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import numpy as np
from scipy.spatial.distance import cdist
from sklearn.metrics import fa_score
import datasets
a : Tuple = '\\n @inproceedings{kakwani2020indicnlpsuite,\n title={{IndicNLPSuite: Monolingual Corpora, Evaluation Benchmarks and Pre-trained Multilingual Language Models for Indian Languages}},\n author={Divyanshu Kakwani and Anoop Kunchukuttan and Satish Golla and Gokul N.C. and Avik Bhattacharyya and Mitesh M. Khapra and Pratyush Kumar},\n year={2020},\n booktitle={Findings of EMNLP},\n}\n'
a : Dict = '\\n IndicGLUE is a natural language understanding benchmark for Indian languages. It contains a wide\n variety of tasks and covers 11 major Indian languages - as, bn, gu, hi, kn, ml, mr, or, pa, ta, te.\n'
a : Optional[Any] = '\nCompute IndicGLUE evaluation metric associated to each IndicGLUE dataset.\nArgs:\n predictions: list of predictions to score (as int64),\n except for \'cvit-mkb-clsr\' where each prediction is a vector (of float32).\n references: list of ground truth labels corresponding to the predictions (as int64),\n except for \'cvit-mkb-clsr\' where each reference is a vector (of float32).\nReturns: depending on the IndicGLUE subset, one or several of:\n \"accuracy\": Accuracy\n \"f1\": F1 score\n \"precision\": Precision@10\nExamples:\n\n >>> indic_glue_metric = datasets.load_metric(\'indic_glue\', \'wnli\') # \'wnli\' or any of [\"copa\", \"sna\", \"csqa\", \"wstp\", \"inltkh\", \"bbca\", \"iitp-mr\", \"iitp-pr\", \"actsa-sc\", \"md\"]\n >>> references = [0, 1]\n >>> predictions = [0, 1]\n >>> results = indic_glue_metric.compute(predictions=predictions, references=references)\n >>> print(results)\n {\'accuracy\': 1.0}\n\n >>> indic_glue_metric = datasets.load_metric(\'indic_glue\', \'wiki-ner\')\n >>> references = [0, 1]\n >>> predictions = [0, 1]\n >>> results = indic_glue_metric.compute(predictions=predictions, references=references)\n >>> print(results)\n {\'accuracy\': 1.0, \'f1\': 1.0}\n\n >>> indic_glue_metric = datasets.load_metric(\'indic_glue\', \'cvit-mkb-clsr\')\n >>> references = [[0.5, 0.5, 0.5], [0.1, 0.2, 0.3]]\n >>> predictions = [[0.5, 0.5, 0.5], [0.1, 0.2, 0.3]]\n >>> results = indic_glue_metric.compute(predictions=predictions, references=references)\n >>> print(results)\n {\'precision@10\': 1.0}\n\n'
def lowerCAmelCase_ (lowerCAmelCase__: List[str] , lowerCAmelCase__: Optional[int] ):
"""simple docstring"""
return float((preds == labels).mean() )
def lowerCAmelCase_ (lowerCAmelCase__: Union[str, Any] , lowerCAmelCase__: int ):
"""simple docstring"""
UpperCAmelCase_: Any = simple_accuracy(_lowerCAmelCase , _lowerCAmelCase )
UpperCAmelCase_: int = float(fa_score(y_true=_lowerCAmelCase , y_pred=_lowerCAmelCase ) )
return {
"accuracy": acc,
"f1": fa,
}
def lowerCAmelCase_ (lowerCAmelCase__: str , lowerCAmelCase__: Any ):
"""simple docstring"""
UpperCAmelCase_: Dict = np.array(_lowerCAmelCase )
UpperCAmelCase_: Any = np.array(_lowerCAmelCase )
UpperCAmelCase_: Any = en_sentvecs.shape[0]
# mean centering
UpperCAmelCase_: Tuple = en_sentvecs - np.mean(_lowerCAmelCase , axis=0 )
UpperCAmelCase_: Dict = in_sentvecs - np.mean(_lowerCAmelCase , axis=0 )
UpperCAmelCase_: List[str] = cdist(_lowerCAmelCase , _lowerCAmelCase , """cosine""" )
UpperCAmelCase_: List[Any] = np.array(range(_lowerCAmelCase ) )
UpperCAmelCase_: Tuple = sim.argsort(axis=1 )[:, :1_0]
UpperCAmelCase_: List[str] = np.any(preds == actual[:, None] , axis=1 )
return float(matches.mean() )
@datasets.utils.file_utils.add_start_docstrings(_DESCRIPTION , _KWARGS_DESCRIPTION )
class _a ( datasets.Metric ):
def __snake_case (self ) -> Tuple:
if self.config_name not in [
"wnli",
"copa",
"sna",
"csqa",
"wstp",
"inltkh",
"bbca",
"cvit-mkb-clsr",
"iitp-mr",
"iitp-pr",
"actsa-sc",
"md",
"wiki-ner",
]:
raise KeyError(
"""You should supply a configuration name selected in """
"""[\"wnli\", \"copa\", \"sna\", \"csqa\", \"wstp\", \"inltkh\", \"bbca\", """
"""\"cvit-mkb-clsr\", \"iitp-mr\", \"iitp-pr\", \"actsa-sc\", \"md\", """
"""\"wiki-ner\"]""" )
return datasets.MetricInfo(
description=_DESCRIPTION, citation=_CITATION, inputs_description=_KWARGS_DESCRIPTION, features=datasets.Features(
{
"""predictions""": datasets.Value("""int64""" )
if self.config_name != """cvit-mkb-clsr"""
else datasets.Sequence(datasets.Value("""float32""" ) ),
"""references""": datasets.Value("""int64""" )
if self.config_name != """cvit-mkb-clsr"""
else datasets.Sequence(datasets.Value("""float32""" ) ),
} ), codebase_urls=[], reference_urls=[], format="""numpy""" if self.config_name != """cvit-mkb-clsr""" else None, )
def __snake_case (self, SCREAMING_SNAKE_CASE_, SCREAMING_SNAKE_CASE_ ) -> Optional[int]:
if self.config_name == "cvit-mkb-clsr":
return {"precision@10": precision_at_aa(snake_case_, snake_case_ )}
elif self.config_name in ["wiki-ner"]:
return acc_and_fa(snake_case_, snake_case_ )
elif self.config_name in [
"wnli",
"copa",
"sna",
"csqa",
"wstp",
"inltkh",
"bbca",
"iitp-mr",
"iitp-pr",
"actsa-sc",
"md",
]:
return {"accuracy": simple_accuracy(snake_case_, snake_case_ )}
else:
raise KeyError(
"""You should supply a configuration name selected in """
"""[\"wnli\", \"copa\", \"sna\", \"csqa\", \"wstp\", \"inltkh\", \"bbca\", """
"""\"cvit-mkb-clsr\", \"iitp-mr\", \"iitp-pr\", \"actsa-sc\", \"md\", """
"""\"wiki-ner\"]""" )
| 147
|
'''simple docstring'''
from __future__ import annotations
import inspect
import unittest
import numpy as np
from transformers import ResNetConfig
from transformers.testing_utils import require_tf, require_vision, slow
from transformers.utils import cached_property, is_tf_available, is_vision_available
from ...test_configuration_common import ConfigTester
from ...test_modeling_tf_common import TFModelTesterMixin, floats_tensor, ids_tensor
from ...test_pipeline_mixin import PipelineTesterMixin
if is_tf_available():
import tensorflow as tf
from transformers import TFResNetForImageClassification, TFResNetModel
from transformers.models.resnet.modeling_tf_resnet import TF_RESNET_PRETRAINED_MODEL_ARCHIVE_LIST
if is_vision_available():
from PIL import Image
from transformers import AutoImageProcessor
class UpperCAmelCase_ :
"""simple docstring"""
def __init__( self : int , snake_case_ : Tuple , snake_case_ : List[str]=3 , snake_case_ : Tuple=32 , snake_case_ : List[Any]=3 , snake_case_ : List[str]=10 , snake_case_ : List[str]=[10, 20, 30, 40] , snake_case_ : Tuple=[1, 1, 2, 1] , snake_case_ : Tuple=True , snake_case_ : str=True , snake_case_ : int="relu" , snake_case_ : List[Any]=3 , snake_case_ : str=None , ):
snake_case__ : List[Any] = parent
snake_case__ : List[Any] = batch_size
snake_case__ : int = image_size
snake_case__ : List[Any] = num_channels
snake_case__ : Optional[Any] = embeddings_size
snake_case__ : Optional[int] = hidden_sizes
snake_case__ : Tuple = depths
snake_case__ : Any = is_training
snake_case__ : Optional[int] = use_labels
snake_case__ : Optional[int] = hidden_act
snake_case__ : Optional[int] = num_labels
snake_case__ : int = scope
snake_case__ : Tuple = len(snake_case_ )
def lowerCamelCase ( self : Any ):
snake_case__ : Union[str, Any] = floats_tensor([self.batch_size, self.num_channels, self.image_size, self.image_size] )
snake_case__ : Union[str, Any] = None
if self.use_labels:
snake_case__ : Optional[Any] = ids_tensor([self.batch_size] , self.num_labels )
snake_case__ : List[str] = self.get_config()
return config, pixel_values, labels
def lowerCamelCase ( self : int ):
return ResNetConfig(
num_channels=self.num_channels , embeddings_size=self.embeddings_size , hidden_sizes=self.hidden_sizes , depths=self.depths , hidden_act=self.hidden_act , num_labels=self.num_labels , image_size=self.image_size , )
def lowerCamelCase ( self : Tuple , snake_case_ : Tuple , snake_case_ : List[Any] , snake_case_ : Optional[int] ):
snake_case__ : Optional[Any] = TFResNetModel(config=snake_case_ )
snake_case__ : int = model(snake_case_ )
# expected last hidden states: B, C, H // 32, W // 32
self.parent.assertEqual(
result.last_hidden_state.shape , (self.batch_size, self.hidden_sizes[-1], self.image_size // 32, self.image_size // 32) , )
def lowerCamelCase ( self : List[str] , snake_case_ : List[str] , snake_case_ : str , snake_case_ : Union[str, Any] ):
snake_case__ : str = self.num_labels
snake_case__ : Optional[int] = TFResNetForImageClassification(snake_case_ )
snake_case__ : Tuple = model(snake_case_ , labels=snake_case_ )
self.parent.assertEqual(result.logits.shape , (self.batch_size, self.num_labels) )
def lowerCamelCase ( self : Tuple ):
snake_case__ : List[Any] = self.prepare_config_and_inputs()
snake_case__ , snake_case__ , snake_case__ : str = config_and_inputs
snake_case__ : int = {"""pixel_values""": pixel_values}
return config, inputs_dict
@require_tf
class UpperCAmelCase_ ( _a , _a , unittest.TestCase ):
"""simple docstring"""
lowercase = (TFResNetModel, TFResNetForImageClassification) if is_tf_available() else ()
lowercase = (
{"feature-extraction": TFResNetModel, "image-classification": TFResNetForImageClassification}
if is_tf_available()
else {}
)
lowercase = False
lowercase = False
lowercase = False
lowercase = False
lowercase = False
def lowerCamelCase ( self : Optional[int] ):
snake_case__ : Tuple = TFResNetModelTester(self )
snake_case__ : List[str] = ConfigTester(self , config_class=snake_case_ , has_text_modality=snake_case_ )
def lowerCamelCase ( self : Dict ):
self.create_and_test_config_common_properties()
self.config_tester.create_and_test_config_to_json_string()
self.config_tester.create_and_test_config_to_json_file()
self.config_tester.create_and_test_config_from_and_save_pretrained()
self.config_tester.create_and_test_config_with_num_labels()
self.config_tester.check_config_can_be_init_without_params()
self.config_tester.check_config_arguments_init()
def lowerCamelCase ( self : str ):
return
@unittest.skip(reason="""ResNet does not use inputs_embeds""" )
def lowerCamelCase ( self : int ):
pass
@unittest.skip(reason="""ResNet does not support input and output embeddings""" )
def lowerCamelCase ( self : List[Any] ):
pass
def lowerCamelCase ( self : List[Any] ):
snake_case__ , snake_case__ : List[Any] = self.model_tester.prepare_config_and_inputs_for_common()
for model_class in self.all_model_classes:
snake_case__ : Dict = model_class(snake_case_ )
snake_case__ : Optional[Any] = inspect.signature(model.call )
# signature.parameters is an OrderedDict => so arg_names order is deterministic
snake_case__ : Union[str, Any] = [*signature.parameters.keys()]
snake_case__ : Optional[int] = ["""pixel_values"""]
self.assertListEqual(arg_names[:1] , snake_case_ )
def lowerCamelCase ( self : Union[str, Any] ):
snake_case__ : Optional[int] = self.model_tester.prepare_config_and_inputs()
self.model_tester.create_and_check_model(*snake_case_ )
def lowerCamelCase ( self : List[str] ):
def check_hidden_states_output(snake_case_ : Any , snake_case_ : Any , snake_case_ : List[str] ):
snake_case__ : List[Any] = model_class(snake_case_ )
snake_case__ : Dict = model(**self._prepare_for_class(snake_case_ , snake_case_ ) )
snake_case__ : str = outputs.encoder_hidden_states if config.is_encoder_decoder else outputs.hidden_states
snake_case__ : List[Any] = self.model_tester.num_stages
self.assertEqual(len(snake_case_ ) , expected_num_stages + 1 )
# ResNet's feature maps are of shape (batch_size, num_channels, height, width)
self.assertListEqual(
list(hidden_states[0].shape[-2:] ) , [self.model_tester.image_size // 4, self.model_tester.image_size // 4] , )
snake_case__ , snake_case__ : Any = self.model_tester.prepare_config_and_inputs_for_common()
snake_case__ : List[Any] = ["""basic""", """bottleneck"""]
for model_class in self.all_model_classes:
for layer_type in layers_type:
snake_case__ : Dict = layer_type
snake_case__ : Optional[int] = True
check_hidden_states_output(snake_case_ , snake_case_ , snake_case_ )
# check that output_hidden_states also work using config
del inputs_dict["output_hidden_states"]
snake_case__ : List[Any] = True
check_hidden_states_output(snake_case_ , snake_case_ , snake_case_ )
def lowerCamelCase ( self : Optional[Any] ):
snake_case__ : Tuple = self.model_tester.prepare_config_and_inputs()
self.model_tester.create_and_check_for_image_classification(*snake_case_ )
@slow
def lowerCamelCase ( self : Optional[Any] ):
for model_name in TF_RESNET_PRETRAINED_MODEL_ARCHIVE_LIST[:1]:
snake_case__ : str = TFResNetModel.from_pretrained(snake_case_ )
self.assertIsNotNone(snake_case_ )
def __snake_case( ) -> Optional[int]:
snake_case__ : Optional[Any] = Image.open("""./tests/fixtures/tests_samples/COCO/000000039769.png""" )
return image
@require_tf
@require_vision
class UpperCAmelCase_ ( unittest.TestCase ):
"""simple docstring"""
@cached_property
def lowerCamelCase ( self : List[Any] ):
return (
AutoImageProcessor.from_pretrained(TF_RESNET_PRETRAINED_MODEL_ARCHIVE_LIST[0] )
if is_vision_available()
else None
)
@slow
def lowerCamelCase ( self : Optional[int] ):
snake_case__ : List[str] = TFResNetForImageClassification.from_pretrained(TF_RESNET_PRETRAINED_MODEL_ARCHIVE_LIST[0] )
snake_case__ : List[Any] = self.default_image_processor
snake_case__ : List[Any] = prepare_img()
snake_case__ : List[str] = image_processor(images=snake_case_ , return_tensors="""tf""" )
# forward pass
snake_case__ : Optional[Any] = model(**snake_case_ )
# verify the logits
snake_case__ : Union[str, Any] = tf.TensorShape((1, 1_000) )
self.assertEqual(outputs.logits.shape , snake_case_ )
snake_case__ : List[str] = tf.constant([-11.1069, -9.7877, -8.3777] )
self.assertTrue(np.allclose(outputs.logits[0, :3].numpy() , snake_case_ , atol=1E-4 ) )
| 35
| 0
|
import gc
import random
import unittest
import numpy as np
import torch
from transformers import CLIPTextConfig, CLIPTextModel, CLIPTextModelWithProjection, CLIPTokenizer
from diffusers import (
AutoencoderKL,
DiffusionPipeline,
EulerDiscreteScheduler,
StableDiffusionXLImgaImgPipeline,
UNetaDConditionModel,
)
from diffusers.utils import floats_tensor, slow, torch_device
from diffusers.utils.testing_utils import enable_full_determinism, require_torch_gpu
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_ ( _a , _a , unittest.TestCase ):
'''simple docstring'''
a__ = StableDiffusionXLImgaImgPipeline
a__ = TEXT_GUIDED_IMAGE_VARIATION_PARAMS - {"""height""", """width"""}
a__ = PipelineTesterMixin.required_optional_params - {"""latents"""}
a__ = TEXT_GUIDED_IMAGE_VARIATION_BATCH_PARAMS
a__ = IMAGE_TO_IMAGE_IMAGE_PARAMS
a__ = IMAGE_TO_IMAGE_IMAGE_PARAMS
def _lowercase ( self : List[Any] ) -> str:
"""simple docstring"""
torch.manual_seed(0 )
__magic_name__ = 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""") , attention_head_dim=(2, 4) , use_linear_projection=snake_case_ , addition_embed_type="""text_time""" , addition_time_embed_dim=8 , transformer_layers_per_block=(1, 2) , projection_class_embeddings_input_dim=80 , cross_attention_dim=64 , )
__magic_name__ = EulerDiscreteScheduler(
beta_start=0.00085 , beta_end=0.012 , steps_offset=1 , beta_schedule="""scaled_linear""" , timestep_spacing="""leading""" , )
torch.manual_seed(0 )
__magic_name__ = 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 )
__magic_name__ = CLIPTextConfig(
bos_token_id=0 , eos_token_id=2 , hidden_size=32 , intermediate_size=37 , layer_norm_eps=1E-05 , num_attention_heads=4 , num_hidden_layers=5 , pad_token_id=1 , vocab_size=1000 , hidden_act="""gelu""" , projection_dim=32 , )
__magic_name__ = CLIPTextModel(snake_case_ )
__magic_name__ = CLIPTokenizer.from_pretrained("""hf-internal-testing/tiny-random-clip""" , local_files_only=snake_case_ )
__magic_name__ = CLIPTextModelWithProjection(snake_case_ )
__magic_name__ = CLIPTokenizer.from_pretrained("""hf-internal-testing/tiny-random-clip""" , local_files_only=snake_case_ )
__magic_name__ = {
"""unet""": unet,
"""scheduler""": scheduler,
"""vae""": vae,
"""text_encoder""": text_encoder,
"""tokenizer""": tokenizer,
"""text_encoder_2""": text_encoder_a,
"""tokenizer_2""": tokenizer_a,
# "safety_checker": None,
# "feature_extractor": None,
}
return components
def _lowercase ( self : Dict , UpperCamelCase__ : str , UpperCamelCase__ : Tuple=0 ) -> Any:
"""simple docstring"""
__magic_name__ = floats_tensor((1, 3, 32, 32) , rng=random.Random(snake_case_ ) ).to(snake_case_ )
__magic_name__ = image / 2 + 0.5
if str(snake_case_ ).startswith("""mps""" ):
__magic_name__ = torch.manual_seed(snake_case_ )
else:
__magic_name__ = torch.Generator(device=snake_case_ ).manual_seed(snake_case_ )
__magic_name__ = {
"""prompt""": """A painting of a squirrel eating a burger""",
"""image""": image,
"""generator""": generator,
"""num_inference_steps""": 2,
"""guidance_scale""": 5.0,
"""output_type""": """numpy""",
"""strength""": 0.75,
}
return inputs
def _lowercase ( self : Dict ) -> Any:
"""simple docstring"""
__magic_name__ = """cpu""" # ensure determinism for the device-dependent torch.Generator
__magic_name__ = self.get_dummy_components()
__magic_name__ = StableDiffusionXLImgaImgPipeline(**snake_case_ )
__magic_name__ = sd_pipe.to(snake_case_ )
sd_pipe.set_progress_bar_config(disable=snake_case_ )
__magic_name__ = self.get_dummy_inputs(snake_case_ )
__magic_name__ = sd_pipe(**snake_case_ ).images
__magic_name__ = image[0, -3:, -3:, -1]
assert image.shape == (1, 32, 32, 3)
__magic_name__ = np.array([0.4656, 0.4840, 0.4439, 0.6698, 0.5574, 0.4524, 0.5799, 0.5943, 0.5165] )
assert np.abs(image_slice.flatten() - expected_slice ).max() < 1E-2
def _lowercase ( self : Union[str, Any] ) -> Optional[int]:
"""simple docstring"""
super().test_attention_slicing_forward_pass(expected_max_diff=3E-3 )
def _lowercase ( self : Any ) -> str:
"""simple docstring"""
super().test_inference_batch_single_identical(expected_max_diff=3E-3 )
def _lowercase ( self : Any ) -> List[Any]:
"""simple docstring"""
pass
def _lowercase ( self : List[str] ) -> int:
"""simple docstring"""
__magic_name__ = self.get_dummy_components()
__magic_name__ = StableDiffusionXLImgaImgPipeline(**snake_case_ )
__magic_name__ = sd_pipe.to(snake_case_ )
__magic_name__ = sd_pipe.to(snake_case_ )
sd_pipe.set_progress_bar_config(disable=snake_case_ )
# forward without prompt embeds
__magic_name__ = self.get_dummy_inputs(snake_case_ )
__magic_name__ = 3 * ["""this is a negative prompt"""]
__magic_name__ = negative_prompt
__magic_name__ = 3 * [inputs["""prompt"""]]
__magic_name__ = sd_pipe(**snake_case_ )
__magic_name__ = output.images[0, -3:, -3:, -1]
# forward with prompt embeds
__magic_name__ = self.get_dummy_inputs(snake_case_ )
__magic_name__ = 3 * ["""this is a negative prompt"""]
__magic_name__ = 3 * [inputs.pop("""prompt""" )]
(
__magic_name__
) = sd_pipe.encode_prompt(snake_case_ , negative_prompt=snake_case_ )
__magic_name__ = sd_pipe(
**snake_case_ , prompt_embeds=snake_case_ , negative_prompt_embeds=snake_case_ , pooled_prompt_embeds=snake_case_ , negative_pooled_prompt_embeds=snake_case_ , )
__magic_name__ = output.images[0, -3:, -3:, -1]
# make sure that it's equal
assert np.abs(image_slice_a.flatten() - image_slice_a.flatten() ).max() < 1E-4
@slow
@require_torch_gpu
class UpperCAmelCase_ ( unittest.TestCase ):
'''simple docstring'''
def _lowercase ( self : Union[str, Any] ) -> List[Any]:
"""simple docstring"""
super().tearDown()
gc.collect()
torch.cuda.empty_cache()
def _lowercase ( self : Optional[Any] , UpperCamelCase__ : Optional[int] , UpperCamelCase__ : Optional[int]="cpu" , UpperCamelCase__ : Dict=torch.floataa , UpperCamelCase__ : Optional[int]=0 ) -> Optional[int]:
"""simple docstring"""
__magic_name__ = torch.Generator(device=snake_case_ ).manual_seed(snake_case_ )
__magic_name__ = np.random.RandomState(snake_case_ ).standard_normal((1, 4, 64, 64) )
__magic_name__ = torch.from_numpy(snake_case_ ).to(device=snake_case_ , dtype=snake_case_ )
__magic_name__ = {
"""prompt""": """a photograph of an astronaut riding a horse""",
"""latents""": latents,
"""generator""": generator,
"""num_inference_steps""": 3,
"""guidance_scale""": 7.5,
"""output_type""": """numpy""",
}
return inputs
def _lowercase ( self : List[Any] ) -> int:
"""simple docstring"""
__magic_name__ = DiffusionPipeline.from_pretrained("""stabilityai/stable-diffusion-2-base""" )
pipe.to(snake_case_ )
pipe.set_progress_bar_config(disable=snake_case_ )
__magic_name__ = self.get_inputs(snake_case_ )
__magic_name__ = pipe(**snake_case_ ).images
__magic_name__ = image[0, -3:, -3:, -1].flatten()
assert image.shape == (1, 512, 512, 3)
__magic_name__ = np.array([0.49493, 0.47896, 0.40798, 0.54214, 0.53212, 0.48202, 0.47656, 0.46329, 0.48506] )
assert np.abs(image_slice - expected_slice ).max() < 7E-3
| 88
|
'''simple docstring'''
from ...configuration_utils import PretrainedConfig
from ...utils import logging
__a = logging.get_logger(__name__)
__a = {
"vinvino02/glpn-kitti": "https://huggingface.co/vinvino02/glpn-kitti/resolve/main/config.json",
# See all GLPN models at https://huggingface.co/models?filter=glpn
}
class UpperCAmelCase_ ( _a ):
"""simple docstring"""
lowercase = "glpn"
def __init__( self : Optional[Any] , snake_case_ : List[str]=3 , snake_case_ : Dict=4 , snake_case_ : List[Any]=[2, 2, 2, 2] , snake_case_ : int=[8, 4, 2, 1] , snake_case_ : List[str]=[32, 64, 160, 256] , snake_case_ : Tuple=[7, 3, 3, 3] , snake_case_ : List[Any]=[4, 2, 2, 2] , snake_case_ : Tuple=[1, 2, 5, 8] , snake_case_ : List[str]=[4, 4, 4, 4] , snake_case_ : Optional[int]="gelu" , snake_case_ : Dict=0.0 , snake_case_ : Union[str, Any]=0.0 , snake_case_ : List[Any]=0.02 , snake_case_ : Tuple=0.1 , snake_case_ : Any=1E-6 , snake_case_ : Dict=64 , snake_case_ : Tuple=10 , snake_case_ : List[Any]=-1 , **snake_case_ : Optional[Any] , ):
super().__init__(**snake_case_ )
snake_case__ : Optional[Any] = num_channels
snake_case__ : Dict = num_encoder_blocks
snake_case__ : Tuple = depths
snake_case__ : Union[str, Any] = sr_ratios
snake_case__ : Tuple = hidden_sizes
snake_case__ : Optional[Any] = patch_sizes
snake_case__ : int = strides
snake_case__ : List[Any] = mlp_ratios
snake_case__ : Optional[int] = num_attention_heads
snake_case__ : Dict = hidden_act
snake_case__ : int = hidden_dropout_prob
snake_case__ : Optional[Any] = attention_probs_dropout_prob
snake_case__ : str = initializer_range
snake_case__ : List[str] = drop_path_rate
snake_case__ : int = layer_norm_eps
snake_case__ : Tuple = decoder_hidden_size
snake_case__ : List[Any] = max_depth
snake_case__ : Dict = head_in_index
| 35
| 0
|
'''simple docstring'''
import tempfile
import unittest
from pathlib import Path
from shutil import copyfile
from transformers import MaMaaaTokenizer, is_torch_available
from transformers.testing_utils import (
get_tests_dir,
nested_simplify,
require_sentencepiece,
require_tokenizers,
require_torch,
slow,
)
from transformers.utils import is_sentencepiece_available
if is_sentencepiece_available():
from transformers.models.mam_aaa.tokenization_mam_aaa import VOCAB_FILES_NAMES, save_json
from ...test_tokenization_common import TokenizerTesterMixin
if is_sentencepiece_available():
lowercase__ : Optional[Any] = get_tests_dir('''fixtures/test_sentencepiece.model''')
if is_torch_available():
from transformers.models.mam_aaa.modeling_mam_aaa import shift_tokens_right
lowercase__ : List[Any] = 12_80_22
lowercase__ : int = 12_80_28
@require_sentencepiece
class SCREAMING_SNAKE_CASE (_a , unittest.TestCase ):
lowerCAmelCase = MaMaaaTokenizer
lowerCAmelCase = False
lowerCAmelCase = False
lowerCAmelCase = True
def SCREAMING_SNAKE_CASE ( self):
'''simple docstring'''
super().setUp()
__A : List[Any] = ["""</s>""", """<unk>""", """▁This""", """▁is""", """▁a""", """▁t""", """est""", """\u0120""", """<pad>"""]
__A : Dict = dict(zip(snake_case_ , range(len(snake_case_))))
__A : List[Any] = Path(self.tmpdirname)
save_json(snake_case_ , save_dir / VOCAB_FILES_NAMES['vocab_file'])
if not (save_dir / VOCAB_FILES_NAMES["spm_file"]).exists():
copyfile(snake_case_ , save_dir / VOCAB_FILES_NAMES['spm_file'])
__A : int = MaMaaaTokenizer.from_pretrained(self.tmpdirname)
tokenizer.save_pretrained(self.tmpdirname)
def SCREAMING_SNAKE_CASE ( self , **_UpperCAmelCase):
'''simple docstring'''
return MaMaaaTokenizer.from_pretrained(self.tmpdirname , **snake_case_)
def SCREAMING_SNAKE_CASE ( self , _UpperCAmelCase):
'''simple docstring'''
return (
"This is a test",
"This is a test",
)
def SCREAMING_SNAKE_CASE ( self):
'''simple docstring'''
__A : List[Any] = """</s>"""
__A : Any = 0
self.assertEqual(self.get_tokenizer()._convert_token_to_id(snake_case_) , snake_case_)
self.assertEqual(self.get_tokenizer()._convert_id_to_token(snake_case_) , snake_case_)
def SCREAMING_SNAKE_CASE ( self):
'''simple docstring'''
__A : List[str] = self.get_tokenizer()
__A : Optional[Any] = list(tokenizer.get_vocab().keys())
self.assertEqual(vocab_keys[0] , '</s>')
self.assertEqual(vocab_keys[1] , '<unk>')
self.assertEqual(vocab_keys[-1] , '<s>')
self.assertEqual(len(snake_case_) , tokenizer.vocab_size + len(tokenizer.get_added_vocab()))
@unittest.skip('Skip this test while all models are still to be uploaded.')
def SCREAMING_SNAKE_CASE ( self):
'''simple docstring'''
pass
def SCREAMING_SNAKE_CASE ( self):
'''simple docstring'''
__A : Dict = self.get_tokenizer()
__A : List[str] = tokenizer.tokenize('This is a test')
self.assertListEqual(snake_case_ , ['▁This', '▁is', '▁a', '▁t', 'est'])
self.assertListEqual(
tokenizer.convert_tokens_to_ids(snake_case_) , [2, 3, 4, 5, 6] , )
__A : str = tokenizer.convert_ids_to_tokens([2, 3, 4, 5, 6])
self.assertListEqual(snake_case_ , ['▁This', '▁is', '▁a', '▁t', 'est'])
__A : Dict = tokenizer.convert_tokens_to_string(snake_case_)
self.assertEqual(snake_case_ , 'This is a test')
@slow
def SCREAMING_SNAKE_CASE ( self):
'''simple docstring'''
__A : str = {"""input_ids""": [[12_8022, 11_0108, 397, 11, 3_8272, 2247, 12_4811, 285, 1_8105, 1586, 207, 7, 3_9534, 4428, 397, 1019, 1_8105, 1586, 207, 7, 4_1337, 1_6786, 241, 7, 2_0214, 17, 12_5690, 1_0398, 7, 4_4378, 5_8069, 6_8342, 7798, 7343, 11, 299, 3_3310, 4, 158, 3_7350, 9_4077, 4569, 299, 3_3310, 90, 4, 5_2840, 290, 4, 3_1270, 112, 299, 682, 4, 5_2840, 3_9953, 1_4079, 193, 5_2519, 9_0894, 1_7894, 12_0697, 11, 4_0445, 551, 17, 1019, 5_2519, 9_0894, 1_7756, 963, 11, 4_0445, 480, 17, 9792, 1120, 5173, 1393, 6240, 1_6786, 241, 12_0996, 28, 1245, 1393, 11_8240, 1_1123, 1019, 9_3612, 2691, 1_0618, 9_8058, 12_0409, 1928, 279, 4, 4_0683, 367, 178, 207, 1019, 103, 10_3121, 506, 6_5296, 5, 2], [12_8022, 2_1217, 367, 117, 12_5450, 128, 719, 7, 7308, 40, 9_3612, 1_2669, 1116, 1_6704, 71, 1_7785, 3699, 1_5592, 35, 144, 9584, 241, 1_1943, 713, 950, 799, 2247, 8_8427, 150, 149, 11_8813, 12_0706, 1019, 10_6906, 8_1518, 28, 1224, 2_2799, 397, 5, 2, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1], [12_8022, 1658, 12_3311, 5155, 5578, 4722, 279, 1_4947, 2366, 1120, 1197, 14, 1348, 9232, 5, 2, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1]], """attention_mask""": [[1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1], [1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0], [1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0]]} # noqa: E501
# fmt: on
self.tokenizer_integration_test_util(
expected_encoding=snake_case_ , model_name='facebook/m2m100_418M' , revision='c168bae485c864188cf9aa0e4108b0b6934dc91e' , )
@require_torch
@require_sentencepiece
@require_tokenizers
class SCREAMING_SNAKE_CASE (unittest.TestCase ):
lowerCAmelCase = '''facebook/m2m100_418M'''
lowerCAmelCase = [
'''In my opinion, there are two levels of response from the French government.''',
'''NSA Affair Emphasizes Complete Lack of Debate on Intelligence''',
]
lowerCAmelCase = [
'''Selon moi, il y a deux niveaux de réponse de la part du gouvernement français.''',
'''L\'affaire NSA souligne l\'absence totale de débat sur le renseignement''',
]
# fmt: off
lowerCAmelCase = [EN_CODE, 593, 1949, 11_5781, 4, 7_1586, 4234, 6_0633, 12_6233, 432, 12_3808, 1_5592, 1197, 11_7132, 12_0618, 5, 2]
@classmethod
def SCREAMING_SNAKE_CASE ( cls):
'''simple docstring'''
__A : MaMaaaTokenizer = MaMaaaTokenizer.from_pretrained(
cls.checkpoint_name , src_lang='en' , tgt_lang='fr')
__A : int = 1
return cls
def SCREAMING_SNAKE_CASE ( self):
'''simple docstring'''
self.assertEqual(self.tokenizer.get_lang_id('ar') , 12_8006)
self.assertEqual(self.tokenizer.get_lang_id('en') , 12_8022)
self.assertEqual(self.tokenizer.get_lang_id('ro') , 12_8076)
self.assertEqual(self.tokenizer.get_lang_id('mr') , 12_8063)
def SCREAMING_SNAKE_CASE ( self):
'''simple docstring'''
__A : Dict = self.tokenizer.get_vocab()
self.assertEqual(len(snake_case_) , self.tokenizer.vocab_size)
self.assertEqual(vocab['<unk>'] , 3)
self.assertIn(self.tokenizer.get_lang_token('en') , snake_case_)
def SCREAMING_SNAKE_CASE ( self):
'''simple docstring'''
__A : Optional[Any] = """en"""
__A : List[str] = self.tokenizer.batch_encode_plus(self.src_text).input_ids[0]
self.assertListEqual(self.expected_src_tokens , snake_case_)
def SCREAMING_SNAKE_CASE ( self):
'''simple docstring'''
self.assertIn(snake_case_ , self.tokenizer.all_special_ids)
# fmt: off
__A : Optional[int] = [FR_CODE, 5364, 82, 8642, 4, 294, 47, 8, 1_4028, 136, 3286, 9706, 6, 9_0797, 6, 14_4012, 162, 8_8128, 3_0061, 5, 2]
# fmt: on
__A : Optional[Any] = self.tokenizer.decode(snake_case_ , skip_special_tokens=snake_case_)
__A : Tuple = self.tokenizer.decode(generated_ids[1:] , skip_special_tokens=snake_case_)
self.assertEqual(snake_case_ , snake_case_)
self.assertNotIn(self.tokenizer.eos_token , snake_case_)
def SCREAMING_SNAKE_CASE ( self):
'''simple docstring'''
__A : int = tempfile.mkdtemp()
__A : Any = self.tokenizer.lang_token_to_id
self.tokenizer.save_pretrained(snake_case_)
__A : str = MaMaaaTokenizer.from_pretrained(snake_case_)
self.assertDictEqual(new_tok.lang_token_to_id , snake_case_)
@require_torch
def SCREAMING_SNAKE_CASE ( self):
'''simple docstring'''
__A : Optional[Any] = """en"""
__A : Optional[Any] = """fr"""
__A : str = self.tokenizer(self.src_text , text_target=self.tgt_text , padding=snake_case_ , return_tensors='pt')
__A : Optional[Any] = shift_tokens_right(
batch['labels'] , self.tokenizer.pad_token_id , self.tokenizer.eos_token_id)
for k in batch:
__A : Union[str, Any] = batch[k].tolist()
# batch = {k: v.tolist() for k,v in batch.items()}
# fairseq batch: https://gist.github.com/sshleifer/cba08bc2109361a74ac3760a7e30e4f4
# batch.decoder_inputs_ids[0][0] ==
assert batch.input_ids[1][0] == EN_CODE
assert batch.input_ids[1][-1] == 2
assert batch.labels[1][0] == FR_CODE
assert batch.labels[1][-1] == 2
assert batch.decoder_input_ids[1][:2] == [2, FR_CODE]
@require_torch
def SCREAMING_SNAKE_CASE ( self):
'''simple docstring'''
__A : Optional[Any] = """mr"""
self.assertListEqual(self.tokenizer.prefix_tokens , [self.tokenizer.get_lang_id('mr')])
self.assertListEqual(self.tokenizer.suffix_tokens , [self.tokenizer.eos_token_id])
__A : str = """zh"""
self.assertListEqual(self.tokenizer.prefix_tokens , [self.tokenizer.get_lang_id('zh')])
self.assertListEqual(self.tokenizer.suffix_tokens , [self.tokenizer.eos_token_id])
@require_torch
def SCREAMING_SNAKE_CASE ( self):
'''simple docstring'''
__A : Union[str, Any] = """mr"""
self.tokenizer._switch_to_target_mode()
self.assertListEqual(self.tokenizer.prefix_tokens , [self.tokenizer.get_lang_id('mr')])
self.assertListEqual(self.tokenizer.suffix_tokens , [self.tokenizer.eos_token_id])
self.tokenizer._switch_to_input_mode()
self.assertListEqual(self.tokenizer.prefix_tokens , [self.tokenizer.get_lang_id(self.tokenizer.src_lang)])
__A : Union[str, Any] = """zh"""
self.tokenizer._switch_to_target_mode()
self.assertListEqual(self.tokenizer.prefix_tokens , [self.tokenizer.get_lang_id('zh')])
self.assertListEqual(self.tokenizer.suffix_tokens , [self.tokenizer.eos_token_id])
self.tokenizer._switch_to_input_mode()
self.assertListEqual(self.tokenizer.prefix_tokens , [self.tokenizer.get_lang_id(self.tokenizer.src_lang)])
@require_torch
def SCREAMING_SNAKE_CASE ( self):
'''simple docstring'''
__A : List[Any] = self.tokenizer._build_translation_inputs('A test' , return_tensors='pt' , src_lang='en' , tgt_lang='ar')
self.assertEqual(
nested_simplify(snake_case_) , {
# en_XX, A, test, EOS
'input_ids': [[12_8022, 58, 4183, 2]],
'attention_mask': [[1, 1, 1, 1]],
# ar_AR
'forced_bos_token_id': 12_8006,
} , )
| 190
|
'''simple docstring'''
import json
from typing import List, Optional, Tuple
from tokenizers import normalizers
from tokenizers.pre_tokenizers import BertPreTokenizer, PreTokenizer
from ...tokenization_utils_fast import PreTrainedTokenizerFast
from ...utils import logging
from .tokenization_roformer import RoFormerTokenizer
from .tokenization_utils import JiebaPreTokenizer
__a = logging.get_logger(__name__)
__a = {"vocab_file": "vocab.txt", "tokenizer_file": "tokenizer.json"}
__a = {
"vocab_file": {
"junnyu/roformer_chinese_small": "https://huggingface.co/junnyu/roformer_chinese_small/resolve/main/vocab.txt",
"junnyu/roformer_chinese_base": "https://huggingface.co/junnyu/roformer_chinese_base/resolve/main/vocab.txt",
"junnyu/roformer_chinese_char_small": (
"https://huggingface.co/junnyu/roformer_chinese_char_small/resolve/main/vocab.txt"
),
"junnyu/roformer_chinese_char_base": (
"https://huggingface.co/junnyu/roformer_chinese_char_base/resolve/main/vocab.txt"
),
"junnyu/roformer_small_discriminator": (
"https://huggingface.co/junnyu/roformer_small_discriminator/resolve/main/vocab.txt"
),
"junnyu/roformer_small_generator": (
"https://huggingface.co/junnyu/roformer_small_generator/resolve/main/vocab.txt"
),
}
}
__a = {
"junnyu/roformer_chinese_small": 1536,
"junnyu/roformer_chinese_base": 1536,
"junnyu/roformer_chinese_char_small": 512,
"junnyu/roformer_chinese_char_base": 512,
"junnyu/roformer_small_discriminator": 128,
"junnyu/roformer_small_generator": 128,
}
__a = {
"junnyu/roformer_chinese_small": {"do_lower_case": True},
"junnyu/roformer_chinese_base": {"do_lower_case": True},
"junnyu/roformer_chinese_char_small": {"do_lower_case": True},
"junnyu/roformer_chinese_char_base": {"do_lower_case": True},
"junnyu/roformer_small_discriminator": {"do_lower_case": True},
"junnyu/roformer_small_generator": {"do_lower_case": True},
}
class UpperCAmelCase_ ( _a ):
"""simple docstring"""
lowercase = VOCAB_FILES_NAMES
lowercase = PRETRAINED_VOCAB_FILES_MAP
lowercase = PRETRAINED_POSITIONAL_EMBEDDINGS_SIZES
lowercase = PRETRAINED_INIT_CONFIGURATION
lowercase = RoFormerTokenizer
def __init__( self : List[Any] , snake_case_ : List[str]=None , snake_case_ : Dict=None , snake_case_ : Any=True , snake_case_ : str="[UNK]" , snake_case_ : List[str]="[SEP]" , snake_case_ : Optional[Any]="[PAD]" , snake_case_ : Union[str, Any]="[CLS]" , snake_case_ : Union[str, Any]="[MASK]" , snake_case_ : List[Any]=True , snake_case_ : Optional[Any]=None , **snake_case_ : Tuple , ):
super().__init__(
snake_case_ , tokenizer_file=snake_case_ , do_lower_case=snake_case_ , unk_token=snake_case_ , sep_token=snake_case_ , pad_token=snake_case_ , cls_token=snake_case_ , mask_token=snake_case_ , tokenize_chinese_chars=snake_case_ , strip_accents=snake_case_ , **snake_case_ , )
snake_case__ : str = json.loads(self.backend_tokenizer.normalizer.__getstate__() )
if (
pre_tok_state.get("""lowercase""" , snake_case_ ) != do_lower_case
or pre_tok_state.get("""strip_accents""" , snake_case_ ) != strip_accents
):
snake_case__ : str = getattr(snake_case_ , pre_tok_state.pop("""type""" ) )
snake_case__ : Optional[int] = do_lower_case
snake_case__ : Union[str, Any] = strip_accents
snake_case__ : Union[str, Any] = pre_tok_class(**snake_case_ )
snake_case__ : str = do_lower_case
def __getstate__( self : int ):
snake_case__ : List[Any] = self.__dict__.copy()
snake_case__ : str = BertPreTokenizer()
return state
def __setstate__( self : Dict , snake_case_ : Dict ):
snake_case__ : List[Any] = d
snake_case__ : Union[str, Any] = self.__dict__["""_tokenizer"""].get_vocab()
snake_case__ : List[Any] = PreTokenizer.custom(JiebaPreTokenizer(snake_case_ ) )
def lowerCamelCase ( self : str , snake_case_ : Optional[Any] , snake_case_ : List[str]=None ):
snake_case__ : str = [self.cls_token_id] + token_ids_a + [self.sep_token_id]
if token_ids_a:
output += token_ids_a + [self.sep_token_id]
return output
def lowerCamelCase ( self : str , snake_case_ : List[int] , snake_case_ : Optional[List[int]] = None ):
snake_case__ : int = [self.sep_token_id]
snake_case__ : str = [self.cls_token_id]
if token_ids_a is None:
return len(cls + token_ids_a + sep ) * [0]
return len(cls + token_ids_a + sep ) * [0] + len(token_ids_a + sep ) * [1]
def lowerCamelCase ( self : Dict , snake_case_ : str , snake_case_ : Optional[str] = None ):
snake_case__ : Union[str, Any] = self._tokenizer.model.save(snake_case_ , name=snake_case_ )
return tuple(snake_case_ )
def lowerCamelCase ( self : Dict , snake_case_ : List[str] , snake_case_ : Tuple=None , snake_case_ : List[str]=None , snake_case_ : Union[str, Any]=False , **snake_case_ : Tuple , ):
snake_case__ : Optional[Any] = BertPreTokenizer()
return super().save_pretrained(snake_case_ , snake_case_ , snake_case_ , snake_case_ , **snake_case_ )
| 35
| 0
|
import asyncio
import os
import shutil
import subprocess
import sys
import tempfile
import unittest
from distutils.util import strtobool
from functools import partial
from pathlib import Path
from typing import List, Union
from unittest import mock
import torch
from ..state import AcceleratorState, PartialState
from ..utils import (
gather,
is_bnb_available,
is_comet_ml_available,
is_datasets_available,
is_deepspeed_available,
is_mps_available,
is_safetensors_available,
is_tensorboard_available,
is_torch_version,
is_tpu_available,
is_transformers_available,
is_wandb_available,
is_xpu_available,
)
def snake_case_ ( snake_case , snake_case=False ) -> List[str]:
try:
lowercase__: Optional[int] = os.environ[key]
except KeyError:
# KEY isn't set, default to `default`.
lowercase__: Dict = default
else:
# KEY is set, convert it to True or False.
try:
lowercase__: List[str] = strtobool(_lowerCAmelCase )
except ValueError:
# More values are supported, but let's keep the message simple.
raise ValueError(f'If set, {key} must be yes or no.' )
return _value
__lowerCAmelCase = parse_flag_from_env('''RUN_SLOW''', default=False)
def snake_case_ ( snake_case ) -> List[Any]:
return unittest.skip('Test was skipped' )(_lowerCAmelCase )
def snake_case_ ( snake_case ) -> Union[str, Any]:
return unittest.skipUnless(_run_slow_tests , 'test is slow' )(_lowerCAmelCase )
def snake_case_ ( snake_case ) -> List[str]:
return unittest.skipUnless(not torch.cuda.is_available() , 'test requires only a CPU' )(_lowerCAmelCase )
def snake_case_ ( snake_case ) -> Any:
return unittest.skipUnless(torch.cuda.is_available() , 'test requires a GPU' )(_lowerCAmelCase )
def snake_case_ ( snake_case ) -> int:
return unittest.skipUnless(is_xpu_available() , 'test requires a XPU' )(_lowerCAmelCase )
def snake_case_ ( snake_case ) -> Union[str, Any]:
return unittest.skipUnless(is_mps_available() , 'test requires a `mps` backend support in `torch`' )(_lowerCAmelCase )
def snake_case_ ( snake_case ) -> List[str]:
return unittest.skipUnless(
is_transformers_available() and is_datasets_available() , 'test requires the Hugging Face suite' )(_lowerCAmelCase )
def snake_case_ ( snake_case ) -> List[Any]:
return unittest.skipUnless(is_bnb_available() , 'test requires the bitsandbytes library' )(_lowerCAmelCase )
def snake_case_ ( snake_case ) -> Any:
return unittest.skipUnless(is_tpu_available() , 'test requires TPU' )(_lowerCAmelCase )
def snake_case_ ( snake_case ) -> Union[str, Any]:
return unittest.skipUnless(torch.cuda.device_count() == 1 , 'test requires a GPU' )(_lowerCAmelCase )
def snake_case_ ( snake_case ) -> List[str]:
return unittest.skipUnless(torch.xpu.device_count() == 1 , 'test requires a XPU' )(_lowerCAmelCase )
def snake_case_ ( snake_case ) -> Dict:
return unittest.skipUnless(torch.cuda.device_count() > 1 , 'test requires multiple GPUs' )(_lowerCAmelCase )
def snake_case_ ( snake_case ) -> List[str]:
return unittest.skipUnless(torch.xpu.device_count() > 1 , 'test requires multiple XPUs' )(_lowerCAmelCase )
def snake_case_ ( snake_case ) -> List[Any]:
return unittest.skipUnless(is_safetensors_available() , 'test requires safetensors' )(_lowerCAmelCase )
def snake_case_ ( snake_case ) -> Union[str, Any]:
return unittest.skipUnless(is_deepspeed_available() , 'test requires DeepSpeed' )(_lowerCAmelCase )
def snake_case_ ( snake_case ) -> Optional[int]:
return unittest.skipUnless(is_torch_version('>=' , '1.12.0' ) , 'test requires torch version >= 1.12.0' )(_lowerCAmelCase )
def snake_case_ ( snake_case=None , snake_case=None ) -> Any:
if test_case is None:
return partial(_lowerCAmelCase , version=_lowerCAmelCase )
return unittest.skipUnless(is_torch_version('>=' , _lowerCAmelCase ) , f'test requires torch version >= {version}' )(_lowerCAmelCase )
def snake_case_ ( snake_case ) -> int:
return unittest.skipUnless(is_tensorboard_available() , 'test requires Tensorboard' )(_lowerCAmelCase )
def snake_case_ ( snake_case ) -> Any:
return unittest.skipUnless(is_wandb_available() , 'test requires wandb' )(_lowerCAmelCase )
def snake_case_ ( snake_case ) -> Optional[Any]:
return unittest.skipUnless(is_comet_ml_available() , 'test requires comet_ml' )(_lowerCAmelCase )
__lowerCAmelCase = (
any([is_wandb_available(), is_tensorboard_available()]) and not is_comet_ml_available()
)
def snake_case_ ( snake_case ) -> int:
return unittest.skipUnless(
_atleast_one_tracker_available , 'test requires at least one tracker to be available and for `comet_ml` to not be installed' , )(_lowerCAmelCase )
class __a ( unittest.TestCase ):
__lowercase : List[Any] = True
@classmethod
def SCREAMING_SNAKE_CASE__ ( cls ) -> Optional[Any]:
'''simple docstring'''
lowercase__: Union[str, Any] = tempfile.mkdtemp()
@classmethod
def SCREAMING_SNAKE_CASE__ ( cls ) -> Optional[int]:
'''simple docstring'''
if os.path.exists(cls.tmpdir ):
shutil.rmtree(cls.tmpdir )
def SCREAMING_SNAKE_CASE__ ( self ) -> int:
'''simple docstring'''
if self.clear_on_setup:
for path in Path(self.tmpdir ).glob('**/*' ):
if path.is_file():
path.unlink()
elif path.is_dir():
shutil.rmtree(snake_case_ )
class __a ( unittest.TestCase ):
def SCREAMING_SNAKE_CASE__ ( self ) -> Tuple:
'''simple docstring'''
super().tearDown()
# Reset the state of the AcceleratorState singleton.
AcceleratorState._reset_state()
PartialState._reset_state()
class __a ( unittest.TestCase ):
def SCREAMING_SNAKE_CASE__ ( self , lowerCAmelCase__ ) -> str:
'''simple docstring'''
lowercase__: Dict = mocks if isinstance(snake_case_ , (tuple, list) ) else [mocks]
for m in self.mocks:
m.start()
self.addCleanup(m.stop )
def snake_case_ ( snake_case ) -> int:
lowercase__: Union[str, Any] = AcceleratorState()
lowercase__: int = tensor[None].clone().to(state.device )
lowercase__: Optional[Any] = gather(_lowerCAmelCase ).cpu()
lowercase__: str = tensor[0].cpu()
for i in range(tensors.shape[0] ):
if not torch.equal(tensors[i] , _lowerCAmelCase ):
return False
return True
class __a :
def __init__( self , lowerCAmelCase__ , lowerCAmelCase__ , lowerCAmelCase__ ) -> int:
'''simple docstring'''
lowercase__: List[Any] = returncode
lowercase__: List[Any] = stdout
lowercase__: List[Any] = stderr
async def snake_case_ ( snake_case , snake_case ) -> Optional[int]:
while True:
lowercase__: Optional[int] = await stream.readline()
if line:
callback(_lowerCAmelCase )
else:
break
async def snake_case_ ( snake_case , snake_case=None , snake_case=None , snake_case=None , snake_case=False , snake_case=False ) -> _RunOutput:
if echo:
print('\nRunning: ' , ' '.join(_lowerCAmelCase ) )
lowercase__: Any = await asyncio.create_subprocess_exec(
cmd[0] , *cmd[1:] , stdin=_lowerCAmelCase , stdout=asyncio.subprocess.PIPE , stderr=asyncio.subprocess.PIPE , env=_lowerCAmelCase , )
# note: there is a warning for a possible deadlock when using `wait` with huge amounts of data in the pipe
# https://docs.python.org/3/library/asyncio-subprocess.html#asyncio.asyncio.subprocess.Process.wait
#
# If it starts hanging, will need to switch to the following code. The problem is that no data
# will be seen until it's done and if it hangs for example there will be no debug info.
# out, err = await p.communicate()
# return _RunOutput(p.returncode, out, err)
lowercase__: List[Any] = []
lowercase__: Any = []
def tee(snake_case , snake_case , snake_case , snake_case="" ):
lowercase__: str = line.decode('utf-8' ).rstrip()
sink.append(_lowerCAmelCase )
if not quiet:
print(_lowerCAmelCase , _lowerCAmelCase , file=_lowerCAmelCase )
# XXX: the timeout doesn't seem to make any difference here
await asyncio.wait(
[
asyncio.create_task(_read_stream(p.stdout , lambda snake_case : tee(_lowerCAmelCase , _lowerCAmelCase , sys.stdout , label='stdout:' ) ) ),
asyncio.create_task(_read_stream(p.stderr , lambda snake_case : tee(_lowerCAmelCase , _lowerCAmelCase , sys.stderr , label='stderr:' ) ) ),
] , timeout=_lowerCAmelCase , )
return _RunOutput(await p.wait() , _lowerCAmelCase , _lowerCAmelCase )
def snake_case_ ( snake_case , snake_case=None , snake_case=None , snake_case=1_80 , snake_case=False , snake_case=True ) -> _RunOutput:
lowercase__: Optional[Any] = asyncio.get_event_loop()
lowercase__: List[Any] = loop.run_until_complete(
_stream_subprocess(_lowerCAmelCase , env=_lowerCAmelCase , stdin=_lowerCAmelCase , timeout=_lowerCAmelCase , quiet=_lowerCAmelCase , echo=_lowerCAmelCase ) )
lowercase__: List[Any] = """ """.join(_lowerCAmelCase )
if result.returncode > 0:
lowercase__: List[str] = """\n""".join(result.stderr )
raise RuntimeError(
f'\'{cmd_str}\' failed with returncode {result.returncode}\n\n'
f'The combined stderr from workers follows:\n{stderr}' )
return result
class __a ( _a ):
pass
def snake_case_ ( snake_case , snake_case=False ) -> List[Any]:
try:
lowercase__: List[Any] = subprocess.check_output(_lowerCAmelCase , stderr=subprocess.STDOUT )
if return_stdout:
if hasattr(_lowerCAmelCase , 'decode' ):
lowercase__: str = output.decode('utf-8' )
return output
except subprocess.CalledProcessError as e:
raise SubprocessCallException(
f'Command `{" ".join(_lowerCAmelCase )}` failed with the following error:\n\n{e.output.decode()}' ) from e
| 196
|
'''simple docstring'''
import os
import time
import pytest
from datasets.utils.filelock import FileLock, Timeout
def __snake_case( _lowerCAmelCase ) -> Optional[int]:
snake_case__ : int = FileLock(str(tmpdir / """foo.lock""" ) )
snake_case__ : Dict = FileLock(str(tmpdir / """foo.lock""" ) )
snake_case__ : List[str] = 0.01
with locka.acquire():
with pytest.raises(_lowerCAmelCase ):
snake_case__ : str = time.time()
locka.acquire(_lowerCAmelCase )
assert time.time() - _start > timeout
def __snake_case( _lowerCAmelCase ) -> Tuple:
snake_case__ : Dict = """a""" * 1_000 + """.lock"""
snake_case__ : int = FileLock(str(tmpdir / filename ) )
assert locka._lock_file.endswith(""".lock""" )
assert not locka._lock_file.endswith(_lowerCAmelCase )
assert len(os.path.basename(locka._lock_file ) ) <= 255
snake_case__ : Dict = FileLock(tmpdir / filename )
with locka.acquire():
with pytest.raises(_lowerCAmelCase ):
locka.acquire(0 )
| 35
| 0
|
from typing import TYPE_CHECKING
from ...utils import OptionalDependencyNotAvailable, _LazyModule, is_tokenizers_available, is_torch_available
A : Any = {
"configuration_nezha": ["NEZHA_PRETRAINED_CONFIG_ARCHIVE_MAP", "NezhaConfig"],
}
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
A : Optional[Any] = [
"NEZHA_PRETRAINED_MODEL_ARCHIVE_LIST",
"NezhaForNextSentencePrediction",
"NezhaForMaskedLM",
"NezhaForPreTraining",
"NezhaForMultipleChoice",
"NezhaForQuestionAnswering",
"NezhaForSequenceClassification",
"NezhaForTokenClassification",
"NezhaModel",
"NezhaPreTrainedModel",
]
if TYPE_CHECKING:
from .configuration_nezha import NEZHA_PRETRAINED_CONFIG_ARCHIVE_MAP, NezhaConfig
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_nezha import (
NEZHA_PRETRAINED_MODEL_ARCHIVE_LIST,
NezhaForMaskedLM,
NezhaForMultipleChoice,
NezhaForNextSentencePrediction,
NezhaForPreTraining,
NezhaForQuestionAnswering,
NezhaForSequenceClassification,
NezhaForTokenClassification,
NezhaModel,
NezhaPreTrainedModel,
)
else:
import sys
A : Optional[Any] = _LazyModule(__name__, globals()["__file__"], _import_structure, module_spec=__spec__)
| 184
|
'''simple docstring'''
def __snake_case( _lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase ) -> float:
snake_case__ : str = (num_of_terms / 2) * (2 * first_term + (num_of_terms - 1) * common_diff)
# formula for sum of series
return total
def __snake_case( ) -> List[str]:
print(sum_of_series(1 , 1 , 10 ) )
if __name__ == "__main__":
import doctest
doctest.testmod()
| 35
| 0
|
'''simple docstring'''
import unittest
from transformers import is_torch_available
from transformers.testing_utils import require_torch
if is_torch_available():
import torch
from transformers.activations import gelu_new, gelu_python, get_activation
@require_torch
class __A ( unittest.TestCase ):
'''simple docstring'''
def a__ (self ) -> str:
"""simple docstring"""
_a = torch.tensor([-100, -1, -0.1, 0, 0.1, 1.0, 100] )
_a = get_activation('''gelu''' )
self.assertTrue(torch.allclose(gelu_python(snake_case_ ) , torch_builtin(snake_case_ ) ) )
self.assertFalse(torch.allclose(gelu_python(snake_case_ ) , gelu_new(snake_case_ ) ) )
def a__ (self ) -> Union[str, Any]:
"""simple docstring"""
_a = torch.tensor([-100, -1, -0.1, 0, 0.1, 1.0, 100] )
_a = get_activation('''gelu''' )
_a = get_activation('''gelu_10''' )
_a = torch_builtin(snake_case_ )
_a = geluaa(snake_case_ )
_a = torch.where(y_gelu_aa < 10.0 , 1 , 0 )
self.assertTrue(torch.max(snake_case_ ).item() == 10.0 )
self.assertTrue(torch.allclose(y_gelu * clipped_mask , y_gelu_aa * clipped_mask ) )
def a__ (self ) -> Optional[Any]:
"""simple docstring"""
get_activation('''gelu''' )
get_activation('''gelu_10''' )
get_activation('''gelu_fast''' )
get_activation('''gelu_new''' )
get_activation('''gelu_python''' )
get_activation('''gelu_pytorch_tanh''' )
get_activation('''linear''' )
get_activation('''mish''' )
get_activation('''quick_gelu''' )
get_activation('''relu''' )
get_activation('''sigmoid''' )
get_activation('''silu''' )
get_activation('''swish''' )
get_activation('''tanh''' )
with self.assertRaises(snake_case_ ):
get_activation('''bogus''' )
with self.assertRaises(snake_case_ ):
get_activation(snake_case_ )
def a__ (self ) -> List[str]:
"""simple docstring"""
_a = get_activation('''gelu''' )
_a = 1
_a = get_activation('''gelu''' )
self.assertEqual(acta.a , 1 )
with self.assertRaises(snake_case_ ):
_a = acta.a
| 211
|
'''simple docstring'''
__a = frozenset(
[
"prompt",
"height",
"width",
"guidance_scale",
"negative_prompt",
"prompt_embeds",
"negative_prompt_embeds",
"cross_attention_kwargs",
]
)
__a = frozenset(["prompt", "negative_prompt"])
__a = frozenset([])
__a = frozenset(["image"])
__a = frozenset(
[
"image",
"height",
"width",
"guidance_scale",
]
)
__a = frozenset(["image"])
__a = frozenset(
[
"prompt",
"image",
"height",
"width",
"guidance_scale",
"negative_prompt",
"prompt_embeds",
"negative_prompt_embeds",
]
)
__a = frozenset(["prompt", "image", "negative_prompt"])
__a = frozenset(
[
# Text guided image variation with an image mask
"prompt",
"image",
"mask_image",
"height",
"width",
"guidance_scale",
"negative_prompt",
"prompt_embeds",
"negative_prompt_embeds",
]
)
__a = frozenset(["prompt", "image", "mask_image", "negative_prompt"])
__a = frozenset(
[
# image variation with an image mask
"image",
"mask_image",
"height",
"width",
"guidance_scale",
]
)
__a = frozenset(["image", "mask_image"])
__a = frozenset(
[
"example_image",
"image",
"mask_image",
"height",
"width",
"guidance_scale",
]
)
__a = frozenset(["example_image", "image", "mask_image"])
__a = frozenset(["class_labels"])
__a = frozenset(["class_labels"])
__a = frozenset(["batch_size"])
__a = frozenset([])
__a = frozenset(["batch_size"])
__a = frozenset([])
__a = frozenset(
[
"prompt",
"audio_length_in_s",
"guidance_scale",
"negative_prompt",
"prompt_embeds",
"negative_prompt_embeds",
"cross_attention_kwargs",
]
)
__a = frozenset(["prompt", "negative_prompt"])
__a = frozenset(["input_tokens"])
__a = frozenset(["input_tokens"])
| 35
| 0
|
from __future__ import annotations
import os
import tempfile
import unittest
import numpy as np
from huggingface_hub import hf_hub_download
from transformers import is_tensorflow_text_available, is_tf_available
from transformers.testing_utils import require_tensorflow_text, require_tf, slow
from ..test_modeling_tf_common import floats_tensor
from .test_framework_agnostic import GenerationIntegrationTestsMixin
if is_tf_available():
import tensorflow as tf
from transformers import (
AutoTokenizer,
TFAutoModelForCausalLM,
TFAutoModelForSeqaSeqLM,
TFAutoModelForSpeechSeqaSeq,
TFAutoModelForVisionaSeq,
TFBartForConditionalGeneration,
TFLogitsProcessorList,
TFMinLengthLogitsProcessor,
tf_top_k_top_p_filtering,
)
if is_tensorflow_text_available():
import tensorflow_text as text
@require_tf
class __lowerCAmelCase ( unittest.TestCase ):
def A__ ( self ) -> str:
'''simple docstring'''
_lowercase =tf.convert_to_tensor(
[
[
8.2220991, # 3rd highest value; idx. 0
-0.5620044,
5.23229752,
4.0386393,
-6.8798378,
-0.54785802,
-3.2012153,
2.92777176,
1.88171953,
7.35341276, # 5th highest value; idx. 9
8.43207833, # 2nd highest value; idx. 10
-9.85711836,
-5.96209236,
-1.13039161,
-7.1115294,
-0.8369633,
-5.3186408,
7.06427407,
0.81369344,
-0.82023817,
-5.9179796,
0.58813443,
-6.99778438,
4.71551189,
-0.18771637,
7.44020759, # 4th highest value; idx. 25
9.38450987, # 1st highest value; idx. 26
2.12662941,
-9.32562038,
2.35652522,
], # cummulative prob of 5 highest values <= 0.6
[
0.58425518,
4.53139238,
-5.57510464,
-6.28030699,
-7.19529503,
-4.02122551,
1.39337037,
-6.06707057,
1.59480517,
-9.643119,
0.03907799,
0.67231762,
-8.88206726,
6.27115922, # 4th highest value; idx. 13
2.28520723,
4.82767506,
4.30421368,
8.8275313, # 2nd highest value; idx. 17
5.44029958, # 5th highest value; idx. 18
-4.4735794,
7.38579536, # 3rd highest value; idx. 20
-2.91051663,
2.61946077,
-2.5674762,
-9.48959302,
-4.02922645,
-1.35416918,
9.67702323, # 1st highest value; idx. 27
-5.89478553,
1.85370467,
], # cummulative prob of 5 highest values <= 0.6
] , dtype=tf.floataa , )
_lowercase =tf.convert_to_tensor(
[[0, 0], [0, 9], [0, 10], [0, 25], [0, 26], [1, 13], [1, 17], [1, 18], [1, 20], [1, 27]] , dtype=tf.intaa , ) # expected non filtered idx as noted above
_lowercase =tf.convert_to_tensor(
[8.222099, 7.3534126, 8.432078, 7.4402075, 9.38451, 6.271159, 8.827531, 5.4402995, 7.3857956, 9.677023] , dtype=tf.floataa , ) # expected non filtered values as noted above
_lowercase =tf_top_k_top_p_filtering(snake_case_ , top_k=10 , top_p=0.6 , min_tokens_to_keep=4 )
_lowercase =output[output != -float('inf' )]
_lowercase =tf.cast(
tf.where(tf.not_equal(snake_case_ , tf.constant(-float('inf' ) , dtype=tf.floataa ) ) ) , dtype=tf.intaa , )
tf.debugging.assert_near(snake_case_ , snake_case_ , rtol=1e-12 )
tf.debugging.assert_equal(snake_case_ , snake_case_ )
@require_tf
class __lowerCAmelCase ( unittest.TestCase , _a ):
if is_tf_available():
_a = {
"""AutoModelForCausalLM""": TFAutoModelForCausalLM,
"""AutoModelForSpeechSeq2Seq""": TFAutoModelForSpeechSeqaSeq,
"""AutoModelForSeq2SeqLM""": TFAutoModelForSeqaSeqLM,
"""AutoModelForVision2Seq""": TFAutoModelForVisionaSeq,
"""LogitsProcessorList""": TFLogitsProcessorList,
"""MinLengthLogitsProcessor""": TFMinLengthLogitsProcessor,
"""create_tensor_fn""": tf.convert_to_tensor,
"""floats_tensor""": floats_tensor,
"""return_tensors""": """tf""",
}
@slow
def A__ ( self ) -> Dict:
'''simple docstring'''
_lowercase =TFAutoModelForCausalLM.from_pretrained('hf-internal-testing/tiny-random-gpt2' )
_lowercase =2
_lowercase =2
class __lowerCAmelCase ( tf.Module ):
def __init__( self , lowerCAmelCase ) -> int:
'''simple docstring'''
super(snake_case_ , self ).__init__()
_lowercase =model
@tf.function(
input_signature=(
tf.TensorSpec((None, input_length) , tf.intaa , name='input_ids' ),
tf.TensorSpec((None, input_length) , tf.intaa , name='attention_mask' ),
) , jit_compile=snake_case_ , )
def A__ ( self , lowerCAmelCase , lowerCAmelCase ) -> Any:
'''simple docstring'''
_lowercase =self.model.generate(
input_ids=snake_case_ , attention_mask=snake_case_ , max_new_tokens=snake_case_ , return_dict_in_generate=snake_case_ , )
return {"sequences": outputs["sequences"]}
_lowercase =[[2, 0], [102, 103]]
_lowercase =[[1, 0], [1, 1]]
_lowercase =DummyModel(model=snake_case_ )
with tempfile.TemporaryDirectory() as tmp_dir:
tf.saved_model.save(snake_case_ , snake_case_ , signatures={'serving_default': dummy_model.serving} )
_lowercase =tf.saved_model.load(snake_case_ ).signatures["""serving_default"""]
for batch_size in range(1 , len(snake_case_ ) + 1 ):
_lowercase ={
"""input_ids""": tf.constant(dummy_input_ids[:batch_size] ),
"""attention_mask""": tf.constant(dummy_attention_masks[:batch_size] ),
}
_lowercase =serving_func(**snake_case_ )["""sequences"""]
_lowercase =test_model.generate(**snake_case_ , max_new_tokens=snake_case_ )
tf.debugging.assert_equal(snake_case_ , snake_case_ )
@slow
def A__ ( self ) -> Dict:
'''simple docstring'''
_lowercase =TFAutoModelForCausalLM.from_pretrained('hf-internal-testing/tiny-random-gpt2' )
_lowercase =1
_lowercase =2
class __lowerCAmelCase ( tf.Module ):
def __init__( self , lowerCAmelCase ) -> Dict:
'''simple docstring'''
super(snake_case_ , self ).__init__()
_lowercase =model
@tf.function(
input_signature=(
tf.TensorSpec((batch_size, None) , tf.intaa , name='input_ids' ),
tf.TensorSpec((batch_size, None) , tf.intaa , name='attention_mask' ),
) , jit_compile=snake_case_ , )
def A__ ( self , lowerCAmelCase , lowerCAmelCase ) -> List[Any]:
'''simple docstring'''
_lowercase =self.model.generate(
input_ids=snake_case_ , attention_mask=snake_case_ , max_new_tokens=snake_case_ , return_dict_in_generate=snake_case_ , )
return {"sequences": outputs["sequences"]}
_lowercase =[[2], [102, 103]]
_lowercase =[[1], [1, 1]]
_lowercase =DummyModel(model=snake_case_ )
with tempfile.TemporaryDirectory() as tmp_dir:
tf.saved_model.save(snake_case_ , snake_case_ , signatures={'serving_default': dummy_model.serving} )
_lowercase =tf.saved_model.load(snake_case_ ).signatures["""serving_default"""]
for input_row in range(len(snake_case_ ) ):
_lowercase ={
"""input_ids""": tf.constant([dummy_input_ids[input_row]] ),
"""attention_mask""": tf.constant([dummy_attention_masks[input_row]] ),
}
_lowercase =serving_func(**snake_case_ )["""sequences"""]
_lowercase =test_model.generate(**snake_case_ , max_new_tokens=snake_case_ )
tf.debugging.assert_equal(snake_case_ , snake_case_ )
@slow
@require_tensorflow_text
def A__ ( self ) -> List[Any]:
'''simple docstring'''
with tempfile.TemporaryDirectory() as tmp_dir:
# file needed to load the TF tokenizer
hf_hub_download(repo_id='google/flan-t5-small' , filename='spiece.model' , local_dir=snake_case_ )
class __lowerCAmelCase ( tf.keras.layers.Layer ):
def __init__( self ) -> Any:
'''simple docstring'''
super().__init__()
_lowercase =text.SentencepieceTokenizer(
model=tf.io.gfile.GFile(os.path.join(snake_case_ , 'spiece.model' ) , 'rb' ).read() )
_lowercase =TFAutoModelForSeqaSeqLM.from_pretrained('hf-internal-testing/tiny-random-t5' )
def A__ ( self , lowerCAmelCase , *lowerCAmelCase , **lowerCAmelCase ) -> Union[str, Any]:
'''simple docstring'''
_lowercase =self.tokenizer.tokenize(snake_case_ )
_lowercase =text.pad_model_inputs(
snake_case_ , max_seq_length=64 , pad_value=self.model.config.pad_token_id )
_lowercase =self.model.generate(input_ids=snake_case_ , attention_mask=snake_case_ )
return self.tokenizer.detokenize(snake_case_ )
_lowercase =CompleteSentenceTransformer()
_lowercase =tf.keras.layers.Input(shape=(1,) , dtype=tf.string , name='inputs' )
_lowercase =complete_model(snake_case_ )
_lowercase =tf.keras.Model(snake_case_ , snake_case_ )
keras_model.save(snake_case_ )
def A__ ( self ) -> Optional[Any]:
'''simple docstring'''
_lowercase ={
"""do_sample""": True,
"""num_beams""": 1,
"""top_p""": 0.7,
"""top_k""": 10,
"""temperature""": 0.7,
}
_lowercase =14
_lowercase =AutoTokenizer.from_pretrained('hf-internal-testing/tiny-random-gpt2' )
_lowercase ="""Hello, my dog is cute and"""
_lowercase =tokenizer(snake_case_ , return_tensors='tf' )
_lowercase =TFAutoModelForCausalLM.from_pretrained('hf-internal-testing/tiny-random-gpt2' )
_lowercase =638
# forces the generation to happen on CPU, to avoid GPU-related quirks
with tf.device(':/CPU:0' ):
tf.random.set_seed(0 )
_lowercase =model.generate(**snake_case_ , eos_token_id=snake_case_ , **snake_case_ )
self.assertTrue(expectation == len(generated_tokens[0] ) )
_lowercase =[638, 198]
with tf.device(':/CPU:0' ):
tf.random.set_seed(0 )
_lowercase =model.generate(**snake_case_ , eos_token_id=snake_case_ , **snake_case_ )
self.assertTrue(expectation == len(generated_tokens[0] ) )
def A__ ( self ) -> Optional[int]:
'''simple docstring'''
_lowercase =AutoTokenizer.from_pretrained('hf-internal-testing/tiny-random-bart' )
_lowercase ="""Hugging Face is a technology company based in New York and Paris."""
_lowercase =bart_tokenizer(snake_case_ , return_tensors='tf' ).input_ids
_lowercase =TFBartForConditionalGeneration.from_pretrained('hf-internal-testing/tiny-random-bart' )
_lowercase =bart_model.generate(snake_case_ ).numpy()
class __lowerCAmelCase ( _a ):
def A__ ( self , lowerCAmelCase , lowerCAmelCase=None , **lowerCAmelCase ) -> Optional[Any]:
'''simple docstring'''
return super().call(snake_case_ , **snake_case_ )
_lowercase =FakeBart.from_pretrained('hf-internal-testing/tiny-random-bart' )
_lowercase =bart_model.generate(snake_case_ , foo='bar' ).numpy()
self.assertTrue(np.array_equal(snake_case_ , snake_case_ ) )
class __lowerCAmelCase ( bart_model.model.encoder.__class__ ):
def A__ ( self , lowerCAmelCase , **lowerCAmelCase ) -> int:
'''simple docstring'''
return super().call(snake_case_ , **snake_case_ )
_lowercase =FakeEncoder(bart_model.config , bart_model.model.shared )
_lowercase =fake_encoder
# Normal generation still works (the output will be different because the encoder weights are different)
_lowercase =bart_model.generate(snake_case_ ).numpy()
with self.assertRaises(snake_case_ ):
# FakeEncoder.call() accepts **kwargs -> no filtering -> value error due to unexpected input "foo"
bart_model.generate(snake_case_ , foo='bar' )
| 205
|
'''simple docstring'''
import json
import os
import unittest
from transformers.models.gptsan_japanese.tokenization_gptsan_japanese import (
VOCAB_FILES_NAMES,
GPTSanJapaneseTokenizer,
)
from transformers.testing_utils import require_tokenizers, slow
from ...test_tokenization_common import TokenizerTesterMixin
@require_tokenizers
class UpperCAmelCase_ ( _a , unittest.TestCase ):
"""simple docstring"""
lowercase = GPTSanJapaneseTokenizer
lowercase = False
lowercase = {"do_clean_text": False, "add_prefix_space": False}
def lowerCamelCase ( self : str ):
super().setUp()
# fmt: off
snake_case__ : Optional[Any] = ["""こん""", """こんに""", """にちは""", """ばんは""", """世界,㔺界""", """、""", """。""", """<BR>""", """<SP>""", """<TAB>""", """<URL>""", """<EMAIL>""", """<TEL>""", """<DATE>""", """<PRICE>""", """<BLOCK>""", """<KIGOU>""", """<U2000U2BFF>""", """<|emoji1|>""", """<unk>""", """<|bagoftoken|>""", """<|endoftext|>"""]
# fmt: on
snake_case__ : int = {"""emoji""": {"""\ud83d\ude00""": """<|emoji1|>"""}, """emoji_inv""": {"""<|emoji1|>""": """\ud83d\ude00"""}} # 😀
snake_case__ : List[Any] = {"""unk_token""": """<unk>"""}
snake_case__ : Optional[Any] = os.path.join(self.tmpdirname , VOCAB_FILES_NAMES["""vocab_file"""] )
snake_case__ : Dict = os.path.join(self.tmpdirname , VOCAB_FILES_NAMES["""emoji_file"""] )
with open(self.vocab_file , """w""" , encoding="""utf-8""" ) as vocab_writer:
vocab_writer.write("""""".join([x + """\n""" for x in vocab_tokens] ) )
with open(self.emoji_file , """w""" ) as emoji_writer:
emoji_writer.write(json.dumps(snake_case_ ) )
def lowerCamelCase ( self : Any , **snake_case_ : Union[str, Any] ):
kwargs.update(self.special_tokens_map )
return GPTSanJapaneseTokenizer.from_pretrained(self.tmpdirname , **snake_case_ )
def lowerCamelCase ( self : Any , snake_case_ : str ):
snake_case__ : Union[str, Any] = """こんにちは、世界。 \nこんばんは、㔺界。😀"""
snake_case__ : List[str] = """こんにちは、世界。 \nこんばんは、世界。😀"""
return input_text, output_text
def lowerCamelCase ( self : Any , snake_case_ : Dict ):
snake_case__ , snake_case__ : int = self.get_input_output_texts(snake_case_ )
snake_case__ : int = tokenizer.encode(snake_case_ , add_special_tokens=snake_case_ )
snake_case__ : List[str] = tokenizer.decode(snake_case_ , clean_up_tokenization_spaces=snake_case_ )
return text, ids
def lowerCamelCase ( self : Optional[Any] ):
pass # TODO add if relevant
def lowerCamelCase ( self : Union[str, Any] ):
pass # TODO add if relevant
def lowerCamelCase ( self : List[str] ):
pass # TODO add if relevant
def lowerCamelCase ( self : Dict ):
snake_case__ : Optional[Any] = self.get_tokenizer()
# Testing tokenization
snake_case__ : int = """こんにちは、世界。 こんばんは、㔺界。"""
snake_case__ : Optional[int] = ["""こん""", """にちは""", """、""", """世界""", """。""", """<SP>""", """こん""", """ばんは""", """、""", """㔺界""", """。"""]
snake_case__ : Dict = tokenizer.tokenize(snake_case_ )
self.assertListEqual(snake_case_ , snake_case_ )
# Testing conversion to ids without special tokens
snake_case__ : Union[str, Any] = [0, 2, 5, 4, 6, 8, 0, 3, 5, 4, 6]
snake_case__ : List[Any] = tokenizer.convert_tokens_to_ids(snake_case_ )
self.assertListEqual(snake_case_ , snake_case_ )
# Testing conversion to ids with special tokens
snake_case__ : Union[str, Any] = tokens + [tokenizer.unk_token]
snake_case__ : Dict = [0, 2, 5, 4, 6, 8, 0, 3, 5, 4, 6, 19]
snake_case__ : Any = tokenizer.convert_tokens_to_ids(snake_case_ )
self.assertListEqual(snake_case_ , snake_case_ )
def lowerCamelCase ( self : Optional[Any] ):
snake_case__ : Union[str, Any] = self.get_tokenizer()
# Testing tokenization
snake_case__ : Union[str, Any] = """こんにちは、<|bagoftoken|>世界。こんばんは、<|bagoftoken|>㔺界。"""
snake_case__ : Optional[int] = """こんにちは、、、、世界。こんばんは、、、、世界。"""
snake_case__ : Any = tokenizer.encode(snake_case_ )
snake_case__ : int = tokenizer.decode(snake_case_ )
self.assertEqual(snake_case_ , snake_case_ )
@slow
def lowerCamelCase ( self : Union[str, Any] ):
snake_case__ : Optional[Any] = self.tokenizer_class.from_pretrained("""Tanrei/GPTSAN-japanese""" )
# Testing tokenization
snake_case__ : Tuple = """こんにちは、世界。"""
snake_case__ : Optional[Any] = """こんばんは、㔺界。😀"""
snake_case__ : List[str] = """こんにちは、世界。こんばんは、世界。😀"""
snake_case__ : Dict = tokenizer.encode(prefix_text + input_text )
snake_case__ : Dict = tokenizer.encode("""""" , prefix_text=prefix_text + input_text )
snake_case__ : int = tokenizer.encode(snake_case_ , prefix_text=snake_case_ )
snake_case__ : Optional[Any] = tokenizer.decode(snake_case_ )
snake_case__ : Union[str, Any] = tokenizer.decode(snake_case_ )
snake_case__ : str = tokenizer.decode(snake_case_ )
self.assertEqual(snake_case_ , snake_case_ )
self.assertEqual(snake_case_ , snake_case_ )
self.assertEqual(snake_case_ , snake_case_ )
@slow
def lowerCamelCase ( self : Union[str, Any] ):
snake_case__ : Optional[Any] = self.tokenizer_class.from_pretrained("""Tanrei/GPTSAN-japanese""" )
# Testing tokenization
snake_case__ : Dict = """こんにちは、世界。"""
snake_case__ : Optional[int] = """こんばんは、㔺界。😀"""
snake_case__ : Any = len(tokenizer.encode(snake_case_ ) ) - 2
snake_case__ : Optional[int] = len(tokenizer.encode(snake_case_ ) ) - 2
snake_case__ : List[str] = [1] + [0] * (len_prefix + len_text + 1)
snake_case__ : Optional[int] = [1] * (len_prefix + len_text + 1) + [0]
snake_case__ : int = [1] + [1] * (len_prefix) + [0] * (len_text + 1)
snake_case__ : Any = tokenizer(prefix_text + input_text ).token_type_ids
snake_case__ : str = tokenizer("""""" , prefix_text=prefix_text + input_text ).token_type_ids
snake_case__ : Optional[Any] = tokenizer(snake_case_ , prefix_text=snake_case_ ).token_type_ids
self.assertListEqual(snake_case_ , snake_case_ )
self.assertListEqual(snake_case_ , snake_case_ )
self.assertListEqual(snake_case_ , snake_case_ )
@slow
def lowerCamelCase ( self : Optional[int] ):
snake_case__ : Optional[Any] = self.tokenizer_class.from_pretrained("""Tanrei/GPTSAN-japanese""" )
snake_case__ : Union[str, Any] = tokenizer.encode("""あンいワ""" )
snake_case__ : int = tokenizer.encode("""""" , prefix_text="""あンいワ""" )
snake_case__ : Dict = tokenizer.encode("""いワ""" , prefix_text="""あン""" )
self.assertEqual(tokenizer.decode(snake_case_ ) , tokenizer.decode(snake_case_ ) )
self.assertEqual(tokenizer.decode(snake_case_ ) , tokenizer.decode(snake_case_ ) )
self.assertNotEqual(snake_case_ , snake_case_ )
self.assertNotEqual(snake_case_ , snake_case_ )
self.assertEqual(x_token_a[1] , x_token_a[-1] ) # SEG token
self.assertEqual(x_token_a[1] , x_token_a[3] ) # SEG token
@slow
def lowerCamelCase ( self : Any ):
snake_case__ : Optional[int] = self.tokenizer_class.from_pretrained("""Tanrei/GPTSAN-japanese""" )
snake_case__ : int = [["""武田信玄""", """は、"""], ["""織田信長""", """の配下の、"""]]
snake_case__ : Optional[Any] = tokenizer(snake_case_ , padding=snake_case_ )
snake_case__ : Tuple = tokenizer.batch_encode_plus(snake_case_ , padding=snake_case_ )
# fmt: off
snake_case__ : Optional[Any] = [[35_993, 8_640, 25_948, 35_998, 30_647, 35_675, 35_999, 35_999], [35_993, 10_382, 9_868, 35_998, 30_646, 9_459, 30_646, 35_675]]
snake_case__ : Optional[Any] = [[1, 1, 1, 0, 0, 0, 0, 0], [1, 1, 1, 0, 0, 0, 0, 0]]
snake_case__ : Optional[Any] = [[1, 1, 1, 1, 1, 1, 0, 0], [1, 1, 1, 1, 1, 1, 1, 1]]
# fmt: on
self.assertListEqual(x_token.input_ids , snake_case_ )
self.assertListEqual(x_token.token_type_ids , snake_case_ )
self.assertListEqual(x_token.attention_mask , snake_case_ )
self.assertListEqual(x_token_a.input_ids , snake_case_ )
self.assertListEqual(x_token_a.token_type_ids , snake_case_ )
self.assertListEqual(x_token_a.attention_mask , snake_case_ )
def lowerCamelCase ( self : Any ):
# Intentionally convert some words to accommodate character fluctuations unique to Japanese
pass
def lowerCamelCase ( self : List[str] ):
# tokenizer has no padding token
pass
| 35
| 0
|
from ..utils import DummyObject, requires_backends
class _SCREAMING_SNAKE_CASE ( metaclass=_a ):
snake_case__ : Optional[int] = ["""keras_nlp"""]
def __init__( self : List[Any] , *__lowerCamelCase : Dict , **__lowerCamelCase : int ):
requires_backends(self , ["""keras_nlp"""] )
| 38
|
'''simple docstring'''
from transformers import BertTokenizerFast
from .custom_tokenization import CustomTokenizer
class UpperCAmelCase_ ( _a ):
"""simple docstring"""
lowercase = CustomTokenizer
pass
| 35
| 0
|
"""simple docstring"""
class UpperCAmelCase_ :
def __init__( self , a ) -> Union[str, Any]:
lowercase__ : List[str] = len(snake_case_ )
lowercase__ : Union[str, Any] = [0] * len_array
if len_array > 0:
lowercase__ : str = array[0]
for i in range(1 , snake_case_ ):
lowercase__ : int = self.prefix_sum[i - 1] + array[i]
def _UpperCAmelCase ( self , a , a ) -> Optional[int]:
if start == 0:
return self.prefix_sum[end]
return self.prefix_sum[end] - self.prefix_sum[start - 1]
def _UpperCAmelCase ( self , a ) -> Dict:
lowercase__ : Optional[Any] = {0}
for sum_item in self.prefix_sum:
if sum_item - target_sum in sums:
return True
sums.add(snake_case_ )
return False
if __name__ == "__main__":
import doctest
doctest.testmod()
| 77
|
'''simple docstring'''
import numpy as np
from transformers import Pipeline
def __snake_case( _lowerCAmelCase ) -> Optional[int]:
snake_case__ : Optional[Any] = np.max(_lowerCAmelCase , axis=-1 , keepdims=_lowerCAmelCase )
snake_case__ : List[str] = np.exp(outputs - maxes )
return shifted_exp / shifted_exp.sum(axis=-1 , keepdims=_lowerCAmelCase )
class UpperCAmelCase_ ( _a ):
"""simple docstring"""
def lowerCamelCase ( self : Optional[Any] , **snake_case_ : int ):
snake_case__ : Optional[int] = {}
if "second_text" in kwargs:
snake_case__ : Union[str, Any] = kwargs["""second_text"""]
return preprocess_kwargs, {}, {}
def lowerCamelCase ( self : str , snake_case_ : Tuple , snake_case_ : Union[str, Any]=None ):
return self.tokenizer(snake_case_ , text_pair=snake_case_ , return_tensors=self.framework )
def lowerCamelCase ( self : List[Any] , snake_case_ : Dict ):
return self.model(**snake_case_ )
def lowerCamelCase ( self : int , snake_case_ : List[Any] ):
snake_case__ : Union[str, Any] = model_outputs.logits[0].numpy()
snake_case__ : List[str] = softmax(snake_case_ )
snake_case__ : List[str] = np.argmax(snake_case_ )
snake_case__ : List[str] = self.model.config.idalabel[best_class]
snake_case__ : Optional[int] = probabilities[best_class].item()
snake_case__ : str = logits.tolist()
return {"label": label, "score": score, "logits": logits}
| 35
| 0
|
'''simple docstring'''
from typing import TYPE_CHECKING
from ...utils import (
OptionalDependencyNotAvailable,
_LazyModule,
is_flax_available,
is_sentencepiece_available,
is_tf_available,
is_tokenizers_available,
is_torch_available,
)
SCREAMING_SNAKE_CASE_: str ={
'configuration_xlm_roberta': [
'XLM_ROBERTA_PRETRAINED_CONFIG_ARCHIVE_MAP',
'XLMRobertaConfig',
'XLMRobertaOnnxConfig',
],
}
try:
if not is_sentencepiece_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
SCREAMING_SNAKE_CASE_: List[str] =['XLMRobertaTokenizer']
try:
if not is_tokenizers_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
SCREAMING_SNAKE_CASE_: int =['XLMRobertaTokenizerFast']
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
SCREAMING_SNAKE_CASE_: Tuple =[
'XLM_ROBERTA_PRETRAINED_MODEL_ARCHIVE_LIST',
'XLMRobertaForCausalLM',
'XLMRobertaForMaskedLM',
'XLMRobertaForMultipleChoice',
'XLMRobertaForQuestionAnswering',
'XLMRobertaForSequenceClassification',
'XLMRobertaForTokenClassification',
'XLMRobertaModel',
'XLMRobertaPreTrainedModel',
]
try:
if not is_tf_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
SCREAMING_SNAKE_CASE_: List[Any] =[
'TF_XLM_ROBERTA_PRETRAINED_MODEL_ARCHIVE_LIST',
'TFXLMRobertaForCausalLM',
'TFXLMRobertaForMaskedLM',
'TFXLMRobertaForMultipleChoice',
'TFXLMRobertaForQuestionAnswering',
'TFXLMRobertaForSequenceClassification',
'TFXLMRobertaForTokenClassification',
'TFXLMRobertaModel',
'TFXLMRobertaPreTrainedModel',
]
try:
if not is_flax_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
SCREAMING_SNAKE_CASE_: List[Any] =[
'FLAX_XLM_ROBERTA_PRETRAINED_MODEL_ARCHIVE_LIST',
'FlaxXLMRobertaForMaskedLM',
'FlaxXLMRobertaForCausalLM',
'FlaxXLMRobertaForMultipleChoice',
'FlaxXLMRobertaForQuestionAnswering',
'FlaxXLMRobertaForSequenceClassification',
'FlaxXLMRobertaForTokenClassification',
'FlaxXLMRobertaModel',
'FlaxXLMRobertaPreTrainedModel',
]
if TYPE_CHECKING:
from .configuration_xlm_roberta import (
XLM_ROBERTA_PRETRAINED_CONFIG_ARCHIVE_MAP,
XLMRobertaConfig,
XLMRobertaOnnxConfig,
)
try:
if not is_sentencepiece_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .tokenization_xlm_roberta import XLMRobertaTokenizer
try:
if not is_tokenizers_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .tokenization_xlm_roberta_fast import XLMRobertaTokenizerFast
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_xlm_roberta import (
XLM_ROBERTA_PRETRAINED_MODEL_ARCHIVE_LIST,
XLMRobertaForCausalLM,
XLMRobertaForMaskedLM,
XLMRobertaForMultipleChoice,
XLMRobertaForQuestionAnswering,
XLMRobertaForSequenceClassification,
XLMRobertaForTokenClassification,
XLMRobertaModel,
XLMRobertaPreTrainedModel,
)
try:
if not is_tf_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_tf_xlm_roberta import (
TF_XLM_ROBERTA_PRETRAINED_MODEL_ARCHIVE_LIST,
TFXLMRobertaForCausalLM,
TFXLMRobertaForMaskedLM,
TFXLMRobertaForMultipleChoice,
TFXLMRobertaForQuestionAnswering,
TFXLMRobertaForSequenceClassification,
TFXLMRobertaForTokenClassification,
TFXLMRobertaModel,
TFXLMRobertaPreTrainedModel,
)
try:
if not is_flax_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_flax_xlm_roberta import (
FLAX_XLM_ROBERTA_PRETRAINED_MODEL_ARCHIVE_LIST,
FlaxXLMRobertaForCausalLM,
FlaxXLMRobertaForMaskedLM,
FlaxXLMRobertaForMultipleChoice,
FlaxXLMRobertaForQuestionAnswering,
FlaxXLMRobertaForSequenceClassification,
FlaxXLMRobertaForTokenClassification,
FlaxXLMRobertaModel,
FlaxXLMRobertaPreTrainedModel,
)
else:
import sys
SCREAMING_SNAKE_CASE_: Optional[Any] =_LazyModule(__name__, globals()['__file__'], _import_structure, module_spec=__spec__)
| 1
|
'''simple docstring'''
# Function to print upper half of diamond (pyramid)
def __snake_case( _lowerCAmelCase ) -> Any:
for i in range(0 , _lowerCAmelCase ):
for _ in range(0 , n - i - 1 ): # printing spaces
print(""" """ , end="""""" )
for _ in range(0 , i + 1 ): # printing stars
print("""* """ , end="""""" )
print()
def __snake_case( _lowerCAmelCase ) -> List[str]:
for i in range(_lowerCAmelCase , 0 , -1 ):
for _ in range(_lowerCAmelCase , 0 , -1 ): # printing stars
print("""* """ , end="""""" )
print()
for _ in range(n - i + 1 , 0 , -1 ): # printing spaces
print(""" """ , end="""""" )
def __snake_case( _lowerCAmelCase ) -> List[Any]:
if n <= 0:
print(""" ... .... nothing printing :(""" )
return
floyd(_lowerCAmelCase ) # upper half
reverse_floyd(_lowerCAmelCase ) # lower half
if __name__ == "__main__":
print(R"| /\ | |- | |- |--| |\ /| |-")
print(R"|/ \| |- |_ |_ |__| | \/ | |_")
__a = 1
while K:
__a = int(input("enter the number and , and see the magic : "))
print()
pretty_print(user_number)
__a = int(input("press 0 to exit... and 1 to continue..."))
print("Good Bye...")
| 35
| 0
|
import torch
from transformers import AutoModel
class A( torch.nn.Module ):
'''simple docstring'''
def __init__( self : Optional[Any] , A_ : Optional[Any]="sayef/fsner-bert-base-uncased" ) -> Optional[int]:
"""simple docstring"""
super(snake_case_ , self ).__init__()
lowerCamelCase_ = AutoModel.from_pretrained(snake_case_ , return_dict=snake_case_ )
lowerCamelCase_ = torch.nn.CosineSimilarity(3 , 1E-08 )
lowerCamelCase_ = torch.nn.Softmax(dim=1 )
def a__ ( self : Optional[int] , **A_ : str ) -> int:
"""simple docstring"""
return self.bert(**snake_case_ ).last_hidden_state
def a__ ( self : Any , A_ : List[Any] ) -> str:
"""simple docstring"""
return token_embeddings.sum(2 , keepdim=snake_case_ )
def a__ ( self : Optional[Any] , A_ : int , A_ : Union[str, Any] , A_ : Union[str, Any]=1 ) -> Tuple:
"""simple docstring"""
return self.softmax(T * self.cos(snake_case_ , snake_case_ ) )
def a__ ( self : Any , A_ : Optional[Any] , A_ : int ) -> List[str]:
"""simple docstring"""
lowerCamelCase_ = W_supports["""sizes"""].tolist()
lowerCamelCase_ = W_supports["""start_token_id"""].item()
lowerCamelCase_ = W_supports["""end_token_id"""].item()
del W_supports["sizes"]
del W_supports["start_token_id"]
del W_supports["end_token_id"]
lowerCamelCase_ = self.BERT(**snake_case_ )
lowerCamelCase_ = self.BERT(**snake_case_ )
lowerCamelCase_ = None
lowerCamelCase_ = None
lowerCamelCase_ = W_supports["""input_ids"""] == start_token_id
lowerCamelCase_ = W_supports["""input_ids"""] == end_token_id
for i, size in enumerate(snake_case_ ):
if i == 0:
lowerCamelCase_ = 0
else:
lowerCamelCase_ = support_sizes[i - 1]
lowerCamelCase_ = S[s : s + size][start_token_masks[s : s + size]]
lowerCamelCase_ = S[s : s + size][end_token_masks[s : s + size]]
lowerCamelCase_ = torch.matmul(q[i] , s_start.T ).sum(1 ).softmax(0 )
lowerCamelCase_ = torch.matmul(q[i] , s_end.T ).sum(1 ).softmax(0 )
if p_starts is not None:
lowerCamelCase_ = torch.vstack((p_starts, p_start) )
lowerCamelCase_ = torch.vstack((p_ends, p_end) )
else:
lowerCamelCase_ = p_start
lowerCamelCase_ = p_end
return p_starts, p_ends
| 204
|
'''simple docstring'''
def __snake_case( _lowerCAmelCase = 1_000 ) -> int:
return sum(e for e in range(3 , _lowerCAmelCase ) if e % 3 == 0 or e % 5 == 0 )
if __name__ == "__main__":
print(F"{solution() = }")
| 35
| 0
|
import io
import math
from typing import Dict, Optional, Union
import numpy as np
from huggingface_hub import hf_hub_download
from ...image_processing_utils import BaseImageProcessor, BatchFeature
from ...image_transforms import convert_to_rgb, normalize, to_channel_dimension_format, to_pil_image
from ...image_utils import (
ChannelDimension,
ImageInput,
get_image_size,
infer_channel_dimension_format,
make_list_of_images,
to_numpy_array,
valid_images,
)
from ...utils import TensorType, is_torch_available, is_vision_available, logging
from ...utils.import_utils import requires_backends
if is_vision_available():
import textwrap
from PIL import Image, ImageDraw, ImageFont
if is_torch_available():
import torch
from transformers.pytorch_utils import is_torch_greater_or_equal_than_1_11
else:
a : Optional[Any] = False
a : Tuple = logging.get_logger(__name__)
a : int = 'ybelkada/fonts'
def lowerCAmelCase_ ():
"""simple docstring"""
if is_torch_available() and not is_torch_greater_or_equal_than_1_11:
raise ImportError(
F'You are using torch=={torch.__version__}, but torch>=1.11.0 is required to use '
"""Pix2StructImageProcessor. Please upgrade torch.""" )
def lowerCAmelCase_ (lowerCAmelCase__: Optional[Any] , lowerCAmelCase__: Optional[Any] , lowerCAmelCase__: Dict ):
"""simple docstring"""
requires_backends(_lowerCAmelCase , ["""torch"""] )
_check_torch_version()
UpperCAmelCase_: Any = image_tensor.unsqueeze(0 )
UpperCAmelCase_: Union[str, Any] = torch.nn.functional.unfold(_lowerCAmelCase , (patch_height, patch_width) , stride=(patch_height, patch_width) )
UpperCAmelCase_: Dict = patches.reshape(image_tensor.size(0 ) , image_tensor.size(1 ) , _lowerCAmelCase , _lowerCAmelCase , -1 )
UpperCAmelCase_: str = patches.permute(0 , 4 , 2 , 3 , 1 ).reshape(
image_tensor.size(2 ) // patch_height , image_tensor.size(3 ) // patch_width , image_tensor.size(1 ) * patch_height * patch_width , )
return patches.unsqueeze(0 )
def lowerCAmelCase_ (lowerCAmelCase__: str , lowerCAmelCase__: List[str] = 3_6 , lowerCAmelCase__: str = "black" , lowerCAmelCase__: str = "white" , lowerCAmelCase__: Tuple = 5 , lowerCAmelCase__: str = 5 , lowerCAmelCase__: Any = 5 , lowerCAmelCase__: Dict = 5 , lowerCAmelCase__: Union[str, Any] = None , lowerCAmelCase__: Optional[Any] = None , ):
"""simple docstring"""
requires_backends(_lowerCAmelCase , """vision""" )
# Add new lines so that each line is no more than 80 characters.
UpperCAmelCase_: List[Any] = textwrap.TextWrapper(width=8_0 )
UpperCAmelCase_: Optional[int] = wrapper.wrap(text=_lowerCAmelCase )
UpperCAmelCase_: List[Any] = """\n""".join(_lowerCAmelCase )
if font_bytes is not None and font_path is None:
UpperCAmelCase_: Union[str, Any] = io.BytesIO(_lowerCAmelCase )
elif font_path is not None:
UpperCAmelCase_: List[str] = font_path
else:
UpperCAmelCase_: Tuple = hf_hub_download(_lowerCAmelCase , """Arial.TTF""" )
UpperCAmelCase_: Any = ImageFont.truetype(_lowerCAmelCase , encoding="""UTF-8""" , size=_lowerCAmelCase )
# Use a temporary canvas to determine the width and height in pixels when
# rendering the text.
UpperCAmelCase_: str = ImageDraw.Draw(Image.new("""RGB""" , (1, 1) , _lowerCAmelCase ) )
UpperCAmelCase_: Any = temp_draw.textbbox((0, 0) , _lowerCAmelCase , _lowerCAmelCase )
# Create the actual image with a bit of padding around the text.
UpperCAmelCase_: str = text_width + left_padding + right_padding
UpperCAmelCase_: Any = text_height + top_padding + bottom_padding
UpperCAmelCase_: Optional[int] = Image.new("""RGB""" , (image_width, image_height) , _lowerCAmelCase )
UpperCAmelCase_: Any = ImageDraw.Draw(_lowerCAmelCase )
draw.text(xy=(left_padding, top_padding) , text=_lowerCAmelCase , fill=_lowerCAmelCase , font=_lowerCAmelCase )
return image
def lowerCAmelCase_ (lowerCAmelCase__: str , lowerCAmelCase__: Optional[int] , **lowerCAmelCase__: List[str] ):
"""simple docstring"""
requires_backends(_lowerCAmelCase , """vision""" )
# Convert to PIL image if necessary
UpperCAmelCase_: Tuple = to_pil_image(_lowerCAmelCase )
UpperCAmelCase_: Any = render_text(_lowerCAmelCase , **_lowerCAmelCase )
UpperCAmelCase_: Optional[Any] = max(header_image.width , image.width )
UpperCAmelCase_: Any = int(image.height * (new_width / image.width) )
UpperCAmelCase_: Optional[int] = int(header_image.height * (new_width / header_image.width) )
UpperCAmelCase_: Optional[Any] = Image.new("""RGB""" , (new_width, new_height + new_header_height) , """white""" )
new_image.paste(header_image.resize((new_width, new_header_height) ) , (0, 0) )
new_image.paste(image.resize((new_width, new_height) ) , (0, new_header_height) )
# Convert back to the original framework if necessary
UpperCAmelCase_: Union[str, Any] = to_numpy_array(_lowerCAmelCase )
if infer_channel_dimension_format(_lowerCAmelCase ) == ChannelDimension.LAST:
UpperCAmelCase_: Optional[Any] = to_channel_dimension_format(_lowerCAmelCase , ChannelDimension.LAST )
return new_image
class _a ( _a ):
A = ['''flattened_patches''']
def __init__(self, SCREAMING_SNAKE_CASE_ = True, SCREAMING_SNAKE_CASE_ = True, SCREAMING_SNAKE_CASE_ = None, SCREAMING_SNAKE_CASE_ = 2048, SCREAMING_SNAKE_CASE_ = False, **SCREAMING_SNAKE_CASE_, ) -> Optional[Any]:
super().__init__(**snake_case_ )
UpperCAmelCase_: List[str] = patch_size if patch_size is not None else {"""height""": 16, """width""": 16}
UpperCAmelCase_: List[str] = do_normalize
UpperCAmelCase_: Tuple = do_convert_rgb
UpperCAmelCase_: str = max_patches
UpperCAmelCase_: Dict = is_vqa
def __snake_case (self, SCREAMING_SNAKE_CASE_, SCREAMING_SNAKE_CASE_, SCREAMING_SNAKE_CASE_, **SCREAMING_SNAKE_CASE_ ) -> int:
requires_backends(self.extract_flattened_patches, """torch""" )
_check_torch_version()
# convert to torch
UpperCAmelCase_: Tuple = to_channel_dimension_format(snake_case_, ChannelDimension.FIRST )
UpperCAmelCase_: Optional[int] = torch.from_numpy(snake_case_ )
UpperCAmelCase_: List[Any] = patch_size["""height"""], patch_size["""width"""]
UpperCAmelCase_: Tuple = get_image_size(snake_case_ )
# maximize scale s.t.
UpperCAmelCase_: Tuple = math.sqrt(max_patches * (patch_height / image_height) * (patch_width / image_width) )
UpperCAmelCase_: Any = max(min(math.floor(scale * image_height / patch_height ), snake_case_ ), 1 )
UpperCAmelCase_: List[Any] = max(min(math.floor(scale * image_width / patch_width ), snake_case_ ), 1 )
UpperCAmelCase_: Union[str, Any] = max(num_feasible_rows * patch_height, 1 )
UpperCAmelCase_: Optional[Any] = max(num_feasible_cols * patch_width, 1 )
UpperCAmelCase_: List[str] = torch.nn.functional.interpolate(
image.unsqueeze(0 ), size=(resized_height, resized_width), mode="""bilinear""", align_corners=snake_case_, antialias=snake_case_, ).squeeze(0 )
# [1, rows, columns, patch_height * patch_width * image_channels]
UpperCAmelCase_: str = torch_extract_patches(snake_case_, snake_case_, snake_case_ )
UpperCAmelCase_: Tuple = patches.shape
UpperCAmelCase_: List[Any] = patches_shape[1]
UpperCAmelCase_: Dict = patches_shape[2]
UpperCAmelCase_: List[str] = patches_shape[3]
# [rows * columns, patch_height * patch_width * image_channels]
UpperCAmelCase_: Optional[int] = patches.reshape([rows * columns, depth] )
# [rows * columns, 1]
UpperCAmelCase_: Optional[int] = torch.arange(snake_case_ ).reshape([rows, 1] ).repeat(1, snake_case_ ).reshape([rows * columns, 1] )
UpperCAmelCase_: Optional[int] = torch.arange(snake_case_ ).reshape([1, columns] ).repeat(snake_case_, 1 ).reshape([rows * columns, 1] )
# Offset by 1 so the ids do not contain zeros, which represent padding.
row_ids += 1
col_ids += 1
# Prepare additional patch features.
# [rows * columns, 1]
UpperCAmelCase_: Optional[int] = row_ids.to(torch.floataa )
UpperCAmelCase_: Tuple = col_ids.to(torch.floataa )
# [rows * columns, 2 + patch_height * patch_width * image_channels]
UpperCAmelCase_: Any = torch.cat([row_ids, col_ids, patches], -1 )
# [max_patches, 2 + patch_height * patch_width * image_channels]
UpperCAmelCase_: Any = torch.nn.functional.pad(snake_case_, [0, 0, 0, max_patches - (rows * columns)] ).float()
UpperCAmelCase_: int = to_numpy_array(snake_case_ )
return result
def __snake_case (self, SCREAMING_SNAKE_CASE_, SCREAMING_SNAKE_CASE_ = None, **SCREAMING_SNAKE_CASE_ ) -> str:
if image.dtype == np.uinta:
UpperCAmelCase_: int = image.astype(np.floataa )
# take mean across the whole `image`
UpperCAmelCase_: List[Any] = np.mean(snake_case_ )
UpperCAmelCase_: List[str] = np.std(snake_case_ )
UpperCAmelCase_: str = max(snake_case_, 1.0 / math.sqrt(np.prod(image.shape ) ) )
return normalize(snake_case_, mean=snake_case_, std=snake_case_, **snake_case_ )
def __snake_case (self, SCREAMING_SNAKE_CASE_, SCREAMING_SNAKE_CASE_ = None, SCREAMING_SNAKE_CASE_ = None, SCREAMING_SNAKE_CASE_ = None, SCREAMING_SNAKE_CASE_ = None, SCREAMING_SNAKE_CASE_ = None, SCREAMING_SNAKE_CASE_ = None, SCREAMING_SNAKE_CASE_ = ChannelDimension.FIRST, **SCREAMING_SNAKE_CASE_, ) -> Optional[Any]:
UpperCAmelCase_: Any = do_normalize if do_normalize is not None else self.do_normalize
UpperCAmelCase_: Dict = do_convert_rgb if do_convert_rgb is not None else self.do_convert_rgb
UpperCAmelCase_: str = patch_size if patch_size is not None else self.patch_size
UpperCAmelCase_: List[Any] = max_patches if max_patches is not None else self.max_patches
UpperCAmelCase_: int = self.is_vqa
if kwargs.get("""data_format""", snake_case_ ) is not None:
raise ValueError("""data_format is not an accepted input as the outputs are """ )
UpperCAmelCase_: Tuple = make_list_of_images(snake_case_ )
if not valid_images(snake_case_ ):
raise ValueError(
"""Invalid image type. Must be of type PIL.Image.Image, numpy.ndarray, """
"""torch.Tensor, tf.Tensor or jax.ndarray.""" )
# PIL RGBA images are converted to RGB
if do_convert_rgb:
UpperCAmelCase_: Union[str, Any] = [convert_to_rgb(snake_case_ ) for image in images]
# All transformations expect numpy arrays.
UpperCAmelCase_: Tuple = [to_numpy_array(snake_case_ ) for image in images]
if is_vqa:
if header_text is None:
raise ValueError("""A header text must be provided for VQA models.""" )
UpperCAmelCase_: Any = kwargs.pop("""font_bytes""", snake_case_ )
UpperCAmelCase_: str = kwargs.pop("""font_path""", snake_case_ )
if isinstance(snake_case_, snake_case_ ):
UpperCAmelCase_: List[str] = [header_text] * len(snake_case_ )
UpperCAmelCase_: int = [
render_header(snake_case_, header_text[i], font_bytes=snake_case_, font_path=snake_case_ )
for i, image in enumerate(snake_case_ )
]
if do_normalize:
UpperCAmelCase_: Union[str, Any] = [self.normalize(image=snake_case_ ) for image in images]
# convert to torch tensor and permute
UpperCAmelCase_: str = [
self.extract_flattened_patches(image=snake_case_, max_patches=snake_case_, patch_size=snake_case_ )
for image in images
]
# create attention mask in numpy
UpperCAmelCase_: List[str] = [(image.sum(axis=-1 ) != 0).astype(np.floataa ) for image in images]
UpperCAmelCase_: List[Any] = BatchFeature(
data={"""flattened_patches""": images, """attention_mask""": attention_masks}, tensor_type=snake_case_ )
return encoded_outputs
| 147
|
'''simple docstring'''
from typing import TYPE_CHECKING
from ...utils import OptionalDependencyNotAvailable, _LazyModule, is_tokenizers_available, is_torch_available
__a = {
"configuration_bloom": ["BLOOM_PRETRAINED_CONFIG_ARCHIVE_MAP", "BloomConfig", "BloomOnnxConfig"],
}
try:
if not is_tokenizers_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__a = ["BloomTokenizerFast"]
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__a = [
"BLOOM_PRETRAINED_MODEL_ARCHIVE_LIST",
"BloomForCausalLM",
"BloomModel",
"BloomPreTrainedModel",
"BloomForSequenceClassification",
"BloomForTokenClassification",
"BloomForQuestionAnswering",
]
if TYPE_CHECKING:
from .configuration_bloom import BLOOM_PRETRAINED_CONFIG_ARCHIVE_MAP, BloomConfig, BloomOnnxConfig
try:
if not is_tokenizers_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .tokenization_bloom_fast import BloomTokenizerFast
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_bloom import (
BLOOM_PRETRAINED_MODEL_ARCHIVE_LIST,
BloomForCausalLM,
BloomForQuestionAnswering,
BloomForSequenceClassification,
BloomForTokenClassification,
BloomModel,
BloomPreTrainedModel,
)
else:
import sys
__a = _LazyModule(__name__, globals()["__file__"], _import_structure, module_spec=__spec__)
| 35
| 0
|
import bza
import gzip
import lzma
import os
import shutil
import struct
import tarfile
import warnings
import zipfile
from abc import ABC, abstractmethod
from pathlib import Path
from typing import Dict, List, Optional, Type, Union
from .. import config
from .filelock import FileLock
from .logging import get_logger
__lowerCAmelCase : List[Any] = get_logger(__name__)
class UpperCAmelCase_ :
'''simple docstring'''
def __init__( self : Any , UpperCamelCase__ : Optional[str] = None ) -> Tuple:
"""simple docstring"""
__magic_name__ = (
os.path.join(snake_case_ , config.EXTRACTED_DATASETS_DIR ) if cache_dir else config.EXTRACTED_DATASETS_PATH
)
__magic_name__ = Extractor
def _lowercase ( self : Optional[Any] , UpperCamelCase__ : str ) -> str:
"""simple docstring"""
from .file_utils import hash_url_to_filename
# Path where we extract compressed archives
# We extract in the cache dir, and get the extracted path name by hashing the original path"
__magic_name__ = os.path.abspath(snake_case_ )
return os.path.join(self.extract_dir , hash_url_to_filename(snake_case_ ) )
def _lowercase ( self : Optional[Any] , UpperCamelCase__ : str , UpperCamelCase__ : bool ) -> Optional[int]:
"""simple docstring"""
return force_extract or (
not os.path.isfile(snake_case_ ) and not (os.path.isdir(snake_case_ ) and os.listdir(snake_case_ ))
)
def _lowercase ( self : str , UpperCamelCase__ : str , UpperCamelCase__ : bool = False ) -> Any:
"""simple docstring"""
__magic_name__ = self.extractor.infer_extractor_format(snake_case_ )
if not extractor_format:
return input_path
__magic_name__ = self._get_output_path(snake_case_ )
if self._do_extract(snake_case_ , snake_case_ ):
self.extractor.extract(snake_case_ , snake_case_ , snake_case_ )
return output_path
class UpperCAmelCase_ ( _a ):
'''simple docstring'''
@classmethod
@abstractmethod
def _lowercase ( cls : Optional[int] , UpperCamelCase__ : Union[Path, str] , **UpperCamelCase__ : Tuple ) -> List[str]:
"""simple docstring"""
...
@staticmethod
@abstractmethod
def _lowercase ( UpperCamelCase__ : Union[Path, str] , UpperCamelCase__ : Union[Path, str] ) -> Optional[int]:
"""simple docstring"""
...
class UpperCAmelCase_ ( _a , _a ):
'''simple docstring'''
a__ = []
@staticmethod
def _lowercase ( UpperCamelCase__ : Union[Path, str] , UpperCamelCase__ : int ) -> Optional[Any]:
"""simple docstring"""
with open(snake_case_ , """rb""" ) as f:
return f.read(snake_case_ )
@classmethod
def _lowercase ( cls : Any , UpperCamelCase__ : Union[Path, str] , UpperCamelCase__ : bytes = b"" ) -> int:
"""simple docstring"""
if not magic_number:
__magic_name__ = max(len(snake_case_ ) for cls_magic_number in cls.magic_numbers )
try:
__magic_name__ = cls.read_magic_number(snake_case_ , snake_case_ )
except OSError:
return False
return any(magic_number.startswith(snake_case_ ) for cls_magic_number in cls.magic_numbers )
class UpperCAmelCase_ ( _a ):
'''simple docstring'''
@classmethod
def _lowercase ( cls : Union[str, Any] , UpperCamelCase__ : Union[Path, str] , **UpperCamelCase__ : Union[str, Any] ) -> List[str]:
"""simple docstring"""
return tarfile.is_tarfile(snake_case_ )
@staticmethod
def _lowercase ( UpperCamelCase__ : List[str] , UpperCamelCase__ : Optional[Any] ) -> str:
"""simple docstring"""
def resolved(UpperCamelCase__ : str ) -> str:
return os.path.realpath(os.path.abspath(snake_case_ ) )
def badpath(UpperCamelCase__ : str , UpperCamelCase__ : str ) -> bool:
# joinpath will ignore base if path is absolute
return not resolved(os.path.join(snake_case_ , snake_case_ ) ).startswith(snake_case_ )
def badlink(UpperCamelCase__ : str , UpperCamelCase__ : str ) -> bool:
# Links are interpreted relative to the directory containing the link
__magic_name__ = resolved(os.path.join(snake_case_ , os.path.dirname(info.name ) ) )
return badpath(info.linkname , base=snake_case_ )
__magic_name__ = resolved(snake_case_ )
for finfo in members:
if badpath(finfo.name , snake_case_ ):
logger.error(F'''Extraction of {finfo.name} is blocked (illegal path)''' )
elif finfo.issym() and badlink(snake_case_ , snake_case_ ):
logger.error(F'''Extraction of {finfo.name} is blocked: Symlink to {finfo.linkname}''' )
elif finfo.islnk() and badlink(snake_case_ , snake_case_ ):
logger.error(F'''Extraction of {finfo.name} is blocked: Hard link to {finfo.linkname}''' )
else:
yield finfo
@staticmethod
def _lowercase ( UpperCamelCase__ : Union[Path, str] , UpperCamelCase__ : Union[Path, str] ) -> Any:
"""simple docstring"""
os.makedirs(snake_case_ , exist_ok=snake_case_ )
__magic_name__ = tarfile.open(snake_case_ )
tar_file.extractall(snake_case_ , members=TarExtractor.safemembers(snake_case_ , snake_case_ ) )
tar_file.close()
class UpperCAmelCase_ ( _a ):
'''simple docstring'''
a__ = [B"""\x1F\x8B"""]
@staticmethod
def _lowercase ( UpperCamelCase__ : Union[Path, str] , UpperCamelCase__ : Union[Path, str] ) -> Any:
"""simple docstring"""
with gzip.open(snake_case_ , """rb""" ) as gzip_file:
with open(snake_case_ , """wb""" ) as extracted_file:
shutil.copyfileobj(snake_case_ , snake_case_ )
class UpperCAmelCase_ ( _a ):
'''simple docstring'''
a__ = [
B"""PK\x03\x04""",
B"""PK\x05\x06""", # empty archive
B"""PK\x07\x08""", # spanned archive
]
@classmethod
def _lowercase ( cls : int , UpperCamelCase__ : Union[Path, str] , UpperCamelCase__ : bytes = b"" ) -> Optional[int]:
"""simple docstring"""
if super().is_extractable(snake_case_ , magic_number=snake_case_ ):
return True
try:
# Alternative version of zipfile.is_zipfile that has less false positives, but misses executable zip archives.
# From: https://github.com/python/cpython/pull/5053
from zipfile import (
_CD_SIGNATURE,
_ECD_DISK_NUMBER,
_ECD_DISK_START,
_ECD_ENTRIES_TOTAL,
_ECD_OFFSET,
_ECD_SIZE,
_EndRecData,
sizeCentralDir,
stringCentralDir,
structCentralDir,
)
with open(snake_case_ , """rb""" ) as fp:
__magic_name__ = _EndRecData(snake_case_ )
if endrec:
if endrec[_ECD_ENTRIES_TOTAL] == 0 and endrec[_ECD_SIZE] == 0 and endrec[_ECD_OFFSET] == 0:
return True # Empty zipfiles are still zipfiles
elif endrec[_ECD_DISK_NUMBER] == endrec[_ECD_DISK_START]:
fp.seek(endrec[_ECD_OFFSET] ) # Central directory is on the same disk
if fp.tell() == endrec[_ECD_OFFSET] and endrec[_ECD_SIZE] >= sizeCentralDir:
__magic_name__ = fp.read(snake_case_ ) # CD is where we expect it to be
if len(snake_case_ ) == sizeCentralDir:
__magic_name__ = struct.unpack(snake_case_ , snake_case_ ) # CD is the right size
if centdir[_CD_SIGNATURE] == stringCentralDir:
return True # First central directory entry has correct magic number
return False
except Exception: # catch all errors in case future python versions change the zipfile internals
return False
@staticmethod
def _lowercase ( UpperCamelCase__ : Union[Path, str] , UpperCamelCase__ : Union[Path, str] ) -> List[Any]:
"""simple docstring"""
os.makedirs(snake_case_ , exist_ok=snake_case_ )
with zipfile.ZipFile(snake_case_ , """r""" ) as zip_file:
zip_file.extractall(snake_case_ )
zip_file.close()
class UpperCAmelCase_ ( _a ):
'''simple docstring'''
a__ = [B"""\xFD\x37\x7A\x58\x5A\x00"""]
@staticmethod
def _lowercase ( UpperCamelCase__ : Union[Path, str] , UpperCamelCase__ : Union[Path, str] ) -> Optional[int]:
"""simple docstring"""
with lzma.open(snake_case_ ) as compressed_file:
with open(snake_case_ , """wb""" ) as extracted_file:
shutil.copyfileobj(snake_case_ , snake_case_ )
class UpperCAmelCase_ ( _a ):
'''simple docstring'''
a__ = [B"""Rar!\x1a\x07\x00""", B"""Rar!\x1a\x07\x01\x00"""] # RAR_ID # RAR5_ID
@staticmethod
def _lowercase ( UpperCamelCase__ : Union[Path, str] , UpperCamelCase__ : Union[Path, str] ) -> List[str]:
"""simple docstring"""
if not config.RARFILE_AVAILABLE:
raise ImportError("""Please pip install rarfile""" )
import rarfile
os.makedirs(snake_case_ , exist_ok=snake_case_ )
__magic_name__ = rarfile.RarFile(snake_case_ )
rf.extractall(snake_case_ )
rf.close()
class UpperCAmelCase_ ( _a ):
'''simple docstring'''
a__ = [B"""\x28\xb5\x2F\xFD"""]
@staticmethod
def _lowercase ( UpperCamelCase__ : Union[Path, str] , UpperCamelCase__ : Union[Path, str] ) -> Tuple:
"""simple docstring"""
if not config.ZSTANDARD_AVAILABLE:
raise ImportError("""Please pip install zstandard""" )
import zstandard as zstd
__magic_name__ = zstd.ZstdDecompressor()
with open(snake_case_ , """rb""" ) as ifh, open(snake_case_ , """wb""" ) as ofh:
dctx.copy_stream(snake_case_ , snake_case_ )
class UpperCAmelCase_ ( _a ):
'''simple docstring'''
a__ = [B"""\x42\x5A\x68"""]
@staticmethod
def _lowercase ( UpperCamelCase__ : Union[Path, str] , UpperCamelCase__ : Union[Path, str] ) -> Tuple:
"""simple docstring"""
with bza.open(snake_case_ , """rb""" ) as compressed_file:
with open(snake_case_ , """wb""" ) as extracted_file:
shutil.copyfileobj(snake_case_ , snake_case_ )
class UpperCAmelCase_ ( _a ):
'''simple docstring'''
a__ = [B"""\x37\x7A\xBC\xAF\x27\x1C"""]
@staticmethod
def _lowercase ( UpperCamelCase__ : Union[Path, str] , UpperCamelCase__ : Union[Path, str] ) -> Optional[int]:
"""simple docstring"""
if not config.PY7ZR_AVAILABLE:
raise ImportError("""Please pip install py7zr""" )
import pyazr
os.makedirs(snake_case_ , exist_ok=snake_case_ )
with pyazr.SevenZipFile(snake_case_ , """r""" ) as archive:
archive.extractall(snake_case_ )
class UpperCAmelCase_ ( _a ):
'''simple docstring'''
a__ = [B"""\x04\x22\x4D\x18"""]
@staticmethod
def _lowercase ( UpperCamelCase__ : Union[Path, str] , UpperCamelCase__ : Union[Path, str] ) -> List[Any]:
"""simple docstring"""
if not config.LZ4_AVAILABLE:
raise ImportError("""Please pip install lz4""" )
import lza.frame
with lza.frame.open(snake_case_ , """rb""" ) as compressed_file:
with open(snake_case_ , """wb""" ) as extracted_file:
shutil.copyfileobj(snake_case_ , snake_case_ )
class UpperCAmelCase_ :
'''simple docstring'''
a__ = {
"""tar""": TarExtractor,
"""gzip""": GzipExtractor,
"""zip""": ZipExtractor,
"""xz""": XzExtractor,
"""rar""": RarExtractor,
"""zstd""": ZstdExtractor,
"""bz2""": BzipaExtractor,
"""7z""": SevenZipExtractor, # <Added version="2.4.0"/>
"""lz4""": LzaExtractor, # <Added version="2.4.0"/>
}
@classmethod
def _lowercase ( cls : List[str] ) -> Any:
"""simple docstring"""
return max(
len(snake_case_ )
for extractor in cls.extractors.values()
if issubclass(snake_case_ , snake_case_ )
for extractor_magic_number in extractor.magic_numbers )
@staticmethod
def _lowercase ( UpperCamelCase__ : Union[Path, str] , UpperCamelCase__ : int ) -> int:
"""simple docstring"""
try:
return MagicNumberBaseExtractor.read_magic_number(snake_case_ , magic_number_length=snake_case_ )
except OSError:
return b""
@classmethod
def _lowercase ( cls : int , UpperCamelCase__ : Union[Path, str] , UpperCamelCase__ : bool = False ) -> Optional[int]:
"""simple docstring"""
warnings.warn(
"""Method 'is_extractable' was deprecated in version 2.4.0 and will be removed in 3.0.0. """
"""Use 'infer_extractor_format' instead.""" , category=snake_case_ , )
__magic_name__ = cls.infer_extractor_format(snake_case_ )
if extractor_format:
return True if not return_extractor else (True, cls.extractors[extractor_format])
return False if not return_extractor else (False, None)
@classmethod
def _lowercase ( cls : Optional[int] , UpperCamelCase__ : Union[Path, str] ) -> Dict: # <Added version="2.4.0"/>
"""simple docstring"""
__magic_name__ = cls._get_magic_number_max_length()
__magic_name__ = cls._read_magic_number(snake_case_ , snake_case_ )
for extractor_format, extractor in cls.extractors.items():
if extractor.is_extractable(snake_case_ , magic_number=snake_case_ ):
return extractor_format
@classmethod
def _lowercase ( cls : Any , UpperCamelCase__ : Union[Path, str] , UpperCamelCase__ : Union[Path, str] , UpperCamelCase__ : Optional[str] = None , UpperCamelCase__ : Optional[BaseExtractor] = "deprecated" , ) -> int:
"""simple docstring"""
os.makedirs(os.path.dirname(snake_case_ ) , exist_ok=snake_case_ )
# Prevent parallel extractions
__magic_name__ = str(Path(snake_case_ ).with_suffix(""".lock""" ) )
with FileLock(snake_case_ ):
shutil.rmtree(snake_case_ , ignore_errors=snake_case_ )
if extractor_format or extractor != "deprecated":
if extractor != "deprecated" or not isinstance(snake_case_ , snake_case_ ): # passed as positional arg
warnings.warn(
"""Parameter 'extractor' was deprecated in version 2.4.0 and will be removed in 3.0.0. """
"""Use 'extractor_format' instead.""" , category=snake_case_ , )
__magic_name__ = extractor if extractor != """deprecated""" else extractor_format
else:
__magic_name__ = cls.extractors[extractor_format]
return extractor.extract(snake_case_ , snake_case_ )
else:
warnings.warn(
"""Parameter 'extractor_format' was made required in version 2.4.0 and not passing it will raise an """
"""exception in 3.0.0.""" , category=snake_case_ , )
for extractor in cls.extractors.values():
if extractor.is_extractable(snake_case_ ):
return extractor.extract(snake_case_ , snake_case_ )
| 88
|
'''simple docstring'''
from PIL import Image
def __snake_case( _lowerCAmelCase , _lowerCAmelCase ) -> Image:
def brightness(_lowerCAmelCase ) -> float:
return 128 + level + (c - 128)
if not -255.0 <= level <= 255.0:
raise ValueError("""level must be between -255.0 (black) and 255.0 (white)""" )
return img.point(_lowerCAmelCase )
if __name__ == "__main__":
# Load image
with Image.open("image_data/lena.jpg") as img:
# Change brightness to 100
__a = change_brightness(img, 100)
brigt_img.save("image_data/lena_brightness.png", format="png")
| 35
| 0
|
'''simple docstring'''
from arguments import InitializationArguments
from transformers import AutoConfig, AutoModelForCausalLM, AutoTokenizer, HfArgumentParser
# Configuration
lowercase__ : Tuple = HfArgumentParser(InitializationArguments)
lowercase__ : List[str] = parser.parse_args()
# Load codeparrot tokenizer trained for Python code tokenization
lowercase__ : Union[str, Any] = AutoTokenizer.from_pretrained(args.tokenizer_name)
# Config: "scale_attn_by_layer_idx" and "reorder_and_upcast_attn" are Mistral stability tweaks
lowercase__ : str = {
'''vocab_size''': len(tokenizer),
'''scale_attn_by_inverse_layer_idx''': True,
'''reorder_and_upcast_attn''': True,
}
# Load model config (GPT-2 large in this case)
lowercase__ : Tuple = AutoConfig.from_pretrained(args.config_name, **config_kwargs)
# Initialize new model with config
lowercase__ : str = AutoModelForCausalLM.from_config(config)
# Save model to the hub
model.save_pretrained(args.model_name, push_to_hub=args.push_to_hub)
| 190
|
'''simple docstring'''
import argparse
import os
import re
__a = "src/transformers"
# Pattern that looks at the indentation in a line.
__a = re.compile(R"^(\s*)\S")
# Pattern that matches `"key":" and puts `key` in group 0.
__a = re.compile(R"^\s*\"([^\"]+)\":")
# Pattern that matches `_import_structure["key"]` and puts `key` in group 0.
__a = re.compile(R"^\s*_import_structure\[\"([^\"]+)\"\]")
# Pattern that matches `"key",` and puts `key` in group 0.
__a = re.compile(R"^\s*\"([^\"]+)\",\s*$")
# Pattern that matches any `[stuff]` and puts `stuff` in group 0.
__a = re.compile(R"\[([^\]]+)\]")
def __snake_case( _lowerCAmelCase ) -> List[Any]:
snake_case__ : int = _re_indent.search(_lowerCAmelCase )
return "" if search is None else search.groups()[0]
def __snake_case( _lowerCAmelCase , _lowerCAmelCase="" , _lowerCAmelCase=None , _lowerCAmelCase=None ) -> List[str]:
snake_case__ : str = 0
snake_case__ : Union[str, Any] = code.split("""\n""" )
if start_prompt is not None:
while not lines[index].startswith(_lowerCAmelCase ):
index += 1
snake_case__ : Tuple = ["""\n""".join(lines[:index] )]
else:
snake_case__ : List[str] = []
# We split into blocks until we get to the `end_prompt` (or the end of the block).
snake_case__ : Optional[int] = [lines[index]]
index += 1
while index < len(_lowerCAmelCase ) and (end_prompt is None or not lines[index].startswith(_lowerCAmelCase )):
if len(lines[index] ) > 0 and get_indent(lines[index] ) == indent_level:
if len(_lowerCAmelCase ) > 0 and get_indent(current_block[-1] ).startswith(indent_level + """ """ ):
current_block.append(lines[index] )
blocks.append("""\n""".join(_lowerCAmelCase ) )
if index < len(_lowerCAmelCase ) - 1:
snake_case__ : str = [lines[index + 1]]
index += 1
else:
snake_case__ : int = []
else:
blocks.append("""\n""".join(_lowerCAmelCase ) )
snake_case__ : Optional[Any] = [lines[index]]
else:
current_block.append(lines[index] )
index += 1
# Adds current block if it's nonempty.
if len(_lowerCAmelCase ) > 0:
blocks.append("""\n""".join(_lowerCAmelCase ) )
# Add final block after end_prompt if provided.
if end_prompt is not None and index < len(_lowerCAmelCase ):
blocks.append("""\n""".join(lines[index:] ) )
return blocks
def __snake_case( _lowerCAmelCase ) -> Tuple:
def _inner(_lowerCAmelCase ):
return key(_lowerCAmelCase ).lower().replace("""_""" , """""" )
return _inner
def __snake_case( _lowerCAmelCase , _lowerCAmelCase=None ) -> List[Any]:
# If no key is provided, we use a noop.
def noop(_lowerCAmelCase ):
return x
if key is None:
snake_case__ : Optional[int] = noop
# Constants are all uppercase, they go first.
snake_case__ : Optional[int] = [obj for obj in objects if key(_lowerCAmelCase ).isupper()]
# Classes are not all uppercase but start with a capital, they go second.
snake_case__ : int = [obj for obj in objects if key(_lowerCAmelCase )[0].isupper() and not key(_lowerCAmelCase ).isupper()]
# Functions begin with a lowercase, they go last.
snake_case__ : str = [obj for obj in objects if not key(_lowerCAmelCase )[0].isupper()]
snake_case__ : List[str] = ignore_underscore(_lowerCAmelCase )
return sorted(_lowerCAmelCase , key=_lowerCAmelCase ) + sorted(_lowerCAmelCase , key=_lowerCAmelCase ) + sorted(_lowerCAmelCase , key=_lowerCAmelCase )
def __snake_case( _lowerCAmelCase ) -> int:
# This inner function sort imports between [ ].
def _replace(_lowerCAmelCase ):
snake_case__ : Union[str, Any] = match.groups()[0]
if "," not in imports:
return f"[{imports}]"
snake_case__ : int = [part.strip().replace("""\"""" , """""" ) for part in imports.split(""",""" )]
# We will have a final empty element if the line finished with a comma.
if len(keys[-1] ) == 0:
snake_case__ : List[str] = keys[:-1]
return "[" + ", ".join([f"\"{k}\"" for k in sort_objects(_lowerCAmelCase )] ) + "]"
snake_case__ : str = import_statement.split("""\n""" )
if len(_lowerCAmelCase ) > 3:
# Here we have to sort internal imports that are on several lines (one per name):
# key: [
# "object1",
# "object2",
# ...
# ]
# We may have to ignore one or two lines on each side.
snake_case__ : Dict = 2 if lines[1].strip() == """[""" else 1
snake_case__ : str = [(i, _re_strip_line.search(_lowerCAmelCase ).groups()[0]) for i, line in enumerate(lines[idx:-idx] )]
snake_case__ : str = sort_objects(_lowerCAmelCase , key=lambda _lowerCAmelCase : x[1] )
snake_case__ : Union[str, Any] = [lines[x[0] + idx] for x in sorted_indices]
return "\n".join(lines[:idx] + sorted_lines + lines[-idx:] )
elif len(_lowerCAmelCase ) == 3:
# Here we have to sort internal imports that are on one separate line:
# key: [
# "object1", "object2", ...
# ]
if _re_bracket_content.search(lines[1] ) is not None:
snake_case__ : Union[str, Any] = _re_bracket_content.sub(_replace , lines[1] )
else:
snake_case__ : List[Any] = [part.strip().replace("""\"""" , """""" ) for part in lines[1].split(""",""" )]
# We will have a final empty element if the line finished with a comma.
if len(keys[-1] ) == 0:
snake_case__ : List[str] = keys[:-1]
snake_case__ : int = get_indent(lines[1] ) + """, """.join([f"\"{k}\"" for k in sort_objects(_lowerCAmelCase )] )
return "\n".join(_lowerCAmelCase )
else:
# Finally we have to deal with imports fitting on one line
snake_case__ : Optional[Any] = _re_bracket_content.sub(_replace , _lowerCAmelCase )
return import_statement
def __snake_case( _lowerCAmelCase , _lowerCAmelCase=True ) -> Dict:
with open(_lowerCAmelCase , encoding="""utf-8""" ) as f:
snake_case__ : Optional[int] = f.read()
if "_import_structure" not in code:
return
# Blocks of indent level 0
snake_case__ : Optional[int] = split_code_in_indented_blocks(
_lowerCAmelCase , start_prompt="""_import_structure = {""" , end_prompt="""if TYPE_CHECKING:""" )
# We ignore block 0 (everything untils start_prompt) and the last block (everything after end_prompt).
for block_idx in range(1 , len(_lowerCAmelCase ) - 1 ):
# Check if the block contains some `_import_structure`s thingy to sort.
snake_case__ : Optional[Any] = main_blocks[block_idx]
snake_case__ : Dict = block.split("""\n""" )
# Get to the start of the imports.
snake_case__ : Dict = 0
while line_idx < len(_lowerCAmelCase ) and "_import_structure" not in block_lines[line_idx]:
# Skip dummy import blocks
if "import dummy" in block_lines[line_idx]:
snake_case__ : Union[str, Any] = len(_lowerCAmelCase )
else:
line_idx += 1
if line_idx >= len(_lowerCAmelCase ):
continue
# Ignore beginning and last line: they don't contain anything.
snake_case__ : List[str] = """\n""".join(block_lines[line_idx:-1] )
snake_case__ : str = get_indent(block_lines[1] )
# Slit the internal block into blocks of indent level 1.
snake_case__ : Optional[int] = split_code_in_indented_blocks(_lowerCAmelCase , indent_level=_lowerCAmelCase )
# We have two categories of import key: list or _import_structure[key].append/extend
snake_case__ : Tuple = _re_direct_key if """_import_structure = {""" in block_lines[0] else _re_indirect_key
# Grab the keys, but there is a trap: some lines are empty or just comments.
snake_case__ : Optional[Any] = [(pattern.search(_lowerCAmelCase ).groups()[0] if pattern.search(_lowerCAmelCase ) is not None else None) for b in internal_blocks]
# We only sort the lines with a key.
snake_case__ : Dict = [(i, key) for i, key in enumerate(_lowerCAmelCase ) if key is not None]
snake_case__ : Union[str, Any] = [x[0] for x in sorted(_lowerCAmelCase , key=lambda _lowerCAmelCase : x[1] )]
# We reorder the blocks by leaving empty lines/comments as they were and reorder the rest.
snake_case__ : List[Any] = 0
snake_case__ : Optional[Any] = []
for i in range(len(_lowerCAmelCase ) ):
if keys[i] is None:
reorderded_blocks.append(internal_blocks[i] )
else:
snake_case__ : Optional[Any] = sort_objects_in_import(internal_blocks[sorted_indices[count]] )
reorderded_blocks.append(_lowerCAmelCase )
count += 1
# And we put our main block back together with its first and last line.
snake_case__ : Dict = """\n""".join(block_lines[:line_idx] + reorderded_blocks + [block_lines[-1]] )
if code != "\n".join(_lowerCAmelCase ):
if check_only:
return True
else:
print(f"Overwriting {file}." )
with open(_lowerCAmelCase , """w""" , encoding="""utf-8""" ) as f:
f.write("""\n""".join(_lowerCAmelCase ) )
def __snake_case( _lowerCAmelCase=True ) -> Tuple:
snake_case__ : str = []
for root, _, files in os.walk(_lowerCAmelCase ):
if "__init__.py" in files:
snake_case__ : Union[str, Any] = sort_imports(os.path.join(_lowerCAmelCase , """__init__.py""" ) , check_only=_lowerCAmelCase )
if result:
snake_case__ : Union[str, Any] = [os.path.join(_lowerCAmelCase , """__init__.py""" )]
if len(_lowerCAmelCase ) > 0:
raise ValueError(f"Would overwrite {len(_lowerCAmelCase )} files, run `make style`." )
if __name__ == "__main__":
__a = argparse.ArgumentParser()
parser.add_argument("--check_only", action="store_true", help="Whether to only check or fix style.")
__a = parser.parse_args()
sort_imports_in_all_inits(check_only=args.check_only)
| 35
| 0
|
from typing import TYPE_CHECKING
from ...utils import (
OptionalDependencyNotAvailable,
_LazyModule,
is_flax_available,
is_tf_available,
is_tokenizers_available,
is_torch_available,
)
__lowerCAmelCase = {
'''configuration_whisper''': ['''WHISPER_PRETRAINED_CONFIG_ARCHIVE_MAP''', '''WhisperConfig''', '''WhisperOnnxConfig'''],
'''feature_extraction_whisper''': ['''WhisperFeatureExtractor'''],
'''processing_whisper''': ['''WhisperProcessor'''],
'''tokenization_whisper''': ['''WhisperTokenizer'''],
}
try:
if not is_tokenizers_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCAmelCase = ['''WhisperTokenizerFast''']
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCAmelCase = [
'''WHISPER_PRETRAINED_MODEL_ARCHIVE_LIST''',
'''WhisperForConditionalGeneration''',
'''WhisperModel''',
'''WhisperPreTrainedModel''',
'''WhisperForAudioClassification''',
]
try:
if not is_tf_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCAmelCase = [
'''TF_WHISPER_PRETRAINED_MODEL_ARCHIVE_LIST''',
'''TFWhisperForConditionalGeneration''',
'''TFWhisperModel''',
'''TFWhisperPreTrainedModel''',
]
try:
if not is_flax_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCAmelCase = [
'''FlaxWhisperForConditionalGeneration''',
'''FlaxWhisperModel''',
'''FlaxWhisperPreTrainedModel''',
'''FlaxWhisperForAudioClassification''',
]
if TYPE_CHECKING:
from .configuration_whisper import WHISPER_PRETRAINED_CONFIG_ARCHIVE_MAP, WhisperConfig, WhisperOnnxConfig
from .feature_extraction_whisper import WhisperFeatureExtractor
from .processing_whisper import WhisperProcessor
from .tokenization_whisper import WhisperTokenizer
try:
if not is_tokenizers_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .tokenization_whisper_fast import WhisperTokenizerFast
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_whisper import (
WHISPER_PRETRAINED_MODEL_ARCHIVE_LIST,
WhisperForAudioClassification,
WhisperForConditionalGeneration,
WhisperModel,
WhisperPreTrainedModel,
)
try:
if not is_tf_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_tf_whisper import (
TF_WHISPER_PRETRAINED_MODEL_ARCHIVE_LIST,
TFWhisperForConditionalGeneration,
TFWhisperModel,
TFWhisperPreTrainedModel,
)
try:
if not is_flax_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_flax_whisper import (
FlaxWhisperForAudioClassification,
FlaxWhisperForConditionalGeneration,
FlaxWhisperModel,
FlaxWhisperPreTrainedModel,
)
else:
import sys
__lowerCAmelCase = _LazyModule(__name__, globals()['''__file__'''], _import_structure, module_spec=__spec__)
| 196
|
'''simple docstring'''
from typing import TYPE_CHECKING
from ...utils import OptionalDependencyNotAvailable, _LazyModule, is_torch_available
__a = {
"configuration_timesformer": ["TIMESFORMER_PRETRAINED_CONFIG_ARCHIVE_MAP", "TimesformerConfig"],
}
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__a = [
"TIMESFORMER_PRETRAINED_MODEL_ARCHIVE_LIST",
"TimesformerModel",
"TimesformerForVideoClassification",
"TimesformerPreTrainedModel",
]
if TYPE_CHECKING:
from .configuration_timesformer import TIMESFORMER_PRETRAINED_CONFIG_ARCHIVE_MAP, TimesformerConfig
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_timesformer import (
TIMESFORMER_PRETRAINED_MODEL_ARCHIVE_LIST,
TimesformerForVideoClassification,
TimesformerModel,
TimesformerPreTrainedModel,
)
else:
import sys
__a = _LazyModule(__name__, globals()["__file__"], _import_structure, module_spec=__spec__)
| 35
| 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 timm.data import resolve_data_config
from timm.data.transforms_factory import create_transform
from transformers import (
BitConfig,
ViTHybridConfig,
ViTHybridForImageClassification,
ViTHybridImageProcessor,
ViTHybridModel,
)
from transformers.image_utils import PILImageResampling
from transformers.utils import logging
logging.set_verbosity_info()
A : Dict = logging.get_logger(__name__)
def lowercase_ ( _A : Dict , _A : List[Any]=False ):
"""simple docstring"""
lowerCamelCase__ : str = []
# fmt: off
# stem:
rename_keys.append(("cls_token", "vit.embeddings.cls_token") )
rename_keys.append(("pos_embed", "vit.embeddings.position_embeddings") )
rename_keys.append(("patch_embed.proj.weight", "vit.embeddings.patch_embeddings.projection.weight") )
rename_keys.append(("patch_embed.proj.bias", "vit.embeddings.patch_embeddings.projection.bias") )
# backbone
rename_keys.append(("patch_embed.backbone.stem.conv.weight", "vit.embeddings.patch_embeddings.backbone.bit.embedder.convolution.weight") )
rename_keys.append(("patch_embed.backbone.stem.norm.weight", "vit.embeddings.patch_embeddings.backbone.bit.embedder.norm.weight") )
rename_keys.append(("patch_embed.backbone.stem.norm.bias", "vit.embeddings.patch_embeddings.backbone.bit.embedder.norm.bias") )
for stage_idx in range(len(config.backbone_config.depths ) ):
for layer_idx in range(config.backbone_config.depths[stage_idx] ):
rename_keys.append((F"patch_embed.backbone.stages.{stage_idx}.blocks.{layer_idx}.conv1.weight", F"vit.embeddings.patch_embeddings.backbone.bit.encoder.stages.{stage_idx}.layers.{layer_idx}.conv1.weight") )
rename_keys.append((F"patch_embed.backbone.stages.{stage_idx}.blocks.{layer_idx}.norm1.weight", F"vit.embeddings.patch_embeddings.backbone.bit.encoder.stages.{stage_idx}.layers.{layer_idx}.norm1.weight") )
rename_keys.append((F"patch_embed.backbone.stages.{stage_idx}.blocks.{layer_idx}.norm1.bias", F"vit.embeddings.patch_embeddings.backbone.bit.encoder.stages.{stage_idx}.layers.{layer_idx}.norm1.bias") )
rename_keys.append((F"patch_embed.backbone.stages.{stage_idx}.blocks.{layer_idx}.conv2.weight", F"vit.embeddings.patch_embeddings.backbone.bit.encoder.stages.{stage_idx}.layers.{layer_idx}.conv2.weight") )
rename_keys.append((F"patch_embed.backbone.stages.{stage_idx}.blocks.{layer_idx}.norm2.weight", F"vit.embeddings.patch_embeddings.backbone.bit.encoder.stages.{stage_idx}.layers.{layer_idx}.norm2.weight") )
rename_keys.append((F"patch_embed.backbone.stages.{stage_idx}.blocks.{layer_idx}.norm2.bias", F"vit.embeddings.patch_embeddings.backbone.bit.encoder.stages.{stage_idx}.layers.{layer_idx}.norm2.bias") )
rename_keys.append((F"patch_embed.backbone.stages.{stage_idx}.blocks.{layer_idx}.conv3.weight", F"vit.embeddings.patch_embeddings.backbone.bit.encoder.stages.{stage_idx}.layers.{layer_idx}.conv3.weight") )
rename_keys.append((F"patch_embed.backbone.stages.{stage_idx}.blocks.{layer_idx}.norm3.weight", F"vit.embeddings.patch_embeddings.backbone.bit.encoder.stages.{stage_idx}.layers.{layer_idx}.norm3.weight") )
rename_keys.append((F"patch_embed.backbone.stages.{stage_idx}.blocks.{layer_idx}.norm3.bias", F"vit.embeddings.patch_embeddings.backbone.bit.encoder.stages.{stage_idx}.layers.{layer_idx}.norm3.bias") )
rename_keys.append((F"patch_embed.backbone.stages.{stage_idx}.blocks.0.downsample.conv.weight", F"vit.embeddings.patch_embeddings.backbone.bit.encoder.stages.{stage_idx}.layers.0.downsample.conv.weight") )
rename_keys.append((F"patch_embed.backbone.stages.{stage_idx}.blocks.0.downsample.norm.weight", F"vit.embeddings.patch_embeddings.backbone.bit.encoder.stages.{stage_idx}.layers.0.downsample.norm.weight") )
rename_keys.append((F"patch_embed.backbone.stages.{stage_idx}.blocks.0.downsample.norm.bias", F"vit.embeddings.patch_embeddings.backbone.bit.encoder.stages.{stage_idx}.layers.0.downsample.norm.bias") )
# transformer encoder
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") )
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"
lowerCamelCase__ : int = [(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"),
] )
# fmt: on
return rename_keys
def lowercase_ ( _A : Tuple , _A : Optional[int] , _A : Optional[Any]=False ):
"""simple docstring"""
for i in range(config.num_hidden_layers ):
if base_model:
lowerCamelCase__ : Any = """"""
else:
lowerCamelCase__ : str = """vit."""
# read in weights + bias of input projection layer (in timm, this is a single matrix + bias)
lowerCamelCase__ : List[str] = state_dict.pop(F"blocks.{i}.attn.qkv.weight" )
lowerCamelCase__ : int = state_dict.pop(F"blocks.{i}.attn.qkv.bias" )
# next, add query, keys and values (in that order) to the state dict
lowerCamelCase__ : Dict = in_proj_weight[
: config.hidden_size, :
]
lowerCamelCase__ : Optional[int] = in_proj_bias[: config.hidden_size]
lowerCamelCase__ : List[str] = in_proj_weight[
config.hidden_size : config.hidden_size * 2, :
]
lowerCamelCase__ : Dict = in_proj_bias[
config.hidden_size : config.hidden_size * 2
]
lowerCamelCase__ : Tuple = in_proj_weight[
-config.hidden_size :, :
]
lowerCamelCase__ : List[str] = in_proj_bias[-config.hidden_size :]
def lowercase_ ( _A : Optional[Any] ):
"""simple docstring"""
lowerCamelCase__ : int = ["""head.weight""", """head.bias"""]
for k in ignore_keys:
state_dict.pop(_lowerCAmelCase , _lowerCAmelCase )
def lowercase_ ( _A : Optional[Any] , _A : Union[str, Any] , _A : List[Any] ):
"""simple docstring"""
lowerCamelCase__ : List[Any] = dct.pop(_lowerCAmelCase )
lowerCamelCase__ : List[str] = val
def lowercase_ ( ):
"""simple docstring"""
lowerCamelCase__ : Tuple = """http://images.cocodataset.org/val2017/000000039769.jpg"""
lowerCamelCase__ : Optional[Any] = Image.open(requests.get(_lowerCAmelCase , stream=_lowerCAmelCase ).raw )
return im
@torch.no_grad()
def lowercase_ ( _A : Dict , _A : str , _A : str=False ):
"""simple docstring"""
lowerCamelCase__ : List[str] = BitConfig(
global_padding="same" , layer_type="bottleneck" , depths=(3, 4, 9) , out_features=["stage3"] , embedding_dynamic_padding=_lowerCAmelCase , )
lowerCamelCase__ : Optional[Any] = ViTHybridConfig(backbone_config=_lowerCAmelCase , image_size=384 , num_labels=1000 )
lowerCamelCase__ : Union[str, Any] = False
# load original model from timm
lowerCamelCase__ : Union[str, Any] = timm.create_model(_lowerCAmelCase , pretrained=_lowerCAmelCase )
timm_model.eval()
# load state_dict of original model, remove and rename some keys
lowerCamelCase__ : Optional[int] = timm_model.state_dict()
if base_model:
remove_classification_head_(_lowerCAmelCase )
lowerCamelCase__ : Any = create_rename_keys(_lowerCAmelCase , _lowerCAmelCase )
for src, dest in rename_keys:
rename_key(_lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase )
read_in_q_k_v(_lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase )
lowerCamelCase__ : str = """huggingface/label-files"""
lowerCamelCase__ : str = """imagenet-1k-id2label.json"""
lowerCamelCase__ : List[str] = json.load(open(hf_hub_download(_lowerCAmelCase , _lowerCAmelCase , repo_type="dataset" ) , "r" ) )
lowerCamelCase__ : Dict = {int(_lowerCAmelCase ): v for k, v in idalabel.items()}
lowerCamelCase__ : Tuple = idalabel
lowerCamelCase__ : List[str] = {v: k for k, v in idalabel.items()}
# load HuggingFace model
if vit_name[-5:] == "in21k":
lowerCamelCase__ : Tuple = ViTHybridModel(_lowerCAmelCase ).eval()
else:
lowerCamelCase__ : str = ViTHybridForImageClassification(_lowerCAmelCase ).eval()
model.load_state_dict(_lowerCAmelCase )
# create image processor
lowerCamelCase__ : int = create_transform(**resolve_data_config({} , model=_lowerCAmelCase ) )
lowerCamelCase__ : List[str] = transform.transforms
lowerCamelCase__ : List[str] = {
"""bilinear""": PILImageResampling.BILINEAR,
"""bicubic""": PILImageResampling.BICUBIC,
"""nearest""": PILImageResampling.NEAREST,
}
lowerCamelCase__ : Optional[int] = ViTHybridImageProcessor(
do_resize=_lowerCAmelCase , size={"shortest_edge": timm_transforms[0].size} , resample=pillow_resamplings[timm_transforms[0].interpolation.value] , do_center_crop=_lowerCAmelCase , crop_size={"height": timm_transforms[1].size[0], "width": timm_transforms[1].size[1]} , do_normalize=_lowerCAmelCase , image_mean=timm_transforms[-1].mean.tolist() , image_std=timm_transforms[-1].std.tolist() , )
lowerCamelCase__ : Union[str, Any] = prepare_img()
lowerCamelCase__ : Dict = transform(_lowerCAmelCase ).unsqueeze(0 )
lowerCamelCase__ : int = processor(_lowerCAmelCase , return_tensors="pt" ).pixel_values
# verify pixel values
assert torch.allclose(_lowerCAmelCase , _lowerCAmelCase )
# verify logits
with torch.no_grad():
lowerCamelCase__ : Optional[Any] = model(_lowerCAmelCase )
lowerCamelCase__ : List[Any] = outputs.logits
print("Predicted class:" , logits.argmax(-1 ).item() )
if base_model:
lowerCamelCase__ : List[str] = timm_model.forward_features(_lowerCAmelCase )
assert timm_pooled_output.shape == outputs.pooler_output.shape
assert torch.allclose(_lowerCAmelCase , outputs.pooler_output , atol=1E-3 )
else:
lowerCamelCase__ : Any = timm_model(_lowerCAmelCase )
assert timm_logits.shape == outputs.logits.shape
assert torch.allclose(_lowerCAmelCase , outputs.logits , atol=1E-3 )
print("Looks ok!" )
if pytorch_dump_folder_path is not None:
Path(_lowerCAmelCase ).mkdir(exist_ok=_lowerCAmelCase )
print(F"Saving model {vit_name} to {pytorch_dump_folder_path}" )
model.save_pretrained(_lowerCAmelCase )
print(F"Saving processor to {pytorch_dump_folder_path}" )
processor.save_pretrained(_lowerCAmelCase )
if push_to_hub:
print(F"Pushing model and processor to the hub {vit_name}" )
model.push_to_hub(F"ybelkada/{vit_name}" )
processor.push_to_hub(F"ybelkada/{vit_name}" )
if __name__ == "__main__":
A : Union[str, Any] = argparse.ArgumentParser()
# Required parameters
parser.add_argument(
"--vit_name",
default="vit_base_r50_s16_384",
type=str,
help="Name of the hybrid 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."
)
parser.add_argument(
"--push_to_hub", action="store_true", help="Whether to upload the model to the HuggingFace hub."
)
A : Dict = parser.parse_args()
convert_vit_checkpoint(args.vit_name, args.pytorch_dump_folder_path, args.push_to_hub)
| 184
|
'''simple docstring'''
import argparse
import json
import os
import fairseq
import torch
from torch import nn
from transformers import (
SpeechaTextaConfig,
SpeechaTextaForCausalLM,
SpeechaTextaTokenizer,
SpeechEncoderDecoderConfig,
SpeechEncoderDecoderModel,
WavaVecaConfig,
WavaVecaFeatureExtractor,
WavaVecaModel,
logging,
)
logging.set_verbosity_info()
__a = logging.get_logger(__name__)
__a = {
"post_extract_proj": "feature_projection.projection",
"encoder.pos_conv.0": "encoder.pos_conv_embed.conv",
"self_attn.k_proj": "encoder.layers.*.attention.k_proj",
"self_attn.v_proj": "encoder.layers.*.attention.v_proj",
"self_attn.q_proj": "encoder.layers.*.attention.q_proj",
"self_attn.out_proj": "encoder.layers.*.attention.out_proj",
"self_attn_layer_norm": "encoder.layers.*.layer_norm",
"fc1": "encoder.layers.*.feed_forward.intermediate_dense",
"fc2": "encoder.layers.*.feed_forward.output_dense",
"final_layer_norm": "encoder.layers.*.final_layer_norm",
"encoder.layer_norm": "encoder.layer_norm",
"w2v_model.layer_norm": "feature_projection.layer_norm",
"quantizer.weight_proj": "quantizer.weight_proj",
"quantizer.vars": "quantizer.codevectors",
"project_q": "project_q",
"final_proj": "project_hid",
"w2v_encoder.proj": "lm_head",
"mask_emb": "masked_spec_embed",
}
__a = [
"lm_head",
"quantizer.weight_proj",
"quantizer.codevectors",
"project_q",
"project_hid",
]
def __snake_case( _lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase ) -> Union[str, Any]:
for attribute in key.split(""".""" ):
snake_case__ : Dict = getattr(_lowerCAmelCase , _lowerCAmelCase )
if weight_type is not None:
snake_case__ : List[Any] = getattr(_lowerCAmelCase , _lowerCAmelCase ).shape
else:
snake_case__ : 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":
snake_case__ : int = value
elif weight_type == "weight_g":
snake_case__ : List[str] = value
elif weight_type == "weight_v":
snake_case__ : List[str] = value
elif weight_type == "bias":
snake_case__ : Optional[Any] = value
else:
snake_case__ : str = value
logger.info(f"{key + '.' + weight_type if weight_type is not None else ''} was initialized from {full_name}." )
def __snake_case( _lowerCAmelCase , _lowerCAmelCase ) -> Any:
snake_case__ : Union[str, Any] = []
snake_case__ : Dict = fairseq_model.state_dict()
snake_case__ : List[Any] = hf_model.feature_extractor
# if encoder has different dim to decoder -> use proj_weight
snake_case__ : Optional[int] = None
for name, value in fairseq_dict.items():
snake_case__ : List[Any] = False
if "conv_layers" in name:
load_conv_layer(
_lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase , hf_model.config.feat_extract_norm == """group""" , )
snake_case__ : Union[str, Any] = True
elif name.split(""".""" )[0] == "proj":
snake_case__ : Tuple = fairseq_model.proj
snake_case__ : int = True
else:
for key, mapped_key in MAPPING.items():
if key in name or key.split("""w2v_model.""" )[-1] == name.split(""".""" )[0]:
snake_case__ : Optional[Any] = True
if "*" in mapped_key:
snake_case__ : Optional[int] = name.split(_lowerCAmelCase )[0].split(""".""" )[-2]
snake_case__ : Tuple = mapped_key.replace("""*""" , _lowerCAmelCase )
if "weight_g" in name:
snake_case__ : str = """weight_g"""
elif "weight_v" in name:
snake_case__ : int = """weight_v"""
elif "bias" in name:
snake_case__ : Dict = """bias"""
elif "weight" in name:
snake_case__ : Union[str, Any] = """weight"""
else:
snake_case__ : Union[str, Any] = None
set_recursively(_lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase )
continue
if not is_used:
unused_weights.append(_lowerCAmelCase )
logger.warning(f"Unused weights: {unused_weights}" )
return proj_weight
def __snake_case( _lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase ) -> Dict:
snake_case__ : int = full_name.split("""conv_layers.""" )[-1]
snake_case__ : Dict = name.split(""".""" )
snake_case__ : Any = int(items[0] )
snake_case__ : Optional[Any] = int(items[1] )
if type_id == 0:
if "bias" in name:
assert value.shape == feature_extractor.conv_layers[layer_id].conv.bias.data.shape, (
f"{full_name} has size {value.shape}, but"
f" {feature_extractor.conv_layers[layer_id].conv.bias.data.shape} was found."
)
snake_case__ : int = value
logger.info(f"Feat extract conv layer {layer_id} was initialized from {full_name}." )
elif "weight" in name:
assert value.shape == feature_extractor.conv_layers[layer_id].conv.weight.data.shape, (
f"{full_name} has size {value.shape}, but"
f" {feature_extractor.conv_layers[layer_id].conv.weight.data.shape} was found."
)
snake_case__ : str = value
logger.info(f"Feat extract conv layer {layer_id} was initialized from {full_name}." )
elif (type_id == 2 and not use_group_norm) or (type_id == 2 and layer_id == 0 and use_group_norm):
if "bias" in name:
assert value.shape == feature_extractor.conv_layers[layer_id].layer_norm.bias.data.shape, (
f"{full_name} has size {value.shape}, but {feature_extractor[layer_id].layer_norm.bias.data.shape} was"
" found."
)
snake_case__ : Union[str, Any] = value
logger.info(f"Feat extract layer norm weight of layer {layer_id} was initialized from {full_name}." )
elif "weight" in name:
assert value.shape == feature_extractor.conv_layers[layer_id].layer_norm.weight.data.shape, (
f"{full_name} has size {value.shape}, but"
f" {feature_extractor[layer_id].layer_norm.weight.data.shape} was found."
)
snake_case__ : int = value
logger.info(f"Feat extract layer norm weight of layer {layer_id} was initialized from {full_name}." )
else:
unused_weights.append(_lowerCAmelCase )
def __snake_case( _lowerCAmelCase ) -> List[str]:
snake_case__ , snake_case__ : str = emb.weight.shape
snake_case__ : List[str] = nn.Linear(_lowerCAmelCase , _lowerCAmelCase , bias=_lowerCAmelCase )
snake_case__ : List[str] = emb.weight.data
return lin_layer
def __snake_case( _lowerCAmelCase ) -> Optional[Any]:
with open(_lowerCAmelCase , """r""" , encoding="""utf-8""" ) as f:
snake_case__ : int = f.readlines()
snake_case__ : List[Any] = [line.split(""" """ )[0] for line in lines]
snake_case__ : Union[str, Any] = len(_lowerCAmelCase )
snake_case__ : Any = {
"""<s>""": 0,
"""<pad>""": 1,
"""</s>""": 2,
"""<unk>""": 3,
}
vocab_dict.update(dict(zip(_lowerCAmelCase , range(4 , num_words + 4 ) ) ) )
return vocab_dict
@torch.no_grad()
def __snake_case( _lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase , ) -> int:
snake_case__ : Optional[Any] = WavaVecaConfig.from_pretrained(_lowerCAmelCase )
snake_case__ : Optional[Any] = SpeechaTextaConfig.from_pretrained(
_lowerCAmelCase , vocab_size=_lowerCAmelCase , decoder_layers=_lowerCAmelCase , do_stable_layer_norm=_lowerCAmelCase )
snake_case__ : Optional[Any] = WavaVecaFeatureExtractor(
feature_size=1 , sampling_rate=16_000 , padding_value=0 , do_normalize=_lowerCAmelCase , return_attention_mask=_lowerCAmelCase , )
snake_case__ , snake_case__ , snake_case__ : Union[str, Any] = fairseq.checkpoint_utils.load_model_ensemble_and_task(
[checkpoint_path] , arg_overrides={"""data""": """/""".join(dict_path.split("""/""" )[:-1] )} )
snake_case__ : Tuple = model[0].eval()
# set weights for wav2vec2 encoder
snake_case__ : Optional[Any] = WavaVecaModel(_lowerCAmelCase )
snake_case__ : Dict = recursively_load_weights_wavaveca(model.encoder , _lowerCAmelCase )
snake_case__ : Optional[Any] = SpeechaTextaForCausalLM(_lowerCAmelCase )
snake_case__ , snake_case__ : Tuple = hf_decoder.model.decoder.load_state_dict(model.decoder.state_dict() , strict=_lowerCAmelCase )
# set output linear layer
unexpected_keys.remove("""embed_out""" )
snake_case__ : Tuple = nn.Parameter(model.decoder.embed_out.detach() )
# layer norm is init to identity matrix so leaving it is fine
logger.warning(f"The following keys are missing when loading the decoder weights: {missing_keys}" )
logger.warning(f"The following keys are unexpected when loading the decoder weights: {unexpected_keys}" )
snake_case__ : List[Any] = SpeechEncoderDecoderModel(encoder=_lowerCAmelCase , decoder=_lowerCAmelCase )
snake_case__ : Tuple = False
# add projection layer
snake_case__ : Union[str, Any] = nn.Parameter(projection_layer.weight )
snake_case__ : int = nn.Parameter(projection_layer.bias )
snake_case__ : Tuple = create_vocab_dict(_lowerCAmelCase )
with open(os.path.join(_lowerCAmelCase , """vocab.json""" ) , """w""" ) as fp:
json.dump(_lowerCAmelCase , _lowerCAmelCase )
snake_case__ : Tuple = SpeechaTextaTokenizer(os.path.join(_lowerCAmelCase , """vocab.json""" ) )
tokenizer.save_pretrained(_lowerCAmelCase )
snake_case__ : Optional[Any] = hf_wavavec.config.to_dict()
snake_case__ : Tuple = tokenizer.pad_token_id
snake_case__ : Optional[Any] = tokenizer.bos_token_id
snake_case__ : int = tokenizer.eos_token_id
snake_case__ : str = """speech_to_text_2"""
snake_case__ : List[Any] = """wav2vec2"""
snake_case__ : List[str] = SpeechEncoderDecoderConfig.from_dict(_lowerCAmelCase )
hf_wavavec.save_pretrained(_lowerCAmelCase )
feature_extractor.save_pretrained(_lowerCAmelCase )
if __name__ == "__main__":
__a = argparse.ArgumentParser()
parser.add_argument("--pytorch_dump_folder_path", default=None, type=str, help="Path to the output PyTorch model.")
parser.add_argument("--checkpoint_path", default=None, type=str, help="Path to fairseq checkpoint")
parser.add_argument("--dict_path", default=None, type=str, help="Path to dict of fine-tuned model")
parser.add_argument(
"--encoder_config_path",
default="facebook/wav2vec2-large-lv60",
type=str,
help="Path to hf encoder wav2vec2 checkpoint config",
)
parser.add_argument(
"--decoder_config_path",
default="facebook/s2t-small-mustc-en-fr-st",
type=str,
help="Path to hf decoder s2t checkpoint config",
)
parser.add_argument("--vocab_size", default=1_0224, type=int, help="Vocab size of decoder")
parser.add_argument("--num_decoder_layers", default=7, type=int, help="Number of decoder layers")
__a = parser.parse_args()
convert_wavaveca_checkpoint(
args.checkpoint_path,
args.pytorch_dump_folder_path,
args.dict_path,
encoder_config_path=args.encoder_config_path,
decoder_config_path=args.decoder_config_path,
vocab_size=args.vocab_size,
num_decoder_layers=args.num_decoder_layers,
)
| 35
| 0
|
'''simple docstring'''
from __future__ import annotations
def lowerCAmelCase (__A):
"""simple docstring"""
for i in range(1 , len(matrix[0])):
matrix[0][i] += matrix[0][i - 1]
# preprocessing the first column
for i in range(1 , len(_lowerCAmelCase)):
matrix[i][0] += matrix[i - 1][0]
# updating the path cost for current position
for i in range(1 , len(_lowerCAmelCase)):
for j in range(1 , len(matrix[0])):
matrix[i][j] += min(matrix[i - 1][j] , matrix[i][j - 1])
return matrix[-1][-1]
if __name__ == "__main__":
import doctest
doctest.testmod()
| 211
|
'''simple docstring'''
import importlib
import os
import sys
# This is required to make the module import works (when the python process is running from the root of the repo)
sys.path.append(".")
def __snake_case( _lowerCAmelCase ) -> int:
snake_case__ : Optional[int] = test_file.split(os.path.sep )
if components[0:2] != ["tests", "models"]:
raise ValueError(
"""`test_file` should start with `tests/models/` (with `/` being the OS specific path separator). Got """
f"{test_file} instead." )
snake_case__ : Dict = components[-1]
if not test_fn.endswith("""py""" ):
raise ValueError(f"`test_file` should be a python file. Got {test_fn} instead." )
if not test_fn.startswith("""test_modeling_""" ):
raise ValueError(
f"`test_file` should point to a file name of the form `test_modeling_*.py`. Got {test_fn} instead." )
snake_case__ : int = components[:-1] + [test_fn.replace(""".py""" , """""" )]
snake_case__ : int = """.""".join(_lowerCAmelCase )
return test_module_path
def __snake_case( _lowerCAmelCase ) -> List[str]:
snake_case__ : str = get_module_path(_lowerCAmelCase )
snake_case__ : Union[str, Any] = importlib.import_module(_lowerCAmelCase )
return test_module
def __snake_case( _lowerCAmelCase ) -> int:
snake_case__ : List[Any] = []
snake_case__ : Optional[int] = get_test_module(_lowerCAmelCase )
for attr in dir(_lowerCAmelCase ):
if attr.endswith("""ModelTester""" ):
tester_classes.append(getattr(_lowerCAmelCase , _lowerCAmelCase ) )
# sort with class names
return sorted(_lowerCAmelCase , key=lambda _lowerCAmelCase : x.__name__ )
def __snake_case( _lowerCAmelCase ) -> Dict:
snake_case__ : List[str] = []
snake_case__ : Any = get_test_module(_lowerCAmelCase )
for attr in dir(_lowerCAmelCase ):
snake_case__ : Dict = getattr(_lowerCAmelCase , _lowerCAmelCase )
# (TF/Flax)ModelTesterMixin is also an attribute in specific model test module. Let's exclude them by checking
# `all_model_classes` is not empty (which also excludes other special classes).
snake_case__ : List[str] = getattr(_lowerCAmelCase , """all_model_classes""" , [] )
if len(_lowerCAmelCase ) > 0:
test_classes.append(_lowerCAmelCase )
# sort with class names
return sorted(_lowerCAmelCase , key=lambda _lowerCAmelCase : x.__name__ )
def __snake_case( _lowerCAmelCase ) -> Dict:
snake_case__ : Any = get_test_classes(_lowerCAmelCase )
snake_case__ : Optional[Any] = set()
for test_class in test_classes:
model_classes.update(test_class.all_model_classes )
# sort with class names
return sorted(_lowerCAmelCase , key=lambda _lowerCAmelCase : x.__name__ )
def __snake_case( _lowerCAmelCase ) -> Optional[Any]:
snake_case__ : Optional[int] = test_class()
if hasattr(_lowerCAmelCase , """setUp""" ):
test.setUp()
snake_case__ : Any = None
if hasattr(_lowerCAmelCase , """model_tester""" ):
# `(TF/Flax)ModelTesterMixin` has this attribute default to `None`. Let's skip this case.
if test.model_tester is not None:
snake_case__ : Tuple = test.model_tester.__class__
return model_tester
def __snake_case( _lowerCAmelCase , _lowerCAmelCase ) -> Dict:
snake_case__ : Union[str, Any] = get_test_classes(_lowerCAmelCase )
snake_case__ : str = []
for test_class in test_classes:
if model_class in test_class.all_model_classes:
target_test_classes.append(_lowerCAmelCase )
# sort with class names
return sorted(_lowerCAmelCase , key=lambda _lowerCAmelCase : x.__name__ )
def __snake_case( _lowerCAmelCase , _lowerCAmelCase ) -> Tuple:
snake_case__ : Optional[Any] = get_test_classes_for_model(_lowerCAmelCase , _lowerCAmelCase )
snake_case__ : Union[str, Any] = []
for test_class in test_classes:
snake_case__ : Tuple = get_model_tester_from_test_class(_lowerCAmelCase )
if tester_class is not None:
tester_classes.append(_lowerCAmelCase )
# sort with class names
return sorted(_lowerCAmelCase , key=lambda _lowerCAmelCase : x.__name__ )
def __snake_case( _lowerCAmelCase ) -> Union[str, Any]:
snake_case__ : Optional[Any] = get_test_classes(_lowerCAmelCase )
snake_case__ : Union[str, Any] = {test_class: get_model_tester_from_test_class(_lowerCAmelCase ) for test_class in test_classes}
return test_tester_mapping
def __snake_case( _lowerCAmelCase ) -> int:
snake_case__ : Any = get_model_classes(_lowerCAmelCase )
snake_case__ : Any = {
model_class: get_test_classes_for_model(_lowerCAmelCase , _lowerCAmelCase ) for model_class in model_classes
}
return model_test_mapping
def __snake_case( _lowerCAmelCase ) -> Optional[int]:
snake_case__ : Union[str, Any] = get_model_classes(_lowerCAmelCase )
snake_case__ : str = {
model_class: get_tester_classes_for_model(_lowerCAmelCase , _lowerCAmelCase ) for model_class in model_classes
}
return model_to_tester_mapping
def __snake_case( _lowerCAmelCase ) -> int:
if isinstance(_lowerCAmelCase , _lowerCAmelCase ):
return o
elif isinstance(_lowerCAmelCase , _lowerCAmelCase ):
return o.__name__
elif isinstance(_lowerCAmelCase , (list, tuple) ):
return [to_json(_lowerCAmelCase ) for x in o]
elif isinstance(_lowerCAmelCase , _lowerCAmelCase ):
return {to_json(_lowerCAmelCase ): to_json(_lowerCAmelCase ) for k, v in o.items()}
else:
return o
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import os
import jsonlines
import numpy as np
from tqdm import tqdm
lowercase_ = 2_0_4_8
lowercase_ = 4_0_9_6
lowercase_ = 4_2
lowercase_ = os.environ.pop('PROCESS_TRAIN', 'false')
lowercase_ = {'null': 0, 'short': 1, 'long': 2, 'yes': 3, 'no': 4}
def a ( A__ : int ) -> Union[str, Any]:
"""simple docstring"""
def choose_first(A__ : Dict , A__ : int=False ):
assert isinstance(_lowerCAmelCase , _lowerCAmelCase )
if len(_lowerCAmelCase ) == 1:
_lowercase =answer[0]
return {k: [answer[k]] for k in answer} if is_long_answer else answer
for a in answer:
if is_long_answer:
_lowercase ={k: [a[k]] for k in a}
if len(a['start_token'] ) > 0:
break
return a
_lowercase ={"""id""": example["""id"""]}
_lowercase =example["""annotations"""]
_lowercase =annotation["""yes_no_answer"""]
if 0 in yes_no_answer or 1 in yes_no_answer:
_lowercase =["""yes"""] if 1 in yes_no_answer else ["""no"""]
_lowercase =[]
_lowercase =[]
_lowercase =["""<cls>"""]
else:
_lowercase =["""short"""]
_lowercase =choose_first(annotation['short_answers'] )
if len(out['start_token'] ) == 0:
# answer will be long if short is not available
_lowercase =["""long"""]
_lowercase =choose_first(annotation['long_answer'] , is_long_answer=_lowerCAmelCase )
_lowercase =[]
answer.update(_lowerCAmelCase )
# disregard some samples
if len(answer['start_token'] ) > 1 or answer["start_token"] == answer["end_token"]:
_lowercase =True
else:
_lowercase =False
_lowercase =["""start_token""", """end_token""", """start_byte""", """end_byte""", """text"""]
if not all(isinstance(answer[k] , _lowerCAmelCase ) for k in cols ):
raise ValueError('Issue in ID' , example['id'] )
return answer
def a ( A__ : Dict , A__ : List[Any]=False ) -> List[Any]:
"""simple docstring"""
_lowercase =_get_single_answer(_lowerCAmelCase )
# bytes are of no use
del answer["start_byte"]
del answer["end_byte"]
# handle yes_no answers explicitly
if answer["category"][0] in ["yes", "no"]: # category is list with one element
_lowercase =example["""document"""]["""tokens"""]
_lowercase =[]
for i in range(len(doc['token'] ) ):
if not doc["is_html"][i]:
context.append(doc['token'][i] )
return {
"context": " ".join(_lowerCAmelCase ),
"answer": {
"start_token": -100, # ignore index in cross-entropy
"end_token": -100, # ignore index in cross-entropy
"category": answer["category"],
"span": answer["category"], # extra
},
}
# later, help in removing all no answers
if answer["start_token"] == [-1]:
return {
"context": "None",
"answer": {
"start_token": -1,
"end_token": -1,
"category": "null",
"span": "None", # extra
},
}
# handling normal samples
_lowercase =["""start_token""", """end_token"""]
answer.update({k: answer[k][0] if len(answer[k] ) > 0 else answer[k] for k in cols} ) # e.g. [10] == 10
_lowercase =example["""document"""]["""tokens"""]
_lowercase =answer["""start_token"""]
_lowercase =answer["""end_token"""]
_lowercase =[]
for i in range(len(doc['token'] ) ):
if not doc["is_html"][i]:
context.append(doc['token'][i] )
else:
if answer["start_token"] > i:
start_token -= 1
if answer["end_token"] > i:
end_token -= 1
_lowercase =""" """.join(context[start_token:end_token] )
# checking above code
if assertion:
_lowercase =doc["""is_html"""][answer["""start_token"""] : answer["""end_token"""]]
_lowercase =doc["""token"""][answer["""start_token"""] : answer["""end_token"""]]
_lowercase =""" """.join([old[i] for i in range(len(_lowerCAmelCase ) ) if not is_html[i]] )
if new != old:
print('ID:' , example['id'] )
print('New:' , _lowerCAmelCase , end='\n' )
print('Old:' , _lowerCAmelCase , end='\n\n' )
return {
"context": " ".join(_lowerCAmelCase ),
"answer": {
"start_token": start_token,
"end_token": end_token - 1, # this makes it inclusive
"category": answer["category"], # either long or short
"span": new, # extra
},
}
def a ( A__ : Tuple , A__ : List[Any] , A__ : str=2048 , A__ : int=4096 , A__ : List[str]=True ) -> Optional[Any]:
"""simple docstring"""
_lowercase =get_context_and_ans(_lowerCAmelCase , assertion=_lowerCAmelCase )
_lowercase =out["""answer"""]
# later, removing these samples
if answer["start_token"] == -1:
return {
"example_id": example["id"],
"input_ids": [[-1]],
"labels": {
"start_token": [-1],
"end_token": [-1],
"category": ["null"],
},
}
_lowercase =tokenizer(example['question']['text'] , out['context'] ).input_ids
_lowercase =input_ids.index(tokenizer.sep_token_id ) + 1
# return yes/no
if answer["category"][0] in ["yes", "no"]: # category is list with one element
_lowercase =[]
_lowercase =[]
_lowercase =input_ids[:q_len]
_lowercase =range(_lowerCAmelCase , len(_lowerCAmelCase ) , max_length - doc_stride )
for i in doc_start_indices:
_lowercase =i + max_length - q_len
_lowercase =input_ids[i:end_index]
inputs.append(q_indices + slice )
category.append(answer['category'][0] )
if slice[-1] == tokenizer.sep_token_id:
break
return {
"example_id": example["id"],
"input_ids": inputs,
"labels": {
"start_token": [-100] * len(_lowerCAmelCase ),
"end_token": [-100] * len(_lowerCAmelCase ),
"category": category,
},
}
_lowercase =out["""context"""].split()
_lowercase =splitted_context[answer["""end_token"""]]
_lowercase =len(
tokenizer(
' '.join(splitted_context[: answer['start_token']] ) , add_special_tokens=_lowerCAmelCase , ).input_ids )
_lowercase =len(
tokenizer(' '.join(splitted_context[: answer['end_token']] ) , add_special_tokens=_lowerCAmelCase ).input_ids )
answer["start_token"] += q_len
answer["end_token"] += q_len
# fixing end token
_lowercase =len(tokenizer(_lowerCAmelCase , add_special_tokens=_lowerCAmelCase ).input_ids )
if num_sub_tokens > 1:
answer["end_token"] += num_sub_tokens - 1
_lowercase =input_ids[answer["""start_token"""] : answer["""end_token"""] + 1] # right & left are inclusive
_lowercase =answer["""start_token"""]
_lowercase =answer["""end_token"""]
if assertion:
_lowercase =tokenizer.decode(_lowerCAmelCase )
if answer["span"] != new:
print('ISSUE IN TOKENIZATION' )
print('OLD:' , answer['span'] )
print('NEW:' , _lowerCAmelCase , end='\n\n' )
if len(_lowerCAmelCase ) <= max_length:
return {
"example_id": example["id"],
"input_ids": [input_ids],
"labels": {
"start_token": [answer["start_token"]],
"end_token": [answer["end_token"]],
"category": answer["category"],
},
}
_lowercase =input_ids[:q_len]
_lowercase =range(_lowerCAmelCase , len(_lowerCAmelCase ) , max_length - doc_stride )
_lowercase =[]
_lowercase =[]
_lowercase =[]
_lowercase =[] # null, yes, no, long, short
for i in doc_start_indices:
_lowercase =i + max_length - q_len
_lowercase =input_ids[i:end_index]
inputs.append(q_indices + slice )
assert len(inputs[-1] ) <= max_length, "Issue in truncating length"
if start_token >= i and end_token <= end_index - 1:
_lowercase =start_token - i + q_len
_lowercase =end_token - i + q_len
answers_category.append(answer['category'][0] ) # ["short"] -> "short"
else:
_lowercase =-100
_lowercase =-100
answers_category.append('null' )
_lowercase =inputs[-1][start_token : end_token + 1]
answers_start_token.append(_lowerCAmelCase )
answers_end_token.append(_lowerCAmelCase )
if assertion:
if new != old and new != [tokenizer.cls_token_id]:
print('ISSUE in strided for ID:' , example['id'] )
print('New:' , tokenizer.decode(_lowerCAmelCase ) )
print('Old:' , tokenizer.decode(_lowerCAmelCase ) , end='\n\n' )
if slice[-1] == tokenizer.sep_token_id:
break
return {
"example_id": example["id"],
"input_ids": inputs,
"labels": {
"start_token": answers_start_token,
"end_token": answers_end_token,
"category": answers_category,
},
}
def a ( A__ : Optional[int] , A__ : Union[str, Any] , A__ : List[str]=2048 , A__ : Union[str, Any]=4096 , A__ : List[str]=False ) -> Optional[Any]:
"""simple docstring"""
_lowercase =get_strided_contexts_and_ans(
_lowerCAmelCase , _lowerCAmelCase , doc_stride=_lowerCAmelCase , max_length=_lowerCAmelCase , assertion=_lowerCAmelCase , )
return example
def a ( A__ : Optional[Any] , A__ : Any ) -> Union[str, Any]:
"""simple docstring"""
with jsonlines.open(_lowerCAmelCase , 'a' ) as writer:
for example in tqdm(_lowerCAmelCase , total=len(_lowerCAmelCase ) , desc='Saving samples ... ' ):
_lowercase =example["""labels"""]
for ids, start, end, cat in zip(
example['input_ids'] , labels['start_token'] , labels['end_token'] , labels['category'] , ):
if start == -1 and end == -1:
continue # leave waste samples with no answer
if cat == "null" and np.random.rand() < 0.6:
continue # removing 50 % samples
writer.write(
{
'input_ids': ids,
'start_token': start,
'end_token': end,
'category': CATEGORY_MAPPING[cat],
} )
if __name__ == "__main__":
from datasets import load_dataset
from transformers import BigBirdTokenizer
lowercase_ = load_dataset('natural_questions')
lowercase_ = BigBirdTokenizer.from_pretrained('google/bigbird-roberta-base')
lowercase_ = data['train' if PROCESS_TRAIN == 'true' else 'validation']
lowercase_ = {
'tokenizer': tokenizer,
'doc_stride': DOC_STRIDE,
'max_length': MAX_LENGTH,
'assertion': False,
}
lowercase_ = data.map(prepare_inputs, fn_kwargs=fn_kwargs)
lowercase_ = data.remove_columns(['annotations', 'document', 'id', 'question'])
print(data)
np.random.seed(SEED)
lowercase_ = 'nq-training.jsonl' if PROCESS_TRAIN == 'true' else 'nq-validation.jsonl'
save_to_disk(data, file_name=cache_file_name)
| 205
|
'''simple docstring'''
import argparse
import json
import requests
import timm
import torch
from huggingface_hub import hf_hub_download
from PIL import Image
from transformers import AutoImageProcessor, SwinConfig, SwinForImageClassification
def __snake_case( _lowerCAmelCase ) -> List[Any]:
snake_case__ : Dict = SwinConfig()
snake_case__ : Optional[Any] = swin_name.split("""_""" )
snake_case__ : Any = name_split[1]
snake_case__ : List[Any] = int(name_split[4] )
snake_case__ : int = int(name_split[3][-1] )
if model_size == "tiny":
snake_case__ : List[Any] = 96
snake_case__ : int = (2, 2, 6, 2)
snake_case__ : int = (3, 6, 12, 24)
elif model_size == "small":
snake_case__ : Union[str, Any] = 96
snake_case__ : Optional[Any] = (2, 2, 18, 2)
snake_case__ : str = (3, 6, 12, 24)
elif model_size == "base":
snake_case__ : Dict = 128
snake_case__ : str = (2, 2, 18, 2)
snake_case__ : Dict = (4, 8, 16, 32)
else:
snake_case__ : List[str] = 192
snake_case__ : str = (2, 2, 18, 2)
snake_case__ : List[Any] = (6, 12, 24, 48)
if "in22k" in swin_name:
snake_case__ : str = 21_841
else:
snake_case__ : List[str] = 1_000
snake_case__ : int = """huggingface/label-files"""
snake_case__ : Any = """imagenet-1k-id2label.json"""
snake_case__ : List[Any] = json.load(open(hf_hub_download(_lowerCAmelCase , _lowerCAmelCase , repo_type="""dataset""" ) , """r""" ) )
snake_case__ : Dict = {int(_lowerCAmelCase ): v for k, v in idalabel.items()}
snake_case__ : Optional[int] = idalabel
snake_case__ : List[Any] = {v: k for k, v in idalabel.items()}
snake_case__ : List[Any] = img_size
snake_case__ : Dict = num_classes
snake_case__ : Dict = embed_dim
snake_case__ : Optional[int] = depths
snake_case__ : int = num_heads
snake_case__ : Optional[int] = window_size
return config
def __snake_case( _lowerCAmelCase ) -> Dict:
if "patch_embed.proj" in name:
snake_case__ : List[str] = name.replace("""patch_embed.proj""" , """embeddings.patch_embeddings.projection""" )
if "patch_embed.norm" in name:
snake_case__ : int = name.replace("""patch_embed.norm""" , """embeddings.norm""" )
if "layers" in name:
snake_case__ : str = """encoder.""" + name
if "attn.proj" in name:
snake_case__ : List[str] = name.replace("""attn.proj""" , """attention.output.dense""" )
if "attn" in name:
snake_case__ : Tuple = name.replace("""attn""" , """attention.self""" )
if "norm1" in name:
snake_case__ : List[str] = name.replace("""norm1""" , """layernorm_before""" )
if "norm2" in name:
snake_case__ : Optional[Any] = name.replace("""norm2""" , """layernorm_after""" )
if "mlp.fc1" in name:
snake_case__ : Union[str, Any] = name.replace("""mlp.fc1""" , """intermediate.dense""" )
if "mlp.fc2" in name:
snake_case__ : Dict = name.replace("""mlp.fc2""" , """output.dense""" )
if name == "norm.weight":
snake_case__ : Tuple = """layernorm.weight"""
if name == "norm.bias":
snake_case__ : Union[str, Any] = """layernorm.bias"""
if "head" in name:
snake_case__ : Optional[int] = name.replace("""head""" , """classifier""" )
else:
snake_case__ : List[str] = """swin.""" + name
return name
def __snake_case( _lowerCAmelCase , _lowerCAmelCase ) -> Optional[Any]:
for key in orig_state_dict.copy().keys():
snake_case__ : Optional[int] = orig_state_dict.pop(_lowerCAmelCase )
if "mask" in key:
continue
elif "qkv" in key:
snake_case__ : Dict = key.split(""".""" )
snake_case__ : Optional[int] = int(key_split[1] )
snake_case__ : Union[str, Any] = int(key_split[3] )
snake_case__ : List[Any] = model.swin.encoder.layers[layer_num].blocks[block_num].attention.self.all_head_size
if "weight" in key:
snake_case__ : Optional[Any] = val[:dim, :]
snake_case__ : Tuple = val[
dim : dim * 2, :
]
snake_case__ : Dict = val[-dim:, :]
else:
snake_case__ : Tuple = val[
:dim
]
snake_case__ : int = val[
dim : dim * 2
]
snake_case__ : int = val[
-dim:
]
else:
snake_case__ : Union[str, Any] = val
return orig_state_dict
def __snake_case( _lowerCAmelCase , _lowerCAmelCase ) -> int:
snake_case__ : Optional[int] = timm.create_model(_lowerCAmelCase , pretrained=_lowerCAmelCase )
timm_model.eval()
snake_case__ : Optional[int] = get_swin_config(_lowerCAmelCase )
snake_case__ : Optional[Any] = SwinForImageClassification(_lowerCAmelCase )
model.eval()
snake_case__ : str = convert_state_dict(timm_model.state_dict() , _lowerCAmelCase )
model.load_state_dict(_lowerCAmelCase )
snake_case__ : int = """http://images.cocodataset.org/val2017/000000039769.jpg"""
snake_case__ : Dict = AutoImageProcessor.from_pretrained("""microsoft/{}""".format(swin_name.replace("""_""" , """-""" ) ) )
snake_case__ : Dict = Image.open(requests.get(_lowerCAmelCase , stream=_lowerCAmelCase ).raw )
snake_case__ : Optional[int] = image_processor(images=_lowerCAmelCase , return_tensors="""pt""" )
snake_case__ : Optional[Any] = timm_model(inputs["""pixel_values"""] )
snake_case__ : str = model(**_lowerCAmelCase ).logits
assert torch.allclose(_lowerCAmelCase , _lowerCAmelCase , atol=1e-3 )
print(f"Saving model {swin_name} to {pytorch_dump_folder_path}" )
model.save_pretrained(_lowerCAmelCase )
print(f"Saving image processor to {pytorch_dump_folder_path}" )
image_processor.save_pretrained(_lowerCAmelCase )
if __name__ == "__main__":
__a = argparse.ArgumentParser()
# Required parameters
parser.add_argument(
"--swin_name",
default="swin_tiny_patch4_window7_224",
type=str,
help="Name of the Swin timm model you'd like to convert.",
)
parser.add_argument(
"--pytorch_dump_folder_path", default=None, type=str, help="Path to the output PyTorch model directory."
)
__a = parser.parse_args()
convert_swin_checkpoint(args.swin_name, args.pytorch_dump_folder_path)
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import datasets
from .nmt_bleu import compute_bleu # From: https://github.com/tensorflow/nmt/blob/master/nmt/scripts/bleu.py
UpperCAmelCase_ : Any = '''\\n@INPROCEEDINGS{Papineni02bleu:a,\n author = {Kishore Papineni and Salim Roukos and Todd Ward and Wei-jing Zhu},\n title = {BLEU: a Method for Automatic Evaluation of Machine Translation},\n booktitle = {},\n year = {2002},\n pages = {311--318}\n}\n@inproceedings{lin-och-2004-orange,\n title = \"{ORANGE}: a Method for Evaluating Automatic Evaluation Metrics for Machine Translation\",\n author = \"Lin, Chin-Yew and\n Och, Franz Josef\",\n booktitle = \"{COLING} 2004: Proceedings of the 20th International Conference on Computational Linguistics\",\n month = \"aug 23{--}aug 27\",\n year = \"2004\",\n address = \"Geneva, Switzerland\",\n publisher = \"COLING\",\n url = \"https://www.aclweb.org/anthology/C04-1072\",\n pages = \"501--507\",\n}\n'''
UpperCAmelCase_ : List[Any] = '''\\nBLEU (bilingual evaluation understudy) is an algorithm for evaluating the quality of text which has been machine-translated from one natural language to another.\nQuality is considered to be the correspondence between a machine\'s output and that of a human: \"the closer a machine translation is to a professional human translation,\nthe better it is\" – this is the central idea behind BLEU. BLEU was one of the first metrics to claim a high correlation with human judgements of quality, and\nremains one of the most popular automated and inexpensive metrics.\n\nScores are calculated for individual translated segments—generally sentences—by comparing them with a set of good quality reference translations.\nThose scores are then averaged over the whole corpus to reach an estimate of the translation\'s overall quality. Intelligibility or grammatical correctness\nare not taken into account[citation needed].\n\nBLEU\'s output is always a number between 0 and 1. This value indicates how similar the candidate text is to the reference texts, with values closer to 1\nrepresenting more similar texts. Few human translations will attain a score of 1, since this would indicate that the candidate is identical to one of the\nreference translations. For this reason, it is not necessary to attain a score of 1. Because there are more opportunities to match, adding additional\nreference translations will increase the BLEU score.\n'''
UpperCAmelCase_ : str = '''\nComputes BLEU score of translated segments against one or more references.\nArgs:\n predictions: list of translations to score.\n Each translation should be tokenized into a list of tokens.\n references: list of lists of references for each translation.\n Each reference should be tokenized into a list of tokens.\n max_order: Maximum n-gram order to use when computing BLEU score.\n smooth: Whether or not to apply Lin et al. 2004 smoothing.\nReturns:\n \'bleu\': bleu score,\n \'precisions\': geometric mean of n-gram precisions,\n \'brevity_penalty\': brevity penalty,\n \'length_ratio\': ratio of lengths,\n \'translation_length\': translation_length,\n \'reference_length\': reference_length\nExamples:\n\n >>> predictions = [\n ... [\"hello\", \"there\", \"general\", \"kenobi\"], # tokenized prediction of the first sample\n ... [\"foo\", \"bar\", \"foobar\"] # tokenized prediction of the second sample\n ... ]\n >>> references = [\n ... [[\"hello\", \"there\", \"general\", \"kenobi\"], [\"hello\", \"there\", \"!\"]], # tokenized references for the first sample (2 references)\n ... [[\"foo\", \"bar\", \"foobar\"]] # tokenized references for the second sample (1 reference)\n ... ]\n >>> bleu = datasets.load_metric(\"bleu\")\n >>> results = bleu.compute(predictions=predictions, references=references)\n >>> print(results[\"bleu\"])\n 1.0\n'''
@datasets.utils.file_utils.add_start_docstrings(_DESCRIPTION , _KWARGS_DESCRIPTION )
class _SCREAMING_SNAKE_CASE ( datasets.Metric ):
def _A ( self : Tuple ):
return datasets.MetricInfo(
description=_DESCRIPTION , citation=_CITATION , inputs_description=_KWARGS_DESCRIPTION , features=datasets.Features(
{
"""predictions""": datasets.Sequence(datasets.Value("""string""" , id="""token""" ) , id="""sequence""" ),
"""references""": datasets.Sequence(
datasets.Sequence(datasets.Value("""string""" , id="""token""" ) , id="""sequence""" ) , id="""references""" ),
} ) , codebase_urls=["""https://github.com/tensorflow/nmt/blob/master/nmt/scripts/bleu.py"""] , reference_urls=[
"""https://en.wikipedia.org/wiki/BLEU""",
"""https://towardsdatascience.com/evaluating-text-output-in-nlp-bleu-at-your-own-risk-e8609665a213""",
] , )
def _A ( self : Optional[int] , __lowerCamelCase : List[Any] , __lowerCamelCase : int , __lowerCamelCase : int=4 , __lowerCamelCase : List[Any]=False ):
UpperCamelCase :Optional[Any] = compute_bleu(
reference_corpus=snake_case_ , translation_corpus=snake_case_ , max_order=snake_case_ , smooth=snake_case_ )
(UpperCamelCase) :Optional[int] = score
return {
"bleu": bleu,
"precisions": precisions,
"brevity_penalty": bp,
"length_ratio": ratio,
"translation_length": translation_length,
"reference_length": reference_length,
}
| 38
|
'''simple docstring'''
import warnings
from ...utils import logging
from .image_processing_beit import BeitImageProcessor
__a = logging.get_logger(__name__)
class UpperCAmelCase_ ( _a ):
"""simple docstring"""
def __init__( self : List[str] , *snake_case_ : str , **snake_case_ : List[str] ):
warnings.warn(
"""The class BeitFeatureExtractor is deprecated and will be removed in version 5 of Transformers. Please"""
""" use BeitImageProcessor instead.""" , snake_case_ , )
super().__init__(*snake_case_ , **snake_case_ )
| 35
| 0
|
"""simple docstring"""
import pytest
from datasets.splits import SplitDict, SplitInfo
from datasets.utils.py_utils import asdict
@pytest.mark.parametrize(
'split_dict' , [
SplitDict(),
SplitDict({'train': SplitInfo(name='train' , num_bytes=1337 , num_examples=42 , dataset_name='my_dataset' )} ),
SplitDict({'train': SplitInfo(name='train' , num_bytes=1337 , num_examples=42 )} ),
SplitDict({'train': SplitInfo()} ),
] , )
def a_ ( _lowerCAmelCase : Tuple ):
'''simple docstring'''
lowercase__ : List[Any] = split_dict._to_yaml_list()
assert len(_lowerCAmelCase ) == len(_lowerCAmelCase )
lowercase__ : List[Any] = SplitDict._from_yaml_list(_lowerCAmelCase )
for split_name, split_info in split_dict.items():
# dataset_name field is deprecated, and is therefore not part of the YAML dump
lowercase__ : Optional[int] = None
# the split name of split_dict takes over the name of the split info object
lowercase__ : List[Any] = split_name
assert split_dict == reloaded
@pytest.mark.parametrize(
'split_info' , [SplitInfo(), SplitInfo(dataset_name=_lowerCAmelCase ), SplitInfo(dataset_name='my_dataset' )] )
def a_ ( _lowerCAmelCase : List[str] ):
'''simple docstring'''
lowercase__ : Any = asdict(SplitDict({'train': split_info} ) )
assert "dataset_name" in split_dict_asdict["train"]
assert split_dict_asdict["train"]["dataset_name"] == split_info.dataset_name
| 77
|
'''simple docstring'''
import logging
from dataclasses import dataclass, field
from pathlib import Path
from typing import Optional, Union
from .generation.configuration_utils import GenerationConfig
from .training_args import TrainingArguments
from .utils import add_start_docstrings
__a = logging.getLogger(__name__)
@dataclass
@add_start_docstrings(TrainingArguments.__doc__ )
class UpperCAmelCase_ ( _a ):
"""simple docstring"""
lowercase = field(default=_a , metadata={"help": "Whether to use SortishSampler or not."} )
lowercase = field(
default=_a , metadata={"help": "Whether to use generate to calculate generative metrics (ROUGE, BLEU)."} )
lowercase = field(
default=_a , metadata={
"help": (
"The `max_length` to use on each evaluation loop when `predict_with_generate=True`. Will default "
"to the `max_length` value of the model configuration."
)
} , )
lowercase = field(
default=_a , metadata={
"help": (
"The `num_beams` to use on each evaluation loop when `predict_with_generate=True`. Will default "
"to the `num_beams` value of the model configuration."
)
} , )
lowercase = field(
default=_a , metadata={
"help": "Model id, file path or url pointing to a GenerationConfig json file, to use during prediction."
} , )
def lowerCamelCase ( self : List[str] ):
snake_case__ : int = super().to_dict()
for k, v in d.items():
if isinstance(snake_case_ , snake_case_ ):
snake_case__ : Optional[int] = v.to_dict()
return d
| 35
| 0
|
'''simple docstring'''
import importlib
import os
import sys
# This is required to make the module import works (when the python process is running from the root of the repo)
sys.path.append('.')
def lowerCAmelCase_ ( snake_case_ : Union[str, Any] ) -> int:
'''simple docstring'''
UpperCAmelCase_ = test_file.split(os.path.sep )
if components[0:2] != ["tests", "models"]:
raise ValueError(
"`test_file` should start with `tests/models/` (with `/` being the OS specific path separator). Got "
f"""{test_file} instead.""" )
UpperCAmelCase_ = components[-1]
if not test_fn.endswith("py" ):
raise ValueError(f"""`test_file` should be a python file. Got {test_fn} instead.""" )
if not test_fn.startswith("test_modeling_" ):
raise ValueError(
f"""`test_file` should point to a file name of the form `test_modeling_*.py`. Got {test_fn} instead.""" )
UpperCAmelCase_ = components[:-1] + [test_fn.replace(".py" , "" )]
UpperCAmelCase_ = """.""".join(_lowerCAmelCase )
return test_module_path
def lowerCAmelCase_ ( snake_case_ : Optional[int] ) -> List[str]:
'''simple docstring'''
UpperCAmelCase_ = get_module_path(_lowerCAmelCase )
UpperCAmelCase_ = importlib.import_module(_lowerCAmelCase )
return test_module
def lowerCAmelCase_ ( snake_case_ : str ) -> int:
'''simple docstring'''
UpperCAmelCase_ = []
UpperCAmelCase_ = get_test_module(_lowerCAmelCase )
for attr in dir(_lowerCAmelCase ):
if attr.endswith("ModelTester" ):
tester_classes.append(getattr(_lowerCAmelCase , _lowerCAmelCase ) )
# sort with class names
return sorted(_lowerCAmelCase , key=lambda snake_case_ : x.__name__ )
def lowerCAmelCase_ ( snake_case_ : Union[str, Any] ) -> Dict:
'''simple docstring'''
UpperCAmelCase_ = []
UpperCAmelCase_ = get_test_module(_lowerCAmelCase )
for attr in dir(_lowerCAmelCase ):
UpperCAmelCase_ = getattr(_lowerCAmelCase , _lowerCAmelCase )
# (TF/Flax)ModelTesterMixin is also an attribute in specific model test module. Let's exclude them by checking
# `all_model_classes` is not empty (which also excludes other special classes).
UpperCAmelCase_ = getattr(_lowerCAmelCase , "all_model_classes" , [] )
if len(_lowerCAmelCase ) > 0:
test_classes.append(_lowerCAmelCase )
# sort with class names
return sorted(_lowerCAmelCase , key=lambda snake_case_ : x.__name__ )
def lowerCAmelCase_ ( snake_case_ : Dict ) -> Dict:
'''simple docstring'''
UpperCAmelCase_ = get_test_classes(_lowerCAmelCase )
UpperCAmelCase_ = set()
for test_class in test_classes:
model_classes.update(test_class.all_model_classes )
# sort with class names
return sorted(_lowerCAmelCase , key=lambda snake_case_ : x.__name__ )
def lowerCAmelCase_ ( snake_case_ : Dict ) -> Optional[Any]:
'''simple docstring'''
UpperCAmelCase_ = test_class()
if hasattr(_lowerCAmelCase , "setUp" ):
test.setUp()
UpperCAmelCase_ = None
if hasattr(_lowerCAmelCase , "model_tester" ):
# `(TF/Flax)ModelTesterMixin` has this attribute default to `None`. Let's skip this case.
if test.model_tester is not None:
UpperCAmelCase_ = test.model_tester.__class__
return model_tester
def lowerCAmelCase_ ( snake_case_ : int , snake_case_ : Optional[int] ) -> Dict:
'''simple docstring'''
UpperCAmelCase_ = get_test_classes(_lowerCAmelCase )
UpperCAmelCase_ = []
for test_class in test_classes:
if model_class in test_class.all_model_classes:
target_test_classes.append(_lowerCAmelCase )
# sort with class names
return sorted(_lowerCAmelCase , key=lambda snake_case_ : x.__name__ )
def lowerCAmelCase_ ( snake_case_ : List[str] , snake_case_ : Optional[int] ) -> Tuple:
'''simple docstring'''
UpperCAmelCase_ = get_test_classes_for_model(_lowerCAmelCase , _lowerCAmelCase )
UpperCAmelCase_ = []
for test_class in test_classes:
UpperCAmelCase_ = get_model_tester_from_test_class(_lowerCAmelCase )
if tester_class is not None:
tester_classes.append(_lowerCAmelCase )
# sort with class names
return sorted(_lowerCAmelCase , key=lambda snake_case_ : x.__name__ )
def lowerCAmelCase_ ( snake_case_ : Union[str, Any] ) -> Union[str, Any]:
'''simple docstring'''
UpperCAmelCase_ = get_test_classes(_lowerCAmelCase )
UpperCAmelCase_ = {test_class: get_model_tester_from_test_class(_lowerCAmelCase ) for test_class in test_classes}
return test_tester_mapping
def lowerCAmelCase_ ( snake_case_ : int ) -> int:
'''simple docstring'''
UpperCAmelCase_ = get_model_classes(_lowerCAmelCase )
UpperCAmelCase_ = {
model_class: get_test_classes_for_model(_lowerCAmelCase , _lowerCAmelCase ) for model_class in model_classes
}
return model_test_mapping
def lowerCAmelCase_ ( snake_case_ : int ) -> Optional[int]:
'''simple docstring'''
UpperCAmelCase_ = get_model_classes(_lowerCAmelCase )
UpperCAmelCase_ = {
model_class: get_tester_classes_for_model(_lowerCAmelCase , _lowerCAmelCase ) for model_class in model_classes
}
return model_to_tester_mapping
def lowerCAmelCase_ ( snake_case_ : Dict ) -> int:
'''simple docstring'''
if isinstance(_lowerCAmelCase , _lowerCAmelCase ):
return o
elif isinstance(_lowerCAmelCase , _lowerCAmelCase ):
return o.__name__
elif isinstance(_lowerCAmelCase , (list, tuple) ):
return [to_json(_lowerCAmelCase ) for x in o]
elif isinstance(_lowerCAmelCase , _lowerCAmelCase ):
return {to_json(_lowerCAmelCase ): to_json(_lowerCAmelCase ) for k, v in o.items()}
else:
return o
| 1
|
'''simple docstring'''
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 DeiTConfig, DeiTForImageClassificationWithTeacher, DeiTImageProcessor
from transformers.utils import logging
logging.set_verbosity_info()
__a = logging.get_logger(__name__)
def __snake_case( _lowerCAmelCase , _lowerCAmelCase=False ) -> str:
snake_case__ : Union[str, Any] = []
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"deit.encoder.layer.{i}.layernorm_before.weight") )
rename_keys.append((f"blocks.{i}.norm1.bias", f"deit.encoder.layer.{i}.layernorm_before.bias") )
rename_keys.append((f"blocks.{i}.attn.proj.weight", f"deit.encoder.layer.{i}.attention.output.dense.weight") )
rename_keys.append((f"blocks.{i}.attn.proj.bias", f"deit.encoder.layer.{i}.attention.output.dense.bias") )
rename_keys.append((f"blocks.{i}.norm2.weight", f"deit.encoder.layer.{i}.layernorm_after.weight") )
rename_keys.append((f"blocks.{i}.norm2.bias", f"deit.encoder.layer.{i}.layernorm_after.bias") )
rename_keys.append((f"blocks.{i}.mlp.fc1.weight", f"deit.encoder.layer.{i}.intermediate.dense.weight") )
rename_keys.append((f"blocks.{i}.mlp.fc1.bias", f"deit.encoder.layer.{i}.intermediate.dense.bias") )
rename_keys.append((f"blocks.{i}.mlp.fc2.weight", f"deit.encoder.layer.{i}.output.dense.weight") )
rename_keys.append((f"blocks.{i}.mlp.fc2.bias", f"deit.encoder.layer.{i}.output.dense.bias") )
# projection layer + position embeddings
rename_keys.extend(
[
("""cls_token""", """deit.embeddings.cls_token"""),
("""dist_token""", """deit.embeddings.distillation_token"""),
("""patch_embed.proj.weight""", """deit.embeddings.patch_embeddings.projection.weight"""),
("""patch_embed.proj.bias""", """deit.embeddings.patch_embeddings.projection.bias"""),
("""pos_embed""", """deit.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 "deit" from all keys that start with "deit"
snake_case__ : List[Any] = [(pair[0], pair[1][4:]) if pair[1].startswith("""deit""" ) else pair for pair in rename_keys]
else:
# layernorm + classification heads
rename_keys.extend(
[
("""norm.weight""", """deit.layernorm.weight"""),
("""norm.bias""", """deit.layernorm.bias"""),
("""head.weight""", """cls_classifier.weight"""),
("""head.bias""", """cls_classifier.bias"""),
("""head_dist.weight""", """distillation_classifier.weight"""),
("""head_dist.bias""", """distillation_classifier.bias"""),
] )
return rename_keys
def __snake_case( _lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase=False ) -> Union[str, Any]:
for i in range(config.num_hidden_layers ):
if base_model:
snake_case__ : Tuple = """"""
else:
snake_case__ : Dict = """deit."""
# read in weights + bias of input projection layer (in timm, this is a single matrix + bias)
snake_case__ : Optional[Any] = state_dict.pop(f"blocks.{i}.attn.qkv.weight" )
snake_case__ : Tuple = state_dict.pop(f"blocks.{i}.attn.qkv.bias" )
# next, add query, keys and values (in that order) to the state dict
snake_case__ : Any = in_proj_weight[
: config.hidden_size, :
]
snake_case__ : Optional[int] = in_proj_bias[: config.hidden_size]
snake_case__ : Any = in_proj_weight[
config.hidden_size : config.hidden_size * 2, :
]
snake_case__ : str = in_proj_bias[
config.hidden_size : config.hidden_size * 2
]
snake_case__ : List[str] = in_proj_weight[
-config.hidden_size :, :
]
snake_case__ : Tuple = in_proj_bias[-config.hidden_size :]
def __snake_case( _lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase ) -> int:
snake_case__ : str = dct.pop(_lowerCAmelCase )
snake_case__ : Tuple = val
def __snake_case( ) -> Tuple:
snake_case__ : Union[str, Any] = """http://images.cocodataset.org/val2017/000000039769.jpg"""
snake_case__ : Optional[int] = Image.open(requests.get(_lowerCAmelCase , stream=_lowerCAmelCase ).raw )
return im
@torch.no_grad()
def __snake_case( _lowerCAmelCase , _lowerCAmelCase ) -> str:
snake_case__ : Optional[int] = DeiTConfig()
# all deit models have fine-tuned heads
snake_case__ : Union[str, Any] = False
# dataset (fine-tuned on ImageNet 2012), patch_size and image_size
snake_case__ : int = 1_000
snake_case__ : Any = """huggingface/label-files"""
snake_case__ : Optional[Any] = """imagenet-1k-id2label.json"""
snake_case__ : Tuple = json.load(open(hf_hub_download(_lowerCAmelCase , _lowerCAmelCase , repo_type="""dataset""" ) , """r""" ) )
snake_case__ : List[Any] = {int(_lowerCAmelCase ): v for k, v in idalabel.items()}
snake_case__ : List[Any] = idalabel
snake_case__ : List[str] = {v: k for k, v in idalabel.items()}
snake_case__ : Tuple = int(deit_name[-6:-4] )
snake_case__ : Optional[Any] = int(deit_name[-3:] )
# size of the architecture
if deit_name[9:].startswith("""tiny""" ):
snake_case__ : Tuple = 192
snake_case__ : Union[str, Any] = 768
snake_case__ : Tuple = 12
snake_case__ : Union[str, Any] = 3
elif deit_name[9:].startswith("""small""" ):
snake_case__ : str = 384
snake_case__ : Any = 1_536
snake_case__ : str = 12
snake_case__ : int = 6
if deit_name[9:].startswith("""base""" ):
pass
elif deit_name[4:].startswith("""large""" ):
snake_case__ : Union[str, Any] = 1_024
snake_case__ : Any = 4_096
snake_case__ : List[Any] = 24
snake_case__ : Tuple = 16
# load original model from timm
snake_case__ : List[Any] = timm.create_model(_lowerCAmelCase , pretrained=_lowerCAmelCase )
timm_model.eval()
# load state_dict of original model, remove and rename some keys
snake_case__ : Optional[Any] = timm_model.state_dict()
snake_case__ : Optional[int] = create_rename_keys(_lowerCAmelCase , _lowerCAmelCase )
for src, dest in rename_keys:
rename_key(_lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase )
read_in_q_k_v(_lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase )
# load HuggingFace model
snake_case__ : Optional[Any] = DeiTForImageClassificationWithTeacher(_lowerCAmelCase ).eval()
model.load_state_dict(_lowerCAmelCase )
# Check outputs on an image, prepared by DeiTImageProcessor
snake_case__ : List[Any] = int(
(256 / 224) * config.image_size ) # to maintain same ratio w.r.t. 224 images, see https://github.com/facebookresearch/deit/blob/ab5715372db8c6cad5740714b2216d55aeae052e/datasets.py#L103
snake_case__ : Optional[Any] = DeiTImageProcessor(size=_lowerCAmelCase , crop_size=config.image_size )
snake_case__ : str = image_processor(images=prepare_img() , return_tensors="""pt""" )
snake_case__ : Optional[Any] = encoding["""pixel_values"""]
snake_case__ : Tuple = model(_lowerCAmelCase )
snake_case__ : Optional[int] = timm_model(_lowerCAmelCase )
assert timm_logits.shape == outputs.logits.shape
assert torch.allclose(_lowerCAmelCase , outputs.logits , atol=1e-3 )
Path(_lowerCAmelCase ).mkdir(exist_ok=_lowerCAmelCase )
print(f"Saving model {deit_name} to {pytorch_dump_folder_path}" )
model.save_pretrained(_lowerCAmelCase )
print(f"Saving image processor to {pytorch_dump_folder_path}" )
image_processor.save_pretrained(_lowerCAmelCase )
if __name__ == "__main__":
__a = argparse.ArgumentParser()
# Required parameters
parser.add_argument(
"--deit_name",
default="vit_deit_base_distilled_patch16_224",
type=str,
help="Name of the DeiT timm model you'd like to convert.",
)
parser.add_argument(
"--pytorch_dump_folder_path", default=None, type=str, help="Path to the output PyTorch model directory."
)
__a = parser.parse_args()
convert_deit_checkpoint(args.deit_name, args.pytorch_dump_folder_path)
| 35
| 0
|
from typing import TYPE_CHECKING
from ...utils import OptionalDependencyNotAvailable, _LazyModule, is_torch_available
lowerCamelCase : Union[str, Any] = {
"configuration_jukebox": [
"JUKEBOX_PRETRAINED_CONFIG_ARCHIVE_MAP",
"JukeboxConfig",
"JukeboxPriorConfig",
"JukeboxVQVAEConfig",
],
"tokenization_jukebox": ["JukeboxTokenizer"],
}
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
lowerCamelCase : Optional[Any] = [
"JUKEBOX_PRETRAINED_MODEL_ARCHIVE_LIST",
"JukeboxModel",
"JukeboxPreTrainedModel",
"JukeboxVQVAE",
"JukeboxPrior",
]
if TYPE_CHECKING:
from .configuration_jukebox import (
JUKEBOX_PRETRAINED_CONFIG_ARCHIVE_MAP,
JukeboxConfig,
JukeboxPriorConfig,
JukeboxVQVAEConfig,
)
from .tokenization_jukebox import JukeboxTokenizer
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_jukebox import (
JUKEBOX_PRETRAINED_MODEL_ARCHIVE_LIST,
JukeboxModel,
JukeboxPreTrainedModel,
JukeboxPrior,
JukeboxVQVAE,
)
else:
import sys
lowerCamelCase : Any = _LazyModule(__name__, globals()["__file__"], _import_structure, module_spec=__spec__)
| 204
|
'''simple docstring'''
import string
from math import logaa
def __snake_case( _lowerCAmelCase , _lowerCAmelCase ) -> int:
snake_case__ : List[str] = document.translate(
str.maketrans("""""" , """""" , string.punctuation ) ).replace("""\n""" , """""" )
snake_case__ : List[str] = document_without_punctuation.split(""" """ ) # word tokenization
return len([word for word in tokenize_document if word.lower() == term.lower()] )
def __snake_case( _lowerCAmelCase , _lowerCAmelCase ) -> tuple[int, int]:
snake_case__ : Dict = corpus.lower().translate(
str.maketrans("""""" , """""" , string.punctuation ) ) # strip all punctuation and replace it with ''
snake_case__ : Any = corpus_without_punctuation.split("""\n""" )
snake_case__ : int = term.lower()
return (len([doc for doc in docs if term in doc] ), len(_lowerCAmelCase ))
def __snake_case( _lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase=False ) -> float:
if smoothing:
if n == 0:
raise ValueError("""log10(0) is undefined.""" )
return round(1 + logaa(n / (1 + df) ) , 3 )
if df == 0:
raise ZeroDivisionError("""df must be > 0""" )
elif n == 0:
raise ValueError("""log10(0) is undefined.""" )
return round(logaa(n / df ) , 3 )
def __snake_case( _lowerCAmelCase , _lowerCAmelCase ) -> float:
return round(tf * idf , 3 )
| 35
| 0
|
import json
import os
import tempfile
import datasets
from utils import generate_example_dataset, get_duration
a : Optional[int] = 50_000
a : str = 5_000
a ,a : Optional[int] = os.path.split(__file__)
a : List[str] = os.path.join(RESULTS_BASEPATH, 'results', RESULTS_FILENAME.replace('.py', '.json'))
@get_duration
def lowerCAmelCase_ (lowerCAmelCase__: List[str] , lowerCAmelCase__: str ):
"""simple docstring"""
for i in range(_lowerCAmelCase ):
UpperCAmelCase_: str = dataset[i]
@get_duration
def lowerCAmelCase_ (lowerCAmelCase__: List[Any] , lowerCAmelCase__: Union[str, Any] , lowerCAmelCase__: Tuple ):
"""simple docstring"""
for i in range(0 , len(_lowerCAmelCase ) , _lowerCAmelCase ):
UpperCAmelCase_: Optional[Any] = dataset[i : i + batch_size]
@get_duration
def lowerCAmelCase_ (lowerCAmelCase__: Tuple , lowerCAmelCase__: Optional[int] , lowerCAmelCase__: int ):
"""simple docstring"""
with dataset.formatted_as(type=_lowerCAmelCase ):
for i in range(_lowerCAmelCase ):
UpperCAmelCase_: Tuple = dataset[i]
@get_duration
def lowerCAmelCase_ (lowerCAmelCase__: Optional[int] , lowerCAmelCase__: Any , lowerCAmelCase__: int , lowerCAmelCase__: Optional[int] ):
"""simple docstring"""
with dataset.formatted_as(type=_lowerCAmelCase ):
for i in range(0 , _lowerCAmelCase , _lowerCAmelCase ):
UpperCAmelCase_: Tuple = dataset[i : i + batch_size]
def lowerCAmelCase_ ():
"""simple docstring"""
UpperCAmelCase_: List[str] = {"""num examples""": SPEED_TEST_N_EXAMPLES}
UpperCAmelCase_: str = [
(read, {"""length""": SMALL_TEST}),
(read, {"""length""": SPEED_TEST_N_EXAMPLES}),
(read_batch, {"""length""": SPEED_TEST_N_EXAMPLES, """batch_size""": 1_0}),
(read_batch, {"""length""": SPEED_TEST_N_EXAMPLES, """batch_size""": 1_0_0}),
(read_batch, {"""length""": SPEED_TEST_N_EXAMPLES, """batch_size""": 1_0_0_0}),
(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""": 1_0}),
(read_formatted_batch, {"""type""": """numpy""", """length""": SMALL_TEST, """batch_size""": 1_0_0_0}),
]
UpperCAmelCase_: Union[str, Any] = [
(read, {"""length""": SMALL_TEST}),
(read, {"""length""": SPEED_TEST_N_EXAMPLES}),
(read_batch, {"""length""": SPEED_TEST_N_EXAMPLES, """batch_size""": 1_0}),
(read_batch, {"""length""": SPEED_TEST_N_EXAMPLES, """batch_size""": 1_0_0}),
(read_batch, {"""length""": SPEED_TEST_N_EXAMPLES, """batch_size""": 1_0_0_0}),
(read_formatted, {"""type""": """numpy""", """length""": SMALL_TEST}),
(read_formatted_batch, {"""type""": """numpy""", """length""": SMALL_TEST, """batch_size""": 1_0}),
(read_formatted_batch, {"""type""": """numpy""", """length""": SMALL_TEST, """batch_size""": 1_0_0_0}),
]
with tempfile.TemporaryDirectory() as tmp_dir:
print("""generating dataset""" )
UpperCAmelCase_: Tuple = datasets.Features(
{"""list""": datasets.Sequence(datasets.Value("""float32""" ) ), """numbers""": datasets.Value("""float32""" )} )
UpperCAmelCase_: Optional[int] = generate_example_dataset(
os.path.join(_lowerCAmelCase , """dataset.arrow""" ) , _lowerCAmelCase , num_examples=_lowerCAmelCase , seq_shapes={"""list""": (1_0_0,)} , )
print("""first set of iterations""" )
for func, kwargs in functions:
print(func.__name__ , str(_lowerCAmelCase ) )
UpperCAmelCase_: int = func(_lowerCAmelCase , **_lowerCAmelCase )
print("""shuffling dataset""" )
UpperCAmelCase_: Optional[Any] = dataset.shuffle()
print("""Second set of iterations (after shuffling""" )
for func, kwargs in functions_shuffled:
print("""shuffled """ , func.__name__ , str(_lowerCAmelCase ) )
UpperCAmelCase_: Dict = func(
_lowerCAmelCase , **_lowerCAmelCase )
with open(_lowerCAmelCase , """wb""" ) as f:
f.write(json.dumps(_lowerCAmelCase ).encode("""utf-8""" ) )
if __name__ == "__main__": # useful to run the profiler
benchmark_iterating()
| 147
|
'''simple docstring'''
from __future__ import annotations
import inspect
import unittest
import numpy as np
from transformers import ResNetConfig
from transformers.testing_utils import require_tf, require_vision, slow
from transformers.utils import cached_property, is_tf_available, is_vision_available
from ...test_configuration_common import ConfigTester
from ...test_modeling_tf_common import TFModelTesterMixin, floats_tensor, ids_tensor
from ...test_pipeline_mixin import PipelineTesterMixin
if is_tf_available():
import tensorflow as tf
from transformers import TFResNetForImageClassification, TFResNetModel
from transformers.models.resnet.modeling_tf_resnet import TF_RESNET_PRETRAINED_MODEL_ARCHIVE_LIST
if is_vision_available():
from PIL import Image
from transformers import AutoImageProcessor
class UpperCAmelCase_ :
"""simple docstring"""
def __init__( self : int , snake_case_ : Tuple , snake_case_ : List[str]=3 , snake_case_ : Tuple=32 , snake_case_ : List[Any]=3 , snake_case_ : List[str]=10 , snake_case_ : List[str]=[10, 20, 30, 40] , snake_case_ : Tuple=[1, 1, 2, 1] , snake_case_ : Tuple=True , snake_case_ : str=True , snake_case_ : int="relu" , snake_case_ : List[Any]=3 , snake_case_ : str=None , ):
snake_case__ : List[Any] = parent
snake_case__ : List[Any] = batch_size
snake_case__ : int = image_size
snake_case__ : List[Any] = num_channels
snake_case__ : Optional[Any] = embeddings_size
snake_case__ : Optional[int] = hidden_sizes
snake_case__ : Tuple = depths
snake_case__ : Any = is_training
snake_case__ : Optional[int] = use_labels
snake_case__ : Optional[int] = hidden_act
snake_case__ : Optional[int] = num_labels
snake_case__ : int = scope
snake_case__ : Tuple = len(snake_case_ )
def lowerCamelCase ( self : Any ):
snake_case__ : Union[str, Any] = floats_tensor([self.batch_size, self.num_channels, self.image_size, self.image_size] )
snake_case__ : Union[str, Any] = None
if self.use_labels:
snake_case__ : Optional[Any] = ids_tensor([self.batch_size] , self.num_labels )
snake_case__ : List[str] = self.get_config()
return config, pixel_values, labels
def lowerCamelCase ( self : int ):
return ResNetConfig(
num_channels=self.num_channels , embeddings_size=self.embeddings_size , hidden_sizes=self.hidden_sizes , depths=self.depths , hidden_act=self.hidden_act , num_labels=self.num_labels , image_size=self.image_size , )
def lowerCamelCase ( self : Tuple , snake_case_ : Tuple , snake_case_ : List[Any] , snake_case_ : Optional[int] ):
snake_case__ : Optional[Any] = TFResNetModel(config=snake_case_ )
snake_case__ : int = model(snake_case_ )
# expected last hidden states: B, C, H // 32, W // 32
self.parent.assertEqual(
result.last_hidden_state.shape , (self.batch_size, self.hidden_sizes[-1], self.image_size // 32, self.image_size // 32) , )
def lowerCamelCase ( self : List[str] , snake_case_ : List[str] , snake_case_ : str , snake_case_ : Union[str, Any] ):
snake_case__ : str = self.num_labels
snake_case__ : Optional[int] = TFResNetForImageClassification(snake_case_ )
snake_case__ : Tuple = model(snake_case_ , labels=snake_case_ )
self.parent.assertEqual(result.logits.shape , (self.batch_size, self.num_labels) )
def lowerCamelCase ( self : Tuple ):
snake_case__ : List[Any] = self.prepare_config_and_inputs()
snake_case__ , snake_case__ , snake_case__ : str = config_and_inputs
snake_case__ : int = {"""pixel_values""": pixel_values}
return config, inputs_dict
@require_tf
class UpperCAmelCase_ ( _a , _a , unittest.TestCase ):
"""simple docstring"""
lowercase = (TFResNetModel, TFResNetForImageClassification) if is_tf_available() else ()
lowercase = (
{"feature-extraction": TFResNetModel, "image-classification": TFResNetForImageClassification}
if is_tf_available()
else {}
)
lowercase = False
lowercase = False
lowercase = False
lowercase = False
lowercase = False
def lowerCamelCase ( self : Optional[int] ):
snake_case__ : Tuple = TFResNetModelTester(self )
snake_case__ : List[str] = ConfigTester(self , config_class=snake_case_ , has_text_modality=snake_case_ )
def lowerCamelCase ( self : Dict ):
self.create_and_test_config_common_properties()
self.config_tester.create_and_test_config_to_json_string()
self.config_tester.create_and_test_config_to_json_file()
self.config_tester.create_and_test_config_from_and_save_pretrained()
self.config_tester.create_and_test_config_with_num_labels()
self.config_tester.check_config_can_be_init_without_params()
self.config_tester.check_config_arguments_init()
def lowerCamelCase ( self : str ):
return
@unittest.skip(reason="""ResNet does not use inputs_embeds""" )
def lowerCamelCase ( self : int ):
pass
@unittest.skip(reason="""ResNet does not support input and output embeddings""" )
def lowerCamelCase ( self : List[Any] ):
pass
def lowerCamelCase ( self : List[Any] ):
snake_case__ , snake_case__ : List[Any] = self.model_tester.prepare_config_and_inputs_for_common()
for model_class in self.all_model_classes:
snake_case__ : Dict = model_class(snake_case_ )
snake_case__ : Optional[Any] = inspect.signature(model.call )
# signature.parameters is an OrderedDict => so arg_names order is deterministic
snake_case__ : Union[str, Any] = [*signature.parameters.keys()]
snake_case__ : Optional[int] = ["""pixel_values"""]
self.assertListEqual(arg_names[:1] , snake_case_ )
def lowerCamelCase ( self : Union[str, Any] ):
snake_case__ : Optional[int] = self.model_tester.prepare_config_and_inputs()
self.model_tester.create_and_check_model(*snake_case_ )
def lowerCamelCase ( self : List[str] ):
def check_hidden_states_output(snake_case_ : Any , snake_case_ : Any , snake_case_ : List[str] ):
snake_case__ : List[Any] = model_class(snake_case_ )
snake_case__ : Dict = model(**self._prepare_for_class(snake_case_ , snake_case_ ) )
snake_case__ : str = outputs.encoder_hidden_states if config.is_encoder_decoder else outputs.hidden_states
snake_case__ : List[Any] = self.model_tester.num_stages
self.assertEqual(len(snake_case_ ) , expected_num_stages + 1 )
# ResNet's feature maps are of shape (batch_size, num_channels, height, width)
self.assertListEqual(
list(hidden_states[0].shape[-2:] ) , [self.model_tester.image_size // 4, self.model_tester.image_size // 4] , )
snake_case__ , snake_case__ : Any = self.model_tester.prepare_config_and_inputs_for_common()
snake_case__ : List[Any] = ["""basic""", """bottleneck"""]
for model_class in self.all_model_classes:
for layer_type in layers_type:
snake_case__ : Dict = layer_type
snake_case__ : Optional[int] = True
check_hidden_states_output(snake_case_ , snake_case_ , snake_case_ )
# check that output_hidden_states also work using config
del inputs_dict["output_hidden_states"]
snake_case__ : List[Any] = True
check_hidden_states_output(snake_case_ , snake_case_ , snake_case_ )
def lowerCamelCase ( self : Optional[Any] ):
snake_case__ : Tuple = self.model_tester.prepare_config_and_inputs()
self.model_tester.create_and_check_for_image_classification(*snake_case_ )
@slow
def lowerCamelCase ( self : Optional[Any] ):
for model_name in TF_RESNET_PRETRAINED_MODEL_ARCHIVE_LIST[:1]:
snake_case__ : str = TFResNetModel.from_pretrained(snake_case_ )
self.assertIsNotNone(snake_case_ )
def __snake_case( ) -> Optional[int]:
snake_case__ : Optional[Any] = Image.open("""./tests/fixtures/tests_samples/COCO/000000039769.png""" )
return image
@require_tf
@require_vision
class UpperCAmelCase_ ( unittest.TestCase ):
"""simple docstring"""
@cached_property
def lowerCamelCase ( self : List[Any] ):
return (
AutoImageProcessor.from_pretrained(TF_RESNET_PRETRAINED_MODEL_ARCHIVE_LIST[0] )
if is_vision_available()
else None
)
@slow
def lowerCamelCase ( self : Optional[int] ):
snake_case__ : List[str] = TFResNetForImageClassification.from_pretrained(TF_RESNET_PRETRAINED_MODEL_ARCHIVE_LIST[0] )
snake_case__ : List[Any] = self.default_image_processor
snake_case__ : List[Any] = prepare_img()
snake_case__ : List[str] = image_processor(images=snake_case_ , return_tensors="""tf""" )
# forward pass
snake_case__ : Optional[Any] = model(**snake_case_ )
# verify the logits
snake_case__ : Union[str, Any] = tf.TensorShape((1, 1_000) )
self.assertEqual(outputs.logits.shape , snake_case_ )
snake_case__ : List[str] = tf.constant([-11.1069, -9.7877, -8.3777] )
self.assertTrue(np.allclose(outputs.logits[0, :3].numpy() , snake_case_ , atol=1E-4 ) )
| 35
| 0
|
from dataclasses import dataclass
from typing import Tuple
import numpy as np
import torch
@dataclass
class UpperCAmelCase_ :
'''simple docstring'''
a__ = 42 # [batch_size x 3]
a__ = 42 # [batch_size x 3]
a__ = 42 # [batch_size x 3]
a__ = 42 # [batch_size x 3]
a__ = 42
a__ = 42
a__ = 42
a__ = 42
a__ = 42
def _lowercase ( self : Optional[Any] ) -> Union[str, Any]:
"""simple docstring"""
assert self.x.shape[0] == self.y.shape[0] == self.z.shape[0] == self.origin.shape[0]
assert self.x.shape[1] == self.y.shape[1] == self.z.shape[1] == self.origin.shape[1] == 3
assert len(self.x.shape ) == len(self.y.shape ) == len(self.z.shape ) == len(self.origin.shape ) == 2
def _lowercase ( self : Union[str, Any] ) -> Optional[Any]:
"""simple docstring"""
return torch.from_numpy(np.array([self.width, self.height] , dtype=np.floataa ) )
def _lowercase ( self : str ) -> Tuple:
"""simple docstring"""
return torch.from_numpy(np.array([self.x_fov, self.y_fov] , dtype=np.floataa ) )
def _lowercase ( self : List[str] ) -> Any:
"""simple docstring"""
__magic_name__ = torch.arange(self.height * self.width )
__magic_name__ = torch.stack(
[
pixel_indices % self.width,
torch.div(snake_case_ , self.width , rounding_mode="""trunc""" ),
] , axis=1 , )
return coords
@property
def _lowercase ( self : Tuple ) -> Dict:
"""simple docstring"""
__magic_name__ = self.shape
__magic_name__ = int(np.prod(snake_case_ ) )
__magic_name__ = self.get_image_coords()
__magic_name__ = torch.broadcast_to(coords.unsqueeze(0 ) , [batch_size * inner_batch_size, *coords.shape] )
__magic_name__ = self.get_camera_rays(snake_case_ )
__magic_name__ = rays.view(snake_case_ , inner_batch_size * self.height * self.width , 2 , 3 )
return rays
def _lowercase ( self : Any , UpperCamelCase__ : torch.Tensor ) -> Optional[Any]:
"""simple docstring"""
__magic_name__ = coords.shape
assert n_coords == 2
assert batch_size == self.origin.shape[0]
__magic_name__ = coords.view(snake_case_ , -1 , 2 )
__magic_name__ = self.resolution()
__magic_name__ = self.fov()
__magic_name__ = (flat.float() / (res - 1)) * 2 - 1
__magic_name__ = fracs * torch.tan(fov / 2 )
__magic_name__ = fracs.view(snake_case_ , -1 , 2 )
__magic_name__ = (
self.z.view(snake_case_ , 1 , 3 )
+ self.x.view(snake_case_ , 1 , 3 ) * fracs[:, :, :1]
+ self.y.view(snake_case_ , 1 , 3 ) * fracs[:, :, 1:]
)
__magic_name__ = directions / directions.norm(dim=-1 , keepdim=snake_case_ )
__magic_name__ = torch.stack(
[
torch.broadcast_to(self.origin.view(snake_case_ , 1 , 3 ) , [batch_size, directions.shape[1], 3] ),
directions,
] , dim=2 , )
return rays.view(snake_case_ , *snake_case_ , 2 , 3 )
def _lowercase ( self : Union[str, Any] , UpperCamelCase__ : int , UpperCamelCase__ : int ) -> Optional[Any]:
"""simple docstring"""
assert width * self.height == height * self.width, "The aspect ratio should not change."
return DifferentiableProjectiveCamera(
origin=self.origin , x=self.x , y=self.y , z=self.z , width=snake_case_ , height=snake_case_ , x_fov=self.x_fov , y_fov=self.y_fov , )
def a__ ( A_ ):
'''simple docstring'''
__magic_name__ = []
__magic_name__ = []
__magic_name__ = []
__magic_name__ = []
for theta in np.linspace(0, 2 * np.pi, num=20 ):
__magic_name__ = np.array([np.sin(_lowerCAmelCase ), np.cos(_lowerCAmelCase ), -0.5] )
z /= np.sqrt(np.sum(z**2 ) )
__magic_name__ = -z * 4
__magic_name__ = np.array([np.cos(_lowerCAmelCase ), -np.sin(_lowerCAmelCase ), 0.0] )
__magic_name__ = np.cross(_lowerCAmelCase, _lowerCAmelCase )
origins.append(_lowerCAmelCase )
xs.append(_lowerCAmelCase )
ys.append(_lowerCAmelCase )
zs.append(_lowerCAmelCase )
return DifferentiableProjectiveCamera(
origin=torch.from_numpy(np.stack(_lowerCAmelCase, axis=0 ) ).float(), x=torch.from_numpy(np.stack(_lowerCAmelCase, axis=0 ) ).float(), y=torch.from_numpy(np.stack(_lowerCAmelCase, axis=0 ) ).float(), z=torch.from_numpy(np.stack(_lowerCAmelCase, axis=0 ) ).float(), width=_lowerCAmelCase, height=_lowerCAmelCase, x_fov=0.7, y_fov=0.7, shape=(1, len(_lowerCAmelCase )), )
| 88
|
'''simple docstring'''
from ...configuration_utils import PretrainedConfig
from ...utils import logging
__a = logging.get_logger(__name__)
__a = {
"vinvino02/glpn-kitti": "https://huggingface.co/vinvino02/glpn-kitti/resolve/main/config.json",
# See all GLPN models at https://huggingface.co/models?filter=glpn
}
class UpperCAmelCase_ ( _a ):
"""simple docstring"""
lowercase = "glpn"
def __init__( self : Optional[Any] , snake_case_ : List[str]=3 , snake_case_ : Dict=4 , snake_case_ : List[Any]=[2, 2, 2, 2] , snake_case_ : int=[8, 4, 2, 1] , snake_case_ : List[str]=[32, 64, 160, 256] , snake_case_ : Tuple=[7, 3, 3, 3] , snake_case_ : List[Any]=[4, 2, 2, 2] , snake_case_ : Tuple=[1, 2, 5, 8] , snake_case_ : List[str]=[4, 4, 4, 4] , snake_case_ : Optional[int]="gelu" , snake_case_ : Dict=0.0 , snake_case_ : Union[str, Any]=0.0 , snake_case_ : List[Any]=0.02 , snake_case_ : Tuple=0.1 , snake_case_ : Any=1E-6 , snake_case_ : Dict=64 , snake_case_ : Tuple=10 , snake_case_ : List[Any]=-1 , **snake_case_ : Optional[Any] , ):
super().__init__(**snake_case_ )
snake_case__ : Optional[Any] = num_channels
snake_case__ : Dict = num_encoder_blocks
snake_case__ : Tuple = depths
snake_case__ : Union[str, Any] = sr_ratios
snake_case__ : Tuple = hidden_sizes
snake_case__ : Optional[Any] = patch_sizes
snake_case__ : int = strides
snake_case__ : List[Any] = mlp_ratios
snake_case__ : Optional[int] = num_attention_heads
snake_case__ : Dict = hidden_act
snake_case__ : int = hidden_dropout_prob
snake_case__ : Optional[Any] = attention_probs_dropout_prob
snake_case__ : str = initializer_range
snake_case__ : List[str] = drop_path_rate
snake_case__ : int = layer_norm_eps
snake_case__ : Tuple = decoder_hidden_size
snake_case__ : List[Any] = max_depth
snake_case__ : Dict = head_in_index
| 35
| 0
|
'''simple docstring'''
from typing import TYPE_CHECKING
from ...utils import (
OptionalDependencyNotAvailable,
_LazyModule,
is_torch_available,
)
lowercase__ : Union[str, Any] = {
'''configuration_encodec''': [
'''ENCODEC_PRETRAINED_CONFIG_ARCHIVE_MAP''',
'''EncodecConfig''',
],
'''feature_extraction_encodec''': ['''EncodecFeatureExtractor'''],
}
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
lowercase__ : Tuple = [
'''ENCODEC_PRETRAINED_MODEL_ARCHIVE_LIST''',
'''EncodecModel''',
'''EncodecPreTrainedModel''',
]
if TYPE_CHECKING:
from .configuration_encodec import (
ENCODEC_PRETRAINED_CONFIG_ARCHIVE_MAP,
EncodecConfig,
)
from .feature_extraction_encodec import EncodecFeatureExtractor
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_encodec import (
ENCODEC_PRETRAINED_MODEL_ARCHIVE_LIST,
EncodecModel,
EncodecPreTrainedModel,
)
else:
import sys
lowercase__ : Optional[Any] = _LazyModule(__name__, globals()['''__file__'''], _import_structure, module_spec=__spec__)
| 190
|
'''simple docstring'''
import json
from typing import List, Optional, Tuple
from tokenizers import normalizers
from tokenizers.pre_tokenizers import BertPreTokenizer, PreTokenizer
from ...tokenization_utils_fast import PreTrainedTokenizerFast
from ...utils import logging
from .tokenization_roformer import RoFormerTokenizer
from .tokenization_utils import JiebaPreTokenizer
__a = logging.get_logger(__name__)
__a = {"vocab_file": "vocab.txt", "tokenizer_file": "tokenizer.json"}
__a = {
"vocab_file": {
"junnyu/roformer_chinese_small": "https://huggingface.co/junnyu/roformer_chinese_small/resolve/main/vocab.txt",
"junnyu/roformer_chinese_base": "https://huggingface.co/junnyu/roformer_chinese_base/resolve/main/vocab.txt",
"junnyu/roformer_chinese_char_small": (
"https://huggingface.co/junnyu/roformer_chinese_char_small/resolve/main/vocab.txt"
),
"junnyu/roformer_chinese_char_base": (
"https://huggingface.co/junnyu/roformer_chinese_char_base/resolve/main/vocab.txt"
),
"junnyu/roformer_small_discriminator": (
"https://huggingface.co/junnyu/roformer_small_discriminator/resolve/main/vocab.txt"
),
"junnyu/roformer_small_generator": (
"https://huggingface.co/junnyu/roformer_small_generator/resolve/main/vocab.txt"
),
}
}
__a = {
"junnyu/roformer_chinese_small": 1536,
"junnyu/roformer_chinese_base": 1536,
"junnyu/roformer_chinese_char_small": 512,
"junnyu/roformer_chinese_char_base": 512,
"junnyu/roformer_small_discriminator": 128,
"junnyu/roformer_small_generator": 128,
}
__a = {
"junnyu/roformer_chinese_small": {"do_lower_case": True},
"junnyu/roformer_chinese_base": {"do_lower_case": True},
"junnyu/roformer_chinese_char_small": {"do_lower_case": True},
"junnyu/roformer_chinese_char_base": {"do_lower_case": True},
"junnyu/roformer_small_discriminator": {"do_lower_case": True},
"junnyu/roformer_small_generator": {"do_lower_case": True},
}
class UpperCAmelCase_ ( _a ):
"""simple docstring"""
lowercase = VOCAB_FILES_NAMES
lowercase = PRETRAINED_VOCAB_FILES_MAP
lowercase = PRETRAINED_POSITIONAL_EMBEDDINGS_SIZES
lowercase = PRETRAINED_INIT_CONFIGURATION
lowercase = RoFormerTokenizer
def __init__( self : List[Any] , snake_case_ : List[str]=None , snake_case_ : Dict=None , snake_case_ : Any=True , snake_case_ : str="[UNK]" , snake_case_ : List[str]="[SEP]" , snake_case_ : Optional[Any]="[PAD]" , snake_case_ : Union[str, Any]="[CLS]" , snake_case_ : Union[str, Any]="[MASK]" , snake_case_ : List[Any]=True , snake_case_ : Optional[Any]=None , **snake_case_ : Tuple , ):
super().__init__(
snake_case_ , tokenizer_file=snake_case_ , do_lower_case=snake_case_ , unk_token=snake_case_ , sep_token=snake_case_ , pad_token=snake_case_ , cls_token=snake_case_ , mask_token=snake_case_ , tokenize_chinese_chars=snake_case_ , strip_accents=snake_case_ , **snake_case_ , )
snake_case__ : str = json.loads(self.backend_tokenizer.normalizer.__getstate__() )
if (
pre_tok_state.get("""lowercase""" , snake_case_ ) != do_lower_case
or pre_tok_state.get("""strip_accents""" , snake_case_ ) != strip_accents
):
snake_case__ : str = getattr(snake_case_ , pre_tok_state.pop("""type""" ) )
snake_case__ : Optional[int] = do_lower_case
snake_case__ : Union[str, Any] = strip_accents
snake_case__ : Union[str, Any] = pre_tok_class(**snake_case_ )
snake_case__ : str = do_lower_case
def __getstate__( self : int ):
snake_case__ : List[Any] = self.__dict__.copy()
snake_case__ : str = BertPreTokenizer()
return state
def __setstate__( self : Dict , snake_case_ : Dict ):
snake_case__ : List[Any] = d
snake_case__ : Union[str, Any] = self.__dict__["""_tokenizer"""].get_vocab()
snake_case__ : List[Any] = PreTokenizer.custom(JiebaPreTokenizer(snake_case_ ) )
def lowerCamelCase ( self : str , snake_case_ : Optional[Any] , snake_case_ : List[str]=None ):
snake_case__ : str = [self.cls_token_id] + token_ids_a + [self.sep_token_id]
if token_ids_a:
output += token_ids_a + [self.sep_token_id]
return output
def lowerCamelCase ( self : str , snake_case_ : List[int] , snake_case_ : Optional[List[int]] = None ):
snake_case__ : int = [self.sep_token_id]
snake_case__ : str = [self.cls_token_id]
if token_ids_a is None:
return len(cls + token_ids_a + sep ) * [0]
return len(cls + token_ids_a + sep ) * [0] + len(token_ids_a + sep ) * [1]
def lowerCamelCase ( self : Dict , snake_case_ : str , snake_case_ : Optional[str] = None ):
snake_case__ : Union[str, Any] = self._tokenizer.model.save(snake_case_ , name=snake_case_ )
return tuple(snake_case_ )
def lowerCamelCase ( self : Dict , snake_case_ : List[str] , snake_case_ : Tuple=None , snake_case_ : List[str]=None , snake_case_ : Union[str, Any]=False , **snake_case_ : Tuple , ):
snake_case__ : Optional[Any] = BertPreTokenizer()
return super().save_pretrained(snake_case_ , snake_case_ , snake_case_ , snake_case_ , **snake_case_ )
| 35
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|
from .dependency_versions_table import deps
from .utils.versions import require_version, require_version_core
# define which module versions we always want to check at run time
# (usually the ones defined in `install_requires` in setup.py)
#
# order specific notes:
# - tqdm must be checked before tokenizers
__lowerCAmelCase = [
'''python''',
'''tqdm''',
'''regex''',
'''requests''',
'''packaging''',
'''filelock''',
'''numpy''',
'''tokenizers''',
'''huggingface-hub''',
'''safetensors''',
'''accelerate''',
'''pyyaml''',
]
for pkg in pkgs_to_check_at_runtime:
if pkg in deps:
if pkg == "tokenizers":
# must be loaded here, or else tqdm check may fail
from .utils import is_tokenizers_available
if not is_tokenizers_available():
continue # not required, check version only if installed
elif pkg == "accelerate":
# must be loaded here, or else tqdm check may fail
from .utils import is_accelerate_available
# Maybe switch to is_torch_available in the future here so that Accelerate is hard dep of
# Transformers with PyTorch
if not is_accelerate_available():
continue # not required, check version only if installed
require_version_core(deps[pkg])
else:
raise ValueError(F'''can\'t find {pkg} in {deps.keys()}, check dependency_versions_table.py''')
def snake_case_ ( snake_case , snake_case=None ) -> int:
require_version(deps[pkg] , _lowerCAmelCase )
| 196
|
'''simple docstring'''
import os
import time
import pytest
from datasets.utils.filelock import FileLock, Timeout
def __snake_case( _lowerCAmelCase ) -> Optional[int]:
snake_case__ : int = FileLock(str(tmpdir / """foo.lock""" ) )
snake_case__ : Dict = FileLock(str(tmpdir / """foo.lock""" ) )
snake_case__ : List[str] = 0.01
with locka.acquire():
with pytest.raises(_lowerCAmelCase ):
snake_case__ : str = time.time()
locka.acquire(_lowerCAmelCase )
assert time.time() - _start > timeout
def __snake_case( _lowerCAmelCase ) -> Tuple:
snake_case__ : Dict = """a""" * 1_000 + """.lock"""
snake_case__ : int = FileLock(str(tmpdir / filename ) )
assert locka._lock_file.endswith(""".lock""" )
assert not locka._lock_file.endswith(_lowerCAmelCase )
assert len(os.path.basename(locka._lock_file ) ) <= 255
snake_case__ : Dict = FileLock(tmpdir / filename )
with locka.acquire():
with pytest.raises(_lowerCAmelCase ):
locka.acquire(0 )
| 35
| 0
|
from __future__ import annotations
A : Optional[int] = list[list[int]]
# assigning initial values to the grid
A : int = [
[3, 0, 6, 5, 0, 8, 4, 0, 0],
[5, 2, 0, 0, 0, 0, 0, 0, 0],
[0, 8, 7, 0, 0, 0, 0, 3, 1],
[0, 0, 3, 0, 1, 0, 0, 8, 0],
[9, 0, 0, 8, 6, 3, 0, 0, 5],
[0, 5, 0, 0, 9, 0, 6, 0, 0],
[1, 3, 0, 0, 0, 0, 2, 5, 0],
[0, 0, 0, 0, 0, 0, 0, 7, 4],
[0, 0, 5, 2, 0, 6, 3, 0, 0],
]
# a grid with no solution
A : Dict = [
[5, 0, 6, 5, 0, 8, 4, 0, 3],
[5, 2, 0, 0, 0, 0, 0, 0, 2],
[1, 8, 7, 0, 0, 0, 0, 3, 1],
[0, 0, 3, 0, 1, 0, 0, 8, 0],
[9, 0, 0, 8, 6, 3, 0, 0, 5],
[0, 5, 0, 0, 9, 0, 6, 0, 0],
[1, 3, 0, 0, 0, 0, 2, 5, 0],
[0, 0, 0, 0, 0, 0, 0, 7, 4],
[0, 0, 5, 2, 0, 6, 3, 0, 0],
]
def lowercase_ ( _A : Union[str, Any] , _A : Optional[Any] , _A : Tuple , _A : List[str] ):
"""simple docstring"""
for i in range(9 ):
if grid[row][i] == n or grid[i][column] == n:
return False
for i in range(3 ):
for j in range(3 ):
if grid[(row - row % 3) + i][(column - column % 3) + j] == n:
return False
return True
def lowercase_ ( _A : int ):
"""simple docstring"""
for i in range(9 ):
for j in range(9 ):
if grid[i][j] == 0:
return i, j
return None
def lowercase_ ( _A : Optional[Any] ):
"""simple docstring"""
if location := find_empty_location(_lowerCAmelCase ):
lowerCamelCase__ : str = location
else:
# If the location is ``None``, then the grid is solved.
return grid
for digit in range(1 , 10 ):
if is_safe(_lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase ):
lowerCamelCase__ : Optional[Any] = digit
if sudoku(_lowerCAmelCase ) is not None:
return grid
lowerCamelCase__ : Any = 0
return None
def lowercase_ ( _A : int ):
"""simple docstring"""
for row in grid:
for cell in row:
print(_lowerCAmelCase , end=" " )
print()
if __name__ == "__main__":
# make a copy of grid so that you can compare with the unmodified grid
for example_grid in (initial_grid, no_solution):
print("\nExample grid:\n" + "=" * 20)
print_solution(example_grid)
print("\nExample grid solution:")
A : int = sudoku(example_grid)
if solution is not None:
print_solution(solution)
else:
print("Cannot find a solution.")
| 184
|
'''simple docstring'''
def __snake_case( _lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase ) -> float:
snake_case__ : str = (num_of_terms / 2) * (2 * first_term + (num_of_terms - 1) * common_diff)
# formula for sum of series
return total
def __snake_case( ) -> List[str]:
print(sum_of_series(1 , 1 , 10 ) )
if __name__ == "__main__":
import doctest
doctest.testmod()
| 35
| 0
|
'''simple docstring'''
from __future__ import annotations
import math
import numpy as np
from numpy.linalg import norm
def lowerCAmelCase (__A , __A):
"""simple docstring"""
return math.sqrt(sum(pow(a - b , 2) for a, b in zip(_lowerCAmelCase , _lowerCAmelCase)))
def lowerCAmelCase (__A , __A):
"""simple docstring"""
if dataset.ndim != value_array.ndim:
_a = (
"""Wrong input data's dimensions... """
F'''dataset : {dataset.ndim}, value_array : {value_array.ndim}'''
)
raise ValueError(_lowerCAmelCase)
try:
if dataset.shape[1] != value_array.shape[1]:
_a = (
"""Wrong input data's shape... """
F'''dataset : {dataset.shape[1]}, value_array : {value_array.shape[1]}'''
)
raise ValueError(_lowerCAmelCase)
except IndexError:
if dataset.ndim != value_array.ndim:
raise TypeError('''Wrong shape''')
if dataset.dtype != value_array.dtype:
_a = (
"""Input data have different datatype... """
F'''dataset : {dataset.dtype}, value_array : {value_array.dtype}'''
)
raise TypeError(_lowerCAmelCase)
_a = []
for value in value_array:
_a = euclidean(_lowerCAmelCase , dataset[0])
_a = dataset[0].tolist()
for dataset_value in dataset[1:]:
_a = euclidean(_lowerCAmelCase , _lowerCAmelCase)
if dist > temp_dist:
_a = temp_dist
_a = dataset_value.tolist()
answer.append([vector, dist])
return answer
def lowerCAmelCase (__A , __A):
"""simple docstring"""
return np.dot(_lowerCAmelCase , _lowerCAmelCase) / (norm(_lowerCAmelCase) * norm(_lowerCAmelCase))
if __name__ == "__main__":
import doctest
doctest.testmod()
| 211
|
'''simple docstring'''
__a = frozenset(
[
"prompt",
"height",
"width",
"guidance_scale",
"negative_prompt",
"prompt_embeds",
"negative_prompt_embeds",
"cross_attention_kwargs",
]
)
__a = frozenset(["prompt", "negative_prompt"])
__a = frozenset([])
__a = frozenset(["image"])
__a = frozenset(
[
"image",
"height",
"width",
"guidance_scale",
]
)
__a = frozenset(["image"])
__a = frozenset(
[
"prompt",
"image",
"height",
"width",
"guidance_scale",
"negative_prompt",
"prompt_embeds",
"negative_prompt_embeds",
]
)
__a = frozenset(["prompt", "image", "negative_prompt"])
__a = frozenset(
[
# Text guided image variation with an image mask
"prompt",
"image",
"mask_image",
"height",
"width",
"guidance_scale",
"negative_prompt",
"prompt_embeds",
"negative_prompt_embeds",
]
)
__a = frozenset(["prompt", "image", "mask_image", "negative_prompt"])
__a = frozenset(
[
# image variation with an image mask
"image",
"mask_image",
"height",
"width",
"guidance_scale",
]
)
__a = frozenset(["image", "mask_image"])
__a = frozenset(
[
"example_image",
"image",
"mask_image",
"height",
"width",
"guidance_scale",
]
)
__a = frozenset(["example_image", "image", "mask_image"])
__a = frozenset(["class_labels"])
__a = frozenset(["class_labels"])
__a = frozenset(["batch_size"])
__a = frozenset([])
__a = frozenset(["batch_size"])
__a = frozenset([])
__a = frozenset(
[
"prompt",
"audio_length_in_s",
"guidance_scale",
"negative_prompt",
"prompt_embeds",
"negative_prompt_embeds",
"cross_attention_kwargs",
]
)
__a = frozenset(["prompt", "negative_prompt"])
__a = frozenset(["input_tokens"])
__a = frozenset(["input_tokens"])
| 35
| 0
|
from __future__ import annotations
from collections import Counter
from random import random
class __lowerCAmelCase :
def __init__( self ) -> Optional[int]:
'''simple docstring'''
_lowercase ={}
def A__ ( self , lowerCAmelCase ) -> Tuple:
'''simple docstring'''
_lowercase ={}
def A__ ( self , lowerCAmelCase , lowerCAmelCase , lowerCAmelCase ) -> List[str]:
'''simple docstring'''
if nodea not in self.connections:
self.add_node(snake_case_ )
if nodea not in self.connections:
self.add_node(snake_case_ )
_lowercase =probability
def A__ ( self ) -> str:
'''simple docstring'''
return list(self.connections )
def A__ ( self , lowerCAmelCase ) -> Any:
'''simple docstring'''
_lowercase =0
_lowercase =random()
for dest in self.connections[node]:
current_probability += self.connections[node][dest]
if current_probability > random_value:
return dest
return ""
def a ( A__ : int , A__ : Dict , A__ : int ) -> dict[str, int]:
"""simple docstring"""
_lowercase =MarkovChainGraphUndirectedUnweighted()
for nodea, nodea, probability in transitions:
graph.add_transition_probability(_lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase )
_lowercase =Counter(graph.get_nodes() )
_lowercase =start
for _ in range(_lowerCAmelCase ):
_lowercase =graph.transition(_lowerCAmelCase )
visited[node] += 1
return visited
if __name__ == "__main__":
import doctest
doctest.testmod()
| 205
|
'''simple docstring'''
import json
import os
import unittest
from transformers.models.gptsan_japanese.tokenization_gptsan_japanese import (
VOCAB_FILES_NAMES,
GPTSanJapaneseTokenizer,
)
from transformers.testing_utils import require_tokenizers, slow
from ...test_tokenization_common import TokenizerTesterMixin
@require_tokenizers
class UpperCAmelCase_ ( _a , unittest.TestCase ):
"""simple docstring"""
lowercase = GPTSanJapaneseTokenizer
lowercase = False
lowercase = {"do_clean_text": False, "add_prefix_space": False}
def lowerCamelCase ( self : str ):
super().setUp()
# fmt: off
snake_case__ : Optional[Any] = ["""こん""", """こんに""", """にちは""", """ばんは""", """世界,㔺界""", """、""", """。""", """<BR>""", """<SP>""", """<TAB>""", """<URL>""", """<EMAIL>""", """<TEL>""", """<DATE>""", """<PRICE>""", """<BLOCK>""", """<KIGOU>""", """<U2000U2BFF>""", """<|emoji1|>""", """<unk>""", """<|bagoftoken|>""", """<|endoftext|>"""]
# fmt: on
snake_case__ : int = {"""emoji""": {"""\ud83d\ude00""": """<|emoji1|>"""}, """emoji_inv""": {"""<|emoji1|>""": """\ud83d\ude00"""}} # 😀
snake_case__ : List[Any] = {"""unk_token""": """<unk>"""}
snake_case__ : Optional[Any] = os.path.join(self.tmpdirname , VOCAB_FILES_NAMES["""vocab_file"""] )
snake_case__ : Dict = os.path.join(self.tmpdirname , VOCAB_FILES_NAMES["""emoji_file"""] )
with open(self.vocab_file , """w""" , encoding="""utf-8""" ) as vocab_writer:
vocab_writer.write("""""".join([x + """\n""" for x in vocab_tokens] ) )
with open(self.emoji_file , """w""" ) as emoji_writer:
emoji_writer.write(json.dumps(snake_case_ ) )
def lowerCamelCase ( self : Any , **snake_case_ : Union[str, Any] ):
kwargs.update(self.special_tokens_map )
return GPTSanJapaneseTokenizer.from_pretrained(self.tmpdirname , **snake_case_ )
def lowerCamelCase ( self : Any , snake_case_ : str ):
snake_case__ : Union[str, Any] = """こんにちは、世界。 \nこんばんは、㔺界。😀"""
snake_case__ : List[str] = """こんにちは、世界。 \nこんばんは、世界。😀"""
return input_text, output_text
def lowerCamelCase ( self : Any , snake_case_ : Dict ):
snake_case__ , snake_case__ : int = self.get_input_output_texts(snake_case_ )
snake_case__ : int = tokenizer.encode(snake_case_ , add_special_tokens=snake_case_ )
snake_case__ : List[str] = tokenizer.decode(snake_case_ , clean_up_tokenization_spaces=snake_case_ )
return text, ids
def lowerCamelCase ( self : Optional[Any] ):
pass # TODO add if relevant
def lowerCamelCase ( self : Union[str, Any] ):
pass # TODO add if relevant
def lowerCamelCase ( self : List[str] ):
pass # TODO add if relevant
def lowerCamelCase ( self : Dict ):
snake_case__ : Optional[Any] = self.get_tokenizer()
# Testing tokenization
snake_case__ : int = """こんにちは、世界。 こんばんは、㔺界。"""
snake_case__ : Optional[int] = ["""こん""", """にちは""", """、""", """世界""", """。""", """<SP>""", """こん""", """ばんは""", """、""", """㔺界""", """。"""]
snake_case__ : Dict = tokenizer.tokenize(snake_case_ )
self.assertListEqual(snake_case_ , snake_case_ )
# Testing conversion to ids without special tokens
snake_case__ : Union[str, Any] = [0, 2, 5, 4, 6, 8, 0, 3, 5, 4, 6]
snake_case__ : List[Any] = tokenizer.convert_tokens_to_ids(snake_case_ )
self.assertListEqual(snake_case_ , snake_case_ )
# Testing conversion to ids with special tokens
snake_case__ : Union[str, Any] = tokens + [tokenizer.unk_token]
snake_case__ : Dict = [0, 2, 5, 4, 6, 8, 0, 3, 5, 4, 6, 19]
snake_case__ : Any = tokenizer.convert_tokens_to_ids(snake_case_ )
self.assertListEqual(snake_case_ , snake_case_ )
def lowerCamelCase ( self : Optional[Any] ):
snake_case__ : Union[str, Any] = self.get_tokenizer()
# Testing tokenization
snake_case__ : Union[str, Any] = """こんにちは、<|bagoftoken|>世界。こんばんは、<|bagoftoken|>㔺界。"""
snake_case__ : Optional[int] = """こんにちは、、、、世界。こんばんは、、、、世界。"""
snake_case__ : Any = tokenizer.encode(snake_case_ )
snake_case__ : int = tokenizer.decode(snake_case_ )
self.assertEqual(snake_case_ , snake_case_ )
@slow
def lowerCamelCase ( self : Union[str, Any] ):
snake_case__ : Optional[Any] = self.tokenizer_class.from_pretrained("""Tanrei/GPTSAN-japanese""" )
# Testing tokenization
snake_case__ : Tuple = """こんにちは、世界。"""
snake_case__ : Optional[Any] = """こんばんは、㔺界。😀"""
snake_case__ : List[str] = """こんにちは、世界。こんばんは、世界。😀"""
snake_case__ : Dict = tokenizer.encode(prefix_text + input_text )
snake_case__ : Dict = tokenizer.encode("""""" , prefix_text=prefix_text + input_text )
snake_case__ : int = tokenizer.encode(snake_case_ , prefix_text=snake_case_ )
snake_case__ : Optional[Any] = tokenizer.decode(snake_case_ )
snake_case__ : Union[str, Any] = tokenizer.decode(snake_case_ )
snake_case__ : str = tokenizer.decode(snake_case_ )
self.assertEqual(snake_case_ , snake_case_ )
self.assertEqual(snake_case_ , snake_case_ )
self.assertEqual(snake_case_ , snake_case_ )
@slow
def lowerCamelCase ( self : Union[str, Any] ):
snake_case__ : Optional[Any] = self.tokenizer_class.from_pretrained("""Tanrei/GPTSAN-japanese""" )
# Testing tokenization
snake_case__ : Dict = """こんにちは、世界。"""
snake_case__ : Optional[int] = """こんばんは、㔺界。😀"""
snake_case__ : Any = len(tokenizer.encode(snake_case_ ) ) - 2
snake_case__ : Optional[int] = len(tokenizer.encode(snake_case_ ) ) - 2
snake_case__ : List[str] = [1] + [0] * (len_prefix + len_text + 1)
snake_case__ : Optional[int] = [1] * (len_prefix + len_text + 1) + [0]
snake_case__ : int = [1] + [1] * (len_prefix) + [0] * (len_text + 1)
snake_case__ : Any = tokenizer(prefix_text + input_text ).token_type_ids
snake_case__ : str = tokenizer("""""" , prefix_text=prefix_text + input_text ).token_type_ids
snake_case__ : Optional[Any] = tokenizer(snake_case_ , prefix_text=snake_case_ ).token_type_ids
self.assertListEqual(snake_case_ , snake_case_ )
self.assertListEqual(snake_case_ , snake_case_ )
self.assertListEqual(snake_case_ , snake_case_ )
@slow
def lowerCamelCase ( self : Optional[int] ):
snake_case__ : Optional[Any] = self.tokenizer_class.from_pretrained("""Tanrei/GPTSAN-japanese""" )
snake_case__ : Union[str, Any] = tokenizer.encode("""あンいワ""" )
snake_case__ : int = tokenizer.encode("""""" , prefix_text="""あンいワ""" )
snake_case__ : Dict = tokenizer.encode("""いワ""" , prefix_text="""あン""" )
self.assertEqual(tokenizer.decode(snake_case_ ) , tokenizer.decode(snake_case_ ) )
self.assertEqual(tokenizer.decode(snake_case_ ) , tokenizer.decode(snake_case_ ) )
self.assertNotEqual(snake_case_ , snake_case_ )
self.assertNotEqual(snake_case_ , snake_case_ )
self.assertEqual(x_token_a[1] , x_token_a[-1] ) # SEG token
self.assertEqual(x_token_a[1] , x_token_a[3] ) # SEG token
@slow
def lowerCamelCase ( self : Any ):
snake_case__ : Optional[int] = self.tokenizer_class.from_pretrained("""Tanrei/GPTSAN-japanese""" )
snake_case__ : int = [["""武田信玄""", """は、"""], ["""織田信長""", """の配下の、"""]]
snake_case__ : Optional[Any] = tokenizer(snake_case_ , padding=snake_case_ )
snake_case__ : Tuple = tokenizer.batch_encode_plus(snake_case_ , padding=snake_case_ )
# fmt: off
snake_case__ : Optional[Any] = [[35_993, 8_640, 25_948, 35_998, 30_647, 35_675, 35_999, 35_999], [35_993, 10_382, 9_868, 35_998, 30_646, 9_459, 30_646, 35_675]]
snake_case__ : Optional[Any] = [[1, 1, 1, 0, 0, 0, 0, 0], [1, 1, 1, 0, 0, 0, 0, 0]]
snake_case__ : Optional[Any] = [[1, 1, 1, 1, 1, 1, 0, 0], [1, 1, 1, 1, 1, 1, 1, 1]]
# fmt: on
self.assertListEqual(x_token.input_ids , snake_case_ )
self.assertListEqual(x_token.token_type_ids , snake_case_ )
self.assertListEqual(x_token.attention_mask , snake_case_ )
self.assertListEqual(x_token_a.input_ids , snake_case_ )
self.assertListEqual(x_token_a.token_type_ids , snake_case_ )
self.assertListEqual(x_token_a.attention_mask , snake_case_ )
def lowerCamelCase ( self : Any ):
# Intentionally convert some words to accommodate character fluctuations unique to Japanese
pass
def lowerCamelCase ( self : List[str] ):
# tokenizer has no padding token
pass
| 35
| 0
|
import time
from dataclasses import dataclass
from multiprocessing import Pool
from unittest import TestCase
from unittest.mock import patch
import multiprocess
import numpy as np
import pytest
from datasets.utils.py_utils import (
NestedDataStructure,
asdict,
iflatmap_unordered,
map_nested,
temp_seed,
temporary_assignment,
zip_dict,
)
from .utils import require_tf, require_torch
def SCREAMING_SNAKE_CASE_ ( __magic_name__ : Any ) -> str: # picklable for multiprocessing
"""simple docstring"""
return x.sum()
def SCREAMING_SNAKE_CASE_ ( __magic_name__ : Union[str, Any] ) -> Tuple: # picklable for multiprocessing
"""simple docstring"""
return i + 1
@dataclass
class _SCREAMING_SNAKE_CASE :
snake_case__ : Dict = 4_2
snake_case__ : Dict = 4_2
class _SCREAMING_SNAKE_CASE ( _a ):
def _A ( self : str ):
UpperCamelCase :int = {}
UpperCamelCase :Tuple = []
UpperCamelCase :Any = 1
UpperCamelCase :str = [1, 2]
UpperCamelCase :List[str] = {"""a""": 1, """b""": 2}
UpperCamelCase :List[str] = {"""a""": [1, 2], """b""": [3, 4]}
UpperCamelCase :Dict = {"""a""": {"""1""": 1}, """b""": 2}
UpperCamelCase :List[Any] = {"""a""": 1, """b""": 2, """c""": 3, """d""": 4}
UpperCamelCase :List[str] = {}
UpperCamelCase :List[str] = []
UpperCamelCase :str = 2
UpperCamelCase :Dict = [2, 3]
UpperCamelCase :List[Any] = {"""a""": 2, """b""": 3}
UpperCamelCase :Dict = {"""a""": [2, 3], """b""": [4, 5]}
UpperCamelCase :List[str] = {"""a""": {"""1""": 2}, """b""": 3}
UpperCamelCase :List[Any] = {"""a""": 2, """b""": 3, """c""": 4, """d""": 5}
self.assertEqual(map_nested(snake_case_ , snake_case_ ) , snake_case_ )
self.assertEqual(map_nested(snake_case_ , snake_case_ ) , snake_case_ )
self.assertEqual(map_nested(snake_case_ , snake_case_ ) , snake_case_ )
self.assertEqual(map_nested(snake_case_ , snake_case_ ) , snake_case_ )
self.assertEqual(map_nested(snake_case_ , snake_case_ ) , snake_case_ )
self.assertEqual(map_nested(snake_case_ , snake_case_ ) , snake_case_ )
self.assertEqual(map_nested(snake_case_ , snake_case_ ) , snake_case_ )
self.assertEqual(map_nested(snake_case_ , snake_case_ ) , snake_case_ )
UpperCamelCase :List[str] = 2
self.assertEqual(map_nested(snake_case_ , snake_case_ , num_proc=snake_case_ ) , snake_case_ )
self.assertEqual(map_nested(snake_case_ , snake_case_ , num_proc=snake_case_ ) , snake_case_ )
self.assertEqual(map_nested(snake_case_ , snake_case_ , num_proc=snake_case_ ) , snake_case_ )
self.assertEqual(map_nested(snake_case_ , snake_case_ , num_proc=snake_case_ ) , snake_case_ )
self.assertEqual(map_nested(snake_case_ , snake_case_ , num_proc=snake_case_ ) , snake_case_ )
self.assertEqual(map_nested(snake_case_ , snake_case_ , num_proc=snake_case_ ) , snake_case_ )
self.assertEqual(map_nested(snake_case_ , snake_case_ , num_proc=snake_case_ ) , snake_case_ )
self.assertEqual(map_nested(snake_case_ , snake_case_ , num_proc=snake_case_ ) , snake_case_ )
UpperCamelCase :Tuple = {"""a""": np.eye(2 ), """b""": np.zeros(3 ), """c""": np.ones(2 )}
UpperCamelCase :Union[str, Any] = {"""a""": 2, """b""": 0, """c""": 2}
UpperCamelCase :Optional[Any] = {
"""a""": np.eye(2 ).astype(snake_case_ ),
"""b""": np.zeros(3 ).astype(snake_case_ ),
"""c""": np.ones(2 ).astype(snake_case_ ),
}
self.assertEqual(map_nested(snake_case_ , snake_case_ , map_numpy=snake_case_ ) , snake_case_ )
self.assertEqual(
{k: v.tolist() for k, v in map_nested(snake_case_ , snake_case_ , map_numpy=snake_case_ ).items()} , {k: v.tolist() for k, v in expected_map_nested_sna_int.items()} , )
self.assertEqual(map_nested(snake_case_ , snake_case_ , map_numpy=snake_case_ , num_proc=snake_case_ ) , snake_case_ )
self.assertEqual(
{k: v.tolist() for k, v in map_nested(snake_case_ , snake_case_ , map_numpy=snake_case_ , num_proc=snake_case_ ).items()} , {k: v.tolist() for k, v in expected_map_nested_sna_int.items()} , )
with self.assertRaises(snake_case_ ): # can't pickle a local lambda
map_nested(lambda __lowerCamelCase : x + 1 , snake_case_ , num_proc=snake_case_ )
def _A ( self : int ):
UpperCamelCase :Tuple = {"""a""": 1, """b""": 2}
UpperCamelCase :Dict = {"""a""": 3, """b""": 4}
UpperCamelCase :List[str] = {"""a""": 5, """b""": 6}
UpperCamelCase :Tuple = sorted([("""a""", (1, 3, 5)), ("""b""", (2, 4, 6))] )
self.assertEqual(sorted(zip_dict(snake_case_ , snake_case_ , snake_case_ ) ) , snake_case_ )
def _A ( self : int ):
class _SCREAMING_SNAKE_CASE :
snake_case__ : str = """bar"""
UpperCamelCase :Tuple = Foo()
self.assertEqual(foo.my_attr , """bar""" )
with temporary_assignment(snake_case_ , """my_attr""" , """BAR""" ):
self.assertEqual(foo.my_attr , """BAR""" )
self.assertEqual(foo.my_attr , """bar""" )
@pytest.mark.parametrize(
"""iterable_length, num_proc, expected_num_proc""" , [
(1, None, 1),
(1, 1, 1),
(2, None, 1),
(2, 1, 1),
(2, 2, 1),
(2, 3, 1),
(3, 2, 1),
(16, 16, 16),
(16, 17, 16),
(17, 16, 16),
] , )
def SCREAMING_SNAKE_CASE_ ( __magic_name__ : Optional[Any] , __magic_name__ : Dict , __magic_name__ : List[Any] ) -> Optional[int]:
"""simple docstring"""
with patch("""datasets.utils.py_utils._single_map_nested""" ) as mock_single_map_nested, patch(
"""datasets.parallel.parallel.Pool""" ) as mock_multiprocessing_pool:
UpperCamelCase :Union[str, Any] = {f"""{i}""": i for i in range(_lowerCAmelCase )}
UpperCamelCase :int = map_nested(lambda __magic_name__ : x + 10 , _lowerCAmelCase , num_proc=_lowerCAmelCase , parallel_min_length=16 )
if expected_num_proc == 1:
assert mock_single_map_nested.called
assert not mock_multiprocessing_pool.called
else:
assert not mock_single_map_nested.called
assert mock_multiprocessing_pool.called
assert mock_multiprocessing_pool.call_args[0][0] == expected_num_proc
class _SCREAMING_SNAKE_CASE ( _a ):
@require_tf
def _A ( self : Optional[int] ):
import tensorflow as tf
from tensorflow.keras import layers
UpperCamelCase :Tuple = layers.Dense(2 )
def gen_random_output():
UpperCamelCase :Union[str, Any] = tf.random.uniform((1, 3) )
return model(snake_case_ ).numpy()
with temp_seed(42 , set_tensorflow=snake_case_ ):
UpperCamelCase :List[Any] = gen_random_output()
with temp_seed(42 , set_tensorflow=snake_case_ ):
UpperCamelCase :List[str] = gen_random_output()
UpperCamelCase :Any = gen_random_output()
np.testing.assert_equal(snake_case_ , snake_case_ )
self.assertGreater(np.abs(outa - outa ).sum() , 0 )
@require_torch
def _A ( self : Union[str, Any] ):
import torch
def gen_random_output():
UpperCamelCase :List[str] = torch.nn.Linear(3 , 2 )
UpperCamelCase :Tuple = torch.rand(1 , 3 )
return model(snake_case_ ).detach().numpy()
with temp_seed(42 , set_pytorch=snake_case_ ):
UpperCamelCase :List[str] = gen_random_output()
with temp_seed(42 , set_pytorch=snake_case_ ):
UpperCamelCase :List[str] = gen_random_output()
UpperCamelCase :List[str] = gen_random_output()
np.testing.assert_equal(snake_case_ , snake_case_ )
self.assertGreater(np.abs(outa - outa ).sum() , 0 )
def _A ( self : Optional[Any] ):
def gen_random_output():
return np.random.rand(1 , 3 )
with temp_seed(42 ):
UpperCamelCase :Union[str, Any] = gen_random_output()
with temp_seed(42 ):
UpperCamelCase :List[str] = gen_random_output()
UpperCamelCase :Optional[int] = gen_random_output()
np.testing.assert_equal(snake_case_ , snake_case_ )
self.assertGreater(np.abs(outa - outa ).sum() , 0 )
@pytest.mark.parametrize("""input_data""" , [{}] )
def SCREAMING_SNAKE_CASE_ ( __magic_name__ : str ) -> Union[str, Any]:
"""simple docstring"""
UpperCamelCase :Any = NestedDataStructure(_lowerCAmelCase ).data
assert output_data == input_data
@pytest.mark.parametrize(
"""data, expected_output""" , [
({}, []),
([], []),
("""foo""", ["""foo"""]),
(["""foo""", """bar"""], ["""foo""", """bar"""]),
([["""foo""", """bar"""]], ["""foo""", """bar"""]),
([[["""foo"""], ["""bar"""]]], ["""foo""", """bar"""]),
([[["""foo"""], """bar"""]], ["""foo""", """bar"""]),
({"""a""": 1, """b""": 2}, [1, 2]),
({"""a""": [1, 2], """b""": [3, 4]}, [1, 2, 3, 4]),
({"""a""": [[1, 2]], """b""": [[3, 4]]}, [1, 2, 3, 4]),
({"""a""": [[1, 2]], """b""": [3, 4]}, [1, 2, 3, 4]),
({"""a""": [[[1], [2]]], """b""": [[[3], [4]]]}, [1, 2, 3, 4]),
({"""a""": [[[1], [2]]], """b""": [[3, 4]]}, [1, 2, 3, 4]),
({"""a""": [[[1], [2]]], """b""": [3, 4]}, [1, 2, 3, 4]),
({"""a""": [[[1], [2]]], """b""": [3, [4]]}, [1, 2, 3, 4]),
({"""a""": {"""1""": 1}, """b""": 2}, [1, 2]),
({"""a""": {"""1""": [1]}, """b""": 2}, [1, 2]),
({"""a""": {"""1""": [1]}, """b""": [2]}, [1, 2]),
] , )
def SCREAMING_SNAKE_CASE_ ( __magic_name__ : str , __magic_name__ : Optional[int] ) -> Union[str, Any]:
"""simple docstring"""
UpperCamelCase :Dict = NestedDataStructure(_lowerCAmelCase ).flatten()
assert output == expected_output
def SCREAMING_SNAKE_CASE_ ( ) -> Any:
"""simple docstring"""
UpperCamelCase :Optional[int] = A(x=1 , y="""foobar""" )
UpperCamelCase :Any = {"""x""": 1, """y""": """foobar"""}
assert asdict(_lowerCAmelCase ) == expected_output
UpperCamelCase :str = {"""a""": {"""b""": A(x=10 , y="""foo""" )}, """c""": [A(x=20 , y="""bar""" )]}
UpperCamelCase :Optional[int] = {"""a""": {"""b""": {"""x""": 10, """y""": """foo"""}}, """c""": [{"""x""": 20, """y""": """bar"""}]}
assert asdict(_lowerCAmelCase ) == expected_output
with pytest.raises(_lowerCAmelCase ):
asdict([1, A(x=10 , y="""foo""" )] )
def SCREAMING_SNAKE_CASE_ ( __magic_name__ : List[str] ) -> Optional[int]:
"""simple docstring"""
return text.split()
def SCREAMING_SNAKE_CASE_ ( __magic_name__ : Tuple ) -> Optional[int]:
"""simple docstring"""
yield (time.time(), content)
time.sleep(2 )
yield (time.time(), content)
def SCREAMING_SNAKE_CASE_ ( ) -> Optional[Any]:
"""simple docstring"""
with Pool(2 ) as pool:
UpperCamelCase :Tuple = list(iflatmap_unordered(_lowerCAmelCase , _split_text , kwargs_iterable=[{"""text""": """hello there"""}] * 10 ) )
assert out.count("""hello""" ) == 10
assert out.count("""there""" ) == 10
assert len(_lowerCAmelCase ) == 20
# check multiprocess from pathos (uses dill for pickling)
with multiprocess.Pool(2 ) as pool:
UpperCamelCase :Optional[Any] = list(iflatmap_unordered(_lowerCAmelCase , _split_text , kwargs_iterable=[{"""text""": """hello there"""}] * 10 ) )
assert out.count("""hello""" ) == 10
assert out.count("""there""" ) == 10
assert len(_lowerCAmelCase ) == 20
# check that we get items as fast as possible
with Pool(2 ) as pool:
UpperCamelCase :str = []
for yield_time, content in iflatmap_unordered(
_lowerCAmelCase , _aseconds_generator_of_aitems_with_timing , kwargs_iterable=[{"""content""": """a"""}, {"""content""": """b"""}] ):
assert yield_time < time.time() + 0.1, "we should each item directly after it was yielded"
out.append(_lowerCAmelCase )
assert out.count("""a""" ) == 2
assert out.count("""b""" ) == 2
assert len(_lowerCAmelCase ) == 4
| 38
|
'''simple docstring'''
from transformers import BertTokenizerFast
from .custom_tokenization import CustomTokenizer
class UpperCAmelCase_ ( _a ):
"""simple docstring"""
lowercase = CustomTokenizer
pass
| 35
| 0
|
"""simple docstring"""
import re
import string
import numpy as np
import datasets
_UpperCamelCase : Optional[int] = "\nReturns the rate at which the input predicted strings exactly match their references, ignoring any strings input as part of the regexes_to_ignore list.\n"
_UpperCamelCase : Optional[Any] = "\nArgs:\n predictions: List of predicted texts.\n references: List of reference texts.\n regexes_to_ignore: List, defaults to None. Regex expressions of characters to\n ignore when calculating the exact matches. Note: these regexes are removed\n from the input data before the changes based on the options below (e.g. ignore_case,\n ignore_punctuation, ignore_numbers) are applied.\n ignore_case: Boolean, defaults to False. If true, turns everything\n to lowercase so that capitalization differences are ignored.\n ignore_punctuation: Boolean, defaults to False. If true, removes all punctuation before\n comparing predictions and references.\n ignore_numbers: Boolean, defaults to False. If true, removes all punctuation before\n comparing predictions and references.\nReturns:\n exact_match: Dictionary containing exact_match rate. Possible values are between 0.0 and 100.0, inclusive.\nExamples:\n >>> exact_match = datasets.load_metric(\"exact_match\")\n >>> refs = [\"the cat\", \"theater\", \"YELLING\", \"agent007\"]\n >>> preds = [\"cat?\", \"theater\", \"yelling\", \"agent\"]\n >>> results = exact_match.compute(references=refs, predictions=preds)\n >>> print(round(results[\"exact_match\"], 1))\n 25.0\n\n >>> exact_match = datasets.load_metric(\"exact_match\")\n >>> refs = [\"the cat\", \"theater\", \"YELLING\", \"agent007\"]\n >>> preds = [\"cat?\", \"theater\", \"yelling\", \"agent\"]\n >>> results = exact_match.compute(references=refs, predictions=preds, regexes_to_ignore=[\"the \", \"yell\"], ignore_case=True, ignore_punctuation=True)\n >>> print(round(results[\"exact_match\"], 1))\n 50.0\n\n\n >>> exact_match = datasets.load_metric(\"exact_match\")\n >>> refs = [\"the cat\", \"theater\", \"YELLING\", \"agent007\"]\n >>> preds = [\"cat?\", \"theater\", \"yelling\", \"agent\"]\n >>> results = exact_match.compute(references=refs, predictions=preds, regexes_to_ignore=[\"the \", \"yell\", \"YELL\"], ignore_case=True, ignore_punctuation=True)\n >>> print(round(results[\"exact_match\"], 1))\n 75.0\n\n >>> exact_match = datasets.load_metric(\"exact_match\")\n >>> refs = [\"the cat\", \"theater\", \"YELLING\", \"agent007\"]\n >>> preds = [\"cat?\", \"theater\", \"yelling\", \"agent\"]\n >>> results = exact_match.compute(references=refs, predictions=preds, regexes_to_ignore=[\"the \", \"yell\", \"YELL\"], ignore_case=True, ignore_punctuation=True, ignore_numbers=True)\n >>> print(round(results[\"exact_match\"], 1))\n 100.0\n\n >>> exact_match = datasets.load_metric(\"exact_match\")\n >>> refs = [\"The cat sat on the mat.\", \"Theaters are great.\", \"It's like comparing oranges and apples.\"]\n >>> preds = [\"The cat sat on the mat?\", \"Theaters are great.\", \"It's like comparing apples and oranges.\"]\n >>> results = exact_match.compute(references=refs, predictions=preds)\n >>> print(round(results[\"exact_match\"], 1))\n 33.3\n\n"
_UpperCamelCase : List[str] = "\n"
@datasets.utils.file_utils.add_start_docstrings(_DESCRIPTION , _KWARGS_DESCRIPTION)
class UpperCAmelCase_ ( datasets.Metric):
def _UpperCAmelCase ( self ) -> Any:
return datasets.MetricInfo(
description=_DESCRIPTION , citation=_CITATION , inputs_description=_KWARGS_DESCRIPTION , features=datasets.Features(
{
'predictions': datasets.Value('string' , id='sequence' ),
'references': datasets.Value('string' , id='sequence' ),
} ) , reference_urls=[] , )
def _UpperCAmelCase ( self , a , a , a=None , a=False , a=False , a=False , ) -> List[Any]:
if regexes_to_ignore is not None:
for s in regexes_to_ignore:
lowercase__ : int = np.array([re.sub(snake_case_ , '' , snake_case_ ) for x in predictions] )
lowercase__ : Any = np.array([re.sub(snake_case_ , '' , snake_case_ ) for x in references] )
else:
lowercase__ : int = np.asarray(snake_case_ )
lowercase__ : Optional[int] = np.asarray(snake_case_ )
if ignore_case:
lowercase__ : Dict = np.char.lower(snake_case_ )
lowercase__ : Tuple = np.char.lower(snake_case_ )
if ignore_punctuation:
lowercase__ : str = string.punctuation.maketrans('' , '' , string.punctuation )
lowercase__ : Tuple = np.char.translate(snake_case_ , table=snake_case_ )
lowercase__ : Dict = np.char.translate(snake_case_ , table=snake_case_ )
if ignore_numbers:
lowercase__ : Any = string.digits.maketrans('' , '' , string.digits )
lowercase__ : Union[str, Any] = np.char.translate(snake_case_ , table=snake_case_ )
lowercase__ : Union[str, Any] = np.char.translate(snake_case_ , table=snake_case_ )
lowercase__ : Tuple = predictions == references
return {"exact_match": np.mean(snake_case_ ) * 1_0_0}
| 77
|
'''simple docstring'''
import numpy as np
from transformers import Pipeline
def __snake_case( _lowerCAmelCase ) -> Optional[int]:
snake_case__ : Optional[Any] = np.max(_lowerCAmelCase , axis=-1 , keepdims=_lowerCAmelCase )
snake_case__ : List[str] = np.exp(outputs - maxes )
return shifted_exp / shifted_exp.sum(axis=-1 , keepdims=_lowerCAmelCase )
class UpperCAmelCase_ ( _a ):
"""simple docstring"""
def lowerCamelCase ( self : Optional[Any] , **snake_case_ : int ):
snake_case__ : Optional[int] = {}
if "second_text" in kwargs:
snake_case__ : Union[str, Any] = kwargs["""second_text"""]
return preprocess_kwargs, {}, {}
def lowerCamelCase ( self : str , snake_case_ : Tuple , snake_case_ : Union[str, Any]=None ):
return self.tokenizer(snake_case_ , text_pair=snake_case_ , return_tensors=self.framework )
def lowerCamelCase ( self : List[Any] , snake_case_ : Dict ):
return self.model(**snake_case_ )
def lowerCamelCase ( self : int , snake_case_ : List[Any] ):
snake_case__ : Union[str, Any] = model_outputs.logits[0].numpy()
snake_case__ : List[str] = softmax(snake_case_ )
snake_case__ : List[str] = np.argmax(snake_case_ )
snake_case__ : List[str] = self.model.config.idalabel[best_class]
snake_case__ : Optional[int] = probabilities[best_class].item()
snake_case__ : str = logits.tolist()
return {"label": label, "score": score, "logits": logits}
| 35
| 0
|
'''simple docstring'''
from __future__ import annotations
def lowerCAmelCase_ ( snake_case_ : List[Any] ) -> None:
'''simple docstring'''
create_state_space_tree(_lowerCAmelCase , [] , 0 , [0 for i in range(len(_lowerCAmelCase ) )] )
def lowerCAmelCase_ ( snake_case_ : Tuple , snake_case_ : Dict , snake_case_ : Dict , snake_case_ : Tuple , ) -> None:
'''simple docstring'''
if index == len(_lowerCAmelCase ):
print(_lowerCAmelCase )
return
for i in range(len(_lowerCAmelCase ) ):
if not index_used[i]:
current_sequence.append(sequence[i] )
UpperCAmelCase_ = True
create_state_space_tree(_lowerCAmelCase , _lowerCAmelCase , index + 1 , _lowerCAmelCase )
current_sequence.pop()
UpperCAmelCase_ = False
SCREAMING_SNAKE_CASE_: List[str] =[3, 1, 2, 4]
generate_all_permutations(sequence)
SCREAMING_SNAKE_CASE_: Tuple =['A', 'B', 'C']
generate_all_permutations(sequence_a)
| 1
|
'''simple docstring'''
# Function to print upper half of diamond (pyramid)
def __snake_case( _lowerCAmelCase ) -> Any:
for i in range(0 , _lowerCAmelCase ):
for _ in range(0 , n - i - 1 ): # printing spaces
print(""" """ , end="""""" )
for _ in range(0 , i + 1 ): # printing stars
print("""* """ , end="""""" )
print()
def __snake_case( _lowerCAmelCase ) -> List[str]:
for i in range(_lowerCAmelCase , 0 , -1 ):
for _ in range(_lowerCAmelCase , 0 , -1 ): # printing stars
print("""* """ , end="""""" )
print()
for _ in range(n - i + 1 , 0 , -1 ): # printing spaces
print(""" """ , end="""""" )
def __snake_case( _lowerCAmelCase ) -> List[Any]:
if n <= 0:
print(""" ... .... nothing printing :(""" )
return
floyd(_lowerCAmelCase ) # upper half
reverse_floyd(_lowerCAmelCase ) # lower half
if __name__ == "__main__":
print(R"| /\ | |- | |- |--| |\ /| |-")
print(R"|/ \| |- |_ |_ |__| | \/ | |_")
__a = 1
while K:
__a = int(input("enter the number and , and see the magic : "))
print()
pretty_print(user_number)
__a = int(input("press 0 to exit... and 1 to continue..."))
print("Good Bye...")
| 35
| 0
|
from typing import TYPE_CHECKING
from ...utils import (
OptionalDependencyNotAvailable,
_LazyModule,
is_tokenizers_available,
is_torch_available,
is_vision_available,
)
lowerCamelCase : int = {
"configuration_layoutlmv2": ["LAYOUTLMV2_PRETRAINED_CONFIG_ARCHIVE_MAP", "LayoutLMv2Config"],
"processing_layoutlmv2": ["LayoutLMv2Processor"],
"tokenization_layoutlmv2": ["LayoutLMv2Tokenizer"],
}
try:
if not is_tokenizers_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
lowerCamelCase : List[Any] = ["LayoutLMv2TokenizerFast"]
try:
if not is_vision_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
lowerCamelCase : int = ["LayoutLMv2FeatureExtractor"]
lowerCamelCase : int = ["LayoutLMv2ImageProcessor"]
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
lowerCamelCase : Union[str, Any] = [
"LAYOUTLMV2_PRETRAINED_MODEL_ARCHIVE_LIST",
"LayoutLMv2ForQuestionAnswering",
"LayoutLMv2ForSequenceClassification",
"LayoutLMv2ForTokenClassification",
"LayoutLMv2Layer",
"LayoutLMv2Model",
"LayoutLMv2PreTrainedModel",
]
if TYPE_CHECKING:
from .configuration_layoutlmva import LAYOUTLMV2_PRETRAINED_CONFIG_ARCHIVE_MAP, LayoutLMvaConfig
from .processing_layoutlmva import LayoutLMvaProcessor
from .tokenization_layoutlmva import LayoutLMvaTokenizer
try:
if not is_tokenizers_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .tokenization_layoutlmva_fast import LayoutLMvaTokenizerFast
try:
if not is_vision_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .feature_extraction_layoutlmva import LayoutLMvaFeatureExtractor, LayoutLMvaImageProcessor
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_layoutlmva import (
LAYOUTLMV2_PRETRAINED_MODEL_ARCHIVE_LIST,
LayoutLMvaForQuestionAnswering,
LayoutLMvaForSequenceClassification,
LayoutLMvaForTokenClassification,
LayoutLMvaLayer,
LayoutLMvaModel,
LayoutLMvaPreTrainedModel,
)
else:
import sys
lowerCamelCase : List[Any] = _LazyModule(__name__, globals()["__file__"], _import_structure, module_spec=__spec__)
| 204
|
'''simple docstring'''
def __snake_case( _lowerCAmelCase = 1_000 ) -> int:
return sum(e for e in range(3 , _lowerCAmelCase ) if e % 3 == 0 or e % 5 == 0 )
if __name__ == "__main__":
print(F"{solution() = }")
| 35
| 0
|
import argparse
from collections import OrderedDict
from pathlib import Path
import requests
import torch
from PIL import Image
from transformers import GLPNConfig, GLPNForDepthEstimation, GLPNImageProcessor
from transformers.utils import logging
logging.set_verbosity_info()
a : Optional[int] = logging.get_logger(__name__)
def lowerCAmelCase_ (lowerCAmelCase__: Union[str, Any] ):
"""simple docstring"""
UpperCAmelCase_: Tuple = OrderedDict()
for key, value in state_dict.items():
if key.startswith("""module.encoder""" ):
UpperCAmelCase_: str = key.replace("""module.encoder""" , """glpn.encoder""" )
if key.startswith("""module.decoder""" ):
UpperCAmelCase_: Optional[int] = key.replace("""module.decoder""" , """decoder.stages""" )
if "patch_embed" in key:
# replace for example patch_embed1 by patch_embeddings.0
UpperCAmelCase_: int = key[key.find("""patch_embed""" ) + len("""patch_embed""" )]
UpperCAmelCase_: Any = key.replace(F'patch_embed{idx}' , F'patch_embeddings.{int(_lowerCAmelCase )-1}' )
if "norm" in key:
UpperCAmelCase_: Union[str, Any] = key.replace("""norm""" , """layer_norm""" )
if "glpn.encoder.layer_norm" in key:
# replace for example layer_norm1 by layer_norm.0
UpperCAmelCase_: int = key[key.find("""glpn.encoder.layer_norm""" ) + len("""glpn.encoder.layer_norm""" )]
UpperCAmelCase_: str = key.replace(F'layer_norm{idx}' , F'layer_norm.{int(_lowerCAmelCase )-1}' )
if "layer_norm1" in key:
UpperCAmelCase_: str = key.replace("""layer_norm1""" , """layer_norm_1""" )
if "layer_norm2" in key:
UpperCAmelCase_: Optional[int] = key.replace("""layer_norm2""" , """layer_norm_2""" )
if "block" in key:
# replace for example block1 by block.0
UpperCAmelCase_: Dict = key[key.find("""block""" ) + len("""block""" )]
UpperCAmelCase_: Any = key.replace(F'block{idx}' , F'block.{int(_lowerCAmelCase )-1}' )
if "attn.q" in key:
UpperCAmelCase_: str = key.replace("""attn.q""" , """attention.self.query""" )
if "attn.proj" in key:
UpperCAmelCase_: Optional[Any] = key.replace("""attn.proj""" , """attention.output.dense""" )
if "attn" in key:
UpperCAmelCase_: Tuple = key.replace("""attn""" , """attention.self""" )
if "fc1" in key:
UpperCAmelCase_: List[Any] = key.replace("""fc1""" , """dense1""" )
if "fc2" in key:
UpperCAmelCase_: List[str] = key.replace("""fc2""" , """dense2""" )
if "linear_pred" in key:
UpperCAmelCase_: Dict = key.replace("""linear_pred""" , """classifier""" )
if "linear_fuse" in key:
UpperCAmelCase_: Union[str, Any] = key.replace("""linear_fuse.conv""" , """linear_fuse""" )
UpperCAmelCase_: Tuple = key.replace("""linear_fuse.bn""" , """batch_norm""" )
if "linear_c" in key:
# replace for example linear_c4 by linear_c.3
UpperCAmelCase_: Optional[int] = key[key.find("""linear_c""" ) + len("""linear_c""" )]
UpperCAmelCase_: str = key.replace(F'linear_c{idx}' , F'linear_c.{int(_lowerCAmelCase )-1}' )
if "bot_conv" in key:
UpperCAmelCase_: Dict = key.replace("""bot_conv""" , """0.convolution""" )
if "skip_conv1" in key:
UpperCAmelCase_: Union[str, Any] = key.replace("""skip_conv1""" , """1.convolution""" )
if "skip_conv2" in key:
UpperCAmelCase_: Tuple = key.replace("""skip_conv2""" , """2.convolution""" )
if "fusion1" in key:
UpperCAmelCase_: Any = key.replace("""fusion1""" , """1.fusion""" )
if "fusion2" in key:
UpperCAmelCase_: List[str] = key.replace("""fusion2""" , """2.fusion""" )
if "fusion3" in key:
UpperCAmelCase_: Optional[int] = key.replace("""fusion3""" , """3.fusion""" )
if "fusion" in key and "conv" in key:
UpperCAmelCase_: Tuple = key.replace("""conv""" , """convolutional_layer""" )
if key.startswith("""module.last_layer_depth""" ):
UpperCAmelCase_: Dict = key.replace("""module.last_layer_depth""" , """head.head""" )
UpperCAmelCase_: List[str] = value
return new_state_dict
def lowerCAmelCase_ (lowerCAmelCase__: Any , lowerCAmelCase__: Union[str, Any] ):
"""simple docstring"""
for i in range(config.num_encoder_blocks ):
for j in range(config.depths[i] ):
# read in weights + bias of keys and values (which is a single matrix in the original implementation)
UpperCAmelCase_: Tuple = state_dict.pop(F'glpn.encoder.block.{i}.{j}.attention.self.kv.weight' )
UpperCAmelCase_: List[Any] = state_dict.pop(F'glpn.encoder.block.{i}.{j}.attention.self.kv.bias' )
# next, add keys and values (in that order) to the state dict
UpperCAmelCase_: str = kv_weight[
: config.hidden_sizes[i], :
]
UpperCAmelCase_: List[str] = kv_bias[: config.hidden_sizes[i]]
UpperCAmelCase_: Union[str, Any] = kv_weight[
config.hidden_sizes[i] :, :
]
UpperCAmelCase_: List[str] = kv_bias[config.hidden_sizes[i] :]
def lowerCAmelCase_ ():
"""simple docstring"""
UpperCAmelCase_: int = """http://images.cocodataset.org/val2017/000000039769.jpg"""
UpperCAmelCase_: Dict = Image.open(requests.get(_lowerCAmelCase , stream=_lowerCAmelCase ).raw )
return image
@torch.no_grad()
def lowerCAmelCase_ (lowerCAmelCase__: List[Any] , lowerCAmelCase__: str , lowerCAmelCase__: Optional[int]=False , lowerCAmelCase__: Any=None ):
"""simple docstring"""
UpperCAmelCase_: str = GLPNConfig(hidden_sizes=[6_4, 1_2_8, 3_2_0, 5_1_2] , decoder_hidden_size=6_4 , depths=[3, 8, 2_7, 3] )
# load image processor (only resize + rescale)
UpperCAmelCase_: Optional[Any] = GLPNImageProcessor()
# prepare image
UpperCAmelCase_: Optional[int] = prepare_img()
UpperCAmelCase_: Optional[Any] = image_processor(images=_lowerCAmelCase , return_tensors="""pt""" ).pixel_values
logger.info("""Converting model...""" )
# load original state dict
UpperCAmelCase_: List[Any] = torch.load(_lowerCAmelCase , map_location=torch.device("""cpu""" ) )
# rename keys
UpperCAmelCase_: str = rename_keys(_lowerCAmelCase )
# key and value matrices need special treatment
read_in_k_v(_lowerCAmelCase , _lowerCAmelCase )
# create HuggingFace model and load state dict
UpperCAmelCase_: int = GLPNForDepthEstimation(_lowerCAmelCase )
model.load_state_dict(_lowerCAmelCase )
model.eval()
# forward pass
UpperCAmelCase_: int = model(_lowerCAmelCase )
UpperCAmelCase_: List[str] = outputs.predicted_depth
# verify output
if model_name is not None:
if "nyu" in model_name:
UpperCAmelCase_: Dict = torch.tensor(
[[4.4147, 4.0873, 4.0673], [3.7890, 3.2881, 3.1525], [3.7674, 3.5423, 3.4913]] )
elif "kitti" in model_name:
UpperCAmelCase_: Optional[int] = torch.tensor(
[[3.4291, 2.7865, 2.5151], [3.2841, 2.7021, 2.3502], [3.1147, 2.4625, 2.2481]] )
else:
raise ValueError(F'Unknown model name: {model_name}' )
UpperCAmelCase_: List[str] = torch.Size([1, 4_8_0, 6_4_0] )
assert predicted_depth.shape == expected_shape
assert torch.allclose(predicted_depth[0, :3, :3] , _lowerCAmelCase , atol=1e-4 )
print("""Looks ok!""" )
# finally, push to hub if required
if push_to_hub:
logger.info("""Pushing model and image processor to the hub...""" )
model.push_to_hub(
repo_path_or_name=Path(_lowerCAmelCase , _lowerCAmelCase ) , organization="""nielsr""" , commit_message="""Add model""" , use_temp_dir=_lowerCAmelCase , )
image_processor.push_to_hub(
repo_path_or_name=Path(_lowerCAmelCase , _lowerCAmelCase ) , organization="""nielsr""" , commit_message="""Add image processor""" , use_temp_dir=_lowerCAmelCase , )
if __name__ == "__main__":
a : Dict = argparse.ArgumentParser()
parser.add_argument(
'--checkpoint_path',
default=None,
type=str,
help='Path to the original PyTorch checkpoint (.pth file).',
)
parser.add_argument(
'--pytorch_dump_folder_path', default=None, type=str, help='Path to the folder to output PyTorch model.'
)
parser.add_argument(
'--push_to_hub', action='store_true', help='Whether to upload the model to the HuggingFace hub.'
)
parser.add_argument(
'--model_name',
default='glpn-kitti',
type=str,
help='Name of the model in case you\'re pushing to the hub.',
)
a : Optional[Any] = parser.parse_args()
convert_glpn_checkpoint(args.checkpoint_path, args.pytorch_dump_folder_path, args.push_to_hub, args.model_name)
| 147
|
'''simple docstring'''
from typing import TYPE_CHECKING
from ...utils import OptionalDependencyNotAvailable, _LazyModule, is_tokenizers_available, is_torch_available
__a = {
"configuration_bloom": ["BLOOM_PRETRAINED_CONFIG_ARCHIVE_MAP", "BloomConfig", "BloomOnnxConfig"],
}
try:
if not is_tokenizers_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__a = ["BloomTokenizerFast"]
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__a = [
"BLOOM_PRETRAINED_MODEL_ARCHIVE_LIST",
"BloomForCausalLM",
"BloomModel",
"BloomPreTrainedModel",
"BloomForSequenceClassification",
"BloomForTokenClassification",
"BloomForQuestionAnswering",
]
if TYPE_CHECKING:
from .configuration_bloom import BLOOM_PRETRAINED_CONFIG_ARCHIVE_MAP, BloomConfig, BloomOnnxConfig
try:
if not is_tokenizers_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .tokenization_bloom_fast import BloomTokenizerFast
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_bloom import (
BLOOM_PRETRAINED_MODEL_ARCHIVE_LIST,
BloomForCausalLM,
BloomForQuestionAnswering,
BloomForSequenceClassification,
BloomForTokenClassification,
BloomModel,
BloomPreTrainedModel,
)
else:
import sys
__a = _LazyModule(__name__, globals()["__file__"], _import_structure, module_spec=__spec__)
| 35
| 0
|
import copy
import os
from typing import TYPE_CHECKING, List, Union
if TYPE_CHECKING:
pass
from ...configuration_utils import PretrainedConfig
from ...utils import logging
__lowerCAmelCase : Optional[int] = logging.get_logger(__name__)
__lowerCAmelCase : Tuple = {
'kakaobrain/align-base': 'https://huggingface.co/kakaobrain/align-base/resolve/main/config.json',
}
class UpperCAmelCase_ ( _a ):
'''simple docstring'''
a__ = """align_text_model"""
def __init__( self : Dict , UpperCamelCase__ : Any=3_0522 , UpperCamelCase__ : Tuple=768 , UpperCamelCase__ : Any=12 , UpperCamelCase__ : Union[str, Any]=12 , UpperCamelCase__ : List[Any]=3072 , UpperCamelCase__ : Dict="gelu" , UpperCamelCase__ : Optional[int]=0.1 , UpperCamelCase__ : str=0.1 , UpperCamelCase__ : List[str]=512 , UpperCamelCase__ : str=2 , UpperCamelCase__ : Optional[Any]=0.02 , UpperCamelCase__ : Optional[Any]=1E-12 , UpperCamelCase__ : List[Any]=0 , UpperCamelCase__ : Union[str, Any]="absolute" , UpperCamelCase__ : List[Any]=True , **UpperCamelCase__ : List[Any] , ) -> Tuple:
"""simple docstring"""
super().__init__(**snake_case_ )
__magic_name__ = vocab_size
__magic_name__ = hidden_size
__magic_name__ = num_hidden_layers
__magic_name__ = num_attention_heads
__magic_name__ = hidden_act
__magic_name__ = intermediate_size
__magic_name__ = hidden_dropout_prob
__magic_name__ = attention_probs_dropout_prob
__magic_name__ = max_position_embeddings
__magic_name__ = type_vocab_size
__magic_name__ = initializer_range
__magic_name__ = layer_norm_eps
__magic_name__ = position_embedding_type
__magic_name__ = use_cache
__magic_name__ = pad_token_id
@classmethod
def _lowercase ( cls : Union[str, Any] , UpperCamelCase__ : Union[str, os.PathLike] , **UpperCamelCase__ : Optional[int] ) -> Optional[int]:
"""simple docstring"""
cls._set_token_in_kwargs(snake_case_ )
__magic_name__ = cls.get_config_dict(snake_case_ , **snake_case_ )
# get the text config dict if we are loading from AlignConfig
if config_dict.get("""model_type""" ) == "align":
__magic_name__ = 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(snake_case_ , **snake_case_ )
class UpperCAmelCase_ ( _a ):
'''simple docstring'''
a__ = """align_vision_model"""
def __init__( self : Union[str, Any] , UpperCamelCase__ : int = 3 , UpperCamelCase__ : int = 600 , UpperCamelCase__ : float = 2.0 , UpperCamelCase__ : float = 3.1 , UpperCamelCase__ : int = 8 , UpperCamelCase__ : List[int] = [3, 3, 5, 3, 5, 5, 3] , UpperCamelCase__ : List[int] = [32, 16, 24, 40, 80, 112, 192] , UpperCamelCase__ : List[int] = [16, 24, 40, 80, 112, 192, 320] , UpperCamelCase__ : List[int] = [] , UpperCamelCase__ : List[int] = [1, 2, 2, 2, 1, 2, 1] , UpperCamelCase__ : List[int] = [1, 2, 2, 3, 3, 4, 1] , UpperCamelCase__ : List[int] = [1, 6, 6, 6, 6, 6, 6] , UpperCamelCase__ : float = 0.25 , UpperCamelCase__ : str = "swish" , UpperCamelCase__ : int = 2560 , UpperCamelCase__ : str = "mean" , UpperCamelCase__ : float = 0.02 , UpperCamelCase__ : float = 0.001 , UpperCamelCase__ : float = 0.99 , UpperCamelCase__ : float = 0.2 , **UpperCamelCase__ : Optional[int] , ) -> str:
"""simple docstring"""
super().__init__(**snake_case_ )
__magic_name__ = num_channels
__magic_name__ = image_size
__magic_name__ = width_coefficient
__magic_name__ = depth_coefficient
__magic_name__ = depth_divisor
__magic_name__ = kernel_sizes
__magic_name__ = in_channels
__magic_name__ = out_channels
__magic_name__ = depthwise_padding
__magic_name__ = strides
__magic_name__ = num_block_repeats
__magic_name__ = expand_ratios
__magic_name__ = squeeze_expansion_ratio
__magic_name__ = hidden_act
__magic_name__ = hidden_dim
__magic_name__ = pooling_type
__magic_name__ = initializer_range
__magic_name__ = batch_norm_eps
__magic_name__ = batch_norm_momentum
__magic_name__ = drop_connect_rate
__magic_name__ = sum(snake_case_ ) * 4
@classmethod
def _lowercase ( cls : str , UpperCamelCase__ : Union[str, os.PathLike] , **UpperCamelCase__ : List[Any] ) -> Optional[Any]:
"""simple docstring"""
cls._set_token_in_kwargs(snake_case_ )
__magic_name__ = cls.get_config_dict(snake_case_ , **snake_case_ )
# get the vision config dict if we are loading from AlignConfig
if config_dict.get("""model_type""" ) == "align":
__magic_name__ = 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(snake_case_ , **snake_case_ )
class UpperCAmelCase_ ( _a ):
'''simple docstring'''
a__ = """align"""
a__ = True
def __init__( self : int , UpperCamelCase__ : List[Any]=None , UpperCamelCase__ : List[str]=None , UpperCamelCase__ : Tuple=640 , UpperCamelCase__ : List[Any]=1.0 , UpperCamelCase__ : List[str]=0.02 , **UpperCamelCase__ : Any , ) -> Optional[Any]:
"""simple docstring"""
super().__init__(**snake_case_ )
if text_config is None:
__magic_name__ = {}
logger.info("""text_config is None. Initializing the AlignTextConfig with default values.""" )
if vision_config is None:
__magic_name__ = {}
logger.info("""vision_config is None. Initializing the AlignVisionConfig with default values.""" )
__magic_name__ = AlignTextConfig(**snake_case_ )
__magic_name__ = AlignVisionConfig(**snake_case_ )
__magic_name__ = projection_dim
__magic_name__ = temperature_init_value
__magic_name__ = initializer_range
@classmethod
def _lowercase ( cls : Union[str, Any] , UpperCamelCase__ : AlignTextConfig , UpperCamelCase__ : AlignVisionConfig , **UpperCamelCase__ : Optional[int] ) -> Optional[int]:
"""simple docstring"""
return cls(text_config=text_config.to_dict() , vision_config=vision_config.to_dict() , **snake_case_ )
def _lowercase ( self : List[Any] ) -> Any:
"""simple docstring"""
__magic_name__ = copy.deepcopy(self.__dict__ )
__magic_name__ = self.text_config.to_dict()
__magic_name__ = self.vision_config.to_dict()
__magic_name__ = self.__class__.model_type
return output
| 88
|
'''simple docstring'''
from PIL import Image
def __snake_case( _lowerCAmelCase , _lowerCAmelCase ) -> Image:
def brightness(_lowerCAmelCase ) -> float:
return 128 + level + (c - 128)
if not -255.0 <= level <= 255.0:
raise ValueError("""level must be between -255.0 (black) and 255.0 (white)""" )
return img.point(_lowerCAmelCase )
if __name__ == "__main__":
# Load image
with Image.open("image_data/lena.jpg") as img:
# Change brightness to 100
__a = change_brightness(img, 100)
brigt_img.save("image_data/lena_brightness.png", format="png")
| 35
| 0
|
'''simple docstring'''
from __future__ import annotations
import inspect
import unittest
import numpy as np
from transformers import ResNetConfig
from transformers.testing_utils import require_tf, require_vision, slow
from transformers.utils import cached_property, is_tf_available, is_vision_available
from ...test_configuration_common import ConfigTester
from ...test_modeling_tf_common import TFModelTesterMixin, floats_tensor, ids_tensor
from ...test_pipeline_mixin import PipelineTesterMixin
if is_tf_available():
import tensorflow as tf
from transformers import TFResNetForImageClassification, TFResNetModel
from transformers.models.resnet.modeling_tf_resnet import TF_RESNET_PRETRAINED_MODEL_ARCHIVE_LIST
if is_vision_available():
from PIL import Image
from transformers import AutoImageProcessor
class SCREAMING_SNAKE_CASE :
def __init__( self , _UpperCAmelCase , _UpperCAmelCase=3 , _UpperCAmelCase=32 , _UpperCAmelCase=3 , _UpperCAmelCase=10 , _UpperCAmelCase=[10, 20, 30, 40] , _UpperCAmelCase=[1, 1, 2, 1] , _UpperCAmelCase=True , _UpperCAmelCase=True , _UpperCAmelCase="relu" , _UpperCAmelCase=3 , _UpperCAmelCase=None , ):
'''simple docstring'''
__A : List[Any] = parent
__A : List[Any] = batch_size
__A : int = image_size
__A : List[Any] = num_channels
__A : Optional[Any] = embeddings_size
__A : Optional[int] = hidden_sizes
__A : Tuple = depths
__A : Any = is_training
__A : Optional[int] = use_labels
__A : Optional[int] = hidden_act
__A : Optional[int] = num_labels
__A : int = scope
__A : Tuple = len(snake_case_)
def SCREAMING_SNAKE_CASE ( self):
'''simple docstring'''
__A : Union[str, Any] = floats_tensor([self.batch_size, self.num_channels, self.image_size, self.image_size])
__A : Union[str, Any] = None
if self.use_labels:
__A : Optional[Any] = ids_tensor([self.batch_size] , self.num_labels)
__A : List[str] = self.get_config()
return config, pixel_values, labels
def SCREAMING_SNAKE_CASE ( self):
'''simple docstring'''
return ResNetConfig(
num_channels=self.num_channels , embeddings_size=self.embeddings_size , hidden_sizes=self.hidden_sizes , depths=self.depths , hidden_act=self.hidden_act , num_labels=self.num_labels , image_size=self.image_size , )
def SCREAMING_SNAKE_CASE ( self , _UpperCAmelCase , _UpperCAmelCase , _UpperCAmelCase):
'''simple docstring'''
__A : Optional[Any] = TFResNetModel(config=snake_case_)
__A : int = model(snake_case_)
# expected last hidden states: B, C, H // 32, W // 32
self.parent.assertEqual(
result.last_hidden_state.shape , (self.batch_size, self.hidden_sizes[-1], self.image_size // 32, self.image_size // 32) , )
def SCREAMING_SNAKE_CASE ( self , _UpperCAmelCase , _UpperCAmelCase , _UpperCAmelCase):
'''simple docstring'''
__A : str = self.num_labels
__A : Optional[int] = TFResNetForImageClassification(snake_case_)
__A : Tuple = model(snake_case_ , labels=snake_case_)
self.parent.assertEqual(result.logits.shape , (self.batch_size, self.num_labels))
def SCREAMING_SNAKE_CASE ( self):
'''simple docstring'''
__A : List[Any] = self.prepare_config_and_inputs()
__A : str = config_and_inputs
__A : int = {"""pixel_values""": pixel_values}
return config, inputs_dict
@require_tf
class SCREAMING_SNAKE_CASE (_a , _a , unittest.TestCase ):
lowerCAmelCase = (TFResNetModel, TFResNetForImageClassification) if is_tf_available() else ()
lowerCAmelCase = (
{'''feature-extraction''': TFResNetModel, '''image-classification''': TFResNetForImageClassification}
if is_tf_available()
else {}
)
lowerCAmelCase = False
lowerCAmelCase = False
lowerCAmelCase = False
lowerCAmelCase = False
lowerCAmelCase = False
def SCREAMING_SNAKE_CASE ( self):
'''simple docstring'''
__A : Tuple = TFResNetModelTester(self)
__A : List[str] = ConfigTester(self , config_class=snake_case_ , has_text_modality=snake_case_)
def SCREAMING_SNAKE_CASE ( self):
'''simple docstring'''
self.create_and_test_config_common_properties()
self.config_tester.create_and_test_config_to_json_string()
self.config_tester.create_and_test_config_to_json_file()
self.config_tester.create_and_test_config_from_and_save_pretrained()
self.config_tester.create_and_test_config_with_num_labels()
self.config_tester.check_config_can_be_init_without_params()
self.config_tester.check_config_arguments_init()
def SCREAMING_SNAKE_CASE ( self):
'''simple docstring'''
return
@unittest.skip(reason='ResNet does not use inputs_embeds')
def SCREAMING_SNAKE_CASE ( self):
'''simple docstring'''
pass
@unittest.skip(reason='ResNet does not support input and output embeddings')
def SCREAMING_SNAKE_CASE ( self):
'''simple docstring'''
pass
def SCREAMING_SNAKE_CASE ( self):
'''simple docstring'''
__A : List[Any] = self.model_tester.prepare_config_and_inputs_for_common()
for model_class in self.all_model_classes:
__A : Dict = model_class(snake_case_)
__A : Optional[Any] = inspect.signature(model.call)
# signature.parameters is an OrderedDict => so arg_names order is deterministic
__A : Union[str, Any] = [*signature.parameters.keys()]
__A : Optional[int] = ["""pixel_values"""]
self.assertListEqual(arg_names[:1] , snake_case_)
def SCREAMING_SNAKE_CASE ( self):
'''simple docstring'''
__A : Optional[int] = self.model_tester.prepare_config_and_inputs()
self.model_tester.create_and_check_model(*snake_case_)
def SCREAMING_SNAKE_CASE ( self):
'''simple docstring'''
def check_hidden_states_output(_UpperCAmelCase , _UpperCAmelCase , _UpperCAmelCase):
__A : List[Any] = model_class(snake_case_)
__A : Dict = model(**self._prepare_for_class(snake_case_ , snake_case_))
__A : str = outputs.encoder_hidden_states if config.is_encoder_decoder else outputs.hidden_states
__A : List[Any] = self.model_tester.num_stages
self.assertEqual(len(snake_case_) , expected_num_stages + 1)
# ResNet's feature maps are of shape (batch_size, num_channels, height, width)
self.assertListEqual(
list(hidden_states[0].shape[-2:]) , [self.model_tester.image_size // 4, self.model_tester.image_size // 4] , )
__A : Any = self.model_tester.prepare_config_and_inputs_for_common()
__A : List[Any] = ["""basic""", """bottleneck"""]
for model_class in self.all_model_classes:
for layer_type in layers_type:
__A : Dict = layer_type
__A : Optional[int] = True
check_hidden_states_output(snake_case_ , snake_case_ , snake_case_)
# check that output_hidden_states also work using config
del inputs_dict["output_hidden_states"]
__A : List[Any] = True
check_hidden_states_output(snake_case_ , snake_case_ , snake_case_)
def SCREAMING_SNAKE_CASE ( self):
'''simple docstring'''
__A : Tuple = self.model_tester.prepare_config_and_inputs()
self.model_tester.create_and_check_for_image_classification(*snake_case_)
@slow
def SCREAMING_SNAKE_CASE ( self):
'''simple docstring'''
for model_name in TF_RESNET_PRETRAINED_MODEL_ARCHIVE_LIST[:1]:
__A : str = TFResNetModel.from_pretrained(snake_case_)
self.assertIsNotNone(snake_case_)
def _lowerCAmelCase ( ) -> Optional[int]:
__A : Optional[Any] = Image.open('./tests/fixtures/tests_samples/COCO/000000039769.png' )
return image
@require_tf
@require_vision
class SCREAMING_SNAKE_CASE (unittest.TestCase ):
@cached_property
def SCREAMING_SNAKE_CASE ( self):
'''simple docstring'''
return (
AutoImageProcessor.from_pretrained(TF_RESNET_PRETRAINED_MODEL_ARCHIVE_LIST[0])
if is_vision_available()
else None
)
@slow
def SCREAMING_SNAKE_CASE ( self):
'''simple docstring'''
__A : List[str] = TFResNetForImageClassification.from_pretrained(TF_RESNET_PRETRAINED_MODEL_ARCHIVE_LIST[0])
__A : List[Any] = self.default_image_processor
__A : List[Any] = prepare_img()
__A : List[str] = image_processor(images=snake_case_ , return_tensors='tf')
# forward pass
__A : Optional[Any] = model(**snake_case_)
# verify the logits
__A : Union[str, Any] = tf.TensorShape((1, 1000))
self.assertEqual(outputs.logits.shape , snake_case_)
__A : List[str] = tf.constant([-11.1069, -9.7877, -8.3777])
self.assertTrue(np.allclose(outputs.logits[0, :3].numpy() , snake_case_ , atol=1e-4))
| 190
|
'''simple docstring'''
import argparse
import os
import re
__a = "src/transformers"
# Pattern that looks at the indentation in a line.
__a = re.compile(R"^(\s*)\S")
# Pattern that matches `"key":" and puts `key` in group 0.
__a = re.compile(R"^\s*\"([^\"]+)\":")
# Pattern that matches `_import_structure["key"]` and puts `key` in group 0.
__a = re.compile(R"^\s*_import_structure\[\"([^\"]+)\"\]")
# Pattern that matches `"key",` and puts `key` in group 0.
__a = re.compile(R"^\s*\"([^\"]+)\",\s*$")
# Pattern that matches any `[stuff]` and puts `stuff` in group 0.
__a = re.compile(R"\[([^\]]+)\]")
def __snake_case( _lowerCAmelCase ) -> List[Any]:
snake_case__ : int = _re_indent.search(_lowerCAmelCase )
return "" if search is None else search.groups()[0]
def __snake_case( _lowerCAmelCase , _lowerCAmelCase="" , _lowerCAmelCase=None , _lowerCAmelCase=None ) -> List[str]:
snake_case__ : str = 0
snake_case__ : Union[str, Any] = code.split("""\n""" )
if start_prompt is not None:
while not lines[index].startswith(_lowerCAmelCase ):
index += 1
snake_case__ : Tuple = ["""\n""".join(lines[:index] )]
else:
snake_case__ : List[str] = []
# We split into blocks until we get to the `end_prompt` (or the end of the block).
snake_case__ : Optional[int] = [lines[index]]
index += 1
while index < len(_lowerCAmelCase ) and (end_prompt is None or not lines[index].startswith(_lowerCAmelCase )):
if len(lines[index] ) > 0 and get_indent(lines[index] ) == indent_level:
if len(_lowerCAmelCase ) > 0 and get_indent(current_block[-1] ).startswith(indent_level + """ """ ):
current_block.append(lines[index] )
blocks.append("""\n""".join(_lowerCAmelCase ) )
if index < len(_lowerCAmelCase ) - 1:
snake_case__ : str = [lines[index + 1]]
index += 1
else:
snake_case__ : int = []
else:
blocks.append("""\n""".join(_lowerCAmelCase ) )
snake_case__ : Optional[Any] = [lines[index]]
else:
current_block.append(lines[index] )
index += 1
# Adds current block if it's nonempty.
if len(_lowerCAmelCase ) > 0:
blocks.append("""\n""".join(_lowerCAmelCase ) )
# Add final block after end_prompt if provided.
if end_prompt is not None and index < len(_lowerCAmelCase ):
blocks.append("""\n""".join(lines[index:] ) )
return blocks
def __snake_case( _lowerCAmelCase ) -> Tuple:
def _inner(_lowerCAmelCase ):
return key(_lowerCAmelCase ).lower().replace("""_""" , """""" )
return _inner
def __snake_case( _lowerCAmelCase , _lowerCAmelCase=None ) -> List[Any]:
# If no key is provided, we use a noop.
def noop(_lowerCAmelCase ):
return x
if key is None:
snake_case__ : Optional[int] = noop
# Constants are all uppercase, they go first.
snake_case__ : Optional[int] = [obj for obj in objects if key(_lowerCAmelCase ).isupper()]
# Classes are not all uppercase but start with a capital, they go second.
snake_case__ : int = [obj for obj in objects if key(_lowerCAmelCase )[0].isupper() and not key(_lowerCAmelCase ).isupper()]
# Functions begin with a lowercase, they go last.
snake_case__ : str = [obj for obj in objects if not key(_lowerCAmelCase )[0].isupper()]
snake_case__ : List[str] = ignore_underscore(_lowerCAmelCase )
return sorted(_lowerCAmelCase , key=_lowerCAmelCase ) + sorted(_lowerCAmelCase , key=_lowerCAmelCase ) + sorted(_lowerCAmelCase , key=_lowerCAmelCase )
def __snake_case( _lowerCAmelCase ) -> int:
# This inner function sort imports between [ ].
def _replace(_lowerCAmelCase ):
snake_case__ : Union[str, Any] = match.groups()[0]
if "," not in imports:
return f"[{imports}]"
snake_case__ : int = [part.strip().replace("""\"""" , """""" ) for part in imports.split(""",""" )]
# We will have a final empty element if the line finished with a comma.
if len(keys[-1] ) == 0:
snake_case__ : List[str] = keys[:-1]
return "[" + ", ".join([f"\"{k}\"" for k in sort_objects(_lowerCAmelCase )] ) + "]"
snake_case__ : str = import_statement.split("""\n""" )
if len(_lowerCAmelCase ) > 3:
# Here we have to sort internal imports that are on several lines (one per name):
# key: [
# "object1",
# "object2",
# ...
# ]
# We may have to ignore one or two lines on each side.
snake_case__ : Dict = 2 if lines[1].strip() == """[""" else 1
snake_case__ : str = [(i, _re_strip_line.search(_lowerCAmelCase ).groups()[0]) for i, line in enumerate(lines[idx:-idx] )]
snake_case__ : str = sort_objects(_lowerCAmelCase , key=lambda _lowerCAmelCase : x[1] )
snake_case__ : Union[str, Any] = [lines[x[0] + idx] for x in sorted_indices]
return "\n".join(lines[:idx] + sorted_lines + lines[-idx:] )
elif len(_lowerCAmelCase ) == 3:
# Here we have to sort internal imports that are on one separate line:
# key: [
# "object1", "object2", ...
# ]
if _re_bracket_content.search(lines[1] ) is not None:
snake_case__ : Union[str, Any] = _re_bracket_content.sub(_replace , lines[1] )
else:
snake_case__ : List[Any] = [part.strip().replace("""\"""" , """""" ) for part in lines[1].split(""",""" )]
# We will have a final empty element if the line finished with a comma.
if len(keys[-1] ) == 0:
snake_case__ : List[str] = keys[:-1]
snake_case__ : int = get_indent(lines[1] ) + """, """.join([f"\"{k}\"" for k in sort_objects(_lowerCAmelCase )] )
return "\n".join(_lowerCAmelCase )
else:
# Finally we have to deal with imports fitting on one line
snake_case__ : Optional[Any] = _re_bracket_content.sub(_replace , _lowerCAmelCase )
return import_statement
def __snake_case( _lowerCAmelCase , _lowerCAmelCase=True ) -> Dict:
with open(_lowerCAmelCase , encoding="""utf-8""" ) as f:
snake_case__ : Optional[int] = f.read()
if "_import_structure" not in code:
return
# Blocks of indent level 0
snake_case__ : Optional[int] = split_code_in_indented_blocks(
_lowerCAmelCase , start_prompt="""_import_structure = {""" , end_prompt="""if TYPE_CHECKING:""" )
# We ignore block 0 (everything untils start_prompt) and the last block (everything after end_prompt).
for block_idx in range(1 , len(_lowerCAmelCase ) - 1 ):
# Check if the block contains some `_import_structure`s thingy to sort.
snake_case__ : Optional[Any] = main_blocks[block_idx]
snake_case__ : Dict = block.split("""\n""" )
# Get to the start of the imports.
snake_case__ : Dict = 0
while line_idx < len(_lowerCAmelCase ) and "_import_structure" not in block_lines[line_idx]:
# Skip dummy import blocks
if "import dummy" in block_lines[line_idx]:
snake_case__ : Union[str, Any] = len(_lowerCAmelCase )
else:
line_idx += 1
if line_idx >= len(_lowerCAmelCase ):
continue
# Ignore beginning and last line: they don't contain anything.
snake_case__ : List[str] = """\n""".join(block_lines[line_idx:-1] )
snake_case__ : str = get_indent(block_lines[1] )
# Slit the internal block into blocks of indent level 1.
snake_case__ : Optional[int] = split_code_in_indented_blocks(_lowerCAmelCase , indent_level=_lowerCAmelCase )
# We have two categories of import key: list or _import_structure[key].append/extend
snake_case__ : Tuple = _re_direct_key if """_import_structure = {""" in block_lines[0] else _re_indirect_key
# Grab the keys, but there is a trap: some lines are empty or just comments.
snake_case__ : Optional[Any] = [(pattern.search(_lowerCAmelCase ).groups()[0] if pattern.search(_lowerCAmelCase ) is not None else None) for b in internal_blocks]
# We only sort the lines with a key.
snake_case__ : Dict = [(i, key) for i, key in enumerate(_lowerCAmelCase ) if key is not None]
snake_case__ : Union[str, Any] = [x[0] for x in sorted(_lowerCAmelCase , key=lambda _lowerCAmelCase : x[1] )]
# We reorder the blocks by leaving empty lines/comments as they were and reorder the rest.
snake_case__ : List[Any] = 0
snake_case__ : Optional[Any] = []
for i in range(len(_lowerCAmelCase ) ):
if keys[i] is None:
reorderded_blocks.append(internal_blocks[i] )
else:
snake_case__ : Optional[Any] = sort_objects_in_import(internal_blocks[sorted_indices[count]] )
reorderded_blocks.append(_lowerCAmelCase )
count += 1
# And we put our main block back together with its first and last line.
snake_case__ : Dict = """\n""".join(block_lines[:line_idx] + reorderded_blocks + [block_lines[-1]] )
if code != "\n".join(_lowerCAmelCase ):
if check_only:
return True
else:
print(f"Overwriting {file}." )
with open(_lowerCAmelCase , """w""" , encoding="""utf-8""" ) as f:
f.write("""\n""".join(_lowerCAmelCase ) )
def __snake_case( _lowerCAmelCase=True ) -> Tuple:
snake_case__ : str = []
for root, _, files in os.walk(_lowerCAmelCase ):
if "__init__.py" in files:
snake_case__ : Union[str, Any] = sort_imports(os.path.join(_lowerCAmelCase , """__init__.py""" ) , check_only=_lowerCAmelCase )
if result:
snake_case__ : Union[str, Any] = [os.path.join(_lowerCAmelCase , """__init__.py""" )]
if len(_lowerCAmelCase ) > 0:
raise ValueError(f"Would overwrite {len(_lowerCAmelCase )} files, run `make style`." )
if __name__ == "__main__":
__a = argparse.ArgumentParser()
parser.add_argument("--check_only", action="store_true", help="Whether to only check or fix style.")
__a = parser.parse_args()
sort_imports_in_all_inits(check_only=args.check_only)
| 35
| 0
|
import math
import random
from typing import Any
from .hill_climbing import SearchProblem
def snake_case_ ( snake_case , snake_case = True , snake_case = math.inf , snake_case = -math.inf , snake_case = math.inf , snake_case = -math.inf , snake_case = False , snake_case = 1_00 , snake_case = 0.0_1 , snake_case = 1 , ) -> Any:
lowercase__: Union[str, Any] = False
lowercase__: Optional[Any] = search_prob
lowercase__: Dict = start_temperate
lowercase__: Optional[int] = []
lowercase__: Optional[Any] = 0
lowercase__: Union[str, Any] = None
while not search_end:
lowercase__: Any = current_state.score()
if best_state is None or current_score > best_state.score():
lowercase__: List[Any] = current_state
scores.append(_lowerCAmelCase )
iterations += 1
lowercase__: Tuple = None
lowercase__: Any = current_state.get_neighbors()
while (
next_state is None and neighbors
): # till we do not find a neighbor that we can move to
lowercase__: Dict = random.randint(0 , len(_lowerCAmelCase ) - 1 ) # picking a random neighbor
lowercase__: Union[str, Any] = neighbors.pop(_lowerCAmelCase )
lowercase__: Optional[int] = picked_neighbor.score() - current_score
if (
picked_neighbor.x > max_x
or picked_neighbor.x < min_x
or picked_neighbor.y > max_y
or picked_neighbor.y < min_y
):
continue # neighbor outside our bounds
if not find_max:
lowercase__: Union[str, Any] = change * -1 # in case we are finding minimum
if change > 0: # improves the solution
lowercase__: Optional[int] = picked_neighbor
else:
lowercase__: List[Any] = (math.e) ** (
change / current_temp
) # probability generation function
if random.random() < probability: # random number within probability
lowercase__: Union[str, Any] = picked_neighbor
lowercase__: List[Any] = current_temp - (current_temp * rate_of_decrease)
if current_temp < threshold_temp or next_state is None:
# temperature below threshold, or could not find a suitable neighbor
lowercase__: Any = True
else:
lowercase__: List[Any] = next_state
if visualization:
from matplotlib import pyplot as plt
plt.plot(range(_lowerCAmelCase ) , _lowerCAmelCase )
plt.xlabel('Iterations' )
plt.ylabel('Function values' )
plt.show()
return best_state
if __name__ == "__main__":
def snake_case_ ( snake_case , snake_case ) -> int:
return (x**2) + (y**2)
# starting the problem with initial coordinates (12, 47)
__lowerCAmelCase = SearchProblem(x=12, y=47, step_size=1, function_to_optimize=test_fa)
__lowerCAmelCase = simulated_annealing(
prob, find_max=False, max_x=1_00, min_x=5, max_y=50, min_y=-5, visualization=True
)
print(
'''The minimum score for f(x, y) = x^2 + y^2 with the domain 100 > x > 5 '''
F'''and 50 > y > - 5 found via hill climbing: {local_min.score()}'''
)
# starting the problem with initial coordinates (12, 47)
__lowerCAmelCase = SearchProblem(x=12, y=47, step_size=1, function_to_optimize=test_fa)
__lowerCAmelCase = simulated_annealing(
prob, find_max=True, max_x=1_00, min_x=5, max_y=50, min_y=-5, visualization=True
)
print(
'''The maximum score for f(x, y) = x^2 + y^2 with the domain 100 > x > 5 '''
F'''and 50 > y > - 5 found via hill climbing: {local_min.score()}'''
)
def snake_case_ ( snake_case , snake_case ) -> Union[str, Any]:
return (3 * x**2) - (6 * y)
__lowerCAmelCase = SearchProblem(x=3, y=4, step_size=1, function_to_optimize=test_fa)
__lowerCAmelCase = simulated_annealing(prob, find_max=False, visualization=True)
print(
'''The minimum score for f(x, y) = 3*x^2 - 6*y found via hill climbing: '''
F'''{local_min.score()}'''
)
__lowerCAmelCase = SearchProblem(x=3, y=4, step_size=1, function_to_optimize=test_fa)
__lowerCAmelCase = simulated_annealing(prob, find_max=True, visualization=True)
print(
'''The maximum score for f(x, y) = 3*x^2 - 6*y found via hill climbing: '''
F'''{local_min.score()}'''
)
| 196
|
'''simple docstring'''
from typing import TYPE_CHECKING
from ...utils import OptionalDependencyNotAvailable, _LazyModule, is_torch_available
__a = {
"configuration_timesformer": ["TIMESFORMER_PRETRAINED_CONFIG_ARCHIVE_MAP", "TimesformerConfig"],
}
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__a = [
"TIMESFORMER_PRETRAINED_MODEL_ARCHIVE_LIST",
"TimesformerModel",
"TimesformerForVideoClassification",
"TimesformerPreTrainedModel",
]
if TYPE_CHECKING:
from .configuration_timesformer import TIMESFORMER_PRETRAINED_CONFIG_ARCHIVE_MAP, TimesformerConfig
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_timesformer import (
TIMESFORMER_PRETRAINED_MODEL_ARCHIVE_LIST,
TimesformerForVideoClassification,
TimesformerModel,
TimesformerPreTrainedModel,
)
else:
import sys
__a = _LazyModule(__name__, globals()["__file__"], _import_structure, module_spec=__spec__)
| 35
| 0
|
import warnings
from ...utils import logging
from .image_processing_chinese_clip import ChineseCLIPImageProcessor
A : Optional[int] = logging.get_logger(__name__)
class _lowercase ( _a):
"""simple docstring"""
def __init__( self : Tuple , *__lowerCamelCase : List[Any] , **__lowerCamelCase : Optional[int] ):
'''simple docstring'''
warnings.warn(
"The class ChineseCLIPFeatureExtractor is deprecated and will be removed in version 5 of Transformers."
" Please use ChineseCLIPImageProcessor instead." , snake_case_ , )
super().__init__(*snake_case_ , **snake_case_ )
| 184
|
'''simple docstring'''
import argparse
import json
import os
import fairseq
import torch
from torch import nn
from transformers import (
SpeechaTextaConfig,
SpeechaTextaForCausalLM,
SpeechaTextaTokenizer,
SpeechEncoderDecoderConfig,
SpeechEncoderDecoderModel,
WavaVecaConfig,
WavaVecaFeatureExtractor,
WavaVecaModel,
logging,
)
logging.set_verbosity_info()
__a = logging.get_logger(__name__)
__a = {
"post_extract_proj": "feature_projection.projection",
"encoder.pos_conv.0": "encoder.pos_conv_embed.conv",
"self_attn.k_proj": "encoder.layers.*.attention.k_proj",
"self_attn.v_proj": "encoder.layers.*.attention.v_proj",
"self_attn.q_proj": "encoder.layers.*.attention.q_proj",
"self_attn.out_proj": "encoder.layers.*.attention.out_proj",
"self_attn_layer_norm": "encoder.layers.*.layer_norm",
"fc1": "encoder.layers.*.feed_forward.intermediate_dense",
"fc2": "encoder.layers.*.feed_forward.output_dense",
"final_layer_norm": "encoder.layers.*.final_layer_norm",
"encoder.layer_norm": "encoder.layer_norm",
"w2v_model.layer_norm": "feature_projection.layer_norm",
"quantizer.weight_proj": "quantizer.weight_proj",
"quantizer.vars": "quantizer.codevectors",
"project_q": "project_q",
"final_proj": "project_hid",
"w2v_encoder.proj": "lm_head",
"mask_emb": "masked_spec_embed",
}
__a = [
"lm_head",
"quantizer.weight_proj",
"quantizer.codevectors",
"project_q",
"project_hid",
]
def __snake_case( _lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase ) -> Union[str, Any]:
for attribute in key.split(""".""" ):
snake_case__ : Dict = getattr(_lowerCAmelCase , _lowerCAmelCase )
if weight_type is not None:
snake_case__ : List[Any] = getattr(_lowerCAmelCase , _lowerCAmelCase ).shape
else:
snake_case__ : 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":
snake_case__ : int = value
elif weight_type == "weight_g":
snake_case__ : List[str] = value
elif weight_type == "weight_v":
snake_case__ : List[str] = value
elif weight_type == "bias":
snake_case__ : Optional[Any] = value
else:
snake_case__ : str = value
logger.info(f"{key + '.' + weight_type if weight_type is not None else ''} was initialized from {full_name}." )
def __snake_case( _lowerCAmelCase , _lowerCAmelCase ) -> Any:
snake_case__ : Union[str, Any] = []
snake_case__ : Dict = fairseq_model.state_dict()
snake_case__ : List[Any] = hf_model.feature_extractor
# if encoder has different dim to decoder -> use proj_weight
snake_case__ : Optional[int] = None
for name, value in fairseq_dict.items():
snake_case__ : List[Any] = False
if "conv_layers" in name:
load_conv_layer(
_lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase , hf_model.config.feat_extract_norm == """group""" , )
snake_case__ : Union[str, Any] = True
elif name.split(""".""" )[0] == "proj":
snake_case__ : Tuple = fairseq_model.proj
snake_case__ : int = True
else:
for key, mapped_key in MAPPING.items():
if key in name or key.split("""w2v_model.""" )[-1] == name.split(""".""" )[0]:
snake_case__ : Optional[Any] = True
if "*" in mapped_key:
snake_case__ : Optional[int] = name.split(_lowerCAmelCase )[0].split(""".""" )[-2]
snake_case__ : Tuple = mapped_key.replace("""*""" , _lowerCAmelCase )
if "weight_g" in name:
snake_case__ : str = """weight_g"""
elif "weight_v" in name:
snake_case__ : int = """weight_v"""
elif "bias" in name:
snake_case__ : Dict = """bias"""
elif "weight" in name:
snake_case__ : Union[str, Any] = """weight"""
else:
snake_case__ : Union[str, Any] = None
set_recursively(_lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase )
continue
if not is_used:
unused_weights.append(_lowerCAmelCase )
logger.warning(f"Unused weights: {unused_weights}" )
return proj_weight
def __snake_case( _lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase ) -> Dict:
snake_case__ : int = full_name.split("""conv_layers.""" )[-1]
snake_case__ : Dict = name.split(""".""" )
snake_case__ : Any = int(items[0] )
snake_case__ : Optional[Any] = int(items[1] )
if type_id == 0:
if "bias" in name:
assert value.shape == feature_extractor.conv_layers[layer_id].conv.bias.data.shape, (
f"{full_name} has size {value.shape}, but"
f" {feature_extractor.conv_layers[layer_id].conv.bias.data.shape} was found."
)
snake_case__ : int = value
logger.info(f"Feat extract conv layer {layer_id} was initialized from {full_name}." )
elif "weight" in name:
assert value.shape == feature_extractor.conv_layers[layer_id].conv.weight.data.shape, (
f"{full_name} has size {value.shape}, but"
f" {feature_extractor.conv_layers[layer_id].conv.weight.data.shape} was found."
)
snake_case__ : str = value
logger.info(f"Feat extract conv layer {layer_id} was initialized from {full_name}." )
elif (type_id == 2 and not use_group_norm) or (type_id == 2 and layer_id == 0 and use_group_norm):
if "bias" in name:
assert value.shape == feature_extractor.conv_layers[layer_id].layer_norm.bias.data.shape, (
f"{full_name} has size {value.shape}, but {feature_extractor[layer_id].layer_norm.bias.data.shape} was"
" found."
)
snake_case__ : Union[str, Any] = value
logger.info(f"Feat extract layer norm weight of layer {layer_id} was initialized from {full_name}." )
elif "weight" in name:
assert value.shape == feature_extractor.conv_layers[layer_id].layer_norm.weight.data.shape, (
f"{full_name} has size {value.shape}, but"
f" {feature_extractor[layer_id].layer_norm.weight.data.shape} was found."
)
snake_case__ : int = value
logger.info(f"Feat extract layer norm weight of layer {layer_id} was initialized from {full_name}." )
else:
unused_weights.append(_lowerCAmelCase )
def __snake_case( _lowerCAmelCase ) -> List[str]:
snake_case__ , snake_case__ : str = emb.weight.shape
snake_case__ : List[str] = nn.Linear(_lowerCAmelCase , _lowerCAmelCase , bias=_lowerCAmelCase )
snake_case__ : List[str] = emb.weight.data
return lin_layer
def __snake_case( _lowerCAmelCase ) -> Optional[Any]:
with open(_lowerCAmelCase , """r""" , encoding="""utf-8""" ) as f:
snake_case__ : int = f.readlines()
snake_case__ : List[Any] = [line.split(""" """ )[0] for line in lines]
snake_case__ : Union[str, Any] = len(_lowerCAmelCase )
snake_case__ : Any = {
"""<s>""": 0,
"""<pad>""": 1,
"""</s>""": 2,
"""<unk>""": 3,
}
vocab_dict.update(dict(zip(_lowerCAmelCase , range(4 , num_words + 4 ) ) ) )
return vocab_dict
@torch.no_grad()
def __snake_case( _lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase , ) -> int:
snake_case__ : Optional[Any] = WavaVecaConfig.from_pretrained(_lowerCAmelCase )
snake_case__ : Optional[Any] = SpeechaTextaConfig.from_pretrained(
_lowerCAmelCase , vocab_size=_lowerCAmelCase , decoder_layers=_lowerCAmelCase , do_stable_layer_norm=_lowerCAmelCase )
snake_case__ : Optional[Any] = WavaVecaFeatureExtractor(
feature_size=1 , sampling_rate=16_000 , padding_value=0 , do_normalize=_lowerCAmelCase , return_attention_mask=_lowerCAmelCase , )
snake_case__ , snake_case__ , snake_case__ : Union[str, Any] = fairseq.checkpoint_utils.load_model_ensemble_and_task(
[checkpoint_path] , arg_overrides={"""data""": """/""".join(dict_path.split("""/""" )[:-1] )} )
snake_case__ : Tuple = model[0].eval()
# set weights for wav2vec2 encoder
snake_case__ : Optional[Any] = WavaVecaModel(_lowerCAmelCase )
snake_case__ : Dict = recursively_load_weights_wavaveca(model.encoder , _lowerCAmelCase )
snake_case__ : Optional[Any] = SpeechaTextaForCausalLM(_lowerCAmelCase )
snake_case__ , snake_case__ : Tuple = hf_decoder.model.decoder.load_state_dict(model.decoder.state_dict() , strict=_lowerCAmelCase )
# set output linear layer
unexpected_keys.remove("""embed_out""" )
snake_case__ : Tuple = nn.Parameter(model.decoder.embed_out.detach() )
# layer norm is init to identity matrix so leaving it is fine
logger.warning(f"The following keys are missing when loading the decoder weights: {missing_keys}" )
logger.warning(f"The following keys are unexpected when loading the decoder weights: {unexpected_keys}" )
snake_case__ : List[Any] = SpeechEncoderDecoderModel(encoder=_lowerCAmelCase , decoder=_lowerCAmelCase )
snake_case__ : Tuple = False
# add projection layer
snake_case__ : Union[str, Any] = nn.Parameter(projection_layer.weight )
snake_case__ : int = nn.Parameter(projection_layer.bias )
snake_case__ : Tuple = create_vocab_dict(_lowerCAmelCase )
with open(os.path.join(_lowerCAmelCase , """vocab.json""" ) , """w""" ) as fp:
json.dump(_lowerCAmelCase , _lowerCAmelCase )
snake_case__ : Tuple = SpeechaTextaTokenizer(os.path.join(_lowerCAmelCase , """vocab.json""" ) )
tokenizer.save_pretrained(_lowerCAmelCase )
snake_case__ : Optional[Any] = hf_wavavec.config.to_dict()
snake_case__ : Tuple = tokenizer.pad_token_id
snake_case__ : Optional[Any] = tokenizer.bos_token_id
snake_case__ : int = tokenizer.eos_token_id
snake_case__ : str = """speech_to_text_2"""
snake_case__ : List[Any] = """wav2vec2"""
snake_case__ : List[str] = SpeechEncoderDecoderConfig.from_dict(_lowerCAmelCase )
hf_wavavec.save_pretrained(_lowerCAmelCase )
feature_extractor.save_pretrained(_lowerCAmelCase )
if __name__ == "__main__":
__a = argparse.ArgumentParser()
parser.add_argument("--pytorch_dump_folder_path", default=None, type=str, help="Path to the output PyTorch model.")
parser.add_argument("--checkpoint_path", default=None, type=str, help="Path to fairseq checkpoint")
parser.add_argument("--dict_path", default=None, type=str, help="Path to dict of fine-tuned model")
parser.add_argument(
"--encoder_config_path",
default="facebook/wav2vec2-large-lv60",
type=str,
help="Path to hf encoder wav2vec2 checkpoint config",
)
parser.add_argument(
"--decoder_config_path",
default="facebook/s2t-small-mustc-en-fr-st",
type=str,
help="Path to hf decoder s2t checkpoint config",
)
parser.add_argument("--vocab_size", default=1_0224, type=int, help="Vocab size of decoder")
parser.add_argument("--num_decoder_layers", default=7, type=int, help="Number of decoder layers")
__a = parser.parse_args()
convert_wavaveca_checkpoint(
args.checkpoint_path,
args.pytorch_dump_folder_path,
args.dict_path,
encoder_config_path=args.encoder_config_path,
decoder_config_path=args.decoder_config_path,
vocab_size=args.vocab_size,
num_decoder_layers=args.num_decoder_layers,
)
| 35
| 0
|
'''simple docstring'''
def lowerCAmelCase (__A , __A , __A):
"""simple docstring"""
return not any(
neighbour == 1 and colored_vertices[i] == color
for i, neighbour in enumerate(_lowerCAmelCase))
def lowerCAmelCase (__A , __A , __A , __A):
"""simple docstring"""
if index == len(_lowerCAmelCase):
return True
# Recursive Step
for i in range(_lowerCAmelCase):
if valid_coloring(graph[index] , _lowerCAmelCase , _lowerCAmelCase):
# Color current vertex
_a = i
# Validate coloring
if util_color(_lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase , index + 1):
return True
# Backtrack
_a = -1
return False
def lowerCAmelCase (__A , __A):
"""simple docstring"""
_a = [-1] * len(_lowerCAmelCase)
if util_color(_lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase , 0):
return colored_vertices
return []
| 211
|
'''simple docstring'''
import importlib
import os
import sys
# This is required to make the module import works (when the python process is running from the root of the repo)
sys.path.append(".")
def __snake_case( _lowerCAmelCase ) -> int:
snake_case__ : Optional[int] = test_file.split(os.path.sep )
if components[0:2] != ["tests", "models"]:
raise ValueError(
"""`test_file` should start with `tests/models/` (with `/` being the OS specific path separator). Got """
f"{test_file} instead." )
snake_case__ : Dict = components[-1]
if not test_fn.endswith("""py""" ):
raise ValueError(f"`test_file` should be a python file. Got {test_fn} instead." )
if not test_fn.startswith("""test_modeling_""" ):
raise ValueError(
f"`test_file` should point to a file name of the form `test_modeling_*.py`. Got {test_fn} instead." )
snake_case__ : int = components[:-1] + [test_fn.replace(""".py""" , """""" )]
snake_case__ : int = """.""".join(_lowerCAmelCase )
return test_module_path
def __snake_case( _lowerCAmelCase ) -> List[str]:
snake_case__ : str = get_module_path(_lowerCAmelCase )
snake_case__ : Union[str, Any] = importlib.import_module(_lowerCAmelCase )
return test_module
def __snake_case( _lowerCAmelCase ) -> int:
snake_case__ : List[Any] = []
snake_case__ : Optional[int] = get_test_module(_lowerCAmelCase )
for attr in dir(_lowerCAmelCase ):
if attr.endswith("""ModelTester""" ):
tester_classes.append(getattr(_lowerCAmelCase , _lowerCAmelCase ) )
# sort with class names
return sorted(_lowerCAmelCase , key=lambda _lowerCAmelCase : x.__name__ )
def __snake_case( _lowerCAmelCase ) -> Dict:
snake_case__ : List[str] = []
snake_case__ : Any = get_test_module(_lowerCAmelCase )
for attr in dir(_lowerCAmelCase ):
snake_case__ : Dict = getattr(_lowerCAmelCase , _lowerCAmelCase )
# (TF/Flax)ModelTesterMixin is also an attribute in specific model test module. Let's exclude them by checking
# `all_model_classes` is not empty (which also excludes other special classes).
snake_case__ : List[str] = getattr(_lowerCAmelCase , """all_model_classes""" , [] )
if len(_lowerCAmelCase ) > 0:
test_classes.append(_lowerCAmelCase )
# sort with class names
return sorted(_lowerCAmelCase , key=lambda _lowerCAmelCase : x.__name__ )
def __snake_case( _lowerCAmelCase ) -> Dict:
snake_case__ : Any = get_test_classes(_lowerCAmelCase )
snake_case__ : Optional[Any] = set()
for test_class in test_classes:
model_classes.update(test_class.all_model_classes )
# sort with class names
return sorted(_lowerCAmelCase , key=lambda _lowerCAmelCase : x.__name__ )
def __snake_case( _lowerCAmelCase ) -> Optional[Any]:
snake_case__ : Optional[int] = test_class()
if hasattr(_lowerCAmelCase , """setUp""" ):
test.setUp()
snake_case__ : Any = None
if hasattr(_lowerCAmelCase , """model_tester""" ):
# `(TF/Flax)ModelTesterMixin` has this attribute default to `None`. Let's skip this case.
if test.model_tester is not None:
snake_case__ : Tuple = test.model_tester.__class__
return model_tester
def __snake_case( _lowerCAmelCase , _lowerCAmelCase ) -> Dict:
snake_case__ : Union[str, Any] = get_test_classes(_lowerCAmelCase )
snake_case__ : str = []
for test_class in test_classes:
if model_class in test_class.all_model_classes:
target_test_classes.append(_lowerCAmelCase )
# sort with class names
return sorted(_lowerCAmelCase , key=lambda _lowerCAmelCase : x.__name__ )
def __snake_case( _lowerCAmelCase , _lowerCAmelCase ) -> Tuple:
snake_case__ : Optional[Any] = get_test_classes_for_model(_lowerCAmelCase , _lowerCAmelCase )
snake_case__ : Union[str, Any] = []
for test_class in test_classes:
snake_case__ : Tuple = get_model_tester_from_test_class(_lowerCAmelCase )
if tester_class is not None:
tester_classes.append(_lowerCAmelCase )
# sort with class names
return sorted(_lowerCAmelCase , key=lambda _lowerCAmelCase : x.__name__ )
def __snake_case( _lowerCAmelCase ) -> Union[str, Any]:
snake_case__ : Optional[Any] = get_test_classes(_lowerCAmelCase )
snake_case__ : Union[str, Any] = {test_class: get_model_tester_from_test_class(_lowerCAmelCase ) for test_class in test_classes}
return test_tester_mapping
def __snake_case( _lowerCAmelCase ) -> int:
snake_case__ : Any = get_model_classes(_lowerCAmelCase )
snake_case__ : Any = {
model_class: get_test_classes_for_model(_lowerCAmelCase , _lowerCAmelCase ) for model_class in model_classes
}
return model_test_mapping
def __snake_case( _lowerCAmelCase ) -> Optional[int]:
snake_case__ : Union[str, Any] = get_model_classes(_lowerCAmelCase )
snake_case__ : str = {
model_class: get_tester_classes_for_model(_lowerCAmelCase , _lowerCAmelCase ) for model_class in model_classes
}
return model_to_tester_mapping
def __snake_case( _lowerCAmelCase ) -> int:
if isinstance(_lowerCAmelCase , _lowerCAmelCase ):
return o
elif isinstance(_lowerCAmelCase , _lowerCAmelCase ):
return o.__name__
elif isinstance(_lowerCAmelCase , (list, tuple) ):
return [to_json(_lowerCAmelCase ) for x in o]
elif isinstance(_lowerCAmelCase , _lowerCAmelCase ):
return {to_json(_lowerCAmelCase ): to_json(_lowerCAmelCase ) for k, v in o.items()}
else:
return o
| 35
| 0
|
from __future__ import annotations
def a ( A__ : Dict ) -> int:
"""simple docstring"""
if not nums:
return 0
_lowercase =nums[0]
_lowercase =0
for num in nums[1:]:
_lowercase =(
max_excluding + num,
max(_lowerCAmelCase , _lowerCAmelCase ),
)
return max(_lowerCAmelCase , _lowerCAmelCase )
if __name__ == "__main__":
import doctest
doctest.testmod()
| 205
|
'''simple docstring'''
import argparse
import json
import requests
import timm
import torch
from huggingface_hub import hf_hub_download
from PIL import Image
from transformers import AutoImageProcessor, SwinConfig, SwinForImageClassification
def __snake_case( _lowerCAmelCase ) -> List[Any]:
snake_case__ : Dict = SwinConfig()
snake_case__ : Optional[Any] = swin_name.split("""_""" )
snake_case__ : Any = name_split[1]
snake_case__ : List[Any] = int(name_split[4] )
snake_case__ : int = int(name_split[3][-1] )
if model_size == "tiny":
snake_case__ : List[Any] = 96
snake_case__ : int = (2, 2, 6, 2)
snake_case__ : int = (3, 6, 12, 24)
elif model_size == "small":
snake_case__ : Union[str, Any] = 96
snake_case__ : Optional[Any] = (2, 2, 18, 2)
snake_case__ : str = (3, 6, 12, 24)
elif model_size == "base":
snake_case__ : Dict = 128
snake_case__ : str = (2, 2, 18, 2)
snake_case__ : Dict = (4, 8, 16, 32)
else:
snake_case__ : List[str] = 192
snake_case__ : str = (2, 2, 18, 2)
snake_case__ : List[Any] = (6, 12, 24, 48)
if "in22k" in swin_name:
snake_case__ : str = 21_841
else:
snake_case__ : List[str] = 1_000
snake_case__ : int = """huggingface/label-files"""
snake_case__ : Any = """imagenet-1k-id2label.json"""
snake_case__ : List[Any] = json.load(open(hf_hub_download(_lowerCAmelCase , _lowerCAmelCase , repo_type="""dataset""" ) , """r""" ) )
snake_case__ : Dict = {int(_lowerCAmelCase ): v for k, v in idalabel.items()}
snake_case__ : Optional[int] = idalabel
snake_case__ : List[Any] = {v: k for k, v in idalabel.items()}
snake_case__ : List[Any] = img_size
snake_case__ : Dict = num_classes
snake_case__ : Dict = embed_dim
snake_case__ : Optional[int] = depths
snake_case__ : int = num_heads
snake_case__ : Optional[int] = window_size
return config
def __snake_case( _lowerCAmelCase ) -> Dict:
if "patch_embed.proj" in name:
snake_case__ : List[str] = name.replace("""patch_embed.proj""" , """embeddings.patch_embeddings.projection""" )
if "patch_embed.norm" in name:
snake_case__ : int = name.replace("""patch_embed.norm""" , """embeddings.norm""" )
if "layers" in name:
snake_case__ : str = """encoder.""" + name
if "attn.proj" in name:
snake_case__ : List[str] = name.replace("""attn.proj""" , """attention.output.dense""" )
if "attn" in name:
snake_case__ : Tuple = name.replace("""attn""" , """attention.self""" )
if "norm1" in name:
snake_case__ : List[str] = name.replace("""norm1""" , """layernorm_before""" )
if "norm2" in name:
snake_case__ : Optional[Any] = name.replace("""norm2""" , """layernorm_after""" )
if "mlp.fc1" in name:
snake_case__ : Union[str, Any] = name.replace("""mlp.fc1""" , """intermediate.dense""" )
if "mlp.fc2" in name:
snake_case__ : Dict = name.replace("""mlp.fc2""" , """output.dense""" )
if name == "norm.weight":
snake_case__ : Tuple = """layernorm.weight"""
if name == "norm.bias":
snake_case__ : Union[str, Any] = """layernorm.bias"""
if "head" in name:
snake_case__ : Optional[int] = name.replace("""head""" , """classifier""" )
else:
snake_case__ : List[str] = """swin.""" + name
return name
def __snake_case( _lowerCAmelCase , _lowerCAmelCase ) -> Optional[Any]:
for key in orig_state_dict.copy().keys():
snake_case__ : Optional[int] = orig_state_dict.pop(_lowerCAmelCase )
if "mask" in key:
continue
elif "qkv" in key:
snake_case__ : Dict = key.split(""".""" )
snake_case__ : Optional[int] = int(key_split[1] )
snake_case__ : Union[str, Any] = int(key_split[3] )
snake_case__ : List[Any] = model.swin.encoder.layers[layer_num].blocks[block_num].attention.self.all_head_size
if "weight" in key:
snake_case__ : Optional[Any] = val[:dim, :]
snake_case__ : Tuple = val[
dim : dim * 2, :
]
snake_case__ : Dict = val[-dim:, :]
else:
snake_case__ : Tuple = val[
:dim
]
snake_case__ : int = val[
dim : dim * 2
]
snake_case__ : int = val[
-dim:
]
else:
snake_case__ : Union[str, Any] = val
return orig_state_dict
def __snake_case( _lowerCAmelCase , _lowerCAmelCase ) -> int:
snake_case__ : Optional[int] = timm.create_model(_lowerCAmelCase , pretrained=_lowerCAmelCase )
timm_model.eval()
snake_case__ : Optional[int] = get_swin_config(_lowerCAmelCase )
snake_case__ : Optional[Any] = SwinForImageClassification(_lowerCAmelCase )
model.eval()
snake_case__ : str = convert_state_dict(timm_model.state_dict() , _lowerCAmelCase )
model.load_state_dict(_lowerCAmelCase )
snake_case__ : int = """http://images.cocodataset.org/val2017/000000039769.jpg"""
snake_case__ : Dict = AutoImageProcessor.from_pretrained("""microsoft/{}""".format(swin_name.replace("""_""" , """-""" ) ) )
snake_case__ : Dict = Image.open(requests.get(_lowerCAmelCase , stream=_lowerCAmelCase ).raw )
snake_case__ : Optional[int] = image_processor(images=_lowerCAmelCase , return_tensors="""pt""" )
snake_case__ : Optional[Any] = timm_model(inputs["""pixel_values"""] )
snake_case__ : str = model(**_lowerCAmelCase ).logits
assert torch.allclose(_lowerCAmelCase , _lowerCAmelCase , atol=1e-3 )
print(f"Saving model {swin_name} to {pytorch_dump_folder_path}" )
model.save_pretrained(_lowerCAmelCase )
print(f"Saving image processor to {pytorch_dump_folder_path}" )
image_processor.save_pretrained(_lowerCAmelCase )
if __name__ == "__main__":
__a = argparse.ArgumentParser()
# Required parameters
parser.add_argument(
"--swin_name",
default="swin_tiny_patch4_window7_224",
type=str,
help="Name of the Swin timm model you'd like to convert.",
)
parser.add_argument(
"--pytorch_dump_folder_path", default=None, type=str, help="Path to the output PyTorch model directory."
)
__a = parser.parse_args()
convert_swin_checkpoint(args.swin_name, args.pytorch_dump_folder_path)
| 35
| 0
|
from typing import List, Optional
from ...configuration_utils import PretrainedConfig
from ...utils import logging
_snake_case = logging.get_logger(__name__)
_snake_case = {
"huggingface/autoformer-tourism-monthly": "https://huggingface.co/huggingface/autoformer-tourism-monthly/resolve/main/config.json",
}
class UpperCAmelCase_ ( a):
lowerCamelCase__ = 'autoformer'
lowerCamelCase__ = {
'hidden_size': 'd_model',
'num_attention_heads': 'encoder_attention_heads',
'num_hidden_layers': 'encoder_layers',
}
def __init__( self, __a = None, __a = None, __a = "student_t", __a = "nll", __a = 1, __a = [1, 2, 3, 4, 5, 6, 7], __a = True, __a = 0, __a = 0, __a = 0, __a = 0, __a = None, __a = None, __a = 64, __a = 2, __a = 2, __a = 2, __a = 2, __a = 32, __a = 32, __a = "gelu", __a = 0.1, __a = 0.1, __a = 0.1, __a = 0.1, __a = 0.1, __a = 100, __a = 0.02, __a = True, __a=True, __a = 10, __a = 25, __a = 3, **__a, ):
'''simple docstring'''
_lowerCAmelCase : Optional[int] = prediction_length
_lowerCAmelCase : Any = context_length if context_length is not None else prediction_length
_lowerCAmelCase : Optional[int] = distribution_output
_lowerCAmelCase : Tuple = loss
_lowerCAmelCase : List[Any] = input_size
_lowerCAmelCase : List[Any] = num_time_features
_lowerCAmelCase : Union[str, Any] = lags_sequence
_lowerCAmelCase : Optional[int] = scaling
_lowerCAmelCase : List[Any] = num_dynamic_real_features
_lowerCAmelCase : str = num_static_real_features
_lowerCAmelCase : Optional[Any] = num_static_categorical_features
if cardinality is not None and num_static_categorical_features > 0:
if len(__a) != num_static_categorical_features:
raise ValueError(
"The cardinality should be a list of the same length as `num_static_categorical_features`")
_lowerCAmelCase : Any = cardinality
else:
_lowerCAmelCase : List[str] = [0]
if embedding_dimension is not None and num_static_categorical_features > 0:
if len(__a) != num_static_categorical_features:
raise ValueError(
"The embedding dimension should be a list of the same length as `num_static_categorical_features`")
_lowerCAmelCase : List[str] = embedding_dimension
else:
_lowerCAmelCase : Union[str, Any] = [min(50, (cat + 1) // 2) for cat in self.cardinality]
_lowerCAmelCase : Any = num_parallel_samples
# Transformer architecture configuration
_lowerCAmelCase : Dict = input_size * len(self.lags_sequence) + self._number_of_features
_lowerCAmelCase : Optional[Any] = d_model
_lowerCAmelCase : Optional[int] = encoder_attention_heads
_lowerCAmelCase : Union[str, Any] = decoder_attention_heads
_lowerCAmelCase : List[Any] = encoder_ffn_dim
_lowerCAmelCase : Union[str, Any] = decoder_ffn_dim
_lowerCAmelCase : List[str] = encoder_layers
_lowerCAmelCase : Tuple = decoder_layers
_lowerCAmelCase : List[str] = dropout
_lowerCAmelCase : List[Any] = attention_dropout
_lowerCAmelCase : Dict = activation_dropout
_lowerCAmelCase : Optional[Any] = encoder_layerdrop
_lowerCAmelCase : Union[str, Any] = decoder_layerdrop
_lowerCAmelCase : Dict = activation_function
_lowerCAmelCase : Optional[Any] = init_std
_lowerCAmelCase : List[Any] = use_cache
# Autoformer
_lowerCAmelCase : Tuple = label_length
_lowerCAmelCase : List[str] = moving_average
_lowerCAmelCase : str = autocorrelation_factor
super().__init__(is_encoder_decoder=__a, **__a)
@property
def snake_case__ ( self):
'''simple docstring'''
return (
sum(self.embedding_dimension)
+ self.num_dynamic_real_features
+ self.num_time_features
+ self.num_static_real_features
+ self.input_size * 2 # the log1p(abs(loc)) and log(scale) features
)
| 36
|
def A ( _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
if density <= 0:
raise ValueError("Impossible fluid density" )
if bulk_modulus <= 0:
raise ValueError("Impossible bulk modulus" )
return (bulk_modulus / density) ** 0.5
if __name__ == "__main__":
import doctest
doctest.testmod()
| 36
| 1
|
from maths.prime_factors import prime_factors
def A ( _lowerCamelCase ):
'''simple docstring'''
if not isinstance(_lowerCamelCase , _lowerCamelCase ):
_lowerCAmelCase : int = F"Input value of [number={number}] must be an integer"
raise TypeError(_lowerCamelCase )
if number < 1:
raise ValueError("Input must be a positive integer" )
return -1 if len(prime_factors(_lowerCamelCase ) ) % 2 else 1
if __name__ == "__main__":
import doctest
doctest.testmod()
| 36
|
from typing import Dict
from transformers import EvalPrediction, HfArgumentParser, TrainingArguments, is_torch_available
from transformers.testing_utils import (
TestCasePlus,
execute_subprocess_async,
get_torch_dist_unique_port,
require_torch_multi_gpu,
require_torch_neuroncore,
)
from transformers.training_args import ParallelMode
from transformers.utils import logging
_snake_case = logging.get_logger(__name__)
if is_torch_available():
import torch
from torch import nn
from torch.utils.data import Dataset
from transformers import Trainer
class UpperCAmelCase_ ( a):
def __init__( self, __a = 101):
'''simple docstring'''
_lowerCAmelCase : str = length
def __len__( self):
'''simple docstring'''
return self.length
def __getitem__( self, __a):
'''simple docstring'''
return i
class UpperCAmelCase_ :
def __call__( self, __a):
'''simple docstring'''
return {"input_ids": torch.tensor(__a), "labels": torch.tensor(__a)}
class UpperCAmelCase_ ( nn.Module):
def __init__( self):
'''simple docstring'''
super().__init__()
# Add some (unused) params otherwise DDP will complain.
_lowerCAmelCase : str = nn.Linear(120, 80)
def snake_case__ ( self, __a, __a=None):
'''simple docstring'''
if labels is not None:
return torch.tensor(0.0, device=input_ids.device), input_ids
else:
return input_ids
class UpperCAmelCase_ ( a):
@require_torch_neuroncore
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : int = f"--nproc_per_node=2\n --master_port={get_torch_dist_unique_port()}\n {self.test_file_dir}/test_trainer_distributed.py\n ".split()
_lowerCAmelCase : Tuple = self.get_auto_remove_tmp_dir()
_lowerCAmelCase : Optional[int] = f"--output_dir {output_dir}".split()
_lowerCAmelCase : List[Any] = ["torchrun"] + distributed_args + args
execute_subprocess_async(__a, env=self.get_env())
# successful return here == success - any errors would have caused an error in the sub-call
class UpperCAmelCase_ ( a):
@require_torch_multi_gpu
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Dict = f"--nproc_per_node={torch.cuda.device_count()}\n --master_port={get_torch_dist_unique_port()}\n {self.test_file_dir}/test_trainer_distributed.py\n ".split()
_lowerCAmelCase : Any = self.get_auto_remove_tmp_dir()
_lowerCAmelCase : Optional[int] = f"--output_dir {output_dir}".split()
_lowerCAmelCase : Any = ["torchrun"] + distributed_args + args
execute_subprocess_async(__a, env=self.get_env())
# successful return here == success - any errors would have caused an error in the sub-call
if __name__ == "__main__":
# The script below is meant to be run under torch.distributed, on a machine with multiple GPUs:
#
# PYTHONPATH="src" python -m torch.distributed.run --nproc_per_node 2 --output_dir output_dir ./tests/test_trainer_distributed.py
_snake_case = HfArgumentParser((TrainingArguments,))
_snake_case = parser.parse_args_into_dataclasses()[0]
logger.warning(
f'''Process rank: {training_args.local_rank}, device: {training_args.device}, n_gpu: {training_args.n_gpu}, '''
f'''distributed training: {training_args.parallel_mode != ParallelMode.NOT_DISTRIBUTED}'''
)
# Essentially, what we want to verify in the distributed case is that we get all samples back,
# in the right order. (this is crucial for prediction for instance)
for dataset_length in [101, 40, 7]:
_snake_case = DummyDataset(dataset_length)
def A ( _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : Dict = list(range(len(_lowerCamelCase ) ) )
_lowerCAmelCase : Union[str, Any] = p.predictions.tolist() == sequential and p.label_ids.tolist() == sequential
if not success and training_args.local_rank == 0:
logger.warning(
"Predictions and/or labels do not match expected results:\n - predictions: "
F"{p.predictions.tolist()}\n - labels: {p.label_ids.tolist()}\n - expected: {sequential}" )
return {"success": success}
_snake_case = Trainer(
model=DummyModel(),
args=training_args,
data_collator=DummyDataCollator(),
eval_dataset=dataset,
compute_metrics=compute_metrics,
)
_snake_case = trainer.evaluate()
logger.info(metrics)
if metrics["eval_success"] is not True:
logger.error(metrics)
exit(1)
_snake_case = trainer.predict(dataset)
logger.info(p.metrics)
if p.metrics["test_success"] is not True:
logger.error(p.metrics)
exit(1)
_snake_case = 2
_snake_case = trainer.evaluate()
logger.info(metrics)
if metrics["eval_success"] is not True:
logger.error(metrics)
exit(1)
_snake_case = trainer.predict(dataset)
logger.info(p.metrics)
if p.metrics["test_success"] is not True:
logger.error(p.metrics)
exit(1)
_snake_case = None
| 36
| 1
|
import shutil
import tempfile
import unittest
from unittest.mock import patch
from transformers import (
DefaultFlowCallback,
IntervalStrategy,
PrinterCallback,
ProgressCallback,
Trainer,
TrainerCallback,
TrainingArguments,
is_torch_available,
)
from transformers.testing_utils import require_torch
if is_torch_available():
from transformers.trainer import DEFAULT_CALLBACKS
from .test_trainer import RegressionDataset, RegressionModelConfig, RegressionPreTrainedModel
class UpperCAmelCase_ ( a):
def __init__( self):
'''simple docstring'''
_lowerCAmelCase : List[str] = []
def snake_case__ ( self, __a, __a, __a, **__a):
'''simple docstring'''
self.events.append("on_init_end")
def snake_case__ ( self, __a, __a, __a, **__a):
'''simple docstring'''
self.events.append("on_train_begin")
def snake_case__ ( self, __a, __a, __a, **__a):
'''simple docstring'''
self.events.append("on_train_end")
def snake_case__ ( self, __a, __a, __a, **__a):
'''simple docstring'''
self.events.append("on_epoch_begin")
def snake_case__ ( self, __a, __a, __a, **__a):
'''simple docstring'''
self.events.append("on_epoch_end")
def snake_case__ ( self, __a, __a, __a, **__a):
'''simple docstring'''
self.events.append("on_step_begin")
def snake_case__ ( self, __a, __a, __a, **__a):
'''simple docstring'''
self.events.append("on_step_end")
def snake_case__ ( self, __a, __a, __a, **__a):
'''simple docstring'''
self.events.append("on_evaluate")
def snake_case__ ( self, __a, __a, __a, **__a):
'''simple docstring'''
self.events.append("on_predict")
def snake_case__ ( self, __a, __a, __a, **__a):
'''simple docstring'''
self.events.append("on_save")
def snake_case__ ( self, __a, __a, __a, **__a):
'''simple docstring'''
self.events.append("on_log")
def snake_case__ ( self, __a, __a, __a, **__a):
'''simple docstring'''
self.events.append("on_prediction_step")
@require_torch
class UpperCAmelCase_ ( unittest.TestCase):
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : int = tempfile.mkdtemp()
def snake_case__ ( self):
'''simple docstring'''
shutil.rmtree(self.output_dir)
def snake_case__ ( self, __a=0, __a=0, __a=64, __a=64, __a=None, __a=False, **__a):
'''simple docstring'''
_lowerCAmelCase : Optional[int] = RegressionDataset(length=__a)
_lowerCAmelCase : Union[str, Any] = RegressionDataset(length=__a)
_lowerCAmelCase : List[str] = RegressionModelConfig(a=__a, b=__a)
_lowerCAmelCase : str = RegressionPreTrainedModel(__a)
_lowerCAmelCase : str = TrainingArguments(self.output_dir, disable_tqdm=__a, report_to=[], **__a)
return Trainer(
__a, __a, train_dataset=__a, eval_dataset=__a, callbacks=__a, )
def snake_case__ ( self, __a, __a):
'''simple docstring'''
self.assertEqual(len(__a), len(__a))
# Order doesn't matter
_lowerCAmelCase : Any = sorted(__a, key=lambda __a: cb.__name__ if isinstance(__a, __a) else cb.__class__.__name__)
_lowerCAmelCase : str = sorted(__a, key=lambda __a: cb.__name__ if isinstance(__a, __a) else cb.__class__.__name__)
for cba, cba in zip(__a, __a):
if isinstance(__a, __a) and isinstance(__a, __a):
self.assertEqual(__a, __a)
elif isinstance(__a, __a) and not isinstance(__a, __a):
self.assertEqual(__a, cba.__class__)
elif not isinstance(__a, __a) and isinstance(__a, __a):
self.assertEqual(cba.__class__, __a)
else:
self.assertEqual(__a, __a)
def snake_case__ ( self, __a):
'''simple docstring'''
_lowerCAmelCase : Optional[Any] = ["on_init_end", "on_train_begin"]
_lowerCAmelCase : str = 0
_lowerCAmelCase : List[Any] = len(trainer.get_eval_dataloader())
_lowerCAmelCase : List[str] = ["on_prediction_step"] * len(trainer.get_eval_dataloader()) + ["on_log", "on_evaluate"]
for _ in range(trainer.state.num_train_epochs):
expected_events.append("on_epoch_begin")
for _ in range(__a):
step += 1
expected_events += ["on_step_begin", "on_step_end"]
if step % trainer.args.logging_steps == 0:
expected_events.append("on_log")
if trainer.args.evaluation_strategy == IntervalStrategy.STEPS and step % trainer.args.eval_steps == 0:
expected_events += evaluation_events.copy()
if step % trainer.args.save_steps == 0:
expected_events.append("on_save")
expected_events.append("on_epoch_end")
if trainer.args.evaluation_strategy == IntervalStrategy.EPOCH:
expected_events += evaluation_events.copy()
expected_events += ["on_log", "on_train_end"]
return expected_events
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : int = self.get_trainer()
_lowerCAmelCase : str = DEFAULT_CALLBACKS.copy() + [ProgressCallback]
self.check_callbacks_equality(trainer.callback_handler.callbacks, __a)
# Callbacks passed at init are added to the default callbacks
_lowerCAmelCase : List[Any] = self.get_trainer(callbacks=[MyTestTrainerCallback])
expected_callbacks.append(__a)
self.check_callbacks_equality(trainer.callback_handler.callbacks, __a)
# TrainingArguments.disable_tqdm controls if use ProgressCallback or PrinterCallback
_lowerCAmelCase : Dict = self.get_trainer(disable_tqdm=__a)
_lowerCAmelCase : List[Any] = DEFAULT_CALLBACKS.copy() + [PrinterCallback]
self.check_callbacks_equality(trainer.callback_handler.callbacks, __a)
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Dict = DEFAULT_CALLBACKS.copy() + [ProgressCallback]
_lowerCAmelCase : Dict = self.get_trainer()
# We can add, pop, or remove by class name
trainer.remove_callback(__a)
expected_callbacks.remove(__a)
self.check_callbacks_equality(trainer.callback_handler.callbacks, __a)
_lowerCAmelCase : Tuple = self.get_trainer()
_lowerCAmelCase : Dict = trainer.pop_callback(__a)
self.assertEqual(cb.__class__, __a)
self.check_callbacks_equality(trainer.callback_handler.callbacks, __a)
trainer.add_callback(__a)
expected_callbacks.insert(0, __a)
self.check_callbacks_equality(trainer.callback_handler.callbacks, __a)
# We can also add, pop, or remove by instance
_lowerCAmelCase : List[str] = self.get_trainer()
_lowerCAmelCase : int = trainer.callback_handler.callbacks[0]
trainer.remove_callback(__a)
expected_callbacks.remove(__a)
self.check_callbacks_equality(trainer.callback_handler.callbacks, __a)
_lowerCAmelCase : Optional[int] = self.get_trainer()
_lowerCAmelCase : Optional[Any] = trainer.callback_handler.callbacks[0]
_lowerCAmelCase : int = trainer.pop_callback(__a)
self.assertEqual(__a, __a)
self.check_callbacks_equality(trainer.callback_handler.callbacks, __a)
trainer.add_callback(__a)
expected_callbacks.insert(0, __a)
self.check_callbacks_equality(trainer.callback_handler.callbacks, __a)
def snake_case__ ( self):
'''simple docstring'''
import warnings
# XXX: for now ignore scatter_gather warnings in this test since it's not relevant to what's being tested
warnings.simplefilter(action="ignore", category=__a)
_lowerCAmelCase : Tuple = self.get_trainer(callbacks=[MyTestTrainerCallback])
trainer.train()
_lowerCAmelCase : List[Any] = trainer.callback_handler.callbacks[-2].events
self.assertEqual(__a, self.get_expected_events(__a))
# Independent log/save/eval
_lowerCAmelCase : str = self.get_trainer(callbacks=[MyTestTrainerCallback], logging_steps=5)
trainer.train()
_lowerCAmelCase : int = trainer.callback_handler.callbacks[-2].events
self.assertEqual(__a, self.get_expected_events(__a))
_lowerCAmelCase : List[str] = self.get_trainer(callbacks=[MyTestTrainerCallback], save_steps=5)
trainer.train()
_lowerCAmelCase : List[str] = trainer.callback_handler.callbacks[-2].events
self.assertEqual(__a, self.get_expected_events(__a))
_lowerCAmelCase : Dict = self.get_trainer(callbacks=[MyTestTrainerCallback], eval_steps=5, evaluation_strategy="steps")
trainer.train()
_lowerCAmelCase : Tuple = trainer.callback_handler.callbacks[-2].events
self.assertEqual(__a, self.get_expected_events(__a))
_lowerCAmelCase : str = self.get_trainer(callbacks=[MyTestTrainerCallback], evaluation_strategy="epoch")
trainer.train()
_lowerCAmelCase : Any = trainer.callback_handler.callbacks[-2].events
self.assertEqual(__a, self.get_expected_events(__a))
# A bit of everything
_lowerCAmelCase : int = self.get_trainer(
callbacks=[MyTestTrainerCallback], logging_steps=3, save_steps=10, eval_steps=5, evaluation_strategy="steps", )
trainer.train()
_lowerCAmelCase : Union[str, Any] = trainer.callback_handler.callbacks[-2].events
self.assertEqual(__a, self.get_expected_events(__a))
# warning should be emitted for duplicated callbacks
with patch("transformers.trainer_callback.logger.warning") as warn_mock:
_lowerCAmelCase : Optional[int] = self.get_trainer(
callbacks=[MyTestTrainerCallback, MyTestTrainerCallback], )
assert str(__a) in warn_mock.call_args[0][0]
| 36
|
from __future__ import annotations
import bisect
def A ( _lowerCamelCase , _lowerCamelCase , _lowerCamelCase = 0 , _lowerCamelCase = -1 ):
'''simple docstring'''
if hi < 0:
_lowerCAmelCase : int = len(_lowerCamelCase )
while lo < hi:
_lowerCAmelCase : Optional[Any] = lo + (hi - lo) // 2
if sorted_collection[mid] < item:
_lowerCAmelCase : Union[str, Any] = mid + 1
else:
_lowerCAmelCase : str = mid
return lo
def A ( _lowerCamelCase , _lowerCamelCase , _lowerCamelCase = 0 , _lowerCamelCase = -1 ):
'''simple docstring'''
if hi < 0:
_lowerCAmelCase : str = len(_lowerCamelCase )
while lo < hi:
_lowerCAmelCase : Tuple = lo + (hi - lo) // 2
if sorted_collection[mid] <= item:
_lowerCAmelCase : Dict = mid + 1
else:
_lowerCAmelCase : str = mid
return lo
def A ( _lowerCamelCase , _lowerCamelCase , _lowerCamelCase = 0 , _lowerCamelCase = -1 ):
'''simple docstring'''
sorted_collection.insert(bisect_left(_lowerCamelCase , _lowerCamelCase , _lowerCamelCase , _lowerCamelCase ) , _lowerCamelCase )
def A ( _lowerCamelCase , _lowerCamelCase , _lowerCamelCase = 0 , _lowerCamelCase = -1 ):
'''simple docstring'''
sorted_collection.insert(bisect_right(_lowerCamelCase , _lowerCamelCase , _lowerCamelCase , _lowerCamelCase ) , _lowerCamelCase )
def A ( _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : int = 0
_lowerCAmelCase : Union[str, Any] = len(_lowerCamelCase ) - 1
while left <= right:
_lowerCAmelCase : int = left + (right - left) // 2
_lowerCAmelCase : int = sorted_collection[midpoint]
if current_item == item:
return midpoint
elif item < current_item:
_lowerCAmelCase : str = midpoint - 1
else:
_lowerCAmelCase : Any = midpoint + 1
return None
def A ( _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : Tuple = bisect.bisect_left(_lowerCamelCase , _lowerCamelCase )
if index != len(_lowerCamelCase ) and sorted_collection[index] == item:
return index
return None
def A ( _lowerCamelCase , _lowerCamelCase , _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
if right < left:
return None
_lowerCAmelCase : Optional[int] = left + (right - left) // 2
if sorted_collection[midpoint] == item:
return midpoint
elif sorted_collection[midpoint] > item:
return binary_search_by_recursion(_lowerCamelCase , _lowerCamelCase , _lowerCamelCase , midpoint - 1 )
else:
return binary_search_by_recursion(_lowerCamelCase , _lowerCamelCase , midpoint + 1 , _lowerCamelCase )
if __name__ == "__main__":
_snake_case = input("Enter numbers separated by comma:\n").strip()
_snake_case = sorted(int(item) for item in user_input.split(","))
_snake_case = int(input("Enter a single number to be found in the list:\n"))
_snake_case = binary_search(collection, target)
if result is None:
print(f'''{target} was not found in {collection}.''')
else:
print(f'''{target} was found at position {result} in {collection}.''')
| 36
| 1
|
import json
from typing import Iterator, List, Union
from tokenizers import AddedToken, Regex, Tokenizer, decoders, normalizers, pre_tokenizers, trainers
from tokenizers.implementations.base_tokenizer import BaseTokenizer
from tokenizers.models import Unigram
from tokenizers.processors import TemplateProcessing
class UpperCAmelCase_ ( a):
def __init__( self, __a = "▁", __a = True, __a = "<unk>", __a = "</s>", __a = "<pad>", ):
'''simple docstring'''
_lowerCAmelCase : List[str] = {
"pad": {"id": 0, "token": pad_token},
"eos": {"id": 1, "token": eos_token},
"unk": {"id": 2, "token": unk_token},
}
_lowerCAmelCase : str = [None] * len(self.special_tokens)
for token_dict in self.special_tokens.values():
_lowerCAmelCase : Dict = token_dict["token"]
_lowerCAmelCase : int = Tokenizer(Unigram())
_lowerCAmelCase : Any = normalizers.Sequence(
[
normalizers.Nmt(),
normalizers.NFKC(),
normalizers.Replace(Regex(" {2,}"), " "),
normalizers.Lowercase(),
])
_lowerCAmelCase : Tuple = pre_tokenizers.Sequence(
[
pre_tokenizers.Metaspace(replacement=__a, add_prefix_space=__a),
pre_tokenizers.Digits(individual_digits=__a),
pre_tokenizers.Punctuation(),
])
_lowerCAmelCase : List[str] = decoders.Metaspace(replacement=__a, add_prefix_space=__a)
_lowerCAmelCase : Tuple = TemplateProcessing(
single=f"$A {self.special_tokens['eos']['token']}", special_tokens=[(self.special_tokens["eos"]["token"], self.special_tokens["eos"]["id"])], )
_lowerCAmelCase : List[Any] = {
"model": "SentencePieceUnigram",
"replacement": replacement,
"add_prefix_space": add_prefix_space,
}
super().__init__(__a, __a)
def snake_case__ ( self, __a, __a = 8000, __a = True, ):
'''simple docstring'''
_lowerCAmelCase : Dict = trainers.UnigramTrainer(
vocab_size=__a, special_tokens=self.special_tokens_list, show_progress=__a, )
if isinstance(__a, __a):
_lowerCAmelCase : Union[str, Any] = [files]
self._tokenizer.train(__a, trainer=__a)
self.add_unk_id()
def snake_case__ ( self, __a, __a = 8000, __a = True, ):
'''simple docstring'''
_lowerCAmelCase : Optional[int] = trainers.UnigramTrainer(
vocab_size=__a, special_tokens=self.special_tokens_list, show_progress=__a, )
self._tokenizer.train_from_iterator(__a, trainer=__a)
self.add_unk_id()
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : str = json.loads(self._tokenizer.to_str())
_lowerCAmelCase : Tuple = self.special_tokens["unk"]["id"]
_lowerCAmelCase : Any = Tokenizer.from_str(json.dumps(__a))
| 36
|
from __future__ import annotations
from math import pi
from typing import Protocol
import matplotlib.pyplot as plt
import numpy as np
class UpperCAmelCase_ ( a):
def snake_case__ ( self, __a):
'''simple docstring'''
return 0.0
def A ( _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : Optional[Any] = min([-20, np.min(fft_results[1 : samplerate // 2 - 1] )] )
_lowerCAmelCase : Optional[int] = max([20, np.max(fft_results[1 : samplerate // 2 - 1] )] )
return lowest, highest
def A ( _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : int = 512
_lowerCAmelCase : Union[str, Any] = [1] + [0] * (size - 1)
_lowerCAmelCase : Optional[Any] = [filter_type.process(_lowerCamelCase ) for item in inputs]
_lowerCAmelCase : int = [0] * (samplerate - size) # zero-padding
outputs += filler
_lowerCAmelCase : str = np.abs(np.fft.fft(_lowerCamelCase ) )
_lowerCAmelCase : Union[str, Any] = 20 * np.logaa(_lowerCamelCase )
# Frequencies on log scale from 24 to nyquist frequency
plt.xlim(24 , samplerate / 2 - 1 )
plt.xlabel("Frequency (Hz)" )
plt.xscale("log" )
# Display within reasonable bounds
_lowerCAmelCase : List[Any] = get_bounds(_lowerCamelCase , _lowerCamelCase )
plt.ylim(max([-80, bounds[0]] ) , min([80, bounds[1]] ) )
plt.ylabel("Gain (dB)" )
plt.plot(_lowerCamelCase )
plt.show()
def A ( _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : Union[str, Any] = 512
_lowerCAmelCase : Optional[Any] = [1] + [0] * (size - 1)
_lowerCAmelCase : str = [filter_type.process(_lowerCamelCase ) for item in inputs]
_lowerCAmelCase : Optional[Any] = [0] * (samplerate - size) # zero-padding
outputs += filler
_lowerCAmelCase : Optional[Any] = np.angle(np.fft.fft(_lowerCamelCase ) )
# Frequencies on log scale from 24 to nyquist frequency
plt.xlim(24 , samplerate / 2 - 1 )
plt.xlabel("Frequency (Hz)" )
plt.xscale("log" )
plt.ylim(-2 * pi , 2 * pi )
plt.ylabel("Phase shift (Radians)" )
plt.plot(np.unwrap(_lowerCamelCase , -2 * pi ) )
plt.show()
| 36
| 1
|
import os
import tempfile
import unittest
from transformers import FlaubertConfig, is_torch_available
from transformers.testing_utils import require_torch, require_torch_gpu, slow, torch_device
from ...test_configuration_common import ConfigTester
from ...test_modeling_common import ModelTesterMixin, ids_tensor, random_attention_mask
from ...test_pipeline_mixin import PipelineTesterMixin
if is_torch_available():
import torch
from transformers import (
FlaubertForMultipleChoice,
FlaubertForQuestionAnswering,
FlaubertForQuestionAnsweringSimple,
FlaubertForSequenceClassification,
FlaubertForTokenClassification,
FlaubertModel,
FlaubertWithLMHeadModel,
)
from transformers.models.flaubert.modeling_flaubert import FLAUBERT_PRETRAINED_MODEL_ARCHIVE_LIST
class UpperCAmelCase_ ( a):
def __init__( self, __a, __a=13, __a=7, __a=True, __a=True, __a=True, __a=True, __a=True, __a=False, __a=False, __a=False, __a=2, __a=99, __a=0, __a=32, __a=5, __a=4, __a=0.1, __a=0.1, __a=512, __a=12, __a=2, __a=0.02, __a=3, __a=4, __a="last", __a=None, __a=None, ):
'''simple docstring'''
_lowerCAmelCase : Dict = parent
_lowerCAmelCase : str = batch_size
_lowerCAmelCase : str = seq_length
_lowerCAmelCase : Any = is_training
_lowerCAmelCase : Union[str, Any] = use_input_lengths
_lowerCAmelCase : Optional[Any] = use_token_type_ids
_lowerCAmelCase : Dict = use_labels
_lowerCAmelCase : Optional[Any] = gelu_activation
_lowerCAmelCase : List[str] = sinusoidal_embeddings
_lowerCAmelCase : Dict = causal
_lowerCAmelCase : Union[str, Any] = asm
_lowerCAmelCase : str = n_langs
_lowerCAmelCase : Optional[Any] = vocab_size
_lowerCAmelCase : Optional[Any] = n_special
_lowerCAmelCase : int = hidden_size
_lowerCAmelCase : Optional[Any] = num_hidden_layers
_lowerCAmelCase : Dict = num_attention_heads
_lowerCAmelCase : Tuple = hidden_dropout_prob
_lowerCAmelCase : Optional[int] = attention_probs_dropout_prob
_lowerCAmelCase : Any = max_position_embeddings
_lowerCAmelCase : Union[str, Any] = type_vocab_size
_lowerCAmelCase : Any = type_sequence_label_size
_lowerCAmelCase : Dict = initializer_range
_lowerCAmelCase : List[Any] = num_labels
_lowerCAmelCase : Any = num_choices
_lowerCAmelCase : Tuple = summary_type
_lowerCAmelCase : Union[str, Any] = use_proj
_lowerCAmelCase : Tuple = scope
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : List[Any] = ids_tensor([self.batch_size, self.seq_length], self.vocab_size)
_lowerCAmelCase : int = random_attention_mask([self.batch_size, self.seq_length])
_lowerCAmelCase : str = None
if self.use_input_lengths:
_lowerCAmelCase : str = (
ids_tensor([self.batch_size], vocab_size=2) + self.seq_length - 2
) # small variation of seq_length
_lowerCAmelCase : Optional[Any] = None
if self.use_token_type_ids:
_lowerCAmelCase : str = ids_tensor([self.batch_size, self.seq_length], self.n_langs)
_lowerCAmelCase : Optional[int] = None
_lowerCAmelCase : Dict = None
_lowerCAmelCase : List[str] = None
if self.use_labels:
_lowerCAmelCase : List[str] = ids_tensor([self.batch_size], self.type_sequence_label_size)
_lowerCAmelCase : List[str] = ids_tensor([self.batch_size, self.seq_length], self.num_labels)
_lowerCAmelCase : Optional[Any] = ids_tensor([self.batch_size], 2).float()
_lowerCAmelCase : int = ids_tensor([self.batch_size], self.num_choices)
_lowerCAmelCase : Union[str, Any] = self.get_config()
return (
config,
input_ids,
token_type_ids,
input_lengths,
sequence_labels,
token_labels,
is_impossible_labels,
choice_labels,
input_mask,
)
def snake_case__ ( self):
'''simple docstring'''
return FlaubertConfig(
vocab_size=self.vocab_size, n_special=self.n_special, emb_dim=self.hidden_size, n_layers=self.num_hidden_layers, n_heads=self.num_attention_heads, dropout=self.hidden_dropout_prob, attention_dropout=self.attention_probs_dropout_prob, gelu_activation=self.gelu_activation, sinusoidal_embeddings=self.sinusoidal_embeddings, asm=self.asm, causal=self.causal, n_langs=self.n_langs, max_position_embeddings=self.max_position_embeddings, initializer_range=self.initializer_range, summary_type=self.summary_type, use_proj=self.use_proj, )
def snake_case__ ( self, __a, __a, __a, __a, __a, __a, __a, __a, __a, ):
'''simple docstring'''
_lowerCAmelCase : Optional[int] = FlaubertModel(config=__a)
model.to(__a)
model.eval()
_lowerCAmelCase : int = model(__a, lengths=__a, langs=__a)
_lowerCAmelCase : Optional[Any] = model(__a, langs=__a)
_lowerCAmelCase : List[str] = model(__a)
self.parent.assertEqual(result.last_hidden_state.shape, (self.batch_size, self.seq_length, self.hidden_size))
def snake_case__ ( self, __a, __a, __a, __a, __a, __a, __a, __a, __a, ):
'''simple docstring'''
_lowerCAmelCase : Optional[Any] = FlaubertWithLMHeadModel(__a)
model.to(__a)
model.eval()
_lowerCAmelCase : List[Any] = model(__a, token_type_ids=__a, labels=__a)
self.parent.assertEqual(result.loss.shape, ())
self.parent.assertEqual(result.logits.shape, (self.batch_size, self.seq_length, self.vocab_size))
def snake_case__ ( self, __a, __a, __a, __a, __a, __a, __a, __a, __a, ):
'''simple docstring'''
_lowerCAmelCase : Dict = FlaubertForQuestionAnsweringSimple(__a)
model.to(__a)
model.eval()
_lowerCAmelCase : Union[str, Any] = model(__a)
_lowerCAmelCase : List[str] = model(__a, start_positions=__a, end_positions=__a)
self.parent.assertEqual(result.start_logits.shape, (self.batch_size, self.seq_length))
self.parent.assertEqual(result.end_logits.shape, (self.batch_size, self.seq_length))
def snake_case__ ( self, __a, __a, __a, __a, __a, __a, __a, __a, __a, ):
'''simple docstring'''
_lowerCAmelCase : Optional[Any] = FlaubertForQuestionAnswering(__a)
model.to(__a)
model.eval()
_lowerCAmelCase : Any = model(__a)
_lowerCAmelCase : str = model(
__a, start_positions=__a, end_positions=__a, cls_index=__a, is_impossible=__a, p_mask=__a, )
_lowerCAmelCase : str = model(
__a, start_positions=__a, end_positions=__a, cls_index=__a, is_impossible=__a, )
((_lowerCAmelCase) , ) : List[Any] = result_with_labels.to_tuple()
_lowerCAmelCase : List[Any] = model(__a, start_positions=__a, end_positions=__a)
((_lowerCAmelCase) , ) : int = result_with_labels.to_tuple()
self.parent.assertEqual(result_with_labels.loss.shape, ())
self.parent.assertEqual(result.start_top_log_probs.shape, (self.batch_size, model.config.start_n_top))
self.parent.assertEqual(result.start_top_index.shape, (self.batch_size, model.config.start_n_top))
self.parent.assertEqual(
result.end_top_log_probs.shape, (self.batch_size, model.config.start_n_top * model.config.end_n_top))
self.parent.assertEqual(
result.end_top_index.shape, (self.batch_size, model.config.start_n_top * model.config.end_n_top))
self.parent.assertEqual(result.cls_logits.shape, (self.batch_size,))
def snake_case__ ( self, __a, __a, __a, __a, __a, __a, __a, __a, __a, ):
'''simple docstring'''
_lowerCAmelCase : int = FlaubertForSequenceClassification(__a)
model.to(__a)
model.eval()
_lowerCAmelCase : Optional[int] = model(__a)
_lowerCAmelCase : List[Any] = model(__a, labels=__a)
self.parent.assertEqual(result.loss.shape, ())
self.parent.assertEqual(result.logits.shape, (self.batch_size, self.type_sequence_label_size))
def snake_case__ ( self, __a, __a, __a, __a, __a, __a, __a, __a, __a, ):
'''simple docstring'''
_lowerCAmelCase : Dict = self.num_labels
_lowerCAmelCase : Any = FlaubertForTokenClassification(__a)
model.to(__a)
model.eval()
_lowerCAmelCase : Any = model(__a, attention_mask=__a, labels=__a)
self.parent.assertEqual(result.logits.shape, (self.batch_size, self.seq_length, self.num_labels))
def snake_case__ ( self, __a, __a, __a, __a, __a, __a, __a, __a, __a, ):
'''simple docstring'''
_lowerCAmelCase : Any = self.num_choices
_lowerCAmelCase : str = FlaubertForMultipleChoice(config=__a)
model.to(__a)
model.eval()
_lowerCAmelCase : Optional[int] = input_ids.unsqueeze(1).expand(-1, self.num_choices, -1).contiguous()
_lowerCAmelCase : Any = token_type_ids.unsqueeze(1).expand(-1, self.num_choices, -1).contiguous()
_lowerCAmelCase : Optional[Any] = input_mask.unsqueeze(1).expand(-1, self.num_choices, -1).contiguous()
_lowerCAmelCase : Tuple = model(
__a, attention_mask=__a, token_type_ids=__a, labels=__a, )
self.parent.assertEqual(result.logits.shape, (self.batch_size, self.num_choices))
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : List[Any] = self.prepare_config_and_inputs()
(
(
_lowerCAmelCase
) , (
_lowerCAmelCase
) , (
_lowerCAmelCase
) , (
_lowerCAmelCase
) , (
_lowerCAmelCase
) , (
_lowerCAmelCase
) , (
_lowerCAmelCase
) , (
_lowerCAmelCase
) , (
_lowerCAmelCase
) ,
) : Optional[int] = config_and_inputs
_lowerCAmelCase : str = {
"input_ids": input_ids,
"token_type_ids": token_type_ids,
"lengths": input_lengths,
"attention_mask": input_mask,
}
return config, inputs_dict
@require_torch
class UpperCAmelCase_ ( a , a , unittest.TestCase):
lowerCamelCase__ = (
(
FlaubertModel,
FlaubertWithLMHeadModel,
FlaubertForQuestionAnswering,
FlaubertForQuestionAnsweringSimple,
FlaubertForSequenceClassification,
FlaubertForTokenClassification,
FlaubertForMultipleChoice,
)
if is_torch_available()
else ()
)
lowerCamelCase__ = (
{
'feature-extraction': FlaubertModel,
'fill-mask': FlaubertWithLMHeadModel,
'question-answering': FlaubertForQuestionAnsweringSimple,
'text-classification': FlaubertForSequenceClassification,
'token-classification': FlaubertForTokenClassification,
'zero-shot': FlaubertForSequenceClassification,
}
if is_torch_available()
else {}
)
def snake_case__ ( self, __a, __a, __a, __a, __a):
'''simple docstring'''
if (
pipeline_test_casse_name == "QAPipelineTests"
and tokenizer_name is not None
and not tokenizer_name.endswith("Fast")
):
# `QAPipelineTests` fails for a few models when the slower tokenizer are used.
# (The slower tokenizers were never used for pipeline tests before the pipeline testing rework)
# TODO: check (and possibly fix) the `QAPipelineTests` with slower tokenizer
return True
return False
def snake_case__ ( self, __a, __a, __a=False):
'''simple docstring'''
_lowerCAmelCase : str = super()._prepare_for_class(__a, __a, return_labels=__a)
if return_labels:
if model_class.__name__ == "FlaubertForQuestionAnswering":
_lowerCAmelCase : List[str] = torch.zeros(
self.model_tester.batch_size, dtype=torch.long, device=__a)
_lowerCAmelCase : Optional[int] = torch.zeros(
self.model_tester.batch_size, dtype=torch.long, device=__a)
return inputs_dict
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Optional[int] = FlaubertModelTester(self)
_lowerCAmelCase : List[str] = ConfigTester(self, config_class=__a, emb_dim=37)
def snake_case__ ( self):
'''simple docstring'''
self.config_tester.run_common_tests()
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Dict = self.model_tester.prepare_config_and_inputs()
self.model_tester.create_and_check_flaubert_model(*__a)
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : int = self.model_tester.prepare_config_and_inputs()
self.model_tester.create_and_check_flaubert_lm_head(*__a)
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Optional[Any] = self.model_tester.prepare_config_and_inputs()
self.model_tester.create_and_check_flaubert_simple_qa(*__a)
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : str = self.model_tester.prepare_config_and_inputs()
self.model_tester.create_and_check_flaubert_qa(*__a)
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Dict = self.model_tester.prepare_config_and_inputs()
self.model_tester.create_and_check_flaubert_sequence_classif(*__a)
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : int = self.model_tester.prepare_config_and_inputs()
self.model_tester.create_and_check_flaubert_token_classif(*__a)
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Any = self.model_tester.prepare_config_and_inputs()
self.model_tester.create_and_check_flaubert_multiple_choice(*__a)
@slow
def snake_case__ ( self):
'''simple docstring'''
for model_name in FLAUBERT_PRETRAINED_MODEL_ARCHIVE_LIST[:1]:
_lowerCAmelCase : Tuple = FlaubertModel.from_pretrained(__a)
self.assertIsNotNone(__a)
@slow
@require_torch_gpu
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase , _lowerCAmelCase : Optional[Any] = self.model_tester.prepare_config_and_inputs_for_common()
for model_class in self.all_model_classes:
# FlauBertForMultipleChoice behaves incorrectly in JIT environments.
if model_class == FlaubertForMultipleChoice:
return
_lowerCAmelCase : Tuple = True
_lowerCAmelCase : List[Any] = model_class(config=__a)
_lowerCAmelCase : Dict = self._prepare_for_class(__a, __a)
_lowerCAmelCase : Any = torch.jit.trace(
__a, (inputs_dict["input_ids"].to("cpu"), inputs_dict["attention_mask"].to("cpu")))
with tempfile.TemporaryDirectory() as tmp:
torch.jit.save(__a, os.path.join(__a, "traced_model.pt"))
_lowerCAmelCase : int = torch.jit.load(os.path.join(__a, "traced_model.pt"), map_location=__a)
loaded(inputs_dict["input_ids"].to(__a), inputs_dict["attention_mask"].to(__a))
@require_torch
class UpperCAmelCase_ ( unittest.TestCase):
@slow
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Dict = FlaubertModel.from_pretrained("flaubert/flaubert_base_cased")
_lowerCAmelCase : List[str] = torch.tensor([[0, 345, 232, 328, 740, 140, 1695, 69, 6078, 1588, 2]])
with torch.no_grad():
_lowerCAmelCase : Optional[int] = model(__a)[0]
_lowerCAmelCase : Dict = torch.Size((1, 11, 768))
self.assertEqual(output.shape, __a)
_lowerCAmelCase : str = torch.tensor(
[[[-2.6_251, -1.4_298, -0.0_227], [-2.8_510, -1.6_387, 0.2_258], [-2.8_114, -1.1_832, -0.3_066]]])
self.assertTrue(torch.allclose(output[:, :3, :3], __a, atol=1E-4))
| 36
|
def A ( _lowerCamelCase ):
'''simple docstring'''
if bit_count < 0:
raise ValueError("The given input must be positive" )
# get the generated string sequence
_lowerCAmelCase : List[str] = gray_code_sequence_string(_lowerCamelCase )
#
# convert them to integers
for i in range(len(_lowerCamelCase ) ):
_lowerCAmelCase : List[str] = int(sequence[i] , 2 )
return sequence
def A ( _lowerCamelCase ):
'''simple docstring'''
if bit_count == 0:
return ["0"]
if bit_count == 1:
return ["0", "1"]
_lowerCAmelCase : List[Any] = 1 << bit_count # defines the length of the sequence
# 1<< n is equivalent to 2^n
# recursive answer will generate answer for n-1 bits
_lowerCAmelCase : Optional[int] = gray_code_sequence_string(bit_count - 1 )
_lowerCAmelCase : str = []
# append 0 to first half of the smaller sequence generated
for i in range(seq_len // 2 ):
_lowerCAmelCase : Dict = "0" + smaller_sequence[i]
sequence.append(_lowerCamelCase )
# append 1 to second half ... start from the end of the list
for i in reversed(range(seq_len // 2 ) ):
_lowerCAmelCase : Optional[Any] = "1" + smaller_sequence[i]
sequence.append(_lowerCamelCase )
return sequence
if __name__ == "__main__":
import doctest
doctest.testmod()
| 36
| 1
|
import requests
from bsa import BeautifulSoup
def A ( _lowerCamelCase = "AAPL" ):
'''simple docstring'''
_lowerCAmelCase : str = F"https://in.finance.yahoo.com/quote/{symbol}?s={symbol}"
_lowerCAmelCase : Optional[int] = BeautifulSoup(requests.get(_lowerCamelCase ).text , "html.parser" )
_lowerCAmelCase : List[Any] = "My(6px) Pos(r) smartphone_Mt(6px)"
return soup.find("div" , class_=class_ ).find("span" ).text
if __name__ == "__main__":
for symbol in "AAPL AMZN IBM GOOG MSFT ORCL".split():
print(f'''Current {symbol:<4} stock price is {stock_price(symbol):>8}''')
| 36
|
from PIL import Image
def A ( _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase , _lowerCAmelCase : int = image.size
_lowerCAmelCase : Any = 0
_lowerCAmelCase : Tuple = image.load()
for i in range(_lowerCamelCase ):
for j in range(_lowerCamelCase ):
_lowerCAmelCase : Union[str, Any] = pixels[j, i]
mean += pixel
mean //= width * height
for j in range(_lowerCamelCase ):
for i in range(_lowerCamelCase ):
_lowerCAmelCase : Optional[Any] = 255 if pixels[i, j] > mean else 0
return image
if __name__ == "__main__":
_snake_case = mean_threshold(Image.open("path_to_image").convert("L"))
image.save("output_image_path")
| 36
| 1
|
import unittest
from transformers import PegasusConfig, PegasusTokenizer, is_flax_available
from transformers.testing_utils import require_flax, slow
from ...test_configuration_common import ConfigTester
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
_snake_case = "platform"
import jax
import jax.numpy as jnp
import numpy as np
from transformers import FlaxPegasusForConditionalGeneration, FlaxPegasusModel
@require_flax
class UpperCAmelCase_ :
lowerCamelCase__ = PegasusConfig
lowerCamelCase__ = {}
lowerCamelCase__ = 'gelu'
def __init__( self, __a, __a=13, __a=7, __a=True, __a=False, __a=99, __a=32, __a=5, __a=4, __a=37, __a=0.1, __a=0.1, __a=20, __a=2, __a=1, __a=0, ):
'''simple docstring'''
_lowerCAmelCase : Optional[int] = parent
_lowerCAmelCase : int = batch_size
_lowerCAmelCase : int = seq_length
_lowerCAmelCase : Dict = is_training
_lowerCAmelCase : List[str] = use_labels
_lowerCAmelCase : int = vocab_size
_lowerCAmelCase : Tuple = hidden_size
_lowerCAmelCase : Dict = num_hidden_layers
_lowerCAmelCase : Dict = num_attention_heads
_lowerCAmelCase : int = intermediate_size
_lowerCAmelCase : str = hidden_dropout_prob
_lowerCAmelCase : List[Any] = attention_probs_dropout_prob
_lowerCAmelCase : Any = max_position_embeddings
_lowerCAmelCase : List[str] = eos_token_id
_lowerCAmelCase : Any = pad_token_id
_lowerCAmelCase : Optional[Any] = bos_token_id
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Optional[int] = ids_tensor([self.batch_size, self.seq_length - 1], self.vocab_size).clip(3, self.vocab_size)
_lowerCAmelCase : str = np.expand_dims(np.array([self.eos_token_id] * self.batch_size), 1)
_lowerCAmelCase : Optional[Any] = np.concatenate([input_ids, eos_tensor], axis=1)
_lowerCAmelCase : Dict = ids_tensor([self.batch_size, self.seq_length], self.vocab_size)
_lowerCAmelCase : str = self.config_cls(
vocab_size=self.vocab_size, d_model=self.hidden_size, encoder_layers=self.num_hidden_layers, decoder_layers=self.num_hidden_layers, encoder_attention_heads=self.num_attention_heads, decoder_attention_heads=self.num_attention_heads, encoder_ffn_dim=self.intermediate_size, decoder_ffn_dim=self.intermediate_size, dropout=self.hidden_dropout_prob, attention_dropout=self.attention_probs_dropout_prob, max_position_embeddings=self.max_position_embeddings, eos_token_ids=[2], bos_token_id=self.bos_token_id, pad_token_id=self.pad_token_id, decoder_start_token_id=self.pad_token_id, **self.config_updates, )
_lowerCAmelCase : int = prepare_pegasus_inputs_dict(__a, __a, __a)
return config, inputs_dict
def snake_case__ ( self, __a, __a, __a):
'''simple docstring'''
_lowerCAmelCase : List[Any] = 20
_lowerCAmelCase : str = model_class_name(__a)
_lowerCAmelCase : int = model.encode(inputs_dict["input_ids"])
_lowerCAmelCase , _lowerCAmelCase : List[Any] = (
inputs_dict["decoder_input_ids"],
inputs_dict["decoder_attention_mask"],
)
_lowerCAmelCase : Union[str, Any] = model.init_cache(decoder_input_ids.shape[0], __a, __a)
_lowerCAmelCase : List[Any] = jnp.ones((decoder_input_ids.shape[0], max_decoder_length), dtype="i4")
_lowerCAmelCase : Dict = jnp.broadcast_to(
jnp.arange(decoder_input_ids.shape[-1] - 1)[None, :], (decoder_input_ids.shape[0], decoder_input_ids.shape[-1] - 1), )
_lowerCAmelCase : Dict = model.decode(
decoder_input_ids[:, :-1], __a, decoder_attention_mask=__a, past_key_values=__a, decoder_position_ids=__a, )
_lowerCAmelCase : str = jnp.array(decoder_input_ids.shape[0] * [[decoder_input_ids.shape[-1] - 1]], dtype="i4")
_lowerCAmelCase : Any = model.decode(
decoder_input_ids[:, -1:], __a, decoder_attention_mask=__a, past_key_values=outputs_cache.past_key_values, decoder_position_ids=__a, )
_lowerCAmelCase : List[str] = model.decode(__a, __a)
_lowerCAmelCase : str = 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 snake_case__ ( self, __a, __a, __a):
'''simple docstring'''
_lowerCAmelCase : Dict = 20
_lowerCAmelCase : Any = model_class_name(__a)
_lowerCAmelCase : List[str] = model.encode(inputs_dict["input_ids"])
_lowerCAmelCase , _lowerCAmelCase : Optional[Any] = (
inputs_dict["decoder_input_ids"],
inputs_dict["decoder_attention_mask"],
)
_lowerCAmelCase : Optional[int] = jnp.concatenate(
[
decoder_attention_mask,
jnp.zeros((decoder_attention_mask.shape[0], max_decoder_length - decoder_attention_mask.shape[1])),
], axis=-1, )
_lowerCAmelCase : Tuple = model.init_cache(decoder_input_ids.shape[0], __a, __a)
_lowerCAmelCase : Union[str, Any] = jnp.broadcast_to(
jnp.arange(decoder_input_ids.shape[-1] - 1)[None, :], (decoder_input_ids.shape[0], decoder_input_ids.shape[-1] - 1), )
_lowerCAmelCase : Optional[int] = model.decode(
decoder_input_ids[:, :-1], __a, decoder_attention_mask=__a, past_key_values=__a, decoder_position_ids=__a, )
_lowerCAmelCase : str = jnp.array(decoder_input_ids.shape[0] * [[decoder_input_ids.shape[-1] - 1]], dtype="i4")
_lowerCAmelCase : 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, )
_lowerCAmelCase : Optional[int] = model.decode(__a, __a, decoder_attention_mask=__a)
_lowerCAmelCase : Union[str, Any] = 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 ( _lowerCamelCase , _lowerCamelCase , _lowerCamelCase , _lowerCamelCase=None , _lowerCamelCase=None , ):
'''simple docstring'''
if attention_mask is None:
_lowerCAmelCase : Tuple = np.not_equal(_lowerCamelCase , config.pad_token_id ).astype(np.inta )
if decoder_attention_mask is None:
_lowerCAmelCase : str = np.concatenate(
[
np.ones(decoder_input_ids[:, :1].shape , dtype=np.inta ),
np.not_equal(decoder_input_ids[:, 1:] , config.pad_token_id ).astype(np.inta ),
] , axis=-1 , )
return {
"input_ids": input_ids,
"decoder_input_ids": decoder_input_ids,
"attention_mask": attention_mask,
"decoder_attention_mask": decoder_attention_mask,
}
@require_flax
class UpperCAmelCase_ ( a , unittest.TestCase):
lowerCamelCase__ = (
(
FlaxPegasusForConditionalGeneration,
FlaxPegasusModel,
)
if is_flax_available()
else ()
)
lowerCamelCase__ = (FlaxPegasusForConditionalGeneration,) if is_flax_available() else ()
lowerCamelCase__ = True
lowerCamelCase__ = False
lowerCamelCase__ = False
lowerCamelCase__ = False
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : int = FlaxPegasusModelTester(self)
_lowerCAmelCase : int = ConfigTester(self, config_class=__a)
def snake_case__ ( self):
'''simple docstring'''
self.config_tester.run_common_tests()
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase , _lowerCAmelCase : Optional[Any] = self.model_tester.prepare_config_and_inputs_for_common()
for model_class in self.all_model_classes:
self.model_tester.check_use_cache_forward(__a, __a, __a)
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase , _lowerCAmelCase : int = self.model_tester.prepare_config_and_inputs_for_common()
for model_class in self.all_model_classes:
self.model_tester.check_use_cache_forward_with_attn_mask(__a, __a, __a)
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase , _lowerCAmelCase : Dict = self.model_tester.prepare_config_and_inputs_for_common()
for model_class in self.all_model_classes:
with self.subTest(model_class.__name__):
_lowerCAmelCase : Dict = self._prepare_for_class(__a, __a)
_lowerCAmelCase : Optional[int] = model_class(__a)
@jax.jit
def encode_jitted(__a, __a=None, **__a):
return model.encode(input_ids=__a, attention_mask=__a)
with self.subTest("JIT Enabled"):
_lowerCAmelCase : List[Any] = encode_jitted(**__a).to_tuple()
with self.subTest("JIT Disabled"):
with jax.disable_jit():
_lowerCAmelCase : 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 snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase , _lowerCAmelCase : Optional[int] = self.model_tester.prepare_config_and_inputs_for_common()
for model_class in self.all_model_classes:
with self.subTest(model_class.__name__):
_lowerCAmelCase : List[str] = model_class(__a)
_lowerCAmelCase : Optional[int] = model.encode(inputs_dict["input_ids"], inputs_dict["attention_mask"])
_lowerCAmelCase : 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, __a, __a):
return model.decode(
decoder_input_ids=__a, decoder_attention_mask=__a, encoder_outputs=__a, )
with self.subTest("JIT Enabled"):
_lowerCAmelCase : str = decode_jitted(**__a).to_tuple()
with self.subTest("JIT Disabled"):
with jax.disable_jit():
_lowerCAmelCase : str = 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 snake_case__ ( self):
'''simple docstring'''
for model_class_name in self.all_model_classes:
_lowerCAmelCase : Optional[int] = model_class_name.from_pretrained("google/pegasus-large", from_pt=__a)
_lowerCAmelCase : Dict = np.ones((1, 1))
_lowerCAmelCase : List[str] = model(__a)
self.assertIsNotNone(__a)
@slow
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : List[Any] = FlaxPegasusForConditionalGeneration.from_pretrained("google/pegasus-xsum")
_lowerCAmelCase : Any = PegasusTokenizer.from_pretrained("google/pegasus-xsum")
_lowerCAmelCase : Optional[int] = [
" PG&E stated it scheduled the blackouts in response to forecasts for high winds amid dry conditions. The aim is to reduce the risk of wildfires. Nearly 800 thousand customers were scheduled to be affected by the shutoffs which were expected to last through at least midday tomorrow.",
" The London trio are up for best UK act and best album, as well as getting two nominations in the best song category.\"We got told like this morning 'Oh I think you're nominated'\", said Dappy.\"And I was like 'Oh yeah, which one?' And now we've got nominated for four awards. I mean, wow!\"Bandmate Fazer added: \"We thought it's best of us to come down and mingle with everyone and say hello to the cameras. And now we find we've got four nominations.\"The band have two shots at the best song prize, getting the nod for their Tynchy Stryder collaboration Number One, and single Strong Again.Their album Uncle B will also go up against records by the likes of Beyonce and Kanye West.N-Dubz picked up the best newcomer Mobo in 2007, but female member Tulisa said they wouldn't be too disappointed if they didn't win this time around.\"At the end of the day we're grateful to be where we are in our careers.\"If it don't happen then it don't happen - live to fight another day and keep on making albums and hits for the fans.\"Dappy also revealed they could be performing live several times on the night.The group will be doing Number One and also a possible rendition of the War Child single, I Got Soul.The charity song is a re-working of The Killers' All These Things That I've Done and is set to feature artists like Chipmunk, Ironik and Pixie Lott.This year's Mobos will be held outside of London for the first time, in Glasgow on 30 September.N-Dubz said they were looking forward to performing for their Scottish fans and boasted about their recent shows north of the border.\"We just done Edinburgh the other day,\" said Dappy.\"We smashed up an N-Dubz show over there. We done Aberdeen about three or four months ago - we smashed up that show over there! Everywhere we go we smash it up!\" ",
]
_lowerCAmelCase : List[Any] = [
"California's largest electricity provider has turned off power to hundreds of thousands of customers.",
"Pop group N-Dubz have revealed they were surprised to get four nominations for this year's Mobo Awards.",
]
_lowerCAmelCase : int = tokenizer(__a, return_tensors="np", truncation=__a, max_length=512, padding=__a)
_lowerCAmelCase : Union[str, Any] = model.generate(**__a, num_beams=2).sequences
_lowerCAmelCase : Union[str, Any] = tokenizer.batch_decode(__a, skip_special_tokens=__a)
assert tgt_text == decoded
| 36
|
import functools
import operator
from ...configuration_utils import PretrainedConfig
from ...utils import logging
_snake_case = logging.get_logger(__name__)
_snake_case = {
"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 UpperCAmelCase_ ( a):
lowerCamelCase__ = 'wav2vec2'
def __init__( self, __a=32, __a=768, __a=12, __a=12, __a=3072, __a="gelu", __a=0.1, __a=0.1, __a=0.1, __a=0.0, __a=0.0, __a=0.1, __a=0.1, __a=0.02, __a=1E-5, __a="group", __a="gelu", __a=(512, 512, 512, 512, 512, 512, 512), __a=(5, 2, 2, 2, 2, 2, 2), __a=(10, 3, 3, 3, 3, 2, 2), __a=False, __a=128, __a=16, __a=False, __a=True, __a=0.05, __a=10, __a=2, __a=0.0, __a=10, __a=0, __a=320, __a=2, __a=0.1, __a=100, __a=256, __a=256, __a=0.1, __a="sum", __a=False, __a=False, __a=256, __a=(512, 512, 512, 512, 1500), __a=(5, 3, 3, 1, 1), __a=(1, 2, 3, 1, 1), __a=512, __a=0, __a=1, __a=2, __a=False, __a=3, __a=2, __a=3, __a=None, __a=None, **__a, ):
'''simple docstring'''
super().__init__(**__a, pad_token_id=__a, bos_token_id=__a, eos_token_id=__a)
_lowerCAmelCase : str = hidden_size
_lowerCAmelCase : Optional[int] = feat_extract_norm
_lowerCAmelCase : Union[str, Any] = feat_extract_activation
_lowerCAmelCase : Optional[Any] = list(__a)
_lowerCAmelCase : List[str] = list(__a)
_lowerCAmelCase : str = list(__a)
_lowerCAmelCase : List[str] = conv_bias
_lowerCAmelCase : str = num_conv_pos_embeddings
_lowerCAmelCase : List[Any] = num_conv_pos_embedding_groups
_lowerCAmelCase : str = len(self.conv_dim)
_lowerCAmelCase : List[str] = num_hidden_layers
_lowerCAmelCase : str = intermediate_size
_lowerCAmelCase : Any = hidden_act
_lowerCAmelCase : int = num_attention_heads
_lowerCAmelCase : Optional[Any] = hidden_dropout
_lowerCAmelCase : List[str] = attention_dropout
_lowerCAmelCase : Tuple = activation_dropout
_lowerCAmelCase : int = feat_proj_dropout
_lowerCAmelCase : List[str] = final_dropout
_lowerCAmelCase : int = layerdrop
_lowerCAmelCase : int = layer_norm_eps
_lowerCAmelCase : Union[str, Any] = initializer_range
_lowerCAmelCase : str = vocab_size
_lowerCAmelCase : Optional[Any] = do_stable_layer_norm
_lowerCAmelCase : 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
_lowerCAmelCase : str = apply_spec_augment
_lowerCAmelCase : Optional[Any] = mask_time_prob
_lowerCAmelCase : Optional[int] = mask_time_length
_lowerCAmelCase : List[str] = mask_time_min_masks
_lowerCAmelCase : Optional[int] = mask_feature_prob
_lowerCAmelCase : Optional[int] = mask_feature_length
_lowerCAmelCase : List[str] = mask_feature_min_masks
# parameters for pretraining with codevector quantized representations
_lowerCAmelCase : Union[str, Any] = num_codevectors_per_group
_lowerCAmelCase : str = num_codevector_groups
_lowerCAmelCase : Optional[int] = contrastive_logits_temperature
_lowerCAmelCase : Optional[int] = feat_quantizer_dropout
_lowerCAmelCase : Optional[int] = num_negatives
_lowerCAmelCase : Union[str, Any] = codevector_dim
_lowerCAmelCase : Any = proj_codevector_dim
_lowerCAmelCase : Optional[int] = diversity_loss_weight
# ctc loss
_lowerCAmelCase : Tuple = ctc_loss_reduction
_lowerCAmelCase : Tuple = ctc_zero_infinity
# adapter
_lowerCAmelCase : List[Any] = add_adapter
_lowerCAmelCase : List[str] = adapter_kernel_size
_lowerCAmelCase : str = adapter_stride
_lowerCAmelCase : List[str] = num_adapter_layers
_lowerCAmelCase : str = output_hidden_size or hidden_size
_lowerCAmelCase : Tuple = adapter_attn_dim
# SequenceClassification-specific parameter. Feel free to ignore for other classes.
_lowerCAmelCase : str = classifier_proj_size
# XVector-specific parameters. Feel free to ignore for other classes.
_lowerCAmelCase : str = list(__a)
_lowerCAmelCase : Union[str, Any] = list(__a)
_lowerCAmelCase : List[str] = list(__a)
_lowerCAmelCase : Tuple = xvector_output_dim
@property
def snake_case__ ( self):
'''simple docstring'''
return functools.reduce(operator.mul, self.conv_stride, 1)
| 36
| 1
|
import json
import os
import shutil
import tempfile
import unittest
import numpy as np
import pytest
from transformers import BertTokenizer, BertTokenizerFast
from transformers.models.bert.tokenization_bert import VOCAB_FILES_NAMES
from transformers.testing_utils import require_vision
from transformers.utils import FEATURE_EXTRACTOR_NAME, is_vision_available
if is_vision_available():
from PIL import Image
from transformers import ChineseCLIPImageProcessor, ChineseCLIPProcessor
@require_vision
class UpperCAmelCase_ ( unittest.TestCase):
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Dict = tempfile.mkdtemp()
_lowerCAmelCase : List[Any] = [
"[UNK]",
"[CLS]",
"[SEP]",
"[PAD]",
"[MASK]",
"的",
"价",
"格",
"是",
"15",
"便",
"alex",
"##andra",
",",
"。",
"-",
"t",
"shirt",
]
_lowerCAmelCase : Tuple = 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]))
_lowerCAmelCase : str = {
"do_resize": True,
"size": {"height": 224, "width": 224},
"do_center_crop": True,
"crop_size": {"height": 18, "width": 18},
"do_normalize": True,
"image_mean": [0.48_145_466, 0.4_578_275, 0.40_821_073],
"image_std": [0.26_862_954, 0.26_130_258, 0.27_577_711],
"do_convert_rgb": True,
}
_lowerCAmelCase : Union[str, Any] = os.path.join(self.tmpdirname, __a)
with open(self.image_processor_file, "w", encoding="utf-8") as fp:
json.dump(__a, __a)
def snake_case__ ( self, **__a):
'''simple docstring'''
return BertTokenizer.from_pretrained(self.tmpdirname, **__a)
def snake_case__ ( self, **__a):
'''simple docstring'''
return BertTokenizerFast.from_pretrained(self.tmpdirname, **__a)
def snake_case__ ( self, **__a):
'''simple docstring'''
return ChineseCLIPImageProcessor.from_pretrained(self.tmpdirname, **__a)
def snake_case__ ( self):
'''simple docstring'''
shutil.rmtree(self.tmpdirname)
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : str = [np.random.randint(255, size=(3, 30, 400), dtype=np.uinta)]
_lowerCAmelCase : Any = [Image.fromarray(np.moveaxis(__a, 0, -1)) for x in image_inputs]
return image_inputs
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : List[Any] = self.get_tokenizer()
_lowerCAmelCase : Dict = self.get_rust_tokenizer()
_lowerCAmelCase : Optional[int] = self.get_image_processor()
_lowerCAmelCase : Tuple = ChineseCLIPProcessor(tokenizer=__a, image_processor=__a)
processor_slow.save_pretrained(self.tmpdirname)
_lowerCAmelCase : Optional[Any] = ChineseCLIPProcessor.from_pretrained(self.tmpdirname, use_fast=__a)
_lowerCAmelCase : Tuple = ChineseCLIPProcessor(tokenizer=__a, image_processor=__a)
processor_fast.save_pretrained(self.tmpdirname)
_lowerCAmelCase : Tuple = ChineseCLIPProcessor.from_pretrained(self.tmpdirname)
self.assertEqual(processor_slow.tokenizer.get_vocab(), tokenizer_slow.get_vocab())
self.assertEqual(processor_fast.tokenizer.get_vocab(), tokenizer_fast.get_vocab())
self.assertEqual(tokenizer_slow.get_vocab(), tokenizer_fast.get_vocab())
self.assertIsInstance(processor_slow.tokenizer, __a)
self.assertIsInstance(processor_fast.tokenizer, __a)
self.assertEqual(processor_slow.image_processor.to_json_string(), image_processor.to_json_string())
self.assertEqual(processor_fast.image_processor.to_json_string(), image_processor.to_json_string())
self.assertIsInstance(processor_slow.image_processor, __a)
self.assertIsInstance(processor_fast.image_processor, __a)
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Union[str, Any] = ChineseCLIPProcessor(tokenizer=self.get_tokenizer(), image_processor=self.get_image_processor())
processor.save_pretrained(self.tmpdirname)
_lowerCAmelCase : int = self.get_tokenizer(cls_token="(CLS)", sep_token="(SEP)")
_lowerCAmelCase : Dict = self.get_image_processor(do_normalize=__a)
_lowerCAmelCase : Tuple = ChineseCLIPProcessor.from_pretrained(
self.tmpdirname, cls_token="(CLS)", sep_token="(SEP)", do_normalize=__a)
self.assertEqual(processor.tokenizer.get_vocab(), tokenizer_add_kwargs.get_vocab())
self.assertIsInstance(processor.tokenizer, __a)
self.assertEqual(processor.image_processor.to_json_string(), image_processor_add_kwargs.to_json_string())
self.assertIsInstance(processor.image_processor, __a)
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : List[str] = self.get_image_processor()
_lowerCAmelCase : List[Any] = self.get_tokenizer()
_lowerCAmelCase : List[Any] = ChineseCLIPProcessor(tokenizer=__a, image_processor=__a)
_lowerCAmelCase : List[str] = self.prepare_image_inputs()
_lowerCAmelCase : str = image_processor(__a, return_tensors="np")
_lowerCAmelCase : Union[str, Any] = 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 snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Dict = self.get_image_processor()
_lowerCAmelCase : int = self.get_tokenizer()
_lowerCAmelCase : Optional[int] = ChineseCLIPProcessor(tokenizer=__a, image_processor=__a)
_lowerCAmelCase : Optional[Any] = "Alexandra,T-shirt的价格是15便士。"
_lowerCAmelCase : Union[str, Any] = processor(text=__a)
_lowerCAmelCase : str = tokenizer(__a)
for key in encoded_tok.keys():
self.assertListEqual(encoded_tok[key], encoded_processor[key])
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : List[Any] = self.get_image_processor()
_lowerCAmelCase : int = self.get_tokenizer()
_lowerCAmelCase : Dict = ChineseCLIPProcessor(tokenizer=__a, image_processor=__a)
_lowerCAmelCase : int = "Alexandra,T-shirt的价格是15便士。"
_lowerCAmelCase : Any = self.prepare_image_inputs()
_lowerCAmelCase : Dict = 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 pytest.raises(__a):
processor()
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : int = self.get_image_processor()
_lowerCAmelCase : List[str] = self.get_tokenizer()
_lowerCAmelCase : Union[str, Any] = ChineseCLIPProcessor(tokenizer=__a, image_processor=__a)
_lowerCAmelCase : Tuple = [[1, 4, 5, 8, 1, 0, 8], [3, 4, 3, 1, 1, 8, 9]]
_lowerCAmelCase : Union[str, Any] = processor.batch_decode(__a)
_lowerCAmelCase : Tuple = tokenizer.batch_decode(__a)
self.assertListEqual(__a, __a)
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : List[Any] = self.get_image_processor()
_lowerCAmelCase : Dict = self.get_tokenizer()
_lowerCAmelCase : Dict = ChineseCLIPProcessor(tokenizer=__a, image_processor=__a)
_lowerCAmelCase : Any = "Alexandra,T-shirt的价格是15便士。"
_lowerCAmelCase : Optional[Any] = self.prepare_image_inputs()
_lowerCAmelCase : Any = processor(text=__a, images=__a)
self.assertListEqual(list(inputs.keys()), processor.model_input_names)
| 36
|
from __future__ import absolute_import, division, print_function, unicode_literals
from torch import nn
from torch.nn import CrossEntropyLoss, MSELoss
from transformers import RobertaConfig
from transformers.file_utils import add_start_docstrings, add_start_docstrings_to_model_forward
from transformers.models.roberta.modeling_roberta import (
ROBERTA_INPUTS_DOCSTRING,
ROBERTA_START_DOCSTRING,
RobertaEmbeddings,
)
from .modeling_highway_bert import BertPreTrainedModel, DeeBertModel, HighwayException, entropy
@add_start_docstrings(
'The RoBERTa Model transformer with early exiting (DeeRoBERTa). ' , a , )
class UpperCAmelCase_ ( a):
lowerCamelCase__ = RobertaConfig
lowerCamelCase__ = 'roberta'
def __init__( self, __a):
'''simple docstring'''
super().__init__(__a)
_lowerCAmelCase : Optional[Any] = RobertaEmbeddings(__a)
self.init_weights()
@add_start_docstrings(
'RoBERTa Model (with early exiting - DeeRoBERTa) with a classifier on top,\n also takes care of multi-layer training. ' , a , )
class UpperCAmelCase_ ( a):
lowerCamelCase__ = RobertaConfig
lowerCamelCase__ = 'roberta'
def __init__( self, __a):
'''simple docstring'''
super().__init__(__a)
_lowerCAmelCase : Optional[int] = config.num_labels
_lowerCAmelCase : Optional[int] = config.num_hidden_layers
_lowerCAmelCase : Optional[int] = DeeRobertaModel(__a)
_lowerCAmelCase : Union[str, Any] = nn.Dropout(config.hidden_dropout_prob)
_lowerCAmelCase : List[str] = nn.Linear(config.hidden_size, self.config.num_labels)
@add_start_docstrings_to_model_forward(__a)
def snake_case__ ( self, __a=None, __a=None, __a=None, __a=None, __a=None, __a=None, __a=None, __a=-1, __a=False, ):
'''simple docstring'''
_lowerCAmelCase : Union[str, Any] = self.num_layers
try:
_lowerCAmelCase : List[Any] = self.roberta(
__a, attention_mask=__a, token_type_ids=__a, position_ids=__a, head_mask=__a, inputs_embeds=__a, )
_lowerCAmelCase : List[Any] = outputs[1]
_lowerCAmelCase : Dict = self.dropout(__a)
_lowerCAmelCase : Dict = self.classifier(__a)
_lowerCAmelCase : Optional[Any] = (logits,) + outputs[2:] # add hidden states and attention if they are here
except HighwayException as e:
_lowerCAmelCase : Tuple = e.message
_lowerCAmelCase : Union[str, Any] = e.exit_layer
_lowerCAmelCase : List[Any] = outputs[0]
if not self.training:
_lowerCAmelCase : int = entropy(__a)
_lowerCAmelCase : List[Any] = []
_lowerCAmelCase : str = []
if labels is not None:
if self.num_labels == 1:
# We are doing regression
_lowerCAmelCase : Optional[Any] = MSELoss()
_lowerCAmelCase : int = loss_fct(logits.view(-1), labels.view(-1))
else:
_lowerCAmelCase : Optional[Any] = CrossEntropyLoss()
_lowerCAmelCase : Optional[Any] = loss_fct(logits.view(-1, self.num_labels), labels.view(-1))
# work with highway exits
_lowerCAmelCase : Optional[int] = []
for highway_exit in outputs[-1]:
_lowerCAmelCase : Any = highway_exit[0]
if not self.training:
highway_logits_all.append(__a)
highway_entropy.append(highway_exit[2])
if self.num_labels == 1:
# We are doing regression
_lowerCAmelCase : List[str] = MSELoss()
_lowerCAmelCase : List[Any] = loss_fct(highway_logits.view(-1), labels.view(-1))
else:
_lowerCAmelCase : Dict = CrossEntropyLoss()
_lowerCAmelCase : Optional[Any] = loss_fct(highway_logits.view(-1, self.num_labels), labels.view(-1))
highway_losses.append(__a)
if train_highway:
_lowerCAmelCase : int = (sum(highway_losses[:-1]),) + outputs
# exclude the final highway, of course
else:
_lowerCAmelCase : Any = (loss,) + outputs
if not self.training:
_lowerCAmelCase : Optional[Any] = outputs + ((original_entropy, highway_entropy), exit_layer)
if output_layer >= 0:
_lowerCAmelCase : Optional[Any] = (
(outputs[0],) + (highway_logits_all[output_layer],) + outputs[2:]
) # use the highway of the last layer
return outputs # (loss), logits, (hidden_states), (attentions), entropy
| 36
| 1
|
from __future__ import annotations
from decimal import Decimal
from math import * # noqa: F403
from sympy import diff
def A ( _lowerCamelCase , _lowerCamelCase , _lowerCamelCase = 10**-10 ):
'''simple docstring'''
_lowerCAmelCase : Dict = a
while True:
_lowerCAmelCase : List[Any] = Decimal(_lowerCamelCase ) - (
Decimal(eval(_lowerCamelCase ) ) / Decimal(eval(str(diff(_lowerCamelCase ) ) ) ) # noqa: S307
)
# This number dictates the accuracy of the answer
if abs(eval(_lowerCamelCase ) ) < precision: # noqa: S307
return float(_lowerCamelCase )
# Let's Execute
if __name__ == "__main__":
# Find root of trigonometric function
# Find value of pi
print(f'''The root of sin(x) = 0 is {newton_raphson("sin(x)", 2)}''')
# Find root of polynomial
print(f'''The root of x**2 - 5*x + 2 = 0 is {newton_raphson("x**2 - 5*x + 2", 0.4)}''')
# Find Square Root of 5
print(f'''The root of log(x) - 1 = 0 is {newton_raphson("log(x) - 1", 2)}''')
# Exponential Roots
print(f'''The root of exp(x) - 1 = 0 is {newton_raphson("exp(x) - 1", 0)}''')
| 36
|
import copy
from typing import TYPE_CHECKING, Any, Mapping, Optional, OrderedDict
from packaging import version
from ...configuration_utils import PretrainedConfig
from ...onnx import OnnxConfig
from ...utils import logging
from ..auto.configuration_auto import AutoConfig
if TYPE_CHECKING:
from ... import PreTrainedTokenizerBase, TensorType
_snake_case = logging.get_logger(__name__)
class UpperCAmelCase_ ( a):
lowerCamelCase__ = 'vision-encoder-decoder'
lowerCamelCase__ = True
def __init__( self, **__a):
'''simple docstring'''
super().__init__(**__a)
if "encoder" not in kwargs or "decoder" not in kwargs:
raise ValueError(
f"A configuraton of type {self.model_type} cannot be instantiated because "
f"not both `encoder` and `decoder` sub-configurations are passed, but only {kwargs}")
_lowerCAmelCase : str = kwargs.pop("encoder")
_lowerCAmelCase : Any = encoder_config.pop("model_type")
_lowerCAmelCase : str = kwargs.pop("decoder")
_lowerCAmelCase : List[str] = decoder_config.pop("model_type")
_lowerCAmelCase : Optional[Any] = AutoConfig.for_model(__a, **__a)
_lowerCAmelCase : Optional[Any] = AutoConfig.for_model(__a, **__a)
_lowerCAmelCase : Optional[int] = True
@classmethod
def snake_case__ ( cls, __a, __a, **__a):
'''simple docstring'''
logger.info("Setting `config.is_decoder=True` and `config.add_cross_attention=True` for decoder_config")
_lowerCAmelCase : Optional[Any] = True
_lowerCAmelCase : str = True
return cls(encoder=encoder_config.to_dict(), decoder=decoder_config.to_dict(), **__a)
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : int = copy.deepcopy(self.__dict__)
_lowerCAmelCase : List[str] = self.encoder.to_dict()
_lowerCAmelCase : List[str] = self.decoder.to_dict()
_lowerCAmelCase : Any = self.__class__.model_type
return output
class UpperCAmelCase_ ( a):
lowerCamelCase__ = version.parse('1.11')
@property
def snake_case__ ( self):
'''simple docstring'''
return OrderedDict(
[
("pixel_values", {0: "batch", 1: "num_channels", 2: "height", 3: "width"}),
])
@property
def snake_case__ ( self):
'''simple docstring'''
return 1E-4
@property
def snake_case__ ( self):
'''simple docstring'''
return OrderedDict({"last_hidden_state": {0: "batch", 1: "encoder_sequence"}})
class UpperCAmelCase_ ( a):
@property
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Optional[Any] = OrderedDict()
_lowerCAmelCase : Any = {0: "batch", 1: "past_decoder_sequence + sequence"}
_lowerCAmelCase : List[str] = {0: "batch", 1: "past_decoder_sequence + sequence"}
_lowerCAmelCase : Optional[Any] = {0: "batch", 1: "encoder_sequence"}
return common_inputs
def snake_case__ ( self, __a, __a = -1, __a = -1, __a = False, __a = None, ):
'''simple docstring'''
import torch
_lowerCAmelCase : Optional[Any] = OrderedDict()
_lowerCAmelCase : List[str] = super().generate_dummy_inputs(
__a, batch_size=__a, seq_length=__a, is_pair=__a, framework=__a)
_lowerCAmelCase , _lowerCAmelCase : Optional[Any] = dummy_input["input_ids"].shape
_lowerCAmelCase : str = (batch, encoder_sequence, self._config.encoder_hidden_size)
_lowerCAmelCase : List[str] = dummy_input.pop("input_ids")
_lowerCAmelCase : List[str] = dummy_input.pop("attention_mask")
_lowerCAmelCase : Optional[int] = torch.zeros(__a)
return common_inputs
class UpperCAmelCase_ ( a):
@property
def snake_case__ ( self):
'''simple docstring'''
pass
def snake_case__ ( self, __a):
'''simple docstring'''
return VisionEncoderDecoderEncoderOnnxConfig(__a)
def snake_case__ ( self, __a, __a, __a = "default"):
'''simple docstring'''
_lowerCAmelCase : Dict = encoder_config.hidden_size
return VisionEncoderDecoderDecoderOnnxConfig(__a, __a)
| 36
| 1
|
import math
import unittest
def A ( _lowerCamelCase ):
'''simple docstring'''
assert isinstance(_lowerCamelCase , _lowerCamelCase ) and (
number >= 0
), "'number' must been an int and positive"
if 1 < number < 4:
# 2 and 3 are primes
return True
elif number < 2 or number % 2 == 0 or number % 3 == 0:
# Negatives, 0, 1, all even numbers, all multiples of 3 are not primes
return False
# All primes number are in format of 6k +/- 1
for i in range(5 , int(math.sqrt(_lowerCamelCase ) + 1 ) , 6 ):
if number % i == 0 or number % (i + 2) == 0:
return False
return True
class UpperCAmelCase_ ( unittest.TestCase):
def snake_case__ ( self):
'''simple docstring'''
self.assertTrue(is_prime(2))
self.assertTrue(is_prime(3))
self.assertTrue(is_prime(5))
self.assertTrue(is_prime(7))
self.assertTrue(is_prime(11))
self.assertTrue(is_prime(13))
self.assertTrue(is_prime(17))
self.assertTrue(is_prime(19))
self.assertTrue(is_prime(23))
self.assertTrue(is_prime(29))
def snake_case__ ( self):
'''simple docstring'''
with self.assertRaises(__a):
is_prime(-19)
self.assertFalse(
is_prime(0), "Zero doesn't have any positive factors, primes must have exactly two.", )
self.assertFalse(
is_prime(1), "One only has 1 positive factor, primes must have exactly two.", )
self.assertFalse(is_prime(2 * 2))
self.assertFalse(is_prime(2 * 3))
self.assertFalse(is_prime(3 * 3))
self.assertFalse(is_prime(3 * 5))
self.assertFalse(is_prime(3 * 5 * 7))
if __name__ == "__main__":
unittest.main()
| 36
|
import inspect
import tempfile
from collections import OrderedDict, UserDict
from collections.abc import MutableMapping
from contextlib import ExitStack, contextmanager
from dataclasses import fields
from enum import Enum
from typing import Any, ContextManager, List, Tuple
import numpy as np
from .import_utils import is_flax_available, is_tf_available, is_torch_available, is_torch_fx_proxy
if is_flax_available():
import jax.numpy as jnp
class UpperCAmelCase_ ( a):
def __get__( self, __a, __a=None):
'''simple docstring'''
if obj is None:
return self
if self.fget is None:
raise AttributeError("unreadable attribute")
_lowerCAmelCase : List[Any] = "__cached_" + self.fget.__name__
_lowerCAmelCase : Dict = getattr(__a, __a, __a)
if cached is None:
_lowerCAmelCase : str = self.fget(__a)
setattr(__a, __a, __a)
return cached
def A ( _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : Any = val.lower()
if val in {"y", "yes", "t", "true", "on", "1"}:
return 1
if val in {"n", "no", "f", "false", "off", "0"}:
return 0
raise ValueError(F"invalid truth value {val!r}" )
def A ( _lowerCamelCase ):
'''simple docstring'''
if is_torch_fx_proxy(_lowerCamelCase ):
return True
if is_torch_available():
import torch
if isinstance(_lowerCamelCase , torch.Tensor ):
return True
if is_tf_available():
import tensorflow as tf
if isinstance(_lowerCamelCase , tf.Tensor ):
return True
if is_flax_available():
import jax.numpy as jnp
from jax.core import Tracer
if isinstance(_lowerCamelCase , (jnp.ndarray, Tracer) ):
return True
return isinstance(_lowerCamelCase , np.ndarray )
def A ( _lowerCamelCase ):
'''simple docstring'''
return isinstance(_lowerCamelCase , np.ndarray )
def A ( _lowerCamelCase ):
'''simple docstring'''
return _is_numpy(_lowerCamelCase )
def A ( _lowerCamelCase ):
'''simple docstring'''
import torch
return isinstance(_lowerCamelCase , torch.Tensor )
def A ( _lowerCamelCase ):
'''simple docstring'''
return False if not is_torch_available() else _is_torch(_lowerCamelCase )
def A ( _lowerCamelCase ):
'''simple docstring'''
import torch
return isinstance(_lowerCamelCase , torch.device )
def A ( _lowerCamelCase ):
'''simple docstring'''
return False if not is_torch_available() else _is_torch_device(_lowerCamelCase )
def A ( _lowerCamelCase ):
'''simple docstring'''
import torch
if isinstance(_lowerCamelCase , _lowerCamelCase ):
if hasattr(_lowerCamelCase , _lowerCamelCase ):
_lowerCAmelCase : Optional[Any] = getattr(_lowerCamelCase , _lowerCamelCase )
else:
return False
return isinstance(_lowerCamelCase , torch.dtype )
def A ( _lowerCamelCase ):
'''simple docstring'''
return False if not is_torch_available() else _is_torch_dtype(_lowerCamelCase )
def A ( _lowerCamelCase ):
'''simple docstring'''
import tensorflow as tf
return isinstance(_lowerCamelCase , tf.Tensor )
def A ( _lowerCamelCase ):
'''simple docstring'''
return False if not is_tf_available() else _is_tensorflow(_lowerCamelCase )
def A ( _lowerCamelCase ):
'''simple docstring'''
import tensorflow as tf
# the `is_symbolic_tensor` predicate is only available starting with TF 2.14
if hasattr(_lowerCamelCase , "is_symbolic_tensor" ):
return tf.is_symbolic_tensor(_lowerCamelCase )
return type(_lowerCamelCase ) == tf.Tensor
def A ( _lowerCamelCase ):
'''simple docstring'''
return False if not is_tf_available() else _is_tf_symbolic_tensor(_lowerCamelCase )
def A ( _lowerCamelCase ):
'''simple docstring'''
import jax.numpy as jnp # noqa: F811
return isinstance(_lowerCamelCase , jnp.ndarray )
def A ( _lowerCamelCase ):
'''simple docstring'''
return False if not is_flax_available() else _is_jax(_lowerCamelCase )
def A ( _lowerCamelCase ):
'''simple docstring'''
if isinstance(_lowerCamelCase , (dict, UserDict) ):
return {k: to_py_obj(_lowerCamelCase ) for k, v in obj.items()}
elif isinstance(_lowerCamelCase , (list, tuple) ):
return [to_py_obj(_lowerCamelCase ) for o in obj]
elif is_tf_tensor(_lowerCamelCase ):
return obj.numpy().tolist()
elif is_torch_tensor(_lowerCamelCase ):
return obj.detach().cpu().tolist()
elif is_jax_tensor(_lowerCamelCase ):
return np.asarray(_lowerCamelCase ).tolist()
elif isinstance(_lowerCamelCase , (np.ndarray, np.number) ): # tolist also works on 0d np arrays
return obj.tolist()
else:
return obj
def A ( _lowerCamelCase ):
'''simple docstring'''
if isinstance(_lowerCamelCase , (dict, UserDict) ):
return {k: to_numpy(_lowerCamelCase ) for k, v in obj.items()}
elif isinstance(_lowerCamelCase , (list, tuple) ):
return np.array(_lowerCamelCase )
elif is_tf_tensor(_lowerCamelCase ):
return obj.numpy()
elif is_torch_tensor(_lowerCamelCase ):
return obj.detach().cpu().numpy()
elif is_jax_tensor(_lowerCamelCase ):
return np.asarray(_lowerCamelCase )
else:
return obj
class UpperCAmelCase_ ( a):
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Tuple = fields(self)
# Safety and consistency checks
if not len(__a):
raise ValueError(f"{self.__class__.__name__} has no fields.")
if not all(field.default is None for field in class_fields[1:]):
raise ValueError(f"{self.__class__.__name__} should not have more than one required field.")
_lowerCAmelCase : Dict = getattr(self, class_fields[0].name)
_lowerCAmelCase : str = all(getattr(self, field.name) is None for field in class_fields[1:])
if other_fields_are_none and not is_tensor(__a):
if isinstance(__a, __a):
_lowerCAmelCase : Tuple = first_field.items()
_lowerCAmelCase : Dict = True
else:
try:
_lowerCAmelCase : Dict = iter(__a)
_lowerCAmelCase : Any = True
except TypeError:
_lowerCAmelCase : Any = False
# if we provided an iterator as first field and the iterator is a (key, value) iterator
# set the associated fields
if first_field_iterator:
for idx, element in enumerate(__a):
if (
not isinstance(__a, (list, tuple))
or not len(__a) == 2
or not isinstance(element[0], __a)
):
if idx == 0:
# If we do not have an iterator of key/values, set it as attribute
_lowerCAmelCase : Any = first_field
else:
# If we have a mixed iterator, raise an error
raise ValueError(
f"Cannot set key/value for {element}. It needs to be a tuple (key, value).")
break
setattr(self, element[0], element[1])
if element[1] is not None:
_lowerCAmelCase : Any = element[1]
elif first_field is not None:
_lowerCAmelCase : Any = first_field
else:
for field in class_fields:
_lowerCAmelCase : Dict = getattr(self, field.name)
if v is not None:
_lowerCAmelCase : Union[str, Any] = v
def __delitem__( self, *__a, **__a):
'''simple docstring'''
raise Exception(f"You cannot use ``__delitem__`` on a {self.__class__.__name__} instance.")
def snake_case__ ( self, *__a, **__a):
'''simple docstring'''
raise Exception(f"You cannot use ``setdefault`` on a {self.__class__.__name__} instance.")
def snake_case__ ( self, *__a, **__a):
'''simple docstring'''
raise Exception(f"You cannot use ``pop`` on a {self.__class__.__name__} instance.")
def snake_case__ ( self, *__a, **__a):
'''simple docstring'''
raise Exception(f"You cannot use ``update`` on a {self.__class__.__name__} instance.")
def __getitem__( self, __a):
'''simple docstring'''
if isinstance(__a, __a):
_lowerCAmelCase : Optional[int] = dict(self.items())
return inner_dict[k]
else:
return self.to_tuple()[k]
def __setattr__( self, __a, __a):
'''simple docstring'''
if name in self.keys() and value is not None:
# Don't call self.__setitem__ to avoid recursion errors
super().__setitem__(__a, __a)
super().__setattr__(__a, __a)
def __setitem__( self, __a, __a):
'''simple docstring'''
super().__setitem__(__a, __a)
# Don't call self.__setattr__ to avoid recursion errors
super().__setattr__(__a, __a)
def snake_case__ ( self):
'''simple docstring'''
return tuple(self[k] for k in self.keys())
class UpperCAmelCase_ ( a , a):
@classmethod
def snake_case__ ( cls, __a):
'''simple docstring'''
raise ValueError(
f"{value} is not a valid {cls.__name__}, please select one of {list(cls._valueamember_map_.keys())}")
class UpperCAmelCase_ ( a):
lowerCamelCase__ = 'longest'
lowerCamelCase__ = 'max_length'
lowerCamelCase__ = 'do_not_pad'
class UpperCAmelCase_ ( a):
lowerCamelCase__ = 'pt'
lowerCamelCase__ = 'tf'
lowerCamelCase__ = 'np'
lowerCamelCase__ = 'jax'
class UpperCAmelCase_ :
def __init__( self, __a):
'''simple docstring'''
_lowerCAmelCase : Tuple = context_managers
_lowerCAmelCase : Dict = ExitStack()
def __enter__( self):
'''simple docstring'''
for context_manager in self.context_managers:
self.stack.enter_context(__a)
def __exit__( self, *__a, **__a):
'''simple docstring'''
self.stack.__exit__(*__a, **__a)
def A ( _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : str = infer_framework(_lowerCamelCase )
if framework == "tf":
_lowerCAmelCase : Tuple = inspect.signature(model_class.call ) # TensorFlow models
elif framework == "pt":
_lowerCAmelCase : str = inspect.signature(model_class.forward ) # PyTorch models
else:
_lowerCAmelCase : Tuple = inspect.signature(model_class.__call__ ) # Flax models
for p in signature.parameters:
if p == "return_loss" and signature.parameters[p].default is True:
return True
return False
def A ( _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : str = model_class.__name__
_lowerCAmelCase : Optional[Any] = infer_framework(_lowerCamelCase )
if framework == "tf":
_lowerCAmelCase : Dict = inspect.signature(model_class.call ) # TensorFlow models
elif framework == "pt":
_lowerCAmelCase : List[Any] = inspect.signature(model_class.forward ) # PyTorch models
else:
_lowerCAmelCase : Dict = inspect.signature(model_class.__call__ ) # Flax models
if "QuestionAnswering" in model_name:
return [p for p in signature.parameters if "label" in p or p in ("start_positions", "end_positions")]
else:
return [p for p in signature.parameters if "label" in p]
def A ( _lowerCamelCase , _lowerCamelCase = "" , _lowerCamelCase = "." ):
'''simple docstring'''
def _flatten_dict(_lowerCamelCase , _lowerCamelCase="" , _lowerCamelCase="." ):
for k, v in d.items():
_lowerCAmelCase : Dict = str(_lowerCamelCase ) + delimiter + str(_lowerCamelCase ) if parent_key else k
if v and isinstance(_lowerCamelCase , _lowerCamelCase ):
yield from flatten_dict(_lowerCamelCase , _lowerCamelCase , delimiter=_lowerCamelCase ).items()
else:
yield key, v
return dict(_flatten_dict(_lowerCamelCase , _lowerCamelCase , _lowerCamelCase ) )
@contextmanager
def A ( _lowerCamelCase , _lowerCamelCase = False ):
'''simple docstring'''
if use_temp_dir:
with tempfile.TemporaryDirectory() as tmp_dir:
yield tmp_dir
else:
yield working_dir
def A ( _lowerCamelCase , _lowerCamelCase=None ):
'''simple docstring'''
if is_numpy_array(_lowerCamelCase ):
return np.transpose(_lowerCamelCase , axes=_lowerCamelCase )
elif is_torch_tensor(_lowerCamelCase ):
return array.T if axes is None else array.permute(*_lowerCamelCase )
elif is_tf_tensor(_lowerCamelCase ):
import tensorflow as tf
return tf.transpose(_lowerCamelCase , perm=_lowerCamelCase )
elif is_jax_tensor(_lowerCamelCase ):
return jnp.transpose(_lowerCamelCase , axes=_lowerCamelCase )
else:
raise ValueError(F"Type not supported for transpose: {type(_lowerCamelCase )}." )
def A ( _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
if is_numpy_array(_lowerCamelCase ):
return np.reshape(_lowerCamelCase , _lowerCamelCase )
elif is_torch_tensor(_lowerCamelCase ):
return array.reshape(*_lowerCamelCase )
elif is_tf_tensor(_lowerCamelCase ):
import tensorflow as tf
return tf.reshape(_lowerCamelCase , _lowerCamelCase )
elif is_jax_tensor(_lowerCamelCase ):
return jnp.reshape(_lowerCamelCase , _lowerCamelCase )
else:
raise ValueError(F"Type not supported for reshape: {type(_lowerCamelCase )}." )
def A ( _lowerCamelCase , _lowerCamelCase=None ):
'''simple docstring'''
if is_numpy_array(_lowerCamelCase ):
return np.squeeze(_lowerCamelCase , axis=_lowerCamelCase )
elif is_torch_tensor(_lowerCamelCase ):
return array.squeeze() if axis is None else array.squeeze(dim=_lowerCamelCase )
elif is_tf_tensor(_lowerCamelCase ):
import tensorflow as tf
return tf.squeeze(_lowerCamelCase , axis=_lowerCamelCase )
elif is_jax_tensor(_lowerCamelCase ):
return jnp.squeeze(_lowerCamelCase , axis=_lowerCamelCase )
else:
raise ValueError(F"Type not supported for squeeze: {type(_lowerCamelCase )}." )
def A ( _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
if is_numpy_array(_lowerCamelCase ):
return np.expand_dims(_lowerCamelCase , _lowerCamelCase )
elif is_torch_tensor(_lowerCamelCase ):
return array.unsqueeze(dim=_lowerCamelCase )
elif is_tf_tensor(_lowerCamelCase ):
import tensorflow as tf
return tf.expand_dims(_lowerCamelCase , axis=_lowerCamelCase )
elif is_jax_tensor(_lowerCamelCase ):
return jnp.expand_dims(_lowerCamelCase , axis=_lowerCamelCase )
else:
raise ValueError(F"Type not supported for expand_dims: {type(_lowerCamelCase )}." )
def A ( _lowerCamelCase ):
'''simple docstring'''
if is_numpy_array(_lowerCamelCase ):
return np.size(_lowerCamelCase )
elif is_torch_tensor(_lowerCamelCase ):
return array.numel()
elif is_tf_tensor(_lowerCamelCase ):
import tensorflow as tf
return tf.size(_lowerCamelCase )
elif is_jax_tensor(_lowerCamelCase ):
return array.size
else:
raise ValueError(F"Type not supported for expand_dims: {type(_lowerCamelCase )}." )
def A ( _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
for key, value in auto_map.items():
if isinstance(_lowerCamelCase , (tuple, list) ):
_lowerCAmelCase : List[Any] = [F"{repo_id}--{v}" if (v is not None and "--" not in v) else v for v in value]
elif value is not None and "--" not in value:
_lowerCAmelCase : Tuple = F"{repo_id}--{value}"
return auto_map
def A ( _lowerCamelCase ):
'''simple docstring'''
for base_class in inspect.getmro(_lowerCamelCase ):
_lowerCAmelCase : Tuple = base_class.__module__
_lowerCAmelCase : int = base_class.__name__
if module.startswith("tensorflow" ) or module.startswith("keras" ) or name == "TFPreTrainedModel":
return "tf"
elif module.startswith("torch" ) or name == "PreTrainedModel":
return "pt"
elif module.startswith("flax" ) or module.startswith("jax" ) or name == "FlaxPreTrainedModel":
return "flax"
else:
raise TypeError(F"Could not infer framework from class {model_class}." )
| 36
| 1
|
import darl # noqa
import gym
import tqdm
from diffusers.experimental import ValueGuidedRLPipeline
_snake_case = {
"n_samples": 64,
"horizon": 32,
"num_inference_steps": 20,
"n_guide_steps": 2, # can set to 0 for faster sampling, does not use value network
"scale_grad_by_std": True,
"scale": 0.1,
"eta": 0.0,
"t_grad_cutoff": 2,
"device": "cpu",
}
if __name__ == "__main__":
_snake_case = "hopper-medium-v2"
_snake_case = gym.make(env_name)
_snake_case = ValueGuidedRLPipeline.from_pretrained(
"bglick13/hopper-medium-v2-value-function-hor32",
env=env,
)
env.seed(0)
_snake_case = env.reset()
_snake_case = 0
_snake_case = 0
_snake_case = 1000
_snake_case = [obs.copy()]
try:
for t in tqdm.tqdm(range(T)):
# call the policy
_snake_case = pipeline(obs, planning_horizon=32)
# execute action in environment
_snake_case, _snake_case, _snake_case, _snake_case = env.step(denorm_actions)
_snake_case = env.get_normalized_score(total_reward)
# update return
total_reward += reward
total_score += score
print(
f'''Step: {t}, Reward: {reward}, Total Reward: {total_reward}, Score: {score}, Total Score:'''
f''' {total_score}'''
)
# save observations for rendering
rollout.append(next_observation.copy())
_snake_case = next_observation
except KeyboardInterrupt:
pass
print(f'''Total reward: {total_reward}''')
| 36
|
import pytest
from datasets.utils.sharding import _distribute_shards, _number_of_shards_in_gen_kwargs, _split_gen_kwargs
@pytest.mark.parametrize(
"kwargs, expected" , [
({"num_shards": 0, "max_num_jobs": 1}, []),
({"num_shards": 10, "max_num_jobs": 1}, [range(10 )]),
({"num_shards": 10, "max_num_jobs": 10}, [range(_lowerCamelCase , i + 1 ) for i in range(10 )]),
({"num_shards": 1, "max_num_jobs": 10}, [range(1 )]),
({"num_shards": 10, "max_num_jobs": 3}, [range(0 , 4 ), range(4 , 7 ), range(7 , 10 )]),
({"num_shards": 3, "max_num_jobs": 10}, [range(0 , 1 ), range(1 , 2 ), range(2 , 3 )]),
] , )
def A ( _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : List[Any] = _distribute_shards(**_lowerCamelCase )
assert out == expected
@pytest.mark.parametrize(
"gen_kwargs, max_num_jobs, expected" , [
({"foo": 0}, 10, [{"foo": 0}]),
({"shards": [0, 1, 2, 3]}, 1, [{"shards": [0, 1, 2, 3]}]),
({"shards": [0, 1, 2, 3]}, 4, [{"shards": [0]}, {"shards": [1]}, {"shards": [2]}, {"shards": [3]}]),
({"shards": [0, 1]}, 4, [{"shards": [0]}, {"shards": [1]}]),
({"shards": [0, 1, 2, 3]}, 2, [{"shards": [0, 1]}, {"shards": [2, 3]}]),
] , )
def A ( _lowerCamelCase , _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : Optional[int] = _split_gen_kwargs(_lowerCamelCase , _lowerCamelCase )
assert out == expected
@pytest.mark.parametrize(
"gen_kwargs, expected" , [
({"foo": 0}, 1),
({"shards": [0]}, 1),
({"shards": [0, 1, 2, 3]}, 4),
({"shards": [0, 1, 2, 3], "foo": 0}, 4),
({"shards": [0, 1, 2, 3], "other": (0, 1)}, 4),
({"shards": [0, 1, 2, 3], "shards2": [0, 1]}, RuntimeError),
] , )
def A ( _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
if expected is RuntimeError:
with pytest.raises(_lowerCamelCase ):
_number_of_shards_in_gen_kwargs(_lowerCamelCase )
else:
_lowerCAmelCase : Optional[int] = _number_of_shards_in_gen_kwargs(_lowerCamelCase )
assert out == expected
| 36
| 1
|
import sys
import tempfile
import unittest
import unittest.mock as mock
from pathlib import Path
from huggingface_hub import HfFolder, delete_repo
from requests.exceptions import HTTPError
from transformers import AutoImageProcessor, ViTImageProcessor
from transformers.testing_utils import TOKEN, USER, get_tests_dir, is_staging_test
sys.path.append(str(Path(__file__).parent.parent / "utils"))
from test_module.custom_image_processing import CustomImageProcessor # noqa E402
_snake_case = get_tests_dir("fixtures")
class UpperCAmelCase_ ( unittest.TestCase):
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Optional[Any] = mock.Mock()
_lowerCAmelCase : int = 500
_lowerCAmelCase : Tuple = {}
_lowerCAmelCase : str = HTTPError
_lowerCAmelCase : Union[str, Any] = {}
# Download this model to make sure it's in the cache.
_lowerCAmelCase : Tuple = ViTImageProcessor.from_pretrained("hf-internal-testing/tiny-random-vit")
# Under the mock environment we get a 500 error when trying to reach the model.
with mock.patch("requests.Session.request", return_value=__a) as mock_head:
_lowerCAmelCase : Optional[int] = ViTImageProcessor.from_pretrained("hf-internal-testing/tiny-random-vit")
# This check we did call the fake head request
mock_head.assert_called()
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Tuple = ViTImageProcessor.from_pretrained(
"https://huggingface.co/hf-internal-testing/tiny-random-vit/resolve/main/preprocessor_config.json")
def snake_case__ ( self):
'''simple docstring'''
with self.assertRaises(__a):
# config is in subfolder, the following should not work without specifying the subfolder
_lowerCAmelCase : int = AutoImageProcessor.from_pretrained("hf-internal-testing/stable-diffusion-all-variants")
_lowerCAmelCase : Optional[Any] = AutoImageProcessor.from_pretrained(
"hf-internal-testing/stable-diffusion-all-variants", subfolder="feature_extractor")
self.assertIsNotNone(__a)
@is_staging_test
class UpperCAmelCase_ ( unittest.TestCase):
@classmethod
def snake_case__ ( cls):
'''simple docstring'''
_lowerCAmelCase : Union[str, Any] = TOKEN
HfFolder.save_token(__a)
@classmethod
def snake_case__ ( cls):
'''simple docstring'''
try:
delete_repo(token=cls._token, repo_id="test-image-processor")
except HTTPError:
pass
try:
delete_repo(token=cls._token, repo_id="valid_org/test-image-processor-org")
except HTTPError:
pass
try:
delete_repo(token=cls._token, repo_id="test-dynamic-image-processor")
except HTTPError:
pass
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Optional[int] = ViTImageProcessor.from_pretrained(__a)
image_processor.push_to_hub("test-image-processor", use_auth_token=self._token)
_lowerCAmelCase : str = ViTImageProcessor.from_pretrained(f"{USER}/test-image-processor")
for k, v in image_processor.__dict__.items():
self.assertEqual(__a, getattr(__a, __a))
# Reset repo
delete_repo(token=self._token, repo_id="test-image-processor")
# Push to hub via save_pretrained
with tempfile.TemporaryDirectory() as tmp_dir:
image_processor.save_pretrained(
__a, repo_id="test-image-processor", push_to_hub=__a, use_auth_token=self._token)
_lowerCAmelCase : Optional[int] = ViTImageProcessor.from_pretrained(f"{USER}/test-image-processor")
for k, v in image_processor.__dict__.items():
self.assertEqual(__a, getattr(__a, __a))
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Any = ViTImageProcessor.from_pretrained(__a)
image_processor.push_to_hub("valid_org/test-image-processor", use_auth_token=self._token)
_lowerCAmelCase : Tuple = ViTImageProcessor.from_pretrained("valid_org/test-image-processor")
for k, v in image_processor.__dict__.items():
self.assertEqual(__a, getattr(__a, __a))
# Reset repo
delete_repo(token=self._token, repo_id="valid_org/test-image-processor")
# Push to hub via save_pretrained
with tempfile.TemporaryDirectory() as tmp_dir:
image_processor.save_pretrained(
__a, repo_id="valid_org/test-image-processor-org", push_to_hub=__a, use_auth_token=self._token)
_lowerCAmelCase : Optional[int] = ViTImageProcessor.from_pretrained("valid_org/test-image-processor-org")
for k, v in image_processor.__dict__.items():
self.assertEqual(__a, getattr(__a, __a))
def snake_case__ ( self):
'''simple docstring'''
CustomImageProcessor.register_for_auto_class()
_lowerCAmelCase : List[str] = CustomImageProcessor.from_pretrained(__a)
image_processor.push_to_hub("test-dynamic-image-processor", use_auth_token=self._token)
# This has added the proper auto_map field to the config
self.assertDictEqual(
image_processor.auto_map, {"AutoImageProcessor": "custom_image_processing.CustomImageProcessor"}, )
_lowerCAmelCase : Tuple = AutoImageProcessor.from_pretrained(
f"{USER}/test-dynamic-image-processor", trust_remote_code=__a)
# Can't make an isinstance check because the new_image_processor is from the CustomImageProcessor class of a dynamic module
self.assertEqual(new_image_processor.__class__.__name__, "CustomImageProcessor")
| 36
|
import os
from glob import glob
import imageio
import torch
import torchvision
import wandb
from img_processing import custom_to_pil, loop_post_process, preprocess, preprocess_vqgan
from loaders import load_vqgan
from PIL import Image
from torch import nn
from transformers import CLIPModel, CLIPTokenizerFast
from utils import get_device, get_timestamp, show_pil
class UpperCAmelCase_ :
def __init__( self, __a = "cpu", __a = "openai/clip-vit-large-patch14"):
'''simple docstring'''
_lowerCAmelCase : Optional[int] = device
_lowerCAmelCase : Optional[int] = CLIPTokenizerFast.from_pretrained(__a)
_lowerCAmelCase : Any = [0.48_145_466, 0.4_578_275, 0.40_821_073]
_lowerCAmelCase : Union[str, Any] = [0.26_862_954, 0.26_130_258, 0.27_577_711]
_lowerCAmelCase : Tuple = torchvision.transforms.Normalize(self.image_mean, self.image_std)
_lowerCAmelCase : Optional[int] = torchvision.transforms.Resize(224)
_lowerCAmelCase : Dict = torchvision.transforms.CenterCrop(224)
def snake_case__ ( self, __a):
'''simple docstring'''
_lowerCAmelCase : Optional[Any] = self.resize(__a)
_lowerCAmelCase : List[str] = self.center_crop(__a)
_lowerCAmelCase : Optional[Any] = self.normalize(__a)
return images
def __call__( self, __a=None, __a=None, **__a):
'''simple docstring'''
_lowerCAmelCase : str = self.tokenizer(text=__a, **__a)
_lowerCAmelCase : List[str] = self.preprocess_img(__a)
_lowerCAmelCase : Tuple = {key: value.to(self.device) for (key, value) in encoding.items()}
return encoding
class UpperCAmelCase_ ( nn.Module):
def __init__( self, __a=10, __a=0.01, __a=None, __a=None, __a=None, __a=None, __a=None, __a=None, __a=False, __a=True, __a="image", __a=True, __a=False, __a=False, __a=False, ):
'''simple docstring'''
super().__init__()
_lowerCAmelCase : List[str] = None
_lowerCAmelCase : List[str] = device if device else get_device()
if vqgan:
_lowerCAmelCase : Union[str, Any] = vqgan
else:
_lowerCAmelCase : Optional[Any] = load_vqgan(self.device, conf_path=__a, ckpt_path=__a)
self.vqgan.eval()
if clip:
_lowerCAmelCase : str = clip
else:
_lowerCAmelCase : int = CLIPModel.from_pretrained("openai/clip-vit-base-patch32")
self.clip.to(self.device)
_lowerCAmelCase : Optional[int] = ProcessorGradientFlow(device=self.device)
_lowerCAmelCase : Any = iterations
_lowerCAmelCase : List[Any] = lr
_lowerCAmelCase : Tuple = log
_lowerCAmelCase : List[str] = make_grid
_lowerCAmelCase : int = return_val
_lowerCAmelCase : Dict = quantize
_lowerCAmelCase : Any = self.vqgan.decoder.z_shape
def snake_case__ ( self, __a=None, __a=None, __a=5, __a=True):
'''simple docstring'''
_lowerCAmelCase : Union[str, Any] = []
if output_path is None:
_lowerCAmelCase : List[Any] = "./animation.gif"
if input_path is None:
_lowerCAmelCase : str = self.save_path
_lowerCAmelCase : str = sorted(glob(input_path + "/*"))
if not len(__a):
raise ValueError(
"No images found in save path, aborting (did you pass save_intermediate=True to the generate"
" function?)")
if len(__a) == 1:
print("Only one image found in save path, (did you pass save_intermediate=True to the generate function?)")
_lowerCAmelCase : Optional[int] = total_duration / len(__a)
_lowerCAmelCase : Union[str, Any] = [frame_duration] * len(__a)
if extend_frames:
_lowerCAmelCase : Any = 1.5
_lowerCAmelCase : List[str] = 3
for file_name in paths:
if file_name.endswith(".png"):
images.append(imageio.imread(__a))
imageio.mimsave(__a, __a, duration=__a)
print(f"gif saved to {output_path}")
def snake_case__ ( self, __a=None, __a=None):
'''simple docstring'''
if not (path or img):
raise ValueError("Input either path or tensor")
if img is not None:
raise NotImplementedError
_lowerCAmelCase : Dict = preprocess(Image.open(__a), target_image_size=256).to(self.device)
_lowerCAmelCase : Dict = preprocess_vqgan(__a)
_lowerCAmelCase , *_lowerCAmelCase : str = self.vqgan.encode(__a)
return z
def snake_case__ ( self, __a):
'''simple docstring'''
_lowerCAmelCase : Optional[Any] = self.latent.detach().requires_grad_()
_lowerCAmelCase : Dict = base_latent + transform_vector
if self.quantize:
_lowerCAmelCase , *_lowerCAmelCase : List[Any] = self.vqgan.quantize(__a)
else:
_lowerCAmelCase : Any = trans_latent
return self.vqgan.decode(__a)
def snake_case__ ( self, __a, __a, __a=None):
'''simple docstring'''
_lowerCAmelCase : int = self.clip_preprocessor(text=__a, images=__a, return_tensors="pt", padding=__a)
_lowerCAmelCase : Optional[int] = self.clip(**__a)
_lowerCAmelCase : Any = clip_outputs.logits_per_image
if weights is not None:
_lowerCAmelCase : Tuple = similarity_logits * weights
return similarity_logits.sum()
def snake_case__ ( self, __a, __a, __a):
'''simple docstring'''
_lowerCAmelCase : List[Any] = self._get_clip_similarity(pos_prompts["prompts"], __a, weights=(1 / pos_prompts["weights"]))
if neg_prompts:
_lowerCAmelCase : List[Any] = self._get_clip_similarity(neg_prompts["prompts"], __a, weights=neg_prompts["weights"])
else:
_lowerCAmelCase : Union[str, Any] = torch.tensor([1], device=self.device)
_lowerCAmelCase : List[str] = -torch.log(__a) + torch.log(__a)
return loss
def snake_case__ ( self, __a, __a, __a):
'''simple docstring'''
_lowerCAmelCase : Optional[Any] = torch.randn_like(self.latent, requires_grad=__a, device=self.device)
_lowerCAmelCase : Optional[int] = torch.optim.Adam([vector], lr=self.lr)
for i in range(self.iterations):
optim.zero_grad()
_lowerCAmelCase : Any = self._add_vector(__a)
_lowerCAmelCase : Optional[Any] = loop_post_process(__a)
_lowerCAmelCase : Optional[Any] = self._get_CLIP_loss(__a, __a, __a)
print("CLIP loss", __a)
if self.log:
wandb.log({"CLIP Loss": clip_loss})
clip_loss.backward(retain_graph=__a)
optim.step()
if self.return_val == "image":
yield custom_to_pil(transformed_img[0])
else:
yield vector
def snake_case__ ( self, __a, __a, __a):
'''simple docstring'''
wandb.init(reinit=__a, project="face-editor")
wandb.config.update({"Positive Prompts": positive_prompts})
wandb.config.update({"Negative Prompts": negative_prompts})
wandb.config.update({"lr": self.lr, "iterations": self.iterations})
if image_path:
_lowerCAmelCase : str = Image.open(__a)
_lowerCAmelCase : int = image.resize((256, 256))
wandb.log("Original Image", wandb.Image(__a))
def snake_case__ ( self, __a):
'''simple docstring'''
if not prompts:
return []
_lowerCAmelCase : int = []
_lowerCAmelCase : List[str] = []
if isinstance(__a, __a):
_lowerCAmelCase : Union[str, Any] = [prompt.strip() for prompt in prompts.split("|")]
for prompt in prompts:
if isinstance(__a, (tuple, list)):
_lowerCAmelCase : Optional[Any] = prompt[0]
_lowerCAmelCase : Union[str, Any] = float(prompt[1])
elif ":" in prompt:
_lowerCAmelCase , _lowerCAmelCase : int = prompt.split(":")
_lowerCAmelCase : Optional[Any] = float(__a)
else:
_lowerCAmelCase : Optional[int] = prompt
_lowerCAmelCase : List[Any] = 1.0
processed_prompts.append(__a)
weights.append(__a)
return {
"prompts": processed_prompts,
"weights": torch.tensor(__a, device=self.device),
}
def snake_case__ ( self, __a, __a=None, __a=None, __a=True, __a=False, __a=True, __a=True, __a=None, ):
'''simple docstring'''
if image_path:
_lowerCAmelCase : List[Any] = self._get_latent(__a)
else:
_lowerCAmelCase : Any = torch.randn(self.latent_dim, device=self.device)
if self.log:
self._init_logging(__a, __a, __a)
assert pos_prompts, "You must provide at least one positive prompt."
_lowerCAmelCase : int = self.process_prompts(__a)
_lowerCAmelCase : List[str] = self.process_prompts(__a)
if save_final and save_path is None:
_lowerCAmelCase : int = os.path.join("./outputs/", "_".join(pos_prompts["prompts"]))
if not os.path.exists(__a):
os.makedirs(__a)
else:
_lowerCAmelCase : Tuple = save_path + "_" + get_timestamp()
os.makedirs(__a)
_lowerCAmelCase : Tuple = save_path
_lowerCAmelCase : List[Any] = self.vqgan.decode(self.latent)[0]
if show_intermediate:
print("Original Image")
show_pil(custom_to_pil(__a))
_lowerCAmelCase : int = loop_post_process(__a)
for iter, transformed_img in enumerate(self._optimize_CLIP(__a, __a, __a)):
if show_intermediate:
show_pil(__a)
if save_intermediate:
transformed_img.save(os.path.join(self.save_path, f"iter_{iter:03d}.png"))
if self.log:
wandb.log({"Image": wandb.Image(__a)})
if show_final:
show_pil(__a)
if save_final:
transformed_img.save(os.path.join(self.save_path, f"iter_{iter:03d}_final.png"))
| 36
| 1
|
import absl # noqa: F401 # Here to have a nice missing dependency error message early on
import nltk # noqa: F401 # Here to have a nice missing dependency error message early on
import numpy # noqa: F401 # Here to have a nice missing dependency error message early on
import six # noqa: F401 # Here to have a nice missing dependency error message early on
from rouge_score import rouge_scorer, scoring
import datasets
_snake_case = "\\n@inproceedings{lin-2004-rouge,\n title = \"{ROUGE}: A Package for Automatic Evaluation of Summaries\",\n author = \"Lin, Chin-Yew\",\n booktitle = \"Text Summarization Branches Out\",\n month = jul,\n year = \"2004\",\n address = \"Barcelona, Spain\",\n publisher = \"Association for Computational Linguistics\",\n url = \"https://www.aclweb.org/anthology/W04-1013\",\n pages = \"74--81\",\n}\n"
_snake_case = "\\nROUGE, or Recall-Oriented Understudy for Gisting Evaluation, is a set of metrics and a software package used for\nevaluating automatic summarization and machine translation software in natural language processing.\nThe metrics compare an automatically produced summary or translation against a reference or a set of references (human-produced) summary or translation.\n\nNote that ROUGE is case insensitive, meaning that upper case letters are treated the same way as lower case letters.\n\nThis metrics is a wrapper around Google Research reimplementation of ROUGE:\nhttps://github.com/google-research/google-research/tree/master/rouge\n"
_snake_case = "\nCalculates average rouge scores for a list of hypotheses and references\nArgs:\n predictions: list of predictions to score. Each prediction\n should be a string with tokens separated by spaces.\n references: list of reference for each prediction. Each\n reference should be a string with tokens separated by spaces.\n rouge_types: A list of rouge types to calculate.\n Valid names:\n `\"rouge{n}\"` (e.g. `\"rouge1\"`, `\"rouge2\"`) where: {n} is the n-gram based scoring,\n `\"rougeL\"`: Longest common subsequence based scoring.\n `\"rougeLSum\"`: rougeLsum splits text using `\"\n\"`.\n See details in https://github.com/huggingface/datasets/issues/617\n use_stemmer: Bool indicating whether Porter stemmer should be used to strip word suffixes.\n use_aggregator: Return aggregates if this is set to True\nReturns:\n rouge1: rouge_1 (precision, recall, f1),\n rouge2: rouge_2 (precision, recall, f1),\n rougeL: rouge_l (precision, recall, f1),\n rougeLsum: rouge_lsum (precision, recall, f1)\nExamples:\n\n >>> rouge = datasets.load_metric('rouge')\n >>> predictions = [\"hello there\", \"general kenobi\"]\n >>> references = [\"hello there\", \"general kenobi\"]\n >>> results = rouge.compute(predictions=predictions, references=references)\n >>> print(list(results.keys()))\n ['rouge1', 'rouge2', 'rougeL', 'rougeLsum']\n >>> print(results[\"rouge1\"])\n AggregateScore(low=Score(precision=1.0, recall=1.0, fmeasure=1.0), mid=Score(precision=1.0, recall=1.0, fmeasure=1.0), high=Score(precision=1.0, recall=1.0, fmeasure=1.0))\n >>> print(results[\"rouge1\"].mid.fmeasure)\n 1.0\n"
@datasets.utils.file_utils.add_start_docstrings(_DESCRIPTION , _KWARGS_DESCRIPTION)
class UpperCAmelCase_ ( datasets.Metric):
def snake_case__ ( self):
'''simple docstring'''
return datasets.MetricInfo(
description=_DESCRIPTION, citation=_CITATION, inputs_description=_KWARGS_DESCRIPTION, features=datasets.Features(
{
"predictions": datasets.Value("string", id="sequence"),
"references": datasets.Value("string", id="sequence"),
}), codebase_urls=["https://github.com/google-research/google-research/tree/master/rouge"], reference_urls=[
"https://en.wikipedia.org/wiki/ROUGE_(metric)",
"https://github.com/google-research/google-research/tree/master/rouge",
], )
def snake_case__ ( self, __a, __a, __a=None, __a=True, __a=False):
'''simple docstring'''
if rouge_types is None:
_lowerCAmelCase : List[str] = ["rouge1", "rouge2", "rougeL", "rougeLsum"]
_lowerCAmelCase : Optional[int] = rouge_scorer.RougeScorer(rouge_types=__a, use_stemmer=__a)
if use_aggregator:
_lowerCAmelCase : Tuple = scoring.BootstrapAggregator()
else:
_lowerCAmelCase : Optional[Any] = []
for ref, pred in zip(__a, __a):
_lowerCAmelCase : int = scorer.score(__a, __a)
if use_aggregator:
aggregator.add_scores(__a)
else:
scores.append(__a)
if use_aggregator:
_lowerCAmelCase : int = aggregator.aggregate()
else:
_lowerCAmelCase : Optional[int] = {}
for key in scores[0]:
_lowerCAmelCase : Optional[int] = [score[key] for score in scores]
return result
| 36
|
import sys
import tempfile
import unittest
import unittest.mock as mock
from pathlib import Path
from huggingface_hub import HfFolder, delete_repo
from requests.exceptions import HTTPError
from transformers import AutoImageProcessor, ViTImageProcessor
from transformers.testing_utils import TOKEN, USER, get_tests_dir, is_staging_test
sys.path.append(str(Path(__file__).parent.parent / "utils"))
from test_module.custom_image_processing import CustomImageProcessor # noqa E402
_snake_case = get_tests_dir("fixtures")
class UpperCAmelCase_ ( unittest.TestCase):
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Optional[Any] = mock.Mock()
_lowerCAmelCase : int = 500
_lowerCAmelCase : Tuple = {}
_lowerCAmelCase : str = HTTPError
_lowerCAmelCase : Union[str, Any] = {}
# Download this model to make sure it's in the cache.
_lowerCAmelCase : Tuple = ViTImageProcessor.from_pretrained("hf-internal-testing/tiny-random-vit")
# Under the mock environment we get a 500 error when trying to reach the model.
with mock.patch("requests.Session.request", return_value=__a) as mock_head:
_lowerCAmelCase : Optional[int] = ViTImageProcessor.from_pretrained("hf-internal-testing/tiny-random-vit")
# This check we did call the fake head request
mock_head.assert_called()
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Tuple = ViTImageProcessor.from_pretrained(
"https://huggingface.co/hf-internal-testing/tiny-random-vit/resolve/main/preprocessor_config.json")
def snake_case__ ( self):
'''simple docstring'''
with self.assertRaises(__a):
# config is in subfolder, the following should not work without specifying the subfolder
_lowerCAmelCase : int = AutoImageProcessor.from_pretrained("hf-internal-testing/stable-diffusion-all-variants")
_lowerCAmelCase : Optional[Any] = AutoImageProcessor.from_pretrained(
"hf-internal-testing/stable-diffusion-all-variants", subfolder="feature_extractor")
self.assertIsNotNone(__a)
@is_staging_test
class UpperCAmelCase_ ( unittest.TestCase):
@classmethod
def snake_case__ ( cls):
'''simple docstring'''
_lowerCAmelCase : Union[str, Any] = TOKEN
HfFolder.save_token(__a)
@classmethod
def snake_case__ ( cls):
'''simple docstring'''
try:
delete_repo(token=cls._token, repo_id="test-image-processor")
except HTTPError:
pass
try:
delete_repo(token=cls._token, repo_id="valid_org/test-image-processor-org")
except HTTPError:
pass
try:
delete_repo(token=cls._token, repo_id="test-dynamic-image-processor")
except HTTPError:
pass
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Optional[int] = ViTImageProcessor.from_pretrained(__a)
image_processor.push_to_hub("test-image-processor", use_auth_token=self._token)
_lowerCAmelCase : str = ViTImageProcessor.from_pretrained(f"{USER}/test-image-processor")
for k, v in image_processor.__dict__.items():
self.assertEqual(__a, getattr(__a, __a))
# Reset repo
delete_repo(token=self._token, repo_id="test-image-processor")
# Push to hub via save_pretrained
with tempfile.TemporaryDirectory() as tmp_dir:
image_processor.save_pretrained(
__a, repo_id="test-image-processor", push_to_hub=__a, use_auth_token=self._token)
_lowerCAmelCase : Optional[int] = ViTImageProcessor.from_pretrained(f"{USER}/test-image-processor")
for k, v in image_processor.__dict__.items():
self.assertEqual(__a, getattr(__a, __a))
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Any = ViTImageProcessor.from_pretrained(__a)
image_processor.push_to_hub("valid_org/test-image-processor", use_auth_token=self._token)
_lowerCAmelCase : Tuple = ViTImageProcessor.from_pretrained("valid_org/test-image-processor")
for k, v in image_processor.__dict__.items():
self.assertEqual(__a, getattr(__a, __a))
# Reset repo
delete_repo(token=self._token, repo_id="valid_org/test-image-processor")
# Push to hub via save_pretrained
with tempfile.TemporaryDirectory() as tmp_dir:
image_processor.save_pretrained(
__a, repo_id="valid_org/test-image-processor-org", push_to_hub=__a, use_auth_token=self._token)
_lowerCAmelCase : Optional[int] = ViTImageProcessor.from_pretrained("valid_org/test-image-processor-org")
for k, v in image_processor.__dict__.items():
self.assertEqual(__a, getattr(__a, __a))
def snake_case__ ( self):
'''simple docstring'''
CustomImageProcessor.register_for_auto_class()
_lowerCAmelCase : List[str] = CustomImageProcessor.from_pretrained(__a)
image_processor.push_to_hub("test-dynamic-image-processor", use_auth_token=self._token)
# This has added the proper auto_map field to the config
self.assertDictEqual(
image_processor.auto_map, {"AutoImageProcessor": "custom_image_processing.CustomImageProcessor"}, )
_lowerCAmelCase : Tuple = AutoImageProcessor.from_pretrained(
f"{USER}/test-dynamic-image-processor", trust_remote_code=__a)
# Can't make an isinstance check because the new_image_processor is from the CustomImageProcessor class of a dynamic module
self.assertEqual(new_image_processor.__class__.__name__, "CustomImageProcessor")
| 36
| 1
|
from __future__ import annotations
import requests
_snake_case = set(
"approved_at_utc approved_by author_flair_background_color\nauthor_flair_css_class author_flair_richtext author_flair_template_id author_fullname\nauthor_premium can_mod_post category clicked content_categories created_utc downs\nedited gilded gildings hidden hide_score is_created_from_ads_ui is_meta\nis_original_content is_reddit_media_domain is_video link_flair_css_class\nlink_flair_richtext link_flair_text link_flair_text_color media_embed mod_reason_title\nname permalink pwls quarantine saved score secure_media secure_media_embed selftext\nsubreddit subreddit_name_prefixed subreddit_type thumbnail title top_awarded_type\ntotal_awards_received ups upvote_ratio url user_reports".split()
)
def A ( _lowerCamelCase , _lowerCamelCase = 1 , _lowerCamelCase = "new" , _lowerCamelCase = None ):
'''simple docstring'''
_lowerCAmelCase : Optional[int] = wanted_data or []
if invalid_search_terms := ", ".join(sorted(set(_lowerCamelCase ) - valid_terms ) ):
_lowerCAmelCase : int = F"Invalid search term: {invalid_search_terms}"
raise ValueError(_lowerCamelCase )
_lowerCAmelCase : Optional[int] = requests.get(
F"https://reddit.com/r/{subreddit}/{age}.json?limit={limit}" , headers={"User-agent": "A random string"} , )
if response.status_code == 429:
raise requests.HTTPError
_lowerCAmelCase : List[str] = response.json()
if not wanted_data:
return {id_: data["data"]["children"][id_] for id_ in range(_lowerCamelCase )}
_lowerCAmelCase : str = {}
for id_ in range(_lowerCamelCase ):
_lowerCAmelCase : Optional[int] = {
item: data["data"]["children"][id_]["data"][item] for item in wanted_data
}
return data_dict
if __name__ == "__main__":
# If you get Error 429, that means you are rate limited.Try after some time
print(get_subreddit_data("learnpython", wanted_data=["title", "url", "selftext"]))
| 36
|
import unittest
from transformers import LiltConfig, is_torch_available
from transformers.testing_utils import require_torch, slow, torch_device
from ...generation.test_utils import GenerationTesterMixin
from ...test_configuration_common import ConfigTester
from ...test_modeling_common import ModelTesterMixin, ids_tensor
from ...test_pipeline_mixin import PipelineTesterMixin
if is_torch_available():
import torch
from transformers import (
LiltForQuestionAnswering,
LiltForSequenceClassification,
LiltForTokenClassification,
LiltModel,
)
from transformers.models.lilt.modeling_lilt import LILT_PRETRAINED_MODEL_ARCHIVE_LIST
class UpperCAmelCase_ :
def __init__( self, __a, __a=13, __a=7, __a=True, __a=True, __a=True, __a=True, __a=99, __a=24, __a=2, __a=6, __a=37, __a="gelu", __a=0.1, __a=0.1, __a=512, __a=16, __a=2, __a=0.02, __a=3, __a=None, __a=1000, ):
'''simple docstring'''
_lowerCAmelCase : Tuple = parent
_lowerCAmelCase : List[str] = batch_size
_lowerCAmelCase : int = seq_length
_lowerCAmelCase : Optional[int] = is_training
_lowerCAmelCase : Dict = use_input_mask
_lowerCAmelCase : List[str] = use_token_type_ids
_lowerCAmelCase : str = use_labels
_lowerCAmelCase : Optional[Any] = vocab_size
_lowerCAmelCase : Tuple = hidden_size
_lowerCAmelCase : List[Any] = num_hidden_layers
_lowerCAmelCase : Optional[Any] = num_attention_heads
_lowerCAmelCase : Any = intermediate_size
_lowerCAmelCase : List[str] = hidden_act
_lowerCAmelCase : Union[str, Any] = hidden_dropout_prob
_lowerCAmelCase : Any = attention_probs_dropout_prob
_lowerCAmelCase : int = max_position_embeddings
_lowerCAmelCase : Optional[int] = type_vocab_size
_lowerCAmelCase : Optional[Any] = type_sequence_label_size
_lowerCAmelCase : List[str] = initializer_range
_lowerCAmelCase : List[Any] = num_labels
_lowerCAmelCase : Tuple = scope
_lowerCAmelCase : str = range_bbox
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Dict = ids_tensor([self.batch_size, self.seq_length], self.vocab_size)
_lowerCAmelCase : int = ids_tensor([self.batch_size, self.seq_length, 4], self.range_bbox)
# Ensure that bbox is legal
for i in range(bbox.shape[0]):
for j in range(bbox.shape[1]):
if bbox[i, j, 3] < bbox[i, j, 1]:
_lowerCAmelCase : Dict = bbox[i, j, 3]
_lowerCAmelCase : int = bbox[i, j, 1]
_lowerCAmelCase : Tuple = t
if bbox[i, j, 2] < bbox[i, j, 0]:
_lowerCAmelCase : str = bbox[i, j, 2]
_lowerCAmelCase : List[Any] = bbox[i, j, 0]
_lowerCAmelCase : str = t
_lowerCAmelCase : Optional[Any] = None
if self.use_input_mask:
_lowerCAmelCase : Union[str, Any] = ids_tensor([self.batch_size, self.seq_length], vocab_size=2)
_lowerCAmelCase : Dict = None
if self.use_token_type_ids:
_lowerCAmelCase : Any = ids_tensor([self.batch_size, self.seq_length], self.type_vocab_size)
_lowerCAmelCase : Optional[int] = None
_lowerCAmelCase : Optional[Any] = None
if self.use_labels:
_lowerCAmelCase : Optional[Any] = ids_tensor([self.batch_size], self.type_sequence_label_size)
_lowerCAmelCase : Any = ids_tensor([self.batch_size, self.seq_length], self.num_labels)
_lowerCAmelCase : Optional[int] = self.get_config()
return config, input_ids, bbox, token_type_ids, input_mask, sequence_labels, token_labels
def snake_case__ ( self):
'''simple docstring'''
return LiltConfig(
vocab_size=self.vocab_size, hidden_size=self.hidden_size, num_hidden_layers=self.num_hidden_layers, num_attention_heads=self.num_attention_heads, intermediate_size=self.intermediate_size, hidden_act=self.hidden_act, hidden_dropout_prob=self.hidden_dropout_prob, attention_probs_dropout_prob=self.attention_probs_dropout_prob, max_position_embeddings=self.max_position_embeddings, type_vocab_size=self.type_vocab_size, initializer_range=self.initializer_range, )
def snake_case__ ( self, __a, __a, __a, __a, __a, __a, __a, ):
'''simple docstring'''
_lowerCAmelCase : Union[str, Any] = LiltModel(config=__a)
model.to(__a)
model.eval()
_lowerCAmelCase : Dict = model(__a, bbox=__a, attention_mask=__a, token_type_ids=__a)
_lowerCAmelCase : str = model(__a, bbox=__a, token_type_ids=__a)
_lowerCAmelCase : List[Any] = model(__a, bbox=__a)
self.parent.assertEqual(result.last_hidden_state.shape, (self.batch_size, self.seq_length, self.hidden_size))
self.parent.assertEqual(result.pooler_output.shape, (self.batch_size, self.hidden_size))
def snake_case__ ( self, __a, __a, __a, __a, __a, __a, __a, ):
'''simple docstring'''
_lowerCAmelCase : List[Any] = self.num_labels
_lowerCAmelCase : Optional[Any] = LiltForTokenClassification(config=__a)
model.to(__a)
model.eval()
_lowerCAmelCase : Dict = model(
__a, bbox=__a, attention_mask=__a, token_type_ids=__a, labels=__a)
self.parent.assertEqual(result.logits.shape, (self.batch_size, self.seq_length, self.num_labels))
def snake_case__ ( self, __a, __a, __a, __a, __a, __a, __a, ):
'''simple docstring'''
_lowerCAmelCase : Optional[int] = LiltForQuestionAnswering(config=__a)
model.to(__a)
model.eval()
_lowerCAmelCase : Tuple = model(
__a, bbox=__a, attention_mask=__a, token_type_ids=__a, start_positions=__a, end_positions=__a, )
self.parent.assertEqual(result.start_logits.shape, (self.batch_size, self.seq_length))
self.parent.assertEqual(result.end_logits.shape, (self.batch_size, self.seq_length))
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Optional[Any] = self.prepare_config_and_inputs()
(
(
_lowerCAmelCase
) , (
_lowerCAmelCase
) , (
_lowerCAmelCase
) , (
_lowerCAmelCase
) , (
_lowerCAmelCase
) , (
_lowerCAmelCase
) , (
_lowerCAmelCase
) ,
) : Dict = config_and_inputs
_lowerCAmelCase : List[Any] = {
"input_ids": input_ids,
"bbox": bbox,
"token_type_ids": token_type_ids,
"attention_mask": input_mask,
}
return config, inputs_dict
@require_torch
class UpperCAmelCase_ ( a , a , a , unittest.TestCase):
lowerCamelCase__ = (
(
LiltModel,
LiltForSequenceClassification,
LiltForTokenClassification,
LiltForQuestionAnswering,
)
if is_torch_available()
else ()
)
lowerCamelCase__ = (
{
'feature-extraction': LiltModel,
'question-answering': LiltForQuestionAnswering,
'text-classification': LiltForSequenceClassification,
'token-classification': LiltForTokenClassification,
'zero-shot': LiltForSequenceClassification,
}
if is_torch_available()
else {}
)
lowerCamelCase__ = False
lowerCamelCase__ = False
def snake_case__ ( self, __a, __a, __a, __a, __a):
'''simple docstring'''
return True
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Optional[Any] = LiltModelTester(self)
_lowerCAmelCase : Union[str, Any] = ConfigTester(self, config_class=__a, hidden_size=37)
def snake_case__ ( self):
'''simple docstring'''
self.config_tester.run_common_tests()
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Dict = self.model_tester.prepare_config_and_inputs()
self.model_tester.create_and_check_model(*__a)
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : int = self.model_tester.prepare_config_and_inputs()
for type in ["absolute", "relative_key", "relative_key_query"]:
_lowerCAmelCase : Any = type
self.model_tester.create_and_check_model(*__a)
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : int = self.model_tester.prepare_config_and_inputs()
self.model_tester.create_and_check_for_token_classification(*__a)
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Optional[int] = self.model_tester.prepare_config_and_inputs()
self.model_tester.create_and_check_for_question_answering(*__a)
@slow
def snake_case__ ( self):
'''simple docstring'''
for model_name in LILT_PRETRAINED_MODEL_ARCHIVE_LIST[:1]:
_lowerCAmelCase : str = LiltModel.from_pretrained(__a)
self.assertIsNotNone(__a)
@require_torch
@slow
class UpperCAmelCase_ ( unittest.TestCase):
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Dict = LiltModel.from_pretrained("SCUT-DLVCLab/lilt-roberta-en-base").to(__a)
_lowerCAmelCase : Any = torch.tensor([[1, 2]], device=__a)
_lowerCAmelCase : str = torch.tensor([[[1, 2, 3, 4], [5, 6, 7, 8]]], device=__a)
# forward pass
with torch.no_grad():
_lowerCAmelCase : Optional[Any] = model(input_ids=__a, bbox=__a)
_lowerCAmelCase : Optional[int] = torch.Size([1, 2, 768])
_lowerCAmelCase : List[str] = torch.tensor(
[[-0.0_653, 0.0_950, -0.0_061], [-0.0_545, 0.0_926, -0.0_324]], device=__a, )
self.assertTrue(outputs.last_hidden_state.shape, __a)
self.assertTrue(torch.allclose(outputs.last_hidden_state[0, :, :3], __a, atol=1E-3))
| 36
| 1
|
import argparse
import os
import re
# All paths are set with the intent you should run this script from the root of the repo with the command
# python utils/check_dummies.py
_snake_case = "src/diffusers"
# Matches is_xxx_available()
_snake_case = re.compile(R"is\_([a-z_]*)_available\(\)")
# Matches from xxx import bla
_snake_case = re.compile(R"\s+from\s+\S*\s+import\s+([^\(\s].*)\n")
_snake_case = "\n{0} = None\n"
_snake_case = "\nclass {0}(metaclass=DummyObject):\n _backends = {1}\n\n def __init__(self, *args, **kwargs):\n requires_backends(self, {1})\n\n @classmethod\n def from_config(cls, *args, **kwargs):\n requires_backends(cls, {1})\n\n @classmethod\n def from_pretrained(cls, *args, **kwargs):\n requires_backends(cls, {1})\n"
_snake_case = "\ndef {0}(*args, **kwargs):\n requires_backends({0}, {1})\n"
def A ( _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : Tuple = _re_backend.findall(_lowerCamelCase )
if len(_lowerCamelCase ) == 0:
return None
return "_and_".join(_lowerCamelCase )
def A ( ):
'''simple docstring'''
with open(os.path.join(_lowerCamelCase , "__init__.py" ) , "r" , encoding="utf-8" , newline="\n" ) as f:
_lowerCAmelCase : int = f.readlines()
# Get to the point we do the actual imports for type checking
_lowerCAmelCase : Dict = 0
_lowerCAmelCase : Optional[int] = {}
# Go through the end of the file
while line_index < len(_lowerCamelCase ):
# If the line contains is_backend_available, we grab all objects associated with the `else` block
_lowerCAmelCase : str = find_backend(lines[line_index] )
if backend is not None:
while not lines[line_index].startswith("else:" ):
line_index += 1
line_index += 1
_lowerCAmelCase : Tuple = []
# Until we unindent, add backend objects to the list
while line_index < len(_lowerCamelCase ) and len(lines[line_index] ) > 1:
_lowerCAmelCase : List[Any] = lines[line_index]
_lowerCAmelCase : Optional[Any] = _re_single_line_import.search(_lowerCamelCase )
if single_line_import_search is not None:
objects.extend(single_line_import_search.groups()[0].split(", " ) )
elif line.startswith(" " * 8 ):
objects.append(line[8:-2] )
line_index += 1
if len(_lowerCamelCase ) > 0:
_lowerCAmelCase : List[Any] = objects
else:
line_index += 1
return backend_specific_objects
def A ( _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
if name.isupper():
return DUMMY_CONSTANT.format(_lowerCamelCase )
elif name.islower():
return DUMMY_FUNCTION.format(_lowerCamelCase , _lowerCamelCase )
else:
return DUMMY_CLASS.format(_lowerCamelCase , _lowerCamelCase )
def A ( _lowerCamelCase=None ):
'''simple docstring'''
if backend_specific_objects is None:
_lowerCAmelCase : Tuple = read_init()
# For special correspondence backend to module name as used in the function requires_modulename
_lowerCAmelCase : List[Any] = {}
for backend, objects in backend_specific_objects.items():
_lowerCAmelCase : int = "[" + ", ".join(F"\"{b}\"" for b in backend.split("_and_" ) ) + "]"
_lowerCAmelCase : int = "# This file is autogenerated by the command `make fix-copies`, do not edit.\n"
dummy_file += "from ..utils import DummyObject, requires_backends\n\n"
dummy_file += "\n".join([create_dummy_object(_lowerCamelCase , _lowerCamelCase ) for o in objects] )
_lowerCAmelCase : Dict = dummy_file
return dummy_files
def A ( _lowerCamelCase=False ):
'''simple docstring'''
_lowerCAmelCase : Union[str, Any] = create_dummy_files()
# For special correspondence backend to shortcut as used in utils/dummy_xxx_objects.py
_lowerCAmelCase : Union[str, Any] = {"torch": "pt"}
# Locate actual dummy modules and read their content.
_lowerCAmelCase : Optional[int] = os.path.join(_lowerCamelCase , "utils" )
_lowerCAmelCase : Tuple = {
backend: os.path.join(_lowerCamelCase , F"dummy_{short_names.get(_lowerCamelCase , _lowerCamelCase )}_objects.py" )
for backend in dummy_files.keys()
}
_lowerCAmelCase : Tuple = {}
for backend, file_path in dummy_file_paths.items():
if os.path.isfile(_lowerCamelCase ):
with open(_lowerCamelCase , "r" , encoding="utf-8" , newline="\n" ) as f:
_lowerCAmelCase : Dict = f.read()
else:
_lowerCAmelCase : Any = ""
for backend in dummy_files.keys():
if dummy_files[backend] != actual_dummies[backend]:
if overwrite:
print(
F"Updating diffusers.utils.dummy_{short_names.get(_lowerCamelCase , _lowerCamelCase )}_objects.py as the main "
"__init__ has new objects." )
with open(dummy_file_paths[backend] , "w" , encoding="utf-8" , newline="\n" ) as f:
f.write(dummy_files[backend] )
else:
raise ValueError(
"The main __init__ has objects that are not present in "
F"diffusers.utils.dummy_{short_names.get(_lowerCamelCase , _lowerCamelCase )}_objects.py. Run `make fix-copies` "
"to fix this." )
if __name__ == "__main__":
_snake_case = argparse.ArgumentParser()
parser.add_argument("--fix_and_overwrite", action="store_true", help="Whether to fix inconsistencies.")
_snake_case = parser.parse_args()
check_dummies(args.fix_and_overwrite)
| 36
|
import argparse
import copy
def A ( _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : int = {}
with open(_lowerCamelCase ) as f:
for line in f:
if line.split()[0] not in dict_of_neighbours:
_lowerCAmelCase : Tuple = []
_list.append([line.split()[1], line.split()[2]] )
_lowerCAmelCase : Any = _list
else:
dict_of_neighbours[line.split()[0]].append(
[line.split()[1], line.split()[2]] )
if line.split()[1] not in dict_of_neighbours:
_lowerCAmelCase : str = []
_list.append([line.split()[0], line.split()[2]] )
_lowerCAmelCase : Any = _list
else:
dict_of_neighbours[line.split()[1]].append(
[line.split()[0], line.split()[2]] )
return dict_of_neighbours
def A ( _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
with open(_lowerCamelCase ) as f:
_lowerCAmelCase : str = f.read(1 )
_lowerCAmelCase : str = start_node
_lowerCAmelCase : List[str] = []
_lowerCAmelCase : Any = start_node
_lowerCAmelCase : str = 0
while visiting not in first_solution:
_lowerCAmelCase : Dict = 10_000
for k in dict_of_neighbours[visiting]:
if int(k[1] ) < int(_lowerCamelCase ) and k[0] not in first_solution:
_lowerCAmelCase : List[str] = k[1]
_lowerCAmelCase : List[Any] = k[0]
first_solution.append(_lowerCamelCase )
_lowerCAmelCase : Optional[int] = distance_of_first_solution + int(_lowerCamelCase )
_lowerCAmelCase : str = best_node
first_solution.append(_lowerCamelCase )
_lowerCAmelCase : Union[str, Any] = 0
for k in dict_of_neighbours[first_solution[-2]]:
if k[0] == start_node:
break
position += 1
_lowerCAmelCase : Tuple = (
distance_of_first_solution
+ int(dict_of_neighbours[first_solution[-2]][position][1] )
- 10_000
)
return first_solution, distance_of_first_solution
def A ( _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : Tuple = []
for n in solution[1:-1]:
_lowerCAmelCase : Dict = solution.index(_lowerCamelCase )
for kn in solution[1:-1]:
_lowerCAmelCase : Dict = solution.index(_lowerCamelCase )
if n == kn:
continue
_lowerCAmelCase : Optional[int] = copy.deepcopy(_lowerCamelCase )
_lowerCAmelCase : int = kn
_lowerCAmelCase : Dict = n
_lowerCAmelCase : Optional[int] = 0
for k in _tmp[:-1]:
_lowerCAmelCase : str = _tmp[_tmp.index(_lowerCamelCase ) + 1]
for i in dict_of_neighbours[k]:
if i[0] == next_node:
_lowerCAmelCase : Optional[Any] = distance + int(i[1] )
_tmp.append(_lowerCamelCase )
if _tmp not in neighborhood_of_solution:
neighborhood_of_solution.append(_tmp )
_lowerCAmelCase : List[Any] = len(neighborhood_of_solution[0] ) - 1
neighborhood_of_solution.sort(key=lambda _lowerCamelCase : x[index_of_last_item_in_the_list] )
return neighborhood_of_solution
def A ( _lowerCamelCase , _lowerCamelCase , _lowerCamelCase , _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : List[str] = 1
_lowerCAmelCase : int = first_solution
_lowerCAmelCase : Tuple = []
_lowerCAmelCase : Tuple = distance_of_first_solution
_lowerCAmelCase : Optional[int] = solution
while count <= iters:
_lowerCAmelCase : int = find_neighborhood(_lowerCamelCase , _lowerCamelCase )
_lowerCAmelCase : Tuple = 0
_lowerCAmelCase : Dict = neighborhood[index_of_best_solution]
_lowerCAmelCase : int = len(_lowerCamelCase ) - 1
_lowerCAmelCase : Union[str, Any] = False
while not found:
_lowerCAmelCase : Tuple = 0
while i < len(_lowerCamelCase ):
if best_solution[i] != solution[i]:
_lowerCAmelCase : str = best_solution[i]
_lowerCAmelCase : Tuple = solution[i]
break
_lowerCAmelCase : int = i + 1
if [first_exchange_node, second_exchange_node] not in tabu_list and [
second_exchange_node,
first_exchange_node,
] not in tabu_list:
tabu_list.append([first_exchange_node, second_exchange_node] )
_lowerCAmelCase : Optional[int] = True
_lowerCAmelCase : Optional[Any] = best_solution[:-1]
_lowerCAmelCase : Tuple = neighborhood[index_of_best_solution][best_cost_index]
if cost < best_cost:
_lowerCAmelCase : Union[str, Any] = cost
_lowerCAmelCase : List[Any] = solution
else:
_lowerCAmelCase : Optional[Any] = index_of_best_solution + 1
_lowerCAmelCase : Optional[Any] = neighborhood[index_of_best_solution]
if len(_lowerCamelCase ) >= size:
tabu_list.pop(0 )
_lowerCAmelCase : int = count + 1
return best_solution_ever, best_cost
def A ( _lowerCamelCase=None ):
'''simple docstring'''
_lowerCAmelCase : int = generate_neighbours(args.File )
_lowerCAmelCase , _lowerCAmelCase : List[str] = generate_first_solution(
args.File , _lowerCamelCase )
_lowerCAmelCase , _lowerCAmelCase : Any = tabu_search(
_lowerCamelCase , _lowerCamelCase , _lowerCamelCase , args.Iterations , args.Size , )
print(F"Best solution: {best_sol}, with total distance: {best_cost}." )
if __name__ == "__main__":
_snake_case = argparse.ArgumentParser(description="Tabu Search")
parser.add_argument(
"-f",
"--File",
type=str,
help="Path to the file containing the data",
required=True,
)
parser.add_argument(
"-i",
"--Iterations",
type=int,
help="How many iterations the algorithm should perform",
required=True,
)
parser.add_argument(
"-s", "--Size", type=int, help="Size of the tabu list", required=True
)
# Pass the arguments to main method
main(parser.parse_args())
| 36
| 1
|
import argparse
import requests
import torch
from PIL import Image
from transformers import SwinConfig, SwinForMaskedImageModeling, ViTImageProcessor
def A ( _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : List[str] = SwinConfig(image_size=192 )
if "base" in model_name:
_lowerCAmelCase : List[Any] = 6
_lowerCAmelCase : Tuple = 128
_lowerCAmelCase : Union[str, Any] = (2, 2, 18, 2)
_lowerCAmelCase : Optional[int] = (4, 8, 16, 32)
elif "large" in model_name:
_lowerCAmelCase : Optional[int] = 12
_lowerCAmelCase : Union[str, Any] = 192
_lowerCAmelCase : Dict = (2, 2, 18, 2)
_lowerCAmelCase : List[Any] = (6, 12, 24, 48)
else:
raise ValueError("Model not supported, only supports base and large variants" )
_lowerCAmelCase : Optional[int] = window_size
_lowerCAmelCase : str = embed_dim
_lowerCAmelCase : Union[str, Any] = depths
_lowerCAmelCase : Tuple = num_heads
return config
def A ( _lowerCamelCase ):
'''simple docstring'''
if "encoder.mask_token" in name:
_lowerCAmelCase : str = name.replace("encoder.mask_token" , "embeddings.mask_token" )
if "encoder.patch_embed.proj" in name:
_lowerCAmelCase : Tuple = name.replace("encoder.patch_embed.proj" , "embeddings.patch_embeddings.projection" )
if "encoder.patch_embed.norm" in name:
_lowerCAmelCase : Optional[int] = name.replace("encoder.patch_embed.norm" , "embeddings.norm" )
if "attn.proj" in name:
_lowerCAmelCase : Tuple = name.replace("attn.proj" , "attention.output.dense" )
if "attn" in name:
_lowerCAmelCase : Tuple = name.replace("attn" , "attention.self" )
if "norm1" in name:
_lowerCAmelCase : str = name.replace("norm1" , "layernorm_before" )
if "norm2" in name:
_lowerCAmelCase : Dict = name.replace("norm2" , "layernorm_after" )
if "mlp.fc1" in name:
_lowerCAmelCase : Union[str, Any] = name.replace("mlp.fc1" , "intermediate.dense" )
if "mlp.fc2" in name:
_lowerCAmelCase : Tuple = name.replace("mlp.fc2" , "output.dense" )
if name == "encoder.norm.weight":
_lowerCAmelCase : str = "layernorm.weight"
if name == "encoder.norm.bias":
_lowerCAmelCase : Dict = "layernorm.bias"
if "decoder" in name:
pass
else:
_lowerCAmelCase : int = "swin." + name
return name
def A ( _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
for key in orig_state_dict.copy().keys():
_lowerCAmelCase : Optional[Any] = orig_state_dict.pop(_lowerCamelCase )
if "attn_mask" in key:
pass
elif "qkv" in key:
_lowerCAmelCase : Union[str, Any] = key.split("." )
_lowerCAmelCase : Tuple = int(key_split[2] )
_lowerCAmelCase : Union[str, Any] = int(key_split[4] )
_lowerCAmelCase : Optional[int] = model.swin.encoder.layers[layer_num].blocks[block_num].attention.self.all_head_size
if "weight" in key:
_lowerCAmelCase : Dict = val[:dim, :]
_lowerCAmelCase : List[Any] = val[
dim : dim * 2, :
]
_lowerCAmelCase : Optional[Any] = val[-dim:, :]
else:
_lowerCAmelCase : List[Any] = val[
:dim
]
_lowerCAmelCase : List[str] = val[
dim : dim * 2
]
_lowerCAmelCase : int = val[
-dim:
]
else:
_lowerCAmelCase : Union[str, Any] = val
return orig_state_dict
def A ( _lowerCamelCase , _lowerCamelCase , _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : Union[str, Any] = torch.load(_lowerCamelCase , map_location="cpu" )["model"]
_lowerCAmelCase : Optional[int] = get_swin_config(_lowerCamelCase )
_lowerCAmelCase : Dict = SwinForMaskedImageModeling(_lowerCamelCase )
model.eval()
_lowerCAmelCase : Tuple = convert_state_dict(_lowerCamelCase , _lowerCamelCase )
model.load_state_dict(_lowerCamelCase )
_lowerCAmelCase : int = "http://images.cocodataset.org/val2017/000000039769.jpg"
_lowerCAmelCase : Union[str, Any] = ViTImageProcessor(size={"height": 192, "width": 192} )
_lowerCAmelCase : Dict = Image.open(requests.get(_lowerCamelCase , stream=_lowerCamelCase ).raw )
_lowerCAmelCase : Dict = image_processor(images=_lowerCamelCase , return_tensors="pt" )
with torch.no_grad():
_lowerCAmelCase : Any = model(**_lowerCamelCase ).logits
print(outputs.keys() )
print("Looks ok!" )
if pytorch_dump_folder_path is not None:
print(F"Saving model {model_name} to {pytorch_dump_folder_path}" )
model.save_pretrained(_lowerCamelCase )
print(F"Saving image processor to {pytorch_dump_folder_path}" )
image_processor.save_pretrained(_lowerCamelCase )
if push_to_hub:
print(F"Pushing model and image processor for {model_name} to hub" )
model.push_to_hub(F"microsoft/{model_name}" )
image_processor.push_to_hub(F"microsoft/{model_name}" )
if __name__ == "__main__":
_snake_case = argparse.ArgumentParser()
# Required parameters
parser.add_argument(
"--model_name",
default="swin-base-simmim-window6-192",
type=str,
choices=["swin-base-simmim-window6-192", "swin-large-simmim-window12-192"],
help="Name of the Swin SimMIM model you'd like to convert.",
)
parser.add_argument(
"--checkpoint_path",
default="/Users/nielsrogge/Documents/SwinSimMIM/simmim_pretrain__swin_base__img192_window6__100ep.pth",
type=str,
help="Path to the original PyTorch checkpoint (.pth file).",
)
parser.add_argument(
"--pytorch_dump_folder_path", default=None, type=str, help="Path to the 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."
)
_snake_case = parser.parse_args()
convert_swin_checkpoint(args.model_name, args.checkpoint_path, args.pytorch_dump_folder_path, args.push_to_hub)
| 36
|
import os
import unittest
from transformers.models.bartpho.tokenization_bartpho import VOCAB_FILES_NAMES, BartphoTokenizer
from transformers.testing_utils import get_tests_dir
from ...test_tokenization_common import TokenizerTesterMixin
_snake_case = get_tests_dir("fixtures/test_sentencepiece_bpe.model")
class UpperCAmelCase_ ( a , unittest.TestCase):
lowerCamelCase__ = BartphoTokenizer
lowerCamelCase__ = False
lowerCamelCase__ = True
def snake_case__ ( self):
'''simple docstring'''
super().setUp()
_lowerCAmelCase : str = ["▁This", "▁is", "▁a", "▁t", "est"]
_lowerCAmelCase : List[str] = dict(zip(__a, range(len(__a))))
_lowerCAmelCase : Optional[Any] = {"unk_token": "<unk>"}
_lowerCAmelCase : Optional[int] = os.path.join(self.tmpdirname, VOCAB_FILES_NAMES["monolingual_vocab_file"])
with open(self.monolingual_vocab_file, "w", encoding="utf-8") as fp:
for token in vocab_tokens:
fp.write(f"{token} {vocab_tokens[token]}\n")
_lowerCAmelCase : Optional[Any] = BartphoTokenizer(__a, self.monolingual_vocab_file, **self.special_tokens_map)
tokenizer.save_pretrained(self.tmpdirname)
def snake_case__ ( self, **__a):
'''simple docstring'''
kwargs.update(self.special_tokens_map)
return BartphoTokenizer.from_pretrained(self.tmpdirname, **__a)
def snake_case__ ( self, __a):
'''simple docstring'''
_lowerCAmelCase : Union[str, Any] = "This is a là test"
_lowerCAmelCase : Optional[int] = "This is a<unk><unk> test"
return input_text, output_text
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Optional[int] = BartphoTokenizer(__a, self.monolingual_vocab_file, **self.special_tokens_map)
_lowerCAmelCase : List[Any] = "This is a là test"
_lowerCAmelCase : str = "▁This ▁is ▁a ▁l à ▁t est".split()
_lowerCAmelCase : str = tokenizer.tokenize(__a)
self.assertListEqual(__a, __a)
_lowerCAmelCase : Tuple = tokens + [tokenizer.unk_token]
_lowerCAmelCase : List[str] = [4, 5, 6, 3, 3, 7, 8, 3]
self.assertListEqual(tokenizer.convert_tokens_to_ids(__a), __a)
| 36
| 1
|
def A ( _lowerCamelCase , _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
if n == 0:
return 1
elif n % 2 == 1:
return (binary_exponentiation(_lowerCamelCase , n - 1 , _lowerCamelCase ) * a) % mod
else:
_lowerCAmelCase : List[Any] = binary_exponentiation(_lowerCamelCase , n / 2 , _lowerCamelCase )
return (b * b) % mod
# a prime number
_snake_case = 701
_snake_case = 10_0000_0000
_snake_case = 10
# using binary exponentiation function, O(log(p)):
print((a / b) % p == (a * binary_exponentiation(b, p - 2, p)) % p)
print((a / b) % p == (a * b ** (p - 2)) % p)
| 36
|
import math
from typing import Dict, Iterable, List, Optional, Tuple, Union
import numpy as np
from ...image_processing_utils import BaseImageProcessor, BatchFeature, get_size_dict
from ...image_transforms import normalize, rescale, resize, to_channel_dimension_format
from ...image_utils import (
IMAGENET_STANDARD_MEAN,
IMAGENET_STANDARD_STD,
ChannelDimension,
ImageInput,
PILImageResampling,
get_image_size,
is_torch_available,
is_torch_tensor,
make_list_of_images,
to_numpy_array,
valid_images,
)
from ...utils import TensorType, is_vision_available, logging
if is_torch_available():
import torch
if is_vision_available():
import PIL
_snake_case = logging.get_logger(__name__)
def A ( _lowerCamelCase , _lowerCamelCase , _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
def constraint_to_multiple_of(_lowerCamelCase , _lowerCamelCase , _lowerCamelCase=0 , _lowerCamelCase=None ):
_lowerCAmelCase : Tuple = round(val / multiple ) * multiple
if max_val is not None and x > max_val:
_lowerCAmelCase : Optional[int] = math.floor(val / multiple ) * multiple
if x < min_val:
_lowerCAmelCase : List[str] = math.ceil(val / multiple ) * multiple
return x
_lowerCAmelCase : Union[str, Any] = (output_size, output_size) if isinstance(_lowerCamelCase , _lowerCamelCase ) else output_size
_lowerCAmelCase , _lowerCAmelCase : Optional[Any] = get_image_size(_lowerCamelCase )
_lowerCAmelCase , _lowerCAmelCase : Any = output_size
# determine new height and width
_lowerCAmelCase : List[Any] = output_height / input_height
_lowerCAmelCase : Any = output_width / input_width
if keep_aspect_ratio:
# scale as little as possible
if abs(1 - scale_width ) < abs(1 - scale_height ):
# fit width
_lowerCAmelCase : Union[str, Any] = scale_width
else:
# fit height
_lowerCAmelCase : Union[str, Any] = scale_height
_lowerCAmelCase : List[str] = constraint_to_multiple_of(scale_height * input_height , multiple=_lowerCamelCase )
_lowerCAmelCase : Dict = constraint_to_multiple_of(scale_width * input_width , multiple=_lowerCamelCase )
return (new_height, new_width)
class UpperCAmelCase_ ( a):
lowerCamelCase__ = ['pixel_values']
def __init__( self, __a = True, __a = None, __a = PILImageResampling.BILINEAR, __a = False, __a = 1, __a = True, __a = 1 / 255, __a = True, __a = None, __a = None, **__a, ):
'''simple docstring'''
super().__init__(**__a)
_lowerCAmelCase : Any = size if size is not None else {"height": 384, "width": 384}
_lowerCAmelCase : Optional[int] = get_size_dict(__a)
_lowerCAmelCase : Optional[Any] = do_resize
_lowerCAmelCase : Dict = size
_lowerCAmelCase : Any = keep_aspect_ratio
_lowerCAmelCase : str = ensure_multiple_of
_lowerCAmelCase : str = resample
_lowerCAmelCase : Dict = do_rescale
_lowerCAmelCase : Optional[int] = rescale_factor
_lowerCAmelCase : Dict = do_normalize
_lowerCAmelCase : Dict = image_mean if image_mean is not None else IMAGENET_STANDARD_MEAN
_lowerCAmelCase : int = image_std if image_std is not None else IMAGENET_STANDARD_STD
def snake_case__ ( self, __a, __a, __a = False, __a = 1, __a = PILImageResampling.BICUBIC, __a = None, **__a, ):
'''simple docstring'''
_lowerCAmelCase : List[Any] = get_size_dict(__a)
if "height" not in size or "width" not in size:
raise ValueError(f"The size dictionary must contain the keys 'height' and 'width'. Got {size.keys()}")
_lowerCAmelCase : List[Any] = get_resize_output_image_size(
__a, output_size=(size["height"], size["width"]), keep_aspect_ratio=__a, multiple=__a, )
return resize(__a, size=__a, resample=__a, data_format=__a, **__a)
def snake_case__ ( self, __a, __a, __a = None, **__a, ):
'''simple docstring'''
return rescale(__a, scale=__a, data_format=__a, **__a)
def snake_case__ ( self, __a, __a, __a, __a = None, **__a, ):
'''simple docstring'''
return normalize(__a, mean=__a, std=__a, data_format=__a, **__a)
def snake_case__ ( self, __a, __a = None, __a = None, __a = None, __a = None, __a = None, __a = None, __a = None, __a = None, __a = None, __a = None, __a = None, __a = ChannelDimension.FIRST, **__a, ):
'''simple docstring'''
_lowerCAmelCase : int = do_resize if do_resize is not None else self.do_resize
_lowerCAmelCase : List[Any] = size if size is not None else self.size
_lowerCAmelCase : str = get_size_dict(__a)
_lowerCAmelCase : Dict = keep_aspect_ratio if keep_aspect_ratio is not None else self.keep_aspect_ratio
_lowerCAmelCase : Any = ensure_multiple_of if ensure_multiple_of is not None else self.ensure_multiple_of
_lowerCAmelCase : int = resample if resample is not None else self.resample
_lowerCAmelCase : Union[str, Any] = do_rescale if do_rescale is not None else self.do_rescale
_lowerCAmelCase : Tuple = rescale_factor if rescale_factor is not None else self.rescale_factor
_lowerCAmelCase : List[str] = do_normalize if do_normalize is not None else self.do_normalize
_lowerCAmelCase : Dict = image_mean if image_mean is not None else self.image_mean
_lowerCAmelCase : List[str] = image_std if image_std is not None else self.image_std
_lowerCAmelCase : Optional[Any] = make_list_of_images(__a)
if not valid_images(__a):
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 or resample is None:
raise ValueError("Size and resample must be specified if do_resize 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.
_lowerCAmelCase : List[Any] = [to_numpy_array(__a) for image in images]
if do_resize:
_lowerCAmelCase : Any = [self.resize(image=__a, size=__a, resample=__a) for image in images]
if do_rescale:
_lowerCAmelCase : List[str] = [self.rescale(image=__a, scale=__a) for image in images]
if do_normalize:
_lowerCAmelCase : Dict = [self.normalize(image=__a, mean=__a, std=__a) for image in images]
_lowerCAmelCase : List[str] = [to_channel_dimension_format(__a, __a) for image in images]
_lowerCAmelCase : Optional[Any] = {"pixel_values": images}
return BatchFeature(data=__a, tensor_type=__a)
def snake_case__ ( self, __a, __a = None):
'''simple docstring'''
_lowerCAmelCase : Optional[Any] = outputs.logits
# Resize logits and compute semantic segmentation maps
if target_sizes is not None:
if len(__a) != len(__a):
raise ValueError(
"Make sure that you pass in as many target sizes as the batch dimension of the logits")
if is_torch_tensor(__a):
_lowerCAmelCase : List[Any] = target_sizes.numpy()
_lowerCAmelCase : Dict = []
for idx in range(len(__a)):
_lowerCAmelCase : int = torch.nn.functional.interpolate(
logits[idx].unsqueeze(dim=0), size=target_sizes[idx], mode="bilinear", align_corners=__a)
_lowerCAmelCase : int = resized_logits[0].argmax(dim=0)
semantic_segmentation.append(__a)
else:
_lowerCAmelCase : Dict = logits.argmax(dim=1)
_lowerCAmelCase : str = [semantic_segmentation[i] for i in range(semantic_segmentation.shape[0])]
return semantic_segmentation
| 36
| 1
|
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
from .tokenization_gpta import GPTaTokenizer
if TYPE_CHECKING:
from transformers.pipelines.conversational import Conversation
_snake_case = logging.get_logger(__name__)
_snake_case = {"vocab_file": "vocab.json", "merges_file": "merges.txt", "tokenizer_file": "tokenizer.json"}
_snake_case = {
"vocab_file": {
"gpt2": "https://huggingface.co/gpt2/resolve/main/vocab.json",
"gpt2-medium": "https://huggingface.co/gpt2-medium/resolve/main/vocab.json",
"gpt2-large": "https://huggingface.co/gpt2-large/resolve/main/vocab.json",
"gpt2-xl": "https://huggingface.co/gpt2-xl/resolve/main/vocab.json",
"distilgpt2": "https://huggingface.co/distilgpt2/resolve/main/vocab.json",
},
"merges_file": {
"gpt2": "https://huggingface.co/gpt2/resolve/main/merges.txt",
"gpt2-medium": "https://huggingface.co/gpt2-medium/resolve/main/merges.txt",
"gpt2-large": "https://huggingface.co/gpt2-large/resolve/main/merges.txt",
"gpt2-xl": "https://huggingface.co/gpt2-xl/resolve/main/merges.txt",
"distilgpt2": "https://huggingface.co/distilgpt2/resolve/main/merges.txt",
},
"tokenizer_file": {
"gpt2": "https://huggingface.co/gpt2/resolve/main/tokenizer.json",
"gpt2-medium": "https://huggingface.co/gpt2-medium/resolve/main/tokenizer.json",
"gpt2-large": "https://huggingface.co/gpt2-large/resolve/main/tokenizer.json",
"gpt2-xl": "https://huggingface.co/gpt2-xl/resolve/main/tokenizer.json",
"distilgpt2": "https://huggingface.co/distilgpt2/resolve/main/tokenizer.json",
},
}
_snake_case = {
"gpt2": 1024,
"gpt2-medium": 1024,
"gpt2-large": 1024,
"gpt2-xl": 1024,
"distilgpt2": 1024,
}
class UpperCAmelCase_ ( a):
lowerCamelCase__ = VOCAB_FILES_NAMES
lowerCamelCase__ = PRETRAINED_VOCAB_FILES_MAP
lowerCamelCase__ = PRETRAINED_POSITIONAL_EMBEDDINGS_SIZES
lowerCamelCase__ = ['input_ids', 'attention_mask']
lowerCamelCase__ = GPTaTokenizer
def __init__( self, __a=None, __a=None, __a=None, __a="<|endoftext|>", __a="<|endoftext|>", __a="<|endoftext|>", __a=False, **__a, ):
'''simple docstring'''
super().__init__(
__a, __a, tokenizer_file=__a, unk_token=__a, bos_token=__a, eos_token=__a, add_prefix_space=__a, **__a, )
_lowerCAmelCase : Tuple = kwargs.pop("add_bos_token", __a)
_lowerCAmelCase : Any = json.loads(self.backend_tokenizer.pre_tokenizer.__getstate__())
if pre_tok_state.get("add_prefix_space", __a) != add_prefix_space:
_lowerCAmelCase : Optional[int] = getattr(__a, pre_tok_state.pop("type"))
_lowerCAmelCase : str = add_prefix_space
_lowerCAmelCase : Tuple = pre_tok_class(**__a)
_lowerCAmelCase : int = add_prefix_space
def snake_case__ ( self, *__a, **__a):
'''simple docstring'''
_lowerCAmelCase : List[str] = kwargs.get("is_split_into_words", __a)
assert self.add_prefix_space or not is_split_into_words, (
f"You need to instantiate {self.__class__.__name__} with add_prefix_space=True "
"to use it with pretokenized inputs."
)
return super()._batch_encode_plus(*__a, **__a)
def snake_case__ ( self, *__a, **__a):
'''simple docstring'''
_lowerCAmelCase : str = kwargs.get("is_split_into_words", __a)
assert self.add_prefix_space or not is_split_into_words, (
f"You need to instantiate {self.__class__.__name__} with add_prefix_space=True "
"to use it with pretokenized inputs."
)
return super()._encode_plus(*__a, **__a)
def snake_case__ ( self, __a, __a = None):
'''simple docstring'''
_lowerCAmelCase : int = self._tokenizer.model.save(__a, name=__a)
return tuple(__a)
def snake_case__ ( self, __a):
'''simple docstring'''
_lowerCAmelCase : int = []
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:
_lowerCAmelCase : Any = input_ids[-self.model_max_length :]
return input_ids
| 36
|
import argparse
import json
from pathlib import Path
import requests
import torch
from huggingface_hub import hf_hub_download
from PIL import Image
from timm import create_model
from timm.data import resolve_data_config
from timm.data.transforms_factory import create_transform
from transformers import BitConfig, BitForImageClassification, BitImageProcessor
from transformers.image_utils import PILImageResampling
from transformers.utils import logging
logging.set_verbosity_info()
_snake_case = logging.get_logger(__name__)
def A ( _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : List[Any] = "huggingface/label-files"
_lowerCAmelCase : int = "imagenet-1k-id2label.json"
_lowerCAmelCase : Tuple = json.load(open(hf_hub_download(_lowerCamelCase , _lowerCamelCase , repo_type="dataset" ) , "r" ) )
_lowerCAmelCase : Tuple = {int(_lowerCamelCase ): v for k, v in idalabel.items()}
_lowerCAmelCase : Union[str, Any] = {v: k for k, v in idalabel.items()}
_lowerCAmelCase : Tuple = "std_conv" if "bit" in model_name else False
# note that when using BiT as backbone for ViT-hybrid checkpoints,
# one needs to additionally set config.layer_type = "bottleneck", config.stem_type = "same",
# config.conv_layer = "std_conv_same"
_lowerCAmelCase : Optional[int] = BitConfig(
conv_layer=_lowerCamelCase , num_labels=1_000 , idalabel=_lowerCamelCase , labelaid=_lowerCamelCase , )
return config
def A ( _lowerCamelCase ):
'''simple docstring'''
if "stem.conv" in name:
_lowerCAmelCase : List[str] = name.replace("stem.conv" , "bit.embedder.convolution" )
if "blocks" in name:
_lowerCAmelCase : Any = name.replace("blocks" , "layers" )
if "head.fc" in name:
_lowerCAmelCase : Optional[Any] = name.replace("head.fc" , "classifier.1" )
if name.startswith("norm" ):
_lowerCAmelCase : Any = "bit." + name
if "bit" not in name and "classifier" not in name:
_lowerCAmelCase : Dict = "bit.encoder." + name
return name
def A ( ):
'''simple docstring'''
_lowerCAmelCase : Tuple = "http://images.cocodataset.org/val2017/000000039769.jpg"
_lowerCAmelCase : Optional[int] = Image.open(requests.get(_lowerCamelCase , stream=_lowerCamelCase ).raw )
return im
@torch.no_grad()
def A ( _lowerCamelCase , _lowerCamelCase , _lowerCamelCase=False ):
'''simple docstring'''
_lowerCAmelCase : Dict = get_config(_lowerCamelCase )
# load original model from timm
_lowerCAmelCase : int = create_model(_lowerCamelCase , pretrained=_lowerCamelCase )
timm_model.eval()
# load state_dict of original model
_lowerCAmelCase : Any = timm_model.state_dict()
for key in state_dict.copy().keys():
_lowerCAmelCase : Dict = state_dict.pop(_lowerCamelCase )
_lowerCAmelCase : Tuple = val.squeeze() if "head" in key else val
# load HuggingFace model
_lowerCAmelCase : Optional[Any] = BitForImageClassification(_lowerCamelCase )
model.eval()
model.load_state_dict(_lowerCamelCase )
# create image processor
_lowerCAmelCase : Dict = create_transform(**resolve_data_config({} , model=_lowerCamelCase ) )
_lowerCAmelCase : Optional[int] = transform.transforms
_lowerCAmelCase : Tuple = {
"bilinear": PILImageResampling.BILINEAR,
"bicubic": PILImageResampling.BICUBIC,
"nearest": PILImageResampling.NEAREST,
}
_lowerCAmelCase : Tuple = BitImageProcessor(
do_resize=_lowerCamelCase , size={"shortest_edge": timm_transforms[0].size} , resample=pillow_resamplings[timm_transforms[0].interpolation.value] , do_center_crop=_lowerCamelCase , crop_size={"height": timm_transforms[1].size[0], "width": timm_transforms[1].size[1]} , do_normalize=_lowerCamelCase , image_mean=timm_transforms[-1].mean.tolist() , image_std=timm_transforms[-1].std.tolist() , )
_lowerCAmelCase : Optional[int] = prepare_img()
_lowerCAmelCase : Any = transform(_lowerCamelCase ).unsqueeze(0 )
_lowerCAmelCase : Optional[int] = processor(_lowerCamelCase , return_tensors="pt" ).pixel_values
# verify pixel values
assert torch.allclose(_lowerCamelCase , _lowerCamelCase )
# verify logits
with torch.no_grad():
_lowerCAmelCase : Tuple = model(_lowerCamelCase )
_lowerCAmelCase : str = outputs.logits
print("Logits:" , logits[0, :3] )
print("Predicted class:" , model.config.idalabel[logits.argmax(-1 ).item()] )
_lowerCAmelCase : Union[str, Any] = timm_model(_lowerCamelCase )
assert timm_logits.shape == outputs.logits.shape
assert torch.allclose(_lowerCamelCase , outputs.logits , atol=1e-3 )
print("Looks ok!" )
if pytorch_dump_folder_path is not None:
Path(_lowerCamelCase ).mkdir(exist_ok=_lowerCamelCase )
print(F"Saving model {model_name} and processor to {pytorch_dump_folder_path}" )
model.save_pretrained(_lowerCamelCase )
processor.save_pretrained(_lowerCamelCase )
if push_to_hub:
print(F"Pushing model {model_name} and processor to the hub" )
model.push_to_hub(F"ybelkada/{model_name}" )
processor.push_to_hub(F"ybelkada/{model_name}" )
if __name__ == "__main__":
_snake_case = argparse.ArgumentParser()
# Required parameters
parser.add_argument(
"--model_name",
default="resnetv2_50x1_bitm",
type=str,
help="Name of the BiT 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."
)
parser.add_argument(
"--push_to_hub",
action="store_true",
help="Whether to push the model to the hub.",
)
_snake_case = parser.parse_args()
convert_bit_checkpoint(args.model_name, args.pytorch_dump_folder_path, args.push_to_hub)
| 36
| 1
|
from ...configuration_utils import PretrainedConfig
from ...utils import logging
_snake_case = logging.get_logger(__name__)
_snake_case = {
"microsoft/trocr-base-handwritten": (
"https://huggingface.co/microsoft/trocr-base-handwritten/resolve/main/config.json"
),
# See all TrOCR models at https://huggingface.co/models?filter=trocr
}
class UpperCAmelCase_ ( a):
lowerCamelCase__ = 'trocr'
lowerCamelCase__ = ['past_key_values']
lowerCamelCase__ = {
'num_attention_heads': 'decoder_attention_heads',
'hidden_size': 'd_model',
'num_hidden_layers': 'decoder_layers',
}
def __init__( self, __a=5_0265, __a=1024, __a=12, __a=16, __a=4096, __a="gelu", __a=512, __a=0.1, __a=0.0, __a=0.0, __a=2, __a=0.02, __a=0.0, __a=True, __a=False, __a=True, __a=True, __a=1, __a=0, __a=2, **__a, ):
'''simple docstring'''
_lowerCAmelCase : List[Any] = vocab_size
_lowerCAmelCase : Dict = d_model
_lowerCAmelCase : str = decoder_layers
_lowerCAmelCase : Dict = decoder_attention_heads
_lowerCAmelCase : int = decoder_ffn_dim
_lowerCAmelCase : int = activation_function
_lowerCAmelCase : str = max_position_embeddings
_lowerCAmelCase : Optional[Any] = dropout
_lowerCAmelCase : str = attention_dropout
_lowerCAmelCase : str = activation_dropout
_lowerCAmelCase : List[Any] = init_std
_lowerCAmelCase : Optional[Any] = decoder_layerdrop
_lowerCAmelCase : Optional[int] = use_cache
_lowerCAmelCase : str = scale_embedding
_lowerCAmelCase : Optional[int] = use_learned_position_embeddings
_lowerCAmelCase : Optional[Any] = layernorm_embedding
super().__init__(
pad_token_id=__a, bos_token_id=__a, eos_token_id=__a, decoder_start_token_id=__a, **__a, )
| 36
|
from collections import OrderedDict
from typing import Mapping
from packaging import version
from ...configuration_utils import PretrainedConfig
from ...onnx import OnnxConfig
from ...utils import logging
from ...utils.backbone_utils import BackboneConfigMixin, get_aligned_output_features_output_indices
_snake_case = logging.get_logger(__name__)
_snake_case = {
"microsoft/swin-tiny-patch4-window7-224": (
"https://huggingface.co/microsoft/swin-tiny-patch4-window7-224/resolve/main/config.json"
),
# See all Swin models at https://huggingface.co/models?filter=swin
}
class UpperCAmelCase_ ( a , a):
lowerCamelCase__ = 'swin'
lowerCamelCase__ = {
'num_attention_heads': 'num_heads',
'num_hidden_layers': 'num_layers',
}
def __init__( self, __a=224, __a=4, __a=3, __a=96, __a=[2, 2, 6, 2], __a=[3, 6, 12, 24], __a=7, __a=4.0, __a=True, __a=0.0, __a=0.0, __a=0.1, __a="gelu", __a=False, __a=0.02, __a=1E-5, __a=32, __a=None, __a=None, **__a, ):
'''simple docstring'''
super().__init__(**__a)
_lowerCAmelCase : Any = image_size
_lowerCAmelCase : Union[str, Any] = patch_size
_lowerCAmelCase : Tuple = num_channels
_lowerCAmelCase : List[Any] = embed_dim
_lowerCAmelCase : Tuple = depths
_lowerCAmelCase : Optional[Any] = len(__a)
_lowerCAmelCase : int = num_heads
_lowerCAmelCase : int = window_size
_lowerCAmelCase : int = mlp_ratio
_lowerCAmelCase : List[Any] = qkv_bias
_lowerCAmelCase : str = hidden_dropout_prob
_lowerCAmelCase : Union[str, Any] = attention_probs_dropout_prob
_lowerCAmelCase : Any = drop_path_rate
_lowerCAmelCase : int = hidden_act
_lowerCAmelCase : Tuple = use_absolute_embeddings
_lowerCAmelCase : Optional[int] = layer_norm_eps
_lowerCAmelCase : Tuple = initializer_range
_lowerCAmelCase : Tuple = encoder_stride
# 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
_lowerCAmelCase : List[str] = int(embed_dim * 2 ** (len(__a) - 1))
_lowerCAmelCase : List[Any] = ["stem"] + [f"stage{idx}" for idx in range(1, len(__a) + 1)]
_lowerCAmelCase , _lowerCAmelCase : Optional[int] = get_aligned_output_features_output_indices(
out_features=__a, out_indices=__a, stage_names=self.stage_names)
class UpperCAmelCase_ ( a):
lowerCamelCase__ = version.parse('1.11')
@property
def snake_case__ ( self):
'''simple docstring'''
return OrderedDict(
[
("pixel_values", {0: "batch", 1: "num_channels", 2: "height", 3: "width"}),
])
@property
def snake_case__ ( self):
'''simple docstring'''
return 1E-4
| 36
| 1
|
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 BeitConfig, BeitForImageClassification, BeitForMaskedImageModeling, BeitImageProcessor
from transformers.image_utils import PILImageResampling
from transformers.utils import logging
logging.set_verbosity_info()
_snake_case = logging.get_logger(__name__)
def A ( _lowerCamelCase , _lowerCamelCase=False , _lowerCamelCase=False ):
'''simple docstring'''
_lowerCAmelCase : int = "backbone." if is_semantic else ""
_lowerCAmelCase : Optional[int] = []
for i in range(config.num_hidden_layers ):
# encoder layers: output projection, 2 feedforward neural networks and 2 layernorms
rename_keys.append((F"{prefix}blocks.{i}.norm1.weight", F"beit.encoder.layer.{i}.layernorm_before.weight") )
rename_keys.append((F"{prefix}blocks.{i}.norm1.bias", F"beit.encoder.layer.{i}.layernorm_before.bias") )
rename_keys.append(
(F"{prefix}blocks.{i}.attn.proj.weight", F"beit.encoder.layer.{i}.attention.output.dense.weight") )
rename_keys.append(
(F"{prefix}blocks.{i}.attn.proj.bias", F"beit.encoder.layer.{i}.attention.output.dense.bias") )
rename_keys.append((F"{prefix}blocks.{i}.norm2.weight", F"beit.encoder.layer.{i}.layernorm_after.weight") )
rename_keys.append((F"{prefix}blocks.{i}.norm2.bias", F"beit.encoder.layer.{i}.layernorm_after.bias") )
rename_keys.append((F"{prefix}blocks.{i}.mlp.fc1.weight", F"beit.encoder.layer.{i}.intermediate.dense.weight") )
rename_keys.append((F"{prefix}blocks.{i}.mlp.fc1.bias", F"beit.encoder.layer.{i}.intermediate.dense.bias") )
rename_keys.append((F"{prefix}blocks.{i}.mlp.fc2.weight", F"beit.encoder.layer.{i}.output.dense.weight") )
rename_keys.append((F"{prefix}blocks.{i}.mlp.fc2.bias", F"beit.encoder.layer.{i}.output.dense.bias") )
# projection layer + position embeddings
rename_keys.extend(
[
(F"{prefix}cls_token", "beit.embeddings.cls_token"),
(F"{prefix}patch_embed.proj.weight", "beit.embeddings.patch_embeddings.projection.weight"),
(F"{prefix}patch_embed.proj.bias", "beit.embeddings.patch_embeddings.projection.bias"),
(F"{prefix}pos_embed", "beit.embeddings.position_embeddings"),
] )
if has_lm_head:
# mask token + layernorm
rename_keys.extend(
[
("mask_token", "beit.embeddings.mask_token"),
("norm.weight", "layernorm.weight"),
("norm.bias", "layernorm.bias"),
] )
else:
# layernorm + classification head
rename_keys.extend(
[
("fc_norm.weight", "beit.pooler.layernorm.weight"),
("fc_norm.bias", "beit.pooler.layernorm.bias"),
("head.weight", "classifier.weight"),
("head.bias", "classifier.bias"),
] )
return rename_keys
def A ( _lowerCamelCase , _lowerCamelCase , _lowerCamelCase=False , _lowerCamelCase=False ):
'''simple docstring'''
for i in range(config.num_hidden_layers ):
_lowerCAmelCase : Tuple = "backbone." if is_semantic else ""
# queries, keys and values
_lowerCAmelCase : int = state_dict.pop(F"{prefix}blocks.{i}.attn.qkv.weight" )
_lowerCAmelCase : Any = state_dict.pop(F"{prefix}blocks.{i}.attn.q_bias" )
_lowerCAmelCase : int = state_dict.pop(F"{prefix}blocks.{i}.attn.v_bias" )
_lowerCAmelCase : Any = in_proj_weight[
: config.hidden_size, :
]
_lowerCAmelCase : Optional[int] = q_bias
_lowerCAmelCase : Tuple = in_proj_weight[
config.hidden_size : config.hidden_size * 2, :
]
_lowerCAmelCase : str = in_proj_weight[
-config.hidden_size :, :
]
_lowerCAmelCase : int = v_bias
# gamma_1 and gamma_2
# we call them lambda because otherwise they are renamed when using .from_pretrained
_lowerCAmelCase : Optional[Any] = state_dict.pop(F"{prefix}blocks.{i}.gamma_1" )
_lowerCAmelCase : Tuple = state_dict.pop(F"{prefix}blocks.{i}.gamma_2" )
_lowerCAmelCase : Dict = gamma_a
_lowerCAmelCase : Union[str, Any] = gamma_a
def A ( _lowerCamelCase , _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : Optional[int] = dct.pop(_lowerCamelCase )
_lowerCAmelCase : int = val
def A ( ):
'''simple docstring'''
_lowerCAmelCase : Union[str, Any] = "http://images.cocodataset.org/val2017/000000039769.jpg"
_lowerCAmelCase : Tuple = Image.open(requests.get(_lowerCamelCase , stream=_lowerCamelCase ).raw )
return im
@torch.no_grad()
def A ( _lowerCamelCase , _lowerCamelCase , _lowerCamelCase=False ):
'''simple docstring'''
_lowerCAmelCase : List[str] = False if "rvlcdip" in checkpoint_url else True
_lowerCAmelCase : str = BeitConfig(use_absolute_position_embeddings=_lowerCamelCase , use_mask_token=_lowerCamelCase )
# size of the architecture
if "large" in checkpoint_url or "dit-l" in checkpoint_url:
_lowerCAmelCase : List[str] = 1_024
_lowerCAmelCase : List[Any] = 4_096
_lowerCAmelCase : Tuple = 24
_lowerCAmelCase : Any = 16
# labels
if "rvlcdip" in checkpoint_url:
_lowerCAmelCase : List[Any] = 16
_lowerCAmelCase : int = "huggingface/label-files"
_lowerCAmelCase : Optional[Any] = "rvlcdip-id2label.json"
_lowerCAmelCase : Any = json.load(open(hf_hub_download(_lowerCamelCase , _lowerCamelCase , repo_type="dataset" ) , "r" ) )
_lowerCAmelCase : str = {int(_lowerCamelCase ): v for k, v in idalabel.items()}
_lowerCAmelCase : Dict = idalabel
_lowerCAmelCase : Any = {v: k for k, v in idalabel.items()}
# load state_dict of original model, remove and rename some keys
_lowerCAmelCase : List[str] = torch.hub.load_state_dict_from_url(_lowerCamelCase , map_location="cpu" )["model"]
_lowerCAmelCase : List[str] = create_rename_keys(_lowerCamelCase , has_lm_head=_lowerCamelCase )
for src, dest in rename_keys:
rename_key(_lowerCamelCase , _lowerCamelCase , _lowerCamelCase )
read_in_q_k_v(_lowerCamelCase , _lowerCamelCase , has_lm_head=_lowerCamelCase )
# load HuggingFace model
_lowerCAmelCase : Dict = BeitForMaskedImageModeling(_lowerCamelCase ) if has_lm_head else BeitForImageClassification(_lowerCamelCase )
model.eval()
model.load_state_dict(_lowerCamelCase )
# Check outputs on an image
_lowerCAmelCase : Optional[Any] = BeitImageProcessor(
size=config.image_size , resample=PILImageResampling.BILINEAR , do_center_crop=_lowerCamelCase )
_lowerCAmelCase : Tuple = prepare_img()
_lowerCAmelCase : Optional[Any] = image_processor(images=_lowerCamelCase , return_tensors="pt" )
_lowerCAmelCase : Optional[int] = encoding["pixel_values"]
_lowerCAmelCase : Any = model(_lowerCamelCase )
_lowerCAmelCase : List[Any] = outputs.logits
# verify logits
_lowerCAmelCase : Optional[Any] = [1, 16] if "rvlcdip" in checkpoint_url else [1, 196, 8_192]
assert logits.shape == torch.Size(_lowerCamelCase ), "Shape of logits not as expected"
Path(_lowerCamelCase ).mkdir(exist_ok=_lowerCamelCase )
print(F"Saving model to {pytorch_dump_folder_path}" )
model.save_pretrained(_lowerCamelCase )
print(F"Saving image processor to {pytorch_dump_folder_path}" )
image_processor.save_pretrained(_lowerCamelCase )
if push_to_hub:
if has_lm_head:
_lowerCAmelCase : Optional[int] = "dit-base" if "base" in checkpoint_url else "dit-large"
else:
_lowerCAmelCase : Dict = "dit-base-finetuned-rvlcdip" if "dit-b" in checkpoint_url else "dit-large-finetuned-rvlcdip"
image_processor.push_to_hub(
repo_path_or_name=Path(_lowerCamelCase , _lowerCamelCase ) , organization="nielsr" , commit_message="Add image processor" , use_temp_dir=_lowerCamelCase , )
model.push_to_hub(
repo_path_or_name=Path(_lowerCamelCase , _lowerCamelCase ) , organization="nielsr" , commit_message="Add model" , use_temp_dir=_lowerCamelCase , )
if __name__ == "__main__":
_snake_case = argparse.ArgumentParser()
parser.add_argument(
"--checkpoint_url",
default="https://layoutlm.blob.core.windows.net/dit/dit-pts/dit-base-224-p16-500k-62d53a.pth",
type=str,
help="URL to the original PyTorch checkpoint (.pth file).",
)
parser.add_argument(
"--pytorch_dump_folder_path", default=None, type=str, help="Path to the folder to output PyTorch model."
)
parser.add_argument(
"--push_to_hub",
action="store_true",
)
_snake_case = parser.parse_args()
convert_dit_checkpoint(args.checkpoint_url, args.pytorch_dump_folder_path, args.push_to_hub)
| 36
|
from ...utils import (
OptionalDependencyNotAvailable,
is_torch_available,
is_transformers_available,
is_transformers_version,
)
try:
if not (is_transformers_available() and is_torch_available() and is_transformers_version(">=", "4.25.0")):
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
from ...utils.dummy_torch_and_transformers_objects import (
VersatileDiffusionDualGuidedPipeline,
VersatileDiffusionImageVariationPipeline,
VersatileDiffusionPipeline,
VersatileDiffusionTextToImagePipeline,
)
else:
from .modeling_text_unet import UNetFlatConditionModel
from .pipeline_versatile_diffusion import VersatileDiffusionPipeline
from .pipeline_versatile_diffusion_dual_guided import VersatileDiffusionDualGuidedPipeline
from .pipeline_versatile_diffusion_image_variation import VersatileDiffusionImageVariationPipeline
from .pipeline_versatile_diffusion_text_to_image import VersatileDiffusionTextToImagePipeline
| 36
| 1
|
_snake_case = [
(1000, "M"),
(900, "CM"),
(500, "D"),
(400, "CD"),
(100, "C"),
(90, "XC"),
(50, "L"),
(40, "XL"),
(10, "X"),
(9, "IX"),
(5, "V"),
(4, "IV"),
(1, "I"),
]
def A ( _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : Optional[int] = {"I": 1, "V": 5, "X": 10, "L": 50, "C": 100, "D": 500, "M": 1_000}
_lowerCAmelCase : Union[str, Any] = 0
_lowerCAmelCase : Optional[int] = 0
while place < len(_lowerCamelCase ):
if (place + 1 < len(_lowerCamelCase )) and (vals[roman[place]] < vals[roman[place + 1]]):
total += vals[roman[place + 1]] - vals[roman[place]]
place += 2
else:
total += vals[roman[place]]
place += 1
return total
def A ( _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : str = []
for arabic, roman in ROMAN:
((_lowerCAmelCase) , (_lowerCAmelCase)) : List[str] = divmod(_lowerCamelCase , _lowerCamelCase )
result.append(roman * factor )
if number == 0:
break
return "".join(_lowerCamelCase )
if __name__ == "__main__":
import doctest
doctest.testmod()
| 36
|
import importlib.metadata
import operator
import re
import sys
from typing import Optional
from packaging import version
_snake_case = {
"<": operator.lt,
"<=": operator.le,
"==": operator.eq,
"!=": operator.ne,
">=": operator.ge,
">": operator.gt,
}
def A ( _lowerCamelCase , _lowerCamelCase , _lowerCamelCase , _lowerCamelCase , _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
if got_ver is None or want_ver is None:
raise ValueError(
F"Unable to compare versions for {requirement}: need={want_ver} found={got_ver}. This is unusual. Consider"
F" reinstalling {pkg}." )
if not ops[op](version.parse(_lowerCamelCase ) , version.parse(_lowerCamelCase ) ):
raise ImportError(
F"{requirement} is required for a normal functioning of this module, but found {pkg}=={got_ver}.{hint}" )
def A ( _lowerCamelCase , _lowerCamelCase = None ):
'''simple docstring'''
_lowerCAmelCase : List[str] = F"\n{hint}" if hint is not None else ""
# non-versioned check
if re.match(r"^[\w_\-\d]+$" , _lowerCamelCase ):
_lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase : List[str] = requirement, None, None
else:
_lowerCAmelCase : Optional[int] = re.findall(r"^([^!=<>\s]+)([\s!=<>]{1,2}.+)" , _lowerCamelCase )
if not match:
raise ValueError(
"requirement needs to be in the pip package format, .e.g., package_a==1.23, or package_b>=1.23, but"
F" got {requirement}" )
_lowerCAmelCase , _lowerCAmelCase : Dict = match[0]
_lowerCAmelCase : Any = want_full.split("," ) # there could be multiple requirements
_lowerCAmelCase : Optional[int] = {}
for w in want_range:
_lowerCAmelCase : Any = re.findall(r"^([\s!=<>]{1,2})(.+)" , _lowerCamelCase )
if not match:
raise ValueError(
"requirement needs to be in the pip package format, .e.g., package_a==1.23, or package_b>=1.23,"
F" but got {requirement}" )
_lowerCAmelCase , _lowerCAmelCase : Tuple = match[0]
_lowerCAmelCase : Union[str, Any] = want_ver
if op not in ops:
raise ValueError(F"{requirement}: need one of {list(ops.keys() )}, but got {op}" )
# special case
if pkg == "python":
_lowerCAmelCase : Tuple = ".".join([str(_lowerCamelCase ) for x in sys.version_info[:3]] )
for op, want_ver in wanted.items():
_compare_versions(_lowerCamelCase , _lowerCamelCase , _lowerCamelCase , _lowerCamelCase , _lowerCamelCase , _lowerCamelCase )
return
# check if any version is installed
try:
_lowerCAmelCase : Any = importlib.metadata.version(_lowerCamelCase )
except importlib.metadata.PackageNotFoundError:
raise importlib.metadata.PackageNotFoundError(
F"The '{requirement}' distribution was not found and is required by this application. {hint}" )
# check that the right version is installed if version number or a range was provided
if want_ver is not None:
for op, want_ver in wanted.items():
_compare_versions(_lowerCamelCase , _lowerCamelCase , _lowerCamelCase , _lowerCamelCase , _lowerCamelCase , _lowerCamelCase )
def A ( _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : List[str] = "Try: pip install transformers -U or pip install -e '.[dev]' if you're working with git main"
return require_version(_lowerCamelCase , _lowerCamelCase )
| 36
| 1
|
import argparse
from collections import OrderedDict
from pathlib import Path
import torch
from huggingface_hub import hf_hub_download
from PIL import Image
from torchvision.transforms import functional as F
from transformers import DetrImageProcessor, TableTransformerConfig, TableTransformerForObjectDetection
from transformers.utils import logging
logging.set_verbosity_info()
_snake_case = logging.get_logger(__name__)
# here we list all keys to be renamed (original name on the left, our name on the right)
_snake_case = []
for i in range(6):
# encoder layers: output projection, 2 feedforward neural networks and 2 layernorms
rename_keys.append(
(f'''transformer.encoder.layers.{i}.self_attn.out_proj.weight''', f'''encoder.layers.{i}.self_attn.out_proj.weight''')
)
rename_keys.append(
(f'''transformer.encoder.layers.{i}.self_attn.out_proj.bias''', f'''encoder.layers.{i}.self_attn.out_proj.bias''')
)
rename_keys.append((f'''transformer.encoder.layers.{i}.linear1.weight''', f'''encoder.layers.{i}.fc1.weight'''))
rename_keys.append((f'''transformer.encoder.layers.{i}.linear1.bias''', f'''encoder.layers.{i}.fc1.bias'''))
rename_keys.append((f'''transformer.encoder.layers.{i}.linear2.weight''', f'''encoder.layers.{i}.fc2.weight'''))
rename_keys.append((f'''transformer.encoder.layers.{i}.linear2.bias''', f'''encoder.layers.{i}.fc2.bias'''))
rename_keys.append(
(f'''transformer.encoder.layers.{i}.norm1.weight''', f'''encoder.layers.{i}.self_attn_layer_norm.weight''')
)
rename_keys.append((f'''transformer.encoder.layers.{i}.norm1.bias''', f'''encoder.layers.{i}.self_attn_layer_norm.bias'''))
rename_keys.append((f'''transformer.encoder.layers.{i}.norm2.weight''', f'''encoder.layers.{i}.final_layer_norm.weight'''))
rename_keys.append((f'''transformer.encoder.layers.{i}.norm2.bias''', f'''encoder.layers.{i}.final_layer_norm.bias'''))
# decoder layers: 2 times output projection, 2 feedforward neural networks and 3 layernorms
rename_keys.append(
(f'''transformer.decoder.layers.{i}.self_attn.out_proj.weight''', f'''decoder.layers.{i}.self_attn.out_proj.weight''')
)
rename_keys.append(
(f'''transformer.decoder.layers.{i}.self_attn.out_proj.bias''', f'''decoder.layers.{i}.self_attn.out_proj.bias''')
)
rename_keys.append(
(
f'''transformer.decoder.layers.{i}.multihead_attn.out_proj.weight''',
f'''decoder.layers.{i}.encoder_attn.out_proj.weight''',
)
)
rename_keys.append(
(
f'''transformer.decoder.layers.{i}.multihead_attn.out_proj.bias''',
f'''decoder.layers.{i}.encoder_attn.out_proj.bias''',
)
)
rename_keys.append((f'''transformer.decoder.layers.{i}.linear1.weight''', f'''decoder.layers.{i}.fc1.weight'''))
rename_keys.append((f'''transformer.decoder.layers.{i}.linear1.bias''', f'''decoder.layers.{i}.fc1.bias'''))
rename_keys.append((f'''transformer.decoder.layers.{i}.linear2.weight''', f'''decoder.layers.{i}.fc2.weight'''))
rename_keys.append((f'''transformer.decoder.layers.{i}.linear2.bias''', f'''decoder.layers.{i}.fc2.bias'''))
rename_keys.append(
(f'''transformer.decoder.layers.{i}.norm1.weight''', f'''decoder.layers.{i}.self_attn_layer_norm.weight''')
)
rename_keys.append((f'''transformer.decoder.layers.{i}.norm1.bias''', f'''decoder.layers.{i}.self_attn_layer_norm.bias'''))
rename_keys.append(
(f'''transformer.decoder.layers.{i}.norm2.weight''', f'''decoder.layers.{i}.encoder_attn_layer_norm.weight''')
)
rename_keys.append(
(f'''transformer.decoder.layers.{i}.norm2.bias''', f'''decoder.layers.{i}.encoder_attn_layer_norm.bias''')
)
rename_keys.append((f'''transformer.decoder.layers.{i}.norm3.weight''', f'''decoder.layers.{i}.final_layer_norm.weight'''))
rename_keys.append((f'''transformer.decoder.layers.{i}.norm3.bias''', f'''decoder.layers.{i}.final_layer_norm.bias'''))
# convolutional projection + query embeddings + layernorm of encoder + layernorm of decoder + class and bounding box heads
rename_keys.extend(
[
("input_proj.weight", "input_projection.weight"),
("input_proj.bias", "input_projection.bias"),
("query_embed.weight", "query_position_embeddings.weight"),
("transformer.encoder.norm.weight", "encoder.layernorm.weight"),
("transformer.encoder.norm.bias", "encoder.layernorm.bias"),
("transformer.decoder.norm.weight", "decoder.layernorm.weight"),
("transformer.decoder.norm.bias", "decoder.layernorm.bias"),
("class_embed.weight", "class_labels_classifier.weight"),
("class_embed.bias", "class_labels_classifier.bias"),
("bbox_embed.layers.0.weight", "bbox_predictor.layers.0.weight"),
("bbox_embed.layers.0.bias", "bbox_predictor.layers.0.bias"),
("bbox_embed.layers.1.weight", "bbox_predictor.layers.1.weight"),
("bbox_embed.layers.1.bias", "bbox_predictor.layers.1.bias"),
("bbox_embed.layers.2.weight", "bbox_predictor.layers.2.weight"),
("bbox_embed.layers.2.bias", "bbox_predictor.layers.2.bias"),
]
)
def A ( _lowerCamelCase , _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : Dict = state_dict.pop(_lowerCamelCase )
_lowerCAmelCase : Tuple = val
def A ( _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : Tuple = OrderedDict()
for key, value in state_dict.items():
if "backbone.0.body" in key:
_lowerCAmelCase : Optional[Any] = key.replace("backbone.0.body" , "backbone.conv_encoder.model" )
_lowerCAmelCase : Union[str, Any] = value
else:
_lowerCAmelCase : Union[str, Any] = value
return new_state_dict
def A ( _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : Dict = ""
# first: transformer encoder
for i in range(6 ):
# read in weights + bias of input projection layer (in PyTorch's MultiHeadAttention, this is a single matrix + bias)
_lowerCAmelCase : List[str] = state_dict.pop(F"{prefix}transformer.encoder.layers.{i}.self_attn.in_proj_weight" )
_lowerCAmelCase : List[str] = state_dict.pop(F"{prefix}transformer.encoder.layers.{i}.self_attn.in_proj_bias" )
# next, add query, keys and values (in that order) to the state dict
_lowerCAmelCase : int = in_proj_weight[:256, :]
_lowerCAmelCase : int = in_proj_bias[:256]
_lowerCAmelCase : List[str] = in_proj_weight[256:512, :]
_lowerCAmelCase : Dict = in_proj_bias[256:512]
_lowerCAmelCase : Tuple = in_proj_weight[-256:, :]
_lowerCAmelCase : str = in_proj_bias[-256:]
# next: transformer decoder (which is a bit more complex because it also includes cross-attention)
for i in range(6 ):
# read in weights + bias of input projection layer of self-attention
_lowerCAmelCase : int = state_dict.pop(F"{prefix}transformer.decoder.layers.{i}.self_attn.in_proj_weight" )
_lowerCAmelCase : Optional[int] = state_dict.pop(F"{prefix}transformer.decoder.layers.{i}.self_attn.in_proj_bias" )
# next, add query, keys and values (in that order) to the state dict
_lowerCAmelCase : List[str] = in_proj_weight[:256, :]
_lowerCAmelCase : Optional[int] = in_proj_bias[:256]
_lowerCAmelCase : List[Any] = in_proj_weight[256:512, :]
_lowerCAmelCase : Union[str, Any] = in_proj_bias[256:512]
_lowerCAmelCase : List[Any] = in_proj_weight[-256:, :]
_lowerCAmelCase : Dict = in_proj_bias[-256:]
# read in weights + bias of input projection layer of cross-attention
_lowerCAmelCase : Optional[Any] = state_dict.pop(
F"{prefix}transformer.decoder.layers.{i}.multihead_attn.in_proj_weight" )
_lowerCAmelCase : Optional[Any] = state_dict.pop(F"{prefix}transformer.decoder.layers.{i}.multihead_attn.in_proj_bias" )
# next, add query, keys and values (in that order) of cross-attention to the state dict
_lowerCAmelCase : List[Any] = in_proj_weight_cross_attn[:256, :]
_lowerCAmelCase : List[str] = in_proj_bias_cross_attn[:256]
_lowerCAmelCase : Union[str, Any] = in_proj_weight_cross_attn[256:512, :]
_lowerCAmelCase : List[str] = in_proj_bias_cross_attn[256:512]
_lowerCAmelCase : Tuple = in_proj_weight_cross_attn[-256:, :]
_lowerCAmelCase : Any = in_proj_bias_cross_attn[-256:]
def A ( _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase , _lowerCAmelCase : Tuple = image.size
_lowerCAmelCase : Union[str, Any] = max(_lowerCamelCase , _lowerCamelCase )
_lowerCAmelCase : Any = 800 if "detection" in checkpoint_url else 1_000
_lowerCAmelCase : Optional[int] = target_max_size / current_max_size
_lowerCAmelCase : Optional[Any] = image.resize((int(round(scale * width ) ), int(round(scale * height ) )) )
return resized_image
def A ( _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : List[Any] = F.to_tensor(_lowerCamelCase )
_lowerCAmelCase : Optional[Any] = F.normalize(_lowerCamelCase , mean=[0.4_85, 0.4_56, 0.4_06] , std=[0.2_29, 0.2_24, 0.2_25] )
return image
@torch.no_grad()
def A ( _lowerCamelCase , _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
logger.info("Converting model..." )
# load original state dict
_lowerCAmelCase : int = torch.hub.load_state_dict_from_url(_lowerCamelCase , map_location="cpu" )
# rename keys
for src, dest in rename_keys:
rename_key(_lowerCamelCase , _lowerCamelCase , _lowerCamelCase )
_lowerCAmelCase : int = rename_backbone_keys(_lowerCamelCase )
# query, key and value matrices need special treatment
read_in_q_k_v(_lowerCamelCase )
# important: we need to prepend a prefix to each of the base model keys as the head models use different attributes for them
_lowerCAmelCase : Union[str, Any] = "model."
for key in state_dict.copy().keys():
if not key.startswith("class_labels_classifier" ) and not key.startswith("bbox_predictor" ):
_lowerCAmelCase : Tuple = state_dict.pop(_lowerCamelCase )
_lowerCAmelCase : Union[str, Any] = val
# create HuggingFace model and load state dict
_lowerCAmelCase : str = TableTransformerConfig(
backbone="resnet18" , mask_loss_coefficient=1 , dice_loss_coefficient=1 , ce_loss_coefficient=1 , bbox_loss_coefficient=5 , giou_loss_coefficient=2 , eos_coefficient=0.4 , class_cost=1 , bbox_cost=5 , giou_cost=2 , )
if "detection" in checkpoint_url:
_lowerCAmelCase : Any = 15
_lowerCAmelCase : Any = 2
_lowerCAmelCase : List[str] = {0: "table", 1: "table rotated"}
_lowerCAmelCase : int = idalabel
_lowerCAmelCase : List[str] = {v: k for k, v in idalabel.items()}
else:
_lowerCAmelCase : Any = 125
_lowerCAmelCase : List[Any] = 6
_lowerCAmelCase : Any = {
0: "table",
1: "table column",
2: "table row",
3: "table column header",
4: "table projected row header",
5: "table spanning cell",
}
_lowerCAmelCase : Optional[Any] = idalabel
_lowerCAmelCase : Union[str, Any] = {v: k for k, v in idalabel.items()}
_lowerCAmelCase : List[Any] = DetrImageProcessor(
format="coco_detection" , max_size=800 if "detection" in checkpoint_url else 1_000 )
_lowerCAmelCase : Tuple = TableTransformerForObjectDetection(_lowerCamelCase )
model.load_state_dict(_lowerCamelCase )
model.eval()
# verify our conversion
_lowerCAmelCase : List[str] = "example_pdf.png" if "detection" in checkpoint_url else "example_table.png"
_lowerCAmelCase : Tuple = hf_hub_download(repo_id="nielsr/example-pdf" , repo_type="dataset" , filename=_lowerCamelCase )
_lowerCAmelCase : str = Image.open(_lowerCamelCase ).convert("RGB" )
_lowerCAmelCase : List[Any] = normalize(resize(_lowerCamelCase , _lowerCamelCase ) ).unsqueeze(0 )
_lowerCAmelCase : List[str] = model(_lowerCamelCase )
if "detection" in checkpoint_url:
_lowerCAmelCase : Optional[Any] = (1, 15, 3)
_lowerCAmelCase : Optional[int] = torch.tensor(
[[-6.78_97, -16.99_85, 6.79_37], [-8.01_86, -22.21_92, 6.96_77], [-7.31_17, -21.07_08, 7.40_55]] )
_lowerCAmelCase : Any = torch.tensor([[0.48_67, 0.17_67, 0.67_32], [0.67_18, 0.44_79, 0.38_30], [0.47_16, 0.17_60, 0.63_64]] )
else:
_lowerCAmelCase : Optional[int] = (1, 125, 7)
_lowerCAmelCase : int = torch.tensor(
[[-18.14_30, -8.32_14, 4.82_74], [-18.46_85, -7.13_61, -4.26_67], [-26.36_93, -9.34_29, -4.99_62]] )
_lowerCAmelCase : List[Any] = torch.tensor([[0.49_83, 0.55_95, 0.94_40], [0.49_16, 0.63_15, 0.59_54], [0.61_08, 0.86_37, 0.11_35]] )
assert outputs.logits.shape == expected_shape
assert torch.allclose(outputs.logits[0, :3, :3] , _lowerCamelCase , atol=1e-4 )
assert torch.allclose(outputs.pred_boxes[0, :3, :3] , _lowerCamelCase , atol=1e-4 )
print("Looks ok!" )
if pytorch_dump_folder_path is not None:
# Save model and image processor
logger.info(F"Saving PyTorch model and image processor to {pytorch_dump_folder_path}..." )
Path(_lowerCamelCase ).mkdir(exist_ok=_lowerCamelCase )
model.save_pretrained(_lowerCamelCase )
image_processor.save_pretrained(_lowerCamelCase )
if push_to_hub:
# Push model to HF hub
logger.info("Pushing model to the hub..." )
_lowerCAmelCase : Tuple = (
"microsoft/table-transformer-detection"
if "detection" in checkpoint_url
else "microsoft/table-transformer-structure-recognition"
)
model.push_to_hub(_lowerCamelCase )
image_processor.push_to_hub(_lowerCamelCase )
if __name__ == "__main__":
_snake_case = argparse.ArgumentParser()
parser.add_argument(
"--checkpoint_url",
default="https://pubtables1m.blob.core.windows.net/model/pubtables1m_detection_detr_r18.pth",
type=str,
choices=[
"https://pubtables1m.blob.core.windows.net/model/pubtables1m_detection_detr_r18.pth",
"https://pubtables1m.blob.core.windows.net/model/pubtables1m_structure_detr_r18.pth",
],
help="URL of the Table Transformer checkpoint you'd like to convert.",
)
parser.add_argument(
"--pytorch_dump_folder_path", default=None, type=str, help="Path to the folder to output PyTorch model."
)
parser.add_argument(
"--push_to_hub", action="store_true", help="Whether or not to push the converted model to the 🤗 hub."
)
_snake_case = parser.parse_args()
convert_table_transformer_checkpoint(args.checkpoint_url, args.pytorch_dump_folder_path, args.push_to_hub)
| 36
|
import argparse
from collections import defaultdict
import yaml
_snake_case = "docs/source/en/_toctree.yml"
def A ( _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : Dict = defaultdict(_lowerCamelCase )
_lowerCAmelCase : Any = []
_lowerCAmelCase : List[str] = []
for doc in doc_list:
if "local" in doc:
counts[doc["local"]] += 1
if doc["title"].lower() == "overview":
overview_doc.append({"local": doc["local"], "title": doc["title"]} )
else:
new_doc_list.append(_lowerCamelCase )
_lowerCAmelCase : Optional[Any] = new_doc_list
_lowerCAmelCase : List[Any] = [key for key, value in counts.items() if value > 1]
_lowerCAmelCase : str = []
for duplicate_key in duplicates:
_lowerCAmelCase : List[str] = list({doc["title"] for doc in doc_list if doc["local"] == duplicate_key} )
if len(_lowerCamelCase ) > 1:
raise ValueError(
F"{duplicate_key} is present several times in the documentation table of content at "
"`docs/source/en/_toctree.yml` with different *Title* values. Choose one of those and remove the "
"others." )
# Only add this once
new_doc.append({"local": duplicate_key, "title": titles[0]} )
# Add none duplicate-keys
new_doc.extend([doc for doc in doc_list if "local" not in counts or counts[doc["local"]] == 1] )
_lowerCAmelCase : Optional[Any] = sorted(_lowerCamelCase , key=lambda _lowerCamelCase : s["title"].lower() )
# "overview" gets special treatment and is always first
if len(_lowerCamelCase ) > 1:
raise ValueError("{doc_list} has two 'overview' docs which is not allowed." )
overview_doc.extend(_lowerCamelCase )
# Sort
return overview_doc
def A ( _lowerCamelCase=False ):
'''simple docstring'''
with open(_lowerCamelCase , encoding="utf-8" ) as f:
_lowerCAmelCase : int = yaml.safe_load(f.read() )
# Get to the API doc
_lowerCAmelCase : Optional[Any] = 0
while content[api_idx]["title"] != "API":
api_idx += 1
_lowerCAmelCase : List[str] = content[api_idx]["sections"]
# Then to the model doc
_lowerCAmelCase : Union[str, Any] = 0
while api_doc[scheduler_idx]["title"] != "Schedulers":
scheduler_idx += 1
_lowerCAmelCase : Optional[Any] = api_doc[scheduler_idx]["sections"]
_lowerCAmelCase : Optional[Any] = clean_doc_toc(_lowerCamelCase )
_lowerCAmelCase : int = False
if new_scheduler_doc != scheduler_doc:
_lowerCAmelCase : List[Any] = True
if overwrite:
_lowerCAmelCase : Dict = new_scheduler_doc
if diff:
if overwrite:
_lowerCAmelCase : Tuple = api_doc
with open(_lowerCamelCase , "w" , encoding="utf-8" ) as f:
f.write(yaml.dump(_lowerCamelCase , allow_unicode=_lowerCamelCase ) )
else:
raise ValueError(
"The model doc part of the table of content is not properly sorted, run `make style` to fix this." )
def A ( _lowerCamelCase=False ):
'''simple docstring'''
with open(_lowerCamelCase , encoding="utf-8" ) as f:
_lowerCAmelCase : Tuple = yaml.safe_load(f.read() )
# Get to the API doc
_lowerCAmelCase : Optional[int] = 0
while content[api_idx]["title"] != "API":
api_idx += 1
_lowerCAmelCase : int = content[api_idx]["sections"]
# Then to the model doc
_lowerCAmelCase : List[str] = 0
while api_doc[pipeline_idx]["title"] != "Pipelines":
pipeline_idx += 1
_lowerCAmelCase : Dict = False
_lowerCAmelCase : Optional[int] = api_doc[pipeline_idx]["sections"]
_lowerCAmelCase : Tuple = []
# sort sub pipeline docs
for pipeline_doc in pipeline_docs:
if "section" in pipeline_doc:
_lowerCAmelCase : List[Any] = pipeline_doc["section"]
_lowerCAmelCase : Union[str, Any] = clean_doc_toc(_lowerCamelCase )
if overwrite:
_lowerCAmelCase : Optional[Any] = new_sub_pipeline_doc
new_pipeline_docs.append(_lowerCamelCase )
# sort overall pipeline doc
_lowerCAmelCase : Union[str, Any] = clean_doc_toc(_lowerCamelCase )
if new_pipeline_docs != pipeline_docs:
_lowerCAmelCase : Dict = True
if overwrite:
_lowerCAmelCase : Optional[int] = new_pipeline_docs
if diff:
if overwrite:
_lowerCAmelCase : Optional[int] = api_doc
with open(_lowerCamelCase , "w" , encoding="utf-8" ) as f:
f.write(yaml.dump(_lowerCamelCase , allow_unicode=_lowerCamelCase ) )
else:
raise ValueError(
"The model doc part of the table of content is not properly sorted, run `make style` to fix this." )
if __name__ == "__main__":
_snake_case = argparse.ArgumentParser()
parser.add_argument("--fix_and_overwrite", action="store_true", help="Whether to fix inconsistencies.")
_snake_case = parser.parse_args()
check_scheduler_doc(args.fix_and_overwrite)
check_pipeline_doc(args.fix_and_overwrite)
| 36
| 1
|
from typing import List
from ...configuration_utils import PretrainedConfig
from ...utils import logging
_snake_case = logging.get_logger(__name__)
_snake_case = {
"snap-research/efficientformer-l1-300": (
"https://huggingface.co/snap-research/efficientformer-l1-300/resolve/main/config.json"
),
}
class UpperCAmelCase_ ( a):
lowerCamelCase__ = 'efficientformer'
def __init__( self, __a = [3, 2, 6, 4], __a = [48, 96, 224, 448], __a = [True, True, True, True], __a = 448, __a = 32, __a = 4, __a = 7, __a = 5, __a = 8, __a = 4, __a = 0.0, __a = 16, __a = 3, __a = 3, __a = 3, __a = 2, __a = 1, __a = 0.0, __a = 1, __a = True, __a = True, __a = 1E-5, __a = "gelu", __a = 0.02, __a = 1E-12, __a = 224, __a = 1E-05, **__a, ):
'''simple docstring'''
super().__init__(**__a)
_lowerCAmelCase : Tuple = hidden_act
_lowerCAmelCase : List[str] = hidden_dropout_prob
_lowerCAmelCase : str = hidden_sizes
_lowerCAmelCase : Union[str, Any] = num_hidden_layers
_lowerCAmelCase : Dict = num_attention_heads
_lowerCAmelCase : List[Any] = initializer_range
_lowerCAmelCase : Dict = layer_norm_eps
_lowerCAmelCase : List[str] = patch_size
_lowerCAmelCase : Optional[Any] = num_channels
_lowerCAmelCase : Tuple = depths
_lowerCAmelCase : str = mlp_expansion_ratio
_lowerCAmelCase : List[str] = downsamples
_lowerCAmelCase : int = dim
_lowerCAmelCase : Any = key_dim
_lowerCAmelCase : Optional[Any] = attention_ratio
_lowerCAmelCase : int = resolution
_lowerCAmelCase : Tuple = pool_size
_lowerCAmelCase : Optional[int] = downsample_patch_size
_lowerCAmelCase : List[str] = downsample_stride
_lowerCAmelCase : str = downsample_pad
_lowerCAmelCase : Any = drop_path_rate
_lowerCAmelCase : Tuple = num_metaad_blocks
_lowerCAmelCase : Dict = distillation
_lowerCAmelCase : List[str] = use_layer_scale
_lowerCAmelCase : Dict = layer_scale_init_value
_lowerCAmelCase : Optional[int] = image_size
_lowerCAmelCase : Any = batch_norm_eps
| 36
|
def A ( _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
if density <= 0:
raise ValueError("Impossible fluid density" )
if bulk_modulus <= 0:
raise ValueError("Impossible bulk modulus" )
return (bulk_modulus / density) ** 0.5
if __name__ == "__main__":
import doctest
doctest.testmod()
| 36
| 1
|
from typing import TYPE_CHECKING
from ...utils import OptionalDependencyNotAvailable, _LazyModule, is_torch_available
_snake_case = {"configuration_sew": ["SEW_PRETRAINED_CONFIG_ARCHIVE_MAP", "SEWConfig"]}
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
_snake_case = [
"SEW_PRETRAINED_MODEL_ARCHIVE_LIST",
"SEWForCTC",
"SEWForSequenceClassification",
"SEWModel",
"SEWPreTrainedModel",
]
if TYPE_CHECKING:
from .configuration_sew import SEW_PRETRAINED_CONFIG_ARCHIVE_MAP, SEWConfig
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_sew import (
SEW_PRETRAINED_MODEL_ARCHIVE_LIST,
SEWForCTC,
SEWForSequenceClassification,
SEWModel,
SEWPreTrainedModel,
)
else:
import sys
_snake_case = _LazyModule(__name__, globals()["__file__"], _import_structure, module_spec=__spec__)
| 36
|
from typing import Dict
from transformers import EvalPrediction, HfArgumentParser, TrainingArguments, is_torch_available
from transformers.testing_utils import (
TestCasePlus,
execute_subprocess_async,
get_torch_dist_unique_port,
require_torch_multi_gpu,
require_torch_neuroncore,
)
from transformers.training_args import ParallelMode
from transformers.utils import logging
_snake_case = logging.get_logger(__name__)
if is_torch_available():
import torch
from torch import nn
from torch.utils.data import Dataset
from transformers import Trainer
class UpperCAmelCase_ ( a):
def __init__( self, __a = 101):
'''simple docstring'''
_lowerCAmelCase : str = length
def __len__( self):
'''simple docstring'''
return self.length
def __getitem__( self, __a):
'''simple docstring'''
return i
class UpperCAmelCase_ :
def __call__( self, __a):
'''simple docstring'''
return {"input_ids": torch.tensor(__a), "labels": torch.tensor(__a)}
class UpperCAmelCase_ ( nn.Module):
def __init__( self):
'''simple docstring'''
super().__init__()
# Add some (unused) params otherwise DDP will complain.
_lowerCAmelCase : str = nn.Linear(120, 80)
def snake_case__ ( self, __a, __a=None):
'''simple docstring'''
if labels is not None:
return torch.tensor(0.0, device=input_ids.device), input_ids
else:
return input_ids
class UpperCAmelCase_ ( a):
@require_torch_neuroncore
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : int = f"--nproc_per_node=2\n --master_port={get_torch_dist_unique_port()}\n {self.test_file_dir}/test_trainer_distributed.py\n ".split()
_lowerCAmelCase : Tuple = self.get_auto_remove_tmp_dir()
_lowerCAmelCase : Optional[int] = f"--output_dir {output_dir}".split()
_lowerCAmelCase : List[Any] = ["torchrun"] + distributed_args + args
execute_subprocess_async(__a, env=self.get_env())
# successful return here == success - any errors would have caused an error in the sub-call
class UpperCAmelCase_ ( a):
@require_torch_multi_gpu
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Dict = f"--nproc_per_node={torch.cuda.device_count()}\n --master_port={get_torch_dist_unique_port()}\n {self.test_file_dir}/test_trainer_distributed.py\n ".split()
_lowerCAmelCase : Any = self.get_auto_remove_tmp_dir()
_lowerCAmelCase : Optional[int] = f"--output_dir {output_dir}".split()
_lowerCAmelCase : Any = ["torchrun"] + distributed_args + args
execute_subprocess_async(__a, env=self.get_env())
# successful return here == success - any errors would have caused an error in the sub-call
if __name__ == "__main__":
# The script below is meant to be run under torch.distributed, on a machine with multiple GPUs:
#
# PYTHONPATH="src" python -m torch.distributed.run --nproc_per_node 2 --output_dir output_dir ./tests/test_trainer_distributed.py
_snake_case = HfArgumentParser((TrainingArguments,))
_snake_case = parser.parse_args_into_dataclasses()[0]
logger.warning(
f'''Process rank: {training_args.local_rank}, device: {training_args.device}, n_gpu: {training_args.n_gpu}, '''
f'''distributed training: {training_args.parallel_mode != ParallelMode.NOT_DISTRIBUTED}'''
)
# Essentially, what we want to verify in the distributed case is that we get all samples back,
# in the right order. (this is crucial for prediction for instance)
for dataset_length in [101, 40, 7]:
_snake_case = DummyDataset(dataset_length)
def A ( _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : Dict = list(range(len(_lowerCamelCase ) ) )
_lowerCAmelCase : Union[str, Any] = p.predictions.tolist() == sequential and p.label_ids.tolist() == sequential
if not success and training_args.local_rank == 0:
logger.warning(
"Predictions and/or labels do not match expected results:\n - predictions: "
F"{p.predictions.tolist()}\n - labels: {p.label_ids.tolist()}\n - expected: {sequential}" )
return {"success": success}
_snake_case = Trainer(
model=DummyModel(),
args=training_args,
data_collator=DummyDataCollator(),
eval_dataset=dataset,
compute_metrics=compute_metrics,
)
_snake_case = trainer.evaluate()
logger.info(metrics)
if metrics["eval_success"] is not True:
logger.error(metrics)
exit(1)
_snake_case = trainer.predict(dataset)
logger.info(p.metrics)
if p.metrics["test_success"] is not True:
logger.error(p.metrics)
exit(1)
_snake_case = 2
_snake_case = trainer.evaluate()
logger.info(metrics)
if metrics["eval_success"] is not True:
logger.error(metrics)
exit(1)
_snake_case = trainer.predict(dataset)
logger.info(p.metrics)
if p.metrics["test_success"] is not True:
logger.error(p.metrics)
exit(1)
_snake_case = None
| 36
| 1
|
import functools
import operator
from ...configuration_utils import PretrainedConfig
from ...utils import logging
_snake_case = logging.get_logger(__name__)
_snake_case = {
"asapp/sew-d-tiny-100k": "https://huggingface.co/asapp/sew-d-tiny-100k/resolve/main/config.json",
# See all SEW-D models at https://huggingface.co/models?filter=sew-d
}
class UpperCAmelCase_ ( a):
lowerCamelCase__ = 'sew-d'
def __init__( self, __a=32, __a=768, __a=12, __a=12, __a=3072, __a=2, __a=512, __a=256, __a=True, __a=True, __a=("p2c", "c2p"), __a="layer_norm", __a="gelu_python", __a=0.1, __a=0.1, __a=0.1, __a=0.0, __a=0.1, __a=0.02, __a=1E-7, __a=1E-5, __a="group", __a="gelu", __a=(64, 128, 128, 128, 128, 256, 256, 256, 256, 512, 512, 512, 512), __a=(5, 2, 1, 2, 1, 2, 1, 2, 1, 2, 1, 2, 1), __a=(10, 3, 1, 3, 1, 3, 1, 3, 1, 2, 1, 2, 1), __a=False, __a=128, __a=16, __a=True, __a=0.05, __a=10, __a=2, __a=0.0, __a=10, __a=0, __a="mean", __a=False, __a=False, __a=256, __a=0, __a=1, __a=2, **__a, ):
'''simple docstring'''
super().__init__(**__a, pad_token_id=__a, bos_token_id=__a, eos_token_id=__a)
_lowerCAmelCase : Tuple = hidden_size
_lowerCAmelCase : List[Any] = feat_extract_norm
_lowerCAmelCase : Dict = feat_extract_activation
_lowerCAmelCase : Dict = list(__a)
_lowerCAmelCase : Dict = list(__a)
_lowerCAmelCase : List[str] = list(__a)
_lowerCAmelCase : Dict = conv_bias
_lowerCAmelCase : str = num_conv_pos_embeddings
_lowerCAmelCase : int = num_conv_pos_embedding_groups
_lowerCAmelCase : Dict = len(self.conv_dim)
_lowerCAmelCase : List[str] = num_hidden_layers
_lowerCAmelCase : List[Any] = intermediate_size
_lowerCAmelCase : Dict = squeeze_factor
_lowerCAmelCase : Any = max_position_embeddings
_lowerCAmelCase : Optional[Any] = position_buckets
_lowerCAmelCase : Optional[int] = share_att_key
_lowerCAmelCase : str = relative_attention
_lowerCAmelCase : Dict = norm_rel_ebd
_lowerCAmelCase : Optional[int] = list(__a)
_lowerCAmelCase : List[str] = hidden_act
_lowerCAmelCase : Union[str, Any] = num_attention_heads
_lowerCAmelCase : Optional[Any] = hidden_dropout
_lowerCAmelCase : Dict = attention_dropout
_lowerCAmelCase : str = activation_dropout
_lowerCAmelCase : Optional[Any] = feat_proj_dropout
_lowerCAmelCase : Tuple = final_dropout
_lowerCAmelCase : Dict = layer_norm_eps
_lowerCAmelCase : Union[str, Any] = feature_layer_norm_eps
_lowerCAmelCase : str = initializer_range
_lowerCAmelCase : str = vocab_size
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)`,"
f"but is `len(config.conv_dim) = {len(self.conv_dim)}`, `len(config.conv_stride)"
f"= {len(self.conv_stride)}`, `len(config.conv_kernel) = {len(self.conv_kernel)}`.")
# fine-tuning config parameters for SpecAugment: https://arxiv.org/abs/1904.08779
_lowerCAmelCase : List[Any] = apply_spec_augment
_lowerCAmelCase : Optional[int] = mask_time_prob
_lowerCAmelCase : Any = mask_time_length
_lowerCAmelCase : Tuple = mask_time_min_masks
_lowerCAmelCase : List[str] = mask_feature_prob
_lowerCAmelCase : List[str] = mask_feature_length
_lowerCAmelCase : Tuple = mask_feature_min_masks
# ctc loss
_lowerCAmelCase : Optional[Any] = ctc_loss_reduction
_lowerCAmelCase : List[str] = ctc_zero_infinity
# sequence classification
_lowerCAmelCase : Optional[int] = use_weighted_layer_sum
_lowerCAmelCase : Union[str, Any] = classifier_proj_size
@property
def snake_case__ ( self):
'''simple docstring'''
return functools.reduce(operator.mul, self.conv_stride, 1)
| 36
|
from __future__ import annotations
import bisect
def A ( _lowerCamelCase , _lowerCamelCase , _lowerCamelCase = 0 , _lowerCamelCase = -1 ):
'''simple docstring'''
if hi < 0:
_lowerCAmelCase : int = len(_lowerCamelCase )
while lo < hi:
_lowerCAmelCase : Optional[Any] = lo + (hi - lo) // 2
if sorted_collection[mid] < item:
_lowerCAmelCase : Union[str, Any] = mid + 1
else:
_lowerCAmelCase : str = mid
return lo
def A ( _lowerCamelCase , _lowerCamelCase , _lowerCamelCase = 0 , _lowerCamelCase = -1 ):
'''simple docstring'''
if hi < 0:
_lowerCAmelCase : str = len(_lowerCamelCase )
while lo < hi:
_lowerCAmelCase : Tuple = lo + (hi - lo) // 2
if sorted_collection[mid] <= item:
_lowerCAmelCase : Dict = mid + 1
else:
_lowerCAmelCase : str = mid
return lo
def A ( _lowerCamelCase , _lowerCamelCase , _lowerCamelCase = 0 , _lowerCamelCase = -1 ):
'''simple docstring'''
sorted_collection.insert(bisect_left(_lowerCamelCase , _lowerCamelCase , _lowerCamelCase , _lowerCamelCase ) , _lowerCamelCase )
def A ( _lowerCamelCase , _lowerCamelCase , _lowerCamelCase = 0 , _lowerCamelCase = -1 ):
'''simple docstring'''
sorted_collection.insert(bisect_right(_lowerCamelCase , _lowerCamelCase , _lowerCamelCase , _lowerCamelCase ) , _lowerCamelCase )
def A ( _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : int = 0
_lowerCAmelCase : Union[str, Any] = len(_lowerCamelCase ) - 1
while left <= right:
_lowerCAmelCase : int = left + (right - left) // 2
_lowerCAmelCase : int = sorted_collection[midpoint]
if current_item == item:
return midpoint
elif item < current_item:
_lowerCAmelCase : str = midpoint - 1
else:
_lowerCAmelCase : Any = midpoint + 1
return None
def A ( _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : Tuple = bisect.bisect_left(_lowerCamelCase , _lowerCamelCase )
if index != len(_lowerCamelCase ) and sorted_collection[index] == item:
return index
return None
def A ( _lowerCamelCase , _lowerCamelCase , _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
if right < left:
return None
_lowerCAmelCase : Optional[int] = left + (right - left) // 2
if sorted_collection[midpoint] == item:
return midpoint
elif sorted_collection[midpoint] > item:
return binary_search_by_recursion(_lowerCamelCase , _lowerCamelCase , _lowerCamelCase , midpoint - 1 )
else:
return binary_search_by_recursion(_lowerCamelCase , _lowerCamelCase , midpoint + 1 , _lowerCamelCase )
if __name__ == "__main__":
_snake_case = input("Enter numbers separated by comma:\n").strip()
_snake_case = sorted(int(item) for item in user_input.split(","))
_snake_case = int(input("Enter a single number to be found in the list:\n"))
_snake_case = binary_search(collection, target)
if result is None:
print(f'''{target} was not found in {collection}.''')
else:
print(f'''{target} was found at position {result} in {collection}.''')
| 36
| 1
|
def A ( _lowerCamelCase = 50 ):
'''simple docstring'''
_lowerCAmelCase : str = [1] * (length + 1)
for row_length in range(3 , length + 1 ):
for block_length in range(3 , row_length + 1 ):
for block_start in range(row_length - block_length ):
ways_number[row_length] += ways_number[
row_length - block_start - block_length - 1
]
ways_number[row_length] += 1
return ways_number[length]
if __name__ == "__main__":
print(f'''{solution() = }''')
| 36
|
from __future__ import annotations
from math import pi
from typing import Protocol
import matplotlib.pyplot as plt
import numpy as np
class UpperCAmelCase_ ( a):
def snake_case__ ( self, __a):
'''simple docstring'''
return 0.0
def A ( _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : Optional[Any] = min([-20, np.min(fft_results[1 : samplerate // 2 - 1] )] )
_lowerCAmelCase : Optional[int] = max([20, np.max(fft_results[1 : samplerate // 2 - 1] )] )
return lowest, highest
def A ( _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : int = 512
_lowerCAmelCase : Union[str, Any] = [1] + [0] * (size - 1)
_lowerCAmelCase : Optional[Any] = [filter_type.process(_lowerCamelCase ) for item in inputs]
_lowerCAmelCase : int = [0] * (samplerate - size) # zero-padding
outputs += filler
_lowerCAmelCase : str = np.abs(np.fft.fft(_lowerCamelCase ) )
_lowerCAmelCase : Union[str, Any] = 20 * np.logaa(_lowerCamelCase )
# Frequencies on log scale from 24 to nyquist frequency
plt.xlim(24 , samplerate / 2 - 1 )
plt.xlabel("Frequency (Hz)" )
plt.xscale("log" )
# Display within reasonable bounds
_lowerCAmelCase : List[Any] = get_bounds(_lowerCamelCase , _lowerCamelCase )
plt.ylim(max([-80, bounds[0]] ) , min([80, bounds[1]] ) )
plt.ylabel("Gain (dB)" )
plt.plot(_lowerCamelCase )
plt.show()
def A ( _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : Union[str, Any] = 512
_lowerCAmelCase : Optional[Any] = [1] + [0] * (size - 1)
_lowerCAmelCase : str = [filter_type.process(_lowerCamelCase ) for item in inputs]
_lowerCAmelCase : Optional[Any] = [0] * (samplerate - size) # zero-padding
outputs += filler
_lowerCAmelCase : Optional[Any] = np.angle(np.fft.fft(_lowerCamelCase ) )
# Frequencies on log scale from 24 to nyquist frequency
plt.xlim(24 , samplerate / 2 - 1 )
plt.xlabel("Frequency (Hz)" )
plt.xscale("log" )
plt.ylim(-2 * pi , 2 * pi )
plt.ylabel("Phase shift (Radians)" )
plt.plot(np.unwrap(_lowerCamelCase , -2 * pi ) )
plt.show()
| 36
| 1
|
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_tf_available():
import tensorflow as tf
from ..models.auto.modeling_tf_auto import TF_MODEL_FOR_IMAGE_CLASSIFICATION_MAPPING
from ..tf_utils import stable_softmax
if is_torch_available():
from ..models.auto.modeling_auto import MODEL_FOR_IMAGE_CLASSIFICATION_MAPPING
_snake_case = logging.get_logger(__name__)
@add_end_docstrings(a)
class UpperCAmelCase_ ( a):
def __init__( self, *__a, **__a):
'''simple docstring'''
super().__init__(*__a, **__a)
requires_backends(self, "vision")
self.check_model_type(
TF_MODEL_FOR_IMAGE_CLASSIFICATION_MAPPING
if self.framework == "tf"
else MODEL_FOR_IMAGE_CLASSIFICATION_MAPPING)
def snake_case__ ( self, __a=None):
'''simple docstring'''
_lowerCAmelCase : Any = {}
if top_k is not None:
_lowerCAmelCase : Dict = top_k
return {}, {}, postprocess_params
def __call__( self, __a, **__a):
'''simple docstring'''
return super().__call__(__a, **__a)
def snake_case__ ( self, __a):
'''simple docstring'''
_lowerCAmelCase : Dict = load_image(__a)
_lowerCAmelCase : Tuple = self.image_processor(images=__a, return_tensors=self.framework)
return model_inputs
def snake_case__ ( self, __a):
'''simple docstring'''
_lowerCAmelCase : Dict = self.model(**__a)
return model_outputs
def snake_case__ ( self, __a, __a=5):
'''simple docstring'''
if top_k > self.model.config.num_labels:
_lowerCAmelCase : Any = self.model.config.num_labels
if self.framework == "pt":
_lowerCAmelCase : int = model_outputs.logits.softmax(-1)[0]
_lowerCAmelCase , _lowerCAmelCase : Any = probs.topk(__a)
elif self.framework == "tf":
_lowerCAmelCase : Optional[Any] = stable_softmax(model_outputs.logits, axis=-1)[0]
_lowerCAmelCase : int = tf.math.top_k(__a, k=__a)
_lowerCAmelCase , _lowerCAmelCase : int = topk.values.numpy(), topk.indices.numpy()
else:
raise ValueError(f"Unsupported framework: {self.framework}")
_lowerCAmelCase : Dict = scores.tolist()
_lowerCAmelCase : List[Any] = ids.tolist()
return [{"score": score, "label": self.model.config.idalabel[_id]} for score, _id in zip(__a, __a)]
| 36
|
def A ( _lowerCamelCase ):
'''simple docstring'''
if bit_count < 0:
raise ValueError("The given input must be positive" )
# get the generated string sequence
_lowerCAmelCase : List[str] = gray_code_sequence_string(_lowerCamelCase )
#
# convert them to integers
for i in range(len(_lowerCamelCase ) ):
_lowerCAmelCase : List[str] = int(sequence[i] , 2 )
return sequence
def A ( _lowerCamelCase ):
'''simple docstring'''
if bit_count == 0:
return ["0"]
if bit_count == 1:
return ["0", "1"]
_lowerCAmelCase : List[Any] = 1 << bit_count # defines the length of the sequence
# 1<< n is equivalent to 2^n
# recursive answer will generate answer for n-1 bits
_lowerCAmelCase : Optional[int] = gray_code_sequence_string(bit_count - 1 )
_lowerCAmelCase : str = []
# append 0 to first half of the smaller sequence generated
for i in range(seq_len // 2 ):
_lowerCAmelCase : Dict = "0" + smaller_sequence[i]
sequence.append(_lowerCamelCase )
# append 1 to second half ... start from the end of the list
for i in reversed(range(seq_len // 2 ) ):
_lowerCAmelCase : Optional[Any] = "1" + smaller_sequence[i]
sequence.append(_lowerCamelCase )
return sequence
if __name__ == "__main__":
import doctest
doctest.testmod()
| 36
| 1
|
from collections import OrderedDict
from typing import Mapping
from ...configuration_utils import PretrainedConfig
from ...onnx import OnnxConfig
from ...utils import logging
_snake_case = logging.get_logger(__name__)
_snake_case = {
"facebook/xlm-roberta-xl": "https://huggingface.co/facebook/xlm-roberta-xl/resolve/main/config.json",
"facebook/xlm-roberta-xxl": "https://huggingface.co/facebook/xlm-roberta-xxl/resolve/main/config.json",
# See all XLM-RoBERTa-XL models at https://huggingface.co/models?filter=xlm-roberta-xl
}
class UpperCAmelCase_ ( a):
lowerCamelCase__ = 'xlm-roberta-xl'
def __init__( self, __a=25_0880, __a=2560, __a=36, __a=32, __a=1_0240, __a="gelu", __a=0.1, __a=0.1, __a=514, __a=1, __a=0.02, __a=1E-05, __a=1, __a=0, __a=2, __a="absolute", __a=True, __a=None, **__a, ):
'''simple docstring'''
super().__init__(pad_token_id=__a, bos_token_id=__a, eos_token_id=__a, **__a)
_lowerCAmelCase : List[Any] = vocab_size
_lowerCAmelCase : List[Any] = hidden_size
_lowerCAmelCase : List[str] = num_hidden_layers
_lowerCAmelCase : Dict = num_attention_heads
_lowerCAmelCase : int = hidden_act
_lowerCAmelCase : int = intermediate_size
_lowerCAmelCase : List[Any] = hidden_dropout_prob
_lowerCAmelCase : Tuple = attention_probs_dropout_prob
_lowerCAmelCase : Any = max_position_embeddings
_lowerCAmelCase : Optional[int] = type_vocab_size
_lowerCAmelCase : Tuple = initializer_range
_lowerCAmelCase : Union[str, Any] = layer_norm_eps
_lowerCAmelCase : str = position_embedding_type
_lowerCAmelCase : Optional[int] = use_cache
_lowerCAmelCase : Optional[Any] = classifier_dropout
class UpperCAmelCase_ ( a):
@property
def snake_case__ ( self):
'''simple docstring'''
if self.task == "multiple-choice":
_lowerCAmelCase : List[str] = {0: "batch", 1: "choice", 2: "sequence"}
else:
_lowerCAmelCase : Optional[Any] = {0: "batch", 1: "sequence"}
return OrderedDict(
[
("input_ids", dynamic_axis),
("attention_mask", dynamic_axis),
])
| 36
|
from PIL import Image
def A ( _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase , _lowerCAmelCase : int = image.size
_lowerCAmelCase : Any = 0
_lowerCAmelCase : Tuple = image.load()
for i in range(_lowerCamelCase ):
for j in range(_lowerCamelCase ):
_lowerCAmelCase : Union[str, Any] = pixels[j, i]
mean += pixel
mean //= width * height
for j in range(_lowerCamelCase ):
for i in range(_lowerCamelCase ):
_lowerCAmelCase : Optional[Any] = 255 if pixels[i, j] > mean else 0
return image
if __name__ == "__main__":
_snake_case = mean_threshold(Image.open("path_to_image").convert("L"))
image.save("output_image_path")
| 36
| 1
|
import math
from collections.abc import Callable
def A ( _lowerCamelCase , _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : float = xa
_lowerCAmelCase : float = xa
while True:
if x_n == x_na or function(_lowerCamelCase ) == function(_lowerCamelCase ):
raise ZeroDivisionError("float division by zero, could not find root" )
_lowerCAmelCase : float = x_na - (
function(_lowerCamelCase ) / ((function(_lowerCamelCase ) - function(_lowerCamelCase )) / (x_na - x_n))
)
if abs(x_na - x_na ) < 10**-5:
return x_na
_lowerCAmelCase : Any = x_na
_lowerCAmelCase : Tuple = x_na
def A ( _lowerCamelCase ):
'''simple docstring'''
return math.pow(_lowerCamelCase , 3 ) - (2 * x) - 5
if __name__ == "__main__":
print(intersection(f, 3, 3.5))
| 36
|
import functools
import operator
from ...configuration_utils import PretrainedConfig
from ...utils import logging
_snake_case = logging.get_logger(__name__)
_snake_case = {
"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 UpperCAmelCase_ ( a):
lowerCamelCase__ = 'wav2vec2'
def __init__( self, __a=32, __a=768, __a=12, __a=12, __a=3072, __a="gelu", __a=0.1, __a=0.1, __a=0.1, __a=0.0, __a=0.0, __a=0.1, __a=0.1, __a=0.02, __a=1E-5, __a="group", __a="gelu", __a=(512, 512, 512, 512, 512, 512, 512), __a=(5, 2, 2, 2, 2, 2, 2), __a=(10, 3, 3, 3, 3, 2, 2), __a=False, __a=128, __a=16, __a=False, __a=True, __a=0.05, __a=10, __a=2, __a=0.0, __a=10, __a=0, __a=320, __a=2, __a=0.1, __a=100, __a=256, __a=256, __a=0.1, __a="sum", __a=False, __a=False, __a=256, __a=(512, 512, 512, 512, 1500), __a=(5, 3, 3, 1, 1), __a=(1, 2, 3, 1, 1), __a=512, __a=0, __a=1, __a=2, __a=False, __a=3, __a=2, __a=3, __a=None, __a=None, **__a, ):
'''simple docstring'''
super().__init__(**__a, pad_token_id=__a, bos_token_id=__a, eos_token_id=__a)
_lowerCAmelCase : str = hidden_size
_lowerCAmelCase : Optional[int] = feat_extract_norm
_lowerCAmelCase : Union[str, Any] = feat_extract_activation
_lowerCAmelCase : Optional[Any] = list(__a)
_lowerCAmelCase : List[str] = list(__a)
_lowerCAmelCase : str = list(__a)
_lowerCAmelCase : List[str] = conv_bias
_lowerCAmelCase : str = num_conv_pos_embeddings
_lowerCAmelCase : List[Any] = num_conv_pos_embedding_groups
_lowerCAmelCase : str = len(self.conv_dim)
_lowerCAmelCase : List[str] = num_hidden_layers
_lowerCAmelCase : str = intermediate_size
_lowerCAmelCase : Any = hidden_act
_lowerCAmelCase : int = num_attention_heads
_lowerCAmelCase : Optional[Any] = hidden_dropout
_lowerCAmelCase : List[str] = attention_dropout
_lowerCAmelCase : Tuple = activation_dropout
_lowerCAmelCase : int = feat_proj_dropout
_lowerCAmelCase : List[str] = final_dropout
_lowerCAmelCase : int = layerdrop
_lowerCAmelCase : int = layer_norm_eps
_lowerCAmelCase : Union[str, Any] = initializer_range
_lowerCAmelCase : str = vocab_size
_lowerCAmelCase : Optional[Any] = do_stable_layer_norm
_lowerCAmelCase : 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
_lowerCAmelCase : str = apply_spec_augment
_lowerCAmelCase : Optional[Any] = mask_time_prob
_lowerCAmelCase : Optional[int] = mask_time_length
_lowerCAmelCase : List[str] = mask_time_min_masks
_lowerCAmelCase : Optional[int] = mask_feature_prob
_lowerCAmelCase : Optional[int] = mask_feature_length
_lowerCAmelCase : List[str] = mask_feature_min_masks
# parameters for pretraining with codevector quantized representations
_lowerCAmelCase : Union[str, Any] = num_codevectors_per_group
_lowerCAmelCase : str = num_codevector_groups
_lowerCAmelCase : Optional[int] = contrastive_logits_temperature
_lowerCAmelCase : Optional[int] = feat_quantizer_dropout
_lowerCAmelCase : Optional[int] = num_negatives
_lowerCAmelCase : Union[str, Any] = codevector_dim
_lowerCAmelCase : Any = proj_codevector_dim
_lowerCAmelCase : Optional[int] = diversity_loss_weight
# ctc loss
_lowerCAmelCase : Tuple = ctc_loss_reduction
_lowerCAmelCase : Tuple = ctc_zero_infinity
# adapter
_lowerCAmelCase : List[Any] = add_adapter
_lowerCAmelCase : List[str] = adapter_kernel_size
_lowerCAmelCase : str = adapter_stride
_lowerCAmelCase : List[str] = num_adapter_layers
_lowerCAmelCase : str = output_hidden_size or hidden_size
_lowerCAmelCase : Tuple = adapter_attn_dim
# SequenceClassification-specific parameter. Feel free to ignore for other classes.
_lowerCAmelCase : str = classifier_proj_size
# XVector-specific parameters. Feel free to ignore for other classes.
_lowerCAmelCase : str = list(__a)
_lowerCAmelCase : Union[str, Any] = list(__a)
_lowerCAmelCase : List[str] = list(__a)
_lowerCAmelCase : Tuple = xvector_output_dim
@property
def snake_case__ ( self):
'''simple docstring'''
return functools.reduce(operator.mul, self.conv_stride, 1)
| 36
| 1
|
from collections import OrderedDict
from typing import Mapping
from packaging import version
from ...configuration_utils import PretrainedConfig
from ...onnx import OnnxConfig
from ...utils import logging
from ...utils.backbone_utils import BackboneConfigMixin, get_aligned_output_features_output_indices
_snake_case = logging.get_logger(__name__)
_snake_case = {
"microsoft/swin-tiny-patch4-window7-224": (
"https://huggingface.co/microsoft/swin-tiny-patch4-window7-224/resolve/main/config.json"
),
# See all Swin models at https://huggingface.co/models?filter=swin
}
class UpperCAmelCase_ ( a , a):
lowerCamelCase__ = 'swin'
lowerCamelCase__ = {
'num_attention_heads': 'num_heads',
'num_hidden_layers': 'num_layers',
}
def __init__( self, __a=224, __a=4, __a=3, __a=96, __a=[2, 2, 6, 2], __a=[3, 6, 12, 24], __a=7, __a=4.0, __a=True, __a=0.0, __a=0.0, __a=0.1, __a="gelu", __a=False, __a=0.02, __a=1E-5, __a=32, __a=None, __a=None, **__a, ):
'''simple docstring'''
super().__init__(**__a)
_lowerCAmelCase : Any = image_size
_lowerCAmelCase : Union[str, Any] = patch_size
_lowerCAmelCase : Tuple = num_channels
_lowerCAmelCase : List[Any] = embed_dim
_lowerCAmelCase : Tuple = depths
_lowerCAmelCase : Optional[Any] = len(__a)
_lowerCAmelCase : int = num_heads
_lowerCAmelCase : int = window_size
_lowerCAmelCase : int = mlp_ratio
_lowerCAmelCase : List[Any] = qkv_bias
_lowerCAmelCase : str = hidden_dropout_prob
_lowerCAmelCase : Union[str, Any] = attention_probs_dropout_prob
_lowerCAmelCase : Any = drop_path_rate
_lowerCAmelCase : int = hidden_act
_lowerCAmelCase : Tuple = use_absolute_embeddings
_lowerCAmelCase : Optional[int] = layer_norm_eps
_lowerCAmelCase : Tuple = initializer_range
_lowerCAmelCase : Tuple = encoder_stride
# 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
_lowerCAmelCase : List[str] = int(embed_dim * 2 ** (len(__a) - 1))
_lowerCAmelCase : List[Any] = ["stem"] + [f"stage{idx}" for idx in range(1, len(__a) + 1)]
_lowerCAmelCase , _lowerCAmelCase : Optional[int] = get_aligned_output_features_output_indices(
out_features=__a, out_indices=__a, stage_names=self.stage_names)
class UpperCAmelCase_ ( a):
lowerCamelCase__ = version.parse('1.11')
@property
def snake_case__ ( self):
'''simple docstring'''
return OrderedDict(
[
("pixel_values", {0: "batch", 1: "num_channels", 2: "height", 3: "width"}),
])
@property
def snake_case__ ( self):
'''simple docstring'''
return 1E-4
| 36
|
from __future__ import absolute_import, division, print_function, unicode_literals
from torch import nn
from torch.nn import CrossEntropyLoss, MSELoss
from transformers import RobertaConfig
from transformers.file_utils import add_start_docstrings, add_start_docstrings_to_model_forward
from transformers.models.roberta.modeling_roberta import (
ROBERTA_INPUTS_DOCSTRING,
ROBERTA_START_DOCSTRING,
RobertaEmbeddings,
)
from .modeling_highway_bert import BertPreTrainedModel, DeeBertModel, HighwayException, entropy
@add_start_docstrings(
'The RoBERTa Model transformer with early exiting (DeeRoBERTa). ' , a , )
class UpperCAmelCase_ ( a):
lowerCamelCase__ = RobertaConfig
lowerCamelCase__ = 'roberta'
def __init__( self, __a):
'''simple docstring'''
super().__init__(__a)
_lowerCAmelCase : Optional[Any] = RobertaEmbeddings(__a)
self.init_weights()
@add_start_docstrings(
'RoBERTa Model (with early exiting - DeeRoBERTa) with a classifier on top,\n also takes care of multi-layer training. ' , a , )
class UpperCAmelCase_ ( a):
lowerCamelCase__ = RobertaConfig
lowerCamelCase__ = 'roberta'
def __init__( self, __a):
'''simple docstring'''
super().__init__(__a)
_lowerCAmelCase : Optional[int] = config.num_labels
_lowerCAmelCase : Optional[int] = config.num_hidden_layers
_lowerCAmelCase : Optional[int] = DeeRobertaModel(__a)
_lowerCAmelCase : Union[str, Any] = nn.Dropout(config.hidden_dropout_prob)
_lowerCAmelCase : List[str] = nn.Linear(config.hidden_size, self.config.num_labels)
@add_start_docstrings_to_model_forward(__a)
def snake_case__ ( self, __a=None, __a=None, __a=None, __a=None, __a=None, __a=None, __a=None, __a=-1, __a=False, ):
'''simple docstring'''
_lowerCAmelCase : Union[str, Any] = self.num_layers
try:
_lowerCAmelCase : List[Any] = self.roberta(
__a, attention_mask=__a, token_type_ids=__a, position_ids=__a, head_mask=__a, inputs_embeds=__a, )
_lowerCAmelCase : List[Any] = outputs[1]
_lowerCAmelCase : Dict = self.dropout(__a)
_lowerCAmelCase : Dict = self.classifier(__a)
_lowerCAmelCase : Optional[Any] = (logits,) + outputs[2:] # add hidden states and attention if they are here
except HighwayException as e:
_lowerCAmelCase : Tuple = e.message
_lowerCAmelCase : Union[str, Any] = e.exit_layer
_lowerCAmelCase : List[Any] = outputs[0]
if not self.training:
_lowerCAmelCase : int = entropy(__a)
_lowerCAmelCase : List[Any] = []
_lowerCAmelCase : str = []
if labels is not None:
if self.num_labels == 1:
# We are doing regression
_lowerCAmelCase : Optional[Any] = MSELoss()
_lowerCAmelCase : int = loss_fct(logits.view(-1), labels.view(-1))
else:
_lowerCAmelCase : Optional[Any] = CrossEntropyLoss()
_lowerCAmelCase : Optional[Any] = loss_fct(logits.view(-1, self.num_labels), labels.view(-1))
# work with highway exits
_lowerCAmelCase : Optional[int] = []
for highway_exit in outputs[-1]:
_lowerCAmelCase : Any = highway_exit[0]
if not self.training:
highway_logits_all.append(__a)
highway_entropy.append(highway_exit[2])
if self.num_labels == 1:
# We are doing regression
_lowerCAmelCase : List[str] = MSELoss()
_lowerCAmelCase : List[Any] = loss_fct(highway_logits.view(-1), labels.view(-1))
else:
_lowerCAmelCase : Dict = CrossEntropyLoss()
_lowerCAmelCase : Optional[Any] = loss_fct(highway_logits.view(-1, self.num_labels), labels.view(-1))
highway_losses.append(__a)
if train_highway:
_lowerCAmelCase : int = (sum(highway_losses[:-1]),) + outputs
# exclude the final highway, of course
else:
_lowerCAmelCase : Any = (loss,) + outputs
if not self.training:
_lowerCAmelCase : Optional[Any] = outputs + ((original_entropy, highway_entropy), exit_layer)
if output_layer >= 0:
_lowerCAmelCase : Optional[Any] = (
(outputs[0],) + (highway_logits_all[output_layer],) + outputs[2:]
) # use the highway of the last layer
return outputs # (loss), logits, (hidden_states), (attentions), entropy
| 36
| 1
|
import copy
from typing import TYPE_CHECKING, Any, Mapping, Optional, OrderedDict
from packaging import version
from ...configuration_utils import PretrainedConfig
from ...onnx import OnnxConfig
from ...utils import logging
from ..auto.configuration_auto import AutoConfig
if TYPE_CHECKING:
from ... import PreTrainedTokenizerBase, TensorType
_snake_case = logging.get_logger(__name__)
class UpperCAmelCase_ ( a):
lowerCamelCase__ = 'vision-encoder-decoder'
lowerCamelCase__ = True
def __init__( self, **__a):
'''simple docstring'''
super().__init__(**__a)
if "encoder" not in kwargs or "decoder" not in kwargs:
raise ValueError(
f"A configuraton of type {self.model_type} cannot be instantiated because "
f"not both `encoder` and `decoder` sub-configurations are passed, but only {kwargs}")
_lowerCAmelCase : str = kwargs.pop("encoder")
_lowerCAmelCase : Any = encoder_config.pop("model_type")
_lowerCAmelCase : str = kwargs.pop("decoder")
_lowerCAmelCase : List[str] = decoder_config.pop("model_type")
_lowerCAmelCase : Optional[Any] = AutoConfig.for_model(__a, **__a)
_lowerCAmelCase : Optional[Any] = AutoConfig.for_model(__a, **__a)
_lowerCAmelCase : Optional[int] = True
@classmethod
def snake_case__ ( cls, __a, __a, **__a):
'''simple docstring'''
logger.info("Setting `config.is_decoder=True` and `config.add_cross_attention=True` for decoder_config")
_lowerCAmelCase : Optional[Any] = True
_lowerCAmelCase : str = True
return cls(encoder=encoder_config.to_dict(), decoder=decoder_config.to_dict(), **__a)
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : int = copy.deepcopy(self.__dict__)
_lowerCAmelCase : List[str] = self.encoder.to_dict()
_lowerCAmelCase : List[str] = self.decoder.to_dict()
_lowerCAmelCase : Any = self.__class__.model_type
return output
class UpperCAmelCase_ ( a):
lowerCamelCase__ = version.parse('1.11')
@property
def snake_case__ ( self):
'''simple docstring'''
return OrderedDict(
[
("pixel_values", {0: "batch", 1: "num_channels", 2: "height", 3: "width"}),
])
@property
def snake_case__ ( self):
'''simple docstring'''
return 1E-4
@property
def snake_case__ ( self):
'''simple docstring'''
return OrderedDict({"last_hidden_state": {0: "batch", 1: "encoder_sequence"}})
class UpperCAmelCase_ ( a):
@property
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Optional[Any] = OrderedDict()
_lowerCAmelCase : Any = {0: "batch", 1: "past_decoder_sequence + sequence"}
_lowerCAmelCase : List[str] = {0: "batch", 1: "past_decoder_sequence + sequence"}
_lowerCAmelCase : Optional[Any] = {0: "batch", 1: "encoder_sequence"}
return common_inputs
def snake_case__ ( self, __a, __a = -1, __a = -1, __a = False, __a = None, ):
'''simple docstring'''
import torch
_lowerCAmelCase : Optional[Any] = OrderedDict()
_lowerCAmelCase : List[str] = super().generate_dummy_inputs(
__a, batch_size=__a, seq_length=__a, is_pair=__a, framework=__a)
_lowerCAmelCase , _lowerCAmelCase : Optional[Any] = dummy_input["input_ids"].shape
_lowerCAmelCase : str = (batch, encoder_sequence, self._config.encoder_hidden_size)
_lowerCAmelCase : List[str] = dummy_input.pop("input_ids")
_lowerCAmelCase : List[str] = dummy_input.pop("attention_mask")
_lowerCAmelCase : Optional[int] = torch.zeros(__a)
return common_inputs
class UpperCAmelCase_ ( a):
@property
def snake_case__ ( self):
'''simple docstring'''
pass
def snake_case__ ( self, __a):
'''simple docstring'''
return VisionEncoderDecoderEncoderOnnxConfig(__a)
def snake_case__ ( self, __a, __a, __a = "default"):
'''simple docstring'''
_lowerCAmelCase : Dict = encoder_config.hidden_size
return VisionEncoderDecoderDecoderOnnxConfig(__a, __a)
| 36
|
import copy
from typing import TYPE_CHECKING, Any, Mapping, Optional, OrderedDict
from packaging import version
from ...configuration_utils import PretrainedConfig
from ...onnx import OnnxConfig
from ...utils import logging
from ..auto.configuration_auto import AutoConfig
if TYPE_CHECKING:
from ... import PreTrainedTokenizerBase, TensorType
_snake_case = logging.get_logger(__name__)
class UpperCAmelCase_ ( a):
lowerCamelCase__ = 'vision-encoder-decoder'
lowerCamelCase__ = True
def __init__( self, **__a):
'''simple docstring'''
super().__init__(**__a)
if "encoder" not in kwargs or "decoder" not in kwargs:
raise ValueError(
f"A configuraton of type {self.model_type} cannot be instantiated because "
f"not both `encoder` and `decoder` sub-configurations are passed, but only {kwargs}")
_lowerCAmelCase : str = kwargs.pop("encoder")
_lowerCAmelCase : Any = encoder_config.pop("model_type")
_lowerCAmelCase : str = kwargs.pop("decoder")
_lowerCAmelCase : List[str] = decoder_config.pop("model_type")
_lowerCAmelCase : Optional[Any] = AutoConfig.for_model(__a, **__a)
_lowerCAmelCase : Optional[Any] = AutoConfig.for_model(__a, **__a)
_lowerCAmelCase : Optional[int] = True
@classmethod
def snake_case__ ( cls, __a, __a, **__a):
'''simple docstring'''
logger.info("Setting `config.is_decoder=True` and `config.add_cross_attention=True` for decoder_config")
_lowerCAmelCase : Optional[Any] = True
_lowerCAmelCase : str = True
return cls(encoder=encoder_config.to_dict(), decoder=decoder_config.to_dict(), **__a)
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : int = copy.deepcopy(self.__dict__)
_lowerCAmelCase : List[str] = self.encoder.to_dict()
_lowerCAmelCase : List[str] = self.decoder.to_dict()
_lowerCAmelCase : Any = self.__class__.model_type
return output
class UpperCAmelCase_ ( a):
lowerCamelCase__ = version.parse('1.11')
@property
def snake_case__ ( self):
'''simple docstring'''
return OrderedDict(
[
("pixel_values", {0: "batch", 1: "num_channels", 2: "height", 3: "width"}),
])
@property
def snake_case__ ( self):
'''simple docstring'''
return 1E-4
@property
def snake_case__ ( self):
'''simple docstring'''
return OrderedDict({"last_hidden_state": {0: "batch", 1: "encoder_sequence"}})
class UpperCAmelCase_ ( a):
@property
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Optional[Any] = OrderedDict()
_lowerCAmelCase : Any = {0: "batch", 1: "past_decoder_sequence + sequence"}
_lowerCAmelCase : List[str] = {0: "batch", 1: "past_decoder_sequence + sequence"}
_lowerCAmelCase : Optional[Any] = {0: "batch", 1: "encoder_sequence"}
return common_inputs
def snake_case__ ( self, __a, __a = -1, __a = -1, __a = False, __a = None, ):
'''simple docstring'''
import torch
_lowerCAmelCase : Optional[Any] = OrderedDict()
_lowerCAmelCase : List[str] = super().generate_dummy_inputs(
__a, batch_size=__a, seq_length=__a, is_pair=__a, framework=__a)
_lowerCAmelCase , _lowerCAmelCase : Optional[Any] = dummy_input["input_ids"].shape
_lowerCAmelCase : str = (batch, encoder_sequence, self._config.encoder_hidden_size)
_lowerCAmelCase : List[str] = dummy_input.pop("input_ids")
_lowerCAmelCase : List[str] = dummy_input.pop("attention_mask")
_lowerCAmelCase : Optional[int] = torch.zeros(__a)
return common_inputs
class UpperCAmelCase_ ( a):
@property
def snake_case__ ( self):
'''simple docstring'''
pass
def snake_case__ ( self, __a):
'''simple docstring'''
return VisionEncoderDecoderEncoderOnnxConfig(__a)
def snake_case__ ( self, __a, __a, __a = "default"):
'''simple docstring'''
_lowerCAmelCase : Dict = encoder_config.hidden_size
return VisionEncoderDecoderDecoderOnnxConfig(__a, __a)
| 36
| 1
|
import argparse
import json
import os
import sys
import tempfile
import unittest
from argparse import Namespace
from dataclasses import dataclass, field
from enum import Enum
from pathlib import Path
from typing import List, Literal, Optional
import yaml
from transformers import HfArgumentParser, TrainingArguments
from transformers.hf_argparser import make_choice_type_function, string_to_bool
# Since Python 3.10, we can use the builtin `|` operator for Union types
# See PEP 604: https://peps.python.org/pep-0604
_snake_case = sys.version_info >= (3, 10)
def A ( _lowerCamelCase=None , _lowerCamelCase=None ):
'''simple docstring'''
return field(default_factory=lambda: default , metadata=_lowerCamelCase )
@dataclass
class UpperCAmelCase_ :
lowerCamelCase__ = 42
lowerCamelCase__ = 42
lowerCamelCase__ = 42
lowerCamelCase__ = 42
@dataclass
class UpperCAmelCase_ :
lowerCamelCase__ = 42
lowerCamelCase__ = field(default='toto' , metadata={'help': 'help message'})
@dataclass
class UpperCAmelCase_ :
lowerCamelCase__ = False
lowerCamelCase__ = True
lowerCamelCase__ = None
class UpperCAmelCase_ ( a):
lowerCamelCase__ = 'titi'
lowerCamelCase__ = 'toto'
class UpperCAmelCase_ ( a):
lowerCamelCase__ = 'titi'
lowerCamelCase__ = 'toto'
lowerCamelCase__ = 42
@dataclass
class UpperCAmelCase_ :
lowerCamelCase__ = "toto"
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Optional[int] = BasicEnum(self.foo)
@dataclass
class UpperCAmelCase_ :
lowerCamelCase__ = "toto"
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Tuple = MixedTypeEnum(self.foo)
@dataclass
class UpperCAmelCase_ :
lowerCamelCase__ = None
lowerCamelCase__ = field(default=a , metadata={'help': 'help message'})
lowerCamelCase__ = None
lowerCamelCase__ = list_field(default=[])
lowerCamelCase__ = list_field(default=[])
@dataclass
class UpperCAmelCase_ :
lowerCamelCase__ = list_field(default=[])
lowerCamelCase__ = list_field(default=[1, 2, 3])
lowerCamelCase__ = list_field(default=['Hallo', 'Bonjour', 'Hello'])
lowerCamelCase__ = list_field(default=[0.1, 0.2, 0.3])
@dataclass
class UpperCAmelCase_ :
lowerCamelCase__ = field()
lowerCamelCase__ = field()
lowerCamelCase__ = field()
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Optional[Any] = BasicEnum(self.required_enum)
@dataclass
class UpperCAmelCase_ :
lowerCamelCase__ = 42
lowerCamelCase__ = field()
lowerCamelCase__ = None
lowerCamelCase__ = field(default='toto' , metadata={'help': 'help message'})
lowerCamelCase__ = list_field(default=['Hallo', 'Bonjour', 'Hello'])
if is_python_no_less_than_3_10:
@dataclass
class UpperCAmelCase_ :
lowerCamelCase__ = False
lowerCamelCase__ = True
lowerCamelCase__ = None
@dataclass
class UpperCAmelCase_ :
lowerCamelCase__ = None
lowerCamelCase__ = field(default=a , metadata={'help': 'help message'})
lowerCamelCase__ = None
lowerCamelCase__ = list_field(default=[])
lowerCamelCase__ = list_field(default=[])
class UpperCAmelCase_ ( unittest.TestCase):
def snake_case__ ( self, __a, __a):
'''simple docstring'''
self.assertEqual(len(a._actions), len(b._actions))
for x, y in zip(a._actions, b._actions):
_lowerCAmelCase : int = {k: v for k, v in vars(__a).items() if k != "container"}
_lowerCAmelCase : Dict = {k: v for k, v in vars(__a).items() if k != "container"}
# Choices with mixed type have custom function as "type"
# So we need to compare results directly for equality
if xx.get("choices", __a) and yy.get("choices", __a):
for expected_choice in yy["choices"] + xx["choices"]:
self.assertEqual(xx["type"](__a), yy["type"](__a))
del xx["type"], yy["type"]
self.assertEqual(__a, __a)
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : List[str] = HfArgumentParser(__a)
_lowerCAmelCase : List[Any] = argparse.ArgumentParser()
expected.add_argument("--foo", type=__a, required=__a)
expected.add_argument("--bar", type=__a, required=__a)
expected.add_argument("--baz", type=__a, required=__a)
expected.add_argument("--flag", type=__a, default=__a, const=__a, nargs="?")
self.argparsersEqual(__a, __a)
_lowerCAmelCase : int = ["--foo", "1", "--baz", "quux", "--bar", "0.5"]
((_lowerCAmelCase) , ) : str = parser.parse_args_into_dataclasses(__a, look_for_args_file=__a)
self.assertFalse(example.flag)
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Optional[Any] = HfArgumentParser(__a)
_lowerCAmelCase : Any = argparse.ArgumentParser()
expected.add_argument("--foo", default=42, type=__a)
expected.add_argument("--baz", default="toto", type=__a, help="help message")
self.argparsersEqual(__a, __a)
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : List[str] = argparse.ArgumentParser()
expected.add_argument("--foo", type=__a, default=__a, const=__a, nargs="?")
expected.add_argument("--baz", type=__a, default=__a, const=__a, nargs="?")
# A boolean no_* argument always has to come after its "default: True" regular counter-part
# and its default must be set to False
expected.add_argument("--no_baz", action="store_false", default=__a, dest="baz")
expected.add_argument("--opt", type=__a, default=__a)
_lowerCAmelCase : List[str] = [WithDefaultBoolExample]
if is_python_no_less_than_3_10:
dataclass_types.append(__a)
for dataclass_type in dataclass_types:
_lowerCAmelCase : Any = HfArgumentParser(__a)
self.argparsersEqual(__a, __a)
_lowerCAmelCase : int = parser.parse_args([])
self.assertEqual(__a, Namespace(foo=__a, baz=__a, opt=__a))
_lowerCAmelCase : int = parser.parse_args(["--foo", "--no_baz"])
self.assertEqual(__a, Namespace(foo=__a, baz=__a, opt=__a))
_lowerCAmelCase : Optional[int] = parser.parse_args(["--foo", "--baz"])
self.assertEqual(__a, Namespace(foo=__a, baz=__a, opt=__a))
_lowerCAmelCase : Dict = parser.parse_args(["--foo", "True", "--baz", "True", "--opt", "True"])
self.assertEqual(__a, Namespace(foo=__a, baz=__a, opt=__a))
_lowerCAmelCase : str = parser.parse_args(["--foo", "False", "--baz", "False", "--opt", "False"])
self.assertEqual(__a, Namespace(foo=__a, baz=__a, opt=__a))
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Optional[int] = HfArgumentParser(__a)
_lowerCAmelCase : str = argparse.ArgumentParser()
expected.add_argument(
"--foo", default="toto", choices=["titi", "toto", 42], type=make_choice_type_function(["titi", "toto", 42]), )
self.argparsersEqual(__a, __a)
_lowerCAmelCase : str = parser.parse_args([])
self.assertEqual(args.foo, "toto")
_lowerCAmelCase : Any = parser.parse_args_into_dataclasses([])[0]
self.assertEqual(enum_ex.foo, MixedTypeEnum.toto)
_lowerCAmelCase : Optional[int] = parser.parse_args(["--foo", "titi"])
self.assertEqual(args.foo, "titi")
_lowerCAmelCase : List[Any] = parser.parse_args_into_dataclasses(["--foo", "titi"])[0]
self.assertEqual(enum_ex.foo, MixedTypeEnum.titi)
_lowerCAmelCase : Union[str, Any] = parser.parse_args(["--foo", "42"])
self.assertEqual(args.foo, 42)
_lowerCAmelCase : Optional[Any] = parser.parse_args_into_dataclasses(["--foo", "42"])[0]
self.assertEqual(enum_ex.foo, MixedTypeEnum.fourtytwo)
def snake_case__ ( self):
'''simple docstring'''
@dataclass
class UpperCAmelCase_ :
lowerCamelCase__ = "toto"
_lowerCAmelCase : Tuple = HfArgumentParser(__a)
_lowerCAmelCase : Union[str, Any] = argparse.ArgumentParser()
expected.add_argument(
"--foo", default="toto", choices=("titi", "toto", 42), type=make_choice_type_function(["titi", "toto", 42]), )
self.argparsersEqual(__a, __a)
_lowerCAmelCase : Any = parser.parse_args([])
self.assertEqual(args.foo, "toto")
_lowerCAmelCase : Optional[Any] = parser.parse_args(["--foo", "titi"])
self.assertEqual(args.foo, "titi")
_lowerCAmelCase : Optional[int] = parser.parse_args(["--foo", "42"])
self.assertEqual(args.foo, 42)
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : List[str] = HfArgumentParser(__a)
_lowerCAmelCase : Any = argparse.ArgumentParser()
expected.add_argument("--foo_int", nargs="+", default=[], type=__a)
expected.add_argument("--bar_int", nargs="+", default=[1, 2, 3], type=__a)
expected.add_argument("--foo_str", nargs="+", default=["Hallo", "Bonjour", "Hello"], type=__a)
expected.add_argument("--foo_float", nargs="+", default=[0.1, 0.2, 0.3], type=__a)
self.argparsersEqual(__a, __a)
_lowerCAmelCase : Optional[Any] = parser.parse_args([])
self.assertEqual(
__a, Namespace(foo_int=[], bar_int=[1, 2, 3], foo_str=["Hallo", "Bonjour", "Hello"], foo_float=[0.1, 0.2, 0.3]), )
_lowerCAmelCase : Optional[Any] = parser.parse_args("--foo_int 1 --bar_int 2 3 --foo_str a b c --foo_float 0.1 0.7".split())
self.assertEqual(__a, Namespace(foo_int=[1], bar_int=[2, 3], foo_str=["a", "b", "c"], foo_float=[0.1, 0.7]))
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Dict = argparse.ArgumentParser()
expected.add_argument("--foo", default=__a, type=__a)
expected.add_argument("--bar", default=__a, type=__a, help="help message")
expected.add_argument("--baz", default=__a, type=__a)
expected.add_argument("--ces", nargs="+", default=[], type=__a)
expected.add_argument("--des", nargs="+", default=[], type=__a)
_lowerCAmelCase : Optional[Any] = [OptionalExample]
if is_python_no_less_than_3_10:
dataclass_types.append(__a)
for dataclass_type in dataclass_types:
_lowerCAmelCase : Tuple = HfArgumentParser(__a)
self.argparsersEqual(__a, __a)
_lowerCAmelCase : int = parser.parse_args([])
self.assertEqual(__a, Namespace(foo=__a, bar=__a, baz=__a, ces=[], des=[]))
_lowerCAmelCase : List[Any] = parser.parse_args("--foo 12 --bar 3.14 --baz 42 --ces a b c --des 1 2 3".split())
self.assertEqual(__a, Namespace(foo=12, bar=3.14, baz="42", ces=["a", "b", "c"], des=[1, 2, 3]))
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Union[str, Any] = HfArgumentParser(__a)
_lowerCAmelCase : Any = argparse.ArgumentParser()
expected.add_argument("--required_list", nargs="+", type=__a, required=__a)
expected.add_argument("--required_str", type=__a, required=__a)
expected.add_argument(
"--required_enum", type=make_choice_type_function(["titi", "toto"]), choices=["titi", "toto"], required=__a, )
self.argparsersEqual(__a, __a)
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Any = HfArgumentParser(__a)
_lowerCAmelCase : Optional[int] = argparse.ArgumentParser()
expected.add_argument("--foo", type=__a, required=__a)
expected.add_argument(
"--required_enum", type=make_choice_type_function(["titi", "toto"]), choices=["titi", "toto"], required=__a, )
expected.add_argument("--opt", type=__a, default=__a)
expected.add_argument("--baz", default="toto", type=__a, help="help message")
expected.add_argument("--foo_str", nargs="+", default=["Hallo", "Bonjour", "Hello"], type=__a)
self.argparsersEqual(__a, __a)
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Dict = HfArgumentParser(__a)
_lowerCAmelCase : Tuple = {
"foo": 12,
"bar": 3.14,
"baz": "42",
"flag": True,
}
_lowerCAmelCase : List[str] = parser.parse_dict(__a)[0]
_lowerCAmelCase : Optional[int] = BasicExample(**__a)
self.assertEqual(__a, __a)
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : str = HfArgumentParser(__a)
_lowerCAmelCase : Optional[int] = {
"foo": 12,
"bar": 3.14,
"baz": "42",
"flag": True,
"extra": 42,
}
self.assertRaises(__a, parser.parse_dict, __a, allow_extra_keys=__a)
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Tuple = HfArgumentParser(__a)
_lowerCAmelCase : Tuple = {
"foo": 12,
"bar": 3.14,
"baz": "42",
"flag": True,
}
with tempfile.TemporaryDirectory() as tmp_dir:
_lowerCAmelCase : Dict = os.path.join(__a, "temp_json")
os.mkdir(__a)
with open(temp_local_path + ".json", "w+") as f:
json.dump(__a, __a)
_lowerCAmelCase : Optional[int] = parser.parse_yaml_file(Path(temp_local_path + ".json"))[0]
_lowerCAmelCase : str = BasicExample(**__a)
self.assertEqual(__a, __a)
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : str = HfArgumentParser(__a)
_lowerCAmelCase : int = {
"foo": 12,
"bar": 3.14,
"baz": "42",
"flag": True,
}
with tempfile.TemporaryDirectory() as tmp_dir:
_lowerCAmelCase : Any = os.path.join(__a, "temp_yaml")
os.mkdir(__a)
with open(temp_local_path + ".yaml", "w+") as f:
yaml.dump(__a, __a)
_lowerCAmelCase : str = parser.parse_yaml_file(Path(temp_local_path + ".yaml"))[0]
_lowerCAmelCase : Optional[int] = BasicExample(**__a)
self.assertEqual(__a, __a)
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : List[str] = HfArgumentParser(__a)
self.assertIsNotNone(__a)
| 36
|
import inspect
import tempfile
from collections import OrderedDict, UserDict
from collections.abc import MutableMapping
from contextlib import ExitStack, contextmanager
from dataclasses import fields
from enum import Enum
from typing import Any, ContextManager, List, Tuple
import numpy as np
from .import_utils import is_flax_available, is_tf_available, is_torch_available, is_torch_fx_proxy
if is_flax_available():
import jax.numpy as jnp
class UpperCAmelCase_ ( a):
def __get__( self, __a, __a=None):
'''simple docstring'''
if obj is None:
return self
if self.fget is None:
raise AttributeError("unreadable attribute")
_lowerCAmelCase : List[Any] = "__cached_" + self.fget.__name__
_lowerCAmelCase : Dict = getattr(__a, __a, __a)
if cached is None:
_lowerCAmelCase : str = self.fget(__a)
setattr(__a, __a, __a)
return cached
def A ( _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : Any = val.lower()
if val in {"y", "yes", "t", "true", "on", "1"}:
return 1
if val in {"n", "no", "f", "false", "off", "0"}:
return 0
raise ValueError(F"invalid truth value {val!r}" )
def A ( _lowerCamelCase ):
'''simple docstring'''
if is_torch_fx_proxy(_lowerCamelCase ):
return True
if is_torch_available():
import torch
if isinstance(_lowerCamelCase , torch.Tensor ):
return True
if is_tf_available():
import tensorflow as tf
if isinstance(_lowerCamelCase , tf.Tensor ):
return True
if is_flax_available():
import jax.numpy as jnp
from jax.core import Tracer
if isinstance(_lowerCamelCase , (jnp.ndarray, Tracer) ):
return True
return isinstance(_lowerCamelCase , np.ndarray )
def A ( _lowerCamelCase ):
'''simple docstring'''
return isinstance(_lowerCamelCase , np.ndarray )
def A ( _lowerCamelCase ):
'''simple docstring'''
return _is_numpy(_lowerCamelCase )
def A ( _lowerCamelCase ):
'''simple docstring'''
import torch
return isinstance(_lowerCamelCase , torch.Tensor )
def A ( _lowerCamelCase ):
'''simple docstring'''
return False if not is_torch_available() else _is_torch(_lowerCamelCase )
def A ( _lowerCamelCase ):
'''simple docstring'''
import torch
return isinstance(_lowerCamelCase , torch.device )
def A ( _lowerCamelCase ):
'''simple docstring'''
return False if not is_torch_available() else _is_torch_device(_lowerCamelCase )
def A ( _lowerCamelCase ):
'''simple docstring'''
import torch
if isinstance(_lowerCamelCase , _lowerCamelCase ):
if hasattr(_lowerCamelCase , _lowerCamelCase ):
_lowerCAmelCase : Optional[Any] = getattr(_lowerCamelCase , _lowerCamelCase )
else:
return False
return isinstance(_lowerCamelCase , torch.dtype )
def A ( _lowerCamelCase ):
'''simple docstring'''
return False if not is_torch_available() else _is_torch_dtype(_lowerCamelCase )
def A ( _lowerCamelCase ):
'''simple docstring'''
import tensorflow as tf
return isinstance(_lowerCamelCase , tf.Tensor )
def A ( _lowerCamelCase ):
'''simple docstring'''
return False if not is_tf_available() else _is_tensorflow(_lowerCamelCase )
def A ( _lowerCamelCase ):
'''simple docstring'''
import tensorflow as tf
# the `is_symbolic_tensor` predicate is only available starting with TF 2.14
if hasattr(_lowerCamelCase , "is_symbolic_tensor" ):
return tf.is_symbolic_tensor(_lowerCamelCase )
return type(_lowerCamelCase ) == tf.Tensor
def A ( _lowerCamelCase ):
'''simple docstring'''
return False if not is_tf_available() else _is_tf_symbolic_tensor(_lowerCamelCase )
def A ( _lowerCamelCase ):
'''simple docstring'''
import jax.numpy as jnp # noqa: F811
return isinstance(_lowerCamelCase , jnp.ndarray )
def A ( _lowerCamelCase ):
'''simple docstring'''
return False if not is_flax_available() else _is_jax(_lowerCamelCase )
def A ( _lowerCamelCase ):
'''simple docstring'''
if isinstance(_lowerCamelCase , (dict, UserDict) ):
return {k: to_py_obj(_lowerCamelCase ) for k, v in obj.items()}
elif isinstance(_lowerCamelCase , (list, tuple) ):
return [to_py_obj(_lowerCamelCase ) for o in obj]
elif is_tf_tensor(_lowerCamelCase ):
return obj.numpy().tolist()
elif is_torch_tensor(_lowerCamelCase ):
return obj.detach().cpu().tolist()
elif is_jax_tensor(_lowerCamelCase ):
return np.asarray(_lowerCamelCase ).tolist()
elif isinstance(_lowerCamelCase , (np.ndarray, np.number) ): # tolist also works on 0d np arrays
return obj.tolist()
else:
return obj
def A ( _lowerCamelCase ):
'''simple docstring'''
if isinstance(_lowerCamelCase , (dict, UserDict) ):
return {k: to_numpy(_lowerCamelCase ) for k, v in obj.items()}
elif isinstance(_lowerCamelCase , (list, tuple) ):
return np.array(_lowerCamelCase )
elif is_tf_tensor(_lowerCamelCase ):
return obj.numpy()
elif is_torch_tensor(_lowerCamelCase ):
return obj.detach().cpu().numpy()
elif is_jax_tensor(_lowerCamelCase ):
return np.asarray(_lowerCamelCase )
else:
return obj
class UpperCAmelCase_ ( a):
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Tuple = fields(self)
# Safety and consistency checks
if not len(__a):
raise ValueError(f"{self.__class__.__name__} has no fields.")
if not all(field.default is None for field in class_fields[1:]):
raise ValueError(f"{self.__class__.__name__} should not have more than one required field.")
_lowerCAmelCase : Dict = getattr(self, class_fields[0].name)
_lowerCAmelCase : str = all(getattr(self, field.name) is None for field in class_fields[1:])
if other_fields_are_none and not is_tensor(__a):
if isinstance(__a, __a):
_lowerCAmelCase : Tuple = first_field.items()
_lowerCAmelCase : Dict = True
else:
try:
_lowerCAmelCase : Dict = iter(__a)
_lowerCAmelCase : Any = True
except TypeError:
_lowerCAmelCase : Any = False
# if we provided an iterator as first field and the iterator is a (key, value) iterator
# set the associated fields
if first_field_iterator:
for idx, element in enumerate(__a):
if (
not isinstance(__a, (list, tuple))
or not len(__a) == 2
or not isinstance(element[0], __a)
):
if idx == 0:
# If we do not have an iterator of key/values, set it as attribute
_lowerCAmelCase : Any = first_field
else:
# If we have a mixed iterator, raise an error
raise ValueError(
f"Cannot set key/value for {element}. It needs to be a tuple (key, value).")
break
setattr(self, element[0], element[1])
if element[1] is not None:
_lowerCAmelCase : Any = element[1]
elif first_field is not None:
_lowerCAmelCase : Any = first_field
else:
for field in class_fields:
_lowerCAmelCase : Dict = getattr(self, field.name)
if v is not None:
_lowerCAmelCase : Union[str, Any] = v
def __delitem__( self, *__a, **__a):
'''simple docstring'''
raise Exception(f"You cannot use ``__delitem__`` on a {self.__class__.__name__} instance.")
def snake_case__ ( self, *__a, **__a):
'''simple docstring'''
raise Exception(f"You cannot use ``setdefault`` on a {self.__class__.__name__} instance.")
def snake_case__ ( self, *__a, **__a):
'''simple docstring'''
raise Exception(f"You cannot use ``pop`` on a {self.__class__.__name__} instance.")
def snake_case__ ( self, *__a, **__a):
'''simple docstring'''
raise Exception(f"You cannot use ``update`` on a {self.__class__.__name__} instance.")
def __getitem__( self, __a):
'''simple docstring'''
if isinstance(__a, __a):
_lowerCAmelCase : Optional[int] = dict(self.items())
return inner_dict[k]
else:
return self.to_tuple()[k]
def __setattr__( self, __a, __a):
'''simple docstring'''
if name in self.keys() and value is not None:
# Don't call self.__setitem__ to avoid recursion errors
super().__setitem__(__a, __a)
super().__setattr__(__a, __a)
def __setitem__( self, __a, __a):
'''simple docstring'''
super().__setitem__(__a, __a)
# Don't call self.__setattr__ to avoid recursion errors
super().__setattr__(__a, __a)
def snake_case__ ( self):
'''simple docstring'''
return tuple(self[k] for k in self.keys())
class UpperCAmelCase_ ( a , a):
@classmethod
def snake_case__ ( cls, __a):
'''simple docstring'''
raise ValueError(
f"{value} is not a valid {cls.__name__}, please select one of {list(cls._valueamember_map_.keys())}")
class UpperCAmelCase_ ( a):
lowerCamelCase__ = 'longest'
lowerCamelCase__ = 'max_length'
lowerCamelCase__ = 'do_not_pad'
class UpperCAmelCase_ ( a):
lowerCamelCase__ = 'pt'
lowerCamelCase__ = 'tf'
lowerCamelCase__ = 'np'
lowerCamelCase__ = 'jax'
class UpperCAmelCase_ :
def __init__( self, __a):
'''simple docstring'''
_lowerCAmelCase : Tuple = context_managers
_lowerCAmelCase : Dict = ExitStack()
def __enter__( self):
'''simple docstring'''
for context_manager in self.context_managers:
self.stack.enter_context(__a)
def __exit__( self, *__a, **__a):
'''simple docstring'''
self.stack.__exit__(*__a, **__a)
def A ( _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : str = infer_framework(_lowerCamelCase )
if framework == "tf":
_lowerCAmelCase : Tuple = inspect.signature(model_class.call ) # TensorFlow models
elif framework == "pt":
_lowerCAmelCase : str = inspect.signature(model_class.forward ) # PyTorch models
else:
_lowerCAmelCase : Tuple = inspect.signature(model_class.__call__ ) # Flax models
for p in signature.parameters:
if p == "return_loss" and signature.parameters[p].default is True:
return True
return False
def A ( _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : str = model_class.__name__
_lowerCAmelCase : Optional[Any] = infer_framework(_lowerCamelCase )
if framework == "tf":
_lowerCAmelCase : Dict = inspect.signature(model_class.call ) # TensorFlow models
elif framework == "pt":
_lowerCAmelCase : List[Any] = inspect.signature(model_class.forward ) # PyTorch models
else:
_lowerCAmelCase : Dict = inspect.signature(model_class.__call__ ) # Flax models
if "QuestionAnswering" in model_name:
return [p for p in signature.parameters if "label" in p or p in ("start_positions", "end_positions")]
else:
return [p for p in signature.parameters if "label" in p]
def A ( _lowerCamelCase , _lowerCamelCase = "" , _lowerCamelCase = "." ):
'''simple docstring'''
def _flatten_dict(_lowerCamelCase , _lowerCamelCase="" , _lowerCamelCase="." ):
for k, v in d.items():
_lowerCAmelCase : Dict = str(_lowerCamelCase ) + delimiter + str(_lowerCamelCase ) if parent_key else k
if v and isinstance(_lowerCamelCase , _lowerCamelCase ):
yield from flatten_dict(_lowerCamelCase , _lowerCamelCase , delimiter=_lowerCamelCase ).items()
else:
yield key, v
return dict(_flatten_dict(_lowerCamelCase , _lowerCamelCase , _lowerCamelCase ) )
@contextmanager
def A ( _lowerCamelCase , _lowerCamelCase = False ):
'''simple docstring'''
if use_temp_dir:
with tempfile.TemporaryDirectory() as tmp_dir:
yield tmp_dir
else:
yield working_dir
def A ( _lowerCamelCase , _lowerCamelCase=None ):
'''simple docstring'''
if is_numpy_array(_lowerCamelCase ):
return np.transpose(_lowerCamelCase , axes=_lowerCamelCase )
elif is_torch_tensor(_lowerCamelCase ):
return array.T if axes is None else array.permute(*_lowerCamelCase )
elif is_tf_tensor(_lowerCamelCase ):
import tensorflow as tf
return tf.transpose(_lowerCamelCase , perm=_lowerCamelCase )
elif is_jax_tensor(_lowerCamelCase ):
return jnp.transpose(_lowerCamelCase , axes=_lowerCamelCase )
else:
raise ValueError(F"Type not supported for transpose: {type(_lowerCamelCase )}." )
def A ( _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
if is_numpy_array(_lowerCamelCase ):
return np.reshape(_lowerCamelCase , _lowerCamelCase )
elif is_torch_tensor(_lowerCamelCase ):
return array.reshape(*_lowerCamelCase )
elif is_tf_tensor(_lowerCamelCase ):
import tensorflow as tf
return tf.reshape(_lowerCamelCase , _lowerCamelCase )
elif is_jax_tensor(_lowerCamelCase ):
return jnp.reshape(_lowerCamelCase , _lowerCamelCase )
else:
raise ValueError(F"Type not supported for reshape: {type(_lowerCamelCase )}." )
def A ( _lowerCamelCase , _lowerCamelCase=None ):
'''simple docstring'''
if is_numpy_array(_lowerCamelCase ):
return np.squeeze(_lowerCamelCase , axis=_lowerCamelCase )
elif is_torch_tensor(_lowerCamelCase ):
return array.squeeze() if axis is None else array.squeeze(dim=_lowerCamelCase )
elif is_tf_tensor(_lowerCamelCase ):
import tensorflow as tf
return tf.squeeze(_lowerCamelCase , axis=_lowerCamelCase )
elif is_jax_tensor(_lowerCamelCase ):
return jnp.squeeze(_lowerCamelCase , axis=_lowerCamelCase )
else:
raise ValueError(F"Type not supported for squeeze: {type(_lowerCamelCase )}." )
def A ( _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
if is_numpy_array(_lowerCamelCase ):
return np.expand_dims(_lowerCamelCase , _lowerCamelCase )
elif is_torch_tensor(_lowerCamelCase ):
return array.unsqueeze(dim=_lowerCamelCase )
elif is_tf_tensor(_lowerCamelCase ):
import tensorflow as tf
return tf.expand_dims(_lowerCamelCase , axis=_lowerCamelCase )
elif is_jax_tensor(_lowerCamelCase ):
return jnp.expand_dims(_lowerCamelCase , axis=_lowerCamelCase )
else:
raise ValueError(F"Type not supported for expand_dims: {type(_lowerCamelCase )}." )
def A ( _lowerCamelCase ):
'''simple docstring'''
if is_numpy_array(_lowerCamelCase ):
return np.size(_lowerCamelCase )
elif is_torch_tensor(_lowerCamelCase ):
return array.numel()
elif is_tf_tensor(_lowerCamelCase ):
import tensorflow as tf
return tf.size(_lowerCamelCase )
elif is_jax_tensor(_lowerCamelCase ):
return array.size
else:
raise ValueError(F"Type not supported for expand_dims: {type(_lowerCamelCase )}." )
def A ( _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
for key, value in auto_map.items():
if isinstance(_lowerCamelCase , (tuple, list) ):
_lowerCAmelCase : List[Any] = [F"{repo_id}--{v}" if (v is not None and "--" not in v) else v for v in value]
elif value is not None and "--" not in value:
_lowerCAmelCase : Tuple = F"{repo_id}--{value}"
return auto_map
def A ( _lowerCamelCase ):
'''simple docstring'''
for base_class in inspect.getmro(_lowerCamelCase ):
_lowerCAmelCase : Tuple = base_class.__module__
_lowerCAmelCase : int = base_class.__name__
if module.startswith("tensorflow" ) or module.startswith("keras" ) or name == "TFPreTrainedModel":
return "tf"
elif module.startswith("torch" ) or name == "PreTrainedModel":
return "pt"
elif module.startswith("flax" ) or module.startswith("jax" ) or name == "FlaxPreTrainedModel":
return "flax"
else:
raise TypeError(F"Could not infer framework from class {model_class}." )
| 36
| 1
|
import argparse
import os
import re
import numpy as np
import PIL
import torch
from timm import create_model
from torch.optim.lr_scheduler import OneCycleLR
from torch.utils.data import DataLoader, Dataset
from torchvision.transforms import Compose, RandomResizedCrop, Resize, ToTensor
from accelerate import Accelerator
def A ( _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : Any = fname.split(os.path.sep )[-1]
return re.search(r"^(.*)_\d+\.jpg$" , _lowerCamelCase ).groups()[0]
class UpperCAmelCase_ ( a):
def __init__( self, __a, __a=None, __a=None):
'''simple docstring'''
_lowerCAmelCase : Optional[int] = file_names
_lowerCAmelCase : Optional[int] = image_transform
_lowerCAmelCase : Optional[int] = label_to_id
def __len__( self):
'''simple docstring'''
return len(self.file_names)
def __getitem__( self, __a):
'''simple docstring'''
_lowerCAmelCase : Union[str, Any] = self.file_names[idx]
_lowerCAmelCase : Any = PIL.Image.open(__a)
_lowerCAmelCase : str = raw_image.convert("RGB")
if self.image_transform is not None:
_lowerCAmelCase : Optional[Any] = self.image_transform(__a)
_lowerCAmelCase : Optional[int] = extract_label(__a)
if self.label_to_id is not None:
_lowerCAmelCase : List[str] = self.label_to_id[label]
return {"image": image, "label": label}
def A ( _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
if args.with_tracking:
_lowerCAmelCase : Dict = Accelerator(
cpu=args.cpu , mixed_precision=args.mixed_precision , log_with="all" , project_dir=args.project_dir )
else:
_lowerCAmelCase : Optional[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 : Optional[Any] = config["lr"]
_lowerCAmelCase : Dict = int(config["num_epochs"] )
_lowerCAmelCase : int = int(config["seed"] )
_lowerCAmelCase : Union[str, Any] = int(config["batch_size"] )
_lowerCAmelCase : List[str] = config["image_size"]
if not isinstance(_lowerCamelCase , (list, tuple) ):
_lowerCAmelCase : List[str] = (image_size, image_size)
# Parse out whether we are saving every epoch or after a certain number of batches
if hasattr(args.checkpointing_steps , "isdigit" ):
if args.checkpointing_steps == "epoch":
_lowerCAmelCase : Union[str, Any] = args.checkpointing_steps
elif args.checkpointing_steps.isdigit():
_lowerCAmelCase : Dict = int(args.checkpointing_steps )
else:
raise ValueError(
F"Argument `checkpointing_steps` must be either a number or `epoch`. `{args.checkpointing_steps}` passed." )
else:
_lowerCAmelCase : Dict = None
# We need to initialize the trackers we use, and also store our configuration
if args.with_tracking:
_lowerCAmelCase : Optional[Any] = os.path.split(_lowerCamelCase )[-1].split("." )[0]
accelerator.init_trackers(_lowerCamelCase , _lowerCamelCase )
# Grab all the image filenames
_lowerCAmelCase : str = [os.path.join(args.data_dir , _lowerCamelCase ) for fname in os.listdir(args.data_dir ) if fname.endswith(".jpg" )]
# Build the label correspondences
_lowerCAmelCase : Optional[int] = [extract_label(_lowerCamelCase ) for fname in file_names]
_lowerCAmelCase : List[str] = list(set(_lowerCamelCase ) )
id_to_label.sort()
_lowerCAmelCase : Optional[int] = {lbl: i for i, lbl in enumerate(_lowerCamelCase )}
# Set the seed before splitting the data.
np.random.seed(_lowerCamelCase )
torch.manual_seed(_lowerCamelCase )
torch.cuda.manual_seed_all(_lowerCamelCase )
# Split our filenames between train and validation
_lowerCAmelCase : Optional[int] = np.random.permutation(len(_lowerCamelCase ) )
_lowerCAmelCase : Tuple = int(0.8 * len(_lowerCamelCase ) )
_lowerCAmelCase : Optional[Any] = random_perm[:cut]
_lowerCAmelCase : List[Any] = random_perm[cut:]
# For training we use a simple RandomResizedCrop
_lowerCAmelCase : Tuple = Compose([RandomResizedCrop(_lowerCamelCase , scale=(0.5, 1.0) ), ToTensor()] )
_lowerCAmelCase : List[Any] = PetsDataset(
[file_names[i] for i in train_split] , image_transform=_lowerCamelCase , label_to_id=_lowerCamelCase )
# For evaluation, we use a deterministic Resize
_lowerCAmelCase : Union[str, Any] = Compose([Resize(_lowerCamelCase ), ToTensor()] )
_lowerCAmelCase : Optional[int] = PetsDataset([file_names[i] for i in eval_split] , image_transform=_lowerCamelCase , label_to_id=_lowerCamelCase )
# Instantiate dataloaders.
_lowerCAmelCase : Any = DataLoader(_lowerCamelCase , shuffle=_lowerCamelCase , batch_size=_lowerCamelCase , num_workers=4 )
_lowerCAmelCase : Any = DataLoader(_lowerCamelCase , shuffle=_lowerCamelCase , batch_size=_lowerCamelCase , num_workers=4 )
# Instantiate the model (we build the model here so that the seed also control new weights initialization)
_lowerCAmelCase : str = create_model("resnet50d" , pretrained=_lowerCamelCase , num_classes=len(_lowerCamelCase ) )
# 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 : List[Any] = model.to(accelerator.device )
# Freezing the base model
for param in model.parameters():
_lowerCAmelCase : int = False
for param in model.get_classifier().parameters():
_lowerCAmelCase : Tuple = True
# We normalize the batches of images to be a bit faster.
_lowerCAmelCase : Any = torch.tensor(model.default_cfg["mean"] )[None, :, None, None].to(accelerator.device )
_lowerCAmelCase : Dict = torch.tensor(model.default_cfg["std"] )[None, :, None, None].to(accelerator.device )
# Instantiate optimizer
_lowerCAmelCase : List[str] = torch.optim.Adam(params=model.parameters() , lr=lr / 25 )
# Instantiate learning rate scheduler
_lowerCAmelCase : Optional[int] = OneCycleLR(optimizer=_lowerCamelCase , max_lr=_lowerCamelCase , epochs=_lowerCamelCase , steps_per_epoch=len(_lowerCamelCase ) )
# 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 : Optional[Any] = accelerator.prepare(
_lowerCamelCase , _lowerCamelCase , _lowerCamelCase , _lowerCamelCase , _lowerCamelCase )
# We need to keep track of how many total steps we have iterated over
_lowerCAmelCase : List[str] = 0
# We also need to keep track of the starting epoch so files are named properly
_lowerCAmelCase : List[Any] = 0
# Potentially load in the weights and states from a previous save
if args.resume_from_checkpoint:
if args.resume_from_checkpoint is not None or args.resume_from_checkpoint != "":
accelerator.print(F"Resumed from checkpoint: {args.resume_from_checkpoint}" )
accelerator.load_state(args.resume_from_checkpoint )
_lowerCAmelCase : Any = os.path.basename(args.resume_from_checkpoint )
else:
# Get the most recent checkpoint
_lowerCAmelCase : int = [f.name for f in os.scandir(os.getcwd() ) if f.is_dir()]
dirs.sort(key=os.path.getctime )
_lowerCAmelCase : List[str] = dirs[-1] # Sorts folders by date modified, most recent checkpoint is the last
# Extract `epoch_{i}` or `step_{i}`
_lowerCAmelCase : List[Any] = os.path.splitext(_lowerCamelCase )[0]
if "epoch" in training_difference:
_lowerCAmelCase : Any = int(training_difference.replace("epoch_" , "" ) ) + 1
_lowerCAmelCase : Union[str, Any] = None
else:
_lowerCAmelCase : Any = int(training_difference.replace("step_" , "" ) )
_lowerCAmelCase : Any = resume_step // len(_lowerCamelCase )
resume_step -= starting_epoch * len(_lowerCamelCase )
# Now we train the model
for epoch in range(_lowerCamelCase , _lowerCamelCase ):
model.train()
if args.with_tracking:
_lowerCAmelCase : Union[str, Any] = 0
if args.resume_from_checkpoint and epoch == starting_epoch and resume_step is not None:
# We need to skip steps until we reach the resumed step
_lowerCAmelCase : Any = accelerator.skip_first_batches(_lowerCamelCase , _lowerCamelCase )
overall_step += resume_step
else:
# After the first iteration though, we need to go back to the original dataloader
_lowerCAmelCase : Optional[int] = train_dataloader
for batch in active_dataloader:
# We could avoid this line since we set the accelerator with `device_placement=True`.
_lowerCAmelCase : Optional[Any] = {k: v.to(accelerator.device ) for k, v in batch.items()}
_lowerCAmelCase : Dict = (batch["image"] - mean) / std
_lowerCAmelCase : Optional[Any] = model(_lowerCamelCase )
_lowerCAmelCase : Union[str, Any] = torch.nn.functional.cross_entropy(_lowerCamelCase , batch["label"] )
# We keep track of the loss at each epoch
if args.with_tracking:
total_loss += loss.detach().float()
accelerator.backward(_lowerCamelCase )
optimizer.step()
lr_scheduler.step()
optimizer.zero_grad()
overall_step += 1
if isinstance(_lowerCamelCase , _lowerCamelCase ):
_lowerCAmelCase : Any = F"step_{overall_step}"
if overall_step % checkpointing_steps == 0:
if args.output_dir is not None:
_lowerCAmelCase : List[Any] = os.path.join(args.output_dir , _lowerCamelCase )
accelerator.save_state(_lowerCamelCase )
model.eval()
_lowerCAmelCase : List[str] = 0
_lowerCAmelCase : Union[str, Any] = 0
for step, batch in enumerate(_lowerCamelCase ):
# We could avoid this line since we set the accelerator with `device_placement=True`.
_lowerCAmelCase : int = {k: v.to(accelerator.device ) for k, v in batch.items()}
_lowerCAmelCase : str = (batch["image"] - mean) / std
with torch.no_grad():
_lowerCAmelCase : Tuple = model(_lowerCamelCase )
_lowerCAmelCase : Dict = outputs.argmax(dim=-1 )
_lowerCAmelCase , _lowerCAmelCase : List[str] = accelerator.gather_for_metrics((predictions, batch["label"]) )
_lowerCAmelCase : int = predictions == references
num_elems += accurate_preds.shape[0]
accurate += accurate_preds.long().sum()
_lowerCAmelCase : List[str] = accurate.item() / num_elems
# Use accelerator.print to print only on the main process.
accelerator.print(F"epoch {epoch}: {100 * eval_metric:.2f}" )
if args.with_tracking:
accelerator.log(
{
"accuracy": 100 * eval_metric,
"train_loss": total_loss.item() / len(_lowerCamelCase ),
"epoch": epoch,
} , step=_lowerCamelCase , )
if checkpointing_steps == "epoch":
_lowerCAmelCase : int = F"epoch_{epoch}"
if args.output_dir is not None:
_lowerCAmelCase : List[Any] = os.path.join(args.output_dir , _lowerCamelCase )
accelerator.save_state(_lowerCamelCase )
if args.with_tracking:
accelerator.end_training()
def A ( ):
'''simple docstring'''
_lowerCAmelCase : Optional[Any] = argparse.ArgumentParser(description="Simple example of training script." )
parser.add_argument("--data_dir" , required=_lowerCamelCase , help="The data folder on disk." )
parser.add_argument("--fp16" , action="store_true" , help="If passed, will use FP16 training." )
parser.add_argument(
"--mixed_precision" , type=_lowerCamelCase , default=_lowerCamelCase , 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." )
parser.add_argument(
"--checkpointing_steps" , type=_lowerCamelCase , default=_lowerCamelCase , help="Whether the various states should be saved at the end of every n steps, or 'epoch' for each epoch." , )
parser.add_argument(
"--output_dir" , type=_lowerCamelCase , default="." , help="Optional save directory where all checkpoint folders will be stored. Default is the current working directory." , )
parser.add_argument(
"--resume_from_checkpoint" , type=_lowerCamelCase , default=_lowerCamelCase , help="If the training should continue from a checkpoint folder." , )
parser.add_argument(
"--with_tracking" , action="store_true" , help="Whether to load in all available experiment trackers from the environment and use them for logging." , )
parser.add_argument(
"--project_dir" , type=_lowerCamelCase , default="logs" , help="Location on where to store experiment tracking logs` and relevent project information" , )
_lowerCAmelCase : Dict = parser.parse_args()
_lowerCAmelCase : Any = {"lr": 3e-2, "num_epochs": 3, "seed": 42, "batch_size": 64, "image_size": 224}
training_function(_lowerCamelCase , _lowerCamelCase )
if __name__ == "__main__":
main()
| 36
|
import pytest
from datasets.utils.sharding import _distribute_shards, _number_of_shards_in_gen_kwargs, _split_gen_kwargs
@pytest.mark.parametrize(
"kwargs, expected" , [
({"num_shards": 0, "max_num_jobs": 1}, []),
({"num_shards": 10, "max_num_jobs": 1}, [range(10 )]),
({"num_shards": 10, "max_num_jobs": 10}, [range(_lowerCamelCase , i + 1 ) for i in range(10 )]),
({"num_shards": 1, "max_num_jobs": 10}, [range(1 )]),
({"num_shards": 10, "max_num_jobs": 3}, [range(0 , 4 ), range(4 , 7 ), range(7 , 10 )]),
({"num_shards": 3, "max_num_jobs": 10}, [range(0 , 1 ), range(1 , 2 ), range(2 , 3 )]),
] , )
def A ( _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : List[Any] = _distribute_shards(**_lowerCamelCase )
assert out == expected
@pytest.mark.parametrize(
"gen_kwargs, max_num_jobs, expected" , [
({"foo": 0}, 10, [{"foo": 0}]),
({"shards": [0, 1, 2, 3]}, 1, [{"shards": [0, 1, 2, 3]}]),
({"shards": [0, 1, 2, 3]}, 4, [{"shards": [0]}, {"shards": [1]}, {"shards": [2]}, {"shards": [3]}]),
({"shards": [0, 1]}, 4, [{"shards": [0]}, {"shards": [1]}]),
({"shards": [0, 1, 2, 3]}, 2, [{"shards": [0, 1]}, {"shards": [2, 3]}]),
] , )
def A ( _lowerCamelCase , _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : Optional[int] = _split_gen_kwargs(_lowerCamelCase , _lowerCamelCase )
assert out == expected
@pytest.mark.parametrize(
"gen_kwargs, expected" , [
({"foo": 0}, 1),
({"shards": [0]}, 1),
({"shards": [0, 1, 2, 3]}, 4),
({"shards": [0, 1, 2, 3], "foo": 0}, 4),
({"shards": [0, 1, 2, 3], "other": (0, 1)}, 4),
({"shards": [0, 1, 2, 3], "shards2": [0, 1]}, RuntimeError),
] , )
def A ( _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
if expected is RuntimeError:
with pytest.raises(_lowerCamelCase ):
_number_of_shards_in_gen_kwargs(_lowerCamelCase )
else:
_lowerCAmelCase : Optional[int] = _number_of_shards_in_gen_kwargs(_lowerCamelCase )
assert out == expected
| 36
| 1
|
import argparse
import os
import gluonnlp as nlp
import mxnet as mx
import numpy as np
import torch
from gluonnlp.base import get_home_dir
from gluonnlp.model.bert import BERTEncoder
from gluonnlp.model.utils import _load_vocab
from gluonnlp.vocab import Vocab
from packaging import version
from torch import nn
from transformers import BertConfig, BertForMaskedLM, BertModel, RobertaTokenizer
from transformers.models.bert.modeling_bert import (
BertIntermediate,
BertLayer,
BertOutput,
BertSelfAttention,
BertSelfOutput,
)
from transformers.utils import logging
if version.parse(nlp.__version__) != version.parse("0.8.3"):
raise Exception("requires gluonnlp == 0.8.3")
if version.parse(mx.__version__) != version.parse("1.5.0"):
raise Exception("requires mxnet == 1.5.0")
logging.set_verbosity_info()
_snake_case = logging.get_logger(__name__)
_snake_case = "The Nymphenburg Palace is a beautiful palace in Munich!"
def A ( _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : str = {
"attention_cell": "multi_head",
"num_layers": 4,
"units": 1_024,
"hidden_size": 768,
"max_length": 512,
"num_heads": 8,
"scaled": True,
"dropout": 0.1,
"use_residual": True,
"embed_size": 1_024,
"embed_dropout": 0.1,
"word_embed": None,
"layer_norm_eps": 1e-5,
"token_type_vocab_size": 2,
}
_lowerCAmelCase : List[Any] = bort_4_8_768_1024_hparams
# Let's construct the original Bort model here
# Taken from official BERT implementation, see:
# https://github.com/alexa/bort/blob/master/bort/bort.py
_lowerCAmelCase : Dict = BERTEncoder(
attention_cell=predefined_args["attention_cell"] , num_layers=predefined_args["num_layers"] , units=predefined_args["units"] , hidden_size=predefined_args["hidden_size"] , max_length=predefined_args["max_length"] , num_heads=predefined_args["num_heads"] , scaled=predefined_args["scaled"] , dropout=predefined_args["dropout"] , output_attention=_lowerCamelCase , output_all_encodings=_lowerCamelCase , use_residual=predefined_args["use_residual"] , activation=predefined_args.get("activation" , "gelu" ) , layer_norm_eps=predefined_args.get("layer_norm_eps" , _lowerCamelCase ) , )
# Vocab information needs to be fetched first
# It's the same as RoBERTa, so RobertaTokenizer can be used later
_lowerCAmelCase : Tuple = "openwebtext_ccnews_stories_books_cased"
# Specify download folder to Gluonnlp's vocab
_lowerCAmelCase : List[str] = os.path.join(get_home_dir() , "models" )
_lowerCAmelCase : int = _load_vocab(_lowerCamelCase , _lowerCamelCase , _lowerCamelCase , cls=_lowerCamelCase )
_lowerCAmelCase : Tuple = nlp.model.BERTModel(
_lowerCamelCase , len(_lowerCamelCase ) , units=predefined_args["units"] , embed_size=predefined_args["embed_size"] , embed_dropout=predefined_args["embed_dropout"] , word_embed=predefined_args["word_embed"] , use_pooler=_lowerCamelCase , use_token_type_embed=_lowerCamelCase , token_type_vocab_size=predefined_args["token_type_vocab_size"] , use_classifier=_lowerCamelCase , use_decoder=_lowerCamelCase , )
original_bort.load_parameters(_lowerCamelCase , cast_dtype=_lowerCamelCase , ignore_extra=_lowerCamelCase )
_lowerCAmelCase : List[str] = original_bort._collect_params_with_prefix()
# Build our config 🤗
_lowerCAmelCase : Tuple = {
"architectures": ["BertForMaskedLM"],
"attention_probs_dropout_prob": predefined_args["dropout"],
"hidden_act": "gelu",
"hidden_dropout_prob": predefined_args["dropout"],
"hidden_size": predefined_args["embed_size"],
"initializer_range": 0.02,
"intermediate_size": predefined_args["hidden_size"],
"layer_norm_eps": predefined_args["layer_norm_eps"],
"max_position_embeddings": predefined_args["max_length"],
"model_type": "bort",
"num_attention_heads": predefined_args["num_heads"],
"num_hidden_layers": predefined_args["num_layers"],
"pad_token_id": 1, # 2 = BERT, 1 = RoBERTa
"type_vocab_size": 1, # 2 = BERT, 1 = RoBERTa
"vocab_size": len(_lowerCamelCase ),
}
_lowerCAmelCase : Union[str, Any] = BertConfig.from_dict(_lowerCamelCase )
_lowerCAmelCase : Dict = BertForMaskedLM(_lowerCamelCase )
hf_bort_model.eval()
# Parameter mapping table (Gluonnlp to Transformers)
# * denotes layer index
#
# | Gluon Parameter | Transformers Parameter
# | -------------------------------------------------------------- | ----------------------
# | `encoder.layer_norm.beta` | `bert.embeddings.LayerNorm.bias`
# | `encoder.layer_norm.gamma` | `bert.embeddings.LayerNorm.weight`
# | `encoder.position_weight` | `bert.embeddings.position_embeddings.weight`
# | `word_embed.0.weight` | `bert.embeddings.word_embeddings.weight`
# | `encoder.transformer_cells.*.attention_cell.proj_key.bias` | `bert.encoder.layer.*.attention.self.key.bias`
# | `encoder.transformer_cells.*.attention_cell.proj_key.weight` | `bert.encoder.layer.*.attention.self.key.weight`
# | `encoder.transformer_cells.*.attention_cell.proj_query.bias` | `bert.encoder.layer.*.attention.self.query.bias`
# | `encoder.transformer_cells.*.attention_cell.proj_query.weight` | `bert.encoder.layer.*.attention.self.query.weight`
# | `encoder.transformer_cells.*.attention_cell.proj_value.bias` | `bert.encoder.layer.*.attention.self.value.bias`
# | `encoder.transformer_cells.*.attention_cell.proj_value.weight` | `bert.encoder.layer.*.attention.self.value.weight`
# | `encoder.transformer_cells.*.ffn.ffn_2.bias` | `bert.encoder.layer.*.attention.output.dense.bias`
# | `encoder.transformer_cells.*.ffn.ffn_2.weight` | `bert.encoder.layer.*.attention.output.dense.weight`
# | `encoder.transformer_cells.*.layer_norm.beta` | `bert.encoder.layer.*.attention.output.LayerNorm.bias`
# | `encoder.transformer_cells.*.layer_norm.gamma` | `bert.encoder.layer.*.attention.output.LayerNorm.weight`
# | `encoder.transformer_cells.*.ffn.ffn_1.bias` | `bert.encoder.layer.*.intermediate.dense.bias`
# | `encoder.transformer_cells.*.ffn.ffn_1.weight` | `bert.encoder.layer.*.intermediate.dense.weight`
# | `encoder.transformer_cells.*.ffn.layer_norm.beta` | `bert.encoder.layer.*.output.LayerNorm.bias`
# | `encoder.transformer_cells.*.ffn.layer_norm.gamma` | `bert.encoder.layer.*.output.LayerNorm.weight`
# | `encoder.transformer_cells.*.proj.bias` | `bert.encoder.layer.*.output.dense.bias`
# | `encoder.transformer_cells.*.proj.weight` | `bert.encoder.layer.*.output.dense.weight`
# Helper function to convert MXNET Arrays to PyTorch
def to_torch(_lowerCamelCase ) -> nn.Parameter:
return nn.Parameter(torch.FloatTensor(mx_array.data().asnumpy() ) )
# Check param shapes and map new HF param back
def check_and_map_params(_lowerCamelCase , _lowerCamelCase ):
_lowerCAmelCase : Dict = hf_param.shape
_lowerCAmelCase : Union[str, Any] = to_torch(params[gluon_param] )
_lowerCAmelCase : Optional[Any] = gluon_param.shape
assert (
shape_hf == shape_gluon
), F"The gluon parameter {gluon_param} has shape {shape_gluon}, but expects shape {shape_hf} for Transformers"
return gluon_param
_lowerCAmelCase : List[Any] = check_and_map_params(
hf_bort_model.bert.embeddings.word_embeddings.weight , "word_embed.0.weight" )
_lowerCAmelCase : str = check_and_map_params(
hf_bort_model.bert.embeddings.position_embeddings.weight , "encoder.position_weight" )
_lowerCAmelCase : List[str] = check_and_map_params(
hf_bort_model.bert.embeddings.LayerNorm.bias , "encoder.layer_norm.beta" )
_lowerCAmelCase : str = check_and_map_params(
hf_bort_model.bert.embeddings.LayerNorm.weight , "encoder.layer_norm.gamma" )
# Inspired by RoBERTa conversion script, we just zero them out (Bort does not use them)
_lowerCAmelCase : List[str] = torch.zeros_like(
hf_bort_model.bert.embeddings.token_type_embeddings.weight.data )
for i in range(hf_bort_config.num_hidden_layers ):
_lowerCAmelCase : BertLayer = hf_bort_model.bert.encoder.layer[i]
# self attention
_lowerCAmelCase : BertSelfAttention = layer.attention.self
_lowerCAmelCase : Dict = check_and_map_params(
self_attn.key.bias.data , F"encoder.transformer_cells.{i}.attention_cell.proj_key.bias" )
_lowerCAmelCase : str = check_and_map_params(
self_attn.key.weight.data , F"encoder.transformer_cells.{i}.attention_cell.proj_key.weight" )
_lowerCAmelCase : Any = check_and_map_params(
self_attn.query.bias.data , F"encoder.transformer_cells.{i}.attention_cell.proj_query.bias" )
_lowerCAmelCase : str = check_and_map_params(
self_attn.query.weight.data , F"encoder.transformer_cells.{i}.attention_cell.proj_query.weight" )
_lowerCAmelCase : Tuple = check_and_map_params(
self_attn.value.bias.data , F"encoder.transformer_cells.{i}.attention_cell.proj_value.bias" )
_lowerCAmelCase : Any = check_and_map_params(
self_attn.value.weight.data , F"encoder.transformer_cells.{i}.attention_cell.proj_value.weight" )
# self attention output
_lowerCAmelCase : BertSelfOutput = layer.attention.output
_lowerCAmelCase : List[Any] = check_and_map_params(
self_output.dense.bias , F"encoder.transformer_cells.{i}.proj.bias" )
_lowerCAmelCase : Dict = check_and_map_params(
self_output.dense.weight , F"encoder.transformer_cells.{i}.proj.weight" )
_lowerCAmelCase : List[str] = check_and_map_params(
self_output.LayerNorm.bias , F"encoder.transformer_cells.{i}.layer_norm.beta" )
_lowerCAmelCase : str = check_and_map_params(
self_output.LayerNorm.weight , F"encoder.transformer_cells.{i}.layer_norm.gamma" )
# intermediate
_lowerCAmelCase : BertIntermediate = layer.intermediate
_lowerCAmelCase : Tuple = check_and_map_params(
intermediate.dense.bias , F"encoder.transformer_cells.{i}.ffn.ffn_1.bias" )
_lowerCAmelCase : Optional[int] = check_and_map_params(
intermediate.dense.weight , F"encoder.transformer_cells.{i}.ffn.ffn_1.weight" )
# output
_lowerCAmelCase : BertOutput = layer.output
_lowerCAmelCase : Optional[Any] = check_and_map_params(
bert_output.dense.bias , F"encoder.transformer_cells.{i}.ffn.ffn_2.bias" )
_lowerCAmelCase : Optional[Any] = check_and_map_params(
bert_output.dense.weight , F"encoder.transformer_cells.{i}.ffn.ffn_2.weight" )
_lowerCAmelCase : Dict = check_and_map_params(
bert_output.LayerNorm.bias , F"encoder.transformer_cells.{i}.ffn.layer_norm.beta" )
_lowerCAmelCase : Tuple = check_and_map_params(
bert_output.LayerNorm.weight , F"encoder.transformer_cells.{i}.ffn.layer_norm.gamma" )
# Save space and energy 🎄
hf_bort_model.half()
# Compare output of both models
_lowerCAmelCase : List[Any] = RobertaTokenizer.from_pretrained("roberta-base" )
_lowerCAmelCase : Union[str, Any] = tokenizer.encode_plus(_lowerCamelCase )["input_ids"]
# Get gluon output
_lowerCAmelCase : Optional[Any] = mx.nd.array([input_ids] )
_lowerCAmelCase : List[Any] = original_bort(inputs=_lowerCamelCase , token_types=[] )
# Get Transformer output (save and reload model again)
hf_bort_model.save_pretrained(_lowerCamelCase )
_lowerCAmelCase : List[str] = BertModel.from_pretrained(_lowerCamelCase )
hf_bort_model.eval()
_lowerCAmelCase : Any = tokenizer.encode_plus(_lowerCamelCase , return_tensors="pt" )
_lowerCAmelCase : Dict = hf_bort_model(**_lowerCamelCase )[0]
_lowerCAmelCase : Optional[int] = output_gluon[0].asnumpy()
_lowerCAmelCase : Union[str, Any] = output_hf[0].detach().numpy()
_lowerCAmelCase : List[str] = np.max(np.abs(hf_layer - gluon_layer ) ).item()
_lowerCAmelCase : str = np.allclose(_lowerCamelCase , _lowerCamelCase , atol=1e-3 )
if success:
print("✔️ Both model do output the same tensors" )
else:
print("❌ Both model do **NOT** output the same tensors" )
print("Absolute difference is:" , _lowerCamelCase )
if __name__ == "__main__":
_snake_case = argparse.ArgumentParser()
# Required parameters
parser.add_argument(
"--bort_checkpoint_path", default=None, type=str, required=True, help="Path the official Bort params file."
)
parser.add_argument(
"--pytorch_dump_folder_path", default=None, type=str, required=True, help="Path to the output PyTorch model."
)
_snake_case = parser.parse_args()
convert_bort_checkpoint_to_pytorch(args.bort_checkpoint_path, args.pytorch_dump_folder_path)
| 36
|
import os
from glob import glob
import imageio
import torch
import torchvision
import wandb
from img_processing import custom_to_pil, loop_post_process, preprocess, preprocess_vqgan
from loaders import load_vqgan
from PIL import Image
from torch import nn
from transformers import CLIPModel, CLIPTokenizerFast
from utils import get_device, get_timestamp, show_pil
class UpperCAmelCase_ :
def __init__( self, __a = "cpu", __a = "openai/clip-vit-large-patch14"):
'''simple docstring'''
_lowerCAmelCase : Optional[int] = device
_lowerCAmelCase : Optional[int] = CLIPTokenizerFast.from_pretrained(__a)
_lowerCAmelCase : Any = [0.48_145_466, 0.4_578_275, 0.40_821_073]
_lowerCAmelCase : Union[str, Any] = [0.26_862_954, 0.26_130_258, 0.27_577_711]
_lowerCAmelCase : Tuple = torchvision.transforms.Normalize(self.image_mean, self.image_std)
_lowerCAmelCase : Optional[int] = torchvision.transforms.Resize(224)
_lowerCAmelCase : Dict = torchvision.transforms.CenterCrop(224)
def snake_case__ ( self, __a):
'''simple docstring'''
_lowerCAmelCase : Optional[Any] = self.resize(__a)
_lowerCAmelCase : List[str] = self.center_crop(__a)
_lowerCAmelCase : Optional[Any] = self.normalize(__a)
return images
def __call__( self, __a=None, __a=None, **__a):
'''simple docstring'''
_lowerCAmelCase : str = self.tokenizer(text=__a, **__a)
_lowerCAmelCase : List[str] = self.preprocess_img(__a)
_lowerCAmelCase : Tuple = {key: value.to(self.device) for (key, value) in encoding.items()}
return encoding
class UpperCAmelCase_ ( nn.Module):
def __init__( self, __a=10, __a=0.01, __a=None, __a=None, __a=None, __a=None, __a=None, __a=None, __a=False, __a=True, __a="image", __a=True, __a=False, __a=False, __a=False, ):
'''simple docstring'''
super().__init__()
_lowerCAmelCase : List[str] = None
_lowerCAmelCase : List[str] = device if device else get_device()
if vqgan:
_lowerCAmelCase : Union[str, Any] = vqgan
else:
_lowerCAmelCase : Optional[Any] = load_vqgan(self.device, conf_path=__a, ckpt_path=__a)
self.vqgan.eval()
if clip:
_lowerCAmelCase : str = clip
else:
_lowerCAmelCase : int = CLIPModel.from_pretrained("openai/clip-vit-base-patch32")
self.clip.to(self.device)
_lowerCAmelCase : Optional[int] = ProcessorGradientFlow(device=self.device)
_lowerCAmelCase : Any = iterations
_lowerCAmelCase : List[Any] = lr
_lowerCAmelCase : Tuple = log
_lowerCAmelCase : List[str] = make_grid
_lowerCAmelCase : int = return_val
_lowerCAmelCase : Dict = quantize
_lowerCAmelCase : Any = self.vqgan.decoder.z_shape
def snake_case__ ( self, __a=None, __a=None, __a=5, __a=True):
'''simple docstring'''
_lowerCAmelCase : Union[str, Any] = []
if output_path is None:
_lowerCAmelCase : List[Any] = "./animation.gif"
if input_path is None:
_lowerCAmelCase : str = self.save_path
_lowerCAmelCase : str = sorted(glob(input_path + "/*"))
if not len(__a):
raise ValueError(
"No images found in save path, aborting (did you pass save_intermediate=True to the generate"
" function?)")
if len(__a) == 1:
print("Only one image found in save path, (did you pass save_intermediate=True to the generate function?)")
_lowerCAmelCase : Optional[int] = total_duration / len(__a)
_lowerCAmelCase : Union[str, Any] = [frame_duration] * len(__a)
if extend_frames:
_lowerCAmelCase : Any = 1.5
_lowerCAmelCase : List[str] = 3
for file_name in paths:
if file_name.endswith(".png"):
images.append(imageio.imread(__a))
imageio.mimsave(__a, __a, duration=__a)
print(f"gif saved to {output_path}")
def snake_case__ ( self, __a=None, __a=None):
'''simple docstring'''
if not (path or img):
raise ValueError("Input either path or tensor")
if img is not None:
raise NotImplementedError
_lowerCAmelCase : Dict = preprocess(Image.open(__a), target_image_size=256).to(self.device)
_lowerCAmelCase : Dict = preprocess_vqgan(__a)
_lowerCAmelCase , *_lowerCAmelCase : str = self.vqgan.encode(__a)
return z
def snake_case__ ( self, __a):
'''simple docstring'''
_lowerCAmelCase : Optional[Any] = self.latent.detach().requires_grad_()
_lowerCAmelCase : Dict = base_latent + transform_vector
if self.quantize:
_lowerCAmelCase , *_lowerCAmelCase : List[Any] = self.vqgan.quantize(__a)
else:
_lowerCAmelCase : Any = trans_latent
return self.vqgan.decode(__a)
def snake_case__ ( self, __a, __a, __a=None):
'''simple docstring'''
_lowerCAmelCase : int = self.clip_preprocessor(text=__a, images=__a, return_tensors="pt", padding=__a)
_lowerCAmelCase : Optional[int] = self.clip(**__a)
_lowerCAmelCase : Any = clip_outputs.logits_per_image
if weights is not None:
_lowerCAmelCase : Tuple = similarity_logits * weights
return similarity_logits.sum()
def snake_case__ ( self, __a, __a, __a):
'''simple docstring'''
_lowerCAmelCase : List[Any] = self._get_clip_similarity(pos_prompts["prompts"], __a, weights=(1 / pos_prompts["weights"]))
if neg_prompts:
_lowerCAmelCase : List[Any] = self._get_clip_similarity(neg_prompts["prompts"], __a, weights=neg_prompts["weights"])
else:
_lowerCAmelCase : Union[str, Any] = torch.tensor([1], device=self.device)
_lowerCAmelCase : List[str] = -torch.log(__a) + torch.log(__a)
return loss
def snake_case__ ( self, __a, __a, __a):
'''simple docstring'''
_lowerCAmelCase : Optional[Any] = torch.randn_like(self.latent, requires_grad=__a, device=self.device)
_lowerCAmelCase : Optional[int] = torch.optim.Adam([vector], lr=self.lr)
for i in range(self.iterations):
optim.zero_grad()
_lowerCAmelCase : Any = self._add_vector(__a)
_lowerCAmelCase : Optional[Any] = loop_post_process(__a)
_lowerCAmelCase : Optional[Any] = self._get_CLIP_loss(__a, __a, __a)
print("CLIP loss", __a)
if self.log:
wandb.log({"CLIP Loss": clip_loss})
clip_loss.backward(retain_graph=__a)
optim.step()
if self.return_val == "image":
yield custom_to_pil(transformed_img[0])
else:
yield vector
def snake_case__ ( self, __a, __a, __a):
'''simple docstring'''
wandb.init(reinit=__a, project="face-editor")
wandb.config.update({"Positive Prompts": positive_prompts})
wandb.config.update({"Negative Prompts": negative_prompts})
wandb.config.update({"lr": self.lr, "iterations": self.iterations})
if image_path:
_lowerCAmelCase : str = Image.open(__a)
_lowerCAmelCase : int = image.resize((256, 256))
wandb.log("Original Image", wandb.Image(__a))
def snake_case__ ( self, __a):
'''simple docstring'''
if not prompts:
return []
_lowerCAmelCase : int = []
_lowerCAmelCase : List[str] = []
if isinstance(__a, __a):
_lowerCAmelCase : Union[str, Any] = [prompt.strip() for prompt in prompts.split("|")]
for prompt in prompts:
if isinstance(__a, (tuple, list)):
_lowerCAmelCase : Optional[Any] = prompt[0]
_lowerCAmelCase : Union[str, Any] = float(prompt[1])
elif ":" in prompt:
_lowerCAmelCase , _lowerCAmelCase : int = prompt.split(":")
_lowerCAmelCase : Optional[Any] = float(__a)
else:
_lowerCAmelCase : Optional[int] = prompt
_lowerCAmelCase : List[Any] = 1.0
processed_prompts.append(__a)
weights.append(__a)
return {
"prompts": processed_prompts,
"weights": torch.tensor(__a, device=self.device),
}
def snake_case__ ( self, __a, __a=None, __a=None, __a=True, __a=False, __a=True, __a=True, __a=None, ):
'''simple docstring'''
if image_path:
_lowerCAmelCase : List[Any] = self._get_latent(__a)
else:
_lowerCAmelCase : Any = torch.randn(self.latent_dim, device=self.device)
if self.log:
self._init_logging(__a, __a, __a)
assert pos_prompts, "You must provide at least one positive prompt."
_lowerCAmelCase : int = self.process_prompts(__a)
_lowerCAmelCase : List[str] = self.process_prompts(__a)
if save_final and save_path is None:
_lowerCAmelCase : int = os.path.join("./outputs/", "_".join(pos_prompts["prompts"]))
if not os.path.exists(__a):
os.makedirs(__a)
else:
_lowerCAmelCase : Tuple = save_path + "_" + get_timestamp()
os.makedirs(__a)
_lowerCAmelCase : Tuple = save_path
_lowerCAmelCase : List[Any] = self.vqgan.decode(self.latent)[0]
if show_intermediate:
print("Original Image")
show_pil(custom_to_pil(__a))
_lowerCAmelCase : int = loop_post_process(__a)
for iter, transformed_img in enumerate(self._optimize_CLIP(__a, __a, __a)):
if show_intermediate:
show_pil(__a)
if save_intermediate:
transformed_img.save(os.path.join(self.save_path, f"iter_{iter:03d}.png"))
if self.log:
wandb.log({"Image": wandb.Image(__a)})
if show_final:
show_pil(__a)
if save_final:
transformed_img.save(os.path.join(self.save_path, f"iter_{iter:03d}_final.png"))
| 36
| 1
|
import argparse
import gc
import json
import os
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
_snake_case = 16
_snake_case = 32
def A ( _lowerCamelCase ):
'''simple docstring'''
return int(x / 2**20 )
class UpperCAmelCase_ :
def __enter__( self):
'''simple docstring'''
gc.collect()
torch.cuda.empty_cache()
torch.cuda.reset_max_memory_allocated() # reset the peak gauge to zero
_lowerCAmelCase : List[str] = torch.cuda.memory_allocated()
return self
def __exit__( self, *__a):
'''simple docstring'''
gc.collect()
torch.cuda.empty_cache()
_lowerCAmelCase : List[Any] = torch.cuda.memory_allocated()
_lowerCAmelCase : Optional[int] = torch.cuda.max_memory_allocated()
_lowerCAmelCase : List[Any] = bamb(self.end - self.begin)
_lowerCAmelCase : int = bamb(self.peak - self.begin)
# print(f"delta used/peak {self.used:4d}/{self.peaked:4d}")
def A ( _lowerCamelCase , _lowerCamelCase = 16 , _lowerCamelCase = "bert-base-cased" , _lowerCamelCase = 320 , _lowerCamelCase = 160 , ):
'''simple docstring'''
_lowerCAmelCase : Optional[Any] = AutoTokenizer.from_pretrained(_lowerCamelCase )
_lowerCAmelCase : Optional[int] = load_dataset(
"glue" , "mrpc" , split={"train": F"train[:{n_train}]", "validation": F"validation[:{n_val}]"} )
def tokenize_function(_lowerCamelCase ):
# max_length=None => use the model max length (it's actually the default)
_lowerCAmelCase : Optional[Any] = tokenizer(examples["sentence1"] , examples["sentence2"] , truncation=_lowerCamelCase , max_length=_lowerCamelCase )
return outputs
# Apply the method we just defined to all the examples in all the splits of the dataset
_lowerCAmelCase : List[str] = datasets.map(
_lowerCamelCase , batched=_lowerCamelCase , remove_columns=["idx", "sentence1", "sentence2"] , load_from_cache_file=_lowerCamelCase )
# We also rename the 'label' column to 'labels' which is the expected name for labels by the models of the
# transformers library
_lowerCAmelCase : Any = tokenized_datasets.rename_column("label" , "labels" )
def collate_fn(_lowerCamelCase ):
# 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(_lowerCamelCase , padding="max_length" , max_length=128 , return_tensors="pt" )
return tokenizer.pad(_lowerCamelCase , padding="longest" , return_tensors="pt" )
# Instantiate dataloaders.
_lowerCAmelCase : Dict = DataLoader(
tokenized_datasets["train"] , shuffle=_lowerCamelCase , collate_fn=_lowerCamelCase , batch_size=_lowerCamelCase )
_lowerCAmelCase : Dict = DataLoader(
tokenized_datasets["validation"] , shuffle=_lowerCamelCase , collate_fn=_lowerCamelCase , batch_size=_lowerCamelCase )
return train_dataloader, eval_dataloader
def A ( _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : Dict = Accelerator()
# Sample hyper-parameters for learning rate, batch size, seed and a few other HPs
_lowerCAmelCase : Optional[int] = config["lr"]
_lowerCAmelCase : Dict = int(config["num_epochs"] )
_lowerCAmelCase : str = int(config["seed"] )
_lowerCAmelCase : Tuple = int(config["batch_size"] )
_lowerCAmelCase : Tuple = args.model_name_or_path
set_seed(_lowerCamelCase )
_lowerCAmelCase , _lowerCAmelCase : List[str] = get_dataloaders(_lowerCamelCase , _lowerCamelCase , _lowerCamelCase , args.n_train , args.n_val )
# Instantiate the model (we build the model here so that the seed also control new weights initialization)
_lowerCAmelCase : Any = AutoModelForSequenceClassification.from_pretrained(_lowerCamelCase , return_dict=_lowerCamelCase )
# Instantiate optimizer
_lowerCAmelCase : Optional[Any] = (
AdamW
if accelerator.state.deepspeed_plugin is None
or "optimizer" not in accelerator.state.deepspeed_plugin.deepspeed_config
else DummyOptim
)
_lowerCAmelCase : Union[str, Any] = optimizer_cls(params=model.parameters() , lr=_lowerCamelCase )
if accelerator.state.deepspeed_plugin is not None:
_lowerCAmelCase : Optional[Any] = accelerator.state.deepspeed_plugin.deepspeed_config[
"gradient_accumulation_steps"
]
else:
_lowerCAmelCase : int = 1
_lowerCAmelCase : List[str] = (len(_lowerCamelCase ) * num_epochs) // gradient_accumulation_steps
# Instantiate scheduler
if (
accelerator.state.deepspeed_plugin is None
or "scheduler" not in accelerator.state.deepspeed_plugin.deepspeed_config
):
_lowerCAmelCase : int = get_linear_schedule_with_warmup(
optimizer=_lowerCamelCase , num_warmup_steps=0 , num_training_steps=_lowerCamelCase , )
else:
_lowerCAmelCase : Optional[int] = DummyScheduler(_lowerCamelCase , total_num_steps=_lowerCamelCase , 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.
_lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase : int = accelerator.prepare(
_lowerCamelCase , _lowerCamelCase , _lowerCamelCase , _lowerCamelCase , _lowerCamelCase )
# We need to keep track of how many total steps we have iterated over
_lowerCAmelCase : int = 0
# We also need to keep track of the stating epoch so files are named properly
_lowerCAmelCase : int = 0
# Now we train the model
_lowerCAmelCase : Optional[Any] = {}
for epoch in range(_lowerCamelCase , _lowerCamelCase ):
with TorchTracemalloc() as tracemalloc:
model.train()
for step, batch in enumerate(_lowerCamelCase ):
_lowerCAmelCase : str = model(**_lowerCamelCase )
_lowerCAmelCase : Optional[int] = outputs.loss
_lowerCAmelCase : Any = loss / gradient_accumulation_steps
accelerator.backward(_lowerCamelCase )
if step % gradient_accumulation_steps == 0:
optimizer.step()
lr_scheduler.step()
optimizer.zero_grad()
overall_step += 1
# Printing the GPU memory usage details such as allocated memory, peak memory, and total memory usage
accelerator.print("Memory before entering the train : {}".format(bamb(tracemalloc.begin ) ) )
accelerator.print("Memory consumed at the end of the train (end-begin): {}".format(tracemalloc.used ) )
accelerator.print("Peak Memory consumed during the train (max-begin): {}".format(tracemalloc.peaked ) )
accelerator.print(
"Total Peak Memory consumed during the train (max): {}".format(
tracemalloc.peaked + bamb(tracemalloc.begin ) ) )
_lowerCAmelCase : Optional[Any] = tracemalloc.peaked + bamb(tracemalloc.begin )
if args.peak_memory_upper_bound is not None:
assert (
train_total_peak_memory[F"epoch-{epoch}"] <= args.peak_memory_upper_bound
), "Peak memory usage exceeded the upper bound"
accelerator.wait_for_everyone()
if accelerator.is_main_process:
with open(os.path.join(args.output_dir , "peak_memory_utilization.json" ) , "w" ) as f:
json.dump(_lowerCamelCase , _lowerCamelCase )
def A ( ):
'''simple docstring'''
_lowerCAmelCase : Dict = argparse.ArgumentParser(description="Simple example of training script tracking peak GPU memory usage." )
parser.add_argument(
"--model_name_or_path" , type=_lowerCamelCase , default="bert-base-cased" , help="Path to pretrained model or model identifier from huggingface.co/models." , required=_lowerCamelCase , )
parser.add_argument(
"--output_dir" , type=_lowerCamelCase , default="." , help="Optional save directory where all checkpoint folders will be stored. Default is the current working directory." , )
parser.add_argument(
"--peak_memory_upper_bound" , type=_lowerCamelCase , default=_lowerCamelCase , help="The upper bound of peak memory usage in MB. If set, the training will throw an error if the peak memory usage exceeds this value." , )
parser.add_argument(
"--n_train" , type=_lowerCamelCase , default=320 , help="Number of training examples to use." , )
parser.add_argument(
"--n_val" , type=_lowerCamelCase , default=160 , help="Number of validation examples to use." , )
parser.add_argument(
"--num_epochs" , type=_lowerCamelCase , default=1 , help="Number of train epochs." , )
_lowerCAmelCase : int = parser.parse_args()
_lowerCAmelCase : int = {"lr": 2e-5, "num_epochs": args.num_epochs, "seed": 42, "batch_size": 16}
training_function(_lowerCamelCase , _lowerCamelCase )
if __name__ == "__main__":
main()
| 36
|
import sys
import tempfile
import unittest
import unittest.mock as mock
from pathlib import Path
from huggingface_hub import HfFolder, delete_repo
from requests.exceptions import HTTPError
from transformers import AutoImageProcessor, ViTImageProcessor
from transformers.testing_utils import TOKEN, USER, get_tests_dir, is_staging_test
sys.path.append(str(Path(__file__).parent.parent / "utils"))
from test_module.custom_image_processing import CustomImageProcessor # noqa E402
_snake_case = get_tests_dir("fixtures")
class UpperCAmelCase_ ( unittest.TestCase):
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Optional[Any] = mock.Mock()
_lowerCAmelCase : int = 500
_lowerCAmelCase : Tuple = {}
_lowerCAmelCase : str = HTTPError
_lowerCAmelCase : Union[str, Any] = {}
# Download this model to make sure it's in the cache.
_lowerCAmelCase : Tuple = ViTImageProcessor.from_pretrained("hf-internal-testing/tiny-random-vit")
# Under the mock environment we get a 500 error when trying to reach the model.
with mock.patch("requests.Session.request", return_value=__a) as mock_head:
_lowerCAmelCase : Optional[int] = ViTImageProcessor.from_pretrained("hf-internal-testing/tiny-random-vit")
# This check we did call the fake head request
mock_head.assert_called()
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Tuple = ViTImageProcessor.from_pretrained(
"https://huggingface.co/hf-internal-testing/tiny-random-vit/resolve/main/preprocessor_config.json")
def snake_case__ ( self):
'''simple docstring'''
with self.assertRaises(__a):
# config is in subfolder, the following should not work without specifying the subfolder
_lowerCAmelCase : int = AutoImageProcessor.from_pretrained("hf-internal-testing/stable-diffusion-all-variants")
_lowerCAmelCase : Optional[Any] = AutoImageProcessor.from_pretrained(
"hf-internal-testing/stable-diffusion-all-variants", subfolder="feature_extractor")
self.assertIsNotNone(__a)
@is_staging_test
class UpperCAmelCase_ ( unittest.TestCase):
@classmethod
def snake_case__ ( cls):
'''simple docstring'''
_lowerCAmelCase : Union[str, Any] = TOKEN
HfFolder.save_token(__a)
@classmethod
def snake_case__ ( cls):
'''simple docstring'''
try:
delete_repo(token=cls._token, repo_id="test-image-processor")
except HTTPError:
pass
try:
delete_repo(token=cls._token, repo_id="valid_org/test-image-processor-org")
except HTTPError:
pass
try:
delete_repo(token=cls._token, repo_id="test-dynamic-image-processor")
except HTTPError:
pass
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Optional[int] = ViTImageProcessor.from_pretrained(__a)
image_processor.push_to_hub("test-image-processor", use_auth_token=self._token)
_lowerCAmelCase : str = ViTImageProcessor.from_pretrained(f"{USER}/test-image-processor")
for k, v in image_processor.__dict__.items():
self.assertEqual(__a, getattr(__a, __a))
# Reset repo
delete_repo(token=self._token, repo_id="test-image-processor")
# Push to hub via save_pretrained
with tempfile.TemporaryDirectory() as tmp_dir:
image_processor.save_pretrained(
__a, repo_id="test-image-processor", push_to_hub=__a, use_auth_token=self._token)
_lowerCAmelCase : Optional[int] = ViTImageProcessor.from_pretrained(f"{USER}/test-image-processor")
for k, v in image_processor.__dict__.items():
self.assertEqual(__a, getattr(__a, __a))
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Any = ViTImageProcessor.from_pretrained(__a)
image_processor.push_to_hub("valid_org/test-image-processor", use_auth_token=self._token)
_lowerCAmelCase : Tuple = ViTImageProcessor.from_pretrained("valid_org/test-image-processor")
for k, v in image_processor.__dict__.items():
self.assertEqual(__a, getattr(__a, __a))
# Reset repo
delete_repo(token=self._token, repo_id="valid_org/test-image-processor")
# Push to hub via save_pretrained
with tempfile.TemporaryDirectory() as tmp_dir:
image_processor.save_pretrained(
__a, repo_id="valid_org/test-image-processor-org", push_to_hub=__a, use_auth_token=self._token)
_lowerCAmelCase : Optional[int] = ViTImageProcessor.from_pretrained("valid_org/test-image-processor-org")
for k, v in image_processor.__dict__.items():
self.assertEqual(__a, getattr(__a, __a))
def snake_case__ ( self):
'''simple docstring'''
CustomImageProcessor.register_for_auto_class()
_lowerCAmelCase : List[str] = CustomImageProcessor.from_pretrained(__a)
image_processor.push_to_hub("test-dynamic-image-processor", use_auth_token=self._token)
# This has added the proper auto_map field to the config
self.assertDictEqual(
image_processor.auto_map, {"AutoImageProcessor": "custom_image_processing.CustomImageProcessor"}, )
_lowerCAmelCase : Tuple = AutoImageProcessor.from_pretrained(
f"{USER}/test-dynamic-image-processor", trust_remote_code=__a)
# Can't make an isinstance check because the new_image_processor is from the CustomImageProcessor class of a dynamic module
self.assertEqual(new_image_processor.__class__.__name__, "CustomImageProcessor")
| 36
| 1
|
import argparse
import requests
import torch
# pip3 install salesforce-lavis
# I'm actually installing a slightly modified version: pip3 install git+https://github.com/nielsrogge/LAVIS.git@fix_lavis_float32 (there's also the fix_lavis branch)
# also note: to convert Vicuna checkpoints, we had to include /home/niels/python_projects/checkpoints/FastChat/vicuna-7b in lavis/configs/models/blip2/blip2_instruct_vicuna7b.yaml
# same for Vicuna-13b
from lavis.models import load_model_and_preprocess
from PIL import Image
from transformers import (
AutoTokenizer,
BlipImageProcessor,
InstructBlipConfig,
InstructBlipForConditionalGeneration,
InstructBlipProcessor,
InstructBlipQFormerConfig,
InstructBlipVisionConfig,
LlamaConfig,
LlamaTokenizerFast,
TaConfig,
TaTokenizerFast,
)
from transformers.utils.constants import OPENAI_CLIP_MEAN, OPENAI_CLIP_STD
def A ( ):
'''simple docstring'''
_lowerCAmelCase : Optional[Any] = "https://raw.githubusercontent.com/salesforce/LAVIS/main/docs/_static/Confusing-Pictures.jpg"
_lowerCAmelCase : List[str] = Image.open(requests.get(_lowerCamelCase , stream=_lowerCamelCase ).raw ).convert("RGB" )
return image
def A ( _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : Optional[int] = []
# fmt: off
# vision encoder
rename_keys.append(("visual_encoder.cls_token", "vision_model.embeddings.class_embedding") )
rename_keys.append(("visual_encoder.pos_embed", "vision_model.embeddings.position_embedding") )
rename_keys.append(("visual_encoder.patch_embed.proj.weight", "vision_model.embeddings.patch_embedding.weight") )
rename_keys.append(("visual_encoder.patch_embed.proj.bias", "vision_model.embeddings.patch_embedding.bias") )
rename_keys.append(("ln_vision.weight", "vision_model.post_layernorm.weight") )
rename_keys.append(("ln_vision.bias", "vision_model.post_layernorm.bias") )
for i in range(config.vision_config.num_hidden_layers ):
rename_keys.append((F"visual_encoder.blocks.{i}.norm1.weight", F"vision_model.encoder.layers.{i}.layer_norm1.weight") )
rename_keys.append((F"visual_encoder.blocks.{i}.norm1.bias", F"vision_model.encoder.layers.{i}.layer_norm1.bias") )
rename_keys.append((F"visual_encoder.blocks.{i}.norm2.weight", F"vision_model.encoder.layers.{i}.layer_norm2.weight") )
rename_keys.append((F"visual_encoder.blocks.{i}.norm2.bias", F"vision_model.encoder.layers.{i}.layer_norm2.bias") )
rename_keys.append((F"visual_encoder.blocks.{i}.attn.qkv.weight", F"vision_model.encoder.layers.{i}.self_attn.qkv.weight") )
rename_keys.append((F"visual_encoder.blocks.{i}.attn.proj.weight", F"vision_model.encoder.layers.{i}.self_attn.projection.weight",) )
rename_keys.append((F"visual_encoder.blocks.{i}.attn.proj.bias", F"vision_model.encoder.layers.{i}.self_attn.projection.bias") )
rename_keys.append((F"visual_encoder.blocks.{i}.mlp.fc1.weight", F"vision_model.encoder.layers.{i}.mlp.fc1.weight") )
rename_keys.append((F"visual_encoder.blocks.{i}.mlp.fc1.bias", F"vision_model.encoder.layers.{i}.mlp.fc1.bias") )
rename_keys.append((F"visual_encoder.blocks.{i}.mlp.fc2.weight", F"vision_model.encoder.layers.{i}.mlp.fc2.weight") )
rename_keys.append((F"visual_encoder.blocks.{i}.mlp.fc2.bias", F"vision_model.encoder.layers.{i}.mlp.fc2.bias") )
# QFormer
rename_keys.append(("Qformer.bert.embeddings.LayerNorm.weight", "qformer.embeddings.layernorm.weight") )
rename_keys.append(("Qformer.bert.embeddings.LayerNorm.bias", "qformer.embeddings.layernorm.bias") )
# fmt: on
return rename_keys
def A ( _lowerCamelCase , _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : Any = dct.pop(_lowerCamelCase )
_lowerCAmelCase : Optional[int] = val
def A ( _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
for i in range(config.vision_config.num_hidden_layers ):
# read in original q and v biases
_lowerCAmelCase : Tuple = state_dict.pop(F"visual_encoder.blocks.{i}.attn.q_bias" )
_lowerCAmelCase : Optional[int] = state_dict.pop(F"visual_encoder.blocks.{i}.attn.v_bias" )
# next, set bias in the state dict
_lowerCAmelCase : str = torch.cat((q_bias, torch.zeros_like(_lowerCamelCase , requires_grad=_lowerCamelCase ), v_bias) )
_lowerCAmelCase : Any = qkv_bias
def A ( _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : List[str] = 364 if "coco" in model_name else 224
_lowerCAmelCase : Dict = InstructBlipVisionConfig(image_size=_lowerCamelCase ).to_dict()
# make sure the models have proper bos_token_id and eos_token_id set (important for generation)
# seems like flan-T5 models don't have bos_token_id properly set?
if "t5-xl" in model_name:
_lowerCAmelCase : Any = TaConfig.from_pretrained("google/flan-t5-xl" , dense_act_fn="gelu" , bos_token_id=1 ).to_dict()
elif "t5-xxl" in model_name:
_lowerCAmelCase : int = TaConfig.from_pretrained("google/flan-t5-xxl" , dense_act_fn="gelu" , bos_token_id=1 ).to_dict()
elif "vicuna-7b" in model_name:
_lowerCAmelCase : Union[str, Any] = LlamaConfig.from_pretrained("decapoda-research/llama-7b-hf" , vocab_size=32_001 ).to_dict()
elif "vicuna-13b" in model_name:
_lowerCAmelCase : Any = LlamaConfig.from_pretrained("decapoda-research/llama-13b-hf" , vocab_size=32_001 ).to_dict()
else:
raise ValueError("Model name not supported" )
# the authors add one special "[DEC]" token to the vocab of Q-Former, hence vocab size = 30522 + 1
_lowerCAmelCase : int = InstructBlipQFormerConfig(vocab_size=30_523 ).to_dict()
_lowerCAmelCase : str = InstructBlipConfig(vision_config=_lowerCamelCase , text_config=_lowerCamelCase , qformer_config=_lowerCamelCase )
return config, image_size
@torch.no_grad()
def A ( _lowerCamelCase , _lowerCamelCase=None , _lowerCamelCase=False ):
'''simple docstring'''
_lowerCAmelCase : Optional[int] = AutoTokenizer.from_pretrained("bert-base-uncased" , truncation_side="left" )
qformer_tokenizer.add_special_tokens({"bos_token": "[DEC]"} )
if "t5" in model_name:
_lowerCAmelCase : Any = TaTokenizerFast.from_pretrained("google/flan-t5-xl" , truncation_side="left" )
elif "vicuna" in model_name:
# the following was used in the original implementation:
# tokenizer = LlamaTokenizer.from_pretrained("huggyllama/llama-7b", use_fast=False, truncation_side="left")
# tokenizer.add_special_tokens({"pad_token": "[PAD]"})
# tokenizer.add_special_tokens({"bos_token": "</s>"})
# tokenizer.add_special_tokens({"eos_token": "</s>"})
# tokenizer.add_special_tokens({"unk_token": "</s>"})
_lowerCAmelCase : str = LlamaTokenizerFast.from_pretrained(
"huggyllama/llama-7b" , truncation_side="left" , bos_token="</s>" , unk_token="</s>" )
tokenizer.add_special_tokens({"pad_token": "[PAD]"} )
_lowerCAmelCase , _lowerCAmelCase : Optional[int] = get_blipa_config(_lowerCamelCase )
_lowerCAmelCase : Optional[int] = InstructBlipForConditionalGeneration(_lowerCamelCase ).eval()
_lowerCAmelCase : Dict = {
"instructblip-vicuna-7b": ("blip2_vicuna_instruct", "vicuna7b"),
"instructblip-vicuna-13b": ("blip2_vicuna_instruct", "vicuna13b"),
"instructblip-flan-t5-xl": ("blip2_t5_instruct", "flant5xl"),
"instructblip-flan-t5-xxl": ("blip2_t5_instruct", "flant5xxl"),
}
_lowerCAmelCase , _lowerCAmelCase : Optional[Any] = model_name_to_original[model_name]
# load original model
print("Loading original model..." )
_lowerCAmelCase : Optional[int] = "cuda:1" if torch.cuda.is_available() else "cpu"
_lowerCAmelCase : Optional[int] = "cuda:2" if torch.cuda.is_available() else "cpu"
_lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase : int = load_model_and_preprocess(
name=_lowerCamelCase , model_type=_lowerCamelCase , is_eval=_lowerCamelCase , device=_lowerCamelCase )
original_model.eval()
print("Done!" )
# update state dict keys
_lowerCAmelCase : Union[str, Any] = original_model.state_dict()
_lowerCAmelCase : Optional[Any] = create_rename_keys(_lowerCamelCase )
for src, dest in rename_keys:
rename_key(_lowerCamelCase , _lowerCamelCase , _lowerCamelCase )
# some keys can be renamed efficiently
for key, val in state_dict.copy().items():
_lowerCAmelCase : Optional[int] = state_dict.pop(_lowerCamelCase )
if key.startswith("Qformer.bert" ):
_lowerCAmelCase : List[Any] = key.replace("Qformer.bert" , "qformer" )
if "attention.self" in key:
_lowerCAmelCase : Optional[int] = key.replace("self" , "attention" )
if "llm_proj" in key:
_lowerCAmelCase : Union[str, Any] = key.replace("llm_proj" , "language_projection" )
if "t5_proj" in key:
_lowerCAmelCase : List[str] = key.replace("t5_proj" , "language_projection" )
if key.startswith("llm_model" ):
_lowerCAmelCase : Tuple = key.replace("llm_model" , "language_model" )
if key.startswith("t5" ):
_lowerCAmelCase : Optional[Any] = key.replace("t5" , "language" )
_lowerCAmelCase : Optional[Any] = val
# read in qv biases
read_in_q_v_bias(_lowerCamelCase , _lowerCamelCase )
# note: weights get loaded in torch.float32 by default
hf_model.load_state_dict(_lowerCamelCase , strict=_lowerCamelCase )
_lowerCAmelCase : int = load_demo_image()
_lowerCAmelCase : Optional[int] = "What is unusual about this image?"
# create processor
_lowerCAmelCase : Union[str, Any] = BlipImageProcessor(
size={"height": image_size, "width": image_size} , image_mean=_lowerCamelCase , image_std=_lowerCamelCase )
_lowerCAmelCase : List[str] = InstructBlipProcessor(
image_processor=_lowerCamelCase , tokenizer=_lowerCamelCase , qformer_tokenizer=_lowerCamelCase , )
_lowerCAmelCase : int = processor(images=_lowerCamelCase , text=_lowerCamelCase , return_tensors="pt" ).to(_lowerCamelCase )
# make sure processor creates exact same pixel values
_lowerCAmelCase : Tuple = vis_processors["eval"](_lowerCamelCase ).unsqueeze(0 ).to(_lowerCamelCase )
_lowerCAmelCase : Any = inputs.pixel_values
assert torch.allclose(original_pixel_values.to(pixel_values.device ) , _lowerCamelCase )
original_model.to(_lowerCamelCase )
hf_model.to(_lowerCamelCase )
with torch.no_grad():
if "vicuna" in model_name:
_lowerCAmelCase : List[Any] = original_model({"image": original_pixel_values, "text_input": [prompt]} ).logits
_lowerCAmelCase : Union[str, Any] = hf_model(**_lowerCamelCase ).logits
else:
_lowerCAmelCase : Optional[int] = original_model(
{"image": original_pixel_values, "text_input": [prompt], "text_output": ["\n"]} ).logits
_lowerCAmelCase : List[str] = tokenizer("\n" , return_tensors="pt" ).input_ids.to(_lowerCamelCase )
_lowerCAmelCase : Optional[Any] = label_input_ids.masked_fill(label_input_ids == tokenizer.pad_token_id , -100 )
_lowerCAmelCase : Tuple = hf_model(**_lowerCamelCase , labels=_lowerCamelCase ).logits
print("First values of original logits:" , original_logits[0, :3, :3] )
print("First values of HF logits:" , logits[0, :3, :3] )
# assert values
assert original_logits.shape == logits.shape
_lowerCAmelCase : Dict = 1e-4 if "vicuna" in model_name else 1e-5
assert torch.allclose(original_logits.to(logits.device ) , _lowerCamelCase , atol=_lowerCamelCase )
print("Looks ok!" )
print("Generating with original model..." )
_lowerCAmelCase : Dict = original_model.generate({"image": original_pixel_values, "prompt": prompt} , num_beams=5 )
# important: we need to cast the weights of the HF model to the appropriate type
print("Generating with HF model..." )
_lowerCAmelCase : Any = hf_model.generate(
**_lowerCamelCase , do_sample=_lowerCamelCase , num_beams=5 , max_length=256 , min_length=1 , top_p=0.9 , repetition_penalty=1.5 , length_penalty=1.0 , temperature=1 , )
if "vicuna" in model_name:
# convert output id 0 to 2 (eos_token_id)
# TODO add this in the generate method?
_lowerCAmelCase : List[str] = 2
print("Original generation:" , _lowerCamelCase )
_lowerCAmelCase : Optional[int] = processor.batch_decode(_lowerCamelCase , skip_special_tokens=_lowerCamelCase )
_lowerCAmelCase : Optional[Any] = [text.strip() for text in output_text]
print("HF generation:" , _lowerCamelCase )
if pytorch_dump_folder_path is not None:
processor.save_pretrained(_lowerCamelCase )
hf_model.save_pretrained(_lowerCamelCase )
if push_to_hub:
processor.push_to_hub(F"Salesforce/{model_name}" )
hf_model.push_to_hub(F"Salesforce/{model_name}" )
if __name__ == "__main__":
_snake_case = argparse.ArgumentParser()
_snake_case = [
"instructblip-vicuna-7b",
"instructblip-vicuna-13b",
"instructblip-flan-t5-xl",
"instructblip-flan-t5-xxl",
]
parser.add_argument(
"--model_name",
default="instructblip-flan-t5-xl",
choices=choices,
type=str,
help="Path to hf config.json of model to convert",
)
parser.add_argument("--pytorch_dump_folder_path", default=None, type=str, help="Path to the output PyTorch model.")
parser.add_argument(
"--push_to_hub",
action="store_true",
help="Whether to push the model and processor to the hub after converting",
)
_snake_case = parser.parse_args()
convert_blipa_checkpoint(args.model_name, args.pytorch_dump_folder_path, args.push_to_hub)
| 36
|
import unittest
from transformers import LiltConfig, is_torch_available
from transformers.testing_utils import require_torch, slow, torch_device
from ...generation.test_utils import GenerationTesterMixin
from ...test_configuration_common import ConfigTester
from ...test_modeling_common import ModelTesterMixin, ids_tensor
from ...test_pipeline_mixin import PipelineTesterMixin
if is_torch_available():
import torch
from transformers import (
LiltForQuestionAnswering,
LiltForSequenceClassification,
LiltForTokenClassification,
LiltModel,
)
from transformers.models.lilt.modeling_lilt import LILT_PRETRAINED_MODEL_ARCHIVE_LIST
class UpperCAmelCase_ :
def __init__( self, __a, __a=13, __a=7, __a=True, __a=True, __a=True, __a=True, __a=99, __a=24, __a=2, __a=6, __a=37, __a="gelu", __a=0.1, __a=0.1, __a=512, __a=16, __a=2, __a=0.02, __a=3, __a=None, __a=1000, ):
'''simple docstring'''
_lowerCAmelCase : Tuple = parent
_lowerCAmelCase : List[str] = batch_size
_lowerCAmelCase : int = seq_length
_lowerCAmelCase : Optional[int] = is_training
_lowerCAmelCase : Dict = use_input_mask
_lowerCAmelCase : List[str] = use_token_type_ids
_lowerCAmelCase : str = use_labels
_lowerCAmelCase : Optional[Any] = vocab_size
_lowerCAmelCase : Tuple = hidden_size
_lowerCAmelCase : List[Any] = num_hidden_layers
_lowerCAmelCase : Optional[Any] = num_attention_heads
_lowerCAmelCase : Any = intermediate_size
_lowerCAmelCase : List[str] = hidden_act
_lowerCAmelCase : Union[str, Any] = hidden_dropout_prob
_lowerCAmelCase : Any = attention_probs_dropout_prob
_lowerCAmelCase : int = max_position_embeddings
_lowerCAmelCase : Optional[int] = type_vocab_size
_lowerCAmelCase : Optional[Any] = type_sequence_label_size
_lowerCAmelCase : List[str] = initializer_range
_lowerCAmelCase : List[Any] = num_labels
_lowerCAmelCase : Tuple = scope
_lowerCAmelCase : str = range_bbox
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Dict = ids_tensor([self.batch_size, self.seq_length], self.vocab_size)
_lowerCAmelCase : int = ids_tensor([self.batch_size, self.seq_length, 4], self.range_bbox)
# Ensure that bbox is legal
for i in range(bbox.shape[0]):
for j in range(bbox.shape[1]):
if bbox[i, j, 3] < bbox[i, j, 1]:
_lowerCAmelCase : Dict = bbox[i, j, 3]
_lowerCAmelCase : int = bbox[i, j, 1]
_lowerCAmelCase : Tuple = t
if bbox[i, j, 2] < bbox[i, j, 0]:
_lowerCAmelCase : str = bbox[i, j, 2]
_lowerCAmelCase : List[Any] = bbox[i, j, 0]
_lowerCAmelCase : str = t
_lowerCAmelCase : Optional[Any] = None
if self.use_input_mask:
_lowerCAmelCase : Union[str, Any] = ids_tensor([self.batch_size, self.seq_length], vocab_size=2)
_lowerCAmelCase : Dict = None
if self.use_token_type_ids:
_lowerCAmelCase : Any = ids_tensor([self.batch_size, self.seq_length], self.type_vocab_size)
_lowerCAmelCase : Optional[int] = None
_lowerCAmelCase : Optional[Any] = None
if self.use_labels:
_lowerCAmelCase : Optional[Any] = ids_tensor([self.batch_size], self.type_sequence_label_size)
_lowerCAmelCase : Any = ids_tensor([self.batch_size, self.seq_length], self.num_labels)
_lowerCAmelCase : Optional[int] = self.get_config()
return config, input_ids, bbox, token_type_ids, input_mask, sequence_labels, token_labels
def snake_case__ ( self):
'''simple docstring'''
return LiltConfig(
vocab_size=self.vocab_size, hidden_size=self.hidden_size, num_hidden_layers=self.num_hidden_layers, num_attention_heads=self.num_attention_heads, intermediate_size=self.intermediate_size, hidden_act=self.hidden_act, hidden_dropout_prob=self.hidden_dropout_prob, attention_probs_dropout_prob=self.attention_probs_dropout_prob, max_position_embeddings=self.max_position_embeddings, type_vocab_size=self.type_vocab_size, initializer_range=self.initializer_range, )
def snake_case__ ( self, __a, __a, __a, __a, __a, __a, __a, ):
'''simple docstring'''
_lowerCAmelCase : Union[str, Any] = LiltModel(config=__a)
model.to(__a)
model.eval()
_lowerCAmelCase : Dict = model(__a, bbox=__a, attention_mask=__a, token_type_ids=__a)
_lowerCAmelCase : str = model(__a, bbox=__a, token_type_ids=__a)
_lowerCAmelCase : List[Any] = model(__a, bbox=__a)
self.parent.assertEqual(result.last_hidden_state.shape, (self.batch_size, self.seq_length, self.hidden_size))
self.parent.assertEqual(result.pooler_output.shape, (self.batch_size, self.hidden_size))
def snake_case__ ( self, __a, __a, __a, __a, __a, __a, __a, ):
'''simple docstring'''
_lowerCAmelCase : List[Any] = self.num_labels
_lowerCAmelCase : Optional[Any] = LiltForTokenClassification(config=__a)
model.to(__a)
model.eval()
_lowerCAmelCase : Dict = model(
__a, bbox=__a, attention_mask=__a, token_type_ids=__a, labels=__a)
self.parent.assertEqual(result.logits.shape, (self.batch_size, self.seq_length, self.num_labels))
def snake_case__ ( self, __a, __a, __a, __a, __a, __a, __a, ):
'''simple docstring'''
_lowerCAmelCase : Optional[int] = LiltForQuestionAnswering(config=__a)
model.to(__a)
model.eval()
_lowerCAmelCase : Tuple = model(
__a, bbox=__a, attention_mask=__a, token_type_ids=__a, start_positions=__a, end_positions=__a, )
self.parent.assertEqual(result.start_logits.shape, (self.batch_size, self.seq_length))
self.parent.assertEqual(result.end_logits.shape, (self.batch_size, self.seq_length))
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Optional[Any] = self.prepare_config_and_inputs()
(
(
_lowerCAmelCase
) , (
_lowerCAmelCase
) , (
_lowerCAmelCase
) , (
_lowerCAmelCase
) , (
_lowerCAmelCase
) , (
_lowerCAmelCase
) , (
_lowerCAmelCase
) ,
) : Dict = config_and_inputs
_lowerCAmelCase : List[Any] = {
"input_ids": input_ids,
"bbox": bbox,
"token_type_ids": token_type_ids,
"attention_mask": input_mask,
}
return config, inputs_dict
@require_torch
class UpperCAmelCase_ ( a , a , a , unittest.TestCase):
lowerCamelCase__ = (
(
LiltModel,
LiltForSequenceClassification,
LiltForTokenClassification,
LiltForQuestionAnswering,
)
if is_torch_available()
else ()
)
lowerCamelCase__ = (
{
'feature-extraction': LiltModel,
'question-answering': LiltForQuestionAnswering,
'text-classification': LiltForSequenceClassification,
'token-classification': LiltForTokenClassification,
'zero-shot': LiltForSequenceClassification,
}
if is_torch_available()
else {}
)
lowerCamelCase__ = False
lowerCamelCase__ = False
def snake_case__ ( self, __a, __a, __a, __a, __a):
'''simple docstring'''
return True
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Optional[Any] = LiltModelTester(self)
_lowerCAmelCase : Union[str, Any] = ConfigTester(self, config_class=__a, hidden_size=37)
def snake_case__ ( self):
'''simple docstring'''
self.config_tester.run_common_tests()
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Dict = self.model_tester.prepare_config_and_inputs()
self.model_tester.create_and_check_model(*__a)
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : int = self.model_tester.prepare_config_and_inputs()
for type in ["absolute", "relative_key", "relative_key_query"]:
_lowerCAmelCase : Any = type
self.model_tester.create_and_check_model(*__a)
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : int = self.model_tester.prepare_config_and_inputs()
self.model_tester.create_and_check_for_token_classification(*__a)
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Optional[int] = self.model_tester.prepare_config_and_inputs()
self.model_tester.create_and_check_for_question_answering(*__a)
@slow
def snake_case__ ( self):
'''simple docstring'''
for model_name in LILT_PRETRAINED_MODEL_ARCHIVE_LIST[:1]:
_lowerCAmelCase : str = LiltModel.from_pretrained(__a)
self.assertIsNotNone(__a)
@require_torch
@slow
class UpperCAmelCase_ ( unittest.TestCase):
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Dict = LiltModel.from_pretrained("SCUT-DLVCLab/lilt-roberta-en-base").to(__a)
_lowerCAmelCase : Any = torch.tensor([[1, 2]], device=__a)
_lowerCAmelCase : str = torch.tensor([[[1, 2, 3, 4], [5, 6, 7, 8]]], device=__a)
# forward pass
with torch.no_grad():
_lowerCAmelCase : Optional[Any] = model(input_ids=__a, bbox=__a)
_lowerCAmelCase : Optional[int] = torch.Size([1, 2, 768])
_lowerCAmelCase : List[str] = torch.tensor(
[[-0.0_653, 0.0_950, -0.0_061], [-0.0_545, 0.0_926, -0.0_324]], device=__a, )
self.assertTrue(outputs.last_hidden_state.shape, __a)
self.assertTrue(torch.allclose(outputs.last_hidden_state[0, :, :3], __a, atol=1E-3))
| 36
| 1
|
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 UpperCAmelCase_ ( a , unittest.TestCase):
lowerCamelCase__ = TextToVideoSDPipeline
lowerCamelCase__ = TEXT_TO_IMAGE_PARAMS
lowerCamelCase__ = TEXT_TO_IMAGE_BATCH_PARAMS
# No `output_type`.
lowerCamelCase__ = frozenset(
[
'num_inference_steps',
'generator',
'latents',
'return_dict',
'callback',
'callback_steps',
])
def snake_case__ ( self):
'''simple docstring'''
torch.manual_seed(0)
_lowerCAmelCase : Optional[int] = 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, )
_lowerCAmelCase : Optional[int] = DDIMScheduler(
beta_start=0.00_085, beta_end=0.012, beta_schedule="scaled_linear", clip_sample=__a, set_alpha_to_one=__a, )
torch.manual_seed(0)
_lowerCAmelCase : str = 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)
_lowerCAmelCase : List[Any] = CLIPTextConfig(
bos_token_id=0, eos_token_id=2, hidden_size=32, intermediate_size=37, layer_norm_eps=1E-05, num_attention_heads=4, num_hidden_layers=5, pad_token_id=1, vocab_size=1000, hidden_act="gelu", projection_dim=512, )
_lowerCAmelCase : Dict = CLIPTextModel(__a)
_lowerCAmelCase : Optional[int] = CLIPTokenizer.from_pretrained("hf-internal-testing/tiny-random-clip")
_lowerCAmelCase : List[Any] = {
"unet": unet,
"scheduler": scheduler,
"vae": vae,
"text_encoder": text_encoder,
"tokenizer": tokenizer,
}
return components
def snake_case__ ( self, __a, __a=0):
'''simple docstring'''
if str(__a).startswith("mps"):
_lowerCAmelCase : str = torch.manual_seed(__a)
else:
_lowerCAmelCase : Optional[int] = torch.Generator(device=__a).manual_seed(__a)
_lowerCAmelCase : Optional[Any] = {
"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 snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : List[str] = "cpu" # ensure determinism for the device-dependent torch.Generator
_lowerCAmelCase : Any = self.get_dummy_components()
_lowerCAmelCase : int = TextToVideoSDPipeline(**__a)
_lowerCAmelCase : Union[str, Any] = sd_pipe.to(__a)
sd_pipe.set_progress_bar_config(disable=__a)
_lowerCAmelCase : str = self.get_dummy_inputs(__a)
_lowerCAmelCase : Union[str, Any] = "np"
_lowerCAmelCase : Union[str, Any] = sd_pipe(**__a).frames
_lowerCAmelCase : Optional[int] = frames[0][-3:, -3:, -1]
assert frames[0].shape == (64, 64, 3)
_lowerCAmelCase : int = np.array([158.0, 160.0, 153.0, 125.0, 100.0, 121.0, 111.0, 93.0, 113.0])
assert np.abs(image_slice.flatten() - expected_slice).max() < 1E-2
def snake_case__ ( self):
'''simple docstring'''
self._test_attention_slicing_forward_pass(test_mean_pixel_difference=__a, 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 snake_case__ ( self):
'''simple docstring'''
self._test_xformers_attention_forwardGenerator_pass(test_mean_pixel_difference=__a, expected_max_diff=1E-2)
@unittest.skip(reason="Batching needs to be properly figured out first for this pipeline.")
def snake_case__ ( self):
'''simple docstring'''
pass
@unittest.skip(reason="Batching needs to be properly figured out first for this pipeline.")
def snake_case__ ( self):
'''simple docstring'''
pass
@unittest.skip(reason="`num_images_per_prompt` argument is not supported for this pipeline.")
def snake_case__ ( self):
'''simple docstring'''
pass
def snake_case__ ( self):
'''simple docstring'''
return super().test_progress_bar()
@slow
@skip_mps
class UpperCAmelCase_ ( unittest.TestCase):
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : List[str] = load_numpy(
"https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main/text_to_video/video.npy")
_lowerCAmelCase : str = TextToVideoSDPipeline.from_pretrained("damo-vilab/text-to-video-ms-1.7b")
_lowerCAmelCase : Tuple = DPMSolverMultistepScheduler.from_config(pipe.scheduler.config)
_lowerCAmelCase : Union[str, Any] = pipe.to("cuda")
_lowerCAmelCase : Any = "Spiderman is surfing"
_lowerCAmelCase : Dict = torch.Generator(device="cpu").manual_seed(0)
_lowerCAmelCase : Optional[Any] = pipe(__a, generator=__a, num_inference_steps=25, output_type="pt").frames
_lowerCAmelCase : List[Any] = video_frames.cpu().numpy()
assert np.abs(expected_video - video).mean() < 5E-2
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Dict = load_numpy(
"https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main/text_to_video/video_2step.npy")
_lowerCAmelCase : List[str] = TextToVideoSDPipeline.from_pretrained("damo-vilab/text-to-video-ms-1.7b")
_lowerCAmelCase : int = pipe.to("cuda")
_lowerCAmelCase : List[Any] = "Spiderman is surfing"
_lowerCAmelCase : int = torch.Generator(device="cpu").manual_seed(0)
_lowerCAmelCase : int = pipe(__a, generator=__a, num_inference_steps=2, output_type="pt").frames
_lowerCAmelCase : str = video_frames.cpu().numpy()
assert np.abs(expected_video - video).mean() < 5E-2
| 36
|
import argparse
import copy
def A ( _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : int = {}
with open(_lowerCamelCase ) as f:
for line in f:
if line.split()[0] not in dict_of_neighbours:
_lowerCAmelCase : Tuple = []
_list.append([line.split()[1], line.split()[2]] )
_lowerCAmelCase : Any = _list
else:
dict_of_neighbours[line.split()[0]].append(
[line.split()[1], line.split()[2]] )
if line.split()[1] not in dict_of_neighbours:
_lowerCAmelCase : str = []
_list.append([line.split()[0], line.split()[2]] )
_lowerCAmelCase : Any = _list
else:
dict_of_neighbours[line.split()[1]].append(
[line.split()[0], line.split()[2]] )
return dict_of_neighbours
def A ( _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
with open(_lowerCamelCase ) as f:
_lowerCAmelCase : str = f.read(1 )
_lowerCAmelCase : str = start_node
_lowerCAmelCase : List[str] = []
_lowerCAmelCase : Any = start_node
_lowerCAmelCase : str = 0
while visiting not in first_solution:
_lowerCAmelCase : Dict = 10_000
for k in dict_of_neighbours[visiting]:
if int(k[1] ) < int(_lowerCamelCase ) and k[0] not in first_solution:
_lowerCAmelCase : List[str] = k[1]
_lowerCAmelCase : List[Any] = k[0]
first_solution.append(_lowerCamelCase )
_lowerCAmelCase : Optional[int] = distance_of_first_solution + int(_lowerCamelCase )
_lowerCAmelCase : str = best_node
first_solution.append(_lowerCamelCase )
_lowerCAmelCase : Union[str, Any] = 0
for k in dict_of_neighbours[first_solution[-2]]:
if k[0] == start_node:
break
position += 1
_lowerCAmelCase : Tuple = (
distance_of_first_solution
+ int(dict_of_neighbours[first_solution[-2]][position][1] )
- 10_000
)
return first_solution, distance_of_first_solution
def A ( _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : Tuple = []
for n in solution[1:-1]:
_lowerCAmelCase : Dict = solution.index(_lowerCamelCase )
for kn in solution[1:-1]:
_lowerCAmelCase : Dict = solution.index(_lowerCamelCase )
if n == kn:
continue
_lowerCAmelCase : Optional[int] = copy.deepcopy(_lowerCamelCase )
_lowerCAmelCase : int = kn
_lowerCAmelCase : Dict = n
_lowerCAmelCase : Optional[int] = 0
for k in _tmp[:-1]:
_lowerCAmelCase : str = _tmp[_tmp.index(_lowerCamelCase ) + 1]
for i in dict_of_neighbours[k]:
if i[0] == next_node:
_lowerCAmelCase : Optional[Any] = distance + int(i[1] )
_tmp.append(_lowerCamelCase )
if _tmp not in neighborhood_of_solution:
neighborhood_of_solution.append(_tmp )
_lowerCAmelCase : List[Any] = len(neighborhood_of_solution[0] ) - 1
neighborhood_of_solution.sort(key=lambda _lowerCamelCase : x[index_of_last_item_in_the_list] )
return neighborhood_of_solution
def A ( _lowerCamelCase , _lowerCamelCase , _lowerCamelCase , _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : List[str] = 1
_lowerCAmelCase : int = first_solution
_lowerCAmelCase : Tuple = []
_lowerCAmelCase : Tuple = distance_of_first_solution
_lowerCAmelCase : Optional[int] = solution
while count <= iters:
_lowerCAmelCase : int = find_neighborhood(_lowerCamelCase , _lowerCamelCase )
_lowerCAmelCase : Tuple = 0
_lowerCAmelCase : Dict = neighborhood[index_of_best_solution]
_lowerCAmelCase : int = len(_lowerCamelCase ) - 1
_lowerCAmelCase : Union[str, Any] = False
while not found:
_lowerCAmelCase : Tuple = 0
while i < len(_lowerCamelCase ):
if best_solution[i] != solution[i]:
_lowerCAmelCase : str = best_solution[i]
_lowerCAmelCase : Tuple = solution[i]
break
_lowerCAmelCase : int = i + 1
if [first_exchange_node, second_exchange_node] not in tabu_list and [
second_exchange_node,
first_exchange_node,
] not in tabu_list:
tabu_list.append([first_exchange_node, second_exchange_node] )
_lowerCAmelCase : Optional[int] = True
_lowerCAmelCase : Optional[Any] = best_solution[:-1]
_lowerCAmelCase : Tuple = neighborhood[index_of_best_solution][best_cost_index]
if cost < best_cost:
_lowerCAmelCase : Union[str, Any] = cost
_lowerCAmelCase : List[Any] = solution
else:
_lowerCAmelCase : Optional[Any] = index_of_best_solution + 1
_lowerCAmelCase : Optional[Any] = neighborhood[index_of_best_solution]
if len(_lowerCamelCase ) >= size:
tabu_list.pop(0 )
_lowerCAmelCase : int = count + 1
return best_solution_ever, best_cost
def A ( _lowerCamelCase=None ):
'''simple docstring'''
_lowerCAmelCase : int = generate_neighbours(args.File )
_lowerCAmelCase , _lowerCAmelCase : List[str] = generate_first_solution(
args.File , _lowerCamelCase )
_lowerCAmelCase , _lowerCAmelCase : Any = tabu_search(
_lowerCamelCase , _lowerCamelCase , _lowerCamelCase , args.Iterations , args.Size , )
print(F"Best solution: {best_sol}, with total distance: {best_cost}." )
if __name__ == "__main__":
_snake_case = argparse.ArgumentParser(description="Tabu Search")
parser.add_argument(
"-f",
"--File",
type=str,
help="Path to the file containing the data",
required=True,
)
parser.add_argument(
"-i",
"--Iterations",
type=int,
help="How many iterations the algorithm should perform",
required=True,
)
parser.add_argument(
"-s", "--Size", type=int, help="Size of the tabu list", required=True
)
# Pass the arguments to main method
main(parser.parse_args())
| 36
| 1
|
from __future__ import absolute_import, division, print_function, unicode_literals
from torch import nn
from torch.nn import CrossEntropyLoss, MSELoss
from transformers import RobertaConfig
from transformers.file_utils import add_start_docstrings, add_start_docstrings_to_model_forward
from transformers.models.roberta.modeling_roberta import (
ROBERTA_INPUTS_DOCSTRING,
ROBERTA_START_DOCSTRING,
RobertaEmbeddings,
)
from .modeling_highway_bert import BertPreTrainedModel, DeeBertModel, HighwayException, entropy
@add_start_docstrings(
'The RoBERTa Model transformer with early exiting (DeeRoBERTa). ' , a , )
class UpperCAmelCase_ ( a):
lowerCamelCase__ = RobertaConfig
lowerCamelCase__ = 'roberta'
def __init__( self, __a):
'''simple docstring'''
super().__init__(__a)
_lowerCAmelCase : Optional[Any] = RobertaEmbeddings(__a)
self.init_weights()
@add_start_docstrings(
'RoBERTa Model (with early exiting - DeeRoBERTa) with a classifier on top,\n also takes care of multi-layer training. ' , a , )
class UpperCAmelCase_ ( a):
lowerCamelCase__ = RobertaConfig
lowerCamelCase__ = 'roberta'
def __init__( self, __a):
'''simple docstring'''
super().__init__(__a)
_lowerCAmelCase : Optional[int] = config.num_labels
_lowerCAmelCase : Optional[int] = config.num_hidden_layers
_lowerCAmelCase : Optional[int] = DeeRobertaModel(__a)
_lowerCAmelCase : Union[str, Any] = nn.Dropout(config.hidden_dropout_prob)
_lowerCAmelCase : List[str] = nn.Linear(config.hidden_size, self.config.num_labels)
@add_start_docstrings_to_model_forward(__a)
def snake_case__ ( self, __a=None, __a=None, __a=None, __a=None, __a=None, __a=None, __a=None, __a=-1, __a=False, ):
'''simple docstring'''
_lowerCAmelCase : Union[str, Any] = self.num_layers
try:
_lowerCAmelCase : List[Any] = self.roberta(
__a, attention_mask=__a, token_type_ids=__a, position_ids=__a, head_mask=__a, inputs_embeds=__a, )
_lowerCAmelCase : List[Any] = outputs[1]
_lowerCAmelCase : Dict = self.dropout(__a)
_lowerCAmelCase : Dict = self.classifier(__a)
_lowerCAmelCase : Optional[Any] = (logits,) + outputs[2:] # add hidden states and attention if they are here
except HighwayException as e:
_lowerCAmelCase : Tuple = e.message
_lowerCAmelCase : Union[str, Any] = e.exit_layer
_lowerCAmelCase : List[Any] = outputs[0]
if not self.training:
_lowerCAmelCase : int = entropy(__a)
_lowerCAmelCase : List[Any] = []
_lowerCAmelCase : str = []
if labels is not None:
if self.num_labels == 1:
# We are doing regression
_lowerCAmelCase : Optional[Any] = MSELoss()
_lowerCAmelCase : int = loss_fct(logits.view(-1), labels.view(-1))
else:
_lowerCAmelCase : Optional[Any] = CrossEntropyLoss()
_lowerCAmelCase : Optional[Any] = loss_fct(logits.view(-1, self.num_labels), labels.view(-1))
# work with highway exits
_lowerCAmelCase : Optional[int] = []
for highway_exit in outputs[-1]:
_lowerCAmelCase : Any = highway_exit[0]
if not self.training:
highway_logits_all.append(__a)
highway_entropy.append(highway_exit[2])
if self.num_labels == 1:
# We are doing regression
_lowerCAmelCase : List[str] = MSELoss()
_lowerCAmelCase : List[Any] = loss_fct(highway_logits.view(-1), labels.view(-1))
else:
_lowerCAmelCase : Dict = CrossEntropyLoss()
_lowerCAmelCase : Optional[Any] = loss_fct(highway_logits.view(-1, self.num_labels), labels.view(-1))
highway_losses.append(__a)
if train_highway:
_lowerCAmelCase : int = (sum(highway_losses[:-1]),) + outputs
# exclude the final highway, of course
else:
_lowerCAmelCase : Any = (loss,) + outputs
if not self.training:
_lowerCAmelCase : Optional[Any] = outputs + ((original_entropy, highway_entropy), exit_layer)
if output_layer >= 0:
_lowerCAmelCase : Optional[Any] = (
(outputs[0],) + (highway_logits_all[output_layer],) + outputs[2:]
) # use the highway of the last layer
return outputs # (loss), logits, (hidden_states), (attentions), entropy
| 36
|
import os
import unittest
from transformers.models.bartpho.tokenization_bartpho import VOCAB_FILES_NAMES, BartphoTokenizer
from transformers.testing_utils import get_tests_dir
from ...test_tokenization_common import TokenizerTesterMixin
_snake_case = get_tests_dir("fixtures/test_sentencepiece_bpe.model")
class UpperCAmelCase_ ( a , unittest.TestCase):
lowerCamelCase__ = BartphoTokenizer
lowerCamelCase__ = False
lowerCamelCase__ = True
def snake_case__ ( self):
'''simple docstring'''
super().setUp()
_lowerCAmelCase : str = ["▁This", "▁is", "▁a", "▁t", "est"]
_lowerCAmelCase : List[str] = dict(zip(__a, range(len(__a))))
_lowerCAmelCase : Optional[Any] = {"unk_token": "<unk>"}
_lowerCAmelCase : Optional[int] = os.path.join(self.tmpdirname, VOCAB_FILES_NAMES["monolingual_vocab_file"])
with open(self.monolingual_vocab_file, "w", encoding="utf-8") as fp:
for token in vocab_tokens:
fp.write(f"{token} {vocab_tokens[token]}\n")
_lowerCAmelCase : Optional[Any] = BartphoTokenizer(__a, self.monolingual_vocab_file, **self.special_tokens_map)
tokenizer.save_pretrained(self.tmpdirname)
def snake_case__ ( self, **__a):
'''simple docstring'''
kwargs.update(self.special_tokens_map)
return BartphoTokenizer.from_pretrained(self.tmpdirname, **__a)
def snake_case__ ( self, __a):
'''simple docstring'''
_lowerCAmelCase : Union[str, Any] = "This is a là test"
_lowerCAmelCase : Optional[int] = "This is a<unk><unk> test"
return input_text, output_text
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Optional[int] = BartphoTokenizer(__a, self.monolingual_vocab_file, **self.special_tokens_map)
_lowerCAmelCase : List[Any] = "This is a là test"
_lowerCAmelCase : str = "▁This ▁is ▁a ▁l à ▁t est".split()
_lowerCAmelCase : str = tokenizer.tokenize(__a)
self.assertListEqual(__a, __a)
_lowerCAmelCase : Tuple = tokens + [tokenizer.unk_token]
_lowerCAmelCase : List[str] = [4, 5, 6, 3, 3, 7, 8, 3]
self.assertListEqual(tokenizer.convert_tokens_to_ids(__a), __a)
| 36
| 1
|
from pathlib import Path
from typing import List
from transformers import is_torch_available, is_vision_available
from transformers.testing_utils import get_tests_dir, is_tool_test
from transformers.tools.agent_types import AGENT_TYPE_MAPPING, AgentAudio, AgentImage, AgentText
if is_torch_available():
import torch
if is_vision_available():
from PIL import Image
_snake_case = ["text", "image", "audio"]
def A ( _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : str = []
for input_type in input_types:
if input_type == "text":
inputs.append("Text input" )
elif input_type == "image":
inputs.append(
Image.open(Path(get_tests_dir("fixtures/tests_samples/COCO" ) ) / "000000039769.png" ).resize((512, 512) ) )
elif input_type == "audio":
inputs.append(torch.ones(3_000 ) )
elif isinstance(_lowerCamelCase , _lowerCamelCase ):
inputs.append(create_inputs(_lowerCamelCase ) )
else:
raise ValueError(F"Invalid type requested: {input_type}" )
return inputs
def A ( _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : Optional[int] = []
for output in outputs:
if isinstance(_lowerCamelCase , (str, AgentText) ):
output_types.append("text" )
elif isinstance(_lowerCamelCase , (Image.Image, AgentImage) ):
output_types.append("image" )
elif isinstance(_lowerCamelCase , (torch.Tensor, AgentAudio) ):
output_types.append("audio" )
else:
raise ValueError(F"Invalid output: {output}" )
return output_types
@is_tool_test
class UpperCAmelCase_ :
def snake_case__ ( self):
'''simple docstring'''
self.assertTrue(hasattr(self.tool, "inputs"))
self.assertTrue(hasattr(self.tool, "outputs"))
_lowerCAmelCase : List[Any] = self.tool.inputs
for _input in inputs:
if isinstance(_input, __a):
for __input in _input:
self.assertTrue(__input in authorized_types)
else:
self.assertTrue(_input in authorized_types)
_lowerCAmelCase : str = self.tool.outputs
for _output in outputs:
self.assertTrue(_output in authorized_types)
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : List[Any] = create_inputs(self.tool.inputs)
_lowerCAmelCase : Dict = self.tool(*__a)
# There is a single output
if len(self.tool.outputs) == 1:
_lowerCAmelCase : Dict = [outputs]
self.assertListEqual(output_types(__a), self.tool.outputs)
def snake_case__ ( self):
'''simple docstring'''
self.assertTrue(hasattr(self.tool, "description"))
self.assertTrue(hasattr(self.tool, "default_checkpoint"))
self.assertTrue(self.tool.description.startswith("This is a tool that"))
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Dict = create_inputs(self.tool.inputs)
_lowerCAmelCase : Any = self.tool(*__a)
if not isinstance(__a, __a):
_lowerCAmelCase : str = [outputs]
self.assertEqual(len(__a), len(self.tool.outputs))
for output, output_type in zip(__a, self.tool.outputs):
_lowerCAmelCase : Any = AGENT_TYPE_MAPPING[output_type]
self.assertTrue(isinstance(__a, __a))
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Tuple = create_inputs(self.tool.inputs)
_lowerCAmelCase : Tuple = []
for _input, input_type in zip(__a, self.tool.inputs):
if isinstance(__a, __a):
_inputs.append([AGENT_TYPE_MAPPING[_input_type](_input) for _input_type in input_type])
else:
_inputs.append(AGENT_TYPE_MAPPING[input_type](_input))
# Should not raise an error
_lowerCAmelCase : Dict = self.tool(*__a)
if not isinstance(__a, __a):
_lowerCAmelCase : Any = [outputs]
self.assertEqual(len(__a), len(self.tool.outputs))
| 36
|
import math
from typing import Dict, Iterable, List, Optional, Tuple, Union
import numpy as np
from ...image_processing_utils import BaseImageProcessor, BatchFeature, get_size_dict
from ...image_transforms import normalize, rescale, resize, to_channel_dimension_format
from ...image_utils import (
IMAGENET_STANDARD_MEAN,
IMAGENET_STANDARD_STD,
ChannelDimension,
ImageInput,
PILImageResampling,
get_image_size,
is_torch_available,
is_torch_tensor,
make_list_of_images,
to_numpy_array,
valid_images,
)
from ...utils import TensorType, is_vision_available, logging
if is_torch_available():
import torch
if is_vision_available():
import PIL
_snake_case = logging.get_logger(__name__)
def A ( _lowerCamelCase , _lowerCamelCase , _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
def constraint_to_multiple_of(_lowerCamelCase , _lowerCamelCase , _lowerCamelCase=0 , _lowerCamelCase=None ):
_lowerCAmelCase : Tuple = round(val / multiple ) * multiple
if max_val is not None and x > max_val:
_lowerCAmelCase : Optional[int] = math.floor(val / multiple ) * multiple
if x < min_val:
_lowerCAmelCase : List[str] = math.ceil(val / multiple ) * multiple
return x
_lowerCAmelCase : Union[str, Any] = (output_size, output_size) if isinstance(_lowerCamelCase , _lowerCamelCase ) else output_size
_lowerCAmelCase , _lowerCAmelCase : Optional[Any] = get_image_size(_lowerCamelCase )
_lowerCAmelCase , _lowerCAmelCase : Any = output_size
# determine new height and width
_lowerCAmelCase : List[Any] = output_height / input_height
_lowerCAmelCase : Any = output_width / input_width
if keep_aspect_ratio:
# scale as little as possible
if abs(1 - scale_width ) < abs(1 - scale_height ):
# fit width
_lowerCAmelCase : Union[str, Any] = scale_width
else:
# fit height
_lowerCAmelCase : Union[str, Any] = scale_height
_lowerCAmelCase : List[str] = constraint_to_multiple_of(scale_height * input_height , multiple=_lowerCamelCase )
_lowerCAmelCase : Dict = constraint_to_multiple_of(scale_width * input_width , multiple=_lowerCamelCase )
return (new_height, new_width)
class UpperCAmelCase_ ( a):
lowerCamelCase__ = ['pixel_values']
def __init__( self, __a = True, __a = None, __a = PILImageResampling.BILINEAR, __a = False, __a = 1, __a = True, __a = 1 / 255, __a = True, __a = None, __a = None, **__a, ):
'''simple docstring'''
super().__init__(**__a)
_lowerCAmelCase : Any = size if size is not None else {"height": 384, "width": 384}
_lowerCAmelCase : Optional[int] = get_size_dict(__a)
_lowerCAmelCase : Optional[Any] = do_resize
_lowerCAmelCase : Dict = size
_lowerCAmelCase : Any = keep_aspect_ratio
_lowerCAmelCase : str = ensure_multiple_of
_lowerCAmelCase : str = resample
_lowerCAmelCase : Dict = do_rescale
_lowerCAmelCase : Optional[int] = rescale_factor
_lowerCAmelCase : Dict = do_normalize
_lowerCAmelCase : Dict = image_mean if image_mean is not None else IMAGENET_STANDARD_MEAN
_lowerCAmelCase : int = image_std if image_std is not None else IMAGENET_STANDARD_STD
def snake_case__ ( self, __a, __a, __a = False, __a = 1, __a = PILImageResampling.BICUBIC, __a = None, **__a, ):
'''simple docstring'''
_lowerCAmelCase : List[Any] = get_size_dict(__a)
if "height" not in size or "width" not in size:
raise ValueError(f"The size dictionary must contain the keys 'height' and 'width'. Got {size.keys()}")
_lowerCAmelCase : List[Any] = get_resize_output_image_size(
__a, output_size=(size["height"], size["width"]), keep_aspect_ratio=__a, multiple=__a, )
return resize(__a, size=__a, resample=__a, data_format=__a, **__a)
def snake_case__ ( self, __a, __a, __a = None, **__a, ):
'''simple docstring'''
return rescale(__a, scale=__a, data_format=__a, **__a)
def snake_case__ ( self, __a, __a, __a, __a = None, **__a, ):
'''simple docstring'''
return normalize(__a, mean=__a, std=__a, data_format=__a, **__a)
def snake_case__ ( self, __a, __a = None, __a = None, __a = None, __a = None, __a = None, __a = None, __a = None, __a = None, __a = None, __a = None, __a = None, __a = ChannelDimension.FIRST, **__a, ):
'''simple docstring'''
_lowerCAmelCase : int = do_resize if do_resize is not None else self.do_resize
_lowerCAmelCase : List[Any] = size if size is not None else self.size
_lowerCAmelCase : str = get_size_dict(__a)
_lowerCAmelCase : Dict = keep_aspect_ratio if keep_aspect_ratio is not None else self.keep_aspect_ratio
_lowerCAmelCase : Any = ensure_multiple_of if ensure_multiple_of is not None else self.ensure_multiple_of
_lowerCAmelCase : int = resample if resample is not None else self.resample
_lowerCAmelCase : Union[str, Any] = do_rescale if do_rescale is not None else self.do_rescale
_lowerCAmelCase : Tuple = rescale_factor if rescale_factor is not None else self.rescale_factor
_lowerCAmelCase : List[str] = do_normalize if do_normalize is not None else self.do_normalize
_lowerCAmelCase : Dict = image_mean if image_mean is not None else self.image_mean
_lowerCAmelCase : List[str] = image_std if image_std is not None else self.image_std
_lowerCAmelCase : Optional[Any] = make_list_of_images(__a)
if not valid_images(__a):
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 or resample is None:
raise ValueError("Size and resample must be specified if do_resize 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.
_lowerCAmelCase : List[Any] = [to_numpy_array(__a) for image in images]
if do_resize:
_lowerCAmelCase : Any = [self.resize(image=__a, size=__a, resample=__a) for image in images]
if do_rescale:
_lowerCAmelCase : List[str] = [self.rescale(image=__a, scale=__a) for image in images]
if do_normalize:
_lowerCAmelCase : Dict = [self.normalize(image=__a, mean=__a, std=__a) for image in images]
_lowerCAmelCase : List[str] = [to_channel_dimension_format(__a, __a) for image in images]
_lowerCAmelCase : Optional[Any] = {"pixel_values": images}
return BatchFeature(data=__a, tensor_type=__a)
def snake_case__ ( self, __a, __a = None):
'''simple docstring'''
_lowerCAmelCase : Optional[Any] = outputs.logits
# Resize logits and compute semantic segmentation maps
if target_sizes is not None:
if len(__a) != len(__a):
raise ValueError(
"Make sure that you pass in as many target sizes as the batch dimension of the logits")
if is_torch_tensor(__a):
_lowerCAmelCase : List[Any] = target_sizes.numpy()
_lowerCAmelCase : Dict = []
for idx in range(len(__a)):
_lowerCAmelCase : int = torch.nn.functional.interpolate(
logits[idx].unsqueeze(dim=0), size=target_sizes[idx], mode="bilinear", align_corners=__a)
_lowerCAmelCase : int = resized_logits[0].argmax(dim=0)
semantic_segmentation.append(__a)
else:
_lowerCAmelCase : Dict = logits.argmax(dim=1)
_lowerCAmelCase : str = [semantic_segmentation[i] for i in range(semantic_segmentation.shape[0])]
return semantic_segmentation
| 36
| 1
|
import json
from typing import List, Optional, Tuple
from tokenizers import pre_tokenizers, processors
from ...tokenization_utils_base import AddedToken, BatchEncoding
from ...tokenization_utils_fast import PreTrainedTokenizerFast
from ...utils import logging
from .tokenization_bart import BartTokenizer
_snake_case = logging.get_logger(__name__)
_snake_case = {"vocab_file": "vocab.json", "merges_file": "merges.txt", "tokenizer_file": "tokenizer.json"}
# See all BART models at https://huggingface.co/models?filter=bart
_snake_case = {
"vocab_file": {
"facebook/bart-base": "https://huggingface.co/facebook/bart-base/resolve/main/vocab.json",
"facebook/bart-large": "https://huggingface.co/facebook/bart-large/resolve/main/vocab.json",
"facebook/bart-large-mnli": "https://huggingface.co/facebook/bart-large-mnli/resolve/main/vocab.json",
"facebook/bart-large-cnn": "https://huggingface.co/facebook/bart-large-cnn/resolve/main/vocab.json",
"facebook/bart-large-xsum": "https://huggingface.co/facebook/bart-large-xsum/resolve/main/vocab.json",
"yjernite/bart_eli5": "https://huggingface.co/yjernite/bart_eli5/resolve/main/vocab.json",
},
"merges_file": {
"facebook/bart-base": "https://huggingface.co/facebook/bart-base/resolve/main/merges.txt",
"facebook/bart-large": "https://huggingface.co/facebook/bart-large/resolve/main/merges.txt",
"facebook/bart-large-mnli": "https://huggingface.co/facebook/bart-large-mnli/resolve/main/merges.txt",
"facebook/bart-large-cnn": "https://huggingface.co/facebook/bart-large-cnn/resolve/main/merges.txt",
"facebook/bart-large-xsum": "https://huggingface.co/facebook/bart-large-xsum/resolve/main/merges.txt",
"yjernite/bart_eli5": "https://huggingface.co/yjernite/bart_eli5/resolve/main/merges.txt",
},
"tokenizer_file": {
"facebook/bart-base": "https://huggingface.co/facebook/bart-base/resolve/main/tokenizer.json",
"facebook/bart-large": "https://huggingface.co/facebook/bart-large/resolve/main/tokenizer.json",
"facebook/bart-large-mnli": "https://huggingface.co/facebook/bart-large-mnli/resolve/main/tokenizer.json",
"facebook/bart-large-cnn": "https://huggingface.co/facebook/bart-large-cnn/resolve/main/tokenizer.json",
"facebook/bart-large-xsum": "https://huggingface.co/facebook/bart-large-xsum/resolve/main/tokenizer.json",
"yjernite/bart_eli5": "https://huggingface.co/yjernite/bart_eli5/resolve/main/tokenizer.json",
},
}
_snake_case = {
"facebook/bart-base": 1024,
"facebook/bart-large": 1024,
"facebook/bart-large-mnli": 1024,
"facebook/bart-large-cnn": 1024,
"facebook/bart-large-xsum": 1024,
"yjernite/bart_eli5": 1024,
}
class UpperCAmelCase_ ( a):
lowerCamelCase__ = VOCAB_FILES_NAMES
lowerCamelCase__ = PRETRAINED_VOCAB_FILES_MAP
lowerCamelCase__ = PRETRAINED_POSITIONAL_EMBEDDINGS_SIZES
lowerCamelCase__ = ['input_ids', 'attention_mask']
lowerCamelCase__ = BartTokenizer
def __init__( self, __a=None, __a=None, __a=None, __a="replace", __a="<s>", __a="</s>", __a="</s>", __a="<s>", __a="<unk>", __a="<pad>", __a="<mask>", __a=False, __a=True, **__a, ):
'''simple docstring'''
super().__init__(
__a, __a, tokenizer_file=__a, errors=__a, bos_token=__a, eos_token=__a, sep_token=__a, cls_token=__a, unk_token=__a, pad_token=__a, mask_token=__a, add_prefix_space=__a, trim_offsets=__a, **__a, )
_lowerCAmelCase : Tuple = json.loads(self.backend_tokenizer.pre_tokenizer.__getstate__())
if pre_tok_state.get("add_prefix_space", __a) != add_prefix_space:
_lowerCAmelCase : List[Any] = getattr(__a, pre_tok_state.pop("type"))
_lowerCAmelCase : Any = add_prefix_space
_lowerCAmelCase : Any = pre_tok_class(**__a)
_lowerCAmelCase : Dict = add_prefix_space
# the pre_tokenizer is already updated in the GPT2TokenizerFast `__init__`
_lowerCAmelCase : Tuple = "post_processor"
_lowerCAmelCase : Union[str, Any] = getattr(self.backend_tokenizer, __a, __a)
if tokenizer_component_instance:
_lowerCAmelCase : Optional[int] = json.loads(tokenizer_component_instance.__getstate__())
# The lists 'sep' and 'cls' must be cased in tuples for the object `post_processor_class`
if "sep" in state:
_lowerCAmelCase : Tuple = tuple(state["sep"])
if "cls" in state:
_lowerCAmelCase : List[Any] = tuple(state["cls"])
_lowerCAmelCase : List[str] = False
if state.get("add_prefix_space", __a) != add_prefix_space:
_lowerCAmelCase : Union[str, Any] = add_prefix_space
_lowerCAmelCase : List[Any] = True
if state.get("trim_offsets", __a) != trim_offsets:
_lowerCAmelCase : Any = trim_offsets
_lowerCAmelCase : Union[str, Any] = True
if changes_to_apply:
_lowerCAmelCase : Optional[int] = getattr(__a, state.pop("type"))
_lowerCAmelCase : Optional[Any] = component_class(**__a)
setattr(self.backend_tokenizer, __a, __a)
@property
def snake_case__ ( self):
'''simple docstring'''
if self._mask_token is None:
if self.verbose:
logger.error("Using mask_token, but it is not set yet.")
return None
return str(self._mask_token)
@mask_token.setter
def snake_case__ ( self, __a):
'''simple docstring'''
_lowerCAmelCase : int = AddedToken(__a, lstrip=__a, rstrip=__a) if isinstance(__a, __a) else value
_lowerCAmelCase : Optional[int] = value
def snake_case__ ( self, *__a, **__a):
'''simple docstring'''
_lowerCAmelCase : Optional[Any] = kwargs.get("is_split_into_words", __a)
if is_split_into_words and not self.add_prefix_space:
raise ValueError(
f"You need to instantiate {self.__class__.__name__} with add_prefix_space=True "
"to use it with pretokenized inputs.")
return super()._batch_encode_plus(*__a, **__a)
def snake_case__ ( self, *__a, **__a):
'''simple docstring'''
_lowerCAmelCase : List[Any] = kwargs.get("is_split_into_words", __a)
if is_split_into_words and not self.add_prefix_space:
raise ValueError(
f"You need to instantiate {self.__class__.__name__} with add_prefix_space=True "
"to use it with pretokenized inputs.")
return super()._encode_plus(*__a, **__a)
def snake_case__ ( self, __a, __a = None):
'''simple docstring'''
_lowerCAmelCase : Any = self._tokenizer.model.save(__a, name=__a)
return tuple(__a)
def snake_case__ ( self, __a, __a=None):
'''simple docstring'''
_lowerCAmelCase : Dict = [self.bos_token_id] + token_ids_a + [self.eos_token_id]
if token_ids_a is None:
return output
return output + [self.eos_token_id] + token_ids_a + [self.eos_token_id]
def snake_case__ ( self, __a, __a = None):
'''simple docstring'''
_lowerCAmelCase : Union[str, Any] = [self.sep_token_id]
_lowerCAmelCase : Optional[Any] = [self.cls_token_id]
if token_ids_a is None:
return len(cls + token_ids_a + sep) * [0]
return len(cls + token_ids_a + sep + sep + token_ids_a + sep) * [0]
| 36
|
import argparse
import json
from pathlib import Path
import requests
import torch
from huggingface_hub import hf_hub_download
from PIL import Image
from timm import create_model
from timm.data import resolve_data_config
from timm.data.transforms_factory import create_transform
from transformers import BitConfig, BitForImageClassification, BitImageProcessor
from transformers.image_utils import PILImageResampling
from transformers.utils import logging
logging.set_verbosity_info()
_snake_case = logging.get_logger(__name__)
def A ( _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : List[Any] = "huggingface/label-files"
_lowerCAmelCase : int = "imagenet-1k-id2label.json"
_lowerCAmelCase : Tuple = json.load(open(hf_hub_download(_lowerCamelCase , _lowerCamelCase , repo_type="dataset" ) , "r" ) )
_lowerCAmelCase : Tuple = {int(_lowerCamelCase ): v for k, v in idalabel.items()}
_lowerCAmelCase : Union[str, Any] = {v: k for k, v in idalabel.items()}
_lowerCAmelCase : Tuple = "std_conv" if "bit" in model_name else False
# note that when using BiT as backbone for ViT-hybrid checkpoints,
# one needs to additionally set config.layer_type = "bottleneck", config.stem_type = "same",
# config.conv_layer = "std_conv_same"
_lowerCAmelCase : Optional[int] = BitConfig(
conv_layer=_lowerCamelCase , num_labels=1_000 , idalabel=_lowerCamelCase , labelaid=_lowerCamelCase , )
return config
def A ( _lowerCamelCase ):
'''simple docstring'''
if "stem.conv" in name:
_lowerCAmelCase : List[str] = name.replace("stem.conv" , "bit.embedder.convolution" )
if "blocks" in name:
_lowerCAmelCase : Any = name.replace("blocks" , "layers" )
if "head.fc" in name:
_lowerCAmelCase : Optional[Any] = name.replace("head.fc" , "classifier.1" )
if name.startswith("norm" ):
_lowerCAmelCase : Any = "bit." + name
if "bit" not in name and "classifier" not in name:
_lowerCAmelCase : Dict = "bit.encoder." + name
return name
def A ( ):
'''simple docstring'''
_lowerCAmelCase : Tuple = "http://images.cocodataset.org/val2017/000000039769.jpg"
_lowerCAmelCase : Optional[int] = Image.open(requests.get(_lowerCamelCase , stream=_lowerCamelCase ).raw )
return im
@torch.no_grad()
def A ( _lowerCamelCase , _lowerCamelCase , _lowerCamelCase=False ):
'''simple docstring'''
_lowerCAmelCase : Dict = get_config(_lowerCamelCase )
# load original model from timm
_lowerCAmelCase : int = create_model(_lowerCamelCase , pretrained=_lowerCamelCase )
timm_model.eval()
# load state_dict of original model
_lowerCAmelCase : Any = timm_model.state_dict()
for key in state_dict.copy().keys():
_lowerCAmelCase : Dict = state_dict.pop(_lowerCamelCase )
_lowerCAmelCase : Tuple = val.squeeze() if "head" in key else val
# load HuggingFace model
_lowerCAmelCase : Optional[Any] = BitForImageClassification(_lowerCamelCase )
model.eval()
model.load_state_dict(_lowerCamelCase )
# create image processor
_lowerCAmelCase : Dict = create_transform(**resolve_data_config({} , model=_lowerCamelCase ) )
_lowerCAmelCase : Optional[int] = transform.transforms
_lowerCAmelCase : Tuple = {
"bilinear": PILImageResampling.BILINEAR,
"bicubic": PILImageResampling.BICUBIC,
"nearest": PILImageResampling.NEAREST,
}
_lowerCAmelCase : Tuple = BitImageProcessor(
do_resize=_lowerCamelCase , size={"shortest_edge": timm_transforms[0].size} , resample=pillow_resamplings[timm_transforms[0].interpolation.value] , do_center_crop=_lowerCamelCase , crop_size={"height": timm_transforms[1].size[0], "width": timm_transforms[1].size[1]} , do_normalize=_lowerCamelCase , image_mean=timm_transforms[-1].mean.tolist() , image_std=timm_transforms[-1].std.tolist() , )
_lowerCAmelCase : Optional[int] = prepare_img()
_lowerCAmelCase : Any = transform(_lowerCamelCase ).unsqueeze(0 )
_lowerCAmelCase : Optional[int] = processor(_lowerCamelCase , return_tensors="pt" ).pixel_values
# verify pixel values
assert torch.allclose(_lowerCamelCase , _lowerCamelCase )
# verify logits
with torch.no_grad():
_lowerCAmelCase : Tuple = model(_lowerCamelCase )
_lowerCAmelCase : str = outputs.logits
print("Logits:" , logits[0, :3] )
print("Predicted class:" , model.config.idalabel[logits.argmax(-1 ).item()] )
_lowerCAmelCase : Union[str, Any] = timm_model(_lowerCamelCase )
assert timm_logits.shape == outputs.logits.shape
assert torch.allclose(_lowerCamelCase , outputs.logits , atol=1e-3 )
print("Looks ok!" )
if pytorch_dump_folder_path is not None:
Path(_lowerCamelCase ).mkdir(exist_ok=_lowerCamelCase )
print(F"Saving model {model_name} and processor to {pytorch_dump_folder_path}" )
model.save_pretrained(_lowerCamelCase )
processor.save_pretrained(_lowerCamelCase )
if push_to_hub:
print(F"Pushing model {model_name} and processor to the hub" )
model.push_to_hub(F"ybelkada/{model_name}" )
processor.push_to_hub(F"ybelkada/{model_name}" )
if __name__ == "__main__":
_snake_case = argparse.ArgumentParser()
# Required parameters
parser.add_argument(
"--model_name",
default="resnetv2_50x1_bitm",
type=str,
help="Name of the BiT 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."
)
parser.add_argument(
"--push_to_hub",
action="store_true",
help="Whether to push the model to the hub.",
)
_snake_case = parser.parse_args()
convert_bit_checkpoint(args.model_name, args.pytorch_dump_folder_path, args.push_to_hub)
| 36
| 1
|
import inspect
import os
import sys
import unittest
import accelerate
from accelerate.test_utils import execute_subprocess_async, require_tpu
class UpperCAmelCase_ ( unittest.TestCase):
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Tuple = inspect.getfile(accelerate.test_utils)
_lowerCAmelCase : Union[str, Any] = os.path.sep.join(mod_file.split(os.path.sep)[:-1] + ["scripts", "test_script.py"])
_lowerCAmelCase : int = os.path.sep.join(inspect.getfile(self.__class__).split(os.path.sep)[:-1])
@require_tpu
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : str = f"\n {self.test_dir}/xla_spawn.py\n --num_cores 8\n {self.test_file_path}\n ".split()
_lowerCAmelCase : Optional[Any] = [sys.executable] + distributed_args
execute_subprocess_async(__a, env=os.environ.copy())
| 36
|
from collections import OrderedDict
from typing import Mapping
from packaging import version
from ...configuration_utils import PretrainedConfig
from ...onnx import OnnxConfig
from ...utils import logging
from ...utils.backbone_utils import BackboneConfigMixin, get_aligned_output_features_output_indices
_snake_case = logging.get_logger(__name__)
_snake_case = {
"microsoft/swin-tiny-patch4-window7-224": (
"https://huggingface.co/microsoft/swin-tiny-patch4-window7-224/resolve/main/config.json"
),
# See all Swin models at https://huggingface.co/models?filter=swin
}
class UpperCAmelCase_ ( a , a):
lowerCamelCase__ = 'swin'
lowerCamelCase__ = {
'num_attention_heads': 'num_heads',
'num_hidden_layers': 'num_layers',
}
def __init__( self, __a=224, __a=4, __a=3, __a=96, __a=[2, 2, 6, 2], __a=[3, 6, 12, 24], __a=7, __a=4.0, __a=True, __a=0.0, __a=0.0, __a=0.1, __a="gelu", __a=False, __a=0.02, __a=1E-5, __a=32, __a=None, __a=None, **__a, ):
'''simple docstring'''
super().__init__(**__a)
_lowerCAmelCase : Any = image_size
_lowerCAmelCase : Union[str, Any] = patch_size
_lowerCAmelCase : Tuple = num_channels
_lowerCAmelCase : List[Any] = embed_dim
_lowerCAmelCase : Tuple = depths
_lowerCAmelCase : Optional[Any] = len(__a)
_lowerCAmelCase : int = num_heads
_lowerCAmelCase : int = window_size
_lowerCAmelCase : int = mlp_ratio
_lowerCAmelCase : List[Any] = qkv_bias
_lowerCAmelCase : str = hidden_dropout_prob
_lowerCAmelCase : Union[str, Any] = attention_probs_dropout_prob
_lowerCAmelCase : Any = drop_path_rate
_lowerCAmelCase : int = hidden_act
_lowerCAmelCase : Tuple = use_absolute_embeddings
_lowerCAmelCase : Optional[int] = layer_norm_eps
_lowerCAmelCase : Tuple = initializer_range
_lowerCAmelCase : Tuple = encoder_stride
# 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
_lowerCAmelCase : List[str] = int(embed_dim * 2 ** (len(__a) - 1))
_lowerCAmelCase : List[Any] = ["stem"] + [f"stage{idx}" for idx in range(1, len(__a) + 1)]
_lowerCAmelCase , _lowerCAmelCase : Optional[int] = get_aligned_output_features_output_indices(
out_features=__a, out_indices=__a, stage_names=self.stage_names)
class UpperCAmelCase_ ( a):
lowerCamelCase__ = version.parse('1.11')
@property
def snake_case__ ( self):
'''simple docstring'''
return OrderedDict(
[
("pixel_values", {0: "batch", 1: "num_channels", 2: "height", 3: "width"}),
])
@property
def snake_case__ ( self):
'''simple docstring'''
return 1E-4
| 36
| 1
|
from __future__ import annotations
from bisect import bisect_left
from functools import total_ordering
from heapq import merge
@total_ordering
class UpperCAmelCase_ ( a):
def __lt__( self, __a):
'''simple docstring'''
return self[-1] < other[-1]
def __eq__( self, __a):
'''simple docstring'''
return self[-1] == other[-1]
def A ( _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : list[Stack] = []
# sort into stacks
for element in collection:
_lowerCAmelCase : Optional[Any] = Stack([element] )
_lowerCAmelCase : Union[str, Any] = bisect_left(_lowerCamelCase , _lowerCamelCase )
if i != len(_lowerCamelCase ):
stacks[i].append(_lowerCamelCase )
else:
stacks.append(_lowerCamelCase )
# use a heap-based merge to merge stack efficiently
_lowerCAmelCase : Dict = merge(*(reversed(_lowerCamelCase ) for stack in stacks) )
return collection
if __name__ == "__main__":
_snake_case = input("Enter numbers separated by a comma:\n").strip()
_snake_case = [int(item) for item in user_input.split(",")]
print(patience_sort(unsorted))
| 36
|
from ...utils import (
OptionalDependencyNotAvailable,
is_torch_available,
is_transformers_available,
is_transformers_version,
)
try:
if not (is_transformers_available() and is_torch_available() and is_transformers_version(">=", "4.25.0")):
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
from ...utils.dummy_torch_and_transformers_objects import (
VersatileDiffusionDualGuidedPipeline,
VersatileDiffusionImageVariationPipeline,
VersatileDiffusionPipeline,
VersatileDiffusionTextToImagePipeline,
)
else:
from .modeling_text_unet import UNetFlatConditionModel
from .pipeline_versatile_diffusion import VersatileDiffusionPipeline
from .pipeline_versatile_diffusion_dual_guided import VersatileDiffusionDualGuidedPipeline
from .pipeline_versatile_diffusion_image_variation import VersatileDiffusionImageVariationPipeline
from .pipeline_versatile_diffusion_text_to_image import VersatileDiffusionTextToImagePipeline
| 36
| 1
|
from dataclasses import dataclass
from typing import Optional, Tuple, Union
import numpy as np
import torch
from ..configuration_utils import ConfigMixin, register_to_config
from ..utils import BaseOutput, randn_tensor
from .scheduling_utils import SchedulerMixin
@dataclass
class UpperCAmelCase_ ( a):
lowerCamelCase__ = 42
lowerCamelCase__ = 42
lowerCamelCase__ = None
class UpperCAmelCase_ ( a , a):
lowerCamelCase__ = 2
@register_to_config
def __init__( self, __a = 0.02, __a = 100, __a = 1.007, __a = 80, __a = 0.05, __a = 50, ):
'''simple docstring'''
_lowerCAmelCase : Union[str, Any] = sigma_max
# setable values
_lowerCAmelCase : int = None
_lowerCAmelCase : np.IntTensor = None
_lowerCAmelCase : torch.FloatTensor = None # sigma(t_i)
def snake_case__ ( self, __a, __a = None):
'''simple docstring'''
return sample
def snake_case__ ( self, __a, __a = None):
'''simple docstring'''
_lowerCAmelCase : Optional[int] = num_inference_steps
_lowerCAmelCase : Optional[Any] = np.arange(0, self.num_inference_steps)[::-1].copy()
_lowerCAmelCase : Tuple = torch.from_numpy(__a).to(__a)
_lowerCAmelCase : Any = [
(
self.config.sigma_max**2
* (self.config.sigma_min**2 / self.config.sigma_max**2) ** (i / (num_inference_steps - 1))
)
for i in self.timesteps
]
_lowerCAmelCase : int = torch.tensor(__a, dtype=torch.floataa, device=__a)
def snake_case__ ( self, __a, __a, __a = None):
'''simple docstring'''
if self.config.s_min <= sigma <= self.config.s_max:
_lowerCAmelCase : Any = min(self.config.s_churn / self.num_inference_steps, 2**0.5 - 1)
else:
_lowerCAmelCase : str = 0
# sample eps ~ N(0, S_noise^2 * I)
_lowerCAmelCase : Any = self.config.s_noise * randn_tensor(sample.shape, generator=__a).to(sample.device)
_lowerCAmelCase : Optional[Any] = sigma + gamma * sigma
_lowerCAmelCase : Any = sample + ((sigma_hat**2 - sigma**2) ** 0.5 * eps)
return sample_hat, sigma_hat
def snake_case__ ( self, __a, __a, __a, __a, __a = True, ):
'''simple docstring'''
_lowerCAmelCase : Dict = sample_hat + sigma_hat * model_output
_lowerCAmelCase : int = (sample_hat - pred_original_sample) / sigma_hat
_lowerCAmelCase : Optional[Any] = sample_hat + (sigma_prev - sigma_hat) * derivative
if not return_dict:
return (sample_prev, derivative)
return KarrasVeOutput(
prev_sample=__a, derivative=__a, pred_original_sample=__a)
def snake_case__ ( self, __a, __a, __a, __a, __a, __a, __a = True, ):
'''simple docstring'''
_lowerCAmelCase : List[Any] = sample_prev + sigma_prev * model_output
_lowerCAmelCase : Optional[int] = (sample_prev - pred_original_sample) / sigma_prev
_lowerCAmelCase : Tuple = sample_hat + (sigma_prev - sigma_hat) * (0.5 * derivative + 0.5 * derivative_corr)
if not return_dict:
return (sample_prev, derivative)
return KarrasVeOutput(
prev_sample=__a, derivative=__a, pred_original_sample=__a)
def snake_case__ ( self, __a, __a, __a):
'''simple docstring'''
raise NotImplementedError()
| 36
|
import importlib.metadata
import operator
import re
import sys
from typing import Optional
from packaging import version
_snake_case = {
"<": operator.lt,
"<=": operator.le,
"==": operator.eq,
"!=": operator.ne,
">=": operator.ge,
">": operator.gt,
}
def A ( _lowerCamelCase , _lowerCamelCase , _lowerCamelCase , _lowerCamelCase , _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
if got_ver is None or want_ver is None:
raise ValueError(
F"Unable to compare versions for {requirement}: need={want_ver} found={got_ver}. This is unusual. Consider"
F" reinstalling {pkg}." )
if not ops[op](version.parse(_lowerCamelCase ) , version.parse(_lowerCamelCase ) ):
raise ImportError(
F"{requirement} is required for a normal functioning of this module, but found {pkg}=={got_ver}.{hint}" )
def A ( _lowerCamelCase , _lowerCamelCase = None ):
'''simple docstring'''
_lowerCAmelCase : List[str] = F"\n{hint}" if hint is not None else ""
# non-versioned check
if re.match(r"^[\w_\-\d]+$" , _lowerCamelCase ):
_lowerCAmelCase , _lowerCAmelCase , _lowerCAmelCase : List[str] = requirement, None, None
else:
_lowerCAmelCase : Optional[int] = re.findall(r"^([^!=<>\s]+)([\s!=<>]{1,2}.+)" , _lowerCamelCase )
if not match:
raise ValueError(
"requirement needs to be in the pip package format, .e.g., package_a==1.23, or package_b>=1.23, but"
F" got {requirement}" )
_lowerCAmelCase , _lowerCAmelCase : Dict = match[0]
_lowerCAmelCase : Any = want_full.split("," ) # there could be multiple requirements
_lowerCAmelCase : Optional[int] = {}
for w in want_range:
_lowerCAmelCase : Any = re.findall(r"^([\s!=<>]{1,2})(.+)" , _lowerCamelCase )
if not match:
raise ValueError(
"requirement needs to be in the pip package format, .e.g., package_a==1.23, or package_b>=1.23,"
F" but got {requirement}" )
_lowerCAmelCase , _lowerCAmelCase : Tuple = match[0]
_lowerCAmelCase : Union[str, Any] = want_ver
if op not in ops:
raise ValueError(F"{requirement}: need one of {list(ops.keys() )}, but got {op}" )
# special case
if pkg == "python":
_lowerCAmelCase : Tuple = ".".join([str(_lowerCamelCase ) for x in sys.version_info[:3]] )
for op, want_ver in wanted.items():
_compare_versions(_lowerCamelCase , _lowerCamelCase , _lowerCamelCase , _lowerCamelCase , _lowerCamelCase , _lowerCamelCase )
return
# check if any version is installed
try:
_lowerCAmelCase : Any = importlib.metadata.version(_lowerCamelCase )
except importlib.metadata.PackageNotFoundError:
raise importlib.metadata.PackageNotFoundError(
F"The '{requirement}' distribution was not found and is required by this application. {hint}" )
# check that the right version is installed if version number or a range was provided
if want_ver is not None:
for op, want_ver in wanted.items():
_compare_versions(_lowerCamelCase , _lowerCamelCase , _lowerCamelCase , _lowerCamelCase , _lowerCamelCase , _lowerCamelCase )
def A ( _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : List[str] = "Try: pip install transformers -U or pip install -e '.[dev]' if you're working with git main"
return require_version(_lowerCamelCase , _lowerCamelCase )
| 36
| 1
|
import os
import unittest
from transformers import MobileBertTokenizer, MobileBertTokenizerFast
from transformers.models.bert.tokenization_bert import (
VOCAB_FILES_NAMES,
BasicTokenizer,
WordpieceTokenizer,
_is_control,
_is_punctuation,
_is_whitespace,
)
from transformers.testing_utils import require_tokenizers, slow
from ...test_tokenization_common import TokenizerTesterMixin, filter_non_english
@require_tokenizers
class UpperCAmelCase_ ( a , unittest.TestCase):
lowerCamelCase__ = MobileBertTokenizer
lowerCamelCase__ = MobileBertTokenizerFast
lowerCamelCase__ = True
lowerCamelCase__ = True
lowerCamelCase__ = filter_non_english
lowerCamelCase__ = 'google/mobilebert-uncased'
def snake_case__ ( self):
'''simple docstring'''
super().setUp()
_lowerCAmelCase : Tuple = [
"[UNK]",
"[CLS]",
"[SEP]",
"[PAD]",
"[MASK]",
"want",
"##want",
"##ed",
"wa",
"un",
"runn",
"##ing",
",",
"low",
"lowest",
]
_lowerCAmelCase : List[str] = 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]))
_lowerCAmelCase : List[Any] = [
(tokenizer_def[0], self.pre_trained_model_path, tokenizer_def[2]) # else the 'google/' prefix is stripped
for tokenizer_def in self.tokenizers_list
]
def snake_case__ ( self, __a):
'''simple docstring'''
_lowerCAmelCase : str = "UNwant\u00E9d,running"
_lowerCAmelCase : Optional[Any] = "unwanted, running"
return input_text, output_text
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : List[Any] = self.tokenizer_class(self.vocab_file)
_lowerCAmelCase : int = tokenizer.tokenize("UNwant\u00E9d,running")
self.assertListEqual(__a, ["un", "##want", "##ed", ",", "runn", "##ing"])
self.assertListEqual(tokenizer.convert_tokens_to_ids(__a), [9, 6, 7, 12, 10, 11])
def snake_case__ ( self):
'''simple docstring'''
if not self.test_rust_tokenizer:
return
_lowerCAmelCase : Optional[int] = self.get_tokenizer()
_lowerCAmelCase : Union[str, Any] = self.get_rust_tokenizer()
_lowerCAmelCase : Any = "UNwant\u00E9d,running"
_lowerCAmelCase : Optional[Any] = tokenizer.tokenize(__a)
_lowerCAmelCase : Optional[int] = rust_tokenizer.tokenize(__a)
self.assertListEqual(__a, __a)
_lowerCAmelCase : List[Any] = tokenizer.encode(__a, add_special_tokens=__a)
_lowerCAmelCase : Optional[int] = rust_tokenizer.encode(__a, add_special_tokens=__a)
self.assertListEqual(__a, __a)
_lowerCAmelCase : List[str] = self.get_rust_tokenizer()
_lowerCAmelCase : Dict = tokenizer.encode(__a)
_lowerCAmelCase : str = rust_tokenizer.encode(__a)
self.assertListEqual(__a, __a)
# With lower casing
_lowerCAmelCase : Any = self.get_tokenizer(do_lower_case=__a)
_lowerCAmelCase : Optional[int] = self.get_rust_tokenizer(do_lower_case=__a)
_lowerCAmelCase : Union[str, Any] = "UNwant\u00E9d,running"
_lowerCAmelCase : List[Any] = tokenizer.tokenize(__a)
_lowerCAmelCase : Optional[Any] = rust_tokenizer.tokenize(__a)
self.assertListEqual(__a, __a)
_lowerCAmelCase : Any = tokenizer.encode(__a, add_special_tokens=__a)
_lowerCAmelCase : Tuple = rust_tokenizer.encode(__a, add_special_tokens=__a)
self.assertListEqual(__a, __a)
_lowerCAmelCase : Optional[Any] = self.get_rust_tokenizer()
_lowerCAmelCase : List[str] = tokenizer.encode(__a)
_lowerCAmelCase : Optional[int] = rust_tokenizer.encode(__a)
self.assertListEqual(__a, __a)
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : int = BasicTokenizer()
self.assertListEqual(tokenizer.tokenize("ah\u535A\u63A8zz"), ["ah", "\u535A", "\u63A8", "zz"])
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Union[str, Any] = BasicTokenizer(do_lower_case=__a)
self.assertListEqual(
tokenizer.tokenize(" \tHeLLo!how \n Are yoU? "), ["hello", "!", "how", "are", "you", "?"])
self.assertListEqual(tokenizer.tokenize("H\u00E9llo"), ["hello"])
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Any = BasicTokenizer(do_lower_case=__a, strip_accents=__a)
self.assertListEqual(
tokenizer.tokenize(" \tHäLLo!how \n Are yoU? "), ["hällo", "!", "how", "are", "you", "?"])
self.assertListEqual(tokenizer.tokenize("H\u00E9llo"), ["h\u00E9llo"])
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : str = BasicTokenizer(do_lower_case=__a, strip_accents=__a)
self.assertListEqual(
tokenizer.tokenize(" \tHäLLo!how \n Are yoU? "), ["hallo", "!", "how", "are", "you", "?"])
self.assertListEqual(tokenizer.tokenize("H\u00E9llo"), ["hello"])
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Optional[Any] = BasicTokenizer(do_lower_case=__a)
self.assertListEqual(
tokenizer.tokenize(" \tHäLLo!how \n Are yoU? "), ["hallo", "!", "how", "are", "you", "?"])
self.assertListEqual(tokenizer.tokenize("H\u00E9llo"), ["hello"])
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Union[str, Any] = BasicTokenizer(do_lower_case=__a)
self.assertListEqual(
tokenizer.tokenize(" \tHeLLo!how \n Are yoU? "), ["HeLLo", "!", "how", "Are", "yoU", "?"])
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Tuple = BasicTokenizer(do_lower_case=__a, strip_accents=__a)
self.assertListEqual(
tokenizer.tokenize(" \tHäLLo!how \n Are yoU? "), ["HäLLo", "!", "how", "Are", "yoU", "?"])
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : str = BasicTokenizer(do_lower_case=__a, strip_accents=__a)
self.assertListEqual(
tokenizer.tokenize(" \tHäLLo!how \n Are yoU? "), ["HaLLo", "!", "how", "Are", "yoU", "?"])
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : str = BasicTokenizer(do_lower_case=__a, never_split=["[UNK]"])
self.assertListEqual(
tokenizer.tokenize(" \tHeLLo!how \n Are yoU? [UNK]"), ["HeLLo", "!", "how", "Are", "yoU", "?", "[UNK]"])
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : int = ["[UNK]", "[CLS]", "[SEP]", "want", "##want", "##ed", "wa", "un", "runn", "##ing"]
_lowerCAmelCase : int = {}
for i, token in enumerate(__a):
_lowerCAmelCase : Dict = i
_lowerCAmelCase : Dict = WordpieceTokenizer(vocab=__a, unk_token="[UNK]")
self.assertListEqual(tokenizer.tokenize(""), [])
self.assertListEqual(tokenizer.tokenize("unwanted running"), ["un", "##want", "##ed", "runn", "##ing"])
self.assertListEqual(tokenizer.tokenize("unwantedX running"), ["[UNK]", "runn", "##ing"])
def snake_case__ ( self):
'''simple docstring'''
self.assertTrue(_is_whitespace(" "))
self.assertTrue(_is_whitespace("\t"))
self.assertTrue(_is_whitespace("\r"))
self.assertTrue(_is_whitespace("\n"))
self.assertTrue(_is_whitespace("\u00A0"))
self.assertFalse(_is_whitespace("A"))
self.assertFalse(_is_whitespace("-"))
def snake_case__ ( self):
'''simple docstring'''
self.assertTrue(_is_control("\u0005"))
self.assertFalse(_is_control("A"))
self.assertFalse(_is_control(" "))
self.assertFalse(_is_control("\t"))
self.assertFalse(_is_control("\r"))
def snake_case__ ( self):
'''simple docstring'''
self.assertTrue(_is_punctuation("-"))
self.assertTrue(_is_punctuation("$"))
self.assertTrue(_is_punctuation("`"))
self.assertTrue(_is_punctuation("."))
self.assertFalse(_is_punctuation("A"))
self.assertFalse(_is_punctuation(" "))
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Optional[Any] = self.get_tokenizer()
_lowerCAmelCase : int = self.get_rust_tokenizer()
# Example taken from the issue https://github.com/huggingface/tokenizers/issues/340
self.assertListEqual([tokenizer.tokenize(__a) for t in ["Test", "\xad", "test"]], [["[UNK]"], [], ["[UNK]"]])
self.assertListEqual(
[rust_tokenizer.tokenize(__a) for t in ["Test", "\xad", "test"]], [["[UNK]"], [], ["[UNK]"]])
@slow
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Dict = self.tokenizer_class.from_pretrained("google/mobilebert-uncased")
_lowerCAmelCase : Tuple = tokenizer.encode("sequence builders", add_special_tokens=__a)
_lowerCAmelCase : Any = tokenizer.encode("multi-sequence build", add_special_tokens=__a)
_lowerCAmelCase : Dict = tokenizer.build_inputs_with_special_tokens(__a)
_lowerCAmelCase : int = tokenizer.build_inputs_with_special_tokens(__a, __a)
assert encoded_sentence == [101] + text + [102]
assert encoded_pair == [101] + text + [102] + text_a + [102]
def snake_case__ ( self):
'''simple docstring'''
for tokenizer, pretrained_name, kwargs in self.tokenizers_list:
with self.subTest(f"{tokenizer.__class__.__name__} ({pretrained_name})"):
_lowerCAmelCase : Union[str, Any] = self.rust_tokenizer_class.from_pretrained(__a, **__a)
_lowerCAmelCase : Optional[int] = f"A, naïve {tokenizer_r.mask_token} AllenNLP sentence."
_lowerCAmelCase : List[Any] = tokenizer_r.encode_plus(
__a, return_attention_mask=__a, return_token_type_ids=__a, return_offsets_mapping=__a, add_special_tokens=__a, )
_lowerCAmelCase : Tuple = tokenizer_r.do_lower_case if hasattr(__a, "do_lower_case") else False
_lowerCAmelCase : Tuple = (
[
((0, 0), tokenizer_r.cls_token),
((0, 1), "A"),
((1, 2), ","),
((3, 5), "na"),
((5, 6), "##ï"),
((6, 8), "##ve"),
((9, 15), tokenizer_r.mask_token),
((16, 21), "Allen"),
((21, 23), "##NL"),
((23, 24), "##P"),
((25, 33), "sentence"),
((33, 34), "."),
((0, 0), tokenizer_r.sep_token),
]
if not do_lower_case
else [
((0, 0), tokenizer_r.cls_token),
((0, 1), "a"),
((1, 2), ","),
((3, 8), "naive"),
((9, 15), tokenizer_r.mask_token),
((16, 21), "allen"),
((21, 23), "##nl"),
((23, 24), "##p"),
((25, 33), "sentence"),
((33, 34), "."),
((0, 0), tokenizer_r.sep_token),
]
)
self.assertEqual(
[e[1] for e in expected_results], tokenizer_r.convert_ids_to_tokens(tokens["input_ids"]))
self.assertEqual([e[0] for e in expected_results], tokens["offset_mapping"])
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : int = ["的", "人", "有"]
_lowerCAmelCase : Tuple = "".join(__a)
for tokenizer, pretrained_name, kwargs in self.tokenizers_list:
with self.subTest(f"{tokenizer.__class__.__name__} ({pretrained_name})"):
_lowerCAmelCase : Dict = True
_lowerCAmelCase : Optional[int] = self.tokenizer_class.from_pretrained(__a, **__a)
_lowerCAmelCase : str = self.rust_tokenizer_class.from_pretrained(__a, **__a)
_lowerCAmelCase : Any = tokenizer_p.encode(__a, add_special_tokens=__a)
_lowerCAmelCase : Union[str, Any] = tokenizer_r.encode(__a, add_special_tokens=__a)
_lowerCAmelCase : Optional[int] = tokenizer_r.convert_ids_to_tokens(__a)
_lowerCAmelCase : Union[str, Any] = tokenizer_p.convert_ids_to_tokens(__a)
# it is expected that each Chinese character is not preceded by "##"
self.assertListEqual(__a, __a)
self.assertListEqual(__a, __a)
_lowerCAmelCase : Optional[Any] = False
_lowerCAmelCase : Tuple = self.rust_tokenizer_class.from_pretrained(__a, **__a)
_lowerCAmelCase : int = self.tokenizer_class.from_pretrained(__a, **__a)
_lowerCAmelCase : Optional[Any] = tokenizer_r.encode(__a, add_special_tokens=__a)
_lowerCAmelCase : str = tokenizer_p.encode(__a, add_special_tokens=__a)
_lowerCAmelCase : List[str] = tokenizer_r.convert_ids_to_tokens(__a)
_lowerCAmelCase : Any = tokenizer_p.convert_ids_to_tokens(__a)
# it is expected that only the first Chinese character is not preceded by "##".
_lowerCAmelCase : Union[str, Any] = [
f"##{token}" if idx != 0 else token for idx, token in enumerate(__a)
]
self.assertListEqual(__a, __a)
self.assertListEqual(__a, __a)
| 36
|
import argparse
from collections import defaultdict
import yaml
_snake_case = "docs/source/en/_toctree.yml"
def A ( _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : Dict = defaultdict(_lowerCamelCase )
_lowerCAmelCase : Any = []
_lowerCAmelCase : List[str] = []
for doc in doc_list:
if "local" in doc:
counts[doc["local"]] += 1
if doc["title"].lower() == "overview":
overview_doc.append({"local": doc["local"], "title": doc["title"]} )
else:
new_doc_list.append(_lowerCamelCase )
_lowerCAmelCase : Optional[Any] = new_doc_list
_lowerCAmelCase : List[Any] = [key for key, value in counts.items() if value > 1]
_lowerCAmelCase : str = []
for duplicate_key in duplicates:
_lowerCAmelCase : List[str] = list({doc["title"] for doc in doc_list if doc["local"] == duplicate_key} )
if len(_lowerCamelCase ) > 1:
raise ValueError(
F"{duplicate_key} is present several times in the documentation table of content at "
"`docs/source/en/_toctree.yml` with different *Title* values. Choose one of those and remove the "
"others." )
# Only add this once
new_doc.append({"local": duplicate_key, "title": titles[0]} )
# Add none duplicate-keys
new_doc.extend([doc for doc in doc_list if "local" not in counts or counts[doc["local"]] == 1] )
_lowerCAmelCase : Optional[Any] = sorted(_lowerCamelCase , key=lambda _lowerCamelCase : s["title"].lower() )
# "overview" gets special treatment and is always first
if len(_lowerCamelCase ) > 1:
raise ValueError("{doc_list} has two 'overview' docs which is not allowed." )
overview_doc.extend(_lowerCamelCase )
# Sort
return overview_doc
def A ( _lowerCamelCase=False ):
'''simple docstring'''
with open(_lowerCamelCase , encoding="utf-8" ) as f:
_lowerCAmelCase : int = yaml.safe_load(f.read() )
# Get to the API doc
_lowerCAmelCase : Optional[Any] = 0
while content[api_idx]["title"] != "API":
api_idx += 1
_lowerCAmelCase : List[str] = content[api_idx]["sections"]
# Then to the model doc
_lowerCAmelCase : Union[str, Any] = 0
while api_doc[scheduler_idx]["title"] != "Schedulers":
scheduler_idx += 1
_lowerCAmelCase : Optional[Any] = api_doc[scheduler_idx]["sections"]
_lowerCAmelCase : Optional[Any] = clean_doc_toc(_lowerCamelCase )
_lowerCAmelCase : int = False
if new_scheduler_doc != scheduler_doc:
_lowerCAmelCase : List[Any] = True
if overwrite:
_lowerCAmelCase : Dict = new_scheduler_doc
if diff:
if overwrite:
_lowerCAmelCase : Tuple = api_doc
with open(_lowerCamelCase , "w" , encoding="utf-8" ) as f:
f.write(yaml.dump(_lowerCamelCase , allow_unicode=_lowerCamelCase ) )
else:
raise ValueError(
"The model doc part of the table of content is not properly sorted, run `make style` to fix this." )
def A ( _lowerCamelCase=False ):
'''simple docstring'''
with open(_lowerCamelCase , encoding="utf-8" ) as f:
_lowerCAmelCase : Tuple = yaml.safe_load(f.read() )
# Get to the API doc
_lowerCAmelCase : Optional[int] = 0
while content[api_idx]["title"] != "API":
api_idx += 1
_lowerCAmelCase : int = content[api_idx]["sections"]
# Then to the model doc
_lowerCAmelCase : List[str] = 0
while api_doc[pipeline_idx]["title"] != "Pipelines":
pipeline_idx += 1
_lowerCAmelCase : Dict = False
_lowerCAmelCase : Optional[int] = api_doc[pipeline_idx]["sections"]
_lowerCAmelCase : Tuple = []
# sort sub pipeline docs
for pipeline_doc in pipeline_docs:
if "section" in pipeline_doc:
_lowerCAmelCase : List[Any] = pipeline_doc["section"]
_lowerCAmelCase : Union[str, Any] = clean_doc_toc(_lowerCamelCase )
if overwrite:
_lowerCAmelCase : Optional[Any] = new_sub_pipeline_doc
new_pipeline_docs.append(_lowerCamelCase )
# sort overall pipeline doc
_lowerCAmelCase : Union[str, Any] = clean_doc_toc(_lowerCamelCase )
if new_pipeline_docs != pipeline_docs:
_lowerCAmelCase : Dict = True
if overwrite:
_lowerCAmelCase : Optional[int] = new_pipeline_docs
if diff:
if overwrite:
_lowerCAmelCase : Optional[int] = api_doc
with open(_lowerCamelCase , "w" , encoding="utf-8" ) as f:
f.write(yaml.dump(_lowerCamelCase , allow_unicode=_lowerCamelCase ) )
else:
raise ValueError(
"The model doc part of the table of content is not properly sorted, run `make style` to fix this." )
if __name__ == "__main__":
_snake_case = argparse.ArgumentParser()
parser.add_argument("--fix_and_overwrite", action="store_true", help="Whether to fix inconsistencies.")
_snake_case = parser.parse_args()
check_scheduler_doc(args.fix_and_overwrite)
check_pipeline_doc(args.fix_and_overwrite)
| 36
| 1
|
import argparse
import logging
import os
import sys
import numpy as np
import onnxruntime
import torch
from bart_onnx.generation_onnx import BARTBeamSearchGenerator
from bart_onnx.reduce_onnx_size import remove_dup_initializers
import transformers
from transformers import BartForConditionalGeneration, BartTokenizer
logging.basicConfig(
format="%(asctime)s | %(levelname)s | %(name)s | [%(filename)s:%(lineno)d] %(message)s",
datefmt="%Y-%m-%d %H:%M:%S",
level=os.environ.get("LOGLEVEL", "INFO").upper(),
stream=sys.stdout,
)
_snake_case = logging.getLogger(__name__)
_snake_case = {"facebook/bart-base": BartForConditionalGeneration}
_snake_case = {"facebook/bart-base": BartTokenizer}
def A ( ):
'''simple docstring'''
_lowerCAmelCase : str = argparse.ArgumentParser(description="Export Bart model + Beam Search to ONNX graph." )
parser.add_argument(
"--validation_file" , type=_lowerCamelCase , default=_lowerCamelCase , help="A csv or a json file containing the validation data." )
parser.add_argument(
"--max_length" , type=_lowerCamelCase , default=5 , help="The maximum total input sequence length after tokenization." , )
parser.add_argument(
"--num_beams" , type=_lowerCamelCase , default=_lowerCamelCase , help=(
"Number of beams to use for evaluation. This argument will be "
"passed to ``model.generate``, which is used during ``evaluate`` and ``predict``."
) , )
parser.add_argument(
"--model_name_or_path" , type=_lowerCamelCase , help="Path to pretrained model or model identifier from huggingface.co/models." , required=_lowerCamelCase , )
parser.add_argument(
"--config_name" , type=_lowerCamelCase , default=_lowerCamelCase , help="Pretrained config name or path if not the same as model_name" , )
parser.add_argument(
"--device" , type=_lowerCamelCase , default="cpu" , help="Device where the model will be run" , )
parser.add_argument("--output_file_path" , type=_lowerCamelCase , default=_lowerCamelCase , help="Where to store the final ONNX file." )
_lowerCAmelCase : List[str] = parser.parse_args()
return args
def A ( _lowerCamelCase , _lowerCamelCase="cpu" ):
'''simple docstring'''
_lowerCAmelCase : Optional[int] = model_dict[model_name].from_pretrained(_lowerCamelCase ).to(_lowerCamelCase )
_lowerCAmelCase : List[Any] = tokenizer_dict[model_name].from_pretrained(_lowerCamelCase )
if model_name in ["facebook/bart-base"]:
_lowerCAmelCase : int = 0
_lowerCAmelCase : int = None
_lowerCAmelCase : Any = 0
return huggingface_model, tokenizer
def A ( _lowerCamelCase , _lowerCamelCase , _lowerCamelCase , _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
model.eval()
_lowerCAmelCase : Optional[int] = None
_lowerCAmelCase : Optional[Any] = torch.jit.script(BARTBeamSearchGenerator(_lowerCamelCase ) )
with torch.no_grad():
_lowerCAmelCase : Tuple = "My friends are cool but they eat too many carbs."
_lowerCAmelCase : List[Any] = tokenizer([ARTICLE_TO_SUMMARIZE] , max_length=1_024 , return_tensors="pt" ).to(model.device )
_lowerCAmelCase : Optional[Any] = model.generate(
inputs["input_ids"] , attention_mask=inputs["attention_mask"] , num_beams=_lowerCamelCase , max_length=_lowerCamelCase , early_stopping=_lowerCamelCase , decoder_start_token_id=model.config.decoder_start_token_id , )
torch.onnx.export(
_lowerCamelCase , (
inputs["input_ids"],
inputs["attention_mask"],
num_beams,
max_length,
model.config.decoder_start_token_id,
) , _lowerCamelCase , opset_version=14 , input_names=["input_ids", "attention_mask", "num_beams", "max_length", "decoder_start_token_id"] , output_names=["output_ids"] , dynamic_axes={
"input_ids": {0: "batch", 1: "seq"},
"output_ids": {0: "batch", 1: "seq_out"},
} , example_outputs=_lowerCamelCase , )
logger.info("Model exported to {}".format(_lowerCamelCase ) )
_lowerCAmelCase : Union[str, Any] = remove_dup_initializers(os.path.abspath(_lowerCamelCase ) )
logger.info("Deduplicated and optimized model written to {}".format(_lowerCamelCase ) )
_lowerCAmelCase : Optional[int] = onnxruntime.InferenceSession(_lowerCamelCase )
_lowerCAmelCase : str = ort_sess.run(
_lowerCamelCase , {
"input_ids": inputs["input_ids"].cpu().numpy(),
"attention_mask": inputs["attention_mask"].cpu().numpy(),
"num_beams": np.array(_lowerCamelCase ),
"max_length": np.array(_lowerCamelCase ),
"decoder_start_token_id": np.array(model.config.decoder_start_token_id ),
} , )
np.testing.assert_allclose(summary_ids.cpu().numpy() , ort_out[0] , rtol=1e-3 , atol=1e-3 )
logger.info("Model outputs from torch and ONNX Runtime are similar." )
logger.info("Success." )
def A ( ):
'''simple docstring'''
_lowerCAmelCase : int = parse_args()
_lowerCAmelCase : Dict = 5
_lowerCAmelCase : Tuple = 4
# Make one log on every process with the configuration for debugging.
logging.basicConfig(
format="%(asctime)s - %(levelname)s - %(name)s - %(message)s" , datefmt="%m/%d/%Y %H:%M:%S" , level=logging.INFO , )
logger.setLevel(logging.INFO )
transformers.utils.logging.set_verbosity_error()
_lowerCAmelCase : int = torch.device(args.device )
_lowerCAmelCase , _lowerCAmelCase : Union[str, Any] = load_model_tokenizer(args.model_name_or_path , _lowerCamelCase )
if model.config.decoder_start_token_id is None:
raise ValueError("Make sure that `config.decoder_start_token_id` is correctly defined" )
model.to(_lowerCamelCase )
if args.max_length:
_lowerCAmelCase : List[Any] = args.max_length
if args.num_beams:
_lowerCAmelCase : Any = args.num_beams
if args.output_file_path:
_lowerCAmelCase : Union[str, Any] = args.output_file_path
else:
_lowerCAmelCase : Any = "BART.onnx"
logger.info("Exporting model to ONNX" )
export_and_validate_model(_lowerCamelCase , _lowerCamelCase , _lowerCamelCase , _lowerCamelCase , _lowerCamelCase )
if __name__ == "__main__":
main()
| 36
|
def A ( _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
if density <= 0:
raise ValueError("Impossible fluid density" )
if bulk_modulus <= 0:
raise ValueError("Impossible bulk modulus" )
return (bulk_modulus / density) ** 0.5
if __name__ == "__main__":
import doctest
doctest.testmod()
| 36
| 1
|
import datasets
from .evaluate import evaluate
_snake_case = "\\n@article{hendrycks2021cuad,\n title={CUAD: An Expert-Annotated NLP Dataset for Legal Contract Review},\n author={Dan Hendrycks and Collin Burns and Anya Chen and Spencer Ball},\n journal={arXiv preprint arXiv:2103.06268},\n year={2021}\n}\n"
_snake_case = "\nThis metric wrap the official scoring script for version 1 of the Contract\nUnderstanding Atticus Dataset (CUAD).\nContract Understanding Atticus Dataset (CUAD) v1 is a corpus of more than 13,000 labels in 510\ncommercial legal contracts that have been manually labeled to identify 41 categories of important\nclauses that lawyers look for when reviewing contracts in connection with corporate transactions.\n"
_snake_case = "\nComputes CUAD scores (EM, F1, AUPR, Precision@80%Recall, and Precision@90%Recall).\nArgs:\n predictions: List of question-answers dictionaries with the following key-values:\n - 'id': id of the question-answer pair as given in the references (see below)\n - 'prediction_text': list of possible texts for the answer, as a list of strings\n depending on a threshold on the confidence probability of each prediction.\n references: List of question-answers dictionaries with the following key-values:\n - 'id': id of the question-answer pair (see above),\n - 'answers': a Dict in the CUAD dataset format\n {\n 'text': list of possible texts for the answer, as a list of strings\n 'answer_start': list of start positions for the answer, as a list of ints\n }\n Note that answer_start values are not taken into account to compute the metric.\nReturns:\n 'exact_match': Exact match (the normalized answer exactly match the gold answer)\n 'f1': The F-score of predicted tokens versus the gold answer\n 'aupr': Area Under the Precision-Recall curve\n 'prec_at_80_recall': Precision at 80% recall\n 'prec_at_90_recall': Precision at 90% recall\nExamples:\n >>> predictions = [{'prediction_text': ['The seller:', 'The buyer/End-User: Shenzhen LOHAS Supply Chain Management Co., Ltd.'], 'id': 'LohaCompanyltd_20191209_F-1_EX-10.16_11917878_EX-10.16_Supply Agreement__Parties'}]\n >>> references = [{'answers': {'answer_start': [143, 49], 'text': ['The seller:', 'The buyer/End-User: Shenzhen LOHAS Supply Chain Management Co., Ltd.']}, 'id': 'LohaCompanyltd_20191209_F-1_EX-10.16_11917878_EX-10.16_Supply Agreement__Parties'}]\n >>> cuad_metric = datasets.load_metric(\"cuad\")\n >>> results = cuad_metric.compute(predictions=predictions, references=references)\n >>> print(results)\n {'exact_match': 100.0, 'f1': 100.0, 'aupr': 0.0, 'prec_at_80_recall': 1.0, 'prec_at_90_recall': 1.0}\n"
@datasets.utils.file_utils.add_start_docstrings(_DESCRIPTION , _KWARGS_DESCRIPTION)
class UpperCAmelCase_ ( datasets.Metric):
def snake_case__ ( self):
'''simple docstring'''
return datasets.MetricInfo(
description=_DESCRIPTION, citation=_CITATION, inputs_description=_KWARGS_DESCRIPTION, features=datasets.Features(
{
"predictions": {
"id": datasets.Value("string"),
"prediction_text": datasets.features.Sequence(datasets.Value("string")),
},
"references": {
"id": datasets.Value("string"),
"answers": datasets.features.Sequence(
{
"text": datasets.Value("string"),
"answer_start": datasets.Value("int32"),
}),
},
}), codebase_urls=["https://www.atticusprojectai.org/cuad"], reference_urls=["https://www.atticusprojectai.org/cuad"], )
def snake_case__ ( self, __a, __a):
'''simple docstring'''
_lowerCAmelCase : Optional[Any] = {prediction["id"]: prediction["prediction_text"] for prediction in predictions}
_lowerCAmelCase : Optional[Any] = [
{
"paragraphs": [
{
"qas": [
{
"answers": [{"text": answer_text} for answer_text in ref["answers"]["text"]],
"id": ref["id"],
}
for ref in references
]
}
]
}
]
_lowerCAmelCase : int = evaluate(dataset=__a, predictions=__a)
return score
| 36
|
from typing import Dict
from transformers import EvalPrediction, HfArgumentParser, TrainingArguments, is_torch_available
from transformers.testing_utils import (
TestCasePlus,
execute_subprocess_async,
get_torch_dist_unique_port,
require_torch_multi_gpu,
require_torch_neuroncore,
)
from transformers.training_args import ParallelMode
from transformers.utils import logging
_snake_case = logging.get_logger(__name__)
if is_torch_available():
import torch
from torch import nn
from torch.utils.data import Dataset
from transformers import Trainer
class UpperCAmelCase_ ( a):
def __init__( self, __a = 101):
'''simple docstring'''
_lowerCAmelCase : str = length
def __len__( self):
'''simple docstring'''
return self.length
def __getitem__( self, __a):
'''simple docstring'''
return i
class UpperCAmelCase_ :
def __call__( self, __a):
'''simple docstring'''
return {"input_ids": torch.tensor(__a), "labels": torch.tensor(__a)}
class UpperCAmelCase_ ( nn.Module):
def __init__( self):
'''simple docstring'''
super().__init__()
# Add some (unused) params otherwise DDP will complain.
_lowerCAmelCase : str = nn.Linear(120, 80)
def snake_case__ ( self, __a, __a=None):
'''simple docstring'''
if labels is not None:
return torch.tensor(0.0, device=input_ids.device), input_ids
else:
return input_ids
class UpperCAmelCase_ ( a):
@require_torch_neuroncore
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : int = f"--nproc_per_node=2\n --master_port={get_torch_dist_unique_port()}\n {self.test_file_dir}/test_trainer_distributed.py\n ".split()
_lowerCAmelCase : Tuple = self.get_auto_remove_tmp_dir()
_lowerCAmelCase : Optional[int] = f"--output_dir {output_dir}".split()
_lowerCAmelCase : List[Any] = ["torchrun"] + distributed_args + args
execute_subprocess_async(__a, env=self.get_env())
# successful return here == success - any errors would have caused an error in the sub-call
class UpperCAmelCase_ ( a):
@require_torch_multi_gpu
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Dict = f"--nproc_per_node={torch.cuda.device_count()}\n --master_port={get_torch_dist_unique_port()}\n {self.test_file_dir}/test_trainer_distributed.py\n ".split()
_lowerCAmelCase : Any = self.get_auto_remove_tmp_dir()
_lowerCAmelCase : Optional[int] = f"--output_dir {output_dir}".split()
_lowerCAmelCase : Any = ["torchrun"] + distributed_args + args
execute_subprocess_async(__a, env=self.get_env())
# successful return here == success - any errors would have caused an error in the sub-call
if __name__ == "__main__":
# The script below is meant to be run under torch.distributed, on a machine with multiple GPUs:
#
# PYTHONPATH="src" python -m torch.distributed.run --nproc_per_node 2 --output_dir output_dir ./tests/test_trainer_distributed.py
_snake_case = HfArgumentParser((TrainingArguments,))
_snake_case = parser.parse_args_into_dataclasses()[0]
logger.warning(
f'''Process rank: {training_args.local_rank}, device: {training_args.device}, n_gpu: {training_args.n_gpu}, '''
f'''distributed training: {training_args.parallel_mode != ParallelMode.NOT_DISTRIBUTED}'''
)
# Essentially, what we want to verify in the distributed case is that we get all samples back,
# in the right order. (this is crucial for prediction for instance)
for dataset_length in [101, 40, 7]:
_snake_case = DummyDataset(dataset_length)
def A ( _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : Dict = list(range(len(_lowerCamelCase ) ) )
_lowerCAmelCase : Union[str, Any] = p.predictions.tolist() == sequential and p.label_ids.tolist() == sequential
if not success and training_args.local_rank == 0:
logger.warning(
"Predictions and/or labels do not match expected results:\n - predictions: "
F"{p.predictions.tolist()}\n - labels: {p.label_ids.tolist()}\n - expected: {sequential}" )
return {"success": success}
_snake_case = Trainer(
model=DummyModel(),
args=training_args,
data_collator=DummyDataCollator(),
eval_dataset=dataset,
compute_metrics=compute_metrics,
)
_snake_case = trainer.evaluate()
logger.info(metrics)
if metrics["eval_success"] is not True:
logger.error(metrics)
exit(1)
_snake_case = trainer.predict(dataset)
logger.info(p.metrics)
if p.metrics["test_success"] is not True:
logger.error(p.metrics)
exit(1)
_snake_case = 2
_snake_case = trainer.evaluate()
logger.info(metrics)
if metrics["eval_success"] is not True:
logger.error(metrics)
exit(1)
_snake_case = trainer.predict(dataset)
logger.info(p.metrics)
if p.metrics["test_success"] is not True:
logger.error(p.metrics)
exit(1)
_snake_case = None
| 36
| 1
|
def A ( _lowerCamelCase ):
'''simple docstring'''
if bit_count < 0:
raise ValueError("The given input must be positive" )
# get the generated string sequence
_lowerCAmelCase : List[str] = gray_code_sequence_string(_lowerCamelCase )
#
# convert them to integers
for i in range(len(_lowerCamelCase ) ):
_lowerCAmelCase : List[str] = int(sequence[i] , 2 )
return sequence
def A ( _lowerCamelCase ):
'''simple docstring'''
if bit_count == 0:
return ["0"]
if bit_count == 1:
return ["0", "1"]
_lowerCAmelCase : List[Any] = 1 << bit_count # defines the length of the sequence
# 1<< n is equivalent to 2^n
# recursive answer will generate answer for n-1 bits
_lowerCAmelCase : Optional[int] = gray_code_sequence_string(bit_count - 1 )
_lowerCAmelCase : str = []
# append 0 to first half of the smaller sequence generated
for i in range(seq_len // 2 ):
_lowerCAmelCase : Dict = "0" + smaller_sequence[i]
sequence.append(_lowerCamelCase )
# append 1 to second half ... start from the end of the list
for i in reversed(range(seq_len // 2 ) ):
_lowerCAmelCase : Optional[Any] = "1" + smaller_sequence[i]
sequence.append(_lowerCamelCase )
return sequence
if __name__ == "__main__":
import doctest
doctest.testmod()
| 36
|
from __future__ import annotations
import bisect
def A ( _lowerCamelCase , _lowerCamelCase , _lowerCamelCase = 0 , _lowerCamelCase = -1 ):
'''simple docstring'''
if hi < 0:
_lowerCAmelCase : int = len(_lowerCamelCase )
while lo < hi:
_lowerCAmelCase : Optional[Any] = lo + (hi - lo) // 2
if sorted_collection[mid] < item:
_lowerCAmelCase : Union[str, Any] = mid + 1
else:
_lowerCAmelCase : str = mid
return lo
def A ( _lowerCamelCase , _lowerCamelCase , _lowerCamelCase = 0 , _lowerCamelCase = -1 ):
'''simple docstring'''
if hi < 0:
_lowerCAmelCase : str = len(_lowerCamelCase )
while lo < hi:
_lowerCAmelCase : Tuple = lo + (hi - lo) // 2
if sorted_collection[mid] <= item:
_lowerCAmelCase : Dict = mid + 1
else:
_lowerCAmelCase : str = mid
return lo
def A ( _lowerCamelCase , _lowerCamelCase , _lowerCamelCase = 0 , _lowerCamelCase = -1 ):
'''simple docstring'''
sorted_collection.insert(bisect_left(_lowerCamelCase , _lowerCamelCase , _lowerCamelCase , _lowerCamelCase ) , _lowerCamelCase )
def A ( _lowerCamelCase , _lowerCamelCase , _lowerCamelCase = 0 , _lowerCamelCase = -1 ):
'''simple docstring'''
sorted_collection.insert(bisect_right(_lowerCamelCase , _lowerCamelCase , _lowerCamelCase , _lowerCamelCase ) , _lowerCamelCase )
def A ( _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : int = 0
_lowerCAmelCase : Union[str, Any] = len(_lowerCamelCase ) - 1
while left <= right:
_lowerCAmelCase : int = left + (right - left) // 2
_lowerCAmelCase : int = sorted_collection[midpoint]
if current_item == item:
return midpoint
elif item < current_item:
_lowerCAmelCase : str = midpoint - 1
else:
_lowerCAmelCase : Any = midpoint + 1
return None
def A ( _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : Tuple = bisect.bisect_left(_lowerCamelCase , _lowerCamelCase )
if index != len(_lowerCamelCase ) and sorted_collection[index] == item:
return index
return None
def A ( _lowerCamelCase , _lowerCamelCase , _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
if right < left:
return None
_lowerCAmelCase : Optional[int] = left + (right - left) // 2
if sorted_collection[midpoint] == item:
return midpoint
elif sorted_collection[midpoint] > item:
return binary_search_by_recursion(_lowerCamelCase , _lowerCamelCase , _lowerCamelCase , midpoint - 1 )
else:
return binary_search_by_recursion(_lowerCamelCase , _lowerCamelCase , midpoint + 1 , _lowerCamelCase )
if __name__ == "__main__":
_snake_case = input("Enter numbers separated by comma:\n").strip()
_snake_case = sorted(int(item) for item in user_input.split(","))
_snake_case = int(input("Enter a single number to be found in the list:\n"))
_snake_case = binary_search(collection, target)
if result is None:
print(f'''{target} was not found in {collection}.''')
else:
print(f'''{target} was found at position {result} in {collection}.''')
| 36
| 1
|
import argparse
from tax import checkpoints
from transformers import AutoConfig, FlaxAutoModelForSeqaSeqLM
def A ( _lowerCamelCase , _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : Union[str, Any] = AutoConfig.from_pretrained(_lowerCamelCase )
_lowerCAmelCase : str = FlaxAutoModelForSeqaSeqLM.from_config(config=_lowerCamelCase )
_lowerCAmelCase : Optional[int] = checkpoints.load_tax_checkpoint(_lowerCamelCase )
_lowerCAmelCase : Optional[Any] = "wi_0" in tax_model["target"]["encoder"]["layers_0"]["mlp"]
if config.model_type == "t5":
_lowerCAmelCase : Tuple = "SelfAttention"
if config.model_type == "longt5" and config.encoder_attention_type == "local":
_lowerCAmelCase : int = "LocalSelfAttention"
elif config.model_type == "longt5" and config.encoder_attention_type == "transient-global":
_lowerCAmelCase : Any = "TransientGlobalSelfAttention"
else:
raise ValueError(
"Given config is expected to have `model_type='t5'`, or `model_type='longt5` with `encoder_attention_type`"
" attribute with a value from ['local', 'transient-global]." )
# Encoder
for layer_index in range(config.num_layers ):
_lowerCAmelCase : Union[str, Any] = F"layers_{str(_lowerCamelCase )}"
# Self-Attention
_lowerCAmelCase : Optional[Any] = tax_model["target"]["encoder"][layer_name]["attention"]["key"]["kernel"]
_lowerCAmelCase : str = tax_model["target"]["encoder"][layer_name]["attention"]["out"]["kernel"]
_lowerCAmelCase : List[str] = tax_model["target"]["encoder"][layer_name]["attention"]["query"]["kernel"]
_lowerCAmelCase : Dict = tax_model["target"]["encoder"][layer_name]["attention"]["value"]["kernel"]
# Global input layer norm
if config.model_type == "longt5" and config.encoder_attention_type == "transient-global":
_lowerCAmelCase : List[Any] = tax_model["target"]["encoder"][layer_name]["attention"]["T5LayerNorm_0"]["scale"]
# Layer Normalization
_lowerCAmelCase : Tuple = tax_model["target"]["encoder"][layer_name]["pre_attention_layer_norm"]["scale"]
if split_mlp_wi:
_lowerCAmelCase : Union[str, Any] = tax_model["target"]["encoder"][layer_name]["mlp"]["wi_0"]["kernel"]
_lowerCAmelCase : Tuple = tax_model["target"]["encoder"][layer_name]["mlp"]["wi_1"]["kernel"]
else:
_lowerCAmelCase : Union[str, Any] = tax_model["target"]["encoder"][layer_name]["mlp"]["wi"]["kernel"]
_lowerCAmelCase : Union[str, Any] = tax_model["target"]["encoder"][layer_name]["mlp"]["wo"]["kernel"]
# Layer Normalization
_lowerCAmelCase : int = tax_model["target"]["encoder"][layer_name]["pre_mlp_layer_norm"]["scale"]
# Assigning
_lowerCAmelCase : Optional[Any] = flax_model.params["encoder"]["block"][str(_lowerCamelCase )]["layer"]
_lowerCAmelCase : Any = tax_attention_key
_lowerCAmelCase : List[str] = tax_attention_out
_lowerCAmelCase : Any = tax_attention_query
_lowerCAmelCase : Dict = tax_attention_value
_lowerCAmelCase : Dict = tax_attention_layer_norm
# Global input layer norm
if config.model_type == "longt5" and config.encoder_attention_type == "transient-global":
_lowerCAmelCase : List[str] = tax_global_layer_norm
if split_mlp_wi:
_lowerCAmelCase : Union[str, Any] = tax_mlp_wi_a
_lowerCAmelCase : Optional[Any] = tax_mlp_wi_a
else:
_lowerCAmelCase : Tuple = tax_mlp_wi
_lowerCAmelCase : Any = tax_mlp_wo
_lowerCAmelCase : Optional[int] = tax_mlp_layer_norm
_lowerCAmelCase : int = flax_model_encoder_layer_block
# Only for layer 0:
_lowerCAmelCase : str = tax_model["target"]["encoder"]["relpos_bias"]["rel_embedding"].T
_lowerCAmelCase : Any = tax_encoder_rel_embedding
# Side/global relative position_bias + layer norm
if config.model_type == "longt5" and config.encoder_attention_type == "transient-global":
_lowerCAmelCase : int = tax_model["target"]["encoder"]["side_relpos_bias"]["rel_embedding"].T
_lowerCAmelCase : int = tax_encoder_global_rel_embedding
# Assigning
_lowerCAmelCase : List[Any] = tax_model["target"]["encoder"]["encoder_norm"]["scale"]
_lowerCAmelCase : List[str] = tax_encoder_norm
# Decoder
for layer_index in range(config.num_layers ):
_lowerCAmelCase : List[Any] = F"layers_{str(_lowerCamelCase )}"
# Self-Attention
_lowerCAmelCase : Optional[Any] = tax_model["target"]["decoder"][layer_name]["self_attention"]["key"]["kernel"]
_lowerCAmelCase : Any = tax_model["target"]["decoder"][layer_name]["self_attention"]["out"]["kernel"]
_lowerCAmelCase : Dict = tax_model["target"]["decoder"][layer_name]["self_attention"]["query"]["kernel"]
_lowerCAmelCase : Dict = tax_model["target"]["decoder"][layer_name]["self_attention"]["value"]["kernel"]
# Layer Normalization
_lowerCAmelCase : str = tax_model["target"]["decoder"][layer_name]["pre_self_attention_layer_norm"][
"scale"
]
# Encoder-Decoder-Attention
_lowerCAmelCase : Dict = tax_model["target"]["decoder"][layer_name]["encoder_decoder_attention"]
_lowerCAmelCase : Union[str, Any] = tax_enc_dec_attention_module["key"]["kernel"]
_lowerCAmelCase : int = tax_enc_dec_attention_module["out"]["kernel"]
_lowerCAmelCase : str = tax_enc_dec_attention_module["query"]["kernel"]
_lowerCAmelCase : Optional[int] = tax_enc_dec_attention_module["value"]["kernel"]
# Layer Normalization
_lowerCAmelCase : Tuple = tax_model["target"]["decoder"][layer_name]["pre_cross_attention_layer_norm"]["scale"]
# MLP
if split_mlp_wi:
_lowerCAmelCase : Union[str, Any] = tax_model["target"]["decoder"][layer_name]["mlp"]["wi_0"]["kernel"]
_lowerCAmelCase : Any = tax_model["target"]["decoder"][layer_name]["mlp"]["wi_1"]["kernel"]
else:
_lowerCAmelCase : List[str] = tax_model["target"]["decoder"][layer_name]["mlp"]["wi"]["kernel"]
_lowerCAmelCase : List[Any] = tax_model["target"]["decoder"][layer_name]["mlp"]["wo"]["kernel"]
# Layer Normalization
_lowerCAmelCase : Any = tax_model["target"]["decoder"][layer_name]["pre_mlp_layer_norm"]["scale"]
# Assigning
_lowerCAmelCase : Optional[int] = flax_model.params["decoder"]["block"][str(_lowerCamelCase )]["layer"]
_lowerCAmelCase : List[str] = tax_attention_key
_lowerCAmelCase : List[Any] = tax_attention_out
_lowerCAmelCase : Any = tax_attention_query
_lowerCAmelCase : Any = tax_attention_value
_lowerCAmelCase : Tuple = tax_pre_attention_layer_norm
_lowerCAmelCase : Any = tax_enc_dec_attention_key
_lowerCAmelCase : str = tax_enc_dec_attention_out
_lowerCAmelCase : List[Any] = tax_enc_dec_attention_query
_lowerCAmelCase : List[str] = tax_enc_dec_attention_value
_lowerCAmelCase : Optional[Any] = tax_cross_layer_norm
if split_mlp_wi:
_lowerCAmelCase : Dict = tax_mlp_wi_a
_lowerCAmelCase : Dict = tax_mlp_wi_a
else:
_lowerCAmelCase : Dict = tax_mlp_wi
_lowerCAmelCase : Dict = tax_mlp_wo
_lowerCAmelCase : str = txa_mlp_layer_norm
_lowerCAmelCase : Tuple = flax_model_decoder_layer_block
# Decoder Normalization
_lowerCAmelCase : Tuple = tax_model["target"]["decoder"]["decoder_norm"]["scale"]
_lowerCAmelCase : Union[str, Any] = txa_decoder_norm
# Only for layer 0:
_lowerCAmelCase : List[str] = tax_model["target"]["decoder"]["relpos_bias"]["rel_embedding"].T
_lowerCAmelCase : List[Any] = tax_decoder_rel_embedding
# Token Embeddings
_lowerCAmelCase : Tuple = tax_model["target"]["token_embedder"]["embedding"]
_lowerCAmelCase : Tuple = txa_token_embeddings
# LM Head (only in v1.1 and LongT5 checkpoints)
if "logits_dense" in tax_model["target"]["decoder"]:
_lowerCAmelCase : Optional[Any] = tax_model["target"]["decoder"]["logits_dense"]["kernel"]
flax_model.save_pretrained(_lowerCamelCase )
print("T5X Model was sucessfully converted!" )
if __name__ == "__main__":
_snake_case = argparse.ArgumentParser()
# Required parameters
parser.add_argument(
"--t5x_checkpoint_path", default=None, type=str, required=True, help="Path the T5X checkpoint."
)
parser.add_argument("--config_name", default=None, type=str, required=True, help="Config name of LongT5/T5 model.")
parser.add_argument(
"--flax_dump_folder_path", default=None, type=str, required=True, help="Path to the output FLAX model."
)
_snake_case = parser.parse_args()
convert_tax_checkpoint_to_flax(args.tax_checkpoint_path, args.config_name, args.flax_dump_folder_path)
| 36
|
from __future__ import annotations
from math import pi
from typing import Protocol
import matplotlib.pyplot as plt
import numpy as np
class UpperCAmelCase_ ( a):
def snake_case__ ( self, __a):
'''simple docstring'''
return 0.0
def A ( _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : Optional[Any] = min([-20, np.min(fft_results[1 : samplerate // 2 - 1] )] )
_lowerCAmelCase : Optional[int] = max([20, np.max(fft_results[1 : samplerate // 2 - 1] )] )
return lowest, highest
def A ( _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : int = 512
_lowerCAmelCase : Union[str, Any] = [1] + [0] * (size - 1)
_lowerCAmelCase : Optional[Any] = [filter_type.process(_lowerCamelCase ) for item in inputs]
_lowerCAmelCase : int = [0] * (samplerate - size) # zero-padding
outputs += filler
_lowerCAmelCase : str = np.abs(np.fft.fft(_lowerCamelCase ) )
_lowerCAmelCase : Union[str, Any] = 20 * np.logaa(_lowerCamelCase )
# Frequencies on log scale from 24 to nyquist frequency
plt.xlim(24 , samplerate / 2 - 1 )
plt.xlabel("Frequency (Hz)" )
plt.xscale("log" )
# Display within reasonable bounds
_lowerCAmelCase : List[Any] = get_bounds(_lowerCamelCase , _lowerCamelCase )
plt.ylim(max([-80, bounds[0]] ) , min([80, bounds[1]] ) )
plt.ylabel("Gain (dB)" )
plt.plot(_lowerCamelCase )
plt.show()
def A ( _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : Union[str, Any] = 512
_lowerCAmelCase : Optional[Any] = [1] + [0] * (size - 1)
_lowerCAmelCase : str = [filter_type.process(_lowerCamelCase ) for item in inputs]
_lowerCAmelCase : Optional[Any] = [0] * (samplerate - size) # zero-padding
outputs += filler
_lowerCAmelCase : Optional[Any] = np.angle(np.fft.fft(_lowerCamelCase ) )
# Frequencies on log scale from 24 to nyquist frequency
plt.xlim(24 , samplerate / 2 - 1 )
plt.xlabel("Frequency (Hz)" )
plt.xscale("log" )
plt.ylim(-2 * pi , 2 * pi )
plt.ylabel("Phase shift (Radians)" )
plt.plot(np.unwrap(_lowerCamelCase , -2 * pi ) )
plt.show()
| 36
| 1
|
from collections.abc import Generator
from math import sin
def A ( _lowerCamelCase ):
'''simple docstring'''
if len(_lowerCamelCase ) != 32:
raise ValueError("Input must be of length 32" )
_lowerCAmelCase : Optional[Any] = b""
for i in [3, 2, 1, 0]:
little_endian += string_aa[8 * i : 8 * i + 8]
return little_endian
def A ( _lowerCamelCase ):
'''simple docstring'''
if i < 0:
raise ValueError("Input must be non-negative" )
_lowerCAmelCase : Dict = format(_lowerCamelCase , "08x" )[-8:]
_lowerCAmelCase : int = b""
for i in [3, 2, 1, 0]:
little_endian_hex += hex_rep[2 * i : 2 * i + 2].encode("utf-8" )
return little_endian_hex
def A ( _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : Tuple = b""
for char in message:
bit_string += format(_lowerCamelCase , "08b" ).encode("utf-8" )
_lowerCAmelCase : Tuple = format(len(_lowerCamelCase ) , "064b" ).encode("utf-8" )
# Pad bit_string to a multiple of 512 chars
bit_string += b"1"
while len(_lowerCamelCase ) % 512 != 448:
bit_string += b"0"
bit_string += to_little_endian(start_len[32:] ) + to_little_endian(start_len[:32] )
return bit_string
def A ( _lowerCamelCase ):
'''simple docstring'''
if len(_lowerCamelCase ) % 512 != 0:
raise ValueError("Input must have length that's a multiple of 512" )
for pos in range(0 , len(_lowerCamelCase ) , 512 ):
_lowerCAmelCase : List[str] = bit_string[pos : pos + 512]
_lowerCAmelCase : Optional[Any] = []
for i in range(0 , 512 , 32 ):
block_words.append(int(to_little_endian(block[i : i + 32] ) , 2 ) )
yield block_words
def A ( _lowerCamelCase ):
'''simple docstring'''
if i < 0:
raise ValueError("Input must be non-negative" )
_lowerCAmelCase : str = format(_lowerCamelCase , "032b" )
_lowerCAmelCase : Optional[Any] = ""
for c in i_str:
new_str += "1" if c == "0" else "0"
return int(_lowerCamelCase , 2 )
def A ( _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
return (a + b) % 2**32
def A ( _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
if i < 0:
raise ValueError("Input must be non-negative" )
if shift < 0:
raise ValueError("Shift must be non-negative" )
return ((i << shift) ^ (i >> (32 - shift))) % 2**32
def A ( _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : Dict = preprocess(_lowerCamelCase )
_lowerCAmelCase : Tuple = [int(2**32 * abs(sin(i + 1 ) ) ) for i in range(64 )]
# Starting states
_lowerCAmelCase : int = 0X67_45_23_01
_lowerCAmelCase : Optional[Any] = 0XEF_CD_AB_89
_lowerCAmelCase : Union[str, Any] = 0X98_BA_DC_FE
_lowerCAmelCase : Dict = 0X10_32_54_76
_lowerCAmelCase : int = [
7,
12,
17,
22,
7,
12,
17,
22,
7,
12,
17,
22,
7,
12,
17,
22,
5,
9,
14,
20,
5,
9,
14,
20,
5,
9,
14,
20,
5,
9,
14,
20,
4,
11,
16,
23,
4,
11,
16,
23,
4,
11,
16,
23,
4,
11,
16,
23,
6,
10,
15,
21,
6,
10,
15,
21,
6,
10,
15,
21,
6,
10,
15,
21,
]
# Process bit string in chunks, each with 16 32-char words
for block_words in get_block_words(_lowerCamelCase ):
_lowerCAmelCase : Dict = aa
_lowerCAmelCase : Union[str, Any] = ba
_lowerCAmelCase : Dict = ca
_lowerCAmelCase : Tuple = da
# Hash current chunk
for i in range(64 ):
if i <= 15:
# f = (b & c) | (not_32(b) & d) # Alternate definition for f
_lowerCAmelCase : List[Any] = d ^ (b & (c ^ d))
_lowerCAmelCase : int = i
elif i <= 31:
# f = (d & b) | (not_32(d) & c) # Alternate definition for f
_lowerCAmelCase : List[str] = c ^ (d & (b ^ c))
_lowerCAmelCase : Dict = (5 * i + 1) % 16
elif i <= 47:
_lowerCAmelCase : Union[str, Any] = b ^ c ^ d
_lowerCAmelCase : Optional[int] = (3 * i + 5) % 16
else:
_lowerCAmelCase : List[str] = c ^ (b | not_aa(_lowerCamelCase ))
_lowerCAmelCase : int = (7 * i) % 16
_lowerCAmelCase : int = (f + a + added_consts[i] + block_words[g]) % 2**32
_lowerCAmelCase : Optional[int] = d
_lowerCAmelCase : Tuple = c
_lowerCAmelCase : int = b
_lowerCAmelCase : Tuple = sum_aa(_lowerCamelCase , left_rotate_aa(_lowerCamelCase , shift_amounts[i] ) )
# Add hashed chunk to running total
_lowerCAmelCase : List[str] = sum_aa(_lowerCamelCase , _lowerCamelCase )
_lowerCAmelCase : Any = sum_aa(_lowerCamelCase , _lowerCamelCase )
_lowerCAmelCase : Any = sum_aa(_lowerCamelCase , _lowerCamelCase )
_lowerCAmelCase : str = sum_aa(_lowerCamelCase , _lowerCamelCase )
_lowerCAmelCase : Union[str, Any] = reformat_hex(_lowerCamelCase ) + reformat_hex(_lowerCamelCase ) + reformat_hex(_lowerCamelCase ) + reformat_hex(_lowerCamelCase )
return digest
if __name__ == "__main__":
import doctest
doctest.testmod()
| 36
|
def A ( _lowerCamelCase ):
'''simple docstring'''
if bit_count < 0:
raise ValueError("The given input must be positive" )
# get the generated string sequence
_lowerCAmelCase : List[str] = gray_code_sequence_string(_lowerCamelCase )
#
# convert them to integers
for i in range(len(_lowerCamelCase ) ):
_lowerCAmelCase : List[str] = int(sequence[i] , 2 )
return sequence
def A ( _lowerCamelCase ):
'''simple docstring'''
if bit_count == 0:
return ["0"]
if bit_count == 1:
return ["0", "1"]
_lowerCAmelCase : List[Any] = 1 << bit_count # defines the length of the sequence
# 1<< n is equivalent to 2^n
# recursive answer will generate answer for n-1 bits
_lowerCAmelCase : Optional[int] = gray_code_sequence_string(bit_count - 1 )
_lowerCAmelCase : str = []
# append 0 to first half of the smaller sequence generated
for i in range(seq_len // 2 ):
_lowerCAmelCase : Dict = "0" + smaller_sequence[i]
sequence.append(_lowerCamelCase )
# append 1 to second half ... start from the end of the list
for i in reversed(range(seq_len // 2 ) ):
_lowerCAmelCase : Optional[Any] = "1" + smaller_sequence[i]
sequence.append(_lowerCamelCase )
return sequence
if __name__ == "__main__":
import doctest
doctest.testmod()
| 36
| 1
|
from typing import TYPE_CHECKING
from ...utils import (
OptionalDependencyNotAvailable,
_LazyModule,
is_flax_available,
is_tensorflow_text_available,
is_tf_available,
is_tokenizers_available,
is_torch_available,
)
_snake_case = {
"configuration_bert": ["BERT_PRETRAINED_CONFIG_ARCHIVE_MAP", "BertConfig", "BertOnnxConfig"],
"tokenization_bert": ["BasicTokenizer", "BertTokenizer", "WordpieceTokenizer"],
}
try:
if not is_tokenizers_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
_snake_case = ["BertTokenizerFast"]
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
_snake_case = [
"BERT_PRETRAINED_MODEL_ARCHIVE_LIST",
"BertForMaskedLM",
"BertForMultipleChoice",
"BertForNextSentencePrediction",
"BertForPreTraining",
"BertForQuestionAnswering",
"BertForSequenceClassification",
"BertForTokenClassification",
"BertLayer",
"BertLMHeadModel",
"BertModel",
"BertPreTrainedModel",
"load_tf_weights_in_bert",
]
try:
if not is_tf_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
_snake_case = [
"TF_BERT_PRETRAINED_MODEL_ARCHIVE_LIST",
"TFBertEmbeddings",
"TFBertForMaskedLM",
"TFBertForMultipleChoice",
"TFBertForNextSentencePrediction",
"TFBertForPreTraining",
"TFBertForQuestionAnswering",
"TFBertForSequenceClassification",
"TFBertForTokenClassification",
"TFBertLMHeadModel",
"TFBertMainLayer",
"TFBertModel",
"TFBertPreTrainedModel",
]
try:
if not is_tensorflow_text_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
_snake_case = ["TFBertTokenizer"]
try:
if not is_flax_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
_snake_case = [
"FlaxBertForCausalLM",
"FlaxBertForMaskedLM",
"FlaxBertForMultipleChoice",
"FlaxBertForNextSentencePrediction",
"FlaxBertForPreTraining",
"FlaxBertForQuestionAnswering",
"FlaxBertForSequenceClassification",
"FlaxBertForTokenClassification",
"FlaxBertModel",
"FlaxBertPreTrainedModel",
]
if TYPE_CHECKING:
from .configuration_bert import BERT_PRETRAINED_CONFIG_ARCHIVE_MAP, BertConfig, BertOnnxConfig
from .tokenization_bert import BasicTokenizer, BertTokenizer, WordpieceTokenizer
try:
if not is_tokenizers_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .tokenization_bert_fast import BertTokenizerFast
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_bert import (
BERT_PRETRAINED_MODEL_ARCHIVE_LIST,
BertForMaskedLM,
BertForMultipleChoice,
BertForNextSentencePrediction,
BertForPreTraining,
BertForQuestionAnswering,
BertForSequenceClassification,
BertForTokenClassification,
BertLayer,
BertLMHeadModel,
BertModel,
BertPreTrainedModel,
load_tf_weights_in_bert,
)
try:
if not is_tf_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_tf_bert import (
TF_BERT_PRETRAINED_MODEL_ARCHIVE_LIST,
TFBertEmbeddings,
TFBertForMaskedLM,
TFBertForMultipleChoice,
TFBertForNextSentencePrediction,
TFBertForPreTraining,
TFBertForQuestionAnswering,
TFBertForSequenceClassification,
TFBertForTokenClassification,
TFBertLMHeadModel,
TFBertMainLayer,
TFBertModel,
TFBertPreTrainedModel,
)
try:
if not is_tensorflow_text_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .tokenization_bert_tf import TFBertTokenizer
try:
if not is_flax_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_flax_bert import (
FlaxBertForCausalLM,
FlaxBertForMaskedLM,
FlaxBertForMultipleChoice,
FlaxBertForNextSentencePrediction,
FlaxBertForPreTraining,
FlaxBertForQuestionAnswering,
FlaxBertForSequenceClassification,
FlaxBertForTokenClassification,
FlaxBertModel,
FlaxBertPreTrainedModel,
)
else:
import sys
_snake_case = _LazyModule(__name__, globals()["__file__"], _import_structure, module_spec=__spec__)
| 36
|
from PIL import Image
def A ( _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase , _lowerCAmelCase : int = image.size
_lowerCAmelCase : Any = 0
_lowerCAmelCase : Tuple = image.load()
for i in range(_lowerCamelCase ):
for j in range(_lowerCamelCase ):
_lowerCAmelCase : Union[str, Any] = pixels[j, i]
mean += pixel
mean //= width * height
for j in range(_lowerCamelCase ):
for i in range(_lowerCamelCase ):
_lowerCAmelCase : Optional[Any] = 255 if pixels[i, j] > mean else 0
return image
if __name__ == "__main__":
_snake_case = mean_threshold(Image.open("path_to_image").convert("L"))
image.save("output_image_path")
| 36
| 1
|
from typing import TYPE_CHECKING
from ...utils import _LazyModule
_snake_case = {"tokenization_bertweet": ["BertweetTokenizer"]}
if TYPE_CHECKING:
from .tokenization_bertweet import BertweetTokenizer
else:
import sys
_snake_case = _LazyModule(__name__, globals()["__file__"], _import_structure, module_spec=__spec__)
| 36
|
import functools
import operator
from ...configuration_utils import PretrainedConfig
from ...utils import logging
_snake_case = logging.get_logger(__name__)
_snake_case = {
"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 UpperCAmelCase_ ( a):
lowerCamelCase__ = 'wav2vec2'
def __init__( self, __a=32, __a=768, __a=12, __a=12, __a=3072, __a="gelu", __a=0.1, __a=0.1, __a=0.1, __a=0.0, __a=0.0, __a=0.1, __a=0.1, __a=0.02, __a=1E-5, __a="group", __a="gelu", __a=(512, 512, 512, 512, 512, 512, 512), __a=(5, 2, 2, 2, 2, 2, 2), __a=(10, 3, 3, 3, 3, 2, 2), __a=False, __a=128, __a=16, __a=False, __a=True, __a=0.05, __a=10, __a=2, __a=0.0, __a=10, __a=0, __a=320, __a=2, __a=0.1, __a=100, __a=256, __a=256, __a=0.1, __a="sum", __a=False, __a=False, __a=256, __a=(512, 512, 512, 512, 1500), __a=(5, 3, 3, 1, 1), __a=(1, 2, 3, 1, 1), __a=512, __a=0, __a=1, __a=2, __a=False, __a=3, __a=2, __a=3, __a=None, __a=None, **__a, ):
'''simple docstring'''
super().__init__(**__a, pad_token_id=__a, bos_token_id=__a, eos_token_id=__a)
_lowerCAmelCase : str = hidden_size
_lowerCAmelCase : Optional[int] = feat_extract_norm
_lowerCAmelCase : Union[str, Any] = feat_extract_activation
_lowerCAmelCase : Optional[Any] = list(__a)
_lowerCAmelCase : List[str] = list(__a)
_lowerCAmelCase : str = list(__a)
_lowerCAmelCase : List[str] = conv_bias
_lowerCAmelCase : str = num_conv_pos_embeddings
_lowerCAmelCase : List[Any] = num_conv_pos_embedding_groups
_lowerCAmelCase : str = len(self.conv_dim)
_lowerCAmelCase : List[str] = num_hidden_layers
_lowerCAmelCase : str = intermediate_size
_lowerCAmelCase : Any = hidden_act
_lowerCAmelCase : int = num_attention_heads
_lowerCAmelCase : Optional[Any] = hidden_dropout
_lowerCAmelCase : List[str] = attention_dropout
_lowerCAmelCase : Tuple = activation_dropout
_lowerCAmelCase : int = feat_proj_dropout
_lowerCAmelCase : List[str] = final_dropout
_lowerCAmelCase : int = layerdrop
_lowerCAmelCase : int = layer_norm_eps
_lowerCAmelCase : Union[str, Any] = initializer_range
_lowerCAmelCase : str = vocab_size
_lowerCAmelCase : Optional[Any] = do_stable_layer_norm
_lowerCAmelCase : 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
_lowerCAmelCase : str = apply_spec_augment
_lowerCAmelCase : Optional[Any] = mask_time_prob
_lowerCAmelCase : Optional[int] = mask_time_length
_lowerCAmelCase : List[str] = mask_time_min_masks
_lowerCAmelCase : Optional[int] = mask_feature_prob
_lowerCAmelCase : Optional[int] = mask_feature_length
_lowerCAmelCase : List[str] = mask_feature_min_masks
# parameters for pretraining with codevector quantized representations
_lowerCAmelCase : Union[str, Any] = num_codevectors_per_group
_lowerCAmelCase : str = num_codevector_groups
_lowerCAmelCase : Optional[int] = contrastive_logits_temperature
_lowerCAmelCase : Optional[int] = feat_quantizer_dropout
_lowerCAmelCase : Optional[int] = num_negatives
_lowerCAmelCase : Union[str, Any] = codevector_dim
_lowerCAmelCase : Any = proj_codevector_dim
_lowerCAmelCase : Optional[int] = diversity_loss_weight
# ctc loss
_lowerCAmelCase : Tuple = ctc_loss_reduction
_lowerCAmelCase : Tuple = ctc_zero_infinity
# adapter
_lowerCAmelCase : List[Any] = add_adapter
_lowerCAmelCase : List[str] = adapter_kernel_size
_lowerCAmelCase : str = adapter_stride
_lowerCAmelCase : List[str] = num_adapter_layers
_lowerCAmelCase : str = output_hidden_size or hidden_size
_lowerCAmelCase : Tuple = adapter_attn_dim
# SequenceClassification-specific parameter. Feel free to ignore for other classes.
_lowerCAmelCase : str = classifier_proj_size
# XVector-specific parameters. Feel free to ignore for other classes.
_lowerCAmelCase : str = list(__a)
_lowerCAmelCase : Union[str, Any] = list(__a)
_lowerCAmelCase : List[str] = list(__a)
_lowerCAmelCase : Tuple = xvector_output_dim
@property
def snake_case__ ( self):
'''simple docstring'''
return functools.reduce(operator.mul, self.conv_stride, 1)
| 36
| 1
|
from __future__ import annotations
from collections.abc import MutableSequence
class UpperCAmelCase_ :
def __init__( self, __a, __a):
'''simple docstring'''
if len(__a) != degree + 1:
raise ValueError(
"The number of coefficients should be equal to the degree + 1.")
_lowerCAmelCase : list[float] = list(__a)
_lowerCAmelCase : Any = degree
def __add__( self, __a):
'''simple docstring'''
if self.degree > polynomial_a.degree:
_lowerCAmelCase : Optional[Any] = self.coefficients[:]
for i in range(polynomial_a.degree + 1):
coefficients[i] += polynomial_a.coefficients[i]
return Polynomial(self.degree, __a)
else:
_lowerCAmelCase : Union[str, Any] = polynomial_a.coefficients[:]
for i in range(self.degree + 1):
coefficients[i] += self.coefficients[i]
return Polynomial(polynomial_a.degree, __a)
def __sub__( self, __a):
'''simple docstring'''
return self + polynomial_a * Polynomial(0, [-1])
def __neg__( self):
'''simple docstring'''
return Polynomial(self.degree, [-c for c in self.coefficients])
def __mul__( self, __a):
'''simple docstring'''
_lowerCAmelCase : list[float] = [0] * (self.degree + polynomial_a.degree + 1)
for i in range(self.degree + 1):
for j in range(polynomial_a.degree + 1):
coefficients[i + j] += (
self.coefficients[i] * polynomial_a.coefficients[j]
)
return Polynomial(self.degree + polynomial_a.degree, __a)
def snake_case__ ( self, __a):
'''simple docstring'''
_lowerCAmelCase : int | float = 0
for i in range(self.degree + 1):
result += self.coefficients[i] * (substitution**i)
return result
def __str__( self):
'''simple docstring'''
_lowerCAmelCase : List[Any] = ""
for i in range(self.degree, -1, -1):
if self.coefficients[i] == 0:
continue
elif self.coefficients[i] > 0:
if polynomial:
polynomial += " + "
else:
polynomial += " - "
if i == 0:
polynomial += str(abs(self.coefficients[i]))
elif i == 1:
polynomial += str(abs(self.coefficients[i])) + "x"
else:
polynomial += str(abs(self.coefficients[i])) + "x^" + str(__a)
return polynomial
def __repr__( self):
'''simple docstring'''
return self.__str__()
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : list[float] = [0] * self.degree
for i in range(self.degree):
_lowerCAmelCase : Optional[Any] = self.coefficients[i + 1] * (i + 1)
return Polynomial(self.degree - 1, __a)
def snake_case__ ( self, __a = 0):
'''simple docstring'''
_lowerCAmelCase : list[float] = [0] * (self.degree + 2)
_lowerCAmelCase : Dict = constant
for i in range(self.degree + 1):
_lowerCAmelCase : Tuple = self.coefficients[i] / (i + 1)
return Polynomial(self.degree + 1, __a)
def __eq__( self, __a):
'''simple docstring'''
if not isinstance(__a, __a):
return False
if self.degree != polynomial_a.degree:
return False
for i in range(self.degree + 1):
if self.coefficients[i] != polynomial_a.coefficients[i]:
return False
return True
def __ne__( self, __a):
'''simple docstring'''
return not self.__eq__(__a)
| 36
|
from __future__ import absolute_import, division, print_function, unicode_literals
from torch import nn
from torch.nn import CrossEntropyLoss, MSELoss
from transformers import RobertaConfig
from transformers.file_utils import add_start_docstrings, add_start_docstrings_to_model_forward
from transformers.models.roberta.modeling_roberta import (
ROBERTA_INPUTS_DOCSTRING,
ROBERTA_START_DOCSTRING,
RobertaEmbeddings,
)
from .modeling_highway_bert import BertPreTrainedModel, DeeBertModel, HighwayException, entropy
@add_start_docstrings(
'The RoBERTa Model transformer with early exiting (DeeRoBERTa). ' , a , )
class UpperCAmelCase_ ( a):
lowerCamelCase__ = RobertaConfig
lowerCamelCase__ = 'roberta'
def __init__( self, __a):
'''simple docstring'''
super().__init__(__a)
_lowerCAmelCase : Optional[Any] = RobertaEmbeddings(__a)
self.init_weights()
@add_start_docstrings(
'RoBERTa Model (with early exiting - DeeRoBERTa) with a classifier on top,\n also takes care of multi-layer training. ' , a , )
class UpperCAmelCase_ ( a):
lowerCamelCase__ = RobertaConfig
lowerCamelCase__ = 'roberta'
def __init__( self, __a):
'''simple docstring'''
super().__init__(__a)
_lowerCAmelCase : Optional[int] = config.num_labels
_lowerCAmelCase : Optional[int] = config.num_hidden_layers
_lowerCAmelCase : Optional[int] = DeeRobertaModel(__a)
_lowerCAmelCase : Union[str, Any] = nn.Dropout(config.hidden_dropout_prob)
_lowerCAmelCase : List[str] = nn.Linear(config.hidden_size, self.config.num_labels)
@add_start_docstrings_to_model_forward(__a)
def snake_case__ ( self, __a=None, __a=None, __a=None, __a=None, __a=None, __a=None, __a=None, __a=-1, __a=False, ):
'''simple docstring'''
_lowerCAmelCase : Union[str, Any] = self.num_layers
try:
_lowerCAmelCase : List[Any] = self.roberta(
__a, attention_mask=__a, token_type_ids=__a, position_ids=__a, head_mask=__a, inputs_embeds=__a, )
_lowerCAmelCase : List[Any] = outputs[1]
_lowerCAmelCase : Dict = self.dropout(__a)
_lowerCAmelCase : Dict = self.classifier(__a)
_lowerCAmelCase : Optional[Any] = (logits,) + outputs[2:] # add hidden states and attention if they are here
except HighwayException as e:
_lowerCAmelCase : Tuple = e.message
_lowerCAmelCase : Union[str, Any] = e.exit_layer
_lowerCAmelCase : List[Any] = outputs[0]
if not self.training:
_lowerCAmelCase : int = entropy(__a)
_lowerCAmelCase : List[Any] = []
_lowerCAmelCase : str = []
if labels is not None:
if self.num_labels == 1:
# We are doing regression
_lowerCAmelCase : Optional[Any] = MSELoss()
_lowerCAmelCase : int = loss_fct(logits.view(-1), labels.view(-1))
else:
_lowerCAmelCase : Optional[Any] = CrossEntropyLoss()
_lowerCAmelCase : Optional[Any] = loss_fct(logits.view(-1, self.num_labels), labels.view(-1))
# work with highway exits
_lowerCAmelCase : Optional[int] = []
for highway_exit in outputs[-1]:
_lowerCAmelCase : Any = highway_exit[0]
if not self.training:
highway_logits_all.append(__a)
highway_entropy.append(highway_exit[2])
if self.num_labels == 1:
# We are doing regression
_lowerCAmelCase : List[str] = MSELoss()
_lowerCAmelCase : List[Any] = loss_fct(highway_logits.view(-1), labels.view(-1))
else:
_lowerCAmelCase : Dict = CrossEntropyLoss()
_lowerCAmelCase : Optional[Any] = loss_fct(highway_logits.view(-1, self.num_labels), labels.view(-1))
highway_losses.append(__a)
if train_highway:
_lowerCAmelCase : int = (sum(highway_losses[:-1]),) + outputs
# exclude the final highway, of course
else:
_lowerCAmelCase : Any = (loss,) + outputs
if not self.training:
_lowerCAmelCase : Optional[Any] = outputs + ((original_entropy, highway_entropy), exit_layer)
if output_layer >= 0:
_lowerCAmelCase : Optional[Any] = (
(outputs[0],) + (highway_logits_all[output_layer],) + outputs[2:]
) # use the highway of the last layer
return outputs # (loss), logits, (hidden_states), (attentions), entropy
| 36
| 1
|
import os
import time
import pytest
from datasets.utils.filelock import FileLock, Timeout
def A ( _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : Dict = FileLock(str(tmpdir / "foo.lock" ) )
_lowerCAmelCase : Union[str, Any] = FileLock(str(tmpdir / "foo.lock" ) )
_lowerCAmelCase : Optional[int] = 0.01
with locka.acquire():
with pytest.raises(_lowerCamelCase ):
_lowerCAmelCase : Optional[Any] = time.time()
locka.acquire(_lowerCamelCase )
assert time.time() - _start > timeout
def A ( _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : Optional[int] = "a" * 1_000 + ".lock"
_lowerCAmelCase : Union[str, Any] = FileLock(str(tmpdir / filename ) )
assert locka._lock_file.endswith(".lock" )
assert not locka._lock_file.endswith(_lowerCamelCase )
assert len(os.path.basename(locka._lock_file ) ) <= 255
_lowerCAmelCase : str = FileLock(tmpdir / filename )
with locka.acquire():
with pytest.raises(_lowerCamelCase ):
locka.acquire(0 )
| 36
|
import copy
from typing import TYPE_CHECKING, Any, Mapping, Optional, OrderedDict
from packaging import version
from ...configuration_utils import PretrainedConfig
from ...onnx import OnnxConfig
from ...utils import logging
from ..auto.configuration_auto import AutoConfig
if TYPE_CHECKING:
from ... import PreTrainedTokenizerBase, TensorType
_snake_case = logging.get_logger(__name__)
class UpperCAmelCase_ ( a):
lowerCamelCase__ = 'vision-encoder-decoder'
lowerCamelCase__ = True
def __init__( self, **__a):
'''simple docstring'''
super().__init__(**__a)
if "encoder" not in kwargs or "decoder" not in kwargs:
raise ValueError(
f"A configuraton of type {self.model_type} cannot be instantiated because "
f"not both `encoder` and `decoder` sub-configurations are passed, but only {kwargs}")
_lowerCAmelCase : str = kwargs.pop("encoder")
_lowerCAmelCase : Any = encoder_config.pop("model_type")
_lowerCAmelCase : str = kwargs.pop("decoder")
_lowerCAmelCase : List[str] = decoder_config.pop("model_type")
_lowerCAmelCase : Optional[Any] = AutoConfig.for_model(__a, **__a)
_lowerCAmelCase : Optional[Any] = AutoConfig.for_model(__a, **__a)
_lowerCAmelCase : Optional[int] = True
@classmethod
def snake_case__ ( cls, __a, __a, **__a):
'''simple docstring'''
logger.info("Setting `config.is_decoder=True` and `config.add_cross_attention=True` for decoder_config")
_lowerCAmelCase : Optional[Any] = True
_lowerCAmelCase : str = True
return cls(encoder=encoder_config.to_dict(), decoder=decoder_config.to_dict(), **__a)
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : int = copy.deepcopy(self.__dict__)
_lowerCAmelCase : List[str] = self.encoder.to_dict()
_lowerCAmelCase : List[str] = self.decoder.to_dict()
_lowerCAmelCase : Any = self.__class__.model_type
return output
class UpperCAmelCase_ ( a):
lowerCamelCase__ = version.parse('1.11')
@property
def snake_case__ ( self):
'''simple docstring'''
return OrderedDict(
[
("pixel_values", {0: "batch", 1: "num_channels", 2: "height", 3: "width"}),
])
@property
def snake_case__ ( self):
'''simple docstring'''
return 1E-4
@property
def snake_case__ ( self):
'''simple docstring'''
return OrderedDict({"last_hidden_state": {0: "batch", 1: "encoder_sequence"}})
class UpperCAmelCase_ ( a):
@property
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Optional[Any] = OrderedDict()
_lowerCAmelCase : Any = {0: "batch", 1: "past_decoder_sequence + sequence"}
_lowerCAmelCase : List[str] = {0: "batch", 1: "past_decoder_sequence + sequence"}
_lowerCAmelCase : Optional[Any] = {0: "batch", 1: "encoder_sequence"}
return common_inputs
def snake_case__ ( self, __a, __a = -1, __a = -1, __a = False, __a = None, ):
'''simple docstring'''
import torch
_lowerCAmelCase : Optional[Any] = OrderedDict()
_lowerCAmelCase : List[str] = super().generate_dummy_inputs(
__a, batch_size=__a, seq_length=__a, is_pair=__a, framework=__a)
_lowerCAmelCase , _lowerCAmelCase : Optional[Any] = dummy_input["input_ids"].shape
_lowerCAmelCase : str = (batch, encoder_sequence, self._config.encoder_hidden_size)
_lowerCAmelCase : List[str] = dummy_input.pop("input_ids")
_lowerCAmelCase : List[str] = dummy_input.pop("attention_mask")
_lowerCAmelCase : Optional[int] = torch.zeros(__a)
return common_inputs
class UpperCAmelCase_ ( a):
@property
def snake_case__ ( self):
'''simple docstring'''
pass
def snake_case__ ( self, __a):
'''simple docstring'''
return VisionEncoderDecoderEncoderOnnxConfig(__a)
def snake_case__ ( self, __a, __a, __a = "default"):
'''simple docstring'''
_lowerCAmelCase : Dict = encoder_config.hidden_size
return VisionEncoderDecoderDecoderOnnxConfig(__a, __a)
| 36
| 1
|
import unittest
from transformers import LiltConfig, is_torch_available
from transformers.testing_utils import require_torch, slow, torch_device
from ...generation.test_utils import GenerationTesterMixin
from ...test_configuration_common import ConfigTester
from ...test_modeling_common import ModelTesterMixin, ids_tensor
from ...test_pipeline_mixin import PipelineTesterMixin
if is_torch_available():
import torch
from transformers import (
LiltForQuestionAnswering,
LiltForSequenceClassification,
LiltForTokenClassification,
LiltModel,
)
from transformers.models.lilt.modeling_lilt import LILT_PRETRAINED_MODEL_ARCHIVE_LIST
class UpperCAmelCase_ :
def __init__( self, __a, __a=13, __a=7, __a=True, __a=True, __a=True, __a=True, __a=99, __a=24, __a=2, __a=6, __a=37, __a="gelu", __a=0.1, __a=0.1, __a=512, __a=16, __a=2, __a=0.02, __a=3, __a=None, __a=1000, ):
'''simple docstring'''
_lowerCAmelCase : Tuple = parent
_lowerCAmelCase : List[str] = batch_size
_lowerCAmelCase : int = seq_length
_lowerCAmelCase : Optional[int] = is_training
_lowerCAmelCase : Dict = use_input_mask
_lowerCAmelCase : List[str] = use_token_type_ids
_lowerCAmelCase : str = use_labels
_lowerCAmelCase : Optional[Any] = vocab_size
_lowerCAmelCase : Tuple = hidden_size
_lowerCAmelCase : List[Any] = num_hidden_layers
_lowerCAmelCase : Optional[Any] = num_attention_heads
_lowerCAmelCase : Any = intermediate_size
_lowerCAmelCase : List[str] = hidden_act
_lowerCAmelCase : Union[str, Any] = hidden_dropout_prob
_lowerCAmelCase : Any = attention_probs_dropout_prob
_lowerCAmelCase : int = max_position_embeddings
_lowerCAmelCase : Optional[int] = type_vocab_size
_lowerCAmelCase : Optional[Any] = type_sequence_label_size
_lowerCAmelCase : List[str] = initializer_range
_lowerCAmelCase : List[Any] = num_labels
_lowerCAmelCase : Tuple = scope
_lowerCAmelCase : str = range_bbox
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Dict = ids_tensor([self.batch_size, self.seq_length], self.vocab_size)
_lowerCAmelCase : int = ids_tensor([self.batch_size, self.seq_length, 4], self.range_bbox)
# Ensure that bbox is legal
for i in range(bbox.shape[0]):
for j in range(bbox.shape[1]):
if bbox[i, j, 3] < bbox[i, j, 1]:
_lowerCAmelCase : Dict = bbox[i, j, 3]
_lowerCAmelCase : int = bbox[i, j, 1]
_lowerCAmelCase : Tuple = t
if bbox[i, j, 2] < bbox[i, j, 0]:
_lowerCAmelCase : str = bbox[i, j, 2]
_lowerCAmelCase : List[Any] = bbox[i, j, 0]
_lowerCAmelCase : str = t
_lowerCAmelCase : Optional[Any] = None
if self.use_input_mask:
_lowerCAmelCase : Union[str, Any] = ids_tensor([self.batch_size, self.seq_length], vocab_size=2)
_lowerCAmelCase : Dict = None
if self.use_token_type_ids:
_lowerCAmelCase : Any = ids_tensor([self.batch_size, self.seq_length], self.type_vocab_size)
_lowerCAmelCase : Optional[int] = None
_lowerCAmelCase : Optional[Any] = None
if self.use_labels:
_lowerCAmelCase : Optional[Any] = ids_tensor([self.batch_size], self.type_sequence_label_size)
_lowerCAmelCase : Any = ids_tensor([self.batch_size, self.seq_length], self.num_labels)
_lowerCAmelCase : Optional[int] = self.get_config()
return config, input_ids, bbox, token_type_ids, input_mask, sequence_labels, token_labels
def snake_case__ ( self):
'''simple docstring'''
return LiltConfig(
vocab_size=self.vocab_size, hidden_size=self.hidden_size, num_hidden_layers=self.num_hidden_layers, num_attention_heads=self.num_attention_heads, intermediate_size=self.intermediate_size, hidden_act=self.hidden_act, hidden_dropout_prob=self.hidden_dropout_prob, attention_probs_dropout_prob=self.attention_probs_dropout_prob, max_position_embeddings=self.max_position_embeddings, type_vocab_size=self.type_vocab_size, initializer_range=self.initializer_range, )
def snake_case__ ( self, __a, __a, __a, __a, __a, __a, __a, ):
'''simple docstring'''
_lowerCAmelCase : Union[str, Any] = LiltModel(config=__a)
model.to(__a)
model.eval()
_lowerCAmelCase : Dict = model(__a, bbox=__a, attention_mask=__a, token_type_ids=__a)
_lowerCAmelCase : str = model(__a, bbox=__a, token_type_ids=__a)
_lowerCAmelCase : List[Any] = model(__a, bbox=__a)
self.parent.assertEqual(result.last_hidden_state.shape, (self.batch_size, self.seq_length, self.hidden_size))
self.parent.assertEqual(result.pooler_output.shape, (self.batch_size, self.hidden_size))
def snake_case__ ( self, __a, __a, __a, __a, __a, __a, __a, ):
'''simple docstring'''
_lowerCAmelCase : List[Any] = self.num_labels
_lowerCAmelCase : Optional[Any] = LiltForTokenClassification(config=__a)
model.to(__a)
model.eval()
_lowerCAmelCase : Dict = model(
__a, bbox=__a, attention_mask=__a, token_type_ids=__a, labels=__a)
self.parent.assertEqual(result.logits.shape, (self.batch_size, self.seq_length, self.num_labels))
def snake_case__ ( self, __a, __a, __a, __a, __a, __a, __a, ):
'''simple docstring'''
_lowerCAmelCase : Optional[int] = LiltForQuestionAnswering(config=__a)
model.to(__a)
model.eval()
_lowerCAmelCase : Tuple = model(
__a, bbox=__a, attention_mask=__a, token_type_ids=__a, start_positions=__a, end_positions=__a, )
self.parent.assertEqual(result.start_logits.shape, (self.batch_size, self.seq_length))
self.parent.assertEqual(result.end_logits.shape, (self.batch_size, self.seq_length))
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Optional[Any] = self.prepare_config_and_inputs()
(
(
_lowerCAmelCase
) , (
_lowerCAmelCase
) , (
_lowerCAmelCase
) , (
_lowerCAmelCase
) , (
_lowerCAmelCase
) , (
_lowerCAmelCase
) , (
_lowerCAmelCase
) ,
) : Dict = config_and_inputs
_lowerCAmelCase : List[Any] = {
"input_ids": input_ids,
"bbox": bbox,
"token_type_ids": token_type_ids,
"attention_mask": input_mask,
}
return config, inputs_dict
@require_torch
class UpperCAmelCase_ ( a , a , a , unittest.TestCase):
lowerCamelCase__ = (
(
LiltModel,
LiltForSequenceClassification,
LiltForTokenClassification,
LiltForQuestionAnswering,
)
if is_torch_available()
else ()
)
lowerCamelCase__ = (
{
'feature-extraction': LiltModel,
'question-answering': LiltForQuestionAnswering,
'text-classification': LiltForSequenceClassification,
'token-classification': LiltForTokenClassification,
'zero-shot': LiltForSequenceClassification,
}
if is_torch_available()
else {}
)
lowerCamelCase__ = False
lowerCamelCase__ = False
def snake_case__ ( self, __a, __a, __a, __a, __a):
'''simple docstring'''
return True
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Optional[Any] = LiltModelTester(self)
_lowerCAmelCase : Union[str, Any] = ConfigTester(self, config_class=__a, hidden_size=37)
def snake_case__ ( self):
'''simple docstring'''
self.config_tester.run_common_tests()
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Dict = self.model_tester.prepare_config_and_inputs()
self.model_tester.create_and_check_model(*__a)
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : int = self.model_tester.prepare_config_and_inputs()
for type in ["absolute", "relative_key", "relative_key_query"]:
_lowerCAmelCase : Any = type
self.model_tester.create_and_check_model(*__a)
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : int = self.model_tester.prepare_config_and_inputs()
self.model_tester.create_and_check_for_token_classification(*__a)
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Optional[int] = self.model_tester.prepare_config_and_inputs()
self.model_tester.create_and_check_for_question_answering(*__a)
@slow
def snake_case__ ( self):
'''simple docstring'''
for model_name in LILT_PRETRAINED_MODEL_ARCHIVE_LIST[:1]:
_lowerCAmelCase : str = LiltModel.from_pretrained(__a)
self.assertIsNotNone(__a)
@require_torch
@slow
class UpperCAmelCase_ ( unittest.TestCase):
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Dict = LiltModel.from_pretrained("SCUT-DLVCLab/lilt-roberta-en-base").to(__a)
_lowerCAmelCase : Any = torch.tensor([[1, 2]], device=__a)
_lowerCAmelCase : str = torch.tensor([[[1, 2, 3, 4], [5, 6, 7, 8]]], device=__a)
# forward pass
with torch.no_grad():
_lowerCAmelCase : Optional[Any] = model(input_ids=__a, bbox=__a)
_lowerCAmelCase : Optional[int] = torch.Size([1, 2, 768])
_lowerCAmelCase : List[str] = torch.tensor(
[[-0.0_653, 0.0_950, -0.0_061], [-0.0_545, 0.0_926, -0.0_324]], device=__a, )
self.assertTrue(outputs.last_hidden_state.shape, __a)
self.assertTrue(torch.allclose(outputs.last_hidden_state[0, :, :3], __a, atol=1E-3))
| 36
|
import inspect
import tempfile
from collections import OrderedDict, UserDict
from collections.abc import MutableMapping
from contextlib import ExitStack, contextmanager
from dataclasses import fields
from enum import Enum
from typing import Any, ContextManager, List, Tuple
import numpy as np
from .import_utils import is_flax_available, is_tf_available, is_torch_available, is_torch_fx_proxy
if is_flax_available():
import jax.numpy as jnp
class UpperCAmelCase_ ( a):
def __get__( self, __a, __a=None):
'''simple docstring'''
if obj is None:
return self
if self.fget is None:
raise AttributeError("unreadable attribute")
_lowerCAmelCase : List[Any] = "__cached_" + self.fget.__name__
_lowerCAmelCase : Dict = getattr(__a, __a, __a)
if cached is None:
_lowerCAmelCase : str = self.fget(__a)
setattr(__a, __a, __a)
return cached
def A ( _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : Any = val.lower()
if val in {"y", "yes", "t", "true", "on", "1"}:
return 1
if val in {"n", "no", "f", "false", "off", "0"}:
return 0
raise ValueError(F"invalid truth value {val!r}" )
def A ( _lowerCamelCase ):
'''simple docstring'''
if is_torch_fx_proxy(_lowerCamelCase ):
return True
if is_torch_available():
import torch
if isinstance(_lowerCamelCase , torch.Tensor ):
return True
if is_tf_available():
import tensorflow as tf
if isinstance(_lowerCamelCase , tf.Tensor ):
return True
if is_flax_available():
import jax.numpy as jnp
from jax.core import Tracer
if isinstance(_lowerCamelCase , (jnp.ndarray, Tracer) ):
return True
return isinstance(_lowerCamelCase , np.ndarray )
def A ( _lowerCamelCase ):
'''simple docstring'''
return isinstance(_lowerCamelCase , np.ndarray )
def A ( _lowerCamelCase ):
'''simple docstring'''
return _is_numpy(_lowerCamelCase )
def A ( _lowerCamelCase ):
'''simple docstring'''
import torch
return isinstance(_lowerCamelCase , torch.Tensor )
def A ( _lowerCamelCase ):
'''simple docstring'''
return False if not is_torch_available() else _is_torch(_lowerCamelCase )
def A ( _lowerCamelCase ):
'''simple docstring'''
import torch
return isinstance(_lowerCamelCase , torch.device )
def A ( _lowerCamelCase ):
'''simple docstring'''
return False if not is_torch_available() else _is_torch_device(_lowerCamelCase )
def A ( _lowerCamelCase ):
'''simple docstring'''
import torch
if isinstance(_lowerCamelCase , _lowerCamelCase ):
if hasattr(_lowerCamelCase , _lowerCamelCase ):
_lowerCAmelCase : Optional[Any] = getattr(_lowerCamelCase , _lowerCamelCase )
else:
return False
return isinstance(_lowerCamelCase , torch.dtype )
def A ( _lowerCamelCase ):
'''simple docstring'''
return False if not is_torch_available() else _is_torch_dtype(_lowerCamelCase )
def A ( _lowerCamelCase ):
'''simple docstring'''
import tensorflow as tf
return isinstance(_lowerCamelCase , tf.Tensor )
def A ( _lowerCamelCase ):
'''simple docstring'''
return False if not is_tf_available() else _is_tensorflow(_lowerCamelCase )
def A ( _lowerCamelCase ):
'''simple docstring'''
import tensorflow as tf
# the `is_symbolic_tensor` predicate is only available starting with TF 2.14
if hasattr(_lowerCamelCase , "is_symbolic_tensor" ):
return tf.is_symbolic_tensor(_lowerCamelCase )
return type(_lowerCamelCase ) == tf.Tensor
def A ( _lowerCamelCase ):
'''simple docstring'''
return False if not is_tf_available() else _is_tf_symbolic_tensor(_lowerCamelCase )
def A ( _lowerCamelCase ):
'''simple docstring'''
import jax.numpy as jnp # noqa: F811
return isinstance(_lowerCamelCase , jnp.ndarray )
def A ( _lowerCamelCase ):
'''simple docstring'''
return False if not is_flax_available() else _is_jax(_lowerCamelCase )
def A ( _lowerCamelCase ):
'''simple docstring'''
if isinstance(_lowerCamelCase , (dict, UserDict) ):
return {k: to_py_obj(_lowerCamelCase ) for k, v in obj.items()}
elif isinstance(_lowerCamelCase , (list, tuple) ):
return [to_py_obj(_lowerCamelCase ) for o in obj]
elif is_tf_tensor(_lowerCamelCase ):
return obj.numpy().tolist()
elif is_torch_tensor(_lowerCamelCase ):
return obj.detach().cpu().tolist()
elif is_jax_tensor(_lowerCamelCase ):
return np.asarray(_lowerCamelCase ).tolist()
elif isinstance(_lowerCamelCase , (np.ndarray, np.number) ): # tolist also works on 0d np arrays
return obj.tolist()
else:
return obj
def A ( _lowerCamelCase ):
'''simple docstring'''
if isinstance(_lowerCamelCase , (dict, UserDict) ):
return {k: to_numpy(_lowerCamelCase ) for k, v in obj.items()}
elif isinstance(_lowerCamelCase , (list, tuple) ):
return np.array(_lowerCamelCase )
elif is_tf_tensor(_lowerCamelCase ):
return obj.numpy()
elif is_torch_tensor(_lowerCamelCase ):
return obj.detach().cpu().numpy()
elif is_jax_tensor(_lowerCamelCase ):
return np.asarray(_lowerCamelCase )
else:
return obj
class UpperCAmelCase_ ( a):
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Tuple = fields(self)
# Safety and consistency checks
if not len(__a):
raise ValueError(f"{self.__class__.__name__} has no fields.")
if not all(field.default is None for field in class_fields[1:]):
raise ValueError(f"{self.__class__.__name__} should not have more than one required field.")
_lowerCAmelCase : Dict = getattr(self, class_fields[0].name)
_lowerCAmelCase : str = all(getattr(self, field.name) is None for field in class_fields[1:])
if other_fields_are_none and not is_tensor(__a):
if isinstance(__a, __a):
_lowerCAmelCase : Tuple = first_field.items()
_lowerCAmelCase : Dict = True
else:
try:
_lowerCAmelCase : Dict = iter(__a)
_lowerCAmelCase : Any = True
except TypeError:
_lowerCAmelCase : Any = False
# if we provided an iterator as first field and the iterator is a (key, value) iterator
# set the associated fields
if first_field_iterator:
for idx, element in enumerate(__a):
if (
not isinstance(__a, (list, tuple))
or not len(__a) == 2
or not isinstance(element[0], __a)
):
if idx == 0:
# If we do not have an iterator of key/values, set it as attribute
_lowerCAmelCase : Any = first_field
else:
# If we have a mixed iterator, raise an error
raise ValueError(
f"Cannot set key/value for {element}. It needs to be a tuple (key, value).")
break
setattr(self, element[0], element[1])
if element[1] is not None:
_lowerCAmelCase : Any = element[1]
elif first_field is not None:
_lowerCAmelCase : Any = first_field
else:
for field in class_fields:
_lowerCAmelCase : Dict = getattr(self, field.name)
if v is not None:
_lowerCAmelCase : Union[str, Any] = v
def __delitem__( self, *__a, **__a):
'''simple docstring'''
raise Exception(f"You cannot use ``__delitem__`` on a {self.__class__.__name__} instance.")
def snake_case__ ( self, *__a, **__a):
'''simple docstring'''
raise Exception(f"You cannot use ``setdefault`` on a {self.__class__.__name__} instance.")
def snake_case__ ( self, *__a, **__a):
'''simple docstring'''
raise Exception(f"You cannot use ``pop`` on a {self.__class__.__name__} instance.")
def snake_case__ ( self, *__a, **__a):
'''simple docstring'''
raise Exception(f"You cannot use ``update`` on a {self.__class__.__name__} instance.")
def __getitem__( self, __a):
'''simple docstring'''
if isinstance(__a, __a):
_lowerCAmelCase : Optional[int] = dict(self.items())
return inner_dict[k]
else:
return self.to_tuple()[k]
def __setattr__( self, __a, __a):
'''simple docstring'''
if name in self.keys() and value is not None:
# Don't call self.__setitem__ to avoid recursion errors
super().__setitem__(__a, __a)
super().__setattr__(__a, __a)
def __setitem__( self, __a, __a):
'''simple docstring'''
super().__setitem__(__a, __a)
# Don't call self.__setattr__ to avoid recursion errors
super().__setattr__(__a, __a)
def snake_case__ ( self):
'''simple docstring'''
return tuple(self[k] for k in self.keys())
class UpperCAmelCase_ ( a , a):
@classmethod
def snake_case__ ( cls, __a):
'''simple docstring'''
raise ValueError(
f"{value} is not a valid {cls.__name__}, please select one of {list(cls._valueamember_map_.keys())}")
class UpperCAmelCase_ ( a):
lowerCamelCase__ = 'longest'
lowerCamelCase__ = 'max_length'
lowerCamelCase__ = 'do_not_pad'
class UpperCAmelCase_ ( a):
lowerCamelCase__ = 'pt'
lowerCamelCase__ = 'tf'
lowerCamelCase__ = 'np'
lowerCamelCase__ = 'jax'
class UpperCAmelCase_ :
def __init__( self, __a):
'''simple docstring'''
_lowerCAmelCase : Tuple = context_managers
_lowerCAmelCase : Dict = ExitStack()
def __enter__( self):
'''simple docstring'''
for context_manager in self.context_managers:
self.stack.enter_context(__a)
def __exit__( self, *__a, **__a):
'''simple docstring'''
self.stack.__exit__(*__a, **__a)
def A ( _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : str = infer_framework(_lowerCamelCase )
if framework == "tf":
_lowerCAmelCase : Tuple = inspect.signature(model_class.call ) # TensorFlow models
elif framework == "pt":
_lowerCAmelCase : str = inspect.signature(model_class.forward ) # PyTorch models
else:
_lowerCAmelCase : Tuple = inspect.signature(model_class.__call__ ) # Flax models
for p in signature.parameters:
if p == "return_loss" and signature.parameters[p].default is True:
return True
return False
def A ( _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : str = model_class.__name__
_lowerCAmelCase : Optional[Any] = infer_framework(_lowerCamelCase )
if framework == "tf":
_lowerCAmelCase : Dict = inspect.signature(model_class.call ) # TensorFlow models
elif framework == "pt":
_lowerCAmelCase : List[Any] = inspect.signature(model_class.forward ) # PyTorch models
else:
_lowerCAmelCase : Dict = inspect.signature(model_class.__call__ ) # Flax models
if "QuestionAnswering" in model_name:
return [p for p in signature.parameters if "label" in p or p in ("start_positions", "end_positions")]
else:
return [p for p in signature.parameters if "label" in p]
def A ( _lowerCamelCase , _lowerCamelCase = "" , _lowerCamelCase = "." ):
'''simple docstring'''
def _flatten_dict(_lowerCamelCase , _lowerCamelCase="" , _lowerCamelCase="." ):
for k, v in d.items():
_lowerCAmelCase : Dict = str(_lowerCamelCase ) + delimiter + str(_lowerCamelCase ) if parent_key else k
if v and isinstance(_lowerCamelCase , _lowerCamelCase ):
yield from flatten_dict(_lowerCamelCase , _lowerCamelCase , delimiter=_lowerCamelCase ).items()
else:
yield key, v
return dict(_flatten_dict(_lowerCamelCase , _lowerCamelCase , _lowerCamelCase ) )
@contextmanager
def A ( _lowerCamelCase , _lowerCamelCase = False ):
'''simple docstring'''
if use_temp_dir:
with tempfile.TemporaryDirectory() as tmp_dir:
yield tmp_dir
else:
yield working_dir
def A ( _lowerCamelCase , _lowerCamelCase=None ):
'''simple docstring'''
if is_numpy_array(_lowerCamelCase ):
return np.transpose(_lowerCamelCase , axes=_lowerCamelCase )
elif is_torch_tensor(_lowerCamelCase ):
return array.T if axes is None else array.permute(*_lowerCamelCase )
elif is_tf_tensor(_lowerCamelCase ):
import tensorflow as tf
return tf.transpose(_lowerCamelCase , perm=_lowerCamelCase )
elif is_jax_tensor(_lowerCamelCase ):
return jnp.transpose(_lowerCamelCase , axes=_lowerCamelCase )
else:
raise ValueError(F"Type not supported for transpose: {type(_lowerCamelCase )}." )
def A ( _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
if is_numpy_array(_lowerCamelCase ):
return np.reshape(_lowerCamelCase , _lowerCamelCase )
elif is_torch_tensor(_lowerCamelCase ):
return array.reshape(*_lowerCamelCase )
elif is_tf_tensor(_lowerCamelCase ):
import tensorflow as tf
return tf.reshape(_lowerCamelCase , _lowerCamelCase )
elif is_jax_tensor(_lowerCamelCase ):
return jnp.reshape(_lowerCamelCase , _lowerCamelCase )
else:
raise ValueError(F"Type not supported for reshape: {type(_lowerCamelCase )}." )
def A ( _lowerCamelCase , _lowerCamelCase=None ):
'''simple docstring'''
if is_numpy_array(_lowerCamelCase ):
return np.squeeze(_lowerCamelCase , axis=_lowerCamelCase )
elif is_torch_tensor(_lowerCamelCase ):
return array.squeeze() if axis is None else array.squeeze(dim=_lowerCamelCase )
elif is_tf_tensor(_lowerCamelCase ):
import tensorflow as tf
return tf.squeeze(_lowerCamelCase , axis=_lowerCamelCase )
elif is_jax_tensor(_lowerCamelCase ):
return jnp.squeeze(_lowerCamelCase , axis=_lowerCamelCase )
else:
raise ValueError(F"Type not supported for squeeze: {type(_lowerCamelCase )}." )
def A ( _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
if is_numpy_array(_lowerCamelCase ):
return np.expand_dims(_lowerCamelCase , _lowerCamelCase )
elif is_torch_tensor(_lowerCamelCase ):
return array.unsqueeze(dim=_lowerCamelCase )
elif is_tf_tensor(_lowerCamelCase ):
import tensorflow as tf
return tf.expand_dims(_lowerCamelCase , axis=_lowerCamelCase )
elif is_jax_tensor(_lowerCamelCase ):
return jnp.expand_dims(_lowerCamelCase , axis=_lowerCamelCase )
else:
raise ValueError(F"Type not supported for expand_dims: {type(_lowerCamelCase )}." )
def A ( _lowerCamelCase ):
'''simple docstring'''
if is_numpy_array(_lowerCamelCase ):
return np.size(_lowerCamelCase )
elif is_torch_tensor(_lowerCamelCase ):
return array.numel()
elif is_tf_tensor(_lowerCamelCase ):
import tensorflow as tf
return tf.size(_lowerCamelCase )
elif is_jax_tensor(_lowerCamelCase ):
return array.size
else:
raise ValueError(F"Type not supported for expand_dims: {type(_lowerCamelCase )}." )
def A ( _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
for key, value in auto_map.items():
if isinstance(_lowerCamelCase , (tuple, list) ):
_lowerCAmelCase : List[Any] = [F"{repo_id}--{v}" if (v is not None and "--" not in v) else v for v in value]
elif value is not None and "--" not in value:
_lowerCAmelCase : Tuple = F"{repo_id}--{value}"
return auto_map
def A ( _lowerCamelCase ):
'''simple docstring'''
for base_class in inspect.getmro(_lowerCamelCase ):
_lowerCAmelCase : Tuple = base_class.__module__
_lowerCAmelCase : int = base_class.__name__
if module.startswith("tensorflow" ) or module.startswith("keras" ) or name == "TFPreTrainedModel":
return "tf"
elif module.startswith("torch" ) or name == "PreTrainedModel":
return "pt"
elif module.startswith("flax" ) or module.startswith("jax" ) or name == "FlaxPreTrainedModel":
return "flax"
else:
raise TypeError(F"Could not infer framework from class {model_class}." )
| 36
| 1
|
def A ( _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : Tuple = abs(_lowerCamelCase )
_lowerCAmelCase : Optional[int] = 0
while n > 0:
res += n % 10
n //= 10
return res
def A ( _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : Optional[Any] = abs(_lowerCamelCase )
return n if n < 10 else n % 10 + sum_of_digits(n // 10 )
def A ( _lowerCamelCase ):
'''simple docstring'''
return sum(int(_lowerCamelCase ) for c in str(abs(_lowerCamelCase ) ) )
def A ( ):
'''simple docstring'''
from collections.abc import Callable
from timeit import timeit
def benchmark_a_function(_lowerCamelCase , _lowerCamelCase ) -> None:
_lowerCAmelCase : Optional[Any] = F"{func.__name__}({value})"
_lowerCAmelCase : str = timeit(F"__main__.{call}" , setup="import __main__" )
print(F"{call:56} = {func(_lowerCamelCase )} -- {timing:.4f} seconds" )
for value in (262_144, 1_125_899_906_842_624, 1_267_650_600_228_229_401_496_703_205_376):
for func in (sum_of_digits, sum_of_digits_recursion, sum_of_digits_compact):
benchmark_a_function(_lowerCamelCase , _lowerCamelCase )
print()
if __name__ == "__main__":
import doctest
doctest.testmod()
benchmark()
| 36
|
import pytest
from datasets.utils.sharding import _distribute_shards, _number_of_shards_in_gen_kwargs, _split_gen_kwargs
@pytest.mark.parametrize(
"kwargs, expected" , [
({"num_shards": 0, "max_num_jobs": 1}, []),
({"num_shards": 10, "max_num_jobs": 1}, [range(10 )]),
({"num_shards": 10, "max_num_jobs": 10}, [range(_lowerCamelCase , i + 1 ) for i in range(10 )]),
({"num_shards": 1, "max_num_jobs": 10}, [range(1 )]),
({"num_shards": 10, "max_num_jobs": 3}, [range(0 , 4 ), range(4 , 7 ), range(7 , 10 )]),
({"num_shards": 3, "max_num_jobs": 10}, [range(0 , 1 ), range(1 , 2 ), range(2 , 3 )]),
] , )
def A ( _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : List[Any] = _distribute_shards(**_lowerCamelCase )
assert out == expected
@pytest.mark.parametrize(
"gen_kwargs, max_num_jobs, expected" , [
({"foo": 0}, 10, [{"foo": 0}]),
({"shards": [0, 1, 2, 3]}, 1, [{"shards": [0, 1, 2, 3]}]),
({"shards": [0, 1, 2, 3]}, 4, [{"shards": [0]}, {"shards": [1]}, {"shards": [2]}, {"shards": [3]}]),
({"shards": [0, 1]}, 4, [{"shards": [0]}, {"shards": [1]}]),
({"shards": [0, 1, 2, 3]}, 2, [{"shards": [0, 1]}, {"shards": [2, 3]}]),
] , )
def A ( _lowerCamelCase , _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : Optional[int] = _split_gen_kwargs(_lowerCamelCase , _lowerCamelCase )
assert out == expected
@pytest.mark.parametrize(
"gen_kwargs, expected" , [
({"foo": 0}, 1),
({"shards": [0]}, 1),
({"shards": [0, 1, 2, 3]}, 4),
({"shards": [0, 1, 2, 3], "foo": 0}, 4),
({"shards": [0, 1, 2, 3], "other": (0, 1)}, 4),
({"shards": [0, 1, 2, 3], "shards2": [0, 1]}, RuntimeError),
] , )
def A ( _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
if expected is RuntimeError:
with pytest.raises(_lowerCamelCase ):
_number_of_shards_in_gen_kwargs(_lowerCamelCase )
else:
_lowerCAmelCase : Optional[int] = _number_of_shards_in_gen_kwargs(_lowerCamelCase )
assert out == expected
| 36
| 1
|
from collections import defaultdict
def A ( _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : int = first_str.lower().strip()
_lowerCAmelCase : int = second_str.lower().strip()
# Remove whitespace
_lowerCAmelCase : str = first_str.replace(" " , "" )
_lowerCAmelCase : Optional[int] = second_str.replace(" " , "" )
# Strings of different lengths are not anagrams
if len(_lowerCamelCase ) != len(_lowerCamelCase ):
return False
# Default values for count should be 0
_lowerCAmelCase : defaultdict[str, int] = defaultdict(_lowerCamelCase )
# For each character in input strings,
# increment count in the corresponding
for i in range(len(_lowerCamelCase ) ):
count[first_str[i]] += 1
count[second_str[i]] -= 1
return all(_count == 0 for _count in count.values() )
if __name__ == "__main__":
from doctest import testmod
testmod()
_snake_case = input("Enter the first string ").strip()
_snake_case = input("Enter the second string ").strip()
_snake_case = check_anagrams(input_a, input_b)
print(f'''{input_a} and {input_b} are {"" if status else "not "}anagrams.''')
| 36
|
import os
from glob import glob
import imageio
import torch
import torchvision
import wandb
from img_processing import custom_to_pil, loop_post_process, preprocess, preprocess_vqgan
from loaders import load_vqgan
from PIL import Image
from torch import nn
from transformers import CLIPModel, CLIPTokenizerFast
from utils import get_device, get_timestamp, show_pil
class UpperCAmelCase_ :
def __init__( self, __a = "cpu", __a = "openai/clip-vit-large-patch14"):
'''simple docstring'''
_lowerCAmelCase : Optional[int] = device
_lowerCAmelCase : Optional[int] = CLIPTokenizerFast.from_pretrained(__a)
_lowerCAmelCase : Any = [0.48_145_466, 0.4_578_275, 0.40_821_073]
_lowerCAmelCase : Union[str, Any] = [0.26_862_954, 0.26_130_258, 0.27_577_711]
_lowerCAmelCase : Tuple = torchvision.transforms.Normalize(self.image_mean, self.image_std)
_lowerCAmelCase : Optional[int] = torchvision.transforms.Resize(224)
_lowerCAmelCase : Dict = torchvision.transforms.CenterCrop(224)
def snake_case__ ( self, __a):
'''simple docstring'''
_lowerCAmelCase : Optional[Any] = self.resize(__a)
_lowerCAmelCase : List[str] = self.center_crop(__a)
_lowerCAmelCase : Optional[Any] = self.normalize(__a)
return images
def __call__( self, __a=None, __a=None, **__a):
'''simple docstring'''
_lowerCAmelCase : str = self.tokenizer(text=__a, **__a)
_lowerCAmelCase : List[str] = self.preprocess_img(__a)
_lowerCAmelCase : Tuple = {key: value.to(self.device) for (key, value) in encoding.items()}
return encoding
class UpperCAmelCase_ ( nn.Module):
def __init__( self, __a=10, __a=0.01, __a=None, __a=None, __a=None, __a=None, __a=None, __a=None, __a=False, __a=True, __a="image", __a=True, __a=False, __a=False, __a=False, ):
'''simple docstring'''
super().__init__()
_lowerCAmelCase : List[str] = None
_lowerCAmelCase : List[str] = device if device else get_device()
if vqgan:
_lowerCAmelCase : Union[str, Any] = vqgan
else:
_lowerCAmelCase : Optional[Any] = load_vqgan(self.device, conf_path=__a, ckpt_path=__a)
self.vqgan.eval()
if clip:
_lowerCAmelCase : str = clip
else:
_lowerCAmelCase : int = CLIPModel.from_pretrained("openai/clip-vit-base-patch32")
self.clip.to(self.device)
_lowerCAmelCase : Optional[int] = ProcessorGradientFlow(device=self.device)
_lowerCAmelCase : Any = iterations
_lowerCAmelCase : List[Any] = lr
_lowerCAmelCase : Tuple = log
_lowerCAmelCase : List[str] = make_grid
_lowerCAmelCase : int = return_val
_lowerCAmelCase : Dict = quantize
_lowerCAmelCase : Any = self.vqgan.decoder.z_shape
def snake_case__ ( self, __a=None, __a=None, __a=5, __a=True):
'''simple docstring'''
_lowerCAmelCase : Union[str, Any] = []
if output_path is None:
_lowerCAmelCase : List[Any] = "./animation.gif"
if input_path is None:
_lowerCAmelCase : str = self.save_path
_lowerCAmelCase : str = sorted(glob(input_path + "/*"))
if not len(__a):
raise ValueError(
"No images found in save path, aborting (did you pass save_intermediate=True to the generate"
" function?)")
if len(__a) == 1:
print("Only one image found in save path, (did you pass save_intermediate=True to the generate function?)")
_lowerCAmelCase : Optional[int] = total_duration / len(__a)
_lowerCAmelCase : Union[str, Any] = [frame_duration] * len(__a)
if extend_frames:
_lowerCAmelCase : Any = 1.5
_lowerCAmelCase : List[str] = 3
for file_name in paths:
if file_name.endswith(".png"):
images.append(imageio.imread(__a))
imageio.mimsave(__a, __a, duration=__a)
print(f"gif saved to {output_path}")
def snake_case__ ( self, __a=None, __a=None):
'''simple docstring'''
if not (path or img):
raise ValueError("Input either path or tensor")
if img is not None:
raise NotImplementedError
_lowerCAmelCase : Dict = preprocess(Image.open(__a), target_image_size=256).to(self.device)
_lowerCAmelCase : Dict = preprocess_vqgan(__a)
_lowerCAmelCase , *_lowerCAmelCase : str = self.vqgan.encode(__a)
return z
def snake_case__ ( self, __a):
'''simple docstring'''
_lowerCAmelCase : Optional[Any] = self.latent.detach().requires_grad_()
_lowerCAmelCase : Dict = base_latent + transform_vector
if self.quantize:
_lowerCAmelCase , *_lowerCAmelCase : List[Any] = self.vqgan.quantize(__a)
else:
_lowerCAmelCase : Any = trans_latent
return self.vqgan.decode(__a)
def snake_case__ ( self, __a, __a, __a=None):
'''simple docstring'''
_lowerCAmelCase : int = self.clip_preprocessor(text=__a, images=__a, return_tensors="pt", padding=__a)
_lowerCAmelCase : Optional[int] = self.clip(**__a)
_lowerCAmelCase : Any = clip_outputs.logits_per_image
if weights is not None:
_lowerCAmelCase : Tuple = similarity_logits * weights
return similarity_logits.sum()
def snake_case__ ( self, __a, __a, __a):
'''simple docstring'''
_lowerCAmelCase : List[Any] = self._get_clip_similarity(pos_prompts["prompts"], __a, weights=(1 / pos_prompts["weights"]))
if neg_prompts:
_lowerCAmelCase : List[Any] = self._get_clip_similarity(neg_prompts["prompts"], __a, weights=neg_prompts["weights"])
else:
_lowerCAmelCase : Union[str, Any] = torch.tensor([1], device=self.device)
_lowerCAmelCase : List[str] = -torch.log(__a) + torch.log(__a)
return loss
def snake_case__ ( self, __a, __a, __a):
'''simple docstring'''
_lowerCAmelCase : Optional[Any] = torch.randn_like(self.latent, requires_grad=__a, device=self.device)
_lowerCAmelCase : Optional[int] = torch.optim.Adam([vector], lr=self.lr)
for i in range(self.iterations):
optim.zero_grad()
_lowerCAmelCase : Any = self._add_vector(__a)
_lowerCAmelCase : Optional[Any] = loop_post_process(__a)
_lowerCAmelCase : Optional[Any] = self._get_CLIP_loss(__a, __a, __a)
print("CLIP loss", __a)
if self.log:
wandb.log({"CLIP Loss": clip_loss})
clip_loss.backward(retain_graph=__a)
optim.step()
if self.return_val == "image":
yield custom_to_pil(transformed_img[0])
else:
yield vector
def snake_case__ ( self, __a, __a, __a):
'''simple docstring'''
wandb.init(reinit=__a, project="face-editor")
wandb.config.update({"Positive Prompts": positive_prompts})
wandb.config.update({"Negative Prompts": negative_prompts})
wandb.config.update({"lr": self.lr, "iterations": self.iterations})
if image_path:
_lowerCAmelCase : str = Image.open(__a)
_lowerCAmelCase : int = image.resize((256, 256))
wandb.log("Original Image", wandb.Image(__a))
def snake_case__ ( self, __a):
'''simple docstring'''
if not prompts:
return []
_lowerCAmelCase : int = []
_lowerCAmelCase : List[str] = []
if isinstance(__a, __a):
_lowerCAmelCase : Union[str, Any] = [prompt.strip() for prompt in prompts.split("|")]
for prompt in prompts:
if isinstance(__a, (tuple, list)):
_lowerCAmelCase : Optional[Any] = prompt[0]
_lowerCAmelCase : Union[str, Any] = float(prompt[1])
elif ":" in prompt:
_lowerCAmelCase , _lowerCAmelCase : int = prompt.split(":")
_lowerCAmelCase : Optional[Any] = float(__a)
else:
_lowerCAmelCase : Optional[int] = prompt
_lowerCAmelCase : List[Any] = 1.0
processed_prompts.append(__a)
weights.append(__a)
return {
"prompts": processed_prompts,
"weights": torch.tensor(__a, device=self.device),
}
def snake_case__ ( self, __a, __a=None, __a=None, __a=True, __a=False, __a=True, __a=True, __a=None, ):
'''simple docstring'''
if image_path:
_lowerCAmelCase : List[Any] = self._get_latent(__a)
else:
_lowerCAmelCase : Any = torch.randn(self.latent_dim, device=self.device)
if self.log:
self._init_logging(__a, __a, __a)
assert pos_prompts, "You must provide at least one positive prompt."
_lowerCAmelCase : int = self.process_prompts(__a)
_lowerCAmelCase : List[str] = self.process_prompts(__a)
if save_final and save_path is None:
_lowerCAmelCase : int = os.path.join("./outputs/", "_".join(pos_prompts["prompts"]))
if not os.path.exists(__a):
os.makedirs(__a)
else:
_lowerCAmelCase : Tuple = save_path + "_" + get_timestamp()
os.makedirs(__a)
_lowerCAmelCase : Tuple = save_path
_lowerCAmelCase : List[Any] = self.vqgan.decode(self.latent)[0]
if show_intermediate:
print("Original Image")
show_pil(custom_to_pil(__a))
_lowerCAmelCase : int = loop_post_process(__a)
for iter, transformed_img in enumerate(self._optimize_CLIP(__a, __a, __a)):
if show_intermediate:
show_pil(__a)
if save_intermediate:
transformed_img.save(os.path.join(self.save_path, f"iter_{iter:03d}.png"))
if self.log:
wandb.log({"Image": wandb.Image(__a)})
if show_final:
show_pil(__a)
if save_final:
transformed_img.save(os.path.join(self.save_path, f"iter_{iter:03d}_final.png"))
| 36
| 1
|
import copy
from collections import OrderedDict
from typing import Mapping
from packaging import version
from ...configuration_utils import PretrainedConfig
from ...onnx import OnnxConfig
from ...utils import logging
from ..auto import CONFIG_MAPPING
_snake_case = logging.get_logger(__name__)
_snake_case = {
"microsoft/conditional-detr-resnet-50": (
"https://huggingface.co/microsoft/conditional-detr-resnet-50/resolve/main/config.json"
),
}
class UpperCAmelCase_ ( a):
lowerCamelCase__ = 'conditional_detr'
lowerCamelCase__ = ['past_key_values']
lowerCamelCase__ = {
'hidden_size': 'd_model',
'num_attention_heads': 'encoder_attention_heads',
}
def __init__( self, __a=True, __a=None, __a=3, __a=300, __a=6, __a=2048, __a=8, __a=6, __a=2048, __a=8, __a=0.0, __a=0.0, __a=True, __a="relu", __a=256, __a=0.1, __a=0.0, __a=0.0, __a=0.02, __a=1.0, __a=False, __a="sine", __a="resnet50", __a=True, __a=False, __a=2, __a=5, __a=2, __a=1, __a=1, __a=2, __a=5, __a=2, __a=0.25, **__a, ):
'''simple docstring'''
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.")
_lowerCAmelCase : str = CONFIG_MAPPING["resnet"](out_features=["stage4"])
elif isinstance(__a, __a):
_lowerCAmelCase : Union[str, Any] = backbone_config.get("model_type")
_lowerCAmelCase : Optional[Any] = CONFIG_MAPPING[backbone_model_type]
_lowerCAmelCase : Dict = config_class.from_dict(__a)
_lowerCAmelCase : Dict = use_timm_backbone
_lowerCAmelCase : Optional[int] = backbone_config
_lowerCAmelCase : Union[str, Any] = num_channels
_lowerCAmelCase : int = num_queries
_lowerCAmelCase : Tuple = d_model
_lowerCAmelCase : Dict = encoder_ffn_dim
_lowerCAmelCase : Any = encoder_layers
_lowerCAmelCase : int = encoder_attention_heads
_lowerCAmelCase : str = decoder_ffn_dim
_lowerCAmelCase : Tuple = decoder_layers
_lowerCAmelCase : Optional[Any] = decoder_attention_heads
_lowerCAmelCase : Tuple = dropout
_lowerCAmelCase : Any = attention_dropout
_lowerCAmelCase : List[str] = activation_dropout
_lowerCAmelCase : Dict = activation_function
_lowerCAmelCase : Union[str, Any] = init_std
_lowerCAmelCase : str = init_xavier_std
_lowerCAmelCase : Optional[Any] = encoder_layerdrop
_lowerCAmelCase : List[str] = decoder_layerdrop
_lowerCAmelCase : Dict = encoder_layers
_lowerCAmelCase : List[str] = auxiliary_loss
_lowerCAmelCase : List[Any] = position_embedding_type
_lowerCAmelCase : Union[str, Any] = backbone
_lowerCAmelCase : Optional[Any] = use_pretrained_backbone
_lowerCAmelCase : int = dilation
# Hungarian matcher
_lowerCAmelCase : Dict = class_cost
_lowerCAmelCase : str = bbox_cost
_lowerCAmelCase : List[Any] = giou_cost
# Loss coefficients
_lowerCAmelCase : Optional[int] = mask_loss_coefficient
_lowerCAmelCase : Optional[int] = dice_loss_coefficient
_lowerCAmelCase : Tuple = cls_loss_coefficient
_lowerCAmelCase : Dict = bbox_loss_coefficient
_lowerCAmelCase : List[Any] = giou_loss_coefficient
_lowerCAmelCase : Union[str, Any] = focal_alpha
super().__init__(is_encoder_decoder=__a, **__a)
@property
def snake_case__ ( self):
'''simple docstring'''
return self.encoder_attention_heads
@property
def snake_case__ ( self):
'''simple docstring'''
return self.d_model
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Dict = copy.deepcopy(self.__dict__)
if self.backbone_config is not None:
_lowerCAmelCase : List[str] = self.backbone_config.to_dict()
_lowerCAmelCase : int = self.__class__.model_type
return output
class UpperCAmelCase_ ( a):
lowerCamelCase__ = version.parse('1.11')
@property
def snake_case__ ( self):
'''simple docstring'''
return OrderedDict(
[
("pixel_values", {0: "batch", 1: "num_channels", 2: "height", 3: "width"}),
("pixel_mask", {0: "batch"}),
])
@property
def snake_case__ ( self):
'''simple docstring'''
return 1E-5
@property
def snake_case__ ( self):
'''simple docstring'''
return 12
| 36
|
import sys
import tempfile
import unittest
import unittest.mock as mock
from pathlib import Path
from huggingface_hub import HfFolder, delete_repo
from requests.exceptions import HTTPError
from transformers import AutoImageProcessor, ViTImageProcessor
from transformers.testing_utils import TOKEN, USER, get_tests_dir, is_staging_test
sys.path.append(str(Path(__file__).parent.parent / "utils"))
from test_module.custom_image_processing import CustomImageProcessor # noqa E402
_snake_case = get_tests_dir("fixtures")
class UpperCAmelCase_ ( unittest.TestCase):
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Optional[Any] = mock.Mock()
_lowerCAmelCase : int = 500
_lowerCAmelCase : Tuple = {}
_lowerCAmelCase : str = HTTPError
_lowerCAmelCase : Union[str, Any] = {}
# Download this model to make sure it's in the cache.
_lowerCAmelCase : Tuple = ViTImageProcessor.from_pretrained("hf-internal-testing/tiny-random-vit")
# Under the mock environment we get a 500 error when trying to reach the model.
with mock.patch("requests.Session.request", return_value=__a) as mock_head:
_lowerCAmelCase : Optional[int] = ViTImageProcessor.from_pretrained("hf-internal-testing/tiny-random-vit")
# This check we did call the fake head request
mock_head.assert_called()
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Tuple = ViTImageProcessor.from_pretrained(
"https://huggingface.co/hf-internal-testing/tiny-random-vit/resolve/main/preprocessor_config.json")
def snake_case__ ( self):
'''simple docstring'''
with self.assertRaises(__a):
# config is in subfolder, the following should not work without specifying the subfolder
_lowerCAmelCase : int = AutoImageProcessor.from_pretrained("hf-internal-testing/stable-diffusion-all-variants")
_lowerCAmelCase : Optional[Any] = AutoImageProcessor.from_pretrained(
"hf-internal-testing/stable-diffusion-all-variants", subfolder="feature_extractor")
self.assertIsNotNone(__a)
@is_staging_test
class UpperCAmelCase_ ( unittest.TestCase):
@classmethod
def snake_case__ ( cls):
'''simple docstring'''
_lowerCAmelCase : Union[str, Any] = TOKEN
HfFolder.save_token(__a)
@classmethod
def snake_case__ ( cls):
'''simple docstring'''
try:
delete_repo(token=cls._token, repo_id="test-image-processor")
except HTTPError:
pass
try:
delete_repo(token=cls._token, repo_id="valid_org/test-image-processor-org")
except HTTPError:
pass
try:
delete_repo(token=cls._token, repo_id="test-dynamic-image-processor")
except HTTPError:
pass
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Optional[int] = ViTImageProcessor.from_pretrained(__a)
image_processor.push_to_hub("test-image-processor", use_auth_token=self._token)
_lowerCAmelCase : str = ViTImageProcessor.from_pretrained(f"{USER}/test-image-processor")
for k, v in image_processor.__dict__.items():
self.assertEqual(__a, getattr(__a, __a))
# Reset repo
delete_repo(token=self._token, repo_id="test-image-processor")
# Push to hub via save_pretrained
with tempfile.TemporaryDirectory() as tmp_dir:
image_processor.save_pretrained(
__a, repo_id="test-image-processor", push_to_hub=__a, use_auth_token=self._token)
_lowerCAmelCase : Optional[int] = ViTImageProcessor.from_pretrained(f"{USER}/test-image-processor")
for k, v in image_processor.__dict__.items():
self.assertEqual(__a, getattr(__a, __a))
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Any = ViTImageProcessor.from_pretrained(__a)
image_processor.push_to_hub("valid_org/test-image-processor", use_auth_token=self._token)
_lowerCAmelCase : Tuple = ViTImageProcessor.from_pretrained("valid_org/test-image-processor")
for k, v in image_processor.__dict__.items():
self.assertEqual(__a, getattr(__a, __a))
# Reset repo
delete_repo(token=self._token, repo_id="valid_org/test-image-processor")
# Push to hub via save_pretrained
with tempfile.TemporaryDirectory() as tmp_dir:
image_processor.save_pretrained(
__a, repo_id="valid_org/test-image-processor-org", push_to_hub=__a, use_auth_token=self._token)
_lowerCAmelCase : Optional[int] = ViTImageProcessor.from_pretrained("valid_org/test-image-processor-org")
for k, v in image_processor.__dict__.items():
self.assertEqual(__a, getattr(__a, __a))
def snake_case__ ( self):
'''simple docstring'''
CustomImageProcessor.register_for_auto_class()
_lowerCAmelCase : List[str] = CustomImageProcessor.from_pretrained(__a)
image_processor.push_to_hub("test-dynamic-image-processor", use_auth_token=self._token)
# This has added the proper auto_map field to the config
self.assertDictEqual(
image_processor.auto_map, {"AutoImageProcessor": "custom_image_processing.CustomImageProcessor"}, )
_lowerCAmelCase : Tuple = AutoImageProcessor.from_pretrained(
f"{USER}/test-dynamic-image-processor", trust_remote_code=__a)
# Can't make an isinstance check because the new_image_processor is from the CustomImageProcessor class of a dynamic module
self.assertEqual(new_image_processor.__class__.__name__, "CustomImageProcessor")
| 36
| 1
|
from __future__ import annotations
from scipy.special import comb # type: ignore
class UpperCAmelCase_ :
def __init__( self, __a):
'''simple docstring'''
_lowerCAmelCase : Optional[int] = list_of_points
# Degree determines the flexibility of the curve.
# Degree = 1 will produce a straight line.
_lowerCAmelCase : Optional[Any] = len(__a) - 1
def snake_case__ ( self, __a):
'''simple docstring'''
assert 0 <= t <= 1, "Time t must be between 0 and 1."
_lowerCAmelCase : list[float] = []
for i in range(len(self.list_of_points)):
# basis function for each i
output_values.append(
comb(self.degree, __a) * ((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(__a), 5) == 1
return output_values
def snake_case__ ( self, __a):
'''simple docstring'''
assert 0 <= t <= 1, "Time t must be between 0 and 1."
_lowerCAmelCase : Tuple = self.basis_function(__a)
_lowerCAmelCase : Any = 0.0
_lowerCAmelCase : Optional[int] = 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 snake_case__ ( self, __a = 0.01):
'''simple docstring'''
from matplotlib import pyplot as plt # type: ignore
_lowerCAmelCase : list[float] = [] # x coordinates of points to plot
_lowerCAmelCase : list[float] = [] # y coordinates of points to plot
_lowerCAmelCase : List[str] = 0.0
while t <= 1:
_lowerCAmelCase : int = self.bezier_curve_function(__a)
to_plot_x.append(value[0])
to_plot_y.append(value[1])
t += step_size
_lowerCAmelCase : List[Any] = [i[0] for i in self.list_of_points]
_lowerCAmelCase : Union[str, Any] = [i[1] for i in self.list_of_points]
plt.plot(
__a, __a, color="blue", label="Curve of Degree " + str(self.degree), )
plt.scatter(__a, __a, 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
| 36
|
import unittest
from transformers import LiltConfig, is_torch_available
from transformers.testing_utils import require_torch, slow, torch_device
from ...generation.test_utils import GenerationTesterMixin
from ...test_configuration_common import ConfigTester
from ...test_modeling_common import ModelTesterMixin, ids_tensor
from ...test_pipeline_mixin import PipelineTesterMixin
if is_torch_available():
import torch
from transformers import (
LiltForQuestionAnswering,
LiltForSequenceClassification,
LiltForTokenClassification,
LiltModel,
)
from transformers.models.lilt.modeling_lilt import LILT_PRETRAINED_MODEL_ARCHIVE_LIST
class UpperCAmelCase_ :
def __init__( self, __a, __a=13, __a=7, __a=True, __a=True, __a=True, __a=True, __a=99, __a=24, __a=2, __a=6, __a=37, __a="gelu", __a=0.1, __a=0.1, __a=512, __a=16, __a=2, __a=0.02, __a=3, __a=None, __a=1000, ):
'''simple docstring'''
_lowerCAmelCase : Tuple = parent
_lowerCAmelCase : List[str] = batch_size
_lowerCAmelCase : int = seq_length
_lowerCAmelCase : Optional[int] = is_training
_lowerCAmelCase : Dict = use_input_mask
_lowerCAmelCase : List[str] = use_token_type_ids
_lowerCAmelCase : str = use_labels
_lowerCAmelCase : Optional[Any] = vocab_size
_lowerCAmelCase : Tuple = hidden_size
_lowerCAmelCase : List[Any] = num_hidden_layers
_lowerCAmelCase : Optional[Any] = num_attention_heads
_lowerCAmelCase : Any = intermediate_size
_lowerCAmelCase : List[str] = hidden_act
_lowerCAmelCase : Union[str, Any] = hidden_dropout_prob
_lowerCAmelCase : Any = attention_probs_dropout_prob
_lowerCAmelCase : int = max_position_embeddings
_lowerCAmelCase : Optional[int] = type_vocab_size
_lowerCAmelCase : Optional[Any] = type_sequence_label_size
_lowerCAmelCase : List[str] = initializer_range
_lowerCAmelCase : List[Any] = num_labels
_lowerCAmelCase : Tuple = scope
_lowerCAmelCase : str = range_bbox
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Dict = ids_tensor([self.batch_size, self.seq_length], self.vocab_size)
_lowerCAmelCase : int = ids_tensor([self.batch_size, self.seq_length, 4], self.range_bbox)
# Ensure that bbox is legal
for i in range(bbox.shape[0]):
for j in range(bbox.shape[1]):
if bbox[i, j, 3] < bbox[i, j, 1]:
_lowerCAmelCase : Dict = bbox[i, j, 3]
_lowerCAmelCase : int = bbox[i, j, 1]
_lowerCAmelCase : Tuple = t
if bbox[i, j, 2] < bbox[i, j, 0]:
_lowerCAmelCase : str = bbox[i, j, 2]
_lowerCAmelCase : List[Any] = bbox[i, j, 0]
_lowerCAmelCase : str = t
_lowerCAmelCase : Optional[Any] = None
if self.use_input_mask:
_lowerCAmelCase : Union[str, Any] = ids_tensor([self.batch_size, self.seq_length], vocab_size=2)
_lowerCAmelCase : Dict = None
if self.use_token_type_ids:
_lowerCAmelCase : Any = ids_tensor([self.batch_size, self.seq_length], self.type_vocab_size)
_lowerCAmelCase : Optional[int] = None
_lowerCAmelCase : Optional[Any] = None
if self.use_labels:
_lowerCAmelCase : Optional[Any] = ids_tensor([self.batch_size], self.type_sequence_label_size)
_lowerCAmelCase : Any = ids_tensor([self.batch_size, self.seq_length], self.num_labels)
_lowerCAmelCase : Optional[int] = self.get_config()
return config, input_ids, bbox, token_type_ids, input_mask, sequence_labels, token_labels
def snake_case__ ( self):
'''simple docstring'''
return LiltConfig(
vocab_size=self.vocab_size, hidden_size=self.hidden_size, num_hidden_layers=self.num_hidden_layers, num_attention_heads=self.num_attention_heads, intermediate_size=self.intermediate_size, hidden_act=self.hidden_act, hidden_dropout_prob=self.hidden_dropout_prob, attention_probs_dropout_prob=self.attention_probs_dropout_prob, max_position_embeddings=self.max_position_embeddings, type_vocab_size=self.type_vocab_size, initializer_range=self.initializer_range, )
def snake_case__ ( self, __a, __a, __a, __a, __a, __a, __a, ):
'''simple docstring'''
_lowerCAmelCase : Union[str, Any] = LiltModel(config=__a)
model.to(__a)
model.eval()
_lowerCAmelCase : Dict = model(__a, bbox=__a, attention_mask=__a, token_type_ids=__a)
_lowerCAmelCase : str = model(__a, bbox=__a, token_type_ids=__a)
_lowerCAmelCase : List[Any] = model(__a, bbox=__a)
self.parent.assertEqual(result.last_hidden_state.shape, (self.batch_size, self.seq_length, self.hidden_size))
self.parent.assertEqual(result.pooler_output.shape, (self.batch_size, self.hidden_size))
def snake_case__ ( self, __a, __a, __a, __a, __a, __a, __a, ):
'''simple docstring'''
_lowerCAmelCase : List[Any] = self.num_labels
_lowerCAmelCase : Optional[Any] = LiltForTokenClassification(config=__a)
model.to(__a)
model.eval()
_lowerCAmelCase : Dict = model(
__a, bbox=__a, attention_mask=__a, token_type_ids=__a, labels=__a)
self.parent.assertEqual(result.logits.shape, (self.batch_size, self.seq_length, self.num_labels))
def snake_case__ ( self, __a, __a, __a, __a, __a, __a, __a, ):
'''simple docstring'''
_lowerCAmelCase : Optional[int] = LiltForQuestionAnswering(config=__a)
model.to(__a)
model.eval()
_lowerCAmelCase : Tuple = model(
__a, bbox=__a, attention_mask=__a, token_type_ids=__a, start_positions=__a, end_positions=__a, )
self.parent.assertEqual(result.start_logits.shape, (self.batch_size, self.seq_length))
self.parent.assertEqual(result.end_logits.shape, (self.batch_size, self.seq_length))
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Optional[Any] = self.prepare_config_and_inputs()
(
(
_lowerCAmelCase
) , (
_lowerCAmelCase
) , (
_lowerCAmelCase
) , (
_lowerCAmelCase
) , (
_lowerCAmelCase
) , (
_lowerCAmelCase
) , (
_lowerCAmelCase
) ,
) : Dict = config_and_inputs
_lowerCAmelCase : List[Any] = {
"input_ids": input_ids,
"bbox": bbox,
"token_type_ids": token_type_ids,
"attention_mask": input_mask,
}
return config, inputs_dict
@require_torch
class UpperCAmelCase_ ( a , a , a , unittest.TestCase):
lowerCamelCase__ = (
(
LiltModel,
LiltForSequenceClassification,
LiltForTokenClassification,
LiltForQuestionAnswering,
)
if is_torch_available()
else ()
)
lowerCamelCase__ = (
{
'feature-extraction': LiltModel,
'question-answering': LiltForQuestionAnswering,
'text-classification': LiltForSequenceClassification,
'token-classification': LiltForTokenClassification,
'zero-shot': LiltForSequenceClassification,
}
if is_torch_available()
else {}
)
lowerCamelCase__ = False
lowerCamelCase__ = False
def snake_case__ ( self, __a, __a, __a, __a, __a):
'''simple docstring'''
return True
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Optional[Any] = LiltModelTester(self)
_lowerCAmelCase : Union[str, Any] = ConfigTester(self, config_class=__a, hidden_size=37)
def snake_case__ ( self):
'''simple docstring'''
self.config_tester.run_common_tests()
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Dict = self.model_tester.prepare_config_and_inputs()
self.model_tester.create_and_check_model(*__a)
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : int = self.model_tester.prepare_config_and_inputs()
for type in ["absolute", "relative_key", "relative_key_query"]:
_lowerCAmelCase : Any = type
self.model_tester.create_and_check_model(*__a)
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : int = self.model_tester.prepare_config_and_inputs()
self.model_tester.create_and_check_for_token_classification(*__a)
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Optional[int] = self.model_tester.prepare_config_and_inputs()
self.model_tester.create_and_check_for_question_answering(*__a)
@slow
def snake_case__ ( self):
'''simple docstring'''
for model_name in LILT_PRETRAINED_MODEL_ARCHIVE_LIST[:1]:
_lowerCAmelCase : str = LiltModel.from_pretrained(__a)
self.assertIsNotNone(__a)
@require_torch
@slow
class UpperCAmelCase_ ( unittest.TestCase):
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Dict = LiltModel.from_pretrained("SCUT-DLVCLab/lilt-roberta-en-base").to(__a)
_lowerCAmelCase : Any = torch.tensor([[1, 2]], device=__a)
_lowerCAmelCase : str = torch.tensor([[[1, 2, 3, 4], [5, 6, 7, 8]]], device=__a)
# forward pass
with torch.no_grad():
_lowerCAmelCase : Optional[Any] = model(input_ids=__a, bbox=__a)
_lowerCAmelCase : Optional[int] = torch.Size([1, 2, 768])
_lowerCAmelCase : List[str] = torch.tensor(
[[-0.0_653, 0.0_950, -0.0_061], [-0.0_545, 0.0_926, -0.0_324]], device=__a, )
self.assertTrue(outputs.last_hidden_state.shape, __a)
self.assertTrue(torch.allclose(outputs.last_hidden_state[0, :, :3], __a, atol=1E-3))
| 36
| 1
|
from ...processing_utils import ProcessorMixin
class UpperCAmelCase_ ( a):
lowerCamelCase__ = 'SpeechT5FeatureExtractor'
lowerCamelCase__ = 'SpeechT5Tokenizer'
def __init__( self, __a, __a):
'''simple docstring'''
super().__init__(__a, __a)
def __call__( self, *__a, **__a):
'''simple docstring'''
_lowerCAmelCase : Union[str, Any] = kwargs.pop("audio", __a)
_lowerCAmelCase : Dict = kwargs.pop("text", __a)
_lowerCAmelCase : Dict = kwargs.pop("text_target", __a)
_lowerCAmelCase : Union[str, Any] = kwargs.pop("audio_target", __a)
_lowerCAmelCase : Any = kwargs.pop("sampling_rate", __a)
if audio is not None and text is not None:
raise ValueError(
"Cannot process both `audio` and `text` inputs. Did you mean `audio_target` or `text_target`?")
if audio_target is not None and text_target is not None:
raise ValueError(
"Cannot process both `audio_target` and `text_target` inputs. Did you mean `audio` or `text`?")
if audio is None and audio_target is None and text is None and text_target is None:
raise ValueError(
"You need to specify either an `audio`, `audio_target`, `text`, or `text_target` input to process.")
if audio is not None:
_lowerCAmelCase : Tuple = self.feature_extractor(__a, *__a, sampling_rate=__a, **__a)
elif text is not None:
_lowerCAmelCase : List[Any] = self.tokenizer(__a, **__a)
else:
_lowerCAmelCase : Dict = None
if audio_target is not None:
_lowerCAmelCase : Union[str, Any] = self.feature_extractor(audio_target=__a, *__a, sampling_rate=__a, **__a)
_lowerCAmelCase : Optional[int] = targets["input_values"]
elif text_target is not None:
_lowerCAmelCase : List[Any] = self.tokenizer(__a, **__a)
_lowerCAmelCase : Union[str, Any] = targets["input_ids"]
else:
_lowerCAmelCase : Union[str, Any] = None
if inputs is None:
return targets
if targets is not None:
_lowerCAmelCase : Any = labels
_lowerCAmelCase : List[Any] = targets.get("attention_mask")
if decoder_attention_mask is not None:
_lowerCAmelCase : Tuple = decoder_attention_mask
return inputs
def snake_case__ ( self, *__a, **__a):
'''simple docstring'''
_lowerCAmelCase : List[str] = kwargs.pop("input_values", __a)
_lowerCAmelCase : int = kwargs.pop("input_ids", __a)
_lowerCAmelCase : List[Any] = kwargs.pop("labels", __a)
if input_values is not None and input_ids is not None:
raise ValueError("Cannot process both `input_values` and `input_ids` inputs.")
if input_values is None and input_ids is None and labels is None:
raise ValueError(
"You need to specify either an `input_values`, `input_ids`, or `labels` input to be padded.")
if input_values is not None:
_lowerCAmelCase : List[str] = self.feature_extractor.pad(__a, *__a, **__a)
elif input_ids is not None:
_lowerCAmelCase : Optional[Any] = self.tokenizer.pad(__a, **__a)
else:
_lowerCAmelCase : List[Any] = None
if labels is not None:
if "input_ids" in labels or (isinstance(__a, __a) and "input_ids" in labels[0]):
_lowerCAmelCase : str = self.tokenizer.pad(__a, **__a)
_lowerCAmelCase : str = targets["input_ids"]
else:
_lowerCAmelCase : Union[str, Any] = self.feature_extractor.feature_size
_lowerCAmelCase : str = self.feature_extractor.num_mel_bins
_lowerCAmelCase : str = self.feature_extractor.pad(__a, *__a, **__a)
_lowerCAmelCase : List[Any] = feature_size_hack
_lowerCAmelCase : str = targets["input_values"]
else:
_lowerCAmelCase : Optional[Any] = None
if inputs is None:
return targets
if targets is not None:
_lowerCAmelCase : str = labels
_lowerCAmelCase : List[str] = targets.get("attention_mask")
if decoder_attention_mask is not None:
_lowerCAmelCase : Any = decoder_attention_mask
return inputs
def snake_case__ ( self, *__a, **__a):
'''simple docstring'''
return self.tokenizer.batch_decode(*__a, **__a)
def snake_case__ ( self, *__a, **__a):
'''simple docstring'''
return self.tokenizer.decode(*__a, **__a)
| 36
|
import argparse
import copy
def A ( _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : int = {}
with open(_lowerCamelCase ) as f:
for line in f:
if line.split()[0] not in dict_of_neighbours:
_lowerCAmelCase : Tuple = []
_list.append([line.split()[1], line.split()[2]] )
_lowerCAmelCase : Any = _list
else:
dict_of_neighbours[line.split()[0]].append(
[line.split()[1], line.split()[2]] )
if line.split()[1] not in dict_of_neighbours:
_lowerCAmelCase : str = []
_list.append([line.split()[0], line.split()[2]] )
_lowerCAmelCase : Any = _list
else:
dict_of_neighbours[line.split()[1]].append(
[line.split()[0], line.split()[2]] )
return dict_of_neighbours
def A ( _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
with open(_lowerCamelCase ) as f:
_lowerCAmelCase : str = f.read(1 )
_lowerCAmelCase : str = start_node
_lowerCAmelCase : List[str] = []
_lowerCAmelCase : Any = start_node
_lowerCAmelCase : str = 0
while visiting not in first_solution:
_lowerCAmelCase : Dict = 10_000
for k in dict_of_neighbours[visiting]:
if int(k[1] ) < int(_lowerCamelCase ) and k[0] not in first_solution:
_lowerCAmelCase : List[str] = k[1]
_lowerCAmelCase : List[Any] = k[0]
first_solution.append(_lowerCamelCase )
_lowerCAmelCase : Optional[int] = distance_of_first_solution + int(_lowerCamelCase )
_lowerCAmelCase : str = best_node
first_solution.append(_lowerCamelCase )
_lowerCAmelCase : Union[str, Any] = 0
for k in dict_of_neighbours[first_solution[-2]]:
if k[0] == start_node:
break
position += 1
_lowerCAmelCase : Tuple = (
distance_of_first_solution
+ int(dict_of_neighbours[first_solution[-2]][position][1] )
- 10_000
)
return first_solution, distance_of_first_solution
def A ( _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : Tuple = []
for n in solution[1:-1]:
_lowerCAmelCase : Dict = solution.index(_lowerCamelCase )
for kn in solution[1:-1]:
_lowerCAmelCase : Dict = solution.index(_lowerCamelCase )
if n == kn:
continue
_lowerCAmelCase : Optional[int] = copy.deepcopy(_lowerCamelCase )
_lowerCAmelCase : int = kn
_lowerCAmelCase : Dict = n
_lowerCAmelCase : Optional[int] = 0
for k in _tmp[:-1]:
_lowerCAmelCase : str = _tmp[_tmp.index(_lowerCamelCase ) + 1]
for i in dict_of_neighbours[k]:
if i[0] == next_node:
_lowerCAmelCase : Optional[Any] = distance + int(i[1] )
_tmp.append(_lowerCamelCase )
if _tmp not in neighborhood_of_solution:
neighborhood_of_solution.append(_tmp )
_lowerCAmelCase : List[Any] = len(neighborhood_of_solution[0] ) - 1
neighborhood_of_solution.sort(key=lambda _lowerCamelCase : x[index_of_last_item_in_the_list] )
return neighborhood_of_solution
def A ( _lowerCamelCase , _lowerCamelCase , _lowerCamelCase , _lowerCamelCase , _lowerCamelCase ):
'''simple docstring'''
_lowerCAmelCase : List[str] = 1
_lowerCAmelCase : int = first_solution
_lowerCAmelCase : Tuple = []
_lowerCAmelCase : Tuple = distance_of_first_solution
_lowerCAmelCase : Optional[int] = solution
while count <= iters:
_lowerCAmelCase : int = find_neighborhood(_lowerCamelCase , _lowerCamelCase )
_lowerCAmelCase : Tuple = 0
_lowerCAmelCase : Dict = neighborhood[index_of_best_solution]
_lowerCAmelCase : int = len(_lowerCamelCase ) - 1
_lowerCAmelCase : Union[str, Any] = False
while not found:
_lowerCAmelCase : Tuple = 0
while i < len(_lowerCamelCase ):
if best_solution[i] != solution[i]:
_lowerCAmelCase : str = best_solution[i]
_lowerCAmelCase : Tuple = solution[i]
break
_lowerCAmelCase : int = i + 1
if [first_exchange_node, second_exchange_node] not in tabu_list and [
second_exchange_node,
first_exchange_node,
] not in tabu_list:
tabu_list.append([first_exchange_node, second_exchange_node] )
_lowerCAmelCase : Optional[int] = True
_lowerCAmelCase : Optional[Any] = best_solution[:-1]
_lowerCAmelCase : Tuple = neighborhood[index_of_best_solution][best_cost_index]
if cost < best_cost:
_lowerCAmelCase : Union[str, Any] = cost
_lowerCAmelCase : List[Any] = solution
else:
_lowerCAmelCase : Optional[Any] = index_of_best_solution + 1
_lowerCAmelCase : Optional[Any] = neighborhood[index_of_best_solution]
if len(_lowerCamelCase ) >= size:
tabu_list.pop(0 )
_lowerCAmelCase : int = count + 1
return best_solution_ever, best_cost
def A ( _lowerCamelCase=None ):
'''simple docstring'''
_lowerCAmelCase : int = generate_neighbours(args.File )
_lowerCAmelCase , _lowerCAmelCase : List[str] = generate_first_solution(
args.File , _lowerCamelCase )
_lowerCAmelCase , _lowerCAmelCase : Any = tabu_search(
_lowerCamelCase , _lowerCamelCase , _lowerCamelCase , args.Iterations , args.Size , )
print(F"Best solution: {best_sol}, with total distance: {best_cost}." )
if __name__ == "__main__":
_snake_case = argparse.ArgumentParser(description="Tabu Search")
parser.add_argument(
"-f",
"--File",
type=str,
help="Path to the file containing the data",
required=True,
)
parser.add_argument(
"-i",
"--Iterations",
type=int,
help="How many iterations the algorithm should perform",
required=True,
)
parser.add_argument(
"-s", "--Size", type=int, help="Size of the tabu list", required=True
)
# Pass the arguments to main method
main(parser.parse_args())
| 36
| 1
|
from typing import TYPE_CHECKING
from ...utils import (
OptionalDependencyNotAvailable,
_LazyModule,
is_flax_available,
is_tf_available,
is_torch_available,
)
_snake_case = {
"configuration_vision_encoder_decoder": ["VisionEncoderDecoderConfig", "VisionEncoderDecoderOnnxConfig"]
}
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
_snake_case = ["VisionEncoderDecoderModel"]
try:
if not is_tf_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
_snake_case = ["TFVisionEncoderDecoderModel"]
try:
if not is_flax_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
_snake_case = ["FlaxVisionEncoderDecoderModel"]
if TYPE_CHECKING:
from .configuration_vision_encoder_decoder import VisionEncoderDecoderConfig, VisionEncoderDecoderOnnxConfig
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_vision_encoder_decoder import VisionEncoderDecoderModel
try:
if not is_tf_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_tf_vision_encoder_decoder import TFVisionEncoderDecoderModel
try:
if not is_flax_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_flax_vision_encoder_decoder import FlaxVisionEncoderDecoderModel
else:
import sys
_snake_case = _LazyModule(__name__, globals()["__file__"], _import_structure, module_spec=__spec__)
| 36
|
import os
import unittest
from transformers.models.bartpho.tokenization_bartpho import VOCAB_FILES_NAMES, BartphoTokenizer
from transformers.testing_utils import get_tests_dir
from ...test_tokenization_common import TokenizerTesterMixin
_snake_case = get_tests_dir("fixtures/test_sentencepiece_bpe.model")
class UpperCAmelCase_ ( a , unittest.TestCase):
lowerCamelCase__ = BartphoTokenizer
lowerCamelCase__ = False
lowerCamelCase__ = True
def snake_case__ ( self):
'''simple docstring'''
super().setUp()
_lowerCAmelCase : str = ["▁This", "▁is", "▁a", "▁t", "est"]
_lowerCAmelCase : List[str] = dict(zip(__a, range(len(__a))))
_lowerCAmelCase : Optional[Any] = {"unk_token": "<unk>"}
_lowerCAmelCase : Optional[int] = os.path.join(self.tmpdirname, VOCAB_FILES_NAMES["monolingual_vocab_file"])
with open(self.monolingual_vocab_file, "w", encoding="utf-8") as fp:
for token in vocab_tokens:
fp.write(f"{token} {vocab_tokens[token]}\n")
_lowerCAmelCase : Optional[Any] = BartphoTokenizer(__a, self.monolingual_vocab_file, **self.special_tokens_map)
tokenizer.save_pretrained(self.tmpdirname)
def snake_case__ ( self, **__a):
'''simple docstring'''
kwargs.update(self.special_tokens_map)
return BartphoTokenizer.from_pretrained(self.tmpdirname, **__a)
def snake_case__ ( self, __a):
'''simple docstring'''
_lowerCAmelCase : Union[str, Any] = "This is a là test"
_lowerCAmelCase : Optional[int] = "This is a<unk><unk> test"
return input_text, output_text
def snake_case__ ( self):
'''simple docstring'''
_lowerCAmelCase : Optional[int] = BartphoTokenizer(__a, self.monolingual_vocab_file, **self.special_tokens_map)
_lowerCAmelCase : List[Any] = "This is a là test"
_lowerCAmelCase : str = "▁This ▁is ▁a ▁l à ▁t est".split()
_lowerCAmelCase : str = tokenizer.tokenize(__a)
self.assertListEqual(__a, __a)
_lowerCAmelCase : Tuple = tokens + [tokenizer.unk_token]
_lowerCAmelCase : List[str] = [4, 5, 6, 3, 3, 7, 8, 3]
self.assertListEqual(tokenizer.convert_tokens_to_ids(__a), __a)
| 36
| 1
|
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