase=0 , __lowercase=1 , __lowercase=2 , __lowercase=False , __lowercase=3 , __lowercase=2 , __lowercase=3 , __lowercase=None , __lowercase=None , **__lowercase , ) -> int:
super().__init__(**__lowercase , pad_token_id=__lowercase , bos_token_id=__lowercase , eos_token_id=__lowercase)
__UpperCamelCase :Any = hidden_size
__UpperCamelCase :int = feat_extract_norm
__UpperCamelCase :Tuple = feat_extract_activation
__UpperCamelCase :Union[str, Any] = list(__lowercase)
__UpperCamelCase :List[Any] = list(__lowercase)
__UpperCamelCase :int = list(__lowercase)
__UpperCamelCase :List[Any] = conv_bias
__UpperCamelCase :Optional[int] = num_conv_pos_embeddings
__UpperCamelCase :Dict = num_conv_pos_embedding_groups
__UpperCamelCase :Any = len(self.conv_dim)
__UpperCamelCase :List[str] = num_hidden_layers
__UpperCamelCase :int = intermediate_size
__UpperCamelCase :str = hidden_act
__UpperCamelCase :Any = num_attention_heads
__UpperCamelCase :int = hidden_dropout
__UpperCamelCase :Tuple = attention_dropout
__UpperCamelCase :List[str] = activation_dropout
__UpperCamelCase :Optional[Any] = feat_proj_dropout
__UpperCamelCase :Any = final_dropout
__UpperCamelCase :Any = layerdrop
__UpperCamelCase :str = layer_norm_eps
__UpperCamelCase :Optional[Any] = initializer_range
__UpperCamelCase :List[str] = vocab_size
__UpperCamelCase :str = do_stable_layer_norm
__UpperCamelCase :Union[str, Any] = use_weighted_layer_sum
if (
(len(self.conv_stride) != self.num_feat_extract_layers)
or (len(self.conv_kernel) != self.num_feat_extract_layers)
or (len(self.conv_dim) != self.num_feat_extract_layers)
):
raise ValueError(
'''Configuration for convolutional layers is incorrect. It is required that `len(config.conv_dim)` =='''
''' `len(config.conv_stride)` == `len(config.conv_kernel)`, but is `len(config.conv_dim) ='''
f""" {len(self.conv_dim)}`, `len(config.conv_stride) = {len(self.conv_stride)}`,"""
f""" `len(config.conv_kernel) = {len(self.conv_kernel)}`.""")
# fine-tuning config parameters for SpecAugment: https://arxiv.org/abs/1904.08779
__UpperCamelCase :List[Any] = apply_spec_augment
__UpperCamelCase :Tuple = mask_time_prob
__UpperCamelCase :int = mask_time_length
__UpperCamelCase :Dict = mask_time_min_masks
__UpperCamelCase :str = mask_feature_prob
__UpperCamelCase :List[str] = mask_feature_length
__UpperCamelCase :Union[str, Any] = mask_feature_min_masks
# parameters for pretraining with codevector quantized representations
__UpperCamelCase :Optional[Any] = num_codevectors_per_group
__UpperCamelCase :List[Any] = num_codevector_groups
__UpperCamelCase :Tuple = contrastive_logits_temperature
__UpperCamelCase :Optional[int] = feat_quantizer_dropout
__UpperCamelCase :Optional[int] = num_negatives
__UpperCamelCase :List[Any] = codevector_dim
__UpperCamelCase :str = proj_codevector_dim
__UpperCamelCase :List[str] = diversity_loss_weight
# ctc loss
__UpperCamelCase :Tuple = ctc_loss_reduction
__UpperCamelCase :Tuple = ctc_zero_infinity
# adapter
__UpperCamelCase :List[str] = add_adapter
__UpperCamelCase :Tuple = adapter_kernel_size
__UpperCamelCase :str = adapter_stride
__UpperCamelCase :Tuple = num_adapter_layers
__UpperCamelCase :Tuple = output_hidden_size or hidden_size
__UpperCamelCase :Optional[Any] = adapter_attn_dim
# SequenceClassification-specific parameter. Feel free to ignore for other classes.
__UpperCamelCase :Optional[Any] = classifier_proj_size
# XVector-specific parameters. Feel free to ignore for other classes.
__UpperCamelCase :Optional[int] = list(__lowercase)
__UpperCamelCase :List[Any] = list(__lowercase)
__UpperCamelCase :List[Any] = list(__lowercase)
__UpperCamelCase :str = xvector_output_dim
@property
def UpperCamelCase__ ( self) -> List[str]:
return functools.reduce(operator.mul , self.conv_stride , 1)
| 43
| 1
|
import argparse
import pathlib
import fairseq
import torch
from fairseq.models.roberta import RobertaModel as FairseqRobertaModel
from fairseq.modules import TransformerSentenceEncoderLayer
from packaging import version
from transformers import XLMRobertaConfig, XLMRobertaXLForMaskedLM, XLMRobertaXLForSequenceClassification
from transformers.models.bert.modeling_bert import (
BertIntermediate,
BertLayer,
BertOutput,
BertSelfAttention,
BertSelfOutput,
)
from transformers.models.roberta.modeling_roberta import RobertaAttention
from transformers.utils import logging
if version.parse(fairseq.__version__) < version.parse('''1.0.0a'''):
raise Exception('''requires fairseq >= 1.0.0a''')
logging.set_verbosity_info()
__lowercase = logging.get_logger(__name__)
__lowercase = '''Hello world! cécé herlolip'''
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Optional[int] = FairseqRobertaModel.from_pretrained(SCREAMING_SNAKE_CASE )
roberta.eval() # disable dropout
__UpperCamelCase :Optional[Any] = roberta.model.encoder.sentence_encoder
__UpperCamelCase :Dict = XLMRobertaConfig(
vocab_size=roberta_sent_encoder.embed_tokens.num_embeddings , hidden_size=roberta.cfg.model.encoder_embed_dim , num_hidden_layers=roberta.cfg.model.encoder_layers , num_attention_heads=roberta.cfg.model.encoder_attention_heads , intermediate_size=roberta.cfg.model.encoder_ffn_embed_dim , max_position_embeddings=514 , type_vocab_size=1 , layer_norm_eps=1e-5 , )
if classification_head:
__UpperCamelCase :Union[str, Any] = roberta.model.classification_heads['''mnli'''].out_proj.weight.shape[0]
print('''Our RoBERTa config:''' , SCREAMING_SNAKE_CASE )
__UpperCamelCase :Tuple = XLMRobertaXLForSequenceClassification(SCREAMING_SNAKE_CASE ) if classification_head else XLMRobertaXLForMaskedLM(SCREAMING_SNAKE_CASE )
model.eval()
# Now let's copy all the weights.
# Embeddings
__UpperCamelCase :str = roberta_sent_encoder.embed_tokens.weight
__UpperCamelCase :int = roberta_sent_encoder.embed_positions.weight
__UpperCamelCase :Optional[Any] = torch.zeros_like(
model.roberta.embeddings.token_type_embeddings.weight ) # just zero them out b/c RoBERTa doesn't use them.
__UpperCamelCase :List[Any] = roberta_sent_encoder.layer_norm.weight
__UpperCamelCase :Dict = roberta_sent_encoder.layer_norm.bias
for i in range(config.num_hidden_layers ):
# Encoder: start of layer
__UpperCamelCase :BertLayer = model.roberta.encoder.layer[i]
__UpperCamelCase :TransformerSentenceEncoderLayer = roberta_sent_encoder.layers[i]
__UpperCamelCase :RobertaAttention = layer.attention
__UpperCamelCase :Optional[int] = roberta_layer.self_attn_layer_norm.weight
__UpperCamelCase :Tuple = roberta_layer.self_attn_layer_norm.bias
# self attention
__UpperCamelCase :BertSelfAttention = layer.attention.self
assert (
roberta_layer.self_attn.k_proj.weight.data.shape
== roberta_layer.self_attn.q_proj.weight.data.shape
== roberta_layer.self_attn.v_proj.weight.data.shape
== torch.Size((config.hidden_size, config.hidden_size) )
)
__UpperCamelCase :List[str] = roberta_layer.self_attn.q_proj.weight
__UpperCamelCase :Optional[Any] = roberta_layer.self_attn.q_proj.bias
__UpperCamelCase :Any = roberta_layer.self_attn.k_proj.weight
__UpperCamelCase :List[Any] = roberta_layer.self_attn.k_proj.bias
__UpperCamelCase :Optional[Any] = roberta_layer.self_attn.v_proj.weight
__UpperCamelCase :Optional[int] = roberta_layer.self_attn.v_proj.bias
# self-attention output
__UpperCamelCase :BertSelfOutput = layer.attention.output
assert self_output.dense.weight.shape == roberta_layer.self_attn.out_proj.weight.shape
__UpperCamelCase :Dict = roberta_layer.self_attn.out_proj.weight
__UpperCamelCase :int = roberta_layer.self_attn.out_proj.bias
# this one is final layer norm
__UpperCamelCase :Optional[Any] = roberta_layer.final_layer_norm.weight
__UpperCamelCase :List[Any] = roberta_layer.final_layer_norm.bias
# intermediate
__UpperCamelCase :BertIntermediate = layer.intermediate
assert intermediate.dense.weight.shape == roberta_layer.fca.weight.shape
__UpperCamelCase :str = roberta_layer.fca.weight
__UpperCamelCase :int = roberta_layer.fca.bias
# output
__UpperCamelCase :BertOutput = layer.output
assert bert_output.dense.weight.shape == roberta_layer.fca.weight.shape
__UpperCamelCase :int = roberta_layer.fca.weight
__UpperCamelCase :Tuple = roberta_layer.fca.bias
# end of layer
if classification_head:
__UpperCamelCase :Optional[Any] = roberta.model.classification_heads['''mnli'''].dense.weight
__UpperCamelCase :Union[str, Any] = roberta.model.classification_heads['''mnli'''].dense.bias
__UpperCamelCase :List[str] = roberta.model.classification_heads['''mnli'''].out_proj.weight
__UpperCamelCase :str = roberta.model.classification_heads['''mnli'''].out_proj.bias
else:
# LM Head
__UpperCamelCase :Tuple = roberta.model.encoder.lm_head.dense.weight
__UpperCamelCase :Any = roberta.model.encoder.lm_head.dense.bias
__UpperCamelCase :int = roberta.model.encoder.lm_head.layer_norm.weight
__UpperCamelCase :List[str] = roberta.model.encoder.lm_head.layer_norm.bias
__UpperCamelCase :List[str] = roberta.model.encoder.lm_head.weight
__UpperCamelCase :Dict = roberta.model.encoder.lm_head.bias
# Let's check that we get the same results.
__UpperCamelCase :torch.Tensor = roberta.encode(SCREAMING_SNAKE_CASE ).unsqueeze(0 ) # batch of size 1
__UpperCamelCase :Optional[int] = model(SCREAMING_SNAKE_CASE )[0]
if classification_head:
__UpperCamelCase :int = roberta.model.classification_heads['''mnli'''](roberta.extract_features(SCREAMING_SNAKE_CASE ) )
else:
__UpperCamelCase :str = roberta.model(SCREAMING_SNAKE_CASE )[0]
print(our_output.shape , their_output.shape )
__UpperCamelCase :Any = torch.max(torch.abs(our_output - their_output ) ).item()
print(f"""max_absolute_diff = {max_absolute_diff}""" ) # ~ 1e-7
__UpperCamelCase :List[str] = torch.allclose(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , atol=1e-3 )
print('''Do both models output the same tensors?''' , '''🔥''' if success else '''💩''' )
if not success:
raise Exception('''Something went wRoNg''' )
pathlib.Path(SCREAMING_SNAKE_CASE ).mkdir(parents=SCREAMING_SNAKE_CASE , exist_ok=SCREAMING_SNAKE_CASE )
print(f"""Saving model to {pytorch_dump_folder_path}""" )
model.save_pretrained(SCREAMING_SNAKE_CASE )
if __name__ == "__main__":
__lowercase = argparse.ArgumentParser()
# Required parameters
parser.add_argument(
'''--roberta_checkpoint_path''', default=None, type=str, required=True, help='''Path the official PyTorch dump.'''
)
parser.add_argument(
'''--pytorch_dump_folder_path''', default=None, type=str, required=True, help='''Path to the output PyTorch model.'''
)
parser.add_argument(
'''--classification_head''', action='''store_true''', help='''Whether to convert a final classification head.'''
)
__lowercase = parser.parse_args()
convert_xlm_roberta_xl_checkpoint_to_pytorch(
args.roberta_checkpoint_path, args.pytorch_dump_folder_path, args.classification_head
)
| 43
|
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
__lowercase = logging.get_logger(__name__)
class lowerCamelCase_ ( UpperCAmelCase_ ):
'''simple docstring'''
a__ : Optional[Any] = ["""pixel_values"""]
def __init__( self , __lowercase = True , __lowercase = 32 , __lowercase=PILImageResampling.BILINEAR , __lowercase = True , **__lowercase , ) -> None:
__UpperCamelCase :Optional[int] = do_resize
__UpperCamelCase :Any = do_rescale
__UpperCamelCase :str = size_divisor
__UpperCamelCase :Dict = resample
super().__init__(**__lowercase)
def UpperCamelCase__ ( self , __lowercase , __lowercase , __lowercase , __lowercase = None , **__lowercase) -> np.ndarray:
__UpperCamelCase , __UpperCamelCase :int = get_image_size(__lowercase)
# Rounds the height and width down to the closest multiple of size_divisor
__UpperCamelCase :List[Any] = height // size_divisor * size_divisor
__UpperCamelCase :List[str] = width // size_divisor * size_divisor
__UpperCamelCase :str = resize(__lowercase , (new_h, new_w) , resample=__lowercase , data_format=__lowercase , **__lowercase)
return image
def UpperCamelCase__ ( self , __lowercase , __lowercase , __lowercase = None , **__lowercase) -> np.ndarray:
return rescale(image=__lowercase , scale=__lowercase , data_format=__lowercase , **__lowercase)
def UpperCamelCase__ ( self , __lowercase , __lowercase = None , __lowercase = None , __lowercase=None , __lowercase = None , __lowercase = None , __lowercase = ChannelDimension.FIRST , **__lowercase , ) -> BatchFeature:
__UpperCamelCase :Union[str, Any] = do_resize if do_resize is not None else self.do_resize
__UpperCamelCase :Tuple = do_rescale if do_rescale is not None else self.do_rescale
__UpperCamelCase :List[str] = size_divisor if size_divisor is not None else self.size_divisor
__UpperCamelCase :List[Any] = 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''')
__UpperCamelCase :List[Any] = make_list_of_images(__lowercase)
if not valid_images(__lowercase):
raise ValueError('''Invalid image(s)''')
# All transformations expect numpy arrays.
__UpperCamelCase :Optional[Any] = [to_numpy_array(__lowercase) for img in images]
if do_resize:
__UpperCamelCase :List[str] = [self.resize(__lowercase , size_divisor=__lowercase , resample=__lowercase) for image in images]
if do_rescale:
__UpperCamelCase :Dict = [self.rescale(__lowercase , scale=1 / 255) for image in images]
__UpperCamelCase :str = [to_channel_dimension_format(__lowercase , __lowercase) for image in images]
__UpperCamelCase :int = {'''pixel_values''': images}
return BatchFeature(data=__lowercase , tensor_type=__lowercase)
| 43
| 1
|
from __future__ import annotations
def lowerCamelCase ( SCREAMING_SNAKE_CASE ):
'''simple docstring'''
return [ord(SCREAMING_SNAKE_CASE ) - 96 for elem in plain]
def lowerCamelCase ( SCREAMING_SNAKE_CASE ):
'''simple docstring'''
return "".join(chr(elem + 96 ) for elem in encoded )
def lowerCamelCase ( ):
'''simple docstring'''
__UpperCamelCase :List[Any] = encode(input('''-> ''' ).strip().lower() )
print('''Encoded: ''' , SCREAMING_SNAKE_CASE )
print('''Decoded:''' , decode(SCREAMING_SNAKE_CASE ) )
if __name__ == "__main__":
main()
| 43
|
from __future__ import annotations
from PIL import Image
# Define glider example
__lowercase = [
[0, 1, 0, 0, 0, 0, 0, 0],
[0, 0, 1, 0, 0, 0, 0, 0],
[1, 1, 1, 0, 0, 0, 0, 0],
[0, 0, 0, 0, 0, 0, 0, 0],
[0, 0, 0, 0, 0, 0, 0, 0],
[0, 0, 0, 0, 0, 0, 0, 0],
[0, 0, 0, 0, 0, 0, 0, 0],
[0, 0, 0, 0, 0, 0, 0, 0],
]
# Define blinker example
__lowercase = [[0, 1, 0], [0, 1, 0], [0, 1, 0]]
def lowerCamelCase ( SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :int = []
for i in range(len(SCREAMING_SNAKE_CASE ) ):
__UpperCamelCase :Dict = []
for j in range(len(cells[i] ) ):
# Get the number of live neighbours
__UpperCamelCase :List[str] = 0
if i > 0 and j > 0:
neighbour_count += cells[i - 1][j - 1]
if i > 0:
neighbour_count += cells[i - 1][j]
if i > 0 and j < len(cells[i] ) - 1:
neighbour_count += cells[i - 1][j + 1]
if j > 0:
neighbour_count += cells[i][j - 1]
if j < len(cells[i] ) - 1:
neighbour_count += cells[i][j + 1]
if i < len(SCREAMING_SNAKE_CASE ) - 1 and j > 0:
neighbour_count += cells[i + 1][j - 1]
if i < len(SCREAMING_SNAKE_CASE ) - 1:
neighbour_count += cells[i + 1][j]
if i < len(SCREAMING_SNAKE_CASE ) - 1 and j < len(cells[i] ) - 1:
neighbour_count += cells[i + 1][j + 1]
# Rules of the game of life (excerpt from Wikipedia):
# 1. Any live cell with two or three live neighbours survives.
# 2. Any dead cell with three live neighbours becomes a live cell.
# 3. All other live cells die in the next generation.
# Similarly, all other dead cells stay dead.
__UpperCamelCase :List[str] = cells[i][j] == 1
if (
(alive and 2 <= neighbour_count <= 3)
or not alive
and neighbour_count == 3
):
next_generation_row.append(1 )
else:
next_generation_row.append(0 )
next_generation.append(SCREAMING_SNAKE_CASE )
return next_generation
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Optional[Any] = []
for _ in range(SCREAMING_SNAKE_CASE ):
# Create output image
__UpperCamelCase :Dict = Image.new('''RGB''' , (len(cells[0] ), len(SCREAMING_SNAKE_CASE )) )
__UpperCamelCase :Any = img.load()
# Save cells to image
for x in range(len(SCREAMING_SNAKE_CASE ) ):
for y in range(len(cells[0] ) ):
__UpperCamelCase :Optional[Any] = 255 - cells[y][x] * 255
__UpperCamelCase :int = (colour, colour, colour)
# Save image
images.append(SCREAMING_SNAKE_CASE )
__UpperCamelCase :Optional[int] = new_generation(SCREAMING_SNAKE_CASE )
return images
if __name__ == "__main__":
__lowercase = generate_images(GLIDER, 16)
images[0].save('''out.gif''', save_all=True, append_images=images[1:])
| 43
| 1
|
from __future__ import annotations
def lowerCamelCase ( SCREAMING_SNAKE_CASE ):
'''simple docstring'''
if not nums:
return 0
__UpperCamelCase :str = nums[0]
__UpperCamelCase :Optional[int] = 0
for num in nums[1:]:
__UpperCamelCase , __UpperCamelCase :List[str] = (
max_excluding + num,
max(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ),
)
return max(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
if __name__ == "__main__":
import doctest
doctest.testmod()
| 43
|
import re
import jax.numpy as jnp
from flax.traverse_util import flatten_dict, unflatten_dict
from jax.random import PRNGKey
from ..utils import logging
__lowercase = logging.get_logger(__name__)
def lowerCamelCase ( SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Tuple = R'''\w+[.]\d+'''
__UpperCamelCase :List[str] = re.findall(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
for pat in pats:
__UpperCamelCase :int = key.replace(SCREAMING_SNAKE_CASE , '''_'''.join(pat.split('''.''' ) ) )
return key
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Tuple = pt_tuple_key[:-1] + ('''scale''',)
if (
any('''norm''' in str_ for str_ in pt_tuple_key )
and (pt_tuple_key[-1] == "bias")
and (pt_tuple_key[:-1] + ("bias",) not in random_flax_state_dict)
and (pt_tuple_key[:-1] + ("scale",) in random_flax_state_dict)
):
__UpperCamelCase :str = pt_tuple_key[:-1] + ('''scale''',)
return renamed_pt_tuple_key, pt_tensor
elif pt_tuple_key[-1] in ["weight", "gamma"] and pt_tuple_key[:-1] + ("scale",) in random_flax_state_dict:
__UpperCamelCase :Any = pt_tuple_key[:-1] + ('''scale''',)
return renamed_pt_tuple_key, pt_tensor
# embedding
if pt_tuple_key[-1] == "weight" and pt_tuple_key[:-1] + ("embedding",) in random_flax_state_dict:
__UpperCamelCase :str = pt_tuple_key[:-1] + ('''embedding''',)
return renamed_pt_tuple_key, pt_tensor
# conv layer
__UpperCamelCase :List[str] = pt_tuple_key[:-1] + ('''kernel''',)
if pt_tuple_key[-1] == "weight" and pt_tensor.ndim == 4:
__UpperCamelCase :List[Any] = pt_tensor.transpose(2 , 3 , 1 , 0 )
return renamed_pt_tuple_key, pt_tensor
# linear layer
__UpperCamelCase :List[str] = pt_tuple_key[:-1] + ('''kernel''',)
if pt_tuple_key[-1] == "weight":
__UpperCamelCase :Any = pt_tensor.T
return renamed_pt_tuple_key, pt_tensor
# old PyTorch layer norm weight
__UpperCamelCase :int = pt_tuple_key[:-1] + ('''weight''',)
if pt_tuple_key[-1] == "gamma":
return renamed_pt_tuple_key, pt_tensor
# old PyTorch layer norm bias
__UpperCamelCase :int = pt_tuple_key[:-1] + ('''bias''',)
if pt_tuple_key[-1] == "beta":
return renamed_pt_tuple_key, pt_tensor
return pt_tuple_key, pt_tensor
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE=42 ):
'''simple docstring'''
__UpperCamelCase :Union[str, Any] = {k: v.numpy() for k, v in pt_state_dict.items()}
# Step 2: Since the model is stateless, get random Flax params
__UpperCamelCase :str = flax_model.init_weights(PRNGKey(SCREAMING_SNAKE_CASE ) )
__UpperCamelCase :int = flatten_dict(SCREAMING_SNAKE_CASE )
__UpperCamelCase :List[Any] = {}
# Need to change some parameters name to match Flax names
for pt_key, pt_tensor in pt_state_dict.items():
__UpperCamelCase :List[Any] = rename_key(SCREAMING_SNAKE_CASE )
__UpperCamelCase :List[Any] = tuple(renamed_pt_key.split('''.''' ) )
# Correctly rename weight parameters
__UpperCamelCase , __UpperCamelCase :Any = rename_key_and_reshape_tensor(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
if flax_key in random_flax_state_dict:
if flax_tensor.shape != random_flax_state_dict[flax_key].shape:
raise ValueError(
f"""PyTorch checkpoint seems to be incorrect. Weight {pt_key} was expected to be of shape """
f"""{random_flax_state_dict[flax_key].shape}, but is {flax_tensor.shape}.""" )
# also add unexpected weight so that warning is thrown
__UpperCamelCase :str = jnp.asarray(SCREAMING_SNAKE_CASE )
return unflatten_dict(SCREAMING_SNAKE_CASE )
| 43
| 1
|
def lowerCamelCase ( SCREAMING_SNAKE_CASE ):
'''simple docstring'''
if number > 0:
raise ValueError('''input must be a negative integer''' )
__UpperCamelCase :str = len(bin(SCREAMING_SNAKE_CASE )[3:] )
__UpperCamelCase :Optional[Any] = bin(abs(SCREAMING_SNAKE_CASE ) - (1 << binary_number_length) )[3:]
__UpperCamelCase :Optional[Any] = (
(
'''1'''
+ '''0''' * (binary_number_length - len(SCREAMING_SNAKE_CASE ))
+ twos_complement_number
)
if number < 0
else '''0'''
)
return "0b" + twos_complement_number
if __name__ == "__main__":
import doctest
doctest.testmod()
| 43
|
import argparse
import torch
from ...utils import logging
from . import AlbertConfig, AlbertForPreTraining, load_tf_weights_in_albert
logging.set_verbosity_info()
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :List[Any] = AlbertConfig.from_json_file(SCREAMING_SNAKE_CASE )
print(f"""Building PyTorch model from configuration: {config}""" )
__UpperCamelCase :List[str] = AlbertForPreTraining(SCREAMING_SNAKE_CASE )
# Load weights from tf checkpoint
load_tf_weights_in_albert(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
# Save pytorch-model
print(f"""Save PyTorch model to {pytorch_dump_path}""" )
torch.save(model.state_dict() , SCREAMING_SNAKE_CASE )
if __name__ == "__main__":
__lowercase = argparse.ArgumentParser()
# Required parameters
parser.add_argument(
'''--tf_checkpoint_path''', default=None, type=str, required=True, help='''Path to the TensorFlow checkpoint path.'''
)
parser.add_argument(
'''--albert_config_file''',
default=None,
type=str,
required=True,
help=(
'''The config json file corresponding to the pre-trained ALBERT model. \n'''
'''This specifies the model architecture.'''
),
)
parser.add_argument(
'''--pytorch_dump_path''', default=None, type=str, required=True, help='''Path to the output PyTorch model.'''
)
__lowercase = parser.parse_args()
convert_tf_checkpoint_to_pytorch(args.tf_checkpoint_path, args.albert_config_file, args.pytorch_dump_path)
| 43
| 1
|
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
__lowercase = logging.get_logger(__name__)
if is_vision_available():
import PIL
class lowerCamelCase_ ( UpperCAmelCase_ ):
'''simple docstring'''
a__ : int = ["""pixel_values"""]
def __init__( self , __lowercase = True , __lowercase = None , __lowercase = PILImageResampling.BICUBIC , __lowercase = True , __lowercase = None , __lowercase = True , __lowercase = 1 / 255 , __lowercase = True , __lowercase = None , __lowercase = None , __lowercase = True , **__lowercase , ) -> None:
super().__init__(**__lowercase)
__UpperCamelCase :List[Any] = size if size is not None else {'''shortest_edge''': 224}
__UpperCamelCase :List[str] = get_size_dict(__lowercase , default_to_square=__lowercase)
__UpperCamelCase :Optional[Any] = crop_size if crop_size is not None else {'''height''': 224, '''width''': 224}
__UpperCamelCase :str = get_size_dict(__lowercase , default_to_square=__lowercase , param_name='''crop_size''')
__UpperCamelCase :List[str] = do_resize
__UpperCamelCase :Union[str, Any] = size
__UpperCamelCase :Dict = resample
__UpperCamelCase :Optional[Any] = do_center_crop
__UpperCamelCase :Dict = crop_size
__UpperCamelCase :List[str] = do_rescale
__UpperCamelCase :Any = rescale_factor
__UpperCamelCase :Any = do_normalize
__UpperCamelCase :int = image_mean if image_mean is not None else OPENAI_CLIP_MEAN
__UpperCamelCase :Union[str, Any] = image_std if image_std is not None else OPENAI_CLIP_STD
__UpperCamelCase :Any = do_convert_rgb
def UpperCamelCase__ ( self , __lowercase , __lowercase , __lowercase = PILImageResampling.BICUBIC , __lowercase = None , **__lowercase , ) -> np.ndarray:
__UpperCamelCase :List[Any] = get_size_dict(__lowercase , default_to_square=__lowercase)
if "shortest_edge" not in size:
raise ValueError(f"""The `size` parameter must contain the key `shortest_edge`. Got {size.keys()}""")
__UpperCamelCase :List[Any] = get_resize_output_image_size(__lowercase , size=size['''shortest_edge'''] , default_to_square=__lowercase)
return resize(__lowercase , size=__lowercase , resample=__lowercase , data_format=__lowercase , **__lowercase)
def UpperCamelCase__ ( self , __lowercase , __lowercase , __lowercase = None , **__lowercase , ) -> np.ndarray:
__UpperCamelCase :Optional[int] = get_size_dict(__lowercase)
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(__lowercase , size=(size['''height'''], size['''width''']) , data_format=__lowercase , **__lowercase)
def UpperCamelCase__ ( self , __lowercase , __lowercase , __lowercase = None , **__lowercase , ) -> List[str]:
return rescale(__lowercase , scale=__lowercase , data_format=__lowercase , **__lowercase)
def UpperCamelCase__ ( self , __lowercase , __lowercase , __lowercase , __lowercase = None , **__lowercase , ) -> np.ndarray:
return normalize(__lowercase , mean=__lowercase , std=__lowercase , data_format=__lowercase , **__lowercase)
def UpperCamelCase__ ( self , __lowercase , __lowercase = None , __lowercase = None , __lowercase = None , __lowercase = None , __lowercase = None , __lowercase = None , __lowercase = None , __lowercase = None , __lowercase = None , __lowercase = None , __lowercase = None , __lowercase = None , __lowercase = ChannelDimension.FIRST , **__lowercase , ) -> PIL.Image.Image:
__UpperCamelCase :int = do_resize if do_resize is not None else self.do_resize
__UpperCamelCase :Dict = size if size is not None else self.size
__UpperCamelCase :Union[str, Any] = get_size_dict(__lowercase , param_name='''size''' , default_to_square=__lowercase)
__UpperCamelCase :Optional[int] = resample if resample is not None else self.resample
__UpperCamelCase :Dict = do_center_crop if do_center_crop is not None else self.do_center_crop
__UpperCamelCase :List[Any] = crop_size if crop_size is not None else self.crop_size
__UpperCamelCase :Optional[Any] = get_size_dict(__lowercase , param_name='''crop_size''' , default_to_square=__lowercase)
__UpperCamelCase :Union[str, Any] = do_rescale if do_rescale is not None else self.do_rescale
__UpperCamelCase :List[str] = rescale_factor if rescale_factor is not None else self.rescale_factor
__UpperCamelCase :Optional[Any] = do_normalize if do_normalize is not None else self.do_normalize
__UpperCamelCase :Union[str, Any] = image_mean if image_mean is not None else self.image_mean
__UpperCamelCase :List[Any] = image_std if image_std is not None else self.image_std
__UpperCamelCase :Optional[Any] = do_convert_rgb if do_convert_rgb is not None else self.do_convert_rgb
__UpperCamelCase :List[str] = make_list_of_images(__lowercase)
if not valid_images(__lowercase):
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:
__UpperCamelCase :Optional[Any] = [convert_to_rgb(__lowercase) for image in images]
# All transformations expect numpy arrays.
__UpperCamelCase :List[Any] = [to_numpy_array(__lowercase) for image in images]
if do_resize:
__UpperCamelCase :Optional[Any] = [self.resize(image=__lowercase , size=__lowercase , resample=__lowercase) for image in images]
if do_center_crop:
__UpperCamelCase :List[Any] = [self.center_crop(image=__lowercase , size=__lowercase) for image in images]
if do_rescale:
__UpperCamelCase :List[Any] = [self.rescale(image=__lowercase , scale=__lowercase) for image in images]
if do_normalize:
__UpperCamelCase :Optional[Any] = [self.normalize(image=__lowercase , mean=__lowercase , std=__lowercase) for image in images]
__UpperCamelCase :Dict = [to_channel_dimension_format(__lowercase , __lowercase) for image in images]
__UpperCamelCase :Dict = {'''pixel_values''': images}
return BatchFeature(data=__lowercase , tensor_type=__lowercase)
| 43
|
import math
import qiskit
def lowerCamelCase ( SCREAMING_SNAKE_CASE = 1 , SCREAMING_SNAKE_CASE = 1 , SCREAMING_SNAKE_CASE = 1 ):
'''simple docstring'''
if (
isinstance(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
or isinstance(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
or isinstance(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
):
raise TypeError('''inputs must be integers.''' )
if (input_a < 0) or (input_a < 0) or (carry_in < 0):
raise ValueError('''inputs must be positive.''' )
if (
(math.floor(SCREAMING_SNAKE_CASE ) != input_a)
or (math.floor(SCREAMING_SNAKE_CASE ) != input_a)
or (math.floor(SCREAMING_SNAKE_CASE ) != carry_in)
):
raise ValueError('''inputs must be exact integers.''' )
if (input_a > 2) or (input_a > 2) or (carry_in > 2):
raise ValueError('''inputs must be less or equal to 2.''' )
# build registers
__UpperCamelCase :List[str] = qiskit.QuantumRegister(4 , '''qr''' )
__UpperCamelCase :str = qiskit.ClassicalRegister(2 , '''cr''' )
# list the entries
__UpperCamelCase :Tuple = [input_a, input_a, carry_in]
__UpperCamelCase :Optional[int] = qiskit.QuantumCircuit(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
for i in range(0 , 3 ):
if entry[i] == 2:
quantum_circuit.h(SCREAMING_SNAKE_CASE ) # for hadamard entries
elif entry[i] == 1:
quantum_circuit.x(SCREAMING_SNAKE_CASE ) # for 1 entries
elif entry[i] == 0:
quantum_circuit.i(SCREAMING_SNAKE_CASE ) # for 0 entries
# build the circuit
quantum_circuit.ccx(0 , 1 , 3 ) # ccx = toffoli gate
quantum_circuit.cx(0 , 1 )
quantum_circuit.ccx(1 , 2 , 3 )
quantum_circuit.cx(1 , 2 )
quantum_circuit.cx(0 , 1 )
quantum_circuit.measure([2, 3] , SCREAMING_SNAKE_CASE ) # measure the last two qbits
__UpperCamelCase :Optional[Any] = qiskit.Aer.get_backend('''aer_simulator''' )
__UpperCamelCase :Tuple = qiskit.execute(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , shots=1_000 )
return job.result().get_counts(SCREAMING_SNAKE_CASE )
if __name__ == "__main__":
print(F'Total sum count for state is: {quantum_full_adder(1, 1, 1)}')
| 43
| 1
|
def lowerCamelCase ( ):
'''simple docstring'''
return [list(range(1_000 - i , -1_000 - i , -1 ) ) for i in range(1_000 )]
__lowercase = generate_large_matrix()
__lowercase = (
[[4, 3, 2, -1], [3, 2, 1, -1], [1, 1, -1, -2], [-1, -1, -2, -3]],
[[3, 2], [1, 0]],
[[7, 7, 6]],
[[7, 7, 6], [-1, -2, -3]],
grid,
)
def lowerCamelCase ( SCREAMING_SNAKE_CASE ):
'''simple docstring'''
assert all(row == sorted(SCREAMING_SNAKE_CASE , reverse=SCREAMING_SNAKE_CASE ) for row in grid )
assert all(list(SCREAMING_SNAKE_CASE ) == sorted(SCREAMING_SNAKE_CASE , reverse=SCREAMING_SNAKE_CASE ) for col in zip(*SCREAMING_SNAKE_CASE ) )
def lowerCamelCase ( SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Any = 0
__UpperCamelCase :Union[str, Any] = len(SCREAMING_SNAKE_CASE ) - 1
# Edge cases such as no values or all numbers are negative.
if not array or array[0] < 0:
return 0
while right + 1 > left:
__UpperCamelCase :Union[str, Any] = (left + right) // 2
__UpperCamelCase :Any = array[mid]
# Num must be negative and the index must be greater than or equal to 0.
if num < 0 and array[mid - 1] >= 0:
return mid
if num >= 0:
__UpperCamelCase :List[Any] = mid + 1
else:
__UpperCamelCase :List[Any] = mid - 1
# No negative numbers so return the last index of the array + 1 which is the length.
return len(SCREAMING_SNAKE_CASE )
def lowerCamelCase ( SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :int = 0
__UpperCamelCase :Optional[int] = len(grid[0] )
for i in range(len(SCREAMING_SNAKE_CASE ) ):
__UpperCamelCase :str = find_negative_index(grid[i][:bound] )
total += bound
return (len(SCREAMING_SNAKE_CASE ) * len(grid[0] )) - total
def lowerCamelCase ( SCREAMING_SNAKE_CASE ):
'''simple docstring'''
return len([number for row in grid for number in row if number < 0] )
def lowerCamelCase ( SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Optional[Any] = 0
for row in grid:
for i, number in enumerate(SCREAMING_SNAKE_CASE ):
if number < 0:
total += len(SCREAMING_SNAKE_CASE ) - i
break
return total
def lowerCamelCase ( ):
'''simple docstring'''
from timeit import timeit
print('''Running benchmarks''' )
__UpperCamelCase :int = (
'''from __main__ import count_negatives_binary_search, '''
'''count_negatives_brute_force, count_negatives_brute_force_with_break, grid'''
)
for func in (
"count_negatives_binary_search", # took 0.7727 seconds
"count_negatives_brute_force_with_break", # took 4.6505 seconds
"count_negatives_brute_force", # took 12.8160 seconds
):
__UpperCamelCase :Optional[Any] = timeit(f"""{func}(grid=grid)""" , setup=SCREAMING_SNAKE_CASE , number=500 )
print(f"""{func}() took {time:0.4f} seconds""" )
if __name__ == "__main__":
import doctest
doctest.testmod()
benchmark()
| 43
|
import random
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Optional[Any] = a[left_index]
__UpperCamelCase :Any = left_index + 1
for j in range(left_index + 1 , SCREAMING_SNAKE_CASE ):
if a[j] < pivot:
__UpperCamelCase , __UpperCamelCase :str = a[i], a[j]
i += 1
__UpperCamelCase , __UpperCamelCase :Optional[int] = a[i - 1], a[left_index]
return i - 1
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
if left < right:
__UpperCamelCase :int = random.randint(SCREAMING_SNAKE_CASE , right - 1 )
__UpperCamelCase , __UpperCamelCase :List[str] = (
a[left],
a[pivot],
) # switches the pivot with the left most bound
__UpperCamelCase :Dict = partition(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
quick_sort_random(
SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ) # recursive quicksort to the left of the pivot point
quick_sort_random(
SCREAMING_SNAKE_CASE , pivot_index + 1 , SCREAMING_SNAKE_CASE ) # recursive quicksort to the right of the pivot point
def lowerCamelCase ( ):
'''simple docstring'''
__UpperCamelCase :Tuple = input('''Enter numbers separated by a comma:\n''' ).strip()
__UpperCamelCase :Union[str, Any] = [int(SCREAMING_SNAKE_CASE ) for item in user_input.split(''',''' )]
quick_sort_random(SCREAMING_SNAKE_CASE , 0 , len(SCREAMING_SNAKE_CASE ) )
print(SCREAMING_SNAKE_CASE )
if __name__ == "__main__":
main()
| 43
| 1
|
# Algorithm for the pigeonhole sorting
def lowerCamelCase ( SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Optional[Any] = min(SCREAMING_SNAKE_CASE ) # min() finds the minimum value
__UpperCamelCase :List[Any] = max(SCREAMING_SNAKE_CASE ) # max() finds the maximum value
__UpperCamelCase :List[Any] = max_val - min_val + 1 # size is difference of max and min values plus one
# list of pigeonholes of size equal to the variable size
__UpperCamelCase :List[Any] = [0] * size
# Populate the pigeonholes.
for x in a:
assert isinstance(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ), "integers only please"
holes[x - min_val] += 1
# Putting the elements back into the array in an order.
__UpperCamelCase :Optional[Any] = 0
for count in range(SCREAMING_SNAKE_CASE ):
while holes[count] > 0:
holes[count] -= 1
__UpperCamelCase :int = count + min_val
i += 1
def lowerCamelCase ( ):
'''simple docstring'''
__UpperCamelCase :Optional[Any] = [8, 3, 2, 7, 4, 6, 8]
pigeonhole_sort(SCREAMING_SNAKE_CASE )
print('''Sorted order is:''' , ''' '''.join(SCREAMING_SNAKE_CASE ) )
if __name__ == "__main__":
main()
| 43
|
def lowerCamelCase ( SCREAMING_SNAKE_CASE = 1 , SCREAMING_SNAKE_CASE = 1_000 ):
'''simple docstring'''
__UpperCamelCase :Union[str, Any] = 1
__UpperCamelCase :Any = 0
for divide_by_number in range(SCREAMING_SNAKE_CASE , digit + 1 ):
__UpperCamelCase :list[int] = []
__UpperCamelCase :Optional[int] = numerator
for _ in range(1 , digit + 1 ):
if now_divide in has_been_divided:
if longest_list_length < len(SCREAMING_SNAKE_CASE ):
__UpperCamelCase :Optional[Any] = len(SCREAMING_SNAKE_CASE )
__UpperCamelCase :int = divide_by_number
else:
has_been_divided.append(SCREAMING_SNAKE_CASE )
__UpperCamelCase :Any = now_divide * 10 % divide_by_number
return the_digit
# Tests
if __name__ == "__main__":
import doctest
doctest.testmod()
| 43
| 1
|
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 lowerCamelCase_ ( UpperCAmelCase_ ):
'''simple docstring'''
a__ : Any = ["""image_processor""", """tokenizer"""]
a__ : Optional[Any] = """ViltImageProcessor"""
a__ : Optional[int] = ("""BertTokenizer""", """BertTokenizerFast""")
def __init__( self , __lowercase=None , __lowercase=None , **__lowercase) -> List[str]:
__UpperCamelCase :Union[str, Any] = None
if "feature_extractor" in kwargs:
warnings.warn(
'''The `feature_extractor` argument is deprecated and will be removed in v5, use `image_processor`'''
''' instead.''' , __lowercase , )
__UpperCamelCase :Tuple = kwargs.pop('''feature_extractor''')
__UpperCamelCase :Any = 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__(__lowercase , __lowercase)
__UpperCamelCase :Optional[Any] = self.image_processor
def __call__( self , __lowercase , __lowercase = None , __lowercase = True , __lowercase = False , __lowercase = None , __lowercase = None , __lowercase = 0 , __lowercase = None , __lowercase = None , __lowercase = None , __lowercase = False , __lowercase = False , __lowercase = False , __lowercase = False , __lowercase = True , __lowercase = None , **__lowercase , ) -> BatchEncoding:
__UpperCamelCase :Tuple = self.tokenizer(
text=__lowercase , add_special_tokens=__lowercase , padding=__lowercase , truncation=__lowercase , max_length=__lowercase , stride=__lowercase , pad_to_multiple_of=__lowercase , return_token_type_ids=__lowercase , return_attention_mask=__lowercase , return_overflowing_tokens=__lowercase , return_special_tokens_mask=__lowercase , return_offsets_mapping=__lowercase , return_length=__lowercase , verbose=__lowercase , return_tensors=__lowercase , **__lowercase , )
# add pixel_values + pixel_mask
__UpperCamelCase :str = self.image_processor(__lowercase , return_tensors=__lowercase)
encoding.update(__lowercase)
return encoding
def UpperCamelCase__ ( self , *__lowercase , **__lowercase) -> str:
return self.tokenizer.batch_decode(*__lowercase , **__lowercase)
def UpperCamelCase__ ( self , *__lowercase , **__lowercase) -> Optional[int]:
return self.tokenizer.decode(*__lowercase , **__lowercase)
@property
def UpperCamelCase__ ( self) -> List[str]:
__UpperCamelCase :int = self.tokenizer.model_input_names
__UpperCamelCase :int = self.image_processor.model_input_names
return list(dict.fromkeys(tokenizer_input_names + image_processor_input_names))
@property
def UpperCamelCase__ ( self) -> Union[str, Any]:
warnings.warn(
'''`feature_extractor_class` is deprecated and will be removed in v5. Use `image_processor_class` instead.''' , __lowercase , )
return self.image_processor_class
@property
def UpperCamelCase__ ( self) -> List[Any]:
warnings.warn(
'''`feature_extractor` is deprecated and will be removed in v5. Use `image_processor` instead.''' , __lowercase , )
return self.image_processor
| 43
|
import argparse
import json
from tqdm import tqdm
def lowerCamelCase ( ):
'''simple docstring'''
__UpperCamelCase :Tuple = argparse.ArgumentParser()
# Required parameters
parser.add_argument(
'''--src_path''' , type=SCREAMING_SNAKE_CASE , default='''biencoder-nq-dev.json''' , help='''Path to raw DPR training data''' , )
parser.add_argument(
'''--evaluation_set''' , type=SCREAMING_SNAKE_CASE , help='''where to store parsed evaluation_set file''' , )
parser.add_argument(
'''--gold_data_path''' , type=SCREAMING_SNAKE_CASE , help='''where to store parsed gold_data_path file''' , )
__UpperCamelCase :str = parser.parse_args()
with open(args.src_path , '''r''' ) as src_file, open(args.evaluation_set , '''w''' ) as eval_file, open(
args.gold_data_path , '''w''' ) as gold_file:
__UpperCamelCase :List[str] = json.load(SCREAMING_SNAKE_CASE )
for dpr_record in tqdm(SCREAMING_SNAKE_CASE ):
__UpperCamelCase :List[str] = dpr_record['''question''']
__UpperCamelCase :Tuple = [context['''title'''] for context in dpr_record['''positive_ctxs''']]
eval_file.write(question + '''\n''' )
gold_file.write('''\t'''.join(SCREAMING_SNAKE_CASE ) + '''\n''' )
if __name__ == "__main__":
main()
| 43
| 1
|
import argparse
import json
import logging
import os
import shutil
import sys
import tempfile
import unittest
from unittest import mock
import torch
from accelerate.utils import write_basic_config
from transformers.testing_utils import TestCasePlus, get_gpu_count, run_command, slow, torch_device
from transformers.utils import is_apex_available
logging.basicConfig(level=logging.DEBUG)
__lowercase = logging.getLogger()
def lowerCamelCase ( ):
'''simple docstring'''
__UpperCamelCase :List[Any] = argparse.ArgumentParser()
parser.add_argument('''-f''' )
__UpperCamelCase :Any = parser.parse_args()
return args.f
def lowerCamelCase ( SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Union[str, Any] = {}
__UpperCamelCase :str = os.path.join(SCREAMING_SNAKE_CASE , '''all_results.json''' )
if os.path.exists(SCREAMING_SNAKE_CASE ):
with open(SCREAMING_SNAKE_CASE , '''r''' ) as f:
__UpperCamelCase :Optional[Any] = json.load(SCREAMING_SNAKE_CASE )
else:
raise ValueError(f"""can't find {path}""" )
return results
def lowerCamelCase ( ):
'''simple docstring'''
__UpperCamelCase :Optional[Any] = torch.cuda.is_available() and torch_device == '''cuda'''
return is_using_cuda and is_apex_available()
__lowercase = logging.StreamHandler(sys.stdout)
logger.addHandler(stream_handler)
class lowerCamelCase_ ( UpperCAmelCase_ ):
'''simple docstring'''
@classmethod
def UpperCamelCase__ ( cls) -> int:
# Write Accelerate config, will pick up on CPU, GPU, and multi-GPU
__UpperCamelCase :List[Any] = tempfile.mkdtemp()
__UpperCamelCase :List[Any] = os.path.join(cls.tmpdir , '''default_config.yml''')
write_basic_config(save_location=cls.configPath)
__UpperCamelCase :int = ['''accelerate''', '''launch''', '''--config_file''', cls.configPath]
@classmethod
def UpperCamelCase__ ( cls) -> Union[str, Any]:
shutil.rmtree(cls.tmpdir)
@mock.patch.dict(os.environ , {'''WANDB_MODE''': '''offline'''})
def UpperCamelCase__ ( self) -> Union[str, Any]:
__UpperCamelCase :List[str] = self.get_auto_remove_tmp_dir()
__UpperCamelCase :Any = f"""
{self.examples_dir}/pytorch/text-classification/run_glue_no_trainer.py
--model_name_or_path distilbert-base-uncased
--output_dir {tmp_dir}
--train_file ./tests/fixtures/tests_samples/MRPC/train.csv
--validation_file ./tests/fixtures/tests_samples/MRPC/dev.csv
--per_device_train_batch_size=2
--per_device_eval_batch_size=1
--learning_rate=1e-4
--seed=42
--checkpointing_steps epoch
--with_tracking
""".split()
if is_cuda_and_apex_available():
testargs.append('''--fp16''')
run_command(self._launch_args + testargs)
__UpperCamelCase :Optional[Any] = get_results(__lowercase)
self.assertGreaterEqual(result['''eval_accuracy'''] , 0.75)
self.assertTrue(os.path.exists(os.path.join(__lowercase , '''epoch_0''')))
self.assertTrue(os.path.exists(os.path.join(__lowercase , '''glue_no_trainer''')))
@mock.patch.dict(os.environ , {'''WANDB_MODE''': '''offline'''})
def UpperCamelCase__ ( self) -> int:
__UpperCamelCase :Any = self.get_auto_remove_tmp_dir()
__UpperCamelCase :List[str] = f"""
{self.examples_dir}/pytorch/language-modeling/run_clm_no_trainer.py
--model_name_or_path distilgpt2
--train_file ./tests/fixtures/sample_text.txt
--validation_file ./tests/fixtures/sample_text.txt
--block_size 128
--per_device_train_batch_size 5
--per_device_eval_batch_size 5
--num_train_epochs 2
--output_dir {tmp_dir}
--checkpointing_steps epoch
--with_tracking
""".split()
if torch.cuda.device_count() > 1:
# Skipping because there are not enough batches to train the model + would need a drop_last to work.
return
run_command(self._launch_args + testargs)
__UpperCamelCase :Dict = get_results(__lowercase)
self.assertLess(result['''perplexity'''] , 100)
self.assertTrue(os.path.exists(os.path.join(__lowercase , '''epoch_0''')))
self.assertTrue(os.path.exists(os.path.join(__lowercase , '''clm_no_trainer''')))
@mock.patch.dict(os.environ , {'''WANDB_MODE''': '''offline'''})
def UpperCamelCase__ ( self) -> Any:
__UpperCamelCase :List[Any] = self.get_auto_remove_tmp_dir()
__UpperCamelCase :List[Any] = f"""
{self.examples_dir}/pytorch/language-modeling/run_mlm_no_trainer.py
--model_name_or_path distilroberta-base
--train_file ./tests/fixtures/sample_text.txt
--validation_file ./tests/fixtures/sample_text.txt
--output_dir {tmp_dir}
--num_train_epochs=1
--checkpointing_steps epoch
--with_tracking
""".split()
run_command(self._launch_args + testargs)
__UpperCamelCase :Union[str, Any] = get_results(__lowercase)
self.assertLess(result['''perplexity'''] , 42)
self.assertTrue(os.path.exists(os.path.join(__lowercase , '''epoch_0''')))
self.assertTrue(os.path.exists(os.path.join(__lowercase , '''mlm_no_trainer''')))
@mock.patch.dict(os.environ , {'''WANDB_MODE''': '''offline'''})
def UpperCamelCase__ ( self) -> Tuple:
# with so little data distributed training needs more epochs to get the score on par with 0/1 gpu
__UpperCamelCase :Union[str, Any] = 7 if get_gpu_count() > 1 else 2
__UpperCamelCase :List[Any] = self.get_auto_remove_tmp_dir()
__UpperCamelCase :List[Any] = f"""
{self.examples_dir}/pytorch/token-classification/run_ner_no_trainer.py
--model_name_or_path bert-base-uncased
--train_file tests/fixtures/tests_samples/conll/sample.json
--validation_file tests/fixtures/tests_samples/conll/sample.json
--output_dir {tmp_dir}
--learning_rate=2e-4
--per_device_train_batch_size=2
--per_device_eval_batch_size=2
--num_train_epochs={epochs}
--seed 7
--checkpointing_steps epoch
--with_tracking
""".split()
run_command(self._launch_args + testargs)
__UpperCamelCase :Optional[Any] = get_results(__lowercase)
self.assertGreaterEqual(result['''eval_accuracy'''] , 0.75)
self.assertLess(result['''train_loss'''] , 0.5)
self.assertTrue(os.path.exists(os.path.join(__lowercase , '''epoch_0''')))
self.assertTrue(os.path.exists(os.path.join(__lowercase , '''ner_no_trainer''')))
@unittest.skip(reason='''Fix me @muellerzr''')
@mock.patch.dict(os.environ , {'''WANDB_MODE''': '''offline'''})
def UpperCamelCase__ ( self) -> Union[str, Any]:
__UpperCamelCase :Union[str, Any] = self.get_auto_remove_tmp_dir()
__UpperCamelCase :int = f"""
{self.examples_dir}/pytorch/question-answering/run_qa_no_trainer.py
--model_name_or_path bert-base-uncased
--version_2_with_negative
--train_file tests/fixtures/tests_samples/SQUAD/sample.json
--validation_file tests/fixtures/tests_samples/SQUAD/sample.json
--output_dir {tmp_dir}
--seed=42
--max_train_steps=10
--num_warmup_steps=2
--learning_rate=2e-4
--per_device_train_batch_size=2
--per_device_eval_batch_size=1
--checkpointing_steps epoch
--with_tracking
""".split()
run_command(self._launch_args + testargs)
__UpperCamelCase :Any = get_results(__lowercase)
# Because we use --version_2_with_negative the testing script uses SQuAD v2 metrics.
self.assertGreaterEqual(result['''eval_f1'''] , 28)
self.assertGreaterEqual(result['''eval_exact'''] , 28)
self.assertTrue(os.path.exists(os.path.join(__lowercase , '''epoch_0''')))
self.assertTrue(os.path.exists(os.path.join(__lowercase , '''qa_no_trainer''')))
@mock.patch.dict(os.environ , {'''WANDB_MODE''': '''offline'''})
def UpperCamelCase__ ( self) -> Union[str, Any]:
__UpperCamelCase :int = self.get_auto_remove_tmp_dir()
__UpperCamelCase :int = f"""
{self.examples_dir}/pytorch/multiple-choice/run_swag_no_trainer.py
--model_name_or_path bert-base-uncased
--train_file tests/fixtures/tests_samples/swag/sample.json
--validation_file tests/fixtures/tests_samples/swag/sample.json
--output_dir {tmp_dir}
--max_train_steps=20
--num_warmup_steps=2
--learning_rate=2e-4
--per_device_train_batch_size=2
--per_device_eval_batch_size=1
--with_tracking
""".split()
run_command(self._launch_args + testargs)
__UpperCamelCase :Dict = get_results(__lowercase)
self.assertGreaterEqual(result['''eval_accuracy'''] , 0.8)
self.assertTrue(os.path.exists(os.path.join(__lowercase , '''swag_no_trainer''')))
@slow
@mock.patch.dict(os.environ , {'''WANDB_MODE''': '''offline'''})
def UpperCamelCase__ ( self) -> str:
__UpperCamelCase :str = self.get_auto_remove_tmp_dir()
__UpperCamelCase :Dict = f"""
{self.examples_dir}/pytorch/summarization/run_summarization_no_trainer.py
--model_name_or_path t5-small
--train_file tests/fixtures/tests_samples/xsum/sample.json
--validation_file tests/fixtures/tests_samples/xsum/sample.json
--output_dir {tmp_dir}
--max_train_steps=50
--num_warmup_steps=8
--learning_rate=2e-4
--per_device_train_batch_size=2
--per_device_eval_batch_size=1
--checkpointing_steps epoch
--with_tracking
""".split()
run_command(self._launch_args + testargs)
__UpperCamelCase :Tuple = get_results(__lowercase)
self.assertGreaterEqual(result['''eval_rouge1'''] , 10)
self.assertGreaterEqual(result['''eval_rouge2'''] , 2)
self.assertGreaterEqual(result['''eval_rougeL'''] , 7)
self.assertGreaterEqual(result['''eval_rougeLsum'''] , 7)
self.assertTrue(os.path.exists(os.path.join(__lowercase , '''epoch_0''')))
self.assertTrue(os.path.exists(os.path.join(__lowercase , '''summarization_no_trainer''')))
@slow
@mock.patch.dict(os.environ , {'''WANDB_MODE''': '''offline'''})
def UpperCamelCase__ ( self) -> str:
__UpperCamelCase :Optional[int] = self.get_auto_remove_tmp_dir()
__UpperCamelCase :Dict = f"""
{self.examples_dir}/pytorch/translation/run_translation_no_trainer.py
--model_name_or_path sshleifer/student_marian_en_ro_6_1
--source_lang en
--target_lang ro
--train_file tests/fixtures/tests_samples/wmt16/sample.json
--validation_file tests/fixtures/tests_samples/wmt16/sample.json
--output_dir {tmp_dir}
--max_train_steps=50
--num_warmup_steps=8
--num_beams=6
--learning_rate=3e-3
--per_device_train_batch_size=2
--per_device_eval_batch_size=1
--source_lang en_XX
--target_lang ro_RO
--checkpointing_steps epoch
--with_tracking
""".split()
run_command(self._launch_args + testargs)
__UpperCamelCase :Optional[int] = get_results(__lowercase)
self.assertGreaterEqual(result['''eval_bleu'''] , 30)
self.assertTrue(os.path.exists(os.path.join(__lowercase , '''epoch_0''')))
self.assertTrue(os.path.exists(os.path.join(__lowercase , '''translation_no_trainer''')))
@slow
def UpperCamelCase__ ( self) -> Tuple:
__UpperCamelCase :Tuple = logging.StreamHandler(sys.stdout)
logger.addHandler(__lowercase)
__UpperCamelCase :int = self.get_auto_remove_tmp_dir()
__UpperCamelCase :Any = f"""
{self.examples_dir}/pytorch/semantic-segmentation/run_semantic_segmentation_no_trainer.py
--dataset_name huggingface/semantic-segmentation-test-sample
--output_dir {tmp_dir}
--max_train_steps=10
--num_warmup_steps=2
--learning_rate=2e-4
--per_device_train_batch_size=2
--per_device_eval_batch_size=1
--checkpointing_steps epoch
""".split()
run_command(self._launch_args + testargs)
__UpperCamelCase :List[str] = get_results(__lowercase)
self.assertGreaterEqual(result['''eval_overall_accuracy'''] , 0.10)
@mock.patch.dict(os.environ , {'''WANDB_MODE''': '''offline'''})
def UpperCamelCase__ ( self) -> Optional[int]:
__UpperCamelCase :Union[str, Any] = self.get_auto_remove_tmp_dir()
__UpperCamelCase :Optional[Any] = f"""
{self.examples_dir}/pytorch/image-classification/run_image_classification_no_trainer.py
--model_name_or_path google/vit-base-patch16-224-in21k
--dataset_name hf-internal-testing/cats_vs_dogs_sample
--learning_rate 1e-4
--per_device_train_batch_size 2
--per_device_eval_batch_size 1
--max_train_steps 2
--train_val_split 0.1
--seed 42
--output_dir {tmp_dir}
--with_tracking
--checkpointing_steps 1
""".split()
if is_cuda_and_apex_available():
testargs.append('''--fp16''')
run_command(self._launch_args + testargs)
__UpperCamelCase :Optional[Any] = get_results(__lowercase)
# The base model scores a 25%
self.assertGreaterEqual(result['''eval_accuracy'''] , 0.6)
self.assertTrue(os.path.exists(os.path.join(__lowercase , '''step_1''')))
self.assertTrue(os.path.exists(os.path.join(__lowercase , '''image_classification_no_trainer''')))
| 43
|
from __future__ import annotations
import random
# Maximum size of the population. Bigger could be faster but is more memory expensive.
__lowercase = 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.
__lowercase = 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.
__lowercase = 0.4
# Just a seed to improve randomness required by the algorithm.
random.seed(random.randint(0, 1000))
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Any = len([g for position, g in enumerate(SCREAMING_SNAKE_CASE ) if g == main_target[position]] )
return (item, float(SCREAMING_SNAKE_CASE ))
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Optional[Any] = random.randint(0 , len(SCREAMING_SNAKE_CASE ) - 1 )
__UpperCamelCase :Tuple = parent_a[:random_slice] + parent_a[random_slice:]
__UpperCamelCase :Union[str, Any] = parent_a[:random_slice] + parent_a[random_slice:]
return (child_a, child_a)
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :int = list(SCREAMING_SNAKE_CASE )
if random.uniform(0 , 1 ) < MUTATION_PROBABILITY:
__UpperCamelCase :str = random.choice(SCREAMING_SNAKE_CASE )
return "".join(SCREAMING_SNAKE_CASE )
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , ):
'''simple docstring'''
__UpperCamelCase :int = []
# Generate more children proportionally to the fitness score.
__UpperCamelCase :int = int(parent_a[1] * 100 ) + 1
__UpperCamelCase :List[str] = 10 if child_n >= 10 else child_n
for _ in range(SCREAMING_SNAKE_CASE ):
__UpperCamelCase :Optional[Any] = population_score[random.randint(0 , SCREAMING_SNAKE_CASE )][0]
__UpperCamelCase , __UpperCamelCase :Any = crossover(parent_a[0] , SCREAMING_SNAKE_CASE )
# Append new string to the population list.
pop.append(mutate(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ) )
pop.append(mutate(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ) )
return pop
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE = True ):
'''simple docstring'''
if N_POPULATION < N_SELECTED:
__UpperCamelCase :List[Any] = f"""{N_POPULATION} must be bigger than {N_SELECTED}"""
raise ValueError(SCREAMING_SNAKE_CASE )
# Verify that the target contains no genes besides the ones inside genes variable.
__UpperCamelCase :List[str] = sorted({c for c in target if c not in genes} )
if not_in_genes_list:
__UpperCamelCase :Optional[int] = f"""{not_in_genes_list} is not in genes list, evolution cannot converge"""
raise ValueError(SCREAMING_SNAKE_CASE )
# Generate random starting population.
__UpperCamelCase :int = []
for _ in range(SCREAMING_SNAKE_CASE ):
population.append(''''''.join([random.choice(SCREAMING_SNAKE_CASE ) for i in range(len(SCREAMING_SNAKE_CASE ) )] ) )
# Just some logs to know what the algorithms is doing.
__UpperCamelCase , __UpperCamelCase :List[Any] = 0, 0
# This loop will end when we find a perfect match for our target.
while True:
generation += 1
total_population += len(SCREAMING_SNAKE_CASE )
# 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.
__UpperCamelCase :Tuple = [evaluate(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ) for item in population]
# Check if there is a matching evolution.
__UpperCamelCase :Tuple = sorted(SCREAMING_SNAKE_CASE , key=lambda SCREAMING_SNAKE_CASE : x[1] , reverse=SCREAMING_SNAKE_CASE )
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.
__UpperCamelCase :str = population[: int(N_POPULATION / 3 )]
population.clear()
population.extend(SCREAMING_SNAKE_CASE )
# Normalize population score to be between 0 and 1.
__UpperCamelCase :Union[str, Any] = [
(item, score / len(SCREAMING_SNAKE_CASE )) for item, score in population_score
]
# This is selection
for i in range(SCREAMING_SNAKE_CASE ):
population.extend(select(population_score[int(SCREAMING_SNAKE_CASE )] , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ) )
# 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(SCREAMING_SNAKE_CASE ) > N_POPULATION:
break
if __name__ == "__main__":
__lowercase = (
'''This is a genetic algorithm to evaluate, combine, evolve, and mutate a string!'''
)
__lowercase = list(
''' ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklm'''
'''nopqrstuvwxyz.,;!?+-*#@^\'èéòà€ù=)(&%$£/\\'''
)
__lowercase , __lowercase , __lowercase = basic(target_str, genes_list)
print(
F'\nGeneration: {generation}\nTotal Population: {population}\nTarget: {target}'
)
| 43
| 1
|
import unittest
from transformers import is_vision_available
from transformers.pipelines import pipeline
from transformers.testing_utils import (
is_pipeline_test,
nested_simplify,
require_tf,
require_torch,
require_vision,
slow,
)
from .test_pipelines_common import ANY
if is_vision_available():
from PIL import Image
else:
class lowerCamelCase_ :
'''simple docstring'''
@staticmethod
def UpperCamelCase__ ( *__lowercase , **__lowercase) -> List[str]:
pass
@is_pipeline_test
@require_vision
class lowerCamelCase_ ( unittest.TestCase ):
'''simple docstring'''
@require_torch
def UpperCamelCase__ ( self) -> str:
__UpperCamelCase :Union[str, Any] = pipeline(
model='''hf-internal-testing/tiny-random-clip-zero-shot-image-classification''' , )
__UpperCamelCase :Tuple = Image.open('''./tests/fixtures/tests_samples/COCO/000000039769.png''')
__UpperCamelCase :Optional[Any] = image_classifier(__lowercase , candidate_labels=['''a''', '''b''', '''c'''])
# The floating scores are so close, we enter floating error approximation and the order is not guaranteed across
# python and torch versions.
self.assertIn(
nested_simplify(__lowercase) , [
[{'''score''': 0.3_33, '''label''': '''a'''}, {'''score''': 0.3_33, '''label''': '''b'''}, {'''score''': 0.3_33, '''label''': '''c'''}],
[{'''score''': 0.3_33, '''label''': '''a'''}, {'''score''': 0.3_33, '''label''': '''c'''}, {'''score''': 0.3_33, '''label''': '''b'''}],
] , )
__UpperCamelCase :Any = image_classifier([image] * 5 , candidate_labels=['''A''', '''B''', '''C'''] , batch_size=2)
self.assertEqual(
nested_simplify(__lowercase) , [
[
{'''score''': 0.3_33, '''label''': ANY(__lowercase)},
{'''score''': 0.3_33, '''label''': ANY(__lowercase)},
{'''score''': 0.3_33, '''label''': ANY(__lowercase)},
],
[
{'''score''': 0.3_33, '''label''': ANY(__lowercase)},
{'''score''': 0.3_33, '''label''': ANY(__lowercase)},
{'''score''': 0.3_33, '''label''': ANY(__lowercase)},
],
[
{'''score''': 0.3_33, '''label''': ANY(__lowercase)},
{'''score''': 0.3_33, '''label''': ANY(__lowercase)},
{'''score''': 0.3_33, '''label''': ANY(__lowercase)},
],
[
{'''score''': 0.3_33, '''label''': ANY(__lowercase)},
{'''score''': 0.3_33, '''label''': ANY(__lowercase)},
{'''score''': 0.3_33, '''label''': ANY(__lowercase)},
],
[
{'''score''': 0.3_33, '''label''': ANY(__lowercase)},
{'''score''': 0.3_33, '''label''': ANY(__lowercase)},
{'''score''': 0.3_33, '''label''': ANY(__lowercase)},
],
] , )
@require_tf
def UpperCamelCase__ ( self) -> Optional[Any]:
__UpperCamelCase :Optional[Any] = pipeline(
model='''hf-internal-testing/tiny-random-clip-zero-shot-image-classification''' , framework='''tf''')
__UpperCamelCase :int = Image.open('''./tests/fixtures/tests_samples/COCO/000000039769.png''')
__UpperCamelCase :List[Any] = image_classifier(__lowercase , candidate_labels=['''a''', '''b''', '''c'''])
self.assertEqual(
nested_simplify(__lowercase) , [{'''score''': 0.3_33, '''label''': '''a'''}, {'''score''': 0.3_33, '''label''': '''b'''}, {'''score''': 0.3_33, '''label''': '''c'''}] , )
__UpperCamelCase :Any = image_classifier([image] * 5 , candidate_labels=['''A''', '''B''', '''C'''] , batch_size=2)
self.assertEqual(
nested_simplify(__lowercase) , [
[
{'''score''': 0.3_33, '''label''': ANY(__lowercase)},
{'''score''': 0.3_33, '''label''': ANY(__lowercase)},
{'''score''': 0.3_33, '''label''': ANY(__lowercase)},
],
[
{'''score''': 0.3_33, '''label''': ANY(__lowercase)},
{'''score''': 0.3_33, '''label''': ANY(__lowercase)},
{'''score''': 0.3_33, '''label''': ANY(__lowercase)},
],
[
{'''score''': 0.3_33, '''label''': ANY(__lowercase)},
{'''score''': 0.3_33, '''label''': ANY(__lowercase)},
{'''score''': 0.3_33, '''label''': ANY(__lowercase)},
],
[
{'''score''': 0.3_33, '''label''': ANY(__lowercase)},
{'''score''': 0.3_33, '''label''': ANY(__lowercase)},
{'''score''': 0.3_33, '''label''': ANY(__lowercase)},
],
[
{'''score''': 0.3_33, '''label''': ANY(__lowercase)},
{'''score''': 0.3_33, '''label''': ANY(__lowercase)},
{'''score''': 0.3_33, '''label''': ANY(__lowercase)},
],
] , )
@slow
@require_torch
def UpperCamelCase__ ( self) -> Optional[int]:
__UpperCamelCase :str = pipeline(
task='''zero-shot-image-classification''' , model='''openai/clip-vit-base-patch32''' , )
# This is an image of 2 cats with remotes and no planes
__UpperCamelCase :Optional[Any] = Image.open('''./tests/fixtures/tests_samples/COCO/000000039769.png''')
__UpperCamelCase :Optional[int] = image_classifier(__lowercase , candidate_labels=['''cat''', '''plane''', '''remote'''])
self.assertEqual(
nested_simplify(__lowercase) , [
{'''score''': 0.5_11, '''label''': '''remote'''},
{'''score''': 0.4_85, '''label''': '''cat'''},
{'''score''': 0.0_04, '''label''': '''plane'''},
] , )
__UpperCamelCase :int = image_classifier([image] * 5 , candidate_labels=['''cat''', '''plane''', '''remote'''] , batch_size=2)
self.assertEqual(
nested_simplify(__lowercase) , [
[
{'''score''': 0.5_11, '''label''': '''remote'''},
{'''score''': 0.4_85, '''label''': '''cat'''},
{'''score''': 0.0_04, '''label''': '''plane'''},
],
]
* 5 , )
@slow
@require_tf
def UpperCamelCase__ ( self) -> List[Any]:
__UpperCamelCase :List[str] = pipeline(
task='''zero-shot-image-classification''' , model='''openai/clip-vit-base-patch32''' , framework='''tf''')
# This is an image of 2 cats with remotes and no planes
__UpperCamelCase :str = Image.open('''./tests/fixtures/tests_samples/COCO/000000039769.png''')
__UpperCamelCase :Dict = image_classifier(__lowercase , candidate_labels=['''cat''', '''plane''', '''remote'''])
self.assertEqual(
nested_simplify(__lowercase) , [
{'''score''': 0.5_11, '''label''': '''remote'''},
{'''score''': 0.4_85, '''label''': '''cat'''},
{'''score''': 0.0_04, '''label''': '''plane'''},
] , )
__UpperCamelCase :List[str] = image_classifier([image] * 5 , candidate_labels=['''cat''', '''plane''', '''remote'''] , batch_size=2)
self.assertEqual(
nested_simplify(__lowercase) , [
[
{'''score''': 0.5_11, '''label''': '''remote'''},
{'''score''': 0.4_85, '''label''': '''cat'''},
{'''score''': 0.0_04, '''label''': '''plane'''},
],
]
* 5 , )
| 43
|
import argparse
import json
import os
import evaluate
import torch
from datasets import load_dataset
from torch.optim import AdamW
from torch.utils.data import DataLoader
from transformers import AutoModelForSequenceClassification, AutoTokenizer, get_linear_schedule_with_warmup, set_seed
from accelerate import Accelerator, DistributedType
from accelerate.utils.deepspeed import DummyOptim, DummyScheduler
__lowercase = 16
__lowercase = 32
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE = 16 , SCREAMING_SNAKE_CASE = "bert-base-cased" ):
'''simple docstring'''
__UpperCamelCase :List[str] = AutoTokenizer.from_pretrained(SCREAMING_SNAKE_CASE )
__UpperCamelCase :Any = load_dataset('''glue''' , '''mrpc''' )
def tokenize_function(SCREAMING_SNAKE_CASE ):
# max_length=None => use the model max length (it's actually the default)
__UpperCamelCase :int = tokenizer(examples['''sentence1'''] , examples['''sentence2'''] , truncation=SCREAMING_SNAKE_CASE , max_length=SCREAMING_SNAKE_CASE )
return outputs
# Apply the method we just defined to all the examples in all the splits of the dataset
__UpperCamelCase :Tuple = datasets.map(
SCREAMING_SNAKE_CASE , batched=SCREAMING_SNAKE_CASE , remove_columns=['''idx''', '''sentence1''', '''sentence2'''] , load_from_cache_file=SCREAMING_SNAKE_CASE )
# We also rename the 'label' column to 'labels' which is the expected name for labels by the models of the
# transformers library
__UpperCamelCase :List[str] = tokenized_datasets.rename_column('''label''' , '''labels''' )
def collate_fn(SCREAMING_SNAKE_CASE ):
# On TPU it's best to pad everything to the same length or training will be very slow.
if accelerator.distributed_type == DistributedType.TPU:
return tokenizer.pad(SCREAMING_SNAKE_CASE , padding='''max_length''' , max_length=128 , return_tensors='''pt''' )
return tokenizer.pad(SCREAMING_SNAKE_CASE , padding='''longest''' , return_tensors='''pt''' )
# Instantiate dataloaders.
__UpperCamelCase :Union[str, Any] = DataLoader(
tokenized_datasets['''train'''] , shuffle=SCREAMING_SNAKE_CASE , collate_fn=SCREAMING_SNAKE_CASE , batch_size=SCREAMING_SNAKE_CASE )
__UpperCamelCase :Dict = DataLoader(
tokenized_datasets['''validation'''] , shuffle=SCREAMING_SNAKE_CASE , collate_fn=SCREAMING_SNAKE_CASE , batch_size=SCREAMING_SNAKE_CASE )
return train_dataloader, eval_dataloader
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :List[Any] = Accelerator()
# Sample hyper-parameters for learning rate, batch size, seed and a few other HPs
__UpperCamelCase :int = config['''lr''']
__UpperCamelCase :str = int(config['''num_epochs'''] )
__UpperCamelCase :Any = int(config['''seed'''] )
__UpperCamelCase :Dict = int(config['''batch_size'''] )
__UpperCamelCase :Optional[Any] = args.model_name_or_path
set_seed(SCREAMING_SNAKE_CASE )
__UpperCamelCase , __UpperCamelCase :Dict = get_dataloaders(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
# Instantiate the model (we build the model here so that the seed also control new weights initialization)
__UpperCamelCase :Any = AutoModelForSequenceClassification.from_pretrained(SCREAMING_SNAKE_CASE , return_dict=SCREAMING_SNAKE_CASE )
# Instantiate optimizer
__UpperCamelCase :List[str] = (
AdamW
if accelerator.state.deepspeed_plugin is None
or '''optimizer''' not in accelerator.state.deepspeed_plugin.deepspeed_config
else DummyOptim
)
__UpperCamelCase :Optional[Any] = optimizer_cls(params=model.parameters() , lr=SCREAMING_SNAKE_CASE )
if accelerator.state.deepspeed_plugin is not None:
__UpperCamelCase :Dict = accelerator.state.deepspeed_plugin.deepspeed_config[
'''gradient_accumulation_steps'''
]
else:
__UpperCamelCase :Dict = 1
__UpperCamelCase :Tuple = (len(SCREAMING_SNAKE_CASE ) * num_epochs) // gradient_accumulation_steps
# Instantiate scheduler
if (
accelerator.state.deepspeed_plugin is None
or "scheduler" not in accelerator.state.deepspeed_plugin.deepspeed_config
):
__UpperCamelCase :str = get_linear_schedule_with_warmup(
optimizer=SCREAMING_SNAKE_CASE , num_warmup_steps=0 , num_training_steps=SCREAMING_SNAKE_CASE , )
else:
__UpperCamelCase :Dict = DummyScheduler(SCREAMING_SNAKE_CASE , total_num_steps=SCREAMING_SNAKE_CASE , warmup_num_steps=0 )
# Prepare everything
# There is no specific order to remember, we just need to unpack the objects in the same order we gave them to the
# prepare method.
__UpperCamelCase , __UpperCamelCase , __UpperCamelCase , __UpperCamelCase , __UpperCamelCase :int = accelerator.prepare(
SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
# We need to keep track of how many total steps we have iterated over
__UpperCamelCase :List[Any] = 0
# We also need to keep track of the stating epoch so files are named properly
__UpperCamelCase :Dict = 0
# Now we train the model
__UpperCamelCase :Any = evaluate.load('''glue''' , '''mrpc''' )
__UpperCamelCase :Union[str, Any] = 0
__UpperCamelCase :Optional[int] = {}
for epoch in range(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
model.train()
for step, batch in enumerate(SCREAMING_SNAKE_CASE ):
__UpperCamelCase :Optional[Any] = model(**SCREAMING_SNAKE_CASE )
__UpperCamelCase :Tuple = outputs.loss
__UpperCamelCase :str = loss / gradient_accumulation_steps
accelerator.backward(SCREAMING_SNAKE_CASE )
if step % gradient_accumulation_steps == 0:
optimizer.step()
lr_scheduler.step()
optimizer.zero_grad()
overall_step += 1
model.eval()
__UpperCamelCase :Any = 0
for step, batch in enumerate(SCREAMING_SNAKE_CASE ):
# We could avoid this line since we set the accelerator with `device_placement=True`.
batch.to(accelerator.device )
with torch.no_grad():
__UpperCamelCase :Any = model(**SCREAMING_SNAKE_CASE )
__UpperCamelCase :Optional[int] = outputs.logits.argmax(dim=-1 )
# It is slightly faster to call this once, than multiple times
__UpperCamelCase , __UpperCamelCase :List[Any] = accelerator.gather(
(predictions, batch['''labels''']) ) # If we are in a multiprocess environment, the last batch has duplicates
if accelerator.use_distributed:
if step == len(SCREAMING_SNAKE_CASE ) - 1:
__UpperCamelCase :List[str] = predictions[: len(eval_dataloader.dataset ) - samples_seen]
__UpperCamelCase :Optional[int] = references[: len(eval_dataloader.dataset ) - samples_seen]
else:
samples_seen += references.shape[0]
metric.add_batch(
predictions=SCREAMING_SNAKE_CASE , references=SCREAMING_SNAKE_CASE , )
__UpperCamelCase :Dict = metric.compute()
# Use accelerator.print to print only on the main process.
accelerator.print(f"""epoch {epoch}:""" , SCREAMING_SNAKE_CASE )
__UpperCamelCase :str = eval_metric['''accuracy''']
if best_performance < eval_metric["accuracy"]:
__UpperCamelCase :int = eval_metric['''accuracy''']
if args.performance_lower_bound is not None:
assert (
args.performance_lower_bound <= best_performance
), f"""Best performance metric {best_performance} is lower than the lower bound {args.performance_lower_bound}"""
accelerator.wait_for_everyone()
if accelerator.is_main_process:
with open(os.path.join(args.output_dir , '''all_results.json''' ) , '''w''' ) as f:
json.dump(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
def lowerCamelCase ( ):
'''simple docstring'''
__UpperCamelCase :Tuple = argparse.ArgumentParser(description='''Simple example of training script tracking peak GPU memory usage.''' )
parser.add_argument(
'''--model_name_or_path''' , type=SCREAMING_SNAKE_CASE , default='''bert-base-cased''' , help='''Path to pretrained model or model identifier from huggingface.co/models.''' , required=SCREAMING_SNAKE_CASE , )
parser.add_argument(
'''--output_dir''' , type=SCREAMING_SNAKE_CASE , default='''.''' , help='''Optional save directory where all checkpoint folders will be stored. Default is the current working directory.''' , )
parser.add_argument(
'''--performance_lower_bound''' , type=SCREAMING_SNAKE_CASE , default=SCREAMING_SNAKE_CASE , help='''Optional lower bound for the performance metric. If set, the training will throw error when the performance metric drops below this value.''' , )
parser.add_argument(
'''--num_epochs''' , type=SCREAMING_SNAKE_CASE , default=3 , help='''Number of train epochs.''' , )
__UpperCamelCase :List[str] = parser.parse_args()
__UpperCamelCase :Tuple = {'''lr''': 2e-5, '''num_epochs''': args.num_epochs, '''seed''': 42, '''batch_size''': 16}
training_function(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
if __name__ == "__main__":
main()
| 43
| 1
|
import argparse
import json
import pickle
from pathlib import Path
import requests
import torch
from huggingface_hub import hf_hub_download
from PIL import Image
from transformers import MaskFormerConfig, MaskFormerForInstanceSegmentation, MaskFormerImageProcessor, SwinConfig
from transformers.utils import logging
logging.set_verbosity_info()
__lowercase = logging.get_logger(__name__)
def lowerCamelCase ( SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :List[str] = SwinConfig.from_pretrained(
'''microsoft/swin-tiny-patch4-window7-224''' , out_features=['''stage1''', '''stage2''', '''stage3''', '''stage4'''] )
__UpperCamelCase :str = MaskFormerConfig(backbone_config=SCREAMING_SNAKE_CASE )
__UpperCamelCase :List[str] = '''huggingface/label-files'''
if "ade20k-full" in model_name:
# this should be ok
__UpperCamelCase :Union[str, Any] = 847
__UpperCamelCase :str = '''maskformer-ade20k-full-id2label.json'''
elif "ade" in model_name:
# this should be ok
__UpperCamelCase :List[Any] = 150
__UpperCamelCase :Union[str, Any] = '''ade20k-id2label.json'''
elif "coco-stuff" in model_name:
# this should be ok
__UpperCamelCase :str = 171
__UpperCamelCase :Optional[int] = '''maskformer-coco-stuff-id2label.json'''
elif "coco" in model_name:
# TODO
__UpperCamelCase :Optional[Any] = 133
__UpperCamelCase :Optional[Any] = '''coco-panoptic-id2label.json'''
elif "cityscapes" in model_name:
# this should be ok
__UpperCamelCase :Dict = 19
__UpperCamelCase :Tuple = '''cityscapes-id2label.json'''
elif "vistas" in model_name:
# this should be ok
__UpperCamelCase :Any = 65
__UpperCamelCase :Union[str, Any] = '''mapillary-vistas-id2label.json'''
__UpperCamelCase :List[Any] = json.load(open(hf_hub_download(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , repo_type='''dataset''' ) , '''r''' ) )
__UpperCamelCase :List[Any] = {int(SCREAMING_SNAKE_CASE ): v for k, v in idalabel.items()}
return config
def lowerCamelCase ( SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :int = []
# stem
# fmt: off
rename_keys.append(('''backbone.patch_embed.proj.weight''', '''model.pixel_level_module.encoder.model.embeddings.patch_embeddings.projection.weight''') )
rename_keys.append(('''backbone.patch_embed.proj.bias''', '''model.pixel_level_module.encoder.model.embeddings.patch_embeddings.projection.bias''') )
rename_keys.append(('''backbone.patch_embed.norm.weight''', '''model.pixel_level_module.encoder.model.embeddings.norm.weight''') )
rename_keys.append(('''backbone.patch_embed.norm.bias''', '''model.pixel_level_module.encoder.model.embeddings.norm.bias''') )
# stages
for i in range(len(config.backbone_config.depths ) ):
for j in range(config.backbone_config.depths[i] ):
rename_keys.append((f"""backbone.layers.{i}.blocks.{j}.norm1.weight""", f"""model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.layernorm_before.weight""") )
rename_keys.append((f"""backbone.layers.{i}.blocks.{j}.norm1.bias""", f"""model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.layernorm_before.bias""") )
rename_keys.append((f"""backbone.layers.{i}.blocks.{j}.attn.relative_position_bias_table""", f"""model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.attention.self.relative_position_bias_table""") )
rename_keys.append((f"""backbone.layers.{i}.blocks.{j}.attn.relative_position_index""", f"""model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.attention.self.relative_position_index""") )
rename_keys.append((f"""backbone.layers.{i}.blocks.{j}.attn.proj.weight""", f"""model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.attention.output.dense.weight""") )
rename_keys.append((f"""backbone.layers.{i}.blocks.{j}.attn.proj.bias""", f"""model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.attention.output.dense.bias""") )
rename_keys.append((f"""backbone.layers.{i}.blocks.{j}.norm2.weight""", f"""model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.layernorm_after.weight""") )
rename_keys.append((f"""backbone.layers.{i}.blocks.{j}.norm2.bias""", f"""model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.layernorm_after.bias""") )
rename_keys.append((f"""backbone.layers.{i}.blocks.{j}.mlp.fc1.weight""", f"""model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.intermediate.dense.weight""") )
rename_keys.append((f"""backbone.layers.{i}.blocks.{j}.mlp.fc1.bias""", f"""model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.intermediate.dense.bias""") )
rename_keys.append((f"""backbone.layers.{i}.blocks.{j}.mlp.fc2.weight""", f"""model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.output.dense.weight""") )
rename_keys.append((f"""backbone.layers.{i}.blocks.{j}.mlp.fc2.bias""", f"""model.pixel_level_module.encoder.model.encoder.layers.{i}.blocks.{j}.output.dense.bias""") )
if i < 3:
rename_keys.append((f"""backbone.layers.{i}.downsample.reduction.weight""", f"""model.pixel_level_module.encoder.model.encoder.layers.{i}.downsample.reduction.weight""") )
rename_keys.append((f"""backbone.layers.{i}.downsample.norm.weight""", f"""model.pixel_level_module.encoder.model.encoder.layers.{i}.downsample.norm.weight""") )
rename_keys.append((f"""backbone.layers.{i}.downsample.norm.bias""", f"""model.pixel_level_module.encoder.model.encoder.layers.{i}.downsample.norm.bias""") )
rename_keys.append((f"""backbone.norm{i}.weight""", f"""model.pixel_level_module.encoder.hidden_states_norms.{i}.weight""") )
rename_keys.append((f"""backbone.norm{i}.bias""", f"""model.pixel_level_module.encoder.hidden_states_norms.{i}.bias""") )
# FPN
rename_keys.append(('''sem_seg_head.layer_4.weight''', '''model.pixel_level_module.decoder.fpn.stem.0.weight''') )
rename_keys.append(('''sem_seg_head.layer_4.norm.weight''', '''model.pixel_level_module.decoder.fpn.stem.1.weight''') )
rename_keys.append(('''sem_seg_head.layer_4.norm.bias''', '''model.pixel_level_module.decoder.fpn.stem.1.bias''') )
for source_index, target_index in zip(range(3 , 0 , -1 ) , range(0 , 3 ) ):
rename_keys.append((f"""sem_seg_head.adapter_{source_index}.weight""", f"""model.pixel_level_module.decoder.fpn.layers.{target_index}.proj.0.weight""") )
rename_keys.append((f"""sem_seg_head.adapter_{source_index}.norm.weight""", f"""model.pixel_level_module.decoder.fpn.layers.{target_index}.proj.1.weight""") )
rename_keys.append((f"""sem_seg_head.adapter_{source_index}.norm.bias""", f"""model.pixel_level_module.decoder.fpn.layers.{target_index}.proj.1.bias""") )
rename_keys.append((f"""sem_seg_head.layer_{source_index}.weight""", f"""model.pixel_level_module.decoder.fpn.layers.{target_index}.block.0.weight""") )
rename_keys.append((f"""sem_seg_head.layer_{source_index}.norm.weight""", f"""model.pixel_level_module.decoder.fpn.layers.{target_index}.block.1.weight""") )
rename_keys.append((f"""sem_seg_head.layer_{source_index}.norm.bias""", f"""model.pixel_level_module.decoder.fpn.layers.{target_index}.block.1.bias""") )
rename_keys.append(('''sem_seg_head.mask_features.weight''', '''model.pixel_level_module.decoder.mask_projection.weight''') )
rename_keys.append(('''sem_seg_head.mask_features.bias''', '''model.pixel_level_module.decoder.mask_projection.bias''') )
# Transformer decoder
for idx in range(config.decoder_config.decoder_layers ):
# self-attention out projection
rename_keys.append((f"""sem_seg_head.predictor.transformer.decoder.layers.{idx}.self_attn.out_proj.weight""", f"""model.transformer_module.decoder.layers.{idx}.self_attn.out_proj.weight""") )
rename_keys.append((f"""sem_seg_head.predictor.transformer.decoder.layers.{idx}.self_attn.out_proj.bias""", f"""model.transformer_module.decoder.layers.{idx}.self_attn.out_proj.bias""") )
# cross-attention out projection
rename_keys.append((f"""sem_seg_head.predictor.transformer.decoder.layers.{idx}.multihead_attn.out_proj.weight""", f"""model.transformer_module.decoder.layers.{idx}.encoder_attn.out_proj.weight""") )
rename_keys.append((f"""sem_seg_head.predictor.transformer.decoder.layers.{idx}.multihead_attn.out_proj.bias""", f"""model.transformer_module.decoder.layers.{idx}.encoder_attn.out_proj.bias""") )
# MLP 1
rename_keys.append((f"""sem_seg_head.predictor.transformer.decoder.layers.{idx}.linear1.weight""", f"""model.transformer_module.decoder.layers.{idx}.fc1.weight""") )
rename_keys.append((f"""sem_seg_head.predictor.transformer.decoder.layers.{idx}.linear1.bias""", f"""model.transformer_module.decoder.layers.{idx}.fc1.bias""") )
# MLP 2
rename_keys.append((f"""sem_seg_head.predictor.transformer.decoder.layers.{idx}.linear2.weight""", f"""model.transformer_module.decoder.layers.{idx}.fc2.weight""") )
rename_keys.append((f"""sem_seg_head.predictor.transformer.decoder.layers.{idx}.linear2.bias""", f"""model.transformer_module.decoder.layers.{idx}.fc2.bias""") )
# layernorm 1 (self-attention layernorm)
rename_keys.append((f"""sem_seg_head.predictor.transformer.decoder.layers.{idx}.norm1.weight""", f"""model.transformer_module.decoder.layers.{idx}.self_attn_layer_norm.weight""") )
rename_keys.append((f"""sem_seg_head.predictor.transformer.decoder.layers.{idx}.norm1.bias""", f"""model.transformer_module.decoder.layers.{idx}.self_attn_layer_norm.bias""") )
# layernorm 2 (cross-attention layernorm)
rename_keys.append((f"""sem_seg_head.predictor.transformer.decoder.layers.{idx}.norm2.weight""", f"""model.transformer_module.decoder.layers.{idx}.encoder_attn_layer_norm.weight""") )
rename_keys.append((f"""sem_seg_head.predictor.transformer.decoder.layers.{idx}.norm2.bias""", f"""model.transformer_module.decoder.layers.{idx}.encoder_attn_layer_norm.bias""") )
# layernorm 3 (final layernorm)
rename_keys.append((f"""sem_seg_head.predictor.transformer.decoder.layers.{idx}.norm3.weight""", f"""model.transformer_module.decoder.layers.{idx}.final_layer_norm.weight""") )
rename_keys.append((f"""sem_seg_head.predictor.transformer.decoder.layers.{idx}.norm3.bias""", f"""model.transformer_module.decoder.layers.{idx}.final_layer_norm.bias""") )
rename_keys.append(('''sem_seg_head.predictor.transformer.decoder.norm.weight''', '''model.transformer_module.decoder.layernorm.weight''') )
rename_keys.append(('''sem_seg_head.predictor.transformer.decoder.norm.bias''', '''model.transformer_module.decoder.layernorm.bias''') )
# heads on top
rename_keys.append(('''sem_seg_head.predictor.query_embed.weight''', '''model.transformer_module.queries_embedder.weight''') )
rename_keys.append(('''sem_seg_head.predictor.input_proj.weight''', '''model.transformer_module.input_projection.weight''') )
rename_keys.append(('''sem_seg_head.predictor.input_proj.bias''', '''model.transformer_module.input_projection.bias''') )
rename_keys.append(('''sem_seg_head.predictor.class_embed.weight''', '''class_predictor.weight''') )
rename_keys.append(('''sem_seg_head.predictor.class_embed.bias''', '''class_predictor.bias''') )
for i in range(3 ):
rename_keys.append((f"""sem_seg_head.predictor.mask_embed.layers.{i}.weight""", f"""mask_embedder.{i}.0.weight""") )
rename_keys.append((f"""sem_seg_head.predictor.mask_embed.layers.{i}.bias""", f"""mask_embedder.{i}.0.bias""") )
# fmt: on
return rename_keys
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :List[str] = dct.pop(SCREAMING_SNAKE_CASE )
__UpperCamelCase :Dict = val
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :int = [int(backbone_config.embed_dim * 2**i ) for i in range(len(backbone_config.depths ) )]
for i in range(len(backbone_config.depths ) ):
__UpperCamelCase :int = num_features[i]
for j in range(backbone_config.depths[i] ):
# fmt: off
# read in weights + bias of input projection layer (in original implementation, this is a single matrix + bias)
__UpperCamelCase :Any = state_dict.pop(f"""backbone.layers.{i}.blocks.{j}.attn.qkv.weight""" )
__UpperCamelCase :List[Any] = state_dict.pop(f"""backbone.layers.{i}.blocks.{j}.attn.qkv.bias""" )
# next, add query, keys and values (in that order) to the state dict
__UpperCamelCase :int = in_proj_weight[:dim, :]
__UpperCamelCase :Union[str, Any] = in_proj_bias[: dim]
__UpperCamelCase :List[Any] = in_proj_weight[
dim : dim * 2, :
]
__UpperCamelCase :Union[str, Any] = in_proj_bias[
dim : dim * 2
]
__UpperCamelCase :Optional[Any] = in_proj_weight[
-dim :, :
]
__UpperCamelCase :Any = in_proj_bias[-dim :]
# fmt: on
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Dict = config.decoder_config.hidden_size
for idx in range(config.decoder_config.decoder_layers ):
# read in weights + bias of self-attention input projection layer (in the original implementation, this is a single matrix + bias)
__UpperCamelCase :Union[str, Any] = state_dict.pop(f"""sem_seg_head.predictor.transformer.decoder.layers.{idx}.self_attn.in_proj_weight""" )
__UpperCamelCase :Optional[int] = state_dict.pop(f"""sem_seg_head.predictor.transformer.decoder.layers.{idx}.self_attn.in_proj_bias""" )
# next, add query, keys and values (in that order) to the state dict
__UpperCamelCase :Optional[Any] = in_proj_weight[: hidden_size, :]
__UpperCamelCase :Tuple = in_proj_bias[:config.hidden_size]
__UpperCamelCase :Any = in_proj_weight[hidden_size : hidden_size * 2, :]
__UpperCamelCase :Dict = in_proj_bias[hidden_size : hidden_size * 2]
__UpperCamelCase :List[str] = in_proj_weight[-hidden_size :, :]
__UpperCamelCase :Optional[Any] = in_proj_bias[-hidden_size :]
# read in weights + bias of cross-attention input projection layer (in the original implementation, this is a single matrix + bias)
__UpperCamelCase :Dict = state_dict.pop(f"""sem_seg_head.predictor.transformer.decoder.layers.{idx}.multihead_attn.in_proj_weight""" )
__UpperCamelCase :Union[str, Any] = state_dict.pop(f"""sem_seg_head.predictor.transformer.decoder.layers.{idx}.multihead_attn.in_proj_bias""" )
# next, add query, keys and values (in that order) to the state dict
__UpperCamelCase :List[str] = in_proj_weight[: hidden_size, :]
__UpperCamelCase :str = in_proj_bias[:config.hidden_size]
__UpperCamelCase :Optional[int] = in_proj_weight[hidden_size : hidden_size * 2, :]
__UpperCamelCase :Union[str, Any] = in_proj_bias[hidden_size : hidden_size * 2]
__UpperCamelCase :Optional[Any] = in_proj_weight[-hidden_size :, :]
__UpperCamelCase :Optional[int] = in_proj_bias[-hidden_size :]
# fmt: on
def lowerCamelCase ( ):
'''simple docstring'''
__UpperCamelCase :Union[str, Any] = '''http://images.cocodataset.org/val2017/000000039769.jpg'''
__UpperCamelCase :List[str] = Image.open(requests.get(SCREAMING_SNAKE_CASE , stream=SCREAMING_SNAKE_CASE ).raw )
return im
@torch.no_grad()
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE = False ):
'''simple docstring'''
__UpperCamelCase :str = get_maskformer_config(SCREAMING_SNAKE_CASE )
# load original state_dict
with open(SCREAMING_SNAKE_CASE , '''rb''' ) as f:
__UpperCamelCase :str = pickle.load(SCREAMING_SNAKE_CASE )
__UpperCamelCase :int = data['''model''']
# for name, param in state_dict.items():
# print(name, param.shape)
# rename keys
__UpperCamelCase :Optional[Any] = create_rename_keys(SCREAMING_SNAKE_CASE )
for src, dest in rename_keys:
rename_key(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
read_in_swin_q_k_v(SCREAMING_SNAKE_CASE , config.backbone_config )
read_in_decoder_q_k_v(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
# update to torch tensors
for key, value in state_dict.items():
__UpperCamelCase :Dict = torch.from_numpy(SCREAMING_SNAKE_CASE )
# load 🤗 model
__UpperCamelCase :Optional[int] = MaskFormerForInstanceSegmentation(SCREAMING_SNAKE_CASE )
model.eval()
for name, param in model.named_parameters():
print(SCREAMING_SNAKE_CASE , param.shape )
__UpperCamelCase , __UpperCamelCase :Optional[int] = model.load_state_dict(SCREAMING_SNAKE_CASE , strict=SCREAMING_SNAKE_CASE )
assert missing_keys == [
"model.pixel_level_module.encoder.model.layernorm.weight",
"model.pixel_level_module.encoder.model.layernorm.bias",
]
assert len(SCREAMING_SNAKE_CASE ) == 0, f"""Unexpected keys: {unexpected_keys}"""
# verify results
__UpperCamelCase :Any = prepare_img()
if "vistas" in model_name:
__UpperCamelCase :Dict = 65
elif "cityscapes" in model_name:
__UpperCamelCase :int = 65_535
else:
__UpperCamelCase :Dict = 255
__UpperCamelCase :Union[str, Any] = True if '''ade''' in model_name else False
__UpperCamelCase :Tuple = MaskFormerImageProcessor(ignore_index=SCREAMING_SNAKE_CASE , reduce_labels=SCREAMING_SNAKE_CASE )
__UpperCamelCase :Union[str, Any] = image_processor(SCREAMING_SNAKE_CASE , return_tensors='''pt''' )
__UpperCamelCase :str = model(**SCREAMING_SNAKE_CASE )
print('''Logits:''' , outputs.class_queries_logits[0, :3, :3] )
if model_name == "maskformer-swin-tiny-ade":
__UpperCamelCase :List[Any] = torch.tensor(
[[3.6_353, -4.4_770, -2.6_065], [0.5_081, -4.2_394, -3.5_343], [2.1_909, -5.0_353, -1.9_323]] )
assert torch.allclose(outputs.class_queries_logits[0, :3, :3] , SCREAMING_SNAKE_CASE , atol=1e-4 )
print('''Looks ok!''' )
if pytorch_dump_folder_path is not None:
print(f"""Saving model and image processor to {pytorch_dump_folder_path}""" )
Path(SCREAMING_SNAKE_CASE ).mkdir(exist_ok=SCREAMING_SNAKE_CASE )
model.save_pretrained(SCREAMING_SNAKE_CASE )
image_processor.save_pretrained(SCREAMING_SNAKE_CASE )
if push_to_hub:
print('''Pushing model and image processor to the hub...''' )
model.push_to_hub(f"""nielsr/{model_name}""" )
image_processor.push_to_hub(f"""nielsr/{model_name}""" )
if __name__ == "__main__":
__lowercase = argparse.ArgumentParser()
# Required parameters
parser.add_argument(
'''--model_name''',
default='''maskformer-swin-tiny-ade''',
type=str,
help=('''Name of the MaskFormer model you\'d like to convert''',),
)
parser.add_argument(
'''--checkpoint_path''',
default='''/Users/nielsrogge/Documents/MaskFormer_checkpoints/MaskFormer-Swin-tiny-ADE20k/model.pkl''',
type=str,
help='''Path to the original state dict (.pth file).''',
)
parser.add_argument(
'''--pytorch_dump_folder_path''', default=None, type=str, help='''Path to the output PyTorch model directory.'''
)
parser.add_argument(
'''--push_to_hub''', action='''store_true''', help='''Whether or not to push the converted model to the 🤗 hub.'''
)
__lowercase = parser.parse_args()
convert_maskformer_checkpoint(
args.model_name, args.checkpoint_path, args.pytorch_dump_folder_path, args.push_to_hub
)
| 43
|
import copy
from ...configuration_utils import PretrainedConfig
from ...utils import logging
from ..auto import CONFIG_MAPPING
__lowercase = logging.get_logger(__name__)
__lowercase = {
'''SenseTime/deformable-detr''': '''https://huggingface.co/sensetime/deformable-detr/resolve/main/config.json''',
# See all Deformable DETR models at https://huggingface.co/models?filter=deformable-detr
}
class lowerCamelCase_ ( UpperCAmelCase_ ):
'''simple docstring'''
a__ : List[str] = """deformable_detr"""
a__ : Union[str, Any] = {
"""hidden_size""": """d_model""",
"""num_attention_heads""": """encoder_attention_heads""",
}
def __init__( self , __lowercase=True , __lowercase=None , __lowercase=3 , __lowercase=300 , __lowercase=1_024 , __lowercase=6 , __lowercase=1_024 , __lowercase=8 , __lowercase=6 , __lowercase=1_024 , __lowercase=8 , __lowercase=0.0 , __lowercase=True , __lowercase="relu" , __lowercase=256 , __lowercase=0.1 , __lowercase=0.0 , __lowercase=0.0 , __lowercase=0.02 , __lowercase=1.0 , __lowercase=True , __lowercase=False , __lowercase="sine" , __lowercase="resnet50" , __lowercase=True , __lowercase=False , __lowercase=4 , __lowercase=4 , __lowercase=4 , __lowercase=False , __lowercase=300 , __lowercase=False , __lowercase=1 , __lowercase=5 , __lowercase=2 , __lowercase=1 , __lowercase=1 , __lowercase=5 , __lowercase=2 , __lowercase=0.1 , __lowercase=0.25 , __lowercase=False , **__lowercase , ) -> int:
if backbone_config is not None and use_timm_backbone:
raise ValueError('''You can\'t specify both `backbone_config` and `use_timm_backbone`.''')
if not use_timm_backbone:
if backbone_config is None:
logger.info('''`backbone_config` is `None`. Initializing the config with the default `ResNet` backbone.''')
__UpperCamelCase :str = CONFIG_MAPPING['''resnet'''](out_features=['''stage4'''])
elif isinstance(__lowercase , __lowercase):
__UpperCamelCase :str = backbone_config.get('''model_type''')
__UpperCamelCase :Tuple = CONFIG_MAPPING[backbone_model_type]
__UpperCamelCase :Any = config_class.from_dict(__lowercase)
__UpperCamelCase :int = use_timm_backbone
__UpperCamelCase :Dict = backbone_config
__UpperCamelCase :Any = num_channels
__UpperCamelCase :Optional[int] = num_queries
__UpperCamelCase :Any = max_position_embeddings
__UpperCamelCase :str = d_model
__UpperCamelCase :Tuple = encoder_ffn_dim
__UpperCamelCase :Union[str, Any] = encoder_layers
__UpperCamelCase :List[Any] = encoder_attention_heads
__UpperCamelCase :Any = decoder_ffn_dim
__UpperCamelCase :List[str] = decoder_layers
__UpperCamelCase :int = decoder_attention_heads
__UpperCamelCase :str = dropout
__UpperCamelCase :Any = attention_dropout
__UpperCamelCase :int = activation_dropout
__UpperCamelCase :List[Any] = activation_function
__UpperCamelCase :List[Any] = init_std
__UpperCamelCase :List[Any] = init_xavier_std
__UpperCamelCase :int = encoder_layerdrop
__UpperCamelCase :str = auxiliary_loss
__UpperCamelCase :Optional[Any] = position_embedding_type
__UpperCamelCase :Union[str, Any] = backbone
__UpperCamelCase :Any = use_pretrained_backbone
__UpperCamelCase :str = dilation
# deformable attributes
__UpperCamelCase :Optional[Any] = num_feature_levels
__UpperCamelCase :str = encoder_n_points
__UpperCamelCase :int = decoder_n_points
__UpperCamelCase :Union[str, Any] = two_stage
__UpperCamelCase :Optional[Any] = two_stage_num_proposals
__UpperCamelCase :Dict = with_box_refine
if two_stage is True and with_box_refine is False:
raise ValueError('''If two_stage is True, with_box_refine must be True.''')
# Hungarian matcher
__UpperCamelCase :Optional[int] = class_cost
__UpperCamelCase :List[Any] = bbox_cost
__UpperCamelCase :str = giou_cost
# Loss coefficients
__UpperCamelCase :Tuple = mask_loss_coefficient
__UpperCamelCase :Tuple = dice_loss_coefficient
__UpperCamelCase :int = bbox_loss_coefficient
__UpperCamelCase :Any = giou_loss_coefficient
__UpperCamelCase :Dict = eos_coefficient
__UpperCamelCase :Optional[Any] = focal_alpha
__UpperCamelCase :Optional[Any] = disable_custom_kernels
super().__init__(is_encoder_decoder=__lowercase , **__lowercase)
@property
def UpperCamelCase__ ( self) -> int:
return self.encoder_attention_heads
@property
def UpperCamelCase__ ( self) -> int:
return self.d_model
def UpperCamelCase__ ( self) -> List[Any]:
__UpperCamelCase :Dict = copy.deepcopy(self.__dict__)
if self.backbone_config is not None:
__UpperCamelCase :Tuple = self.backbone_config.to_dict()
__UpperCamelCase :List[Any] = self.__class__.model_type
return output
| 43
| 1
|
import os
from shutil import copyfile
from typing import List, Optional, Tuple
from ...tokenization_utils import AddedToken
from ...tokenization_utils_fast import PreTrainedTokenizerFast
from ...utils import is_sentencepiece_available, logging
if is_sentencepiece_available():
from .tokenization_rembert import RemBertTokenizer
else:
__lowercase = None
__lowercase = logging.get_logger(__name__)
__lowercase = {'''vocab_file''': '''sentencepiece.model''', '''tokenizer_file''': '''tokenizer.json'''}
__lowercase = {
'''vocab_file''': {
'''google/rembert''': '''https://huggingface.co/google/rembert/resolve/main/sentencepiece.model''',
},
'''tokenizer_file''': {
'''google/rembert''': '''https://huggingface.co/google/rembert/resolve/main/tokenizer.json''',
},
}
__lowercase = {
'''google/rembert''': 256,
}
__lowercase = '''▁'''
class lowerCamelCase_ ( UpperCAmelCase_ ):
'''simple docstring'''
a__ : Union[str, Any] = VOCAB_FILES_NAMES
a__ : Union[str, Any] = PRETRAINED_VOCAB_FILES_MAP
a__ : str = PRETRAINED_POSITIONAL_EMBEDDINGS_SIZES
a__ : Optional[Any] = RemBertTokenizer
def __init__( self , __lowercase=None , __lowercase=None , __lowercase=True , __lowercase=True , __lowercase=False , __lowercase="[CLS]" , __lowercase="[SEP]" , __lowercase="<unk>" , __lowercase="[SEP]" , __lowercase="<pad>" , __lowercase="[CLS]" , __lowercase="[MASK]" , **__lowercase , ) -> Dict:
# Mask token behave like a normal word, i.e. include the space before it
__UpperCamelCase :int = AddedToken(__lowercase , lstrip=__lowercase , rstrip=__lowercase) if isinstance(__lowercase , __lowercase) else mask_token
super().__init__(
__lowercase , tokenizer_file=__lowercase , do_lower_case=__lowercase , remove_space=__lowercase , keep_accents=__lowercase , bos_token=__lowercase , eos_token=__lowercase , unk_token=__lowercase , sep_token=__lowercase , pad_token=__lowercase , cls_token=__lowercase , mask_token=__lowercase , **__lowercase , )
__UpperCamelCase :Dict = do_lower_case
__UpperCamelCase :List[Any] = remove_space
__UpperCamelCase :Tuple = keep_accents
__UpperCamelCase :Dict = vocab_file
__UpperCamelCase :List[str] = False if not self.vocab_file else True
def UpperCamelCase__ ( self , __lowercase , __lowercase = None) -> List[int]:
__UpperCamelCase :Dict = [self.sep_token_id]
__UpperCamelCase :int = [self.cls_token_id]
if token_ids_a is None:
return cls + token_ids_a + sep
return cls + token_ids_a + sep + token_ids_a + sep
def UpperCamelCase__ ( self , __lowercase , __lowercase = None , __lowercase = False) -> List[int]:
if already_has_special_tokens:
if token_ids_a is not None:
raise ValueError(
'''You should not supply a second sequence if the provided sequence of '''
'''ids is already formatted with special tokens for the model.''')
return [1 if x in [self.sep_token_id, self.cls_token_id] else 0 for x in token_ids_a]
if token_ids_a is not None:
return [1] + ([0] * len(__lowercase)) + [1] + ([0] * len(__lowercase)) + [1]
return [1] + ([0] * len(__lowercase)) + [1]
def UpperCamelCase__ ( self , __lowercase , __lowercase = None) -> List[int]:
__UpperCamelCase :Optional[Any] = [self.sep_token_id]
__UpperCamelCase :List[Any] = [self.cls_token_id]
if token_ids_a is None:
return len(cls + token_ids_a + sep) * [0]
return len(cls + token_ids_a + sep) * [0] + len(token_ids_a + sep) * [1]
def UpperCamelCase__ ( self , __lowercase , __lowercase = None) -> Tuple[str]:
if not os.path.isdir(__lowercase):
logger.error('''Vocabulary path ({}) should be a directory'''.format(__lowercase))
return
__UpperCamelCase :List[str] = os.path.join(
__lowercase , (filename_prefix + '''-''' if filename_prefix else '''''') + VOCAB_FILES_NAMES['''vocab_file'''])
if os.path.abspath(self.vocab_file) != os.path.abspath(__lowercase):
copyfile(self.vocab_file , __lowercase)
return (out_vocab_file,)
| 43
|
# Copyright 2023 The HuggingFace Inc. team. All rights reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
import torch
from ..models.auto import AutoModelForSequenceClassification, AutoTokenizer
from .base import PipelineTool
class lowerCamelCase_ ( UpperCAmelCase_ ):
'''simple docstring'''
a__ : Optional[Any] = """facebook/bart-large-mnli"""
a__ : int = (
"""This is a tool that classifies an English text using provided labels. It takes two inputs: `text`, which """
"""should be the text to classify, and `labels`, which should be the list of labels to use for classification. """
"""It returns the most likely label in the list of provided `labels` for the input text."""
)
a__ : Optional[Any] = """text_classifier"""
a__ : Any = AutoTokenizer
a__ : str = AutoModelForSequenceClassification
a__ : str = ["""text""", ["""text"""]]
a__ : Optional[int] = ["""text"""]
def UpperCamelCase__ ( self) -> Union[str, Any]:
super().setup()
__UpperCamelCase :int = self.model.config
__UpperCamelCase :Optional[Any] = -1
for idx, label in config.idalabel.items():
if label.lower().startswith('''entail'''):
__UpperCamelCase :List[Any] = int(__lowercase)
if self.entailment_id == -1:
raise ValueError('''Could not determine the entailment ID from the model config, please pass it at init.''')
def UpperCamelCase__ ( self , __lowercase , __lowercase) -> Union[str, Any]:
__UpperCamelCase :Any = labels
return self.pre_processor(
[text] * len(__lowercase) , [f"""This example is {label}""" for label in labels] , return_tensors='''pt''' , padding='''max_length''' , )
def UpperCamelCase__ ( self , __lowercase) -> Optional[Any]:
__UpperCamelCase :List[Any] = outputs.logits
__UpperCamelCase :Any = torch.argmax(logits[:, 2]).item()
return self._labels[label_id]
| 43
| 1
|
import json
import os
import shutil
import tempfile
import unittest
import numpy as np
from transformers import BertTokenizerFast
from transformers.models.bert.tokenization_bert import VOCAB_FILES_NAMES, BertTokenizer
from transformers.testing_utils import require_tokenizers, require_vision
from transformers.utils import IMAGE_PROCESSOR_NAME, is_vision_available
if is_vision_available():
from PIL import Image
from transformers import VisionTextDualEncoderProcessor, ViTImageProcessor
@require_tokenizers
@require_vision
class lowerCamelCase_ ( unittest.TestCase ):
'''simple docstring'''
def UpperCamelCase__ ( self) -> int:
__UpperCamelCase :List[str] = tempfile.mkdtemp()
# fmt: off
__UpperCamelCase :Any = ['''[UNK]''', '''[CLS]''', '''[SEP]''', '''[PAD]''', '''[MASK]''', '''want''', '''##want''', '''##ed''', '''wa''', '''un''', '''runn''', '''##ing''', ''',''', '''low''', '''lowest''']
# fmt: on
__UpperCamelCase :Union[str, Any] = os.path.join(self.tmpdirname , VOCAB_FILES_NAMES['''vocab_file'''])
with open(self.vocab_file , '''w''' , encoding='''utf-8''') as vocab_writer:
vocab_writer.write(''''''.join([x + '''\n''' for x in vocab_tokens]))
__UpperCamelCase :List[Any] = {
'''do_resize''': True,
'''size''': {'''height''': 18, '''width''': 18},
'''do_normalize''': True,
'''image_mean''': [0.5, 0.5, 0.5],
'''image_std''': [0.5, 0.5, 0.5],
}
__UpperCamelCase :List[str] = os.path.join(self.tmpdirname , __lowercase)
with open(self.image_processor_file , '''w''' , encoding='''utf-8''') as fp:
json.dump(__lowercase , __lowercase)
def UpperCamelCase__ ( self , **__lowercase) -> List[Any]:
return BertTokenizer.from_pretrained(self.tmpdirname , **__lowercase)
def UpperCamelCase__ ( self , **__lowercase) -> Any:
return ViTImageProcessor.from_pretrained(self.tmpdirname , **__lowercase)
def UpperCamelCase__ ( self) -> Dict:
shutil.rmtree(self.tmpdirname)
def UpperCamelCase__ ( self) -> Tuple:
__UpperCamelCase :List[Any] = [np.random.randint(255 , size=(3, 30, 400) , dtype=np.uinta)]
__UpperCamelCase :Any = [Image.fromarray(np.moveaxis(__lowercase , 0 , -1)) for x in image_inputs]
return image_inputs
def UpperCamelCase__ ( self) -> Tuple:
__UpperCamelCase :str = self.get_tokenizer()
__UpperCamelCase :List[str] = self.get_image_processor()
__UpperCamelCase :List[Any] = VisionTextDualEncoderProcessor(tokenizer=__lowercase , image_processor=__lowercase)
processor.save_pretrained(self.tmpdirname)
__UpperCamelCase :Any = VisionTextDualEncoderProcessor.from_pretrained(self.tmpdirname)
self.assertEqual(processor.tokenizer.get_vocab() , tokenizer.get_vocab())
self.assertIsInstance(processor.tokenizer , (BertTokenizer, BertTokenizerFast))
self.assertEqual(processor.image_processor.to_json_string() , image_processor.to_json_string())
self.assertIsInstance(processor.image_processor , __lowercase)
def UpperCamelCase__ ( self) -> Any:
__UpperCamelCase :List[Any] = VisionTextDualEncoderProcessor(
tokenizer=self.get_tokenizer() , image_processor=self.get_image_processor())
processor.save_pretrained(self.tmpdirname)
__UpperCamelCase :List[Any] = self.get_tokenizer(bos_token='''(BOS)''' , eos_token='''(EOS)''')
__UpperCamelCase :Any = self.get_image_processor(do_normalize=__lowercase , padding_value=1.0)
__UpperCamelCase :List[Any] = VisionTextDualEncoderProcessor.from_pretrained(
self.tmpdirname , bos_token='''(BOS)''' , eos_token='''(EOS)''' , do_normalize=__lowercase , padding_value=1.0)
self.assertEqual(processor.tokenizer.get_vocab() , tokenizer_add_kwargs.get_vocab())
self.assertIsInstance(processor.tokenizer , (BertTokenizer, BertTokenizerFast))
self.assertEqual(processor.image_processor.to_json_string() , image_processor_add_kwargs.to_json_string())
self.assertIsInstance(processor.image_processor , __lowercase)
def UpperCamelCase__ ( self) -> Optional[Any]:
__UpperCamelCase :Optional[Any] = self.get_image_processor()
__UpperCamelCase :Optional[Any] = self.get_tokenizer()
__UpperCamelCase :str = VisionTextDualEncoderProcessor(tokenizer=__lowercase , image_processor=__lowercase)
__UpperCamelCase :str = self.prepare_image_inputs()
__UpperCamelCase :Optional[int] = image_processor(__lowercase , return_tensors='''np''')
__UpperCamelCase :str = processor(images=__lowercase , return_tensors='''np''')
for key in input_feat_extract.keys():
self.assertAlmostEqual(input_feat_extract[key].sum() , input_processor[key].sum() , delta=1E-2)
def UpperCamelCase__ ( self) -> str:
__UpperCamelCase :List[Any] = self.get_image_processor()
__UpperCamelCase :List[Any] = self.get_tokenizer()
__UpperCamelCase :Any = VisionTextDualEncoderProcessor(tokenizer=__lowercase , image_processor=__lowercase)
__UpperCamelCase :Optional[Any] = '''lower newer'''
__UpperCamelCase :Optional[int] = processor(text=__lowercase)
__UpperCamelCase :Any = tokenizer(__lowercase)
for key in encoded_tok.keys():
self.assertListEqual(encoded_tok[key] , encoded_processor[key])
def UpperCamelCase__ ( self) -> Optional[int]:
__UpperCamelCase :str = self.get_image_processor()
__UpperCamelCase :int = self.get_tokenizer()
__UpperCamelCase :Any = VisionTextDualEncoderProcessor(tokenizer=__lowercase , image_processor=__lowercase)
__UpperCamelCase :Tuple = '''lower newer'''
__UpperCamelCase :Tuple = self.prepare_image_inputs()
__UpperCamelCase :Dict = processor(text=__lowercase , images=__lowercase)
self.assertListEqual(list(inputs.keys()) , ['''input_ids''', '''token_type_ids''', '''attention_mask''', '''pixel_values'''])
# test if it raises when no input is passed
with self.assertRaises(__lowercase):
processor()
def UpperCamelCase__ ( self) -> List[Any]:
__UpperCamelCase :Dict = self.get_image_processor()
__UpperCamelCase :Dict = self.get_tokenizer()
__UpperCamelCase :Optional[int] = VisionTextDualEncoderProcessor(tokenizer=__lowercase , image_processor=__lowercase)
__UpperCamelCase :Union[str, Any] = [[1, 4, 5, 8, 1, 0, 8], [3, 4, 3, 1, 1, 8, 9]]
__UpperCamelCase :Union[str, Any] = processor.batch_decode(__lowercase)
__UpperCamelCase :str = tokenizer.batch_decode(__lowercase)
self.assertListEqual(__lowercase , __lowercase)
def UpperCamelCase__ ( self) -> Any:
__UpperCamelCase :int = self.get_image_processor()
__UpperCamelCase :Tuple = self.get_tokenizer()
__UpperCamelCase :Optional[int] = VisionTextDualEncoderProcessor(tokenizer=__lowercase , image_processor=__lowercase)
__UpperCamelCase :Tuple = '''lower newer'''
__UpperCamelCase :Optional[int] = self.prepare_image_inputs()
__UpperCamelCase :Tuple = processor(text=__lowercase , images=__lowercase)
self.assertListEqual(list(inputs.keys()) , processor.model_input_names)
| 43
|
import gc
import random
import unittest
import numpy as np
import torch
from transformers import (
CLIPImageProcessor,
CLIPTextConfig,
CLIPTextModel,
CLIPTokenizer,
CLIPVisionConfig,
CLIPVisionModelWithProjection,
)
from diffusers import AutoencoderKL, DDIMScheduler, DDPMScheduler, StableUnCLIPImgaImgPipeline, UNetaDConditionModel
from diffusers.pipelines.pipeline_utils import DiffusionPipeline
from diffusers.pipelines.stable_diffusion.stable_unclip_image_normalizer import StableUnCLIPImageNormalizer
from diffusers.utils.import_utils import is_xformers_available
from diffusers.utils.testing_utils import (
enable_full_determinism,
floats_tensor,
load_image,
load_numpy,
require_torch_gpu,
skip_mps,
slow,
torch_device,
)
from ..pipeline_params import TEXT_GUIDED_IMAGE_VARIATION_BATCH_PARAMS, TEXT_GUIDED_IMAGE_VARIATION_PARAMS
from ..test_pipelines_common import (
PipelineKarrasSchedulerTesterMixin,
PipelineLatentTesterMixin,
PipelineTesterMixin,
assert_mean_pixel_difference,
)
enable_full_determinism()
class lowerCamelCase_ ( UpperCAmelCase_ , UpperCAmelCase_ , UpperCAmelCase_ , unittest.TestCase ):
'''simple docstring'''
a__ : int = StableUnCLIPImgaImgPipeline
a__ : Optional[int] = TEXT_GUIDED_IMAGE_VARIATION_PARAMS
a__ : Union[str, Any] = TEXT_GUIDED_IMAGE_VARIATION_BATCH_PARAMS
a__ : Optional[Any] = frozenset(
[] ) # TO-DO: update image_params once pipeline is refactored with VaeImageProcessor.preprocess
a__ : int = frozenset([] )
def UpperCamelCase__ ( self) -> Tuple:
__UpperCamelCase :Tuple = 32
__UpperCamelCase :Optional[int] = embedder_hidden_size
# image encoding components
__UpperCamelCase :Union[str, Any] = CLIPImageProcessor(crop_size=32 , size=32)
torch.manual_seed(0)
__UpperCamelCase :Union[str, Any] = CLIPVisionModelWithProjection(
CLIPVisionConfig(
hidden_size=__lowercase , projection_dim=__lowercase , num_hidden_layers=5 , num_attention_heads=4 , image_size=32 , intermediate_size=37 , patch_size=1 , ))
# regular denoising components
torch.manual_seed(0)
__UpperCamelCase :str = StableUnCLIPImageNormalizer(embedding_dim=__lowercase)
__UpperCamelCase :Optional[int] = DDPMScheduler(beta_schedule='''squaredcos_cap_v2''')
torch.manual_seed(0)
__UpperCamelCase :Union[str, Any] = CLIPTokenizer.from_pretrained('''hf-internal-testing/tiny-random-clip''')
torch.manual_seed(0)
__UpperCamelCase :Dict = CLIPTextModel(
CLIPTextConfig(
bos_token_id=0 , eos_token_id=2 , hidden_size=__lowercase , projection_dim=32 , intermediate_size=37 , layer_norm_eps=1E-0_5 , num_attention_heads=4 , num_hidden_layers=5 , pad_token_id=1 , vocab_size=1_000 , ))
torch.manual_seed(0)
__UpperCamelCase :List[Any] = UNetaDConditionModel(
sample_size=32 , in_channels=4 , out_channels=4 , down_block_types=('''CrossAttnDownBlock2D''', '''DownBlock2D''') , up_block_types=('''UpBlock2D''', '''CrossAttnUpBlock2D''') , block_out_channels=(32, 64) , attention_head_dim=(2, 4) , class_embed_type='''projection''' , projection_class_embeddings_input_dim=embedder_projection_dim * 2 , cross_attention_dim=__lowercase , layers_per_block=1 , upcast_attention=__lowercase , use_linear_projection=__lowercase , )
torch.manual_seed(0)
__UpperCamelCase :Tuple = DDIMScheduler(
beta_schedule='''scaled_linear''' , beta_start=0.0_00_85 , beta_end=0.0_12 , prediction_type='''v_prediction''' , set_alpha_to_one=__lowercase , steps_offset=1 , )
torch.manual_seed(0)
__UpperCamelCase :List[str] = AutoencoderKL()
__UpperCamelCase :Tuple = {
# image encoding components
'''feature_extractor''': feature_extractor,
'''image_encoder''': image_encoder.eval(),
# image noising components
'''image_normalizer''': image_normalizer.eval(),
'''image_noising_scheduler''': image_noising_scheduler,
# regular denoising components
'''tokenizer''': tokenizer,
'''text_encoder''': text_encoder.eval(),
'''unet''': unet.eval(),
'''scheduler''': scheduler,
'''vae''': vae.eval(),
}
return components
def UpperCamelCase__ ( self , __lowercase , __lowercase=0 , __lowercase=True) -> str:
if str(__lowercase).startswith('''mps'''):
__UpperCamelCase :Union[str, Any] = torch.manual_seed(__lowercase)
else:
__UpperCamelCase :int = torch.Generator(device=__lowercase).manual_seed(__lowercase)
__UpperCamelCase :int = floats_tensor((1, 3, 32, 32) , rng=random.Random(__lowercase)).to(__lowercase)
if pil_image:
__UpperCamelCase :List[Any] = input_image * 0.5 + 0.5
__UpperCamelCase :Optional[Any] = input_image.clamp(0 , 1)
__UpperCamelCase :int = input_image.cpu().permute(0 , 2 , 3 , 1).float().numpy()
__UpperCamelCase :Optional[Any] = DiffusionPipeline.numpy_to_pil(__lowercase)[0]
return {
"prompt": "An anime racoon running a marathon",
"image": input_image,
"generator": generator,
"num_inference_steps": 2,
"output_type": "np",
}
@skip_mps
def UpperCamelCase__ ( self) -> Union[str, Any]:
__UpperCamelCase :Dict = '''cpu''' # ensure determinism for the device-dependent torch.Generator
__UpperCamelCase :Tuple = self.get_dummy_components()
__UpperCamelCase :Any = StableUnCLIPImgaImgPipeline(**__lowercase)
__UpperCamelCase :Optional[Any] = sd_pipe.to(__lowercase)
sd_pipe.set_progress_bar_config(disable=__lowercase)
__UpperCamelCase :List[Any] = self.get_dummy_inputs(__lowercase)
inputs.update({'''image_embeds''': None})
__UpperCamelCase :Any = sd_pipe(**__lowercase).images
__UpperCamelCase :List[str] = image[0, -3:, -3:, -1]
assert image.shape == (1, 32, 32, 3)
__UpperCamelCase :List[Any] = np.array([0.38_72, 0.72_24, 0.56_01, 0.47_41, 0.68_72, 0.58_14, 0.46_36, 0.38_67, 0.50_78])
assert np.abs(image_slice.flatten() - expected_slice).max() < 1E-3
def UpperCamelCase__ ( self) -> str:
__UpperCamelCase :Optional[Any] = torch_device in ['''cpu''', '''mps''']
self._test_attention_slicing_forward_pass(test_max_difference=__lowercase)
def UpperCamelCase__ ( self) -> List[Any]:
__UpperCamelCase :Optional[Any] = torch_device in ['''cpu''', '''mps''']
self._test_inference_batch_single_identical(test_max_difference=__lowercase)
@unittest.skipIf(
torch_device != '''cuda''' or not is_xformers_available() , reason='''XFormers attention is only available with CUDA and `xformers` installed''' , )
def UpperCamelCase__ ( self) -> Union[str, Any]:
self._test_xformers_attention_forwardGenerator_pass(test_max_difference=__lowercase)
@slow
@require_torch_gpu
class lowerCamelCase_ ( unittest.TestCase ):
'''simple docstring'''
def UpperCamelCase__ ( self) -> Union[str, Any]:
# clean up the VRAM after each test
super().tearDown()
gc.collect()
torch.cuda.empty_cache()
def UpperCamelCase__ ( self) -> Union[str, Any]:
__UpperCamelCase :int = load_image(
'''https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main/stable_unclip/turtle.png''')
__UpperCamelCase :Any = load_numpy(
'''https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main/stable_unclip/stable_unclip_2_1_l_img2img_anime_turtle_fp16.npy''')
__UpperCamelCase :List[Any] = StableUnCLIPImgaImgPipeline.from_pretrained(
'''fusing/stable-unclip-2-1-l-img2img''' , torch_dtype=torch.floataa)
pipe.to(__lowercase)
pipe.set_progress_bar_config(disable=__lowercase)
# stable unclip will oom when integration tests are run on a V100,
# so turn on memory savings
pipe.enable_attention_slicing()
pipe.enable_sequential_cpu_offload()
__UpperCamelCase :int = torch.Generator(device='''cpu''').manual_seed(0)
__UpperCamelCase :Dict = pipe(__lowercase , '''anime turle''' , generator=__lowercase , output_type='''np''')
__UpperCamelCase :Dict = output.images[0]
assert image.shape == (768, 768, 3)
assert_mean_pixel_difference(__lowercase , __lowercase)
def UpperCamelCase__ ( self) -> List[str]:
__UpperCamelCase :Optional[Any] = load_image(
'''https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main/stable_unclip/turtle.png''')
__UpperCamelCase :Any = load_numpy(
'''https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main/stable_unclip/stable_unclip_2_1_h_img2img_anime_turtle_fp16.npy''')
__UpperCamelCase :Any = StableUnCLIPImgaImgPipeline.from_pretrained(
'''fusing/stable-unclip-2-1-h-img2img''' , torch_dtype=torch.floataa)
pipe.to(__lowercase)
pipe.set_progress_bar_config(disable=__lowercase)
# stable unclip will oom when integration tests are run on a V100,
# so turn on memory savings
pipe.enable_attention_slicing()
pipe.enable_sequential_cpu_offload()
__UpperCamelCase :int = torch.Generator(device='''cpu''').manual_seed(0)
__UpperCamelCase :Optional[int] = pipe(__lowercase , '''anime turle''' , generator=__lowercase , output_type='''np''')
__UpperCamelCase :List[Any] = output.images[0]
assert image.shape == (768, 768, 3)
assert_mean_pixel_difference(__lowercase , __lowercase)
def UpperCamelCase__ ( self) -> List[str]:
__UpperCamelCase :Dict = load_image(
'''https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main/stable_unclip/turtle.png''')
torch.cuda.empty_cache()
torch.cuda.reset_max_memory_allocated()
torch.cuda.reset_peak_memory_stats()
__UpperCamelCase :List[Any] = StableUnCLIPImgaImgPipeline.from_pretrained(
'''fusing/stable-unclip-2-1-h-img2img''' , torch_dtype=torch.floataa)
__UpperCamelCase :Union[str, Any] = pipe.to(__lowercase)
pipe.set_progress_bar_config(disable=__lowercase)
pipe.enable_attention_slicing()
pipe.enable_sequential_cpu_offload()
__UpperCamelCase :Optional[Any] = pipe(
__lowercase , '''anime turtle''' , num_inference_steps=2 , output_type='''np''' , )
__UpperCamelCase :int = torch.cuda.max_memory_allocated()
# make sure that less than 7 GB is allocated
assert mem_bytes < 7 * 10**9
| 43
| 1
|
from typing import TYPE_CHECKING
from ...utils import OptionalDependencyNotAvailable, _LazyModule, is_tf_available, is_torch_available
__lowercase = {
'''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:
__lowercase = [
'''DATA2VEC_AUDIO_PRETRAINED_MODEL_ARCHIVE_LIST''',
'''Data2VecAudioForAudioFrameClassification''',
'''Data2VecAudioForCTC''',
'''Data2VecAudioForSequenceClassification''',
'''Data2VecAudioForXVector''',
'''Data2VecAudioModel''',
'''Data2VecAudioPreTrainedModel''',
]
__lowercase = [
'''DATA2VEC_TEXT_PRETRAINED_MODEL_ARCHIVE_LIST''',
'''Data2VecTextForCausalLM''',
'''Data2VecTextForMaskedLM''',
'''Data2VecTextForMultipleChoice''',
'''Data2VecTextForQuestionAnswering''',
'''Data2VecTextForSequenceClassification''',
'''Data2VecTextForTokenClassification''',
'''Data2VecTextModel''',
'''Data2VecTextPreTrainedModel''',
]
__lowercase = [
'''DATA2VEC_VISION_PRETRAINED_MODEL_ARCHIVE_LIST''',
'''Data2VecVisionForImageClassification''',
'''Data2VecVisionForMaskedImageModeling''',
'''Data2VecVisionForSemanticSegmentation''',
'''Data2VecVisionModel''',
'''Data2VecVisionPreTrainedModel''',
]
if is_tf_available():
__lowercase = [
'''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
__lowercase = _LazyModule(__name__, globals()['''__file__'''], _import_structure, module_spec=__spec__)
| 43
|
import numpy as np
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE = 1e-12 , SCREAMING_SNAKE_CASE = 100 , ):
'''simple docstring'''
assert np.shape(SCREAMING_SNAKE_CASE )[0] == np.shape(SCREAMING_SNAKE_CASE )[1]
# Ensure proper dimensionality.
assert np.shape(SCREAMING_SNAKE_CASE )[0] == np.shape(SCREAMING_SNAKE_CASE )[0]
# Ensure inputs are either both complex or both real
assert np.iscomplexobj(SCREAMING_SNAKE_CASE ) == np.iscomplexobj(SCREAMING_SNAKE_CASE )
__UpperCamelCase :List[Any] = np.iscomplexobj(SCREAMING_SNAKE_CASE )
if is_complex:
# Ensure complex input_matrix is Hermitian
assert np.array_equal(SCREAMING_SNAKE_CASE , input_matrix.conj().T )
# Set convergence to False. Will define convergence when we exceed max_iterations
# or when we have small changes from one iteration to next.
__UpperCamelCase :str = False
__UpperCamelCase :int = 0
__UpperCamelCase :Optional[Any] = 0
__UpperCamelCase :Union[str, Any] = 1e12
while not convergence:
# Multiple matrix by the vector.
__UpperCamelCase :List[str] = np.dot(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
# Normalize the resulting output vector.
__UpperCamelCase :Tuple = w / np.linalg.norm(SCREAMING_SNAKE_CASE )
# Find rayleigh quotient
# (faster than usual b/c we know vector is normalized already)
__UpperCamelCase :int = vector.conj().T if is_complex else vector.T
__UpperCamelCase :Optional[int] = np.dot(SCREAMING_SNAKE_CASE , np.dot(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ) )
# Check convergence.
__UpperCamelCase :Optional[Any] = np.abs(lambda_ - lambda_previous ) / lambda_
iterations += 1
if error <= error_tol or iterations >= max_iterations:
__UpperCamelCase :Dict = True
__UpperCamelCase :List[Any] = lambda_
if is_complex:
__UpperCamelCase :Tuple = np.real(lambda_ )
return lambda_, vector
def lowerCamelCase ( ):
'''simple docstring'''
__UpperCamelCase :int = np.array([[41, 4, 20], [4, 26, 30], [20, 30, 50]] )
__UpperCamelCase :Optional[Any] = np.array([41, 4, 20] )
__UpperCamelCase :Any = real_input_matrix.astype(np.complexaaa )
__UpperCamelCase :Dict = np.triu(1j * complex_input_matrix , 1 )
complex_input_matrix += imag_matrix
complex_input_matrix += -1 * imag_matrix.T
__UpperCamelCase :Optional[int] = np.array([41, 4, 20] ).astype(np.complexaaa )
for problem_type in ["real", "complex"]:
if problem_type == "real":
__UpperCamelCase :Any = real_input_matrix
__UpperCamelCase :int = real_vector
elif problem_type == "complex":
__UpperCamelCase :Tuple = complex_input_matrix
__UpperCamelCase :Optional[Any] = complex_vector
# Our implementation.
__UpperCamelCase , __UpperCamelCase :Dict = power_iteration(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
# Numpy implementation.
# Get eigenvalues and eigenvectors using built-in numpy
# eigh (eigh used for symmetric or hermetian matrices).
__UpperCamelCase , __UpperCamelCase :List[Any] = np.linalg.eigh(SCREAMING_SNAKE_CASE )
# Last eigenvalue is the maximum one.
__UpperCamelCase :List[Any] = eigen_values[-1]
# Last column in this matrix is eigenvector corresponding to largest eigenvalue.
__UpperCamelCase :str = eigen_vectors[:, -1]
# Check our implementation and numpy gives close answers.
assert np.abs(eigen_value - eigen_value_max ) <= 1e-6
# Take absolute values element wise of each eigenvector.
# as they are only unique to a minus sign.
assert np.linalg.norm(np.abs(SCREAMING_SNAKE_CASE ) - np.abs(SCREAMING_SNAKE_CASE ) ) <= 1e-6
if __name__ == "__main__":
import doctest
doctest.testmod()
test_power_iteration()
| 43
| 1
|
from typing import TYPE_CHECKING
from ...utils import (
OptionalDependencyNotAvailable,
_LazyModule,
is_flax_available,
is_tf_available,
is_torch_available,
is_vision_available,
)
__lowercase = {'''configuration_vit''': ['''VIT_PRETRAINED_CONFIG_ARCHIVE_MAP''', '''ViTConfig''', '''ViTOnnxConfig''']}
try:
if not is_vision_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowercase = ['''ViTFeatureExtractor''']
__lowercase = ['''ViTImageProcessor''']
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowercase = [
'''VIT_PRETRAINED_MODEL_ARCHIVE_LIST''',
'''ViTForImageClassification''',
'''ViTForMaskedImageModeling''',
'''ViTModel''',
'''ViTPreTrainedModel''',
]
try:
if not is_tf_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowercase = [
'''TFViTForImageClassification''',
'''TFViTModel''',
'''TFViTPreTrainedModel''',
]
try:
if not is_flax_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowercase = [
'''FlaxViTForImageClassification''',
'''FlaxViTModel''',
'''FlaxViTPreTrainedModel''',
]
if TYPE_CHECKING:
from .configuration_vit import VIT_PRETRAINED_CONFIG_ARCHIVE_MAP, ViTConfig, ViTOnnxConfig
try:
if not is_vision_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .feature_extraction_vit import ViTFeatureExtractor
from .image_processing_vit import ViTImageProcessor
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_vit import (
VIT_PRETRAINED_MODEL_ARCHIVE_LIST,
ViTForImageClassification,
ViTForMaskedImageModeling,
ViTModel,
ViTPreTrainedModel,
)
try:
if not is_tf_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_tf_vit import TFViTForImageClassification, TFViTModel, TFViTPreTrainedModel
try:
if not is_flax_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_flax_vit import FlaxViTForImageClassification, FlaxViTModel, FlaxViTPreTrainedModel
else:
import sys
__lowercase = _LazyModule(__name__, globals()['''__file__'''], _import_structure, module_spec=__spec__)
| 43
|
import json
from typing import TYPE_CHECKING, List, Optional, Tuple
from tokenizers import pre_tokenizers
from ...tokenization_utils_base import BatchEncoding
from ...tokenization_utils_fast import PreTrainedTokenizerFast
from ...utils import logging
if TYPE_CHECKING:
from transformers.pipelines.conversational import Conversation
__lowercase = logging.get_logger(__name__)
__lowercase = {'''tokenizer_file''': '''tokenizer.json'''}
__lowercase = {
'''tokenizer_file''': {
'''bigscience/tokenizer''': '''https://huggingface.co/bigscience/tokenizer/blob/main/tokenizer.json''',
'''bigscience/bloom-560m''': '''https://huggingface.co/bigscience/bloom-560m/blob/main/tokenizer.json''',
'''bigscience/bloom-1b1''': '''https://huggingface.co/bigscience/bloom-1b1/blob/main/tokenizer.json''',
'''bigscience/bloom-1b7''': '''https://huggingface.co/bigscience/bloom-1b7/blob/main/tokenizer.json''',
'''bigscience/bloom-3b''': '''https://huggingface.co/bigscience/bloom-3b/blob/main/tokenizer.json''',
'''bigscience/bloom-7b1''': '''https://huggingface.co/bigscience/bloom-7b1/blob/main/tokenizer.json''',
'''bigscience/bloom''': '''https://huggingface.co/bigscience/bloom/blob/main/tokenizer.json''',
},
}
class lowerCamelCase_ ( UpperCAmelCase_ ):
'''simple docstring'''
a__ : int = VOCAB_FILES_NAMES
a__ : Tuple = PRETRAINED_VOCAB_FILES_MAP
a__ : List[str] = ["""input_ids""", """attention_mask"""]
a__ : int = None
def __init__( self , __lowercase=None , __lowercase=None , __lowercase=None , __lowercase="<unk>" , __lowercase="<s>" , __lowercase="</s>" , __lowercase="<pad>" , __lowercase=False , __lowercase=False , **__lowercase , ) -> List[str]:
super().__init__(
__lowercase , __lowercase , tokenizer_file=__lowercase , unk_token=__lowercase , bos_token=__lowercase , eos_token=__lowercase , pad_token=__lowercase , add_prefix_space=__lowercase , clean_up_tokenization_spaces=__lowercase , **__lowercase , )
__UpperCamelCase :int = json.loads(self.backend_tokenizer.pre_tokenizer.__getstate__())
if pre_tok_state.get('''add_prefix_space''' , __lowercase) != add_prefix_space:
__UpperCamelCase :Any = getattr(__lowercase , pre_tok_state.pop('''type'''))
__UpperCamelCase :str = add_prefix_space
__UpperCamelCase :List[str] = pre_tok_class(**__lowercase)
__UpperCamelCase :Tuple = add_prefix_space
def UpperCamelCase__ ( self , *__lowercase , **__lowercase) -> BatchEncoding:
__UpperCamelCase :Tuple = kwargs.get('''is_split_into_words''' , __lowercase)
if not (self.add_prefix_space or not is_split_into_words):
raise Exception(
f"""You need to instantiate {self.__class__.__name__} with add_prefix_space=True to use it with"""
''' pretokenized inputs.''')
return super()._batch_encode_plus(*__lowercase , **__lowercase)
def UpperCamelCase__ ( self , *__lowercase , **__lowercase) -> BatchEncoding:
__UpperCamelCase :List[str] = kwargs.get('''is_split_into_words''' , __lowercase)
if not (self.add_prefix_space or not is_split_into_words):
raise Exception(
f"""You need to instantiate {self.__class__.__name__} with add_prefix_space=True to use it with"""
''' pretokenized inputs.''')
return super()._encode_plus(*__lowercase , **__lowercase)
def UpperCamelCase__ ( self , __lowercase , __lowercase = None) -> Tuple[str]:
__UpperCamelCase :Optional[Any] = self._tokenizer.model.save(__lowercase , name=__lowercase)
return tuple(__lowercase)
def UpperCamelCase__ ( self , __lowercase) -> List[int]:
__UpperCamelCase :str = []
for is_user, text in conversation.iter_texts():
input_ids.extend(self.encode(__lowercase , add_special_tokens=__lowercase) + [self.eos_token_id])
if len(__lowercase) > self.model_max_length:
__UpperCamelCase :Any = input_ids[-self.model_max_length :]
return input_ids
| 43
| 1
|
from ...configuration_utils import PretrainedConfig
from ...utils import logging
__lowercase = logging.get_logger(__name__)
__lowercase = {
'''microsoft/markuplm-base''': '''https://huggingface.co/microsoft/markuplm-base/resolve/main/config.json''',
'''microsoft/markuplm-large''': '''https://huggingface.co/microsoft/markuplm-large/resolve/main/config.json''',
}
class lowerCamelCase_ ( UpperCAmelCase_ ):
'''simple docstring'''
a__ : List[Any] = """markuplm"""
def __init__( self , __lowercase=30_522 , __lowercase=768 , __lowercase=12 , __lowercase=12 , __lowercase=3_072 , __lowercase="gelu" , __lowercase=0.1 , __lowercase=0.1 , __lowercase=512 , __lowercase=2 , __lowercase=0.02 , __lowercase=1E-1_2 , __lowercase=0 , __lowercase=0 , __lowercase=2 , __lowercase=256 , __lowercase=1_024 , __lowercase=216 , __lowercase=1_001 , __lowercase=32 , __lowercase=50 , __lowercase="absolute" , __lowercase=True , __lowercase=None , **__lowercase , ) -> str:
super().__init__(
pad_token_id=__lowercase , bos_token_id=__lowercase , eos_token_id=__lowercase , **__lowercase , )
__UpperCamelCase :Any = vocab_size
__UpperCamelCase :List[Any] = hidden_size
__UpperCamelCase :str = num_hidden_layers
__UpperCamelCase :str = num_attention_heads
__UpperCamelCase :Dict = hidden_act
__UpperCamelCase :List[str] = intermediate_size
__UpperCamelCase :int = hidden_dropout_prob
__UpperCamelCase :Union[str, Any] = attention_probs_dropout_prob
__UpperCamelCase :Dict = max_position_embeddings
__UpperCamelCase :List[str] = type_vocab_size
__UpperCamelCase :Optional[int] = initializer_range
__UpperCamelCase :Any = layer_norm_eps
__UpperCamelCase :Optional[Any] = position_embedding_type
__UpperCamelCase :List[Any] = use_cache
__UpperCamelCase :Optional[int] = classifier_dropout
# additional properties
__UpperCamelCase :Optional[Any] = max_depth
__UpperCamelCase :Optional[Any] = max_xpath_tag_unit_embeddings
__UpperCamelCase :str = max_xpath_subs_unit_embeddings
__UpperCamelCase :Union[str, Any] = tag_pad_id
__UpperCamelCase :Optional[int] = subs_pad_id
__UpperCamelCase :Optional[int] = xpath_unit_hidden_size
| 43
|
from ...configuration_utils import PretrainedConfig
from ...utils import logging
__lowercase = logging.get_logger(__name__)
__lowercase = {'''ctrl''': '''https://huggingface.co/ctrl/resolve/main/config.json'''}
class lowerCamelCase_ ( UpperCAmelCase_ ):
'''simple docstring'''
a__ : str = """ctrl"""
a__ : Dict = ["""past_key_values"""]
a__ : Tuple = {
"""max_position_embeddings""": """n_positions""",
"""hidden_size""": """n_embd""",
"""num_attention_heads""": """n_head""",
"""num_hidden_layers""": """n_layer""",
}
def __init__( self , __lowercase=246_534 , __lowercase=256 , __lowercase=1_280 , __lowercase=8_192 , __lowercase=48 , __lowercase=16 , __lowercase=0.1 , __lowercase=0.1 , __lowercase=1E-6 , __lowercase=0.02 , __lowercase=True , **__lowercase , ) -> List[Any]:
__UpperCamelCase :List[str] = vocab_size
__UpperCamelCase :Optional[Any] = n_positions
__UpperCamelCase :Dict = n_embd
__UpperCamelCase :Dict = n_layer
__UpperCamelCase :List[Any] = n_head
__UpperCamelCase :int = dff
__UpperCamelCase :Union[str, Any] = resid_pdrop
__UpperCamelCase :Optional[int] = embd_pdrop
__UpperCamelCase :List[Any] = layer_norm_epsilon
__UpperCamelCase :Dict = initializer_range
__UpperCamelCase :Any = use_cache
super().__init__(**__lowercase)
| 43
| 1
|
from typing import Any
class lowerCamelCase_ :
'''simple docstring'''
def __init__( self , __lowercase) -> List[Any]:
__UpperCamelCase :Optional[int] = data
__UpperCamelCase :List[Any] = None
class lowerCamelCase_ :
'''simple docstring'''
def __init__( self) -> Dict:
__UpperCamelCase :Union[str, Any] = None
def UpperCamelCase__ ( self) -> str:
__UpperCamelCase :str = self.head
while temp is not None:
print(temp.data , end=''' ''')
__UpperCamelCase :Optional[Any] = temp.next
print()
def UpperCamelCase__ ( self , __lowercase) -> List[str]:
__UpperCamelCase :Any = Node(__lowercase)
__UpperCamelCase :Dict = self.head
__UpperCamelCase :Any = new_node
def UpperCamelCase__ ( self , __lowercase , __lowercase) -> Dict:
if node_data_a == node_data_a:
return
else:
__UpperCamelCase :List[Any] = self.head
while node_a is not None and node_a.data != node_data_a:
__UpperCamelCase :Optional[Any] = node_a.next
__UpperCamelCase :Union[str, Any] = self.head
while node_a is not None and node_a.data != node_data_a:
__UpperCamelCase :Tuple = node_a.next
if node_a is None or node_a is None:
return
__UpperCamelCase , __UpperCamelCase :Optional[int] = node_a.data, node_a.data
if __name__ == "__main__":
__lowercase = LinkedList()
for i in range(5, 0, -1):
ll.push(i)
ll.print_list()
ll.swap_nodes(1, 4)
print('''After swapping''')
ll.print_list()
| 43
|
import unittest
import numpy as np
import torch
from transformers import CLIPTextConfig, CLIPTextModel, CLIPTokenizer
from diffusers import (
AutoencoderKL,
DDIMScheduler,
DPMSolverMultistepScheduler,
TextToVideoSDPipeline,
UNetaDConditionModel,
)
from diffusers.utils import is_xformers_available, load_numpy, skip_mps, slow, torch_device
from diffusers.utils.testing_utils import enable_full_determinism
from ..pipeline_params import TEXT_TO_IMAGE_BATCH_PARAMS, TEXT_TO_IMAGE_PARAMS
from ..test_pipelines_common import PipelineTesterMixin
enable_full_determinism()
@skip_mps
class lowerCamelCase_ ( UpperCAmelCase_ , unittest.TestCase ):
'''simple docstring'''
a__ : str = TextToVideoSDPipeline
a__ : Union[str, Any] = TEXT_TO_IMAGE_PARAMS
a__ : Tuple = TEXT_TO_IMAGE_BATCH_PARAMS
# No `output_type`.
a__ : int = frozenset(
[
"""num_inference_steps""",
"""generator""",
"""latents""",
"""return_dict""",
"""callback""",
"""callback_steps""",
] )
def UpperCamelCase__ ( self) -> Optional[Any]:
torch.manual_seed(0)
__UpperCamelCase :str = UNetaDConditionModel(
block_out_channels=(32, 64, 64, 64) , layers_per_block=2 , sample_size=32 , in_channels=4 , out_channels=4 , down_block_types=('''CrossAttnDownBlock3D''', '''CrossAttnDownBlock3D''', '''CrossAttnDownBlock3D''', '''DownBlock3D''') , up_block_types=('''UpBlock3D''', '''CrossAttnUpBlock3D''', '''CrossAttnUpBlock3D''', '''CrossAttnUpBlock3D''') , cross_attention_dim=32 , attention_head_dim=4 , )
__UpperCamelCase :Optional[int] = DDIMScheduler(
beta_start=0.0_00_85 , beta_end=0.0_12 , beta_schedule='''scaled_linear''' , clip_sample=__lowercase , set_alpha_to_one=__lowercase , )
torch.manual_seed(0)
__UpperCamelCase :Optional[int] = AutoencoderKL(
block_out_channels=[32, 64] , in_channels=3 , out_channels=3 , down_block_types=['''DownEncoderBlock2D''', '''DownEncoderBlock2D'''] , up_block_types=['''UpDecoderBlock2D''', '''UpDecoderBlock2D'''] , latent_channels=4 , sample_size=128 , )
torch.manual_seed(0)
__UpperCamelCase :Optional[int] = CLIPTextConfig(
bos_token_id=0 , eos_token_id=2 , hidden_size=32 , intermediate_size=37 , layer_norm_eps=1E-0_5 , num_attention_heads=4 , num_hidden_layers=5 , pad_token_id=1 , vocab_size=1_000 , hidden_act='''gelu''' , projection_dim=512 , )
__UpperCamelCase :Optional[Any] = CLIPTextModel(__lowercase)
__UpperCamelCase :Optional[int] = CLIPTokenizer.from_pretrained('''hf-internal-testing/tiny-random-clip''')
__UpperCamelCase :Union[str, Any] = {
'''unet''': unet,
'''scheduler''': scheduler,
'''vae''': vae,
'''text_encoder''': text_encoder,
'''tokenizer''': tokenizer,
}
return components
def UpperCamelCase__ ( self , __lowercase , __lowercase=0) -> Optional[int]:
if str(__lowercase).startswith('''mps'''):
__UpperCamelCase :List[Any] = torch.manual_seed(__lowercase)
else:
__UpperCamelCase :Tuple = torch.Generator(device=__lowercase).manual_seed(__lowercase)
__UpperCamelCase :Dict = {
'''prompt''': '''A painting of a squirrel eating a burger''',
'''generator''': generator,
'''num_inference_steps''': 2,
'''guidance_scale''': 6.0,
'''output_type''': '''pt''',
}
return inputs
def UpperCamelCase__ ( self) -> Optional[Any]:
__UpperCamelCase :int = '''cpu''' # ensure determinism for the device-dependent torch.Generator
__UpperCamelCase :Optional[int] = self.get_dummy_components()
__UpperCamelCase :Dict = TextToVideoSDPipeline(**__lowercase)
__UpperCamelCase :Any = sd_pipe.to(__lowercase)
sd_pipe.set_progress_bar_config(disable=__lowercase)
__UpperCamelCase :Optional[Any] = self.get_dummy_inputs(__lowercase)
__UpperCamelCase :int = '''np'''
__UpperCamelCase :List[str] = sd_pipe(**__lowercase).frames
__UpperCamelCase :Optional[Any] = frames[0][-3:, -3:, -1]
assert frames[0].shape == (64, 64, 3)
__UpperCamelCase :str = np.array([1_58.0, 1_60.0, 1_53.0, 1_25.0, 1_00.0, 1_21.0, 1_11.0, 93.0, 1_13.0])
assert np.abs(image_slice.flatten() - expected_slice).max() < 1E-2
def UpperCamelCase__ ( self) -> Tuple:
self._test_attention_slicing_forward_pass(test_mean_pixel_difference=__lowercase , expected_max_diff=3E-3)
@unittest.skipIf(
torch_device != '''cuda''' or not is_xformers_available() , reason='''XFormers attention is only available with CUDA and `xformers` installed''' , )
def UpperCamelCase__ ( self) -> Optional[int]:
self._test_xformers_attention_forwardGenerator_pass(test_mean_pixel_difference=__lowercase , expected_max_diff=1E-2)
@unittest.skip(reason='''Batching needs to be properly figured out first for this pipeline.''')
def UpperCamelCase__ ( self) -> Union[str, Any]:
pass
@unittest.skip(reason='''Batching needs to be properly figured out first for this pipeline.''')
def UpperCamelCase__ ( self) -> Dict:
pass
@unittest.skip(reason='''`num_images_per_prompt` argument is not supported for this pipeline.''')
def UpperCamelCase__ ( self) -> str:
pass
def UpperCamelCase__ ( self) -> List[str]:
return super().test_progress_bar()
@slow
@skip_mps
class lowerCamelCase_ ( unittest.TestCase ):
'''simple docstring'''
def UpperCamelCase__ ( self) -> Dict:
__UpperCamelCase :Union[str, Any] = load_numpy(
'''https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main/text_to_video/video.npy''')
__UpperCamelCase :List[str] = TextToVideoSDPipeline.from_pretrained('''damo-vilab/text-to-video-ms-1.7b''')
__UpperCamelCase :Union[str, Any] = DPMSolverMultistepScheduler.from_config(pipe.scheduler.config)
__UpperCamelCase :str = pipe.to('''cuda''')
__UpperCamelCase :Optional[Any] = '''Spiderman is surfing'''
__UpperCamelCase :Union[str, Any] = torch.Generator(device='''cpu''').manual_seed(0)
__UpperCamelCase :List[Any] = pipe(__lowercase , generator=__lowercase , num_inference_steps=25 , output_type='''pt''').frames
__UpperCamelCase :Optional[int] = video_frames.cpu().numpy()
assert np.abs(expected_video - video).mean() < 5E-2
def UpperCamelCase__ ( self) -> int:
__UpperCamelCase :str = load_numpy(
'''https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main/text_to_video/video_2step.npy''')
__UpperCamelCase :Union[str, Any] = TextToVideoSDPipeline.from_pretrained('''damo-vilab/text-to-video-ms-1.7b''')
__UpperCamelCase :str = pipe.to('''cuda''')
__UpperCamelCase :Union[str, Any] = '''Spiderman is surfing'''
__UpperCamelCase :int = torch.Generator(device='''cpu''').manual_seed(0)
__UpperCamelCase :List[Any] = pipe(__lowercase , generator=__lowercase , num_inference_steps=2 , output_type='''pt''').frames
__UpperCamelCase :Optional[Any] = video_frames.cpu().numpy()
assert np.abs(expected_video - video).mean() < 5E-2
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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
__lowercase = logging.get_logger(__name__)
__lowercase = {'''vocab_file''': '''vocab.json''', '''merges_file''': '''merges.txt''', '''tokenizer_file''': '''tokenizer.json'''}
__lowercase = {
'''tokenizer_file''': {
'''EleutherAI/gpt-neox-20b''': '''https://huggingface.co/EleutherAI/gpt-neox-20b/resolve/main/tokenizer.json''',
},
}
__lowercase = {
'''gpt-neox-20b''': 2048,
}
class lowerCamelCase_ ( UpperCAmelCase_ ):
'''simple docstring'''
a__ : Tuple = VOCAB_FILES_NAMES
a__ : List[Any] = PRETRAINED_VOCAB_FILES_MAP
a__ : List[Any] = PRETRAINED_POSITIONAL_EMBEDDINGS_SIZES
a__ : int = ["""input_ids""", """attention_mask"""]
def __init__( self , __lowercase=None , __lowercase=None , __lowercase=None , __lowercase="<|endoftext|>" , __lowercase="<|endoftext|>" , __lowercase="<|endoftext|>" , __lowercase=False , **__lowercase , ) -> List[Any]:
super().__init__(
__lowercase , __lowercase , tokenizer_file=__lowercase , unk_token=__lowercase , bos_token=__lowercase , eos_token=__lowercase , add_prefix_space=__lowercase , **__lowercase , )
__UpperCamelCase :Optional[int] = json.loads(self.backend_tokenizer.pre_tokenizer.__getstate__())
if pre_tok_state.get('''add_prefix_space''' , __lowercase) != add_prefix_space:
__UpperCamelCase :Union[str, Any] = getattr(__lowercase , pre_tok_state.pop('''type'''))
__UpperCamelCase :int = add_prefix_space
__UpperCamelCase :str = pre_tok_class(**__lowercase)
__UpperCamelCase :int = add_prefix_space
def UpperCamelCase__ ( self , __lowercase , __lowercase = None) -> Tuple[str]:
__UpperCamelCase :Optional[int] = self._tokenizer.model.save(__lowercase , name=__lowercase)
return tuple(__lowercase)
def UpperCamelCase__ ( self , __lowercase) -> List[int]:
__UpperCamelCase :List[str] = []
for is_user, text in conversation.iter_texts():
input_ids.extend(self.encode(__lowercase , add_special_tokens=__lowercase) + [self.eos_token_id])
if len(__lowercase) > self.model_max_length:
__UpperCamelCase :Optional[int] = input_ids[-self.model_max_length :]
return input_ids
| 43
|
def lowerCamelCase ( SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Tuple = [0 for i in range(len(SCREAMING_SNAKE_CASE ) )]
# initialize interval's left pointer and right pointer
__UpperCamelCase , __UpperCamelCase :str = 0, 0
for i in range(1 , len(SCREAMING_SNAKE_CASE ) ):
# case when current index is inside the interval
if i <= right_pointer:
__UpperCamelCase :Union[str, Any] = min(right_pointer - i + 1 , z_result[i - left_pointer] )
__UpperCamelCase :Tuple = min_edge
while go_next(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
z_result[i] += 1
# if new index's result gives us more right interval,
# we've to update left_pointer and right_pointer
if i + z_result[i] - 1 > right_pointer:
__UpperCamelCase , __UpperCamelCase :Union[str, Any] = i, i + z_result[i] - 1
return z_result
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
return i + z_result[i] < len(SCREAMING_SNAKE_CASE ) and s[z_result[i]] == s[i + z_result[i]]
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :List[Any] = 0
# concatenate 'pattern' and 'input_str' and call z_function
# with concatenated string
__UpperCamelCase :Tuple = z_function(pattern + input_str )
for val in z_result:
# if value is greater then length of the pattern string
# that means this index is starting position of substring
# which is equal to pattern string
if val >= len(SCREAMING_SNAKE_CASE ):
answer += 1
return answer
if __name__ == "__main__":
import doctest
doctest.testmod()
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|
from __future__ import annotations
from scipy.special import comb # type: ignore
class lowerCamelCase_ :
'''simple docstring'''
def __init__( self , __lowercase) -> Tuple:
__UpperCamelCase :str = list_of_points
# Degree determines the flexibility of the curve.
# Degree = 1 will produce a straight line.
__UpperCamelCase :Optional[int] = len(__lowercase) - 1
def UpperCamelCase__ ( self , __lowercase) -> list[float]:
assert 0 <= t <= 1, "Time t must be between 0 and 1."
__UpperCamelCase :list[float] = []
for i in range(len(self.list_of_points)):
# basis function for each i
output_values.append(
comb(self.degree , __lowercase) * ((1 - t) ** (self.degree - i)) * (t**i))
# the basis must sum up to 1 for it to produce a valid Bezier curve.
assert round(sum(__lowercase) , 5) == 1
return output_values
def UpperCamelCase__ ( self , __lowercase) -> tuple[float, float]:
assert 0 <= t <= 1, "Time t must be between 0 and 1."
__UpperCamelCase :Tuple = self.basis_function(__lowercase)
__UpperCamelCase :Optional[Any] = 0.0
__UpperCamelCase :Dict = 0.0
for i in range(len(self.list_of_points)):
# For all points, sum up the product of i-th basis function and i-th point.
x += basis_function[i] * self.list_of_points[i][0]
y += basis_function[i] * self.list_of_points[i][1]
return (x, y)
def UpperCamelCase__ ( self , __lowercase = 0.01) -> Optional[Any]:
from matplotlib import pyplot as plt # type: ignore
__UpperCamelCase :list[float] = [] # x coordinates of points to plot
__UpperCamelCase :list[float] = [] # y coordinates of points to plot
__UpperCamelCase :int = 0.0
while t <= 1:
__UpperCamelCase :str = self.bezier_curve_function(__lowercase)
to_plot_x.append(value[0])
to_plot_y.append(value[1])
t += step_size
__UpperCamelCase :List[Any] = [i[0] for i in self.list_of_points]
__UpperCamelCase :List[str] = [i[1] for i in self.list_of_points]
plt.plot(
__lowercase , __lowercase , color='''blue''' , label='''Curve of Degree ''' + str(self.degree) , )
plt.scatter(__lowercase , __lowercase , color='''red''' , label='''Control Points''')
plt.legend()
plt.show()
if __name__ == "__main__":
import doctest
doctest.testmod()
BezierCurve([(1, 2), (3, 5)]).plot_curve() # degree 1
BezierCurve([(0, 0), (5, 5), (5, 0)]).plot_curve() # degree 2
BezierCurve([(0, 0), (5, 5), (5, 0), (2.5, -2.5)]).plot_curve() # degree 3
| 43
|
import math
from typing import Any, Callable, List, Optional, Tuple, Union
import numpy as np
import torch
from ...models import TaFilmDecoder
from ...schedulers import DDPMScheduler
from ...utils import is_onnx_available, logging, randn_tensor
if is_onnx_available():
from ..onnx_utils import OnnxRuntimeModel
from ..pipeline_utils import AudioPipelineOutput, DiffusionPipeline
from .continous_encoder import SpectrogramContEncoder
from .notes_encoder import SpectrogramNotesEncoder
__lowercase = logging.get_logger(__name__) # pylint: disable=invalid-name
__lowercase = 256
class lowerCamelCase_ ( UpperCAmelCase_ ):
'''simple docstring'''
a__ : Tuple = ["""melgan"""]
def __init__( self , __lowercase , __lowercase , __lowercase , __lowercase , __lowercase , ) -> None:
super().__init__()
# From MELGAN
__UpperCamelCase :int = math.log(1E-5) # Matches MelGAN training.
__UpperCamelCase :int = 4.0 # Largest value for most examples
__UpperCamelCase :str = 128
self.register_modules(
notes_encoder=__lowercase , continuous_encoder=__lowercase , decoder=__lowercase , scheduler=__lowercase , melgan=__lowercase , )
def UpperCamelCase__ ( self , __lowercase , __lowercase=(-1.0, 1.0) , __lowercase=False) -> Dict:
__UpperCamelCase , __UpperCamelCase :str = output_range
if clip:
__UpperCamelCase :Union[str, Any] = torch.clip(__lowercase , self.min_value , self.max_value)
# Scale to [0, 1].
__UpperCamelCase :Union[str, Any] = (features - self.min_value) / (self.max_value - self.min_value)
# Scale to [min_out, max_out].
return zero_one * (max_out - min_out) + min_out
def UpperCamelCase__ ( self , __lowercase , __lowercase=(-1.0, 1.0) , __lowercase=False) -> Optional[int]:
__UpperCamelCase , __UpperCamelCase :int = input_range
__UpperCamelCase :Optional[int] = torch.clip(__lowercase , __lowercase , __lowercase) if clip else outputs
# Scale to [0, 1].
__UpperCamelCase :List[str] = (outputs - min_out) / (max_out - min_out)
# Scale to [self.min_value, self.max_value].
return zero_one * (self.max_value - self.min_value) + self.min_value
def UpperCamelCase__ ( self , __lowercase , __lowercase , __lowercase) -> List[Any]:
__UpperCamelCase :List[str] = input_tokens > 0
__UpperCamelCase , __UpperCamelCase :Union[str, Any] = self.notes_encoder(
encoder_input_tokens=__lowercase , encoder_inputs_mask=__lowercase)
__UpperCamelCase , __UpperCamelCase :Union[str, Any] = self.continuous_encoder(
encoder_inputs=__lowercase , encoder_inputs_mask=__lowercase)
return [(tokens_encoded, tokens_mask), (continuous_encoded, continuous_mask)]
def UpperCamelCase__ ( self , __lowercase , __lowercase , __lowercase) -> str:
__UpperCamelCase :Optional[int] = noise_time
if not torch.is_tensor(__lowercase):
__UpperCamelCase :str = torch.tensor([timesteps] , dtype=torch.long , device=input_tokens.device)
elif torch.is_tensor(__lowercase) and len(timesteps.shape) == 0:
__UpperCamelCase :Dict = timesteps[None].to(input_tokens.device)
# broadcast to batch dimension in a way that's compatible with ONNX/Core ML
__UpperCamelCase :List[str] = timesteps * torch.ones(input_tokens.shape[0] , dtype=timesteps.dtype , device=timesteps.device)
__UpperCamelCase :Tuple = self.decoder(
encodings_and_masks=__lowercase , decoder_input_tokens=__lowercase , decoder_noise_time=__lowercase)
return logits
@torch.no_grad()
def __call__( self , __lowercase , __lowercase = None , __lowercase = 100 , __lowercase = True , __lowercase = "numpy" , __lowercase = None , __lowercase = 1 , ) -> Union[AudioPipelineOutput, Tuple]:
if (callback_steps is None) or (
callback_steps is not None and (not isinstance(__lowercase , __lowercase) or callback_steps <= 0)
):
raise ValueError(
f"""`callback_steps` has to be a positive integer but is {callback_steps} of type"""
f""" {type(__lowercase)}.""")
__UpperCamelCase :Union[str, Any] = np.zeros([1, TARGET_FEATURE_LENGTH, self.n_dims] , dtype=np.floataa)
__UpperCamelCase :Union[str, Any] = np.zeros([1, 0, self.n_dims] , np.floataa)
__UpperCamelCase :Union[str, Any] = torch.ones((1, TARGET_FEATURE_LENGTH) , dtype=__lowercase , device=self.device)
for i, encoder_input_tokens in enumerate(__lowercase):
if i == 0:
__UpperCamelCase :int = torch.from_numpy(pred_mel[:1].copy()).to(
device=self.device , dtype=self.decoder.dtype)
# The first chunk has no previous context.
__UpperCamelCase :int = torch.zeros((1, TARGET_FEATURE_LENGTH) , dtype=__lowercase , device=self.device)
else:
# The full song pipeline does not feed in a context feature, so the mask
# will be all 0s after the feature converter. Because we know we're
# feeding in a full context chunk from the previous prediction, set it
# to all 1s.
__UpperCamelCase :Tuple = ones
__UpperCamelCase :Optional[Any] = self.scale_features(
__lowercase , output_range=[-1.0, 1.0] , clip=__lowercase)
__UpperCamelCase :int = self.encode(
input_tokens=torch.IntTensor([encoder_input_tokens]).to(device=self.device) , continuous_inputs=__lowercase , continuous_mask=__lowercase , )
# Sample encoder_continuous_inputs shaped gaussian noise to begin loop
__UpperCamelCase :int = randn_tensor(
shape=encoder_continuous_inputs.shape , generator=__lowercase , device=self.device , dtype=self.decoder.dtype , )
# set step values
self.scheduler.set_timesteps(__lowercase)
# Denoising diffusion loop
for j, t in enumerate(self.progress_bar(self.scheduler.timesteps)):
__UpperCamelCase :Optional[int] = self.decode(
encodings_and_masks=__lowercase , input_tokens=__lowercase , noise_time=t / self.scheduler.config.num_train_timesteps , )
# Compute previous output: x_t -> x_t-1
__UpperCamelCase :int = self.scheduler.step(__lowercase , __lowercase , __lowercase , generator=__lowercase).prev_sample
__UpperCamelCase :Tuple = self.scale_to_features(__lowercase , input_range=[-1.0, 1.0])
__UpperCamelCase :List[Any] = mel[:1]
__UpperCamelCase :Optional[Any] = mel.cpu().float().numpy()
__UpperCamelCase :Any = np.concatenate([full_pred_mel, pred_mel[:1]] , axis=1)
# call the callback, if provided
if callback is not None and i % callback_steps == 0:
callback(__lowercase , __lowercase)
logger.info('''Generated segment''' , __lowercase)
if output_type == "numpy" and not is_onnx_available():
raise ValueError(
'''Cannot return output in \'np\' format if ONNX is not available. Make sure to have ONNX installed or set \'output_type\' to \'mel\'.''')
elif output_type == "numpy" and self.melgan is None:
raise ValueError(
'''Cannot return output in \'np\' format if melgan component is not defined. Make sure to define `self.melgan` or set \'output_type\' to \'mel\'.''')
if output_type == "numpy":
__UpperCamelCase :Optional[Any] = self.melgan(input_features=full_pred_mel.astype(np.floataa))
else:
__UpperCamelCase :List[str] = full_pred_mel
if not return_dict:
return (output,)
return AudioPipelineOutput(audios=__lowercase)
| 43
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|
import gc
import random
import unittest
import numpy as np
import torch
from transformers import CLIPTextConfig, CLIPTextModel, CLIPTokenizer
from diffusers import AutoencoderKL, CycleDiffusionPipeline, DDIMScheduler, UNetaDConditionModel
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, skip_mps
from ..pipeline_params import (
IMAGE_TO_IMAGE_IMAGE_PARAMS,
TEXT_GUIDED_IMAGE_VARIATION_BATCH_PARAMS,
TEXT_GUIDED_IMAGE_VARIATION_PARAMS,
)
from ..test_pipelines_common import PipelineLatentTesterMixin, PipelineTesterMixin
enable_full_determinism()
class lowerCamelCase_ ( UpperCAmelCase_ , UpperCAmelCase_ , unittest.TestCase ):
'''simple docstring'''
a__ : str = CycleDiffusionPipeline
a__ : List[str] = TEXT_GUIDED_IMAGE_VARIATION_PARAMS - {
"""negative_prompt""",
"""height""",
"""width""",
"""negative_prompt_embeds""",
}
a__ : Union[str, Any] = PipelineTesterMixin.required_optional_params - {"""latents"""}
a__ : List[Any] = TEXT_GUIDED_IMAGE_VARIATION_BATCH_PARAMS.union({"""source_prompt"""} )
a__ : List[str] = IMAGE_TO_IMAGE_IMAGE_PARAMS
a__ : str = IMAGE_TO_IMAGE_IMAGE_PARAMS
def UpperCamelCase__ ( self) -> Any:
torch.manual_seed(0)
__UpperCamelCase :Union[str, Any] = UNetaDConditionModel(
block_out_channels=(32, 64) , layers_per_block=2 , sample_size=32 , in_channels=4 , out_channels=4 , down_block_types=('''DownBlock2D''', '''CrossAttnDownBlock2D''') , up_block_types=('''CrossAttnUpBlock2D''', '''UpBlock2D''') , cross_attention_dim=32 , )
__UpperCamelCase :Any = DDIMScheduler(
beta_start=0.0_00_85 , beta_end=0.0_12 , beta_schedule='''scaled_linear''' , num_train_timesteps=1_000 , clip_sample=__lowercase , set_alpha_to_one=__lowercase , )
torch.manual_seed(0)
__UpperCamelCase :Any = AutoencoderKL(
block_out_channels=[32, 64] , in_channels=3 , out_channels=3 , down_block_types=['''DownEncoderBlock2D''', '''DownEncoderBlock2D'''] , up_block_types=['''UpDecoderBlock2D''', '''UpDecoderBlock2D'''] , latent_channels=4 , )
torch.manual_seed(0)
__UpperCamelCase :Tuple = CLIPTextConfig(
bos_token_id=0 , eos_token_id=2 , hidden_size=32 , intermediate_size=37 , layer_norm_eps=1E-0_5 , num_attention_heads=4 , num_hidden_layers=5 , pad_token_id=1 , vocab_size=1_000 , )
__UpperCamelCase :List[str] = CLIPTextModel(__lowercase)
__UpperCamelCase :Tuple = CLIPTokenizer.from_pretrained('''hf-internal-testing/tiny-random-clip''')
__UpperCamelCase :str = {
'''unet''': unet,
'''scheduler''': scheduler,
'''vae''': vae,
'''text_encoder''': text_encoder,
'''tokenizer''': tokenizer,
'''safety_checker''': None,
'''feature_extractor''': None,
}
return components
def UpperCamelCase__ ( self , __lowercase , __lowercase=0) -> str:
__UpperCamelCase :List[str] = floats_tensor((1, 3, 32, 32) , rng=random.Random(__lowercase)).to(__lowercase)
__UpperCamelCase :List[Any] = image / 2 + 0.5
if str(__lowercase).startswith('''mps'''):
__UpperCamelCase :Optional[int] = torch.manual_seed(__lowercase)
else:
__UpperCamelCase :Optional[int] = torch.Generator(device=__lowercase).manual_seed(__lowercase)
__UpperCamelCase :Any = {
'''prompt''': '''An astronaut riding an elephant''',
'''source_prompt''': '''An astronaut riding a horse''',
'''image''': image,
'''generator''': generator,
'''num_inference_steps''': 2,
'''eta''': 0.1,
'''strength''': 0.8,
'''guidance_scale''': 3,
'''source_guidance_scale''': 1,
'''output_type''': '''numpy''',
}
return inputs
def UpperCamelCase__ ( self) -> List[Any]:
__UpperCamelCase :Optional[Any] = '''cpu''' # ensure determinism for the device-dependent torch.Generator
__UpperCamelCase :Optional[Any] = self.get_dummy_components()
__UpperCamelCase :List[str] = CycleDiffusionPipeline(**__lowercase)
__UpperCamelCase :Tuple = pipe.to(__lowercase)
pipe.set_progress_bar_config(disable=__lowercase)
__UpperCamelCase :List[Any] = self.get_dummy_inputs(__lowercase)
__UpperCamelCase :Tuple = pipe(**__lowercase)
__UpperCamelCase :Tuple = output.images
__UpperCamelCase :Union[str, Any] = images[0, -3:, -3:, -1]
assert images.shape == (1, 32, 32, 3)
__UpperCamelCase :int = np.array([0.44_59, 0.49_43, 0.45_44, 0.66_43, 0.54_74, 0.43_27, 0.57_01, 0.59_59, 0.51_79])
assert np.abs(image_slice.flatten() - expected_slice).max() < 1E-2
@unittest.skipIf(torch_device != '''cuda''' , '''This test requires a GPU''')
def UpperCamelCase__ ( self) -> Optional[int]:
__UpperCamelCase :Any = self.get_dummy_components()
for name, module in components.items():
if hasattr(__lowercase , '''half'''):
__UpperCamelCase :Any = module.half()
__UpperCamelCase :int = CycleDiffusionPipeline(**__lowercase)
__UpperCamelCase :Optional[int] = pipe.to(__lowercase)
pipe.set_progress_bar_config(disable=__lowercase)
__UpperCamelCase :Optional[Any] = self.get_dummy_inputs(__lowercase)
__UpperCamelCase :str = pipe(**__lowercase)
__UpperCamelCase :Any = output.images
__UpperCamelCase :str = images[0, -3:, -3:, -1]
assert images.shape == (1, 32, 32, 3)
__UpperCamelCase :Optional[Any] = np.array([0.35_06, 0.45_43, 0.4_46, 0.45_75, 0.51_95, 0.41_55, 0.52_73, 0.5_18, 0.41_16])
assert np.abs(image_slice.flatten() - expected_slice).max() < 1E-2
@skip_mps
def UpperCamelCase__ ( self) -> List[Any]:
return super().test_save_load_local()
@unittest.skip('''non-deterministic pipeline''')
def UpperCamelCase__ ( self) -> Optional[int]:
return super().test_inference_batch_single_identical()
@skip_mps
def UpperCamelCase__ ( self) -> Tuple:
return super().test_dict_tuple_outputs_equivalent()
@skip_mps
def UpperCamelCase__ ( self) -> Any:
return super().test_save_load_optional_components()
@skip_mps
def UpperCamelCase__ ( self) -> Tuple:
return super().test_attention_slicing_forward_pass()
@slow
@require_torch_gpu
class lowerCamelCase_ ( unittest.TestCase ):
'''simple docstring'''
def UpperCamelCase__ ( self) -> Dict:
# clean up the VRAM after each test
super().tearDown()
gc.collect()
torch.cuda.empty_cache()
def UpperCamelCase__ ( self) -> Dict:
__UpperCamelCase :int = load_image(
'''https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main'''
'''/cycle-diffusion/black_colored_car.png''')
__UpperCamelCase :str = load_numpy(
'''https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main/cycle-diffusion/blue_colored_car_fp16.npy''')
__UpperCamelCase :int = init_image.resize((512, 512))
__UpperCamelCase :List[Any] = '''CompVis/stable-diffusion-v1-4'''
__UpperCamelCase :Optional[Any] = DDIMScheduler.from_pretrained(__lowercase , subfolder='''scheduler''')
__UpperCamelCase :Optional[Any] = CycleDiffusionPipeline.from_pretrained(
__lowercase , scheduler=__lowercase , safety_checker=__lowercase , torch_dtype=torch.floataa , revision='''fp16''')
pipe.to(__lowercase)
pipe.set_progress_bar_config(disable=__lowercase)
pipe.enable_attention_slicing()
__UpperCamelCase :Dict = '''A black colored car'''
__UpperCamelCase :List[str] = '''A blue colored car'''
__UpperCamelCase :Optional[int] = torch.manual_seed(0)
__UpperCamelCase :Optional[int] = pipe(
prompt=__lowercase , source_prompt=__lowercase , image=__lowercase , num_inference_steps=100 , eta=0.1 , strength=0.85 , guidance_scale=3 , source_guidance_scale=1 , generator=__lowercase , output_type='''np''' , )
__UpperCamelCase :List[Any] = output.images
# the values aren't exactly equal, but the images look the same visually
assert np.abs(image - expected_image).max() < 5E-1
def UpperCamelCase__ ( self) -> int:
__UpperCamelCase :str = load_image(
'''https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main'''
'''/cycle-diffusion/black_colored_car.png''')
__UpperCamelCase :str = load_numpy(
'''https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main/cycle-diffusion/blue_colored_car.npy''')
__UpperCamelCase :List[Any] = init_image.resize((512, 512))
__UpperCamelCase :Optional[int] = '''CompVis/stable-diffusion-v1-4'''
__UpperCamelCase :str = DDIMScheduler.from_pretrained(__lowercase , subfolder='''scheduler''')
__UpperCamelCase :List[str] = CycleDiffusionPipeline.from_pretrained(__lowercase , scheduler=__lowercase , safety_checker=__lowercase)
pipe.to(__lowercase)
pipe.set_progress_bar_config(disable=__lowercase)
pipe.enable_attention_slicing()
__UpperCamelCase :Tuple = '''A black colored car'''
__UpperCamelCase :str = '''A blue colored car'''
__UpperCamelCase :Tuple = torch.manual_seed(0)
__UpperCamelCase :int = pipe(
prompt=__lowercase , source_prompt=__lowercase , image=__lowercase , num_inference_steps=100 , eta=0.1 , strength=0.85 , guidance_scale=3 , source_guidance_scale=1 , generator=__lowercase , output_type='''np''' , )
__UpperCamelCase :Optional[Any] = output.images
assert np.abs(image - expected_image).max() < 2E-2
| 43
|
import argparse
import json
import os
import fairseq
import torch
from fairseq.data import Dictionary
from transformers import (
HubertConfig,
HubertForCTC,
HubertModel,
WavaVecaCTCTokenizer,
WavaVecaFeatureExtractor,
WavaVecaProcessor,
logging,
)
logging.set_verbosity_info()
__lowercase = logging.get_logger(__name__)
__lowercase = {
'''post_extract_proj''': '''feature_projection.projection''',
'''encoder.pos_conv.0''': '''encoder.pos_conv_embed.conv''',
'''self_attn.k_proj''': '''encoder.layers.*.attention.k_proj''',
'''self_attn.v_proj''': '''encoder.layers.*.attention.v_proj''',
'''self_attn.q_proj''': '''encoder.layers.*.attention.q_proj''',
'''self_attn.out_proj''': '''encoder.layers.*.attention.out_proj''',
'''self_attn_layer_norm''': '''encoder.layers.*.layer_norm''',
'''fc1''': '''encoder.layers.*.feed_forward.intermediate_dense''',
'''fc2''': '''encoder.layers.*.feed_forward.output_dense''',
'''final_layer_norm''': '''encoder.layers.*.final_layer_norm''',
'''encoder.layer_norm''': '''encoder.layer_norm''',
'''w2v_model.layer_norm''': '''feature_projection.layer_norm''',
'''w2v_encoder.proj''': '''lm_head''',
'''mask_emb''': '''masked_spec_embed''',
}
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
for attribute in key.split('''.''' ):
__UpperCamelCase :str = getattr(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
if weight_type is not None:
__UpperCamelCase :Any = getattr(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ).shape
else:
__UpperCamelCase :Union[str, Any] = hf_pointer.shape
assert hf_shape == value.shape, (
f"""Shape of hf {key + '.' + weight_type if weight_type is not None else ''} is {hf_shape}, but should be"""
f""" {value.shape} for {full_name}"""
)
if weight_type == "weight":
__UpperCamelCase :str = value
elif weight_type == "weight_g":
__UpperCamelCase :List[str] = value
elif weight_type == "weight_v":
__UpperCamelCase :str = value
elif weight_type == "bias":
__UpperCamelCase :Union[str, Any] = value
else:
__UpperCamelCase :str = value
logger.info(f"""{key + '.' + weight_type if weight_type is not None else ''} was initialized from {full_name}.""" )
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :List[Any] = []
__UpperCamelCase :int = fairseq_model.state_dict()
__UpperCamelCase :List[Any] = hf_model.hubert.feature_extractor if is_finetuned else hf_model.feature_extractor
for name, value in fairseq_dict.items():
__UpperCamelCase :List[Any] = False
if "conv_layers" in name:
load_conv_layer(
SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , hf_model.config.feat_extract_norm == '''group''' , )
__UpperCamelCase :List[str] = True
else:
for key, mapped_key in MAPPING.items():
__UpperCamelCase :Dict = '''hubert.''' + mapped_key if (is_finetuned and mapped_key != '''lm_head''') else mapped_key
if key in name or (key.split('''w2v_model.''' )[-1] == name.split('''.''' )[0] and not is_finetuned):
__UpperCamelCase :Optional[Any] = True
if "*" in mapped_key:
__UpperCamelCase :List[str] = name.split(SCREAMING_SNAKE_CASE )[0].split('''.''' )[-2]
__UpperCamelCase :Optional[int] = mapped_key.replace('''*''' , SCREAMING_SNAKE_CASE )
if "weight_g" in name:
__UpperCamelCase :int = '''weight_g'''
elif "weight_v" in name:
__UpperCamelCase :List[Any] = '''weight_v'''
elif "weight" in name:
__UpperCamelCase :Dict = '''weight'''
elif "bias" in name:
__UpperCamelCase :Dict = '''bias'''
else:
__UpperCamelCase :Dict = None
set_recursively(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
continue
if not is_used:
unused_weights.append(SCREAMING_SNAKE_CASE )
logger.warning(f"""Unused weights: {unused_weights}""" )
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Tuple = full_name.split('''conv_layers.''' )[-1]
__UpperCamelCase :Optional[int] = name.split('''.''' )
__UpperCamelCase :str = int(items[0] )
__UpperCamelCase :List[Any] = int(items[1] )
if type_id == 0:
if "bias" in name:
assert value.shape == feature_extractor.conv_layers[layer_id].conv.bias.data.shape, (
f"""{full_name} has size {value.shape}, but"""
f""" {feature_extractor.conv_layers[layer_id].conv.bias.data.shape} was found."""
)
__UpperCamelCase :Dict = value
logger.info(f"""Feat extract conv layer {layer_id} was initialized from {full_name}.""" )
elif "weight" in name:
assert value.shape == feature_extractor.conv_layers[layer_id].conv.weight.data.shape, (
f"""{full_name} has size {value.shape}, but"""
f""" {feature_extractor.conv_layers[layer_id].conv.weight.data.shape} was found."""
)
__UpperCamelCase :Any = value
logger.info(f"""Feat extract conv layer {layer_id} was initialized from {full_name}.""" )
elif (type_id == 2 and not use_group_norm) or (type_id == 2 and layer_id == 0 and use_group_norm):
if "bias" in name:
assert value.shape == feature_extractor.conv_layers[layer_id].layer_norm.bias.data.shape, (
f"""{full_name} has size {value.shape}, but {feature_extractor[layer_id].layer_norm.bias.data.shape} was"""
" found."
)
__UpperCamelCase :int = value
logger.info(f"""Feat extract layer norm weight of layer {layer_id} was initialized from {full_name}.""" )
elif "weight" in name:
assert value.shape == feature_extractor.conv_layers[layer_id].layer_norm.weight.data.shape, (
f"""{full_name} has size {value.shape}, but"""
f""" {feature_extractor[layer_id].layer_norm.weight.data.shape} was found."""
)
__UpperCamelCase :Union[str, Any] = value
logger.info(f"""Feat extract layer norm weight of layer {layer_id} was initialized from {full_name}.""" )
else:
unused_weights.append(SCREAMING_SNAKE_CASE )
@torch.no_grad()
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE=None , SCREAMING_SNAKE_CASE=None , SCREAMING_SNAKE_CASE=True ):
'''simple docstring'''
if config_path is not None:
__UpperCamelCase :Tuple = HubertConfig.from_pretrained(SCREAMING_SNAKE_CASE )
else:
__UpperCamelCase :Optional[int] = HubertConfig()
if is_finetuned:
if dict_path:
__UpperCamelCase :Optional[int] = Dictionary.load(SCREAMING_SNAKE_CASE )
# important change bos & pad token id since CTC symbol is <pad> and
# not <s> as in fairseq
__UpperCamelCase :Optional[int] = target_dict.pad_index
__UpperCamelCase :Dict = target_dict.bos_index
__UpperCamelCase :str = target_dict.eos_index
__UpperCamelCase :Dict = len(target_dict.symbols )
__UpperCamelCase :List[Any] = os.path.join(SCREAMING_SNAKE_CASE , '''vocab.json''' )
if not os.path.isdir(SCREAMING_SNAKE_CASE ):
logger.error('''--pytorch_dump_folder_path ({}) should be a directory'''.format(SCREAMING_SNAKE_CASE ) )
return
os.makedirs(SCREAMING_SNAKE_CASE , exist_ok=SCREAMING_SNAKE_CASE )
with open(SCREAMING_SNAKE_CASE , '''w''' , encoding='''utf-8''' ) as vocab_handle:
json.dump(target_dict.indices , SCREAMING_SNAKE_CASE )
__UpperCamelCase :Optional[int] = WavaVecaCTCTokenizer(
SCREAMING_SNAKE_CASE , unk_token=target_dict.unk_word , pad_token=target_dict.pad_word , bos_token=target_dict.bos_word , eos_token=target_dict.eos_word , word_delimiter_token='''|''' , do_lower_case=SCREAMING_SNAKE_CASE , )
__UpperCamelCase :Union[str, Any] = True if config.feat_extract_norm == '''layer''' else False
__UpperCamelCase :Any = WavaVecaFeatureExtractor(
feature_size=1 , sampling_rate=16_000 , padding_value=0 , do_normalize=SCREAMING_SNAKE_CASE , return_attention_mask=SCREAMING_SNAKE_CASE , )
__UpperCamelCase :Any = WavaVecaProcessor(feature_extractor=SCREAMING_SNAKE_CASE , tokenizer=SCREAMING_SNAKE_CASE )
processor.save_pretrained(SCREAMING_SNAKE_CASE )
__UpperCamelCase :List[str] = HubertForCTC(SCREAMING_SNAKE_CASE )
else:
__UpperCamelCase :str = HubertModel(SCREAMING_SNAKE_CASE )
if is_finetuned:
__UpperCamelCase , __UpperCamelCase , __UpperCamelCase :int = fairseq.checkpoint_utils.load_model_ensemble_and_task(
[checkpoint_path] , arg_overrides={'''data''': '''/'''.join(dict_path.split('''/''' )[:-1] )} )
else:
__UpperCamelCase , __UpperCamelCase , __UpperCamelCase :Any = fairseq.checkpoint_utils.load_model_ensemble_and_task([checkpoint_path] )
__UpperCamelCase :Dict = model[0].eval()
recursively_load_weights(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
hf_wavavec.save_pretrained(SCREAMING_SNAKE_CASE )
if __name__ == "__main__":
__lowercase = argparse.ArgumentParser()
parser.add_argument('''--pytorch_dump_folder_path''', default=None, type=str, help='''Path to the output PyTorch model.''')
parser.add_argument('''--checkpoint_path''', default=None, type=str, help='''Path to fairseq checkpoint''')
parser.add_argument('''--dict_path''', default=None, type=str, help='''Path to dict of fine-tuned model''')
parser.add_argument('''--config_path''', default=None, type=str, help='''Path to hf config.json of model to convert''')
parser.add_argument(
'''--not_finetuned''', action='''store_true''', help='''Whether the model to convert is a fine-tuned model or not'''
)
__lowercase = parser.parse_args()
convert_hubert_checkpoint(
args.checkpoint_path, args.pytorch_dump_folder_path, args.config_path, args.dict_path, not args.not_finetuned
)
| 43
| 1
|
__lowercase = {
'''Pillow''': '''Pillow''',
'''accelerate''': '''accelerate>=0.11.0''',
'''compel''': '''compel==0.1.8''',
'''black''': '''black~=23.1''',
'''datasets''': '''datasets''',
'''filelock''': '''filelock''',
'''flax''': '''flax>=0.4.1''',
'''hf-doc-builder''': '''hf-doc-builder>=0.3.0''',
'''huggingface-hub''': '''huggingface-hub>=0.13.2''',
'''requests-mock''': '''requests-mock==1.10.0''',
'''importlib_metadata''': '''importlib_metadata''',
'''invisible-watermark''': '''invisible-watermark''',
'''isort''': '''isort>=5.5.4''',
'''jax''': '''jax>=0.2.8,!=0.3.2''',
'''jaxlib''': '''jaxlib>=0.1.65''',
'''Jinja2''': '''Jinja2''',
'''k-diffusion''': '''k-diffusion>=0.0.12''',
'''torchsde''': '''torchsde''',
'''note_seq''': '''note_seq''',
'''librosa''': '''librosa''',
'''numpy''': '''numpy''',
'''omegaconf''': '''omegaconf''',
'''parameterized''': '''parameterized''',
'''protobuf''': '''protobuf>=3.20.3,<4''',
'''pytest''': '''pytest''',
'''pytest-timeout''': '''pytest-timeout''',
'''pytest-xdist''': '''pytest-xdist''',
'''ruff''': '''ruff>=0.0.241''',
'''safetensors''': '''safetensors''',
'''sentencepiece''': '''sentencepiece>=0.1.91,!=0.1.92''',
'''scipy''': '''scipy''',
'''onnx''': '''onnx''',
'''regex''': '''regex!=2019.12.17''',
'''requests''': '''requests''',
'''tensorboard''': '''tensorboard''',
'''torch''': '''torch>=1.4''',
'''torchvision''': '''torchvision''',
'''transformers''': '''transformers>=4.25.1''',
'''urllib3''': '''urllib3<=2.0.0''',
}
| 43
|
import glob
import os
import random
from string import ascii_lowercase, digits
import cva
import numpy as np
# Parrameters
__lowercase = (720, 1280) # Height, Width
__lowercase = (0.4, 0.6) # if height or width lower than this scale, drop it.
__lowercase = 1 / 100
__lowercase = ''''''
__lowercase = ''''''
__lowercase = ''''''
__lowercase = 250
def lowerCamelCase ( ):
'''simple docstring'''
__UpperCamelCase , __UpperCamelCase :List[Any] = get_dataset(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
for index in range(SCREAMING_SNAKE_CASE ):
__UpperCamelCase :Optional[Any] = random.sample(range(len(SCREAMING_SNAKE_CASE ) ) , 4 )
__UpperCamelCase , __UpperCamelCase , __UpperCamelCase :str = update_image_and_anno(
SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , filter_scale=SCREAMING_SNAKE_CASE , )
# Get random string code: '7b7ad245cdff75241935e4dd860f3bad'
__UpperCamelCase :List[Any] = random_chars(32 )
__UpperCamelCase :List[str] = path.split(os.sep )[-1].rsplit('''.''' , 1 )[0]
__UpperCamelCase :Tuple = f"""{OUTPUT_DIR}/{file_name}_MOSAIC_{letter_code}"""
cva.imwrite(f"""{file_root}.jpg""" , SCREAMING_SNAKE_CASE , [cva.IMWRITE_JPEG_QUALITY, 85] )
print(f"""Succeeded {index+1}/{NUMBER_IMAGES} with {file_name}""" )
__UpperCamelCase :Optional[Any] = []
for anno in new_annos:
__UpperCamelCase :int = anno[3] - anno[1]
__UpperCamelCase :Optional[int] = anno[4] - anno[2]
__UpperCamelCase :int = anno[1] + width / 2
__UpperCamelCase :List[str] = anno[2] + height / 2
__UpperCamelCase :str = f"""{anno[0]} {x_center} {y_center} {width} {height}"""
annos_list.append(SCREAMING_SNAKE_CASE )
with open(f"""{file_root}.txt""" , '''w''' ) as outfile:
outfile.write('''\n'''.join(line for line in annos_list ) )
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :str = []
__UpperCamelCase :str = []
for label_file in glob.glob(os.path.join(SCREAMING_SNAKE_CASE , '''*.txt''' ) ):
__UpperCamelCase :Any = label_file.split(os.sep )[-1].rsplit('''.''' , 1 )[0]
with open(SCREAMING_SNAKE_CASE ) as in_file:
__UpperCamelCase :str = in_file.readlines()
__UpperCamelCase :Optional[int] = os.path.join(SCREAMING_SNAKE_CASE , f"""{label_name}.jpg""" )
__UpperCamelCase :int = []
for obj_list in obj_lists:
__UpperCamelCase :Optional[int] = obj_list.rstrip('''\n''' ).split(''' ''' )
__UpperCamelCase :Any = float(obj[1] ) - float(obj[3] ) / 2
__UpperCamelCase :List[str] = float(obj[2] ) - float(obj[4] ) / 2
__UpperCamelCase :Dict = float(obj[1] ) + float(obj[3] ) / 2
__UpperCamelCase :List[str] = float(obj[2] ) + float(obj[4] ) / 2
boxes.append([int(obj[0] ), xmin, ymin, xmax, ymax] )
if not boxes:
continue
img_paths.append(SCREAMING_SNAKE_CASE )
labels.append(SCREAMING_SNAKE_CASE )
return img_paths, labels
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE = 0.0 , ):
'''simple docstring'''
__UpperCamelCase :List[str] = np.zeros([output_size[0], output_size[1], 3] , dtype=np.uinta )
__UpperCamelCase :List[Any] = scale_range[0] + random.random() * (scale_range[1] - scale_range[0])
__UpperCamelCase :int = scale_range[0] + random.random() * (scale_range[1] - scale_range[0])
__UpperCamelCase :Optional[int] = int(scale_x * output_size[1] )
__UpperCamelCase :Any = int(scale_y * output_size[0] )
__UpperCamelCase :List[str] = []
__UpperCamelCase :Dict = []
for i, index in enumerate(SCREAMING_SNAKE_CASE ):
__UpperCamelCase :Any = all_img_list[index]
path_list.append(SCREAMING_SNAKE_CASE )
__UpperCamelCase :Any = all_annos[index]
__UpperCamelCase :Union[str, Any] = cva.imread(SCREAMING_SNAKE_CASE )
if i == 0: # top-left
__UpperCamelCase :str = cva.resize(SCREAMING_SNAKE_CASE , (divid_point_x, divid_point_y) )
__UpperCamelCase :Union[str, Any] = img
for bbox in img_annos:
__UpperCamelCase :Union[str, Any] = bbox[1] * scale_x
__UpperCamelCase :Optional[Any] = bbox[2] * scale_y
__UpperCamelCase :int = bbox[3] * scale_x
__UpperCamelCase :Union[str, Any] = bbox[4] * scale_y
new_anno.append([bbox[0], xmin, ymin, xmax, ymax] )
elif i == 1: # top-right
__UpperCamelCase :str = cva.resize(SCREAMING_SNAKE_CASE , (output_size[1] - divid_point_x, divid_point_y) )
__UpperCamelCase :List[str] = img
for bbox in img_annos:
__UpperCamelCase :str = scale_x + bbox[1] * (1 - scale_x)
__UpperCamelCase :Dict = bbox[2] * scale_y
__UpperCamelCase :Optional[Any] = scale_x + bbox[3] * (1 - scale_x)
__UpperCamelCase :List[Any] = bbox[4] * scale_y
new_anno.append([bbox[0], xmin, ymin, xmax, ymax] )
elif i == 2: # bottom-left
__UpperCamelCase :str = cva.resize(SCREAMING_SNAKE_CASE , (divid_point_x, output_size[0] - divid_point_y) )
__UpperCamelCase :Optional[int] = img
for bbox in img_annos:
__UpperCamelCase :Tuple = bbox[1] * scale_x
__UpperCamelCase :Optional[Any] = scale_y + bbox[2] * (1 - scale_y)
__UpperCamelCase :Tuple = bbox[3] * scale_x
__UpperCamelCase :Dict = scale_y + bbox[4] * (1 - scale_y)
new_anno.append([bbox[0], xmin, ymin, xmax, ymax] )
else: # bottom-right
__UpperCamelCase :Optional[int] = cva.resize(
SCREAMING_SNAKE_CASE , (output_size[1] - divid_point_x, output_size[0] - divid_point_y) )
__UpperCamelCase :Optional[int] = img
for bbox in img_annos:
__UpperCamelCase :Optional[Any] = scale_x + bbox[1] * (1 - scale_x)
__UpperCamelCase :Optional[int] = scale_y + bbox[2] * (1 - scale_y)
__UpperCamelCase :Optional[Any] = scale_x + bbox[3] * (1 - scale_x)
__UpperCamelCase :int = scale_y + bbox[4] * (1 - scale_y)
new_anno.append([bbox[0], xmin, ymin, xmax, ymax] )
# Remove bounding box small than scale of filter
if filter_scale > 0:
__UpperCamelCase :List[Any] = [
anno
for anno in new_anno
if filter_scale < (anno[3] - anno[1]) and filter_scale < (anno[4] - anno[2])
]
return output_img, new_anno, path_list[0]
def lowerCamelCase ( SCREAMING_SNAKE_CASE ):
'''simple docstring'''
assert number_char > 1, "The number of character should greater than 1"
__UpperCamelCase :Optional[Any] = ascii_lowercase + digits
return "".join(random.choice(SCREAMING_SNAKE_CASE ) for _ in range(SCREAMING_SNAKE_CASE ) )
if __name__ == "__main__":
main()
print('''DONE ✅''')
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import unittest
import numpy as np
import torch
from diffusers import DDIMPipeline, DDIMScheduler, UNetaDModel
from diffusers.utils.testing_utils import enable_full_determinism, require_torch_gpu, slow, torch_device
from ..pipeline_params import UNCONDITIONAL_IMAGE_GENERATION_BATCH_PARAMS, UNCONDITIONAL_IMAGE_GENERATION_PARAMS
from ..test_pipelines_common import PipelineTesterMixin
enable_full_determinism()
class lowerCamelCase_ ( UpperCAmelCase_ , unittest.TestCase ):
'''simple docstring'''
a__ : Any = DDIMPipeline
a__ : Dict = UNCONDITIONAL_IMAGE_GENERATION_PARAMS
a__ : str = PipelineTesterMixin.required_optional_params - {
"""num_images_per_prompt""",
"""latents""",
"""callback""",
"""callback_steps""",
}
a__ : int = UNCONDITIONAL_IMAGE_GENERATION_BATCH_PARAMS
a__ : List[Any] = False
def UpperCamelCase__ ( self) -> Optional[Any]:
torch.manual_seed(0)
__UpperCamelCase :Optional[int] = UNetaDModel(
block_out_channels=(32, 64) , layers_per_block=2 , sample_size=32 , in_channels=3 , out_channels=3 , down_block_types=('''DownBlock2D''', '''AttnDownBlock2D''') , up_block_types=('''AttnUpBlock2D''', '''UpBlock2D''') , )
__UpperCamelCase :Union[str, Any] = DDIMScheduler()
__UpperCamelCase :str = {'''unet''': unet, '''scheduler''': scheduler}
return components
def UpperCamelCase__ ( self , __lowercase , __lowercase=0) -> Optional[Any]:
if str(__lowercase).startswith('''mps'''):
__UpperCamelCase :Optional[Any] = torch.manual_seed(__lowercase)
else:
__UpperCamelCase :Dict = torch.Generator(device=__lowercase).manual_seed(__lowercase)
__UpperCamelCase :List[str] = {
'''batch_size''': 1,
'''generator''': generator,
'''num_inference_steps''': 2,
'''output_type''': '''numpy''',
}
return inputs
def UpperCamelCase__ ( self) -> List[Any]:
__UpperCamelCase :str = '''cpu'''
__UpperCamelCase :Tuple = self.get_dummy_components()
__UpperCamelCase :Optional[Any] = self.pipeline_class(**__lowercase)
pipe.to(__lowercase)
pipe.set_progress_bar_config(disable=__lowercase)
__UpperCamelCase :Any = self.get_dummy_inputs(__lowercase)
__UpperCamelCase :Optional[Any] = pipe(**__lowercase).images
__UpperCamelCase :Union[str, Any] = image[0, -3:, -3:, -1]
self.assertEqual(image.shape , (1, 32, 32, 3))
__UpperCamelCase :Optional[int] = np.array(
[1.0_0_0E0_0, 5.7_1_7E-0_1, 4.7_1_7E-0_1, 1.0_0_0E0_0, 0.0_0_0E0_0, 1.0_0_0E0_0, 3.0_0_0E-0_4, 0.0_0_0E0_0, 9.0_0_0E-0_4])
__UpperCamelCase :str = np.abs(image_slice.flatten() - expected_slice).max()
self.assertLessEqual(__lowercase , 1E-3)
def UpperCamelCase__ ( self) -> Union[str, Any]:
super().test_dict_tuple_outputs_equivalent(expected_max_difference=3E-3)
def UpperCamelCase__ ( self) -> Optional[int]:
super().test_save_load_local(expected_max_difference=3E-3)
def UpperCamelCase__ ( self) -> List[Any]:
super().test_save_load_optional_components(expected_max_difference=3E-3)
def UpperCamelCase__ ( self) -> Any:
super().test_inference_batch_single_identical(expected_max_diff=3E-3)
@slow
@require_torch_gpu
class lowerCamelCase_ ( unittest.TestCase ):
'''simple docstring'''
def UpperCamelCase__ ( self) -> Tuple:
__UpperCamelCase :List[str] = '''google/ddpm-cifar10-32'''
__UpperCamelCase :Union[str, Any] = UNetaDModel.from_pretrained(__lowercase)
__UpperCamelCase :str = DDIMScheduler()
__UpperCamelCase :Union[str, Any] = DDIMPipeline(unet=__lowercase , scheduler=__lowercase)
ddim.to(__lowercase)
ddim.set_progress_bar_config(disable=__lowercase)
__UpperCamelCase :List[Any] = torch.manual_seed(0)
__UpperCamelCase :Any = ddim(generator=__lowercase , eta=0.0 , output_type='''numpy''').images
__UpperCamelCase :int = image[0, -3:, -3:, -1]
assert image.shape == (1, 32, 32, 3)
__UpperCamelCase :int = np.array([0.17_23, 0.16_17, 0.16_00, 0.16_26, 0.14_97, 0.15_13, 0.15_05, 0.14_42, 0.14_53])
assert np.abs(image_slice.flatten() - expected_slice).max() < 1E-2
def UpperCamelCase__ ( self) -> List[Any]:
__UpperCamelCase :Optional[Any] = '''google/ddpm-ema-bedroom-256'''
__UpperCamelCase :List[str] = UNetaDModel.from_pretrained(__lowercase)
__UpperCamelCase :Dict = DDIMScheduler.from_pretrained(__lowercase)
__UpperCamelCase :Optional[Any] = DDIMPipeline(unet=__lowercase , scheduler=__lowercase)
ddpm.to(__lowercase)
ddpm.set_progress_bar_config(disable=__lowercase)
__UpperCamelCase :Dict = torch.manual_seed(0)
__UpperCamelCase :str = ddpm(generator=__lowercase , output_type='''numpy''').images
__UpperCamelCase :Dict = image[0, -3:, -3:, -1]
assert image.shape == (1, 256, 256, 3)
__UpperCamelCase :Tuple = np.array([0.00_60, 0.02_01, 0.03_44, 0.00_24, 0.00_18, 0.00_02, 0.00_22, 0.00_00, 0.00_69])
assert np.abs(image_slice.flatten() - expected_slice).max() < 1E-2
| 43
|
import functools
import operator
from ...configuration_utils import PretrainedConfig
from ...utils import logging
__lowercase = logging.get_logger(__name__)
__lowercase = {
'''facebook/wav2vec2-base-960h''': '''https://huggingface.co/facebook/wav2vec2-base-960h/resolve/main/config.json''',
# See all Wav2Vec2 models at https://huggingface.co/models?filter=wav2vec2
}
class lowerCamelCase_ ( UpperCAmelCase_ ):
'''simple docstring'''
a__ : Union[str, Any] = """wav2vec2"""
def __init__( self , __lowercase=32 , __lowercase=768 , __lowercase=12 , __lowercase=12 , __lowercase=3_072 , __lowercase="gelu" , __lowercase=0.1 , __lowercase=0.1 , __lowercase=0.1 , __lowercase=0.0 , __lowercase=0.0 , __lowercase=0.1 , __lowercase=0.1 , __lowercase=0.02 , __lowercase=1E-5 , __lowercase="group" , __lowercase="gelu" , __lowercase=(512, 512, 512, 512, 512, 512, 512) , __lowercase=(5, 2, 2, 2, 2, 2, 2) , __lowercase=(10, 3, 3, 3, 3, 2, 2) , __lowercase=False , __lowercase=128 , __lowercase=16 , __lowercase=False , __lowercase=True , __lowercase=0.05 , __lowercase=10 , __lowercase=2 , __lowercase=0.0 , __lowercase=10 , __lowercase=0 , __lowercase=320 , __lowercase=2 , __lowercase=0.1 , __lowercase=100 , __lowercase=256 , __lowercase=256 , __lowercase=0.1 , __lowercase="sum" , __lowercase=False , __lowercase=False , __lowercase=256 , __lowercase=(512, 512, 512, 512, 1_500) , __lowercase=(5, 3, 3, 1, 1) , __lowercase=(1, 2, 3, 1, 1) , __lowercase=512 , __lowercase=0 , __lowercase=1 , __lowercase=2 , __lowercase=False , __lowercase=3 , __lowercase=2 , __lowercase=3 , __lowercase=None , __lowercase=None , **__lowercase , ) -> int:
super().__init__(**__lowercase , pad_token_id=__lowercase , bos_token_id=__lowercase , eos_token_id=__lowercase)
__UpperCamelCase :Any = hidden_size
__UpperCamelCase :int = feat_extract_norm
__UpperCamelCase :Tuple = feat_extract_activation
__UpperCamelCase :Union[str, Any] = list(__lowercase)
__UpperCamelCase :List[Any] = list(__lowercase)
__UpperCamelCase :int = list(__lowercase)
__UpperCamelCase :List[Any] = conv_bias
__UpperCamelCase :Optional[int] = num_conv_pos_embeddings
__UpperCamelCase :Dict = num_conv_pos_embedding_groups
__UpperCamelCase :Any = len(self.conv_dim)
__UpperCamelCase :List[str] = num_hidden_layers
__UpperCamelCase :int = intermediate_size
__UpperCamelCase :str = hidden_act
__UpperCamelCase :Any = num_attention_heads
__UpperCamelCase :int = hidden_dropout
__UpperCamelCase :Tuple = attention_dropout
__UpperCamelCase :List[str] = activation_dropout
__UpperCamelCase :Optional[Any] = feat_proj_dropout
__UpperCamelCase :Any = final_dropout
__UpperCamelCase :Any = layerdrop
__UpperCamelCase :str = layer_norm_eps
__UpperCamelCase :Optional[Any] = initializer_range
__UpperCamelCase :List[str] = vocab_size
__UpperCamelCase :str = do_stable_layer_norm
__UpperCamelCase :Union[str, Any] = use_weighted_layer_sum
if (
(len(self.conv_stride) != self.num_feat_extract_layers)
or (len(self.conv_kernel) != self.num_feat_extract_layers)
or (len(self.conv_dim) != self.num_feat_extract_layers)
):
raise ValueError(
'''Configuration for convolutional layers is incorrect. It is required that `len(config.conv_dim)` =='''
''' `len(config.conv_stride)` == `len(config.conv_kernel)`, but is `len(config.conv_dim) ='''
f""" {len(self.conv_dim)}`, `len(config.conv_stride) = {len(self.conv_stride)}`,"""
f""" `len(config.conv_kernel) = {len(self.conv_kernel)}`.""")
# fine-tuning config parameters for SpecAugment: https://arxiv.org/abs/1904.08779
__UpperCamelCase :List[Any] = apply_spec_augment
__UpperCamelCase :Tuple = mask_time_prob
__UpperCamelCase :int = mask_time_length
__UpperCamelCase :Dict = mask_time_min_masks
__UpperCamelCase :str = mask_feature_prob
__UpperCamelCase :List[str] = mask_feature_length
__UpperCamelCase :Union[str, Any] = mask_feature_min_masks
# parameters for pretraining with codevector quantized representations
__UpperCamelCase :Optional[Any] = num_codevectors_per_group
__UpperCamelCase :List[Any] = num_codevector_groups
__UpperCamelCase :Tuple = contrastive_logits_temperature
__UpperCamelCase :Optional[int] = feat_quantizer_dropout
__UpperCamelCase :Optional[int] = num_negatives
__UpperCamelCase :List[Any] = codevector_dim
__UpperCamelCase :str = proj_codevector_dim
__UpperCamelCase :List[str] = diversity_loss_weight
# ctc loss
__UpperCamelCase :Tuple = ctc_loss_reduction
__UpperCamelCase :Tuple = ctc_zero_infinity
# adapter
__UpperCamelCase :List[str] = add_adapter
__UpperCamelCase :Tuple = adapter_kernel_size
__UpperCamelCase :str = adapter_stride
__UpperCamelCase :Tuple = num_adapter_layers
__UpperCamelCase :Tuple = output_hidden_size or hidden_size
__UpperCamelCase :Optional[Any] = adapter_attn_dim
# SequenceClassification-specific parameter. Feel free to ignore for other classes.
__UpperCamelCase :Optional[Any] = classifier_proj_size
# XVector-specific parameters. Feel free to ignore for other classes.
__UpperCamelCase :Optional[int] = list(__lowercase)
__UpperCamelCase :List[Any] = list(__lowercase)
__UpperCamelCase :List[Any] = list(__lowercase)
__UpperCamelCase :str = xvector_output_dim
@property
def UpperCamelCase__ ( self) -> List[str]:
return functools.reduce(operator.mul , self.conv_stride , 1)
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|
def lowerCamelCase ( SCREAMING_SNAKE_CASE = 1_000_000 ):
'''simple docstring'''
__UpperCamelCase :str = [i - 1 for i in range(limit + 1 )]
for i in range(2 , limit + 1 ):
if phi[i] == i - 1:
for j in range(2 * i , limit + 1 , SCREAMING_SNAKE_CASE ):
phi[j] -= phi[j] // i
return sum(phi[2 : limit + 1] )
if __name__ == "__main__":
print(solution())
| 43
|
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
__lowercase = logging.get_logger(__name__)
class lowerCamelCase_ ( UpperCAmelCase_ ):
'''simple docstring'''
a__ : Optional[Any] = ["""pixel_values"""]
def __init__( self , __lowercase = True , __lowercase = 32 , __lowercase=PILImageResampling.BILINEAR , __lowercase = True , **__lowercase , ) -> None:
__UpperCamelCase :Optional[int] = do_resize
__UpperCamelCase :Any = do_rescale
__UpperCamelCase :str = size_divisor
__UpperCamelCase :Dict = resample
super().__init__(**__lowercase)
def UpperCamelCase__ ( self , __lowercase , __lowercase , __lowercase , __lowercase = None , **__lowercase) -> np.ndarray:
__UpperCamelCase , __UpperCamelCase :int = get_image_size(__lowercase)
# Rounds the height and width down to the closest multiple of size_divisor
__UpperCamelCase :List[Any] = height // size_divisor * size_divisor
__UpperCamelCase :List[str] = width // size_divisor * size_divisor
__UpperCamelCase :str = resize(__lowercase , (new_h, new_w) , resample=__lowercase , data_format=__lowercase , **__lowercase)
return image
def UpperCamelCase__ ( self , __lowercase , __lowercase , __lowercase = None , **__lowercase) -> np.ndarray:
return rescale(image=__lowercase , scale=__lowercase , data_format=__lowercase , **__lowercase)
def UpperCamelCase__ ( self , __lowercase , __lowercase = None , __lowercase = None , __lowercase=None , __lowercase = None , __lowercase = None , __lowercase = ChannelDimension.FIRST , **__lowercase , ) -> BatchFeature:
__UpperCamelCase :Union[str, Any] = do_resize if do_resize is not None else self.do_resize
__UpperCamelCase :Tuple = do_rescale if do_rescale is not None else self.do_rescale
__UpperCamelCase :List[str] = size_divisor if size_divisor is not None else self.size_divisor
__UpperCamelCase :List[Any] = 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''')
__UpperCamelCase :List[Any] = make_list_of_images(__lowercase)
if not valid_images(__lowercase):
raise ValueError('''Invalid image(s)''')
# All transformations expect numpy arrays.
__UpperCamelCase :Optional[Any] = [to_numpy_array(__lowercase) for img in images]
if do_resize:
__UpperCamelCase :List[str] = [self.resize(__lowercase , size_divisor=__lowercase , resample=__lowercase) for image in images]
if do_rescale:
__UpperCamelCase :Dict = [self.rescale(__lowercase , scale=1 / 255) for image in images]
__UpperCamelCase :str = [to_channel_dimension_format(__lowercase , __lowercase) for image in images]
__UpperCamelCase :int = {'''pixel_values''': images}
return BatchFeature(data=__lowercase , tensor_type=__lowercase)
| 43
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|
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE = 0 , SCREAMING_SNAKE_CASE = 0 ):
'''simple docstring'''
__UpperCamelCase :List[Any] = right or len(SCREAMING_SNAKE_CASE ) - 1
if left > right:
return -1
elif list_data[left] == key:
return left
elif list_data[right] == key:
return right
else:
return search(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , left + 1 , right - 1 )
if __name__ == "__main__":
import doctest
doctest.testmod()
| 43
|
from __future__ import annotations
from PIL import Image
# Define glider example
__lowercase = [
[0, 1, 0, 0, 0, 0, 0, 0],
[0, 0, 1, 0, 0, 0, 0, 0],
[1, 1, 1, 0, 0, 0, 0, 0],
[0, 0, 0, 0, 0, 0, 0, 0],
[0, 0, 0, 0, 0, 0, 0, 0],
[0, 0, 0, 0, 0, 0, 0, 0],
[0, 0, 0, 0, 0, 0, 0, 0],
[0, 0, 0, 0, 0, 0, 0, 0],
]
# Define blinker example
__lowercase = [[0, 1, 0], [0, 1, 0], [0, 1, 0]]
def lowerCamelCase ( SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :int = []
for i in range(len(SCREAMING_SNAKE_CASE ) ):
__UpperCamelCase :Dict = []
for j in range(len(cells[i] ) ):
# Get the number of live neighbours
__UpperCamelCase :List[str] = 0
if i > 0 and j > 0:
neighbour_count += cells[i - 1][j - 1]
if i > 0:
neighbour_count += cells[i - 1][j]
if i > 0 and j < len(cells[i] ) - 1:
neighbour_count += cells[i - 1][j + 1]
if j > 0:
neighbour_count += cells[i][j - 1]
if j < len(cells[i] ) - 1:
neighbour_count += cells[i][j + 1]
if i < len(SCREAMING_SNAKE_CASE ) - 1 and j > 0:
neighbour_count += cells[i + 1][j - 1]
if i < len(SCREAMING_SNAKE_CASE ) - 1:
neighbour_count += cells[i + 1][j]
if i < len(SCREAMING_SNAKE_CASE ) - 1 and j < len(cells[i] ) - 1:
neighbour_count += cells[i + 1][j + 1]
# Rules of the game of life (excerpt from Wikipedia):
# 1. Any live cell with two or three live neighbours survives.
# 2. Any dead cell with three live neighbours becomes a live cell.
# 3. All other live cells die in the next generation.
# Similarly, all other dead cells stay dead.
__UpperCamelCase :List[str] = cells[i][j] == 1
if (
(alive and 2 <= neighbour_count <= 3)
or not alive
and neighbour_count == 3
):
next_generation_row.append(1 )
else:
next_generation_row.append(0 )
next_generation.append(SCREAMING_SNAKE_CASE )
return next_generation
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Optional[Any] = []
for _ in range(SCREAMING_SNAKE_CASE ):
# Create output image
__UpperCamelCase :Dict = Image.new('''RGB''' , (len(cells[0] ), len(SCREAMING_SNAKE_CASE )) )
__UpperCamelCase :Any = img.load()
# Save cells to image
for x in range(len(SCREAMING_SNAKE_CASE ) ):
for y in range(len(cells[0] ) ):
__UpperCamelCase :Optional[Any] = 255 - cells[y][x] * 255
__UpperCamelCase :int = (colour, colour, colour)
# Save image
images.append(SCREAMING_SNAKE_CASE )
__UpperCamelCase :Optional[int] = new_generation(SCREAMING_SNAKE_CASE )
return images
if __name__ == "__main__":
__lowercase = generate_images(GLIDER, 16)
images[0].save('''out.gif''', save_all=True, append_images=images[1:])
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|
import json
import multiprocessing
import os
import re
from collections import defaultdict
import torch
from accelerate import Accelerator
from accelerate.utils import set_seed
from arguments import HumanEvalArguments
from datasets import load_dataset, load_metric
from torch.utils.data import IterableDataset
from torch.utils.data.dataloader import DataLoader
from tqdm import tqdm
import transformers
from transformers import AutoModelForCausalLM, AutoTokenizer, HfArgumentParser, StoppingCriteria, StoppingCriteriaList
__lowercase = ['''\nclass''', '''\ndef''', '''\n#''', '''\n@''', '''\nprint''', '''\nif''']
class lowerCamelCase_ ( UpperCAmelCase_ ):
'''simple docstring'''
def __init__( self , __lowercase , __lowercase , __lowercase=None , __lowercase=1) -> List[Any]:
__UpperCamelCase :List[Any] = tokenizer
__UpperCamelCase :Tuple = dataset
__UpperCamelCase :Optional[Any] = len(__lowercase) if n_tasks is None else n_tasks
__UpperCamelCase :List[Any] = n_copies
def __iter__( self) -> List[Any]:
__UpperCamelCase :Tuple = []
for task in range(self.n_tasks):
# without strip, the model generate commented codes ...
prompts.append(self.tokenizer.eos_token + self.dataset[task]['''prompt'''].strip())
__UpperCamelCase :List[str] = self.tokenizer(__lowercase , padding=__lowercase , return_tensors='''pt''')
for task in range(self.n_tasks):
for _ in range(self.n_copies):
yield {
"ids": outputs.input_ids[task],
"task_id": task,
"input_len": outputs.attention_mask[task].sum(),
}
class lowerCamelCase_ ( UpperCAmelCase_ ):
'''simple docstring'''
def __init__( self , __lowercase , __lowercase , __lowercase) -> Any:
__UpperCamelCase :Optional[Any] = start_length
__UpperCamelCase :Any = eof_strings
__UpperCamelCase :int = tokenizer
def __call__( self , __lowercase , __lowercase , **__lowercase) -> Tuple:
__UpperCamelCase :Union[str, Any] = self.tokenizer.batch_decode(input_ids[:, self.start_length :])
__UpperCamelCase :Tuple = []
for decoded_generation in decoded_generations:
done.append(any(stop_string in decoded_generation for stop_string in self.eof_strings))
return all(__lowercase)
def lowerCamelCase ( SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Dict = re.split('''(%s)''' % '''|'''.join(SCREAMING_SNAKE_CASE ) , SCREAMING_SNAKE_CASE )
# last string should be ""
return "".join(string_list[:-2] )
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE=20 , **SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Dict = defaultdict(SCREAMING_SNAKE_CASE ) # dict of list of generated tokens
for step, batch in tqdm(enumerate(SCREAMING_SNAKE_CASE ) ):
with torch.no_grad():
__UpperCamelCase :str = batch['''ids'''].shape[-1]
__UpperCamelCase :List[str] = accelerator.unwrap_model(SCREAMING_SNAKE_CASE ).generate(
input_ids=batch['''ids'''][:, : batch['''input_len''']] , num_return_sequences=SCREAMING_SNAKE_CASE , **SCREAMING_SNAKE_CASE )
# each task is generated batch_size times
__UpperCamelCase :int = batch['''task_id'''].repeat(SCREAMING_SNAKE_CASE )
__UpperCamelCase :List[str] = accelerator.pad_across_processes(
SCREAMING_SNAKE_CASE , dim=1 , pad_index=tokenizer.pad_token_id )
__UpperCamelCase , __UpperCamelCase :Union[str, Any] = accelerator.gather((generated_tokens, generated_tasks) )
__UpperCamelCase :Tuple = generated_tokens.cpu().numpy()
__UpperCamelCase :Dict = generated_tasks.cpu().numpy()
for task, generated_tokens in zip(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
gen_token_dict[task].append(SCREAMING_SNAKE_CASE )
__UpperCamelCase :str = [[] for _ in range(SCREAMING_SNAKE_CASE )]
for task, generated_tokens in gen_token_dict.items():
for s in generated_tokens:
__UpperCamelCase :Any = tokenizer.decode(SCREAMING_SNAKE_CASE , skip_special_tokens=SCREAMING_SNAKE_CASE , clean_up_tokenization_spaces=SCREAMING_SNAKE_CASE )
code_gens[task].append(remove_last_block(SCREAMING_SNAKE_CASE ) )
return code_gens
def lowerCamelCase ( ):
'''simple docstring'''
__UpperCamelCase :Optional[Any] = HfArgumentParser(SCREAMING_SNAKE_CASE )
__UpperCamelCase :Any = parser.parse_args()
transformers.logging.set_verbosity_error()
# enables code execution in code_eval metric
__UpperCamelCase :Union[str, Any] = args.HF_ALLOW_CODE_EVAL
# make sure tokenizer plays nice with multiprocessing
__UpperCamelCase :Optional[int] = '''false'''
if args.num_workers is None:
__UpperCamelCase :str = multiprocessing.cpu_count()
# Use dataset load to feed to accelerate
__UpperCamelCase :int = Accelerator()
set_seed(args.seed , device_specific=SCREAMING_SNAKE_CASE )
# Load model and tokenizer
__UpperCamelCase :int = AutoTokenizer.from_pretrained(args.model_ckpt )
__UpperCamelCase :Dict = tokenizer.eos_token
__UpperCamelCase :int = AutoModelForCausalLM.from_pretrained(args.model_ckpt )
# Generation settings
__UpperCamelCase :Union[str, Any] = {
'''do_sample''': args.do_sample,
'''temperature''': args.temperature,
'''max_new_tokens''': args.max_new_tokens,
'''top_p''': args.top_p,
'''top_k''': args.top_k,
'''stopping_criteria''': StoppingCriteriaList([EndOfFunctionCriteria(0 , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )] ),
}
# Load evaluation dataset and metric
__UpperCamelCase :Union[str, Any] = load_dataset('''openai_humaneval''' )
__UpperCamelCase :List[Any] = load_metric('''code_eval''' )
__UpperCamelCase :str = args.num_tasks if args.num_tasks is not None else len(human_eval['''test'''] )
__UpperCamelCase :int = args.n_samples // args.batch_size
__UpperCamelCase :int = TokenizedDataset(SCREAMING_SNAKE_CASE , human_eval['''test'''] , n_copies=SCREAMING_SNAKE_CASE , n_tasks=SCREAMING_SNAKE_CASE )
# do not confuse args.batch_size, which is actually the num_return_sequences
__UpperCamelCase :Optional[Any] = DataLoader(SCREAMING_SNAKE_CASE , batch_size=1 )
# Run a quick test to see if code evaluation is enabled
try:
__UpperCamelCase :int = code_eval_metric.compute(references=[''''''] , predictions=[['''''']] )
except ValueError as exception:
print(
'''Code evaluation not enabled. Read the warning below carefully and then use `--HF_ALLOW_CODE_EVAL="1"`'''
''' flag to enable code evaluation.''' )
raise exception
__UpperCamelCase , __UpperCamelCase :List[Any] = accelerator.prepare(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
__UpperCamelCase :Any = complete_code(
SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , n_tasks=SCREAMING_SNAKE_CASE , batch_size=args.batch_size , **SCREAMING_SNAKE_CASE , )
if accelerator.is_main_process:
__UpperCamelCase :Optional[int] = []
for task in tqdm(range(SCREAMING_SNAKE_CASE ) ):
__UpperCamelCase :List[Any] = human_eval['''test'''][task]['''test''']
__UpperCamelCase :Any = f"""check({human_eval['test'][task]['entry_point']})"""
references.append('''\n''' + test_func + '''\n''' + entry_point )
# Evaluate completions with "code_eval" metric
__UpperCamelCase , __UpperCamelCase :Optional[Any] = code_eval_metric.compute(
references=SCREAMING_SNAKE_CASE , predictions=SCREAMING_SNAKE_CASE , num_workers=args.num_workers )
print(f"""Results: {pass_at_k}""" )
# Save results to json file
with open(args.output_file , '''w''' ) as fp:
json.dump(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
# For some reason the folliwng seems to be necessary sometimes for code_eval to work nice with multiprocessing
# https://stackoverflow.com/questions/60804599/python-multiprocessing-keeps-spawning-the-whole-script
if __name__ == "__main__":
main()
| 43
|
import re
import jax.numpy as jnp
from flax.traverse_util import flatten_dict, unflatten_dict
from jax.random import PRNGKey
from ..utils import logging
__lowercase = logging.get_logger(__name__)
def lowerCamelCase ( SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Tuple = R'''\w+[.]\d+'''
__UpperCamelCase :List[str] = re.findall(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
for pat in pats:
__UpperCamelCase :int = key.replace(SCREAMING_SNAKE_CASE , '''_'''.join(pat.split('''.''' ) ) )
return key
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Tuple = pt_tuple_key[:-1] + ('''scale''',)
if (
any('''norm''' in str_ for str_ in pt_tuple_key )
and (pt_tuple_key[-1] == "bias")
and (pt_tuple_key[:-1] + ("bias",) not in random_flax_state_dict)
and (pt_tuple_key[:-1] + ("scale",) in random_flax_state_dict)
):
__UpperCamelCase :str = pt_tuple_key[:-1] + ('''scale''',)
return renamed_pt_tuple_key, pt_tensor
elif pt_tuple_key[-1] in ["weight", "gamma"] and pt_tuple_key[:-1] + ("scale",) in random_flax_state_dict:
__UpperCamelCase :Any = pt_tuple_key[:-1] + ('''scale''',)
return renamed_pt_tuple_key, pt_tensor
# embedding
if pt_tuple_key[-1] == "weight" and pt_tuple_key[:-1] + ("embedding",) in random_flax_state_dict:
__UpperCamelCase :str = pt_tuple_key[:-1] + ('''embedding''',)
return renamed_pt_tuple_key, pt_tensor
# conv layer
__UpperCamelCase :List[str] = pt_tuple_key[:-1] + ('''kernel''',)
if pt_tuple_key[-1] == "weight" and pt_tensor.ndim == 4:
__UpperCamelCase :List[Any] = pt_tensor.transpose(2 , 3 , 1 , 0 )
return renamed_pt_tuple_key, pt_tensor
# linear layer
__UpperCamelCase :List[str] = pt_tuple_key[:-1] + ('''kernel''',)
if pt_tuple_key[-1] == "weight":
__UpperCamelCase :Any = pt_tensor.T
return renamed_pt_tuple_key, pt_tensor
# old PyTorch layer norm weight
__UpperCamelCase :int = pt_tuple_key[:-1] + ('''weight''',)
if pt_tuple_key[-1] == "gamma":
return renamed_pt_tuple_key, pt_tensor
# old PyTorch layer norm bias
__UpperCamelCase :int = pt_tuple_key[:-1] + ('''bias''',)
if pt_tuple_key[-1] == "beta":
return renamed_pt_tuple_key, pt_tensor
return pt_tuple_key, pt_tensor
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE=42 ):
'''simple docstring'''
__UpperCamelCase :Union[str, Any] = {k: v.numpy() for k, v in pt_state_dict.items()}
# Step 2: Since the model is stateless, get random Flax params
__UpperCamelCase :str = flax_model.init_weights(PRNGKey(SCREAMING_SNAKE_CASE ) )
__UpperCamelCase :int = flatten_dict(SCREAMING_SNAKE_CASE )
__UpperCamelCase :List[Any] = {}
# Need to change some parameters name to match Flax names
for pt_key, pt_tensor in pt_state_dict.items():
__UpperCamelCase :List[Any] = rename_key(SCREAMING_SNAKE_CASE )
__UpperCamelCase :List[Any] = tuple(renamed_pt_key.split('''.''' ) )
# Correctly rename weight parameters
__UpperCamelCase , __UpperCamelCase :Any = rename_key_and_reshape_tensor(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
if flax_key in random_flax_state_dict:
if flax_tensor.shape != random_flax_state_dict[flax_key].shape:
raise ValueError(
f"""PyTorch checkpoint seems to be incorrect. Weight {pt_key} was expected to be of shape """
f"""{random_flax_state_dict[flax_key].shape}, but is {flax_tensor.shape}.""" )
# also add unexpected weight so that warning is thrown
__UpperCamelCase :str = jnp.asarray(SCREAMING_SNAKE_CASE )
return unflatten_dict(SCREAMING_SNAKE_CASE )
| 43
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|
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Any = ''''''
for word_or_phrase in separated:
if not isinstance(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
raise Exception('''join() accepts only strings to be joined''' )
joined += word_or_phrase + separator
return joined.strip(SCREAMING_SNAKE_CASE )
if __name__ == "__main__":
from doctest import testmod
testmod()
| 43
|
import argparse
import torch
from ...utils import logging
from . import AlbertConfig, AlbertForPreTraining, load_tf_weights_in_albert
logging.set_verbosity_info()
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :List[Any] = AlbertConfig.from_json_file(SCREAMING_SNAKE_CASE )
print(f"""Building PyTorch model from configuration: {config}""" )
__UpperCamelCase :List[str] = AlbertForPreTraining(SCREAMING_SNAKE_CASE )
# Load weights from tf checkpoint
load_tf_weights_in_albert(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
# Save pytorch-model
print(f"""Save PyTorch model to {pytorch_dump_path}""" )
torch.save(model.state_dict() , SCREAMING_SNAKE_CASE )
if __name__ == "__main__":
__lowercase = argparse.ArgumentParser()
# Required parameters
parser.add_argument(
'''--tf_checkpoint_path''', default=None, type=str, required=True, help='''Path to the TensorFlow checkpoint path.'''
)
parser.add_argument(
'''--albert_config_file''',
default=None,
type=str,
required=True,
help=(
'''The config json file corresponding to the pre-trained ALBERT model. \n'''
'''This specifies the model architecture.'''
),
)
parser.add_argument(
'''--pytorch_dump_path''', default=None, type=str, required=True, help='''Path to the output PyTorch model.'''
)
__lowercase = parser.parse_args()
convert_tf_checkpoint_to_pytorch(args.tf_checkpoint_path, args.albert_config_file, args.pytorch_dump_path)
| 43
| 1
|
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , ):
'''simple docstring'''
__UpperCamelCase :List[Any] = [redshift, radiation_density, matter_density, dark_energy]
if any(p < 0 for p in parameters ):
raise ValueError('''All input parameters must be positive''' )
if any(p > 1 for p in parameters[1:4] ):
raise ValueError('''Relative densities cannot be greater than one''' )
else:
__UpperCamelCase :Dict = 1 - (matter_density + radiation_density + dark_energy)
__UpperCamelCase :Optional[Any] = (
radiation_density * (redshift + 1) ** 4
+ matter_density * (redshift + 1) ** 3
+ curvature * (redshift + 1) ** 2
+ dark_energy
)
__UpperCamelCase :int = hubble_constant * e_a ** (1 / 2)
return hubble
if __name__ == "__main__":
import doctest
# run doctest
doctest.testmod()
# demo LCDM approximation
__lowercase = 0.3
print(
hubble_parameter(
hubble_constant=6_8.3,
radiation_density=1e-4,
matter_density=matter_density,
dark_energy=1 - matter_density,
redshift=0,
)
)
| 43
|
import math
import qiskit
def lowerCamelCase ( SCREAMING_SNAKE_CASE = 1 , SCREAMING_SNAKE_CASE = 1 , SCREAMING_SNAKE_CASE = 1 ):
'''simple docstring'''
if (
isinstance(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
or isinstance(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
or isinstance(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
):
raise TypeError('''inputs must be integers.''' )
if (input_a < 0) or (input_a < 0) or (carry_in < 0):
raise ValueError('''inputs must be positive.''' )
if (
(math.floor(SCREAMING_SNAKE_CASE ) != input_a)
or (math.floor(SCREAMING_SNAKE_CASE ) != input_a)
or (math.floor(SCREAMING_SNAKE_CASE ) != carry_in)
):
raise ValueError('''inputs must be exact integers.''' )
if (input_a > 2) or (input_a > 2) or (carry_in > 2):
raise ValueError('''inputs must be less or equal to 2.''' )
# build registers
__UpperCamelCase :List[str] = qiskit.QuantumRegister(4 , '''qr''' )
__UpperCamelCase :str = qiskit.ClassicalRegister(2 , '''cr''' )
# list the entries
__UpperCamelCase :Tuple = [input_a, input_a, carry_in]
__UpperCamelCase :Optional[int] = qiskit.QuantumCircuit(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
for i in range(0 , 3 ):
if entry[i] == 2:
quantum_circuit.h(SCREAMING_SNAKE_CASE ) # for hadamard entries
elif entry[i] == 1:
quantum_circuit.x(SCREAMING_SNAKE_CASE ) # for 1 entries
elif entry[i] == 0:
quantum_circuit.i(SCREAMING_SNAKE_CASE ) # for 0 entries
# build the circuit
quantum_circuit.ccx(0 , 1 , 3 ) # ccx = toffoli gate
quantum_circuit.cx(0 , 1 )
quantum_circuit.ccx(1 , 2 , 3 )
quantum_circuit.cx(1 , 2 )
quantum_circuit.cx(0 , 1 )
quantum_circuit.measure([2, 3] , SCREAMING_SNAKE_CASE ) # measure the last two qbits
__UpperCamelCase :Optional[Any] = qiskit.Aer.get_backend('''aer_simulator''' )
__UpperCamelCase :Tuple = qiskit.execute(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , shots=1_000 )
return job.result().get_counts(SCREAMING_SNAKE_CASE )
if __name__ == "__main__":
print(F'Total sum count for state is: {quantum_full_adder(1, 1, 1)}')
| 43
| 1
|
from math import ceil
from typing import List, Optional, Union
import numpy as np
from ...audio_utils import mel_filter_bank, spectrogram, window_function
from ...feature_extraction_sequence_utils import BatchFeature, SequenceFeatureExtractor
from ...utils import TensorType, logging
__lowercase = logging.get_logger(__name__)
class lowerCamelCase_ ( UpperCAmelCase_ ):
'''simple docstring'''
a__ : Dict = ["""audio_values""", """audio_mask"""]
def __init__( self , __lowercase=2_048 , __lowercase=1 , __lowercase=[16, 16] , __lowercase=128 , __lowercase=44_100 , __lowercase=86 , __lowercase=2_048 , __lowercase=0.0 , **__lowercase , ) -> Optional[int]:
super().__init__(
feature_size=__lowercase , sampling_rate=__lowercase , padding_value=__lowercase , **__lowercase , )
__UpperCamelCase :Any = spectrogram_length
__UpperCamelCase :Tuple = num_channels
__UpperCamelCase :Tuple = patch_size
__UpperCamelCase :Any = feature_size // self.patch_size[1]
__UpperCamelCase :Union[str, Any] = n_fft
__UpperCamelCase :Any = sampling_rate // hop_length_to_sampling_rate
__UpperCamelCase :int = sampling_rate
__UpperCamelCase :List[str] = padding_value
__UpperCamelCase :List[Any] = mel_filter_bank(
num_frequency_bins=1 + n_fft // 2 , num_mel_filters=__lowercase , min_frequency=0.0 , max_frequency=2_20_50.0 , sampling_rate=__lowercase , norm='''slaney''' , mel_scale='''slaney''' , ).T
def UpperCamelCase__ ( self , __lowercase) -> np.ndarray:
__UpperCamelCase :str = spectrogram(
__lowercase , window_function(self.n_fft , '''hann''') , frame_length=self.n_fft , hop_length=self.hop_length , power=2.0 , mel_filters=self.mel_filters.T , log_mel='''dB''' , db_range=80.0 , )
__UpperCamelCase :Union[str, Any] = log_spec[:, :-1]
__UpperCamelCase :int = log_spec - 20.0
__UpperCamelCase :Optional[int] = np.clip(log_spec / 40.0 , -2.0 , 0.0) + 1.0
return log_spec
def __call__( self , __lowercase , __lowercase = None , __lowercase = True , __lowercase = None , __lowercase = False , __lowercase = False , **__lowercase , ) -> BatchFeature:
if sampling_rate is not None:
if sampling_rate != self.sampling_rate:
raise ValueError(
'''This feature extractor is set to support sampling rate'''
f""" of {self.sampling_rate}. Please make sure that the provided `raw_speech` input was sampled"""
f""" 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.''')
__UpperCamelCase :Dict = isinstance(__lowercase , 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 :str = is_batched_numpy or (
isinstance(__lowercase , (list, tuple)) and (isinstance(raw_speech[0] , (np.ndarray, tuple, list)))
)
if is_batched:
__UpperCamelCase :Optional[int] = [np.asarray([speech] , dtype=np.floataa).T for speech in raw_speech]
elif not is_batched and not isinstance(__lowercase , np.ndarray):
__UpperCamelCase :int = np.asarray(__lowercase , dtype=np.floataa)
elif isinstance(__lowercase , np.ndarray) and raw_speech.dtype is np.dtype(np.floataa):
__UpperCamelCase :Optional[int] = raw_speech.astype(np.floataa)
# always return batch
if not is_batched:
__UpperCamelCase :Optional[int] = [np.asarray([raw_speech]).T]
# Convert audio signals to log mel spectrograms, truncate by time axis
__UpperCamelCase :List[Any] = [
self._np_extract_fbank_features(waveform.squeeze()).T[: self.spectrogram_length] for waveform in raw_speech
]
if isinstance(audio_features[0] , __lowercase):
__UpperCamelCase :List[str] = [np.asarray(__lowercase , dtype=np.floataa) for feature in audio_features]
# Create audio attention mask
__UpperCamelCase :Dict = max(
[ceil(feature.shape[0] / self.patch_size[0]) * self.freq_len for feature in audio_features]) # The maximum number of audio patches in a batch
if return_attention_mask:
__UpperCamelCase :List[Any] = [
(ceil(feature.shape[0] / self.patch_size[0]) * self.freq_len) * [1]
+ (max_patch_len - ceil(feature.shape[0] / self.patch_size[0]) * self.freq_len) * [0]
for feature in audio_features
]
__UpperCamelCase :Union[str, Any] = np.array(__lowercase).astype(np.floataa)
# convert into correct format for padding
__UpperCamelCase :str = max_patch_len // self.freq_len * self.patch_size[0] # The maximum audio size in a batch
__UpperCamelCase :List[str] = np.ones([len(__lowercase), 1, max_time_len, self.feature_size]).astype(np.floataa)
__UpperCamelCase :List[Any] = padded_audio_features * self.padding_value
for i in range(len(__lowercase)):
__UpperCamelCase :Optional[int] = audio_features[i]
__UpperCamelCase :Any = feature
# return as BatchFeature
if return_attention_mask:
__UpperCamelCase :Optional[Any] = {'''audio_values''': padded_audio_features, '''audio_mask''': audio_mask}
else:
__UpperCamelCase :Optional[Any] = {'''audio_values''': padded_audio_features}
__UpperCamelCase :Any = BatchFeature(data=__lowercase , tensor_type=__lowercase)
return encoded_inputs
| 43
|
import random
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Optional[Any] = a[left_index]
__UpperCamelCase :Any = left_index + 1
for j in range(left_index + 1 , SCREAMING_SNAKE_CASE ):
if a[j] < pivot:
__UpperCamelCase , __UpperCamelCase :str = a[i], a[j]
i += 1
__UpperCamelCase , __UpperCamelCase :Optional[int] = a[i - 1], a[left_index]
return i - 1
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
if left < right:
__UpperCamelCase :int = random.randint(SCREAMING_SNAKE_CASE , right - 1 )
__UpperCamelCase , __UpperCamelCase :List[str] = (
a[left],
a[pivot],
) # switches the pivot with the left most bound
__UpperCamelCase :Dict = partition(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
quick_sort_random(
SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ) # recursive quicksort to the left of the pivot point
quick_sort_random(
SCREAMING_SNAKE_CASE , pivot_index + 1 , SCREAMING_SNAKE_CASE ) # recursive quicksort to the right of the pivot point
def lowerCamelCase ( ):
'''simple docstring'''
__UpperCamelCase :Tuple = input('''Enter numbers separated by a comma:\n''' ).strip()
__UpperCamelCase :Union[str, Any] = [int(SCREAMING_SNAKE_CASE ) for item in user_input.split(''',''' )]
quick_sort_random(SCREAMING_SNAKE_CASE , 0 , len(SCREAMING_SNAKE_CASE ) )
print(SCREAMING_SNAKE_CASE )
if __name__ == "__main__":
main()
| 43
| 1
|
import collections
from typing import List, Optional, Union
from ...tokenization_utils_base import BatchEncoding
from ...utils import TensorType, add_end_docstrings, add_start_docstrings, logging
from ..bert.tokenization_bert import BertTokenizer
__lowercase = logging.get_logger(__name__)
__lowercase = {'''vocab_file''': '''vocab.txt''', '''tokenizer_file''': '''tokenizer.json'''}
__lowercase = {
'''vocab_file''': {
'''facebook/dpr-ctx_encoder-single-nq-base''': (
'''https://huggingface.co/facebook/dpr-ctx_encoder-single-nq-base/resolve/main/vocab.txt'''
),
'''facebook/dpr-ctx_encoder-multiset-base''': (
'''https://huggingface.co/facebook/dpr-ctx_encoder-multiset-base/resolve/main/vocab.txt'''
),
},
'''tokenizer_file''': {
'''facebook/dpr-ctx_encoder-single-nq-base''': (
'''https://huggingface.co/facebook/dpr-ctx_encoder-single-nq-base/resolve/main/tokenizer.json'''
),
'''facebook/dpr-ctx_encoder-multiset-base''': (
'''https://huggingface.co/facebook/dpr-ctx_encoder-multiset-base/resolve/main/tokenizer.json'''
),
},
}
__lowercase = {
'''vocab_file''': {
'''facebook/dpr-question_encoder-single-nq-base''': (
'''https://huggingface.co/facebook/dpr-question_encoder-single-nq-base/resolve/main/vocab.txt'''
),
'''facebook/dpr-question_encoder-multiset-base''': (
'''https://huggingface.co/facebook/dpr-question_encoder-multiset-base/resolve/main/vocab.txt'''
),
},
'''tokenizer_file''': {
'''facebook/dpr-question_encoder-single-nq-base''': (
'''https://huggingface.co/facebook/dpr-question_encoder-single-nq-base/resolve/main/tokenizer.json'''
),
'''facebook/dpr-question_encoder-multiset-base''': (
'''https://huggingface.co/facebook/dpr-question_encoder-multiset-base/resolve/main/tokenizer.json'''
),
},
}
__lowercase = {
'''vocab_file''': {
'''facebook/dpr-reader-single-nq-base''': (
'''https://huggingface.co/facebook/dpr-reader-single-nq-base/resolve/main/vocab.txt'''
),
'''facebook/dpr-reader-multiset-base''': (
'''https://huggingface.co/facebook/dpr-reader-multiset-base/resolve/main/vocab.txt'''
),
},
'''tokenizer_file''': {
'''facebook/dpr-reader-single-nq-base''': (
'''https://huggingface.co/facebook/dpr-reader-single-nq-base/resolve/main/tokenizer.json'''
),
'''facebook/dpr-reader-multiset-base''': (
'''https://huggingface.co/facebook/dpr-reader-multiset-base/resolve/main/tokenizer.json'''
),
},
}
__lowercase = {
'''facebook/dpr-ctx_encoder-single-nq-base''': 512,
'''facebook/dpr-ctx_encoder-multiset-base''': 512,
}
__lowercase = {
'''facebook/dpr-question_encoder-single-nq-base''': 512,
'''facebook/dpr-question_encoder-multiset-base''': 512,
}
__lowercase = {
'''facebook/dpr-reader-single-nq-base''': 512,
'''facebook/dpr-reader-multiset-base''': 512,
}
__lowercase = {
'''facebook/dpr-ctx_encoder-single-nq-base''': {'''do_lower_case''': True},
'''facebook/dpr-ctx_encoder-multiset-base''': {'''do_lower_case''': True},
}
__lowercase = {
'''facebook/dpr-question_encoder-single-nq-base''': {'''do_lower_case''': True},
'''facebook/dpr-question_encoder-multiset-base''': {'''do_lower_case''': True},
}
__lowercase = {
'''facebook/dpr-reader-single-nq-base''': {'''do_lower_case''': True},
'''facebook/dpr-reader-multiset-base''': {'''do_lower_case''': True},
}
class lowerCamelCase_ ( UpperCAmelCase_ ):
'''simple docstring'''
a__ : List[Any] = VOCAB_FILES_NAMES
a__ : Optional[int] = CONTEXT_ENCODER_PRETRAINED_VOCAB_FILES_MAP
a__ : Tuple = CONTEXT_ENCODER_PRETRAINED_POSITIONAL_EMBEDDINGS_SIZES
a__ : List[str] = CONTEXT_ENCODER_PRETRAINED_INIT_CONFIGURATION
class lowerCamelCase_ ( UpperCAmelCase_ ):
'''simple docstring'''
a__ : Dict = VOCAB_FILES_NAMES
a__ : Optional[int] = QUESTION_ENCODER_PRETRAINED_VOCAB_FILES_MAP
a__ : Optional[int] = QUESTION_ENCODER_PRETRAINED_POSITIONAL_EMBEDDINGS_SIZES
a__ : Optional[Any] = QUESTION_ENCODER_PRETRAINED_INIT_CONFIGURATION
__lowercase = collections.namedtuple(
'''DPRSpanPrediction''', ['''span_score''', '''relevance_score''', '''doc_id''', '''start_index''', '''end_index''', '''text''']
)
__lowercase = collections.namedtuple('''DPRReaderOutput''', ['''start_logits''', '''end_logits''', '''relevance_logits'''])
__lowercase = r'''
Return a dictionary with the token ids of the input strings and other information to give to `.decode_best_spans`.
It converts the strings of a question and different passages (title and text) in a sequence of IDs (integers),
using the tokenizer and vocabulary. The resulting `input_ids` is a matrix of size `(n_passages, sequence_length)`
with the format:
```
[CLS] <question token ids> [SEP] <titles ids> [SEP] <texts ids>
```
Args:
questions (`str` or `List[str]`):
The questions to be encoded. You can specify one question for many passages. In this case, the question
will be duplicated like `[questions] * n_passages`. Otherwise you have to specify as many questions as in
`titles` or `texts`.
titles (`str` or `List[str]`):
The passages titles to be encoded. This can be a string or a list of strings if there are several passages.
texts (`str` or `List[str]`):
The passages texts to be encoded. This can be a string or a list of strings if there are several passages.
padding (`bool`, `str` or [`~utils.PaddingStrategy`], *optional*, defaults to `False`):
Activates and controls padding. Accepts the following values:
- `True` or `\'longest\'`: Pad to the longest sequence in the batch (or no padding if only a single sequence
if provided).
- `\'max_length\'`: Pad to a maximum length specified with the argument `max_length` or to the maximum
acceptable input length for the model if that argument is not provided.
- `False` or `\'do_not_pad\'` (default): No padding (i.e., can output a batch with sequences of different
lengths).
truncation (`bool`, `str` or [`~tokenization_utils_base.TruncationStrategy`], *optional*, defaults to `False`):
Activates and controls truncation. Accepts the following values:
- `True` or `\'longest_first\'`: Truncate to a maximum length specified with the argument `max_length` or to
the maximum acceptable input length for the model if that argument is not provided. This will truncate
token by token, removing a token from the longest sequence in the pair if a pair of sequences (or a batch
of pairs) is provided.
- `\'only_first\'`: Truncate to a maximum length specified with the argument `max_length` or to the maximum
acceptable input length for the model if that argument is not provided. This will only truncate the first
sequence of a pair if a pair of sequences (or a batch of pairs) is provided.
- `\'only_second\'`: Truncate to a maximum length specified with the argument `max_length` or to the maximum
acceptable input length for the model if that argument is not provided. This will only truncate the
second sequence of a pair if a pair of sequences (or a batch of pairs) is provided.
- `False` or `\'do_not_truncate\'` (default): No truncation (i.e., can output batch with sequence lengths
greater than the model maximum admissible input size).
max_length (`int`, *optional*):
Controls the maximum length to use by one of the truncation/padding parameters.
If left unset or set to `None`, this will use the predefined model maximum length if a maximum length
is required by one of the truncation/padding parameters. If the model has no specific maximum input
length (like XLNet) truncation/padding to a maximum length will be deactivated.
return_tensors (`str` or [`~utils.TensorType`], *optional*):
If set, will return tensors instead of list of python integers. Acceptable values are:
- `\'tf\'`: Return TensorFlow `tf.constant` objects.
- `\'pt\'`: Return PyTorch `torch.Tensor` objects.
- `\'np\'`: Return Numpy `np.ndarray` objects.
return_attention_mask (`bool`, *optional*):
Whether or not to return the attention mask. If not set, will return the attention mask according to the
specific tokenizer\'s default, defined by the `return_outputs` attribute.
[What are attention masks?](../glossary#attention-mask)
Returns:
`Dict[str, List[List[int]]]`: A dictionary with the following keys:
- `input_ids`: List of token ids to be fed to a model.
- `attention_mask`: List of indices specifying which tokens should be attended to by the model.
'''
@add_start_docstrings(UpperCAmelCase_ )
class lowerCamelCase_ :
'''simple docstring'''
def __call__( self , __lowercase , __lowercase = None , __lowercase = None , __lowercase = False , __lowercase = False , __lowercase = None , __lowercase = None , __lowercase = None , **__lowercase , ) -> BatchEncoding:
if titles is None and texts is None:
return super().__call__(
__lowercase , padding=__lowercase , truncation=__lowercase , max_length=__lowercase , return_tensors=__lowercase , return_attention_mask=__lowercase , **__lowercase , )
elif titles is None or texts is None:
__UpperCamelCase :List[Any] = titles if texts is None else texts
return super().__call__(
__lowercase , __lowercase , padding=__lowercase , truncation=__lowercase , max_length=__lowercase , return_tensors=__lowercase , return_attention_mask=__lowercase , **__lowercase , )
__UpperCamelCase :List[Any] = titles if not isinstance(__lowercase , __lowercase) else [titles]
__UpperCamelCase :int = texts if not isinstance(__lowercase , __lowercase) else [texts]
__UpperCamelCase :Optional[Any] = len(__lowercase)
__UpperCamelCase :Union[str, Any] = questions if not isinstance(__lowercase , __lowercase) else [questions] * n_passages
if len(__lowercase) != len(__lowercase):
raise ValueError(
f"""There should be as many titles than texts but got {len(__lowercase)} titles and {len(__lowercase)} texts.""")
__UpperCamelCase :Optional[int] = super().__call__(__lowercase , __lowercase , padding=__lowercase , truncation=__lowercase)['''input_ids''']
__UpperCamelCase :Tuple = super().__call__(__lowercase , add_special_tokens=__lowercase , padding=__lowercase , truncation=__lowercase)['''input_ids''']
__UpperCamelCase :Optional[Any] = {
'''input_ids''': [
(encoded_question_and_title + encoded_text)[:max_length]
if max_length is not None and truncation
else encoded_question_and_title + encoded_text
for encoded_question_and_title, encoded_text in zip(__lowercase , __lowercase)
]
}
if return_attention_mask is not False:
__UpperCamelCase :List[str] = []
for input_ids in encoded_inputs["input_ids"]:
attention_mask.append([int(input_id != self.pad_token_id) for input_id in input_ids])
__UpperCamelCase :Union[str, Any] = attention_mask
return self.pad(__lowercase , padding=__lowercase , max_length=__lowercase , return_tensors=__lowercase)
def UpperCamelCase__ ( self , __lowercase , __lowercase , __lowercase = 16 , __lowercase = 64 , __lowercase = 4 , ) -> List[DPRSpanPrediction]:
__UpperCamelCase :Union[str, Any] = reader_input['''input_ids''']
__UpperCamelCase , __UpperCamelCase , __UpperCamelCase :Any = reader_output[:3]
__UpperCamelCase :Optional[Any] = len(__lowercase)
__UpperCamelCase :List[Any] = sorted(range(__lowercase) , reverse=__lowercase , key=relevance_logits.__getitem__)
__UpperCamelCase :List[DPRReaderOutput] = []
for doc_id in sorted_docs:
__UpperCamelCase :Dict = list(input_ids[doc_id])
# assuming question & title information is at the beginning of the sequence
__UpperCamelCase :List[Any] = sequence_ids.index(self.sep_token_id , 2) + 1 # second sep id
if sequence_ids[-1] == self.pad_token_id:
__UpperCamelCase :Any = sequence_ids.index(self.pad_token_id)
else:
__UpperCamelCase :Optional[int] = len(__lowercase)
__UpperCamelCase :Dict = self._get_best_spans(
start_logits=start_logits[doc_id][passage_offset:sequence_len] , end_logits=end_logits[doc_id][passage_offset:sequence_len] , max_answer_length=__lowercase , top_spans=__lowercase , )
for start_index, end_index in best_spans:
start_index += passage_offset
end_index += passage_offset
nbest_spans_predictions.append(
DPRSpanPrediction(
span_score=start_logits[doc_id][start_index] + end_logits[doc_id][end_index] , relevance_score=relevance_logits[doc_id] , doc_id=__lowercase , start_index=__lowercase , end_index=__lowercase , text=self.decode(sequence_ids[start_index : end_index + 1]) , ))
if len(__lowercase) >= num_spans:
break
return nbest_spans_predictions[:num_spans]
def UpperCamelCase__ ( self , __lowercase , __lowercase , __lowercase , __lowercase , ) -> List[DPRSpanPrediction]:
__UpperCamelCase :Optional[int] = []
for start_index, start_score in enumerate(__lowercase):
for answer_length, end_score in enumerate(end_logits[start_index : start_index + max_answer_length]):
scores.append(((start_index, start_index + answer_length), start_score + end_score))
__UpperCamelCase :Tuple = sorted(__lowercase , key=lambda __lowercase: x[1] , reverse=__lowercase)
__UpperCamelCase :str = []
for (start_index, end_index), score in scores:
if start_index > end_index:
raise ValueError(f"""Wrong span indices: [{start_index}:{end_index}]""")
__UpperCamelCase :List[str] = end_index - start_index + 1
if length > max_answer_length:
raise ValueError(f"""Span is too long: {length} > {max_answer_length}""")
if any(
start_index <= prev_start_index <= prev_end_index <= end_index
or prev_start_index <= start_index <= end_index <= prev_end_index
for (prev_start_index, prev_end_index) in chosen_span_intervals):
continue
chosen_span_intervals.append((start_index, end_index))
if len(__lowercase) == top_spans:
break
return chosen_span_intervals
@add_end_docstrings(UpperCAmelCase_ )
class lowerCamelCase_ ( UpperCAmelCase_ , UpperCAmelCase_ ):
'''simple docstring'''
a__ : Optional[int] = VOCAB_FILES_NAMES
a__ : Dict = READER_PRETRAINED_VOCAB_FILES_MAP
a__ : Any = READER_PRETRAINED_POSITIONAL_EMBEDDINGS_SIZES
a__ : int = READER_PRETRAINED_INIT_CONFIGURATION
a__ : int = ["""input_ids""", """attention_mask"""]
| 43
|
def lowerCamelCase ( SCREAMING_SNAKE_CASE = 1 , SCREAMING_SNAKE_CASE = 1_000 ):
'''simple docstring'''
__UpperCamelCase :Union[str, Any] = 1
__UpperCamelCase :Any = 0
for divide_by_number in range(SCREAMING_SNAKE_CASE , digit + 1 ):
__UpperCamelCase :list[int] = []
__UpperCamelCase :Optional[int] = numerator
for _ in range(1 , digit + 1 ):
if now_divide in has_been_divided:
if longest_list_length < len(SCREAMING_SNAKE_CASE ):
__UpperCamelCase :Optional[Any] = len(SCREAMING_SNAKE_CASE )
__UpperCamelCase :int = divide_by_number
else:
has_been_divided.append(SCREAMING_SNAKE_CASE )
__UpperCamelCase :Any = now_divide * 10 % divide_by_number
return the_digit
# Tests
if __name__ == "__main__":
import doctest
doctest.testmod()
| 43
| 1
|
from math import factorial
__lowercase = {str(digit): factorial(digit) for digit in range(10)}
def lowerCamelCase ( SCREAMING_SNAKE_CASE ):
'''simple docstring'''
if not isinstance(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
raise TypeError('''Parameter number must be int''' )
if number < 0:
raise ValueError('''Parameter number must be greater than or equal to 0''' )
# Converts number in string to iterate on its digits and adds its factorial.
return sum(DIGIT_FACTORIAL[digit] for digit in str(SCREAMING_SNAKE_CASE ) )
def lowerCamelCase ( SCREAMING_SNAKE_CASE = 60 , SCREAMING_SNAKE_CASE = 1_000_000 ):
'''simple docstring'''
if not isinstance(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ) or not isinstance(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
raise TypeError('''Parameters chain_length and number_limit must be int''' )
if chain_length <= 0 or number_limit <= 0:
raise ValueError(
'''Parameters chain_length and number_limit must be greater than 0''' )
# the counter for the chains with the exact desired length
__UpperCamelCase :Dict = 0
# the cached sizes of the previous chains
__UpperCamelCase :dict[int, int] = {}
for start_chain_element in range(1 , SCREAMING_SNAKE_CASE ):
# The temporary set will contain the elements of the chain
__UpperCamelCase :Tuple = set()
__UpperCamelCase :Union[str, Any] = 0
# Stop computing the chain when you find a cached size, a repeating item or the
# length is greater then the desired one.
__UpperCamelCase :Dict = start_chain_element
while (
chain_element not in chain_sets_lengths
and chain_element not in chain_set
and chain_set_length <= chain_length
):
chain_set.add(SCREAMING_SNAKE_CASE )
chain_set_length += 1
__UpperCamelCase :Tuple = digit_factorial_sum(SCREAMING_SNAKE_CASE )
if chain_element in chain_sets_lengths:
chain_set_length += chain_sets_lengths[chain_element]
__UpperCamelCase :Tuple = chain_set_length
# If chain contains the exact amount of elements increase the counter
if chain_set_length == chain_length:
chains_counter += 1
return chains_counter
if __name__ == "__main__":
import doctest
doctest.testmod()
print(F'{solution()}')
| 43
|
import argparse
import json
from tqdm import tqdm
def lowerCamelCase ( ):
'''simple docstring'''
__UpperCamelCase :Tuple = argparse.ArgumentParser()
# Required parameters
parser.add_argument(
'''--src_path''' , type=SCREAMING_SNAKE_CASE , default='''biencoder-nq-dev.json''' , help='''Path to raw DPR training data''' , )
parser.add_argument(
'''--evaluation_set''' , type=SCREAMING_SNAKE_CASE , help='''where to store parsed evaluation_set file''' , )
parser.add_argument(
'''--gold_data_path''' , type=SCREAMING_SNAKE_CASE , help='''where to store parsed gold_data_path file''' , )
__UpperCamelCase :str = parser.parse_args()
with open(args.src_path , '''r''' ) as src_file, open(args.evaluation_set , '''w''' ) as eval_file, open(
args.gold_data_path , '''w''' ) as gold_file:
__UpperCamelCase :List[str] = json.load(SCREAMING_SNAKE_CASE )
for dpr_record in tqdm(SCREAMING_SNAKE_CASE ):
__UpperCamelCase :List[str] = dpr_record['''question''']
__UpperCamelCase :Tuple = [context['''title'''] for context in dpr_record['''positive_ctxs''']]
eval_file.write(question + '''\n''' )
gold_file.write('''\t'''.join(SCREAMING_SNAKE_CASE ) + '''\n''' )
if __name__ == "__main__":
main()
| 43
| 1
|
from __future__ import annotations
def lowerCamelCase ( SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Dict = str(SCREAMING_SNAKE_CASE )
return len(SCREAMING_SNAKE_CASE ) == 9 and set(SCREAMING_SNAKE_CASE ) == set('''123456789''' )
def lowerCamelCase ( ):
'''simple docstring'''
for base_num in range(9_999 , 4_999 , -1 ):
__UpperCamelCase :Any = 100_002 * base_num
if is_9_pandigital(SCREAMING_SNAKE_CASE ):
return candidate
for base_num in range(333 , 99 , -1 ):
__UpperCamelCase :Optional[Any] = 1_002_003 * base_num
if is_9_pandigital(SCREAMING_SNAKE_CASE ):
return candidate
return None
if __name__ == "__main__":
print(F'{solution() = }')
| 43
|
from __future__ import annotations
import random
# Maximum size of the population. Bigger could be faster but is more memory expensive.
__lowercase = 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.
__lowercase = 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.
__lowercase = 0.4
# Just a seed to improve randomness required by the algorithm.
random.seed(random.randint(0, 1000))
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Any = len([g for position, g in enumerate(SCREAMING_SNAKE_CASE ) if g == main_target[position]] )
return (item, float(SCREAMING_SNAKE_CASE ))
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Optional[Any] = random.randint(0 , len(SCREAMING_SNAKE_CASE ) - 1 )
__UpperCamelCase :Tuple = parent_a[:random_slice] + parent_a[random_slice:]
__UpperCamelCase :Union[str, Any] = parent_a[:random_slice] + parent_a[random_slice:]
return (child_a, child_a)
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :int = list(SCREAMING_SNAKE_CASE )
if random.uniform(0 , 1 ) < MUTATION_PROBABILITY:
__UpperCamelCase :str = random.choice(SCREAMING_SNAKE_CASE )
return "".join(SCREAMING_SNAKE_CASE )
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , ):
'''simple docstring'''
__UpperCamelCase :int = []
# Generate more children proportionally to the fitness score.
__UpperCamelCase :int = int(parent_a[1] * 100 ) + 1
__UpperCamelCase :List[str] = 10 if child_n >= 10 else child_n
for _ in range(SCREAMING_SNAKE_CASE ):
__UpperCamelCase :Optional[Any] = population_score[random.randint(0 , SCREAMING_SNAKE_CASE )][0]
__UpperCamelCase , __UpperCamelCase :Any = crossover(parent_a[0] , SCREAMING_SNAKE_CASE )
# Append new string to the population list.
pop.append(mutate(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ) )
pop.append(mutate(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ) )
return pop
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE = True ):
'''simple docstring'''
if N_POPULATION < N_SELECTED:
__UpperCamelCase :List[Any] = f"""{N_POPULATION} must be bigger than {N_SELECTED}"""
raise ValueError(SCREAMING_SNAKE_CASE )
# Verify that the target contains no genes besides the ones inside genes variable.
__UpperCamelCase :List[str] = sorted({c for c in target if c not in genes} )
if not_in_genes_list:
__UpperCamelCase :Optional[int] = f"""{not_in_genes_list} is not in genes list, evolution cannot converge"""
raise ValueError(SCREAMING_SNAKE_CASE )
# Generate random starting population.
__UpperCamelCase :int = []
for _ in range(SCREAMING_SNAKE_CASE ):
population.append(''''''.join([random.choice(SCREAMING_SNAKE_CASE ) for i in range(len(SCREAMING_SNAKE_CASE ) )] ) )
# Just some logs to know what the algorithms is doing.
__UpperCamelCase , __UpperCamelCase :List[Any] = 0, 0
# This loop will end when we find a perfect match for our target.
while True:
generation += 1
total_population += len(SCREAMING_SNAKE_CASE )
# 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.
__UpperCamelCase :Tuple = [evaluate(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ) for item in population]
# Check if there is a matching evolution.
__UpperCamelCase :Tuple = sorted(SCREAMING_SNAKE_CASE , key=lambda SCREAMING_SNAKE_CASE : x[1] , reverse=SCREAMING_SNAKE_CASE )
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.
__UpperCamelCase :str = population[: int(N_POPULATION / 3 )]
population.clear()
population.extend(SCREAMING_SNAKE_CASE )
# Normalize population score to be between 0 and 1.
__UpperCamelCase :Union[str, Any] = [
(item, score / len(SCREAMING_SNAKE_CASE )) for item, score in population_score
]
# This is selection
for i in range(SCREAMING_SNAKE_CASE ):
population.extend(select(population_score[int(SCREAMING_SNAKE_CASE )] , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ) )
# 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(SCREAMING_SNAKE_CASE ) > N_POPULATION:
break
if __name__ == "__main__":
__lowercase = (
'''This is a genetic algorithm to evaluate, combine, evolve, and mutate a string!'''
)
__lowercase = list(
''' ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklm'''
'''nopqrstuvwxyz.,;!?+-*#@^\'èéòà€ù=)(&%$£/\\'''
)
__lowercase , __lowercase , __lowercase = basic(target_str, genes_list)
print(
F'\nGeneration: {generation}\nTotal Population: {population}\nTarget: {target}'
)
| 43
| 1
|
import glob
import os
import random
from string import ascii_lowercase, digits
import cva
import numpy as np
# Parrameters
__lowercase = (720, 1280) # Height, Width
__lowercase = (0.4, 0.6) # if height or width lower than this scale, drop it.
__lowercase = 1 / 100
__lowercase = ''''''
__lowercase = ''''''
__lowercase = ''''''
__lowercase = 250
def lowerCamelCase ( ):
'''simple docstring'''
__UpperCamelCase , __UpperCamelCase :List[Any] = get_dataset(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
for index in range(SCREAMING_SNAKE_CASE ):
__UpperCamelCase :Optional[Any] = random.sample(range(len(SCREAMING_SNAKE_CASE ) ) , 4 )
__UpperCamelCase , __UpperCamelCase , __UpperCamelCase :str = update_image_and_anno(
SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , filter_scale=SCREAMING_SNAKE_CASE , )
# Get random string code: '7b7ad245cdff75241935e4dd860f3bad'
__UpperCamelCase :List[Any] = random_chars(32 )
__UpperCamelCase :List[str] = path.split(os.sep )[-1].rsplit('''.''' , 1 )[0]
__UpperCamelCase :Tuple = f"""{OUTPUT_DIR}/{file_name}_MOSAIC_{letter_code}"""
cva.imwrite(f"""{file_root}.jpg""" , SCREAMING_SNAKE_CASE , [cva.IMWRITE_JPEG_QUALITY, 85] )
print(f"""Succeeded {index+1}/{NUMBER_IMAGES} with {file_name}""" )
__UpperCamelCase :Optional[Any] = []
for anno in new_annos:
__UpperCamelCase :int = anno[3] - anno[1]
__UpperCamelCase :Optional[int] = anno[4] - anno[2]
__UpperCamelCase :int = anno[1] + width / 2
__UpperCamelCase :List[str] = anno[2] + height / 2
__UpperCamelCase :str = f"""{anno[0]} {x_center} {y_center} {width} {height}"""
annos_list.append(SCREAMING_SNAKE_CASE )
with open(f"""{file_root}.txt""" , '''w''' ) as outfile:
outfile.write('''\n'''.join(line for line in annos_list ) )
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :str = []
__UpperCamelCase :str = []
for label_file in glob.glob(os.path.join(SCREAMING_SNAKE_CASE , '''*.txt''' ) ):
__UpperCamelCase :Any = label_file.split(os.sep )[-1].rsplit('''.''' , 1 )[0]
with open(SCREAMING_SNAKE_CASE ) as in_file:
__UpperCamelCase :str = in_file.readlines()
__UpperCamelCase :Optional[int] = os.path.join(SCREAMING_SNAKE_CASE , f"""{label_name}.jpg""" )
__UpperCamelCase :int = []
for obj_list in obj_lists:
__UpperCamelCase :Optional[int] = obj_list.rstrip('''\n''' ).split(''' ''' )
__UpperCamelCase :Any = float(obj[1] ) - float(obj[3] ) / 2
__UpperCamelCase :List[str] = float(obj[2] ) - float(obj[4] ) / 2
__UpperCamelCase :Dict = float(obj[1] ) + float(obj[3] ) / 2
__UpperCamelCase :List[str] = float(obj[2] ) + float(obj[4] ) / 2
boxes.append([int(obj[0] ), xmin, ymin, xmax, ymax] )
if not boxes:
continue
img_paths.append(SCREAMING_SNAKE_CASE )
labels.append(SCREAMING_SNAKE_CASE )
return img_paths, labels
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE = 0.0 , ):
'''simple docstring'''
__UpperCamelCase :List[str] = np.zeros([output_size[0], output_size[1], 3] , dtype=np.uinta )
__UpperCamelCase :List[Any] = scale_range[0] + random.random() * (scale_range[1] - scale_range[0])
__UpperCamelCase :int = scale_range[0] + random.random() * (scale_range[1] - scale_range[0])
__UpperCamelCase :Optional[int] = int(scale_x * output_size[1] )
__UpperCamelCase :Any = int(scale_y * output_size[0] )
__UpperCamelCase :List[str] = []
__UpperCamelCase :Dict = []
for i, index in enumerate(SCREAMING_SNAKE_CASE ):
__UpperCamelCase :Any = all_img_list[index]
path_list.append(SCREAMING_SNAKE_CASE )
__UpperCamelCase :Any = all_annos[index]
__UpperCamelCase :Union[str, Any] = cva.imread(SCREAMING_SNAKE_CASE )
if i == 0: # top-left
__UpperCamelCase :str = cva.resize(SCREAMING_SNAKE_CASE , (divid_point_x, divid_point_y) )
__UpperCamelCase :Union[str, Any] = img
for bbox in img_annos:
__UpperCamelCase :Union[str, Any] = bbox[1] * scale_x
__UpperCamelCase :Optional[Any] = bbox[2] * scale_y
__UpperCamelCase :int = bbox[3] * scale_x
__UpperCamelCase :Union[str, Any] = bbox[4] * scale_y
new_anno.append([bbox[0], xmin, ymin, xmax, ymax] )
elif i == 1: # top-right
__UpperCamelCase :str = cva.resize(SCREAMING_SNAKE_CASE , (output_size[1] - divid_point_x, divid_point_y) )
__UpperCamelCase :List[str] = img
for bbox in img_annos:
__UpperCamelCase :str = scale_x + bbox[1] * (1 - scale_x)
__UpperCamelCase :Dict = bbox[2] * scale_y
__UpperCamelCase :Optional[Any] = scale_x + bbox[3] * (1 - scale_x)
__UpperCamelCase :List[Any] = bbox[4] * scale_y
new_anno.append([bbox[0], xmin, ymin, xmax, ymax] )
elif i == 2: # bottom-left
__UpperCamelCase :str = cva.resize(SCREAMING_SNAKE_CASE , (divid_point_x, output_size[0] - divid_point_y) )
__UpperCamelCase :Optional[int] = img
for bbox in img_annos:
__UpperCamelCase :Tuple = bbox[1] * scale_x
__UpperCamelCase :Optional[Any] = scale_y + bbox[2] * (1 - scale_y)
__UpperCamelCase :Tuple = bbox[3] * scale_x
__UpperCamelCase :Dict = scale_y + bbox[4] * (1 - scale_y)
new_anno.append([bbox[0], xmin, ymin, xmax, ymax] )
else: # bottom-right
__UpperCamelCase :Optional[int] = cva.resize(
SCREAMING_SNAKE_CASE , (output_size[1] - divid_point_x, output_size[0] - divid_point_y) )
__UpperCamelCase :Optional[int] = img
for bbox in img_annos:
__UpperCamelCase :Optional[Any] = scale_x + bbox[1] * (1 - scale_x)
__UpperCamelCase :Optional[int] = scale_y + bbox[2] * (1 - scale_y)
__UpperCamelCase :Optional[Any] = scale_x + bbox[3] * (1 - scale_x)
__UpperCamelCase :int = scale_y + bbox[4] * (1 - scale_y)
new_anno.append([bbox[0], xmin, ymin, xmax, ymax] )
# Remove bounding box small than scale of filter
if filter_scale > 0:
__UpperCamelCase :List[Any] = [
anno
for anno in new_anno
if filter_scale < (anno[3] - anno[1]) and filter_scale < (anno[4] - anno[2])
]
return output_img, new_anno, path_list[0]
def lowerCamelCase ( SCREAMING_SNAKE_CASE ):
'''simple docstring'''
assert number_char > 1, "The number of character should greater than 1"
__UpperCamelCase :Optional[Any] = ascii_lowercase + digits
return "".join(random.choice(SCREAMING_SNAKE_CASE ) for _ in range(SCREAMING_SNAKE_CASE ) )
if __name__ == "__main__":
main()
print('''DONE ✅''')
| 43
|
import argparse
import json
import os
import evaluate
import torch
from datasets import load_dataset
from torch.optim import AdamW
from torch.utils.data import DataLoader
from transformers import AutoModelForSequenceClassification, AutoTokenizer, get_linear_schedule_with_warmup, set_seed
from accelerate import Accelerator, DistributedType
from accelerate.utils.deepspeed import DummyOptim, DummyScheduler
__lowercase = 16
__lowercase = 32
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE = 16 , SCREAMING_SNAKE_CASE = "bert-base-cased" ):
'''simple docstring'''
__UpperCamelCase :List[str] = AutoTokenizer.from_pretrained(SCREAMING_SNAKE_CASE )
__UpperCamelCase :Any = load_dataset('''glue''' , '''mrpc''' )
def tokenize_function(SCREAMING_SNAKE_CASE ):
# max_length=None => use the model max length (it's actually the default)
__UpperCamelCase :int = tokenizer(examples['''sentence1'''] , examples['''sentence2'''] , truncation=SCREAMING_SNAKE_CASE , max_length=SCREAMING_SNAKE_CASE )
return outputs
# Apply the method we just defined to all the examples in all the splits of the dataset
__UpperCamelCase :Tuple = datasets.map(
SCREAMING_SNAKE_CASE , batched=SCREAMING_SNAKE_CASE , remove_columns=['''idx''', '''sentence1''', '''sentence2'''] , load_from_cache_file=SCREAMING_SNAKE_CASE )
# We also rename the 'label' column to 'labels' which is the expected name for labels by the models of the
# transformers library
__UpperCamelCase :List[str] = tokenized_datasets.rename_column('''label''' , '''labels''' )
def collate_fn(SCREAMING_SNAKE_CASE ):
# On TPU it's best to pad everything to the same length or training will be very slow.
if accelerator.distributed_type == DistributedType.TPU:
return tokenizer.pad(SCREAMING_SNAKE_CASE , padding='''max_length''' , max_length=128 , return_tensors='''pt''' )
return tokenizer.pad(SCREAMING_SNAKE_CASE , padding='''longest''' , return_tensors='''pt''' )
# Instantiate dataloaders.
__UpperCamelCase :Union[str, Any] = DataLoader(
tokenized_datasets['''train'''] , shuffle=SCREAMING_SNAKE_CASE , collate_fn=SCREAMING_SNAKE_CASE , batch_size=SCREAMING_SNAKE_CASE )
__UpperCamelCase :Dict = DataLoader(
tokenized_datasets['''validation'''] , shuffle=SCREAMING_SNAKE_CASE , collate_fn=SCREAMING_SNAKE_CASE , batch_size=SCREAMING_SNAKE_CASE )
return train_dataloader, eval_dataloader
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :List[Any] = Accelerator()
# Sample hyper-parameters for learning rate, batch size, seed and a few other HPs
__UpperCamelCase :int = config['''lr''']
__UpperCamelCase :str = int(config['''num_epochs'''] )
__UpperCamelCase :Any = int(config['''seed'''] )
__UpperCamelCase :Dict = int(config['''batch_size'''] )
__UpperCamelCase :Optional[Any] = args.model_name_or_path
set_seed(SCREAMING_SNAKE_CASE )
__UpperCamelCase , __UpperCamelCase :Dict = get_dataloaders(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
# Instantiate the model (we build the model here so that the seed also control new weights initialization)
__UpperCamelCase :Any = AutoModelForSequenceClassification.from_pretrained(SCREAMING_SNAKE_CASE , return_dict=SCREAMING_SNAKE_CASE )
# Instantiate optimizer
__UpperCamelCase :List[str] = (
AdamW
if accelerator.state.deepspeed_plugin is None
or '''optimizer''' not in accelerator.state.deepspeed_plugin.deepspeed_config
else DummyOptim
)
__UpperCamelCase :Optional[Any] = optimizer_cls(params=model.parameters() , lr=SCREAMING_SNAKE_CASE )
if accelerator.state.deepspeed_plugin is not None:
__UpperCamelCase :Dict = accelerator.state.deepspeed_plugin.deepspeed_config[
'''gradient_accumulation_steps'''
]
else:
__UpperCamelCase :Dict = 1
__UpperCamelCase :Tuple = (len(SCREAMING_SNAKE_CASE ) * num_epochs) // gradient_accumulation_steps
# Instantiate scheduler
if (
accelerator.state.deepspeed_plugin is None
or "scheduler" not in accelerator.state.deepspeed_plugin.deepspeed_config
):
__UpperCamelCase :str = get_linear_schedule_with_warmup(
optimizer=SCREAMING_SNAKE_CASE , num_warmup_steps=0 , num_training_steps=SCREAMING_SNAKE_CASE , )
else:
__UpperCamelCase :Dict = DummyScheduler(SCREAMING_SNAKE_CASE , total_num_steps=SCREAMING_SNAKE_CASE , warmup_num_steps=0 )
# Prepare everything
# There is no specific order to remember, we just need to unpack the objects in the same order we gave them to the
# prepare method.
__UpperCamelCase , __UpperCamelCase , __UpperCamelCase , __UpperCamelCase , __UpperCamelCase :int = accelerator.prepare(
SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
# We need to keep track of how many total steps we have iterated over
__UpperCamelCase :List[Any] = 0
# We also need to keep track of the stating epoch so files are named properly
__UpperCamelCase :Dict = 0
# Now we train the model
__UpperCamelCase :Any = evaluate.load('''glue''' , '''mrpc''' )
__UpperCamelCase :Union[str, Any] = 0
__UpperCamelCase :Optional[int] = {}
for epoch in range(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
model.train()
for step, batch in enumerate(SCREAMING_SNAKE_CASE ):
__UpperCamelCase :Optional[Any] = model(**SCREAMING_SNAKE_CASE )
__UpperCamelCase :Tuple = outputs.loss
__UpperCamelCase :str = loss / gradient_accumulation_steps
accelerator.backward(SCREAMING_SNAKE_CASE )
if step % gradient_accumulation_steps == 0:
optimizer.step()
lr_scheduler.step()
optimizer.zero_grad()
overall_step += 1
model.eval()
__UpperCamelCase :Any = 0
for step, batch in enumerate(SCREAMING_SNAKE_CASE ):
# We could avoid this line since we set the accelerator with `device_placement=True`.
batch.to(accelerator.device )
with torch.no_grad():
__UpperCamelCase :Any = model(**SCREAMING_SNAKE_CASE )
__UpperCamelCase :Optional[int] = outputs.logits.argmax(dim=-1 )
# It is slightly faster to call this once, than multiple times
__UpperCamelCase , __UpperCamelCase :List[Any] = accelerator.gather(
(predictions, batch['''labels''']) ) # If we are in a multiprocess environment, the last batch has duplicates
if accelerator.use_distributed:
if step == len(SCREAMING_SNAKE_CASE ) - 1:
__UpperCamelCase :List[str] = predictions[: len(eval_dataloader.dataset ) - samples_seen]
__UpperCamelCase :Optional[int] = references[: len(eval_dataloader.dataset ) - samples_seen]
else:
samples_seen += references.shape[0]
metric.add_batch(
predictions=SCREAMING_SNAKE_CASE , references=SCREAMING_SNAKE_CASE , )
__UpperCamelCase :Dict = metric.compute()
# Use accelerator.print to print only on the main process.
accelerator.print(f"""epoch {epoch}:""" , SCREAMING_SNAKE_CASE )
__UpperCamelCase :str = eval_metric['''accuracy''']
if best_performance < eval_metric["accuracy"]:
__UpperCamelCase :int = eval_metric['''accuracy''']
if args.performance_lower_bound is not None:
assert (
args.performance_lower_bound <= best_performance
), f"""Best performance metric {best_performance} is lower than the lower bound {args.performance_lower_bound}"""
accelerator.wait_for_everyone()
if accelerator.is_main_process:
with open(os.path.join(args.output_dir , '''all_results.json''' ) , '''w''' ) as f:
json.dump(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
def lowerCamelCase ( ):
'''simple docstring'''
__UpperCamelCase :Tuple = argparse.ArgumentParser(description='''Simple example of training script tracking peak GPU memory usage.''' )
parser.add_argument(
'''--model_name_or_path''' , type=SCREAMING_SNAKE_CASE , default='''bert-base-cased''' , help='''Path to pretrained model or model identifier from huggingface.co/models.''' , required=SCREAMING_SNAKE_CASE , )
parser.add_argument(
'''--output_dir''' , type=SCREAMING_SNAKE_CASE , default='''.''' , help='''Optional save directory where all checkpoint folders will be stored. Default is the current working directory.''' , )
parser.add_argument(
'''--performance_lower_bound''' , type=SCREAMING_SNAKE_CASE , default=SCREAMING_SNAKE_CASE , help='''Optional lower bound for the performance metric. If set, the training will throw error when the performance metric drops below this value.''' , )
parser.add_argument(
'''--num_epochs''' , type=SCREAMING_SNAKE_CASE , default=3 , help='''Number of train epochs.''' , )
__UpperCamelCase :List[str] = parser.parse_args()
__UpperCamelCase :Tuple = {'''lr''': 2e-5, '''num_epochs''': args.num_epochs, '''seed''': 42, '''batch_size''': 16}
training_function(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
if __name__ == "__main__":
main()
| 43
| 1
|
from __future__ import annotations
class lowerCamelCase_ :
'''simple docstring'''
def __init__( self , __lowercase) -> None:
__UpperCamelCase :Optional[int] = data
__UpperCamelCase :Node | None = None
__UpperCamelCase :Node | None = None
def lowerCamelCase ( SCREAMING_SNAKE_CASE ): # In Order traversal of the tree
'''simple docstring'''
if tree:
display(tree.left )
print(tree.data )
display(tree.right )
def lowerCamelCase ( SCREAMING_SNAKE_CASE ):
'''simple docstring'''
return 1 + max(depth_of_tree(tree.left ) , depth_of_tree(tree.right ) ) if tree else 0
def lowerCamelCase ( SCREAMING_SNAKE_CASE ):
'''simple docstring'''
if not tree:
return True
if tree.left and tree.right:
return is_full_binary_tree(tree.left ) and is_full_binary_tree(tree.right )
else:
return not tree.left and not tree.right
def lowerCamelCase ( ): # Main function for testing.
'''simple docstring'''
__UpperCamelCase :int = Node(1 )
__UpperCamelCase :Dict = Node(2 )
__UpperCamelCase :List[str] = Node(3 )
__UpperCamelCase :Optional[int] = Node(4 )
__UpperCamelCase :Optional[Any] = Node(5 )
__UpperCamelCase :List[str] = Node(6 )
__UpperCamelCase :str = Node(7 )
__UpperCamelCase :Dict = Node(8 )
__UpperCamelCase :Optional[int] = Node(9 )
print(is_full_binary_tree(SCREAMING_SNAKE_CASE ) )
print(depth_of_tree(SCREAMING_SNAKE_CASE ) )
print('''Tree is: ''' )
display(SCREAMING_SNAKE_CASE )
if __name__ == "__main__":
main()
| 43
|
import copy
from ...configuration_utils import PretrainedConfig
from ...utils import logging
from ..auto import CONFIG_MAPPING
__lowercase = logging.get_logger(__name__)
__lowercase = {
'''SenseTime/deformable-detr''': '''https://huggingface.co/sensetime/deformable-detr/resolve/main/config.json''',
# See all Deformable DETR models at https://huggingface.co/models?filter=deformable-detr
}
class lowerCamelCase_ ( UpperCAmelCase_ ):
'''simple docstring'''
a__ : List[str] = """deformable_detr"""
a__ : Union[str, Any] = {
"""hidden_size""": """d_model""",
"""num_attention_heads""": """encoder_attention_heads""",
}
def __init__( self , __lowercase=True , __lowercase=None , __lowercase=3 , __lowercase=300 , __lowercase=1_024 , __lowercase=6 , __lowercase=1_024 , __lowercase=8 , __lowercase=6 , __lowercase=1_024 , __lowercase=8 , __lowercase=0.0 , __lowercase=True , __lowercase="relu" , __lowercase=256 , __lowercase=0.1 , __lowercase=0.0 , __lowercase=0.0 , __lowercase=0.02 , __lowercase=1.0 , __lowercase=True , __lowercase=False , __lowercase="sine" , __lowercase="resnet50" , __lowercase=True , __lowercase=False , __lowercase=4 , __lowercase=4 , __lowercase=4 , __lowercase=False , __lowercase=300 , __lowercase=False , __lowercase=1 , __lowercase=5 , __lowercase=2 , __lowercase=1 , __lowercase=1 , __lowercase=5 , __lowercase=2 , __lowercase=0.1 , __lowercase=0.25 , __lowercase=False , **__lowercase , ) -> int:
if backbone_config is not None and use_timm_backbone:
raise ValueError('''You can\'t specify both `backbone_config` and `use_timm_backbone`.''')
if not use_timm_backbone:
if backbone_config is None:
logger.info('''`backbone_config` is `None`. Initializing the config with the default `ResNet` backbone.''')
__UpperCamelCase :str = CONFIG_MAPPING['''resnet'''](out_features=['''stage4'''])
elif isinstance(__lowercase , __lowercase):
__UpperCamelCase :str = backbone_config.get('''model_type''')
__UpperCamelCase :Tuple = CONFIG_MAPPING[backbone_model_type]
__UpperCamelCase :Any = config_class.from_dict(__lowercase)
__UpperCamelCase :int = use_timm_backbone
__UpperCamelCase :Dict = backbone_config
__UpperCamelCase :Any = num_channels
__UpperCamelCase :Optional[int] = num_queries
__UpperCamelCase :Any = max_position_embeddings
__UpperCamelCase :str = d_model
__UpperCamelCase :Tuple = encoder_ffn_dim
__UpperCamelCase :Union[str, Any] = encoder_layers
__UpperCamelCase :List[Any] = encoder_attention_heads
__UpperCamelCase :Any = decoder_ffn_dim
__UpperCamelCase :List[str] = decoder_layers
__UpperCamelCase :int = decoder_attention_heads
__UpperCamelCase :str = dropout
__UpperCamelCase :Any = attention_dropout
__UpperCamelCase :int = activation_dropout
__UpperCamelCase :List[Any] = activation_function
__UpperCamelCase :List[Any] = init_std
__UpperCamelCase :List[Any] = init_xavier_std
__UpperCamelCase :int = encoder_layerdrop
__UpperCamelCase :str = auxiliary_loss
__UpperCamelCase :Optional[Any] = position_embedding_type
__UpperCamelCase :Union[str, Any] = backbone
__UpperCamelCase :Any = use_pretrained_backbone
__UpperCamelCase :str = dilation
# deformable attributes
__UpperCamelCase :Optional[Any] = num_feature_levels
__UpperCamelCase :str = encoder_n_points
__UpperCamelCase :int = decoder_n_points
__UpperCamelCase :Union[str, Any] = two_stage
__UpperCamelCase :Optional[Any] = two_stage_num_proposals
__UpperCamelCase :Dict = with_box_refine
if two_stage is True and with_box_refine is False:
raise ValueError('''If two_stage is True, with_box_refine must be True.''')
# Hungarian matcher
__UpperCamelCase :Optional[int] = class_cost
__UpperCamelCase :List[Any] = bbox_cost
__UpperCamelCase :str = giou_cost
# Loss coefficients
__UpperCamelCase :Tuple = mask_loss_coefficient
__UpperCamelCase :Tuple = dice_loss_coefficient
__UpperCamelCase :int = bbox_loss_coefficient
__UpperCamelCase :Any = giou_loss_coefficient
__UpperCamelCase :Dict = eos_coefficient
__UpperCamelCase :Optional[Any] = focal_alpha
__UpperCamelCase :Optional[Any] = disable_custom_kernels
super().__init__(is_encoder_decoder=__lowercase , **__lowercase)
@property
def UpperCamelCase__ ( self) -> int:
return self.encoder_attention_heads
@property
def UpperCamelCase__ ( self) -> int:
return self.d_model
def UpperCamelCase__ ( self) -> List[Any]:
__UpperCamelCase :Dict = copy.deepcopy(self.__dict__)
if self.backbone_config is not None:
__UpperCamelCase :Tuple = self.backbone_config.to_dict()
__UpperCamelCase :List[Any] = self.__class__.model_type
return output
| 43
| 1
|
import logging
import re
import pytorch_quantization
import pytorch_quantization.nn as quant_nn
import torch
from pytorch_quantization import calib
from pytorch_quantization.tensor_quant import QuantDescriptor
__lowercase = logging.getLogger(__name__)
__lowercase = 50 # max width of layer names
__lowercase = 70 # max width of quantizer names
def lowerCamelCase ( SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :List[Any] = parser.add_argument_group('''quant_trainer arguments''' )
group.add_argument('''--wprec''' , type=SCREAMING_SNAKE_CASE , default=8 , help='''weight precision''' )
group.add_argument('''--aprec''' , type=SCREAMING_SNAKE_CASE , default=8 , help='''activation precision''' )
group.add_argument('''--quant-per-tensor''' , action='''store_true''' , help='''per tensor weight scaling''' )
group.add_argument('''--quant-disable''' , action='''store_true''' , help='''disable all quantizers''' )
group.add_argument('''--quant-disable-embeddings''' , action='''store_true''' , help='''disable all embeddings quantizers''' )
group.add_argument('''--quant-disable-keyword''' , type=SCREAMING_SNAKE_CASE , nargs='''+''' , help='''disable quantizers by keyword''' )
group.add_argument('''--quant-disable-layer-module''' , type=SCREAMING_SNAKE_CASE , help='''disable quantizers by keyword under layer.''' )
group.add_argument('''--quant-enable-layer-module''' , type=SCREAMING_SNAKE_CASE , help='''enable quantizers by keyword under layer''' )
group.add_argument('''--calibrator''' , default='''max''' , help='''which quantization range calibrator to use''' )
group.add_argument('''--percentile''' , default=SCREAMING_SNAKE_CASE , type=SCREAMING_SNAKE_CASE , help='''percentile for PercentileCalibrator''' )
group.add_argument('''--fuse-qkv''' , action='''store_true''' , help='''use the same scale factor for qkv''' )
group.add_argument('''--clip-gelu''' , metavar='''N''' , type=SCREAMING_SNAKE_CASE , help='''clip gelu output maximum value to N''' )
group.add_argument(
'''--recalibrate-weights''' , action='''store_true''' , help=(
'''recalibrate weight amaxes by taking the max of the weights.'''
''' amaxes will be computed with the current quantization granularity (axis).'''
) , )
def lowerCamelCase ( SCREAMING_SNAKE_CASE ):
'''simple docstring'''
if args.calibrator == "max":
__UpperCamelCase :Union[str, Any] = '''max'''
elif args.calibrator == "percentile":
if args.percentile is None:
raise ValueError('''Specify --percentile when using percentile calibrator''' )
__UpperCamelCase :str = '''histogram'''
elif args.calibrator == "mse":
__UpperCamelCase :Union[str, Any] = '''histogram'''
else:
raise ValueError(f"""Invalid calibrator {args.calibrator}""" )
__UpperCamelCase :List[str] = QuantDescriptor(num_bits=args.aprec , calib_method=SCREAMING_SNAKE_CASE )
__UpperCamelCase :Tuple = QuantDescriptor(num_bits=args.wprec , axis=(None if args.quant_per_tensor else (0,)) )
quant_nn.QuantLinear.set_default_quant_desc_input(SCREAMING_SNAKE_CASE )
quant_nn.QuantLinear.set_default_quant_desc_weight(SCREAMING_SNAKE_CASE )
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE=False , SCREAMING_SNAKE_CASE=False ):
'''simple docstring'''
logger.info('''Configuring Model for Quantization''' )
logger.info(f"""using quantization package {pytorch_quantization.__file__}""" )
if not calib:
if args.quant_disable_embeddings:
set_quantizer_by_name(SCREAMING_SNAKE_CASE , ['''embeddings'''] , which='''weight''' , _disabled=SCREAMING_SNAKE_CASE )
if args.quant_disable:
set_quantizer_by_name(SCREAMING_SNAKE_CASE , [''''''] , _disabled=SCREAMING_SNAKE_CASE )
if args.quant_disable_keyword:
set_quantizer_by_name(SCREAMING_SNAKE_CASE , args.quant_disable_keyword , _disabled=SCREAMING_SNAKE_CASE )
if args.quant_disable_layer_module:
set_quantizer_by_name(SCREAMING_SNAKE_CASE , [R'''layer.\d+.''' + args.quant_disable_layer_module] , _disabled=SCREAMING_SNAKE_CASE )
if args.quant_enable_layer_module:
set_quantizer_by_name(SCREAMING_SNAKE_CASE , [R'''layer.\d+.''' + args.quant_enable_layer_module] , _disabled=SCREAMING_SNAKE_CASE )
if args.recalibrate_weights:
recalibrate_weights(SCREAMING_SNAKE_CASE )
if args.fuse_qkv:
fuse_qkv(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
if args.clip_gelu:
clip_gelu(SCREAMING_SNAKE_CASE , args.clip_gelu )
# if args.local_rank in [-1, 0] and not calib:
print_quant_summary(SCREAMING_SNAKE_CASE )
def lowerCamelCase ( SCREAMING_SNAKE_CASE ):
'''simple docstring'''
logger.info('''Enabling Calibration''' )
for name, module in model.named_modules():
if name.endswith('''_quantizer''' ):
if module._calibrator is not None:
module.disable_quant()
module.enable_calib()
else:
module.disable()
logger.info(f"""{name:80}: {module}""" )
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
logger.info('''Loading calibrated amax''' )
for name, module in model.named_modules():
if name.endswith('''_quantizer''' ):
if module._calibrator is not None:
if isinstance(module._calibrator , calib.MaxCalibrator ):
module.load_calib_amax()
else:
module.load_calib_amax('''percentile''' , percentile=args.percentile )
module.enable_quant()
module.disable_calib()
else:
module.enable()
model.cuda()
print_quant_summary(SCREAMING_SNAKE_CASE )
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
def fusea(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
for mod in [qq, qk, qv]:
if not hasattr(SCREAMING_SNAKE_CASE , '''_amax''' ):
print(''' WARNING: NO AMAX BUFFER''' )
return
__UpperCamelCase :Tuple = qq._amax.detach().item()
__UpperCamelCase :List[str] = qk._amax.detach().item()
__UpperCamelCase :Dict = qv._amax.detach().item()
__UpperCamelCase :Any = max(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
qq._amax.fill_(SCREAMING_SNAKE_CASE )
qk._amax.fill_(SCREAMING_SNAKE_CASE )
qv._amax.fill_(SCREAMING_SNAKE_CASE )
logger.info(f""" q={q:5.2f} k={k:5.2f} v={v:5.2f} -> {amax:5.2f}""" )
for name, mod in model.named_modules():
if name.endswith('''.attention.self''' ):
logger.info(f"""FUSE_QKV: {name:{name_width}}""" )
fusea(mod.matmul_q_input_quantizer , mod.matmul_k_input_quantizer , mod.matmul_v_input_quantizer )
if args.quant_per_tensor:
fusea(mod.query._weight_quantizer , mod.key._weight_quantizer , mod.value._weight_quantizer )
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
for name, mod in model.named_modules():
if name.endswith('''.output.dense''' ) and not name.endswith('''attention.output.dense''' ):
__UpperCamelCase :List[str] = mod._input_quantizer._amax.data.detach().item()
mod._input_quantizer._amax.data.detach().clamp_(max=SCREAMING_SNAKE_CASE )
__UpperCamelCase :Optional[Any] = mod._input_quantizer._amax.data.detach().item()
logger.info(f"""CLIP_GELU: {name:{name_width}} amax: {amax_init:5.2f} -> {amax:5.2f}""" )
def lowerCamelCase ( SCREAMING_SNAKE_CASE ):
'''simple docstring'''
for name, mod in model.named_modules():
if hasattr(SCREAMING_SNAKE_CASE , '''_weight_quantizer''' ) and mod._weight_quantizer.axis is not None:
__UpperCamelCase :Dict = mod.weight.shape[0]
__UpperCamelCase :Tuple = mod._weight_quantizer._amax.detach()
__UpperCamelCase :str = torch.ones(SCREAMING_SNAKE_CASE , dtype=amax.dtype , device=amax.device ) * amax
print(f"""expanding {name} {amax} -> {mod._weight_quantizer._amax}""" )
def lowerCamelCase ( SCREAMING_SNAKE_CASE ):
'''simple docstring'''
for name, mod in model.named_modules():
if hasattr(SCREAMING_SNAKE_CASE , '''_weight_quantizer''' ):
if not hasattr(mod.weight_quantizer , '''_amax''' ):
print('''RECALIB: {name:{name_width}} WARNING: NO AMAX BUFFER''' )
continue
# determine which axes to reduce across
# e.g. a 4D tensor quantized per axis 0 should reduce over (1,2,3)
__UpperCamelCase :Tuple = set() if mod._weight_quantizer.axis is None else set(mod._weight_quantizer.axis )
__UpperCamelCase :List[str] = set(range(len(mod.weight.size() ) ) ) - axis_set
__UpperCamelCase :Tuple = pytorch_quantization.utils.reduce_amax(mod.weight , axis=SCREAMING_SNAKE_CASE , keepdims=SCREAMING_SNAKE_CASE ).detach()
logger.info(f"""RECALIB: {name:{name_width}} {mod._weight_quantizer._amax.flatten()} -> {amax.flatten()}""" )
__UpperCamelCase :List[Any] = amax
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE=25 , SCREAMING_SNAKE_CASE=180 , SCREAMING_SNAKE_CASE=None ):
'''simple docstring'''
if ignore is None:
__UpperCamelCase :Optional[int] = []
elif not isinstance(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
__UpperCamelCase :Optional[Any] = [ignore]
__UpperCamelCase :str = 0
for name, mod in model.named_modules():
if not hasattr(SCREAMING_SNAKE_CASE , '''weight''' ):
continue
__UpperCamelCase :Any = max(SCREAMING_SNAKE_CASE , len(SCREAMING_SNAKE_CASE ) )
for name, mod in model.named_modules():
__UpperCamelCase :Any = getattr(SCREAMING_SNAKE_CASE , '''_input_quantizer''' , SCREAMING_SNAKE_CASE )
__UpperCamelCase :Union[str, Any] = getattr(SCREAMING_SNAKE_CASE , '''_weight_quantizer''' , SCREAMING_SNAKE_CASE )
if not hasattr(SCREAMING_SNAKE_CASE , '''weight''' ):
continue
if type(SCREAMING_SNAKE_CASE ) in ignore:
continue
if [True for s in ignore if type(SCREAMING_SNAKE_CASE ) is str and s in name]:
continue
__UpperCamelCase :Optional[int] = f"""Act:{input_q.extra_repr()}"""
__UpperCamelCase :List[str] = f"""Wgt:{weight_q.extra_repr()}"""
__UpperCamelCase :int = f"""{name:{name_width}} {act_str} {wgt_str}"""
if len(SCREAMING_SNAKE_CASE ) <= line_width:
logger.info(SCREAMING_SNAKE_CASE )
else:
logger.info(f"""{name:{name_width}} {act_str}""" )
logger.info(f"""{' ':{name_width}} {wgt_str}""" )
def lowerCamelCase ( SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :str = 0
for name, mod in model.named_modules():
if isinstance(SCREAMING_SNAKE_CASE , pytorch_quantization.nn.TensorQuantizer ):
print(f"""{name:80} {mod}""" )
count += 1
print(f"""{count} TensorQuantizers found in model""" )
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Any = getattr(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
if quantizer_mod is not None:
assert hasattr(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
setattr(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
else:
logger.warning(f"""{name} has no {quantizer}""" )
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE="both" , **SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Tuple = f"""Warning: changing {which} quantizers of {name:{qname_width}}"""
for k, v in kwargs.items():
s += f""" {k}={v}"""
if which in ["input", "both"]:
set_quantizer(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , '''_input_quantizer''' , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
if which in ["weight", "both"]:
set_quantizer(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , '''_weight_quantizer''' , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
logger.info(SCREAMING_SNAKE_CASE )
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , **SCREAMING_SNAKE_CASE ):
'''simple docstring'''
for name, mod in model.named_modules():
if hasattr(SCREAMING_SNAKE_CASE , '''_input_quantizer''' ) or hasattr(SCREAMING_SNAKE_CASE , '''_weight_quantizer''' ):
for n in names:
if re.search(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
set_quantizers(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , **SCREAMING_SNAKE_CASE )
elif name.endswith('''_quantizer''' ):
for n in names:
if re.search(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
__UpperCamelCase :str = f"""Warning: changing {name:{name_width}}"""
for k, v in kwargs.items():
s += f""" {k}={v}"""
setattr(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
logger.info(SCREAMING_SNAKE_CASE )
| 43
|
# Copyright 2023 The HuggingFace Inc. team. All rights reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
import torch
from ..models.auto import AutoModelForSequenceClassification, AutoTokenizer
from .base import PipelineTool
class lowerCamelCase_ ( UpperCAmelCase_ ):
'''simple docstring'''
a__ : Optional[Any] = """facebook/bart-large-mnli"""
a__ : int = (
"""This is a tool that classifies an English text using provided labels. It takes two inputs: `text`, which """
"""should be the text to classify, and `labels`, which should be the list of labels to use for classification. """
"""It returns the most likely label in the list of provided `labels` for the input text."""
)
a__ : Optional[Any] = """text_classifier"""
a__ : Any = AutoTokenizer
a__ : str = AutoModelForSequenceClassification
a__ : str = ["""text""", ["""text"""]]
a__ : Optional[int] = ["""text"""]
def UpperCamelCase__ ( self) -> Union[str, Any]:
super().setup()
__UpperCamelCase :int = self.model.config
__UpperCamelCase :Optional[Any] = -1
for idx, label in config.idalabel.items():
if label.lower().startswith('''entail'''):
__UpperCamelCase :List[Any] = int(__lowercase)
if self.entailment_id == -1:
raise ValueError('''Could not determine the entailment ID from the model config, please pass it at init.''')
def UpperCamelCase__ ( self , __lowercase , __lowercase) -> Union[str, Any]:
__UpperCamelCase :Any = labels
return self.pre_processor(
[text] * len(__lowercase) , [f"""This example is {label}""" for label in labels] , return_tensors='''pt''' , padding='''max_length''' , )
def UpperCamelCase__ ( self , __lowercase) -> Optional[Any]:
__UpperCamelCase :List[Any] = outputs.logits
__UpperCamelCase :Any = torch.argmax(logits[:, 2]).item()
return self._labels[label_id]
| 43
| 1
|
import re
import jax.numpy as jnp
from flax.traverse_util import flatten_dict, unflatten_dict
from jax.random import PRNGKey
from ..utils import logging
__lowercase = logging.get_logger(__name__)
def lowerCamelCase ( SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Tuple = R'''\w+[.]\d+'''
__UpperCamelCase :List[str] = re.findall(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
for pat in pats:
__UpperCamelCase :int = key.replace(SCREAMING_SNAKE_CASE , '''_'''.join(pat.split('''.''' ) ) )
return key
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Tuple = pt_tuple_key[:-1] + ('''scale''',)
if (
any('''norm''' in str_ for str_ in pt_tuple_key )
and (pt_tuple_key[-1] == "bias")
and (pt_tuple_key[:-1] + ("bias",) not in random_flax_state_dict)
and (pt_tuple_key[:-1] + ("scale",) in random_flax_state_dict)
):
__UpperCamelCase :str = pt_tuple_key[:-1] + ('''scale''',)
return renamed_pt_tuple_key, pt_tensor
elif pt_tuple_key[-1] in ["weight", "gamma"] and pt_tuple_key[:-1] + ("scale",) in random_flax_state_dict:
__UpperCamelCase :Any = pt_tuple_key[:-1] + ('''scale''',)
return renamed_pt_tuple_key, pt_tensor
# embedding
if pt_tuple_key[-1] == "weight" and pt_tuple_key[:-1] + ("embedding",) in random_flax_state_dict:
__UpperCamelCase :str = pt_tuple_key[:-1] + ('''embedding''',)
return renamed_pt_tuple_key, pt_tensor
# conv layer
__UpperCamelCase :List[str] = pt_tuple_key[:-1] + ('''kernel''',)
if pt_tuple_key[-1] == "weight" and pt_tensor.ndim == 4:
__UpperCamelCase :List[Any] = pt_tensor.transpose(2 , 3 , 1 , 0 )
return renamed_pt_tuple_key, pt_tensor
# linear layer
__UpperCamelCase :List[str] = pt_tuple_key[:-1] + ('''kernel''',)
if pt_tuple_key[-1] == "weight":
__UpperCamelCase :Any = pt_tensor.T
return renamed_pt_tuple_key, pt_tensor
# old PyTorch layer norm weight
__UpperCamelCase :int = pt_tuple_key[:-1] + ('''weight''',)
if pt_tuple_key[-1] == "gamma":
return renamed_pt_tuple_key, pt_tensor
# old PyTorch layer norm bias
__UpperCamelCase :int = pt_tuple_key[:-1] + ('''bias''',)
if pt_tuple_key[-1] == "beta":
return renamed_pt_tuple_key, pt_tensor
return pt_tuple_key, pt_tensor
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE=42 ):
'''simple docstring'''
__UpperCamelCase :Union[str, Any] = {k: v.numpy() for k, v in pt_state_dict.items()}
# Step 2: Since the model is stateless, get random Flax params
__UpperCamelCase :str = flax_model.init_weights(PRNGKey(SCREAMING_SNAKE_CASE ) )
__UpperCamelCase :int = flatten_dict(SCREAMING_SNAKE_CASE )
__UpperCamelCase :List[Any] = {}
# Need to change some parameters name to match Flax names
for pt_key, pt_tensor in pt_state_dict.items():
__UpperCamelCase :List[Any] = rename_key(SCREAMING_SNAKE_CASE )
__UpperCamelCase :List[Any] = tuple(renamed_pt_key.split('''.''' ) )
# Correctly rename weight parameters
__UpperCamelCase , __UpperCamelCase :Any = rename_key_and_reshape_tensor(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
if flax_key in random_flax_state_dict:
if flax_tensor.shape != random_flax_state_dict[flax_key].shape:
raise ValueError(
f"""PyTorch checkpoint seems to be incorrect. Weight {pt_key} was expected to be of shape """
f"""{random_flax_state_dict[flax_key].shape}, but is {flax_tensor.shape}.""" )
# also add unexpected weight so that warning is thrown
__UpperCamelCase :str = jnp.asarray(SCREAMING_SNAKE_CASE )
return unflatten_dict(SCREAMING_SNAKE_CASE )
| 43
|
import gc
import random
import unittest
import numpy as np
import torch
from transformers import (
CLIPImageProcessor,
CLIPTextConfig,
CLIPTextModel,
CLIPTokenizer,
CLIPVisionConfig,
CLIPVisionModelWithProjection,
)
from diffusers import AutoencoderKL, DDIMScheduler, DDPMScheduler, StableUnCLIPImgaImgPipeline, UNetaDConditionModel
from diffusers.pipelines.pipeline_utils import DiffusionPipeline
from diffusers.pipelines.stable_diffusion.stable_unclip_image_normalizer import StableUnCLIPImageNormalizer
from diffusers.utils.import_utils import is_xformers_available
from diffusers.utils.testing_utils import (
enable_full_determinism,
floats_tensor,
load_image,
load_numpy,
require_torch_gpu,
skip_mps,
slow,
torch_device,
)
from ..pipeline_params import TEXT_GUIDED_IMAGE_VARIATION_BATCH_PARAMS, TEXT_GUIDED_IMAGE_VARIATION_PARAMS
from ..test_pipelines_common import (
PipelineKarrasSchedulerTesterMixin,
PipelineLatentTesterMixin,
PipelineTesterMixin,
assert_mean_pixel_difference,
)
enable_full_determinism()
class lowerCamelCase_ ( UpperCAmelCase_ , UpperCAmelCase_ , UpperCAmelCase_ , unittest.TestCase ):
'''simple docstring'''
a__ : int = StableUnCLIPImgaImgPipeline
a__ : Optional[int] = TEXT_GUIDED_IMAGE_VARIATION_PARAMS
a__ : Union[str, Any] = TEXT_GUIDED_IMAGE_VARIATION_BATCH_PARAMS
a__ : Optional[Any] = frozenset(
[] ) # TO-DO: update image_params once pipeline is refactored with VaeImageProcessor.preprocess
a__ : int = frozenset([] )
def UpperCamelCase__ ( self) -> Tuple:
__UpperCamelCase :Tuple = 32
__UpperCamelCase :Optional[int] = embedder_hidden_size
# image encoding components
__UpperCamelCase :Union[str, Any] = CLIPImageProcessor(crop_size=32 , size=32)
torch.manual_seed(0)
__UpperCamelCase :Union[str, Any] = CLIPVisionModelWithProjection(
CLIPVisionConfig(
hidden_size=__lowercase , projection_dim=__lowercase , num_hidden_layers=5 , num_attention_heads=4 , image_size=32 , intermediate_size=37 , patch_size=1 , ))
# regular denoising components
torch.manual_seed(0)
__UpperCamelCase :str = StableUnCLIPImageNormalizer(embedding_dim=__lowercase)
__UpperCamelCase :Optional[int] = DDPMScheduler(beta_schedule='''squaredcos_cap_v2''')
torch.manual_seed(0)
__UpperCamelCase :Union[str, Any] = CLIPTokenizer.from_pretrained('''hf-internal-testing/tiny-random-clip''')
torch.manual_seed(0)
__UpperCamelCase :Dict = CLIPTextModel(
CLIPTextConfig(
bos_token_id=0 , eos_token_id=2 , hidden_size=__lowercase , projection_dim=32 , intermediate_size=37 , layer_norm_eps=1E-0_5 , num_attention_heads=4 , num_hidden_layers=5 , pad_token_id=1 , vocab_size=1_000 , ))
torch.manual_seed(0)
__UpperCamelCase :List[Any] = UNetaDConditionModel(
sample_size=32 , in_channels=4 , out_channels=4 , down_block_types=('''CrossAttnDownBlock2D''', '''DownBlock2D''') , up_block_types=('''UpBlock2D''', '''CrossAttnUpBlock2D''') , block_out_channels=(32, 64) , attention_head_dim=(2, 4) , class_embed_type='''projection''' , projection_class_embeddings_input_dim=embedder_projection_dim * 2 , cross_attention_dim=__lowercase , layers_per_block=1 , upcast_attention=__lowercase , use_linear_projection=__lowercase , )
torch.manual_seed(0)
__UpperCamelCase :Tuple = DDIMScheduler(
beta_schedule='''scaled_linear''' , beta_start=0.0_00_85 , beta_end=0.0_12 , prediction_type='''v_prediction''' , set_alpha_to_one=__lowercase , steps_offset=1 , )
torch.manual_seed(0)
__UpperCamelCase :List[str] = AutoencoderKL()
__UpperCamelCase :Tuple = {
# image encoding components
'''feature_extractor''': feature_extractor,
'''image_encoder''': image_encoder.eval(),
# image noising components
'''image_normalizer''': image_normalizer.eval(),
'''image_noising_scheduler''': image_noising_scheduler,
# regular denoising components
'''tokenizer''': tokenizer,
'''text_encoder''': text_encoder.eval(),
'''unet''': unet.eval(),
'''scheduler''': scheduler,
'''vae''': vae.eval(),
}
return components
def UpperCamelCase__ ( self , __lowercase , __lowercase=0 , __lowercase=True) -> str:
if str(__lowercase).startswith('''mps'''):
__UpperCamelCase :Union[str, Any] = torch.manual_seed(__lowercase)
else:
__UpperCamelCase :int = torch.Generator(device=__lowercase).manual_seed(__lowercase)
__UpperCamelCase :int = floats_tensor((1, 3, 32, 32) , rng=random.Random(__lowercase)).to(__lowercase)
if pil_image:
__UpperCamelCase :List[Any] = input_image * 0.5 + 0.5
__UpperCamelCase :Optional[Any] = input_image.clamp(0 , 1)
__UpperCamelCase :int = input_image.cpu().permute(0 , 2 , 3 , 1).float().numpy()
__UpperCamelCase :Optional[Any] = DiffusionPipeline.numpy_to_pil(__lowercase)[0]
return {
"prompt": "An anime racoon running a marathon",
"image": input_image,
"generator": generator,
"num_inference_steps": 2,
"output_type": "np",
}
@skip_mps
def UpperCamelCase__ ( self) -> Union[str, Any]:
__UpperCamelCase :Dict = '''cpu''' # ensure determinism for the device-dependent torch.Generator
__UpperCamelCase :Tuple = self.get_dummy_components()
__UpperCamelCase :Any = StableUnCLIPImgaImgPipeline(**__lowercase)
__UpperCamelCase :Optional[Any] = sd_pipe.to(__lowercase)
sd_pipe.set_progress_bar_config(disable=__lowercase)
__UpperCamelCase :List[Any] = self.get_dummy_inputs(__lowercase)
inputs.update({'''image_embeds''': None})
__UpperCamelCase :Any = sd_pipe(**__lowercase).images
__UpperCamelCase :List[str] = image[0, -3:, -3:, -1]
assert image.shape == (1, 32, 32, 3)
__UpperCamelCase :List[Any] = np.array([0.38_72, 0.72_24, 0.56_01, 0.47_41, 0.68_72, 0.58_14, 0.46_36, 0.38_67, 0.50_78])
assert np.abs(image_slice.flatten() - expected_slice).max() < 1E-3
def UpperCamelCase__ ( self) -> str:
__UpperCamelCase :Optional[Any] = torch_device in ['''cpu''', '''mps''']
self._test_attention_slicing_forward_pass(test_max_difference=__lowercase)
def UpperCamelCase__ ( self) -> List[Any]:
__UpperCamelCase :Optional[Any] = torch_device in ['''cpu''', '''mps''']
self._test_inference_batch_single_identical(test_max_difference=__lowercase)
@unittest.skipIf(
torch_device != '''cuda''' or not is_xformers_available() , reason='''XFormers attention is only available with CUDA and `xformers` installed''' , )
def UpperCamelCase__ ( self) -> Union[str, Any]:
self._test_xformers_attention_forwardGenerator_pass(test_max_difference=__lowercase)
@slow
@require_torch_gpu
class lowerCamelCase_ ( unittest.TestCase ):
'''simple docstring'''
def UpperCamelCase__ ( self) -> Union[str, Any]:
# clean up the VRAM after each test
super().tearDown()
gc.collect()
torch.cuda.empty_cache()
def UpperCamelCase__ ( self) -> Union[str, Any]:
__UpperCamelCase :int = load_image(
'''https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main/stable_unclip/turtle.png''')
__UpperCamelCase :Any = load_numpy(
'''https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main/stable_unclip/stable_unclip_2_1_l_img2img_anime_turtle_fp16.npy''')
__UpperCamelCase :List[Any] = StableUnCLIPImgaImgPipeline.from_pretrained(
'''fusing/stable-unclip-2-1-l-img2img''' , torch_dtype=torch.floataa)
pipe.to(__lowercase)
pipe.set_progress_bar_config(disable=__lowercase)
# stable unclip will oom when integration tests are run on a V100,
# so turn on memory savings
pipe.enable_attention_slicing()
pipe.enable_sequential_cpu_offload()
__UpperCamelCase :int = torch.Generator(device='''cpu''').manual_seed(0)
__UpperCamelCase :Dict = pipe(__lowercase , '''anime turle''' , generator=__lowercase , output_type='''np''')
__UpperCamelCase :Dict = output.images[0]
assert image.shape == (768, 768, 3)
assert_mean_pixel_difference(__lowercase , __lowercase)
def UpperCamelCase__ ( self) -> List[str]:
__UpperCamelCase :Optional[Any] = load_image(
'''https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main/stable_unclip/turtle.png''')
__UpperCamelCase :Any = load_numpy(
'''https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main/stable_unclip/stable_unclip_2_1_h_img2img_anime_turtle_fp16.npy''')
__UpperCamelCase :Any = StableUnCLIPImgaImgPipeline.from_pretrained(
'''fusing/stable-unclip-2-1-h-img2img''' , torch_dtype=torch.floataa)
pipe.to(__lowercase)
pipe.set_progress_bar_config(disable=__lowercase)
# stable unclip will oom when integration tests are run on a V100,
# so turn on memory savings
pipe.enable_attention_slicing()
pipe.enable_sequential_cpu_offload()
__UpperCamelCase :int = torch.Generator(device='''cpu''').manual_seed(0)
__UpperCamelCase :Optional[int] = pipe(__lowercase , '''anime turle''' , generator=__lowercase , output_type='''np''')
__UpperCamelCase :List[Any] = output.images[0]
assert image.shape == (768, 768, 3)
assert_mean_pixel_difference(__lowercase , __lowercase)
def UpperCamelCase__ ( self) -> List[str]:
__UpperCamelCase :Dict = load_image(
'''https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main/stable_unclip/turtle.png''')
torch.cuda.empty_cache()
torch.cuda.reset_max_memory_allocated()
torch.cuda.reset_peak_memory_stats()
__UpperCamelCase :List[Any] = StableUnCLIPImgaImgPipeline.from_pretrained(
'''fusing/stable-unclip-2-1-h-img2img''' , torch_dtype=torch.floataa)
__UpperCamelCase :Union[str, Any] = pipe.to(__lowercase)
pipe.set_progress_bar_config(disable=__lowercase)
pipe.enable_attention_slicing()
pipe.enable_sequential_cpu_offload()
__UpperCamelCase :Optional[Any] = pipe(
__lowercase , '''anime turtle''' , num_inference_steps=2 , output_type='''np''' , )
__UpperCamelCase :int = torch.cuda.max_memory_allocated()
# make sure that less than 7 GB is allocated
assert mem_bytes < 7 * 10**9
| 43
| 1
|
class lowerCamelCase_ :
'''simple docstring'''
def __init__( self) -> int:
__UpperCamelCase :List[Any] = ''''''
__UpperCamelCase :Dict = ''''''
__UpperCamelCase :Union[str, Any] = []
def UpperCamelCase__ ( self , __lowercase , __lowercase) -> 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]:
__UpperCamelCase :int = self.__min_dist_top_down_dp(m - 1 , n - 1)
else:
__UpperCamelCase :int = self.__min_dist_top_down_dp(__lowercase , n - 1)
__UpperCamelCase :Dict = self.__min_dist_top_down_dp(m - 1 , __lowercase)
__UpperCamelCase :int = self.__min_dist_top_down_dp(m - 1 , n - 1)
__UpperCamelCase :List[Any] = 1 + min(__lowercase , __lowercase , __lowercase)
return self.dp[m][n]
def UpperCamelCase__ ( self , __lowercase , __lowercase) -> int:
__UpperCamelCase :Optional[int] = worda
__UpperCamelCase :Optional[int] = worda
__UpperCamelCase :Any = [[-1 for _ in range(len(__lowercase))] for _ in range(len(__lowercase))]
return self.__min_dist_top_down_dp(len(__lowercase) - 1 , len(__lowercase) - 1)
def UpperCamelCase__ ( self , __lowercase , __lowercase) -> int:
__UpperCamelCase :Optional[int] = worda
__UpperCamelCase :Tuple = worda
__UpperCamelCase :str = len(__lowercase)
__UpperCamelCase :Union[str, Any] = len(__lowercase)
__UpperCamelCase :Union[str, Any] = [[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
__UpperCamelCase :Dict = j
elif j == 0: # second string is empty
__UpperCamelCase :Union[str, Any] = i
elif worda[i - 1] == worda[j - 1]: # last characters are equal
__UpperCamelCase :List[str] = self.dp[i - 1][j - 1]
else:
__UpperCamelCase :str = self.dp[i][j - 1]
__UpperCamelCase :List[str] = self.dp[i - 1][j]
__UpperCamelCase :Union[str, Any] = self.dp[i - 1][j - 1]
__UpperCamelCase :str = 1 + min(__lowercase , __lowercase , __lowercase)
return self.dp[m][n]
if __name__ == "__main__":
__lowercase = EditDistance()
print('''****************** Testing Edit Distance DP Algorithm ******************''')
print()
__lowercase = input('''Enter the first string: ''').strip()
__lowercase = 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 ***************''')
| 43
|
import numpy as np
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE = 1e-12 , SCREAMING_SNAKE_CASE = 100 , ):
'''simple docstring'''
assert np.shape(SCREAMING_SNAKE_CASE )[0] == np.shape(SCREAMING_SNAKE_CASE )[1]
# Ensure proper dimensionality.
assert np.shape(SCREAMING_SNAKE_CASE )[0] == np.shape(SCREAMING_SNAKE_CASE )[0]
# Ensure inputs are either both complex or both real
assert np.iscomplexobj(SCREAMING_SNAKE_CASE ) == np.iscomplexobj(SCREAMING_SNAKE_CASE )
__UpperCamelCase :List[Any] = np.iscomplexobj(SCREAMING_SNAKE_CASE )
if is_complex:
# Ensure complex input_matrix is Hermitian
assert np.array_equal(SCREAMING_SNAKE_CASE , input_matrix.conj().T )
# Set convergence to False. Will define convergence when we exceed max_iterations
# or when we have small changes from one iteration to next.
__UpperCamelCase :str = False
__UpperCamelCase :int = 0
__UpperCamelCase :Optional[Any] = 0
__UpperCamelCase :Union[str, Any] = 1e12
while not convergence:
# Multiple matrix by the vector.
__UpperCamelCase :List[str] = np.dot(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
# Normalize the resulting output vector.
__UpperCamelCase :Tuple = w / np.linalg.norm(SCREAMING_SNAKE_CASE )
# Find rayleigh quotient
# (faster than usual b/c we know vector is normalized already)
__UpperCamelCase :int = vector.conj().T if is_complex else vector.T
__UpperCamelCase :Optional[int] = np.dot(SCREAMING_SNAKE_CASE , np.dot(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ) )
# Check convergence.
__UpperCamelCase :Optional[Any] = np.abs(lambda_ - lambda_previous ) / lambda_
iterations += 1
if error <= error_tol or iterations >= max_iterations:
__UpperCamelCase :Dict = True
__UpperCamelCase :List[Any] = lambda_
if is_complex:
__UpperCamelCase :Tuple = np.real(lambda_ )
return lambda_, vector
def lowerCamelCase ( ):
'''simple docstring'''
__UpperCamelCase :int = np.array([[41, 4, 20], [4, 26, 30], [20, 30, 50]] )
__UpperCamelCase :Optional[Any] = np.array([41, 4, 20] )
__UpperCamelCase :Any = real_input_matrix.astype(np.complexaaa )
__UpperCamelCase :Dict = np.triu(1j * complex_input_matrix , 1 )
complex_input_matrix += imag_matrix
complex_input_matrix += -1 * imag_matrix.T
__UpperCamelCase :Optional[int] = np.array([41, 4, 20] ).astype(np.complexaaa )
for problem_type in ["real", "complex"]:
if problem_type == "real":
__UpperCamelCase :Any = real_input_matrix
__UpperCamelCase :int = real_vector
elif problem_type == "complex":
__UpperCamelCase :Tuple = complex_input_matrix
__UpperCamelCase :Optional[Any] = complex_vector
# Our implementation.
__UpperCamelCase , __UpperCamelCase :Dict = power_iteration(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
# Numpy implementation.
# Get eigenvalues and eigenvectors using built-in numpy
# eigh (eigh used for symmetric or hermetian matrices).
__UpperCamelCase , __UpperCamelCase :List[Any] = np.linalg.eigh(SCREAMING_SNAKE_CASE )
# Last eigenvalue is the maximum one.
__UpperCamelCase :List[Any] = eigen_values[-1]
# Last column in this matrix is eigenvector corresponding to largest eigenvalue.
__UpperCamelCase :str = eigen_vectors[:, -1]
# Check our implementation and numpy gives close answers.
assert np.abs(eigen_value - eigen_value_max ) <= 1e-6
# Take absolute values element wise of each eigenvector.
# as they are only unique to a minus sign.
assert np.linalg.norm(np.abs(SCREAMING_SNAKE_CASE ) - np.abs(SCREAMING_SNAKE_CASE ) ) <= 1e-6
if __name__ == "__main__":
import doctest
doctest.testmod()
test_power_iteration()
| 43
| 1
|
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(UpperCAmelCase_ )
class lowerCamelCase_ ( UpperCAmelCase_ ):
'''simple docstring'''
def __init__( self , **__lowercase) -> int:
super().__init__(**__lowercase)
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) -> Union[str, Any]:
return super().__call__(__lowercase , **__lowercase)
def UpperCamelCase__ ( self , **__lowercase) -> int:
__UpperCamelCase :int = {}
if "candidate_labels" in kwargs:
__UpperCamelCase :Union[str, Any] = kwargs['''candidate_labels''']
if "hypothesis_template" in kwargs:
__UpperCamelCase :List[str] = kwargs['''hypothesis_template''']
return preprocess_params, {}, {}
def UpperCamelCase__ ( self , __lowercase , __lowercase=None , __lowercase="This is a photo of {}.") -> List[Any]:
__UpperCamelCase :Dict = load_image(__lowercase)
__UpperCamelCase :Dict = self.image_processor(images=[image] , return_tensors=self.framework)
__UpperCamelCase :Optional[int] = candidate_labels
__UpperCamelCase :int = [hypothesis_template.format(__lowercase) for x in candidate_labels]
__UpperCamelCase :Optional[Any] = self.tokenizer(__lowercase , return_tensors=self.framework , padding=__lowercase)
__UpperCamelCase :List[str] = [text_inputs]
return inputs
def UpperCamelCase__ ( self , __lowercase) -> List[str]:
__UpperCamelCase :List[str] = model_inputs.pop('''candidate_labels''')
__UpperCamelCase :List[str] = model_inputs.pop('''text_inputs''')
if isinstance(text_inputs[0] , __lowercase):
__UpperCamelCase :int = text_inputs[0]
else:
# Batching case.
__UpperCamelCase :str = text_inputs[0][0]
__UpperCamelCase :Dict = self.model(**__lowercase , **__lowercase)
__UpperCamelCase :str = {
'''candidate_labels''': candidate_labels,
'''logits''': outputs.logits_per_image,
}
return model_outputs
def UpperCamelCase__ ( self , __lowercase) -> Union[str, Any]:
__UpperCamelCase :Optional[Any] = model_outputs.pop('''candidate_labels''')
__UpperCamelCase :List[Any] = model_outputs['''logits'''][0]
if self.framework == "pt":
__UpperCamelCase :Tuple = logits.softmax(dim=-1).squeeze(-1)
__UpperCamelCase :Optional[int] = probs.tolist()
if not isinstance(__lowercase , __lowercase):
__UpperCamelCase :Dict = [scores]
elif self.framework == "tf":
__UpperCamelCase :Optional[Any] = stable_softmax(__lowercase , axis=-1)
__UpperCamelCase :Dict = probs.numpy().tolist()
else:
raise ValueError(f"""Unsupported framework: {self.framework}""")
__UpperCamelCase :Optional[int] = [
{'''score''': score, '''label''': candidate_label}
for score, candidate_label in sorted(zip(__lowercase , __lowercase) , key=lambda __lowercase: -x[0])
]
return result
| 43
|
import json
from typing import TYPE_CHECKING, List, Optional, Tuple
from tokenizers import pre_tokenizers
from ...tokenization_utils_base import BatchEncoding
from ...tokenization_utils_fast import PreTrainedTokenizerFast
from ...utils import logging
if TYPE_CHECKING:
from transformers.pipelines.conversational import Conversation
__lowercase = logging.get_logger(__name__)
__lowercase = {'''tokenizer_file''': '''tokenizer.json'''}
__lowercase = {
'''tokenizer_file''': {
'''bigscience/tokenizer''': '''https://huggingface.co/bigscience/tokenizer/blob/main/tokenizer.json''',
'''bigscience/bloom-560m''': '''https://huggingface.co/bigscience/bloom-560m/blob/main/tokenizer.json''',
'''bigscience/bloom-1b1''': '''https://huggingface.co/bigscience/bloom-1b1/blob/main/tokenizer.json''',
'''bigscience/bloom-1b7''': '''https://huggingface.co/bigscience/bloom-1b7/blob/main/tokenizer.json''',
'''bigscience/bloom-3b''': '''https://huggingface.co/bigscience/bloom-3b/blob/main/tokenizer.json''',
'''bigscience/bloom-7b1''': '''https://huggingface.co/bigscience/bloom-7b1/blob/main/tokenizer.json''',
'''bigscience/bloom''': '''https://huggingface.co/bigscience/bloom/blob/main/tokenizer.json''',
},
}
class lowerCamelCase_ ( UpperCAmelCase_ ):
'''simple docstring'''
a__ : int = VOCAB_FILES_NAMES
a__ : Tuple = PRETRAINED_VOCAB_FILES_MAP
a__ : List[str] = ["""input_ids""", """attention_mask"""]
a__ : int = None
def __init__( self , __lowercase=None , __lowercase=None , __lowercase=None , __lowercase="<unk>" , __lowercase="<s>" , __lowercase="</s>" , __lowercase="<pad>" , __lowercase=False , __lowercase=False , **__lowercase , ) -> List[str]:
super().__init__(
__lowercase , __lowercase , tokenizer_file=__lowercase , unk_token=__lowercase , bos_token=__lowercase , eos_token=__lowercase , pad_token=__lowercase , add_prefix_space=__lowercase , clean_up_tokenization_spaces=__lowercase , **__lowercase , )
__UpperCamelCase :int = json.loads(self.backend_tokenizer.pre_tokenizer.__getstate__())
if pre_tok_state.get('''add_prefix_space''' , __lowercase) != add_prefix_space:
__UpperCamelCase :Any = getattr(__lowercase , pre_tok_state.pop('''type'''))
__UpperCamelCase :str = add_prefix_space
__UpperCamelCase :List[str] = pre_tok_class(**__lowercase)
__UpperCamelCase :Tuple = add_prefix_space
def UpperCamelCase__ ( self , *__lowercase , **__lowercase) -> BatchEncoding:
__UpperCamelCase :Tuple = kwargs.get('''is_split_into_words''' , __lowercase)
if not (self.add_prefix_space or not is_split_into_words):
raise Exception(
f"""You need to instantiate {self.__class__.__name__} with add_prefix_space=True to use it with"""
''' pretokenized inputs.''')
return super()._batch_encode_plus(*__lowercase , **__lowercase)
def UpperCamelCase__ ( self , *__lowercase , **__lowercase) -> BatchEncoding:
__UpperCamelCase :List[str] = kwargs.get('''is_split_into_words''' , __lowercase)
if not (self.add_prefix_space or not is_split_into_words):
raise Exception(
f"""You need to instantiate {self.__class__.__name__} with add_prefix_space=True to use it with"""
''' pretokenized inputs.''')
return super()._encode_plus(*__lowercase , **__lowercase)
def UpperCamelCase__ ( self , __lowercase , __lowercase = None) -> Tuple[str]:
__UpperCamelCase :Optional[Any] = self._tokenizer.model.save(__lowercase , name=__lowercase)
return tuple(__lowercase)
def UpperCamelCase__ ( self , __lowercase) -> List[int]:
__UpperCamelCase :str = []
for is_user, text in conversation.iter_texts():
input_ids.extend(self.encode(__lowercase , add_special_tokens=__lowercase) + [self.eos_token_id])
if len(__lowercase) > self.model_max_length:
__UpperCamelCase :Any = input_ids[-self.model_max_length :]
return input_ids
| 43
| 1
|
from typing import TYPE_CHECKING
from ...utils import (
OptionalDependencyNotAvailable,
_LazyModule,
is_sentencepiece_available,
is_tokenizers_available,
is_torch_available,
is_vision_available,
)
__lowercase = {'''processing_layoutxlm''': ['''LayoutXLMProcessor''']}
try:
if not is_sentencepiece_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowercase = ['''LayoutXLMTokenizer''']
try:
if not is_tokenizers_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowercase = ['''LayoutXLMTokenizerFast''']
if TYPE_CHECKING:
from .processing_layoutxlm import LayoutXLMProcessor
try:
if not is_sentencepiece_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .tokenization_layoutxlm import LayoutXLMTokenizer
try:
if not is_tokenizers_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .tokenization_layoutxlm_fast import LayoutXLMTokenizerFast
else:
import sys
__lowercase = _LazyModule(__name__, globals()['''__file__'''], _import_structure, module_spec=__spec__)
| 43
|
from ...configuration_utils import PretrainedConfig
from ...utils import logging
__lowercase = logging.get_logger(__name__)
__lowercase = {'''ctrl''': '''https://huggingface.co/ctrl/resolve/main/config.json'''}
class lowerCamelCase_ ( UpperCAmelCase_ ):
'''simple docstring'''
a__ : str = """ctrl"""
a__ : Dict = ["""past_key_values"""]
a__ : Tuple = {
"""max_position_embeddings""": """n_positions""",
"""hidden_size""": """n_embd""",
"""num_attention_heads""": """n_head""",
"""num_hidden_layers""": """n_layer""",
}
def __init__( self , __lowercase=246_534 , __lowercase=256 , __lowercase=1_280 , __lowercase=8_192 , __lowercase=48 , __lowercase=16 , __lowercase=0.1 , __lowercase=0.1 , __lowercase=1E-6 , __lowercase=0.02 , __lowercase=True , **__lowercase , ) -> List[Any]:
__UpperCamelCase :List[str] = vocab_size
__UpperCamelCase :Optional[Any] = n_positions
__UpperCamelCase :Dict = n_embd
__UpperCamelCase :Dict = n_layer
__UpperCamelCase :List[Any] = n_head
__UpperCamelCase :int = dff
__UpperCamelCase :Union[str, Any] = resid_pdrop
__UpperCamelCase :Optional[int] = embd_pdrop
__UpperCamelCase :List[Any] = layer_norm_epsilon
__UpperCamelCase :Dict = initializer_range
__UpperCamelCase :Any = use_cache
super().__init__(**__lowercase)
| 43
| 1
|
from ..utils import DummyObject, requires_backends
class lowercase_ ( metaclass=lowercase ):
'''simple docstring'''
__snake_case = ['''torch''', '''transformers''', '''onnx''']
def __init__( self : Dict , *__UpperCAmelCase : Optional[int] , **__UpperCAmelCase : Tuple ) ->Dict:
"""simple docstring"""
requires_backends(self , ['''torch''', '''transformers''', '''onnx'''] )
@classmethod
def __lowerCAmelCase ( cls : Tuple , *__UpperCAmelCase : Tuple , **__UpperCAmelCase : List[Any] ) ->Optional[int]:
"""simple docstring"""
requires_backends(cls , ['''torch''', '''transformers''', '''onnx'''] )
@classmethod
def __lowerCAmelCase ( cls : List[str] , *__UpperCAmelCase : Any , **__UpperCAmelCase : int ) ->Tuple:
"""simple docstring"""
requires_backends(cls , ['''torch''', '''transformers''', '''onnx'''] )
class lowercase_ ( metaclass=lowercase ):
'''simple docstring'''
__snake_case = ['''torch''', '''transformers''', '''onnx''']
def __init__( self : List[str] , *__UpperCAmelCase : Union[str, Any] , **__UpperCAmelCase : List[Any] ) ->Optional[int]:
"""simple docstring"""
requires_backends(self , ['''torch''', '''transformers''', '''onnx'''] )
@classmethod
def __lowerCAmelCase ( cls : List[Any] , *__UpperCAmelCase : Tuple , **__UpperCAmelCase : Optional[int] ) ->Any:
"""simple docstring"""
requires_backends(cls , ['''torch''', '''transformers''', '''onnx'''] )
@classmethod
def __lowerCAmelCase ( cls : Tuple , *__UpperCAmelCase : List[Any] , **__UpperCAmelCase : Optional[Any] ) ->Tuple:
"""simple docstring"""
requires_backends(cls , ['''torch''', '''transformers''', '''onnx'''] )
class lowercase_ ( metaclass=lowercase ):
'''simple docstring'''
__snake_case = ['''torch''', '''transformers''', '''onnx''']
def __init__( self : str , *__UpperCAmelCase : str , **__UpperCAmelCase : Any ) ->Optional[Any]:
"""simple docstring"""
requires_backends(self , ['''torch''', '''transformers''', '''onnx'''] )
@classmethod
def __lowerCAmelCase ( cls : Union[str, Any] , *__UpperCAmelCase : Optional[int] , **__UpperCAmelCase : int ) ->Tuple:
"""simple docstring"""
requires_backends(cls , ['''torch''', '''transformers''', '''onnx'''] )
@classmethod
def __lowerCAmelCase ( cls : List[str] , *__UpperCAmelCase : List[Any] , **__UpperCAmelCase : List[str] ) ->List[str]:
"""simple docstring"""
requires_backends(cls , ['''torch''', '''transformers''', '''onnx'''] )
class lowercase_ ( metaclass=lowercase ):
'''simple docstring'''
__snake_case = ['''torch''', '''transformers''', '''onnx''']
def __init__( self : List[Any] , *__UpperCAmelCase : Optional[int] , **__UpperCAmelCase : Dict ) ->Tuple:
"""simple docstring"""
requires_backends(self , ['''torch''', '''transformers''', '''onnx'''] )
@classmethod
def __lowerCAmelCase ( cls : int , *__UpperCAmelCase : List[Any] , **__UpperCAmelCase : int ) ->Dict:
"""simple docstring"""
requires_backends(cls , ['''torch''', '''transformers''', '''onnx'''] )
@classmethod
def __lowerCAmelCase ( cls : Optional[int] , *__UpperCAmelCase : Any , **__UpperCAmelCase : List[Any] ) ->Union[str, Any]:
"""simple docstring"""
requires_backends(cls , ['''torch''', '''transformers''', '''onnx'''] )
class lowercase_ ( metaclass=lowercase ):
'''simple docstring'''
__snake_case = ['''torch''', '''transformers''', '''onnx''']
def __init__( self : Union[str, Any] , *__UpperCAmelCase : Any , **__UpperCAmelCase : Tuple ) ->Dict:
"""simple docstring"""
requires_backends(self , ['''torch''', '''transformers''', '''onnx'''] )
@classmethod
def __lowerCAmelCase ( cls : Union[str, Any] , *__UpperCAmelCase : Optional[Any] , **__UpperCAmelCase : Any ) ->str:
"""simple docstring"""
requires_backends(cls , ['''torch''', '''transformers''', '''onnx'''] )
@classmethod
def __lowerCAmelCase ( cls : str , *__UpperCAmelCase : Tuple , **__UpperCAmelCase : Dict ) ->Union[str, Any]:
"""simple docstring"""
requires_backends(cls , ['''torch''', '''transformers''', '''onnx'''] )
class lowercase_ ( metaclass=lowercase ):
'''simple docstring'''
__snake_case = ['''torch''', '''transformers''', '''onnx''']
def __init__( self : int , *__UpperCAmelCase : List[str] , **__UpperCAmelCase : Optional[Any] ) ->Any:
"""simple docstring"""
requires_backends(self , ['''torch''', '''transformers''', '''onnx'''] )
@classmethod
def __lowerCAmelCase ( cls : Optional[Any] , *__UpperCAmelCase : Tuple , **__UpperCAmelCase : Dict ) ->Any:
"""simple docstring"""
requires_backends(cls , ['''torch''', '''transformers''', '''onnx'''] )
@classmethod
def __lowerCAmelCase ( cls : Tuple , *__UpperCAmelCase : str , **__UpperCAmelCase : Union[str, Any] ) ->Optional[Any]:
"""simple docstring"""
requires_backends(cls , ['''torch''', '''transformers''', '''onnx'''] )
| 0
|
import unittest
import numpy as np
import torch
from transformers import CLIPTextConfig, CLIPTextModel, CLIPTokenizer
from diffusers import (
AutoencoderKL,
DDIMScheduler,
DPMSolverMultistepScheduler,
TextToVideoSDPipeline,
UNetaDConditionModel,
)
from diffusers.utils import is_xformers_available, load_numpy, skip_mps, slow, torch_device
from diffusers.utils.testing_utils import enable_full_determinism
from ..pipeline_params import TEXT_TO_IMAGE_BATCH_PARAMS, TEXT_TO_IMAGE_PARAMS
from ..test_pipelines_common import PipelineTesterMixin
enable_full_determinism()
@skip_mps
class lowerCamelCase_ ( UpperCAmelCase_ , unittest.TestCase ):
'''simple docstring'''
a__ : str = TextToVideoSDPipeline
a__ : Union[str, Any] = TEXT_TO_IMAGE_PARAMS
a__ : Tuple = TEXT_TO_IMAGE_BATCH_PARAMS
# No `output_type`.
a__ : int = frozenset(
[
"""num_inference_steps""",
"""generator""",
"""latents""",
"""return_dict""",
"""callback""",
"""callback_steps""",
] )
def UpperCamelCase__ ( self) -> Optional[Any]:
torch.manual_seed(0)
__UpperCamelCase :str = UNetaDConditionModel(
block_out_channels=(32, 64, 64, 64) , layers_per_block=2 , sample_size=32 , in_channels=4 , out_channels=4 , down_block_types=('''CrossAttnDownBlock3D''', '''CrossAttnDownBlock3D''', '''CrossAttnDownBlock3D''', '''DownBlock3D''') , up_block_types=('''UpBlock3D''', '''CrossAttnUpBlock3D''', '''CrossAttnUpBlock3D''', '''CrossAttnUpBlock3D''') , cross_attention_dim=32 , attention_head_dim=4 , )
__UpperCamelCase :Optional[int] = DDIMScheduler(
beta_start=0.0_00_85 , beta_end=0.0_12 , beta_schedule='''scaled_linear''' , clip_sample=__lowercase , set_alpha_to_one=__lowercase , )
torch.manual_seed(0)
__UpperCamelCase :Optional[int] = AutoencoderKL(
block_out_channels=[32, 64] , in_channels=3 , out_channels=3 , down_block_types=['''DownEncoderBlock2D''', '''DownEncoderBlock2D'''] , up_block_types=['''UpDecoderBlock2D''', '''UpDecoderBlock2D'''] , latent_channels=4 , sample_size=128 , )
torch.manual_seed(0)
__UpperCamelCase :Optional[int] = CLIPTextConfig(
bos_token_id=0 , eos_token_id=2 , hidden_size=32 , intermediate_size=37 , layer_norm_eps=1E-0_5 , num_attention_heads=4 , num_hidden_layers=5 , pad_token_id=1 , vocab_size=1_000 , hidden_act='''gelu''' , projection_dim=512 , )
__UpperCamelCase :Optional[Any] = CLIPTextModel(__lowercase)
__UpperCamelCase :Optional[int] = CLIPTokenizer.from_pretrained('''hf-internal-testing/tiny-random-clip''')
__UpperCamelCase :Union[str, Any] = {
'''unet''': unet,
'''scheduler''': scheduler,
'''vae''': vae,
'''text_encoder''': text_encoder,
'''tokenizer''': tokenizer,
}
return components
def UpperCamelCase__ ( self , __lowercase , __lowercase=0) -> Optional[int]:
if str(__lowercase).startswith('''mps'''):
__UpperCamelCase :List[Any] = torch.manual_seed(__lowercase)
else:
__UpperCamelCase :Tuple = torch.Generator(device=__lowercase).manual_seed(__lowercase)
__UpperCamelCase :Dict = {
'''prompt''': '''A painting of a squirrel eating a burger''',
'''generator''': generator,
'''num_inference_steps''': 2,
'''guidance_scale''': 6.0,
'''output_type''': '''pt''',
}
return inputs
def UpperCamelCase__ ( self) -> Optional[Any]:
__UpperCamelCase :int = '''cpu''' # ensure determinism for the device-dependent torch.Generator
__UpperCamelCase :Optional[int] = self.get_dummy_components()
__UpperCamelCase :Dict = TextToVideoSDPipeline(**__lowercase)
__UpperCamelCase :Any = sd_pipe.to(__lowercase)
sd_pipe.set_progress_bar_config(disable=__lowercase)
__UpperCamelCase :Optional[Any] = self.get_dummy_inputs(__lowercase)
__UpperCamelCase :int = '''np'''
__UpperCamelCase :List[str] = sd_pipe(**__lowercase).frames
__UpperCamelCase :Optional[Any] = frames[0][-3:, -3:, -1]
assert frames[0].shape == (64, 64, 3)
__UpperCamelCase :str = np.array([1_58.0, 1_60.0, 1_53.0, 1_25.0, 1_00.0, 1_21.0, 1_11.0, 93.0, 1_13.0])
assert np.abs(image_slice.flatten() - expected_slice).max() < 1E-2
def UpperCamelCase__ ( self) -> Tuple:
self._test_attention_slicing_forward_pass(test_mean_pixel_difference=__lowercase , expected_max_diff=3E-3)
@unittest.skipIf(
torch_device != '''cuda''' or not is_xformers_available() , reason='''XFormers attention is only available with CUDA and `xformers` installed''' , )
def UpperCamelCase__ ( self) -> Optional[int]:
self._test_xformers_attention_forwardGenerator_pass(test_mean_pixel_difference=__lowercase , expected_max_diff=1E-2)
@unittest.skip(reason='''Batching needs to be properly figured out first for this pipeline.''')
def UpperCamelCase__ ( self) -> Union[str, Any]:
pass
@unittest.skip(reason='''Batching needs to be properly figured out first for this pipeline.''')
def UpperCamelCase__ ( self) -> Dict:
pass
@unittest.skip(reason='''`num_images_per_prompt` argument is not supported for this pipeline.''')
def UpperCamelCase__ ( self) -> str:
pass
def UpperCamelCase__ ( self) -> List[str]:
return super().test_progress_bar()
@slow
@skip_mps
class lowerCamelCase_ ( unittest.TestCase ):
'''simple docstring'''
def UpperCamelCase__ ( self) -> Dict:
__UpperCamelCase :Union[str, Any] = load_numpy(
'''https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main/text_to_video/video.npy''')
__UpperCamelCase :List[str] = TextToVideoSDPipeline.from_pretrained('''damo-vilab/text-to-video-ms-1.7b''')
__UpperCamelCase :Union[str, Any] = DPMSolverMultistepScheduler.from_config(pipe.scheduler.config)
__UpperCamelCase :str = pipe.to('''cuda''')
__UpperCamelCase :Optional[Any] = '''Spiderman is surfing'''
__UpperCamelCase :Union[str, Any] = torch.Generator(device='''cpu''').manual_seed(0)
__UpperCamelCase :List[Any] = pipe(__lowercase , generator=__lowercase , num_inference_steps=25 , output_type='''pt''').frames
__UpperCamelCase :Optional[int] = video_frames.cpu().numpy()
assert np.abs(expected_video - video).mean() < 5E-2
def UpperCamelCase__ ( self) -> int:
__UpperCamelCase :str = load_numpy(
'''https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main/text_to_video/video_2step.npy''')
__UpperCamelCase :Union[str, Any] = TextToVideoSDPipeline.from_pretrained('''damo-vilab/text-to-video-ms-1.7b''')
__UpperCamelCase :str = pipe.to('''cuda''')
__UpperCamelCase :Union[str, Any] = '''Spiderman is surfing'''
__UpperCamelCase :int = torch.Generator(device='''cpu''').manual_seed(0)
__UpperCamelCase :List[Any] = pipe(__lowercase , generator=__lowercase , num_inference_steps=2 , output_type='''pt''').frames
__UpperCamelCase :Optional[Any] = video_frames.cpu().numpy()
assert np.abs(expected_video - video).mean() < 5E-2
| 43
| 0
|
'''simple docstring'''
import tempfile
import unittest
import numpy as np
from diffusers import (
DDIMScheduler,
DPMSolverMultistepScheduler,
EulerAncestralDiscreteScheduler,
EulerDiscreteScheduler,
LMSDiscreteScheduler,
OnnxStableDiffusionPipeline,
PNDMScheduler,
)
from diffusers.utils.testing_utils import is_onnx_available, nightly, require_onnxruntime, require_torch_gpu
from ..test_pipelines_onnx_common import OnnxPipelineTesterMixin
if is_onnx_available():
import onnxruntime as ort
class __A ( UpperCamelCase__ , unittest.TestCase ):
a__ : str = """hf-internal-testing/tiny-random-OnnxStableDiffusionPipeline"""
def _lowercase (self : List[str] , __a : str=0 ):
UpperCAmelCase_ = np.random.RandomState(__a )
UpperCAmelCase_ = {
"prompt": "A painting of a squirrel eating a burger",
"generator": generator,
"num_inference_steps": 2,
"guidance_scale": 7.5,
"output_type": "numpy",
}
return inputs
def _lowercase (self : Dict ):
UpperCAmelCase_ = OnnxStableDiffusionPipeline.from_pretrained(self.hub_checkpoint , provider="CPUExecutionProvider" )
pipe.set_progress_bar_config(disable=__a )
UpperCAmelCase_ = self.get_dummy_inputs()
UpperCAmelCase_ = pipe(**__a ).images
UpperCAmelCase_ = image[0, -3:, -3:, -1]
assert image.shape == (1, 128, 128, 3)
UpperCAmelCase_ = np.array([0.6_50_72, 0.5_84_92, 0.4_82_19, 0.5_55_21, 0.5_31_80, 0.5_59_39, 0.5_06_97, 0.3_98_00, 0.4_64_55] )
assert np.abs(image_slice.flatten() - expected_slice ).max() < 1E-2
def _lowercase (self : Any ):
UpperCAmelCase_ = OnnxStableDiffusionPipeline.from_pretrained(self.hub_checkpoint , provider="CPUExecutionProvider" )
UpperCAmelCase_ = PNDMScheduler.from_config(pipe.scheduler.config , skip_prk_steps=__a )
pipe.set_progress_bar_config(disable=__a )
UpperCAmelCase_ = self.get_dummy_inputs()
UpperCAmelCase_ = pipe(**__a ).images
UpperCAmelCase_ = image[0, -3:, -3:, -1]
assert image.shape == (1, 128, 128, 3)
UpperCAmelCase_ = np.array([0.6_58_63, 0.5_94_25, 0.4_93_26, 0.5_63_13, 0.5_38_75, 0.5_66_27, 0.5_10_65, 0.3_97_77, 0.4_63_30] )
assert np.abs(image_slice.flatten() - expected_slice ).max() < 1E-2
def _lowercase (self : Tuple ):
UpperCAmelCase_ = OnnxStableDiffusionPipeline.from_pretrained(self.hub_checkpoint , provider="CPUExecutionProvider" )
UpperCAmelCase_ = LMSDiscreteScheduler.from_config(pipe.scheduler.config )
pipe.set_progress_bar_config(disable=__a )
UpperCAmelCase_ = self.get_dummy_inputs()
UpperCAmelCase_ = pipe(**__a ).images
UpperCAmelCase_ = image[0, -3:, -3:, -1]
assert image.shape == (1, 128, 128, 3)
UpperCAmelCase_ = np.array([0.5_37_55, 0.6_07_86, 0.4_74_02, 0.4_94_88, 0.5_18_69, 0.4_98_19, 0.4_79_85, 0.3_89_57, 0.4_42_79] )
assert np.abs(image_slice.flatten() - expected_slice ).max() < 1E-2
def _lowercase (self : Union[str, Any] ):
UpperCAmelCase_ = OnnxStableDiffusionPipeline.from_pretrained(self.hub_checkpoint , provider="CPUExecutionProvider" )
UpperCAmelCase_ = EulerDiscreteScheduler.from_config(pipe.scheduler.config )
pipe.set_progress_bar_config(disable=__a )
UpperCAmelCase_ = self.get_dummy_inputs()
UpperCAmelCase_ = pipe(**__a ).images
UpperCAmelCase_ = image[0, -3:, -3:, -1]
assert image.shape == (1, 128, 128, 3)
UpperCAmelCase_ = np.array([0.5_37_55, 0.6_07_86, 0.4_74_02, 0.4_94_88, 0.5_18_69, 0.4_98_19, 0.4_79_85, 0.3_89_57, 0.4_42_79] )
assert np.abs(image_slice.flatten() - expected_slice ).max() < 1E-2
def _lowercase (self : Tuple ):
UpperCAmelCase_ = OnnxStableDiffusionPipeline.from_pretrained(self.hub_checkpoint , provider="CPUExecutionProvider" )
UpperCAmelCase_ = EulerAncestralDiscreteScheduler.from_config(pipe.scheduler.config )
pipe.set_progress_bar_config(disable=__a )
UpperCAmelCase_ = self.get_dummy_inputs()
UpperCAmelCase_ = pipe(**__a ).images
UpperCAmelCase_ = image[0, -3:, -3:, -1]
assert image.shape == (1, 128, 128, 3)
UpperCAmelCase_ = np.array([0.5_38_17, 0.6_08_12, 0.4_73_84, 0.4_95_30, 0.5_18_94, 0.4_98_14, 0.4_79_84, 0.3_89_58, 0.4_42_71] )
assert np.abs(image_slice.flatten() - expected_slice ).max() < 1E-2
def _lowercase (self : Dict ):
UpperCAmelCase_ = OnnxStableDiffusionPipeline.from_pretrained(self.hub_checkpoint , provider="CPUExecutionProvider" )
UpperCAmelCase_ = DPMSolverMultistepScheduler.from_config(pipe.scheduler.config )
pipe.set_progress_bar_config(disable=__a )
UpperCAmelCase_ = self.get_dummy_inputs()
UpperCAmelCase_ = pipe(**__a ).images
UpperCAmelCase_ = image[0, -3:, -3:, -1]
assert image.shape == (1, 128, 128, 3)
UpperCAmelCase_ = np.array([0.5_38_95, 0.6_08_08, 0.4_79_33, 0.4_96_08, 0.5_18_86, 0.4_99_50, 0.4_80_53, 0.3_89_57, 0.4_42_00] )
assert np.abs(image_slice.flatten() - expected_slice ).max() < 1E-2
def _lowercase (self : Dict ):
UpperCAmelCase_ = OnnxStableDiffusionPipeline.from_pretrained(self.hub_checkpoint , provider="CPUExecutionProvider" )
pipe.set_progress_bar_config(disable=__a )
UpperCAmelCase_ = self.get_dummy_inputs()
UpperCAmelCase_ = 3 * [inputs["prompt"]]
# forward
UpperCAmelCase_ = pipe(**__a )
UpperCAmelCase_ = output.images[0, -3:, -3:, -1]
UpperCAmelCase_ = self.get_dummy_inputs()
UpperCAmelCase_ = 3 * [inputs.pop("prompt" )]
UpperCAmelCase_ = pipe.tokenizer(
__a , padding="max_length" , max_length=pipe.tokenizer.model_max_length , truncation=__a , return_tensors="np" , )
UpperCAmelCase_ = text_inputs["input_ids"]
UpperCAmelCase_ = pipe.text_encoder(input_ids=text_inputs.astype(np.intaa ) )[0]
UpperCAmelCase_ = prompt_embeds
# forward
UpperCAmelCase_ = pipe(**__a )
UpperCAmelCase_ = output.images[0, -3:, -3:, -1]
assert np.abs(image_slice_a.flatten() - image_slice_a.flatten() ).max() < 1E-4
def _lowercase (self : Any ):
UpperCAmelCase_ = OnnxStableDiffusionPipeline.from_pretrained(self.hub_checkpoint , provider="CPUExecutionProvider" )
pipe.set_progress_bar_config(disable=__a )
UpperCAmelCase_ = self.get_dummy_inputs()
UpperCAmelCase_ = 3 * ["this is a negative prompt"]
UpperCAmelCase_ = negative_prompt
UpperCAmelCase_ = 3 * [inputs["prompt"]]
# forward
UpperCAmelCase_ = pipe(**__a )
UpperCAmelCase_ = output.images[0, -3:, -3:, -1]
UpperCAmelCase_ = self.get_dummy_inputs()
UpperCAmelCase_ = 3 * [inputs.pop("prompt" )]
UpperCAmelCase_ = []
for p in [prompt, negative_prompt]:
UpperCAmelCase_ = pipe.tokenizer(
__a , padding="max_length" , max_length=pipe.tokenizer.model_max_length , truncation=__a , return_tensors="np" , )
UpperCAmelCase_ = text_inputs["input_ids"]
embeds.append(pipe.text_encoder(input_ids=text_inputs.astype(np.intaa ) )[0] )
UpperCAmelCase_ , UpperCAmelCase_ = embeds
# forward
UpperCAmelCase_ = pipe(**__a )
UpperCAmelCase_ = output.images[0, -3:, -3:, -1]
assert np.abs(image_slice_a.flatten() - image_slice_a.flatten() ).max() < 1E-4
@nightly
@require_onnxruntime
@require_torch_gpu
class __A ( unittest.TestCase ):
@property
def _lowercase (self : List[str] ):
return (
"CUDAExecutionProvider",
{
"gpu_mem_limit": "15000000000", # 15GB
"arena_extend_strategy": "kSameAsRequested",
},
)
@property
def _lowercase (self : int ):
UpperCAmelCase_ = ort.SessionOptions()
UpperCAmelCase_ = False
return options
def _lowercase (self : str ):
# using the PNDM scheduler by default
UpperCAmelCase_ = OnnxStableDiffusionPipeline.from_pretrained(
"CompVis/stable-diffusion-v1-4" , revision="onnx" , safety_checker=__a , feature_extractor=__a , provider=self.gpu_provider , sess_options=self.gpu_options , )
sd_pipe.set_progress_bar_config(disable=__a )
UpperCAmelCase_ = "A painting of a squirrel eating a burger"
np.random.seed(0 )
UpperCAmelCase_ = sd_pipe([prompt] , guidance_scale=6.0 , num_inference_steps=10 , output_type="np" )
UpperCAmelCase_ = output.images
UpperCAmelCase_ = image[0, -3:, -3:, -1]
assert image.shape == (1, 512, 512, 3)
UpperCAmelCase_ = np.array([0.04_52, 0.03_90, 0.00_87, 0.03_50, 0.06_17, 0.03_64, 0.05_44, 0.05_23, 0.07_20] )
assert np.abs(image_slice.flatten() - expected_slice ).max() < 1E-3
def _lowercase (self : Tuple ):
UpperCAmelCase_ = DDIMScheduler.from_pretrained(
"runwayml/stable-diffusion-v1-5" , subfolder="scheduler" , revision="onnx" )
UpperCAmelCase_ = OnnxStableDiffusionPipeline.from_pretrained(
"runwayml/stable-diffusion-v1-5" , revision="onnx" , scheduler=__a , safety_checker=__a , feature_extractor=__a , provider=self.gpu_provider , sess_options=self.gpu_options , )
sd_pipe.set_progress_bar_config(disable=__a )
UpperCAmelCase_ = "open neural network exchange"
UpperCAmelCase_ = np.random.RandomState(0 )
UpperCAmelCase_ = sd_pipe([prompt] , guidance_scale=7.5 , num_inference_steps=10 , generator=__a , output_type="np" )
UpperCAmelCase_ = output.images
UpperCAmelCase_ = image[0, -3:, -3:, -1]
assert image.shape == (1, 512, 512, 3)
UpperCAmelCase_ = np.array([0.28_67, 0.19_74, 0.14_81, 0.72_94, 0.72_51, 0.66_67, 0.41_94, 0.56_42, 0.64_86] )
assert np.abs(image_slice.flatten() - expected_slice ).max() < 1E-3
def _lowercase (self : List[Any] ):
UpperCAmelCase_ = LMSDiscreteScheduler.from_pretrained(
"runwayml/stable-diffusion-v1-5" , subfolder="scheduler" , revision="onnx" )
UpperCAmelCase_ = OnnxStableDiffusionPipeline.from_pretrained(
"runwayml/stable-diffusion-v1-5" , revision="onnx" , scheduler=__a , safety_checker=__a , feature_extractor=__a , provider=self.gpu_provider , sess_options=self.gpu_options , )
sd_pipe.set_progress_bar_config(disable=__a )
UpperCAmelCase_ = "open neural network exchange"
UpperCAmelCase_ = np.random.RandomState(0 )
UpperCAmelCase_ = sd_pipe([prompt] , guidance_scale=7.5 , num_inference_steps=10 , generator=__a , output_type="np" )
UpperCAmelCase_ = output.images
UpperCAmelCase_ = image[0, -3:, -3:, -1]
assert image.shape == (1, 512, 512, 3)
UpperCAmelCase_ = np.array([0.23_06, 0.19_59, 0.15_93, 0.65_49, 0.63_94, 0.54_08, 0.50_65, 0.60_10, 0.61_61] )
assert np.abs(image_slice.flatten() - expected_slice ).max() < 1E-3
def _lowercase (self : Optional[int] ):
UpperCAmelCase_ = 0
def test_callback_fn(__a : int , __a : int , __a : np.ndarray ) -> None:
UpperCAmelCase_ = True
nonlocal number_of_steps
number_of_steps += 1
if step == 0:
assert latents.shape == (1, 4, 64, 64)
UpperCAmelCase_ = latents[0, -3:, -3:, -1]
UpperCAmelCase_ = np.array(
[-0.67_72, -0.38_35, -1.24_56, 0.19_05, -1.09_74, 0.69_67, -1.93_53, 0.01_78, 1.01_67] )
assert np.abs(latents_slice.flatten() - expected_slice ).max() < 1E-3
elif step == 5:
assert latents.shape == (1, 4, 64, 64)
UpperCAmelCase_ = latents[0, -3:, -3:, -1]
UpperCAmelCase_ = np.array(
[-0.33_51, 0.22_41, -0.18_37, -0.23_25, -0.65_77, 0.33_93, -0.02_41, 0.58_99, 1.38_75] )
assert np.abs(latents_slice.flatten() - expected_slice ).max() < 1E-3
UpperCAmelCase_ = False
UpperCAmelCase_ = OnnxStableDiffusionPipeline.from_pretrained(
"runwayml/stable-diffusion-v1-5" , revision="onnx" , safety_checker=__a , feature_extractor=__a , provider=self.gpu_provider , sess_options=self.gpu_options , )
pipe.set_progress_bar_config(disable=__a )
UpperCAmelCase_ = "Andromeda galaxy in a bottle"
UpperCAmelCase_ = np.random.RandomState(0 )
pipe(
prompt=__a , num_inference_steps=5 , guidance_scale=7.5 , generator=__a , callback=__a , callback_steps=1 , )
assert test_callback_fn.has_been_called
assert number_of_steps == 6
def _lowercase (self : List[Any] ):
UpperCAmelCase_ = OnnxStableDiffusionPipeline.from_pretrained(
"runwayml/stable-diffusion-v1-5" , revision="onnx" , safety_checker=__a , feature_extractor=__a , provider=self.gpu_provider , sess_options=self.gpu_options , )
assert isinstance(__a , __a )
assert pipe.safety_checker is None
UpperCAmelCase_ = pipe("example prompt" , num_inference_steps=2 ).images[0]
assert image is not None
# check that there's no error when saving a pipeline with one of the models being None
with tempfile.TemporaryDirectory() as tmpdirname:
pipe.save_pretrained(__a )
UpperCAmelCase_ = OnnxStableDiffusionPipeline.from_pretrained(__a )
# sanity check that the pipeline still works
assert pipe.safety_checker is None
UpperCAmelCase_ = pipe("example prompt" , num_inference_steps=2 ).images[0]
assert image is not None
| 1
|
def lowerCamelCase ( SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Tuple = [0 for i in range(len(SCREAMING_SNAKE_CASE ) )]
# initialize interval's left pointer and right pointer
__UpperCamelCase , __UpperCamelCase :str = 0, 0
for i in range(1 , len(SCREAMING_SNAKE_CASE ) ):
# case when current index is inside the interval
if i <= right_pointer:
__UpperCamelCase :Union[str, Any] = min(right_pointer - i + 1 , z_result[i - left_pointer] )
__UpperCamelCase :Tuple = min_edge
while go_next(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
z_result[i] += 1
# if new index's result gives us more right interval,
# we've to update left_pointer and right_pointer
if i + z_result[i] - 1 > right_pointer:
__UpperCamelCase , __UpperCamelCase :Union[str, Any] = i, i + z_result[i] - 1
return z_result
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
return i + z_result[i] < len(SCREAMING_SNAKE_CASE ) and s[z_result[i]] == s[i + z_result[i]]
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :List[Any] = 0
# concatenate 'pattern' and 'input_str' and call z_function
# with concatenated string
__UpperCamelCase :Tuple = z_function(pattern + input_str )
for val in z_result:
# if value is greater then length of the pattern string
# that means this index is starting position of substring
# which is equal to pattern string
if val >= len(SCREAMING_SNAKE_CASE ):
answer += 1
return answer
if __name__ == "__main__":
import doctest
doctest.testmod()
| 43
| 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
| 2
|
import math
from typing import Any, Callable, List, Optional, Tuple, Union
import numpy as np
import torch
from ...models import TaFilmDecoder
from ...schedulers import DDPMScheduler
from ...utils import is_onnx_available, logging, randn_tensor
if is_onnx_available():
from ..onnx_utils import OnnxRuntimeModel
from ..pipeline_utils import AudioPipelineOutput, DiffusionPipeline
from .continous_encoder import SpectrogramContEncoder
from .notes_encoder import SpectrogramNotesEncoder
__lowercase = logging.get_logger(__name__) # pylint: disable=invalid-name
__lowercase = 256
class lowerCamelCase_ ( UpperCAmelCase_ ):
'''simple docstring'''
a__ : Tuple = ["""melgan"""]
def __init__( self , __lowercase , __lowercase , __lowercase , __lowercase , __lowercase , ) -> None:
super().__init__()
# From MELGAN
__UpperCamelCase :int = math.log(1E-5) # Matches MelGAN training.
__UpperCamelCase :int = 4.0 # Largest value for most examples
__UpperCamelCase :str = 128
self.register_modules(
notes_encoder=__lowercase , continuous_encoder=__lowercase , decoder=__lowercase , scheduler=__lowercase , melgan=__lowercase , )
def UpperCamelCase__ ( self , __lowercase , __lowercase=(-1.0, 1.0) , __lowercase=False) -> Dict:
__UpperCamelCase , __UpperCamelCase :str = output_range
if clip:
__UpperCamelCase :Union[str, Any] = torch.clip(__lowercase , self.min_value , self.max_value)
# Scale to [0, 1].
__UpperCamelCase :Union[str, Any] = (features - self.min_value) / (self.max_value - self.min_value)
# Scale to [min_out, max_out].
return zero_one * (max_out - min_out) + min_out
def UpperCamelCase__ ( self , __lowercase , __lowercase=(-1.0, 1.0) , __lowercase=False) -> Optional[int]:
__UpperCamelCase , __UpperCamelCase :int = input_range
__UpperCamelCase :Optional[int] = torch.clip(__lowercase , __lowercase , __lowercase) if clip else outputs
# Scale to [0, 1].
__UpperCamelCase :List[str] = (outputs - min_out) / (max_out - min_out)
# Scale to [self.min_value, self.max_value].
return zero_one * (self.max_value - self.min_value) + self.min_value
def UpperCamelCase__ ( self , __lowercase , __lowercase , __lowercase) -> List[Any]:
__UpperCamelCase :List[str] = input_tokens > 0
__UpperCamelCase , __UpperCamelCase :Union[str, Any] = self.notes_encoder(
encoder_input_tokens=__lowercase , encoder_inputs_mask=__lowercase)
__UpperCamelCase , __UpperCamelCase :Union[str, Any] = self.continuous_encoder(
encoder_inputs=__lowercase , encoder_inputs_mask=__lowercase)
return [(tokens_encoded, tokens_mask), (continuous_encoded, continuous_mask)]
def UpperCamelCase__ ( self , __lowercase , __lowercase , __lowercase) -> str:
__UpperCamelCase :Optional[int] = noise_time
if not torch.is_tensor(__lowercase):
__UpperCamelCase :str = torch.tensor([timesteps] , dtype=torch.long , device=input_tokens.device)
elif torch.is_tensor(__lowercase) and len(timesteps.shape) == 0:
__UpperCamelCase :Dict = timesteps[None].to(input_tokens.device)
# broadcast to batch dimension in a way that's compatible with ONNX/Core ML
__UpperCamelCase :List[str] = timesteps * torch.ones(input_tokens.shape[0] , dtype=timesteps.dtype , device=timesteps.device)
__UpperCamelCase :Tuple = self.decoder(
encodings_and_masks=__lowercase , decoder_input_tokens=__lowercase , decoder_noise_time=__lowercase)
return logits
@torch.no_grad()
def __call__( self , __lowercase , __lowercase = None , __lowercase = 100 , __lowercase = True , __lowercase = "numpy" , __lowercase = None , __lowercase = 1 , ) -> Union[AudioPipelineOutput, Tuple]:
if (callback_steps is None) or (
callback_steps is not None and (not isinstance(__lowercase , __lowercase) or callback_steps <= 0)
):
raise ValueError(
f"""`callback_steps` has to be a positive integer but is {callback_steps} of type"""
f""" {type(__lowercase)}.""")
__UpperCamelCase :Union[str, Any] = np.zeros([1, TARGET_FEATURE_LENGTH, self.n_dims] , dtype=np.floataa)
__UpperCamelCase :Union[str, Any] = np.zeros([1, 0, self.n_dims] , np.floataa)
__UpperCamelCase :Union[str, Any] = torch.ones((1, TARGET_FEATURE_LENGTH) , dtype=__lowercase , device=self.device)
for i, encoder_input_tokens in enumerate(__lowercase):
if i == 0:
__UpperCamelCase :int = torch.from_numpy(pred_mel[:1].copy()).to(
device=self.device , dtype=self.decoder.dtype)
# The first chunk has no previous context.
__UpperCamelCase :int = torch.zeros((1, TARGET_FEATURE_LENGTH) , dtype=__lowercase , device=self.device)
else:
# The full song pipeline does not feed in a context feature, so the mask
# will be all 0s after the feature converter. Because we know we're
# feeding in a full context chunk from the previous prediction, set it
# to all 1s.
__UpperCamelCase :Tuple = ones
__UpperCamelCase :Optional[Any] = self.scale_features(
__lowercase , output_range=[-1.0, 1.0] , clip=__lowercase)
__UpperCamelCase :int = self.encode(
input_tokens=torch.IntTensor([encoder_input_tokens]).to(device=self.device) , continuous_inputs=__lowercase , continuous_mask=__lowercase , )
# Sample encoder_continuous_inputs shaped gaussian noise to begin loop
__UpperCamelCase :int = randn_tensor(
shape=encoder_continuous_inputs.shape , generator=__lowercase , device=self.device , dtype=self.decoder.dtype , )
# set step values
self.scheduler.set_timesteps(__lowercase)
# Denoising diffusion loop
for j, t in enumerate(self.progress_bar(self.scheduler.timesteps)):
__UpperCamelCase :Optional[int] = self.decode(
encodings_and_masks=__lowercase , input_tokens=__lowercase , noise_time=t / self.scheduler.config.num_train_timesteps , )
# Compute previous output: x_t -> x_t-1
__UpperCamelCase :int = self.scheduler.step(__lowercase , __lowercase , __lowercase , generator=__lowercase).prev_sample
__UpperCamelCase :Tuple = self.scale_to_features(__lowercase , input_range=[-1.0, 1.0])
__UpperCamelCase :List[Any] = mel[:1]
__UpperCamelCase :Optional[Any] = mel.cpu().float().numpy()
__UpperCamelCase :Any = np.concatenate([full_pred_mel, pred_mel[:1]] , axis=1)
# call the callback, if provided
if callback is not None and i % callback_steps == 0:
callback(__lowercase , __lowercase)
logger.info('''Generated segment''' , __lowercase)
if output_type == "numpy" and not is_onnx_available():
raise ValueError(
'''Cannot return output in \'np\' format if ONNX is not available. Make sure to have ONNX installed or set \'output_type\' to \'mel\'.''')
elif output_type == "numpy" and self.melgan is None:
raise ValueError(
'''Cannot return output in \'np\' format if melgan component is not defined. Make sure to define `self.melgan` or set \'output_type\' to \'mel\'.''')
if output_type == "numpy":
__UpperCamelCase :Optional[Any] = self.melgan(input_features=full_pred_mel.astype(np.floataa))
else:
__UpperCamelCase :List[str] = full_pred_mel
if not return_dict:
return (output,)
return AudioPipelineOutput(audios=__lowercase)
| 43
| 0
|
'''simple docstring'''
import warnings
from ...processing_utils import ProcessorMixin
from ...tokenization_utils_base import BatchEncoding
class A ( __snake_case ):
__magic_name__ = ['''image_processor''', '''tokenizer''']
__magic_name__ = '''ViTImageProcessor'''
__magic_name__ = ('''CLIPTokenizer''', '''CLIPTokenizerFast''')
def __init__( self , SCREAMING_SNAKE_CASE=None , SCREAMING_SNAKE_CASE=None , **SCREAMING_SNAKE_CASE ) -> Tuple:
"""simple docstring"""
A : Optional[Any] = None
if "feature_extractor" in kwargs:
warnings.warn(
'''The `feature_extractor` argument is deprecated and will be removed in v5, use `image_processor`'''
''' instead.''' , SCREAMING_SNAKE_CASE , )
A : int = kwargs.pop('''feature_extractor''' )
A : Dict = 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__(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
def __call__( self , SCREAMING_SNAKE_CASE=None , SCREAMING_SNAKE_CASE=None , SCREAMING_SNAKE_CASE=None , SCREAMING_SNAKE_CASE=None , **SCREAMING_SNAKE_CASE ) -> Any:
"""simple docstring"""
if text is None and visual_prompt is None and images is None:
raise ValueError('''You have to specify either text, visual prompt or images.''' )
if text is not None and visual_prompt is not None:
raise ValueError('''You have to specify exactly one type of prompt. Either text or visual prompt.''' )
if text is not None:
A : str = self.tokenizer(SCREAMING_SNAKE_CASE , return_tensors=SCREAMING_SNAKE_CASE , **SCREAMING_SNAKE_CASE )
if visual_prompt is not None:
A : str = self.image_processor(SCREAMING_SNAKE_CASE , return_tensors=SCREAMING_SNAKE_CASE , **SCREAMING_SNAKE_CASE )
if images is not None:
A : Any = self.image_processor(SCREAMING_SNAKE_CASE , return_tensors=SCREAMING_SNAKE_CASE , **SCREAMING_SNAKE_CASE )
if visual_prompt is not None and images is not None:
A : Optional[int] = {
'''pixel_values''': image_features.pixel_values,
'''conditional_pixel_values''': prompt_features.pixel_values,
}
return encoding
elif text is not None and images is not None:
A : List[Any] = image_features.pixel_values
return encoding
elif text is not None:
return encoding
elif visual_prompt is not None:
A : int = {
'''conditional_pixel_values''': prompt_features.pixel_values,
}
return encoding
else:
return BatchEncoding(data=dict(**SCREAMING_SNAKE_CASE ) , tensor_type=SCREAMING_SNAKE_CASE )
def __lowerCAmelCase ( self , *SCREAMING_SNAKE_CASE , **SCREAMING_SNAKE_CASE ) -> Dict:
"""simple docstring"""
return self.tokenizer.batch_decode(*SCREAMING_SNAKE_CASE , **SCREAMING_SNAKE_CASE )
def __lowerCAmelCase ( self , *SCREAMING_SNAKE_CASE , **SCREAMING_SNAKE_CASE ) -> int:
"""simple docstring"""
return self.tokenizer.decode(*SCREAMING_SNAKE_CASE , **SCREAMING_SNAKE_CASE )
@property
def __lowerCAmelCase ( self ) -> str:
"""simple docstring"""
warnings.warn(
'''`feature_extractor_class` is deprecated and will be removed in v5. Use `image_processor_class` instead.''' , SCREAMING_SNAKE_CASE , )
return self.image_processor_class
@property
def __lowerCAmelCase ( self ) -> Union[str, Any]:
"""simple docstring"""
warnings.warn(
'''`feature_extractor` is deprecated and will be removed in v5. Use `image_processor` instead.''' , SCREAMING_SNAKE_CASE , )
return self.image_processor
| 3
|
import argparse
import json
import os
import fairseq
import torch
from fairseq.data import Dictionary
from transformers import (
HubertConfig,
HubertForCTC,
HubertModel,
WavaVecaCTCTokenizer,
WavaVecaFeatureExtractor,
WavaVecaProcessor,
logging,
)
logging.set_verbosity_info()
__lowercase = logging.get_logger(__name__)
__lowercase = {
'''post_extract_proj''': '''feature_projection.projection''',
'''encoder.pos_conv.0''': '''encoder.pos_conv_embed.conv''',
'''self_attn.k_proj''': '''encoder.layers.*.attention.k_proj''',
'''self_attn.v_proj''': '''encoder.layers.*.attention.v_proj''',
'''self_attn.q_proj''': '''encoder.layers.*.attention.q_proj''',
'''self_attn.out_proj''': '''encoder.layers.*.attention.out_proj''',
'''self_attn_layer_norm''': '''encoder.layers.*.layer_norm''',
'''fc1''': '''encoder.layers.*.feed_forward.intermediate_dense''',
'''fc2''': '''encoder.layers.*.feed_forward.output_dense''',
'''final_layer_norm''': '''encoder.layers.*.final_layer_norm''',
'''encoder.layer_norm''': '''encoder.layer_norm''',
'''w2v_model.layer_norm''': '''feature_projection.layer_norm''',
'''w2v_encoder.proj''': '''lm_head''',
'''mask_emb''': '''masked_spec_embed''',
}
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
for attribute in key.split('''.''' ):
__UpperCamelCase :str = getattr(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
if weight_type is not None:
__UpperCamelCase :Any = getattr(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ).shape
else:
__UpperCamelCase :Union[str, Any] = hf_pointer.shape
assert hf_shape == value.shape, (
f"""Shape of hf {key + '.' + weight_type if weight_type is not None else ''} is {hf_shape}, but should be"""
f""" {value.shape} for {full_name}"""
)
if weight_type == "weight":
__UpperCamelCase :str = value
elif weight_type == "weight_g":
__UpperCamelCase :List[str] = value
elif weight_type == "weight_v":
__UpperCamelCase :str = value
elif weight_type == "bias":
__UpperCamelCase :Union[str, Any] = value
else:
__UpperCamelCase :str = value
logger.info(f"""{key + '.' + weight_type if weight_type is not None else ''} was initialized from {full_name}.""" )
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :List[Any] = []
__UpperCamelCase :int = fairseq_model.state_dict()
__UpperCamelCase :List[Any] = hf_model.hubert.feature_extractor if is_finetuned else hf_model.feature_extractor
for name, value in fairseq_dict.items():
__UpperCamelCase :List[Any] = False
if "conv_layers" in name:
load_conv_layer(
SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , hf_model.config.feat_extract_norm == '''group''' , )
__UpperCamelCase :List[str] = True
else:
for key, mapped_key in MAPPING.items():
__UpperCamelCase :Dict = '''hubert.''' + mapped_key if (is_finetuned and mapped_key != '''lm_head''') else mapped_key
if key in name or (key.split('''w2v_model.''' )[-1] == name.split('''.''' )[0] and not is_finetuned):
__UpperCamelCase :Optional[Any] = True
if "*" in mapped_key:
__UpperCamelCase :List[str] = name.split(SCREAMING_SNAKE_CASE )[0].split('''.''' )[-2]
__UpperCamelCase :Optional[int] = mapped_key.replace('''*''' , SCREAMING_SNAKE_CASE )
if "weight_g" in name:
__UpperCamelCase :int = '''weight_g'''
elif "weight_v" in name:
__UpperCamelCase :List[Any] = '''weight_v'''
elif "weight" in name:
__UpperCamelCase :Dict = '''weight'''
elif "bias" in name:
__UpperCamelCase :Dict = '''bias'''
else:
__UpperCamelCase :Dict = None
set_recursively(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
continue
if not is_used:
unused_weights.append(SCREAMING_SNAKE_CASE )
logger.warning(f"""Unused weights: {unused_weights}""" )
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Tuple = full_name.split('''conv_layers.''' )[-1]
__UpperCamelCase :Optional[int] = name.split('''.''' )
__UpperCamelCase :str = int(items[0] )
__UpperCamelCase :List[Any] = int(items[1] )
if type_id == 0:
if "bias" in name:
assert value.shape == feature_extractor.conv_layers[layer_id].conv.bias.data.shape, (
f"""{full_name} has size {value.shape}, but"""
f""" {feature_extractor.conv_layers[layer_id].conv.bias.data.shape} was found."""
)
__UpperCamelCase :Dict = value
logger.info(f"""Feat extract conv layer {layer_id} was initialized from {full_name}.""" )
elif "weight" in name:
assert value.shape == feature_extractor.conv_layers[layer_id].conv.weight.data.shape, (
f"""{full_name} has size {value.shape}, but"""
f""" {feature_extractor.conv_layers[layer_id].conv.weight.data.shape} was found."""
)
__UpperCamelCase :Any = value
logger.info(f"""Feat extract conv layer {layer_id} was initialized from {full_name}.""" )
elif (type_id == 2 and not use_group_norm) or (type_id == 2 and layer_id == 0 and use_group_norm):
if "bias" in name:
assert value.shape == feature_extractor.conv_layers[layer_id].layer_norm.bias.data.shape, (
f"""{full_name} has size {value.shape}, but {feature_extractor[layer_id].layer_norm.bias.data.shape} was"""
" found."
)
__UpperCamelCase :int = value
logger.info(f"""Feat extract layer norm weight of layer {layer_id} was initialized from {full_name}.""" )
elif "weight" in name:
assert value.shape == feature_extractor.conv_layers[layer_id].layer_norm.weight.data.shape, (
f"""{full_name} has size {value.shape}, but"""
f""" {feature_extractor[layer_id].layer_norm.weight.data.shape} was found."""
)
__UpperCamelCase :Union[str, Any] = value
logger.info(f"""Feat extract layer norm weight of layer {layer_id} was initialized from {full_name}.""" )
else:
unused_weights.append(SCREAMING_SNAKE_CASE )
@torch.no_grad()
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE=None , SCREAMING_SNAKE_CASE=None , SCREAMING_SNAKE_CASE=True ):
'''simple docstring'''
if config_path is not None:
__UpperCamelCase :Tuple = HubertConfig.from_pretrained(SCREAMING_SNAKE_CASE )
else:
__UpperCamelCase :Optional[int] = HubertConfig()
if is_finetuned:
if dict_path:
__UpperCamelCase :Optional[int] = Dictionary.load(SCREAMING_SNAKE_CASE )
# important change bos & pad token id since CTC symbol is <pad> and
# not <s> as in fairseq
__UpperCamelCase :Optional[int] = target_dict.pad_index
__UpperCamelCase :Dict = target_dict.bos_index
__UpperCamelCase :str = target_dict.eos_index
__UpperCamelCase :Dict = len(target_dict.symbols )
__UpperCamelCase :List[Any] = os.path.join(SCREAMING_SNAKE_CASE , '''vocab.json''' )
if not os.path.isdir(SCREAMING_SNAKE_CASE ):
logger.error('''--pytorch_dump_folder_path ({}) should be a directory'''.format(SCREAMING_SNAKE_CASE ) )
return
os.makedirs(SCREAMING_SNAKE_CASE , exist_ok=SCREAMING_SNAKE_CASE )
with open(SCREAMING_SNAKE_CASE , '''w''' , encoding='''utf-8''' ) as vocab_handle:
json.dump(target_dict.indices , SCREAMING_SNAKE_CASE )
__UpperCamelCase :Optional[int] = WavaVecaCTCTokenizer(
SCREAMING_SNAKE_CASE , unk_token=target_dict.unk_word , pad_token=target_dict.pad_word , bos_token=target_dict.bos_word , eos_token=target_dict.eos_word , word_delimiter_token='''|''' , do_lower_case=SCREAMING_SNAKE_CASE , )
__UpperCamelCase :Union[str, Any] = True if config.feat_extract_norm == '''layer''' else False
__UpperCamelCase :Any = WavaVecaFeatureExtractor(
feature_size=1 , sampling_rate=16_000 , padding_value=0 , do_normalize=SCREAMING_SNAKE_CASE , return_attention_mask=SCREAMING_SNAKE_CASE , )
__UpperCamelCase :Any = WavaVecaProcessor(feature_extractor=SCREAMING_SNAKE_CASE , tokenizer=SCREAMING_SNAKE_CASE )
processor.save_pretrained(SCREAMING_SNAKE_CASE )
__UpperCamelCase :List[str] = HubertForCTC(SCREAMING_SNAKE_CASE )
else:
__UpperCamelCase :str = HubertModel(SCREAMING_SNAKE_CASE )
if is_finetuned:
__UpperCamelCase , __UpperCamelCase , __UpperCamelCase :int = fairseq.checkpoint_utils.load_model_ensemble_and_task(
[checkpoint_path] , arg_overrides={'''data''': '''/'''.join(dict_path.split('''/''' )[:-1] )} )
else:
__UpperCamelCase , __UpperCamelCase , __UpperCamelCase :Any = fairseq.checkpoint_utils.load_model_ensemble_and_task([checkpoint_path] )
__UpperCamelCase :Dict = model[0].eval()
recursively_load_weights(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
hf_wavavec.save_pretrained(SCREAMING_SNAKE_CASE )
if __name__ == "__main__":
__lowercase = argparse.ArgumentParser()
parser.add_argument('''--pytorch_dump_folder_path''', default=None, type=str, help='''Path to the output PyTorch model.''')
parser.add_argument('''--checkpoint_path''', default=None, type=str, help='''Path to fairseq checkpoint''')
parser.add_argument('''--dict_path''', default=None, type=str, help='''Path to dict of fine-tuned model''')
parser.add_argument('''--config_path''', default=None, type=str, help='''Path to hf config.json of model to convert''')
parser.add_argument(
'''--not_finetuned''', action='''store_true''', help='''Whether the model to convert is a fine-tuned model or not'''
)
__lowercase = parser.parse_args()
convert_hubert_checkpoint(
args.checkpoint_path, args.pytorch_dump_folder_path, args.config_path, args.dict_path, not args.not_finetuned
)
| 43
| 0
|
'''simple docstring'''
def a_ ( lowerCamelCase : str , lowerCamelCase : str ):
lowerCAmelCase = len(lowerCamelCase )
lowerCAmelCase = []
for i in range(len(lowerCamelCase ) - pat_len + 1 ):
lowerCAmelCase = True
for j in range(lowerCamelCase ):
if s[i + j] != pattern[j]:
lowerCAmelCase = False
break
if match_found:
position.append(lowerCamelCase )
return position
if __name__ == "__main__":
assert naive_pattern_search("""ABCDEFG""", """DE""") == [3]
print(naive_pattern_search("""ABAAABCDBBABCDDEBCABC""", """ABC"""))
| 4
|
import glob
import os
import random
from string import ascii_lowercase, digits
import cva
import numpy as np
# Parrameters
__lowercase = (720, 1280) # Height, Width
__lowercase = (0.4, 0.6) # if height or width lower than this scale, drop it.
__lowercase = 1 / 100
__lowercase = ''''''
__lowercase = ''''''
__lowercase = ''''''
__lowercase = 250
def lowerCamelCase ( ):
'''simple docstring'''
__UpperCamelCase , __UpperCamelCase :List[Any] = get_dataset(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
for index in range(SCREAMING_SNAKE_CASE ):
__UpperCamelCase :Optional[Any] = random.sample(range(len(SCREAMING_SNAKE_CASE ) ) , 4 )
__UpperCamelCase , __UpperCamelCase , __UpperCamelCase :str = update_image_and_anno(
SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , filter_scale=SCREAMING_SNAKE_CASE , )
# Get random string code: '7b7ad245cdff75241935e4dd860f3bad'
__UpperCamelCase :List[Any] = random_chars(32 )
__UpperCamelCase :List[str] = path.split(os.sep )[-1].rsplit('''.''' , 1 )[0]
__UpperCamelCase :Tuple = f"""{OUTPUT_DIR}/{file_name}_MOSAIC_{letter_code}"""
cva.imwrite(f"""{file_root}.jpg""" , SCREAMING_SNAKE_CASE , [cva.IMWRITE_JPEG_QUALITY, 85] )
print(f"""Succeeded {index+1}/{NUMBER_IMAGES} with {file_name}""" )
__UpperCamelCase :Optional[Any] = []
for anno in new_annos:
__UpperCamelCase :int = anno[3] - anno[1]
__UpperCamelCase :Optional[int] = anno[4] - anno[2]
__UpperCamelCase :int = anno[1] + width / 2
__UpperCamelCase :List[str] = anno[2] + height / 2
__UpperCamelCase :str = f"""{anno[0]} {x_center} {y_center} {width} {height}"""
annos_list.append(SCREAMING_SNAKE_CASE )
with open(f"""{file_root}.txt""" , '''w''' ) as outfile:
outfile.write('''\n'''.join(line for line in annos_list ) )
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :str = []
__UpperCamelCase :str = []
for label_file in glob.glob(os.path.join(SCREAMING_SNAKE_CASE , '''*.txt''' ) ):
__UpperCamelCase :Any = label_file.split(os.sep )[-1].rsplit('''.''' , 1 )[0]
with open(SCREAMING_SNAKE_CASE ) as in_file:
__UpperCamelCase :str = in_file.readlines()
__UpperCamelCase :Optional[int] = os.path.join(SCREAMING_SNAKE_CASE , f"""{label_name}.jpg""" )
__UpperCamelCase :int = []
for obj_list in obj_lists:
__UpperCamelCase :Optional[int] = obj_list.rstrip('''\n''' ).split(''' ''' )
__UpperCamelCase :Any = float(obj[1] ) - float(obj[3] ) / 2
__UpperCamelCase :List[str] = float(obj[2] ) - float(obj[4] ) / 2
__UpperCamelCase :Dict = float(obj[1] ) + float(obj[3] ) / 2
__UpperCamelCase :List[str] = float(obj[2] ) + float(obj[4] ) / 2
boxes.append([int(obj[0] ), xmin, ymin, xmax, ymax] )
if not boxes:
continue
img_paths.append(SCREAMING_SNAKE_CASE )
labels.append(SCREAMING_SNAKE_CASE )
return img_paths, labels
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE = 0.0 , ):
'''simple docstring'''
__UpperCamelCase :List[str] = np.zeros([output_size[0], output_size[1], 3] , dtype=np.uinta )
__UpperCamelCase :List[Any] = scale_range[0] + random.random() * (scale_range[1] - scale_range[0])
__UpperCamelCase :int = scale_range[0] + random.random() * (scale_range[1] - scale_range[0])
__UpperCamelCase :Optional[int] = int(scale_x * output_size[1] )
__UpperCamelCase :Any = int(scale_y * output_size[0] )
__UpperCamelCase :List[str] = []
__UpperCamelCase :Dict = []
for i, index in enumerate(SCREAMING_SNAKE_CASE ):
__UpperCamelCase :Any = all_img_list[index]
path_list.append(SCREAMING_SNAKE_CASE )
__UpperCamelCase :Any = all_annos[index]
__UpperCamelCase :Union[str, Any] = cva.imread(SCREAMING_SNAKE_CASE )
if i == 0: # top-left
__UpperCamelCase :str = cva.resize(SCREAMING_SNAKE_CASE , (divid_point_x, divid_point_y) )
__UpperCamelCase :Union[str, Any] = img
for bbox in img_annos:
__UpperCamelCase :Union[str, Any] = bbox[1] * scale_x
__UpperCamelCase :Optional[Any] = bbox[2] * scale_y
__UpperCamelCase :int = bbox[3] * scale_x
__UpperCamelCase :Union[str, Any] = bbox[4] * scale_y
new_anno.append([bbox[0], xmin, ymin, xmax, ymax] )
elif i == 1: # top-right
__UpperCamelCase :str = cva.resize(SCREAMING_SNAKE_CASE , (output_size[1] - divid_point_x, divid_point_y) )
__UpperCamelCase :List[str] = img
for bbox in img_annos:
__UpperCamelCase :str = scale_x + bbox[1] * (1 - scale_x)
__UpperCamelCase :Dict = bbox[2] * scale_y
__UpperCamelCase :Optional[Any] = scale_x + bbox[3] * (1 - scale_x)
__UpperCamelCase :List[Any] = bbox[4] * scale_y
new_anno.append([bbox[0], xmin, ymin, xmax, ymax] )
elif i == 2: # bottom-left
__UpperCamelCase :str = cva.resize(SCREAMING_SNAKE_CASE , (divid_point_x, output_size[0] - divid_point_y) )
__UpperCamelCase :Optional[int] = img
for bbox in img_annos:
__UpperCamelCase :Tuple = bbox[1] * scale_x
__UpperCamelCase :Optional[Any] = scale_y + bbox[2] * (1 - scale_y)
__UpperCamelCase :Tuple = bbox[3] * scale_x
__UpperCamelCase :Dict = scale_y + bbox[4] * (1 - scale_y)
new_anno.append([bbox[0], xmin, ymin, xmax, ymax] )
else: # bottom-right
__UpperCamelCase :Optional[int] = cva.resize(
SCREAMING_SNAKE_CASE , (output_size[1] - divid_point_x, output_size[0] - divid_point_y) )
__UpperCamelCase :Optional[int] = img
for bbox in img_annos:
__UpperCamelCase :Optional[Any] = scale_x + bbox[1] * (1 - scale_x)
__UpperCamelCase :Optional[int] = scale_y + bbox[2] * (1 - scale_y)
__UpperCamelCase :Optional[Any] = scale_x + bbox[3] * (1 - scale_x)
__UpperCamelCase :int = scale_y + bbox[4] * (1 - scale_y)
new_anno.append([bbox[0], xmin, ymin, xmax, ymax] )
# Remove bounding box small than scale of filter
if filter_scale > 0:
__UpperCamelCase :List[Any] = [
anno
for anno in new_anno
if filter_scale < (anno[3] - anno[1]) and filter_scale < (anno[4] - anno[2])
]
return output_img, new_anno, path_list[0]
def lowerCamelCase ( SCREAMING_SNAKE_CASE ):
'''simple docstring'''
assert number_char > 1, "The number of character should greater than 1"
__UpperCamelCase :Optional[Any] = ascii_lowercase + digits
return "".join(random.choice(SCREAMING_SNAKE_CASE ) for _ in range(SCREAMING_SNAKE_CASE ) )
if __name__ == "__main__":
main()
print('''DONE ✅''')
| 43
| 0
|
import argparse
import json
from pathlib import Path
import requests
import torch
from huggingface_hub import hf_hub_download
from PIL import Image
from transformers import (
MobileViTConfig,
MobileViTForImageClassification,
MobileViTForSemanticSegmentation,
MobileViTImageProcessor,
)
from transformers.utils import logging
logging.set_verbosity_info()
UpperCAmelCase__ = logging.get_logger(__name__)
def UpperCAmelCase_ ( __snake_case ) -> Optional[Any]:
"""simple docstring"""
_lowercase =MobileViTConfig()
# size of the architecture
if "mobilevit_s" in mobilevit_name:
_lowercase =[144, 192, 240]
_lowercase =[16, 32, 64, 96, 128, 160, 640]
elif "mobilevit_xs" in mobilevit_name:
_lowercase =[96, 120, 144]
_lowercase =[16, 32, 48, 64, 80, 96, 384]
elif "mobilevit_xxs" in mobilevit_name:
_lowercase =[64, 80, 96]
_lowercase =[16, 16, 24, 48, 64, 80, 320]
_lowercase =0.05
_lowercase =2.0
if mobilevit_name.startswith('''deeplabv3_''' ):
_lowercase =512
_lowercase =16
_lowercase =21
_lowercase ='''pascal-voc-id2label.json'''
else:
_lowercase =1000
_lowercase ='''imagenet-1k-id2label.json'''
_lowercase ='''huggingface/label-files'''
_lowercase =json.load(open(hf_hub_download(__snake_case , __snake_case , repo_type='''dataset''' ) , '''r''' ) )
_lowercase ={int(__snake_case ): v for k, v in idalabel.items()}
_lowercase =idalabel
_lowercase ={v: k for k, v in idalabel.items()}
return config
def UpperCAmelCase_ ( __snake_case , __snake_case=False ) -> Tuple:
"""simple docstring"""
for i in range(1 , 6 ):
if F"layer_{i}." in name:
_lowercase =name.replace(F"layer_{i}." , F"encoder.layer.{i - 1}." )
if "conv_1." in name:
_lowercase =name.replace('''conv_1.''' , '''conv_stem.''' )
if ".block." in name:
_lowercase =name.replace('''.block.''' , '''.''' )
if "exp_1x1" in name:
_lowercase =name.replace('''exp_1x1''' , '''expand_1x1''' )
if "red_1x1" in name:
_lowercase =name.replace('''red_1x1''' , '''reduce_1x1''' )
if ".local_rep.conv_3x3." in name:
_lowercase =name.replace('''.local_rep.conv_3x3.''' , '''.conv_kxk.''' )
if ".local_rep.conv_1x1." in name:
_lowercase =name.replace('''.local_rep.conv_1x1.''' , '''.conv_1x1.''' )
if ".norm." in name:
_lowercase =name.replace('''.norm.''' , '''.normalization.''' )
if ".conv." in name:
_lowercase =name.replace('''.conv.''' , '''.convolution.''' )
if ".conv_proj." in name:
_lowercase =name.replace('''.conv_proj.''' , '''.conv_projection.''' )
for i in range(0 , 2 ):
for j in range(0 , 4 ):
if F".{i}.{j}." in name:
_lowercase =name.replace(F".{i}.{j}." , F".{i}.layer.{j}." )
for i in range(2 , 6 ):
for j in range(0 , 4 ):
if F".{i}.{j}." in name:
_lowercase =name.replace(F".{i}.{j}." , F".{i}." )
if "expand_1x1" in name:
_lowercase =name.replace('''expand_1x1''' , '''downsampling_layer.expand_1x1''' )
if "conv_3x3" in name:
_lowercase =name.replace('''conv_3x3''' , '''downsampling_layer.conv_3x3''' )
if "reduce_1x1" in name:
_lowercase =name.replace('''reduce_1x1''' , '''downsampling_layer.reduce_1x1''' )
for i in range(2 , 5 ):
if F".global_rep.{i}.weight" in name:
_lowercase =name.replace(F".global_rep.{i}.weight" , '''.layernorm.weight''' )
if F".global_rep.{i}.bias" in name:
_lowercase =name.replace(F".global_rep.{i}.bias" , '''.layernorm.bias''' )
if ".global_rep." in name:
_lowercase =name.replace('''.global_rep.''' , '''.transformer.''' )
if ".pre_norm_mha.0." in name:
_lowercase =name.replace('''.pre_norm_mha.0.''' , '''.layernorm_before.''' )
if ".pre_norm_mha.1.out_proj." in name:
_lowercase =name.replace('''.pre_norm_mha.1.out_proj.''' , '''.attention.output.dense.''' )
if ".pre_norm_ffn.0." in name:
_lowercase =name.replace('''.pre_norm_ffn.0.''' , '''.layernorm_after.''' )
if ".pre_norm_ffn.1." in name:
_lowercase =name.replace('''.pre_norm_ffn.1.''' , '''.intermediate.dense.''' )
if ".pre_norm_ffn.4." in name:
_lowercase =name.replace('''.pre_norm_ffn.4.''' , '''.output.dense.''' )
if ".transformer." in name:
_lowercase =name.replace('''.transformer.''' , '''.transformer.layer.''' )
if ".aspp_layer." in name:
_lowercase =name.replace('''.aspp_layer.''' , '''.''' )
if ".aspp_pool." in name:
_lowercase =name.replace('''.aspp_pool.''' , '''.''' )
if "seg_head." in name:
_lowercase =name.replace('''seg_head.''' , '''segmentation_head.''' )
if "segmentation_head.classifier.classifier." in name:
_lowercase =name.replace('''segmentation_head.classifier.classifier.''' , '''segmentation_head.classifier.''' )
if "classifier.fc." in name:
_lowercase =name.replace('''classifier.fc.''' , '''classifier.''' )
elif (not base_model) and ("segmentation_head." not in name):
_lowercase ='''mobilevit.''' + name
return name
def UpperCAmelCase_ ( __snake_case , __snake_case , __snake_case=False ) -> Optional[Any]:
"""simple docstring"""
if base_model:
_lowercase =''''''
else:
_lowercase ='''mobilevit.'''
for key in orig_state_dict.copy().keys():
_lowercase =orig_state_dict.pop(__snake_case )
if key[:8] == "encoder.":
_lowercase =key[8:]
if "qkv" in key:
_lowercase =key.split('''.''' )
_lowercase =int(key_split[0][6:] ) - 1
_lowercase =int(key_split[3] )
_lowercase =model.get_submodule(F"{model_prefix}encoder.layer.{layer_num}" )
_lowercase =layer.transformer.layer[transformer_num].attention.attention.all_head_size
_lowercase =(
F"{model_prefix}encoder.layer.{layer_num}.transformer.layer.{transformer_num}.attention.attention."
)
if "weight" in key:
_lowercase =val[:dim, :]
_lowercase =val[dim : dim * 2, :]
_lowercase =val[-dim:, :]
else:
_lowercase =val[:dim]
_lowercase =val[dim : dim * 2]
_lowercase =val[-dim:]
else:
_lowercase =val
return orig_state_dict
def UpperCAmelCase_ ( ) -> Union[str, Any]:
"""simple docstring"""
_lowercase ='''http://images.cocodataset.org/val2017/000000039769.jpg'''
_lowercase =Image.open(requests.get(__snake_case , stream=__snake_case ).raw )
return im
@torch.no_grad()
def UpperCAmelCase_ ( __snake_case , __snake_case , __snake_case , __snake_case=False ) -> int:
"""simple docstring"""
_lowercase =get_mobilevit_config(__snake_case )
# load original state_dict
_lowercase =torch.load(__snake_case , map_location='''cpu''' )
# load 🤗 model
if mobilevit_name.startswith('''deeplabv3_''' ):
_lowercase =MobileViTForSemanticSegmentation(__snake_case ).eval()
else:
_lowercase =MobileViTForImageClassification(__snake_case ).eval()
_lowercase =convert_state_dict(__snake_case , __snake_case )
model.load_state_dict(__snake_case )
# Check outputs on an image, prepared by MobileViTImageProcessor
_lowercase =MobileViTImageProcessor(crop_size=config.image_size , size=config.image_size + 32 )
_lowercase =image_processor(images=prepare_img() , return_tensors='''pt''' )
_lowercase =model(**__snake_case )
_lowercase =outputs.logits
if mobilevit_name.startswith('''deeplabv3_''' ):
assert logits.shape == (1, 21, 32, 32)
if mobilevit_name == "deeplabv3_mobilevit_s":
_lowercase =torch.tensor(
[
[[6.20_65, 6.12_92, 6.20_70], [6.10_79, 6.12_54, 6.17_47], [6.00_42, 6.10_71, 6.10_34]],
[[-6.92_53, -6.86_53, -7.03_98], [-7.32_18, -7.39_83, -7.36_70], [-7.19_61, -7.24_82, -7.15_69]],
[[-4.47_23, -4.43_48, -4.37_69], [-5.36_29, -5.46_32, -5.45_98], [-5.15_87, -5.34_02, -5.50_59]],
] )
elif mobilevit_name == "deeplabv3_mobilevit_xs":
_lowercase =torch.tensor(
[
[[5.44_49, 5.57_33, 5.63_14], [5.18_15, 5.39_30, 5.59_63], [5.16_56, 5.43_33, 5.48_53]],
[[-9.44_23, -9.77_66, -9.67_14], [-9.15_81, -9.57_20, -9.55_19], [-9.10_06, -9.64_58, -9.57_03]],
[[-7.77_21, -7.37_16, -7.15_83], [-8.45_99, -8.06_24, -7.79_44], [-8.41_72, -7.83_66, -7.50_25]],
] )
elif mobilevit_name == "deeplabv3_mobilevit_xxs":
_lowercase =torch.tensor(
[
[[6.98_11, 6.97_43, 7.31_23], [7.17_77, 7.19_31, 7.39_38], [7.56_33, 7.80_50, 7.89_01]],
[[-10.55_36, -10.23_32, -10.29_24], [-10.23_36, -9.86_24, -9.59_64], [-10.88_40, -10.81_58, -10.66_59]],
[[-3.49_38, -3.06_31, -2.86_20], [-3.42_05, -2.81_35, -2.68_75], [-3.41_79, -2.79_45, -2.87_50]],
] )
else:
raise ValueError(F"Unknown mobilevit_name: {mobilevit_name}" )
assert torch.allclose(logits[0, :3, :3, :3] , __snake_case , atol=1e-4 )
else:
assert logits.shape == (1, 1000)
if mobilevit_name == "mobilevit_s":
_lowercase =torch.tensor([-0.98_66, 0.23_92, -1.12_41] )
elif mobilevit_name == "mobilevit_xs":
_lowercase =torch.tensor([-2.47_61, -0.93_99, -1.95_87] )
elif mobilevit_name == "mobilevit_xxs":
_lowercase =torch.tensor([-1.93_64, -1.23_27, -0.46_53] )
else:
raise ValueError(F"Unknown mobilevit_name: {mobilevit_name}" )
assert torch.allclose(logits[0, :3] , __snake_case , atol=1e-4 )
Path(__snake_case ).mkdir(exist_ok=__snake_case )
print(F"Saving model {mobilevit_name} to {pytorch_dump_folder_path}" )
model.save_pretrained(__snake_case )
print(F"Saving image processor to {pytorch_dump_folder_path}" )
image_processor.save_pretrained(__snake_case )
if push_to_hub:
_lowercase ={
'''mobilevit_s''': '''mobilevit-small''',
'''mobilevit_xs''': '''mobilevit-x-small''',
'''mobilevit_xxs''': '''mobilevit-xx-small''',
'''deeplabv3_mobilevit_s''': '''deeplabv3-mobilevit-small''',
'''deeplabv3_mobilevit_xs''': '''deeplabv3-mobilevit-x-small''',
'''deeplabv3_mobilevit_xxs''': '''deeplabv3-mobilevit-xx-small''',
}
print('''Pushing to the hub...''' )
_lowercase =model_mapping[mobilevit_name]
image_processor.push_to_hub(__snake_case , organization='''apple''' )
model.push_to_hub(__snake_case , organization='''apple''' )
if __name__ == "__main__":
UpperCAmelCase__ = argparse.ArgumentParser()
# Required parameters
parser.add_argument(
'''--mobilevit_name''',
default='''mobilevit_s''',
type=str,
help=(
'''Name of the MobileViT model you\'d like to convert. Should be one of \'mobilevit_s\', \'mobilevit_xs\','''
''' \'mobilevit_xxs\', \'deeplabv3_mobilevit_s\', \'deeplabv3_mobilevit_xs\', \'deeplabv3_mobilevit_xxs\'.'''
),
)
parser.add_argument(
'''--checkpoint_path''', required=True, type=str, help='''Path to the original state dict (.pt file).'''
)
parser.add_argument(
'''--pytorch_dump_folder_path''', required=True, type=str, help='''Path to the output PyTorch model directory.'''
)
parser.add_argument(
'''--push_to_hub''', action='''store_true''', help='''Whether or not to push the converted model to the 🤗 hub.'''
)
UpperCAmelCase__ = parser.parse_args()
convert_movilevit_checkpoint(
args.mobilevit_name, args.checkpoint_path, args.pytorch_dump_folder_path, args.push_to_hub
)
| 5
|
import functools
import operator
from ...configuration_utils import PretrainedConfig
from ...utils import logging
__lowercase = logging.get_logger(__name__)
__lowercase = {
'''facebook/wav2vec2-base-960h''': '''https://huggingface.co/facebook/wav2vec2-base-960h/resolve/main/config.json''',
# See all Wav2Vec2 models at https://huggingface.co/models?filter=wav2vec2
}
class lowerCamelCase_ ( UpperCAmelCase_ ):
'''simple docstring'''
a__ : Union[str, Any] = """wav2vec2"""
def __init__( self , __lowercase=32 , __lowercase=768 , __lowercase=12 , __lowercase=12 , __lowercase=3_072 , __lowercase="gelu" , __lowercase=0.1 , __lowercase=0.1 , __lowercase=0.1 , __lowercase=0.0 , __lowercase=0.0 , __lowercase=0.1 , __lowercase=0.1 , __lowercase=0.02 , __lowercase=1E-5 , __lowercase="group" , __lowercase="gelu" , __lowercase=(512, 512, 512, 512, 512, 512, 512) , __lowercase=(5, 2, 2, 2, 2, 2, 2) , __lowercase=(10, 3, 3, 3, 3, 2, 2) , __lowercase=False , __lowercase=128 , __lowercase=16 , __lowercase=False , __lowercase=True , __lowercase=0.05 , __lowercase=10 , __lowercase=2 , __lowercase=0.0 , __lowercase=10 , __lowercase=0 , __lowercase=320 , __lowercase=2 , __lowercase=0.1 , __lowercase=100 , __lowercase=256 , __lowercase=256 , __lowercase=0.1 , __lowercase="sum" , __lowercase=False , __lowercase=False , __lowercase=256 , __lowercase=(512, 512, 512, 512, 1_500) , __lowercase=(5, 3, 3, 1, 1) , __lowercase=(1, 2, 3, 1, 1) , __lowercase=512 , __lowercase=0 , __lowercase=1 , __lowercase=2 , __lowercase=False , __lowercase=3 , __lowercase=2 , __lowercase=3 , __lowercase=None , __lowercase=None , **__lowercase , ) -> int:
super().__init__(**__lowercase , pad_token_id=__lowercase , bos_token_id=__lowercase , eos_token_id=__lowercase)
__UpperCamelCase :Any = hidden_size
__UpperCamelCase :int = feat_extract_norm
__UpperCamelCase :Tuple = feat_extract_activation
__UpperCamelCase :Union[str, Any] = list(__lowercase)
__UpperCamelCase :List[Any] = list(__lowercase)
__UpperCamelCase :int = list(__lowercase)
__UpperCamelCase :List[Any] = conv_bias
__UpperCamelCase :Optional[int] = num_conv_pos_embeddings
__UpperCamelCase :Dict = num_conv_pos_embedding_groups
__UpperCamelCase :Any = len(self.conv_dim)
__UpperCamelCase :List[str] = num_hidden_layers
__UpperCamelCase :int = intermediate_size
__UpperCamelCase :str = hidden_act
__UpperCamelCase :Any = num_attention_heads
__UpperCamelCase :int = hidden_dropout
__UpperCamelCase :Tuple = attention_dropout
__UpperCamelCase :List[str] = activation_dropout
__UpperCamelCase :Optional[Any] = feat_proj_dropout
__UpperCamelCase :Any = final_dropout
__UpperCamelCase :Any = layerdrop
__UpperCamelCase :str = layer_norm_eps
__UpperCamelCase :Optional[Any] = initializer_range
__UpperCamelCase :List[str] = vocab_size
__UpperCamelCase :str = do_stable_layer_norm
__UpperCamelCase :Union[str, Any] = use_weighted_layer_sum
if (
(len(self.conv_stride) != self.num_feat_extract_layers)
or (len(self.conv_kernel) != self.num_feat_extract_layers)
or (len(self.conv_dim) != self.num_feat_extract_layers)
):
raise ValueError(
'''Configuration for convolutional layers is incorrect. It is required that `len(config.conv_dim)` =='''
''' `len(config.conv_stride)` == `len(config.conv_kernel)`, but is `len(config.conv_dim) ='''
f""" {len(self.conv_dim)}`, `len(config.conv_stride) = {len(self.conv_stride)}`,"""
f""" `len(config.conv_kernel) = {len(self.conv_kernel)}`.""")
# fine-tuning config parameters for SpecAugment: https://arxiv.org/abs/1904.08779
__UpperCamelCase :List[Any] = apply_spec_augment
__UpperCamelCase :Tuple = mask_time_prob
__UpperCamelCase :int = mask_time_length
__UpperCamelCase :Dict = mask_time_min_masks
__UpperCamelCase :str = mask_feature_prob
__UpperCamelCase :List[str] = mask_feature_length
__UpperCamelCase :Union[str, Any] = mask_feature_min_masks
# parameters for pretraining with codevector quantized representations
__UpperCamelCase :Optional[Any] = num_codevectors_per_group
__UpperCamelCase :List[Any] = num_codevector_groups
__UpperCamelCase :Tuple = contrastive_logits_temperature
__UpperCamelCase :Optional[int] = feat_quantizer_dropout
__UpperCamelCase :Optional[int] = num_negatives
__UpperCamelCase :List[Any] = codevector_dim
__UpperCamelCase :str = proj_codevector_dim
__UpperCamelCase :List[str] = diversity_loss_weight
# ctc loss
__UpperCamelCase :Tuple = ctc_loss_reduction
__UpperCamelCase :Tuple = ctc_zero_infinity
# adapter
__UpperCamelCase :List[str] = add_adapter
__UpperCamelCase :Tuple = adapter_kernel_size
__UpperCamelCase :str = adapter_stride
__UpperCamelCase :Tuple = num_adapter_layers
__UpperCamelCase :Tuple = output_hidden_size or hidden_size
__UpperCamelCase :Optional[Any] = adapter_attn_dim
# SequenceClassification-specific parameter. Feel free to ignore for other classes.
__UpperCamelCase :Optional[Any] = classifier_proj_size
# XVector-specific parameters. Feel free to ignore for other classes.
__UpperCamelCase :Optional[int] = list(__lowercase)
__UpperCamelCase :List[Any] = list(__lowercase)
__UpperCamelCase :List[Any] = list(__lowercase)
__UpperCamelCase :str = xvector_output_dim
@property
def UpperCamelCase__ ( self) -> List[str]:
return functools.reduce(operator.mul , self.conv_stride , 1)
| 43
| 0
|
# Logistic Regression from scratch
# In[62]:
# In[63]:
# importing all the required libraries
import numpy as np
from matplotlib import pyplot as plt
from sklearn import datasets
def __lowerCAmelCase ( a__ ) -> Dict:
return 1 / (1 + np.exp(-z ))
def __lowerCAmelCase ( a__ , a__ ) -> Tuple:
return (-y * np.log(a__ ) - (1 - y) * np.log(1 - h )).mean()
def __lowerCAmelCase ( a__ , a__ , a__ ) -> List[Any]:
__a = np.dot(a__ , a__ )
return np.sum(y * scores - np.log(1 + np.exp(a__ ) ) )
def __lowerCAmelCase ( a__ , a__ , a__ , a__=7_0000 ) -> Tuple:
__a = np.zeros(x.shape[1] )
for iterations in range(a__ ):
__a = np.dot(a__ , a__ )
__a = sigmoid_function(a__ )
__a = np.dot(x.T , h - y ) / y.size
__a = theta - alpha * gradient # updating the weights
__a = np.dot(a__ , a__ )
__a = sigmoid_function(a__ )
__a = cost_function(a__ , a__ )
if iterations % 100 == 0:
print(F"""loss: {j} \t""" ) # printing the loss after every 100 iterations
return theta
# In[68]:
if __name__ == "__main__":
A : List[Any] = datasets.load_iris()
A : Any = iris.data[:, :2]
A : int = (iris.target != 0) * 1
A : Dict = 0.1
A : str = logistic_reg(alpha, x, y, max_iterations=7_0_0_0_0)
print('theta: ', theta) # printing the theta i.e our weights vector
def __lowerCAmelCase ( a__ ) -> Union[str, Any]:
return sigmoid_function(
np.dot(a__ , a__ ) ) # predicting the value of probability from the logistic regression algorithm
plt.figure(figsize=(1_0, 6))
plt.scatter(x[y == 0][:, 0], x[y == 0][:, 1], color='b', label='0')
plt.scatter(x[y == 1][:, 0], x[y == 1][:, 1], color='r', label='1')
((A) , (A)) : Tuple = (x[:, 0].min(), x[:, 0].max())
((A) , (A)) : int = (x[:, 1].min(), x[:, 1].max())
((A) , (A)) : List[str] = np.meshgrid(np.linspace(xa_min, xa_max), np.linspace(xa_min, xa_max))
A : int = np.c_[xxa.ravel(), xxa.ravel()]
A : Any = predict_prob(grid).reshape(xxa.shape)
plt.contour(xxa, xxa, probs, [0.5], linewidths=1, colors='black')
plt.legend()
plt.show()
| 6
|
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
__lowercase = logging.get_logger(__name__)
class lowerCamelCase_ ( UpperCAmelCase_ ):
'''simple docstring'''
a__ : Optional[Any] = ["""pixel_values"""]
def __init__( self , __lowercase = True , __lowercase = 32 , __lowercase=PILImageResampling.BILINEAR , __lowercase = True , **__lowercase , ) -> None:
__UpperCamelCase :Optional[int] = do_resize
__UpperCamelCase :Any = do_rescale
__UpperCamelCase :str = size_divisor
__UpperCamelCase :Dict = resample
super().__init__(**__lowercase)
def UpperCamelCase__ ( self , __lowercase , __lowercase , __lowercase , __lowercase = None , **__lowercase) -> np.ndarray:
__UpperCamelCase , __UpperCamelCase :int = get_image_size(__lowercase)
# Rounds the height and width down to the closest multiple of size_divisor
__UpperCamelCase :List[Any] = height // size_divisor * size_divisor
__UpperCamelCase :List[str] = width // size_divisor * size_divisor
__UpperCamelCase :str = resize(__lowercase , (new_h, new_w) , resample=__lowercase , data_format=__lowercase , **__lowercase)
return image
def UpperCamelCase__ ( self , __lowercase , __lowercase , __lowercase = None , **__lowercase) -> np.ndarray:
return rescale(image=__lowercase , scale=__lowercase , data_format=__lowercase , **__lowercase)
def UpperCamelCase__ ( self , __lowercase , __lowercase = None , __lowercase = None , __lowercase=None , __lowercase = None , __lowercase = None , __lowercase = ChannelDimension.FIRST , **__lowercase , ) -> BatchFeature:
__UpperCamelCase :Union[str, Any] = do_resize if do_resize is not None else self.do_resize
__UpperCamelCase :Tuple = do_rescale if do_rescale is not None else self.do_rescale
__UpperCamelCase :List[str] = size_divisor if size_divisor is not None else self.size_divisor
__UpperCamelCase :List[Any] = 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''')
__UpperCamelCase :List[Any] = make_list_of_images(__lowercase)
if not valid_images(__lowercase):
raise ValueError('''Invalid image(s)''')
# All transformations expect numpy arrays.
__UpperCamelCase :Optional[Any] = [to_numpy_array(__lowercase) for img in images]
if do_resize:
__UpperCamelCase :List[str] = [self.resize(__lowercase , size_divisor=__lowercase , resample=__lowercase) for image in images]
if do_rescale:
__UpperCamelCase :Dict = [self.rescale(__lowercase , scale=1 / 255) for image in images]
__UpperCamelCase :str = [to_channel_dimension_format(__lowercase , __lowercase) for image in images]
__UpperCamelCase :int = {'''pixel_values''': images}
return BatchFeature(data=__lowercase , tensor_type=__lowercase)
| 43
| 0
|
import argparse
import json
from pathlib import Path
import requests
import timm
import torch
from huggingface_hub import hf_hub_download
from PIL import Image
from transformers import DeiTImageProcessor, ViTConfig, ViTForImageClassification, ViTImageProcessor, ViTModel
from transformers.utils import logging
logging.set_verbosity_info()
lowercase_ = logging.get_logger(__name__)
def _snake_case( SCREAMING_SNAKE_CASE__ : List[Any] , SCREAMING_SNAKE_CASE__ : List[Any]=False ) -> List[Any]:
'''simple docstring'''
A__ = []
for i in range(config.num_hidden_layers ):
# encoder layers: output projection, 2 feedforward neural networks and 2 layernorms
rename_keys.append((f'blocks.{i}.norm1.weight', f'vit.encoder.layer.{i}.layernorm_before.weight') )
rename_keys.append((f'blocks.{i}.norm1.bias', f'vit.encoder.layer.{i}.layernorm_before.bias') )
rename_keys.append((f'blocks.{i}.attn.proj.weight', f'vit.encoder.layer.{i}.attention.output.dense.weight') )
rename_keys.append((f'blocks.{i}.attn.proj.bias', f'vit.encoder.layer.{i}.attention.output.dense.bias') )
rename_keys.append((f'blocks.{i}.norm2.weight', f'vit.encoder.layer.{i}.layernorm_after.weight') )
rename_keys.append((f'blocks.{i}.norm2.bias', f'vit.encoder.layer.{i}.layernorm_after.bias') )
rename_keys.append((f'blocks.{i}.mlp.fc1.weight', f'vit.encoder.layer.{i}.intermediate.dense.weight') )
rename_keys.append((f'blocks.{i}.mlp.fc1.bias', f'vit.encoder.layer.{i}.intermediate.dense.bias') )
rename_keys.append((f'blocks.{i}.mlp.fc2.weight', f'vit.encoder.layer.{i}.output.dense.weight') )
rename_keys.append((f'blocks.{i}.mlp.fc2.bias', f'vit.encoder.layer.{i}.output.dense.bias') )
# projection layer + position embeddings
rename_keys.extend(
[
('cls_token', 'vit.embeddings.cls_token'),
('patch_embed.proj.weight', 'vit.embeddings.patch_embeddings.projection.weight'),
('patch_embed.proj.bias', 'vit.embeddings.patch_embeddings.projection.bias'),
('pos_embed', 'vit.embeddings.position_embeddings'),
] )
if base_model:
# layernorm + pooler
rename_keys.extend(
[
('norm.weight', 'layernorm.weight'),
('norm.bias', 'layernorm.bias'),
('pre_logits.fc.weight', 'pooler.dense.weight'),
('pre_logits.fc.bias', 'pooler.dense.bias'),
] )
# if just the base model, we should remove "vit" from all keys that start with "vit"
A__ = [(pair[0], pair[1][4:]) if pair[1].startswith('vit' ) else pair for pair in rename_keys]
else:
# layernorm + classification head
rename_keys.extend(
[
('norm.weight', 'vit.layernorm.weight'),
('norm.bias', 'vit.layernorm.bias'),
('head.weight', 'classifier.weight'),
('head.bias', 'classifier.bias'),
] )
return rename_keys
def _snake_case( SCREAMING_SNAKE_CASE__ : str , SCREAMING_SNAKE_CASE__ : Tuple , SCREAMING_SNAKE_CASE__ : Tuple=False ) -> Optional[int]:
'''simple docstring'''
for i in range(config.num_hidden_layers ):
if base_model:
A__ = ''
else:
A__ = 'vit.'
# read in weights + bias of input projection layer (in timm, this is a single matrix + bias)
A__ = state_dict.pop(f'blocks.{i}.attn.qkv.weight' )
A__ = state_dict.pop(f'blocks.{i}.attn.qkv.bias' )
# next, add query, keys and values (in that order) to the state dict
A__ = in_proj_weight[
: config.hidden_size, :
]
A__ = in_proj_bias[: config.hidden_size]
A__ = in_proj_weight[
config.hidden_size : config.hidden_size * 2, :
]
A__ = in_proj_bias[
config.hidden_size : config.hidden_size * 2
]
A__ = in_proj_weight[
-config.hidden_size :, :
]
A__ = in_proj_bias[-config.hidden_size :]
def _snake_case( SCREAMING_SNAKE_CASE__ : Tuple ) -> Union[str, Any]:
'''simple docstring'''
A__ = ['head.weight', 'head.bias']
for k in ignore_keys:
state_dict.pop(SCREAMING_SNAKE_CASE__ , SCREAMING_SNAKE_CASE__ )
def _snake_case( SCREAMING_SNAKE_CASE__ : Optional[int] , SCREAMING_SNAKE_CASE__ : List[str] , SCREAMING_SNAKE_CASE__ : Dict ) -> Optional[int]:
'''simple docstring'''
A__ = dct.pop(SCREAMING_SNAKE_CASE__ )
A__ = val
def _snake_case( ) -> Any:
'''simple docstring'''
A__ = 'http://images.cocodataset.org/val2017/000000039769.jpg'
A__ = Image.open(requests.get(SCREAMING_SNAKE_CASE__ , stream=SCREAMING_SNAKE_CASE__ ).raw )
return im
@torch.no_grad()
def _snake_case( SCREAMING_SNAKE_CASE__ : Tuple , SCREAMING_SNAKE_CASE__ : int ) -> Dict:
'''simple docstring'''
A__ = ViTConfig()
A__ = False
# dataset (ImageNet-21k only or also fine-tuned on ImageNet 2012), patch_size and image_size
if vit_name[-5:] == "in21k":
A__ = True
A__ = int(vit_name[-12:-10] )
A__ = int(vit_name[-9:-6] )
else:
A__ = 1000
A__ = 'huggingface/label-files'
A__ = 'imagenet-1k-id2label.json'
A__ = json.load(open(hf_hub_download(SCREAMING_SNAKE_CASE__ , SCREAMING_SNAKE_CASE__ , repo_type='dataset' ) , 'r' ) )
A__ = {int(SCREAMING_SNAKE_CASE__ ): v for k, v in idalabel.items()}
A__ = idalabel
A__ = {v: k for k, v in idalabel.items()}
A__ = int(vit_name[-6:-4] )
A__ = int(vit_name[-3:] )
# size of the architecture
if "deit" in vit_name:
if vit_name[9:].startswith('tiny' ):
A__ = 192
A__ = 768
A__ = 12
A__ = 3
elif vit_name[9:].startswith('small' ):
A__ = 384
A__ = 1536
A__ = 12
A__ = 6
else:
pass
else:
if vit_name[4:].startswith('small' ):
A__ = 768
A__ = 2304
A__ = 8
A__ = 8
elif vit_name[4:].startswith('base' ):
pass
elif vit_name[4:].startswith('large' ):
A__ = 1024
A__ = 4096
A__ = 24
A__ = 16
elif vit_name[4:].startswith('huge' ):
A__ = 1280
A__ = 5120
A__ = 32
A__ = 16
# load original model from timm
A__ = timm.create_model(SCREAMING_SNAKE_CASE__ , pretrained=SCREAMING_SNAKE_CASE__ )
timm_model.eval()
# load state_dict of original model, remove and rename some keys
A__ = timm_model.state_dict()
if base_model:
remove_classification_head_(SCREAMING_SNAKE_CASE__ )
A__ = create_rename_keys(SCREAMING_SNAKE_CASE__ , SCREAMING_SNAKE_CASE__ )
for src, dest in rename_keys:
rename_key(SCREAMING_SNAKE_CASE__ , SCREAMING_SNAKE_CASE__ , SCREAMING_SNAKE_CASE__ )
read_in_q_k_v(SCREAMING_SNAKE_CASE__ , SCREAMING_SNAKE_CASE__ , SCREAMING_SNAKE_CASE__ )
# load HuggingFace model
if vit_name[-5:] == "in21k":
A__ = ViTModel(SCREAMING_SNAKE_CASE__ ).eval()
else:
A__ = ViTForImageClassification(SCREAMING_SNAKE_CASE__ ).eval()
model.load_state_dict(SCREAMING_SNAKE_CASE__ )
# Check outputs on an image, prepared by ViTImageProcessor/DeiTImageProcessor
if "deit" in vit_name:
A__ = DeiTImageProcessor(size=config.image_size )
else:
A__ = ViTImageProcessor(size=config.image_size )
A__ = image_processor(images=prepare_img() , return_tensors='pt' )
A__ = encoding['pixel_values']
A__ = model(SCREAMING_SNAKE_CASE__ )
if base_model:
A__ = timm_model.forward_features(SCREAMING_SNAKE_CASE__ )
assert timm_pooled_output.shape == outputs.pooler_output.shape
assert torch.allclose(SCREAMING_SNAKE_CASE__ , outputs.pooler_output , atol=1E-3 )
else:
A__ = timm_model(SCREAMING_SNAKE_CASE__ )
assert timm_logits.shape == outputs.logits.shape
assert torch.allclose(SCREAMING_SNAKE_CASE__ , outputs.logits , atol=1E-3 )
Path(SCREAMING_SNAKE_CASE__ ).mkdir(exist_ok=SCREAMING_SNAKE_CASE__ )
print(f'Saving model {vit_name} to {pytorch_dump_folder_path}' )
model.save_pretrained(SCREAMING_SNAKE_CASE__ )
print(f'Saving image processor to {pytorch_dump_folder_path}' )
image_processor.save_pretrained(SCREAMING_SNAKE_CASE__ )
if __name__ == "__main__":
lowercase_ = argparse.ArgumentParser()
# Required parameters
parser.add_argument(
"--vit_name",
default="vit_base_patch16_224",
type=str,
help="Name of the ViT timm model you'd like to convert.",
)
parser.add_argument(
"--pytorch_dump_folder_path", default=None, type=str, help="Path to the output PyTorch model directory."
)
lowercase_ = parser.parse_args()
convert_vit_checkpoint(args.vit_name, args.pytorch_dump_folder_path)
| 7
|
from __future__ import annotations
from PIL import Image
# Define glider example
__lowercase = [
[0, 1, 0, 0, 0, 0, 0, 0],
[0, 0, 1, 0, 0, 0, 0, 0],
[1, 1, 1, 0, 0, 0, 0, 0],
[0, 0, 0, 0, 0, 0, 0, 0],
[0, 0, 0, 0, 0, 0, 0, 0],
[0, 0, 0, 0, 0, 0, 0, 0],
[0, 0, 0, 0, 0, 0, 0, 0],
[0, 0, 0, 0, 0, 0, 0, 0],
]
# Define blinker example
__lowercase = [[0, 1, 0], [0, 1, 0], [0, 1, 0]]
def lowerCamelCase ( SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :int = []
for i in range(len(SCREAMING_SNAKE_CASE ) ):
__UpperCamelCase :Dict = []
for j in range(len(cells[i] ) ):
# Get the number of live neighbours
__UpperCamelCase :List[str] = 0
if i > 0 and j > 0:
neighbour_count += cells[i - 1][j - 1]
if i > 0:
neighbour_count += cells[i - 1][j]
if i > 0 and j < len(cells[i] ) - 1:
neighbour_count += cells[i - 1][j + 1]
if j > 0:
neighbour_count += cells[i][j - 1]
if j < len(cells[i] ) - 1:
neighbour_count += cells[i][j + 1]
if i < len(SCREAMING_SNAKE_CASE ) - 1 and j > 0:
neighbour_count += cells[i + 1][j - 1]
if i < len(SCREAMING_SNAKE_CASE ) - 1:
neighbour_count += cells[i + 1][j]
if i < len(SCREAMING_SNAKE_CASE ) - 1 and j < len(cells[i] ) - 1:
neighbour_count += cells[i + 1][j + 1]
# Rules of the game of life (excerpt from Wikipedia):
# 1. Any live cell with two or three live neighbours survives.
# 2. Any dead cell with three live neighbours becomes a live cell.
# 3. All other live cells die in the next generation.
# Similarly, all other dead cells stay dead.
__UpperCamelCase :List[str] = cells[i][j] == 1
if (
(alive and 2 <= neighbour_count <= 3)
or not alive
and neighbour_count == 3
):
next_generation_row.append(1 )
else:
next_generation_row.append(0 )
next_generation.append(SCREAMING_SNAKE_CASE )
return next_generation
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Optional[Any] = []
for _ in range(SCREAMING_SNAKE_CASE ):
# Create output image
__UpperCamelCase :Dict = Image.new('''RGB''' , (len(cells[0] ), len(SCREAMING_SNAKE_CASE )) )
__UpperCamelCase :Any = img.load()
# Save cells to image
for x in range(len(SCREAMING_SNAKE_CASE ) ):
for y in range(len(cells[0] ) ):
__UpperCamelCase :Optional[Any] = 255 - cells[y][x] * 255
__UpperCamelCase :int = (colour, colour, colour)
# Save image
images.append(SCREAMING_SNAKE_CASE )
__UpperCamelCase :Optional[int] = new_generation(SCREAMING_SNAKE_CASE )
return images
if __name__ == "__main__":
__lowercase = generate_images(GLIDER, 16)
images[0].save('''out.gif''', save_all=True, append_images=images[1:])
| 43
| 0
|
from ...utils import (
OptionalDependencyNotAvailable,
is_flax_available,
is_torch_available,
is_transformers_available,
)
try:
if not (is_transformers_available() and is_torch_available()):
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
from ...utils.dummy_torch_and_transformers_objects import * # noqa F403
else:
from .multicontrolnet import MultiControlNetModel
from .pipeline_controlnet import StableDiffusionControlNetPipeline
from .pipeline_controlnet_imgaimg import StableDiffusionControlNetImgaImgPipeline
from .pipeline_controlnet_inpaint import StableDiffusionControlNetInpaintPipeline
if is_transformers_available() and is_flax_available():
from .pipeline_flax_controlnet import FlaxStableDiffusionControlNetPipeline
| 8
|
import re
import jax.numpy as jnp
from flax.traverse_util import flatten_dict, unflatten_dict
from jax.random import PRNGKey
from ..utils import logging
__lowercase = logging.get_logger(__name__)
def lowerCamelCase ( SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Tuple = R'''\w+[.]\d+'''
__UpperCamelCase :List[str] = re.findall(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
for pat in pats:
__UpperCamelCase :int = key.replace(SCREAMING_SNAKE_CASE , '''_'''.join(pat.split('''.''' ) ) )
return key
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Tuple = pt_tuple_key[:-1] + ('''scale''',)
if (
any('''norm''' in str_ for str_ in pt_tuple_key )
and (pt_tuple_key[-1] == "bias")
and (pt_tuple_key[:-1] + ("bias",) not in random_flax_state_dict)
and (pt_tuple_key[:-1] + ("scale",) in random_flax_state_dict)
):
__UpperCamelCase :str = pt_tuple_key[:-1] + ('''scale''',)
return renamed_pt_tuple_key, pt_tensor
elif pt_tuple_key[-1] in ["weight", "gamma"] and pt_tuple_key[:-1] + ("scale",) in random_flax_state_dict:
__UpperCamelCase :Any = pt_tuple_key[:-1] + ('''scale''',)
return renamed_pt_tuple_key, pt_tensor
# embedding
if pt_tuple_key[-1] == "weight" and pt_tuple_key[:-1] + ("embedding",) in random_flax_state_dict:
__UpperCamelCase :str = pt_tuple_key[:-1] + ('''embedding''',)
return renamed_pt_tuple_key, pt_tensor
# conv layer
__UpperCamelCase :List[str] = pt_tuple_key[:-1] + ('''kernel''',)
if pt_tuple_key[-1] == "weight" and pt_tensor.ndim == 4:
__UpperCamelCase :List[Any] = pt_tensor.transpose(2 , 3 , 1 , 0 )
return renamed_pt_tuple_key, pt_tensor
# linear layer
__UpperCamelCase :List[str] = pt_tuple_key[:-1] + ('''kernel''',)
if pt_tuple_key[-1] == "weight":
__UpperCamelCase :Any = pt_tensor.T
return renamed_pt_tuple_key, pt_tensor
# old PyTorch layer norm weight
__UpperCamelCase :int = pt_tuple_key[:-1] + ('''weight''',)
if pt_tuple_key[-1] == "gamma":
return renamed_pt_tuple_key, pt_tensor
# old PyTorch layer norm bias
__UpperCamelCase :int = pt_tuple_key[:-1] + ('''bias''',)
if pt_tuple_key[-1] == "beta":
return renamed_pt_tuple_key, pt_tensor
return pt_tuple_key, pt_tensor
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE=42 ):
'''simple docstring'''
__UpperCamelCase :Union[str, Any] = {k: v.numpy() for k, v in pt_state_dict.items()}
# Step 2: Since the model is stateless, get random Flax params
__UpperCamelCase :str = flax_model.init_weights(PRNGKey(SCREAMING_SNAKE_CASE ) )
__UpperCamelCase :int = flatten_dict(SCREAMING_SNAKE_CASE )
__UpperCamelCase :List[Any] = {}
# Need to change some parameters name to match Flax names
for pt_key, pt_tensor in pt_state_dict.items():
__UpperCamelCase :List[Any] = rename_key(SCREAMING_SNAKE_CASE )
__UpperCamelCase :List[Any] = tuple(renamed_pt_key.split('''.''' ) )
# Correctly rename weight parameters
__UpperCamelCase , __UpperCamelCase :Any = rename_key_and_reshape_tensor(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
if flax_key in random_flax_state_dict:
if flax_tensor.shape != random_flax_state_dict[flax_key].shape:
raise ValueError(
f"""PyTorch checkpoint seems to be incorrect. Weight {pt_key} was expected to be of shape """
f"""{random_flax_state_dict[flax_key].shape}, but is {flax_tensor.shape}.""" )
# also add unexpected weight so that warning is thrown
__UpperCamelCase :str = jnp.asarray(SCREAMING_SNAKE_CASE )
return unflatten_dict(SCREAMING_SNAKE_CASE )
| 43
| 0
|
from typing import Dict, List, Optional, Tuple, Union
import numpy as np
from ...image_processing_utils import BaseImageProcessor, BatchFeature, get_size_dict
from ...image_transforms import (
center_crop,
get_resize_output_image_size,
normalize,
rescale,
resize,
to_channel_dimension_format,
)
from ...image_utils import (
IMAGENET_STANDARD_MEAN,
IMAGENET_STANDARD_STD,
ChannelDimension,
ImageInput,
PILImageResampling,
make_list_of_images,
to_numpy_array,
valid_images,
)
from ...utils import TensorType, is_torch_available, is_torch_tensor, logging
if is_torch_available():
import torch
__lowerCAmelCase : str =logging.get_logger(__name__)
class _lowercase ( A__ ):
'''simple docstring'''
SCREAMING_SNAKE_CASE__ : Tuple = ['''pixel_values''']
def __init__( self :Optional[Any] , lowerCAmelCase__ :bool = True , lowerCAmelCase__ :Optional[Dict[str, int]] = None , lowerCAmelCase__ :PILImageResampling = PILImageResampling.BILINEAR , lowerCAmelCase__ :bool = True , lowerCAmelCase__ :Dict[str, int] = None , lowerCAmelCase__ :bool = True , lowerCAmelCase__ :Union[int, float] = 1 / 255 , lowerCAmelCase__ :bool = True , lowerCAmelCase__ :Optional[Union[float, List[float]]] = None , lowerCAmelCase__ :Optional[Union[float, List[float]]] = None , **lowerCAmelCase__ :Tuple , ) -> None:
super().__init__(**lowerCAmelCase__ )
__SCREAMING_SNAKE_CASE : Optional[Any] = size if size is not None else {'''shortest_edge''': 256}
__SCREAMING_SNAKE_CASE : int = get_size_dict(lowerCAmelCase__ , default_to_square=lowerCAmelCase__ )
__SCREAMING_SNAKE_CASE : Optional[int] = crop_size if crop_size is not None else {'''height''': 224, '''width''': 224}
__SCREAMING_SNAKE_CASE : str = get_size_dict(lowerCAmelCase__ , param_name='''crop_size''' )
__SCREAMING_SNAKE_CASE : Union[str, Any] = do_resize
__SCREAMING_SNAKE_CASE : int = size
__SCREAMING_SNAKE_CASE : Union[str, Any] = resample
__SCREAMING_SNAKE_CASE : Any = do_center_crop
__SCREAMING_SNAKE_CASE : Dict = crop_size
__SCREAMING_SNAKE_CASE : Tuple = do_rescale
__SCREAMING_SNAKE_CASE : Union[str, Any] = rescale_factor
__SCREAMING_SNAKE_CASE : Any = do_normalize
__SCREAMING_SNAKE_CASE : List[str] = image_mean if image_mean is not None else IMAGENET_STANDARD_MEAN
__SCREAMING_SNAKE_CASE : int = image_std if image_std is not None else IMAGENET_STANDARD_STD
def __magic_name__( self :Any , lowerCAmelCase__ :np.ndarray , lowerCAmelCase__ :Dict[str, int] , lowerCAmelCase__ :PILImageResampling = PILImageResampling.BICUBIC , lowerCAmelCase__ :Optional[Union[str, ChannelDimension]] = None , **lowerCAmelCase__ :int , ) -> np.ndarray:
__SCREAMING_SNAKE_CASE : Optional[Any] = 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()}''' )
__SCREAMING_SNAKE_CASE : Dict = 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 __magic_name__( self :List[Any] , lowerCAmelCase__ :np.ndarray , lowerCAmelCase__ :Dict[str, int] , lowerCAmelCase__ :Optional[Union[str, ChannelDimension]] = None , **lowerCAmelCase__ :str , ) -> np.ndarray:
__SCREAMING_SNAKE_CASE : List[str] = 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` and `width`. Got {size.keys()}''' )
return center_crop(lowerCAmelCase__ , size=(size['''height'''], size['''width''']) , data_format=lowerCAmelCase__ , **lowerCAmelCase__ )
def __magic_name__( self :Union[str, Any] , lowerCAmelCase__ :np.ndarray , lowerCAmelCase__ :float , lowerCAmelCase__ :Optional[Union[str, ChannelDimension]] = None , **lowerCAmelCase__ :int ) -> np.ndarray:
return rescale(lowerCAmelCase__ , scale=lowerCAmelCase__ , data_format=lowerCAmelCase__ , **lowerCAmelCase__ )
def __magic_name__( self :Any , lowerCAmelCase__ :np.ndarray , lowerCAmelCase__ :Union[float, List[float]] , lowerCAmelCase__ :Union[float, List[float]] , lowerCAmelCase__ :Optional[Union[str, ChannelDimension]] = None , **lowerCAmelCase__ :str , ) -> np.ndarray:
return normalize(lowerCAmelCase__ , mean=lowerCAmelCase__ , std=lowerCAmelCase__ , data_format=lowerCAmelCase__ , **lowerCAmelCase__ )
def __magic_name__( self :List[Any] , lowerCAmelCase__ :ImageInput , lowerCAmelCase__ :Optional[bool] = None , lowerCAmelCase__ :Dict[str, int] = None , lowerCAmelCase__ :PILImageResampling = None , lowerCAmelCase__ :bool = None , lowerCAmelCase__ :Dict[str, int] = None , lowerCAmelCase__ :Optional[bool] = None , lowerCAmelCase__ :Optional[float] = None , lowerCAmelCase__ :Optional[bool] = None , lowerCAmelCase__ :Optional[Union[float, List[float]]] = None , lowerCAmelCase__ :Optional[Union[float, List[float]]] = None , lowerCAmelCase__ :Optional[Union[str, TensorType]] = None , lowerCAmelCase__ :Union[str, ChannelDimension] = ChannelDimension.FIRST , **lowerCAmelCase__ :Optional[int] , ) -> str:
__SCREAMING_SNAKE_CASE : Optional[int] = do_resize if do_resize is not None else self.do_resize
__SCREAMING_SNAKE_CASE : Any = size if size is not None else self.size
__SCREAMING_SNAKE_CASE : Any = get_size_dict(lowerCAmelCase__ , default_to_square=lowerCAmelCase__ )
__SCREAMING_SNAKE_CASE : Optional[int] = resample if resample is not None else self.resample
__SCREAMING_SNAKE_CASE : Union[str, Any] = do_center_crop if do_center_crop is not None else self.do_center_crop
__SCREAMING_SNAKE_CASE : str = crop_size if crop_size is not None else self.crop_size
__SCREAMING_SNAKE_CASE : Union[str, Any] = get_size_dict(lowerCAmelCase__ , param_name='''crop_size''' )
__SCREAMING_SNAKE_CASE : List[Any] = do_rescale if do_rescale is not None else self.do_rescale
__SCREAMING_SNAKE_CASE : Optional[int] = rescale_factor if rescale_factor is not None else self.rescale_factor
__SCREAMING_SNAKE_CASE : int = do_normalize if do_normalize is not None else self.do_normalize
__SCREAMING_SNAKE_CASE : Tuple = image_mean if image_mean is not None else self.image_mean
__SCREAMING_SNAKE_CASE : List[str] = image_std if image_std is not None else self.image_std
__SCREAMING_SNAKE_CASE : Union[str, Any] = 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.''' )
# All transformations expect numpy arrays.
__SCREAMING_SNAKE_CASE : Optional[Any] = [to_numpy_array(lowerCAmelCase__ ) for image in images]
if do_resize:
__SCREAMING_SNAKE_CASE : Dict = [self.resize(image=lowerCAmelCase__ , size=lowerCAmelCase__ , resample=lowerCAmelCase__ ) for image in images]
if do_center_crop:
__SCREAMING_SNAKE_CASE : Tuple = [self.center_crop(image=lowerCAmelCase__ , size=lowerCAmelCase__ ) for image in images]
if do_rescale:
__SCREAMING_SNAKE_CASE : List[str] = [self.rescale(image=lowerCAmelCase__ , scale=lowerCAmelCase__ ) for image in images]
if do_normalize:
__SCREAMING_SNAKE_CASE : int = [self.normalize(image=lowerCAmelCase__ , mean=lowerCAmelCase__ , std=lowerCAmelCase__ ) for image in images]
__SCREAMING_SNAKE_CASE : int = [to_channel_dimension_format(lowerCAmelCase__ , lowerCAmelCase__ ) for image in images]
__SCREAMING_SNAKE_CASE : Any = {'''pixel_values''': images}
return BatchFeature(data=lowerCAmelCase__ , tensor_type=lowerCAmelCase__ )
def __magic_name__( self :int , lowerCAmelCase__ :Union[str, Any] , lowerCAmelCase__ :List[Tuple] = None ) -> str:
__SCREAMING_SNAKE_CASE : Dict = outputs.logits
# Resize logits and compute semantic segmentation maps
if target_sizes is not None:
if len(lowerCAmelCase__ ) != len(lowerCAmelCase__ ):
raise ValueError(
'''Make sure that you pass in as many target sizes as the batch dimension of the logits''' )
if is_torch_tensor(lowerCAmelCase__ ):
__SCREAMING_SNAKE_CASE : Optional[Any] = target_sizes.numpy()
__SCREAMING_SNAKE_CASE : Any = []
for idx in range(len(lowerCAmelCase__ ) ):
__SCREAMING_SNAKE_CASE : Any = torch.nn.functional.interpolate(
logits[idx].unsqueeze(dim=0 ) , size=target_sizes[idx] , mode='''bilinear''' , align_corners=lowerCAmelCase__ )
__SCREAMING_SNAKE_CASE : List[Any] = resized_logits[0].argmax(dim=0 )
semantic_segmentation.append(lowerCAmelCase__ )
else:
__SCREAMING_SNAKE_CASE : List[str] = logits.argmax(dim=1 )
__SCREAMING_SNAKE_CASE : Dict = [semantic_segmentation[i] for i in range(semantic_segmentation.shape[0] )]
return semantic_segmentation
| 9
|
import argparse
import torch
from ...utils import logging
from . import AlbertConfig, AlbertForPreTraining, load_tf_weights_in_albert
logging.set_verbosity_info()
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :List[Any] = AlbertConfig.from_json_file(SCREAMING_SNAKE_CASE )
print(f"""Building PyTorch model from configuration: {config}""" )
__UpperCamelCase :List[str] = AlbertForPreTraining(SCREAMING_SNAKE_CASE )
# Load weights from tf checkpoint
load_tf_weights_in_albert(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
# Save pytorch-model
print(f"""Save PyTorch model to {pytorch_dump_path}""" )
torch.save(model.state_dict() , SCREAMING_SNAKE_CASE )
if __name__ == "__main__":
__lowercase = argparse.ArgumentParser()
# Required parameters
parser.add_argument(
'''--tf_checkpoint_path''', default=None, type=str, required=True, help='''Path to the TensorFlow checkpoint path.'''
)
parser.add_argument(
'''--albert_config_file''',
default=None,
type=str,
required=True,
help=(
'''The config json file corresponding to the pre-trained ALBERT model. \n'''
'''This specifies the model architecture.'''
),
)
parser.add_argument(
'''--pytorch_dump_path''', default=None, type=str, required=True, help='''Path to the output PyTorch model.'''
)
__lowercase = parser.parse_args()
convert_tf_checkpoint_to_pytorch(args.tf_checkpoint_path, args.albert_config_file, args.pytorch_dump_path)
| 43
| 0
|
from urllib.parse import quote
import pytest
from datasets.utils.hub import hf_hub_url
@pytest.mark.parametrize("repo_id" , ["canonical_dataset_name", "org-name/dataset-name"] )
@pytest.mark.parametrize("path" , ["filename.csv", "filename with blanks.csv"] )
@pytest.mark.parametrize("revision" , [None, "v2"] )
def lowerCAmelCase_ ( __a , __a , __a ) -> Any:
"""simple docstring"""
lowerCamelCase__: Optional[int] =hf_hub_url(repo_id=__a , path=__a , revision=__a )
assert url == F"""https://huggingface.co/datasets/{repo_id}/resolve/{revision or "main"}/{quote(__a )}"""
| 10
|
import math
import qiskit
def lowerCamelCase ( SCREAMING_SNAKE_CASE = 1 , SCREAMING_SNAKE_CASE = 1 , SCREAMING_SNAKE_CASE = 1 ):
'''simple docstring'''
if (
isinstance(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
or isinstance(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
or isinstance(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
):
raise TypeError('''inputs must be integers.''' )
if (input_a < 0) or (input_a < 0) or (carry_in < 0):
raise ValueError('''inputs must be positive.''' )
if (
(math.floor(SCREAMING_SNAKE_CASE ) != input_a)
or (math.floor(SCREAMING_SNAKE_CASE ) != input_a)
or (math.floor(SCREAMING_SNAKE_CASE ) != carry_in)
):
raise ValueError('''inputs must be exact integers.''' )
if (input_a > 2) or (input_a > 2) or (carry_in > 2):
raise ValueError('''inputs must be less or equal to 2.''' )
# build registers
__UpperCamelCase :List[str] = qiskit.QuantumRegister(4 , '''qr''' )
__UpperCamelCase :str = qiskit.ClassicalRegister(2 , '''cr''' )
# list the entries
__UpperCamelCase :Tuple = [input_a, input_a, carry_in]
__UpperCamelCase :Optional[int] = qiskit.QuantumCircuit(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
for i in range(0 , 3 ):
if entry[i] == 2:
quantum_circuit.h(SCREAMING_SNAKE_CASE ) # for hadamard entries
elif entry[i] == 1:
quantum_circuit.x(SCREAMING_SNAKE_CASE ) # for 1 entries
elif entry[i] == 0:
quantum_circuit.i(SCREAMING_SNAKE_CASE ) # for 0 entries
# build the circuit
quantum_circuit.ccx(0 , 1 , 3 ) # ccx = toffoli gate
quantum_circuit.cx(0 , 1 )
quantum_circuit.ccx(1 , 2 , 3 )
quantum_circuit.cx(1 , 2 )
quantum_circuit.cx(0 , 1 )
quantum_circuit.measure([2, 3] , SCREAMING_SNAKE_CASE ) # measure the last two qbits
__UpperCamelCase :Optional[Any] = qiskit.Aer.get_backend('''aer_simulator''' )
__UpperCamelCase :Tuple = qiskit.execute(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , shots=1_000 )
return job.result().get_counts(SCREAMING_SNAKE_CASE )
if __name__ == "__main__":
print(F'Total sum count for state is: {quantum_full_adder(1, 1, 1)}')
| 43
| 0
|
import argparse
import csv
import logging
import os
import random
import numpy as np
import torch
from torch.utils.data import DataLoader, RandomSampler, SequentialSampler, TensorDataset
from tqdm import tqdm, trange
from transformers import (
CONFIG_NAME,
WEIGHTS_NAME,
AdamW,
OpenAIGPTDoubleHeadsModel,
OpenAIGPTTokenizer,
get_linear_schedule_with_warmup,
)
logging.basicConfig(
format='%(asctime)s - %(levelname)s - %(name)s - %(message)s', datefmt='%m/%d/%Y %H:%M:%S', level=logging.INFO
)
lowerCAmelCase__ = logging.getLogger(__name__)
def _UpperCAmelCase (UpperCamelCase__ : str , UpperCamelCase__ : str ):
_A : Optional[int] = np.argmax(UpperCamelCase__ , axis=1 )
return np.sum(outputs == labels )
def _UpperCAmelCase (UpperCamelCase__ : Optional[Any] ):
with open(UpperCamelCase__ , encoding="utf_8" ) as f:
_A : str = csv.reader(UpperCamelCase__ )
_A : List[Any] = []
next(UpperCamelCase__ ) # skip the first line
for line in tqdm(UpperCamelCase__ ):
output.append((" ".join(line[1:5] ), line[5], line[6], int(line[-1] ) - 1) )
return output
def _UpperCAmelCase (UpperCamelCase__ : Any , UpperCamelCase__ : Any , UpperCamelCase__ : int , UpperCamelCase__ : Union[str, Any] , UpperCamelCase__ : Optional[Any] , UpperCamelCase__ : Optional[int] ):
_A : int = []
for dataset in encoded_datasets:
_A : Tuple = len(UpperCamelCase__ )
_A : List[str] = np.zeros((n_batch, 2, input_len) , dtype=np.intaa )
_A : Optional[int] = np.zeros((n_batch, 2) , dtype=np.intaa )
_A : Any = np.full((n_batch, 2, input_len) , fill_value=-100 , dtype=np.intaa )
_A : List[Any] = np.zeros((n_batch,) , dtype=np.intaa )
for (
i,
(story, conta, conta, mc_label),
) in enumerate(UpperCamelCase__ ):
_A : Dict = [start_token] + story[:cap_length] + [delimiter_token] + conta[:cap_length] + [clf_token]
_A : List[str] = [start_token] + story[:cap_length] + [delimiter_token] + conta[:cap_length] + [clf_token]
_A : int = with_conta
_A : str = with_conta
_A : int = len(UpperCamelCase__ ) - 1
_A : str = len(UpperCamelCase__ ) - 1
_A : List[Any] = with_conta
_A : str = with_conta
_A : Union[str, Any] = mc_label
_A : int = (input_ids, mc_token_ids, lm_labels, mc_labels)
tensor_datasets.append(tuple(torch.tensor(UpperCamelCase__ ) for t in all_inputs ) )
return tensor_datasets
def _UpperCAmelCase ():
_A : Optional[int] = argparse.ArgumentParser()
parser.add_argument("--model_name" , type=UpperCamelCase__ , default="openai-gpt" , help="pretrained model name" )
parser.add_argument("--do_train" , action="store_true" , help="Whether to run training." )
parser.add_argument("--do_eval" , action="store_true" , help="Whether to run eval on the dev set." )
parser.add_argument(
"--output_dir" , default=UpperCamelCase__ , type=UpperCamelCase__ , required=UpperCamelCase__ , help="The output directory where the model predictions and checkpoints will be written." , )
parser.add_argument("--train_dataset" , type=UpperCamelCase__ , default="" )
parser.add_argument("--eval_dataset" , type=UpperCamelCase__ , default="" )
parser.add_argument("--seed" , type=UpperCamelCase__ , default=42 )
parser.add_argument("--num_train_epochs" , type=UpperCamelCase__ , default=3 )
parser.add_argument("--train_batch_size" , type=UpperCamelCase__ , default=8 )
parser.add_argument("--eval_batch_size" , type=UpperCamelCase__ , default=16 )
parser.add_argument("--adam_epsilon" , default=1E-8 , type=UpperCamelCase__ , help="Epsilon for Adam optimizer." )
parser.add_argument("--max_grad_norm" , type=UpperCamelCase__ , default=1 )
parser.add_argument(
"--max_steps" , default=-1 , type=UpperCamelCase__ , help=(
"If > 0: set total number of training steps to perform. Override num_train_epochs."
) , )
parser.add_argument(
"--gradient_accumulation_steps" , type=UpperCamelCase__ , default=1 , help="Number of updates steps to accumulate before performing a backward/update pass." , )
parser.add_argument("--learning_rate" , type=UpperCamelCase__ , default=6.25E-5 )
parser.add_argument("--warmup_steps" , default=0 , type=UpperCamelCase__ , help="Linear warmup over warmup_steps." )
parser.add_argument("--lr_schedule" , type=UpperCamelCase__ , default="warmup_linear" )
parser.add_argument("--weight_decay" , type=UpperCamelCase__ , default=0.01 )
parser.add_argument("--lm_coef" , type=UpperCamelCase__ , default=0.9 )
parser.add_argument("--n_valid" , type=UpperCamelCase__ , default=374 )
parser.add_argument("--server_ip" , type=UpperCamelCase__ , default="" , help="Can be used for distant debugging." )
parser.add_argument("--server_port" , type=UpperCamelCase__ , default="" , help="Can be used for distant debugging." )
_A : Optional[int] = parser.parse_args()
print(UpperCamelCase__ )
if args.server_ip and args.server_port:
# Distant debugging - see https://code.visualstudio.com/docs/python/debugging#_attach-to-a-local-script
import ptvsd
print("Waiting for debugger attach" )
ptvsd.enable_attach(address=(args.server_ip, args.server_port) , redirect_output=UpperCamelCase__ )
ptvsd.wait_for_attach()
random.seed(args.seed )
np.random.seed(args.seed )
torch.manual_seed(args.seed )
torch.cuda.manual_seed_all(args.seed )
_A : List[Any] = torch.device("cuda" if torch.cuda.is_available() else "cpu" )
_A : Optional[int] = torch.cuda.device_count()
logger.info("device: {}, n_gpu {}".format(UpperCamelCase__ , UpperCamelCase__ ) )
if not args.do_train and not args.do_eval:
raise ValueError("At least one of `do_train` or `do_eval` must be True." )
if not os.path.exists(args.output_dir ):
os.makedirs(args.output_dir )
# Load tokenizer and model
# This loading functions also add new tokens and embeddings called `special tokens`
# These new embeddings will be fine-tuned on the RocStories dataset
_A : Tuple = ["_start_", "_delimiter_", "_classify_"]
_A : Tuple = OpenAIGPTTokenizer.from_pretrained(args.model_name )
tokenizer.add_tokens(UpperCamelCase__ )
_A : Any = tokenizer.convert_tokens_to_ids(UpperCamelCase__ )
_A : Optional[int] = OpenAIGPTDoubleHeadsModel.from_pretrained(args.model_name )
model.resize_token_embeddings(len(UpperCamelCase__ ) )
model.to(UpperCamelCase__ )
# Load and encode the datasets
def tokenize_and_encode(UpperCamelCase__ : int ):
if isinstance(UpperCamelCase__ , UpperCamelCase__ ):
return tokenizer.convert_tokens_to_ids(tokenizer.tokenize(UpperCamelCase__ ) )
elif isinstance(UpperCamelCase__ , UpperCamelCase__ ):
return obj
return [tokenize_and_encode(UpperCamelCase__ ) for o in obj]
logger.info("Encoding dataset..." )
_A : Any = load_rocstories_dataset(args.train_dataset )
_A : Union[str, Any] = load_rocstories_dataset(args.eval_dataset )
_A : List[str] = (train_dataset, eval_dataset)
_A : int = tokenize_and_encode(UpperCamelCase__ )
# Compute the max input length for the Transformer
_A : str = model.config.n_positions // 2 - 2
_A : Any = max(
len(story[:max_length] ) + max(len(conta[:max_length] ) , len(conta[:max_length] ) ) + 3
for dataset in encoded_datasets
for story, conta, conta, _ in dataset )
_A : Dict = min(UpperCamelCase__ , model.config.n_positions ) # Max size of input for the pre-trained model
# Prepare inputs tensors and dataloaders
_A : Dict = pre_process_datasets(UpperCamelCase__ , UpperCamelCase__ , UpperCamelCase__ , *UpperCamelCase__ )
_A , _A : List[Any] = tensor_datasets[0], tensor_datasets[1]
_A : Dict = TensorDataset(*UpperCamelCase__ )
_A : Optional[int] = RandomSampler(UpperCamelCase__ )
_A : int = DataLoader(UpperCamelCase__ , sampler=UpperCamelCase__ , batch_size=args.train_batch_size )
_A : int = TensorDataset(*UpperCamelCase__ )
_A : List[Any] = SequentialSampler(UpperCamelCase__ )
_A : Optional[Any] = DataLoader(UpperCamelCase__ , sampler=UpperCamelCase__ , batch_size=args.eval_batch_size )
# Prepare optimizer
if args.do_train:
if args.max_steps > 0:
_A : Tuple = args.max_steps
_A : Tuple = args.max_steps // (len(UpperCamelCase__ ) // args.gradient_accumulation_steps) + 1
else:
_A : Any = len(UpperCamelCase__ ) // args.gradient_accumulation_steps * args.num_train_epochs
_A : List[str] = list(model.named_parameters() )
_A : List[Any] = ["bias", "LayerNorm.bias", "LayerNorm.weight"]
_A : Dict = [
{
"params": [p for n, p in param_optimizer if not any(nd in n for nd in no_decay )],
"weight_decay": args.weight_decay,
},
{"params": [p for n, p in param_optimizer if any(nd in n for nd in no_decay )], "weight_decay": 0.0},
]
_A : Union[str, Any] = AdamW(UpperCamelCase__ , lr=args.learning_rate , eps=args.adam_epsilon )
_A : List[Any] = get_linear_schedule_with_warmup(
UpperCamelCase__ , num_warmup_steps=args.warmup_steps , num_training_steps=UpperCamelCase__ )
if args.do_train:
_A , _A , _A : Union[str, Any] = 0, 0, None
model.train()
for _ in trange(int(args.num_train_epochs ) , desc="Epoch" ):
_A : Tuple = 0
_A : str = 0
_A : Dict = tqdm(UpperCamelCase__ , desc="Training" )
for step, batch in enumerate(UpperCamelCase__ ):
_A : List[Any] = tuple(t.to(UpperCamelCase__ ) for t in batch )
_A , _A , _A , _A : List[str] = batch
_A : int = model(UpperCamelCase__ , mc_token_ids=UpperCamelCase__ , lm_labels=UpperCamelCase__ , mc_labels=UpperCamelCase__ )
_A : str = args.lm_coef * losses[0] + losses[1]
loss.backward()
optimizer.step()
scheduler.step()
optimizer.zero_grad()
tr_loss += loss.item()
_A : Any = (
loss.item() if exp_average_loss is None else 0.7 * exp_average_loss + 0.3 * loss.item()
)
nb_tr_steps += 1
_A : Optional[Any] = "Training loss: {:.2e} lr: {:.2e}".format(UpperCamelCase__ , scheduler.get_lr()[0] )
# Save a trained model
if args.do_train:
# Save a trained model, configuration and tokenizer
_A : List[Any] = model.module if hasattr(UpperCamelCase__ , "module" ) else model # Only save the model itself
# If we save using the predefined names, we can load using `from_pretrained`
_A : List[str] = os.path.join(args.output_dir , UpperCamelCase__ )
_A : Dict = os.path.join(args.output_dir , UpperCamelCase__ )
torch.save(model_to_save.state_dict() , UpperCamelCase__ )
model_to_save.config.to_json_file(UpperCamelCase__ )
tokenizer.save_vocabulary(args.output_dir )
# Load a trained model and vocabulary that you have fine-tuned
_A : Optional[int] = OpenAIGPTDoubleHeadsModel.from_pretrained(args.output_dir )
_A : int = OpenAIGPTTokenizer.from_pretrained(args.output_dir )
model.to(UpperCamelCase__ )
if args.do_eval:
model.eval()
_A , _A : str = 0, 0
_A , _A : Any = 0, 0
for batch in tqdm(UpperCamelCase__ , desc="Evaluating" ):
_A : Union[str, Any] = tuple(t.to(UpperCamelCase__ ) for t in batch )
_A , _A , _A , _A : Any = batch
with torch.no_grad():
_A , _A , _A , _A : Tuple = model(
UpperCamelCase__ , mc_token_ids=UpperCamelCase__ , lm_labels=UpperCamelCase__ , mc_labels=UpperCamelCase__ )
_A : List[Any] = mc_logits.detach().cpu().numpy()
_A : Optional[Any] = mc_labels.to("cpu" ).numpy()
_A : Union[str, Any] = accuracy(UpperCamelCase__ , UpperCamelCase__ )
eval_loss += mc_loss.mean().item()
eval_accuracy += tmp_eval_accuracy
nb_eval_examples += input_ids.size(0 )
nb_eval_steps += 1
_A : Any = eval_loss / nb_eval_steps
_A : int = eval_accuracy / nb_eval_examples
_A : Dict = tr_loss / nb_tr_steps if args.do_train else None
_A : Any = {"eval_loss": eval_loss, "eval_accuracy": eval_accuracy, "train_loss": train_loss}
_A : Union[str, Any] = os.path.join(args.output_dir , "eval_results.txt" )
with open(UpperCamelCase__ , "w" ) as writer:
logger.info("***** Eval results *****" )
for key in sorted(result.keys() ):
logger.info(" %s = %s" , UpperCamelCase__ , str(result[key] ) )
writer.write("%s = %s\n" % (key, str(result[key] )) )
if __name__ == "__main__":
main()
| 11
|
import random
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Optional[Any] = a[left_index]
__UpperCamelCase :Any = left_index + 1
for j in range(left_index + 1 , SCREAMING_SNAKE_CASE ):
if a[j] < pivot:
__UpperCamelCase , __UpperCamelCase :str = a[i], a[j]
i += 1
__UpperCamelCase , __UpperCamelCase :Optional[int] = a[i - 1], a[left_index]
return i - 1
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
if left < right:
__UpperCamelCase :int = random.randint(SCREAMING_SNAKE_CASE , right - 1 )
__UpperCamelCase , __UpperCamelCase :List[str] = (
a[left],
a[pivot],
) # switches the pivot with the left most bound
__UpperCamelCase :Dict = partition(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
quick_sort_random(
SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ) # recursive quicksort to the left of the pivot point
quick_sort_random(
SCREAMING_SNAKE_CASE , pivot_index + 1 , SCREAMING_SNAKE_CASE ) # recursive quicksort to the right of the pivot point
def lowerCamelCase ( ):
'''simple docstring'''
__UpperCamelCase :Tuple = input('''Enter numbers separated by a comma:\n''' ).strip()
__UpperCamelCase :Union[str, Any] = [int(SCREAMING_SNAKE_CASE ) for item in user_input.split(''',''' )]
quick_sort_random(SCREAMING_SNAKE_CASE , 0 , len(SCREAMING_SNAKE_CASE ) )
print(SCREAMING_SNAKE_CASE )
if __name__ == "__main__":
main()
| 43
| 0
|
from typing import TYPE_CHECKING
from ...utils import OptionalDependencyNotAvailable, _LazyModule, is_sentencepiece_available
UpperCAmelCase_ = {}
try:
if not is_sentencepiece_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
UpperCAmelCase_ = ['MLukeTokenizer']
if TYPE_CHECKING:
try:
if not is_sentencepiece_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .tokenization_mluke import MLukeTokenizer
else:
import sys
UpperCAmelCase_ = _LazyModule(__name__, globals()['__file__'], _import_structure, module_spec=__spec__)
| 12
|
def lowerCamelCase ( SCREAMING_SNAKE_CASE = 1 , SCREAMING_SNAKE_CASE = 1_000 ):
'''simple docstring'''
__UpperCamelCase :Union[str, Any] = 1
__UpperCamelCase :Any = 0
for divide_by_number in range(SCREAMING_SNAKE_CASE , digit + 1 ):
__UpperCamelCase :list[int] = []
__UpperCamelCase :Optional[int] = numerator
for _ in range(1 , digit + 1 ):
if now_divide in has_been_divided:
if longest_list_length < len(SCREAMING_SNAKE_CASE ):
__UpperCamelCase :Optional[Any] = len(SCREAMING_SNAKE_CASE )
__UpperCamelCase :int = divide_by_number
else:
has_been_divided.append(SCREAMING_SNAKE_CASE )
__UpperCamelCase :Any = now_divide * 10 % divide_by_number
return the_digit
# Tests
if __name__ == "__main__":
import doctest
doctest.testmod()
| 43
| 0
|
import numpy as np
def A_ ( _UpperCAmelCase , _UpperCAmelCase ):
return np.where(vector > 0 , _UpperCAmelCase , (alpha * (np.exp(_UpperCAmelCase ) - 1)) )
if __name__ == "__main__":
import doctest
doctest.testmod()
| 13
|
import argparse
import json
from tqdm import tqdm
def lowerCamelCase ( ):
'''simple docstring'''
__UpperCamelCase :Tuple = argparse.ArgumentParser()
# Required parameters
parser.add_argument(
'''--src_path''' , type=SCREAMING_SNAKE_CASE , default='''biencoder-nq-dev.json''' , help='''Path to raw DPR training data''' , )
parser.add_argument(
'''--evaluation_set''' , type=SCREAMING_SNAKE_CASE , help='''where to store parsed evaluation_set file''' , )
parser.add_argument(
'''--gold_data_path''' , type=SCREAMING_SNAKE_CASE , help='''where to store parsed gold_data_path file''' , )
__UpperCamelCase :str = parser.parse_args()
with open(args.src_path , '''r''' ) as src_file, open(args.evaluation_set , '''w''' ) as eval_file, open(
args.gold_data_path , '''w''' ) as gold_file:
__UpperCamelCase :List[str] = json.load(SCREAMING_SNAKE_CASE )
for dpr_record in tqdm(SCREAMING_SNAKE_CASE ):
__UpperCamelCase :List[str] = dpr_record['''question''']
__UpperCamelCase :Tuple = [context['''title'''] for context in dpr_record['''positive_ctxs''']]
eval_file.write(question + '''\n''' )
gold_file.write('''\t'''.join(SCREAMING_SNAKE_CASE ) + '''\n''' )
if __name__ == "__main__":
main()
| 43
| 0
|
import argparse
import json
from pathlib import Path
import requests
import torch
from huggingface_hub import hf_hub_download
from PIL import Image
from transformers import (
MobileViTConfig,
MobileViTForImageClassification,
MobileViTForSemanticSegmentation,
MobileViTImageProcessor,
)
from transformers.utils import logging
logging.set_verbosity_info()
_lowerCamelCase : List[str] = logging.get_logger(__name__)
def SCREAMING_SNAKE_CASE ( lowercase_ ) -> List[Any]:
"""simple docstring"""
A__ = MobileViTConfig()
# size of the architecture
if "mobilevit_s" in mobilevit_name:
A__ = [144, 192, 240]
A__ = [16, 32, 64, 96, 128, 160, 640]
elif "mobilevit_xs" in mobilevit_name:
A__ = [96, 120, 144]
A__ = [16, 32, 48, 64, 80, 96, 384]
elif "mobilevit_xxs" in mobilevit_name:
A__ = [64, 80, 96]
A__ = [16, 16, 24, 48, 64, 80, 320]
A__ = 0.05
A__ = 2.0
if mobilevit_name.startswith('''deeplabv3_''' ):
A__ = 512
A__ = 16
A__ = 21
A__ = '''pascal-voc-id2label.json'''
else:
A__ = 1_000
A__ = '''imagenet-1k-id2label.json'''
A__ = '''huggingface/label-files'''
A__ = json.load(open(hf_hub_download(lowercase_ , lowercase_ , repo_type='''dataset''' ) , '''r''' ) )
A__ = {int(lowercase_ ): v for k, v in idalabel.items()}
A__ = idalabel
A__ = {v: k for k, v in idalabel.items()}
return config
def SCREAMING_SNAKE_CASE ( lowercase_ , lowercase_=False ) -> Tuple:
"""simple docstring"""
for i in range(1 , 6 ):
if f"""layer_{i}.""" in name:
A__ = name.replace(f"""layer_{i}.""" , f"""encoder.layer.{i - 1}.""" )
if "conv_1." in name:
A__ = name.replace('''conv_1.''' , '''conv_stem.''' )
if ".block." in name:
A__ = name.replace('''.block.''' , '''.''' )
if "exp_1x1" in name:
A__ = name.replace('''exp_1x1''' , '''expand_1x1''' )
if "red_1x1" in name:
A__ = name.replace('''red_1x1''' , '''reduce_1x1''' )
if ".local_rep.conv_3x3." in name:
A__ = name.replace('''.local_rep.conv_3x3.''' , '''.conv_kxk.''' )
if ".local_rep.conv_1x1." in name:
A__ = name.replace('''.local_rep.conv_1x1.''' , '''.conv_1x1.''' )
if ".norm." in name:
A__ = name.replace('''.norm.''' , '''.normalization.''' )
if ".conv." in name:
A__ = name.replace('''.conv.''' , '''.convolution.''' )
if ".conv_proj." in name:
A__ = name.replace('''.conv_proj.''' , '''.conv_projection.''' )
for i in range(0 , 2 ):
for j in range(0 , 4 ):
if f""".{i}.{j}.""" in name:
A__ = name.replace(f""".{i}.{j}.""" , f""".{i}.layer.{j}.""" )
for i in range(2 , 6 ):
for j in range(0 , 4 ):
if f""".{i}.{j}.""" in name:
A__ = name.replace(f""".{i}.{j}.""" , f""".{i}.""" )
if "expand_1x1" in name:
A__ = name.replace('''expand_1x1''' , '''downsampling_layer.expand_1x1''' )
if "conv_3x3" in name:
A__ = name.replace('''conv_3x3''' , '''downsampling_layer.conv_3x3''' )
if "reduce_1x1" in name:
A__ = name.replace('''reduce_1x1''' , '''downsampling_layer.reduce_1x1''' )
for i in range(2 , 5 ):
if f""".global_rep.{i}.weight""" in name:
A__ = name.replace(f""".global_rep.{i}.weight""" , '''.layernorm.weight''' )
if f""".global_rep.{i}.bias""" in name:
A__ = name.replace(f""".global_rep.{i}.bias""" , '''.layernorm.bias''' )
if ".global_rep." in name:
A__ = name.replace('''.global_rep.''' , '''.transformer.''' )
if ".pre_norm_mha.0." in name:
A__ = name.replace('''.pre_norm_mha.0.''' , '''.layernorm_before.''' )
if ".pre_norm_mha.1.out_proj." in name:
A__ = name.replace('''.pre_norm_mha.1.out_proj.''' , '''.attention.output.dense.''' )
if ".pre_norm_ffn.0." in name:
A__ = name.replace('''.pre_norm_ffn.0.''' , '''.layernorm_after.''' )
if ".pre_norm_ffn.1." in name:
A__ = name.replace('''.pre_norm_ffn.1.''' , '''.intermediate.dense.''' )
if ".pre_norm_ffn.4." in name:
A__ = name.replace('''.pre_norm_ffn.4.''' , '''.output.dense.''' )
if ".transformer." in name:
A__ = name.replace('''.transformer.''' , '''.transformer.layer.''' )
if ".aspp_layer." in name:
A__ = name.replace('''.aspp_layer.''' , '''.''' )
if ".aspp_pool." in name:
A__ = name.replace('''.aspp_pool.''' , '''.''' )
if "seg_head." in name:
A__ = name.replace('''seg_head.''' , '''segmentation_head.''' )
if "segmentation_head.classifier.classifier." in name:
A__ = name.replace('''segmentation_head.classifier.classifier.''' , '''segmentation_head.classifier.''' )
if "classifier.fc." in name:
A__ = name.replace('''classifier.fc.''' , '''classifier.''' )
elif (not base_model) and ("segmentation_head." not in name):
A__ = '''mobilevit.''' + name
return name
def SCREAMING_SNAKE_CASE ( lowercase_ , lowercase_ , lowercase_=False ) -> Union[str, Any]:
"""simple docstring"""
if base_model:
A__ = ''''''
else:
A__ = '''mobilevit.'''
for key in orig_state_dict.copy().keys():
A__ = orig_state_dict.pop(lowercase_ )
if key[:8] == "encoder.":
A__ = key[8:]
if "qkv" in key:
A__ = key.split('''.''' )
A__ = int(key_split[0][6:] ) - 1
A__ = int(key_split[3] )
A__ = model.get_submodule(f"""{model_prefix}encoder.layer.{layer_num}""" )
A__ = layer.transformer.layer[transformer_num].attention.attention.all_head_size
A__ = (
f"""{model_prefix}encoder.layer.{layer_num}.transformer.layer.{transformer_num}.attention.attention."""
)
if "weight" in key:
A__ = val[:dim, :]
A__ = val[dim : dim * 2, :]
A__ = val[-dim:, :]
else:
A__ = val[:dim]
A__ = val[dim : dim * 2]
A__ = val[-dim:]
else:
A__ = val
return orig_state_dict
def SCREAMING_SNAKE_CASE ( ) -> List[Any]:
"""simple docstring"""
A__ = '''http://images.cocodataset.org/val2017/000000039769.jpg'''
A__ = Image.open(requests.get(lowercase_ , stream=lowercase_ ).raw )
return im
@torch.no_grad()
def SCREAMING_SNAKE_CASE ( lowercase_ , lowercase_ , lowercase_ , lowercase_=False ) -> Optional[Any]:
"""simple docstring"""
A__ = get_mobilevit_config(lowercase_ )
# load original state_dict
A__ = torch.load(lowercase_ , map_location='''cpu''' )
# load 🤗 model
if mobilevit_name.startswith('''deeplabv3_''' ):
A__ = MobileViTForSemanticSegmentation(lowercase_ ).eval()
else:
A__ = MobileViTForImageClassification(lowercase_ ).eval()
A__ = convert_state_dict(lowercase_ , lowercase_ )
model.load_state_dict(lowercase_ )
# Check outputs on an image, prepared by MobileViTImageProcessor
A__ = MobileViTImageProcessor(crop_size=config.image_size , size=config.image_size + 32 )
A__ = image_processor(images=prepare_img() , return_tensors='''pt''' )
A__ = model(**lowercase_ )
A__ = outputs.logits
if mobilevit_name.startswith('''deeplabv3_''' ):
assert logits.shape == (1, 21, 32, 32)
if mobilevit_name == "deeplabv3_mobilevit_s":
A__ = torch.tensor(
[
[[6.20_65, 6.12_92, 6.20_70], [6.10_79, 6.12_54, 6.17_47], [6.00_42, 6.10_71, 6.10_34]],
[[-6.92_53, -6.86_53, -7.03_98], [-7.32_18, -7.39_83, -7.36_70], [-7.19_61, -7.24_82, -7.15_69]],
[[-4.47_23, -4.43_48, -4.37_69], [-5.36_29, -5.46_32, -5.45_98], [-5.15_87, -5.34_02, -5.50_59]],
] )
elif mobilevit_name == "deeplabv3_mobilevit_xs":
A__ = torch.tensor(
[
[[5.44_49, 5.57_33, 5.63_14], [5.18_15, 5.39_30, 5.59_63], [5.16_56, 5.43_33, 5.48_53]],
[[-9.44_23, -9.77_66, -9.67_14], [-9.15_81, -9.57_20, -9.55_19], [-9.10_06, -9.64_58, -9.57_03]],
[[-7.77_21, -7.37_16, -7.15_83], [-8.45_99, -8.06_24, -7.79_44], [-8.41_72, -7.83_66, -7.50_25]],
] )
elif mobilevit_name == "deeplabv3_mobilevit_xxs":
A__ = torch.tensor(
[
[[6.98_11, 6.97_43, 7.31_23], [7.17_77, 7.19_31, 7.39_38], [7.56_33, 7.80_50, 7.89_01]],
[[-10.55_36, -10.23_32, -10.29_24], [-10.23_36, -9.86_24, -9.59_64], [-10.88_40, -10.81_58, -10.66_59]],
[[-3.49_38, -3.06_31, -2.86_20], [-3.42_05, -2.81_35, -2.68_75], [-3.41_79, -2.79_45, -2.87_50]],
] )
else:
raise ValueError(f"""Unknown mobilevit_name: {mobilevit_name}""" )
assert torch.allclose(logits[0, :3, :3, :3] , lowercase_ , atol=1E-4 )
else:
assert logits.shape == (1, 1_000)
if mobilevit_name == "mobilevit_s":
A__ = torch.tensor([-0.98_66, 0.23_92, -1.12_41] )
elif mobilevit_name == "mobilevit_xs":
A__ = torch.tensor([-2.47_61, -0.93_99, -1.95_87] )
elif mobilevit_name == "mobilevit_xxs":
A__ = torch.tensor([-1.93_64, -1.23_27, -0.46_53] )
else:
raise ValueError(f"""Unknown mobilevit_name: {mobilevit_name}""" )
assert torch.allclose(logits[0, :3] , lowercase_ , atol=1E-4 )
Path(lowercase_ ).mkdir(exist_ok=lowercase_ )
print(f"""Saving model {mobilevit_name} to {pytorch_dump_folder_path}""" )
model.save_pretrained(lowercase_ )
print(f"""Saving image processor to {pytorch_dump_folder_path}""" )
image_processor.save_pretrained(lowercase_ )
if push_to_hub:
A__ = {
'''mobilevit_s''': '''mobilevit-small''',
'''mobilevit_xs''': '''mobilevit-x-small''',
'''mobilevit_xxs''': '''mobilevit-xx-small''',
'''deeplabv3_mobilevit_s''': '''deeplabv3-mobilevit-small''',
'''deeplabv3_mobilevit_xs''': '''deeplabv3-mobilevit-x-small''',
'''deeplabv3_mobilevit_xxs''': '''deeplabv3-mobilevit-xx-small''',
}
print('''Pushing to the hub...''' )
A__ = model_mapping[mobilevit_name]
image_processor.push_to_hub(lowercase_ , organization='''apple''' )
model.push_to_hub(lowercase_ , organization='''apple''' )
if __name__ == "__main__":
_lowerCamelCase : int = argparse.ArgumentParser()
# Required parameters
parser.add_argument(
"""--mobilevit_name""",
default="""mobilevit_s""",
type=str,
help=(
"""Name of the MobileViT model you'd like to convert. Should be one of 'mobilevit_s', 'mobilevit_xs',"""
""" 'mobilevit_xxs', 'deeplabv3_mobilevit_s', 'deeplabv3_mobilevit_xs', 'deeplabv3_mobilevit_xxs'."""
),
)
parser.add_argument(
"""--checkpoint_path""", required=True, type=str, help="""Path to the original state dict (.pt file)."""
)
parser.add_argument(
"""--pytorch_dump_folder_path""", required=True, 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."""
)
_lowerCamelCase : str = parser.parse_args()
convert_movilevit_checkpoint(
args.mobilevit_name, args.checkpoint_path, args.pytorch_dump_folder_path, args.push_to_hub
)
| 14
|
from __future__ import annotations
import random
# Maximum size of the population. Bigger could be faster but is more memory expensive.
__lowercase = 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.
__lowercase = 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.
__lowercase = 0.4
# Just a seed to improve randomness required by the algorithm.
random.seed(random.randint(0, 1000))
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Any = len([g for position, g in enumerate(SCREAMING_SNAKE_CASE ) if g == main_target[position]] )
return (item, float(SCREAMING_SNAKE_CASE ))
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Optional[Any] = random.randint(0 , len(SCREAMING_SNAKE_CASE ) - 1 )
__UpperCamelCase :Tuple = parent_a[:random_slice] + parent_a[random_slice:]
__UpperCamelCase :Union[str, Any] = parent_a[:random_slice] + parent_a[random_slice:]
return (child_a, child_a)
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :int = list(SCREAMING_SNAKE_CASE )
if random.uniform(0 , 1 ) < MUTATION_PROBABILITY:
__UpperCamelCase :str = random.choice(SCREAMING_SNAKE_CASE )
return "".join(SCREAMING_SNAKE_CASE )
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , ):
'''simple docstring'''
__UpperCamelCase :int = []
# Generate more children proportionally to the fitness score.
__UpperCamelCase :int = int(parent_a[1] * 100 ) + 1
__UpperCamelCase :List[str] = 10 if child_n >= 10 else child_n
for _ in range(SCREAMING_SNAKE_CASE ):
__UpperCamelCase :Optional[Any] = population_score[random.randint(0 , SCREAMING_SNAKE_CASE )][0]
__UpperCamelCase , __UpperCamelCase :Any = crossover(parent_a[0] , SCREAMING_SNAKE_CASE )
# Append new string to the population list.
pop.append(mutate(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ) )
pop.append(mutate(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ) )
return pop
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE = True ):
'''simple docstring'''
if N_POPULATION < N_SELECTED:
__UpperCamelCase :List[Any] = f"""{N_POPULATION} must be bigger than {N_SELECTED}"""
raise ValueError(SCREAMING_SNAKE_CASE )
# Verify that the target contains no genes besides the ones inside genes variable.
__UpperCamelCase :List[str] = sorted({c for c in target if c not in genes} )
if not_in_genes_list:
__UpperCamelCase :Optional[int] = f"""{not_in_genes_list} is not in genes list, evolution cannot converge"""
raise ValueError(SCREAMING_SNAKE_CASE )
# Generate random starting population.
__UpperCamelCase :int = []
for _ in range(SCREAMING_SNAKE_CASE ):
population.append(''''''.join([random.choice(SCREAMING_SNAKE_CASE ) for i in range(len(SCREAMING_SNAKE_CASE ) )] ) )
# Just some logs to know what the algorithms is doing.
__UpperCamelCase , __UpperCamelCase :List[Any] = 0, 0
# This loop will end when we find a perfect match for our target.
while True:
generation += 1
total_population += len(SCREAMING_SNAKE_CASE )
# 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.
__UpperCamelCase :Tuple = [evaluate(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ) for item in population]
# Check if there is a matching evolution.
__UpperCamelCase :Tuple = sorted(SCREAMING_SNAKE_CASE , key=lambda SCREAMING_SNAKE_CASE : x[1] , reverse=SCREAMING_SNAKE_CASE )
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.
__UpperCamelCase :str = population[: int(N_POPULATION / 3 )]
population.clear()
population.extend(SCREAMING_SNAKE_CASE )
# Normalize population score to be between 0 and 1.
__UpperCamelCase :Union[str, Any] = [
(item, score / len(SCREAMING_SNAKE_CASE )) for item, score in population_score
]
# This is selection
for i in range(SCREAMING_SNAKE_CASE ):
population.extend(select(population_score[int(SCREAMING_SNAKE_CASE )] , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ) )
# 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(SCREAMING_SNAKE_CASE ) > N_POPULATION:
break
if __name__ == "__main__":
__lowercase = (
'''This is a genetic algorithm to evaluate, combine, evolve, and mutate a string!'''
)
__lowercase = list(
''' ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklm'''
'''nopqrstuvwxyz.,;!?+-*#@^\'èéòà€ù=)(&%$£/\\'''
)
__lowercase , __lowercase , __lowercase = basic(target_str, genes_list)
print(
F'\nGeneration: {generation}\nTotal Population: {population}\nTarget: {target}'
)
| 43
| 0
|
import json
import os
import shutil
import tempfile
import unittest
import numpy as np
from transformers import BertTokenizerFast
from transformers.models.bert.tokenization_bert import VOCAB_FILES_NAMES, BertTokenizer
from transformers.testing_utils import require_tokenizers, require_vision
from transformers.utils import IMAGE_PROCESSOR_NAME, is_vision_available
if is_vision_available():
from PIL import Image
from transformers import VisionTextDualEncoderProcessor, ViTImageProcessor
@require_tokenizers
@require_vision
class UpperCAmelCase ( unittest.TestCase ):
'''simple docstring'''
def UpperCamelCase_ ( self : Union[str, Any] ):
__A = tempfile.mkdtemp()
# fmt: off
__A = ["[UNK]", "[CLS]", "[SEP]", "[PAD]", "[MASK]", "want", "##want", "##ed", "wa", "un", "runn", "##ing", ",", "low", "lowest"]
# fmt: on
__A = os.path.join(self.tmpdirname ,VOCAB_FILES_NAMES["vocab_file"] )
with open(self.vocab_file ,"w" ,encoding="utf-8" ) as vocab_writer:
vocab_writer.write("".join([x + "\n" for x in vocab_tokens] ) )
__A = {
"do_resize": True,
"size": {"height": 18, "width": 18},
"do_normalize": True,
"image_mean": [0.5, 0.5, 0.5],
"image_std": [0.5, 0.5, 0.5],
}
__A = os.path.join(self.tmpdirname ,A )
with open(self.image_processor_file ,"w" ,encoding="utf-8" ) as fp:
json.dump(A ,A )
def UpperCamelCase_ ( self : int ,**A : List[Any] ):
return BertTokenizer.from_pretrained(self.tmpdirname ,**A )
def UpperCamelCase_ ( self : int ,**A : Optional[Any] ):
return ViTImageProcessor.from_pretrained(self.tmpdirname ,**A )
def UpperCamelCase_ ( self : Union[str, Any] ):
shutil.rmtree(self.tmpdirname )
def UpperCamelCase_ ( self : Dict ):
__A = [np.random.randint(2_55 ,size=(3, 30, 4_00) ,dtype=np.uinta )]
__A = [Image.fromarray(np.moveaxis(A ,0 ,-1 ) ) for x in image_inputs]
return image_inputs
def UpperCamelCase_ ( self : Dict ):
__A = self.get_tokenizer()
__A = self.get_image_processor()
__A = VisionTextDualEncoderProcessor(tokenizer=A ,image_processor=A )
processor.save_pretrained(self.tmpdirname )
__A = VisionTextDualEncoderProcessor.from_pretrained(self.tmpdirname )
self.assertEqual(processor.tokenizer.get_vocab() ,tokenizer.get_vocab() )
self.assertIsInstance(processor.tokenizer ,(BertTokenizer, BertTokenizerFast) )
self.assertEqual(processor.image_processor.to_json_string() ,image_processor.to_json_string() )
self.assertIsInstance(processor.image_processor ,A )
def UpperCamelCase_ ( self : Tuple ):
__A = VisionTextDualEncoderProcessor(
tokenizer=self.get_tokenizer() ,image_processor=self.get_image_processor() )
processor.save_pretrained(self.tmpdirname )
__A = self.get_tokenizer(bos_token="(BOS)" ,eos_token="(EOS)" )
__A = self.get_image_processor(do_normalize=A ,padding_value=1.0 )
__A = VisionTextDualEncoderProcessor.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 ,(BertTokenizer, BertTokenizerFast) )
self.assertEqual(processor.image_processor.to_json_string() ,image_processor_add_kwargs.to_json_string() )
self.assertIsInstance(processor.image_processor ,A )
def UpperCamelCase_ ( self : int ):
__A = self.get_image_processor()
__A = self.get_tokenizer()
__A = VisionTextDualEncoderProcessor(tokenizer=A ,image_processor=A )
__A = self.prepare_image_inputs()
__A = image_processor(A ,return_tensors="np" )
__A = processor(images=A ,return_tensors="np" )
for key in input_feat_extract.keys():
self.assertAlmostEqual(input_feat_extract[key].sum() ,input_processor[key].sum() ,delta=1E-2 )
def UpperCamelCase_ ( self : Optional[int] ):
__A = self.get_image_processor()
__A = self.get_tokenizer()
__A = VisionTextDualEncoderProcessor(tokenizer=A ,image_processor=A )
__A = "lower newer"
__A = processor(text=A )
__A = tokenizer(A )
for key in encoded_tok.keys():
self.assertListEqual(encoded_tok[key] ,encoded_processor[key] )
def UpperCamelCase_ ( self : Any ):
__A = self.get_image_processor()
__A = self.get_tokenizer()
__A = VisionTextDualEncoderProcessor(tokenizer=A ,image_processor=A )
__A = "lower newer"
__A = self.prepare_image_inputs()
__A = processor(text=A ,images=A )
self.assertListEqual(list(inputs.keys() ) ,["input_ids", "token_type_ids", "attention_mask", "pixel_values"] )
# test if it raises when no input is passed
with self.assertRaises(A ):
processor()
def UpperCamelCase_ ( self : int ):
__A = self.get_image_processor()
__A = self.get_tokenizer()
__A = VisionTextDualEncoderProcessor(tokenizer=A ,image_processor=A )
__A = [[1, 4, 5, 8, 1, 0, 8], [3, 4, 3, 1, 1, 8, 9]]
__A = processor.batch_decode(A )
__A = tokenizer.batch_decode(A )
self.assertListEqual(A ,A )
def UpperCamelCase_ ( self : int ):
__A = self.get_image_processor()
__A = self.get_tokenizer()
__A = VisionTextDualEncoderProcessor(tokenizer=A ,image_processor=A )
__A = "lower newer"
__A = self.prepare_image_inputs()
__A = processor(text=A ,images=A )
self.assertListEqual(list(inputs.keys() ) ,processor.model_input_names )
| 15
|
import argparse
import json
import os
import evaluate
import torch
from datasets import load_dataset
from torch.optim import AdamW
from torch.utils.data import DataLoader
from transformers import AutoModelForSequenceClassification, AutoTokenizer, get_linear_schedule_with_warmup, set_seed
from accelerate import Accelerator, DistributedType
from accelerate.utils.deepspeed import DummyOptim, DummyScheduler
__lowercase = 16
__lowercase = 32
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE = 16 , SCREAMING_SNAKE_CASE = "bert-base-cased" ):
'''simple docstring'''
__UpperCamelCase :List[str] = AutoTokenizer.from_pretrained(SCREAMING_SNAKE_CASE )
__UpperCamelCase :Any = load_dataset('''glue''' , '''mrpc''' )
def tokenize_function(SCREAMING_SNAKE_CASE ):
# max_length=None => use the model max length (it's actually the default)
__UpperCamelCase :int = tokenizer(examples['''sentence1'''] , examples['''sentence2'''] , truncation=SCREAMING_SNAKE_CASE , max_length=SCREAMING_SNAKE_CASE )
return outputs
# Apply the method we just defined to all the examples in all the splits of the dataset
__UpperCamelCase :Tuple = datasets.map(
SCREAMING_SNAKE_CASE , batched=SCREAMING_SNAKE_CASE , remove_columns=['''idx''', '''sentence1''', '''sentence2'''] , load_from_cache_file=SCREAMING_SNAKE_CASE )
# We also rename the 'label' column to 'labels' which is the expected name for labels by the models of the
# transformers library
__UpperCamelCase :List[str] = tokenized_datasets.rename_column('''label''' , '''labels''' )
def collate_fn(SCREAMING_SNAKE_CASE ):
# On TPU it's best to pad everything to the same length or training will be very slow.
if accelerator.distributed_type == DistributedType.TPU:
return tokenizer.pad(SCREAMING_SNAKE_CASE , padding='''max_length''' , max_length=128 , return_tensors='''pt''' )
return tokenizer.pad(SCREAMING_SNAKE_CASE , padding='''longest''' , return_tensors='''pt''' )
# Instantiate dataloaders.
__UpperCamelCase :Union[str, Any] = DataLoader(
tokenized_datasets['''train'''] , shuffle=SCREAMING_SNAKE_CASE , collate_fn=SCREAMING_SNAKE_CASE , batch_size=SCREAMING_SNAKE_CASE )
__UpperCamelCase :Dict = DataLoader(
tokenized_datasets['''validation'''] , shuffle=SCREAMING_SNAKE_CASE , collate_fn=SCREAMING_SNAKE_CASE , batch_size=SCREAMING_SNAKE_CASE )
return train_dataloader, eval_dataloader
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :List[Any] = Accelerator()
# Sample hyper-parameters for learning rate, batch size, seed and a few other HPs
__UpperCamelCase :int = config['''lr''']
__UpperCamelCase :str = int(config['''num_epochs'''] )
__UpperCamelCase :Any = int(config['''seed'''] )
__UpperCamelCase :Dict = int(config['''batch_size'''] )
__UpperCamelCase :Optional[Any] = args.model_name_or_path
set_seed(SCREAMING_SNAKE_CASE )
__UpperCamelCase , __UpperCamelCase :Dict = get_dataloaders(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
# Instantiate the model (we build the model here so that the seed also control new weights initialization)
__UpperCamelCase :Any = AutoModelForSequenceClassification.from_pretrained(SCREAMING_SNAKE_CASE , return_dict=SCREAMING_SNAKE_CASE )
# Instantiate optimizer
__UpperCamelCase :List[str] = (
AdamW
if accelerator.state.deepspeed_plugin is None
or '''optimizer''' not in accelerator.state.deepspeed_plugin.deepspeed_config
else DummyOptim
)
__UpperCamelCase :Optional[Any] = optimizer_cls(params=model.parameters() , lr=SCREAMING_SNAKE_CASE )
if accelerator.state.deepspeed_plugin is not None:
__UpperCamelCase :Dict = accelerator.state.deepspeed_plugin.deepspeed_config[
'''gradient_accumulation_steps'''
]
else:
__UpperCamelCase :Dict = 1
__UpperCamelCase :Tuple = (len(SCREAMING_SNAKE_CASE ) * num_epochs) // gradient_accumulation_steps
# Instantiate scheduler
if (
accelerator.state.deepspeed_plugin is None
or "scheduler" not in accelerator.state.deepspeed_plugin.deepspeed_config
):
__UpperCamelCase :str = get_linear_schedule_with_warmup(
optimizer=SCREAMING_SNAKE_CASE , num_warmup_steps=0 , num_training_steps=SCREAMING_SNAKE_CASE , )
else:
__UpperCamelCase :Dict = DummyScheduler(SCREAMING_SNAKE_CASE , total_num_steps=SCREAMING_SNAKE_CASE , warmup_num_steps=0 )
# Prepare everything
# There is no specific order to remember, we just need to unpack the objects in the same order we gave them to the
# prepare method.
__UpperCamelCase , __UpperCamelCase , __UpperCamelCase , __UpperCamelCase , __UpperCamelCase :int = accelerator.prepare(
SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
# We need to keep track of how many total steps we have iterated over
__UpperCamelCase :List[Any] = 0
# We also need to keep track of the stating epoch so files are named properly
__UpperCamelCase :Dict = 0
# Now we train the model
__UpperCamelCase :Any = evaluate.load('''glue''' , '''mrpc''' )
__UpperCamelCase :Union[str, Any] = 0
__UpperCamelCase :Optional[int] = {}
for epoch in range(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
model.train()
for step, batch in enumerate(SCREAMING_SNAKE_CASE ):
__UpperCamelCase :Optional[Any] = model(**SCREAMING_SNAKE_CASE )
__UpperCamelCase :Tuple = outputs.loss
__UpperCamelCase :str = loss / gradient_accumulation_steps
accelerator.backward(SCREAMING_SNAKE_CASE )
if step % gradient_accumulation_steps == 0:
optimizer.step()
lr_scheduler.step()
optimizer.zero_grad()
overall_step += 1
model.eval()
__UpperCamelCase :Any = 0
for step, batch in enumerate(SCREAMING_SNAKE_CASE ):
# We could avoid this line since we set the accelerator with `device_placement=True`.
batch.to(accelerator.device )
with torch.no_grad():
__UpperCamelCase :Any = model(**SCREAMING_SNAKE_CASE )
__UpperCamelCase :Optional[int] = outputs.logits.argmax(dim=-1 )
# It is slightly faster to call this once, than multiple times
__UpperCamelCase , __UpperCamelCase :List[Any] = accelerator.gather(
(predictions, batch['''labels''']) ) # If we are in a multiprocess environment, the last batch has duplicates
if accelerator.use_distributed:
if step == len(SCREAMING_SNAKE_CASE ) - 1:
__UpperCamelCase :List[str] = predictions[: len(eval_dataloader.dataset ) - samples_seen]
__UpperCamelCase :Optional[int] = references[: len(eval_dataloader.dataset ) - samples_seen]
else:
samples_seen += references.shape[0]
metric.add_batch(
predictions=SCREAMING_SNAKE_CASE , references=SCREAMING_SNAKE_CASE , )
__UpperCamelCase :Dict = metric.compute()
# Use accelerator.print to print only on the main process.
accelerator.print(f"""epoch {epoch}:""" , SCREAMING_SNAKE_CASE )
__UpperCamelCase :str = eval_metric['''accuracy''']
if best_performance < eval_metric["accuracy"]:
__UpperCamelCase :int = eval_metric['''accuracy''']
if args.performance_lower_bound is not None:
assert (
args.performance_lower_bound <= best_performance
), f"""Best performance metric {best_performance} is lower than the lower bound {args.performance_lower_bound}"""
accelerator.wait_for_everyone()
if accelerator.is_main_process:
with open(os.path.join(args.output_dir , '''all_results.json''' ) , '''w''' ) as f:
json.dump(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
def lowerCamelCase ( ):
'''simple docstring'''
__UpperCamelCase :Tuple = argparse.ArgumentParser(description='''Simple example of training script tracking peak GPU memory usage.''' )
parser.add_argument(
'''--model_name_or_path''' , type=SCREAMING_SNAKE_CASE , default='''bert-base-cased''' , help='''Path to pretrained model or model identifier from huggingface.co/models.''' , required=SCREAMING_SNAKE_CASE , )
parser.add_argument(
'''--output_dir''' , type=SCREAMING_SNAKE_CASE , default='''.''' , help='''Optional save directory where all checkpoint folders will be stored. Default is the current working directory.''' , )
parser.add_argument(
'''--performance_lower_bound''' , type=SCREAMING_SNAKE_CASE , default=SCREAMING_SNAKE_CASE , help='''Optional lower bound for the performance metric. If set, the training will throw error when the performance metric drops below this value.''' , )
parser.add_argument(
'''--num_epochs''' , type=SCREAMING_SNAKE_CASE , default=3 , help='''Number of train epochs.''' , )
__UpperCamelCase :List[str] = parser.parse_args()
__UpperCamelCase :Tuple = {'''lr''': 2e-5, '''num_epochs''': args.num_epochs, '''seed''': 42, '''batch_size''': 16}
training_function(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
if __name__ == "__main__":
main()
| 43
| 0
|
"""simple docstring"""
from typing import TYPE_CHECKING
from ...utils import OptionalDependencyNotAvailable, _LazyModule, is_torch_available
lowerCAmelCase_ = {
'configuration_xlm_roberta_xl': [
'XLM_ROBERTA_XL_PRETRAINED_CONFIG_ARCHIVE_MAP',
'XLMRobertaXLConfig',
'XLMRobertaXLOnnxConfig',
],
}
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
lowerCAmelCase_ = [
'XLM_ROBERTA_XL_PRETRAINED_MODEL_ARCHIVE_LIST',
'XLMRobertaXLForCausalLM',
'XLMRobertaXLForMaskedLM',
'XLMRobertaXLForMultipleChoice',
'XLMRobertaXLForQuestionAnswering',
'XLMRobertaXLForSequenceClassification',
'XLMRobertaXLForTokenClassification',
'XLMRobertaXLModel',
'XLMRobertaXLPreTrainedModel',
]
if TYPE_CHECKING:
from .configuration_xlm_roberta_xl import (
XLM_ROBERTA_XL_PRETRAINED_CONFIG_ARCHIVE_MAP,
XLMRobertaXLConfig,
XLMRobertaXLOnnxConfig,
)
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_xlm_roberta_xl import (
XLM_ROBERTA_XL_PRETRAINED_MODEL_ARCHIVE_LIST,
XLMRobertaXLForCausalLM,
XLMRobertaXLForMaskedLM,
XLMRobertaXLForMultipleChoice,
XLMRobertaXLForQuestionAnswering,
XLMRobertaXLForSequenceClassification,
XLMRobertaXLForTokenClassification,
XLMRobertaXLModel,
XLMRobertaXLPreTrainedModel,
)
else:
import sys
lowerCAmelCase_ = _LazyModule(__name__, globals()['__file__'], _import_structure)
| 16
|
import copy
from ...configuration_utils import PretrainedConfig
from ...utils import logging
from ..auto import CONFIG_MAPPING
__lowercase = logging.get_logger(__name__)
__lowercase = {
'''SenseTime/deformable-detr''': '''https://huggingface.co/sensetime/deformable-detr/resolve/main/config.json''',
# See all Deformable DETR models at https://huggingface.co/models?filter=deformable-detr
}
class lowerCamelCase_ ( UpperCAmelCase_ ):
'''simple docstring'''
a__ : List[str] = """deformable_detr"""
a__ : Union[str, Any] = {
"""hidden_size""": """d_model""",
"""num_attention_heads""": """encoder_attention_heads""",
}
def __init__( self , __lowercase=True , __lowercase=None , __lowercase=3 , __lowercase=300 , __lowercase=1_024 , __lowercase=6 , __lowercase=1_024 , __lowercase=8 , __lowercase=6 , __lowercase=1_024 , __lowercase=8 , __lowercase=0.0 , __lowercase=True , __lowercase="relu" , __lowercase=256 , __lowercase=0.1 , __lowercase=0.0 , __lowercase=0.0 , __lowercase=0.02 , __lowercase=1.0 , __lowercase=True , __lowercase=False , __lowercase="sine" , __lowercase="resnet50" , __lowercase=True , __lowercase=False , __lowercase=4 , __lowercase=4 , __lowercase=4 , __lowercase=False , __lowercase=300 , __lowercase=False , __lowercase=1 , __lowercase=5 , __lowercase=2 , __lowercase=1 , __lowercase=1 , __lowercase=5 , __lowercase=2 , __lowercase=0.1 , __lowercase=0.25 , __lowercase=False , **__lowercase , ) -> int:
if backbone_config is not None and use_timm_backbone:
raise ValueError('''You can\'t specify both `backbone_config` and `use_timm_backbone`.''')
if not use_timm_backbone:
if backbone_config is None:
logger.info('''`backbone_config` is `None`. Initializing the config with the default `ResNet` backbone.''')
__UpperCamelCase :str = CONFIG_MAPPING['''resnet'''](out_features=['''stage4'''])
elif isinstance(__lowercase , __lowercase):
__UpperCamelCase :str = backbone_config.get('''model_type''')
__UpperCamelCase :Tuple = CONFIG_MAPPING[backbone_model_type]
__UpperCamelCase :Any = config_class.from_dict(__lowercase)
__UpperCamelCase :int = use_timm_backbone
__UpperCamelCase :Dict = backbone_config
__UpperCamelCase :Any = num_channels
__UpperCamelCase :Optional[int] = num_queries
__UpperCamelCase :Any = max_position_embeddings
__UpperCamelCase :str = d_model
__UpperCamelCase :Tuple = encoder_ffn_dim
__UpperCamelCase :Union[str, Any] = encoder_layers
__UpperCamelCase :List[Any] = encoder_attention_heads
__UpperCamelCase :Any = decoder_ffn_dim
__UpperCamelCase :List[str] = decoder_layers
__UpperCamelCase :int = decoder_attention_heads
__UpperCamelCase :str = dropout
__UpperCamelCase :Any = attention_dropout
__UpperCamelCase :int = activation_dropout
__UpperCamelCase :List[Any] = activation_function
__UpperCamelCase :List[Any] = init_std
__UpperCamelCase :List[Any] = init_xavier_std
__UpperCamelCase :int = encoder_layerdrop
__UpperCamelCase :str = auxiliary_loss
__UpperCamelCase :Optional[Any] = position_embedding_type
__UpperCamelCase :Union[str, Any] = backbone
__UpperCamelCase :Any = use_pretrained_backbone
__UpperCamelCase :str = dilation
# deformable attributes
__UpperCamelCase :Optional[Any] = num_feature_levels
__UpperCamelCase :str = encoder_n_points
__UpperCamelCase :int = decoder_n_points
__UpperCamelCase :Union[str, Any] = two_stage
__UpperCamelCase :Optional[Any] = two_stage_num_proposals
__UpperCamelCase :Dict = with_box_refine
if two_stage is True and with_box_refine is False:
raise ValueError('''If two_stage is True, with_box_refine must be True.''')
# Hungarian matcher
__UpperCamelCase :Optional[int] = class_cost
__UpperCamelCase :List[Any] = bbox_cost
__UpperCamelCase :str = giou_cost
# Loss coefficients
__UpperCamelCase :Tuple = mask_loss_coefficient
__UpperCamelCase :Tuple = dice_loss_coefficient
__UpperCamelCase :int = bbox_loss_coefficient
__UpperCamelCase :Any = giou_loss_coefficient
__UpperCamelCase :Dict = eos_coefficient
__UpperCamelCase :Optional[Any] = focal_alpha
__UpperCamelCase :Optional[Any] = disable_custom_kernels
super().__init__(is_encoder_decoder=__lowercase , **__lowercase)
@property
def UpperCamelCase__ ( self) -> int:
return self.encoder_attention_heads
@property
def UpperCamelCase__ ( self) -> int:
return self.d_model
def UpperCamelCase__ ( self) -> List[Any]:
__UpperCamelCase :Dict = copy.deepcopy(self.__dict__)
if self.backbone_config is not None:
__UpperCamelCase :Tuple = self.backbone_config.to_dict()
__UpperCamelCase :List[Any] = self.__class__.model_type
return output
| 43
| 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 _lowerCAmelCase ( lowercase ):
"""simple docstring"""
__UpperCAmelCase : Dict = ["image_processor", "tokenizer"]
__UpperCAmelCase : List[Any] = "ViltImageProcessor"
__UpperCAmelCase : Optional[int] = ("BertTokenizer", "BertTokenizerFast")
def __init__( self : Any, UpperCAmelCase__ : List[Any]=None, UpperCAmelCase__ : Optional[int]=None, **UpperCAmelCase__ : str ):
__lowercase = None
if "feature_extractor" in kwargs:
warnings.warn(
"The `feature_extractor` argument is deprecated and will be removed in v5, use `image_processor`"
" instead.", UpperCAmelCase__, )
__lowercase = kwargs.pop("feature_extractor" )
__lowercase = 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__(UpperCAmelCase__, UpperCAmelCase__ )
__lowercase = self.image_processor
def __call__( self : Optional[Any], UpperCAmelCase__ : Union[str, Any], UpperCAmelCase__ : Union[TextInput, PreTokenizedInput, List[TextInput], List[PreTokenizedInput]] = None, UpperCAmelCase__ : bool = True, UpperCAmelCase__ : Union[bool, str, PaddingStrategy] = False, UpperCAmelCase__ : Union[bool, str, TruncationStrategy] = None, UpperCAmelCase__ : Optional[int] = None, UpperCAmelCase__ : int = 0, UpperCAmelCase__ : Optional[int] = None, UpperCAmelCase__ : Optional[bool] = None, UpperCAmelCase__ : Optional[bool] = None, UpperCAmelCase__ : bool = False, UpperCAmelCase__ : bool = False, UpperCAmelCase__ : bool = False, UpperCAmelCase__ : bool = False, UpperCAmelCase__ : bool = True, UpperCAmelCase__ : Optional[Union[str, TensorType]] = None, **UpperCAmelCase__ : Tuple, ):
__lowercase = self.tokenizer(
text=UpperCAmelCase__, add_special_tokens=UpperCAmelCase__, padding=UpperCAmelCase__, truncation=UpperCAmelCase__, max_length=UpperCAmelCase__, stride=UpperCAmelCase__, pad_to_multiple_of=UpperCAmelCase__, return_token_type_ids=UpperCAmelCase__, return_attention_mask=UpperCAmelCase__, return_overflowing_tokens=UpperCAmelCase__, return_special_tokens_mask=UpperCAmelCase__, return_offsets_mapping=UpperCAmelCase__, return_length=UpperCAmelCase__, verbose=UpperCAmelCase__, return_tensors=UpperCAmelCase__, **UpperCAmelCase__, )
# add pixel_values + pixel_mask
__lowercase = self.image_processor(UpperCAmelCase__, return_tensors=UpperCAmelCase__ )
encoding.update(UpperCAmelCase__ )
return encoding
def _lowercase ( self : List[str], *UpperCAmelCase__ : int, **UpperCAmelCase__ : Any ):
return self.tokenizer.batch_decode(*UpperCAmelCase__, **UpperCAmelCase__ )
def _lowercase ( self : Optional[Any], *UpperCAmelCase__ : Optional[int], **UpperCAmelCase__ : List[Any] ):
return self.tokenizer.decode(*UpperCAmelCase__, **UpperCAmelCase__ )
@property
def _lowercase ( self : List[str] ):
__lowercase = self.tokenizer.model_input_names
__lowercase = self.image_processor.model_input_names
return list(dict.fromkeys(tokenizer_input_names + image_processor_input_names ) )
@property
def _lowercase ( self : Optional[Any] ):
warnings.warn(
"`feature_extractor_class` is deprecated and will be removed in v5. Use `image_processor_class` instead.", UpperCAmelCase__, )
return self.image_processor_class
@property
def _lowercase ( self : Dict ):
warnings.warn(
"`feature_extractor` is deprecated and will be removed in v5. Use `image_processor` instead.", UpperCAmelCase__, )
return self.image_processor
| 17
|
# Copyright 2023 The HuggingFace Inc. team. All rights reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
import torch
from ..models.auto import AutoModelForSequenceClassification, AutoTokenizer
from .base import PipelineTool
class lowerCamelCase_ ( UpperCAmelCase_ ):
'''simple docstring'''
a__ : Optional[Any] = """facebook/bart-large-mnli"""
a__ : int = (
"""This is a tool that classifies an English text using provided labels. It takes two inputs: `text`, which """
"""should be the text to classify, and `labels`, which should be the list of labels to use for classification. """
"""It returns the most likely label in the list of provided `labels` for the input text."""
)
a__ : Optional[Any] = """text_classifier"""
a__ : Any = AutoTokenizer
a__ : str = AutoModelForSequenceClassification
a__ : str = ["""text""", ["""text"""]]
a__ : Optional[int] = ["""text"""]
def UpperCamelCase__ ( self) -> Union[str, Any]:
super().setup()
__UpperCamelCase :int = self.model.config
__UpperCamelCase :Optional[Any] = -1
for idx, label in config.idalabel.items():
if label.lower().startswith('''entail'''):
__UpperCamelCase :List[Any] = int(__lowercase)
if self.entailment_id == -1:
raise ValueError('''Could not determine the entailment ID from the model config, please pass it at init.''')
def UpperCamelCase__ ( self , __lowercase , __lowercase) -> Union[str, Any]:
__UpperCamelCase :Any = labels
return self.pre_processor(
[text] * len(__lowercase) , [f"""This example is {label}""" for label in labels] , return_tensors='''pt''' , padding='''max_length''' , )
def UpperCamelCase__ ( self , __lowercase) -> Optional[Any]:
__UpperCamelCase :List[Any] = outputs.logits
__UpperCamelCase :Any = torch.argmax(logits[:, 2]).item()
return self._labels[label_id]
| 43
| 0
|
import argparse
from pathlib import Path
from transformers import AutoConfig, AutoTokenizer, RagConfig, RagSequenceForGeneration, RagTokenForGeneration
def _snake_case ( lowerCAmelCase : int , lowerCAmelCase : str , lowerCAmelCase : str , lowerCAmelCase : Path , lowerCAmelCase : str = None , lowerCAmelCase : str = None , lowerCAmelCase : str = None , ):
"""simple docstring"""
if config_name_or_path is None:
SCREAMING_SNAKE_CASE_ : Union[str, Any] = "facebook/rag-token-base" if model_type == "rag_token" else "facebook/rag-sequence-base"
if generator_tokenizer_name_or_path is None:
SCREAMING_SNAKE_CASE_ : Dict = generator_name_or_path
if question_encoder_tokenizer_name_or_path is None:
SCREAMING_SNAKE_CASE_ : Union[str, Any] = question_encoder_name_or_path
SCREAMING_SNAKE_CASE_ : Union[str, Any] = RagTokenForGeneration if model_type == "rag_token" else RagSequenceForGeneration
# Save model.
SCREAMING_SNAKE_CASE_ : List[Any] = RagConfig.from_pretrained(lowerCAmelCase )
SCREAMING_SNAKE_CASE_ : Tuple = AutoConfig.from_pretrained(lowerCAmelCase )
SCREAMING_SNAKE_CASE_ : int = AutoConfig.from_pretrained(lowerCAmelCase )
SCREAMING_SNAKE_CASE_ : Union[str, Any] = gen_config
SCREAMING_SNAKE_CASE_ : Optional[Any] = question_encoder_config
SCREAMING_SNAKE_CASE_ : Dict = model_class.from_pretrained_question_encoder_generator(
lowerCAmelCase , lowerCAmelCase , config=lowerCAmelCase )
rag_model.save_pretrained(lowerCAmelCase )
# Sanity check.
model_class.from_pretrained(lowerCAmelCase )
# Save tokenizers.
SCREAMING_SNAKE_CASE_ : Optional[Any] = AutoTokenizer.from_pretrained(lowerCAmelCase )
gen_tokenizer.save_pretrained(dest_dir / "generator_tokenizer/" )
SCREAMING_SNAKE_CASE_ : Union[str, Any] = AutoTokenizer.from_pretrained(lowerCAmelCase )
question_encoder_tokenizer.save_pretrained(dest_dir / "question_encoder_tokenizer/" )
if __name__ == "__main__":
__lowerCamelCase : List[Any] = argparse.ArgumentParser()
parser.add_argument(
'''--model_type''',
choices=['''rag_sequence''', '''rag_token'''],
required=True,
type=str,
help='''RAG model type: rag_sequence, rag_token''',
)
parser.add_argument('''--dest''', type=str, required=True, help='''Path to the output checkpoint directory.''')
parser.add_argument('''--generator_name_or_path''', type=str, required=True, help='''Generator model identifier''')
parser.add_argument(
'''--question_encoder_name_or_path''', type=str, required=True, help='''Question encoder model identifier'''
)
parser.add_argument(
'''--generator_tokenizer_name_or_path''',
type=str,
help='''Generator tokenizer identifier, if not specified, resolves to ``generator_name_or_path``''',
)
parser.add_argument(
'''--question_encoder_tokenizer_name_or_path''',
type=str,
help='''Question encoder tokenizer identifier, if not specified, resolves to ``question_encoder_name_or_path``''',
)
parser.add_argument(
'''--config_name_or_path''',
type=str,
help=(
'''Identifier of the model config to use, if not provided, resolves to a base config for a given'''
''' ``model_type``'''
),
)
__lowerCamelCase : str = parser.parse_args()
__lowerCamelCase : int = Path(args.dest)
dest_dir.mkdir(exist_ok=True)
consolidate(
args.model_type,
args.generator_name_or_path,
args.question_encoder_name_or_path,
dest_dir,
args.config_name_or_path,
args.generator_tokenizer_name_or_path,
args.question_encoder_tokenizer_name_or_path,
)
| 18
|
import gc
import random
import unittest
import numpy as np
import torch
from transformers import (
CLIPImageProcessor,
CLIPTextConfig,
CLIPTextModel,
CLIPTokenizer,
CLIPVisionConfig,
CLIPVisionModelWithProjection,
)
from diffusers import AutoencoderKL, DDIMScheduler, DDPMScheduler, StableUnCLIPImgaImgPipeline, UNetaDConditionModel
from diffusers.pipelines.pipeline_utils import DiffusionPipeline
from diffusers.pipelines.stable_diffusion.stable_unclip_image_normalizer import StableUnCLIPImageNormalizer
from diffusers.utils.import_utils import is_xformers_available
from diffusers.utils.testing_utils import (
enable_full_determinism,
floats_tensor,
load_image,
load_numpy,
require_torch_gpu,
skip_mps,
slow,
torch_device,
)
from ..pipeline_params import TEXT_GUIDED_IMAGE_VARIATION_BATCH_PARAMS, TEXT_GUIDED_IMAGE_VARIATION_PARAMS
from ..test_pipelines_common import (
PipelineKarrasSchedulerTesterMixin,
PipelineLatentTesterMixin,
PipelineTesterMixin,
assert_mean_pixel_difference,
)
enable_full_determinism()
class lowerCamelCase_ ( UpperCAmelCase_ , UpperCAmelCase_ , UpperCAmelCase_ , unittest.TestCase ):
'''simple docstring'''
a__ : int = StableUnCLIPImgaImgPipeline
a__ : Optional[int] = TEXT_GUIDED_IMAGE_VARIATION_PARAMS
a__ : Union[str, Any] = TEXT_GUIDED_IMAGE_VARIATION_BATCH_PARAMS
a__ : Optional[Any] = frozenset(
[] ) # TO-DO: update image_params once pipeline is refactored with VaeImageProcessor.preprocess
a__ : int = frozenset([] )
def UpperCamelCase__ ( self) -> Tuple:
__UpperCamelCase :Tuple = 32
__UpperCamelCase :Optional[int] = embedder_hidden_size
# image encoding components
__UpperCamelCase :Union[str, Any] = CLIPImageProcessor(crop_size=32 , size=32)
torch.manual_seed(0)
__UpperCamelCase :Union[str, Any] = CLIPVisionModelWithProjection(
CLIPVisionConfig(
hidden_size=__lowercase , projection_dim=__lowercase , num_hidden_layers=5 , num_attention_heads=4 , image_size=32 , intermediate_size=37 , patch_size=1 , ))
# regular denoising components
torch.manual_seed(0)
__UpperCamelCase :str = StableUnCLIPImageNormalizer(embedding_dim=__lowercase)
__UpperCamelCase :Optional[int] = DDPMScheduler(beta_schedule='''squaredcos_cap_v2''')
torch.manual_seed(0)
__UpperCamelCase :Union[str, Any] = CLIPTokenizer.from_pretrained('''hf-internal-testing/tiny-random-clip''')
torch.manual_seed(0)
__UpperCamelCase :Dict = CLIPTextModel(
CLIPTextConfig(
bos_token_id=0 , eos_token_id=2 , hidden_size=__lowercase , projection_dim=32 , intermediate_size=37 , layer_norm_eps=1E-0_5 , num_attention_heads=4 , num_hidden_layers=5 , pad_token_id=1 , vocab_size=1_000 , ))
torch.manual_seed(0)
__UpperCamelCase :List[Any] = UNetaDConditionModel(
sample_size=32 , in_channels=4 , out_channels=4 , down_block_types=('''CrossAttnDownBlock2D''', '''DownBlock2D''') , up_block_types=('''UpBlock2D''', '''CrossAttnUpBlock2D''') , block_out_channels=(32, 64) , attention_head_dim=(2, 4) , class_embed_type='''projection''' , projection_class_embeddings_input_dim=embedder_projection_dim * 2 , cross_attention_dim=__lowercase , layers_per_block=1 , upcast_attention=__lowercase , use_linear_projection=__lowercase , )
torch.manual_seed(0)
__UpperCamelCase :Tuple = DDIMScheduler(
beta_schedule='''scaled_linear''' , beta_start=0.0_00_85 , beta_end=0.0_12 , prediction_type='''v_prediction''' , set_alpha_to_one=__lowercase , steps_offset=1 , )
torch.manual_seed(0)
__UpperCamelCase :List[str] = AutoencoderKL()
__UpperCamelCase :Tuple = {
# image encoding components
'''feature_extractor''': feature_extractor,
'''image_encoder''': image_encoder.eval(),
# image noising components
'''image_normalizer''': image_normalizer.eval(),
'''image_noising_scheduler''': image_noising_scheduler,
# regular denoising components
'''tokenizer''': tokenizer,
'''text_encoder''': text_encoder.eval(),
'''unet''': unet.eval(),
'''scheduler''': scheduler,
'''vae''': vae.eval(),
}
return components
def UpperCamelCase__ ( self , __lowercase , __lowercase=0 , __lowercase=True) -> str:
if str(__lowercase).startswith('''mps'''):
__UpperCamelCase :Union[str, Any] = torch.manual_seed(__lowercase)
else:
__UpperCamelCase :int = torch.Generator(device=__lowercase).manual_seed(__lowercase)
__UpperCamelCase :int = floats_tensor((1, 3, 32, 32) , rng=random.Random(__lowercase)).to(__lowercase)
if pil_image:
__UpperCamelCase :List[Any] = input_image * 0.5 + 0.5
__UpperCamelCase :Optional[Any] = input_image.clamp(0 , 1)
__UpperCamelCase :int = input_image.cpu().permute(0 , 2 , 3 , 1).float().numpy()
__UpperCamelCase :Optional[Any] = DiffusionPipeline.numpy_to_pil(__lowercase)[0]
return {
"prompt": "An anime racoon running a marathon",
"image": input_image,
"generator": generator,
"num_inference_steps": 2,
"output_type": "np",
}
@skip_mps
def UpperCamelCase__ ( self) -> Union[str, Any]:
__UpperCamelCase :Dict = '''cpu''' # ensure determinism for the device-dependent torch.Generator
__UpperCamelCase :Tuple = self.get_dummy_components()
__UpperCamelCase :Any = StableUnCLIPImgaImgPipeline(**__lowercase)
__UpperCamelCase :Optional[Any] = sd_pipe.to(__lowercase)
sd_pipe.set_progress_bar_config(disable=__lowercase)
__UpperCamelCase :List[Any] = self.get_dummy_inputs(__lowercase)
inputs.update({'''image_embeds''': None})
__UpperCamelCase :Any = sd_pipe(**__lowercase).images
__UpperCamelCase :List[str] = image[0, -3:, -3:, -1]
assert image.shape == (1, 32, 32, 3)
__UpperCamelCase :List[Any] = np.array([0.38_72, 0.72_24, 0.56_01, 0.47_41, 0.68_72, 0.58_14, 0.46_36, 0.38_67, 0.50_78])
assert np.abs(image_slice.flatten() - expected_slice).max() < 1E-3
def UpperCamelCase__ ( self) -> str:
__UpperCamelCase :Optional[Any] = torch_device in ['''cpu''', '''mps''']
self._test_attention_slicing_forward_pass(test_max_difference=__lowercase)
def UpperCamelCase__ ( self) -> List[Any]:
__UpperCamelCase :Optional[Any] = torch_device in ['''cpu''', '''mps''']
self._test_inference_batch_single_identical(test_max_difference=__lowercase)
@unittest.skipIf(
torch_device != '''cuda''' or not is_xformers_available() , reason='''XFormers attention is only available with CUDA and `xformers` installed''' , )
def UpperCamelCase__ ( self) -> Union[str, Any]:
self._test_xformers_attention_forwardGenerator_pass(test_max_difference=__lowercase)
@slow
@require_torch_gpu
class lowerCamelCase_ ( unittest.TestCase ):
'''simple docstring'''
def UpperCamelCase__ ( self) -> Union[str, Any]:
# clean up the VRAM after each test
super().tearDown()
gc.collect()
torch.cuda.empty_cache()
def UpperCamelCase__ ( self) -> Union[str, Any]:
__UpperCamelCase :int = load_image(
'''https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main/stable_unclip/turtle.png''')
__UpperCamelCase :Any = load_numpy(
'''https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main/stable_unclip/stable_unclip_2_1_l_img2img_anime_turtle_fp16.npy''')
__UpperCamelCase :List[Any] = StableUnCLIPImgaImgPipeline.from_pretrained(
'''fusing/stable-unclip-2-1-l-img2img''' , torch_dtype=torch.floataa)
pipe.to(__lowercase)
pipe.set_progress_bar_config(disable=__lowercase)
# stable unclip will oom when integration tests are run on a V100,
# so turn on memory savings
pipe.enable_attention_slicing()
pipe.enable_sequential_cpu_offload()
__UpperCamelCase :int = torch.Generator(device='''cpu''').manual_seed(0)
__UpperCamelCase :Dict = pipe(__lowercase , '''anime turle''' , generator=__lowercase , output_type='''np''')
__UpperCamelCase :Dict = output.images[0]
assert image.shape == (768, 768, 3)
assert_mean_pixel_difference(__lowercase , __lowercase)
def UpperCamelCase__ ( self) -> List[str]:
__UpperCamelCase :Optional[Any] = load_image(
'''https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main/stable_unclip/turtle.png''')
__UpperCamelCase :Any = load_numpy(
'''https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main/stable_unclip/stable_unclip_2_1_h_img2img_anime_turtle_fp16.npy''')
__UpperCamelCase :Any = StableUnCLIPImgaImgPipeline.from_pretrained(
'''fusing/stable-unclip-2-1-h-img2img''' , torch_dtype=torch.floataa)
pipe.to(__lowercase)
pipe.set_progress_bar_config(disable=__lowercase)
# stable unclip will oom when integration tests are run on a V100,
# so turn on memory savings
pipe.enable_attention_slicing()
pipe.enable_sequential_cpu_offload()
__UpperCamelCase :int = torch.Generator(device='''cpu''').manual_seed(0)
__UpperCamelCase :Optional[int] = pipe(__lowercase , '''anime turle''' , generator=__lowercase , output_type='''np''')
__UpperCamelCase :List[Any] = output.images[0]
assert image.shape == (768, 768, 3)
assert_mean_pixel_difference(__lowercase , __lowercase)
def UpperCamelCase__ ( self) -> List[str]:
__UpperCamelCase :Dict = load_image(
'''https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main/stable_unclip/turtle.png''')
torch.cuda.empty_cache()
torch.cuda.reset_max_memory_allocated()
torch.cuda.reset_peak_memory_stats()
__UpperCamelCase :List[Any] = StableUnCLIPImgaImgPipeline.from_pretrained(
'''fusing/stable-unclip-2-1-h-img2img''' , torch_dtype=torch.floataa)
__UpperCamelCase :Union[str, Any] = pipe.to(__lowercase)
pipe.set_progress_bar_config(disable=__lowercase)
pipe.enable_attention_slicing()
pipe.enable_sequential_cpu_offload()
__UpperCamelCase :Optional[Any] = pipe(
__lowercase , '''anime turtle''' , num_inference_steps=2 , output_type='''np''' , )
__UpperCamelCase :int = torch.cuda.max_memory_allocated()
# make sure that less than 7 GB is allocated
assert mem_bytes < 7 * 10**9
| 43
| 0
|
from typing import TYPE_CHECKING
from ...utils import (
OptionalDependencyNotAvailable,
_LazyModule,
is_tf_available,
is_tokenizers_available,
is_torch_available,
)
__A ={
'''configuration_mobilebert''': [
'''MOBILEBERT_PRETRAINED_CONFIG_ARCHIVE_MAP''',
'''MobileBertConfig''',
'''MobileBertOnnxConfig''',
],
'''tokenization_mobilebert''': ['''MobileBertTokenizer'''],
}
try:
if not is_tokenizers_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__A =['''MobileBertTokenizerFast''']
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__A =[
'''MOBILEBERT_PRETRAINED_MODEL_ARCHIVE_LIST''',
'''MobileBertForMaskedLM''',
'''MobileBertForMultipleChoice''',
'''MobileBertForNextSentencePrediction''',
'''MobileBertForPreTraining''',
'''MobileBertForQuestionAnswering''',
'''MobileBertForSequenceClassification''',
'''MobileBertForTokenClassification''',
'''MobileBertLayer''',
'''MobileBertModel''',
'''MobileBertPreTrainedModel''',
'''load_tf_weights_in_mobilebert''',
]
try:
if not is_tf_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__A =[
'''TF_MOBILEBERT_PRETRAINED_MODEL_ARCHIVE_LIST''',
'''TFMobileBertForMaskedLM''',
'''TFMobileBertForMultipleChoice''',
'''TFMobileBertForNextSentencePrediction''',
'''TFMobileBertForPreTraining''',
'''TFMobileBertForQuestionAnswering''',
'''TFMobileBertForSequenceClassification''',
'''TFMobileBertForTokenClassification''',
'''TFMobileBertMainLayer''',
'''TFMobileBertModel''',
'''TFMobileBertPreTrainedModel''',
]
if TYPE_CHECKING:
from .configuration_mobilebert import (
MOBILEBERT_PRETRAINED_CONFIG_ARCHIVE_MAP,
MobileBertConfig,
MobileBertOnnxConfig,
)
from .tokenization_mobilebert import MobileBertTokenizer
try:
if not is_tokenizers_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .tokenization_mobilebert_fast import MobileBertTokenizerFast
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_mobilebert import (
MOBILEBERT_PRETRAINED_MODEL_ARCHIVE_LIST,
MobileBertForMaskedLM,
MobileBertForMultipleChoice,
MobileBertForNextSentencePrediction,
MobileBertForPreTraining,
MobileBertForQuestionAnswering,
MobileBertForSequenceClassification,
MobileBertForTokenClassification,
MobileBertLayer,
MobileBertModel,
MobileBertPreTrainedModel,
load_tf_weights_in_mobilebert,
)
try:
if not is_tf_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_tf_mobilebert import (
TF_MOBILEBERT_PRETRAINED_MODEL_ARCHIVE_LIST,
TFMobileBertForMaskedLM,
TFMobileBertForMultipleChoice,
TFMobileBertForNextSentencePrediction,
TFMobileBertForPreTraining,
TFMobileBertForQuestionAnswering,
TFMobileBertForSequenceClassification,
TFMobileBertForTokenClassification,
TFMobileBertMainLayer,
TFMobileBertModel,
TFMobileBertPreTrainedModel,
)
else:
import sys
__A =_LazyModule(__name__, globals()['''__file__'''], _import_structure, module_spec=__spec__)
| 19
|
import numpy as np
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE = 1e-12 , SCREAMING_SNAKE_CASE = 100 , ):
'''simple docstring'''
assert np.shape(SCREAMING_SNAKE_CASE )[0] == np.shape(SCREAMING_SNAKE_CASE )[1]
# Ensure proper dimensionality.
assert np.shape(SCREAMING_SNAKE_CASE )[0] == np.shape(SCREAMING_SNAKE_CASE )[0]
# Ensure inputs are either both complex or both real
assert np.iscomplexobj(SCREAMING_SNAKE_CASE ) == np.iscomplexobj(SCREAMING_SNAKE_CASE )
__UpperCamelCase :List[Any] = np.iscomplexobj(SCREAMING_SNAKE_CASE )
if is_complex:
# Ensure complex input_matrix is Hermitian
assert np.array_equal(SCREAMING_SNAKE_CASE , input_matrix.conj().T )
# Set convergence to False. Will define convergence when we exceed max_iterations
# or when we have small changes from one iteration to next.
__UpperCamelCase :str = False
__UpperCamelCase :int = 0
__UpperCamelCase :Optional[Any] = 0
__UpperCamelCase :Union[str, Any] = 1e12
while not convergence:
# Multiple matrix by the vector.
__UpperCamelCase :List[str] = np.dot(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
# Normalize the resulting output vector.
__UpperCamelCase :Tuple = w / np.linalg.norm(SCREAMING_SNAKE_CASE )
# Find rayleigh quotient
# (faster than usual b/c we know vector is normalized already)
__UpperCamelCase :int = vector.conj().T if is_complex else vector.T
__UpperCamelCase :Optional[int] = np.dot(SCREAMING_SNAKE_CASE , np.dot(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ) )
# Check convergence.
__UpperCamelCase :Optional[Any] = np.abs(lambda_ - lambda_previous ) / lambda_
iterations += 1
if error <= error_tol or iterations >= max_iterations:
__UpperCamelCase :Dict = True
__UpperCamelCase :List[Any] = lambda_
if is_complex:
__UpperCamelCase :Tuple = np.real(lambda_ )
return lambda_, vector
def lowerCamelCase ( ):
'''simple docstring'''
__UpperCamelCase :int = np.array([[41, 4, 20], [4, 26, 30], [20, 30, 50]] )
__UpperCamelCase :Optional[Any] = np.array([41, 4, 20] )
__UpperCamelCase :Any = real_input_matrix.astype(np.complexaaa )
__UpperCamelCase :Dict = np.triu(1j * complex_input_matrix , 1 )
complex_input_matrix += imag_matrix
complex_input_matrix += -1 * imag_matrix.T
__UpperCamelCase :Optional[int] = np.array([41, 4, 20] ).astype(np.complexaaa )
for problem_type in ["real", "complex"]:
if problem_type == "real":
__UpperCamelCase :Any = real_input_matrix
__UpperCamelCase :int = real_vector
elif problem_type == "complex":
__UpperCamelCase :Tuple = complex_input_matrix
__UpperCamelCase :Optional[Any] = complex_vector
# Our implementation.
__UpperCamelCase , __UpperCamelCase :Dict = power_iteration(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
# Numpy implementation.
# Get eigenvalues and eigenvectors using built-in numpy
# eigh (eigh used for symmetric or hermetian matrices).
__UpperCamelCase , __UpperCamelCase :List[Any] = np.linalg.eigh(SCREAMING_SNAKE_CASE )
# Last eigenvalue is the maximum one.
__UpperCamelCase :List[Any] = eigen_values[-1]
# Last column in this matrix is eigenvector corresponding to largest eigenvalue.
__UpperCamelCase :str = eigen_vectors[:, -1]
# Check our implementation and numpy gives close answers.
assert np.abs(eigen_value - eigen_value_max ) <= 1e-6
# Take absolute values element wise of each eigenvector.
# as they are only unique to a minus sign.
assert np.linalg.norm(np.abs(SCREAMING_SNAKE_CASE ) - np.abs(SCREAMING_SNAKE_CASE ) ) <= 1e-6
if __name__ == "__main__":
import doctest
doctest.testmod()
test_power_iteration()
| 43
| 0
|
from __future__ import annotations
import numpy as np
def _snake_case( SCREAMING_SNAKE_CASE__ ) -> tuple[np.ndarray, np.ndarray]:
lowercase , lowercase : Optional[int] = np.shape(SCREAMING_SNAKE_CASE__ )
if rows != columns:
lowercase : Dict = (
"""'table' has to be of square shaped array but got a """
f"{rows}x{columns} array:\n{table}"
)
raise ValueError(SCREAMING_SNAKE_CASE__ )
lowercase : Optional[Any] = np.zeros((rows, columns) )
lowercase : int = np.zeros((rows, columns) )
for i in range(SCREAMING_SNAKE_CASE__ ):
for j in range(SCREAMING_SNAKE_CASE__ ):
lowercase : Dict = sum(lower[i][k] * upper[k][j] for k in range(SCREAMING_SNAKE_CASE__ ) )
if upper[j][j] == 0:
raise ArithmeticError("""No LU decomposition exists""" )
lowercase : int = (table[i][j] - total) / upper[j][j]
lowercase : int = 1
for j in range(SCREAMING_SNAKE_CASE__ , SCREAMING_SNAKE_CASE__ ):
lowercase : List[Any] = sum(lower[i][k] * upper[k][j] for k in range(SCREAMING_SNAKE_CASE__ ) )
lowercase : Optional[int] = table[i][j] - total
return lower, upper
if __name__ == "__main__":
import doctest
doctest.testmod()
| 20
|
import json
from typing import TYPE_CHECKING, List, Optional, Tuple
from tokenizers import pre_tokenizers
from ...tokenization_utils_base import BatchEncoding
from ...tokenization_utils_fast import PreTrainedTokenizerFast
from ...utils import logging
if TYPE_CHECKING:
from transformers.pipelines.conversational import Conversation
__lowercase = logging.get_logger(__name__)
__lowercase = {'''tokenizer_file''': '''tokenizer.json'''}
__lowercase = {
'''tokenizer_file''': {
'''bigscience/tokenizer''': '''https://huggingface.co/bigscience/tokenizer/blob/main/tokenizer.json''',
'''bigscience/bloom-560m''': '''https://huggingface.co/bigscience/bloom-560m/blob/main/tokenizer.json''',
'''bigscience/bloom-1b1''': '''https://huggingface.co/bigscience/bloom-1b1/blob/main/tokenizer.json''',
'''bigscience/bloom-1b7''': '''https://huggingface.co/bigscience/bloom-1b7/blob/main/tokenizer.json''',
'''bigscience/bloom-3b''': '''https://huggingface.co/bigscience/bloom-3b/blob/main/tokenizer.json''',
'''bigscience/bloom-7b1''': '''https://huggingface.co/bigscience/bloom-7b1/blob/main/tokenizer.json''',
'''bigscience/bloom''': '''https://huggingface.co/bigscience/bloom/blob/main/tokenizer.json''',
},
}
class lowerCamelCase_ ( UpperCAmelCase_ ):
'''simple docstring'''
a__ : int = VOCAB_FILES_NAMES
a__ : Tuple = PRETRAINED_VOCAB_FILES_MAP
a__ : List[str] = ["""input_ids""", """attention_mask"""]
a__ : int = None
def __init__( self , __lowercase=None , __lowercase=None , __lowercase=None , __lowercase="<unk>" , __lowercase="<s>" , __lowercase="</s>" , __lowercase="<pad>" , __lowercase=False , __lowercase=False , **__lowercase , ) -> List[str]:
super().__init__(
__lowercase , __lowercase , tokenizer_file=__lowercase , unk_token=__lowercase , bos_token=__lowercase , eos_token=__lowercase , pad_token=__lowercase , add_prefix_space=__lowercase , clean_up_tokenization_spaces=__lowercase , **__lowercase , )
__UpperCamelCase :int = json.loads(self.backend_tokenizer.pre_tokenizer.__getstate__())
if pre_tok_state.get('''add_prefix_space''' , __lowercase) != add_prefix_space:
__UpperCamelCase :Any = getattr(__lowercase , pre_tok_state.pop('''type'''))
__UpperCamelCase :str = add_prefix_space
__UpperCamelCase :List[str] = pre_tok_class(**__lowercase)
__UpperCamelCase :Tuple = add_prefix_space
def UpperCamelCase__ ( self , *__lowercase , **__lowercase) -> BatchEncoding:
__UpperCamelCase :Tuple = kwargs.get('''is_split_into_words''' , __lowercase)
if not (self.add_prefix_space or not is_split_into_words):
raise Exception(
f"""You need to instantiate {self.__class__.__name__} with add_prefix_space=True to use it with"""
''' pretokenized inputs.''')
return super()._batch_encode_plus(*__lowercase , **__lowercase)
def UpperCamelCase__ ( self , *__lowercase , **__lowercase) -> BatchEncoding:
__UpperCamelCase :List[str] = kwargs.get('''is_split_into_words''' , __lowercase)
if not (self.add_prefix_space or not is_split_into_words):
raise Exception(
f"""You need to instantiate {self.__class__.__name__} with add_prefix_space=True to use it with"""
''' pretokenized inputs.''')
return super()._encode_plus(*__lowercase , **__lowercase)
def UpperCamelCase__ ( self , __lowercase , __lowercase = None) -> Tuple[str]:
__UpperCamelCase :Optional[Any] = self._tokenizer.model.save(__lowercase , name=__lowercase)
return tuple(__lowercase)
def UpperCamelCase__ ( self , __lowercase) -> List[int]:
__UpperCamelCase :str = []
for is_user, text in conversation.iter_texts():
input_ids.extend(self.encode(__lowercase , add_special_tokens=__lowercase) + [self.eos_token_id])
if len(__lowercase) > self.model_max_length:
__UpperCamelCase :Any = input_ids[-self.model_max_length :]
return input_ids
| 43
| 0
|
def UpperCamelCase_( lowerCamelCase_ ) -> float:
_lowercase : Dict = 0
while len(lowerCamelCase_ ) > 1:
_lowercase : Dict = 0
# Consider two files with minimum cost to be merged
for _ in range(2 ):
_lowercase : Union[str, Any] = files.index(min(lowerCamelCase_ ) )
temp += files[min_index]
files.pop(lowerCamelCase_ )
files.append(lowerCamelCase_ )
optimal_merge_cost += temp
return optimal_merge_cost
if __name__ == "__main__":
import doctest
doctest.testmod()
| 21
|
from ...configuration_utils import PretrainedConfig
from ...utils import logging
__lowercase = logging.get_logger(__name__)
__lowercase = {'''ctrl''': '''https://huggingface.co/ctrl/resolve/main/config.json'''}
class lowerCamelCase_ ( UpperCAmelCase_ ):
'''simple docstring'''
a__ : str = """ctrl"""
a__ : Dict = ["""past_key_values"""]
a__ : Tuple = {
"""max_position_embeddings""": """n_positions""",
"""hidden_size""": """n_embd""",
"""num_attention_heads""": """n_head""",
"""num_hidden_layers""": """n_layer""",
}
def __init__( self , __lowercase=246_534 , __lowercase=256 , __lowercase=1_280 , __lowercase=8_192 , __lowercase=48 , __lowercase=16 , __lowercase=0.1 , __lowercase=0.1 , __lowercase=1E-6 , __lowercase=0.02 , __lowercase=True , **__lowercase , ) -> List[Any]:
__UpperCamelCase :List[str] = vocab_size
__UpperCamelCase :Optional[Any] = n_positions
__UpperCamelCase :Dict = n_embd
__UpperCamelCase :Dict = n_layer
__UpperCamelCase :List[Any] = n_head
__UpperCamelCase :int = dff
__UpperCamelCase :Union[str, Any] = resid_pdrop
__UpperCamelCase :Optional[int] = embd_pdrop
__UpperCamelCase :List[Any] = layer_norm_epsilon
__UpperCamelCase :Dict = initializer_range
__UpperCamelCase :Any = use_cache
super().__init__(**__lowercase)
| 43
| 0
|
'''simple docstring'''
import json
import os
import tempfile
import datasets
from utils import generate_example_dataset, get_duration
__SCREAMING_SNAKE_CASE :Any = 50000
__SCREAMING_SNAKE_CASE :List[str] = 5000
__SCREAMING_SNAKE_CASE ,__SCREAMING_SNAKE_CASE :Dict = os.path.split(__file__)
__SCREAMING_SNAKE_CASE :str = os.path.join(RESULTS_BASEPATH, '''results''', RESULTS_FILENAME.replace('''.py''', '''.json'''))
@get_duration
def UpperCAmelCase_ ( __lowercase : datasets.Dataset , __lowercase : Any ) -> Dict:
'''simple docstring'''
for i in range(__lowercase ):
_UpperCAmelCase = dataset[i]
@get_duration
def UpperCAmelCase_ ( __lowercase : datasets.Dataset , __lowercase : int , __lowercase : Union[str, Any] ) -> str:
'''simple docstring'''
for i in range(0 , len(__lowercase ) , __lowercase ):
_UpperCAmelCase = dataset[i : i + batch_size]
@get_duration
def UpperCAmelCase_ ( __lowercase : datasets.Dataset , __lowercase : int , __lowercase : Union[str, Any] ) -> Dict:
'''simple docstring'''
with dataset.formatted_as(type=__lowercase ):
for i in range(__lowercase ):
_UpperCAmelCase = dataset[i]
@get_duration
def UpperCAmelCase_ ( __lowercase : datasets.Dataset , __lowercase : Optional[int] , __lowercase : List[str] , __lowercase : Any ) -> Union[str, Any]:
'''simple docstring'''
with dataset.formatted_as(type=__lowercase ):
for i in range(0 , __lowercase , __lowercase ):
_UpperCAmelCase = dataset[i : i + batch_size]
def UpperCAmelCase_ ( ) -> Union[str, Any]:
'''simple docstring'''
_UpperCAmelCase = {"num examples": SPEED_TEST_N_EXAMPLES}
_UpperCAmelCase = [
(read, {"length": SMALL_TEST}),
(read, {"length": SPEED_TEST_N_EXAMPLES}),
(read_batch, {"length": SPEED_TEST_N_EXAMPLES, "batch_size": 10}),
(read_batch, {"length": SPEED_TEST_N_EXAMPLES, "batch_size": 100}),
(read_batch, {"length": SPEED_TEST_N_EXAMPLES, "batch_size": 1000}),
(read_formatted, {"type": "numpy", "length": SMALL_TEST}),
(read_formatted, {"type": "pandas", "length": SMALL_TEST}),
(read_formatted, {"type": "torch", "length": SMALL_TEST}),
(read_formatted, {"type": "tensorflow", "length": SMALL_TEST}),
(read_formatted_batch, {"type": "numpy", "length": SMALL_TEST, "batch_size": 10}),
(read_formatted_batch, {"type": "numpy", "length": SMALL_TEST, "batch_size": 1000}),
]
_UpperCAmelCase = [
(read, {"length": SMALL_TEST}),
(read, {"length": SPEED_TEST_N_EXAMPLES}),
(read_batch, {"length": SPEED_TEST_N_EXAMPLES, "batch_size": 10}),
(read_batch, {"length": SPEED_TEST_N_EXAMPLES, "batch_size": 100}),
(read_batch, {"length": SPEED_TEST_N_EXAMPLES, "batch_size": 1000}),
(read_formatted, {"type": "numpy", "length": SMALL_TEST}),
(read_formatted_batch, {"type": "numpy", "length": SMALL_TEST, "batch_size": 10}),
(read_formatted_batch, {"type": "numpy", "length": SMALL_TEST, "batch_size": 1000}),
]
with tempfile.TemporaryDirectory() as tmp_dir:
print("generating dataset" )
_UpperCAmelCase = datasets.Features(
{"list": datasets.Sequence(datasets.Value("float32" ) ), "numbers": datasets.Value("float32" )} )
_UpperCAmelCase = generate_example_dataset(
os.path.join(__lowercase , "dataset.arrow" ) , __lowercase , num_examples=__lowercase , seq_shapes={"list": (100,)} , )
print("first set of iterations" )
for func, kwargs in functions:
print(func.__name__ , str(__lowercase ) )
_UpperCAmelCase = func(__lowercase , **__lowercase )
print("shuffling dataset" )
_UpperCAmelCase = dataset.shuffle()
print("Second set of iterations (after shuffling" )
for func, kwargs in functions_shuffled:
print("shuffled " , func.__name__ , str(__lowercase ) )
_UpperCAmelCase = func(
__lowercase , **__lowercase )
with open(__lowercase , "wb" ) as f:
f.write(json.dumps(__lowercase ).encode("utf-8" ) )
if __name__ == "__main__": # useful to run the profiler
benchmark_iterating()
| 22
|
import unittest
import numpy as np
import torch
from transformers import CLIPTextConfig, CLIPTextModel, CLIPTokenizer
from diffusers import (
AutoencoderKL,
DDIMScheduler,
DPMSolverMultistepScheduler,
TextToVideoSDPipeline,
UNetaDConditionModel,
)
from diffusers.utils import is_xformers_available, load_numpy, skip_mps, slow, torch_device
from diffusers.utils.testing_utils import enable_full_determinism
from ..pipeline_params import TEXT_TO_IMAGE_BATCH_PARAMS, TEXT_TO_IMAGE_PARAMS
from ..test_pipelines_common import PipelineTesterMixin
enable_full_determinism()
@skip_mps
class lowerCamelCase_ ( UpperCAmelCase_ , unittest.TestCase ):
'''simple docstring'''
a__ : str = TextToVideoSDPipeline
a__ : Union[str, Any] = TEXT_TO_IMAGE_PARAMS
a__ : Tuple = TEXT_TO_IMAGE_BATCH_PARAMS
# No `output_type`.
a__ : int = frozenset(
[
"""num_inference_steps""",
"""generator""",
"""latents""",
"""return_dict""",
"""callback""",
"""callback_steps""",
] )
def UpperCamelCase__ ( self) -> Optional[Any]:
torch.manual_seed(0)
__UpperCamelCase :str = UNetaDConditionModel(
block_out_channels=(32, 64, 64, 64) , layers_per_block=2 , sample_size=32 , in_channels=4 , out_channels=4 , down_block_types=('''CrossAttnDownBlock3D''', '''CrossAttnDownBlock3D''', '''CrossAttnDownBlock3D''', '''DownBlock3D''') , up_block_types=('''UpBlock3D''', '''CrossAttnUpBlock3D''', '''CrossAttnUpBlock3D''', '''CrossAttnUpBlock3D''') , cross_attention_dim=32 , attention_head_dim=4 , )
__UpperCamelCase :Optional[int] = DDIMScheduler(
beta_start=0.0_00_85 , beta_end=0.0_12 , beta_schedule='''scaled_linear''' , clip_sample=__lowercase , set_alpha_to_one=__lowercase , )
torch.manual_seed(0)
__UpperCamelCase :Optional[int] = AutoencoderKL(
block_out_channels=[32, 64] , in_channels=3 , out_channels=3 , down_block_types=['''DownEncoderBlock2D''', '''DownEncoderBlock2D'''] , up_block_types=['''UpDecoderBlock2D''', '''UpDecoderBlock2D'''] , latent_channels=4 , sample_size=128 , )
torch.manual_seed(0)
__UpperCamelCase :Optional[int] = CLIPTextConfig(
bos_token_id=0 , eos_token_id=2 , hidden_size=32 , intermediate_size=37 , layer_norm_eps=1E-0_5 , num_attention_heads=4 , num_hidden_layers=5 , pad_token_id=1 , vocab_size=1_000 , hidden_act='''gelu''' , projection_dim=512 , )
__UpperCamelCase :Optional[Any] = CLIPTextModel(__lowercase)
__UpperCamelCase :Optional[int] = CLIPTokenizer.from_pretrained('''hf-internal-testing/tiny-random-clip''')
__UpperCamelCase :Union[str, Any] = {
'''unet''': unet,
'''scheduler''': scheduler,
'''vae''': vae,
'''text_encoder''': text_encoder,
'''tokenizer''': tokenizer,
}
return components
def UpperCamelCase__ ( self , __lowercase , __lowercase=0) -> Optional[int]:
if str(__lowercase).startswith('''mps'''):
__UpperCamelCase :List[Any] = torch.manual_seed(__lowercase)
else:
__UpperCamelCase :Tuple = torch.Generator(device=__lowercase).manual_seed(__lowercase)
__UpperCamelCase :Dict = {
'''prompt''': '''A painting of a squirrel eating a burger''',
'''generator''': generator,
'''num_inference_steps''': 2,
'''guidance_scale''': 6.0,
'''output_type''': '''pt''',
}
return inputs
def UpperCamelCase__ ( self) -> Optional[Any]:
__UpperCamelCase :int = '''cpu''' # ensure determinism for the device-dependent torch.Generator
__UpperCamelCase :Optional[int] = self.get_dummy_components()
__UpperCamelCase :Dict = TextToVideoSDPipeline(**__lowercase)
__UpperCamelCase :Any = sd_pipe.to(__lowercase)
sd_pipe.set_progress_bar_config(disable=__lowercase)
__UpperCamelCase :Optional[Any] = self.get_dummy_inputs(__lowercase)
__UpperCamelCase :int = '''np'''
__UpperCamelCase :List[str] = sd_pipe(**__lowercase).frames
__UpperCamelCase :Optional[Any] = frames[0][-3:, -3:, -1]
assert frames[0].shape == (64, 64, 3)
__UpperCamelCase :str = np.array([1_58.0, 1_60.0, 1_53.0, 1_25.0, 1_00.0, 1_21.0, 1_11.0, 93.0, 1_13.0])
assert np.abs(image_slice.flatten() - expected_slice).max() < 1E-2
def UpperCamelCase__ ( self) -> Tuple:
self._test_attention_slicing_forward_pass(test_mean_pixel_difference=__lowercase , expected_max_diff=3E-3)
@unittest.skipIf(
torch_device != '''cuda''' or not is_xformers_available() , reason='''XFormers attention is only available with CUDA and `xformers` installed''' , )
def UpperCamelCase__ ( self) -> Optional[int]:
self._test_xformers_attention_forwardGenerator_pass(test_mean_pixel_difference=__lowercase , expected_max_diff=1E-2)
@unittest.skip(reason='''Batching needs to be properly figured out first for this pipeline.''')
def UpperCamelCase__ ( self) -> Union[str, Any]:
pass
@unittest.skip(reason='''Batching needs to be properly figured out first for this pipeline.''')
def UpperCamelCase__ ( self) -> Dict:
pass
@unittest.skip(reason='''`num_images_per_prompt` argument is not supported for this pipeline.''')
def UpperCamelCase__ ( self) -> str:
pass
def UpperCamelCase__ ( self) -> List[str]:
return super().test_progress_bar()
@slow
@skip_mps
class lowerCamelCase_ ( unittest.TestCase ):
'''simple docstring'''
def UpperCamelCase__ ( self) -> Dict:
__UpperCamelCase :Union[str, Any] = load_numpy(
'''https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main/text_to_video/video.npy''')
__UpperCamelCase :List[str] = TextToVideoSDPipeline.from_pretrained('''damo-vilab/text-to-video-ms-1.7b''')
__UpperCamelCase :Union[str, Any] = DPMSolverMultistepScheduler.from_config(pipe.scheduler.config)
__UpperCamelCase :str = pipe.to('''cuda''')
__UpperCamelCase :Optional[Any] = '''Spiderman is surfing'''
__UpperCamelCase :Union[str, Any] = torch.Generator(device='''cpu''').manual_seed(0)
__UpperCamelCase :List[Any] = pipe(__lowercase , generator=__lowercase , num_inference_steps=25 , output_type='''pt''').frames
__UpperCamelCase :Optional[int] = video_frames.cpu().numpy()
assert np.abs(expected_video - video).mean() < 5E-2
def UpperCamelCase__ ( self) -> int:
__UpperCamelCase :str = load_numpy(
'''https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main/text_to_video/video_2step.npy''')
__UpperCamelCase :Union[str, Any] = TextToVideoSDPipeline.from_pretrained('''damo-vilab/text-to-video-ms-1.7b''')
__UpperCamelCase :str = pipe.to('''cuda''')
__UpperCamelCase :Union[str, Any] = '''Spiderman is surfing'''
__UpperCamelCase :int = torch.Generator(device='''cpu''').manual_seed(0)
__UpperCamelCase :List[Any] = pipe(__lowercase , generator=__lowercase , num_inference_steps=2 , output_type='''pt''').frames
__UpperCamelCase :Optional[Any] = video_frames.cpu().numpy()
assert np.abs(expected_video - video).mean() < 5E-2
| 43
| 0
|
'''simple docstring'''
from ...configuration_utils import PretrainedConfig
from ...utils import logging
UpperCamelCase__: int = logging.get_logger(__name__)
UpperCamelCase__: List[Any] = {
"naver-clova-ix/donut-base": "https://huggingface.co/naver-clova-ix/donut-base/resolve/main/config.json",
# See all Donut models at https://huggingface.co/models?filter=donut-swin
}
class SCREAMING_SNAKE_CASE( A__ ):
"""simple docstring"""
lowerCamelCase__ = """donut-swin"""
lowerCamelCase__ = {
"""num_attention_heads""": """num_heads""",
"""num_hidden_layers""": """num_layers""",
}
def __init__( self : Union[str, Any] , __snake_case : List[str]=224 , __snake_case : Optional[int]=4 , __snake_case : int=3 , __snake_case : Tuple=96 , __snake_case : Union[str, Any]=[2, 2, 6, 2] , __snake_case : str=[3, 6, 12, 24] , __snake_case : List[str]=7 , __snake_case : str=4.0 , __snake_case : Tuple=True , __snake_case : Union[str, Any]=0.0 , __snake_case : str=0.0 , __snake_case : Optional[Any]=0.1 , __snake_case : Union[str, Any]="gelu" , __snake_case : str=False , __snake_case : Optional[int]=0.02 , __snake_case : List[Any]=1E-5 , **__snake_case : int , ) -> Optional[Any]:
super().__init__(**__snake_case )
UpperCAmelCase : Any = image_size
UpperCAmelCase : List[str] = patch_size
UpperCAmelCase : List[Any] = num_channels
UpperCAmelCase : Union[str, Any] = embed_dim
UpperCAmelCase : Union[str, Any] = depths
UpperCAmelCase : Any = len(__snake_case )
UpperCAmelCase : Union[str, Any] = num_heads
UpperCAmelCase : Any = window_size
UpperCAmelCase : Tuple = mlp_ratio
UpperCAmelCase : Optional[Any] = qkv_bias
UpperCAmelCase : Any = hidden_dropout_prob
UpperCAmelCase : str = attention_probs_dropout_prob
UpperCAmelCase : Dict = drop_path_rate
UpperCAmelCase : List[Any] = hidden_act
UpperCAmelCase : Union[str, Any] = use_absolute_embeddings
UpperCAmelCase : Tuple = layer_norm_eps
UpperCAmelCase : Optional[int] = initializer_range
# we set the hidden_size attribute in order to make Swin work with VisionEncoderDecoderModel
# this indicates the channel dimension after the last stage of the model
UpperCAmelCase : str = int(embed_dim * 2 ** (len(__snake_case ) - 1) )
| 23
|
def lowerCamelCase ( SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Tuple = [0 for i in range(len(SCREAMING_SNAKE_CASE ) )]
# initialize interval's left pointer and right pointer
__UpperCamelCase , __UpperCamelCase :str = 0, 0
for i in range(1 , len(SCREAMING_SNAKE_CASE ) ):
# case when current index is inside the interval
if i <= right_pointer:
__UpperCamelCase :Union[str, Any] = min(right_pointer - i + 1 , z_result[i - left_pointer] )
__UpperCamelCase :Tuple = min_edge
while go_next(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
z_result[i] += 1
# if new index's result gives us more right interval,
# we've to update left_pointer and right_pointer
if i + z_result[i] - 1 > right_pointer:
__UpperCamelCase , __UpperCamelCase :Union[str, Any] = i, i + z_result[i] - 1
return z_result
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
return i + z_result[i] < len(SCREAMING_SNAKE_CASE ) and s[z_result[i]] == s[i + z_result[i]]
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :List[Any] = 0
# concatenate 'pattern' and 'input_str' and call z_function
# with concatenated string
__UpperCamelCase :Tuple = z_function(pattern + input_str )
for val in z_result:
# if value is greater then length of the pattern string
# that means this index is starting position of substring
# which is equal to pattern string
if val >= len(SCREAMING_SNAKE_CASE ):
answer += 1
return answer
if __name__ == "__main__":
import doctest
doctest.testmod()
| 43
| 0
|
from __future__ import annotations
def lowerCamelCase__ ( snake_case_ : float , snake_case_ : float , snake_case_ : float ) -> dict[str, float]:
if (voltage, current, resistance).count(0 ) != 1:
raise ValueError('''One and only one argument must be 0''' )
if resistance < 0:
raise ValueError('''Resistance cannot be negative''' )
if voltage == 0:
return {"voltage": float(current * resistance )}
elif current == 0:
return {"current": voltage / resistance}
elif resistance == 0:
return {"resistance": voltage / current}
else:
raise ValueError('''Exactly one argument must be 0''' )
if __name__ == "__main__":
import doctest
doctest.testmod()
| 24
|
import math
from typing import Any, Callable, List, Optional, Tuple, Union
import numpy as np
import torch
from ...models import TaFilmDecoder
from ...schedulers import DDPMScheduler
from ...utils import is_onnx_available, logging, randn_tensor
if is_onnx_available():
from ..onnx_utils import OnnxRuntimeModel
from ..pipeline_utils import AudioPipelineOutput, DiffusionPipeline
from .continous_encoder import SpectrogramContEncoder
from .notes_encoder import SpectrogramNotesEncoder
__lowercase = logging.get_logger(__name__) # pylint: disable=invalid-name
__lowercase = 256
class lowerCamelCase_ ( UpperCAmelCase_ ):
'''simple docstring'''
a__ : Tuple = ["""melgan"""]
def __init__( self , __lowercase , __lowercase , __lowercase , __lowercase , __lowercase , ) -> None:
super().__init__()
# From MELGAN
__UpperCamelCase :int = math.log(1E-5) # Matches MelGAN training.
__UpperCamelCase :int = 4.0 # Largest value for most examples
__UpperCamelCase :str = 128
self.register_modules(
notes_encoder=__lowercase , continuous_encoder=__lowercase , decoder=__lowercase , scheduler=__lowercase , melgan=__lowercase , )
def UpperCamelCase__ ( self , __lowercase , __lowercase=(-1.0, 1.0) , __lowercase=False) -> Dict:
__UpperCamelCase , __UpperCamelCase :str = output_range
if clip:
__UpperCamelCase :Union[str, Any] = torch.clip(__lowercase , self.min_value , self.max_value)
# Scale to [0, 1].
__UpperCamelCase :Union[str, Any] = (features - self.min_value) / (self.max_value - self.min_value)
# Scale to [min_out, max_out].
return zero_one * (max_out - min_out) + min_out
def UpperCamelCase__ ( self , __lowercase , __lowercase=(-1.0, 1.0) , __lowercase=False) -> Optional[int]:
__UpperCamelCase , __UpperCamelCase :int = input_range
__UpperCamelCase :Optional[int] = torch.clip(__lowercase , __lowercase , __lowercase) if clip else outputs
# Scale to [0, 1].
__UpperCamelCase :List[str] = (outputs - min_out) / (max_out - min_out)
# Scale to [self.min_value, self.max_value].
return zero_one * (self.max_value - self.min_value) + self.min_value
def UpperCamelCase__ ( self , __lowercase , __lowercase , __lowercase) -> List[Any]:
__UpperCamelCase :List[str] = input_tokens > 0
__UpperCamelCase , __UpperCamelCase :Union[str, Any] = self.notes_encoder(
encoder_input_tokens=__lowercase , encoder_inputs_mask=__lowercase)
__UpperCamelCase , __UpperCamelCase :Union[str, Any] = self.continuous_encoder(
encoder_inputs=__lowercase , encoder_inputs_mask=__lowercase)
return [(tokens_encoded, tokens_mask), (continuous_encoded, continuous_mask)]
def UpperCamelCase__ ( self , __lowercase , __lowercase , __lowercase) -> str:
__UpperCamelCase :Optional[int] = noise_time
if not torch.is_tensor(__lowercase):
__UpperCamelCase :str = torch.tensor([timesteps] , dtype=torch.long , device=input_tokens.device)
elif torch.is_tensor(__lowercase) and len(timesteps.shape) == 0:
__UpperCamelCase :Dict = timesteps[None].to(input_tokens.device)
# broadcast to batch dimension in a way that's compatible with ONNX/Core ML
__UpperCamelCase :List[str] = timesteps * torch.ones(input_tokens.shape[0] , dtype=timesteps.dtype , device=timesteps.device)
__UpperCamelCase :Tuple = self.decoder(
encodings_and_masks=__lowercase , decoder_input_tokens=__lowercase , decoder_noise_time=__lowercase)
return logits
@torch.no_grad()
def __call__( self , __lowercase , __lowercase = None , __lowercase = 100 , __lowercase = True , __lowercase = "numpy" , __lowercase = None , __lowercase = 1 , ) -> Union[AudioPipelineOutput, Tuple]:
if (callback_steps is None) or (
callback_steps is not None and (not isinstance(__lowercase , __lowercase) or callback_steps <= 0)
):
raise ValueError(
f"""`callback_steps` has to be a positive integer but is {callback_steps} of type"""
f""" {type(__lowercase)}.""")
__UpperCamelCase :Union[str, Any] = np.zeros([1, TARGET_FEATURE_LENGTH, self.n_dims] , dtype=np.floataa)
__UpperCamelCase :Union[str, Any] = np.zeros([1, 0, self.n_dims] , np.floataa)
__UpperCamelCase :Union[str, Any] = torch.ones((1, TARGET_FEATURE_LENGTH) , dtype=__lowercase , device=self.device)
for i, encoder_input_tokens in enumerate(__lowercase):
if i == 0:
__UpperCamelCase :int = torch.from_numpy(pred_mel[:1].copy()).to(
device=self.device , dtype=self.decoder.dtype)
# The first chunk has no previous context.
__UpperCamelCase :int = torch.zeros((1, TARGET_FEATURE_LENGTH) , dtype=__lowercase , device=self.device)
else:
# The full song pipeline does not feed in a context feature, so the mask
# will be all 0s after the feature converter. Because we know we're
# feeding in a full context chunk from the previous prediction, set it
# to all 1s.
__UpperCamelCase :Tuple = ones
__UpperCamelCase :Optional[Any] = self.scale_features(
__lowercase , output_range=[-1.0, 1.0] , clip=__lowercase)
__UpperCamelCase :int = self.encode(
input_tokens=torch.IntTensor([encoder_input_tokens]).to(device=self.device) , continuous_inputs=__lowercase , continuous_mask=__lowercase , )
# Sample encoder_continuous_inputs shaped gaussian noise to begin loop
__UpperCamelCase :int = randn_tensor(
shape=encoder_continuous_inputs.shape , generator=__lowercase , device=self.device , dtype=self.decoder.dtype , )
# set step values
self.scheduler.set_timesteps(__lowercase)
# Denoising diffusion loop
for j, t in enumerate(self.progress_bar(self.scheduler.timesteps)):
__UpperCamelCase :Optional[int] = self.decode(
encodings_and_masks=__lowercase , input_tokens=__lowercase , noise_time=t / self.scheduler.config.num_train_timesteps , )
# Compute previous output: x_t -> x_t-1
__UpperCamelCase :int = self.scheduler.step(__lowercase , __lowercase , __lowercase , generator=__lowercase).prev_sample
__UpperCamelCase :Tuple = self.scale_to_features(__lowercase , input_range=[-1.0, 1.0])
__UpperCamelCase :List[Any] = mel[:1]
__UpperCamelCase :Optional[Any] = mel.cpu().float().numpy()
__UpperCamelCase :Any = np.concatenate([full_pred_mel, pred_mel[:1]] , axis=1)
# call the callback, if provided
if callback is not None and i % callback_steps == 0:
callback(__lowercase , __lowercase)
logger.info('''Generated segment''' , __lowercase)
if output_type == "numpy" and not is_onnx_available():
raise ValueError(
'''Cannot return output in \'np\' format if ONNX is not available. Make sure to have ONNX installed or set \'output_type\' to \'mel\'.''')
elif output_type == "numpy" and self.melgan is None:
raise ValueError(
'''Cannot return output in \'np\' format if melgan component is not defined. Make sure to define `self.melgan` or set \'output_type\' to \'mel\'.''')
if output_type == "numpy":
__UpperCamelCase :Optional[Any] = self.melgan(input_features=full_pred_mel.astype(np.floataa))
else:
__UpperCamelCase :List[str] = full_pred_mel
if not return_dict:
return (output,)
return AudioPipelineOutput(audios=__lowercase)
| 43
| 0
|
"""simple docstring"""
import argparse
import pathlib
import fairseq
import torch
from fairseq.models.roberta import RobertaModel as FairseqRobertaModel
from fairseq.modules import TransformerSentenceEncoderLayer
from packaging import version
from transformers import XLMRobertaConfig, XLMRobertaXLForMaskedLM, XLMRobertaXLForSequenceClassification
from transformers.models.bert.modeling_bert import (
BertIntermediate,
BertLayer,
BertOutput,
BertSelfAttention,
BertSelfOutput,
)
from transformers.models.roberta.modeling_roberta import RobertaAttention
from transformers.utils import logging
if version.parse(fairseq.__version__) < version.parse('1.0.0a'):
raise Exception('requires fairseq >= 1.0.0a')
logging.set_verbosity_info()
UpperCAmelCase__ : Union[str, Any] = logging.get_logger(__name__)
UpperCAmelCase__ : List[str] = 'Hello world! cécé herlolip'
def lowercase_ ( _snake_case ,_snake_case ,_snake_case ):
SCREAMING_SNAKE_CASE__ : int = FairseqRobertaModel.from_pretrained(_snake_case )
roberta.eval() # disable dropout
SCREAMING_SNAKE_CASE__ : Any = roberta.model.encoder.sentence_encoder
SCREAMING_SNAKE_CASE__ : Any = XLMRobertaConfig(
vocab_size=roberta_sent_encoder.embed_tokens.num_embeddings ,hidden_size=roberta.cfg.model.encoder_embed_dim ,num_hidden_layers=roberta.cfg.model.encoder_layers ,num_attention_heads=roberta.cfg.model.encoder_attention_heads ,intermediate_size=roberta.cfg.model.encoder_ffn_embed_dim ,max_position_embeddings=514 ,type_vocab_size=1 ,layer_norm_eps=1E-5 ,)
if classification_head:
SCREAMING_SNAKE_CASE__ : Dict = roberta.model.classification_heads["""mnli"""].out_proj.weight.shape[0]
print("""Our RoBERTa config:""" ,_snake_case )
SCREAMING_SNAKE_CASE__ : Union[str, Any] = XLMRobertaXLForSequenceClassification(_snake_case ) if classification_head else XLMRobertaXLForMaskedLM(_snake_case )
model.eval()
# Now let's copy all the weights.
# Embeddings
SCREAMING_SNAKE_CASE__ : Optional[int] = roberta_sent_encoder.embed_tokens.weight
SCREAMING_SNAKE_CASE__ : int = roberta_sent_encoder.embed_positions.weight
SCREAMING_SNAKE_CASE__ : Union[str, Any] = torch.zeros_like(
model.roberta.embeddings.token_type_embeddings.weight ) # just zero them out b/c RoBERTa doesn't use them.
SCREAMING_SNAKE_CASE__ : Optional[int] = roberta_sent_encoder.layer_norm.weight
SCREAMING_SNAKE_CASE__ : Dict = roberta_sent_encoder.layer_norm.bias
for i in range(config.num_hidden_layers ):
# Encoder: start of layer
SCREAMING_SNAKE_CASE__ : BertLayer = model.roberta.encoder.layer[i]
SCREAMING_SNAKE_CASE__ : TransformerSentenceEncoderLayer = roberta_sent_encoder.layers[i]
SCREAMING_SNAKE_CASE__ : RobertaAttention = layer.attention
SCREAMING_SNAKE_CASE__ : List[str] = roberta_layer.self_attn_layer_norm.weight
SCREAMING_SNAKE_CASE__ : List[Any] = roberta_layer.self_attn_layer_norm.bias
# self attention
SCREAMING_SNAKE_CASE__ : BertSelfAttention = layer.attention.self
assert (
roberta_layer.self_attn.k_proj.weight.data.shape
== roberta_layer.self_attn.q_proj.weight.data.shape
== roberta_layer.self_attn.v_proj.weight.data.shape
== torch.Size((config.hidden_size, config.hidden_size) )
)
SCREAMING_SNAKE_CASE__ : List[str] = roberta_layer.self_attn.q_proj.weight
SCREAMING_SNAKE_CASE__ : Tuple = roberta_layer.self_attn.q_proj.bias
SCREAMING_SNAKE_CASE__ : Tuple = roberta_layer.self_attn.k_proj.weight
SCREAMING_SNAKE_CASE__ : int = roberta_layer.self_attn.k_proj.bias
SCREAMING_SNAKE_CASE__ : List[str] = roberta_layer.self_attn.v_proj.weight
SCREAMING_SNAKE_CASE__ : Union[str, Any] = roberta_layer.self_attn.v_proj.bias
# self-attention output
SCREAMING_SNAKE_CASE__ : BertSelfOutput = layer.attention.output
assert self_output.dense.weight.shape == roberta_layer.self_attn.out_proj.weight.shape
SCREAMING_SNAKE_CASE__ : Union[str, Any] = roberta_layer.self_attn.out_proj.weight
SCREAMING_SNAKE_CASE__ : List[str] = roberta_layer.self_attn.out_proj.bias
# this one is final layer norm
SCREAMING_SNAKE_CASE__ : Tuple = roberta_layer.final_layer_norm.weight
SCREAMING_SNAKE_CASE__ : Optional[int] = roberta_layer.final_layer_norm.bias
# intermediate
SCREAMING_SNAKE_CASE__ : BertIntermediate = layer.intermediate
assert intermediate.dense.weight.shape == roberta_layer.fca.weight.shape
SCREAMING_SNAKE_CASE__ : List[Any] = roberta_layer.fca.weight
SCREAMING_SNAKE_CASE__ : Tuple = roberta_layer.fca.bias
# output
SCREAMING_SNAKE_CASE__ : BertOutput = layer.output
assert bert_output.dense.weight.shape == roberta_layer.fca.weight.shape
SCREAMING_SNAKE_CASE__ : Tuple = roberta_layer.fca.weight
SCREAMING_SNAKE_CASE__ : Optional[int] = roberta_layer.fca.bias
# end of layer
if classification_head:
SCREAMING_SNAKE_CASE__ : List[Any] = roberta.model.classification_heads["""mnli"""].dense.weight
SCREAMING_SNAKE_CASE__ : Optional[Any] = roberta.model.classification_heads["""mnli"""].dense.bias
SCREAMING_SNAKE_CASE__ : Optional[Any] = roberta.model.classification_heads["""mnli"""].out_proj.weight
SCREAMING_SNAKE_CASE__ : Union[str, Any] = roberta.model.classification_heads["""mnli"""].out_proj.bias
else:
# LM Head
SCREAMING_SNAKE_CASE__ : str = roberta.model.encoder.lm_head.dense.weight
SCREAMING_SNAKE_CASE__ : List[Any] = roberta.model.encoder.lm_head.dense.bias
SCREAMING_SNAKE_CASE__ : Union[str, Any] = roberta.model.encoder.lm_head.layer_norm.weight
SCREAMING_SNAKE_CASE__ : Dict = roberta.model.encoder.lm_head.layer_norm.bias
SCREAMING_SNAKE_CASE__ : Optional[int] = roberta.model.encoder.lm_head.weight
SCREAMING_SNAKE_CASE__ : List[str] = roberta.model.encoder.lm_head.bias
# Let's check that we get the same results.
SCREAMING_SNAKE_CASE__ : torch.Tensor = roberta.encode(_snake_case ).unsqueeze(0 ) # batch of size 1
SCREAMING_SNAKE_CASE__ : Tuple = model(_snake_case )[0]
if classification_head:
SCREAMING_SNAKE_CASE__ : Dict = roberta.model.classification_heads["""mnli"""](roberta.extract_features(_snake_case ) )
else:
SCREAMING_SNAKE_CASE__ : Tuple = roberta.model(_snake_case )[0]
print(our_output.shape ,their_output.shape )
SCREAMING_SNAKE_CASE__ : Optional[Any] = torch.max(torch.abs(our_output - their_output ) ).item()
print(f'''max_absolute_diff = {max_absolute_diff}''' ) # ~ 1e-7
SCREAMING_SNAKE_CASE__ : Tuple = torch.allclose(_snake_case ,_snake_case ,atol=1E-3 )
print("""Do both models output the same tensors?""" ,"""🔥""" if success else """💩""" )
if not success:
raise Exception("""Something went wRoNg""" )
pathlib.Path(_snake_case ).mkdir(parents=_snake_case ,exist_ok=_snake_case )
print(f'''Saving model to {pytorch_dump_folder_path}''' )
model.save_pretrained(_snake_case )
if __name__ == "__main__":
UpperCAmelCase__ : Union[str, Any] = argparse.ArgumentParser()
# Required parameters
parser.add_argument(
'--roberta_checkpoint_path', default=None, type=str, required=True, help='Path the official PyTorch dump.'
)
parser.add_argument(
'--pytorch_dump_folder_path', default=None, type=str, required=True, help='Path to the output PyTorch model.'
)
parser.add_argument(
'--classification_head', action='store_true', help='Whether to convert a final classification head.'
)
UpperCAmelCase__ : Any = parser.parse_args()
convert_xlm_roberta_xl_checkpoint_to_pytorch(
args.roberta_checkpoint_path, args.pytorch_dump_folder_path, args.classification_head
)
| 25
|
import argparse
import json
import os
import fairseq
import torch
from fairseq.data import Dictionary
from transformers import (
HubertConfig,
HubertForCTC,
HubertModel,
WavaVecaCTCTokenizer,
WavaVecaFeatureExtractor,
WavaVecaProcessor,
logging,
)
logging.set_verbosity_info()
__lowercase = logging.get_logger(__name__)
__lowercase = {
'''post_extract_proj''': '''feature_projection.projection''',
'''encoder.pos_conv.0''': '''encoder.pos_conv_embed.conv''',
'''self_attn.k_proj''': '''encoder.layers.*.attention.k_proj''',
'''self_attn.v_proj''': '''encoder.layers.*.attention.v_proj''',
'''self_attn.q_proj''': '''encoder.layers.*.attention.q_proj''',
'''self_attn.out_proj''': '''encoder.layers.*.attention.out_proj''',
'''self_attn_layer_norm''': '''encoder.layers.*.layer_norm''',
'''fc1''': '''encoder.layers.*.feed_forward.intermediate_dense''',
'''fc2''': '''encoder.layers.*.feed_forward.output_dense''',
'''final_layer_norm''': '''encoder.layers.*.final_layer_norm''',
'''encoder.layer_norm''': '''encoder.layer_norm''',
'''w2v_model.layer_norm''': '''feature_projection.layer_norm''',
'''w2v_encoder.proj''': '''lm_head''',
'''mask_emb''': '''masked_spec_embed''',
}
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
for attribute in key.split('''.''' ):
__UpperCamelCase :str = getattr(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
if weight_type is not None:
__UpperCamelCase :Any = getattr(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ).shape
else:
__UpperCamelCase :Union[str, Any] = hf_pointer.shape
assert hf_shape == value.shape, (
f"""Shape of hf {key + '.' + weight_type if weight_type is not None else ''} is {hf_shape}, but should be"""
f""" {value.shape} for {full_name}"""
)
if weight_type == "weight":
__UpperCamelCase :str = value
elif weight_type == "weight_g":
__UpperCamelCase :List[str] = value
elif weight_type == "weight_v":
__UpperCamelCase :str = value
elif weight_type == "bias":
__UpperCamelCase :Union[str, Any] = value
else:
__UpperCamelCase :str = value
logger.info(f"""{key + '.' + weight_type if weight_type is not None else ''} was initialized from {full_name}.""" )
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :List[Any] = []
__UpperCamelCase :int = fairseq_model.state_dict()
__UpperCamelCase :List[Any] = hf_model.hubert.feature_extractor if is_finetuned else hf_model.feature_extractor
for name, value in fairseq_dict.items():
__UpperCamelCase :List[Any] = False
if "conv_layers" in name:
load_conv_layer(
SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , hf_model.config.feat_extract_norm == '''group''' , )
__UpperCamelCase :List[str] = True
else:
for key, mapped_key in MAPPING.items():
__UpperCamelCase :Dict = '''hubert.''' + mapped_key if (is_finetuned and mapped_key != '''lm_head''') else mapped_key
if key in name or (key.split('''w2v_model.''' )[-1] == name.split('''.''' )[0] and not is_finetuned):
__UpperCamelCase :Optional[Any] = True
if "*" in mapped_key:
__UpperCamelCase :List[str] = name.split(SCREAMING_SNAKE_CASE )[0].split('''.''' )[-2]
__UpperCamelCase :Optional[int] = mapped_key.replace('''*''' , SCREAMING_SNAKE_CASE )
if "weight_g" in name:
__UpperCamelCase :int = '''weight_g'''
elif "weight_v" in name:
__UpperCamelCase :List[Any] = '''weight_v'''
elif "weight" in name:
__UpperCamelCase :Dict = '''weight'''
elif "bias" in name:
__UpperCamelCase :Dict = '''bias'''
else:
__UpperCamelCase :Dict = None
set_recursively(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
continue
if not is_used:
unused_weights.append(SCREAMING_SNAKE_CASE )
logger.warning(f"""Unused weights: {unused_weights}""" )
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Tuple = full_name.split('''conv_layers.''' )[-1]
__UpperCamelCase :Optional[int] = name.split('''.''' )
__UpperCamelCase :str = int(items[0] )
__UpperCamelCase :List[Any] = int(items[1] )
if type_id == 0:
if "bias" in name:
assert value.shape == feature_extractor.conv_layers[layer_id].conv.bias.data.shape, (
f"""{full_name} has size {value.shape}, but"""
f""" {feature_extractor.conv_layers[layer_id].conv.bias.data.shape} was found."""
)
__UpperCamelCase :Dict = value
logger.info(f"""Feat extract conv layer {layer_id} was initialized from {full_name}.""" )
elif "weight" in name:
assert value.shape == feature_extractor.conv_layers[layer_id].conv.weight.data.shape, (
f"""{full_name} has size {value.shape}, but"""
f""" {feature_extractor.conv_layers[layer_id].conv.weight.data.shape} was found."""
)
__UpperCamelCase :Any = value
logger.info(f"""Feat extract conv layer {layer_id} was initialized from {full_name}.""" )
elif (type_id == 2 and not use_group_norm) or (type_id == 2 and layer_id == 0 and use_group_norm):
if "bias" in name:
assert value.shape == feature_extractor.conv_layers[layer_id].layer_norm.bias.data.shape, (
f"""{full_name} has size {value.shape}, but {feature_extractor[layer_id].layer_norm.bias.data.shape} was"""
" found."
)
__UpperCamelCase :int = value
logger.info(f"""Feat extract layer norm weight of layer {layer_id} was initialized from {full_name}.""" )
elif "weight" in name:
assert value.shape == feature_extractor.conv_layers[layer_id].layer_norm.weight.data.shape, (
f"""{full_name} has size {value.shape}, but"""
f""" {feature_extractor[layer_id].layer_norm.weight.data.shape} was found."""
)
__UpperCamelCase :Union[str, Any] = value
logger.info(f"""Feat extract layer norm weight of layer {layer_id} was initialized from {full_name}.""" )
else:
unused_weights.append(SCREAMING_SNAKE_CASE )
@torch.no_grad()
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE=None , SCREAMING_SNAKE_CASE=None , SCREAMING_SNAKE_CASE=True ):
'''simple docstring'''
if config_path is not None:
__UpperCamelCase :Tuple = HubertConfig.from_pretrained(SCREAMING_SNAKE_CASE )
else:
__UpperCamelCase :Optional[int] = HubertConfig()
if is_finetuned:
if dict_path:
__UpperCamelCase :Optional[int] = Dictionary.load(SCREAMING_SNAKE_CASE )
# important change bos & pad token id since CTC symbol is <pad> and
# not <s> as in fairseq
__UpperCamelCase :Optional[int] = target_dict.pad_index
__UpperCamelCase :Dict = target_dict.bos_index
__UpperCamelCase :str = target_dict.eos_index
__UpperCamelCase :Dict = len(target_dict.symbols )
__UpperCamelCase :List[Any] = os.path.join(SCREAMING_SNAKE_CASE , '''vocab.json''' )
if not os.path.isdir(SCREAMING_SNAKE_CASE ):
logger.error('''--pytorch_dump_folder_path ({}) should be a directory'''.format(SCREAMING_SNAKE_CASE ) )
return
os.makedirs(SCREAMING_SNAKE_CASE , exist_ok=SCREAMING_SNAKE_CASE )
with open(SCREAMING_SNAKE_CASE , '''w''' , encoding='''utf-8''' ) as vocab_handle:
json.dump(target_dict.indices , SCREAMING_SNAKE_CASE )
__UpperCamelCase :Optional[int] = WavaVecaCTCTokenizer(
SCREAMING_SNAKE_CASE , unk_token=target_dict.unk_word , pad_token=target_dict.pad_word , bos_token=target_dict.bos_word , eos_token=target_dict.eos_word , word_delimiter_token='''|''' , do_lower_case=SCREAMING_SNAKE_CASE , )
__UpperCamelCase :Union[str, Any] = True if config.feat_extract_norm == '''layer''' else False
__UpperCamelCase :Any = WavaVecaFeatureExtractor(
feature_size=1 , sampling_rate=16_000 , padding_value=0 , do_normalize=SCREAMING_SNAKE_CASE , return_attention_mask=SCREAMING_SNAKE_CASE , )
__UpperCamelCase :Any = WavaVecaProcessor(feature_extractor=SCREAMING_SNAKE_CASE , tokenizer=SCREAMING_SNAKE_CASE )
processor.save_pretrained(SCREAMING_SNAKE_CASE )
__UpperCamelCase :List[str] = HubertForCTC(SCREAMING_SNAKE_CASE )
else:
__UpperCamelCase :str = HubertModel(SCREAMING_SNAKE_CASE )
if is_finetuned:
__UpperCamelCase , __UpperCamelCase , __UpperCamelCase :int = fairseq.checkpoint_utils.load_model_ensemble_and_task(
[checkpoint_path] , arg_overrides={'''data''': '''/'''.join(dict_path.split('''/''' )[:-1] )} )
else:
__UpperCamelCase , __UpperCamelCase , __UpperCamelCase :Any = fairseq.checkpoint_utils.load_model_ensemble_and_task([checkpoint_path] )
__UpperCamelCase :Dict = model[0].eval()
recursively_load_weights(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
hf_wavavec.save_pretrained(SCREAMING_SNAKE_CASE )
if __name__ == "__main__":
__lowercase = argparse.ArgumentParser()
parser.add_argument('''--pytorch_dump_folder_path''', default=None, type=str, help='''Path to the output PyTorch model.''')
parser.add_argument('''--checkpoint_path''', default=None, type=str, help='''Path to fairseq checkpoint''')
parser.add_argument('''--dict_path''', default=None, type=str, help='''Path to dict of fine-tuned model''')
parser.add_argument('''--config_path''', default=None, type=str, help='''Path to hf config.json of model to convert''')
parser.add_argument(
'''--not_finetuned''', action='''store_true''', help='''Whether the model to convert is a fine-tuned model or not'''
)
__lowercase = parser.parse_args()
convert_hubert_checkpoint(
args.checkpoint_path, args.pytorch_dump_folder_path, args.config_path, args.dict_path, not args.not_finetuned
)
| 43
| 0
|
import io
import itertools
import json
from dataclasses import dataclass
from typing import Optional
import pyarrow as pa
import pyarrow.json as paj
import datasets
from datasets.table import table_cast
from datasets.utils.file_utils import readline
_snake_case = datasets.utils.logging.get_logger(__name__)
@dataclass
class lowercase ( datasets.BuilderConfig ):
_a = None
_a = "utf-8"
_a = None
_a = None
_a = True # deprecated
_a = None # deprecated
_a = 1_0 << 2_0 # 10MB
_a = None
class lowercase ( datasets.ArrowBasedBuilder ):
_a = JsonConfig
def a__ ( self ) -> Union[str, Any]:
if self.config.block_size is not None:
logger.warning("""The JSON loader parameter `block_size` is deprecated. Please use `chunksize` instead""" )
_A : Optional[Any] = self.config.block_size
if self.config.use_threads is not True:
logger.warning(
"""The JSON loader parameter `use_threads` is deprecated and doesn't have any effect anymore.""" )
if self.config.newlines_in_values is not None:
raise ValueError("""The JSON loader parameter `newlines_in_values` is no longer supported""" )
return datasets.DatasetInfo(features=self.config.features )
def a__ ( self , _a ) -> Union[str, Any]:
if not self.config.data_files:
raise ValueError(F'''At least one data file must be specified, but got data_files={self.config.data_files}''' )
_A : Optional[Any] = dl_manager.download_and_extract(self.config.data_files )
if isinstance(_a , (str, list, tuple) ):
_A : List[str] = data_files
if isinstance(_a , _a ):
_A : Optional[int] = [files]
_A : str = [dl_manager.iter_files(_a ) for file in files]
return [datasets.SplitGenerator(name=datasets.Split.TRAIN , gen_kwargs={"""files""": files} )]
_A : Tuple = []
for split_name, files in data_files.items():
if isinstance(_a , _a ):
_A : Optional[int] = [files]
_A : Tuple = [dl_manager.iter_files(_a ) for file in files]
splits.append(datasets.SplitGenerator(name=_a , gen_kwargs={"""files""": files} ) )
return splits
def a__ ( self , _a ) -> pa.Table:
if self.config.features is not None:
# adding missing columns
for column_name in set(self.config.features ) - set(pa_table.column_names ):
_A : List[Any] = self.config.features.arrow_schema.field(_a ).type
_A : str = pa_table.append_column(_a , pa.array([None] * len(_a ) , type=_a ) )
# more expensive cast to support nested structures with keys in a different order
# allows str <-> int/float or str to Audio for example
_A : Optional[Any] = table_cast(_a , self.config.features.arrow_schema )
return pa_table
def a__ ( self , _a ) -> Optional[int]:
for file_idx, file in enumerate(itertools.chain.from_iterable(_a ) ):
# If the file is one json object and if we need to look at the list of items in one specific field
if self.config.field is not None:
with open(_a , encoding=self.config.encoding , errors=self.config.encoding_errors ) as f:
_A : Any = json.load(_a )
# We keep only the field we are interested in
_A : Optional[int] = dataset[self.config.field]
# We accept two format: a list of dicts or a dict of lists
if isinstance(_a , (list, tuple) ):
_A : Union[str, Any] = set().union(*[row.keys() for row in dataset] )
_A : Union[str, Any] = {col: [row.get(_a ) for row in dataset] for col in keys}
else:
_A : List[str] = dataset
_A : Optional[Any] = pa.Table.from_pydict(_a )
yield file_idx, self._cast_table(_a )
# If the file has one json object per line
else:
with open(_a , """rb""" ) as f:
_A : Dict = 0
# Use block_size equal to the chunk size divided by 32 to leverage multithreading
# Set a default minimum value of 16kB if the chunk size is really small
_A : List[str] = max(self.config.chunksize // 32 , 16 << 10 )
_A : Any = (
self.config.encoding_errors if self.config.encoding_errors is not None else """strict"""
)
while True:
_A : List[Any] = f.read(self.config.chunksize )
if not batch:
break
# Finish current line
try:
batch += f.readline()
except (AttributeError, io.UnsupportedOperation):
batch += readline(_a )
# PyArrow only accepts utf-8 encoded bytes
if self.config.encoding != "utf-8":
_A : List[str] = batch.decode(self.config.encoding , errors=_a ).encode("""utf-8""" )
try:
while True:
try:
_A : Union[str, Any] = paj.read_json(
io.BytesIO(_a ) , read_options=paj.ReadOptions(block_size=_a ) )
break
except (pa.ArrowInvalid, pa.ArrowNotImplementedError) as e:
if (
isinstance(_a , pa.ArrowInvalid )
and "straddling" not in str(_a )
or block_size > len(_a )
):
raise
else:
# Increase the block size in case it was too small.
# The block size will be reset for the next file.
logger.debug(
F'''Batch of {len(_a )} bytes couldn\'t be parsed with block_size={block_size}. Retrying with block_size={block_size * 2}.''' )
block_size *= 2
except pa.ArrowInvalid as e:
try:
with open(
_a , encoding=self.config.encoding , errors=self.config.encoding_errors ) as f:
_A : List[str] = json.load(_a )
except json.JSONDecodeError:
logger.error(F'''Failed to read file \'{file}\' with error {type(_a )}: {e}''' )
raise e
# If possible, parse the file as a list of json objects and exit the loop
if isinstance(_a , _a ): # list is the only sequence type supported in JSON
try:
_A : str = set().union(*[row.keys() for row in dataset] )
_A : Dict = {col: [row.get(_a ) for row in dataset] for col in keys}
_A : List[Any] = pa.Table.from_pydict(_a )
except (pa.ArrowInvalid, AttributeError) as e:
logger.error(F'''Failed to read file \'{file}\' with error {type(_a )}: {e}''' )
raise ValueError(F'''Not able to read records in the JSON file at {file}.''' ) from None
yield file_idx, self._cast_table(_a )
break
else:
logger.error(F'''Failed to read file \'{file}\' with error {type(_a )}: {e}''' )
raise ValueError(
F'''Not able to read records in the JSON file at {file}. '''
F'''You should probably indicate the field of the JSON file containing your records. '''
F'''This JSON file contain the following fields: {str(list(dataset.keys() ) )}. '''
F'''Select the correct one and provide it as `field=\'XXX\'` to the dataset loading method. ''' ) from None
# Uncomment for debugging (will print the Arrow table size and elements)
# logger.warning(f"pa_table: {pa_table} num rows: {pa_table.num_rows}")
# logger.warning('\n'.join(str(pa_table.slice(i, 1).to_pydict()) for i in range(pa_table.num_rows)))
yield (file_idx, batch_idx), self._cast_table(_a )
batch_idx += 1
| 26
|
import glob
import os
import random
from string import ascii_lowercase, digits
import cva
import numpy as np
# Parrameters
__lowercase = (720, 1280) # Height, Width
__lowercase = (0.4, 0.6) # if height or width lower than this scale, drop it.
__lowercase = 1 / 100
__lowercase = ''''''
__lowercase = ''''''
__lowercase = ''''''
__lowercase = 250
def lowerCamelCase ( ):
'''simple docstring'''
__UpperCamelCase , __UpperCamelCase :List[Any] = get_dataset(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
for index in range(SCREAMING_SNAKE_CASE ):
__UpperCamelCase :Optional[Any] = random.sample(range(len(SCREAMING_SNAKE_CASE ) ) , 4 )
__UpperCamelCase , __UpperCamelCase , __UpperCamelCase :str = update_image_and_anno(
SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , filter_scale=SCREAMING_SNAKE_CASE , )
# Get random string code: '7b7ad245cdff75241935e4dd860f3bad'
__UpperCamelCase :List[Any] = random_chars(32 )
__UpperCamelCase :List[str] = path.split(os.sep )[-1].rsplit('''.''' , 1 )[0]
__UpperCamelCase :Tuple = f"""{OUTPUT_DIR}/{file_name}_MOSAIC_{letter_code}"""
cva.imwrite(f"""{file_root}.jpg""" , SCREAMING_SNAKE_CASE , [cva.IMWRITE_JPEG_QUALITY, 85] )
print(f"""Succeeded {index+1}/{NUMBER_IMAGES} with {file_name}""" )
__UpperCamelCase :Optional[Any] = []
for anno in new_annos:
__UpperCamelCase :int = anno[3] - anno[1]
__UpperCamelCase :Optional[int] = anno[4] - anno[2]
__UpperCamelCase :int = anno[1] + width / 2
__UpperCamelCase :List[str] = anno[2] + height / 2
__UpperCamelCase :str = f"""{anno[0]} {x_center} {y_center} {width} {height}"""
annos_list.append(SCREAMING_SNAKE_CASE )
with open(f"""{file_root}.txt""" , '''w''' ) as outfile:
outfile.write('''\n'''.join(line for line in annos_list ) )
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :str = []
__UpperCamelCase :str = []
for label_file in glob.glob(os.path.join(SCREAMING_SNAKE_CASE , '''*.txt''' ) ):
__UpperCamelCase :Any = label_file.split(os.sep )[-1].rsplit('''.''' , 1 )[0]
with open(SCREAMING_SNAKE_CASE ) as in_file:
__UpperCamelCase :str = in_file.readlines()
__UpperCamelCase :Optional[int] = os.path.join(SCREAMING_SNAKE_CASE , f"""{label_name}.jpg""" )
__UpperCamelCase :int = []
for obj_list in obj_lists:
__UpperCamelCase :Optional[int] = obj_list.rstrip('''\n''' ).split(''' ''' )
__UpperCamelCase :Any = float(obj[1] ) - float(obj[3] ) / 2
__UpperCamelCase :List[str] = float(obj[2] ) - float(obj[4] ) / 2
__UpperCamelCase :Dict = float(obj[1] ) + float(obj[3] ) / 2
__UpperCamelCase :List[str] = float(obj[2] ) + float(obj[4] ) / 2
boxes.append([int(obj[0] ), xmin, ymin, xmax, ymax] )
if not boxes:
continue
img_paths.append(SCREAMING_SNAKE_CASE )
labels.append(SCREAMING_SNAKE_CASE )
return img_paths, labels
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE = 0.0 , ):
'''simple docstring'''
__UpperCamelCase :List[str] = np.zeros([output_size[0], output_size[1], 3] , dtype=np.uinta )
__UpperCamelCase :List[Any] = scale_range[0] + random.random() * (scale_range[1] - scale_range[0])
__UpperCamelCase :int = scale_range[0] + random.random() * (scale_range[1] - scale_range[0])
__UpperCamelCase :Optional[int] = int(scale_x * output_size[1] )
__UpperCamelCase :Any = int(scale_y * output_size[0] )
__UpperCamelCase :List[str] = []
__UpperCamelCase :Dict = []
for i, index in enumerate(SCREAMING_SNAKE_CASE ):
__UpperCamelCase :Any = all_img_list[index]
path_list.append(SCREAMING_SNAKE_CASE )
__UpperCamelCase :Any = all_annos[index]
__UpperCamelCase :Union[str, Any] = cva.imread(SCREAMING_SNAKE_CASE )
if i == 0: # top-left
__UpperCamelCase :str = cva.resize(SCREAMING_SNAKE_CASE , (divid_point_x, divid_point_y) )
__UpperCamelCase :Union[str, Any] = img
for bbox in img_annos:
__UpperCamelCase :Union[str, Any] = bbox[1] * scale_x
__UpperCamelCase :Optional[Any] = bbox[2] * scale_y
__UpperCamelCase :int = bbox[3] * scale_x
__UpperCamelCase :Union[str, Any] = bbox[4] * scale_y
new_anno.append([bbox[0], xmin, ymin, xmax, ymax] )
elif i == 1: # top-right
__UpperCamelCase :str = cva.resize(SCREAMING_SNAKE_CASE , (output_size[1] - divid_point_x, divid_point_y) )
__UpperCamelCase :List[str] = img
for bbox in img_annos:
__UpperCamelCase :str = scale_x + bbox[1] * (1 - scale_x)
__UpperCamelCase :Dict = bbox[2] * scale_y
__UpperCamelCase :Optional[Any] = scale_x + bbox[3] * (1 - scale_x)
__UpperCamelCase :List[Any] = bbox[4] * scale_y
new_anno.append([bbox[0], xmin, ymin, xmax, ymax] )
elif i == 2: # bottom-left
__UpperCamelCase :str = cva.resize(SCREAMING_SNAKE_CASE , (divid_point_x, output_size[0] - divid_point_y) )
__UpperCamelCase :Optional[int] = img
for bbox in img_annos:
__UpperCamelCase :Tuple = bbox[1] * scale_x
__UpperCamelCase :Optional[Any] = scale_y + bbox[2] * (1 - scale_y)
__UpperCamelCase :Tuple = bbox[3] * scale_x
__UpperCamelCase :Dict = scale_y + bbox[4] * (1 - scale_y)
new_anno.append([bbox[0], xmin, ymin, xmax, ymax] )
else: # bottom-right
__UpperCamelCase :Optional[int] = cva.resize(
SCREAMING_SNAKE_CASE , (output_size[1] - divid_point_x, output_size[0] - divid_point_y) )
__UpperCamelCase :Optional[int] = img
for bbox in img_annos:
__UpperCamelCase :Optional[Any] = scale_x + bbox[1] * (1 - scale_x)
__UpperCamelCase :Optional[int] = scale_y + bbox[2] * (1 - scale_y)
__UpperCamelCase :Optional[Any] = scale_x + bbox[3] * (1 - scale_x)
__UpperCamelCase :int = scale_y + bbox[4] * (1 - scale_y)
new_anno.append([bbox[0], xmin, ymin, xmax, ymax] )
# Remove bounding box small than scale of filter
if filter_scale > 0:
__UpperCamelCase :List[Any] = [
anno
for anno in new_anno
if filter_scale < (anno[3] - anno[1]) and filter_scale < (anno[4] - anno[2])
]
return output_img, new_anno, path_list[0]
def lowerCamelCase ( SCREAMING_SNAKE_CASE ):
'''simple docstring'''
assert number_char > 1, "The number of character should greater than 1"
__UpperCamelCase :Optional[Any] = ascii_lowercase + digits
return "".join(random.choice(SCREAMING_SNAKE_CASE ) for _ in range(SCREAMING_SNAKE_CASE ) )
if __name__ == "__main__":
main()
print('''DONE ✅''')
| 43
| 0
|
'''simple docstring'''
from math import factorial
def lowerCamelCase (_SCREAMING_SNAKE_CASE : int , _SCREAMING_SNAKE_CASE : int ):
# If either of the conditions are true, the function is being asked
# to calculate a factorial of a negative number, which is not possible
if n < k or k < 0:
raise ValueError('Please enter positive integers for n and k where n >= k' )
return factorial(_SCREAMING_SNAKE_CASE ) // (factorial(_SCREAMING_SNAKE_CASE ) * factorial(n - k ))
if __name__ == "__main__":
print(
'The number of five-card hands possible from a standard',
f'''fifty-two card deck is: {combinations(52, 5)}\n''',
)
print(
'If a class of 40 students must be arranged into groups of',
f'''4 for group projects, there are {combinations(40, 4)} ways''',
'to arrange them.\n',
)
print(
'If 10 teams are competing in a Formula One race, there',
f'''are {combinations(10, 3)} ways that first, second and''',
'third place can be awarded.',
)
| 27
|
import functools
import operator
from ...configuration_utils import PretrainedConfig
from ...utils import logging
__lowercase = logging.get_logger(__name__)
__lowercase = {
'''facebook/wav2vec2-base-960h''': '''https://huggingface.co/facebook/wav2vec2-base-960h/resolve/main/config.json''',
# See all Wav2Vec2 models at https://huggingface.co/models?filter=wav2vec2
}
class lowerCamelCase_ ( UpperCAmelCase_ ):
'''simple docstring'''
a__ : Union[str, Any] = """wav2vec2"""
def __init__( self , __lowercase=32 , __lowercase=768 , __lowercase=12 , __lowercase=12 , __lowercase=3_072 , __lowercase="gelu" , __lowercase=0.1 , __lowercase=0.1 , __lowercase=0.1 , __lowercase=0.0 , __lowercase=0.0 , __lowercase=0.1 , __lowercase=0.1 , __lowercase=0.02 , __lowercase=1E-5 , __lowercase="group" , __lowercase="gelu" , __lowercase=(512, 512, 512, 512, 512, 512, 512) , __lowercase=(5, 2, 2, 2, 2, 2, 2) , __lowercase=(10, 3, 3, 3, 3, 2, 2) , __lowercase=False , __lowercase=128 , __lowercase=16 , __lowercase=False , __lowercase=True , __lowercase=0.05 , __lowercase=10 , __lowercase=2 , __lowercase=0.0 , __lowercase=10 , __lowercase=0 , __lowercase=320 , __lowercase=2 , __lowercase=0.1 , __lowercase=100 , __lowercase=256 , __lowercase=256 , __lowercase=0.1 , __lowercase="sum" , __lowercase=False , __lowercase=False , __lowercase=256 , __lowercase=(512, 512, 512, 512, 1_500) , __lowercase=(5, 3, 3, 1, 1) , __lowercase=(1, 2, 3, 1, 1) , __lowercase=512 , __lowercase=0 , __lowercase=1 , __lowercase=2 , __lowercase=False , __lowercase=3 , __lowercase=2 , __lowercase=3 , __lowercase=None , __lowercase=None , **__lowercase , ) -> int:
super().__init__(**__lowercase , pad_token_id=__lowercase , bos_token_id=__lowercase , eos_token_id=__lowercase)
__UpperCamelCase :Any = hidden_size
__UpperCamelCase :int = feat_extract_norm
__UpperCamelCase :Tuple = feat_extract_activation
__UpperCamelCase :Union[str, Any] = list(__lowercase)
__UpperCamelCase :List[Any] = list(__lowercase)
__UpperCamelCase :int = list(__lowercase)
__UpperCamelCase :List[Any] = conv_bias
__UpperCamelCase :Optional[int] = num_conv_pos_embeddings
__UpperCamelCase :Dict = num_conv_pos_embedding_groups
__UpperCamelCase :Any = len(self.conv_dim)
__UpperCamelCase :List[str] = num_hidden_layers
__UpperCamelCase :int = intermediate_size
__UpperCamelCase :str = hidden_act
__UpperCamelCase :Any = num_attention_heads
__UpperCamelCase :int = hidden_dropout
__UpperCamelCase :Tuple = attention_dropout
__UpperCamelCase :List[str] = activation_dropout
__UpperCamelCase :Optional[Any] = feat_proj_dropout
__UpperCamelCase :Any = final_dropout
__UpperCamelCase :Any = layerdrop
__UpperCamelCase :str = layer_norm_eps
__UpperCamelCase :Optional[Any] = initializer_range
__UpperCamelCase :List[str] = vocab_size
__UpperCamelCase :str = do_stable_layer_norm
__UpperCamelCase :Union[str, Any] = use_weighted_layer_sum
if (
(len(self.conv_stride) != self.num_feat_extract_layers)
or (len(self.conv_kernel) != self.num_feat_extract_layers)
or (len(self.conv_dim) != self.num_feat_extract_layers)
):
raise ValueError(
'''Configuration for convolutional layers is incorrect. It is required that `len(config.conv_dim)` =='''
''' `len(config.conv_stride)` == `len(config.conv_kernel)`, but is `len(config.conv_dim) ='''
f""" {len(self.conv_dim)}`, `len(config.conv_stride) = {len(self.conv_stride)}`,"""
f""" `len(config.conv_kernel) = {len(self.conv_kernel)}`.""")
# fine-tuning config parameters for SpecAugment: https://arxiv.org/abs/1904.08779
__UpperCamelCase :List[Any] = apply_spec_augment
__UpperCamelCase :Tuple = mask_time_prob
__UpperCamelCase :int = mask_time_length
__UpperCamelCase :Dict = mask_time_min_masks
__UpperCamelCase :str = mask_feature_prob
__UpperCamelCase :List[str] = mask_feature_length
__UpperCamelCase :Union[str, Any] = mask_feature_min_masks
# parameters for pretraining with codevector quantized representations
__UpperCamelCase :Optional[Any] = num_codevectors_per_group
__UpperCamelCase :List[Any] = num_codevector_groups
__UpperCamelCase :Tuple = contrastive_logits_temperature
__UpperCamelCase :Optional[int] = feat_quantizer_dropout
__UpperCamelCase :Optional[int] = num_negatives
__UpperCamelCase :List[Any] = codevector_dim
__UpperCamelCase :str = proj_codevector_dim
__UpperCamelCase :List[str] = diversity_loss_weight
# ctc loss
__UpperCamelCase :Tuple = ctc_loss_reduction
__UpperCamelCase :Tuple = ctc_zero_infinity
# adapter
__UpperCamelCase :List[str] = add_adapter
__UpperCamelCase :Tuple = adapter_kernel_size
__UpperCamelCase :str = adapter_stride
__UpperCamelCase :Tuple = num_adapter_layers
__UpperCamelCase :Tuple = output_hidden_size or hidden_size
__UpperCamelCase :Optional[Any] = adapter_attn_dim
# SequenceClassification-specific parameter. Feel free to ignore for other classes.
__UpperCamelCase :Optional[Any] = classifier_proj_size
# XVector-specific parameters. Feel free to ignore for other classes.
__UpperCamelCase :Optional[int] = list(__lowercase)
__UpperCamelCase :List[Any] = list(__lowercase)
__UpperCamelCase :List[Any] = list(__lowercase)
__UpperCamelCase :str = xvector_output_dim
@property
def UpperCamelCase__ ( self) -> List[str]:
return functools.reduce(operator.mul , self.conv_stride , 1)
| 43
| 0
|
'''simple docstring'''
from abc import ABC, abstractmethod
from argparse import ArgumentParser
class SCREAMING_SNAKE_CASE ( _a ):
"""simple docstring"""
@staticmethod
@abstractmethod
def A ( UpperCamelCase__ : ArgumentParser ):
"""simple docstring"""
raise NotImplementedError()
@abstractmethod
def A ( self : Any ):
"""simple docstring"""
raise NotImplementedError()
| 28
|
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
__lowercase = logging.get_logger(__name__)
class lowerCamelCase_ ( UpperCAmelCase_ ):
'''simple docstring'''
a__ : Optional[Any] = ["""pixel_values"""]
def __init__( self , __lowercase = True , __lowercase = 32 , __lowercase=PILImageResampling.BILINEAR , __lowercase = True , **__lowercase , ) -> None:
__UpperCamelCase :Optional[int] = do_resize
__UpperCamelCase :Any = do_rescale
__UpperCamelCase :str = size_divisor
__UpperCamelCase :Dict = resample
super().__init__(**__lowercase)
def UpperCamelCase__ ( self , __lowercase , __lowercase , __lowercase , __lowercase = None , **__lowercase) -> np.ndarray:
__UpperCamelCase , __UpperCamelCase :int = get_image_size(__lowercase)
# Rounds the height and width down to the closest multiple of size_divisor
__UpperCamelCase :List[Any] = height // size_divisor * size_divisor
__UpperCamelCase :List[str] = width // size_divisor * size_divisor
__UpperCamelCase :str = resize(__lowercase , (new_h, new_w) , resample=__lowercase , data_format=__lowercase , **__lowercase)
return image
def UpperCamelCase__ ( self , __lowercase , __lowercase , __lowercase = None , **__lowercase) -> np.ndarray:
return rescale(image=__lowercase , scale=__lowercase , data_format=__lowercase , **__lowercase)
def UpperCamelCase__ ( self , __lowercase , __lowercase = None , __lowercase = None , __lowercase=None , __lowercase = None , __lowercase = None , __lowercase = ChannelDimension.FIRST , **__lowercase , ) -> BatchFeature:
__UpperCamelCase :Union[str, Any] = do_resize if do_resize is not None else self.do_resize
__UpperCamelCase :Tuple = do_rescale if do_rescale is not None else self.do_rescale
__UpperCamelCase :List[str] = size_divisor if size_divisor is not None else self.size_divisor
__UpperCamelCase :List[Any] = 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''')
__UpperCamelCase :List[Any] = make_list_of_images(__lowercase)
if not valid_images(__lowercase):
raise ValueError('''Invalid image(s)''')
# All transformations expect numpy arrays.
__UpperCamelCase :Optional[Any] = [to_numpy_array(__lowercase) for img in images]
if do_resize:
__UpperCamelCase :List[str] = [self.resize(__lowercase , size_divisor=__lowercase , resample=__lowercase) for image in images]
if do_rescale:
__UpperCamelCase :Dict = [self.rescale(__lowercase , scale=1 / 255) for image in images]
__UpperCamelCase :str = [to_channel_dimension_format(__lowercase , __lowercase) for image in images]
__UpperCamelCase :int = {'''pixel_values''': images}
return BatchFeature(data=__lowercase , tensor_type=__lowercase)
| 43
| 0
|
import logging
import numpy as np
import pytest
from scipy.linalg import eigh
logging.basicConfig(level=logging.INFO, format='%(message)s')
def lowercase__ ( __snake_case : np.ndarray ):
'''simple docstring'''
return input_array.reshape((input_array.size, 1) )
def lowercase__ ( __snake_case : np.ndarray , __snake_case : np.ndarray , __snake_case : int ):
'''simple docstring'''
UpperCAmelCase_ : Union[str, Any] = np.nan
for i in range(__snake_case ):
UpperCAmelCase_ : Any = features[:, labels == i]
UpperCAmelCase_ : Tuple = data.mean(1 )
# Centralize the data of class i
UpperCAmelCase_ : List[str] = data - column_reshape(__snake_case )
if i > 0:
# If covariance_sum is not None
covariance_sum += np.dot(__snake_case , centered_data.T )
else:
# If covariance_sum is np.nan (i.e. first loop)
UpperCAmelCase_ : Optional[Any] = np.dot(__snake_case , centered_data.T )
return covariance_sum / features.shape[1]
def lowercase__ ( __snake_case : np.ndarray , __snake_case : np.ndarray , __snake_case : int ):
'''simple docstring'''
UpperCAmelCase_ : List[str] = features.mean(1 )
UpperCAmelCase_ : Tuple = np.nan
for i in range(__snake_case ):
UpperCAmelCase_ : Tuple = features[:, labels == i]
UpperCAmelCase_ : Union[str, Any] = data.shape[1]
UpperCAmelCase_ : List[str] = data.mean(1 )
if i > 0:
# If covariance_sum is not None
covariance_sum += device_data * np.dot(
column_reshape(__snake_case ) - column_reshape(__snake_case ) , (column_reshape(__snake_case ) - column_reshape(__snake_case )).T , )
else:
# If covariance_sum is np.nan (i.e. first loop)
UpperCAmelCase_ : Any = device_data * np.dot(
column_reshape(__snake_case ) - column_reshape(__snake_case ) , (column_reshape(__snake_case ) - column_reshape(__snake_case )).T , )
return covariance_sum / features.shape[1]
def lowercase__ ( __snake_case : np.ndarray , __snake_case : int ):
'''simple docstring'''
if features.any():
UpperCAmelCase_ : int = features.mean(1 )
# Center the dataset
UpperCAmelCase_ : Optional[int] = features - np.reshape(__snake_case , (data_mean.size, 1) )
UpperCAmelCase_ : int = np.dot(__snake_case , centered_data.T ) / features.shape[1]
UpperCAmelCase_ , UpperCAmelCase_ : List[str] = np.linalg.eigh(__snake_case )
# Take all the columns in the reverse order (-1), and then takes only the first
UpperCAmelCase_ : Optional[int] = eigenvectors[:, ::-1][:, 0:dimensions]
# Project the database on the new space
UpperCAmelCase_ : Optional[Any] = np.dot(filtered_eigenvectors.T , __snake_case )
logging.info('Principal Component Analysis computed' )
return projected_data
else:
logging.basicConfig(level=logging.ERROR , format='%(message)s' , force=__snake_case )
logging.error('Dataset empty' )
raise AssertionError
def lowercase__ ( __snake_case : np.ndarray , __snake_case : np.ndarray , __snake_case : int , __snake_case : int ):
'''simple docstring'''
assert classes > dimensions
# Check if features have been already loaded
if features.any:
UpperCAmelCase_ , UpperCAmelCase_ : List[Any] = eigh(
covariance_between_classes(__snake_case , __snake_case , __snake_case ) , covariance_within_classes(__snake_case , __snake_case , __snake_case ) , )
UpperCAmelCase_ : Tuple = eigenvectors[:, ::-1][:, :dimensions]
UpperCAmelCase_ , UpperCAmelCase_ , UpperCAmelCase_ : Optional[Any] = np.linalg.svd(__snake_case )
UpperCAmelCase_ : List[str] = svd_matrix[:, 0:dimensions]
UpperCAmelCase_ : Dict = np.dot(filtered_svd_matrix.T , __snake_case )
logging.info('Linear Discriminant Analysis computed' )
return projected_data
else:
logging.basicConfig(level=logging.ERROR , format='%(message)s' , force=__snake_case )
logging.error('Dataset empty' )
raise AssertionError
def lowercase__ ( ):
'''simple docstring'''
UpperCAmelCase_ : Union[str, Any] = np.array([[1, 2, 3, 4, 5], [2, 3, 4, 5, 6], [3, 4, 5, 6, 7]] )
UpperCAmelCase_ : Any = np.array([0, 0, 0, 1, 1] )
UpperCAmelCase_ : Optional[int] = 2
UpperCAmelCase_ : Dict = 2
# Assert that the function raises an AssertionError if dimensions > classes
with pytest.raises(__snake_case ) as error_info:
UpperCAmelCase_ : Union[str, Any] = linear_discriminant_analysis(
__snake_case , __snake_case , __snake_case , __snake_case )
if isinstance(__snake_case , np.ndarray ):
raise AssertionError(
'Did not raise AssertionError for dimensions > classes' )
assert error_info.type is AssertionError
def lowercase__ ( ):
'''simple docstring'''
UpperCAmelCase_ : str = np.array([[1, 2, 3], [4, 5, 6], [7, 8, 9]] )
UpperCAmelCase_ : Optional[Any] = 2
UpperCAmelCase_ : Optional[Any] = np.array([[6.92820323, 8.66025404, 10.39230485], [3.0, 3.0, 3.0]] )
with pytest.raises(__snake_case ) as error_info:
UpperCAmelCase_ : Dict = principal_component_analysis(__snake_case , __snake_case )
if not np.allclose(__snake_case , __snake_case ):
raise AssertionError
assert error_info.type is AssertionError
if __name__ == "__main__":
import doctest
doctest.testmod()
| 29
|
from __future__ import annotations
from PIL import Image
# Define glider example
__lowercase = [
[0, 1, 0, 0, 0, 0, 0, 0],
[0, 0, 1, 0, 0, 0, 0, 0],
[1, 1, 1, 0, 0, 0, 0, 0],
[0, 0, 0, 0, 0, 0, 0, 0],
[0, 0, 0, 0, 0, 0, 0, 0],
[0, 0, 0, 0, 0, 0, 0, 0],
[0, 0, 0, 0, 0, 0, 0, 0],
[0, 0, 0, 0, 0, 0, 0, 0],
]
# Define blinker example
__lowercase = [[0, 1, 0], [0, 1, 0], [0, 1, 0]]
def lowerCamelCase ( SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :int = []
for i in range(len(SCREAMING_SNAKE_CASE ) ):
__UpperCamelCase :Dict = []
for j in range(len(cells[i] ) ):
# Get the number of live neighbours
__UpperCamelCase :List[str] = 0
if i > 0 and j > 0:
neighbour_count += cells[i - 1][j - 1]
if i > 0:
neighbour_count += cells[i - 1][j]
if i > 0 and j < len(cells[i] ) - 1:
neighbour_count += cells[i - 1][j + 1]
if j > 0:
neighbour_count += cells[i][j - 1]
if j < len(cells[i] ) - 1:
neighbour_count += cells[i][j + 1]
if i < len(SCREAMING_SNAKE_CASE ) - 1 and j > 0:
neighbour_count += cells[i + 1][j - 1]
if i < len(SCREAMING_SNAKE_CASE ) - 1:
neighbour_count += cells[i + 1][j]
if i < len(SCREAMING_SNAKE_CASE ) - 1 and j < len(cells[i] ) - 1:
neighbour_count += cells[i + 1][j + 1]
# Rules of the game of life (excerpt from Wikipedia):
# 1. Any live cell with two or three live neighbours survives.
# 2. Any dead cell with three live neighbours becomes a live cell.
# 3. All other live cells die in the next generation.
# Similarly, all other dead cells stay dead.
__UpperCamelCase :List[str] = cells[i][j] == 1
if (
(alive and 2 <= neighbour_count <= 3)
or not alive
and neighbour_count == 3
):
next_generation_row.append(1 )
else:
next_generation_row.append(0 )
next_generation.append(SCREAMING_SNAKE_CASE )
return next_generation
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Optional[Any] = []
for _ in range(SCREAMING_SNAKE_CASE ):
# Create output image
__UpperCamelCase :Dict = Image.new('''RGB''' , (len(cells[0] ), len(SCREAMING_SNAKE_CASE )) )
__UpperCamelCase :Any = img.load()
# Save cells to image
for x in range(len(SCREAMING_SNAKE_CASE ) ):
for y in range(len(cells[0] ) ):
__UpperCamelCase :Optional[Any] = 255 - cells[y][x] * 255
__UpperCamelCase :int = (colour, colour, colour)
# Save image
images.append(SCREAMING_SNAKE_CASE )
__UpperCamelCase :Optional[int] = new_generation(SCREAMING_SNAKE_CASE )
return images
if __name__ == "__main__":
__lowercase = generate_images(GLIDER, 16)
images[0].save('''out.gif''', save_all=True, append_images=images[1:])
| 43
| 0
|
import copy
import os
from typing import Union
from ...configuration_utils import PretrainedConfig
from ...utils import logging
__a = logging.get_logger(__name__)
__a = {
'BAAI/AltCLIP': 'https://huggingface.co/BAAI/AltCLIP/resolve/main/config.json',
# See all AltCLIP models at https://huggingface.co/models?filter=altclip
}
class lowercase__( UpperCAmelCase ):
"""simple docstring"""
a :str = 'altclip_text_model'
def __init__( self : Union[str, Any] , SCREAMING_SNAKE_CASE_ : Union[str, Any]=2_5_0_0_0_2 , SCREAMING_SNAKE_CASE_ : int=1_0_2_4 , SCREAMING_SNAKE_CASE_ : Union[str, Any]=2_4 , SCREAMING_SNAKE_CASE_ : Tuple=1_6 , SCREAMING_SNAKE_CASE_ : Union[str, Any]=4_0_9_6 , SCREAMING_SNAKE_CASE_ : str="gelu" , SCREAMING_SNAKE_CASE_ : Dict=0.1 , SCREAMING_SNAKE_CASE_ : str=0.1 , SCREAMING_SNAKE_CASE_ : List[str]=5_1_4 , SCREAMING_SNAKE_CASE_ : Union[str, Any]=1 , SCREAMING_SNAKE_CASE_ : Any=0.02 , SCREAMING_SNAKE_CASE_ : Optional[Any]=0.02 , SCREAMING_SNAKE_CASE_ : str=1e-05 , SCREAMING_SNAKE_CASE_ : List[str]=1 , SCREAMING_SNAKE_CASE_ : str=0 , SCREAMING_SNAKE_CASE_ : Dict=2 , SCREAMING_SNAKE_CASE_ : int="absolute" , SCREAMING_SNAKE_CASE_ : Tuple=True , SCREAMING_SNAKE_CASE_ : Optional[Any]=7_6_8 , **SCREAMING_SNAKE_CASE_ : int , ) -> Any:
super().__init__(pad_token_id=SCREAMING_SNAKE_CASE_ , bos_token_id=SCREAMING_SNAKE_CASE_ , eos_token_id=SCREAMING_SNAKE_CASE_ , **SCREAMING_SNAKE_CASE_ )
lowercase_ = vocab_size
lowercase_ = hidden_size
lowercase_ = num_hidden_layers
lowercase_ = num_attention_heads
lowercase_ = hidden_act
lowercase_ = intermediate_size
lowercase_ = hidden_dropout_prob
lowercase_ = attention_probs_dropout_prob
lowercase_ = max_position_embeddings
lowercase_ = type_vocab_size
lowercase_ = initializer_range
lowercase_ = initializer_factor
lowercase_ = layer_norm_eps
lowercase_ = position_embedding_type
lowercase_ = use_cache
lowercase_ = project_dim
class lowercase__( UpperCAmelCase ):
"""simple docstring"""
a :Tuple = 'altclip_vision_model'
def __init__( self : List[str] , SCREAMING_SNAKE_CASE_ : List[Any]=7_6_8 , SCREAMING_SNAKE_CASE_ : Dict=3_0_7_2 , SCREAMING_SNAKE_CASE_ : List[Any]=5_1_2 , SCREAMING_SNAKE_CASE_ : Optional[Any]=1_2 , SCREAMING_SNAKE_CASE_ : List[Any]=1_2 , SCREAMING_SNAKE_CASE_ : Dict=3 , SCREAMING_SNAKE_CASE_ : Optional[int]=2_2_4 , SCREAMING_SNAKE_CASE_ : List[str]=3_2 , SCREAMING_SNAKE_CASE_ : Tuple="quick_gelu" , SCREAMING_SNAKE_CASE_ : Dict=1e-5 , SCREAMING_SNAKE_CASE_ : Dict=0.0 , SCREAMING_SNAKE_CASE_ : Dict=0.02 , SCREAMING_SNAKE_CASE_ : Tuple=1.0 , **SCREAMING_SNAKE_CASE_ : str , ) -> str:
super().__init__(**SCREAMING_SNAKE_CASE_ )
lowercase_ = hidden_size
lowercase_ = intermediate_size
lowercase_ = projection_dim
lowercase_ = num_hidden_layers
lowercase_ = num_attention_heads
lowercase_ = num_channels
lowercase_ = patch_size
lowercase_ = image_size
lowercase_ = initializer_range
lowercase_ = initializer_factor
lowercase_ = attention_dropout
lowercase_ = layer_norm_eps
lowercase_ = hidden_act
@classmethod
def _lowercase ( cls : Dict , SCREAMING_SNAKE_CASE_ : Union[str, os.PathLike] , **SCREAMING_SNAKE_CASE_ : Optional[Any] ) -> "PretrainedConfig":
cls._set_token_in_kwargs(SCREAMING_SNAKE_CASE_ )
lowercase_ , lowercase_ = cls.get_config_dict(SCREAMING_SNAKE_CASE_ , **SCREAMING_SNAKE_CASE_ )
# get the vision config dict if we are loading from AltCLIPConfig
if config_dict.get('''model_type''' ) == "altclip":
lowercase_ = config_dict['''vision_config''']
if "model_type" in config_dict and hasattr(cls , '''model_type''' ) and config_dict["model_type"] != cls.model_type:
logger.warning(
f'''You are using a model of type {config_dict['model_type']} to instantiate a model of type '''
f'''{cls.model_type}. This is not supported for all configurations of models and can yield errors.''' )
return cls.from_dict(SCREAMING_SNAKE_CASE_ , **SCREAMING_SNAKE_CASE_ )
class lowercase__( UpperCAmelCase ):
"""simple docstring"""
a :Any = 'altclip'
a :List[str] = True
def __init__( self : List[Any] , SCREAMING_SNAKE_CASE_ : int=None , SCREAMING_SNAKE_CASE_ : List[Any]=None , SCREAMING_SNAKE_CASE_ : List[str]=7_6_8 , SCREAMING_SNAKE_CASE_ : Dict=2.65_92 , **SCREAMING_SNAKE_CASE_ : List[Any] ) -> List[str]:
# If `_config_dict` exist, we use them for the backward compatibility.
# We pop out these 2 attributes before calling `super().__init__` to avoid them being saved (which causes a lot
# of confusion!).
lowercase_ = kwargs.pop('''text_config_dict''' , SCREAMING_SNAKE_CASE_ )
lowercase_ = kwargs.pop('''vision_config_dict''' , SCREAMING_SNAKE_CASE_ )
super().__init__(**SCREAMING_SNAKE_CASE_ )
# Instead of simply assigning `[text|vision]_config_dict` to `[text|vision]_config`, we use the values in
# `[text|vision]_config_dict` to update the values in `[text|vision]_config`. The values should be same in most
# cases, but we don't want to break anything regarding `_config_dict` that existed before commit `8827e1b2`.
if text_config_dict is not None:
if text_config is None:
lowercase_ = {}
# This is the complete result when using `text_config_dict`.
lowercase_ = AltCLIPTextConfig(**SCREAMING_SNAKE_CASE_ ).to_dict()
# Give a warning if the values exist in both `_text_config_dict` and `text_config` but being different.
for key, value in _text_config_dict.items():
if key in text_config and value != text_config[key] and key not in ["transformers_version"]:
# If specified in `text_config_dict`
if key in text_config_dict:
lowercase_ = (
f'''`{key}` is found in both `text_config_dict` and `text_config` but with different values. '''
f'''The value `text_config_dict["{key}"]` will be used instead.'''
)
# If inferred from default argument values (just to be super careful)
else:
lowercase_ = (
f'''`text_config_dict` is provided which will be used to initialize `AltCLIPTextConfig`. The '''
f'''value `text_config["{key}"]` will be overriden.'''
)
logger.warning(SCREAMING_SNAKE_CASE_ )
# Update all values in `text_config` with the ones in `_text_config_dict`.
text_config.update(_text_config_dict )
if vision_config_dict is not None:
if vision_config is None:
lowercase_ = {}
# This is the complete result when using `vision_config_dict`.
lowercase_ = AltCLIPVisionConfig(**SCREAMING_SNAKE_CASE_ ).to_dict()
# convert keys to string instead of integer
if "id2label" in _vision_config_dict:
lowercase_ = {
str(SCREAMING_SNAKE_CASE_ ): value for key, value in _vision_config_dict['''id2label'''].items()
}
# Give a warning if the values exist in both `_vision_config_dict` and `vision_config` but being different.
for key, value in _vision_config_dict.items():
if key in vision_config and value != vision_config[key] and key not in ["transformers_version"]:
# If specified in `vision_config_dict`
if key in vision_config_dict:
lowercase_ = (
f'''`{key}` is found in both `vision_config_dict` and `vision_config` but with different '''
f'''values. The value `vision_config_dict["{key}"]` will be used instead.'''
)
# If inferred from default argument values (just to be super careful)
else:
lowercase_ = (
f'''`vision_config_dict` is provided which will be used to initialize `AltCLIPVisionConfig`. '''
f'''The value `vision_config["{key}"]` will be overriden.'''
)
logger.warning(SCREAMING_SNAKE_CASE_ )
# Update all values in `vision_config` with the ones in `_vision_config_dict`.
vision_config.update(_vision_config_dict )
if text_config is None:
lowercase_ = {}
logger.info('''`text_config` is `None`. Initializing the `AltCLIPTextConfig` with default values.''' )
if vision_config is None:
lowercase_ = {}
logger.info('''`vision_config` is `None`. initializing the `AltCLIPVisionConfig` with default values.''' )
lowercase_ = AltCLIPTextConfig(**SCREAMING_SNAKE_CASE_ )
lowercase_ = AltCLIPVisionConfig(**SCREAMING_SNAKE_CASE_ )
lowercase_ = projection_dim
lowercase_ = logit_scale_init_value
lowercase_ = 1.0
@classmethod
def _lowercase ( cls : Union[str, Any] , SCREAMING_SNAKE_CASE_ : AltCLIPTextConfig , SCREAMING_SNAKE_CASE_ : AltCLIPVisionConfig , **SCREAMING_SNAKE_CASE_ : Any ) -> List[Any]:
return cls(text_config=text_config.to_dict() , vision_config=vision_config.to_dict() , **SCREAMING_SNAKE_CASE_ )
def _lowercase ( self : Union[str, Any] ) -> Dict:
lowercase_ = copy.deepcopy(self.__dict__ )
lowercase_ = self.text_config.to_dict()
lowercase_ = self.vision_config.to_dict()
lowercase_ = self.__class__.model_type
return output
| 30
|
import re
import jax.numpy as jnp
from flax.traverse_util import flatten_dict, unflatten_dict
from jax.random import PRNGKey
from ..utils import logging
__lowercase = logging.get_logger(__name__)
def lowerCamelCase ( SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Tuple = R'''\w+[.]\d+'''
__UpperCamelCase :List[str] = re.findall(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
for pat in pats:
__UpperCamelCase :int = key.replace(SCREAMING_SNAKE_CASE , '''_'''.join(pat.split('''.''' ) ) )
return key
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Tuple = pt_tuple_key[:-1] + ('''scale''',)
if (
any('''norm''' in str_ for str_ in pt_tuple_key )
and (pt_tuple_key[-1] == "bias")
and (pt_tuple_key[:-1] + ("bias",) not in random_flax_state_dict)
and (pt_tuple_key[:-1] + ("scale",) in random_flax_state_dict)
):
__UpperCamelCase :str = pt_tuple_key[:-1] + ('''scale''',)
return renamed_pt_tuple_key, pt_tensor
elif pt_tuple_key[-1] in ["weight", "gamma"] and pt_tuple_key[:-1] + ("scale",) in random_flax_state_dict:
__UpperCamelCase :Any = pt_tuple_key[:-1] + ('''scale''',)
return renamed_pt_tuple_key, pt_tensor
# embedding
if pt_tuple_key[-1] == "weight" and pt_tuple_key[:-1] + ("embedding",) in random_flax_state_dict:
__UpperCamelCase :str = pt_tuple_key[:-1] + ('''embedding''',)
return renamed_pt_tuple_key, pt_tensor
# conv layer
__UpperCamelCase :List[str] = pt_tuple_key[:-1] + ('''kernel''',)
if pt_tuple_key[-1] == "weight" and pt_tensor.ndim == 4:
__UpperCamelCase :List[Any] = pt_tensor.transpose(2 , 3 , 1 , 0 )
return renamed_pt_tuple_key, pt_tensor
# linear layer
__UpperCamelCase :List[str] = pt_tuple_key[:-1] + ('''kernel''',)
if pt_tuple_key[-1] == "weight":
__UpperCamelCase :Any = pt_tensor.T
return renamed_pt_tuple_key, pt_tensor
# old PyTorch layer norm weight
__UpperCamelCase :int = pt_tuple_key[:-1] + ('''weight''',)
if pt_tuple_key[-1] == "gamma":
return renamed_pt_tuple_key, pt_tensor
# old PyTorch layer norm bias
__UpperCamelCase :int = pt_tuple_key[:-1] + ('''bias''',)
if pt_tuple_key[-1] == "beta":
return renamed_pt_tuple_key, pt_tensor
return pt_tuple_key, pt_tensor
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE=42 ):
'''simple docstring'''
__UpperCamelCase :Union[str, Any] = {k: v.numpy() for k, v in pt_state_dict.items()}
# Step 2: Since the model is stateless, get random Flax params
__UpperCamelCase :str = flax_model.init_weights(PRNGKey(SCREAMING_SNAKE_CASE ) )
__UpperCamelCase :int = flatten_dict(SCREAMING_SNAKE_CASE )
__UpperCamelCase :List[Any] = {}
# Need to change some parameters name to match Flax names
for pt_key, pt_tensor in pt_state_dict.items():
__UpperCamelCase :List[Any] = rename_key(SCREAMING_SNAKE_CASE )
__UpperCamelCase :List[Any] = tuple(renamed_pt_key.split('''.''' ) )
# Correctly rename weight parameters
__UpperCamelCase , __UpperCamelCase :Any = rename_key_and_reshape_tensor(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
if flax_key in random_flax_state_dict:
if flax_tensor.shape != random_flax_state_dict[flax_key].shape:
raise ValueError(
f"""PyTorch checkpoint seems to be incorrect. Weight {pt_key} was expected to be of shape """
f"""{random_flax_state_dict[flax_key].shape}, but is {flax_tensor.shape}.""" )
# also add unexpected weight so that warning is thrown
__UpperCamelCase :str = jnp.asarray(SCREAMING_SNAKE_CASE )
return unflatten_dict(SCREAMING_SNAKE_CASE )
| 43
| 0
|
'''simple docstring'''
import unittest
import numpy as np
import timeout_decorator # noqa
from transformers import BlenderbotSmallConfig, is_flax_available
from transformers.testing_utils import require_flax, slow
from ...generation.test_flax_utils import FlaxGenerationTesterMixin
from ...test_modeling_flax_common import FlaxModelTesterMixin, ids_tensor
if is_flax_available():
import os
# The slow tests are often failing with OOM error on GPU
# This makes JAX allocate exactly what is needed on demand, and deallocate memory that is no longer needed
# but will be slower as stated here https://jax.readthedocs.io/en/latest/gpu_memory_allocation.html
__SCREAMING_SNAKE_CASE : List[str] = """platform"""
import jax
import jax.numpy as jnp
from transformers.models.blenderbot_small.modeling_flax_blenderbot_small import (
FlaxBlenderbotSmallForConditionalGeneration,
FlaxBlenderbotSmallModel,
shift_tokens_right,
)
def UpperCamelCase_ ( _UpperCAmelCase : Dict , _UpperCAmelCase : Any , _UpperCAmelCase : List[Any]=None , _UpperCAmelCase : str=None , _UpperCAmelCase : Tuple=None , _UpperCAmelCase : Tuple=None , _UpperCAmelCase : List[str]=None , _UpperCAmelCase : List[str]=None , ) -> Dict:
"""simple docstring"""
if attention_mask is None:
_UpperCAmelCase : List[str] = np.where(input_ids != config.pad_token_id , 1 , 0 )
if decoder_attention_mask is None:
_UpperCAmelCase : Union[str, Any] = np.where(decoder_input_ids != config.pad_token_id , 1 , 0 )
if head_mask is None:
_UpperCAmelCase : Union[str, Any] = np.ones((config.encoder_layers, config.encoder_attention_heads) )
if decoder_head_mask is None:
_UpperCAmelCase : List[str] = np.ones((config.decoder_layers, config.decoder_attention_heads) )
if cross_attn_head_mask is None:
_UpperCAmelCase : Union[str, Any] = np.ones((config.decoder_layers, config.decoder_attention_heads) )
return {
"input_ids": input_ids,
"decoder_input_ids": decoder_input_ids,
"attention_mask": attention_mask,
"decoder_attention_mask": attention_mask,
}
class lowerCamelCase_ :
'''simple docstring'''
def __init__( self : Tuple , A : List[str] , A : List[Any]=13 , A : Tuple=7 , A : Union[str, Any]=True , A : int=False , A : Union[str, Any]=99 , A : Dict=16 , A : Any=2 , A : int=4 , A : int=4 , A : str="gelu" , A : List[Any]=0.1 , A : Optional[int]=0.1 , A : Any=32 , A : List[str]=2 , A : Any=1 , A : int=0 , A : int=0.02 , ):
_UpperCAmelCase : int = parent
_UpperCAmelCase : Tuple = batch_size
_UpperCAmelCase : Any = seq_length
_UpperCAmelCase : int = is_training
_UpperCAmelCase : Optional[Any] = use_labels
_UpperCAmelCase : Any = vocab_size
_UpperCAmelCase : List[str] = hidden_size
_UpperCAmelCase : List[str] = num_hidden_layers
_UpperCAmelCase : Optional[Any] = num_attention_heads
_UpperCAmelCase : int = intermediate_size
_UpperCAmelCase : List[Any] = hidden_act
_UpperCAmelCase : List[str] = hidden_dropout_prob
_UpperCAmelCase : Tuple = attention_probs_dropout_prob
_UpperCAmelCase : str = max_position_embeddings
_UpperCAmelCase : List[Any] = eos_token_id
_UpperCAmelCase : Any = pad_token_id
_UpperCAmelCase : Tuple = bos_token_id
_UpperCAmelCase : Tuple = initializer_range
def _A ( self : Optional[Any] ):
_UpperCAmelCase : List[Any] = np.clip(ids_tensor([self.batch_size, self.seq_length - 1] , self.vocab_size ) , 3 , self.vocab_size )
_UpperCAmelCase : Optional[int] = np.concatenate((input_ids, 2 * np.ones((self.batch_size, 1) , dtype=np.intaa )) , -1 )
_UpperCAmelCase : str = shift_tokens_right(A , 1 , 2 )
_UpperCAmelCase : str = BlenderbotSmallConfig(
vocab_size=self.vocab_size , d_model=self.hidden_size , encoder_layers=self.num_hidden_layers , decoder_layers=self.num_hidden_layers , encoder_attention_heads=self.num_attention_heads , decoder_attention_heads=self.num_attention_heads , encoder_ffn_dim=self.intermediate_size , decoder_ffn_dim=self.intermediate_size , dropout=self.hidden_dropout_prob , attention_dropout=self.attention_probs_dropout_prob , max_position_embeddings=self.max_position_embeddings , eos_token_id=self.eos_token_id , bos_token_id=self.bos_token_id , pad_token_id=self.pad_token_id , initializer_range=self.initializer_range , use_cache=A , )
_UpperCAmelCase : Tuple = prepare_blenderbot_inputs_dict(A , A , A )
return config, inputs_dict
def _A ( self : List[Any] ):
_UpperCAmelCase , _UpperCAmelCase : List[str] = self.prepare_config_and_inputs()
return config, inputs_dict
def _A ( self : Optional[Any] , A : Optional[Any] , A : Optional[int] , A : List[str] ):
_UpperCAmelCase : str = 20
_UpperCAmelCase : Optional[Any] = model_class_name(A )
_UpperCAmelCase : List[Any] = model.encode(inputs_dict["input_ids"] )
_UpperCAmelCase , _UpperCAmelCase : Optional[Any] = (
inputs_dict["decoder_input_ids"],
inputs_dict["decoder_attention_mask"],
)
_UpperCAmelCase : List[Any] = model.init_cache(decoder_input_ids.shape[0] , A , A )
_UpperCAmelCase : Tuple = jnp.ones((decoder_input_ids.shape[0], max_decoder_length) , dtype="i4" )
_UpperCAmelCase : Optional[Any] = jnp.broadcast_to(
jnp.arange(decoder_input_ids.shape[-1] - 1 )[None, :] , (decoder_input_ids.shape[0], decoder_input_ids.shape[-1] - 1) , )
_UpperCAmelCase : List[Any] = model.decode(
decoder_input_ids[:, :-1] , A , decoder_attention_mask=A , past_key_values=A , decoder_position_ids=A , )
_UpperCAmelCase : int = jnp.array(decoder_input_ids.shape[0] * [[decoder_input_ids.shape[-1] - 1]] , dtype="i4" )
_UpperCAmelCase : Dict = model.decode(
decoder_input_ids[:, -1:] , A , decoder_attention_mask=A , past_key_values=outputs_cache.past_key_values , decoder_position_ids=A , )
_UpperCAmelCase : Optional[Any] = model.decode(A , A )
_UpperCAmelCase : int = np.max(np.abs((outputs_cache_next[0][:, -1, :5] - outputs[0][:, -1, :5]) ) )
self.parent.assertTrue(diff < 1E-3 , msg=F"""Max diff is {diff}""" )
def _A ( self : Optional[int] , A : List[str] , A : List[str] , A : Optional[Any] ):
_UpperCAmelCase : Union[str, Any] = 20
_UpperCAmelCase : List[str] = model_class_name(A )
_UpperCAmelCase : Dict = model.encode(inputs_dict["input_ids"] )
_UpperCAmelCase , _UpperCAmelCase : Union[str, Any] = (
inputs_dict["decoder_input_ids"],
inputs_dict["decoder_attention_mask"],
)
_UpperCAmelCase : int = jnp.concatenate(
[
decoder_attention_mask,
jnp.zeros((decoder_attention_mask.shape[0], max_decoder_length - decoder_attention_mask.shape[1]) ),
] , axis=-1 , )
_UpperCAmelCase : Any = model.init_cache(decoder_input_ids.shape[0] , A , A )
_UpperCAmelCase : Optional[Any] = jnp.broadcast_to(
jnp.arange(decoder_input_ids.shape[-1] - 1 )[None, :] , (decoder_input_ids.shape[0], decoder_input_ids.shape[-1] - 1) , )
_UpperCAmelCase : List[str] = model.decode(
decoder_input_ids[:, :-1] , A , decoder_attention_mask=A , past_key_values=A , decoder_position_ids=A , )
_UpperCAmelCase : int = jnp.array(decoder_input_ids.shape[0] * [[decoder_input_ids.shape[-1] - 1]] , dtype="i4" )
_UpperCAmelCase : Union[str, Any] = model.decode(
decoder_input_ids[:, -1:] , A , past_key_values=outputs_cache.past_key_values , decoder_attention_mask=A , decoder_position_ids=A , )
_UpperCAmelCase : Dict = model.decode(A , A , decoder_attention_mask=A )
_UpperCAmelCase : int = np.max(np.abs((outputs_cache_next[0][:, -1, :5] - outputs[0][:, -1, :5]) ) )
self.parent.assertTrue(diff < 1E-3 , msg=F"""Max diff is {diff}""" )
@require_flax
class lowerCamelCase_ (unittest.TestCase ):
'''simple docstring'''
__UpperCamelCase: Optional[int] = 9_9
def _A ( self : List[str] ):
_UpperCAmelCase : Tuple = np.array(
[
[71, 82, 18, 33, 46, 91, 2],
[68, 34, 26, 58, 30, 82, 2],
[5, 97, 17, 39, 94, 40, 2],
[76, 83, 94, 25, 70, 78, 2],
[87, 59, 41, 35, 48, 66, 2],
[55, 13, 16, 58, 5, 2, 1], # note padding
[64, 27, 31, 51, 12, 75, 2],
[52, 64, 86, 17, 83, 39, 2],
[48, 61, 9, 24, 71, 82, 2],
[26, 1, 60, 48, 22, 13, 2],
[21, 5, 62, 28, 14, 76, 2],
[45, 98, 37, 86, 59, 48, 2],
[70, 70, 50, 9, 28, 0, 2],
] , dtype=np.intaa , )
_UpperCAmelCase : int = input_ids.shape[0]
_UpperCAmelCase : Any = BlenderbotSmallConfig(
vocab_size=self.vocab_size , d_model=24 , encoder_layers=2 , decoder_layers=2 , encoder_attention_heads=2 , decoder_attention_heads=2 , encoder_ffn_dim=32 , decoder_ffn_dim=32 , max_position_embeddings=48 , eos_token_id=2 , pad_token_id=1 , bos_token_id=0 , )
return config, input_ids, batch_size
def _A ( self : Optional[Any] ):
_UpperCAmelCase , _UpperCAmelCase , _UpperCAmelCase : Optional[Any] = self._get_config_and_data()
_UpperCAmelCase : int = FlaxBlenderbotSmallForConditionalGeneration(A )
_UpperCAmelCase : int = lm_model(input_ids=A )
_UpperCAmelCase : List[str] = (batch_size, input_ids.shape[1], config.vocab_size)
self.assertEqual(outputs["logits"].shape , A )
def _A ( self : Union[str, Any] ):
_UpperCAmelCase : Union[str, Any] = BlenderbotSmallConfig(
vocab_size=self.vocab_size , d_model=14 , encoder_layers=2 , decoder_layers=2 , encoder_attention_heads=2 , decoder_attention_heads=2 , encoder_ffn_dim=8 , decoder_ffn_dim=8 , max_position_embeddings=48 , )
_UpperCAmelCase : Optional[int] = FlaxBlenderbotSmallForConditionalGeneration(A )
_UpperCAmelCase : Dict = np.array([[71, 82, 18, 33, 46, 91, 2], [68, 34, 26, 58, 30, 2, 1]] , dtype=np.intaa )
_UpperCAmelCase : List[str] = np.array([[82, 71, 82, 18, 2], [58, 68, 2, 1, 1]] , dtype=np.intaa )
_UpperCAmelCase : List[str] = lm_model(input_ids=A , decoder_input_ids=A )
_UpperCAmelCase : Union[str, Any] = (*summary.shape, config.vocab_size)
self.assertEqual(outputs["logits"].shape , A )
def _A ( self : Optional[int] ):
_UpperCAmelCase : Union[str, Any] = np.array([[71, 82, 18, 33, 2, 1, 1], [68, 34, 26, 58, 30, 82, 2]] , dtype=np.intaa )
_UpperCAmelCase : Dict = shift_tokens_right(A , 1 , 2 )
_UpperCAmelCase : Dict = np.equal(A , 1 ).astype(np.floataa ).sum()
_UpperCAmelCase : str = np.equal(A , 1 ).astype(np.floataa ).sum()
self.assertEqual(shifted.shape , input_ids.shape )
self.assertEqual(A , n_pad_before - 1 )
self.assertTrue(np.equal(shifted[:, 0] , 2 ).all() )
@require_flax
class lowerCamelCase_ (snake_case__ , unittest.TestCase , snake_case__ ):
'''simple docstring'''
__UpperCamelCase: List[Any] = True
__UpperCamelCase: Tuple = (
(
FlaxBlenderbotSmallModel,
FlaxBlenderbotSmallForConditionalGeneration,
)
if is_flax_available()
else ()
)
__UpperCamelCase: List[Any] = (FlaxBlenderbotSmallForConditionalGeneration,) if is_flax_available() else ()
def _A ( self : Optional[int] ):
_UpperCAmelCase : Union[str, Any] = FlaxBlenderbotSmallModelTester(self )
def _A ( self : Optional[int] ):
_UpperCAmelCase , _UpperCAmelCase : Union[str, Any] = self.model_tester.prepare_config_and_inputs()
for model_class in self.all_model_classes:
self.model_tester.check_use_cache_forward(A , A , A )
def _A ( self : Any ):
_UpperCAmelCase , _UpperCAmelCase : Optional[int] = self.model_tester.prepare_config_and_inputs()
for model_class in self.all_model_classes:
self.model_tester.check_use_cache_forward_with_attn_mask(A , A , A )
def _A ( self : Dict ):
_UpperCAmelCase , _UpperCAmelCase : List[Any] = self.model_tester.prepare_config_and_inputs_for_common()
for model_class in self.all_model_classes:
with self.subTest(model_class.__name__ ):
_UpperCAmelCase : Any = self._prepare_for_class(A , A )
_UpperCAmelCase : Any = model_class(A )
@jax.jit
def encode_jitted(A : Dict , A : str=None , **A : List[Any] ):
return model.encode(input_ids=A , attention_mask=A )
with self.subTest("JIT Enabled" ):
_UpperCAmelCase : int = encode_jitted(**A ).to_tuple()
with self.subTest("JIT Disabled" ):
with jax.disable_jit():
_UpperCAmelCase : Optional[int] = encode_jitted(**A ).to_tuple()
self.assertEqual(len(A ) , len(A ) )
for jitted_output, output in zip(A , A ):
self.assertEqual(jitted_output.shape , output.shape )
def _A ( self : Tuple ):
_UpperCAmelCase , _UpperCAmelCase : Union[str, Any] = self.model_tester.prepare_config_and_inputs_for_common()
for model_class in self.all_model_classes:
with self.subTest(model_class.__name__ ):
_UpperCAmelCase : Dict = model_class(A )
_UpperCAmelCase : Union[str, Any] = model.encode(inputs_dict["input_ids"] , inputs_dict["attention_mask"] )
_UpperCAmelCase : str = {
"decoder_input_ids": inputs_dict["decoder_input_ids"],
"decoder_attention_mask": inputs_dict["decoder_attention_mask"],
"encoder_outputs": encoder_outputs,
}
@jax.jit
def decode_jitted(A : Dict , A : Tuple , A : List[str] ):
return model.decode(
decoder_input_ids=A , decoder_attention_mask=A , encoder_outputs=A , )
with self.subTest("JIT Enabled" ):
_UpperCAmelCase : str = decode_jitted(**A ).to_tuple()
with self.subTest("JIT Disabled" ):
with jax.disable_jit():
_UpperCAmelCase : Dict = decode_jitted(**A ).to_tuple()
self.assertEqual(len(A ) , len(A ) )
for jitted_output, output in zip(A , A ):
self.assertEqual(jitted_output.shape , output.shape )
@slow
def _A ( self : Union[str, Any] ):
for model_class_name in self.all_model_classes:
_UpperCAmelCase : int = model_class_name.from_pretrained("facebook/blenderbot_small-90M" )
# FlaxBlenderbotForSequenceClassification expects eos token in input_ids
_UpperCAmelCase : Dict = np.ones((1, 1) ) * model.config.eos_token_id
_UpperCAmelCase : Optional[int] = model(A )
self.assertIsNotNone(A )
| 31
|
import argparse
import torch
from ...utils import logging
from . import AlbertConfig, AlbertForPreTraining, load_tf_weights_in_albert
logging.set_verbosity_info()
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :List[Any] = AlbertConfig.from_json_file(SCREAMING_SNAKE_CASE )
print(f"""Building PyTorch model from configuration: {config}""" )
__UpperCamelCase :List[str] = AlbertForPreTraining(SCREAMING_SNAKE_CASE )
# Load weights from tf checkpoint
load_tf_weights_in_albert(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
# Save pytorch-model
print(f"""Save PyTorch model to {pytorch_dump_path}""" )
torch.save(model.state_dict() , SCREAMING_SNAKE_CASE )
if __name__ == "__main__":
__lowercase = argparse.ArgumentParser()
# Required parameters
parser.add_argument(
'''--tf_checkpoint_path''', default=None, type=str, required=True, help='''Path to the TensorFlow checkpoint path.'''
)
parser.add_argument(
'''--albert_config_file''',
default=None,
type=str,
required=True,
help=(
'''The config json file corresponding to the pre-trained ALBERT model. \n'''
'''This specifies the model architecture.'''
),
)
parser.add_argument(
'''--pytorch_dump_path''', default=None, type=str, required=True, help='''Path to the output PyTorch model.'''
)
__lowercase = parser.parse_args()
convert_tf_checkpoint_to_pytorch(args.tf_checkpoint_path, args.albert_config_file, args.pytorch_dump_path)
| 43
| 0
|
from __future__ import annotations
import math
from collections.abc import Callable
def SCREAMING_SNAKE_CASE_ ( __A : Callable[[int | float], int | float] , __A : int | float , __A : int | float , __A : int = 1_00 , ) -> float:
"""simple docstring"""
a_ : Optional[Any] = x_start
a_ : List[str] = fnc(__A )
a_ : str = 0.0
for _ in range(__A ):
# Approximates curve as a sequence of linear lines and sums their length
a_ : List[str] = (x_end - x_start) / steps + xa
a_ : List[Any] = fnc(__A )
length += math.hypot(xa - xa , fxa - fxa )
# Increment step
a_ : Optional[int] = xa
a_ : int = fxa
return length
if __name__ == "__main__":
def SCREAMING_SNAKE_CASE_ ( __A : Union[str, Any] ) -> Any:
"""simple docstring"""
return math.sin(10 * x )
print('f(x) = sin(10 * x)')
print('The length of the curve from x = -10 to x = 10 is:')
UpperCAmelCase_ : List[str] = 10
while i <= 10_0000:
print(F'With {i} steps: {line_length(f, -10, 10, i)}')
i *= 10
| 32
|
import math
import qiskit
def lowerCamelCase ( SCREAMING_SNAKE_CASE = 1 , SCREAMING_SNAKE_CASE = 1 , SCREAMING_SNAKE_CASE = 1 ):
'''simple docstring'''
if (
isinstance(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
or isinstance(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
or isinstance(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
):
raise TypeError('''inputs must be integers.''' )
if (input_a < 0) or (input_a < 0) or (carry_in < 0):
raise ValueError('''inputs must be positive.''' )
if (
(math.floor(SCREAMING_SNAKE_CASE ) != input_a)
or (math.floor(SCREAMING_SNAKE_CASE ) != input_a)
or (math.floor(SCREAMING_SNAKE_CASE ) != carry_in)
):
raise ValueError('''inputs must be exact integers.''' )
if (input_a > 2) or (input_a > 2) or (carry_in > 2):
raise ValueError('''inputs must be less or equal to 2.''' )
# build registers
__UpperCamelCase :List[str] = qiskit.QuantumRegister(4 , '''qr''' )
__UpperCamelCase :str = qiskit.ClassicalRegister(2 , '''cr''' )
# list the entries
__UpperCamelCase :Tuple = [input_a, input_a, carry_in]
__UpperCamelCase :Optional[int] = qiskit.QuantumCircuit(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
for i in range(0 , 3 ):
if entry[i] == 2:
quantum_circuit.h(SCREAMING_SNAKE_CASE ) # for hadamard entries
elif entry[i] == 1:
quantum_circuit.x(SCREAMING_SNAKE_CASE ) # for 1 entries
elif entry[i] == 0:
quantum_circuit.i(SCREAMING_SNAKE_CASE ) # for 0 entries
# build the circuit
quantum_circuit.ccx(0 , 1 , 3 ) # ccx = toffoli gate
quantum_circuit.cx(0 , 1 )
quantum_circuit.ccx(1 , 2 , 3 )
quantum_circuit.cx(1 , 2 )
quantum_circuit.cx(0 , 1 )
quantum_circuit.measure([2, 3] , SCREAMING_SNAKE_CASE ) # measure the last two qbits
__UpperCamelCase :Optional[Any] = qiskit.Aer.get_backend('''aer_simulator''' )
__UpperCamelCase :Tuple = qiskit.execute(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , shots=1_000 )
return job.result().get_counts(SCREAMING_SNAKE_CASE )
if __name__ == "__main__":
print(F'Total sum count for state is: {quantum_full_adder(1, 1, 1)}')
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|
"""simple docstring"""
from typing import TYPE_CHECKING
from ...utils import (
OptionalDependencyNotAvailable,
_LazyModule,
is_sentencepiece_available,
is_speech_available,
is_torch_available,
)
__A : Tuple = {
'''configuration_trocr''': ['''TROCR_PRETRAINED_CONFIG_ARCHIVE_MAP''', '''TrOCRConfig'''],
'''processing_trocr''': ['''TrOCRProcessor'''],
}
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__A : str = [
'''TROCR_PRETRAINED_MODEL_ARCHIVE_LIST''',
'''TrOCRForCausalLM''',
'''TrOCRPreTrainedModel''',
]
if TYPE_CHECKING:
from .configuration_trocr import TROCR_PRETRAINED_CONFIG_ARCHIVE_MAP, TrOCRConfig
from .processing_trocr import TrOCRProcessor
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_trocr import TROCR_PRETRAINED_MODEL_ARCHIVE_LIST, TrOCRForCausalLM, TrOCRPreTrainedModel
else:
import sys
__A : List[str] = _LazyModule(__name__, globals()['''__file__'''], _import_structure, module_spec=__spec__)
| 33
|
import random
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Optional[Any] = a[left_index]
__UpperCamelCase :Any = left_index + 1
for j in range(left_index + 1 , SCREAMING_SNAKE_CASE ):
if a[j] < pivot:
__UpperCamelCase , __UpperCamelCase :str = a[i], a[j]
i += 1
__UpperCamelCase , __UpperCamelCase :Optional[int] = a[i - 1], a[left_index]
return i - 1
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
if left < right:
__UpperCamelCase :int = random.randint(SCREAMING_SNAKE_CASE , right - 1 )
__UpperCamelCase , __UpperCamelCase :List[str] = (
a[left],
a[pivot],
) # switches the pivot with the left most bound
__UpperCamelCase :Dict = partition(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
quick_sort_random(
SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ) # recursive quicksort to the left of the pivot point
quick_sort_random(
SCREAMING_SNAKE_CASE , pivot_index + 1 , SCREAMING_SNAKE_CASE ) # recursive quicksort to the right of the pivot point
def lowerCamelCase ( ):
'''simple docstring'''
__UpperCamelCase :Tuple = input('''Enter numbers separated by a comma:\n''' ).strip()
__UpperCamelCase :Union[str, Any] = [int(SCREAMING_SNAKE_CASE ) for item in user_input.split(''',''' )]
quick_sort_random(SCREAMING_SNAKE_CASE , 0 , len(SCREAMING_SNAKE_CASE ) )
print(SCREAMING_SNAKE_CASE )
if __name__ == "__main__":
main()
| 43
| 0
|
'''simple docstring'''
import importlib
import sys
from argparse import REMAINDER, ArgumentParser
from pathlib import Path
import torch_xla.distributed.xla_multiprocessing as xmp
def snake_case_ ():
UpperCAmelCase = ArgumentParser(
description=(
'''PyTorch TPU distributed training launch '''
'''helper utility that will spawn up '''
'''multiple distributed processes'''
) )
# Optional arguments for the launch helper
parser.add_argument('''--num_cores''' , type=_a , default=1 , help='''Number of TPU cores to use (1 or 8).''' )
# positional
parser.add_argument(
'''training_script''' , type=_a , help=(
'''The full path to the single TPU training '''
'''program/script to be launched in parallel, '''
'''followed by all the arguments for the '''
'''training script'''
) , )
# rest from the training program
parser.add_argument('''training_script_args''' , nargs=_a )
return parser.parse_args()
def snake_case_ ():
UpperCAmelCase = parse_args()
# Import training_script as a module.
UpperCAmelCase = Path(args.training_script )
sys.path.append(str(script_fpath.parent.resolve() ) )
UpperCAmelCase = script_fpath.stem
UpperCAmelCase = importlib.import_module(_a )
# Patch sys.argv
UpperCAmelCase = [args.training_script] + args.training_script_args + ['''--tpu_num_cores''', str(args.num_cores )]
xmp.spawn(mod._mp_fn , args=() , nprocs=args.num_cores )
if __name__ == "__main__":
main()
| 34
|
def lowerCamelCase ( SCREAMING_SNAKE_CASE = 1 , SCREAMING_SNAKE_CASE = 1_000 ):
'''simple docstring'''
__UpperCamelCase :Union[str, Any] = 1
__UpperCamelCase :Any = 0
for divide_by_number in range(SCREAMING_SNAKE_CASE , digit + 1 ):
__UpperCamelCase :list[int] = []
__UpperCamelCase :Optional[int] = numerator
for _ in range(1 , digit + 1 ):
if now_divide in has_been_divided:
if longest_list_length < len(SCREAMING_SNAKE_CASE ):
__UpperCamelCase :Optional[Any] = len(SCREAMING_SNAKE_CASE )
__UpperCamelCase :int = divide_by_number
else:
has_been_divided.append(SCREAMING_SNAKE_CASE )
__UpperCamelCase :Any = now_divide * 10 % divide_by_number
return the_digit
# Tests
if __name__ == "__main__":
import doctest
doctest.testmod()
| 43
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|
'''simple docstring'''
import random
import sys
import numpy as np
from matplotlib import pyplot as plt
from matplotlib.colors import ListedColormap
__a = "Usage of script: script_name <size_of_canvas:int>"
__a = [0] * 100 + [1] * 10
random.shuffle(choice)
def __snake_case( _lowerCAmelCase ) -> list[list[bool]]:
snake_case__ : Tuple = [[False for i in range(_lowerCAmelCase )] for j in range(_lowerCAmelCase )]
return canvas
def __snake_case( _lowerCAmelCase ) -> None:
for i, row in enumerate(_lowerCAmelCase ):
for j, _ in enumerate(_lowerCAmelCase ):
snake_case__ : List[str] = bool(random.getrandbits(1 ) )
def __snake_case( _lowerCAmelCase ) -> list[list[bool]]:
snake_case__ : Union[str, Any] = np.array(_lowerCAmelCase )
snake_case__ : Tuple = np.array(create_canvas(current_canvas.shape[0] ) )
for r, row in enumerate(_lowerCAmelCase ):
for c, pt in enumerate(_lowerCAmelCase ):
snake_case__ : List[Any] = __judge_point(
_lowerCAmelCase , current_canvas[r - 1 : r + 2, c - 1 : c + 2] )
snake_case__ : Optional[int] = next_gen_canvas
del next_gen_canvas # cleaning memory as we move on.
snake_case__ : list[list[bool]] = current_canvas.tolist()
return return_canvas
def __snake_case( _lowerCAmelCase , _lowerCAmelCase ) -> bool:
snake_case__ : List[Any] = 0
snake_case__ : Optional[Any] = 0
# finding dead or alive neighbours count.
for i in neighbours:
for status in i:
if status:
alive += 1
else:
dead += 1
# handling duplicate entry for focus pt.
if pt:
alive -= 1
else:
dead -= 1
# running the rules of game here.
snake_case__ : int = pt
if pt:
if alive < 2:
snake_case__ : Tuple = False
elif alive == 2 or alive == 3:
snake_case__ : Tuple = True
elif alive > 3:
snake_case__ : List[Any] = False
else:
if alive == 3:
snake_case__ : Optional[Any] = True
return state
if __name__ == "__main__":
if len(sys.argv) != 2:
raise Exception(usage_doc)
__a = int(sys.argv[1])
# main working structure of this module.
__a = create_canvas(canvas_size)
seed(c)
__a , __a = plt.subplots()
fig.show()
__a = ListedColormap(["w", "k"])
try:
while True:
__a = run(c)
ax.matshow(c, cmap=cmap)
fig.canvas.draw()
ax.cla()
except KeyboardInterrupt:
# do nothing.
pass
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|
import argparse
import json
from tqdm import tqdm
def lowerCamelCase ( ):
'''simple docstring'''
__UpperCamelCase :Tuple = argparse.ArgumentParser()
# Required parameters
parser.add_argument(
'''--src_path''' , type=SCREAMING_SNAKE_CASE , default='''biencoder-nq-dev.json''' , help='''Path to raw DPR training data''' , )
parser.add_argument(
'''--evaluation_set''' , type=SCREAMING_SNAKE_CASE , help='''where to store parsed evaluation_set file''' , )
parser.add_argument(
'''--gold_data_path''' , type=SCREAMING_SNAKE_CASE , help='''where to store parsed gold_data_path file''' , )
__UpperCamelCase :str = parser.parse_args()
with open(args.src_path , '''r''' ) as src_file, open(args.evaluation_set , '''w''' ) as eval_file, open(
args.gold_data_path , '''w''' ) as gold_file:
__UpperCamelCase :List[str] = json.load(SCREAMING_SNAKE_CASE )
for dpr_record in tqdm(SCREAMING_SNAKE_CASE ):
__UpperCamelCase :List[str] = dpr_record['''question''']
__UpperCamelCase :Tuple = [context['''title'''] for context in dpr_record['''positive_ctxs''']]
eval_file.write(question + '''\n''' )
gold_file.write('''\t'''.join(SCREAMING_SNAKE_CASE ) + '''\n''' )
if __name__ == "__main__":
main()
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|
import json
import os
import unittest
from transformers import MgpstrTokenizer
from transformers.models.mgp_str.tokenization_mgp_str import VOCAB_FILES_NAMES
from transformers.testing_utils import require_tokenizers
from ...test_tokenization_common import TokenizerTesterMixin
@require_tokenizers
class UpperCAmelCase_ ( a , unittest.TestCase):
lowerCamelCase__ = MgpstrTokenizer
lowerCamelCase__ = False
lowerCamelCase__ = {}
lowerCamelCase__ = False
def snake_case__ ( self):
'''simple docstring'''
super().setUp()
# fmt: off
_lowerCAmelCase : Union[str, Any] = ["[GO]", "[s]", "0", "1", "2", "3", "4", "5", "6", "7", "8", "9", "a", "b", "c", "d", "e", "f", "g", "h", "i", "j", "k", "l", "m", "n", "o", "p", "q", "r", "s", "t", "u", "v", "w", "x", "y", "z"]
# fmt: on
_lowerCAmelCase : List[str] = dict(zip(__a, range(len(__a))))
_lowerCAmelCase : Optional[int] = 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(__a) + "\n")
def snake_case__ ( self, **__a):
'''simple docstring'''
return MgpstrTokenizer.from_pretrained(self.tmpdirname, **__a)
def snake_case__ ( self, __a):
'''simple docstring'''
_lowerCAmelCase : str = "tester"
_lowerCAmelCase : List[str] = "tester"
return input_text, output_text
@unittest.skip("MGP-STR always lower cases letters.")
def snake_case__ ( self):
'''simple docstring'''
pass
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : List[str] = self.get_tokenizers(do_lower_case=__a)
for tokenizer in tokenizers:
with self.subTest(f"{tokenizer.__class__.__name__}"):
_lowerCAmelCase : str = "[SPECIAL_TOKEN]"
tokenizer.add_special_tokens({"cls_token": special_token})
_lowerCAmelCase : List[str] = tokenizer.encode([special_token], add_special_tokens=__a)
self.assertEqual(len(__a), 1)
_lowerCAmelCase : Optional[Any] = tokenizer.decode(__a, skip_special_tokens=__a)
self.assertTrue(special_token not in decoded)
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : List[Any] = self.get_tokenizers()
for tokenizer in tokenizers:
with self.subTest(f"{tokenizer.__class__.__name__}"):
_lowerCAmelCase , _lowerCAmelCase : Union[str, Any] = self.get_input_output_texts(__a)
_lowerCAmelCase : int = tokenizer.tokenize(__a)
_lowerCAmelCase : Dict = tokenizer.convert_tokens_to_ids(__a)
_lowerCAmelCase : Dict = tokenizer.encode(__a, add_special_tokens=__a)
self.assertListEqual(__a, __a)
_lowerCAmelCase : Dict = tokenizer.convert_ids_to_tokens(__a)
self.assertNotEqual(len(__a), 0)
_lowerCAmelCase : List[str] = tokenizer.decode(__a)
self.assertIsInstance(__a, __a)
self.assertEqual(text_a.replace(" ", ""), __a)
@unittest.skip("MGP-STR tokenizer only handles one sequence.")
def snake_case__ ( self):
'''simple docstring'''
pass
@unittest.skip("inputs cannot be pretokenized in MgpstrTokenizer")
def snake_case__ ( self):
'''simple docstring'''
pass
| 36
|
from __future__ import annotations
import random
# Maximum size of the population. Bigger could be faster but is more memory expensive.
__lowercase = 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.
__lowercase = 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.
__lowercase = 0.4
# Just a seed to improve randomness required by the algorithm.
random.seed(random.randint(0, 1000))
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Any = len([g for position, g in enumerate(SCREAMING_SNAKE_CASE ) if g == main_target[position]] )
return (item, float(SCREAMING_SNAKE_CASE ))
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Optional[Any] = random.randint(0 , len(SCREAMING_SNAKE_CASE ) - 1 )
__UpperCamelCase :Tuple = parent_a[:random_slice] + parent_a[random_slice:]
__UpperCamelCase :Union[str, Any] = parent_a[:random_slice] + parent_a[random_slice:]
return (child_a, child_a)
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :int = list(SCREAMING_SNAKE_CASE )
if random.uniform(0 , 1 ) < MUTATION_PROBABILITY:
__UpperCamelCase :str = random.choice(SCREAMING_SNAKE_CASE )
return "".join(SCREAMING_SNAKE_CASE )
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , ):
'''simple docstring'''
__UpperCamelCase :int = []
# Generate more children proportionally to the fitness score.
__UpperCamelCase :int = int(parent_a[1] * 100 ) + 1
__UpperCamelCase :List[str] = 10 if child_n >= 10 else child_n
for _ in range(SCREAMING_SNAKE_CASE ):
__UpperCamelCase :Optional[Any] = population_score[random.randint(0 , SCREAMING_SNAKE_CASE )][0]
__UpperCamelCase , __UpperCamelCase :Any = crossover(parent_a[0] , SCREAMING_SNAKE_CASE )
# Append new string to the population list.
pop.append(mutate(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ) )
pop.append(mutate(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ) )
return pop
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE = True ):
'''simple docstring'''
if N_POPULATION < N_SELECTED:
__UpperCamelCase :List[Any] = f"""{N_POPULATION} must be bigger than {N_SELECTED}"""
raise ValueError(SCREAMING_SNAKE_CASE )
# Verify that the target contains no genes besides the ones inside genes variable.
__UpperCamelCase :List[str] = sorted({c for c in target if c not in genes} )
if not_in_genes_list:
__UpperCamelCase :Optional[int] = f"""{not_in_genes_list} is not in genes list, evolution cannot converge"""
raise ValueError(SCREAMING_SNAKE_CASE )
# Generate random starting population.
__UpperCamelCase :int = []
for _ in range(SCREAMING_SNAKE_CASE ):
population.append(''''''.join([random.choice(SCREAMING_SNAKE_CASE ) for i in range(len(SCREAMING_SNAKE_CASE ) )] ) )
# Just some logs to know what the algorithms is doing.
__UpperCamelCase , __UpperCamelCase :List[Any] = 0, 0
# This loop will end when we find a perfect match for our target.
while True:
generation += 1
total_population += len(SCREAMING_SNAKE_CASE )
# 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.
__UpperCamelCase :Tuple = [evaluate(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ) for item in population]
# Check if there is a matching evolution.
__UpperCamelCase :Tuple = sorted(SCREAMING_SNAKE_CASE , key=lambda SCREAMING_SNAKE_CASE : x[1] , reverse=SCREAMING_SNAKE_CASE )
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.
__UpperCamelCase :str = population[: int(N_POPULATION / 3 )]
population.clear()
population.extend(SCREAMING_SNAKE_CASE )
# Normalize population score to be between 0 and 1.
__UpperCamelCase :Union[str, Any] = [
(item, score / len(SCREAMING_SNAKE_CASE )) for item, score in population_score
]
# This is selection
for i in range(SCREAMING_SNAKE_CASE ):
population.extend(select(population_score[int(SCREAMING_SNAKE_CASE )] , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ) )
# 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(SCREAMING_SNAKE_CASE ) > N_POPULATION:
break
if __name__ == "__main__":
__lowercase = (
'''This is a genetic algorithm to evaluate, combine, evolve, and mutate a string!'''
)
__lowercase = list(
''' ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklm'''
'''nopqrstuvwxyz.,;!?+-*#@^\'èéòà€ù=)(&%$£/\\'''
)
__lowercase , __lowercase , __lowercase = basic(target_str, genes_list)
print(
F'\nGeneration: {generation}\nTotal Population: {population}\nTarget: {target}'
)
| 43
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|
'''simple docstring'''
import inspect
import unittest
import numpy as np
from tests.test_modeling_common import floats_tensor
from transformers import DetrConfig, MaskFormerConfig, SwinConfig, is_torch_available, is_vision_available
from transformers.testing_utils import require_torch, require_torch_multi_gpu, require_vision, slow, torch_device
from transformers.utils import cached_property
from ...test_configuration_common import ConfigTester
from ...test_modeling_common import ModelTesterMixin
from ...test_pipeline_mixin import PipelineTesterMixin
if is_torch_available():
import torch
from transformers import MaskFormerForInstanceSegmentation, MaskFormerModel
if is_vision_available():
from transformers import MaskFormerImageProcessor
if is_vision_available():
from PIL import Image
class lowerCAmelCase_:
'''simple docstring'''
def __init__( self ,__UpperCAmelCase ,__UpperCAmelCase=2 ,__UpperCAmelCase=True ,__UpperCAmelCase=False ,__UpperCAmelCase=10 ,__UpperCAmelCase=3 ,__UpperCAmelCase=32 * 4 ,__UpperCAmelCase=32 * 6 ,__UpperCAmelCase=4 ,__UpperCAmelCase=32 ,) -> str:
lowerCAmelCase__ : Optional[int] = parent
lowerCAmelCase__ : Optional[int] = batch_size
lowerCAmelCase__ : Optional[int] = is_training
lowerCAmelCase__ : Dict = use_auxiliary_loss
lowerCAmelCase__ : Union[str, Any] = num_queries
lowerCAmelCase__ : str = num_channels
lowerCAmelCase__ : List[str] = min_size
lowerCAmelCase__ : int = max_size
lowerCAmelCase__ : Optional[Any] = num_labels
lowerCAmelCase__ : List[Any] = mask_feature_size
def UpperCAmelCase_ ( self ) -> Tuple:
lowerCAmelCase__ : str = floats_tensor([self.batch_size, self.num_channels, self.min_size, self.max_size] ).to(
__UpperCAmelCase )
lowerCAmelCase__ : str = torch.ones([self.batch_size, self.min_size, self.max_size] ,device=__UpperCAmelCase )
lowerCAmelCase__ : Any = (
torch.rand([self.batch_size, self.num_labels, self.min_size, self.max_size] ,device=__UpperCAmelCase ) > 0.5
).float()
lowerCAmelCase__ : Optional[int] = (torch.rand((self.batch_size, self.num_labels) ,device=__UpperCAmelCase ) > 0.5).long()
lowerCAmelCase__ : Any = self.get_config()
return config, pixel_values, pixel_mask, mask_labels, class_labels
def UpperCAmelCase_ ( self ) -> Dict:
return MaskFormerConfig.from_backbone_and_decoder_configs(
backbone_config=SwinConfig(
depths=[1, 1, 1, 1] ,) ,decoder_config=DetrConfig(
decoder_ffn_dim=128 ,num_queries=self.num_queries ,decoder_attention_heads=2 ,d_model=self.mask_feature_size ,) ,mask_feature_size=self.mask_feature_size ,fpn_feature_size=self.mask_feature_size ,num_channels=self.num_channels ,num_labels=self.num_labels ,)
def UpperCAmelCase_ ( self ) -> Optional[int]:
lowerCAmelCase__ , lowerCAmelCase__ , lowerCAmelCase__ , lowerCAmelCase__ , lowerCAmelCase__ : List[str] = self.prepare_config_and_inputs()
lowerCAmelCase__ : List[str] = {"""pixel_values""": pixel_values, """pixel_mask""": pixel_mask}
return config, inputs_dict
def UpperCAmelCase_ ( self ,__UpperCAmelCase ,__UpperCAmelCase ) -> Any:
lowerCAmelCase__ : Optional[int] = output.encoder_hidden_states
lowerCAmelCase__ : Optional[int] = output.pixel_decoder_hidden_states
lowerCAmelCase__ : Dict = output.transformer_decoder_hidden_states
self.parent.assertTrue(len(__UpperCAmelCase ) ,len(config.backbone_config.depths ) )
self.parent.assertTrue(len(__UpperCAmelCase ) ,len(config.backbone_config.depths ) )
self.parent.assertTrue(len(__UpperCAmelCase ) ,config.decoder_config.decoder_layers )
def UpperCAmelCase_ ( self ,__UpperCAmelCase ,__UpperCAmelCase ,__UpperCAmelCase ,__UpperCAmelCase=False ) -> Optional[Any]:
with torch.no_grad():
lowerCAmelCase__ : int = MaskFormerModel(config=__UpperCAmelCase )
model.to(__UpperCAmelCase )
model.eval()
lowerCAmelCase__ : str = model(pixel_values=__UpperCAmelCase ,pixel_mask=__UpperCAmelCase )
lowerCAmelCase__ : int = model(__UpperCAmelCase ,output_hidden_states=__UpperCAmelCase )
# the correct shape of output.transformer_decoder_hidden_states ensure the correcteness of the
# encoder and pixel decoder
self.parent.assertEqual(
output.transformer_decoder_last_hidden_state.shape ,(self.batch_size, self.num_queries, self.mask_feature_size) ,)
# let's ensure the other two hidden state exists
self.parent.assertTrue(output.pixel_decoder_last_hidden_state is not None )
self.parent.assertTrue(output.encoder_last_hidden_state is not None )
if output_hidden_states:
self.check_output_hidden_state(__UpperCAmelCase ,__UpperCAmelCase )
def UpperCAmelCase_ ( self ,__UpperCAmelCase ,__UpperCAmelCase ,__UpperCAmelCase ,__UpperCAmelCase ,__UpperCAmelCase ) -> Optional[int]:
lowerCAmelCase__ : Dict = MaskFormerForInstanceSegmentation(config=__UpperCAmelCase )
model.to(__UpperCAmelCase )
model.eval()
def comm_check_on_output(__UpperCAmelCase ):
# let's still check that all the required stuff is there
self.parent.assertTrue(result.transformer_decoder_last_hidden_state is not None )
self.parent.assertTrue(result.pixel_decoder_last_hidden_state is not None )
self.parent.assertTrue(result.encoder_last_hidden_state is not None )
# okay, now we need to check the logits shape
# due to the encoder compression, masks have a //4 spatial size
self.parent.assertEqual(
result.masks_queries_logits.shape ,(self.batch_size, self.num_queries, self.min_size // 4, self.max_size // 4) ,)
# + 1 for null class
self.parent.assertEqual(
result.class_queries_logits.shape ,(self.batch_size, self.num_queries, self.num_labels + 1) )
with torch.no_grad():
lowerCAmelCase__ : List[Any] = model(pixel_values=__UpperCAmelCase ,pixel_mask=__UpperCAmelCase )
lowerCAmelCase__ : Dict = model(__UpperCAmelCase )
comm_check_on_output(__UpperCAmelCase )
lowerCAmelCase__ : Optional[int] = model(
pixel_values=__UpperCAmelCase ,pixel_mask=__UpperCAmelCase ,mask_labels=__UpperCAmelCase ,class_labels=__UpperCAmelCase )
comm_check_on_output(__UpperCAmelCase )
self.parent.assertTrue(result.loss is not None )
self.parent.assertEqual(result.loss.shape ,torch.Size([1] ) )
@require_torch
class lowerCAmelCase_( SCREAMING_SNAKE_CASE_ , SCREAMING_SNAKE_CASE_ , unittest.TestCase ):
'''simple docstring'''
__lowercase : Optional[Any] = (MaskFormerModel, MaskFormerForInstanceSegmentation) if is_torch_available() else ()
__lowercase : int = (
{'''feature-extraction''': MaskFormerModel, '''image-segmentation''': MaskFormerForInstanceSegmentation}
if is_torch_available()
else {}
)
__lowercase : Union[str, Any] = False
__lowercase : Dict = False
__lowercase : Tuple = False
__lowercase : List[Any] = False
def UpperCAmelCase_ ( self ) -> Optional[int]:
lowerCAmelCase__ : str = MaskFormerModelTester(self )
lowerCAmelCase__ : List[Any] = ConfigTester(self ,config_class=__UpperCAmelCase ,has_text_modality=__UpperCAmelCase )
def UpperCAmelCase_ ( self ) -> List[str]:
self.config_tester.run_common_tests()
def UpperCAmelCase_ ( self ) -> Union[str, Any]:
lowerCAmelCase__ , lowerCAmelCase__ : str = self.model_tester.prepare_config_and_inputs_for_common()
self.model_tester.create_and_check_maskformer_model(__UpperCAmelCase ,**__UpperCAmelCase ,output_hidden_states=__UpperCAmelCase )
def UpperCAmelCase_ ( self ) -> Optional[int]:
lowerCAmelCase__ : List[str] = self.model_tester.prepare_config_and_inputs()
self.model_tester.create_and_check_maskformer_instance_segmentation_head_model(*__UpperCAmelCase )
@unittest.skip(reason="""MaskFormer does not use inputs_embeds""" )
def UpperCAmelCase_ ( self ) -> List[Any]:
pass
@unittest.skip(reason="""MaskFormer does not have a get_input_embeddings method""" )
def UpperCAmelCase_ ( self ) -> str:
pass
@unittest.skip(reason="""MaskFormer is not a generative model""" )
def UpperCAmelCase_ ( self ) -> Any:
pass
@unittest.skip(reason="""MaskFormer does not use token embeddings""" )
def UpperCAmelCase_ ( self ) -> List[str]:
pass
@require_torch_multi_gpu
@unittest.skip(
reason="""MaskFormer has some layers using `add_module` which doesn't work well with `nn.DataParallel`""" )
def UpperCAmelCase_ ( self ) -> Union[str, Any]:
pass
@unittest.skip("""Will be fixed soon by reducing the size of the model used for common tests.""" )
def UpperCAmelCase_ ( self ) -> List[str]:
pass
def UpperCAmelCase_ ( self ) -> Tuple:
lowerCAmelCase__ , lowerCAmelCase__ : Union[str, Any] = self.model_tester.prepare_config_and_inputs_for_common()
for model_class in self.all_model_classes:
lowerCAmelCase__ : str = model_class(__UpperCAmelCase )
lowerCAmelCase__ : Dict = inspect.signature(model.forward )
# signature.parameters is an OrderedDict => so arg_names order is deterministic
lowerCAmelCase__ : Dict = [*signature.parameters.keys()]
lowerCAmelCase__ : Tuple = ["""pixel_values"""]
self.assertListEqual(arg_names[:1] ,__UpperCAmelCase )
@slow
def UpperCAmelCase_ ( self ) -> Union[str, Any]:
for model_name in ["facebook/maskformer-swin-small-coco"]:
lowerCAmelCase__ : List[str] = MaskFormerModel.from_pretrained(__UpperCAmelCase )
self.assertIsNotNone(__UpperCAmelCase )
def UpperCAmelCase_ ( self ) -> str:
lowerCAmelCase__ : List[Any] = (self.model_tester.min_size,) * 2
lowerCAmelCase__ : Any = {
"""pixel_values""": torch.randn((2, 3, *size) ,device=__UpperCAmelCase ),
"""mask_labels""": torch.randn((2, 10, *size) ,device=__UpperCAmelCase ),
"""class_labels""": torch.zeros(2 ,10 ,device=__UpperCAmelCase ).long(),
}
lowerCAmelCase__ : Tuple = MaskFormerForInstanceSegmentation(MaskFormerConfig() ).to(__UpperCAmelCase )
lowerCAmelCase__ : Union[str, Any] = model(**__UpperCAmelCase )
self.assertTrue(outputs.loss is not None )
def UpperCAmelCase_ ( self ) -> str:
lowerCAmelCase__ , lowerCAmelCase__ : List[str] = self.model_tester.prepare_config_and_inputs_for_common()
self.model_tester.create_and_check_maskformer_model(__UpperCAmelCase ,**__UpperCAmelCase ,output_hidden_states=__UpperCAmelCase )
def UpperCAmelCase_ ( self ) -> Tuple:
lowerCAmelCase__ , lowerCAmelCase__ : Any = self.model_tester.prepare_config_and_inputs_for_common()
for model_class in self.all_model_classes:
lowerCAmelCase__ : int = model_class(__UpperCAmelCase ).to(__UpperCAmelCase )
lowerCAmelCase__ : List[Any] = model(**__UpperCAmelCase ,output_attentions=__UpperCAmelCase )
self.assertTrue(outputs.attentions is not None )
def UpperCAmelCase_ ( self ) -> int:
if not self.model_tester.is_training:
return
# only MaskFormerForInstanceSegmentation has the loss
lowerCAmelCase__ : Dict = self.all_model_classes[1]
lowerCAmelCase__ , lowerCAmelCase__ , lowerCAmelCase__ , lowerCAmelCase__ , lowerCAmelCase__ : Optional[int] = self.model_tester.prepare_config_and_inputs()
lowerCAmelCase__ : List[Any] = model_class(__UpperCAmelCase )
model.to(__UpperCAmelCase )
model.train()
lowerCAmelCase__ : List[str] = model(__UpperCAmelCase ,mask_labels=__UpperCAmelCase ,class_labels=__UpperCAmelCase ).loss
loss.backward()
def UpperCAmelCase_ ( self ) -> List[str]:
# only MaskFormerForInstanceSegmentation has the loss
lowerCAmelCase__ : Tuple = self.all_model_classes[1]
lowerCAmelCase__ , lowerCAmelCase__ , lowerCAmelCase__ , lowerCAmelCase__ , lowerCAmelCase__ : Optional[int] = self.model_tester.prepare_config_and_inputs()
lowerCAmelCase__ : Union[str, Any] = True
lowerCAmelCase__ : Tuple = True
lowerCAmelCase__ : Optional[Any] = model_class(__UpperCAmelCase )
model.to(__UpperCAmelCase )
model.train()
lowerCAmelCase__ : Dict = model(__UpperCAmelCase ,mask_labels=__UpperCAmelCase ,class_labels=__UpperCAmelCase )
lowerCAmelCase__ : Optional[Any] = outputs.encoder_hidden_states[0]
encoder_hidden_states.retain_grad()
lowerCAmelCase__ : str = outputs.pixel_decoder_hidden_states[0]
pixel_decoder_hidden_states.retain_grad()
# we requires_grad=True in inputs_embeds (line 2152), the original implementation don't
lowerCAmelCase__ : Union[str, Any] = outputs.transformer_decoder_hidden_states[0]
transformer_decoder_hidden_states.retain_grad()
lowerCAmelCase__ : List[Any] = outputs.attentions[0]
attentions.retain_grad()
outputs.loss.backward(retain_graph=__UpperCAmelCase )
self.assertIsNotNone(encoder_hidden_states.grad )
self.assertIsNotNone(pixel_decoder_hidden_states.grad )
self.assertIsNotNone(transformer_decoder_hidden_states.grad )
self.assertIsNotNone(attentions.grad )
_lowerCAmelCase = 1e-4
def _SCREAMING_SNAKE_CASE ( ):
"""simple docstring"""
lowerCAmelCase__ : Union[str, Any] = Image.open("""./tests/fixtures/tests_samples/COCO/000000039769.png""" )
return image
@require_vision
@slow
class lowerCAmelCase_( unittest.TestCase ):
'''simple docstring'''
@cached_property
def UpperCAmelCase_ ( self ) -> List[Any]:
return (
MaskFormerImageProcessor.from_pretrained("""facebook/maskformer-swin-small-coco""" )
if is_vision_available()
else None
)
def UpperCAmelCase_ ( self ) -> Any:
lowerCAmelCase__ : Any = MaskFormerModel.from_pretrained("""facebook/maskformer-swin-small-coco""" ).to(__UpperCAmelCase )
lowerCAmelCase__ : str = self.default_image_processor
lowerCAmelCase__ : str = prepare_img()
lowerCAmelCase__ : Optional[int] = image_processor(__UpperCAmelCase ,return_tensors="""pt""" ).to(__UpperCAmelCase )
lowerCAmelCase__ : Dict = inputs["""pixel_values"""].shape
# check size is divisible by 32
self.assertTrue((inputs_shape[-1] % 32) == 0 and (inputs_shape[-2] % 32) == 0 )
# check size
self.assertEqual(__UpperCAmelCase ,(1, 3, 800, 1088) )
with torch.no_grad():
lowerCAmelCase__ : Union[str, Any] = model(**__UpperCAmelCase )
lowerCAmelCase__ : Optional[Any] = torch.tensor(
[[-0.0_4_8_2, 0.9_2_2_8, 0.4_9_5_1], [-0.2_5_4_7, 0.8_0_1_7, 0.8_5_2_7], [-0.0_0_6_9, 0.3_3_8_5, -0.0_0_8_9]] ).to(__UpperCAmelCase )
self.assertTrue(
torch.allclose(
outputs.encoder_last_hidden_state[0, 0, :3, :3] ,__UpperCAmelCase ,atol=__UpperCAmelCase ) )
lowerCAmelCase__ : Dict = torch.tensor(
[[-0.8_4_2_2, -0.8_4_3_4, -0.9_7_1_8], [-1.0_1_4_4, -0.5_5_6_5, -0.4_1_9_5], [-1.0_0_3_8, -0.4_4_8_4, -0.1_9_6_1]] ).to(__UpperCAmelCase )
self.assertTrue(
torch.allclose(
outputs.pixel_decoder_last_hidden_state[0, 0, :3, :3] ,__UpperCAmelCase ,atol=__UpperCAmelCase ) )
lowerCAmelCase__ : Optional[int] = torch.tensor(
[[0.2_8_5_2, -0.0_1_5_9, 0.9_7_3_5], [0.6_2_5_4, 0.1_8_5_8, 0.8_5_2_9], [-0.0_6_8_0, -0.4_1_1_6, 1.8_4_1_3]] ).to(__UpperCAmelCase )
self.assertTrue(
torch.allclose(
outputs.transformer_decoder_last_hidden_state[0, :3, :3] ,__UpperCAmelCase ,atol=__UpperCAmelCase ) )
def UpperCAmelCase_ ( self ) -> Optional[Any]:
lowerCAmelCase__ : List[Any] = (
MaskFormerForInstanceSegmentation.from_pretrained("""facebook/maskformer-swin-small-coco""" )
.to(__UpperCAmelCase )
.eval()
)
lowerCAmelCase__ : Optional[Any] = self.default_image_processor
lowerCAmelCase__ : List[str] = prepare_img()
lowerCAmelCase__ : str = image_processor(__UpperCAmelCase ,return_tensors="""pt""" ).to(__UpperCAmelCase )
lowerCAmelCase__ : Optional[int] = inputs["""pixel_values"""].shape
# check size is divisible by 32
self.assertTrue((inputs_shape[-1] % 32) == 0 and (inputs_shape[-2] % 32) == 0 )
# check size
self.assertEqual(__UpperCAmelCase ,(1, 3, 800, 1088) )
with torch.no_grad():
lowerCAmelCase__ : List[Any] = model(**__UpperCAmelCase )
# masks_queries_logits
lowerCAmelCase__ : Optional[int] = outputs.masks_queries_logits
self.assertEqual(
masks_queries_logits.shape ,(1, model.config.decoder_config.num_queries, inputs_shape[-2] // 4, inputs_shape[-1] // 4) ,)
lowerCAmelCase__ : Optional[int] = [
[-1.3_7_3_7_1_2_4, -1.7_7_2_4_9_3_7, -1.9_3_6_4_2_3_3],
[-1.5_9_7_7_2_8_1, -1.9_8_6_7_9_3_9, -2.1_5_2_3_6_9_5],
[-1.5_7_9_5_3_9_8, -1.9_2_6_9_8_3_2, -2.0_9_3_9_4_2],
]
lowerCAmelCase__ : Optional[int] = torch.tensor(__UpperCAmelCase ).to(__UpperCAmelCase )
self.assertTrue(torch.allclose(masks_queries_logits[0, 0, :3, :3] ,__UpperCAmelCase ,atol=__UpperCAmelCase ) )
# class_queries_logits
lowerCAmelCase__ : Tuple = outputs.class_queries_logits
self.assertEqual(
class_queries_logits.shape ,(1, model.config.decoder_config.num_queries, model.config.num_labels + 1) )
lowerCAmelCase__ : Union[str, Any] = torch.tensor(
[
[1.65_12E00, -5.25_72E00, -3.35_19E00],
[3.61_69E-02, -5.90_25E00, -2.93_13E00],
[1.07_66E-04, -7.76_30E00, -5.12_63E00],
] ).to(__UpperCAmelCase )
self.assertTrue(torch.allclose(outputs.class_queries_logits[0, :3, :3] ,__UpperCAmelCase ,atol=__UpperCAmelCase ) )
def UpperCAmelCase_ ( self ) -> str:
lowerCAmelCase__ : List[Any] = (
MaskFormerForInstanceSegmentation.from_pretrained("""facebook/maskformer-resnet101-coco-stuff""" )
.to(__UpperCAmelCase )
.eval()
)
lowerCAmelCase__ : Optional[Any] = self.default_image_processor
lowerCAmelCase__ : int = prepare_img()
lowerCAmelCase__ : Optional[Any] = image_processor(__UpperCAmelCase ,return_tensors="""pt""" ).to(__UpperCAmelCase )
lowerCAmelCase__ : str = inputs["""pixel_values"""].shape
# check size is divisible by 32
self.assertTrue((inputs_shape[-1] % 32) == 0 and (inputs_shape[-2] % 32) == 0 )
# check size
self.assertEqual(__UpperCAmelCase ,(1, 3, 800, 1088) )
with torch.no_grad():
lowerCAmelCase__ : str = model(**__UpperCAmelCase )
# masks_queries_logits
lowerCAmelCase__ : Optional[Any] = outputs.masks_queries_logits
self.assertEqual(
masks_queries_logits.shape ,(1, model.config.decoder_config.num_queries, inputs_shape[-2] // 4, inputs_shape[-1] // 4) ,)
lowerCAmelCase__ : int = [[-0.9_0_4_6, -2.6_3_6_6, -4.6_0_6_2], [-3.4_1_7_9, -5.7_8_9_0, -8.8_0_5_7], [-4.9_1_7_9, -7.6_5_6_0, -1_0.7_7_1_1]]
lowerCAmelCase__ : List[str] = torch.tensor(__UpperCAmelCase ).to(__UpperCAmelCase )
self.assertTrue(torch.allclose(masks_queries_logits[0, 0, :3, :3] ,__UpperCAmelCase ,atol=__UpperCAmelCase ) )
# class_queries_logits
lowerCAmelCase__ : Optional[Any] = outputs.class_queries_logits
self.assertEqual(
class_queries_logits.shape ,(1, model.config.decoder_config.num_queries, model.config.num_labels + 1) )
lowerCAmelCase__ : Tuple = torch.tensor(
[[4.7_1_8_8, -3.2_5_8_5, -2.8_8_5_7], [6.6_8_7_1, -2.9_1_8_1, -1.2_4_8_7], [7.2_4_4_9, -2.2_7_6_4, -2.1_8_7_4]] ).to(__UpperCAmelCase )
self.assertTrue(torch.allclose(outputs.class_queries_logits[0, :3, :3] ,__UpperCAmelCase ,atol=__UpperCAmelCase ) )
def UpperCAmelCase_ ( self ) -> Optional[Any]:
lowerCAmelCase__ : str = (
MaskFormerForInstanceSegmentation.from_pretrained("""facebook/maskformer-swin-small-coco""" )
.to(__UpperCAmelCase )
.eval()
)
lowerCAmelCase__ : Dict = self.default_image_processor
lowerCAmelCase__ : Union[str, Any] = image_processor(
[np.zeros((3, 800, 1333) ), np.zeros((3, 800, 1333) )] ,segmentation_maps=[np.zeros((384, 384) ).astype(np.floataa ), np.zeros((384, 384) ).astype(np.floataa )] ,return_tensors="""pt""" ,)
lowerCAmelCase__ : Tuple = inputs["""pixel_values"""].to(__UpperCAmelCase )
lowerCAmelCase__ : Union[str, Any] = [el.to(__UpperCAmelCase ) for el in inputs["""mask_labels"""]]
lowerCAmelCase__ : Union[str, Any] = [el.to(__UpperCAmelCase ) for el in inputs["""class_labels"""]]
with torch.no_grad():
lowerCAmelCase__ : Any = model(**__UpperCAmelCase )
self.assertTrue(outputs.loss is not None )
| 37
|
import argparse
import json
import os
import evaluate
import torch
from datasets import load_dataset
from torch.optim import AdamW
from torch.utils.data import DataLoader
from transformers import AutoModelForSequenceClassification, AutoTokenizer, get_linear_schedule_with_warmup, set_seed
from accelerate import Accelerator, DistributedType
from accelerate.utils.deepspeed import DummyOptim, DummyScheduler
__lowercase = 16
__lowercase = 32
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE = 16 , SCREAMING_SNAKE_CASE = "bert-base-cased" ):
'''simple docstring'''
__UpperCamelCase :List[str] = AutoTokenizer.from_pretrained(SCREAMING_SNAKE_CASE )
__UpperCamelCase :Any = load_dataset('''glue''' , '''mrpc''' )
def tokenize_function(SCREAMING_SNAKE_CASE ):
# max_length=None => use the model max length (it's actually the default)
__UpperCamelCase :int = tokenizer(examples['''sentence1'''] , examples['''sentence2'''] , truncation=SCREAMING_SNAKE_CASE , max_length=SCREAMING_SNAKE_CASE )
return outputs
# Apply the method we just defined to all the examples in all the splits of the dataset
__UpperCamelCase :Tuple = datasets.map(
SCREAMING_SNAKE_CASE , batched=SCREAMING_SNAKE_CASE , remove_columns=['''idx''', '''sentence1''', '''sentence2'''] , load_from_cache_file=SCREAMING_SNAKE_CASE )
# We also rename the 'label' column to 'labels' which is the expected name for labels by the models of the
# transformers library
__UpperCamelCase :List[str] = tokenized_datasets.rename_column('''label''' , '''labels''' )
def collate_fn(SCREAMING_SNAKE_CASE ):
# On TPU it's best to pad everything to the same length or training will be very slow.
if accelerator.distributed_type == DistributedType.TPU:
return tokenizer.pad(SCREAMING_SNAKE_CASE , padding='''max_length''' , max_length=128 , return_tensors='''pt''' )
return tokenizer.pad(SCREAMING_SNAKE_CASE , padding='''longest''' , return_tensors='''pt''' )
# Instantiate dataloaders.
__UpperCamelCase :Union[str, Any] = DataLoader(
tokenized_datasets['''train'''] , shuffle=SCREAMING_SNAKE_CASE , collate_fn=SCREAMING_SNAKE_CASE , batch_size=SCREAMING_SNAKE_CASE )
__UpperCamelCase :Dict = DataLoader(
tokenized_datasets['''validation'''] , shuffle=SCREAMING_SNAKE_CASE , collate_fn=SCREAMING_SNAKE_CASE , batch_size=SCREAMING_SNAKE_CASE )
return train_dataloader, eval_dataloader
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :List[Any] = Accelerator()
# Sample hyper-parameters for learning rate, batch size, seed and a few other HPs
__UpperCamelCase :int = config['''lr''']
__UpperCamelCase :str = int(config['''num_epochs'''] )
__UpperCamelCase :Any = int(config['''seed'''] )
__UpperCamelCase :Dict = int(config['''batch_size'''] )
__UpperCamelCase :Optional[Any] = args.model_name_or_path
set_seed(SCREAMING_SNAKE_CASE )
__UpperCamelCase , __UpperCamelCase :Dict = get_dataloaders(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
# Instantiate the model (we build the model here so that the seed also control new weights initialization)
__UpperCamelCase :Any = AutoModelForSequenceClassification.from_pretrained(SCREAMING_SNAKE_CASE , return_dict=SCREAMING_SNAKE_CASE )
# Instantiate optimizer
__UpperCamelCase :List[str] = (
AdamW
if accelerator.state.deepspeed_plugin is None
or '''optimizer''' not in accelerator.state.deepspeed_plugin.deepspeed_config
else DummyOptim
)
__UpperCamelCase :Optional[Any] = optimizer_cls(params=model.parameters() , lr=SCREAMING_SNAKE_CASE )
if accelerator.state.deepspeed_plugin is not None:
__UpperCamelCase :Dict = accelerator.state.deepspeed_plugin.deepspeed_config[
'''gradient_accumulation_steps'''
]
else:
__UpperCamelCase :Dict = 1
__UpperCamelCase :Tuple = (len(SCREAMING_SNAKE_CASE ) * num_epochs) // gradient_accumulation_steps
# Instantiate scheduler
if (
accelerator.state.deepspeed_plugin is None
or "scheduler" not in accelerator.state.deepspeed_plugin.deepspeed_config
):
__UpperCamelCase :str = get_linear_schedule_with_warmup(
optimizer=SCREAMING_SNAKE_CASE , num_warmup_steps=0 , num_training_steps=SCREAMING_SNAKE_CASE , )
else:
__UpperCamelCase :Dict = DummyScheduler(SCREAMING_SNAKE_CASE , total_num_steps=SCREAMING_SNAKE_CASE , warmup_num_steps=0 )
# Prepare everything
# There is no specific order to remember, we just need to unpack the objects in the same order we gave them to the
# prepare method.
__UpperCamelCase , __UpperCamelCase , __UpperCamelCase , __UpperCamelCase , __UpperCamelCase :int = accelerator.prepare(
SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
# We need to keep track of how many total steps we have iterated over
__UpperCamelCase :List[Any] = 0
# We also need to keep track of the stating epoch so files are named properly
__UpperCamelCase :Dict = 0
# Now we train the model
__UpperCamelCase :Any = evaluate.load('''glue''' , '''mrpc''' )
__UpperCamelCase :Union[str, Any] = 0
__UpperCamelCase :Optional[int] = {}
for epoch in range(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
model.train()
for step, batch in enumerate(SCREAMING_SNAKE_CASE ):
__UpperCamelCase :Optional[Any] = model(**SCREAMING_SNAKE_CASE )
__UpperCamelCase :Tuple = outputs.loss
__UpperCamelCase :str = loss / gradient_accumulation_steps
accelerator.backward(SCREAMING_SNAKE_CASE )
if step % gradient_accumulation_steps == 0:
optimizer.step()
lr_scheduler.step()
optimizer.zero_grad()
overall_step += 1
model.eval()
__UpperCamelCase :Any = 0
for step, batch in enumerate(SCREAMING_SNAKE_CASE ):
# We could avoid this line since we set the accelerator with `device_placement=True`.
batch.to(accelerator.device )
with torch.no_grad():
__UpperCamelCase :Any = model(**SCREAMING_SNAKE_CASE )
__UpperCamelCase :Optional[int] = outputs.logits.argmax(dim=-1 )
# It is slightly faster to call this once, than multiple times
__UpperCamelCase , __UpperCamelCase :List[Any] = accelerator.gather(
(predictions, batch['''labels''']) ) # If we are in a multiprocess environment, the last batch has duplicates
if accelerator.use_distributed:
if step == len(SCREAMING_SNAKE_CASE ) - 1:
__UpperCamelCase :List[str] = predictions[: len(eval_dataloader.dataset ) - samples_seen]
__UpperCamelCase :Optional[int] = references[: len(eval_dataloader.dataset ) - samples_seen]
else:
samples_seen += references.shape[0]
metric.add_batch(
predictions=SCREAMING_SNAKE_CASE , references=SCREAMING_SNAKE_CASE , )
__UpperCamelCase :Dict = metric.compute()
# Use accelerator.print to print only on the main process.
accelerator.print(f"""epoch {epoch}:""" , SCREAMING_SNAKE_CASE )
__UpperCamelCase :str = eval_metric['''accuracy''']
if best_performance < eval_metric["accuracy"]:
__UpperCamelCase :int = eval_metric['''accuracy''']
if args.performance_lower_bound is not None:
assert (
args.performance_lower_bound <= best_performance
), f"""Best performance metric {best_performance} is lower than the lower bound {args.performance_lower_bound}"""
accelerator.wait_for_everyone()
if accelerator.is_main_process:
with open(os.path.join(args.output_dir , '''all_results.json''' ) , '''w''' ) as f:
json.dump(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
def lowerCamelCase ( ):
'''simple docstring'''
__UpperCamelCase :Tuple = argparse.ArgumentParser(description='''Simple example of training script tracking peak GPU memory usage.''' )
parser.add_argument(
'''--model_name_or_path''' , type=SCREAMING_SNAKE_CASE , default='''bert-base-cased''' , help='''Path to pretrained model or model identifier from huggingface.co/models.''' , required=SCREAMING_SNAKE_CASE , )
parser.add_argument(
'''--output_dir''' , type=SCREAMING_SNAKE_CASE , default='''.''' , help='''Optional save directory where all checkpoint folders will be stored. Default is the current working directory.''' , )
parser.add_argument(
'''--performance_lower_bound''' , type=SCREAMING_SNAKE_CASE , default=SCREAMING_SNAKE_CASE , help='''Optional lower bound for the performance metric. If set, the training will throw error when the performance metric drops below this value.''' , )
parser.add_argument(
'''--num_epochs''' , type=SCREAMING_SNAKE_CASE , default=3 , help='''Number of train epochs.''' , )
__UpperCamelCase :List[str] = parser.parse_args()
__UpperCamelCase :Tuple = {'''lr''': 2e-5, '''num_epochs''': args.num_epochs, '''seed''': 42, '''batch_size''': 16}
training_function(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
if __name__ == "__main__":
main()
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import numpy as np
import skfuzzy as fuzz
if __name__ == "__main__":
# Create universe of discourse in Python using linspace ()
UpperCAmelCase_ : Tuple = np.linspace(start=0, stop=75, num=75, endpoint=True, retstep=False)
# Create two fuzzy sets by defining any membership function
# (trapmf(), gbellmf(), gaussmf(), etc).
UpperCAmelCase_ : List[str] = [0, 25, 50]
UpperCAmelCase_ : Dict = [25, 50, 75]
UpperCAmelCase_ : Tuple = fuzz.membership.trimf(X, abca)
UpperCAmelCase_ : str = fuzz.membership.trimf(X, abca)
# Compute the different operations using inbuilt functions.
UpperCAmelCase_ : Tuple = np.ones(75)
UpperCAmelCase_ : Optional[int] = np.zeros((75,))
# 1. Union = max(µA(x), µB(x))
UpperCAmelCase_ : Tuple = fuzz.fuzzy_or(X, young, X, middle_aged)[1]
# 2. Intersection = min(µA(x), µB(x))
UpperCAmelCase_ : str = fuzz.fuzzy_and(X, young, X, middle_aged)[1]
# 3. Complement (A) = (1- min(µA(x))
UpperCAmelCase_ : int = fuzz.fuzzy_not(young)
# 4. Difference (A/B) = min(µA(x),(1- µB(x)))
UpperCAmelCase_ : int = fuzz.fuzzy_and(X, young, X, fuzz.fuzzy_not(middle_aged)[1])[1]
# 5. Algebraic Sum = [µA(x) + µB(x) – (µA(x) * µB(x))]
UpperCAmelCase_ : Union[str, Any] = young + middle_aged - (young * middle_aged)
# 6. Algebraic Product = (µA(x) * µB(x))
UpperCAmelCase_ : Optional[int] = young * middle_aged
# 7. Bounded Sum = min[1,(µA(x), µB(x))]
UpperCAmelCase_ : int = fuzz.fuzzy_and(X, one, X, young + middle_aged)[1]
# 8. Bounded difference = min[0,(µA(x), µB(x))]
UpperCAmelCase_ : Tuple = fuzz.fuzzy_or(X, zero, X, young - middle_aged)[1]
# max-min composition
# max-product composition
# Plot each set A, set B and each operation result using plot() and subplot().
from matplotlib import pyplot as plt
plt.figure()
plt.subplot(4, 3, 1)
plt.plot(X, young)
plt.title('''Young''')
plt.grid(True)
plt.subplot(4, 3, 2)
plt.plot(X, middle_aged)
plt.title('''Middle aged''')
plt.grid(True)
plt.subplot(4, 3, 3)
plt.plot(X, union)
plt.title('''union''')
plt.grid(True)
plt.subplot(4, 3, 4)
plt.plot(X, intersection)
plt.title('''intersection''')
plt.grid(True)
plt.subplot(4, 3, 5)
plt.plot(X, complement_a)
plt.title('''complement_a''')
plt.grid(True)
plt.subplot(4, 3, 6)
plt.plot(X, difference)
plt.title('''difference a/b''')
plt.grid(True)
plt.subplot(4, 3, 7)
plt.plot(X, alg_sum)
plt.title('''alg_sum''')
plt.grid(True)
plt.subplot(4, 3, 8)
plt.plot(X, alg_product)
plt.title('''alg_product''')
plt.grid(True)
plt.subplot(4, 3, 9)
plt.plot(X, bdd_sum)
plt.title('''bdd_sum''')
plt.grid(True)
plt.subplot(4, 3, 10)
plt.plot(X, bdd_difference)
plt.title('''bdd_difference''')
plt.grid(True)
plt.subplots_adjust(hspace=0.5)
plt.show()
| 38
|
import copy
from ...configuration_utils import PretrainedConfig
from ...utils import logging
from ..auto import CONFIG_MAPPING
__lowercase = logging.get_logger(__name__)
__lowercase = {
'''SenseTime/deformable-detr''': '''https://huggingface.co/sensetime/deformable-detr/resolve/main/config.json''',
# See all Deformable DETR models at https://huggingface.co/models?filter=deformable-detr
}
class lowerCamelCase_ ( UpperCAmelCase_ ):
'''simple docstring'''
a__ : List[str] = """deformable_detr"""
a__ : Union[str, Any] = {
"""hidden_size""": """d_model""",
"""num_attention_heads""": """encoder_attention_heads""",
}
def __init__( self , __lowercase=True , __lowercase=None , __lowercase=3 , __lowercase=300 , __lowercase=1_024 , __lowercase=6 , __lowercase=1_024 , __lowercase=8 , __lowercase=6 , __lowercase=1_024 , __lowercase=8 , __lowercase=0.0 , __lowercase=True , __lowercase="relu" , __lowercase=256 , __lowercase=0.1 , __lowercase=0.0 , __lowercase=0.0 , __lowercase=0.02 , __lowercase=1.0 , __lowercase=True , __lowercase=False , __lowercase="sine" , __lowercase="resnet50" , __lowercase=True , __lowercase=False , __lowercase=4 , __lowercase=4 , __lowercase=4 , __lowercase=False , __lowercase=300 , __lowercase=False , __lowercase=1 , __lowercase=5 , __lowercase=2 , __lowercase=1 , __lowercase=1 , __lowercase=5 , __lowercase=2 , __lowercase=0.1 , __lowercase=0.25 , __lowercase=False , **__lowercase , ) -> int:
if backbone_config is not None and use_timm_backbone:
raise ValueError('''You can\'t specify both `backbone_config` and `use_timm_backbone`.''')
if not use_timm_backbone:
if backbone_config is None:
logger.info('''`backbone_config` is `None`. Initializing the config with the default `ResNet` backbone.''')
__UpperCamelCase :str = CONFIG_MAPPING['''resnet'''](out_features=['''stage4'''])
elif isinstance(__lowercase , __lowercase):
__UpperCamelCase :str = backbone_config.get('''model_type''')
__UpperCamelCase :Tuple = CONFIG_MAPPING[backbone_model_type]
__UpperCamelCase :Any = config_class.from_dict(__lowercase)
__UpperCamelCase :int = use_timm_backbone
__UpperCamelCase :Dict = backbone_config
__UpperCamelCase :Any = num_channels
__UpperCamelCase :Optional[int] = num_queries
__UpperCamelCase :Any = max_position_embeddings
__UpperCamelCase :str = d_model
__UpperCamelCase :Tuple = encoder_ffn_dim
__UpperCamelCase :Union[str, Any] = encoder_layers
__UpperCamelCase :List[Any] = encoder_attention_heads
__UpperCamelCase :Any = decoder_ffn_dim
__UpperCamelCase :List[str] = decoder_layers
__UpperCamelCase :int = decoder_attention_heads
__UpperCamelCase :str = dropout
__UpperCamelCase :Any = attention_dropout
__UpperCamelCase :int = activation_dropout
__UpperCamelCase :List[Any] = activation_function
__UpperCamelCase :List[Any] = init_std
__UpperCamelCase :List[Any] = init_xavier_std
__UpperCamelCase :int = encoder_layerdrop
__UpperCamelCase :str = auxiliary_loss
__UpperCamelCase :Optional[Any] = position_embedding_type
__UpperCamelCase :Union[str, Any] = backbone
__UpperCamelCase :Any = use_pretrained_backbone
__UpperCamelCase :str = dilation
# deformable attributes
__UpperCamelCase :Optional[Any] = num_feature_levels
__UpperCamelCase :str = encoder_n_points
__UpperCamelCase :int = decoder_n_points
__UpperCamelCase :Union[str, Any] = two_stage
__UpperCamelCase :Optional[Any] = two_stage_num_proposals
__UpperCamelCase :Dict = with_box_refine
if two_stage is True and with_box_refine is False:
raise ValueError('''If two_stage is True, with_box_refine must be True.''')
# Hungarian matcher
__UpperCamelCase :Optional[int] = class_cost
__UpperCamelCase :List[Any] = bbox_cost
__UpperCamelCase :str = giou_cost
# Loss coefficients
__UpperCamelCase :Tuple = mask_loss_coefficient
__UpperCamelCase :Tuple = dice_loss_coefficient
__UpperCamelCase :int = bbox_loss_coefficient
__UpperCamelCase :Any = giou_loss_coefficient
__UpperCamelCase :Dict = eos_coefficient
__UpperCamelCase :Optional[Any] = focal_alpha
__UpperCamelCase :Optional[Any] = disable_custom_kernels
super().__init__(is_encoder_decoder=__lowercase , **__lowercase)
@property
def UpperCamelCase__ ( self) -> int:
return self.encoder_attention_heads
@property
def UpperCamelCase__ ( self) -> int:
return self.d_model
def UpperCamelCase__ ( self) -> List[Any]:
__UpperCamelCase :Dict = copy.deepcopy(self.__dict__)
if self.backbone_config is not None:
__UpperCamelCase :Tuple = self.backbone_config.to_dict()
__UpperCamelCase :List[Any] = self.__class__.model_type
return output
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|
from ...configuration_utils import PretrainedConfig
from ...utils import logging
from ...utils.backbone_utils import BackboneConfigMixin, get_aligned_output_features_output_indices
_a = logging.get_logger(__name__)
_a = {
'''shi-labs/nat-mini-in1k-224''': '''https://huggingface.co/shi-labs/nat-mini-in1k-224/resolve/main/config.json''',
# See all Nat models at https://huggingface.co/models?filter=nat
}
class __lowerCamelCase ( snake_case__ , snake_case__):
"""simple docstring"""
UpperCamelCase__ = "nat"
UpperCamelCase__ = {
"num_attention_heads": "num_heads",
"num_hidden_layers": "num_layers",
}
def __init__( self , UpperCAmelCase=4 , UpperCAmelCase=3 , UpperCAmelCase=64 , UpperCAmelCase=[3, 4, 6, 5] , UpperCAmelCase=[2, 4, 8, 16] , UpperCAmelCase=7 , UpperCAmelCase=3.0 , UpperCAmelCase=True , UpperCAmelCase=0.0 , UpperCAmelCase=0.0 , UpperCAmelCase=0.1 , UpperCAmelCase="gelu" , UpperCAmelCase=0.02 , UpperCAmelCase=1e-5 , UpperCAmelCase=0.0 , UpperCAmelCase=None , UpperCAmelCase=None , **UpperCAmelCase , ):
"""simple docstring"""
super().__init__(**UpperCAmelCase )
_UpperCAmelCase = patch_size
_UpperCAmelCase = num_channels
_UpperCAmelCase = embed_dim
_UpperCAmelCase = depths
_UpperCAmelCase = len(UpperCAmelCase )
_UpperCAmelCase = num_heads
_UpperCAmelCase = kernel_size
_UpperCAmelCase = mlp_ratio
_UpperCAmelCase = qkv_bias
_UpperCAmelCase = hidden_dropout_prob
_UpperCAmelCase = attention_probs_dropout_prob
_UpperCAmelCase = drop_path_rate
_UpperCAmelCase = hidden_act
_UpperCAmelCase = layer_norm_eps
_UpperCAmelCase = initializer_range
# we set the hidden_size attribute in order to make Nat work with VisionEncoderDecoderModel
# this indicates the channel dimension after the last stage of the model
_UpperCAmelCase = int(embed_dim * 2 ** (len(UpperCAmelCase ) - 1) )
_UpperCAmelCase = layer_scale_init_value
_UpperCAmelCase = ['stem'] + [F"""stage{idx}""" for idx in range(1 , len(UpperCAmelCase ) + 1 )]
_UpperCAmelCase , _UpperCAmelCase = get_aligned_output_features_output_indices(
out_features=UpperCAmelCase , out_indices=UpperCAmelCase , stage_names=self.stage_names )
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|
# Copyright 2023 The HuggingFace Inc. team. All rights reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
import torch
from ..models.auto import AutoModelForSequenceClassification, AutoTokenizer
from .base import PipelineTool
class lowerCamelCase_ ( UpperCAmelCase_ ):
'''simple docstring'''
a__ : Optional[Any] = """facebook/bart-large-mnli"""
a__ : int = (
"""This is a tool that classifies an English text using provided labels. It takes two inputs: `text`, which """
"""should be the text to classify, and `labels`, which should be the list of labels to use for classification. """
"""It returns the most likely label in the list of provided `labels` for the input text."""
)
a__ : Optional[Any] = """text_classifier"""
a__ : Any = AutoTokenizer
a__ : str = AutoModelForSequenceClassification
a__ : str = ["""text""", ["""text"""]]
a__ : Optional[int] = ["""text"""]
def UpperCamelCase__ ( self) -> Union[str, Any]:
super().setup()
__UpperCamelCase :int = self.model.config
__UpperCamelCase :Optional[Any] = -1
for idx, label in config.idalabel.items():
if label.lower().startswith('''entail'''):
__UpperCamelCase :List[Any] = int(__lowercase)
if self.entailment_id == -1:
raise ValueError('''Could not determine the entailment ID from the model config, please pass it at init.''')
def UpperCamelCase__ ( self , __lowercase , __lowercase) -> Union[str, Any]:
__UpperCamelCase :Any = labels
return self.pre_processor(
[text] * len(__lowercase) , [f"""This example is {label}""" for label in labels] , return_tensors='''pt''' , padding='''max_length''' , )
def UpperCamelCase__ ( self , __lowercase) -> Optional[Any]:
__UpperCamelCase :List[Any] = outputs.logits
__UpperCamelCase :Any = torch.argmax(logits[:, 2]).item()
return self._labels[label_id]
| 43
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|
"""simple docstring"""
from typing import TYPE_CHECKING
from ...utils import OptionalDependencyNotAvailable, _LazyModule, is_torch_available
__lowercase = {"""configuration_wavlm""": ["""WAVLM_PRETRAINED_CONFIG_ARCHIVE_MAP""", """WavLMConfig"""]}
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowercase = [
"""WAVLM_PRETRAINED_MODEL_ARCHIVE_LIST""",
"""WavLMForAudioFrameClassification""",
"""WavLMForCTC""",
"""WavLMForSequenceClassification""",
"""WavLMForXVector""",
"""WavLMModel""",
"""WavLMPreTrainedModel""",
]
if TYPE_CHECKING:
from .configuration_wavlm import WAVLM_PRETRAINED_CONFIG_ARCHIVE_MAP, WavLMConfig
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_wavlm import (
WAVLM_PRETRAINED_MODEL_ARCHIVE_LIST,
WavLMForAudioFrameClassification,
WavLMForCTC,
WavLMForSequenceClassification,
WavLMForXVector,
WavLMModel,
WavLMPreTrainedModel,
)
else:
import sys
__lowercase = _LazyModule(__name__, globals()["""__file__"""], _import_structure, module_spec=__spec__)
| 40
|
import gc
import random
import unittest
import numpy as np
import torch
from transformers import (
CLIPImageProcessor,
CLIPTextConfig,
CLIPTextModel,
CLIPTokenizer,
CLIPVisionConfig,
CLIPVisionModelWithProjection,
)
from diffusers import AutoencoderKL, DDIMScheduler, DDPMScheduler, StableUnCLIPImgaImgPipeline, UNetaDConditionModel
from diffusers.pipelines.pipeline_utils import DiffusionPipeline
from diffusers.pipelines.stable_diffusion.stable_unclip_image_normalizer import StableUnCLIPImageNormalizer
from diffusers.utils.import_utils import is_xformers_available
from diffusers.utils.testing_utils import (
enable_full_determinism,
floats_tensor,
load_image,
load_numpy,
require_torch_gpu,
skip_mps,
slow,
torch_device,
)
from ..pipeline_params import TEXT_GUIDED_IMAGE_VARIATION_BATCH_PARAMS, TEXT_GUIDED_IMAGE_VARIATION_PARAMS
from ..test_pipelines_common import (
PipelineKarrasSchedulerTesterMixin,
PipelineLatentTesterMixin,
PipelineTesterMixin,
assert_mean_pixel_difference,
)
enable_full_determinism()
class lowerCamelCase_ ( UpperCAmelCase_ , UpperCAmelCase_ , UpperCAmelCase_ , unittest.TestCase ):
'''simple docstring'''
a__ : int = StableUnCLIPImgaImgPipeline
a__ : Optional[int] = TEXT_GUIDED_IMAGE_VARIATION_PARAMS
a__ : Union[str, Any] = TEXT_GUIDED_IMAGE_VARIATION_BATCH_PARAMS
a__ : Optional[Any] = frozenset(
[] ) # TO-DO: update image_params once pipeline is refactored with VaeImageProcessor.preprocess
a__ : int = frozenset([] )
def UpperCamelCase__ ( self) -> Tuple:
__UpperCamelCase :Tuple = 32
__UpperCamelCase :Optional[int] = embedder_hidden_size
# image encoding components
__UpperCamelCase :Union[str, Any] = CLIPImageProcessor(crop_size=32 , size=32)
torch.manual_seed(0)
__UpperCamelCase :Union[str, Any] = CLIPVisionModelWithProjection(
CLIPVisionConfig(
hidden_size=__lowercase , projection_dim=__lowercase , num_hidden_layers=5 , num_attention_heads=4 , image_size=32 , intermediate_size=37 , patch_size=1 , ))
# regular denoising components
torch.manual_seed(0)
__UpperCamelCase :str = StableUnCLIPImageNormalizer(embedding_dim=__lowercase)
__UpperCamelCase :Optional[int] = DDPMScheduler(beta_schedule='''squaredcos_cap_v2''')
torch.manual_seed(0)
__UpperCamelCase :Union[str, Any] = CLIPTokenizer.from_pretrained('''hf-internal-testing/tiny-random-clip''')
torch.manual_seed(0)
__UpperCamelCase :Dict = CLIPTextModel(
CLIPTextConfig(
bos_token_id=0 , eos_token_id=2 , hidden_size=__lowercase , projection_dim=32 , intermediate_size=37 , layer_norm_eps=1E-0_5 , num_attention_heads=4 , num_hidden_layers=5 , pad_token_id=1 , vocab_size=1_000 , ))
torch.manual_seed(0)
__UpperCamelCase :List[Any] = UNetaDConditionModel(
sample_size=32 , in_channels=4 , out_channels=4 , down_block_types=('''CrossAttnDownBlock2D''', '''DownBlock2D''') , up_block_types=('''UpBlock2D''', '''CrossAttnUpBlock2D''') , block_out_channels=(32, 64) , attention_head_dim=(2, 4) , class_embed_type='''projection''' , projection_class_embeddings_input_dim=embedder_projection_dim * 2 , cross_attention_dim=__lowercase , layers_per_block=1 , upcast_attention=__lowercase , use_linear_projection=__lowercase , )
torch.manual_seed(0)
__UpperCamelCase :Tuple = DDIMScheduler(
beta_schedule='''scaled_linear''' , beta_start=0.0_00_85 , beta_end=0.0_12 , prediction_type='''v_prediction''' , set_alpha_to_one=__lowercase , steps_offset=1 , )
torch.manual_seed(0)
__UpperCamelCase :List[str] = AutoencoderKL()
__UpperCamelCase :Tuple = {
# image encoding components
'''feature_extractor''': feature_extractor,
'''image_encoder''': image_encoder.eval(),
# image noising components
'''image_normalizer''': image_normalizer.eval(),
'''image_noising_scheduler''': image_noising_scheduler,
# regular denoising components
'''tokenizer''': tokenizer,
'''text_encoder''': text_encoder.eval(),
'''unet''': unet.eval(),
'''scheduler''': scheduler,
'''vae''': vae.eval(),
}
return components
def UpperCamelCase__ ( self , __lowercase , __lowercase=0 , __lowercase=True) -> str:
if str(__lowercase).startswith('''mps'''):
__UpperCamelCase :Union[str, Any] = torch.manual_seed(__lowercase)
else:
__UpperCamelCase :int = torch.Generator(device=__lowercase).manual_seed(__lowercase)
__UpperCamelCase :int = floats_tensor((1, 3, 32, 32) , rng=random.Random(__lowercase)).to(__lowercase)
if pil_image:
__UpperCamelCase :List[Any] = input_image * 0.5 + 0.5
__UpperCamelCase :Optional[Any] = input_image.clamp(0 , 1)
__UpperCamelCase :int = input_image.cpu().permute(0 , 2 , 3 , 1).float().numpy()
__UpperCamelCase :Optional[Any] = DiffusionPipeline.numpy_to_pil(__lowercase)[0]
return {
"prompt": "An anime racoon running a marathon",
"image": input_image,
"generator": generator,
"num_inference_steps": 2,
"output_type": "np",
}
@skip_mps
def UpperCamelCase__ ( self) -> Union[str, Any]:
__UpperCamelCase :Dict = '''cpu''' # ensure determinism for the device-dependent torch.Generator
__UpperCamelCase :Tuple = self.get_dummy_components()
__UpperCamelCase :Any = StableUnCLIPImgaImgPipeline(**__lowercase)
__UpperCamelCase :Optional[Any] = sd_pipe.to(__lowercase)
sd_pipe.set_progress_bar_config(disable=__lowercase)
__UpperCamelCase :List[Any] = self.get_dummy_inputs(__lowercase)
inputs.update({'''image_embeds''': None})
__UpperCamelCase :Any = sd_pipe(**__lowercase).images
__UpperCamelCase :List[str] = image[0, -3:, -3:, -1]
assert image.shape == (1, 32, 32, 3)
__UpperCamelCase :List[Any] = np.array([0.38_72, 0.72_24, 0.56_01, 0.47_41, 0.68_72, 0.58_14, 0.46_36, 0.38_67, 0.50_78])
assert np.abs(image_slice.flatten() - expected_slice).max() < 1E-3
def UpperCamelCase__ ( self) -> str:
__UpperCamelCase :Optional[Any] = torch_device in ['''cpu''', '''mps''']
self._test_attention_slicing_forward_pass(test_max_difference=__lowercase)
def UpperCamelCase__ ( self) -> List[Any]:
__UpperCamelCase :Optional[Any] = torch_device in ['''cpu''', '''mps''']
self._test_inference_batch_single_identical(test_max_difference=__lowercase)
@unittest.skipIf(
torch_device != '''cuda''' or not is_xformers_available() , reason='''XFormers attention is only available with CUDA and `xformers` installed''' , )
def UpperCamelCase__ ( self) -> Union[str, Any]:
self._test_xformers_attention_forwardGenerator_pass(test_max_difference=__lowercase)
@slow
@require_torch_gpu
class lowerCamelCase_ ( unittest.TestCase ):
'''simple docstring'''
def UpperCamelCase__ ( self) -> Union[str, Any]:
# clean up the VRAM after each test
super().tearDown()
gc.collect()
torch.cuda.empty_cache()
def UpperCamelCase__ ( self) -> Union[str, Any]:
__UpperCamelCase :int = load_image(
'''https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main/stable_unclip/turtle.png''')
__UpperCamelCase :Any = load_numpy(
'''https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main/stable_unclip/stable_unclip_2_1_l_img2img_anime_turtle_fp16.npy''')
__UpperCamelCase :List[Any] = StableUnCLIPImgaImgPipeline.from_pretrained(
'''fusing/stable-unclip-2-1-l-img2img''' , torch_dtype=torch.floataa)
pipe.to(__lowercase)
pipe.set_progress_bar_config(disable=__lowercase)
# stable unclip will oom when integration tests are run on a V100,
# so turn on memory savings
pipe.enable_attention_slicing()
pipe.enable_sequential_cpu_offload()
__UpperCamelCase :int = torch.Generator(device='''cpu''').manual_seed(0)
__UpperCamelCase :Dict = pipe(__lowercase , '''anime turle''' , generator=__lowercase , output_type='''np''')
__UpperCamelCase :Dict = output.images[0]
assert image.shape == (768, 768, 3)
assert_mean_pixel_difference(__lowercase , __lowercase)
def UpperCamelCase__ ( self) -> List[str]:
__UpperCamelCase :Optional[Any] = load_image(
'''https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main/stable_unclip/turtle.png''')
__UpperCamelCase :Any = load_numpy(
'''https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main/stable_unclip/stable_unclip_2_1_h_img2img_anime_turtle_fp16.npy''')
__UpperCamelCase :Any = StableUnCLIPImgaImgPipeline.from_pretrained(
'''fusing/stable-unclip-2-1-h-img2img''' , torch_dtype=torch.floataa)
pipe.to(__lowercase)
pipe.set_progress_bar_config(disable=__lowercase)
# stable unclip will oom when integration tests are run on a V100,
# so turn on memory savings
pipe.enable_attention_slicing()
pipe.enable_sequential_cpu_offload()
__UpperCamelCase :int = torch.Generator(device='''cpu''').manual_seed(0)
__UpperCamelCase :Optional[int] = pipe(__lowercase , '''anime turle''' , generator=__lowercase , output_type='''np''')
__UpperCamelCase :List[Any] = output.images[0]
assert image.shape == (768, 768, 3)
assert_mean_pixel_difference(__lowercase , __lowercase)
def UpperCamelCase__ ( self) -> List[str]:
__UpperCamelCase :Dict = load_image(
'''https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main/stable_unclip/turtle.png''')
torch.cuda.empty_cache()
torch.cuda.reset_max_memory_allocated()
torch.cuda.reset_peak_memory_stats()
__UpperCamelCase :List[Any] = StableUnCLIPImgaImgPipeline.from_pretrained(
'''fusing/stable-unclip-2-1-h-img2img''' , torch_dtype=torch.floataa)
__UpperCamelCase :Union[str, Any] = pipe.to(__lowercase)
pipe.set_progress_bar_config(disable=__lowercase)
pipe.enable_attention_slicing()
pipe.enable_sequential_cpu_offload()
__UpperCamelCase :Optional[Any] = pipe(
__lowercase , '''anime turtle''' , num_inference_steps=2 , output_type='''np''' , )
__UpperCamelCase :int = torch.cuda.max_memory_allocated()
# make sure that less than 7 GB is allocated
assert mem_bytes < 7 * 10**9
| 43
| 0
|
'''simple docstring'''
# DISCLAIMER: This file is strongly influenced by https://github.com/yang-song/score_sde_pytorch
import math
from typing import Union
import torch
from ..configuration_utils import ConfigMixin, register_to_config
from ..utils import randn_tensor
from .scheduling_utils import SchedulerMixin
class _lowercase ( _lowercase , _lowercase ):
a = 1
@register_to_config
def __init__( self: List[Any] , UpperCamelCase__: Any=2_000 , UpperCamelCase__: Any=0.1 , UpperCamelCase__: Union[str, Any]=20 , UpperCamelCase__: int=1e-3 ):
lowerCamelCase__ : List[Any] = None
lowerCamelCase__ : Dict = None
lowerCamelCase__ : Dict = None
def lowerCamelCase_ ( self: int , UpperCamelCase__: Union[str, Any] , UpperCamelCase__: Union[str, torch.device] = None ):
lowerCamelCase__ : List[Any] = torch.linspace(1 , self.config.sampling_eps , UpperCamelCase__ , device=UpperCamelCase__ )
def lowerCamelCase_ ( self: int , UpperCamelCase__: str , UpperCamelCase__: Dict , UpperCamelCase__: Tuple , UpperCamelCase__: List[Any]=None ):
if self.timesteps is None:
raise ValueError(
"""`self.timesteps` is not set, you need to run 'set_timesteps' after creating the scheduler""" )
# TODO(Patrick) better comments + non-PyTorch
# postprocess model score
lowerCamelCase__ : Dict = (
-0.25 * t**2 * (self.config.beta_max - self.config.beta_min) - 0.5 * t * self.config.beta_min
)
lowerCamelCase__ : Optional[int] = torch.sqrt(1.0 - torch.exp(2.0 * log_mean_coeff ) )
lowerCamelCase__ : Dict = std.flatten()
while len(std.shape ) < len(score.shape ):
lowerCamelCase__ : Any = std.unsqueeze(-1 )
lowerCamelCase__ : Dict = -score / std
# compute
lowerCamelCase__ : Any = -1.0 / len(self.timesteps )
lowerCamelCase__ : Optional[int] = self.config.beta_min + t * (self.config.beta_max - self.config.beta_min)
lowerCamelCase__ : List[str] = beta_t.flatten()
while len(beta_t.shape ) < len(x.shape ):
lowerCamelCase__ : Tuple = beta_t.unsqueeze(-1 )
lowerCamelCase__ : Union[str, Any] = -0.5 * beta_t * x
lowerCamelCase__ : List[str] = torch.sqrt(UpperCamelCase__ )
lowerCamelCase__ : List[Any] = drift - diffusion**2 * score
lowerCamelCase__ : Dict = x + drift * dt
# add noise
lowerCamelCase__ : int = randn_tensor(x.shape , layout=x.layout , generator=UpperCamelCase__ , device=x.device , dtype=x.dtype )
lowerCamelCase__ : str = x_mean + diffusion * math.sqrt(-dt ) * noise
return x, x_mean
def __len__( self: Dict ):
return self.config.num_train_timesteps
| 41
|
import numpy as np
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE = 1e-12 , SCREAMING_SNAKE_CASE = 100 , ):
'''simple docstring'''
assert np.shape(SCREAMING_SNAKE_CASE )[0] == np.shape(SCREAMING_SNAKE_CASE )[1]
# Ensure proper dimensionality.
assert np.shape(SCREAMING_SNAKE_CASE )[0] == np.shape(SCREAMING_SNAKE_CASE )[0]
# Ensure inputs are either both complex or both real
assert np.iscomplexobj(SCREAMING_SNAKE_CASE ) == np.iscomplexobj(SCREAMING_SNAKE_CASE )
__UpperCamelCase :List[Any] = np.iscomplexobj(SCREAMING_SNAKE_CASE )
if is_complex:
# Ensure complex input_matrix is Hermitian
assert np.array_equal(SCREAMING_SNAKE_CASE , input_matrix.conj().T )
# Set convergence to False. Will define convergence when we exceed max_iterations
# or when we have small changes from one iteration to next.
__UpperCamelCase :str = False
__UpperCamelCase :int = 0
__UpperCamelCase :Optional[Any] = 0
__UpperCamelCase :Union[str, Any] = 1e12
while not convergence:
# Multiple matrix by the vector.
__UpperCamelCase :List[str] = np.dot(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
# Normalize the resulting output vector.
__UpperCamelCase :Tuple = w / np.linalg.norm(SCREAMING_SNAKE_CASE )
# Find rayleigh quotient
# (faster than usual b/c we know vector is normalized already)
__UpperCamelCase :int = vector.conj().T if is_complex else vector.T
__UpperCamelCase :Optional[int] = np.dot(SCREAMING_SNAKE_CASE , np.dot(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ) )
# Check convergence.
__UpperCamelCase :Optional[Any] = np.abs(lambda_ - lambda_previous ) / lambda_
iterations += 1
if error <= error_tol or iterations >= max_iterations:
__UpperCamelCase :Dict = True
__UpperCamelCase :List[Any] = lambda_
if is_complex:
__UpperCamelCase :Tuple = np.real(lambda_ )
return lambda_, vector
def lowerCamelCase ( ):
'''simple docstring'''
__UpperCamelCase :int = np.array([[41, 4, 20], [4, 26, 30], [20, 30, 50]] )
__UpperCamelCase :Optional[Any] = np.array([41, 4, 20] )
__UpperCamelCase :Any = real_input_matrix.astype(np.complexaaa )
__UpperCamelCase :Dict = np.triu(1j * complex_input_matrix , 1 )
complex_input_matrix += imag_matrix
complex_input_matrix += -1 * imag_matrix.T
__UpperCamelCase :Optional[int] = np.array([41, 4, 20] ).astype(np.complexaaa )
for problem_type in ["real", "complex"]:
if problem_type == "real":
__UpperCamelCase :Any = real_input_matrix
__UpperCamelCase :int = real_vector
elif problem_type == "complex":
__UpperCamelCase :Tuple = complex_input_matrix
__UpperCamelCase :Optional[Any] = complex_vector
# Our implementation.
__UpperCamelCase , __UpperCamelCase :Dict = power_iteration(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
# Numpy implementation.
# Get eigenvalues and eigenvectors using built-in numpy
# eigh (eigh used for symmetric or hermetian matrices).
__UpperCamelCase , __UpperCamelCase :List[Any] = np.linalg.eigh(SCREAMING_SNAKE_CASE )
# Last eigenvalue is the maximum one.
__UpperCamelCase :List[Any] = eigen_values[-1]
# Last column in this matrix is eigenvector corresponding to largest eigenvalue.
__UpperCamelCase :str = eigen_vectors[:, -1]
# Check our implementation and numpy gives close answers.
assert np.abs(eigen_value - eigen_value_max ) <= 1e-6
# Take absolute values element wise of each eigenvector.
# as they are only unique to a minus sign.
assert np.linalg.norm(np.abs(SCREAMING_SNAKE_CASE ) - np.abs(SCREAMING_SNAKE_CASE ) ) <= 1e-6
if __name__ == "__main__":
import doctest
doctest.testmod()
test_power_iteration()
| 43
| 0
|
'''simple docstring'''
import gc
import unittest
from transformers import CTRLConfig, 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 (
CTRL_PRETRAINED_MODEL_ARCHIVE_LIST,
CTRLForSequenceClassification,
CTRLLMHeadModel,
CTRLModel,
)
class __UpperCAmelCase :
def __init__( self , lowerCAmelCase_ , lowerCAmelCase_=14 , lowerCAmelCase_=7 , lowerCAmelCase_=True , 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_=5_12 , lowerCAmelCase_=16 , lowerCAmelCase_=2 , lowerCAmelCase_=0.02 , lowerCAmelCase_=3 , lowerCAmelCase_=4 , lowerCAmelCase_=None , ):
"""simple docstring"""
_snake_case = parent
_snake_case = batch_size
_snake_case = seq_length
_snake_case = is_training
_snake_case = use_token_type_ids
_snake_case = use_input_mask
_snake_case = use_labels
_snake_case = use_mc_token_ids
_snake_case = vocab_size
_snake_case = hidden_size
_snake_case = num_hidden_layers
_snake_case = num_attention_heads
_snake_case = intermediate_size
_snake_case = hidden_act
_snake_case = hidden_dropout_prob
_snake_case = attention_probs_dropout_prob
_snake_case = max_position_embeddings
_snake_case = type_vocab_size
_snake_case = type_sequence_label_size
_snake_case = initializer_range
_snake_case = num_labels
_snake_case = num_choices
_snake_case = scope
_snake_case = self.vocab_size - 1
def lowerCamelCase ( self ):
"""simple docstring"""
_snake_case = ids_tensor([self.batch_size, self.seq_length] , self.vocab_size )
_snake_case = None
if self.use_input_mask:
_snake_case = random_attention_mask([self.batch_size, self.seq_length] )
_snake_case = None
if self.use_token_type_ids:
_snake_case = ids_tensor([self.batch_size, self.seq_length] , self.type_vocab_size )
_snake_case = None
if self.use_mc_token_ids:
_snake_case = ids_tensor([self.batch_size, self.num_choices] , self.seq_length )
_snake_case = None
_snake_case = None
_snake_case = None
if self.use_labels:
_snake_case = ids_tensor([self.batch_size] , self.type_sequence_label_size )
_snake_case = ids_tensor([self.batch_size, self.seq_length] , self.num_labels )
_snake_case = ids_tensor([self.batch_size] , self.num_choices )
_snake_case = self.get_config()
_snake_case = ids_tensor([self.num_hidden_layers, self.num_attention_heads] , 2 )
return (
config,
input_ids,
input_mask,
head_mask,
token_type_ids,
mc_token_ids,
sequence_labels,
token_labels,
choice_labels,
)
def lowerCamelCase ( self ):
"""simple docstring"""
return CTRLConfig(
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 , )
def lowerCamelCase ( self , lowerCAmelCase_ , lowerCAmelCase_ , lowerCAmelCase_ , lowerCAmelCase_ , lowerCAmelCase_ , *lowerCAmelCase_ ):
"""simple docstring"""
_snake_case = CTRLModel(config=lowerCAmelCase_ )
model.to(lowerCAmelCase_ )
model.eval()
model(lowerCAmelCase_ , token_type_ids=lowerCAmelCase_ , head_mask=lowerCAmelCase_ )
model(lowerCAmelCase_ , token_type_ids=lowerCAmelCase_ )
_snake_case = model(lowerCAmelCase_ )
self.parent.assertEqual(result.last_hidden_state.shape , (self.batch_size, self.seq_length, self.hidden_size) )
self.parent.assertEqual(len(result.past_key_values ) , config.n_layer )
def lowerCamelCase ( self , lowerCAmelCase_ , lowerCAmelCase_ , lowerCAmelCase_ , lowerCAmelCase_ , lowerCAmelCase_ , *lowerCAmelCase_ ):
"""simple docstring"""
_snake_case = CTRLLMHeadModel(lowerCAmelCase_ )
model.to(lowerCAmelCase_ )
model.eval()
_snake_case = 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 lowerCamelCase ( self ):
"""simple docstring"""
_snake_case = self.prepare_config_and_inputs()
(
(
_snake_case
) , (
_snake_case
) , (
_snake_case
) , (
_snake_case
) , (
_snake_case
) , (
_snake_case
) , (
_snake_case
) , (
_snake_case
) , (
_snake_case
) ,
) = config_and_inputs
_snake_case = {'input_ids': input_ids, 'token_type_ids': token_type_ids, 'head_mask': head_mask}
return config, inputs_dict
def lowerCamelCase ( self , lowerCAmelCase_ , lowerCAmelCase_ , lowerCAmelCase_ , lowerCAmelCase_ , *lowerCAmelCase_ ):
"""simple docstring"""
_snake_case = self.num_labels
_snake_case = CTRLForSequenceClassification(lowerCAmelCase_ )
model.to(lowerCAmelCase_ )
model.eval()
_snake_case = ids_tensor([self.batch_size] , self.type_sequence_label_size )
_snake_case = model(lowerCAmelCase_ , token_type_ids=lowerCAmelCase_ , labels=lowerCAmelCase_ )
self.parent.assertEqual(result.logits.shape , (self.batch_size, self.num_labels) )
@require_torch
class __UpperCAmelCase ( _lowerCamelCase , _lowerCamelCase , _lowerCamelCase , unittest.TestCase ):
__lowercase = (CTRLModel, CTRLLMHeadModel, CTRLForSequenceClassification) if is_torch_available() else ()
__lowercase = (CTRLLMHeadModel,) if is_torch_available() else ()
__lowercase = (
{
"""feature-extraction""": CTRLModel,
"""text-classification""": CTRLForSequenceClassification,
"""text-generation""": CTRLLMHeadModel,
"""zero-shot""": CTRLForSequenceClassification,
}
if is_torch_available()
else {}
)
__lowercase = True
__lowercase = False
__lowercase = False
def lowerCamelCase ( self , lowerCAmelCase_ , lowerCAmelCase_ , lowerCAmelCase_ , lowerCAmelCase_ , lowerCAmelCase_ ):
"""simple docstring"""
if pipeline_test_casse_name == "ZeroShotClassificationPipelineTests":
# Get `tokenizer does not have a padding token` error for both fast/slow tokenizers.
# `CTRLConfig` 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 lowerCamelCase ( self ):
"""simple docstring"""
_snake_case = CTRLModelTester(self )
_snake_case = ConfigTester(self , config_class=lowerCAmelCase_ , n_embd=37 )
def lowerCamelCase ( self ):
"""simple docstring"""
super().tearDown()
# clean-up as much as possible GPU memory occupied by PyTorch
gc.collect()
torch.cuda.empty_cache()
def lowerCamelCase ( self ):
"""simple docstring"""
self.config_tester.run_common_tests()
def lowerCamelCase ( self ):
"""simple docstring"""
_snake_case = self.model_tester.prepare_config_and_inputs()
self.model_tester.create_and_check_ctrl_model(*lowerCAmelCase_ )
def lowerCamelCase ( self ):
"""simple docstring"""
_snake_case = self.model_tester.prepare_config_and_inputs()
self.model_tester.create_and_check_lm_head_model(*lowerCAmelCase_ )
@unittest.skip('Will be fixed soon by reducing the size of the model used for common tests.' )
def lowerCamelCase ( self ):
"""simple docstring"""
pass
@slow
def lowerCamelCase ( self ):
"""simple docstring"""
for model_name in CTRL_PRETRAINED_MODEL_ARCHIVE_LIST[:1]:
_snake_case = CTRLModel.from_pretrained(lowerCAmelCase_ )
self.assertIsNotNone(lowerCAmelCase_ )
@unittest.skip('The model doesn\'t support left padding' ) # and it's not used enough to be worth fixing :)
def lowerCamelCase ( self ):
"""simple docstring"""
pass
@require_torch
class __UpperCAmelCase ( unittest.TestCase ):
def lowerCamelCase ( self ):
"""simple docstring"""
super().tearDown()
# clean-up as much as possible GPU memory occupied by PyTorch
gc.collect()
torch.cuda.empty_cache()
@slow
def lowerCamelCase ( self ):
"""simple docstring"""
_snake_case = CTRLLMHeadModel.from_pretrained('ctrl' )
model.to(lowerCAmelCase_ )
_snake_case = torch.tensor(
[[1_18_59, 0, 16_11, 8]] , dtype=torch.long , device=lowerCAmelCase_ ) # Legal the president is
_snake_case = [
1_18_59,
0,
16_11,
8,
5,
1_50,
2_64_49,
2,
19,
3_48,
4_69,
3,
25_95,
48,
2_07_40,
24_65_33,
24_65_33,
19,
30,
5,
] # Legal the president is a good guy and I don't want to lose my job. \n \n I have a
_snake_case = model.generate(lowerCAmelCase_ , do_sample=lowerCAmelCase_ )
self.assertListEqual(output_ids[0].tolist() , lowerCAmelCase_ )
| 42
|
import json
from typing import TYPE_CHECKING, List, Optional, Tuple
from tokenizers import pre_tokenizers
from ...tokenization_utils_base import BatchEncoding
from ...tokenization_utils_fast import PreTrainedTokenizerFast
from ...utils import logging
if TYPE_CHECKING:
from transformers.pipelines.conversational import Conversation
__lowercase = logging.get_logger(__name__)
__lowercase = {'''tokenizer_file''': '''tokenizer.json'''}
__lowercase = {
'''tokenizer_file''': {
'''bigscience/tokenizer''': '''https://huggingface.co/bigscience/tokenizer/blob/main/tokenizer.json''',
'''bigscience/bloom-560m''': '''https://huggingface.co/bigscience/bloom-560m/blob/main/tokenizer.json''',
'''bigscience/bloom-1b1''': '''https://huggingface.co/bigscience/bloom-1b1/blob/main/tokenizer.json''',
'''bigscience/bloom-1b7''': '''https://huggingface.co/bigscience/bloom-1b7/blob/main/tokenizer.json''',
'''bigscience/bloom-3b''': '''https://huggingface.co/bigscience/bloom-3b/blob/main/tokenizer.json''',
'''bigscience/bloom-7b1''': '''https://huggingface.co/bigscience/bloom-7b1/blob/main/tokenizer.json''',
'''bigscience/bloom''': '''https://huggingface.co/bigscience/bloom/blob/main/tokenizer.json''',
},
}
class lowerCamelCase_ ( UpperCAmelCase_ ):
'''simple docstring'''
a__ : int = VOCAB_FILES_NAMES
a__ : Tuple = PRETRAINED_VOCAB_FILES_MAP
a__ : List[str] = ["""input_ids""", """attention_mask"""]
a__ : int = None
def __init__( self , __lowercase=None , __lowercase=None , __lowercase=None , __lowercase="<unk>" , __lowercase="<s>" , __lowercase="</s>" , __lowercase="<pad>" , __lowercase=False , __lowercase=False , **__lowercase , ) -> List[str]:
super().__init__(
__lowercase , __lowercase , tokenizer_file=__lowercase , unk_token=__lowercase , bos_token=__lowercase , eos_token=__lowercase , pad_token=__lowercase , add_prefix_space=__lowercase , clean_up_tokenization_spaces=__lowercase , **__lowercase , )
__UpperCamelCase :int = json.loads(self.backend_tokenizer.pre_tokenizer.__getstate__())
if pre_tok_state.get('''add_prefix_space''' , __lowercase) != add_prefix_space:
__UpperCamelCase :Any = getattr(__lowercase , pre_tok_state.pop('''type'''))
__UpperCamelCase :str = add_prefix_space
__UpperCamelCase :List[str] = pre_tok_class(**__lowercase)
__UpperCamelCase :Tuple = add_prefix_space
def UpperCamelCase__ ( self , *__lowercase , **__lowercase) -> BatchEncoding:
__UpperCamelCase :Tuple = kwargs.get('''is_split_into_words''' , __lowercase)
if not (self.add_prefix_space or not is_split_into_words):
raise Exception(
f"""You need to instantiate {self.__class__.__name__} with add_prefix_space=True to use it with"""
''' pretokenized inputs.''')
return super()._batch_encode_plus(*__lowercase , **__lowercase)
def UpperCamelCase__ ( self , *__lowercase , **__lowercase) -> BatchEncoding:
__UpperCamelCase :List[str] = kwargs.get('''is_split_into_words''' , __lowercase)
if not (self.add_prefix_space or not is_split_into_words):
raise Exception(
f"""You need to instantiate {self.__class__.__name__} with add_prefix_space=True to use it with"""
''' pretokenized inputs.''')
return super()._encode_plus(*__lowercase , **__lowercase)
def UpperCamelCase__ ( self , __lowercase , __lowercase = None) -> Tuple[str]:
__UpperCamelCase :Optional[Any] = self._tokenizer.model.save(__lowercase , name=__lowercase)
return tuple(__lowercase)
def UpperCamelCase__ ( self , __lowercase) -> List[int]:
__UpperCamelCase :str = []
for is_user, text in conversation.iter_texts():
input_ids.extend(self.encode(__lowercase , add_special_tokens=__lowercase) + [self.eos_token_id])
if len(__lowercase) > self.model_max_length:
__UpperCamelCase :Any = input_ids[-self.model_max_length :]
return input_ids
| 43
| 0
|
"""simple docstring"""
import unittest
import numpy as np
from transformers.testing_utils import require_torch, require_vision
from transformers.utils import is_torch_available, is_vision_available
from ...test_image_processing_common import ImageProcessingSavingTestMixin, prepare_image_inputs
if is_torch_available():
import torch
if is_vision_available():
from PIL import Image
from transformers import PoolFormerImageProcessor
class __A ( unittest.TestCase ):
def __init__( self , a__ , a__=7 , a__=3 , a__=30 , a__=400 , a__=True , a__=None , a__=0.9 , a__=None , a__=True , a__=[0.5, 0.5, 0.5] , a__=[0.5, 0.5, 0.5] , ):
_lowerCAmelCase : Dict = size if size is not None else {"""shortest_edge""": 30}
_lowerCAmelCase : Union[str, Any] = crop_size if crop_size is not None else {"""height""": 30, """width""": 30}
_lowerCAmelCase : List[str] = parent
_lowerCAmelCase : int = batch_size
_lowerCAmelCase : Optional[Any] = num_channels
_lowerCAmelCase : List[Any] = min_resolution
_lowerCAmelCase : Tuple = max_resolution
_lowerCAmelCase : Optional[int] = do_resize_and_center_crop
_lowerCAmelCase : Dict = size
_lowerCAmelCase : int = crop_pct
_lowerCAmelCase : Optional[Any] = crop_size
_lowerCAmelCase : Tuple = do_normalize
_lowerCAmelCase : List[str] = image_mean
_lowerCAmelCase : Optional[Any] = image_std
def __A ( self ):
return {
"size": self.size,
"do_resize_and_center_crop": self.do_resize_and_center_crop,
"crop_pct": self.crop_pct,
"crop_size": self.crop_size,
"do_normalize": self.do_normalize,
"image_mean": self.image_mean,
"image_std": self.image_std,
}
@require_torch
@require_vision
class __A ( SCREAMING_SNAKE_CASE_ , unittest.TestCase ):
_UpperCamelCase : List[Any] = PoolFormerImageProcessor if is_vision_available() else None
def __A ( self ):
_lowerCAmelCase : Tuple = PoolFormerImageProcessingTester(self )
@property
def __A ( self ):
return self.image_processor_tester.prepare_image_processor_dict()
def __A ( self ):
_lowerCAmelCase : Dict = self.image_processing_class(**self.image_processor_dict )
self.assertTrue(hasattr(a__ , """do_resize_and_center_crop""" ) )
self.assertTrue(hasattr(a__ , """size""" ) )
self.assertTrue(hasattr(a__ , """crop_pct""" ) )
self.assertTrue(hasattr(a__ , """do_normalize""" ) )
self.assertTrue(hasattr(a__ , """image_mean""" ) )
self.assertTrue(hasattr(a__ , """image_std""" ) )
def __A ( self ):
_lowerCAmelCase : List[Any] = self.image_processing_class.from_dict(self.image_processor_dict )
self.assertEqual(image_processor.size , {"""shortest_edge""": 30} )
self.assertEqual(image_processor.crop_size , {"""height""": 30, """width""": 30} )
_lowerCAmelCase : str = self.image_processing_class.from_dict(self.image_processor_dict , size=42 , crop_size=84 )
self.assertEqual(image_processor.size , {"""shortest_edge""": 42} )
self.assertEqual(image_processor.crop_size , {"""height""": 84, """width""": 84} )
def __A ( self ):
pass
def __A ( self ):
# Initialize image_processing
_lowerCAmelCase : Optional[Any] = self.image_processing_class(**self.image_processor_dict )
# create random PIL images
_lowerCAmelCase : Union[str, Any] = prepare_image_inputs(self.image_processor_tester , equal_resolution=a__ )
for image in image_inputs:
self.assertIsInstance(a__ , Image.Image )
# Test not batched input
_lowerCAmelCase : Any = image_processing(image_inputs[0] , return_tensors="""pt""" ).pixel_values
self.assertEqual(
encoded_images.shape , (
1,
self.image_processor_tester.num_channels,
self.image_processor_tester.crop_size["""height"""],
self.image_processor_tester.crop_size["""width"""],
) , )
# Test batched
_lowerCAmelCase : str = image_processing(a__ , return_tensors="""pt""" ).pixel_values
self.assertEqual(
encoded_images.shape , (
self.image_processor_tester.batch_size,
self.image_processor_tester.num_channels,
self.image_processor_tester.crop_size["""height"""],
self.image_processor_tester.crop_size["""width"""],
) , )
def __A ( self ):
# Initialize image_processing
_lowerCAmelCase : int = self.image_processing_class(**self.image_processor_dict )
# create random numpy tensors
_lowerCAmelCase : Optional[Any] = prepare_image_inputs(self.image_processor_tester , equal_resolution=a__ , numpify=a__ )
for image in image_inputs:
self.assertIsInstance(a__ , np.ndarray )
# Test not batched input
_lowerCAmelCase : Union[str, Any] = image_processing(image_inputs[0] , return_tensors="""pt""" ).pixel_values
self.assertEqual(
encoded_images.shape , (
1,
self.image_processor_tester.num_channels,
self.image_processor_tester.crop_size["""height"""],
self.image_processor_tester.crop_size["""width"""],
) , )
# Test batched
_lowerCAmelCase : List[Any] = image_processing(a__ , return_tensors="""pt""" ).pixel_values
self.assertEqual(
encoded_images.shape , (
self.image_processor_tester.batch_size,
self.image_processor_tester.num_channels,
self.image_processor_tester.crop_size["""height"""],
self.image_processor_tester.crop_size["""width"""],
) , )
def __A ( self ):
# Initialize image_processing
_lowerCAmelCase : str = self.image_processing_class(**self.image_processor_dict )
# create random PyTorch tensors
_lowerCAmelCase : Dict = prepare_image_inputs(self.image_processor_tester , equal_resolution=a__ , torchify=a__ )
for image in image_inputs:
self.assertIsInstance(a__ , torch.Tensor )
# Test not batched input
_lowerCAmelCase : Dict = image_processing(image_inputs[0] , return_tensors="""pt""" ).pixel_values
self.assertEqual(
encoded_images.shape , (
1,
self.image_processor_tester.num_channels,
self.image_processor_tester.crop_size["""height"""],
self.image_processor_tester.crop_size["""width"""],
) , )
# Test batched
_lowerCAmelCase : Any = image_processing(a__ , return_tensors="""pt""" ).pixel_values
self.assertEqual(
encoded_images.shape , (
self.image_processor_tester.batch_size,
self.image_processor_tester.num_channels,
self.image_processor_tester.crop_size["""height"""],
self.image_processor_tester.crop_size["""width"""],
) , )
| 44
|
from ...configuration_utils import PretrainedConfig
from ...utils import logging
__lowercase = logging.get_logger(__name__)
__lowercase = {'''ctrl''': '''https://huggingface.co/ctrl/resolve/main/config.json'''}
class lowerCamelCase_ ( UpperCAmelCase_ ):
'''simple docstring'''
a__ : str = """ctrl"""
a__ : Dict = ["""past_key_values"""]
a__ : Tuple = {
"""max_position_embeddings""": """n_positions""",
"""hidden_size""": """n_embd""",
"""num_attention_heads""": """n_head""",
"""num_hidden_layers""": """n_layer""",
}
def __init__( self , __lowercase=246_534 , __lowercase=256 , __lowercase=1_280 , __lowercase=8_192 , __lowercase=48 , __lowercase=16 , __lowercase=0.1 , __lowercase=0.1 , __lowercase=1E-6 , __lowercase=0.02 , __lowercase=True , **__lowercase , ) -> List[Any]:
__UpperCamelCase :List[str] = vocab_size
__UpperCamelCase :Optional[Any] = n_positions
__UpperCamelCase :Dict = n_embd
__UpperCamelCase :Dict = n_layer
__UpperCamelCase :List[Any] = n_head
__UpperCamelCase :int = dff
__UpperCamelCase :Union[str, Any] = resid_pdrop
__UpperCamelCase :Optional[int] = embd_pdrop
__UpperCamelCase :List[Any] = layer_norm_epsilon
__UpperCamelCase :Dict = initializer_range
__UpperCamelCase :Any = use_cache
super().__init__(**__lowercase)
| 43
| 0
|
"""simple docstring"""
import unittest
import numpy as np
import torch
from torch import nn
from transformers import (
CLIPImageProcessor,
CLIPTextConfig,
CLIPTextModelWithProjection,
CLIPTokenizer,
CLIPVisionConfig,
CLIPVisionModelWithProjection,
)
from diffusers import KandinskyVaaPriorPipeline, PriorTransformer, UnCLIPScheduler
from diffusers.utils import torch_device
from diffusers.utils.testing_utils import enable_full_determinism, skip_mps
from ..test_pipelines_common import PipelineTesterMixin
enable_full_determinism()
class __lowerCAmelCase ( __SCREAMING_SNAKE_CASE , unittest.TestCase ):
'''simple docstring'''
__UpperCAmelCase : List[str] = KandinskyVaaPriorPipeline
__UpperCAmelCase : Optional[int] = ['prompt']
__UpperCAmelCase : int = ['prompt', 'negative_prompt']
__UpperCAmelCase : Optional[Any] = [
'num_images_per_prompt',
'generator',
'num_inference_steps',
'latents',
'negative_prompt',
'guidance_scale',
'output_type',
'return_dict',
]
__UpperCAmelCase : Any = False
@property
def __UpperCAmelCase ( self ):
return 32
@property
def __UpperCAmelCase ( self ):
return 32
@property
def __UpperCAmelCase ( self ):
return self.time_input_dim
@property
def __UpperCAmelCase ( self ):
return self.time_input_dim * 4
@property
def __UpperCAmelCase ( self ):
return 100
@property
def __UpperCAmelCase ( self ):
__a = CLIPTokenizer.from_pretrained('''hf-internal-testing/tiny-random-clip''' )
return tokenizer
@property
def __UpperCAmelCase ( self ):
torch.manual_seed(0 )
__a = 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=1_000 , )
return CLIPTextModelWithProjection(_a )
@property
def __UpperCAmelCase ( self ):
torch.manual_seed(0 )
__a = {
'''num_attention_heads''': 2,
'''attention_head_dim''': 12,
'''embedding_dim''': self.text_embedder_hidden_size,
'''num_layers''': 1,
}
__a = PriorTransformer(**_a )
# clip_std and clip_mean is initialized to be 0 so PriorTransformer.post_process_latents will always return 0 - set clip_std to be 1 so it won't return 0
__a = nn.Parameter(torch.ones(model.clip_std.shape ) )
return model
@property
def __UpperCAmelCase ( self ):
torch.manual_seed(0 )
__a = CLIPVisionConfig(
hidden_size=self.text_embedder_hidden_size , image_size=224 , projection_dim=self.text_embedder_hidden_size , intermediate_size=37 , num_attention_heads=4 , num_channels=3 , num_hidden_layers=5 , patch_size=14 , )
__a = CLIPVisionModelWithProjection(_a )
return model
@property
def __UpperCAmelCase ( self ):
__a = CLIPImageProcessor(
crop_size=224 , do_center_crop=_a , do_normalize=_a , do_resize=_a , image_mean=[0.4814_5466, 0.457_8275, 0.4082_1073] , image_std=[0.2686_2954, 0.2613_0258, 0.2757_7711] , resample=3 , size=224 , )
return image_processor
def __UpperCAmelCase ( self ):
__a = self.dummy_prior
__a = self.dummy_image_encoder
__a = self.dummy_text_encoder
__a = self.dummy_tokenizer
__a = self.dummy_image_processor
__a = UnCLIPScheduler(
variance_type='''fixed_small_log''' , prediction_type='''sample''' , num_train_timesteps=1_000 , clip_sample=_a , clip_sample_range=10.0 , )
__a = {
'''prior''': prior,
'''image_encoder''': image_encoder,
'''text_encoder''': text_encoder,
'''tokenizer''': tokenizer,
'''scheduler''': scheduler,
'''image_processor''': image_processor,
}
return components
def __UpperCAmelCase ( self , _a , _a=0 ):
if str(_a ).startswith('''mps''' ):
__a = torch.manual_seed(_a )
else:
__a = torch.Generator(device=_a ).manual_seed(_a )
__a = {
'''prompt''': '''horse''',
'''generator''': generator,
'''guidance_scale''': 4.0,
'''num_inference_steps''': 2,
'''output_type''': '''np''',
}
return inputs
def __UpperCAmelCase ( self ):
__a = '''cpu'''
__a = self.get_dummy_components()
__a = self.pipeline_class(**_a )
__a = pipe.to(_a )
pipe.set_progress_bar_config(disable=_a )
__a = pipe(**self.get_dummy_inputs(_a ) )
__a = output.image_embeds
__a = pipe(
**self.get_dummy_inputs(_a ) , return_dict=_a , )[0]
__a = image[0, -10:]
__a = image_from_tuple[0, -10:]
assert image.shape == (1, 32)
__a = np.array(
[-0.0532, 1.7120, 0.3656, -1.0852, -0.8946, -1.1756, 0.4348, 0.2482, 0.5146, -0.1156] )
assert np.abs(image_slice.flatten() - expected_slice ).max() < 1E-2
assert np.abs(image_from_tuple_slice.flatten() - expected_slice ).max() < 1E-2
@skip_mps
def __UpperCAmelCase ( self ):
__a = torch_device == '''cpu'''
__a = True
__a = False
self._test_inference_batch_single_identical(
test_max_difference=_a , relax_max_difference=_a , test_mean_pixel_difference=_a , )
@skip_mps
def __UpperCAmelCase ( self ):
__a = torch_device == '''cpu'''
__a = False
self._test_attention_slicing_forward_pass(
test_max_difference=_a , test_mean_pixel_difference=_a , )
| 45
|
import unittest
import numpy as np
import torch
from transformers import CLIPTextConfig, CLIPTextModel, CLIPTokenizer
from diffusers import (
AutoencoderKL,
DDIMScheduler,
DPMSolverMultistepScheduler,
TextToVideoSDPipeline,
UNetaDConditionModel,
)
from diffusers.utils import is_xformers_available, load_numpy, skip_mps, slow, torch_device
from diffusers.utils.testing_utils import enable_full_determinism
from ..pipeline_params import TEXT_TO_IMAGE_BATCH_PARAMS, TEXT_TO_IMAGE_PARAMS
from ..test_pipelines_common import PipelineTesterMixin
enable_full_determinism()
@skip_mps
class lowerCamelCase_ ( UpperCAmelCase_ , unittest.TestCase ):
'''simple docstring'''
a__ : str = TextToVideoSDPipeline
a__ : Union[str, Any] = TEXT_TO_IMAGE_PARAMS
a__ : Tuple = TEXT_TO_IMAGE_BATCH_PARAMS
# No `output_type`.
a__ : int = frozenset(
[
"""num_inference_steps""",
"""generator""",
"""latents""",
"""return_dict""",
"""callback""",
"""callback_steps""",
] )
def UpperCamelCase__ ( self) -> Optional[Any]:
torch.manual_seed(0)
__UpperCamelCase :str = UNetaDConditionModel(
block_out_channels=(32, 64, 64, 64) , layers_per_block=2 , sample_size=32 , in_channels=4 , out_channels=4 , down_block_types=('''CrossAttnDownBlock3D''', '''CrossAttnDownBlock3D''', '''CrossAttnDownBlock3D''', '''DownBlock3D''') , up_block_types=('''UpBlock3D''', '''CrossAttnUpBlock3D''', '''CrossAttnUpBlock3D''', '''CrossAttnUpBlock3D''') , cross_attention_dim=32 , attention_head_dim=4 , )
__UpperCamelCase :Optional[int] = DDIMScheduler(
beta_start=0.0_00_85 , beta_end=0.0_12 , beta_schedule='''scaled_linear''' , clip_sample=__lowercase , set_alpha_to_one=__lowercase , )
torch.manual_seed(0)
__UpperCamelCase :Optional[int] = AutoencoderKL(
block_out_channels=[32, 64] , in_channels=3 , out_channels=3 , down_block_types=['''DownEncoderBlock2D''', '''DownEncoderBlock2D'''] , up_block_types=['''UpDecoderBlock2D''', '''UpDecoderBlock2D'''] , latent_channels=4 , sample_size=128 , )
torch.manual_seed(0)
__UpperCamelCase :Optional[int] = CLIPTextConfig(
bos_token_id=0 , eos_token_id=2 , hidden_size=32 , intermediate_size=37 , layer_norm_eps=1E-0_5 , num_attention_heads=4 , num_hidden_layers=5 , pad_token_id=1 , vocab_size=1_000 , hidden_act='''gelu''' , projection_dim=512 , )
__UpperCamelCase :Optional[Any] = CLIPTextModel(__lowercase)
__UpperCamelCase :Optional[int] = CLIPTokenizer.from_pretrained('''hf-internal-testing/tiny-random-clip''')
__UpperCamelCase :Union[str, Any] = {
'''unet''': unet,
'''scheduler''': scheduler,
'''vae''': vae,
'''text_encoder''': text_encoder,
'''tokenizer''': tokenizer,
}
return components
def UpperCamelCase__ ( self , __lowercase , __lowercase=0) -> Optional[int]:
if str(__lowercase).startswith('''mps'''):
__UpperCamelCase :List[Any] = torch.manual_seed(__lowercase)
else:
__UpperCamelCase :Tuple = torch.Generator(device=__lowercase).manual_seed(__lowercase)
__UpperCamelCase :Dict = {
'''prompt''': '''A painting of a squirrel eating a burger''',
'''generator''': generator,
'''num_inference_steps''': 2,
'''guidance_scale''': 6.0,
'''output_type''': '''pt''',
}
return inputs
def UpperCamelCase__ ( self) -> Optional[Any]:
__UpperCamelCase :int = '''cpu''' # ensure determinism for the device-dependent torch.Generator
__UpperCamelCase :Optional[int] = self.get_dummy_components()
__UpperCamelCase :Dict = TextToVideoSDPipeline(**__lowercase)
__UpperCamelCase :Any = sd_pipe.to(__lowercase)
sd_pipe.set_progress_bar_config(disable=__lowercase)
__UpperCamelCase :Optional[Any] = self.get_dummy_inputs(__lowercase)
__UpperCamelCase :int = '''np'''
__UpperCamelCase :List[str] = sd_pipe(**__lowercase).frames
__UpperCamelCase :Optional[Any] = frames[0][-3:, -3:, -1]
assert frames[0].shape == (64, 64, 3)
__UpperCamelCase :str = np.array([1_58.0, 1_60.0, 1_53.0, 1_25.0, 1_00.0, 1_21.0, 1_11.0, 93.0, 1_13.0])
assert np.abs(image_slice.flatten() - expected_slice).max() < 1E-2
def UpperCamelCase__ ( self) -> Tuple:
self._test_attention_slicing_forward_pass(test_mean_pixel_difference=__lowercase , expected_max_diff=3E-3)
@unittest.skipIf(
torch_device != '''cuda''' or not is_xformers_available() , reason='''XFormers attention is only available with CUDA and `xformers` installed''' , )
def UpperCamelCase__ ( self) -> Optional[int]:
self._test_xformers_attention_forwardGenerator_pass(test_mean_pixel_difference=__lowercase , expected_max_diff=1E-2)
@unittest.skip(reason='''Batching needs to be properly figured out first for this pipeline.''')
def UpperCamelCase__ ( self) -> Union[str, Any]:
pass
@unittest.skip(reason='''Batching needs to be properly figured out first for this pipeline.''')
def UpperCamelCase__ ( self) -> Dict:
pass
@unittest.skip(reason='''`num_images_per_prompt` argument is not supported for this pipeline.''')
def UpperCamelCase__ ( self) -> str:
pass
def UpperCamelCase__ ( self) -> List[str]:
return super().test_progress_bar()
@slow
@skip_mps
class lowerCamelCase_ ( unittest.TestCase ):
'''simple docstring'''
def UpperCamelCase__ ( self) -> Dict:
__UpperCamelCase :Union[str, Any] = load_numpy(
'''https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main/text_to_video/video.npy''')
__UpperCamelCase :List[str] = TextToVideoSDPipeline.from_pretrained('''damo-vilab/text-to-video-ms-1.7b''')
__UpperCamelCase :Union[str, Any] = DPMSolverMultistepScheduler.from_config(pipe.scheduler.config)
__UpperCamelCase :str = pipe.to('''cuda''')
__UpperCamelCase :Optional[Any] = '''Spiderman is surfing'''
__UpperCamelCase :Union[str, Any] = torch.Generator(device='''cpu''').manual_seed(0)
__UpperCamelCase :List[Any] = pipe(__lowercase , generator=__lowercase , num_inference_steps=25 , output_type='''pt''').frames
__UpperCamelCase :Optional[int] = video_frames.cpu().numpy()
assert np.abs(expected_video - video).mean() < 5E-2
def UpperCamelCase__ ( self) -> int:
__UpperCamelCase :str = load_numpy(
'''https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main/text_to_video/video_2step.npy''')
__UpperCamelCase :Union[str, Any] = TextToVideoSDPipeline.from_pretrained('''damo-vilab/text-to-video-ms-1.7b''')
__UpperCamelCase :str = pipe.to('''cuda''')
__UpperCamelCase :Union[str, Any] = '''Spiderman is surfing'''
__UpperCamelCase :int = torch.Generator(device='''cpu''').manual_seed(0)
__UpperCamelCase :List[Any] = pipe(__lowercase , generator=__lowercase , num_inference_steps=2 , output_type='''pt''').frames
__UpperCamelCase :Optional[Any] = video_frames.cpu().numpy()
assert np.abs(expected_video - video).mean() < 5E-2
| 43
| 0
|
"""simple docstring"""
import argparse
import json
from collections import OrderedDict
from functools import partial
from pathlib import Path
import timm
import torch
from huggingface_hub import hf_hub_download
from transformers import LevitConfig, LevitForImageClassificationWithTeacher, LevitImageProcessor
from transformers.utils import logging
logging.set_verbosity_info()
SCREAMING_SNAKE_CASE__ = logging.get_logger()
def UpperCAmelCase__ ( SCREAMING_SNAKE_CASE : int , SCREAMING_SNAKE_CASE : str , SCREAMING_SNAKE_CASE : LevitConfig , SCREAMING_SNAKE_CASE : Path , SCREAMING_SNAKE_CASE : bool = True ):
'''simple docstring'''
print(F'Converting {name}...' )
with torch.no_grad():
if hidden_sizes == 1_28:
if name[-1] == "S":
lowerCAmelCase = timm.create_model("""levit_128s""" , pretrained=SCREAMING_SNAKE_CASE )
else:
lowerCAmelCase = timm.create_model("""levit_128""" , pretrained=SCREAMING_SNAKE_CASE )
if hidden_sizes == 1_92:
lowerCAmelCase = timm.create_model("""levit_192""" , pretrained=SCREAMING_SNAKE_CASE )
if hidden_sizes == 2_56:
lowerCAmelCase = timm.create_model("""levit_256""" , pretrained=SCREAMING_SNAKE_CASE )
if hidden_sizes == 3_84:
lowerCAmelCase = timm.create_model("""levit_384""" , pretrained=SCREAMING_SNAKE_CASE )
from_model.eval()
lowerCAmelCase = LevitForImageClassificationWithTeacher(SCREAMING_SNAKE_CASE ).eval()
lowerCAmelCase = OrderedDict()
lowerCAmelCase = from_model.state_dict()
lowerCAmelCase = list(from_model.state_dict().keys() )
lowerCAmelCase = list(our_model.state_dict().keys() )
print(len(SCREAMING_SNAKE_CASE ) , len(SCREAMING_SNAKE_CASE ) )
for i in range(len(SCREAMING_SNAKE_CASE ) ):
lowerCAmelCase = weights[og_keys[i]]
our_model.load_state_dict(SCREAMING_SNAKE_CASE )
lowerCAmelCase = torch.randn((2, 3, 2_24, 2_24) )
lowerCAmelCase = from_model(SCREAMING_SNAKE_CASE )
lowerCAmelCase = our_model(SCREAMING_SNAKE_CASE ).logits
assert torch.allclose(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ), "The model logits don't match the original one."
lowerCAmelCase = name
print(SCREAMING_SNAKE_CASE )
if push_to_hub:
our_model.save_pretrained(save_directory / checkpoint_name )
lowerCAmelCase = LevitImageProcessor()
image_processor.save_pretrained(save_directory / checkpoint_name )
print(F'Pushed {checkpoint_name}' )
def UpperCAmelCase__ ( SCREAMING_SNAKE_CASE : Path , SCREAMING_SNAKE_CASE : str = None , SCREAMING_SNAKE_CASE : bool = True ):
'''simple docstring'''
lowerCAmelCase = """imagenet-1k-id2label.json"""
lowerCAmelCase = 10_00
lowerCAmelCase = (1, num_labels)
lowerCAmelCase = """huggingface/label-files"""
lowerCAmelCase = num_labels
lowerCAmelCase = json.load(open(hf_hub_download(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , repo_type="""dataset""" ) , """r""" ) )
lowerCAmelCase = {int(SCREAMING_SNAKE_CASE ): v for k, v in idalabel.items()}
lowerCAmelCase = idalabel
lowerCAmelCase = {v: k for k, v in idalabel.items()}
lowerCAmelCase = partial(SCREAMING_SNAKE_CASE , num_labels=SCREAMING_SNAKE_CASE , idalabel=SCREAMING_SNAKE_CASE , labelaid=SCREAMING_SNAKE_CASE )
lowerCAmelCase = {
"""levit-128S""": 1_28,
"""levit-128""": 1_28,
"""levit-192""": 1_92,
"""levit-256""": 2_56,
"""levit-384""": 3_84,
}
lowerCAmelCase = {
"""levit-128S""": ImageNetPreTrainedConfig(
hidden_sizes=[1_28, 2_56, 3_84] , num_attention_heads=[4, 6, 8] , depths=[2, 3, 4] , key_dim=[16, 16, 16] , drop_path_rate=0 , ),
"""levit-128""": ImageNetPreTrainedConfig(
hidden_sizes=[1_28, 2_56, 3_84] , num_attention_heads=[4, 8, 12] , depths=[4, 4, 4] , key_dim=[16, 16, 16] , drop_path_rate=0 , ),
"""levit-192""": ImageNetPreTrainedConfig(
hidden_sizes=[1_92, 2_88, 3_84] , num_attention_heads=[3, 5, 6] , depths=[4, 4, 4] , key_dim=[32, 32, 32] , drop_path_rate=0 , ),
"""levit-256""": ImageNetPreTrainedConfig(
hidden_sizes=[2_56, 3_84, 5_12] , num_attention_heads=[4, 6, 8] , depths=[4, 4, 4] , key_dim=[32, 32, 32] , drop_path_rate=0 , ),
"""levit-384""": ImageNetPreTrainedConfig(
hidden_sizes=[3_84, 5_12, 7_68] , num_attention_heads=[6, 9, 12] , depths=[4, 4, 4] , key_dim=[32, 32, 32] , drop_path_rate=0.1 , ),
}
if model_name:
convert_weight_and_push(
names_to_hidden_sizes[model_name] , SCREAMING_SNAKE_CASE , names_to_config[model_name] , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
else:
for model_name, config in names_to_config.items():
convert_weight_and_push(names_to_hidden_sizes[model_name] , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
return config, expected_shape
if __name__ == "__main__":
SCREAMING_SNAKE_CASE__ = argparse.ArgumentParser()
# Required parameters
parser.add_argument(
"--model_name",
default=None,
type=str,
help="The name of the model you wish to convert, it must be one of the supported Levit* architecture,",
)
parser.add_argument(
"--pytorch_dump_folder_path",
default="levit-dump-folder/",
type=Path,
required=False,
help="Path to the output PyTorch model directory.",
)
parser.add_argument("--push_to_hub", action="store_true", help="Push model and image processor to the hub")
parser.add_argument(
"--no-push_to_hub",
dest="push_to_hub",
action="store_false",
help="Do not push model and image processor to the hub",
)
SCREAMING_SNAKE_CASE__ = parser.parse_args()
SCREAMING_SNAKE_CASE__ = args.pytorch_dump_folder_path
pytorch_dump_folder_path.mkdir(exist_ok=True, parents=True)
convert_weights_and_push(pytorch_dump_folder_path, args.model_name, args.push_to_hub)
| 46
|
def lowerCamelCase ( SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Tuple = [0 for i in range(len(SCREAMING_SNAKE_CASE ) )]
# initialize interval's left pointer and right pointer
__UpperCamelCase , __UpperCamelCase :str = 0, 0
for i in range(1 , len(SCREAMING_SNAKE_CASE ) ):
# case when current index is inside the interval
if i <= right_pointer:
__UpperCamelCase :Union[str, Any] = min(right_pointer - i + 1 , z_result[i - left_pointer] )
__UpperCamelCase :Tuple = min_edge
while go_next(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
z_result[i] += 1
# if new index's result gives us more right interval,
# we've to update left_pointer and right_pointer
if i + z_result[i] - 1 > right_pointer:
__UpperCamelCase , __UpperCamelCase :Union[str, Any] = i, i + z_result[i] - 1
return z_result
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
return i + z_result[i] < len(SCREAMING_SNAKE_CASE ) and s[z_result[i]] == s[i + z_result[i]]
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :List[Any] = 0
# concatenate 'pattern' and 'input_str' and call z_function
# with concatenated string
__UpperCamelCase :Tuple = z_function(pattern + input_str )
for val in z_result:
# if value is greater then length of the pattern string
# that means this index is starting position of substring
# which is equal to pattern string
if val >= len(SCREAMING_SNAKE_CASE ):
answer += 1
return answer
if __name__ == "__main__":
import doctest
doctest.testmod()
| 43
| 0
|
'''simple docstring'''
def _lowerCAmelCase ( _UpperCamelCase : str ) -> str:
"""simple docstring"""
return "".join(chr(ord(_UpperCamelCase ) - 32 ) if 'a' <= char <= 'z' else char for char in word )
if __name__ == "__main__":
from doctest import testmod
testmod()
| 47
|
import math
from typing import Any, Callable, List, Optional, Tuple, Union
import numpy as np
import torch
from ...models import TaFilmDecoder
from ...schedulers import DDPMScheduler
from ...utils import is_onnx_available, logging, randn_tensor
if is_onnx_available():
from ..onnx_utils import OnnxRuntimeModel
from ..pipeline_utils import AudioPipelineOutput, DiffusionPipeline
from .continous_encoder import SpectrogramContEncoder
from .notes_encoder import SpectrogramNotesEncoder
__lowercase = logging.get_logger(__name__) # pylint: disable=invalid-name
__lowercase = 256
class lowerCamelCase_ ( UpperCAmelCase_ ):
'''simple docstring'''
a__ : Tuple = ["""melgan"""]
def __init__( self , __lowercase , __lowercase , __lowercase , __lowercase , __lowercase , ) -> None:
super().__init__()
# From MELGAN
__UpperCamelCase :int = math.log(1E-5) # Matches MelGAN training.
__UpperCamelCase :int = 4.0 # Largest value for most examples
__UpperCamelCase :str = 128
self.register_modules(
notes_encoder=__lowercase , continuous_encoder=__lowercase , decoder=__lowercase , scheduler=__lowercase , melgan=__lowercase , )
def UpperCamelCase__ ( self , __lowercase , __lowercase=(-1.0, 1.0) , __lowercase=False) -> Dict:
__UpperCamelCase , __UpperCamelCase :str = output_range
if clip:
__UpperCamelCase :Union[str, Any] = torch.clip(__lowercase , self.min_value , self.max_value)
# Scale to [0, 1].
__UpperCamelCase :Union[str, Any] = (features - self.min_value) / (self.max_value - self.min_value)
# Scale to [min_out, max_out].
return zero_one * (max_out - min_out) + min_out
def UpperCamelCase__ ( self , __lowercase , __lowercase=(-1.0, 1.0) , __lowercase=False) -> Optional[int]:
__UpperCamelCase , __UpperCamelCase :int = input_range
__UpperCamelCase :Optional[int] = torch.clip(__lowercase , __lowercase , __lowercase) if clip else outputs
# Scale to [0, 1].
__UpperCamelCase :List[str] = (outputs - min_out) / (max_out - min_out)
# Scale to [self.min_value, self.max_value].
return zero_one * (self.max_value - self.min_value) + self.min_value
def UpperCamelCase__ ( self , __lowercase , __lowercase , __lowercase) -> List[Any]:
__UpperCamelCase :List[str] = input_tokens > 0
__UpperCamelCase , __UpperCamelCase :Union[str, Any] = self.notes_encoder(
encoder_input_tokens=__lowercase , encoder_inputs_mask=__lowercase)
__UpperCamelCase , __UpperCamelCase :Union[str, Any] = self.continuous_encoder(
encoder_inputs=__lowercase , encoder_inputs_mask=__lowercase)
return [(tokens_encoded, tokens_mask), (continuous_encoded, continuous_mask)]
def UpperCamelCase__ ( self , __lowercase , __lowercase , __lowercase) -> str:
__UpperCamelCase :Optional[int] = noise_time
if not torch.is_tensor(__lowercase):
__UpperCamelCase :str = torch.tensor([timesteps] , dtype=torch.long , device=input_tokens.device)
elif torch.is_tensor(__lowercase) and len(timesteps.shape) == 0:
__UpperCamelCase :Dict = timesteps[None].to(input_tokens.device)
# broadcast to batch dimension in a way that's compatible with ONNX/Core ML
__UpperCamelCase :List[str] = timesteps * torch.ones(input_tokens.shape[0] , dtype=timesteps.dtype , device=timesteps.device)
__UpperCamelCase :Tuple = self.decoder(
encodings_and_masks=__lowercase , decoder_input_tokens=__lowercase , decoder_noise_time=__lowercase)
return logits
@torch.no_grad()
def __call__( self , __lowercase , __lowercase = None , __lowercase = 100 , __lowercase = True , __lowercase = "numpy" , __lowercase = None , __lowercase = 1 , ) -> Union[AudioPipelineOutput, Tuple]:
if (callback_steps is None) or (
callback_steps is not None and (not isinstance(__lowercase , __lowercase) or callback_steps <= 0)
):
raise ValueError(
f"""`callback_steps` has to be a positive integer but is {callback_steps} of type"""
f""" {type(__lowercase)}.""")
__UpperCamelCase :Union[str, Any] = np.zeros([1, TARGET_FEATURE_LENGTH, self.n_dims] , dtype=np.floataa)
__UpperCamelCase :Union[str, Any] = np.zeros([1, 0, self.n_dims] , np.floataa)
__UpperCamelCase :Union[str, Any] = torch.ones((1, TARGET_FEATURE_LENGTH) , dtype=__lowercase , device=self.device)
for i, encoder_input_tokens in enumerate(__lowercase):
if i == 0:
__UpperCamelCase :int = torch.from_numpy(pred_mel[:1].copy()).to(
device=self.device , dtype=self.decoder.dtype)
# The first chunk has no previous context.
__UpperCamelCase :int = torch.zeros((1, TARGET_FEATURE_LENGTH) , dtype=__lowercase , device=self.device)
else:
# The full song pipeline does not feed in a context feature, so the mask
# will be all 0s after the feature converter. Because we know we're
# feeding in a full context chunk from the previous prediction, set it
# to all 1s.
__UpperCamelCase :Tuple = ones
__UpperCamelCase :Optional[Any] = self.scale_features(
__lowercase , output_range=[-1.0, 1.0] , clip=__lowercase)
__UpperCamelCase :int = self.encode(
input_tokens=torch.IntTensor([encoder_input_tokens]).to(device=self.device) , continuous_inputs=__lowercase , continuous_mask=__lowercase , )
# Sample encoder_continuous_inputs shaped gaussian noise to begin loop
__UpperCamelCase :int = randn_tensor(
shape=encoder_continuous_inputs.shape , generator=__lowercase , device=self.device , dtype=self.decoder.dtype , )
# set step values
self.scheduler.set_timesteps(__lowercase)
# Denoising diffusion loop
for j, t in enumerate(self.progress_bar(self.scheduler.timesteps)):
__UpperCamelCase :Optional[int] = self.decode(
encodings_and_masks=__lowercase , input_tokens=__lowercase , noise_time=t / self.scheduler.config.num_train_timesteps , )
# Compute previous output: x_t -> x_t-1
__UpperCamelCase :int = self.scheduler.step(__lowercase , __lowercase , __lowercase , generator=__lowercase).prev_sample
__UpperCamelCase :Tuple = self.scale_to_features(__lowercase , input_range=[-1.0, 1.0])
__UpperCamelCase :List[Any] = mel[:1]
__UpperCamelCase :Optional[Any] = mel.cpu().float().numpy()
__UpperCamelCase :Any = np.concatenate([full_pred_mel, pred_mel[:1]] , axis=1)
# call the callback, if provided
if callback is not None and i % callback_steps == 0:
callback(__lowercase , __lowercase)
logger.info('''Generated segment''' , __lowercase)
if output_type == "numpy" and not is_onnx_available():
raise ValueError(
'''Cannot return output in \'np\' format if ONNX is not available. Make sure to have ONNX installed or set \'output_type\' to \'mel\'.''')
elif output_type == "numpy" and self.melgan is None:
raise ValueError(
'''Cannot return output in \'np\' format if melgan component is not defined. Make sure to define `self.melgan` or set \'output_type\' to \'mel\'.''')
if output_type == "numpy":
__UpperCamelCase :Optional[Any] = self.melgan(input_features=full_pred_mel.astype(np.floataa))
else:
__UpperCamelCase :List[str] = full_pred_mel
if not return_dict:
return (output,)
return AudioPipelineOutput(audios=__lowercase)
| 43
| 0
|
def A ( _SCREAMING_SNAKE_CASE ,_SCREAMING_SNAKE_CASE ) -> Any:
# "extended trapezoidal rule"
# int(f) = dx/2 * (f1 + 2f2 + ... + fn)
lowerCamelCase : str = (boundary[1] - boundary[0]) / steps
lowerCamelCase : List[str] = boundary[0]
lowerCamelCase : Union[str, Any] = boundary[1]
lowerCamelCase : int = make_points(_SCREAMING_SNAKE_CASE ,_SCREAMING_SNAKE_CASE ,_SCREAMING_SNAKE_CASE )
lowerCamelCase : List[str] = 0.0
y += (h / 2.0) * f(_SCREAMING_SNAKE_CASE )
for i in x_i:
# print(i)
y += h * f(_SCREAMING_SNAKE_CASE )
y += (h / 2.0) * f(_SCREAMING_SNAKE_CASE )
return y
def A ( _SCREAMING_SNAKE_CASE ,_SCREAMING_SNAKE_CASE ,_SCREAMING_SNAKE_CASE ) -> int:
lowerCamelCase : int = a + h
while x < (b - h):
yield x
lowerCamelCase : List[str] = x + h
def A ( _SCREAMING_SNAKE_CASE ) -> Optional[Any]: # enter your function here
lowerCamelCase : str = (x - 0) * (x - 0)
return y
def A ( ) -> int:
lowerCamelCase : int = 0.0 # Lower bound of integration
lowerCamelCase : int = 1.0 # Upper bound of integration
lowerCamelCase : Dict = 10.0 # define number of steps or resolution
lowerCamelCase : int = [a, b] # define boundary of integration
lowerCamelCase : str = method_a(_SCREAMING_SNAKE_CASE ,_SCREAMING_SNAKE_CASE )
print(f'''y = {y}''' )
if __name__ == "__main__":
main()
| 48
|
import argparse
import json
import os
import fairseq
import torch
from fairseq.data import Dictionary
from transformers import (
HubertConfig,
HubertForCTC,
HubertModel,
WavaVecaCTCTokenizer,
WavaVecaFeatureExtractor,
WavaVecaProcessor,
logging,
)
logging.set_verbosity_info()
__lowercase = logging.get_logger(__name__)
__lowercase = {
'''post_extract_proj''': '''feature_projection.projection''',
'''encoder.pos_conv.0''': '''encoder.pos_conv_embed.conv''',
'''self_attn.k_proj''': '''encoder.layers.*.attention.k_proj''',
'''self_attn.v_proj''': '''encoder.layers.*.attention.v_proj''',
'''self_attn.q_proj''': '''encoder.layers.*.attention.q_proj''',
'''self_attn.out_proj''': '''encoder.layers.*.attention.out_proj''',
'''self_attn_layer_norm''': '''encoder.layers.*.layer_norm''',
'''fc1''': '''encoder.layers.*.feed_forward.intermediate_dense''',
'''fc2''': '''encoder.layers.*.feed_forward.output_dense''',
'''final_layer_norm''': '''encoder.layers.*.final_layer_norm''',
'''encoder.layer_norm''': '''encoder.layer_norm''',
'''w2v_model.layer_norm''': '''feature_projection.layer_norm''',
'''w2v_encoder.proj''': '''lm_head''',
'''mask_emb''': '''masked_spec_embed''',
}
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
for attribute in key.split('''.''' ):
__UpperCamelCase :str = getattr(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
if weight_type is not None:
__UpperCamelCase :Any = getattr(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ).shape
else:
__UpperCamelCase :Union[str, Any] = hf_pointer.shape
assert hf_shape == value.shape, (
f"""Shape of hf {key + '.' + weight_type if weight_type is not None else ''} is {hf_shape}, but should be"""
f""" {value.shape} for {full_name}"""
)
if weight_type == "weight":
__UpperCamelCase :str = value
elif weight_type == "weight_g":
__UpperCamelCase :List[str] = value
elif weight_type == "weight_v":
__UpperCamelCase :str = value
elif weight_type == "bias":
__UpperCamelCase :Union[str, Any] = value
else:
__UpperCamelCase :str = value
logger.info(f"""{key + '.' + weight_type if weight_type is not None else ''} was initialized from {full_name}.""" )
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :List[Any] = []
__UpperCamelCase :int = fairseq_model.state_dict()
__UpperCamelCase :List[Any] = hf_model.hubert.feature_extractor if is_finetuned else hf_model.feature_extractor
for name, value in fairseq_dict.items():
__UpperCamelCase :List[Any] = False
if "conv_layers" in name:
load_conv_layer(
SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , hf_model.config.feat_extract_norm == '''group''' , )
__UpperCamelCase :List[str] = True
else:
for key, mapped_key in MAPPING.items():
__UpperCamelCase :Dict = '''hubert.''' + mapped_key if (is_finetuned and mapped_key != '''lm_head''') else mapped_key
if key in name or (key.split('''w2v_model.''' )[-1] == name.split('''.''' )[0] and not is_finetuned):
__UpperCamelCase :Optional[Any] = True
if "*" in mapped_key:
__UpperCamelCase :List[str] = name.split(SCREAMING_SNAKE_CASE )[0].split('''.''' )[-2]
__UpperCamelCase :Optional[int] = mapped_key.replace('''*''' , SCREAMING_SNAKE_CASE )
if "weight_g" in name:
__UpperCamelCase :int = '''weight_g'''
elif "weight_v" in name:
__UpperCamelCase :List[Any] = '''weight_v'''
elif "weight" in name:
__UpperCamelCase :Dict = '''weight'''
elif "bias" in name:
__UpperCamelCase :Dict = '''bias'''
else:
__UpperCamelCase :Dict = None
set_recursively(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
continue
if not is_used:
unused_weights.append(SCREAMING_SNAKE_CASE )
logger.warning(f"""Unused weights: {unused_weights}""" )
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Tuple = full_name.split('''conv_layers.''' )[-1]
__UpperCamelCase :Optional[int] = name.split('''.''' )
__UpperCamelCase :str = int(items[0] )
__UpperCamelCase :List[Any] = int(items[1] )
if type_id == 0:
if "bias" in name:
assert value.shape == feature_extractor.conv_layers[layer_id].conv.bias.data.shape, (
f"""{full_name} has size {value.shape}, but"""
f""" {feature_extractor.conv_layers[layer_id].conv.bias.data.shape} was found."""
)
__UpperCamelCase :Dict = value
logger.info(f"""Feat extract conv layer {layer_id} was initialized from {full_name}.""" )
elif "weight" in name:
assert value.shape == feature_extractor.conv_layers[layer_id].conv.weight.data.shape, (
f"""{full_name} has size {value.shape}, but"""
f""" {feature_extractor.conv_layers[layer_id].conv.weight.data.shape} was found."""
)
__UpperCamelCase :Any = value
logger.info(f"""Feat extract conv layer {layer_id} was initialized from {full_name}.""" )
elif (type_id == 2 and not use_group_norm) or (type_id == 2 and layer_id == 0 and use_group_norm):
if "bias" in name:
assert value.shape == feature_extractor.conv_layers[layer_id].layer_norm.bias.data.shape, (
f"""{full_name} has size {value.shape}, but {feature_extractor[layer_id].layer_norm.bias.data.shape} was"""
" found."
)
__UpperCamelCase :int = value
logger.info(f"""Feat extract layer norm weight of layer {layer_id} was initialized from {full_name}.""" )
elif "weight" in name:
assert value.shape == feature_extractor.conv_layers[layer_id].layer_norm.weight.data.shape, (
f"""{full_name} has size {value.shape}, but"""
f""" {feature_extractor[layer_id].layer_norm.weight.data.shape} was found."""
)
__UpperCamelCase :Union[str, Any] = value
logger.info(f"""Feat extract layer norm weight of layer {layer_id} was initialized from {full_name}.""" )
else:
unused_weights.append(SCREAMING_SNAKE_CASE )
@torch.no_grad()
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE=None , SCREAMING_SNAKE_CASE=None , SCREAMING_SNAKE_CASE=True ):
'''simple docstring'''
if config_path is not None:
__UpperCamelCase :Tuple = HubertConfig.from_pretrained(SCREAMING_SNAKE_CASE )
else:
__UpperCamelCase :Optional[int] = HubertConfig()
if is_finetuned:
if dict_path:
__UpperCamelCase :Optional[int] = Dictionary.load(SCREAMING_SNAKE_CASE )
# important change bos & pad token id since CTC symbol is <pad> and
# not <s> as in fairseq
__UpperCamelCase :Optional[int] = target_dict.pad_index
__UpperCamelCase :Dict = target_dict.bos_index
__UpperCamelCase :str = target_dict.eos_index
__UpperCamelCase :Dict = len(target_dict.symbols )
__UpperCamelCase :List[Any] = os.path.join(SCREAMING_SNAKE_CASE , '''vocab.json''' )
if not os.path.isdir(SCREAMING_SNAKE_CASE ):
logger.error('''--pytorch_dump_folder_path ({}) should be a directory'''.format(SCREAMING_SNAKE_CASE ) )
return
os.makedirs(SCREAMING_SNAKE_CASE , exist_ok=SCREAMING_SNAKE_CASE )
with open(SCREAMING_SNAKE_CASE , '''w''' , encoding='''utf-8''' ) as vocab_handle:
json.dump(target_dict.indices , SCREAMING_SNAKE_CASE )
__UpperCamelCase :Optional[int] = WavaVecaCTCTokenizer(
SCREAMING_SNAKE_CASE , unk_token=target_dict.unk_word , pad_token=target_dict.pad_word , bos_token=target_dict.bos_word , eos_token=target_dict.eos_word , word_delimiter_token='''|''' , do_lower_case=SCREAMING_SNAKE_CASE , )
__UpperCamelCase :Union[str, Any] = True if config.feat_extract_norm == '''layer''' else False
__UpperCamelCase :Any = WavaVecaFeatureExtractor(
feature_size=1 , sampling_rate=16_000 , padding_value=0 , do_normalize=SCREAMING_SNAKE_CASE , return_attention_mask=SCREAMING_SNAKE_CASE , )
__UpperCamelCase :Any = WavaVecaProcessor(feature_extractor=SCREAMING_SNAKE_CASE , tokenizer=SCREAMING_SNAKE_CASE )
processor.save_pretrained(SCREAMING_SNAKE_CASE )
__UpperCamelCase :List[str] = HubertForCTC(SCREAMING_SNAKE_CASE )
else:
__UpperCamelCase :str = HubertModel(SCREAMING_SNAKE_CASE )
if is_finetuned:
__UpperCamelCase , __UpperCamelCase , __UpperCamelCase :int = fairseq.checkpoint_utils.load_model_ensemble_and_task(
[checkpoint_path] , arg_overrides={'''data''': '''/'''.join(dict_path.split('''/''' )[:-1] )} )
else:
__UpperCamelCase , __UpperCamelCase , __UpperCamelCase :Any = fairseq.checkpoint_utils.load_model_ensemble_and_task([checkpoint_path] )
__UpperCamelCase :Dict = model[0].eval()
recursively_load_weights(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
hf_wavavec.save_pretrained(SCREAMING_SNAKE_CASE )
if __name__ == "__main__":
__lowercase = argparse.ArgumentParser()
parser.add_argument('''--pytorch_dump_folder_path''', default=None, type=str, help='''Path to the output PyTorch model.''')
parser.add_argument('''--checkpoint_path''', default=None, type=str, help='''Path to fairseq checkpoint''')
parser.add_argument('''--dict_path''', default=None, type=str, help='''Path to dict of fine-tuned model''')
parser.add_argument('''--config_path''', default=None, type=str, help='''Path to hf config.json of model to convert''')
parser.add_argument(
'''--not_finetuned''', action='''store_true''', help='''Whether the model to convert is a fine-tuned model or not'''
)
__lowercase = parser.parse_args()
convert_hubert_checkpoint(
args.checkpoint_path, args.pytorch_dump_folder_path, args.config_path, args.dict_path, not args.not_finetuned
)
| 43
| 0
|
from __future__ import annotations
import numpy as np
from numpy import floataa
from numpy.typing import NDArray
def __snake_case ( _UpperCAmelCase , _UpperCAmelCase , _UpperCAmelCase , _UpperCAmelCase , ):
__a , __a = coefficient_matrix.shape
__a , __a = constant_matrix.shape
if rowsa != colsa:
__a = f'Coefficient matrix dimensions must be nxn but received {rowsa}x{colsa}'
raise ValueError(_UpperCAmelCase )
if colsa != 1:
__a = f'Constant matrix must be nx1 but received {rowsa}x{colsa}'
raise ValueError(_UpperCAmelCase )
if rowsa != rowsa:
__a = (
'''Coefficient and constant matrices dimensions must be nxn and nx1 but '''
f'received {rowsa}x{colsa} and {rowsa}x{colsa}'
)
raise ValueError(_UpperCAmelCase )
if len(_UpperCAmelCase ) != rowsa:
__a = (
'''Number of initial values must be equal to number of rows in coefficient '''
f'matrix but received {len(_UpperCAmelCase )} and {rowsa}'
)
raise ValueError(_UpperCAmelCase )
if iterations <= 0:
raise ValueError('''Iterations must be at least 1''' )
__a = np.concatenate(
(coefficient_matrix, constant_matrix) , axis=1 )
__a , __a = table.shape
strictly_diagonally_dominant(_UpperCAmelCase )
# Iterates the whole matrix for given number of times
for _ in range(_UpperCAmelCase ):
__a = []
for row in range(_UpperCAmelCase ):
__a = 0
for col in range(_UpperCAmelCase ):
if col == row:
__a = table[row][col]
elif col == cols - 1:
__a = table[row][col]
else:
temp += (-1) * table[row][col] * init_val[col]
__a = (temp + val) / denom
new_val.append(_UpperCAmelCase )
__a = new_val
return [float(_UpperCAmelCase ) for i in new_val]
def __snake_case ( _UpperCAmelCase ):
__a , __a = table.shape
__a = True
for i in range(0 , _UpperCAmelCase ):
__a = 0
for j in range(0 , cols - 1 ):
if i == j:
continue
else:
total += table[i][j]
if table[i][i] <= total:
raise ValueError('''Coefficient matrix is not strictly diagonally dominant''' )
return is_diagonally_dominant
# Test Cases
if __name__ == "__main__":
import doctest
doctest.testmod()
| 49
|
import glob
import os
import random
from string import ascii_lowercase, digits
import cva
import numpy as np
# Parrameters
__lowercase = (720, 1280) # Height, Width
__lowercase = (0.4, 0.6) # if height or width lower than this scale, drop it.
__lowercase = 1 / 100
__lowercase = ''''''
__lowercase = ''''''
__lowercase = ''''''
__lowercase = 250
def lowerCamelCase ( ):
'''simple docstring'''
__UpperCamelCase , __UpperCamelCase :List[Any] = get_dataset(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
for index in range(SCREAMING_SNAKE_CASE ):
__UpperCamelCase :Optional[Any] = random.sample(range(len(SCREAMING_SNAKE_CASE ) ) , 4 )
__UpperCamelCase , __UpperCamelCase , __UpperCamelCase :str = update_image_and_anno(
SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , filter_scale=SCREAMING_SNAKE_CASE , )
# Get random string code: '7b7ad245cdff75241935e4dd860f3bad'
__UpperCamelCase :List[Any] = random_chars(32 )
__UpperCamelCase :List[str] = path.split(os.sep )[-1].rsplit('''.''' , 1 )[0]
__UpperCamelCase :Tuple = f"""{OUTPUT_DIR}/{file_name}_MOSAIC_{letter_code}"""
cva.imwrite(f"""{file_root}.jpg""" , SCREAMING_SNAKE_CASE , [cva.IMWRITE_JPEG_QUALITY, 85] )
print(f"""Succeeded {index+1}/{NUMBER_IMAGES} with {file_name}""" )
__UpperCamelCase :Optional[Any] = []
for anno in new_annos:
__UpperCamelCase :int = anno[3] - anno[1]
__UpperCamelCase :Optional[int] = anno[4] - anno[2]
__UpperCamelCase :int = anno[1] + width / 2
__UpperCamelCase :List[str] = anno[2] + height / 2
__UpperCamelCase :str = f"""{anno[0]} {x_center} {y_center} {width} {height}"""
annos_list.append(SCREAMING_SNAKE_CASE )
with open(f"""{file_root}.txt""" , '''w''' ) as outfile:
outfile.write('''\n'''.join(line for line in annos_list ) )
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :str = []
__UpperCamelCase :str = []
for label_file in glob.glob(os.path.join(SCREAMING_SNAKE_CASE , '''*.txt''' ) ):
__UpperCamelCase :Any = label_file.split(os.sep )[-1].rsplit('''.''' , 1 )[0]
with open(SCREAMING_SNAKE_CASE ) as in_file:
__UpperCamelCase :str = in_file.readlines()
__UpperCamelCase :Optional[int] = os.path.join(SCREAMING_SNAKE_CASE , f"""{label_name}.jpg""" )
__UpperCamelCase :int = []
for obj_list in obj_lists:
__UpperCamelCase :Optional[int] = obj_list.rstrip('''\n''' ).split(''' ''' )
__UpperCamelCase :Any = float(obj[1] ) - float(obj[3] ) / 2
__UpperCamelCase :List[str] = float(obj[2] ) - float(obj[4] ) / 2
__UpperCamelCase :Dict = float(obj[1] ) + float(obj[3] ) / 2
__UpperCamelCase :List[str] = float(obj[2] ) + float(obj[4] ) / 2
boxes.append([int(obj[0] ), xmin, ymin, xmax, ymax] )
if not boxes:
continue
img_paths.append(SCREAMING_SNAKE_CASE )
labels.append(SCREAMING_SNAKE_CASE )
return img_paths, labels
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE = 0.0 , ):
'''simple docstring'''
__UpperCamelCase :List[str] = np.zeros([output_size[0], output_size[1], 3] , dtype=np.uinta )
__UpperCamelCase :List[Any] = scale_range[0] + random.random() * (scale_range[1] - scale_range[0])
__UpperCamelCase :int = scale_range[0] + random.random() * (scale_range[1] - scale_range[0])
__UpperCamelCase :Optional[int] = int(scale_x * output_size[1] )
__UpperCamelCase :Any = int(scale_y * output_size[0] )
__UpperCamelCase :List[str] = []
__UpperCamelCase :Dict = []
for i, index in enumerate(SCREAMING_SNAKE_CASE ):
__UpperCamelCase :Any = all_img_list[index]
path_list.append(SCREAMING_SNAKE_CASE )
__UpperCamelCase :Any = all_annos[index]
__UpperCamelCase :Union[str, Any] = cva.imread(SCREAMING_SNAKE_CASE )
if i == 0: # top-left
__UpperCamelCase :str = cva.resize(SCREAMING_SNAKE_CASE , (divid_point_x, divid_point_y) )
__UpperCamelCase :Union[str, Any] = img
for bbox in img_annos:
__UpperCamelCase :Union[str, Any] = bbox[1] * scale_x
__UpperCamelCase :Optional[Any] = bbox[2] * scale_y
__UpperCamelCase :int = bbox[3] * scale_x
__UpperCamelCase :Union[str, Any] = bbox[4] * scale_y
new_anno.append([bbox[0], xmin, ymin, xmax, ymax] )
elif i == 1: # top-right
__UpperCamelCase :str = cva.resize(SCREAMING_SNAKE_CASE , (output_size[1] - divid_point_x, divid_point_y) )
__UpperCamelCase :List[str] = img
for bbox in img_annos:
__UpperCamelCase :str = scale_x + bbox[1] * (1 - scale_x)
__UpperCamelCase :Dict = bbox[2] * scale_y
__UpperCamelCase :Optional[Any] = scale_x + bbox[3] * (1 - scale_x)
__UpperCamelCase :List[Any] = bbox[4] * scale_y
new_anno.append([bbox[0], xmin, ymin, xmax, ymax] )
elif i == 2: # bottom-left
__UpperCamelCase :str = cva.resize(SCREAMING_SNAKE_CASE , (divid_point_x, output_size[0] - divid_point_y) )
__UpperCamelCase :Optional[int] = img
for bbox in img_annos:
__UpperCamelCase :Tuple = bbox[1] * scale_x
__UpperCamelCase :Optional[Any] = scale_y + bbox[2] * (1 - scale_y)
__UpperCamelCase :Tuple = bbox[3] * scale_x
__UpperCamelCase :Dict = scale_y + bbox[4] * (1 - scale_y)
new_anno.append([bbox[0], xmin, ymin, xmax, ymax] )
else: # bottom-right
__UpperCamelCase :Optional[int] = cva.resize(
SCREAMING_SNAKE_CASE , (output_size[1] - divid_point_x, output_size[0] - divid_point_y) )
__UpperCamelCase :Optional[int] = img
for bbox in img_annos:
__UpperCamelCase :Optional[Any] = scale_x + bbox[1] * (1 - scale_x)
__UpperCamelCase :Optional[int] = scale_y + bbox[2] * (1 - scale_y)
__UpperCamelCase :Optional[Any] = scale_x + bbox[3] * (1 - scale_x)
__UpperCamelCase :int = scale_y + bbox[4] * (1 - scale_y)
new_anno.append([bbox[0], xmin, ymin, xmax, ymax] )
# Remove bounding box small than scale of filter
if filter_scale > 0:
__UpperCamelCase :List[Any] = [
anno
for anno in new_anno
if filter_scale < (anno[3] - anno[1]) and filter_scale < (anno[4] - anno[2])
]
return output_img, new_anno, path_list[0]
def lowerCamelCase ( SCREAMING_SNAKE_CASE ):
'''simple docstring'''
assert number_char > 1, "The number of character should greater than 1"
__UpperCamelCase :Optional[Any] = ascii_lowercase + digits
return "".join(random.choice(SCREAMING_SNAKE_CASE ) for _ in range(SCREAMING_SNAKE_CASE ) )
if __name__ == "__main__":
main()
print('''DONE ✅''')
| 43
| 0
|
import argparse
import evaluate
import torch
from datasets import load_dataset
from torch.optim import AdamW
from torch.utils.data import DataLoader
from transformers import AutoModelForSequenceClassification, AutoTokenizer, get_linear_schedule_with_warmup, set_seed
from accelerate import Accelerator, DistributedType
########################################################################
# This is a fully working simple example to use Accelerate
#
# This example trains a Bert base model on GLUE MRPC
# in any of the following settings (with the same script):
# - single CPU or single GPU
# - multi GPUS (using PyTorch distributed mode)
# - (multi) TPUs
# - fp16 (mixed-precision) or fp32 (normal precision)
#
# To run it in each of these various modes, follow the instructions
# in the readme for examples:
# https://github.com/huggingface/accelerate/tree/main/examples
#
########################################################################
_UpperCAmelCase : str = 16
_UpperCAmelCase : str = 32
def SCREAMING_SNAKE_CASE ( _UpperCAmelCase , _UpperCAmelCase = 16 ) -> str:
lowerCamelCase__ : int = AutoTokenizer.from_pretrained('bert-base-cased' )
lowerCamelCase__ : Union[str, Any] = load_dataset('glue' , 'mrpc' )
def tokenize_function(_UpperCAmelCase ):
# max_length=None => use the model max length (it's actually the default)
lowerCamelCase__ : int = tokenizer(examples['sentence1'] , examples['sentence2'] , truncation=_UpperCAmelCase , max_length=_UpperCAmelCase )
return outputs
# Apply the method we just defined to all the examples in all the splits of the dataset
# starting with the main process first:
with accelerator.main_process_first():
lowerCamelCase__ : Any = datasets.map(
_UpperCAmelCase , batched=_UpperCAmelCase , remove_columns=['idx', 'sentence1', 'sentence2'] , )
# We also rename the 'label' column to 'labels' which is the expected name for labels by the models of the
# transformers library
lowerCamelCase__ : Dict = tokenized_datasets.rename_column('label' , 'labels' )
def collate_fn(_UpperCAmelCase ):
# On TPU it's best to pad everything to the same length or training will be very slow.
lowerCamelCase__ : Dict = 128 if accelerator.distributed_type == DistributedType.TPU else None
# When using mixed precision we want round multiples of 8/16
if accelerator.mixed_precision == "fp8":
lowerCamelCase__ : List[Any] = 16
elif accelerator.mixed_precision != "no":
lowerCamelCase__ : Dict = 8
else:
lowerCamelCase__ : Any = None
return tokenizer.pad(
_UpperCAmelCase , padding='longest' , max_length=_UpperCAmelCase , pad_to_multiple_of=_UpperCAmelCase , return_tensors='pt' , )
# Instantiate dataloaders.
lowerCamelCase__ : List[str] = DataLoader(
tokenized_datasets['train'] , shuffle=_UpperCAmelCase , collate_fn=_UpperCAmelCase , batch_size=_UpperCAmelCase , drop_last=_UpperCAmelCase )
lowerCamelCase__ : str = DataLoader(
tokenized_datasets['validation'] , shuffle=_UpperCAmelCase , collate_fn=_UpperCAmelCase , batch_size=_UpperCAmelCase , drop_last=(accelerator.mixed_precision == 'fp8') , )
return train_dataloader, eval_dataloader
def SCREAMING_SNAKE_CASE ( _UpperCAmelCase , _UpperCAmelCase ) -> Optional[Any]:
# Initialize accelerator
lowerCamelCase__ : Union[str, Any] = Accelerator(cpu=args.cpu , mixed_precision=args.mixed_precision )
# Sample hyper-parameters for learning rate, batch size, seed and a few other HPs
lowerCamelCase__ : int = config['lr']
lowerCamelCase__ : Tuple = int(config['num_epochs'] )
lowerCamelCase__ : Union[str, Any] = int(config['seed'] )
lowerCamelCase__ : List[str] = int(config['batch_size'] )
lowerCamelCase__ : List[str] = evaluate.load('glue' , 'mrpc' )
# If the batch size is too big we use gradient accumulation
lowerCamelCase__ : Dict = 1
if batch_size > MAX_GPU_BATCH_SIZE and accelerator.distributed_type != DistributedType.TPU:
lowerCamelCase__ : Optional[Any] = batch_size // MAX_GPU_BATCH_SIZE
lowerCamelCase__ : Any = MAX_GPU_BATCH_SIZE
set_seed(_UpperCAmelCase )
lowerCamelCase__ , lowerCamelCase__ : Dict = get_dataloaders(_UpperCAmelCase , _UpperCAmelCase )
# Instantiate the model (we build the model here so that the seed also control new weights initialization)
lowerCamelCase__ : Any = AutoModelForSequenceClassification.from_pretrained('bert-base-cased' , return_dict=_UpperCAmelCase )
# We could avoid this line since the accelerator is set with `device_placement=True` (default value).
# Note that if you are placing tensors on devices manually, this line absolutely needs to be before the optimizer
# creation otherwise training will not work on TPU (`accelerate` will kindly throw an error to make us aware of that).
lowerCamelCase__ : Dict = model.to(accelerator.device )
# Instantiate optimizer
lowerCamelCase__ : int = AdamW(params=model.parameters() , lr=_UpperCAmelCase )
# Instantiate scheduler
lowerCamelCase__ : Dict = get_linear_schedule_with_warmup(
optimizer=_UpperCAmelCase , num_warmup_steps=100 , num_training_steps=(len(_UpperCAmelCase ) * num_epochs) // gradient_accumulation_steps , )
# Prepare everything
# There is no specific order to remember, we just need to unpack the objects in the same order we gave them to the
# prepare method.
lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ , lowerCamelCase__ : int = accelerator.prepare(
_UpperCAmelCase , _UpperCAmelCase , _UpperCAmelCase , _UpperCAmelCase , _UpperCAmelCase )
# Now we train the model
for epoch in range(_UpperCAmelCase ):
model.train()
for step, batch in enumerate(_UpperCAmelCase ):
# We could avoid this line since we set the accelerator with `device_placement=True`.
batch.to(accelerator.device )
lowerCamelCase__ : Optional[int] = model(**_UpperCAmelCase )
lowerCamelCase__ : Any = outputs.loss
lowerCamelCase__ : Optional[Any] = loss / gradient_accumulation_steps
accelerator.backward(_UpperCAmelCase )
if step % gradient_accumulation_steps == 0:
optimizer.step()
lr_scheduler.step()
optimizer.zero_grad()
model.eval()
for step, batch in enumerate(_UpperCAmelCase ):
# We could avoid this line since we set the accelerator with `device_placement=True`.
batch.to(accelerator.device )
with torch.no_grad():
lowerCamelCase__ : List[Any] = model(**_UpperCAmelCase )
lowerCamelCase__ : Any = outputs.logits.argmax(dim=-1 )
lowerCamelCase__ , lowerCamelCase__ : Optional[int] = accelerator.gather_for_metrics((predictions, batch['labels']) )
metric.add_batch(
predictions=_UpperCAmelCase , references=_UpperCAmelCase , )
lowerCamelCase__ : List[Any] = metric.compute()
# Use accelerator.print to print only on the main process.
accelerator.print(F"""epoch {epoch}:""" , _UpperCAmelCase )
def SCREAMING_SNAKE_CASE ( ) -> Optional[Any]:
lowerCamelCase__ : str = argparse.ArgumentParser(description='Simple example of training script.' )
parser.add_argument(
'--mixed_precision' , type=_UpperCAmelCase , default=_UpperCAmelCase , choices=['no', 'fp16', 'bf16', 'fp8'] , help='Whether to use mixed precision. Choose'
'between fp16 and bf16 (bfloat16). Bf16 requires PyTorch >= 1.10.'
'and an Nvidia Ampere GPU.' , )
parser.add_argument('--cpu' , action='store_true' , help='If passed, will train on the CPU.' )
lowerCamelCase__ : Tuple = parser.parse_args()
lowerCamelCase__ : Dict = {'lr': 2e-5, 'num_epochs': 3, 'seed': 42, 'batch_size': 16}
training_function(_UpperCAmelCase , _UpperCAmelCase )
if __name__ == "__main__":
main()
| 50
|
import functools
import operator
from ...configuration_utils import PretrainedConfig
from ...utils import logging
__lowercase = logging.get_logger(__name__)
__lowercase = {
'''facebook/wav2vec2-base-960h''': '''https://huggingface.co/facebook/wav2vec2-base-960h/resolve/main/config.json''',
# See all Wav2Vec2 models at https://huggingface.co/models?filter=wav2vec2
}
class lowerCamelCase_ ( UpperCAmelCase_ ):
'''simple docstring'''
a__ : Union[str, Any] = """wav2vec2"""
def __init__( self , __lowercase=32 , __lowercase=768 , __lowercase=12 , __lowercase=12 , __lowercase=3_072 , __lowercase="gelu" , __lowercase=0.1 , __lowercase=0.1 , __lowercase=0.1 , __lowercase=0.0 , __lowercase=0.0 , __lowercase=0.1 , __lowercase=0.1 , __lowercase=0.02 , __lowercase=1E-5 , __lowercase="group" , __lowercase="gelu" , __lowercase=(512, 512, 512, 512, 512, 512, 512) , __lowercase=(5, 2, 2, 2, 2, 2, 2) , __lowercase=(10, 3, 3, 3, 3, 2, 2) , __lowercase=False , __lowercase=128 , __lowercase=16 , __lowercase=False , __lowercase=True , __lowercase=0.05 , __lowercase=10 , __lowercase=2 , __lowercase=0.0 , __lowercase=10 , __lowercase=0 , __lowercase=320 , __lowercase=2 , __lowercase=0.1 , __lowercase=100 , __lowercase=256 , __lowercase=256 , __lowercase=0.1 , __lowercase="sum" , __lowercase=False , __lowercase=False , __lowercase=256 , __lowercase=(512, 512, 512, 512, 1_500) , __lowercase=(5, 3, 3, 1, 1) , __lowercase=(1, 2, 3, 1, 1) , __lowercase=512 , __lowercase=0 , __lowercase=1 , __lowercase=2 , __lowercase=False , __lowercase=3 , __lowercase=2 , __lowercase=3 , __lowercase=None , __lowercase=None , **__lowercase , ) -> int:
super().__init__(**__lowercase , pad_token_id=__lowercase , bos_token_id=__lowercase , eos_token_id=__lowercase)
__UpperCamelCase :Any = hidden_size
__UpperCamelCase :int = feat_extract_norm
__UpperCamelCase :Tuple = feat_extract_activation
__UpperCamelCase :Union[str, Any] = list(__lowercase)
__UpperCamelCase :List[Any] = list(__lowercase)
__UpperCamelCase :int = list(__lowercase)
__UpperCamelCase :List[Any] = conv_bias
__UpperCamelCase :Optional[int] = num_conv_pos_embeddings
__UpperCamelCase :Dict = num_conv_pos_embedding_groups
__UpperCamelCase :Any = len(self.conv_dim)
__UpperCamelCase :List[str] = num_hidden_layers
__UpperCamelCase :int = intermediate_size
__UpperCamelCase :str = hidden_act
__UpperCamelCase :Any = num_attention_heads
__UpperCamelCase :int = hidden_dropout
__UpperCamelCase :Tuple = attention_dropout
__UpperCamelCase :List[str] = activation_dropout
__UpperCamelCase :Optional[Any] = feat_proj_dropout
__UpperCamelCase :Any = final_dropout
__UpperCamelCase :Any = layerdrop
__UpperCamelCase :str = layer_norm_eps
__UpperCamelCase :Optional[Any] = initializer_range
__UpperCamelCase :List[str] = vocab_size
__UpperCamelCase :str = do_stable_layer_norm
__UpperCamelCase :Union[str, Any] = use_weighted_layer_sum
if (
(len(self.conv_stride) != self.num_feat_extract_layers)
or (len(self.conv_kernel) != self.num_feat_extract_layers)
or (len(self.conv_dim) != self.num_feat_extract_layers)
):
raise ValueError(
'''Configuration for convolutional layers is incorrect. It is required that `len(config.conv_dim)` =='''
''' `len(config.conv_stride)` == `len(config.conv_kernel)`, but is `len(config.conv_dim) ='''
f""" {len(self.conv_dim)}`, `len(config.conv_stride) = {len(self.conv_stride)}`,"""
f""" `len(config.conv_kernel) = {len(self.conv_kernel)}`.""")
# fine-tuning config parameters for SpecAugment: https://arxiv.org/abs/1904.08779
__UpperCamelCase :List[Any] = apply_spec_augment
__UpperCamelCase :Tuple = mask_time_prob
__UpperCamelCase :int = mask_time_length
__UpperCamelCase :Dict = mask_time_min_masks
__UpperCamelCase :str = mask_feature_prob
__UpperCamelCase :List[str] = mask_feature_length
__UpperCamelCase :Union[str, Any] = mask_feature_min_masks
# parameters for pretraining with codevector quantized representations
__UpperCamelCase :Optional[Any] = num_codevectors_per_group
__UpperCamelCase :List[Any] = num_codevector_groups
__UpperCamelCase :Tuple = contrastive_logits_temperature
__UpperCamelCase :Optional[int] = feat_quantizer_dropout
__UpperCamelCase :Optional[int] = num_negatives
__UpperCamelCase :List[Any] = codevector_dim
__UpperCamelCase :str = proj_codevector_dim
__UpperCamelCase :List[str] = diversity_loss_weight
# ctc loss
__UpperCamelCase :Tuple = ctc_loss_reduction
__UpperCamelCase :Tuple = ctc_zero_infinity
# adapter
__UpperCamelCase :List[str] = add_adapter
__UpperCamelCase :Tuple = adapter_kernel_size
__UpperCamelCase :str = adapter_stride
__UpperCamelCase :Tuple = num_adapter_layers
__UpperCamelCase :Tuple = output_hidden_size or hidden_size
__UpperCamelCase :Optional[Any] = adapter_attn_dim
# SequenceClassification-specific parameter. Feel free to ignore for other classes.
__UpperCamelCase :Optional[Any] = classifier_proj_size
# XVector-specific parameters. Feel free to ignore for other classes.
__UpperCamelCase :Optional[int] = list(__lowercase)
__UpperCamelCase :List[Any] = list(__lowercase)
__UpperCamelCase :List[Any] = list(__lowercase)
__UpperCamelCase :str = xvector_output_dim
@property
def UpperCamelCase__ ( self) -> List[str]:
return functools.reduce(operator.mul , self.conv_stride , 1)
| 43
| 0
|
from ...configuration_utils import PretrainedConfig
from ...utils import logging
snake_case_ : List[Any] = logging.get_logger(__name__)
snake_case_ : int = {
"transfo-xl-wt103": "https://huggingface.co/transfo-xl-wt103/resolve/main/config.json",
}
class __snake_case ( a ):
UpperCAmelCase__ : Optional[int] = '''transfo-xl'''
UpperCAmelCase__ : Optional[Any] = ['''mems''']
UpperCAmelCase__ : Optional[Any] = {
'''n_token''': '''vocab_size''',
'''hidden_size''': '''d_model''',
'''num_attention_heads''': '''n_head''',
'''num_hidden_layers''': '''n_layer''',
}
def __init__( self : List[str] , _snake_case : Union[str, Any]=267735 , _snake_case : str=[20000, 40000, 200000] , _snake_case : List[Any]=1024 , _snake_case : Any=1024 , _snake_case : Optional[Any]=16 , _snake_case : Tuple=64 , _snake_case : Dict=4096 , _snake_case : Optional[int]=4 , _snake_case : Optional[int]=False , _snake_case : Optional[int]=18 , _snake_case : List[str]=1600 , _snake_case : Any=1000 , _snake_case : Tuple=True , _snake_case : Optional[Any]=True , _snake_case : Optional[Any]=0 , _snake_case : List[str]=-1 , _snake_case : str=True , _snake_case : List[Any]=0.1 , _snake_case : int=0.0 , _snake_case : Optional[int]=True , _snake_case : Optional[int]="normal" , _snake_case : Optional[Any]=0.0_1 , _snake_case : Tuple=0.0_1 , _snake_case : Tuple=0.0_2 , _snake_case : Optional[int]=1e-5 , _snake_case : Union[str, Any]=0 , **_snake_case : Optional[Any] , ):
"""simple docstring"""
UpperCAmelCase_ = vocab_size
UpperCAmelCase_ = []
self.cutoffs.extend(_snake_case)
if proj_share_all_but_first:
UpperCAmelCase_ = [False] + [True] * len(self.cutoffs)
else:
UpperCAmelCase_ = [False] + [False] * len(self.cutoffs)
UpperCAmelCase_ = d_model
UpperCAmelCase_ = d_embed
UpperCAmelCase_ = d_head
UpperCAmelCase_ = d_inner
UpperCAmelCase_ = div_val
UpperCAmelCase_ = pre_lnorm
UpperCAmelCase_ = n_layer
UpperCAmelCase_ = n_head
UpperCAmelCase_ = mem_len
UpperCAmelCase_ = same_length
UpperCAmelCase_ = attn_type
UpperCAmelCase_ = clamp_len
UpperCAmelCase_ = sample_softmax
UpperCAmelCase_ = adaptive
UpperCAmelCase_ = dropout
UpperCAmelCase_ = dropatt
UpperCAmelCase_ = untie_r
UpperCAmelCase_ = init
UpperCAmelCase_ = init_range
UpperCAmelCase_ = proj_init_std
UpperCAmelCase_ = init_std
UpperCAmelCase_ = layer_norm_epsilon
super().__init__(eos_token_id=_snake_case , **_snake_case)
@property
def lowerCamelCase ( self : Optional[int]):
"""simple docstring"""
logger.info(F"""The model {self.model_type} is one of the few models that has no sequence length limit.""")
return -1
@max_position_embeddings.setter
def lowerCamelCase ( self : Union[str, Any] , _snake_case : Dict):
"""simple docstring"""
raise NotImplementedError(
F"""The model {self.model_type} is one of the few models that has no sequence length limit.""")
| 51
|
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
__lowercase = logging.get_logger(__name__)
class lowerCamelCase_ ( UpperCAmelCase_ ):
'''simple docstring'''
a__ : Optional[Any] = ["""pixel_values"""]
def __init__( self , __lowercase = True , __lowercase = 32 , __lowercase=PILImageResampling.BILINEAR , __lowercase = True , **__lowercase , ) -> None:
__UpperCamelCase :Optional[int] = do_resize
__UpperCamelCase :Any = do_rescale
__UpperCamelCase :str = size_divisor
__UpperCamelCase :Dict = resample
super().__init__(**__lowercase)
def UpperCamelCase__ ( self , __lowercase , __lowercase , __lowercase , __lowercase = None , **__lowercase) -> np.ndarray:
__UpperCamelCase , __UpperCamelCase :int = get_image_size(__lowercase)
# Rounds the height and width down to the closest multiple of size_divisor
__UpperCamelCase :List[Any] = height // size_divisor * size_divisor
__UpperCamelCase :List[str] = width // size_divisor * size_divisor
__UpperCamelCase :str = resize(__lowercase , (new_h, new_w) , resample=__lowercase , data_format=__lowercase , **__lowercase)
return image
def UpperCamelCase__ ( self , __lowercase , __lowercase , __lowercase = None , **__lowercase) -> np.ndarray:
return rescale(image=__lowercase , scale=__lowercase , data_format=__lowercase , **__lowercase)
def UpperCamelCase__ ( self , __lowercase , __lowercase = None , __lowercase = None , __lowercase=None , __lowercase = None , __lowercase = None , __lowercase = ChannelDimension.FIRST , **__lowercase , ) -> BatchFeature:
__UpperCamelCase :Union[str, Any] = do_resize if do_resize is not None else self.do_resize
__UpperCamelCase :Tuple = do_rescale if do_rescale is not None else self.do_rescale
__UpperCamelCase :List[str] = size_divisor if size_divisor is not None else self.size_divisor
__UpperCamelCase :List[Any] = 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''')
__UpperCamelCase :List[Any] = make_list_of_images(__lowercase)
if not valid_images(__lowercase):
raise ValueError('''Invalid image(s)''')
# All transformations expect numpy arrays.
__UpperCamelCase :Optional[Any] = [to_numpy_array(__lowercase) for img in images]
if do_resize:
__UpperCamelCase :List[str] = [self.resize(__lowercase , size_divisor=__lowercase , resample=__lowercase) for image in images]
if do_rescale:
__UpperCamelCase :Dict = [self.rescale(__lowercase , scale=1 / 255) for image in images]
__UpperCamelCase :str = [to_channel_dimension_format(__lowercase , __lowercase) for image in images]
__UpperCamelCase :int = {'''pixel_values''': images}
return BatchFeature(data=__lowercase , tensor_type=__lowercase)
| 43
| 0
|
def A_ ( _lowerCAmelCase = 1000 ) -> int:
UpperCamelCase , UpperCamelCase : List[Any] = 1, 1
UpperCamelCase : Union[str, Any] = 2
while True:
UpperCamelCase : Union[str, Any] = 0
UpperCamelCase : Tuple = fa + fa
UpperCamelCase , UpperCamelCase : Optional[Any] = fa, f
index += 1
for _ in str(_lowerCAmelCase ):
i += 1
if i == n:
break
return index
if __name__ == "__main__":
print(solution(int(str(input()).strip())))
| 52
|
from __future__ import annotations
from PIL import Image
# Define glider example
__lowercase = [
[0, 1, 0, 0, 0, 0, 0, 0],
[0, 0, 1, 0, 0, 0, 0, 0],
[1, 1, 1, 0, 0, 0, 0, 0],
[0, 0, 0, 0, 0, 0, 0, 0],
[0, 0, 0, 0, 0, 0, 0, 0],
[0, 0, 0, 0, 0, 0, 0, 0],
[0, 0, 0, 0, 0, 0, 0, 0],
[0, 0, 0, 0, 0, 0, 0, 0],
]
# Define blinker example
__lowercase = [[0, 1, 0], [0, 1, 0], [0, 1, 0]]
def lowerCamelCase ( SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :int = []
for i in range(len(SCREAMING_SNAKE_CASE ) ):
__UpperCamelCase :Dict = []
for j in range(len(cells[i] ) ):
# Get the number of live neighbours
__UpperCamelCase :List[str] = 0
if i > 0 and j > 0:
neighbour_count += cells[i - 1][j - 1]
if i > 0:
neighbour_count += cells[i - 1][j]
if i > 0 and j < len(cells[i] ) - 1:
neighbour_count += cells[i - 1][j + 1]
if j > 0:
neighbour_count += cells[i][j - 1]
if j < len(cells[i] ) - 1:
neighbour_count += cells[i][j + 1]
if i < len(SCREAMING_SNAKE_CASE ) - 1 and j > 0:
neighbour_count += cells[i + 1][j - 1]
if i < len(SCREAMING_SNAKE_CASE ) - 1:
neighbour_count += cells[i + 1][j]
if i < len(SCREAMING_SNAKE_CASE ) - 1 and j < len(cells[i] ) - 1:
neighbour_count += cells[i + 1][j + 1]
# Rules of the game of life (excerpt from Wikipedia):
# 1. Any live cell with two or three live neighbours survives.
# 2. Any dead cell with three live neighbours becomes a live cell.
# 3. All other live cells die in the next generation.
# Similarly, all other dead cells stay dead.
__UpperCamelCase :List[str] = cells[i][j] == 1
if (
(alive and 2 <= neighbour_count <= 3)
or not alive
and neighbour_count == 3
):
next_generation_row.append(1 )
else:
next_generation_row.append(0 )
next_generation.append(SCREAMING_SNAKE_CASE )
return next_generation
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Optional[Any] = []
for _ in range(SCREAMING_SNAKE_CASE ):
# Create output image
__UpperCamelCase :Dict = Image.new('''RGB''' , (len(cells[0] ), len(SCREAMING_SNAKE_CASE )) )
__UpperCamelCase :Any = img.load()
# Save cells to image
for x in range(len(SCREAMING_SNAKE_CASE ) ):
for y in range(len(cells[0] ) ):
__UpperCamelCase :Optional[Any] = 255 - cells[y][x] * 255
__UpperCamelCase :int = (colour, colour, colour)
# Save image
images.append(SCREAMING_SNAKE_CASE )
__UpperCamelCase :Optional[int] = new_generation(SCREAMING_SNAKE_CASE )
return images
if __name__ == "__main__":
__lowercase = generate_images(GLIDER, 16)
images[0].save('''out.gif''', save_all=True, append_images=images[1:])
| 43
| 0
|
'''simple docstring'''
import collections
import json
import os
import re
from typing import TYPE_CHECKING, List, Optional, Tuple
import numpy as np
from ...tokenization_utils_fast import PreTrainedTokenizer
from ...utils import logging
if TYPE_CHECKING:
from transformers.pipelines.conversational import Conversation
a__ : int =logging.get_logger(__name__)
a__ : List[Any] ={'''vocab_file''': '''vocab.txt''', '''emoji_file''': '''emoji.json'''}
a__ : int ={
'''vocab_file''': {
'''abeja/gpt-neox-japanese-2.7b''': '''https://huggingface.co/abeja/gpt-neox-japanese-2.7b/resolve/main/vocab.txt''',
},
'''emoji_file''': {
'''abeja/gpt-neox-japanese-2.7b''': '''https://huggingface.co/abeja/gpt-neox-japanese-2.7b/resolve/main/emoji.json''',
},
}
a__ : Dict ={
'''abeja/gpt-neox-japanese-2.7b''': 2_048,
}
def lowercase__ ( __lowercase : Tuple , __lowercase : Dict ) -> Any:
"""simple docstring"""
with open(__lowercase , 'r' , encoding='utf-8' ) as f:
__UpperCamelCase = json.loads(f.read() )
__UpperCamelCase = collections.OrderedDict()
__UpperCamelCase = collections.OrderedDict()
__UpperCamelCase = collections.OrderedDict()
with open(__lowercase , 'r' , encoding='utf-8' ) as f:
__UpperCamelCase = f.readlines()
__UpperCamelCase = [[t.rstrip('\n' )] if (t == ',' or ',' not in t) else t.rstrip('\n' ).split(',' ) for t in token]
for idx, b in enumerate(__lowercase ):
__UpperCamelCase = b
__UpperCamelCase = idx
for wd in b:
__UpperCamelCase = idx
return vocab, raw_vocab, ids_to_tokens, emoji
class snake_case ( __lowerCamelCase ):
"""simple docstring"""
SCREAMING_SNAKE_CASE_ : Any =VOCAB_FILES_NAMES
SCREAMING_SNAKE_CASE_ : List[str] =PRETRAINED_VOCAB_FILES_MAP
SCREAMING_SNAKE_CASE_ : str =PRETRAINED_POSITIONAL_EMBEDDINGS_SIZES
SCREAMING_SNAKE_CASE_ : Dict =["input_ids", "attention_mask"]
def __init__( self : Dict , __A : List[Any] , __A : Union[str, Any] , __A : List[str]="<|endoftext|>" , __A : int="<|endoftext|>" , __A : Optional[Any]="<|startoftext|>" , __A : Dict="<|endoftext|>" , __A : Dict=False , **__A : Any , ):
super().__init__(
unk_token=__A , pad_token=__A , bos_token=__A , eos_token=__A , do_clean_text=__A , **__A , )
if not os.path.isfile(__A ):
raise ValueError(
f'''Can\'t find a vocabulary file at path \'{vocab_file}\'. To load the vocabulary from a Google pretrained'''
' model use `tokenizer = GPTNeoXJapaneseokenizer.from_pretrained(PRETRAINED_MODEL_NAME)`' )
if not os.path.isfile(__A ):
raise ValueError(
f'''Can\'t find a emoji file at path \'{emoji_file}\'. To load the emoji information from a Google'''
' pretrained model use `tokenizer = GPTNeoXJapaneseokenizer.from_pretrained(PRETRAINED_MODEL_NAME)`' )
__UpperCamelCase = do_clean_text
__UpperCamelCase , __UpperCamelCase , __UpperCamelCase , __UpperCamelCase = load_vocab_and_emoji(__A , __A )
__UpperCamelCase = SubWordJapaneseTokenizer(
vocab=self.vocab , ids_to_tokens=self.ids_to_tokens , emoji=self.emoji )
@property
def _lowerCamelCase ( self : str ):
# self.vocab contains support for character fluctuation unique to Japanese, and has a large number of vocab
return len(self.raw_vocab )
def _lowerCamelCase ( self : Any ):
return dict(self.raw_vocab , **self.added_tokens_encoder )
def _lowerCamelCase ( self : Optional[int] , __A : str ):
return self.subword_tokenizer.tokenize(__A , clean=self.do_clean_text )
def _lowerCamelCase ( self : Dict , __A : int ):
return self.vocab.get(__A , self.vocab.get(self.unk_token ) )
def _lowerCamelCase ( self : Any , __A : List[Any] ):
return self.subword_tokenizer.convert_id_to_token(__A )
def _lowerCamelCase ( self : Tuple , __A : List[str] ):
__UpperCamelCase = ''.join(__A ).strip()
return out_string
def _lowerCamelCase ( self : Union[str, Any] , __A : "Conversation" ):
__UpperCamelCase = []
for is_user, text in conversation.iter_texts():
input_ids.extend(self.encode(__A , add_special_tokens=__A ) + [self.eos_token_id] )
if len(__A ) > self.model_max_length:
__UpperCamelCase = input_ids[-self.model_max_length :]
return input_ids
def _lowerCamelCase ( self : List[Any] , __A : str , __A : Optional[str] = None ):
__UpperCamelCase = 0
if os.path.isdir(__A ):
__UpperCamelCase = os.path.join(
__A , (filename_prefix + '-' if filename_prefix else '') + VOCAB_FILES_NAMES['vocab_file'] )
__UpperCamelCase = os.path.join(
__A , (filename_prefix + '-' if filename_prefix else '') + VOCAB_FILES_NAMES['emoji_file'] )
else:
__UpperCamelCase = (
(filename_prefix + '-' if filename_prefix else '') + save_directory + VOCAB_FILES_NAMES['vocab_file']
)
__UpperCamelCase = (
(filename_prefix + '-' if filename_prefix else '') + save_directory + VOCAB_FILES_NAMES['emoji_file']
)
with open(__A , 'w' , encoding='utf-8' ) as writer:
for token_index, token in self.ids_to_tokens.items():
if index != token_index:
logger.warning(
f'''Saving vocabulary to {vocab_file}: vocabulary indices are not consecutive.'''
' Please check that the vocabulary is not corrupted!' )
__UpperCamelCase = token_index
writer.write(','.join(__A ) + '\n' )
index += 1
with open(__A , 'w' , encoding='utf-8' ) as writer:
json.dump(self.emoji , __A )
return vocab_file, emoji_file
class snake_case ( __lowerCamelCase ):
"""simple docstring"""
def __init__( self : Optional[Any] , __A : Optional[int] , __A : List[str] , __A : Dict ):
__UpperCamelCase = vocab # same as swe
__UpperCamelCase = ids_to_tokens # same as bpe
__UpperCamelCase = emoji
__UpperCamelCase = np.max([len(__A ) for w in self.vocab.keys()] )
__UpperCamelCase = re.compile(R'(https?|ftp)(:\/\/[-_\.!~*\'()a-zA-Z0-9;\/?:\@&=\+$,%#]+)' )
__UpperCamelCase = re.compile(R'[A-Za-z0-9\._+]*@[\-_0-9A-Za-z]+(\.[A-Za-z]+)*' )
__UpperCamelCase = re.compile(R'[\(]{0,1}[0-9]{2,4}[\)\-\(]{0,1}[0-9]{2,4}[\)\-]{0,1}[0-9]{3,4}' )
__UpperCamelCase = re.compile(
R'([12]\d{3}[/\-年])*(0?[1-9]|1[0-2])[/\-月]((0?[1-9]|[12][0-9]|3[01])日?)*(\d{1,2}|:|\d{1,2}時|\d{1,2}分|\(日\)|\(月\)|\(火\)|\(水\)|\(木\)|\(金\)|\(土\)|㈰|㈪|㈫|㈬|㈭|㈮|㈯)*' )
__UpperCamelCase = re.compile(
R'(明治|大正|昭和|平成|令和|㍾|㍽|㍼|㍻|\u32ff)\d{1,2}年(0?[1-9]|1[0-2])月(0?[1-9]|[12][0-9]|3[01])日(\d{1,2}|:|\d{1,2}時|\d{1,2}分|\(日\)|\(月\)|\(火\)|\(水\)|\(木\)|\(金\)|\(土\)|㈰|㈪|㈫|㈬|㈭|㈮|㈯)*' )
__UpperCamelCase = re.compile(
R'((0|[1-9]\d*|[1-9]\d{0,2}(,\d{3})+)*億)*((0|[1-9]\d*|[1-9]\d{0,2}(,\d{3})+)*万)*((0|[1-9]\d*|[1-9]\d{0,2}(,\d{3})+)*千)*(0|[1-9]\d*|[1-9]\d{0,2}(,\d{3})+)*(千円|万円|千万円|円|千ドル|万ドル|千万ドル|ドル|千ユーロ|万ユーロ|千万ユーロ|ユーロ)+(\(税込\)|\(税抜\)|\+tax)*' )
__UpperCamelCase = '─━│┃┄┅┆┇┈┉┊┋┌┍┎┏┐┑┒┓└┕┖┗┘┙┚┛├┝┞┟┠┡┢┣┤┥┦┧┨┩┪┫┬┭┮┯┰┱┲┳┴┵┶┷┸┹┺┻┼┽┾┿╀╁╂╃╄╅╆╇╈╉╊╋╌╍╎╏═║╒╓╔╕╖╗╘╙╚╛╜╝╞╟╠╡╢╣╤╥╦╧╨╩╪╫╬╭╮╯╰╱╲╳╴╵╶╷╸╹╺╻╼╽╾╿'
__UpperCamelCase = '▀▁▂▃▄▅▆▇█▉▊▋▌▍▎▏▐░▒▓▔▕▖▗▘▙▚▛▜▝▞▟'
__UpperCamelCase = str.maketrans({k: '<BLOCK>' for k in keisen + blocks} )
def __len__( self : List[Any] ):
return len(self.ids_to_tokens )
def _lowerCamelCase ( self : List[str] , __A : List[str] ):
__UpperCamelCase = self.content_repattera.sub('<URL>' , __A )
__UpperCamelCase = self.content_repattera.sub('<EMAIL>' , __A )
__UpperCamelCase = self.content_repattera.sub('<TEL>' , __A )
__UpperCamelCase = self.content_repattera.sub('<DATE>' , __A )
__UpperCamelCase = self.content_repattera.sub('<DATE>' , __A )
__UpperCamelCase = self.content_repattera.sub('<PRICE>' , __A )
__UpperCamelCase = content.translate(self.content_transa )
while "<BLOCK><BLOCK>" in content:
__UpperCamelCase = content.replace('<BLOCK><BLOCK>' , '<BLOCK>' )
return content
def _lowerCamelCase ( self : List[Any] , __A : Any , __A : Union[str, Any]=False ):
__UpperCamelCase = text.replace(' ' , '<SP>' )
__UpperCamelCase = text.replace(' ' , '<SP>' )
__UpperCamelCase = text.replace('\r\n' , '<BR>' )
__UpperCamelCase = text.replace('\n' , '<BR>' )
__UpperCamelCase = text.replace('\r' , '<BR>' )
__UpperCamelCase = text.replace('\t' , '<TAB>' )
__UpperCamelCase = text.replace('—' , 'ー' )
__UpperCamelCase = text.replace('−' , 'ー' )
for k, v in self.emoji["emoji"].items():
if k in text:
__UpperCamelCase = text.replace(__A , __A )
if clean:
__UpperCamelCase = self.clean_text(__A )
def check_simbol(__A : str ):
__UpperCamelCase = x.encode()
if len(__A ) == 1 and len(__A ) == 2:
__UpperCamelCase = (int(e[0] ) << 8) + int(e[1] )
if (
(c >= 0xc2a1 and c <= 0xc2bf)
or (c >= 0xc780 and c <= 0xc783)
or (c >= 0xcab9 and c <= 0xcbbf)
or (c >= 0xcc80 and c <= 0xcda2)
):
return True
return False
def checkuae(__A : Tuple ):
__UpperCamelCase = x.encode()
if len(__A ) == 1 and len(__A ) == 3:
__UpperCamelCase = (int(e[0] ) << 1_6) + (int(e[1] ) << 8) + int(e[2] )
if c >= 0xe2_8080 and c <= 0xe2_b07f:
return True
return False
__UpperCamelCase = 0
__UpperCamelCase = []
while pos < len(__A ):
__UpperCamelCase = min(len(__A ) , pos + self.maxlen + 1 ) if text[pos] == '<' else pos + 3
__UpperCamelCase = [] # (token_id, token, pos)
for e in range(__A , __A , -1 ):
__UpperCamelCase = text[pos:e]
if wd in self.vocab:
if wd[0] == "<" and len(__A ) > 2:
__UpperCamelCase = [(self.vocab[wd], wd, e)]
break
else:
candidates.append((self.vocab[wd], wd, e) )
if len(__A ) > 0:
# the smallest token_id is adopted
__UpperCamelCase , __UpperCamelCase , __UpperCamelCase = sorted(__A , key=lambda __A : x[0] )[0]
result.append(__A )
__UpperCamelCase = e
else:
__UpperCamelCase = pos + 1
__UpperCamelCase = text[pos:end]
if check_simbol(__A ):
result.append('<KIGOU>' )
elif checkuae(__A ):
result.append('<U2000U2BFF>' )
else:
for i in wd.encode('utf-8' ):
result.append('<|byte%d|>' % i )
__UpperCamelCase = end
return result
def _lowerCamelCase ( self : Union[str, Any] , __A : Any , __A : List[Any]="\n" ):
__UpperCamelCase = []
__UpperCamelCase = []
__UpperCamelCase = self.ids_to_tokens[index][0]
if word[:6] == "<|byte" and word[-2:] == "|>":
byte_tokens.append(int(word[6:-2] ) )
else:
if len(__A ) > 0:
words.append(bytearray(__A ).decode('utf-8' , errors='replace' ) )
__UpperCamelCase = []
if word[:7] == "<|emoji" and word[-2:] == "|>":
words.append(self.emoji['emoji_inv'][word] )
elif word == "<SP>":
words.append(' ' )
elif word == "<BR>":
words.append(__A )
elif word == "<TAB>":
words.append('\t' )
elif word == "<BLOCK>":
words.append('▀' )
elif word == "<KIGOU>":
words.append('ǀ' )
elif word == "<U2000U2BFF>":
words.append('‖' )
else:
words.append(__A )
if len(__A ) > 0:
words.append(bytearray(__A ).decode('utf-8' , errors='replace' ) )
__UpperCamelCase = ''.join(__A )
return text
| 53
|
import re
import jax.numpy as jnp
from flax.traverse_util import flatten_dict, unflatten_dict
from jax.random import PRNGKey
from ..utils import logging
__lowercase = logging.get_logger(__name__)
def lowerCamelCase ( SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Tuple = R'''\w+[.]\d+'''
__UpperCamelCase :List[str] = re.findall(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
for pat in pats:
__UpperCamelCase :int = key.replace(SCREAMING_SNAKE_CASE , '''_'''.join(pat.split('''.''' ) ) )
return key
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Tuple = pt_tuple_key[:-1] + ('''scale''',)
if (
any('''norm''' in str_ for str_ in pt_tuple_key )
and (pt_tuple_key[-1] == "bias")
and (pt_tuple_key[:-1] + ("bias",) not in random_flax_state_dict)
and (pt_tuple_key[:-1] + ("scale",) in random_flax_state_dict)
):
__UpperCamelCase :str = pt_tuple_key[:-1] + ('''scale''',)
return renamed_pt_tuple_key, pt_tensor
elif pt_tuple_key[-1] in ["weight", "gamma"] and pt_tuple_key[:-1] + ("scale",) in random_flax_state_dict:
__UpperCamelCase :Any = pt_tuple_key[:-1] + ('''scale''',)
return renamed_pt_tuple_key, pt_tensor
# embedding
if pt_tuple_key[-1] == "weight" and pt_tuple_key[:-1] + ("embedding",) in random_flax_state_dict:
__UpperCamelCase :str = pt_tuple_key[:-1] + ('''embedding''',)
return renamed_pt_tuple_key, pt_tensor
# conv layer
__UpperCamelCase :List[str] = pt_tuple_key[:-1] + ('''kernel''',)
if pt_tuple_key[-1] == "weight" and pt_tensor.ndim == 4:
__UpperCamelCase :List[Any] = pt_tensor.transpose(2 , 3 , 1 , 0 )
return renamed_pt_tuple_key, pt_tensor
# linear layer
__UpperCamelCase :List[str] = pt_tuple_key[:-1] + ('''kernel''',)
if pt_tuple_key[-1] == "weight":
__UpperCamelCase :Any = pt_tensor.T
return renamed_pt_tuple_key, pt_tensor
# old PyTorch layer norm weight
__UpperCamelCase :int = pt_tuple_key[:-1] + ('''weight''',)
if pt_tuple_key[-1] == "gamma":
return renamed_pt_tuple_key, pt_tensor
# old PyTorch layer norm bias
__UpperCamelCase :int = pt_tuple_key[:-1] + ('''bias''',)
if pt_tuple_key[-1] == "beta":
return renamed_pt_tuple_key, pt_tensor
return pt_tuple_key, pt_tensor
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE=42 ):
'''simple docstring'''
__UpperCamelCase :Union[str, Any] = {k: v.numpy() for k, v in pt_state_dict.items()}
# Step 2: Since the model is stateless, get random Flax params
__UpperCamelCase :str = flax_model.init_weights(PRNGKey(SCREAMING_SNAKE_CASE ) )
__UpperCamelCase :int = flatten_dict(SCREAMING_SNAKE_CASE )
__UpperCamelCase :List[Any] = {}
# Need to change some parameters name to match Flax names
for pt_key, pt_tensor in pt_state_dict.items():
__UpperCamelCase :List[Any] = rename_key(SCREAMING_SNAKE_CASE )
__UpperCamelCase :List[Any] = tuple(renamed_pt_key.split('''.''' ) )
# Correctly rename weight parameters
__UpperCamelCase , __UpperCamelCase :Any = rename_key_and_reshape_tensor(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
if flax_key in random_flax_state_dict:
if flax_tensor.shape != random_flax_state_dict[flax_key].shape:
raise ValueError(
f"""PyTorch checkpoint seems to be incorrect. Weight {pt_key} was expected to be of shape """
f"""{random_flax_state_dict[flax_key].shape}, but is {flax_tensor.shape}.""" )
# also add unexpected weight so that warning is thrown
__UpperCamelCase :str = jnp.asarray(SCREAMING_SNAKE_CASE )
return unflatten_dict(SCREAMING_SNAKE_CASE )
| 43
| 0
|
"""simple docstring"""
import gc
import random
import unittest
import numpy as np
import torch
from transformers import CLIPTextConfig, CLIPTextModel, CLIPTokenizer
from diffusers import AutoencoderKL, CycleDiffusionPipeline, DDIMScheduler, UNetaDConditionModel
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, skip_mps
from ..pipeline_params import (
IMAGE_TO_IMAGE_IMAGE_PARAMS,
TEXT_GUIDED_IMAGE_VARIATION_BATCH_PARAMS,
TEXT_GUIDED_IMAGE_VARIATION_PARAMS,
)
from ..test_pipelines_common import PipelineLatentTesterMixin, PipelineTesterMixin
enable_full_determinism()
class UpperCamelCase_ ( UpperCamelCase , UpperCamelCase , unittest.TestCase):
"""simple docstring"""
snake_case__ : Any = CycleDiffusionPipeline
snake_case__ : Dict = TEXT_GUIDED_IMAGE_VARIATION_PARAMS - {
"negative_prompt",
"height",
"width",
"negative_prompt_embeds",
}
snake_case__ : List[Any] = PipelineTesterMixin.required_optional_params - {"latents"}
snake_case__ : Any = TEXT_GUIDED_IMAGE_VARIATION_BATCH_PARAMS.union({"source_prompt"})
snake_case__ : Union[str, Any] = IMAGE_TO_IMAGE_IMAGE_PARAMS
snake_case__ : str = IMAGE_TO_IMAGE_IMAGE_PARAMS
def UpperCAmelCase_ ( self : Tuple ) -> str:
torch.manual_seed(0 )
__SCREAMING_SNAKE_CASE = UNetaDConditionModel(
block_out_channels=(3_2, 6_4) , layers_per_block=2 , sample_size=3_2 , in_channels=4 , out_channels=4 , down_block_types=("DownBlock2D", "CrossAttnDownBlock2D") , up_block_types=("CrossAttnUpBlock2D", "UpBlock2D") , cross_attention_dim=3_2 , )
__SCREAMING_SNAKE_CASE = DDIMScheduler(
beta_start=0.00_085 , beta_end=0.012 , beta_schedule="scaled_linear" , num_train_timesteps=1_0_0_0 , clip_sample=UpperCAmelCase__ , set_alpha_to_one=UpperCAmelCase__ , )
torch.manual_seed(0 )
__SCREAMING_SNAKE_CASE = AutoencoderKL(
block_out_channels=[3_2, 6_4] , in_channels=3 , out_channels=3 , down_block_types=["DownEncoderBlock2D", "DownEncoderBlock2D"] , up_block_types=["UpDecoderBlock2D", "UpDecoderBlock2D"] , latent_channels=4 , )
torch.manual_seed(0 )
__SCREAMING_SNAKE_CASE = CLIPTextConfig(
bos_token_id=0 , eos_token_id=2 , hidden_size=3_2 , intermediate_size=3_7 , layer_norm_eps=1E-05 , num_attention_heads=4 , num_hidden_layers=5 , pad_token_id=1 , vocab_size=1_0_0_0 , )
__SCREAMING_SNAKE_CASE = CLIPTextModel(UpperCAmelCase__ )
__SCREAMING_SNAKE_CASE = CLIPTokenizer.from_pretrained("hf-internal-testing/tiny-random-clip" )
__SCREAMING_SNAKE_CASE = {
"unet": unet,
"scheduler": scheduler,
"vae": vae,
"text_encoder": text_encoder,
"tokenizer": tokenizer,
"safety_checker": None,
"feature_extractor": None,
}
return components
def UpperCAmelCase_ ( self : Optional[int] , UpperCAmelCase__ : List[str] , UpperCAmelCase__ : Optional[int]=0 ) -> Any:
__SCREAMING_SNAKE_CASE = floats_tensor((1, 3, 3_2, 3_2) , rng=random.Random(UpperCAmelCase__ ) ).to(UpperCAmelCase__ )
__SCREAMING_SNAKE_CASE = image / 2 + 0.5
if str(UpperCAmelCase__ ).startswith("mps" ):
__SCREAMING_SNAKE_CASE = torch.manual_seed(UpperCAmelCase__ )
else:
__SCREAMING_SNAKE_CASE = torch.Generator(device=UpperCAmelCase__ ).manual_seed(UpperCAmelCase__ )
__SCREAMING_SNAKE_CASE = {
"prompt": "An astronaut riding an elephant",
"source_prompt": "An astronaut riding a horse",
"image": image,
"generator": generator,
"num_inference_steps": 2,
"eta": 0.1,
"strength": 0.8,
"guidance_scale": 3,
"source_guidance_scale": 1,
"output_type": "numpy",
}
return inputs
def UpperCAmelCase_ ( self : Tuple ) -> List[Any]:
__SCREAMING_SNAKE_CASE = "cpu" # ensure determinism for the device-dependent torch.Generator
__SCREAMING_SNAKE_CASE = self.get_dummy_components()
__SCREAMING_SNAKE_CASE = CycleDiffusionPipeline(**UpperCAmelCase__ )
__SCREAMING_SNAKE_CASE = pipe.to(UpperCAmelCase__ )
pipe.set_progress_bar_config(disable=UpperCAmelCase__ )
__SCREAMING_SNAKE_CASE = self.get_dummy_inputs(UpperCAmelCase__ )
__SCREAMING_SNAKE_CASE = pipe(**UpperCAmelCase__ )
__SCREAMING_SNAKE_CASE = output.images
__SCREAMING_SNAKE_CASE = images[0, -3:, -3:, -1]
assert images.shape == (1, 3_2, 3_2, 3)
__SCREAMING_SNAKE_CASE = np.array([0.4_459, 0.4_943, 0.4_544, 0.6_643, 0.5_474, 0.4_327, 0.5_701, 0.5_959, 0.5_179] )
assert np.abs(image_slice.flatten() - expected_slice ).max() < 1E-2
@unittest.skipIf(torch_device != "cuda" , "This test requires a GPU" )
def UpperCAmelCase_ ( self : Union[str, Any] ) -> Tuple:
__SCREAMING_SNAKE_CASE = self.get_dummy_components()
for name, module in components.items():
if hasattr(UpperCAmelCase__ , "half" ):
__SCREAMING_SNAKE_CASE = module.half()
__SCREAMING_SNAKE_CASE = CycleDiffusionPipeline(**UpperCAmelCase__ )
__SCREAMING_SNAKE_CASE = pipe.to(UpperCAmelCase__ )
pipe.set_progress_bar_config(disable=UpperCAmelCase__ )
__SCREAMING_SNAKE_CASE = self.get_dummy_inputs(UpperCAmelCase__ )
__SCREAMING_SNAKE_CASE = pipe(**UpperCAmelCase__ )
__SCREAMING_SNAKE_CASE = output.images
__SCREAMING_SNAKE_CASE = images[0, -3:, -3:, -1]
assert images.shape == (1, 3_2, 3_2, 3)
__SCREAMING_SNAKE_CASE = np.array([0.3_506, 0.4_543, 0.446, 0.4_575, 0.5_195, 0.4_155, 0.5_273, 0.518, 0.4_116] )
assert np.abs(image_slice.flatten() - expected_slice ).max() < 1E-2
@skip_mps
def UpperCAmelCase_ ( self : int ) -> Tuple:
return super().test_save_load_local()
@unittest.skip("non-deterministic pipeline" )
def UpperCAmelCase_ ( self : List[str] ) -> Union[str, Any]:
return super().test_inference_batch_single_identical()
@skip_mps
def UpperCAmelCase_ ( self : Optional[Any] ) -> Tuple:
return super().test_dict_tuple_outputs_equivalent()
@skip_mps
def UpperCAmelCase_ ( self : Dict ) -> List[Any]:
return super().test_save_load_optional_components()
@skip_mps
def UpperCAmelCase_ ( self : int ) -> str:
return super().test_attention_slicing_forward_pass()
@slow
@require_torch_gpu
class UpperCamelCase_ ( unittest.TestCase):
"""simple docstring"""
def UpperCAmelCase_ ( self : Tuple ) -> List[Any]:
# clean up the VRAM after each test
super().tearDown()
gc.collect()
torch.cuda.empty_cache()
def UpperCAmelCase_ ( self : Optional[int] ) -> Tuple:
__SCREAMING_SNAKE_CASE = load_image(
"https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main"
"/cycle-diffusion/black_colored_car.png" )
__SCREAMING_SNAKE_CASE = load_numpy(
"https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main/cycle-diffusion/blue_colored_car_fp16.npy" )
__SCREAMING_SNAKE_CASE = init_image.resize((5_1_2, 5_1_2) )
__SCREAMING_SNAKE_CASE = "CompVis/stable-diffusion-v1-4"
__SCREAMING_SNAKE_CASE = DDIMScheduler.from_pretrained(UpperCAmelCase__ , subfolder="scheduler" )
__SCREAMING_SNAKE_CASE = CycleDiffusionPipeline.from_pretrained(
UpperCAmelCase__ , scheduler=UpperCAmelCase__ , safety_checker=UpperCAmelCase__ , torch_dtype=torch.floataa , revision="fp16" )
pipe.to(UpperCAmelCase__ )
pipe.set_progress_bar_config(disable=UpperCAmelCase__ )
pipe.enable_attention_slicing()
__SCREAMING_SNAKE_CASE = "A black colored car"
__SCREAMING_SNAKE_CASE = "A blue colored car"
__SCREAMING_SNAKE_CASE = torch.manual_seed(0 )
__SCREAMING_SNAKE_CASE = pipe(
prompt=UpperCAmelCase__ , source_prompt=UpperCAmelCase__ , image=UpperCAmelCase__ , num_inference_steps=1_0_0 , eta=0.1 , strength=0.85 , guidance_scale=3 , source_guidance_scale=1 , generator=UpperCAmelCase__ , output_type="np" , )
__SCREAMING_SNAKE_CASE = output.images
# the values aren't exactly equal, but the images look the same visually
assert np.abs(image - expected_image ).max() < 5E-1
def UpperCAmelCase_ ( self : List[Any] ) -> List[Any]:
__SCREAMING_SNAKE_CASE = load_image(
"https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main"
"/cycle-diffusion/black_colored_car.png" )
__SCREAMING_SNAKE_CASE = load_numpy(
"https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main/cycle-diffusion/blue_colored_car.npy" )
__SCREAMING_SNAKE_CASE = init_image.resize((5_1_2, 5_1_2) )
__SCREAMING_SNAKE_CASE = "CompVis/stable-diffusion-v1-4"
__SCREAMING_SNAKE_CASE = DDIMScheduler.from_pretrained(UpperCAmelCase__ , subfolder="scheduler" )
__SCREAMING_SNAKE_CASE = CycleDiffusionPipeline.from_pretrained(UpperCAmelCase__ , scheduler=UpperCAmelCase__ , safety_checker=UpperCAmelCase__ )
pipe.to(UpperCAmelCase__ )
pipe.set_progress_bar_config(disable=UpperCAmelCase__ )
pipe.enable_attention_slicing()
__SCREAMING_SNAKE_CASE = "A black colored car"
__SCREAMING_SNAKE_CASE = "A blue colored car"
__SCREAMING_SNAKE_CASE = torch.manual_seed(0 )
__SCREAMING_SNAKE_CASE = pipe(
prompt=UpperCAmelCase__ , source_prompt=UpperCAmelCase__ , image=UpperCAmelCase__ , num_inference_steps=1_0_0 , eta=0.1 , strength=0.85 , guidance_scale=3 , source_guidance_scale=1 , generator=UpperCAmelCase__ , output_type="np" , )
__SCREAMING_SNAKE_CASE = output.images
assert np.abs(image - expected_image ).max() < 2E-2
| 54
|
import argparse
import torch
from ...utils import logging
from . import AlbertConfig, AlbertForPreTraining, load_tf_weights_in_albert
logging.set_verbosity_info()
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :List[Any] = AlbertConfig.from_json_file(SCREAMING_SNAKE_CASE )
print(f"""Building PyTorch model from configuration: {config}""" )
__UpperCamelCase :List[str] = AlbertForPreTraining(SCREAMING_SNAKE_CASE )
# Load weights from tf checkpoint
load_tf_weights_in_albert(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
# Save pytorch-model
print(f"""Save PyTorch model to {pytorch_dump_path}""" )
torch.save(model.state_dict() , SCREAMING_SNAKE_CASE )
if __name__ == "__main__":
__lowercase = argparse.ArgumentParser()
# Required parameters
parser.add_argument(
'''--tf_checkpoint_path''', default=None, type=str, required=True, help='''Path to the TensorFlow checkpoint path.'''
)
parser.add_argument(
'''--albert_config_file''',
default=None,
type=str,
required=True,
help=(
'''The config json file corresponding to the pre-trained ALBERT model. \n'''
'''This specifies the model architecture.'''
),
)
parser.add_argument(
'''--pytorch_dump_path''', default=None, type=str, required=True, help='''Path to the output PyTorch model.'''
)
__lowercase = parser.parse_args()
convert_tf_checkpoint_to_pytorch(args.tf_checkpoint_path, args.albert_config_file, args.pytorch_dump_path)
| 43
| 0
|
'''simple docstring'''
import json
import logging
import math
import os
import sys
from dataclasses import dataclass, field
from typing import Optional
from datasets import Dataset, load_dataset
import transformers
from transformers import (
CONFIG_MAPPING,
MODEL_FOR_MASKED_LM_MAPPING,
AutoConfig,
AutoModelForMaskedLM,
AutoTokenizer,
DataCollatorForWholeWordMask,
HfArgumentParser,
Trainer,
TrainingArguments,
set_seed,
)
from transformers.trainer_utils import get_last_checkpoint, is_main_process
a_ : str = logging.getLogger(__name__)
a_ : List[str] = list(MODEL_FOR_MASKED_LM_MAPPING.keys())
a_ : Any = tuple(conf.model_type for conf in MODEL_CONFIG_CLASSES)
@dataclass
class snake_case :
"""simple docstring"""
_lowerCamelCase = field(
default=lowercase , metadata={
"help": (
"The model checkpoint for weights initialization.Don't set if you want to train a model from scratch."
)
} , )
_lowerCamelCase = field(
default=lowercase , metadata={"help": "If training from scratch, pass a model type from the list: " + ", ".join(lowercase )} , )
_lowerCamelCase = field(
default=lowercase , metadata={
"help": (
"Override some existing default config settings when a model is trained from scratch. Example: "
"n_embd=10,resid_pdrop=0.2,scale_attn_weights=false,summary_type=cls_index"
)
} , )
_lowerCamelCase = field(
default=lowercase , metadata={"help": "Pretrained config name or path if not the same as model_name"} )
_lowerCamelCase = field(
default=lowercase , metadata={"help": "Pretrained tokenizer name or path if not the same as model_name"} )
_lowerCamelCase = field(
default=lowercase , metadata={"help": "Where do you want to store the pretrained models downloaded from huggingface.co"} , )
_lowerCamelCase = field(
default=lowercase , metadata={"help": "Whether to use one of the fast tokenizer (backed by the tokenizers library) or not."} , )
_lowerCamelCase = field(
default="main" , metadata={"help": "The specific model version to use (can be a branch name, tag name or commit id)."} , )
_lowerCamelCase = field(
default=lowercase , metadata={
"help": (
"Will use the token generated when running `huggingface-cli login` (necessary to use this script "
"with private models)."
)
} , )
def snake_case ( self ):
"""simple docstring"""
if self.config_overrides is not None and (self.config_name is not None or self.model_name_or_path is not None):
raise ValueError(
"--config_overrides can't be used in combination with --config_name or --model_name_or_path" )
@dataclass
class snake_case :
"""simple docstring"""
_lowerCamelCase = field(
default=lowercase , metadata={"help": "The name of the dataset to use (via the datasets library)."} )
_lowerCamelCase = field(
default=lowercase , metadata={"help": "The configuration name of the dataset to use (via the datasets library)."} )
_lowerCamelCase = field(default=lowercase , metadata={"help": "The input training data file (a text file)."} )
_lowerCamelCase = field(
default=lowercase , metadata={"help": "An optional input evaluation data file to evaluate the perplexity on (a text file)."} , )
_lowerCamelCase = field(
default=lowercase , metadata={"help": "An optional input train ref data file for whole word masking in Chinese."} , )
_lowerCamelCase = field(
default=lowercase , metadata={"help": "An optional input validation ref data file for whole word masking in Chinese."} , )
_lowerCamelCase = field(
default=lowercase , metadata={"help": "Overwrite the cached training and evaluation sets"} )
_lowerCamelCase = field(
default=5 , metadata={
"help": "The percentage of the train set used as validation set in case there's no validation split"
} , )
_lowerCamelCase = field(
default=lowercase , metadata={
"help": (
"The maximum total input sequence length after tokenization. Sequences longer "
"than this will be truncated. Default to the max input length of the model."
)
} , )
_lowerCamelCase = field(
default=lowercase , metadata={"help": "The number of processes to use for the preprocessing."} , )
_lowerCamelCase = field(
default=0.15 , metadata={"help": "Ratio of tokens to mask for masked language modeling loss"} )
_lowerCamelCase = field(
default=lowercase , metadata={
"help": (
"Whether to pad all samples to `max_seq_length`. "
"If False, will pad the samples dynamically when batching to the maximum length in the batch."
)
} , )
def snake_case ( self ):
"""simple docstring"""
if self.train_file is not None:
lowerCamelCase_ = self.train_file.split("." )[-1]
assert extension in ["csv", "json", "txt"], "`train_file` should be a csv, a json or a txt file."
if self.validation_file is not None:
lowerCamelCase_ = self.validation_file.split("." )[-1]
assert extension in ["csv", "json", "txt"], "`validation_file` should be a csv, a json or a txt file."
def __snake_case ( UpperCAmelCase_ : str , UpperCAmelCase_ : Optional[int] ):
with open(UpperCAmelCase_ , "r" , encoding="utf-8" ) as f:
lowerCamelCase_ = [json.loads(UpperCAmelCase_ ) for line in f.read().splitlines() if (len(UpperCAmelCase_ ) > 0 and not line.isspace())]
assert len(UpperCAmelCase_ ) == len(UpperCAmelCase_ )
lowerCamelCase_ = {c: dataset[c] for c in dataset.column_names}
lowerCamelCase_ = refs
return Dataset.from_dict(UpperCAmelCase_ )
def __snake_case ( ):
# 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.
lowerCamelCase_ = 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.
lowerCamelCase_ ,lowerCamelCase_ ,lowerCamelCase_ = parser.parse_json_file(json_file=os.path.abspath(sys.argv[1] ) )
else:
lowerCamelCase_ ,lowerCamelCase_ ,lowerCamelCase_ = parser.parse_args_into_dataclasses()
# Detecting last checkpoint.
lowerCamelCase_ = None
if os.path.isdir(training_args.output_dir ) and training_args.do_train and not training_args.overwrite_output_dir:
lowerCamelCase_ = 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:
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." )
# 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 )] , )
logger.setLevel(logging.INFO if is_main_process(training_args.local_rank ) else logging.WARN )
# 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}''' )
# Set the verbosity to info of the Transformers logger (on main process only):
if is_main_process(training_args.local_rank ):
transformers.utils.logging.set_verbosity_info()
transformers.utils.logging.enable_default_handler()
transformers.utils.logging.enable_explicit_format()
logger.info("Training/evaluation parameters %s" , UpperCAmelCase_ )
# 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.dataset_name is not None:
# Downloading and loading a dataset from the hub.
lowerCamelCase_ = load_dataset(data_args.dataset_name , data_args.dataset_config_name )
if "validation" not in datasets.keys():
lowerCamelCase_ = load_dataset(
data_args.dataset_name , data_args.dataset_config_name , split=F'''train[:{data_args.validation_split_percentage}%]''' , )
lowerCamelCase_ = load_dataset(
data_args.dataset_name , data_args.dataset_config_name , split=F'''train[{data_args.validation_split_percentage}%:]''' , )
else:
lowerCamelCase_ = {}
if data_args.train_file is not None:
lowerCamelCase_ = data_args.train_file
if data_args.validation_file is not None:
lowerCamelCase_ = data_args.validation_file
lowerCamelCase_ = data_args.train_file.split("." )[-1]
if extension == "txt":
lowerCamelCase_ = "text"
lowerCamelCase_ = load_dataset(UpperCAmelCase_ , data_files=UpperCAmelCase_ )
# 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.
lowerCamelCase_ = {
"cache_dir": model_args.cache_dir,
"revision": model_args.model_revision,
"use_auth_token": True if model_args.use_auth_token else None,
}
if model_args.config_name:
lowerCamelCase_ = AutoConfig.from_pretrained(model_args.config_name , **UpperCAmelCase_ )
elif model_args.model_name_or_path:
lowerCamelCase_ = AutoConfig.from_pretrained(model_args.model_name_or_path , **UpperCAmelCase_ )
else:
lowerCamelCase_ = CONFIG_MAPPING[model_args.model_type]()
logger.warning("You are instantiating a new config instance from scratch." )
if model_args.config_overrides is not None:
logger.info(F'''Overriding config: {model_args.config_overrides}''' )
config.update_from_string(model_args.config_overrides )
logger.info(F'''New config: {config}''' )
lowerCamelCase_ = {
"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,
}
if model_args.tokenizer_name:
lowerCamelCase_ = AutoTokenizer.from_pretrained(model_args.tokenizer_name , **UpperCAmelCase_ )
elif model_args.model_name_or_path:
lowerCamelCase_ = AutoTokenizer.from_pretrained(model_args.model_name_or_path , **UpperCAmelCase_ )
else:
raise ValueError(
"You are instantiating a new tokenizer from scratch. This is not supported by this script."
"You can do it from another script, save it, and load it from here, using --tokenizer_name." )
if model_args.model_name_or_path:
lowerCamelCase_ = AutoModelForMaskedLM.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 , )
else:
logger.info("Training new model from scratch" )
lowerCamelCase_ = AutoModelForMaskedLM.from_config(UpperCAmelCase_ )
model.resize_token_embeddings(len(UpperCAmelCase_ ) )
# Preprocessing the datasets.
# First we tokenize all the texts.
if training_args.do_train:
lowerCamelCase_ = datasets["train"].column_names
else:
lowerCamelCase_ = datasets["validation"].column_names
lowerCamelCase_ = "text" if "text" in column_names else column_names[0]
lowerCamelCase_ = "max_length" if data_args.pad_to_max_length else False
def tokenize_function(UpperCAmelCase_ : Union[str, Any] ):
# Remove empty lines
lowerCamelCase_ = [line for line in examples["text"] if len(UpperCAmelCase_ ) > 0 and not line.isspace()]
return tokenizer(examples["text"] , padding=UpperCAmelCase_ , truncation=UpperCAmelCase_ , max_length=data_args.max_seq_length )
lowerCamelCase_ = datasets.map(
UpperCAmelCase_ , batched=UpperCAmelCase_ , num_proc=data_args.preprocessing_num_workers , remove_columns=[text_column_name] , load_from_cache_file=not data_args.overwrite_cache , )
# Add the chinese references if provided
if data_args.train_ref_file is not None:
lowerCamelCase_ = add_chinese_references(tokenized_datasets["train"] , data_args.train_ref_file )
if data_args.validation_ref_file is not None:
lowerCamelCase_ = add_chinese_references(
tokenized_datasets["validation"] , data_args.validation_ref_file )
# If we have ref files, need to avoid it removed by trainer
lowerCamelCase_ = data_args.train_ref_file or data_args.validation_ref_file
if has_ref:
lowerCamelCase_ = False
# Data collator
# This one will take care of randomly masking the tokens.
lowerCamelCase_ = DataCollatorForWholeWordMask(tokenizer=UpperCAmelCase_ , mlm_probability=data_args.mlm_probability )
# Initialize our Trainer
lowerCamelCase_ = Trainer(
model=UpperCAmelCase_ , args=UpperCAmelCase_ , train_dataset=tokenized_datasets["train"] if training_args.do_train else None , eval_dataset=tokenized_datasets["validation"] if training_args.do_eval else None , tokenizer=UpperCAmelCase_ , data_collator=UpperCAmelCase_ , )
# Training
if training_args.do_train:
if last_checkpoint is not None:
lowerCamelCase_ = last_checkpoint
elif model_args.model_name_or_path is not None and os.path.isdir(model_args.model_name_or_path ):
lowerCamelCase_ = model_args.model_name_or_path
else:
lowerCamelCase_ = None
lowerCamelCase_ = trainer.train(resume_from_checkpoint=UpperCAmelCase_ )
trainer.save_model() # Saves the tokenizer too for easy upload
lowerCamelCase_ = os.path.join(training_args.output_dir , "train_results.txt" )
if trainer.is_world_process_zero():
with open(UpperCAmelCase_ , "w" ) as writer:
logger.info("***** Train results *****" )
for key, value in sorted(train_result.metrics.items() ):
logger.info(F''' {key} = {value}''' )
writer.write(F'''{key} = {value}\n''' )
# Need to save the state, since Trainer.save_model saves only the tokenizer with the model
trainer.state.save_to_json(os.path.join(training_args.output_dir , "trainer_state.json" ) )
# Evaluation
lowerCamelCase_ = {}
if training_args.do_eval:
logger.info("*** Evaluate ***" )
lowerCamelCase_ = trainer.evaluate()
lowerCamelCase_ = math.exp(eval_output["eval_loss"] )
lowerCamelCase_ = perplexity
lowerCamelCase_ = os.path.join(training_args.output_dir , "eval_results_mlm_wwm.txt" )
if trainer.is_world_process_zero():
with open(UpperCAmelCase_ , "w" ) as writer:
logger.info("***** Eval results *****" )
for key, value in sorted(results.items() ):
logger.info(F''' {key} = {value}''' )
writer.write(F'''{key} = {value}\n''' )
return results
def __snake_case ( UpperCAmelCase_ : List[Any] ):
# For xla_spawn (TPUs)
main()
if __name__ == "__main__":
main()
| 55
|
import math
import qiskit
def lowerCamelCase ( SCREAMING_SNAKE_CASE = 1 , SCREAMING_SNAKE_CASE = 1 , SCREAMING_SNAKE_CASE = 1 ):
'''simple docstring'''
if (
isinstance(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
or isinstance(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
or isinstance(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
):
raise TypeError('''inputs must be integers.''' )
if (input_a < 0) or (input_a < 0) or (carry_in < 0):
raise ValueError('''inputs must be positive.''' )
if (
(math.floor(SCREAMING_SNAKE_CASE ) != input_a)
or (math.floor(SCREAMING_SNAKE_CASE ) != input_a)
or (math.floor(SCREAMING_SNAKE_CASE ) != carry_in)
):
raise ValueError('''inputs must be exact integers.''' )
if (input_a > 2) or (input_a > 2) or (carry_in > 2):
raise ValueError('''inputs must be less or equal to 2.''' )
# build registers
__UpperCamelCase :List[str] = qiskit.QuantumRegister(4 , '''qr''' )
__UpperCamelCase :str = qiskit.ClassicalRegister(2 , '''cr''' )
# list the entries
__UpperCamelCase :Tuple = [input_a, input_a, carry_in]
__UpperCamelCase :Optional[int] = qiskit.QuantumCircuit(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
for i in range(0 , 3 ):
if entry[i] == 2:
quantum_circuit.h(SCREAMING_SNAKE_CASE ) # for hadamard entries
elif entry[i] == 1:
quantum_circuit.x(SCREAMING_SNAKE_CASE ) # for 1 entries
elif entry[i] == 0:
quantum_circuit.i(SCREAMING_SNAKE_CASE ) # for 0 entries
# build the circuit
quantum_circuit.ccx(0 , 1 , 3 ) # ccx = toffoli gate
quantum_circuit.cx(0 , 1 )
quantum_circuit.ccx(1 , 2 , 3 )
quantum_circuit.cx(1 , 2 )
quantum_circuit.cx(0 , 1 )
quantum_circuit.measure([2, 3] , SCREAMING_SNAKE_CASE ) # measure the last two qbits
__UpperCamelCase :Optional[Any] = qiskit.Aer.get_backend('''aer_simulator''' )
__UpperCamelCase :Tuple = qiskit.execute(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , shots=1_000 )
return job.result().get_counts(SCREAMING_SNAKE_CASE )
if __name__ == "__main__":
print(F'Total sum count for state is: {quantum_full_adder(1, 1, 1)}')
| 43
| 0
|
'''simple docstring'''
import copy
import os
from typing import TYPE_CHECKING, List, Union
if TYPE_CHECKING:
pass
from ...configuration_utils import PretrainedConfig
from ...utils import logging
a : str = logging.get_logger(__name__)
a : str = {
'kakaobrain/align-base': 'https://huggingface.co/kakaobrain/align-base/resolve/main/config.json',
}
class a ( _lowerCamelCase ):
snake_case_ = "align_text_model"
def __init__( self : Any , lowercase_ : str=3_0522 , lowercase_ : int=768 , lowercase_ : Tuple=12 , lowercase_ : int=12 , lowercase_ : Dict=3072 , lowercase_ : List[Any]="gelu" , lowercase_ : str=0.1 , lowercase_ : Optional[Any]=0.1 , lowercase_ : Any=512 , lowercase_ : Dict=2 , lowercase_ : Optional[int]=0.02 , lowercase_ : Union[str, Any]=1e-12 , lowercase_ : Optional[int]=0 , lowercase_ : Union[str, Any]="absolute" , lowercase_ : Tuple=True , **lowercase_ : List[str] , ):
super().__init__(**lowercase_ )
snake_case_ = vocab_size
snake_case_ = hidden_size
snake_case_ = num_hidden_layers
snake_case_ = num_attention_heads
snake_case_ = hidden_act
snake_case_ = intermediate_size
snake_case_ = hidden_dropout_prob
snake_case_ = attention_probs_dropout_prob
snake_case_ = max_position_embeddings
snake_case_ = type_vocab_size
snake_case_ = initializer_range
snake_case_ = layer_norm_eps
snake_case_ = position_embedding_type
snake_case_ = use_cache
snake_case_ = pad_token_id
@classmethod
def A_ ( cls : int , lowercase_ : Union[str, os.PathLike] , **lowercase_ : Tuple ):
cls._set_token_in_kwargs(lowercase_ )
snake_case_ ,snake_case_ = cls.get_config_dict(lowercase_ , **lowercase_ )
# get the text config dict if we are loading from AlignConfig
if config_dict.get('''model_type''' ) == "align":
snake_case_ = config_dict['''text_config''']
if "model_type" in config_dict and hasattr(cls , '''model_type''' ) and config_dict["model_type"] != cls.model_type:
logger.warning(
F"You are using a model of type {config_dict['model_type']} to instantiate a model of type "
F"{cls.model_type}. This is not supported for all configurations of models and can yield errors." )
return cls.from_dict(lowercase_ , **lowercase_ )
class a ( _lowerCamelCase ):
snake_case_ = "align_vision_model"
def __init__( self : Any , lowercase_ : int = 3 , lowercase_ : int = 600 , lowercase_ : float = 2.0 , lowercase_ : float = 3.1 , lowercase_ : int = 8 , lowercase_ : List[int] = [3, 3, 5, 3, 5, 5, 3] , lowercase_ : List[int] = [32, 16, 24, 40, 80, 112, 192] , lowercase_ : List[int] = [16, 24, 40, 80, 112, 192, 320] , lowercase_ : List[int] = [] , lowercase_ : List[int] = [1, 2, 2, 2, 1, 2, 1] , lowercase_ : List[int] = [1, 2, 2, 3, 3, 4, 1] , lowercase_ : List[int] = [1, 6, 6, 6, 6, 6, 6] , lowercase_ : float = 0.25 , lowercase_ : str = "swish" , lowercase_ : int = 2560 , lowercase_ : str = "mean" , lowercase_ : float = 0.02 , lowercase_ : float = 0.001 , lowercase_ : float = 0.99 , lowercase_ : float = 0.2 , **lowercase_ : Any , ):
super().__init__(**lowercase_ )
snake_case_ = num_channels
snake_case_ = image_size
snake_case_ = width_coefficient
snake_case_ = depth_coefficient
snake_case_ = depth_divisor
snake_case_ = kernel_sizes
snake_case_ = in_channels
snake_case_ = out_channels
snake_case_ = depthwise_padding
snake_case_ = strides
snake_case_ = num_block_repeats
snake_case_ = expand_ratios
snake_case_ = squeeze_expansion_ratio
snake_case_ = hidden_act
snake_case_ = hidden_dim
snake_case_ = pooling_type
snake_case_ = initializer_range
snake_case_ = batch_norm_eps
snake_case_ = batch_norm_momentum
snake_case_ = drop_connect_rate
snake_case_ = sum(lowercase_ ) * 4
@classmethod
def A_ ( cls : Optional[int] , lowercase_ : Union[str, os.PathLike] , **lowercase_ : Any ):
cls._set_token_in_kwargs(lowercase_ )
snake_case_ ,snake_case_ = cls.get_config_dict(lowercase_ , **lowercase_ )
# get the vision config dict if we are loading from AlignConfig
if config_dict.get('''model_type''' ) == "align":
snake_case_ = config_dict['''vision_config''']
if "model_type" in config_dict and hasattr(cls , '''model_type''' ) and config_dict["model_type"] != cls.model_type:
logger.warning(
F"You are using a model of type {config_dict['model_type']} to instantiate a model of type "
F"{cls.model_type}. This is not supported for all configurations of models and can yield errors." )
return cls.from_dict(lowercase_ , **lowercase_ )
class a ( _lowerCamelCase ):
snake_case_ = "align"
snake_case_ = True
def __init__( self : List[Any] , lowercase_ : int=None , lowercase_ : List[Any]=None , lowercase_ : Dict=640 , lowercase_ : Optional[int]=1.0 , lowercase_ : Any=0.02 , **lowercase_ : Optional[int] , ):
super().__init__(**lowercase_ )
if text_config is None:
snake_case_ = {}
logger.info('''text_config is None. Initializing the AlignTextConfig with default values.''' )
if vision_config is None:
snake_case_ = {}
logger.info('''vision_config is None. Initializing the AlignVisionConfig with default values.''' )
snake_case_ = AlignTextConfig(**lowercase_ )
snake_case_ = AlignVisionConfig(**lowercase_ )
snake_case_ = projection_dim
snake_case_ = temperature_init_value
snake_case_ = initializer_range
@classmethod
def A_ ( cls : Optional[int] , lowercase_ : AlignTextConfig , lowercase_ : AlignVisionConfig , **lowercase_ : List[str] ):
return cls(text_config=text_config.to_dict() , vision_config=vision_config.to_dict() , **lowercase_ )
def A_ ( self : Tuple ):
snake_case_ = copy.deepcopy(self.__dict__ )
snake_case_ = self.text_config.to_dict()
snake_case_ = self.vision_config.to_dict()
snake_case_ = self.__class__.model_type
return output
| 56
|
import random
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Optional[Any] = a[left_index]
__UpperCamelCase :Any = left_index + 1
for j in range(left_index + 1 , SCREAMING_SNAKE_CASE ):
if a[j] < pivot:
__UpperCamelCase , __UpperCamelCase :str = a[i], a[j]
i += 1
__UpperCamelCase , __UpperCamelCase :Optional[int] = a[i - 1], a[left_index]
return i - 1
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
if left < right:
__UpperCamelCase :int = random.randint(SCREAMING_SNAKE_CASE , right - 1 )
__UpperCamelCase , __UpperCamelCase :List[str] = (
a[left],
a[pivot],
) # switches the pivot with the left most bound
__UpperCamelCase :Dict = partition(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
quick_sort_random(
SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ) # recursive quicksort to the left of the pivot point
quick_sort_random(
SCREAMING_SNAKE_CASE , pivot_index + 1 , SCREAMING_SNAKE_CASE ) # recursive quicksort to the right of the pivot point
def lowerCamelCase ( ):
'''simple docstring'''
__UpperCamelCase :Tuple = input('''Enter numbers separated by a comma:\n''' ).strip()
__UpperCamelCase :Union[str, Any] = [int(SCREAMING_SNAKE_CASE ) for item in user_input.split(''',''' )]
quick_sort_random(SCREAMING_SNAKE_CASE , 0 , len(SCREAMING_SNAKE_CASE ) )
print(SCREAMING_SNAKE_CASE )
if __name__ == "__main__":
main()
| 43
| 0
|
"""simple docstring"""
import numpy as np
import torch
import torch.nn as nn
from transformers import CLIPConfig, CLIPVisionModelWithProjection, PreTrainedModel
from ...utils import logging
A : str = logging.get_logger(__name__)
class _UpperCamelCase ( lowerCAmelCase__ ):
'''simple docstring'''
__UpperCAmelCase : List[str] =CLIPConfig
__UpperCAmelCase : Dict =["""CLIPEncoderLayer"""]
def __init__( self , __a ):
super().__init__(__a )
__lowerCAmelCase = CLIPVisionModelWithProjection(config.vision_config )
__lowerCAmelCase = nn.Linear(config.vision_config.projection_dim , 1 )
__lowerCAmelCase = nn.Linear(config.vision_config.projection_dim , 1 )
@torch.no_grad()
def snake_case ( self , __a , __a , __a=0.5 , __a=0.5 ):
__lowerCAmelCase = self.vision_model(__a )[0]
__lowerCAmelCase = self.p_head(__a )
__lowerCAmelCase = nsfw_detected.flatten()
__lowerCAmelCase = nsfw_detected > p_threshold
__lowerCAmelCase = nsfw_detected.tolist()
if any(__a ):
logger.warning(
"Potential NSFW content was detected in one or more images. A black image will be returned instead."
" Try again with a different prompt and/or seed." )
for idx, nsfw_detected_ in enumerate(__a ):
if nsfw_detected_:
__lowerCAmelCase = np.zeros(images[idx].shape )
__lowerCAmelCase = self.w_head(__a )
__lowerCAmelCase = watermark_detected.flatten()
__lowerCAmelCase = watermark_detected > w_threshold
__lowerCAmelCase = watermark_detected.tolist()
if any(__a ):
logger.warning(
"Potential watermarked content was detected in one or more images. A black image will be returned instead."
" Try again with a different prompt and/or seed." )
for idx, watermark_detected_ in enumerate(__a ):
if watermark_detected_:
__lowerCAmelCase = np.zeros(images[idx].shape )
return images, nsfw_detected, watermark_detected
| 57
|
def lowerCamelCase ( SCREAMING_SNAKE_CASE = 1 , SCREAMING_SNAKE_CASE = 1_000 ):
'''simple docstring'''
__UpperCamelCase :Union[str, Any] = 1
__UpperCamelCase :Any = 0
for divide_by_number in range(SCREAMING_SNAKE_CASE , digit + 1 ):
__UpperCamelCase :list[int] = []
__UpperCamelCase :Optional[int] = numerator
for _ in range(1 , digit + 1 ):
if now_divide in has_been_divided:
if longest_list_length < len(SCREAMING_SNAKE_CASE ):
__UpperCamelCase :Optional[Any] = len(SCREAMING_SNAKE_CASE )
__UpperCamelCase :int = divide_by_number
else:
has_been_divided.append(SCREAMING_SNAKE_CASE )
__UpperCamelCase :Any = now_divide * 10 % divide_by_number
return the_digit
# Tests
if __name__ == "__main__":
import doctest
doctest.testmod()
| 43
| 0
|
'''simple docstring'''
def lowerCamelCase ( __lowerCamelCase : int = 10 , __lowerCamelCase : int = 1000 , __lowerCamelCase : bool = True ) ->int:
assert (
isinstance(__lowerCamelCase , __lowerCamelCase )
and isinstance(__lowerCamelCase , __lowerCamelCase )
and isinstance(__lowerCamelCase , __lowerCamelCase )
), "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 lowerCamelCase ( __lowerCamelCase : int , __lowerCamelCase : int ) ->int:
return int((number_a + number_a) / 2 )
def lowerCamelCase ( __lowerCamelCase : int , __lowerCamelCase : int , __lowerCamelCase : int ) ->None:
assert (
isinstance(__lowerCamelCase , __lowerCamelCase ) and isinstance(__lowerCamelCase , __lowerCamelCase ) and isinstance(__lowerCamelCase , __lowerCamelCase )
), '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(__lowerCamelCase : int ) -> str:
if number > to_guess:
return "high"
elif number < to_guess:
return "low"
else:
return "same"
print("""started...""" )
_SCREAMING_SNAKE_CASE = lower
_SCREAMING_SNAKE_CASE = higher
_SCREAMING_SNAKE_CASE = []
while True:
_SCREAMING_SNAKE_CASE = get_avg(__lowerCamelCase , __lowerCamelCase )
last_numbers.append(__lowerCamelCase )
if answer(__lowerCamelCase ) == "low":
_SCREAMING_SNAKE_CASE = number
elif answer(__lowerCamelCase ) == "high":
_SCREAMING_SNAKE_CASE = number
else:
break
print(F'guess the number : {last_numbers[-1]}' )
print(F'details : {last_numbers!s}' )
def lowerCamelCase ( ) ->None:
_SCREAMING_SNAKE_CASE = int(input("""Enter lower value : """ ).strip() )
_SCREAMING_SNAKE_CASE = int(input("""Enter high value : """ ).strip() )
_SCREAMING_SNAKE_CASE = int(input("""Enter value to guess : """ ).strip() )
guess_the_number(__lowerCamelCase , __lowerCamelCase , __lowerCamelCase )
if __name__ == "__main__":
main()
| 58
|
import argparse
import json
from tqdm import tqdm
def lowerCamelCase ( ):
'''simple docstring'''
__UpperCamelCase :Tuple = argparse.ArgumentParser()
# Required parameters
parser.add_argument(
'''--src_path''' , type=SCREAMING_SNAKE_CASE , default='''biencoder-nq-dev.json''' , help='''Path to raw DPR training data''' , )
parser.add_argument(
'''--evaluation_set''' , type=SCREAMING_SNAKE_CASE , help='''where to store parsed evaluation_set file''' , )
parser.add_argument(
'''--gold_data_path''' , type=SCREAMING_SNAKE_CASE , help='''where to store parsed gold_data_path file''' , )
__UpperCamelCase :str = parser.parse_args()
with open(args.src_path , '''r''' ) as src_file, open(args.evaluation_set , '''w''' ) as eval_file, open(
args.gold_data_path , '''w''' ) as gold_file:
__UpperCamelCase :List[str] = json.load(SCREAMING_SNAKE_CASE )
for dpr_record in tqdm(SCREAMING_SNAKE_CASE ):
__UpperCamelCase :List[str] = dpr_record['''question''']
__UpperCamelCase :Tuple = [context['''title'''] for context in dpr_record['''positive_ctxs''']]
eval_file.write(question + '''\n''' )
gold_file.write('''\t'''.join(SCREAMING_SNAKE_CASE ) + '''\n''' )
if __name__ == "__main__":
main()
| 43
| 0
|
import os
from shutil import copyfile
from typing import Any, Dict, List, Optional, Tuple
import sentencepiece as spm
from ...tokenization_utils import AddedToken, BatchEncoding, PreTrainedTokenizer
from ...utils import logging
__lowerCamelCase = logging.get_logger(__name__)
__lowerCamelCase = """▁"""
__lowerCamelCase = {"""vocab_file""": """sentencepiece.bpe.model"""}
__lowerCamelCase = {
"""vocab_file""": {
"""facebook/mbart-large-50-one-to-many-mmt""": (
"""https://huggingface.co/facebook/mbart-large-50-one-to-many-mmt/resolve/main/sentencepiece.bpe.model"""
),
}
}
__lowerCamelCase = {
"""facebook/mbart-large-50-one-to-many-mmt""": 10_24,
}
# fmt: off
__lowerCamelCase = ["""ar_AR""", """cs_CZ""", """de_DE""", """en_XX""", """es_XX""", """et_EE""", """fi_FI""", """fr_XX""", """gu_IN""", """hi_IN""", """it_IT""", """ja_XX""", """kk_KZ""", """ko_KR""", """lt_LT""", """lv_LV""", """my_MM""", """ne_NP""", """nl_XX""", """ro_RO""", """ru_RU""", """si_LK""", """tr_TR""", """vi_VN""", """zh_CN""", """af_ZA""", """az_AZ""", """bn_IN""", """fa_IR""", """he_IL""", """hr_HR""", """id_ID""", """ka_GE""", """km_KH""", """mk_MK""", """ml_IN""", """mn_MN""", """mr_IN""", """pl_PL""", """ps_AF""", """pt_XX""", """sv_SE""", """sw_KE""", """ta_IN""", """te_IN""", """th_TH""", """tl_XX""", """uk_UA""", """ur_PK""", """xh_ZA""", """gl_ES""", """sl_SI"""]
class UpperCAmelCase ( A_ ):
A__ : Optional[Any] = VOCAB_FILES_NAMES
A__ : Union[str, Any] = PRETRAINED_POSITIONAL_EMBEDDINGS_SIZES
A__ : str = PRETRAINED_VOCAB_FILES_MAP
A__ : str = ["input_ids", "attention_mask"]
A__ : List[int] = []
A__ : List[int] = []
def __init__(self : List[Any] , snake_case__ : Tuple , snake_case__ : Dict=None , snake_case__ : Any=None , snake_case__ : int="</s>" , snake_case__ : List[Any]="</s>" , snake_case__ : Optional[int]="<s>" , snake_case__ : Tuple="<unk>" , snake_case__ : List[str]="<pad>" , snake_case__ : Dict="<mask>" , snake_case__ : Optional[Dict[str, Any]] = None , **snake_case__ : Tuple , ) -> None:
'''simple docstring'''
snake_case : int = AddedToken(snake_case__ , lstrip=snake_case__ , rstrip=snake_case__ ) if isinstance(snake_case__ , snake_case__ ) else mask_token
snake_case : Tuple = {} if sp_model_kwargs is None else sp_model_kwargs
snake_case : Union[str, Any] = kwargs.get("additional_special_tokens" , [] )
kwargs["additional_special_tokens"] += [
code for code in FAIRSEQ_LANGUAGE_CODES if code not in kwargs["additional_special_tokens"]
]
super().__init__(
src_lang=snake_case__ , tgt_lang=snake_case__ , eos_token=snake_case__ , unk_token=snake_case__ , sep_token=snake_case__ , cls_token=snake_case__ , pad_token=snake_case__ , mask_token=snake_case__ , sp_model_kwargs=self.sp_model_kwargs , **snake_case__ , )
snake_case : Tuple = spm.SentencePieceProcessor(**self.sp_model_kwargs )
self.sp_model.Load(str(snake_case__ ) )
snake_case : Tuple = vocab_file
# Original fairseq vocab and spm vocab must be "aligned":
# Vocab | 0 | 1 | 2 | 3 | 4 | 5 | 6 | 7 | 8 | 9
# -------- | ------- | ------- | ------ | ------- | --- | --- | --- | ----- | ----- | ----
# fairseq | '<s>' | '<pad>' | '</s>' | '<unk>' | ',' | '.' | '▁' | 's' | '▁de' | '-'
# spm | '<unk>' | '<s>' | '</s>' | ',' | '.' | '▁' | 's' | '▁de' | '-' | '▁a'
# Mimic fairseq token-to-id alignment for the first 4 token
snake_case : Optional[int] = {"<s>": 0, "<pad>": 1, "</s>": 2, "<unk>": 3}
# The first "real" token "," has position 4 in the original fairseq vocab and position 3 in the spm vocab
snake_case : List[str] = 1
snake_case : int = len(self.sp_model )
snake_case : Any = {
code: self.sp_model_size + i + self.fairseq_offset for i, code in enumerate(snake_case__ )
}
snake_case : Union[str, Any] = {v: k for k, v in self.lang_code_to_id.items()}
snake_case : List[Any] = len(self.sp_model ) + len(self.lang_code_to_id ) + self.fairseq_offset
self.fairseq_tokens_to_ids.update(self.lang_code_to_id )
snake_case : Any = {v: k for k, v in self.fairseq_tokens_to_ids.items()}
snake_case : str = src_lang if src_lang is not None else "en_XX"
snake_case : Dict = self.lang_code_to_id[self._src_lang]
snake_case : int = tgt_lang
self.set_src_lang_special_tokens(self._src_lang )
@property
def _SCREAMING_SNAKE_CASE (self : Tuple ) -> int:
'''simple docstring'''
return len(self.sp_model ) + len(self.lang_code_to_id ) + self.fairseq_offset + 1 # Plus 1 for the mask token
@property
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> str:
'''simple docstring'''
return self._src_lang
@src_lang.setter
def _SCREAMING_SNAKE_CASE (self : List[str] , snake_case__ : str ) -> None:
'''simple docstring'''
snake_case : Dict = new_src_lang
self.set_src_lang_special_tokens(self._src_lang )
def __getstate__(self : str ) -> Dict:
'''simple docstring'''
snake_case : Optional[int] = self.__dict__.copy()
snake_case : List[str] = None
return state
def __setstate__(self : str , snake_case__ : Dict ) -> None:
'''simple docstring'''
snake_case : List[Any] = d
# for backward compatibility
if not hasattr(self , "sp_model_kwargs" ):
snake_case : Dict = {}
snake_case : int = spm.SentencePieceProcessor(**self.sp_model_kwargs )
self.sp_model.Load(self.vocab_file )
def _SCREAMING_SNAKE_CASE (self : Tuple ) -> Dict:
'''simple docstring'''
snake_case : Dict = {self.convert_ids_to_tokens(snake_case__ ): i for i in range(self.vocab_size )}
vocab.update(self.added_tokens_encoder )
return vocab
def _SCREAMING_SNAKE_CASE (self : str , snake_case__ : str ) -> List[str]:
'''simple docstring'''
return self.sp_model.encode(snake_case__ , out_type=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : List[Any] , snake_case__ : str ) -> int:
'''simple docstring'''
if token in self.fairseq_tokens_to_ids:
return self.fairseq_tokens_to_ids[token]
snake_case : List[Any] = self.sp_model.PieceToId(snake_case__ )
# Need to return unknown token if the SP model returned 0
return spm_id + self.fairseq_offset if spm_id else self.unk_token_id
def _SCREAMING_SNAKE_CASE (self : Optional[int] , snake_case__ : int ) -> str:
'''simple docstring'''
if index in self.fairseq_ids_to_tokens:
return self.fairseq_ids_to_tokens[index]
return self.sp_model.IdToPiece(index - self.fairseq_offset )
def _SCREAMING_SNAKE_CASE (self : List[str] , snake_case__ : List[Any] ) -> Union[str, Any]:
'''simple docstring'''
snake_case : int = []
snake_case : Union[str, Any] = ""
snake_case : Tuple = False
for token in tokens:
# make sure that special tokens are not decoded using sentencepiece model
if token in self.all_special_tokens:
if not prev_is_special:
out_string += " "
out_string += self.sp_model.decode(snake_case__ ) + token
snake_case : List[Any] = True
snake_case : List[Any] = []
else:
current_sub_tokens.append(snake_case__ )
snake_case : Optional[Any] = False
out_string += self.sp_model.decode(snake_case__ )
return out_string.strip()
def _SCREAMING_SNAKE_CASE (self : Any , snake_case__ : str , snake_case__ : Optional[str] = None ) -> Tuple[str]:
'''simple docstring'''
if not os.path.isdir(snake_case__ ):
logger.error(f"""Vocabulary path ({save_directory}) should be a directory""" )
return
snake_case : Any = os.path.join(
snake_case__ , (filename_prefix + "-" if filename_prefix else "") + VOCAB_FILES_NAMES["vocab_file"] )
if os.path.abspath(self.vocab_file ) != os.path.abspath(snake_case__ ) and os.path.isfile(self.vocab_file ):
copyfile(self.vocab_file , snake_case__ )
elif not os.path.isfile(self.vocab_file ):
with open(snake_case__ , "wb" ) as fi:
snake_case : str = self.sp_model.serialized_model_proto()
fi.write(snake_case__ )
return (out_vocab_file,)
def _SCREAMING_SNAKE_CASE (self : List[Any] , snake_case__ : List[int] , snake_case__ : Optional[List[int]] = None , snake_case__ : bool = False ) -> List[int]:
'''simple docstring'''
if already_has_special_tokens:
return super().get_special_tokens_mask(
token_ids_a=snake_case__ , token_ids_a=snake_case__ , already_has_special_tokens=snake_case__ )
snake_case : Union[str, Any] = [1] * len(self.prefix_tokens )
snake_case : int = [1] * len(self.suffix_tokens )
if token_ids_a is None:
return prefix_ones + ([0] * len(snake_case__ )) + suffix_ones
return prefix_ones + ([0] * len(snake_case__ )) + ([0] * len(snake_case__ )) + suffix_ones
def _SCREAMING_SNAKE_CASE (self : Optional[int] , snake_case__ : List[int] , snake_case__ : Optional[List[int]] = None ) -> List[int]:
'''simple docstring'''
if token_ids_a is None:
return self.prefix_tokens + token_ids_a + self.suffix_tokens
# 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.suffix_tokens
def _SCREAMING_SNAKE_CASE (self : Optional[Any] , snake_case__ : Dict , snake_case__ : str , snake_case__ : Optional[str] , snake_case__ : Optional[str] , **snake_case__ : Optional[int] ) -> Optional[int]:
'''simple docstring'''
if src_lang is None or tgt_lang is None:
raise ValueError("Translation requires a `src_lang` and a `tgt_lang` for this model" )
snake_case : str = src_lang
snake_case : List[str] = self(snake_case__ , add_special_tokens=snake_case__ , return_tensors=snake_case__ , **snake_case__ )
snake_case : Optional[int] = self.convert_tokens_to_ids(snake_case__ )
snake_case : Optional[int] = tgt_lang_id
return inputs
def _SCREAMING_SNAKE_CASE (self : int , snake_case__ : List[str] , snake_case__ : str = "en_XX" , snake_case__ : Optional[List[str]] = None , snake_case__ : str = "ro_RO" , **snake_case__ : Union[str, Any] , ) -> BatchEncoding:
'''simple docstring'''
snake_case : str = src_lang
snake_case : int = tgt_lang
return super().prepare_seqaseq_batch(snake_case__ , snake_case__ , **snake_case__ )
def _SCREAMING_SNAKE_CASE (self : str ) -> Optional[Any]:
'''simple docstring'''
return self.set_src_lang_special_tokens(self.src_lang )
def _SCREAMING_SNAKE_CASE (self : Optional[Any] ) -> str:
'''simple docstring'''
return self.set_tgt_lang_special_tokens(self.tgt_lang )
def _SCREAMING_SNAKE_CASE (self : Optional[int] , snake_case__ : str ) -> None:
'''simple docstring'''
snake_case : List[str] = self.lang_code_to_id[src_lang]
snake_case : List[str] = [self.cur_lang_code_id]
snake_case : Any = [self.eos_token_id]
def _SCREAMING_SNAKE_CASE (self : List[Any] , snake_case__ : str ) -> None:
'''simple docstring'''
snake_case : Tuple = self.lang_code_to_id[tgt_lang]
snake_case : Union[str, Any] = [self.cur_lang_code_id]
snake_case : Tuple = [self.eos_token_id]
| 59
|
from __future__ import annotations
import random
# Maximum size of the population. Bigger could be faster but is more memory expensive.
__lowercase = 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.
__lowercase = 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.
__lowercase = 0.4
# Just a seed to improve randomness required by the algorithm.
random.seed(random.randint(0, 1000))
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Any = len([g for position, g in enumerate(SCREAMING_SNAKE_CASE ) if g == main_target[position]] )
return (item, float(SCREAMING_SNAKE_CASE ))
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :Optional[Any] = random.randint(0 , len(SCREAMING_SNAKE_CASE ) - 1 )
__UpperCamelCase :Tuple = parent_a[:random_slice] + parent_a[random_slice:]
__UpperCamelCase :Union[str, Any] = parent_a[:random_slice] + parent_a[random_slice:]
return (child_a, child_a)
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :int = list(SCREAMING_SNAKE_CASE )
if random.uniform(0 , 1 ) < MUTATION_PROBABILITY:
__UpperCamelCase :str = random.choice(SCREAMING_SNAKE_CASE )
return "".join(SCREAMING_SNAKE_CASE )
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , ):
'''simple docstring'''
__UpperCamelCase :int = []
# Generate more children proportionally to the fitness score.
__UpperCamelCase :int = int(parent_a[1] * 100 ) + 1
__UpperCamelCase :List[str] = 10 if child_n >= 10 else child_n
for _ in range(SCREAMING_SNAKE_CASE ):
__UpperCamelCase :Optional[Any] = population_score[random.randint(0 , SCREAMING_SNAKE_CASE )][0]
__UpperCamelCase , __UpperCamelCase :Any = crossover(parent_a[0] , SCREAMING_SNAKE_CASE )
# Append new string to the population list.
pop.append(mutate(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ) )
pop.append(mutate(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ) )
return pop
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE = True ):
'''simple docstring'''
if N_POPULATION < N_SELECTED:
__UpperCamelCase :List[Any] = f"""{N_POPULATION} must be bigger than {N_SELECTED}"""
raise ValueError(SCREAMING_SNAKE_CASE )
# Verify that the target contains no genes besides the ones inside genes variable.
__UpperCamelCase :List[str] = sorted({c for c in target if c not in genes} )
if not_in_genes_list:
__UpperCamelCase :Optional[int] = f"""{not_in_genes_list} is not in genes list, evolution cannot converge"""
raise ValueError(SCREAMING_SNAKE_CASE )
# Generate random starting population.
__UpperCamelCase :int = []
for _ in range(SCREAMING_SNAKE_CASE ):
population.append(''''''.join([random.choice(SCREAMING_SNAKE_CASE ) for i in range(len(SCREAMING_SNAKE_CASE ) )] ) )
# Just some logs to know what the algorithms is doing.
__UpperCamelCase , __UpperCamelCase :List[Any] = 0, 0
# This loop will end when we find a perfect match for our target.
while True:
generation += 1
total_population += len(SCREAMING_SNAKE_CASE )
# 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.
__UpperCamelCase :Tuple = [evaluate(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ) for item in population]
# Check if there is a matching evolution.
__UpperCamelCase :Tuple = sorted(SCREAMING_SNAKE_CASE , key=lambda SCREAMING_SNAKE_CASE : x[1] , reverse=SCREAMING_SNAKE_CASE )
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.
__UpperCamelCase :str = population[: int(N_POPULATION / 3 )]
population.clear()
population.extend(SCREAMING_SNAKE_CASE )
# Normalize population score to be between 0 and 1.
__UpperCamelCase :Union[str, Any] = [
(item, score / len(SCREAMING_SNAKE_CASE )) for item, score in population_score
]
# This is selection
for i in range(SCREAMING_SNAKE_CASE ):
population.extend(select(population_score[int(SCREAMING_SNAKE_CASE )] , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ) )
# 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(SCREAMING_SNAKE_CASE ) > N_POPULATION:
break
if __name__ == "__main__":
__lowercase = (
'''This is a genetic algorithm to evaluate, combine, evolve, and mutate a string!'''
)
__lowercase = list(
''' ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklm'''
'''nopqrstuvwxyz.,;!?+-*#@^\'èéòà€ù=)(&%$£/\\'''
)
__lowercase , __lowercase , __lowercase = basic(target_str, genes_list)
print(
F'\nGeneration: {generation}\nTotal Population: {population}\nTarget: {target}'
)
| 43
| 0
|
"""simple docstring"""
#
# This a `torch.distributed` diagnostics script that checks that all GPUs in the cluster (one or
# many nodes) can talk to each other via nccl and allocate gpu memory.
#
# To run first adjust the number of processes and nodes:
#
# python -m torch.distributed.run --nproc_per_node 2 --nnodes 1 torch-distributed-gpu-test.py
#
# You may need to add --master_addr $MASTER_ADDR --master_port $MASTER_PORT if using a custom addr:port
#
# You can also use the rdzv API: --rdzv_endpoint $MASTER_ADDR:$MASTER_PORT --rdzv_backend c10d
#
# use torch.distributed.launch instead of torch.distributed.run for torch < 1.9
#
# If you get a hanging in `barrier` calls you have some network issues, you may try to debug this with:
#
# NCCL_DEBUG=INFO python -m torch.distributed.run --nproc_per_node 2 --nnodes 1 torch-distributed-gpu-test.py
#
# which should tell you what's going on behind the scenes.
#
#
# This script can be run via `srun` in the SLURM environment as well. Here is a SLURM script that
# runs on 2 nodes of 4 gpus per node:
#
# #SBATCH --job-name=test-nodes # name
# #SBATCH --nodes=2 # nodes
# #SBATCH --ntasks-per-node=1 # crucial - only 1 task per dist per node!
# #SBATCH --cpus-per-task=10 # number of cores per tasks
# #SBATCH --gres=gpu:4 # number of gpus
# #SBATCH --time 0:05:00 # maximum execution time (HH:MM:SS)
# #SBATCH --output=%x-%j.out # output file name
#
# GPUS_PER_NODE=4
# MASTER_ADDR=$(scontrol show hostnames $SLURM_JOB_NODELIST | head -n 1)
# MASTER_PORT=6000
#
# srun --jobid $SLURM_JOBID bash -c 'python -m torch.distributed.run \
# --nproc_per_node $GPUS_PER_NODE --nnodes $SLURM_NNODES --node_rank $SLURM_PROCID \
# --master_addr $MASTER_ADDR --master_port $MASTER_PORT \
# torch-distributed-gpu-test.py'
#
import fcntl
import os
import socket
import torch
import torch.distributed as dist
def _snake_case ( *_snake_case : Dict ):
with open(_snake_case , '''r''' ) as fh:
fcntl.flock(_snake_case , fcntl.LOCK_EX )
try:
print(*_snake_case )
finally:
fcntl.flock(_snake_case , fcntl.LOCK_UN )
snake_case__ : str = int(os.environ['''LOCAL_RANK'''])
torch.cuda.set_device(local_rank)
snake_case__ : int = torch.device('''cuda''', local_rank)
snake_case__ : Union[str, Any] = socket.gethostname()
snake_case__ : str = f"""[{hostname}-{local_rank}]"""
try:
# test distributed
dist.init_process_group('''nccl''')
dist.all_reduce(torch.ones(1).to(device), op=dist.ReduceOp.SUM)
dist.barrier()
# test cuda is available and can allocate memory
torch.cuda.is_available()
torch.ones(1).cuda(local_rank)
# global rank
snake_case__ : List[Any] = dist.get_rank()
snake_case__ : List[str] = dist.get_world_size()
printflock(f"""{gpu} is OK (global rank: {rank}/{world_size})""")
dist.barrier()
if rank == 0:
printflock(f"""pt={torch.__version__}, cuda={torch.version.cuda}, nccl={torch.cuda.nccl.version()}""")
except Exception:
printflock(f"""{gpu} is broken""")
raise
| 60
|
import argparse
import json
import os
import evaluate
import torch
from datasets import load_dataset
from torch.optim import AdamW
from torch.utils.data import DataLoader
from transformers import AutoModelForSequenceClassification, AutoTokenizer, get_linear_schedule_with_warmup, set_seed
from accelerate import Accelerator, DistributedType
from accelerate.utils.deepspeed import DummyOptim, DummyScheduler
__lowercase = 16
__lowercase = 32
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE = 16 , SCREAMING_SNAKE_CASE = "bert-base-cased" ):
'''simple docstring'''
__UpperCamelCase :List[str] = AutoTokenizer.from_pretrained(SCREAMING_SNAKE_CASE )
__UpperCamelCase :Any = load_dataset('''glue''' , '''mrpc''' )
def tokenize_function(SCREAMING_SNAKE_CASE ):
# max_length=None => use the model max length (it's actually the default)
__UpperCamelCase :int = tokenizer(examples['''sentence1'''] , examples['''sentence2'''] , truncation=SCREAMING_SNAKE_CASE , max_length=SCREAMING_SNAKE_CASE )
return outputs
# Apply the method we just defined to all the examples in all the splits of the dataset
__UpperCamelCase :Tuple = datasets.map(
SCREAMING_SNAKE_CASE , batched=SCREAMING_SNAKE_CASE , remove_columns=['''idx''', '''sentence1''', '''sentence2'''] , load_from_cache_file=SCREAMING_SNAKE_CASE )
# We also rename the 'label' column to 'labels' which is the expected name for labels by the models of the
# transformers library
__UpperCamelCase :List[str] = tokenized_datasets.rename_column('''label''' , '''labels''' )
def collate_fn(SCREAMING_SNAKE_CASE ):
# On TPU it's best to pad everything to the same length or training will be very slow.
if accelerator.distributed_type == DistributedType.TPU:
return tokenizer.pad(SCREAMING_SNAKE_CASE , padding='''max_length''' , max_length=128 , return_tensors='''pt''' )
return tokenizer.pad(SCREAMING_SNAKE_CASE , padding='''longest''' , return_tensors='''pt''' )
# Instantiate dataloaders.
__UpperCamelCase :Union[str, Any] = DataLoader(
tokenized_datasets['''train'''] , shuffle=SCREAMING_SNAKE_CASE , collate_fn=SCREAMING_SNAKE_CASE , batch_size=SCREAMING_SNAKE_CASE )
__UpperCamelCase :Dict = DataLoader(
tokenized_datasets['''validation'''] , shuffle=SCREAMING_SNAKE_CASE , collate_fn=SCREAMING_SNAKE_CASE , batch_size=SCREAMING_SNAKE_CASE )
return train_dataloader, eval_dataloader
def lowerCamelCase ( SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
'''simple docstring'''
__UpperCamelCase :List[Any] = Accelerator()
# Sample hyper-parameters for learning rate, batch size, seed and a few other HPs
__UpperCamelCase :int = config['''lr''']
__UpperCamelCase :str = int(config['''num_epochs'''] )
__UpperCamelCase :Any = int(config['''seed'''] )
__UpperCamelCase :Dict = int(config['''batch_size'''] )
__UpperCamelCase :Optional[Any] = args.model_name_or_path
set_seed(SCREAMING_SNAKE_CASE )
__UpperCamelCase , __UpperCamelCase :Dict = get_dataloaders(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
# Instantiate the model (we build the model here so that the seed also control new weights initialization)
__UpperCamelCase :Any = AutoModelForSequenceClassification.from_pretrained(SCREAMING_SNAKE_CASE , return_dict=SCREAMING_SNAKE_CASE )
# Instantiate optimizer
__UpperCamelCase :List[str] = (
AdamW
if accelerator.state.deepspeed_plugin is None
or '''optimizer''' not in accelerator.state.deepspeed_plugin.deepspeed_config
else DummyOptim
)
__UpperCamelCase :Optional[Any] = optimizer_cls(params=model.parameters() , lr=SCREAMING_SNAKE_CASE )
if accelerator.state.deepspeed_plugin is not None:
__UpperCamelCase :Dict = accelerator.state.deepspeed_plugin.deepspeed_config[
'''gradient_accumulation_steps'''
]
else:
__UpperCamelCase :Dict = 1
__UpperCamelCase :Tuple = (len(SCREAMING_SNAKE_CASE ) * num_epochs) // gradient_accumulation_steps
# Instantiate scheduler
if (
accelerator.state.deepspeed_plugin is None
or "scheduler" not in accelerator.state.deepspeed_plugin.deepspeed_config
):
__UpperCamelCase :str = get_linear_schedule_with_warmup(
optimizer=SCREAMING_SNAKE_CASE , num_warmup_steps=0 , num_training_steps=SCREAMING_SNAKE_CASE , )
else:
__UpperCamelCase :Dict = DummyScheduler(SCREAMING_SNAKE_CASE , total_num_steps=SCREAMING_SNAKE_CASE , warmup_num_steps=0 )
# Prepare everything
# There is no specific order to remember, we just need to unpack the objects in the same order we gave them to the
# prepare method.
__UpperCamelCase , __UpperCamelCase , __UpperCamelCase , __UpperCamelCase , __UpperCamelCase :int = accelerator.prepare(
SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
# We need to keep track of how many total steps we have iterated over
__UpperCamelCase :List[Any] = 0
# We also need to keep track of the stating epoch so files are named properly
__UpperCamelCase :Dict = 0
# Now we train the model
__UpperCamelCase :Any = evaluate.load('''glue''' , '''mrpc''' )
__UpperCamelCase :Union[str, Any] = 0
__UpperCamelCase :Optional[int] = {}
for epoch in range(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE ):
model.train()
for step, batch in enumerate(SCREAMING_SNAKE_CASE ):
__UpperCamelCase :Optional[Any] = model(**SCREAMING_SNAKE_CASE )
__UpperCamelCase :Tuple = outputs.loss
__UpperCamelCase :str = loss / gradient_accumulation_steps
accelerator.backward(SCREAMING_SNAKE_CASE )
if step % gradient_accumulation_steps == 0:
optimizer.step()
lr_scheduler.step()
optimizer.zero_grad()
overall_step += 1
model.eval()
__UpperCamelCase :Any = 0
for step, batch in enumerate(SCREAMING_SNAKE_CASE ):
# We could avoid this line since we set the accelerator with `device_placement=True`.
batch.to(accelerator.device )
with torch.no_grad():
__UpperCamelCase :Any = model(**SCREAMING_SNAKE_CASE )
__UpperCamelCase :Optional[int] = outputs.logits.argmax(dim=-1 )
# It is slightly faster to call this once, than multiple times
__UpperCamelCase , __UpperCamelCase :List[Any] = accelerator.gather(
(predictions, batch['''labels''']) ) # If we are in a multiprocess environment, the last batch has duplicates
if accelerator.use_distributed:
if step == len(SCREAMING_SNAKE_CASE ) - 1:
__UpperCamelCase :List[str] = predictions[: len(eval_dataloader.dataset ) - samples_seen]
__UpperCamelCase :Optional[int] = references[: len(eval_dataloader.dataset ) - samples_seen]
else:
samples_seen += references.shape[0]
metric.add_batch(
predictions=SCREAMING_SNAKE_CASE , references=SCREAMING_SNAKE_CASE , )
__UpperCamelCase :Dict = metric.compute()
# Use accelerator.print to print only on the main process.
accelerator.print(f"""epoch {epoch}:""" , SCREAMING_SNAKE_CASE )
__UpperCamelCase :str = eval_metric['''accuracy''']
if best_performance < eval_metric["accuracy"]:
__UpperCamelCase :int = eval_metric['''accuracy''']
if args.performance_lower_bound is not None:
assert (
args.performance_lower_bound <= best_performance
), f"""Best performance metric {best_performance} is lower than the lower bound {args.performance_lower_bound}"""
accelerator.wait_for_everyone()
if accelerator.is_main_process:
with open(os.path.join(args.output_dir , '''all_results.json''' ) , '''w''' ) as f:
json.dump(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
def lowerCamelCase ( ):
'''simple docstring'''
__UpperCamelCase :Tuple = argparse.ArgumentParser(description='''Simple example of training script tracking peak GPU memory usage.''' )
parser.add_argument(
'''--model_name_or_path''' , type=SCREAMING_SNAKE_CASE , default='''bert-base-cased''' , help='''Path to pretrained model or model identifier from huggingface.co/models.''' , required=SCREAMING_SNAKE_CASE , )
parser.add_argument(
'''--output_dir''' , type=SCREAMING_SNAKE_CASE , default='''.''' , help='''Optional save directory where all checkpoint folders will be stored. Default is the current working directory.''' , )
parser.add_argument(
'''--performance_lower_bound''' , type=SCREAMING_SNAKE_CASE , default=SCREAMING_SNAKE_CASE , help='''Optional lower bound for the performance metric. If set, the training will throw error when the performance metric drops below this value.''' , )
parser.add_argument(
'''--num_epochs''' , type=SCREAMING_SNAKE_CASE , default=3 , help='''Number of train epochs.''' , )
__UpperCamelCase :List[str] = parser.parse_args()
__UpperCamelCase :Tuple = {'''lr''': 2e-5, '''num_epochs''': args.num_epochs, '''seed''': 42, '''batch_size''': 16}
training_function(SCREAMING_SNAKE_CASE , SCREAMING_SNAKE_CASE )
if __name__ == "__main__":
main()
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