Datasets:

infinityofspace

/

python_codestyles-random-1k

like 0

import argparse from transformers import ( TapasConfig, TapasForMaskedLM, TapasForQuestionAnswering, TapasForSequenceClassification, TapasModel, TapasTokenizer, load_tf_weights_in_tapas, ) from transformers.utils import logging logging.set_verbosity_info() def _A ( _lowercase , _lowercase , _lowercase , _lowercase , _lowercase ) -> Optional[Any]: """simple docstring""" __UpperCamelCase = TapasConfig.from_json_file(_lowercase ) # set absolute/relative position embeddings parameter __UpperCamelCase = reset_position_index_per_cell # set remaining parameters of TapasConfig as well as the model based on the task if task == "SQA": __UpperCamelCase = TapasForQuestionAnswering(config=_lowercase ) elif task == "WTQ": # run_task_main.py hparams __UpperCamelCase = 4 __UpperCamelCase = True # hparam_utils.py hparams __UpperCamelCase = 0.66_46_94 __UpperCamelCase = 0.20_79_51 __UpperCamelCase = 0.12_11_94 __UpperCamelCase = True __UpperCamelCase = True __UpperCamelCase = False __UpperCamelCase = 0.0_35_25_13 __UpperCamelCase = TapasForQuestionAnswering(config=_lowercase ) elif task == "WIKISQL_SUPERVISED": # run_task_main.py hparams __UpperCamelCase = 4 __UpperCamelCase = False # hparam_utils.py hparams __UpperCamelCase = 36.45_19 __UpperCamelCase = 0.90_34_21 __UpperCamelCase = 2_22.0_88 __UpperCamelCase = True __UpperCamelCase = True __UpperCamelCase = True __UpperCamelCase = 0.76_31_41 __UpperCamelCase = TapasForQuestionAnswering(config=_lowercase ) elif task == "TABFACT": __UpperCamelCase = TapasForSequenceClassification(config=_lowercase ) elif task == "MLM": __UpperCamelCase = TapasForMaskedLM(config=_lowercase ) elif task == "INTERMEDIATE_PRETRAINING": __UpperCamelCase = TapasModel(config=_lowercase ) else: raise ValueError(f'''Task {task} not supported.''' ) print(f'''Building PyTorch model from configuration: {config}''' ) # Load weights from tf checkpoint load_tf_weights_in_tapas(_lowercase , _lowercase , _lowercase ) # Save pytorch-model (weights and configuration) print(f'''Save PyTorch model to {pytorch_dump_path}''' ) model.save_pretrained(_lowercase ) # Save tokenizer files print(f'''Save tokenizer files to {pytorch_dump_path}''' ) __UpperCamelCase = TapasTokenizer(vocab_file=tf_checkpoint_path[:-10] + 'vocab.txt' , model_max_length=5_12 ) tokenizer.save_pretrained(_lowercase ) print('Used relative position embeddings:' , model.config.reset_position_index_per_cell ) if __name__ == "__main__": __snake_case = argparse.ArgumentParser() # Required parameters parser.add_argument( '''--task''', default='''SQA''', type=str, help='''Model task for which to convert a checkpoint. Defaults to SQA.''' ) parser.add_argument( '''--reset_position_index_per_cell''', default=False, action='''store_true''', help='''Whether to use relative position embeddings or not. Defaults to True.''', ) parser.add_argument( '''--tf_checkpoint_path''', default=None, type=str, required=True, help='''Path to the TensorFlow checkpoint path.''' ) parser.add_argument( '''--tapas_config_file''', default=None, type=str, required=True, help=( '''The config json file corresponding to the pre-trained TAPAS model. \n''' '''This specifies the model architecture.''' ), ) parser.add_argument( '''--pytorch_dump_path''', default=None, type=str, required=True, help='''Path to the output PyTorch model.''' ) __snake_case = parser.parse_args() convert_tf_checkpoint_to_pytorch( args.task, args.reset_position_index_per_cell, args.tf_checkpoint_path, args.tapas_config_file, args.pytorch_dump_path, )

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 AutoFeatureExtractor, WavaVecaFeatureExtractor 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_feature_extraction import CustomFeatureExtractor # noqa E402 __snake_case = get_tests_dir('''fixtures''') class __lowerCamelCase (unittest.TestCase ): def snake_case_ ( self: int ): '''simple docstring''' __UpperCamelCase = mock.Mock() __UpperCamelCase = 500 __UpperCamelCase = {} __UpperCamelCase = HTTPError __UpperCamelCase = {} # Download this model to make sure it's in the cache. __UpperCamelCase = WavaVecaFeatureExtractor.from_pretrained('hf-internal-testing/tiny-random-wav2vec2' ) # 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: __UpperCamelCase = WavaVecaFeatureExtractor.from_pretrained('hf-internal-testing/tiny-random-wav2vec2' ) # This check we did call the fake head request mock_head.assert_called() def snake_case_ ( self: Dict ): '''simple docstring''' __UpperCamelCase = WavaVecaFeatureExtractor.from_pretrained( 'https://huggingface.co/hf-internal-testing/tiny-random-wav2vec2/resolve/main/preprocessor_config.json' ) @is_staging_test class __lowerCamelCase (unittest.TestCase ): @classmethod def snake_case_ ( cls: Tuple ): '''simple docstring''' __UpperCamelCase = TOKEN HfFolder.save_token(A_ ) @classmethod def snake_case_ ( cls: Tuple ): '''simple docstring''' try: delete_repo(token=cls._token,repo_id='test-feature-extractor' ) except HTTPError: pass try: delete_repo(token=cls._token,repo_id='valid_org/test-feature-extractor-org' ) except HTTPError: pass try: delete_repo(token=cls._token,repo_id='test-dynamic-feature-extractor' ) except HTTPError: pass def snake_case_ ( self: Tuple ): '''simple docstring''' __UpperCamelCase = WavaVecaFeatureExtractor.from_pretrained(A_ ) feature_extractor.push_to_hub('test-feature-extractor',use_auth_token=self._token ) __UpperCamelCase = WavaVecaFeatureExtractor.from_pretrained(F'''{USER}/test-feature-extractor''' ) for k, v in feature_extractor.__dict__.items(): self.assertEqual(A_,getattr(A_,A_ ) ) # Reset repo delete_repo(token=self._token,repo_id='test-feature-extractor' ) # Push to hub via save_pretrained with tempfile.TemporaryDirectory() as tmp_dir: feature_extractor.save_pretrained( A_,repo_id='test-feature-extractor',push_to_hub=A_,use_auth_token=self._token ) __UpperCamelCase = WavaVecaFeatureExtractor.from_pretrained(F'''{USER}/test-feature-extractor''' ) for k, v in feature_extractor.__dict__.items(): self.assertEqual(A_,getattr(A_,A_ ) ) def snake_case_ ( self: List[str] ): '''simple docstring''' __UpperCamelCase = WavaVecaFeatureExtractor.from_pretrained(A_ ) feature_extractor.push_to_hub('valid_org/test-feature-extractor',use_auth_token=self._token ) __UpperCamelCase = WavaVecaFeatureExtractor.from_pretrained('valid_org/test-feature-extractor' ) for k, v in feature_extractor.__dict__.items(): self.assertEqual(A_,getattr(A_,A_ ) ) # Reset repo delete_repo(token=self._token,repo_id='valid_org/test-feature-extractor' ) # Push to hub via save_pretrained with tempfile.TemporaryDirectory() as tmp_dir: feature_extractor.save_pretrained( A_,repo_id='valid_org/test-feature-extractor-org',push_to_hub=A_,use_auth_token=self._token ) __UpperCamelCase = WavaVecaFeatureExtractor.from_pretrained('valid_org/test-feature-extractor-org' ) for k, v in feature_extractor.__dict__.items(): self.assertEqual(A_,getattr(A_,A_ ) ) def snake_case_ ( self: int ): '''simple docstring''' CustomFeatureExtractor.register_for_auto_class() __UpperCamelCase = CustomFeatureExtractor.from_pretrained(A_ ) feature_extractor.push_to_hub('test-dynamic-feature-extractor',use_auth_token=self._token ) # This has added the proper auto_map field to the config self.assertDictEqual( feature_extractor.auto_map,{'AutoFeatureExtractor': 'custom_feature_extraction.CustomFeatureExtractor'},) __UpperCamelCase = AutoFeatureExtractor.from_pretrained( F'''{USER}/test-dynamic-feature-extractor''',trust_remote_code=A_ ) # Can't make an isinstance check because the new_feature_extractor is from the CustomFeatureExtractor class of a dynamic module self.assertEqual(new_feature_extractor.__class__.__name__,'CustomFeatureExtractor' )

import inspect import math import tempfile import unittest import numpy as np from transformers import ViTMAEConfig from transformers.testing_utils import require_torch, require_vision, slow, torch_device from transformers.utils import cached_property, is_torch_available, is_vision_available from ...test_configuration_common import ConfigTester from ...test_modeling_common import ModelTesterMixin, floats_tensor, ids_tensor from ...test_pipeline_mixin import PipelineTesterMixin if is_torch_available(): import torch from torch import nn from transformers import ViTMAEForPreTraining, ViTMAEModel from transformers.models.vit.modeling_vit import VIT_PRETRAINED_MODEL_ARCHIVE_LIST if is_vision_available(): from PIL import Image from transformers import ViTImageProcessor class __lowerCamelCase : def __init__( self: Dict,A_: List[Any],A_: Dict=13,A_: Union[str, Any]=30,A_: str=2,A_: int=3,A_: Any=True,A_: Union[str, Any]=True,A_: Dict=32,A_: Optional[Any]=5,A_: Optional[Any]=4,A_: Tuple=37,A_: List[Any]="gelu",A_: str=0.1,A_: Tuple=0.1,A_: List[str]=10,A_: Union[str, Any]=0.0_2,A_: Dict=3,A_: Any=0.6,A_: int=None,): '''simple docstring''' __UpperCamelCase = parent __UpperCamelCase = batch_size __UpperCamelCase = image_size __UpperCamelCase = patch_size __UpperCamelCase = num_channels __UpperCamelCase = is_training __UpperCamelCase = use_labels __UpperCamelCase = hidden_size __UpperCamelCase = num_hidden_layers __UpperCamelCase = num_attention_heads __UpperCamelCase = intermediate_size __UpperCamelCase = hidden_act __UpperCamelCase = hidden_dropout_prob __UpperCamelCase = attention_probs_dropout_prob __UpperCamelCase = type_sequence_label_size __UpperCamelCase = initializer_range __UpperCamelCase = mask_ratio __UpperCamelCase = scope # in ViTMAE, the expected sequence length = (num_patches + 1) * (1 - config.mask_ratio), rounded above # (we add 1 for the [CLS] token) __UpperCamelCase = (image_size // patch_size) ** 2 __UpperCamelCase = int(math.ceil((1 - mask_ratio) * (num_patches + 1) ) ) def snake_case_ ( self: Dict ): '''simple docstring''' __UpperCamelCase = floats_tensor([self.batch_size, self.num_channels, self.image_size, self.image_size] ) __UpperCamelCase = None if self.use_labels: __UpperCamelCase = ids_tensor([self.batch_size],self.type_sequence_label_size ) __UpperCamelCase = self.get_config() return config, pixel_values, labels def snake_case_ ( self: Dict ): '''simple docstring''' return ViTMAEConfig( image_size=self.image_size,patch_size=self.patch_size,num_channels=self.num_channels,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,is_decoder=A_,initializer_range=self.initializer_range,mask_ratio=self.mask_ratio,) def snake_case_ ( self: Optional[Any],A_: List[str],A_: List[Any],A_: Union[str, Any] ): '''simple docstring''' __UpperCamelCase = ViTMAEModel(config=A_ ) model.to(A_ ) model.eval() __UpperCamelCase = model(A_ ) self.parent.assertEqual(result.last_hidden_state.shape,(self.batch_size, self.seq_length, self.hidden_size) ) def snake_case_ ( self: List[Any],A_: Optional[int],A_: Dict,A_: Dict ): '''simple docstring''' __UpperCamelCase = ViTMAEForPreTraining(A_ ) model.to(A_ ) model.eval() __UpperCamelCase = model(A_ ) __UpperCamelCase = (self.image_size // self.patch_size) ** 2 __UpperCamelCase = self.patch_size**2 * self.num_channels self.parent.assertEqual(result.logits.shape,(self.batch_size, num_patches, expected_num_channels) ) # test greyscale images __UpperCamelCase = 1 __UpperCamelCase = ViTMAEForPreTraining(A_ ) model.to(A_ ) model.eval() __UpperCamelCase = floats_tensor([self.batch_size, 1, self.image_size, self.image_size] ) __UpperCamelCase = model(A_ ) __UpperCamelCase = self.patch_size**2 self.parent.assertEqual(result.logits.shape,(self.batch_size, num_patches, expected_num_channels) ) def snake_case_ ( self: List[Any] ): '''simple docstring''' __UpperCamelCase = self.prepare_config_and_inputs() __UpperCamelCase, __UpperCamelCase, __UpperCamelCase = config_and_inputs __UpperCamelCase = {'pixel_values': pixel_values} return config, inputs_dict @require_torch class __lowerCamelCase (_a , _a , unittest.TestCase ): _lowercase = (ViTMAEModel, ViTMAEForPreTraining) if is_torch_available() else () _lowercase = {"""feature-extraction""": ViTMAEModel} if is_torch_available() else {} _lowercase = False _lowercase = False _lowercase = False _lowercase = False def snake_case_ ( self: str ): '''simple docstring''' __UpperCamelCase = ViTMAEModelTester(self ) __UpperCamelCase = ConfigTester(self,config_class=A_,has_text_modality=A_,hidden_size=37 ) def snake_case_ ( self: Dict ): '''simple docstring''' self.config_tester.run_common_tests() @unittest.skip(reason='ViTMAE does not use inputs_embeds' ) def snake_case_ ( self: List[str] ): '''simple docstring''' pass def snake_case_ ( self: str ): '''simple docstring''' __UpperCamelCase, __UpperCamelCase = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: __UpperCamelCase = model_class(A_ ) self.assertIsInstance(model.get_input_embeddings(),(nn.Module) ) __UpperCamelCase = model.get_output_embeddings() self.assertTrue(x is None or isinstance(A_,nn.Linear ) ) def snake_case_ ( self: Any ): '''simple docstring''' __UpperCamelCase, __UpperCamelCase = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: __UpperCamelCase = model_class(A_ ) __UpperCamelCase = inspect.signature(model.forward ) # signature.parameters is an OrderedDict => so arg_names order is deterministic __UpperCamelCase = [*signature.parameters.keys()] __UpperCamelCase = ['pixel_values'] self.assertListEqual(arg_names[:1],A_ ) def snake_case_ ( self: str ): '''simple docstring''' __UpperCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_model(*A_ ) def snake_case_ ( self: Union[str, Any] ): '''simple docstring''' __UpperCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_for_pretraining(*A_ ) def snake_case_ ( self: str,A_: str,A_: List[str],A_: Union[str, Any] ): '''simple docstring''' np.random.seed(2 ) __UpperCamelCase = int((pt_model.config.image_size // pt_model.config.patch_size) ** 2 ) __UpperCamelCase = np.random.uniform(size=(self.model_tester.batch_size, num_patches) ) __UpperCamelCase = torch.from_numpy(A_ ) # Add `noise` argument. # PT inputs will be prepared in `super().check_pt_tf_models()` with this added `noise` argument __UpperCamelCase = pt_noise super().check_pt_tf_models(A_,A_,A_ ) def snake_case_ ( self: Any ): '''simple docstring''' __UpperCamelCase, __UpperCamelCase = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: __UpperCamelCase = model_class(A_ ) model.to(A_ ) model.eval() # make random mask reproducible torch.manual_seed(2 ) with torch.no_grad(): __UpperCamelCase = model(**self._prepare_for_class(A_,A_ ) ) __UpperCamelCase = outputs[0].cpu().numpy() __UpperCamelCase = 0 with tempfile.TemporaryDirectory() as tmpdirname: model.save_pretrained(A_ ) __UpperCamelCase = model_class.from_pretrained(A_ ) model.to(A_ ) # make random mask reproducible torch.manual_seed(2 ) with torch.no_grad(): __UpperCamelCase = model(**self._prepare_for_class(A_,A_ ) ) # Make sure we don't have nans __UpperCamelCase = after_outputs[0].cpu().numpy() __UpperCamelCase = 0 __UpperCamelCase = np.amax(np.abs(out_a - out_a ) ) self.assertLessEqual(A_,1E-5 ) @unittest.skip( reason='ViTMAE returns a random mask + ids_restore in each forward pass. See test_save_load\n to get deterministic results.' ) def snake_case_ ( self: List[str] ): '''simple docstring''' pass @unittest.skip( reason='ViTMAE returns a random mask + ids_restore in each forward pass. See test_save_load\n to get deterministic results.' ) def snake_case_ ( self: Dict ): '''simple docstring''' pass @unittest.skip( reason='ViTMAE returns a random mask + ids_restore in each forward pass. See test_save_load\n to get deterministic results.' ) def snake_case_ ( self: int ): '''simple docstring''' pass @unittest.skip(reason='ViTMAE returns a random mask + ids_restore in each forward pass. See test_save_load' ) def snake_case_ ( self: Dict ): '''simple docstring''' pass @unittest.skip('Will be fixed soon by reducing the size of the model used for common tests.' ) def snake_case_ ( self: int ): '''simple docstring''' pass @slow def snake_case_ ( self: str ): '''simple docstring''' for model_name in VIT_PRETRAINED_MODEL_ARCHIVE_LIST[:1]: __UpperCamelCase = ViTMAEModel.from_pretrained(A_ ) self.assertIsNotNone(A_ ) def _A ( ) -> Any: """simple docstring""" __UpperCamelCase = Image.open('./tests/fixtures/tests_samples/COCO/000000039769.png' ) return image @require_torch @require_vision class __lowerCamelCase (unittest.TestCase ): @cached_property def snake_case_ ( self: Tuple ): '''simple docstring''' return ViTImageProcessor.from_pretrained('facebook/vit-mae-base' ) if is_vision_available() else None @slow def snake_case_ ( self: Union[str, Any] ): '''simple docstring''' np.random.seed(2 ) __UpperCamelCase = ViTMAEForPreTraining.from_pretrained('facebook/vit-mae-base' ).to(A_ ) __UpperCamelCase = self.default_image_processor __UpperCamelCase = prepare_img() __UpperCamelCase = image_processor(images=A_,return_tensors='pt' ).to(A_ ) # prepare a noise vector that will be also used for testing the TF model # (this way we can ensure that the PT and TF models operate on the same inputs) __UpperCamelCase = ViTMAEConfig() __UpperCamelCase = int((vit_mae_config.image_size // vit_mae_config.patch_size) ** 2 ) __UpperCamelCase = np.random.uniform(size=(1, num_patches) ) # forward pass with torch.no_grad(): __UpperCamelCase = model(**A_,noise=torch.from_numpy(A_ ).to(device=A_ ) ) # verify the logits __UpperCamelCase = torch.Size((1, 196, 768) ) self.assertEqual(outputs.logits.shape,A_ ) __UpperCamelCase = torch.tensor( [[-0.0_5_4_8, -1.7_0_2_3, -0.9_3_2_5], [0.3_7_2_1, -0.5_6_7_0, -0.2_2_3_3], [0.8_2_3_5, -1.3_8_7_8, -0.3_5_2_4]] ) self.assertTrue(torch.allclose(outputs.logits[0, :3, :3],expected_slice.to(A_ ),atol=1E-4 ) )

import argparse import json import os import evaluate import torch from datasets import load_dataset from torch.optim import AdamW from torch.utils.data import DataLoader from transformers import AutoModelForSequenceClassification, AutoTokenizer, get_linear_schedule_with_warmup, set_seed from accelerate import Accelerator, DistributedType from accelerate.utils.deepspeed import DummyOptim, DummyScheduler __snake_case = 1_6 __snake_case = 3_2 def _A ( _lowercase , _lowercase = 16 , _lowercase = "bert-base-cased" ) -> Union[str, Any]: """simple docstring""" __UpperCamelCase = AutoTokenizer.from_pretrained(_lowercase ) __UpperCamelCase = load_dataset('glue' , 'mrpc' ) def tokenize_function(_lowercase ): # max_length=None => use the model max length (it's actually the default) __UpperCamelCase = tokenizer(examples['sentence1'] , examples['sentence2'] , truncation=_lowercase , max_length=_lowercase ) return outputs # Apply the method we just defined to all the examples in all the splits of the dataset __UpperCamelCase = datasets.map( _lowercase , batched=_lowercase , remove_columns=['idx', 'sentence1', 'sentence2'] , load_from_cache_file=_lowercase ) # We also rename the 'label' column to 'labels' which is the expected name for labels by the models of the # transformers library __UpperCamelCase = tokenized_datasets.rename_column('label' , 'labels' ) def collate_fn(_lowercase ): # 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(_lowercase , padding='max_length' , max_length=1_28 , return_tensors='pt' ) return tokenizer.pad(_lowercase , padding='longest' , return_tensors='pt' ) # Instantiate dataloaders. __UpperCamelCase = DataLoader( tokenized_datasets['train'] , shuffle=_lowercase , collate_fn=_lowercase , batch_size=_lowercase ) __UpperCamelCase = DataLoader( tokenized_datasets['validation'] , shuffle=_lowercase , collate_fn=_lowercase , batch_size=_lowercase ) return train_dataloader, eval_dataloader def _A ( _lowercase , _lowercase ) -> int: """simple docstring""" __UpperCamelCase = Accelerator() # Sample hyper-parameters for learning rate, batch size, seed and a few other HPs __UpperCamelCase = config['lr'] __UpperCamelCase = int(config['num_epochs'] ) __UpperCamelCase = int(config['seed'] ) __UpperCamelCase = int(config['batch_size'] ) __UpperCamelCase = args.model_name_or_path set_seed(_lowercase ) __UpperCamelCase, __UpperCamelCase = get_dataloaders(_lowercase , _lowercase , _lowercase ) # Instantiate the model (we build the model here so that the seed also control new weights initialization) __UpperCamelCase = AutoModelForSequenceClassification.from_pretrained(_lowercase , return_dict=_lowercase ) # Instantiate optimizer __UpperCamelCase = ( AdamW if accelerator.state.deepspeed_plugin is None or 'optimizer' not in accelerator.state.deepspeed_plugin.deepspeed_config else DummyOptim ) __UpperCamelCase = optimizer_cls(params=model.parameters() , lr=_lowercase ) if accelerator.state.deepspeed_plugin is not None: __UpperCamelCase = accelerator.state.deepspeed_plugin.deepspeed_config[ 'gradient_accumulation_steps' ] else: __UpperCamelCase = 1 __UpperCamelCase = (len(_lowercase ) * num_epochs) // gradient_accumulation_steps # Instantiate scheduler if ( accelerator.state.deepspeed_plugin is None or "scheduler" not in accelerator.state.deepspeed_plugin.deepspeed_config ): __UpperCamelCase = get_linear_schedule_with_warmup( optimizer=_lowercase , num_warmup_steps=0 , num_training_steps=_lowercase , ) else: __UpperCamelCase = DummyScheduler(_lowercase , total_num_steps=_lowercase , warmup_num_steps=0 ) # Prepare everything # There is no specific order to remember, we just need to unpack the objects in the same order we gave them to the # prepare method. __UpperCamelCase, __UpperCamelCase, __UpperCamelCase, __UpperCamelCase, __UpperCamelCase = accelerator.prepare( _lowercase , _lowercase , _lowercase , _lowercase , _lowercase ) # We need to keep track of how many total steps we have iterated over __UpperCamelCase = 0 # We also need to keep track of the stating epoch so files are named properly __UpperCamelCase = 0 # Now we train the model __UpperCamelCase = evaluate.load('glue' , 'mrpc' ) __UpperCamelCase = 0 __UpperCamelCase = {} for epoch in range(_lowercase , _lowercase ): model.train() for step, batch in enumerate(_lowercase ): __UpperCamelCase = model(**_lowercase ) __UpperCamelCase = outputs.loss __UpperCamelCase = loss / gradient_accumulation_steps accelerator.backward(_lowercase ) if step % gradient_accumulation_steps == 0: optimizer.step() lr_scheduler.step() optimizer.zero_grad() overall_step += 1 model.eval() __UpperCamelCase = 0 for step, batch in enumerate(_lowercase ): # We could avoid this line since we set the accelerator with `device_placement=True`. batch.to(accelerator.device ) with torch.no_grad(): __UpperCamelCase = model(**_lowercase ) __UpperCamelCase = outputs.logits.argmax(dim=-1 ) # It is slightly faster to call this once, than multiple times __UpperCamelCase, __UpperCamelCase = accelerator.gather( (predictions, batch['labels']) ) # If we are in a multiprocess environment, the last batch has duplicates if accelerator.use_distributed: if step == len(_lowercase ) - 1: __UpperCamelCase = predictions[: len(eval_dataloader.dataset ) - samples_seen] __UpperCamelCase = references[: len(eval_dataloader.dataset ) - samples_seen] else: samples_seen += references.shape[0] metric.add_batch( predictions=_lowercase , references=_lowercase , ) __UpperCamelCase = metric.compute() # Use accelerator.print to print only on the main process. accelerator.print(f'''epoch {epoch}:''' , _lowercase ) __UpperCamelCase = eval_metric['accuracy'] if best_performance < eval_metric["accuracy"]: __UpperCamelCase = eval_metric['accuracy'] if args.performance_lower_bound is not None: assert ( args.performance_lower_bound <= best_performance ), f'''Best performance metric {best_performance} is lower than the lower bound {args.performance_lower_bound}''' accelerator.wait_for_everyone() if accelerator.is_main_process: with open(os.path.join(args.output_dir , 'all_results.json' ) , 'w' ) as f: json.dump(_lowercase , _lowercase ) def _A ( ) -> List[str]: """simple docstring""" __UpperCamelCase = argparse.ArgumentParser(description='Simple example of training script tracking peak GPU memory usage.' ) parser.add_argument( '--model_name_or_path' , type=_lowercase , default='bert-base-cased' , help='Path to pretrained model or model identifier from huggingface.co/models.' , required=_lowercase , ) parser.add_argument( '--output_dir' , type=_lowercase , default='.' , help='Optional save directory where all checkpoint folders will be stored. Default is the current working directory.' , ) parser.add_argument( '--performance_lower_bound' , type=_lowercase , default=_lowercase , help='Optional lower bound for the performance metric. If set, the training will throw error when the performance metric drops below this value.' , ) parser.add_argument( '--num_epochs' , type=_lowercase , default=3 , help='Number of train epochs.' , ) __UpperCamelCase = parser.parse_args() __UpperCamelCase = {'lr': 2e-5, 'num_epochs': args.num_epochs, 'seed': 42, 'batch_size': 16} training_function(_lowercase , _lowercase ) if __name__ == "__main__": main()

import os import unittest from transformers.models.cpmant.tokenization_cpmant import VOCAB_FILES_NAMES, CpmAntTokenizer from transformers.testing_utils import require_jieba, tooslow from ...test_tokenization_common import TokenizerTesterMixin @require_jieba class __lowerCamelCase (_a , unittest.TestCase ): _lowercase = CpmAntTokenizer _lowercase = False def snake_case_ ( self: Optional[Any] ): '''simple docstring''' super().setUp() __UpperCamelCase = [ '<d>', '</d>', '<s>', '</s>', '</_>', '<unk>', '<pad>', '</n>', '我', '是', 'C', 'P', 'M', 'A', 'n', 't', ] __UpperCamelCase = os.path.join(self.tmpdirname,VOCAB_FILES_NAMES['vocab_file'] ) with open(self.vocab_file,'w',encoding='utf-8' ) as vocab_writer: vocab_writer.write(''.join([x + '\n' for x in vocab_tokens] ) ) @tooslow def snake_case_ ( self: Any ): '''simple docstring''' __UpperCamelCase = CpmAntTokenizer.from_pretrained('openbmb/cpm-ant-10b' ) __UpperCamelCase = '今天天气真好！' __UpperCamelCase = ['今天', '天气', '真', '好', '！'] __UpperCamelCase = tokenizer.tokenize(A_ ) self.assertListEqual(A_,A_ ) __UpperCamelCase = '今天天气真好！' __UpperCamelCase = [tokenizer.bos_token] + tokens __UpperCamelCase = [6, 9802, 1_4962, 2082, 831, 244] self.assertListEqual(tokenizer.convert_tokens_to_ids(A_ ),A_ ) __UpperCamelCase = tokenizer.decode(A_ ) self.assertEqual(A_,A_ )

from transformers import BertTokenizer, EncoderDecoderModel, SeqaSeqTrainer, SeqaSeqTrainingArguments from transformers.testing_utils import TestCasePlus, require_torch, slow from transformers.utils import is_datasets_available if is_datasets_available(): import datasets class __lowerCamelCase (_a ): @slow @require_torch def snake_case_ ( self: Union[str, Any] ): '''simple docstring''' __UpperCamelCase = EncoderDecoderModel.from_encoder_decoder_pretrained('prajjwal1/bert-tiny','prajjwal1/bert-tiny' ) __UpperCamelCase = BertTokenizer.from_pretrained('bert-base-uncased' ) __UpperCamelCase = bertabert.config.encoder.vocab_size __UpperCamelCase = tokenizer.sep_token_id __UpperCamelCase = tokenizer.cls_token_id __UpperCamelCase = 128 __UpperCamelCase = datasets.load_dataset('cnn_dailymail','3.0.0',split='train[:1%]' ) __UpperCamelCase = datasets.load_dataset('cnn_dailymail','3.0.0',split='validation[:1%]' ) __UpperCamelCase = train_dataset.select(range(32 ) ) __UpperCamelCase = val_dataset.select(range(16 ) ) __UpperCamelCase = 4 def _map_to_encoder_decoder_inputs(A_: Dict ): # Tokenizer will automatically set [BOS] <text> [EOS] __UpperCamelCase = tokenizer(batch['article'],padding='max_length',truncation=A_,max_length=512 ) __UpperCamelCase = tokenizer(batch['highlights'],padding='max_length',truncation=A_,max_length=128 ) __UpperCamelCase = inputs.input_ids __UpperCamelCase = inputs.attention_mask __UpperCamelCase = outputs.input_ids __UpperCamelCase = outputs.input_ids.copy() __UpperCamelCase = [ [-100 if token == tokenizer.pad_token_id else token for token in labels] for labels in batch['labels'] ] __UpperCamelCase = outputs.attention_mask assert all(len(A_ ) == 512 for x in inputs.input_ids ) assert all(len(A_ ) == 128 for x in outputs.input_ids ) return batch def _compute_metrics(A_: str ): __UpperCamelCase = pred.label_ids __UpperCamelCase = pred.predictions # all unnecessary tokens are removed __UpperCamelCase = tokenizer.batch_decode(A_,skip_special_tokens=A_ ) __UpperCamelCase = tokenizer.batch_decode(A_,skip_special_tokens=A_ ) __UpperCamelCase = sum([int(pred_str[i] == label_str[i] ) for i in range(len(A_ ) )] ) / len(A_ ) return {"accuracy": accuracy} # map train dataset __UpperCamelCase = train_dataset.map( _map_to_encoder_decoder_inputs,batched=A_,batch_size=A_,remove_columns=['article', 'highlights'],) train_dataset.set_format( type='torch',columns=['input_ids', 'attention_mask', 'decoder_input_ids', 'decoder_attention_mask', 'labels'],) # same for validation dataset __UpperCamelCase = val_dataset.map( _map_to_encoder_decoder_inputs,batched=A_,batch_size=A_,remove_columns=['article', 'highlights'],) val_dataset.set_format( type='torch',columns=['input_ids', 'attention_mask', 'decoder_input_ids', 'decoder_attention_mask', 'labels'],) __UpperCamelCase = self.get_auto_remove_tmp_dir() __UpperCamelCase = SeqaSeqTrainingArguments( output_dir=A_,per_device_train_batch_size=A_,per_device_eval_batch_size=A_,predict_with_generate=A_,evaluation_strategy='steps',do_train=A_,do_eval=A_,warmup_steps=0,eval_steps=2,logging_steps=2,) # instantiate trainer __UpperCamelCase = SeqaSeqTrainer( model=A_,args=A_,compute_metrics=_compute_metrics,train_dataset=A_,eval_dataset=A_,tokenizer=A_,) # start training trainer.train()

__snake_case = '''Input must be a string of 8 numbers plus letter''' __snake_case = '''TRWAGMYFPDXBNJZSQVHLCKE''' def _A ( _lowercase ) -> bool: """simple docstring""" if not isinstance(_lowercase , _lowercase ): __UpperCamelCase = f'''Expected string as input, found {type(_lowercase ).__name__}''' raise TypeError(_lowercase ) __UpperCamelCase = spanish_id.replace('-' , '' ).upper() if len(_lowercase ) != 9: raise ValueError(_lowercase ) try: __UpperCamelCase = int(spanish_id_clean[0:8] ) __UpperCamelCase = spanish_id_clean[8] except ValueError as ex: raise ValueError(_lowercase ) from ex if letter.isdigit(): raise ValueError(_lowercase ) return letter == LOOKUP_LETTERS[number % 23] if __name__ == "__main__": import doctest doctest.testmod()

def _A ( _lowercase = 1_00 ) -> int: """simple docstring""" __UpperCamelCase = 0 __UpperCamelCase = 0 for i in range(1 , n + 1 ): sum_of_squares += i**2 sum_of_ints += i return sum_of_ints**2 - sum_of_squares if __name__ == "__main__": print(f"""{solution() = }""")

def _A ( ) -> list[list[int]]: """simple docstring""" return [list(range(10_00 - i , -10_00 - i , -1 ) ) for i in range(10_00 )] __snake_case = generate_large_matrix() __snake_case = ( [[4, 3, 2, -1], [3, 2, 1, -1], [1, 1, -1, -2], [-1, -1, -2, -3]], [[3, 2], [1, 0]], [[7, 7, 6]], [[7, 7, 6], [-1, -2, -3]], grid, ) def _A ( _lowercase ) -> None: """simple docstring""" assert all(row == sorted(_lowercase , reverse=_lowercase ) for row in grid ) assert all(list(_lowercase ) == sorted(_lowercase , reverse=_lowercase ) for col in zip(*_lowercase ) ) def _A ( _lowercase ) -> int: """simple docstring""" __UpperCamelCase = 0 __UpperCamelCase = len(_lowercase ) - 1 # Edge cases such as no values or all numbers are negative. if not array or array[0] < 0: return 0 while right + 1 > left: __UpperCamelCase = (left + right) // 2 __UpperCamelCase = array[mid] # Num must be negative and the index must be greater than or equal to 0. if num < 0 and array[mid - 1] >= 0: return mid if num >= 0: __UpperCamelCase = mid + 1 else: __UpperCamelCase = mid - 1 # No negative numbers so return the last index of the array + 1 which is the length. return len(_lowercase ) def _A ( _lowercase ) -> int: """simple docstring""" __UpperCamelCase = 0 __UpperCamelCase = len(grid[0] ) for i in range(len(_lowercase ) ): __UpperCamelCase = find_negative_index(grid[i][:bound] ) total += bound return (len(_lowercase ) * len(grid[0] )) - total def _A ( _lowercase ) -> int: """simple docstring""" return len([number for row in grid for number in row if number < 0] ) def _A ( _lowercase ) -> int: """simple docstring""" __UpperCamelCase = 0 for row in grid: for i, number in enumerate(_lowercase ): if number < 0: total += len(_lowercase ) - i break return total def _A ( ) -> None: """simple docstring""" from timeit import timeit print('Running benchmarks' ) __UpperCamelCase = ( 'from __main__ import count_negatives_binary_search, ' 'count_negatives_brute_force, count_negatives_brute_force_with_break, grid' ) for func in ( "count_negatives_binary_search", # took 0.7727 seconds "count_negatives_brute_force_with_break", # took 4.6505 seconds "count_negatives_brute_force", # took 12.8160 seconds ): __UpperCamelCase = timeit(f'''{func}(grid=grid)''' , setup=_lowercase , number=5_00 ) print(f'''{func}() took {time:0.4f} seconds''' ) if __name__ == "__main__": import doctest doctest.testmod() benchmark()

def _A ( _lowercase , _lowercase ) -> int: """simple docstring""" return (pointa[0] - pointa[0]) ** 2 + (pointa[1] - pointa[1]) ** 2 def _A ( _lowercase , _lowercase=0 ) -> Dict: """simple docstring""" return sorted(_lowercase , key=lambda _lowercase : x[column] ) def _A ( _lowercase , _lowercase , _lowercase=float('inf' ) ) -> List[Any]: """simple docstring""" for i in range(points_counts - 1 ): for j in range(i + 1 , _lowercase ): __UpperCamelCase = euclidean_distance_sqr(points[i] , points[j] ) if current_dis < min_dis: __UpperCamelCase = current_dis return min_dis def _A ( _lowercase , _lowercase , _lowercase=float('inf' ) ) -> Tuple: """simple docstring""" for i in range(min(6 , points_counts - 1 ) , _lowercase ): for j in range(max(0 , i - 6 ) , _lowercase ): __UpperCamelCase = euclidean_distance_sqr(points[i] , points[j] ) if current_dis < min_dis: __UpperCamelCase = current_dis return min_dis def _A ( _lowercase , _lowercase , _lowercase ) -> Optional[Any]: """simple docstring""" if points_counts <= 3: return dis_between_closest_pair(_lowercase , _lowercase ) # recursion __UpperCamelCase = points_counts // 2 __UpperCamelCase = closest_pair_of_points_sqr( _lowercase , points_sorted_on_y[:mid] , _lowercase ) __UpperCamelCase = closest_pair_of_points_sqr( _lowercase , points_sorted_on_y[mid:] , points_counts - mid ) __UpperCamelCase = min(_lowercase , _lowercase ) __UpperCamelCase = [] for point in points_sorted_on_x: if abs(point[0] - points_sorted_on_x[mid][0] ) < closest_pair_dis: cross_strip.append(_lowercase ) __UpperCamelCase = dis_between_closest_in_strip( _lowercase , len(_lowercase ) , _lowercase ) return min(_lowercase , _lowercase ) def _A ( _lowercase , _lowercase ) -> Optional[int]: """simple docstring""" __UpperCamelCase = column_based_sort(_lowercase , column=0 ) __UpperCamelCase = column_based_sort(_lowercase , column=1 ) return ( closest_pair_of_points_sqr( _lowercase , _lowercase , _lowercase ) ) ** 0.5 if __name__ == "__main__": __snake_case = [(2, 3), (1_2, 3_0), (4_0, 5_0), (5, 1), (1_2, 1_0), (3, 4)] print('''Distance:''', closest_pair_of_points(points, len(points)))

import math def _A ( _lowercase ) -> bool: """simple docstring""" return math.sqrt(_lowercase ) * math.sqrt(_lowercase ) == num def _A ( _lowercase ) -> bool: """simple docstring""" __UpperCamelCase = 0 __UpperCamelCase = n while left <= right: __UpperCamelCase = (left + right) // 2 if mid**2 == n: return True elif mid**2 > n: __UpperCamelCase = mid - 1 else: __UpperCamelCase = mid + 1 return False if __name__ == "__main__": import doctest doctest.testmod()

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 = { '''bert-base-uncased''': '''https://huggingface.co/bert-base-uncased/resolve/main/config.json''', '''bert-large-uncased''': '''https://huggingface.co/bert-large-uncased/resolve/main/config.json''', '''bert-base-cased''': '''https://huggingface.co/bert-base-cased/resolve/main/config.json''', '''bert-large-cased''': '''https://huggingface.co/bert-large-cased/resolve/main/config.json''', '''bert-base-multilingual-uncased''': '''https://huggingface.co/bert-base-multilingual-uncased/resolve/main/config.json''', '''bert-base-multilingual-cased''': '''https://huggingface.co/bert-base-multilingual-cased/resolve/main/config.json''', '''bert-base-chinese''': '''https://huggingface.co/bert-base-chinese/resolve/main/config.json''', '''bert-base-german-cased''': '''https://huggingface.co/bert-base-german-cased/resolve/main/config.json''', '''bert-large-uncased-whole-word-masking''': ( '''https://huggingface.co/bert-large-uncased-whole-word-masking/resolve/main/config.json''' ), '''bert-large-cased-whole-word-masking''': ( '''https://huggingface.co/bert-large-cased-whole-word-masking/resolve/main/config.json''' ), '''bert-large-uncased-whole-word-masking-finetuned-squad''': ( '''https://huggingface.co/bert-large-uncased-whole-word-masking-finetuned-squad/resolve/main/config.json''' ), '''bert-large-cased-whole-word-masking-finetuned-squad''': ( '''https://huggingface.co/bert-large-cased-whole-word-masking-finetuned-squad/resolve/main/config.json''' ), '''bert-base-cased-finetuned-mrpc''': '''https://huggingface.co/bert-base-cased-finetuned-mrpc/resolve/main/config.json''', '''bert-base-german-dbmdz-cased''': '''https://huggingface.co/bert-base-german-dbmdz-cased/resolve/main/config.json''', '''bert-base-german-dbmdz-uncased''': '''https://huggingface.co/bert-base-german-dbmdz-uncased/resolve/main/config.json''', '''cl-tohoku/bert-base-japanese''': '''https://huggingface.co/cl-tohoku/bert-base-japanese/resolve/main/config.json''', '''cl-tohoku/bert-base-japanese-whole-word-masking''': ( '''https://huggingface.co/cl-tohoku/bert-base-japanese-whole-word-masking/resolve/main/config.json''' ), '''cl-tohoku/bert-base-japanese-char''': ( '''https://huggingface.co/cl-tohoku/bert-base-japanese-char/resolve/main/config.json''' ), '''cl-tohoku/bert-base-japanese-char-whole-word-masking''': ( '''https://huggingface.co/cl-tohoku/bert-base-japanese-char-whole-word-masking/resolve/main/config.json''' ), '''TurkuNLP/bert-base-finnish-cased-v1''': ( '''https://huggingface.co/TurkuNLP/bert-base-finnish-cased-v1/resolve/main/config.json''' ), '''TurkuNLP/bert-base-finnish-uncased-v1''': ( '''https://huggingface.co/TurkuNLP/bert-base-finnish-uncased-v1/resolve/main/config.json''' ), '''wietsedv/bert-base-dutch-cased''': '''https://huggingface.co/wietsedv/bert-base-dutch-cased/resolve/main/config.json''', # See all BERT models at https://huggingface.co/models?filter=bert } class __lowerCamelCase (_a ): _lowercase = """bert""" def __init__( self: Any,A_: Dict=3_0522,A_: Optional[Any]=768,A_: Union[str, Any]=12,A_: List[Any]=12,A_: Optional[int]=3072,A_: Union[str, Any]="gelu",A_: List[str]=0.1,A_: Dict=0.1,A_: Optional[int]=512,A_: Optional[Any]=2,A_: Union[str, Any]=0.0_2,A_: List[Any]=1E-12,A_: Optional[int]=0,A_: List[Any]="absolute",A_: str=True,A_: Union[str, Any]=None,**A_: int,): '''simple docstring''' super().__init__(pad_token_id=A_,**A_ ) __UpperCamelCase = vocab_size __UpperCamelCase = hidden_size __UpperCamelCase = num_hidden_layers __UpperCamelCase = num_attention_heads __UpperCamelCase = hidden_act __UpperCamelCase = intermediate_size __UpperCamelCase = hidden_dropout_prob __UpperCamelCase = attention_probs_dropout_prob __UpperCamelCase = max_position_embeddings __UpperCamelCase = type_vocab_size __UpperCamelCase = initializer_range __UpperCamelCase = layer_norm_eps __UpperCamelCase = position_embedding_type __UpperCamelCase = use_cache __UpperCamelCase = classifier_dropout class __lowerCamelCase (_a ): @property def snake_case_ ( self: Optional[int] ): '''simple docstring''' if self.task == "multiple-choice": __UpperCamelCase = {0: 'batch', 1: 'choice', 2: 'sequence'} else: __UpperCamelCase = {0: 'batch', 1: 'sequence'} return OrderedDict( [ ('input_ids', dynamic_axis), ('attention_mask', dynamic_axis), ('token_type_ids', dynamic_axis), ] )

import os from shutil import copyfile from typing import List, Optional, Tuple from ...tokenization_utils_fast import PreTrainedTokenizerFast from ...utils import is_sentencepiece_available, logging if is_sentencepiece_available(): from .tokenization_pegasus import PegasusTokenizer else: __snake_case = None __snake_case = logging.get_logger(__name__) __snake_case = '''▁''' __snake_case = {'''vocab_file''': '''spiece.model''', '''tokenizer_file''': '''tokenizer.json'''} __snake_case = { '''vocab_file''': {'''google/pegasus-xsum''': '''https://huggingface.co/google/pegasus-xsum/resolve/main/spiece.model'''}, '''tokenizer_file''': { '''google/pegasus-xsum''': '''https://huggingface.co/google/pegasus-xsum/resolve/main/tokenizer.json''' }, } __snake_case = { '''google/pegasus-xsum''': 5_1_2, } class __lowerCamelCase (_a ): _lowercase = VOCAB_FILES_NAMES _lowercase = PRETRAINED_VOCAB_FILES_MAP _lowercase = PRETRAINED_POSITIONAL_EMBEDDINGS_SIZES _lowercase = PegasusTokenizer _lowercase = ["""input_ids""", """attention_mask"""] def __init__( self: Tuple,A_: Optional[Any]=None,A_: List[str]=None,A_: Dict="<pad>",A_: int="</s>",A_: List[str]="<unk>",A_: Tuple="<mask_2>",A_: Any="<mask_1>",A_: Union[str, Any]=None,A_: Optional[int]=103,**A_: List[str],): '''simple docstring''' __UpperCamelCase = offset if additional_special_tokens is not None: if not isinstance(A_,A_ ): raise TypeError( F'''additional_special_tokens should be of type {type(A_ )}, but is''' F''' {type(A_ )}''' ) __UpperCamelCase = ( ([mask_token_sent] + additional_special_tokens) if mask_token_sent not in additional_special_tokens and mask_token_sent is not None else additional_special_tokens ) # fill additional tokens with ..., <unk_token_102> in case not all additional tokens are already taken additional_special_tokens_extended += [ F'''<unk_{i}>''' for i in range(len(A_ ),self.offset - 1 ) ] if len(set(A_ ) ) != len(A_ ): raise ValueError( 'Please make sure that the provided additional_special_tokens do not contain an incorrectly' F''' shifted list of <unk_x> tokens. Found {additional_special_tokens_extended}.''' ) __UpperCamelCase = additional_special_tokens_extended else: __UpperCamelCase = [mask_token_sent] if mask_token_sent is not None else [] additional_special_tokens += [F'''<unk_{i}>''' for i in range(2,self.offset )] super().__init__( A_,tokenizer_file=A_,pad_token=A_,eos_token=A_,unk_token=A_,mask_token=A_,mask_token_sent=A_,offset=A_,additional_special_tokens=A_,**A_,) __UpperCamelCase = vocab_file __UpperCamelCase = False if not self.vocab_file else True def snake_case_ ( self: Optional[Any],A_: List[str] ): '''simple docstring''' __UpperCamelCase = set(self.all_special_ids ) # call it once instead of inside list comp all_special_ids.remove(self.unk_token_id ) # <unk> is only sometimes special if all_special_ids != set(range(len(self.additional_special_tokens ) + 3 ) ): raise ValueError( 'There should be 3 special tokens: mask_token, pad_token, and eos_token +' F''' {len(self.additional_special_tokens )} additional_special_tokens, but got {all_special_ids}''' ) return [1 if x in all_special_ids else 0 for x in seq] def snake_case_ ( self: List[Any],A_: List,A_: Optional[List] = None,A_: bool = False ): '''simple docstring''' if already_has_special_tokens: return self._special_token_mask(A_ ) elif token_ids_a is None: return self._special_token_mask(A_ ) + [1] else: return self._special_token_mask(token_ids_a + token_ids_a ) + [1] def snake_case_ ( self: int,A_: Dict,A_: List[Any]=None ): '''simple docstring''' if token_ids_a is None: return token_ids_a + [self.eos_token_id] # We don't expect to process pairs, but leave the pair logic for API consistency return token_ids_a + token_ids_a + [self.eos_token_id] def snake_case_ ( self: List[Any],A_: str,A_: Optional[str] = None ): '''simple docstring''' if not self.can_save_slow_tokenizer: raise ValueError( 'Your fast tokenizer does not have the necessary information to save the vocabulary for a slow ' 'tokenizer.' ) if not os.path.isdir(A_ ): logger.error(F'''Vocabulary path ({save_directory}) should be a directory''' ) return __UpperCamelCase = os.path.join( A_,(filename_prefix + '-' if filename_prefix else '') + VOCAB_FILES_NAMES['vocab_file'] ) if os.path.abspath(self.vocab_file ) != os.path.abspath(A_ ): copyfile(self.vocab_file,A_ ) return (out_vocab_file,)

def _A ( _lowercase ) -> int: """simple docstring""" assert column_title.isupper() __UpperCamelCase = 0 __UpperCamelCase = len(_lowercase ) - 1 __UpperCamelCase = 0 while index >= 0: __UpperCamelCase = (ord(column_title[index] ) - 64) * pow(26 , _lowercase ) answer += value power += 1 index -= 1 return answer if __name__ == "__main__": from doctest import testmod testmod()

def _A ( _lowercase , _lowercase ) -> int: """simple docstring""" return abs(_lowercase ) if a == 0 else greatest_common_divisor(b % a , _lowercase ) def _A ( _lowercase , _lowercase ) -> int: """simple docstring""" while y: # --> when y=0 then loop will terminate and return x as final GCD. __UpperCamelCase, __UpperCamelCase = y, x % y return abs(_lowercase ) def _A ( ) -> Optional[int]: """simple docstring""" try: __UpperCamelCase = input('Enter two integers separated by comma (,): ' ).split(',' ) __UpperCamelCase = int(nums[0] ) __UpperCamelCase = int(nums[1] ) print( f'''greatest_common_divisor({num_a}, {num_a}) = ''' f'''{greatest_common_divisor(_lowercase , _lowercase )}''' ) print(f'''By iterative gcd({num_a}, {num_a}) = {gcd_by_iterative(_lowercase , _lowercase )}''' ) except (IndexError, UnboundLocalError, ValueError): print('Wrong input' ) if __name__ == "__main__": main()

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 from lavis.models import load_model_and_preprocess from PIL import Image from transformers import ( AutoTokenizer, BlipaConfig, BlipaForConditionalGeneration, BlipaProcessor, BlipaVisionConfig, BlipImageProcessor, OPTConfig, TaConfig, ) from transformers.utils.constants import OPENAI_CLIP_MEAN, OPENAI_CLIP_STD def _A ( ) -> int: """simple docstring""" __UpperCamelCase = 'https://storage.googleapis.com/sfr-vision-language-research/LAVIS/assets/merlion.png' __UpperCamelCase = Image.open(requests.get(_lowercase , stream=_lowercase ).raw ).convert('RGB' ) return image def _A ( _lowercase ) -> int: """simple docstring""" __UpperCamelCase = [] # 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.layernorm.weight') ) rename_keys.append(('Qformer.bert.embeddings.LayerNorm.bias', 'qformer.layernorm.bias') ) # fmt: on return rename_keys def _A ( _lowercase , _lowercase , _lowercase ) -> Optional[int]: """simple docstring""" __UpperCamelCase = dct.pop(_lowercase ) __UpperCamelCase = val def _A ( _lowercase , _lowercase ) -> int: """simple docstring""" for i in range(config.vision_config.num_hidden_layers ): # read in original q and v biases __UpperCamelCase = state_dict.pop(f'''visual_encoder.blocks.{i}.attn.q_bias''' ) __UpperCamelCase = state_dict.pop(f'''visual_encoder.blocks.{i}.attn.v_bias''' ) # next, set bias in the state dict __UpperCamelCase = torch.cat((q_bias, torch.zeros_like(_lowercase , requires_grad=_lowercase ), v_bias) ) __UpperCamelCase = qkv_bias def _A ( _lowercase , _lowercase ) -> Any: """simple docstring""" __UpperCamelCase = 3_64 if 'coco' in model_name else 2_24 __UpperCamelCase = BlipaVisionConfig(image_size=_lowercase ).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 "opt-2.7b" in model_name: __UpperCamelCase = OPTConfig.from_pretrained('facebook/opt-2.7b' , eos_token_id=_lowercase ).to_dict() elif "opt-6.7b" in model_name: __UpperCamelCase = OPTConfig.from_pretrained('facebook/opt-6.7b' , eos_token_id=_lowercase ).to_dict() elif "t5-xl" in model_name: __UpperCamelCase = TaConfig.from_pretrained('google/flan-t5-xl' , dense_act_fn='gelu' , bos_token_id=1 ).to_dict() elif "t5-xxl" in model_name: __UpperCamelCase = TaConfig.from_pretrained('google/flan-t5-xxl' , dense_act_fn='gelu' , bos_token_id=1 ).to_dict() __UpperCamelCase = BlipaConfig(vision_config=_lowercase , text_config=_lowercase ) return config, image_size @torch.no_grad() def _A ( _lowercase , _lowercase=None , _lowercase=False ) -> Union[str, Any]: """simple docstring""" __UpperCamelCase = ( AutoTokenizer.from_pretrained('facebook/opt-2.7b' ) if 'opt' in model_name else AutoTokenizer.from_pretrained('google/flan-t5-xl' ) ) __UpperCamelCase = tokenizer('\n' , add_special_tokens=_lowercase ).input_ids[0] __UpperCamelCase, __UpperCamelCase = get_blipa_config(_lowercase , eos_token_id=_lowercase ) __UpperCamelCase = BlipaForConditionalGeneration(_lowercase ).eval() __UpperCamelCase = { 'blip2-opt-2.7b': ('blip2_opt', 'pretrain_opt2.7b'), 'blip2-opt-6.7b': ('blip2_opt', 'pretrain_opt6.7b'), 'blip2-opt-2.7b-coco': ('blip2_opt', 'caption_coco_opt2.7b'), 'blip2-opt-6.7b-coco': ('blip2_opt', 'caption_coco_opt6.7b'), 'blip2-flan-t5-xl': ('blip2_t5', 'pretrain_flant5xl'), 'blip2-flan-t5-xl-coco': ('blip2_t5', 'caption_coco_flant5xl'), 'blip2-flan-t5-xxl': ('blip2_t5', 'pretrain_flant5xxl'), } __UpperCamelCase, __UpperCamelCase = model_name_to_original[model_name] # load original model print('Loading original model...' ) __UpperCamelCase = 'cuda' if torch.cuda.is_available() else 'cpu' __UpperCamelCase, __UpperCamelCase, __UpperCamelCase = load_model_and_preprocess( name=_lowercase , model_type=_lowercase , is_eval=_lowercase , device=_lowercase ) original_model.eval() print('Done!' ) # update state dict keys __UpperCamelCase = original_model.state_dict() __UpperCamelCase = create_rename_keys(_lowercase ) for src, dest in rename_keys: rename_key(_lowercase , _lowercase , _lowercase ) # some keys can be renamed efficiently for key, val in state_dict.copy().items(): __UpperCamelCase = state_dict.pop(_lowercase ) if key.startswith('Qformer.bert' ): __UpperCamelCase = key.replace('Qformer.bert' , 'qformer' ) if "attention.self" in key: __UpperCamelCase = key.replace('self' , 'attention' ) if "opt_proj" in key: __UpperCamelCase = key.replace('opt_proj' , 'language_projection' ) if "t5_proj" in key: __UpperCamelCase = key.replace('t5_proj' , 'language_projection' ) if key.startswith('opt' ): __UpperCamelCase = key.replace('opt' , 'language' ) if key.startswith('t5' ): __UpperCamelCase = key.replace('t5' , 'language' ) __UpperCamelCase = val # read in qv biases read_in_q_v_bias(_lowercase , _lowercase ) __UpperCamelCase, __UpperCamelCase = hf_model.load_state_dict(_lowercase , strict=_lowercase ) assert len(_lowercase ) == 0 assert unexpected_keys == ["qformer.embeddings.position_ids"] __UpperCamelCase = load_demo_image() __UpperCamelCase = vis_processors['eval'](_lowercase ).unsqueeze(0 ).to(_lowercase ) __UpperCamelCase = tokenizer(['\n'] , return_tensors='pt' ).input_ids.to(_lowercase ) # create processor __UpperCamelCase = BlipImageProcessor( size={'height': image_size, 'width': image_size} , image_mean=_lowercase , image_std=_lowercase ) __UpperCamelCase = BlipaProcessor(image_processor=_lowercase , tokenizer=_lowercase ) __UpperCamelCase = processor(images=_lowercase , return_tensors='pt' ).pixel_values.to(_lowercase ) # make sure processor creates exact same pixel values assert torch.allclose(_lowercase , _lowercase ) original_model.to(_lowercase ) hf_model.to(_lowercase ) with torch.no_grad(): if "opt" in model_name: __UpperCamelCase = original_model({'image': original_pixel_values, 'text_input': ['']} ).logits __UpperCamelCase = hf_model(_lowercase , _lowercase ).logits else: __UpperCamelCase = original_model( {'image': original_pixel_values, 'text_input': ['\n'], 'text_output': ['\n']} ).logits __UpperCamelCase = input_ids.masked_fill(input_ids == tokenizer.pad_token_id , -1_00 ) __UpperCamelCase = hf_model(_lowercase , _lowercase , labels=_lowercase ).logits assert original_logits.shape == logits.shape print('First values of original logits:' , original_logits[0, :3, :3] ) print('First values of HF logits:' , logits[0, :3, :3] ) # assert values if model_name == "blip2-flan-t5-xl": __UpperCamelCase = torch.tensor( [[-41.58_50, -4.44_40, -8.99_22], [-47.43_22, -5.91_43, -1.73_40]] , device=_lowercase ) assert torch.allclose(logits[0, :3, :3] , _lowercase , atol=1e-4 ) elif model_name == "blip2-flan-t5-xl-coco": __UpperCamelCase = torch.tensor( [[-57.01_09, -9.89_67, -12.62_80], [-68.65_78, -12.71_91, -10.50_65]] , device=_lowercase ) else: # cast to same type __UpperCamelCase = logits.dtype assert torch.allclose(original_logits.to(_lowercase ) , _lowercase , atol=1e-2 ) print('Looks ok!' ) print('Generating a caption...' ) __UpperCamelCase = '' __UpperCamelCase = tokenizer(_lowercase , return_tensors='pt' ).input_ids.to(_lowercase ) __UpperCamelCase = original_model.generate({'image': original_pixel_values} ) __UpperCamelCase = hf_model.generate( _lowercase , _lowercase , do_sample=_lowercase , num_beams=5 , max_length=30 , min_length=1 , top_p=0.9 , repetition_penalty=1.0 , length_penalty=1.0 , temperature=1 , ) print('Original generation:' , _lowercase ) __UpperCamelCase = input_ids.shape[1] __UpperCamelCase = processor.batch_decode(outputs[:, prompt_length:] , skip_special_tokens=_lowercase ) __UpperCamelCase = [text.strip() for text in output_text] print('HF generation:' , _lowercase ) if pytorch_dump_folder_path is not None: processor.save_pretrained(_lowercase ) hf_model.save_pretrained(_lowercase ) if push_to_hub: processor.push_to_hub(f'''nielsr/{model_name}''' ) hf_model.push_to_hub(f'''nielsr/{model_name}''' ) if __name__ == "__main__": __snake_case = argparse.ArgumentParser() __snake_case = [ '''blip2-opt-2.7b''', '''blip2-opt-6.7b''', '''blip2-opt-2.7b-coco''', '''blip2-opt-6.7b-coco''', '''blip2-flan-t5-xl''', '''blip2-flan-t5-xl-coco''', '''blip2-flan-t5-xxl''', ] parser.add_argument( '''--model_name''', default='''blip2-opt-2.7b''', 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)

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/data2vec-text-base''': '''https://huggingface.co/data2vec/resolve/main/config.json''', } class __lowerCamelCase (_a ): _lowercase = """data2vec-text""" def __init__( self: Any,A_: Union[str, Any]=3_0522,A_: Optional[Any]=768,A_: Optional[int]=12,A_: int=12,A_: int=3072,A_: Tuple="gelu",A_: List[str]=0.1,A_: str=0.1,A_: str=512,A_: Union[str, Any]=2,A_: Union[str, Any]=0.0_2,A_: Optional[int]=1E-12,A_: Dict=1,A_: str=0,A_: Any=2,A_: Optional[int]="absolute",A_: Tuple=True,A_: int=None,**A_: List[Any],): '''simple docstring''' super().__init__(pad_token_id=A_,bos_token_id=A_,eos_token_id=A_,**A_ ) __UpperCamelCase = vocab_size __UpperCamelCase = hidden_size __UpperCamelCase = num_hidden_layers __UpperCamelCase = num_attention_heads __UpperCamelCase = hidden_act __UpperCamelCase = intermediate_size __UpperCamelCase = hidden_dropout_prob __UpperCamelCase = attention_probs_dropout_prob __UpperCamelCase = max_position_embeddings __UpperCamelCase = type_vocab_size __UpperCamelCase = initializer_range __UpperCamelCase = layer_norm_eps __UpperCamelCase = position_embedding_type __UpperCamelCase = use_cache __UpperCamelCase = classifier_dropout class __lowerCamelCase (_a ): @property def snake_case_ ( self: Dict ): '''simple docstring''' if self.task == "multiple-choice": __UpperCamelCase = {0: 'batch', 1: 'choice', 2: 'sequence'} else: __UpperCamelCase = {0: 'batch', 1: 'sequence'} return OrderedDict( [ ('input_ids', dynamic_axis), ('attention_mask', dynamic_axis), ] )

import logging import os import sys from dataclasses import dataclass, field from importlib import import_module from typing import Dict, List, Optional, Tuple import numpy as np from seqeval.metrics import accuracy_score, fa_score, precision_score, recall_score from torch import nn from utils_ner import Split, TokenClassificationDataset, TokenClassificationTask import transformers from transformers import ( AutoConfig, AutoModelForTokenClassification, AutoTokenizer, DataCollatorWithPadding, EvalPrediction, HfArgumentParser, Trainer, TrainingArguments, set_seed, ) from transformers.trainer_utils import is_main_process __snake_case = logging.getLogger(__name__) @dataclass class __lowerCamelCase : _lowercase = field( metadata={"""help""": """Path to pretrained model or model identifier from huggingface.co/models"""} ) _lowercase = field( default=_a , metadata={"""help""": """Pretrained config name or path if not the same as model_name"""} ) _lowercase = field( default="""NER""" , metadata={"""help""": """Task type to fine tune in training (e.g. NER, POS, etc)"""} ) _lowercase = field( default=_a , metadata={"""help""": """Pretrained tokenizer name or path if not the same as model_name"""} ) _lowercase = field(default=_a , metadata={"""help""": """Set this flag to use fast tokenization."""} ) # If you want to tweak more attributes on your tokenizer, you should do it in a distinct script, # or just modify its tokenizer_config.json. _lowercase = field( default=_a , metadata={"""help""": """Where do you want to store the pretrained models downloaded from huggingface.co"""} , ) @dataclass class __lowerCamelCase : _lowercase = field( metadata={"""help""": """The input data dir. Should contain the .txt files for a CoNLL-2003-formatted task."""} ) _lowercase = field( default=_a , metadata={"""help""": """Path to a file containing all labels. If not specified, CoNLL-2003 labels are used."""} , ) _lowercase = field( default=128 , metadata={ """help""": ( """The maximum total input sequence length after tokenization. Sequences longer """ """than this will be truncated, sequences shorter will be padded.""" ) } , ) _lowercase = field( default=_a , metadata={"""help""": """Overwrite the cached training and evaluation sets"""} ) def _A ( ) -> str: """simple docstring""" __UpperCamelCase = HfArgumentParser((ModelArguments, DataTrainingArguments, TrainingArguments) ) if len(sys.argv ) == 2 and sys.argv[1].endswith('.json' ): # If we pass only one argument to the script and it's the path to a json file, # let's parse it to get our arguments. __UpperCamelCase, __UpperCamelCase, __UpperCamelCase = parser.parse_json_file(json_file=os.path.abspath(sys.argv[1] ) ) else: __UpperCamelCase, __UpperCamelCase, __UpperCamelCase = parser.parse_args_into_dataclasses() if ( os.path.exists(training_args.output_dir ) and os.listdir(training_args.output_dir ) and training_args.do_train and not training_args.overwrite_output_dir ): raise ValueError( f'''Output directory ({training_args.output_dir}) already exists and is not empty. Use''' ' --overwrite_output_dir to overcome.' ) __UpperCamelCase = import_module('tasks' ) try: __UpperCamelCase = getattr(_lowercase , model_args.task_type ) __UpperCamelCase = token_classification_task_clazz() except AttributeError: raise ValueError( f'''Task {model_args.task_type} needs to be defined as a TokenClassificationTask subclass in {module}. ''' f'''Available tasks classes are: {TokenClassificationTask.__subclasses__()}''' ) # Setup logging logging.basicConfig( format='%(asctime)s - %(levelname)s - %(name)s - %(message)s' , datefmt='%m/%d/%Y %H:%M:%S' , level=logging.INFO if training_args.local_rank in [-1, 0] else logging.WARN , ) logger.warning( 'Process rank: %s, device: %s, n_gpu: %s, distributed training: %s, 16-bits training: %s' , training_args.local_rank , training_args.device , training_args.n_gpu , bool(training_args.local_rank != -1 ) , training_args.fpaa , ) # Set the verbosity to info of the Transformers logger (on main process only): if is_main_process(training_args.local_rank ): transformers.utils.logging.set_verbosity_info() transformers.utils.logging.enable_default_handler() transformers.utils.logging.enable_explicit_format() logger.info('Training/evaluation parameters %s' , _lowercase ) # Set seed set_seed(training_args.seed ) # Prepare CONLL-2003 task __UpperCamelCase = token_classification_task.get_labels(data_args.labels ) __UpperCamelCase = dict(enumerate(_lowercase ) ) __UpperCamelCase = len(_lowercase ) # Load pretrained model and tokenizer # # Distributed training: # The .from_pretrained methods guarantee that only one local process can concurrently # download model & vocab. __UpperCamelCase = AutoConfig.from_pretrained( model_args.config_name if model_args.config_name else model_args.model_name_or_path , num_labels=_lowercase , idalabel=_lowercase , labelaid={label: i for i, label in enumerate(_lowercase )} , cache_dir=model_args.cache_dir , ) __UpperCamelCase = AutoTokenizer.from_pretrained( model_args.tokenizer_name if model_args.tokenizer_name else model_args.model_name_or_path , cache_dir=model_args.cache_dir , use_fast=model_args.use_fast , ) __UpperCamelCase = AutoModelForTokenClassification.from_pretrained( model_args.model_name_or_path , from_tf=bool('.ckpt' in model_args.model_name_or_path ) , config=_lowercase , cache_dir=model_args.cache_dir , ) # Get datasets __UpperCamelCase = ( TokenClassificationDataset( token_classification_task=_lowercase , data_dir=data_args.data_dir , tokenizer=_lowercase , labels=_lowercase , model_type=config.model_type , max_seq_length=data_args.max_seq_length , overwrite_cache=data_args.overwrite_cache , mode=Split.train , ) if training_args.do_train else None ) __UpperCamelCase = ( TokenClassificationDataset( token_classification_task=_lowercase , data_dir=data_args.data_dir , tokenizer=_lowercase , labels=_lowercase , model_type=config.model_type , max_seq_length=data_args.max_seq_length , overwrite_cache=data_args.overwrite_cache , mode=Split.dev , ) if training_args.do_eval else None ) def align_predictions(_lowercase , _lowercase ) -> Tuple[List[int], List[int]]: __UpperCamelCase = np.argmax(_lowercase , axis=2 ) __UpperCamelCase, __UpperCamelCase = preds.shape __UpperCamelCase = [[] for _ in range(_lowercase )] __UpperCamelCase = [[] for _ in range(_lowercase )] for i in range(_lowercase ): for j in range(_lowercase ): if label_ids[i, j] != nn.CrossEntropyLoss().ignore_index: out_label_list[i].append(label_map[label_ids[i][j]] ) preds_list[i].append(label_map[preds[i][j]] ) return preds_list, out_label_list def compute_metrics(_lowercase ) -> Dict: __UpperCamelCase, __UpperCamelCase = align_predictions(p.predictions , p.label_ids ) return { "accuracy_score": accuracy_score(_lowercase , _lowercase ), "precision": precision_score(_lowercase , _lowercase ), "recall": recall_score(_lowercase , _lowercase ), "f1": fa_score(_lowercase , _lowercase ), } # Data collator __UpperCamelCase = DataCollatorWithPadding(_lowercase , pad_to_multiple_of=8 ) if training_args.fpaa else None # Initialize our Trainer __UpperCamelCase = Trainer( model=_lowercase , args=_lowercase , train_dataset=_lowercase , eval_dataset=_lowercase , compute_metrics=_lowercase , data_collator=_lowercase , ) # Training if training_args.do_train: trainer.train( model_path=model_args.model_name_or_path if os.path.isdir(model_args.model_name_or_path ) else None ) trainer.save_model() # For convenience, we also re-save the tokenizer to the same directory, # so that you can share your model easily on huggingface.co/models =) if trainer.is_world_process_zero(): tokenizer.save_pretrained(training_args.output_dir ) # Evaluation __UpperCamelCase = {} if training_args.do_eval: logger.info('*** Evaluate ***' ) __UpperCamelCase = trainer.evaluate() __UpperCamelCase = os.path.join(training_args.output_dir , 'eval_results.txt' ) if trainer.is_world_process_zero(): with open(_lowercase , 'w' ) as writer: logger.info('***** Eval results *****' ) for key, value in result.items(): logger.info(' %s = %s' , _lowercase , _lowercase ) writer.write('%s = %s\n' % (key, value) ) results.update(_lowercase ) # Predict if training_args.do_predict: __UpperCamelCase = TokenClassificationDataset( token_classification_task=_lowercase , data_dir=data_args.data_dir , tokenizer=_lowercase , labels=_lowercase , model_type=config.model_type , max_seq_length=data_args.max_seq_length , overwrite_cache=data_args.overwrite_cache , mode=Split.test , ) __UpperCamelCase, __UpperCamelCase, __UpperCamelCase = trainer.predict(_lowercase ) __UpperCamelCase, __UpperCamelCase = align_predictions(_lowercase , _lowercase ) __UpperCamelCase = os.path.join(training_args.output_dir , 'test_results.txt' ) if trainer.is_world_process_zero(): with open(_lowercase , 'w' ) as writer: for key, value in metrics.items(): logger.info(' %s = %s' , _lowercase , _lowercase ) writer.write('%s = %s\n' % (key, value) ) # Save predictions __UpperCamelCase = os.path.join(training_args.output_dir , 'test_predictions.txt' ) if trainer.is_world_process_zero(): with open(_lowercase , 'w' ) as writer: with open(os.path.join(data_args.data_dir , 'test.txt' ) , 'r' ) as f: token_classification_task.write_predictions_to_file(_lowercase , _lowercase , _lowercase ) return results def _A ( _lowercase ) -> Dict: """simple docstring""" main() if __name__ == "__main__": main()

__snake_case = { '''a''': '''AAAAA''', '''b''': '''AAAAB''', '''c''': '''AAABA''', '''d''': '''AAABB''', '''e''': '''AABAA''', '''f''': '''AABAB''', '''g''': '''AABBA''', '''h''': '''AABBB''', '''i''': '''ABAAA''', '''j''': '''BBBAA''', '''k''': '''ABAAB''', '''l''': '''ABABA''', '''m''': '''ABABB''', '''n''': '''ABBAA''', '''o''': '''ABBAB''', '''p''': '''ABBBA''', '''q''': '''ABBBB''', '''r''': '''BAAAA''', '''s''': '''BAAAB''', '''t''': '''BAABA''', '''u''': '''BAABB''', '''v''': '''BBBAB''', '''w''': '''BABAA''', '''x''': '''BABAB''', '''y''': '''BABBA''', '''z''': '''BABBB''', ''' ''': ''' ''', } __snake_case = {value: key for key, value in encode_dict.items()} def _A ( _lowercase ) -> str: """simple docstring""" __UpperCamelCase = '' for letter in word.lower(): if letter.isalpha() or letter == " ": encoded += encode_dict[letter] else: raise Exception('encode() accepts only letters of the alphabet and spaces' ) return encoded def _A ( _lowercase ) -> str: """simple docstring""" if set(_lowercase ) - {"A", "B", " "} != set(): raise Exception('decode() accepts only \'A\', \'B\' and spaces' ) __UpperCamelCase = '' for word in coded.split(): while len(_lowercase ) != 0: decoded += decode_dict[word[:5]] __UpperCamelCase = word[5:] decoded += " " return decoded.strip() if __name__ == "__main__": from doctest import testmod testmod()

# # This a `torch.distributed` diagnostics script that checks that all GPUs in the cluster (one or # many nodes) can talk to each other via nccl and allocate gpu memory. # # To run first adjust the number of processes and nodes: # # python -m torch.distributed.run --nproc_per_node 2 --nnodes 1 torch-distributed-gpu-test.py # # You may need to add --master_addr $MASTER_ADDR --master_port $MASTER_PORT if using a custom addr:port # # You can also use the rdzv API: --rdzv_endpoint $MASTER_ADDR:$MASTER_PORT --rdzv_backend c10d # # use torch.distributed.launch instead of torch.distributed.run for torch < 1.9 # # If you get a hanging in `barrier` calls you have some network issues, you may try to debug this with: # # NCCL_DEBUG=INFO python -m torch.distributed.run --nproc_per_node 2 --nnodes 1 torch-distributed-gpu-test.py # # which should tell you what's going on behind the scenes. # # # This script can be run via `srun` in the SLURM environment as well. Here is a SLURM script that # runs on 2 nodes of 4 gpus per node: # # #SBATCH --job-name=test-nodes # name # #SBATCH --nodes=2 # nodes # #SBATCH --ntasks-per-node=1 # crucial - only 1 task per dist per node! # #SBATCH --cpus-per-task=10 # number of cores per tasks # #SBATCH --gres=gpu:4 # number of gpus # #SBATCH --time 0:05:00 # maximum execution time (HH:MM:SS) # #SBATCH --output=%x-%j.out # output file name # # GPUS_PER_NODE=4 # MASTER_ADDR=$(scontrol show hostnames $SLURM_JOB_NODELIST | head -n 1) # MASTER_PORT=6000 # # srun --jobid $SLURM_JOBID bash -c 'python -m torch.distributed.run \ # --nproc_per_node $GPUS_PER_NODE --nnodes $SLURM_NNODES --node_rank $SLURM_PROCID \ # --master_addr $MASTER_ADDR --master_port $MASTER_PORT \ # torch-distributed-gpu-test.py' # import fcntl import os import socket import torch import torch.distributed as dist def _A ( *_lowercase ) -> Tuple: """simple docstring""" with open(_lowercase , 'r' ) as fh: fcntl.flock(_lowercase , fcntl.LOCK_EX ) try: print(*_lowercase ) finally: fcntl.flock(_lowercase , fcntl.LOCK_UN ) __snake_case = int(os.environ['''LOCAL_RANK''']) torch.cuda.set_device(local_rank) __snake_case = torch.device('''cuda''', local_rank) __snake_case = socket.gethostname() __snake_case = f"""[{hostname}-{local_rank}]""" try: # test distributed dist.init_process_group('''nccl''') dist.all_reduce(torch.ones(1).to(device), op=dist.ReduceOp.SUM) dist.barrier() # test cuda is available and can allocate memory torch.cuda.is_available() torch.ones(1).cuda(local_rank) # global rank __snake_case = dist.get_rank() __snake_case = dist.get_world_size() printflock(f"""{gpu} is OK (global rank: {rank}/{world_size})""") dist.barrier() if rank == 0: printflock(f"""pt={torch.__version__}, cuda={torch.version.cuda}, nccl={torch.cuda.nccl.version()}""") except Exception: printflock(f"""{gpu} is broken""") raise

from math import pi def _A ( _lowercase , _lowercase ) -> float: """simple docstring""" return 2 * pi * radius * (angle / 3_60) if __name__ == "__main__": print(arc_length(9_0, 1_0))

import pytest import datasets # Import fixture modules as plugins __snake_case = ['''tests.fixtures.files''', '''tests.fixtures.hub''', '''tests.fixtures.fsspec'''] def _A ( _lowercase , _lowercase ) -> Tuple: """simple docstring""" for item in items: if any(marker in item.keywords for marker in ['integration', 'unit'] ): continue item.add_marker(pytest.mark.unit ) def _A ( _lowercase ) -> str: """simple docstring""" config.addinivalue_line('markers' , 'torchaudio_latest: mark test to run with torchaudio>=0.12' ) @pytest.fixture(autouse=_lowercase ) def _A ( _lowercase , _lowercase ) -> Any: """simple docstring""" __UpperCamelCase = tmp_path_factory.getbasetemp() / 'cache' __UpperCamelCase = test_hf_cache_home / 'datasets' __UpperCamelCase = test_hf_cache_home / 'metrics' __UpperCamelCase = test_hf_cache_home / 'modules' monkeypatch.setattr('datasets.config.HF_DATASETS_CACHE' , str(_lowercase ) ) monkeypatch.setattr('datasets.config.HF_METRICS_CACHE' , str(_lowercase ) ) monkeypatch.setattr('datasets.config.HF_MODULES_CACHE' , str(_lowercase ) ) __UpperCamelCase = test_hf_datasets_cache / 'downloads' monkeypatch.setattr('datasets.config.DOWNLOADED_DATASETS_PATH' , str(_lowercase ) ) __UpperCamelCase = test_hf_datasets_cache / 'downloads' / 'extracted' monkeypatch.setattr('datasets.config.EXTRACTED_DATASETS_PATH' , str(_lowercase ) ) @pytest.fixture(autouse=_lowercase , scope='session' ) def _A ( ) -> Dict: """simple docstring""" datasets.disable_progress_bar() @pytest.fixture(autouse=_lowercase ) def _A ( _lowercase ) -> Tuple: """simple docstring""" monkeypatch.setattr('datasets.config.HF_UPDATE_DOWNLOAD_COUNTS' , _lowercase ) @pytest.fixture def _A ( _lowercase ) -> Any: """simple docstring""" monkeypatch.setattr('sqlalchemy.util.deprecations.SILENCE_UBER_WARNING' , _lowercase )

# This is the module that test_patching.py uses to test patch_submodule() import os # noqa: this is just for tests import os as renamed_os # noqa: this is just for tests from os import path # noqa: this is just for tests from os import path as renamed_path # noqa: this is just for tests from os.path import join # noqa: this is just for tests from os.path import join as renamed_join # noqa: this is just for tests __snake_case = open # noqa: we just need to have a builtin inside this module to test it properly

import random import unittest import numpy as np import torch from transformers import CLIPTextConfig, CLIPTextModel, CLIPTokenizer from diffusers import ( AutoencoderKL, DDIMScheduler, UNetaDConditionModel, VideoToVideoSDPipeline, ) from diffusers.utils import floats_tensor, is_xformers_available, skip_mps from diffusers.utils.testing_utils import enable_full_determinism, slow, torch_device from ..pipeline_params import ( TEXT_GUIDED_IMAGE_VARIATION_BATCH_PARAMS, TEXT_GUIDED_IMAGE_VARIATION_PARAMS, ) from ..test_pipelines_common import PipelineTesterMixin enable_full_determinism() @skip_mps class __lowerCamelCase (_a , unittest.TestCase ): _lowercase = VideoToVideoSDPipeline _lowercase = TEXT_GUIDED_IMAGE_VARIATION_PARAMS.union({"""video"""} ) - {"""image""", """width""", """height"""} _lowercase = TEXT_GUIDED_IMAGE_VARIATION_BATCH_PARAMS.union({"""video"""} ) - {"""image"""} _lowercase = PipelineTesterMixin.required_optional_params - {"""latents"""} _lowercase = False # No `output_type`. _lowercase = frozenset( [ """num_inference_steps""", """generator""", """latents""", """return_dict""", """callback""", """callback_steps""", ] ) def snake_case_ ( self: List[str] ): '''simple docstring''' torch.manual_seed(0 ) __UpperCamelCase = UNetaDConditionModel( block_out_channels=(32, 64, 64, 64),layers_per_block=2,sample_size=32,in_channels=4,out_channels=4,down_block_types=('CrossAttnDownBlock3D', 'CrossAttnDownBlock3D', 'CrossAttnDownBlock3D', 'DownBlock3D'),up_block_types=('UpBlock3D', 'CrossAttnUpBlock3D', 'CrossAttnUpBlock3D', 'CrossAttnUpBlock3D'),cross_attention_dim=32,attention_head_dim=4,) __UpperCamelCase = DDIMScheduler( beta_start=0.0_0_0_8_5,beta_end=0.0_1_2,beta_schedule='scaled_linear',clip_sample=A_,set_alpha_to_one=A_,) torch.manual_seed(0 ) __UpperCamelCase = AutoencoderKL( block_out_channels=[32, 64],in_channels=3,out_channels=3,down_block_types=['DownEncoderBlock2D', 'DownEncoderBlock2D'],up_block_types=['UpDecoderBlock2D', 'UpDecoderBlock2D'],latent_channels=4,sample_size=128,) torch.manual_seed(0 ) __UpperCamelCase = 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,) __UpperCamelCase = CLIPTextModel(A_ ) __UpperCamelCase = CLIPTokenizer.from_pretrained('hf-internal-testing/tiny-random-clip' ) __UpperCamelCase = { 'unet': unet, 'scheduler': scheduler, 'vae': vae, 'text_encoder': text_encoder, 'tokenizer': tokenizer, } return components def snake_case_ ( self: Union[str, Any],A_: Any,A_: Any=0 ): '''simple docstring''' __UpperCamelCase = floats_tensor((1, 3, 3, 32, 32),rng=random.Random(A_ ) ).to(A_ ) if str(A_ ).startswith('mps' ): __UpperCamelCase = torch.manual_seed(A_ ) else: __UpperCamelCase = torch.Generator(device=A_ ).manual_seed(A_ ) __UpperCamelCase = { 'prompt': 'A painting of a squirrel eating a burger', 'video': video, 'generator': generator, 'num_inference_steps': 2, 'guidance_scale': 6.0, 'output_type': 'pt', } return inputs def snake_case_ ( self: Union[str, Any] ): '''simple docstring''' __UpperCamelCase = 'cpu' # ensure determinism for the device-dependent torch.Generator __UpperCamelCase = self.get_dummy_components() __UpperCamelCase = VideoToVideoSDPipeline(**A_ ) __UpperCamelCase = sd_pipe.to(A_ ) sd_pipe.set_progress_bar_config(disable=A_ ) __UpperCamelCase = self.get_dummy_inputs(A_ ) __UpperCamelCase = 'np' __UpperCamelCase = sd_pipe(**A_ ).frames __UpperCamelCase = frames[0][-3:, -3:, -1] assert frames[0].shape == (32, 32, 3) __UpperCamelCase = np.array([106, 117, 113, 174, 137, 112, 148, 151, 131] ) assert np.abs(image_slice.flatten() - expected_slice ).max() < 1E-2 @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: Any ): '''simple docstring''' self._test_xformers_attention_forwardGenerator_pass(test_mean_pixel_difference=A_,expected_max_diff=5E-3 ) @unittest.skip(reason='Batching needs to be properly figured out first for this pipeline.' ) def snake_case_ ( self: str ): '''simple docstring''' pass @unittest.skip(reason='Batching needs to be properly figured out first for this pipeline.' ) def snake_case_ ( self: Optional[Any] ): '''simple docstring''' pass @unittest.skip(reason='`num_images_per_prompt` argument is not supported for this pipeline.' ) def snake_case_ ( self: int ): '''simple docstring''' pass def snake_case_ ( self: Any ): '''simple docstring''' return super().test_progress_bar() @slow @skip_mps class __lowerCamelCase (unittest.TestCase ): def snake_case_ ( self: Tuple ): '''simple docstring''' __UpperCamelCase = VideoToVideoSDPipeline.from_pretrained('cerspense/zeroscope_v2_XL',torch_dtype=torch.floataa ) pipe.enable_model_cpu_offload() # 10 frames __UpperCamelCase = torch.Generator(device='cpu' ).manual_seed(0 ) __UpperCamelCase = torch.randn((1, 10, 3, 1024, 576),generator=A_ ) __UpperCamelCase = video.to('cuda' ) __UpperCamelCase = 'Spiderman is surfing' __UpperCamelCase = pipe(A_,video=A_,generator=A_,num_inference_steps=3,output_type='pt' ).frames __UpperCamelCase = np.array([-1.0_4_5_8_9_8_4, -1.1_2_7_9_2_9_7, -0.9_6_6_3_0_8_6, -0.9_1_5_0_3_9_0_6, -0.7_5_0_9_7_6_5_6] ) assert np.abs(video_frames.cpu().numpy()[0, 0, 0, 0, -5:] - expected_array ).sum() < 1E-2

import logging import os import sys from dataclasses import dataclass, field from importlib import import_module from typing import Dict, List, Optional, Tuple import numpy as np from seqeval.metrics import accuracy_score, fa_score, precision_score, recall_score from torch import nn from utils_ner import Split, TokenClassificationDataset, TokenClassificationTask import transformers from transformers import ( AutoConfig, AutoModelForTokenClassification, AutoTokenizer, DataCollatorWithPadding, EvalPrediction, HfArgumentParser, Trainer, TrainingArguments, set_seed, ) from transformers.trainer_utils import is_main_process __snake_case = logging.getLogger(__name__) @dataclass class __lowerCamelCase : _lowercase = field( metadata={"""help""": """Path to pretrained model or model identifier from huggingface.co/models"""} ) _lowercase = field( default=_a , metadata={"""help""": """Pretrained config name or path if not the same as model_name"""} ) _lowercase = field( default="""NER""" , metadata={"""help""": """Task type to fine tune in training (e.g. NER, POS, etc)"""} ) _lowercase = field( default=_a , metadata={"""help""": """Pretrained tokenizer name or path if not the same as model_name"""} ) _lowercase = field(default=_a , metadata={"""help""": """Set this flag to use fast tokenization."""} ) # If you want to tweak more attributes on your tokenizer, you should do it in a distinct script, # or just modify its tokenizer_config.json. _lowercase = field( default=_a , metadata={"""help""": """Where do you want to store the pretrained models downloaded from huggingface.co"""} , ) @dataclass class __lowerCamelCase : _lowercase = field( metadata={"""help""": """The input data dir. Should contain the .txt files for a CoNLL-2003-formatted task."""} ) _lowercase = field( default=_a , metadata={"""help""": """Path to a file containing all labels. If not specified, CoNLL-2003 labels are used."""} , ) _lowercase = field( default=128 , metadata={ """help""": ( """The maximum total input sequence length after tokenization. Sequences longer """ """than this will be truncated, sequences shorter will be padded.""" ) } , ) _lowercase = field( default=_a , metadata={"""help""": """Overwrite the cached training and evaluation sets"""} ) def _A ( ) -> str: """simple docstring""" __UpperCamelCase = HfArgumentParser((ModelArguments, DataTrainingArguments, TrainingArguments) ) if len(sys.argv ) == 2 and sys.argv[1].endswith('.json' ): # If we pass only one argument to the script and it's the path to a json file, # let's parse it to get our arguments. __UpperCamelCase, __UpperCamelCase, __UpperCamelCase = parser.parse_json_file(json_file=os.path.abspath(sys.argv[1] ) ) else: __UpperCamelCase, __UpperCamelCase, __UpperCamelCase = parser.parse_args_into_dataclasses() if ( os.path.exists(training_args.output_dir ) and os.listdir(training_args.output_dir ) and training_args.do_train and not training_args.overwrite_output_dir ): raise ValueError( f'''Output directory ({training_args.output_dir}) already exists and is not empty. Use''' ' --overwrite_output_dir to overcome.' ) __UpperCamelCase = import_module('tasks' ) try: __UpperCamelCase = getattr(_lowercase , model_args.task_type ) __UpperCamelCase = token_classification_task_clazz() except AttributeError: raise ValueError( f'''Task {model_args.task_type} needs to be defined as a TokenClassificationTask subclass in {module}. ''' f'''Available tasks classes are: {TokenClassificationTask.__subclasses__()}''' ) # Setup logging logging.basicConfig( format='%(asctime)s - %(levelname)s - %(name)s - %(message)s' , datefmt='%m/%d/%Y %H:%M:%S' , level=logging.INFO if training_args.local_rank in [-1, 0] else logging.WARN , ) logger.warning( 'Process rank: %s, device: %s, n_gpu: %s, distributed training: %s, 16-bits training: %s' , training_args.local_rank , training_args.device , training_args.n_gpu , bool(training_args.local_rank != -1 ) , training_args.fpaa , ) # Set the verbosity to info of the Transformers logger (on main process only): if is_main_process(training_args.local_rank ): transformers.utils.logging.set_verbosity_info() transformers.utils.logging.enable_default_handler() transformers.utils.logging.enable_explicit_format() logger.info('Training/evaluation parameters %s' , _lowercase ) # Set seed set_seed(training_args.seed ) # Prepare CONLL-2003 task __UpperCamelCase = token_classification_task.get_labels(data_args.labels ) __UpperCamelCase = dict(enumerate(_lowercase ) ) __UpperCamelCase = len(_lowercase ) # Load pretrained model and tokenizer # # Distributed training: # The .from_pretrained methods guarantee that only one local process can concurrently # download model & vocab. __UpperCamelCase = AutoConfig.from_pretrained( model_args.config_name if model_args.config_name else model_args.model_name_or_path , num_labels=_lowercase , idalabel=_lowercase , labelaid={label: i for i, label in enumerate(_lowercase )} , cache_dir=model_args.cache_dir , ) __UpperCamelCase = AutoTokenizer.from_pretrained( model_args.tokenizer_name if model_args.tokenizer_name else model_args.model_name_or_path , cache_dir=model_args.cache_dir , use_fast=model_args.use_fast , ) __UpperCamelCase = AutoModelForTokenClassification.from_pretrained( model_args.model_name_or_path , from_tf=bool('.ckpt' in model_args.model_name_or_path ) , config=_lowercase , cache_dir=model_args.cache_dir , ) # Get datasets __UpperCamelCase = ( TokenClassificationDataset( token_classification_task=_lowercase , data_dir=data_args.data_dir , tokenizer=_lowercase , labels=_lowercase , model_type=config.model_type , max_seq_length=data_args.max_seq_length , overwrite_cache=data_args.overwrite_cache , mode=Split.train , ) if training_args.do_train else None ) __UpperCamelCase = ( TokenClassificationDataset( token_classification_task=_lowercase , data_dir=data_args.data_dir , tokenizer=_lowercase , labels=_lowercase , model_type=config.model_type , max_seq_length=data_args.max_seq_length , overwrite_cache=data_args.overwrite_cache , mode=Split.dev , ) if training_args.do_eval else None ) def align_predictions(_lowercase , _lowercase ) -> Tuple[List[int], List[int]]: __UpperCamelCase = np.argmax(_lowercase , axis=2 ) __UpperCamelCase, __UpperCamelCase = preds.shape __UpperCamelCase = [[] for _ in range(_lowercase )] __UpperCamelCase = [[] for _ in range(_lowercase )] for i in range(_lowercase ): for j in range(_lowercase ): if label_ids[i, j] != nn.CrossEntropyLoss().ignore_index: out_label_list[i].append(label_map[label_ids[i][j]] ) preds_list[i].append(label_map[preds[i][j]] ) return preds_list, out_label_list def compute_metrics(_lowercase ) -> Dict: __UpperCamelCase, __UpperCamelCase = align_predictions(p.predictions , p.label_ids ) return { "accuracy_score": accuracy_score(_lowercase , _lowercase ), "precision": precision_score(_lowercase , _lowercase ), "recall": recall_score(_lowercase , _lowercase ), "f1": fa_score(_lowercase , _lowercase ), } # Data collator __UpperCamelCase = DataCollatorWithPadding(_lowercase , pad_to_multiple_of=8 ) if training_args.fpaa else None # Initialize our Trainer __UpperCamelCase = Trainer( model=_lowercase , args=_lowercase , train_dataset=_lowercase , eval_dataset=_lowercase , compute_metrics=_lowercase , data_collator=_lowercase , ) # Training if training_args.do_train: trainer.train( model_path=model_args.model_name_or_path if os.path.isdir(model_args.model_name_or_path ) else None ) trainer.save_model() # For convenience, we also re-save the tokenizer to the same directory, # so that you can share your model easily on huggingface.co/models =) if trainer.is_world_process_zero(): tokenizer.save_pretrained(training_args.output_dir ) # Evaluation __UpperCamelCase = {} if training_args.do_eval: logger.info('*** Evaluate ***' ) __UpperCamelCase = trainer.evaluate() __UpperCamelCase = os.path.join(training_args.output_dir , 'eval_results.txt' ) if trainer.is_world_process_zero(): with open(_lowercase , 'w' ) as writer: logger.info('***** Eval results *****' ) for key, value in result.items(): logger.info(' %s = %s' , _lowercase , _lowercase ) writer.write('%s = %s\n' % (key, value) ) results.update(_lowercase ) # Predict if training_args.do_predict: __UpperCamelCase = TokenClassificationDataset( token_classification_task=_lowercase , data_dir=data_args.data_dir , tokenizer=_lowercase , labels=_lowercase , model_type=config.model_type , max_seq_length=data_args.max_seq_length , overwrite_cache=data_args.overwrite_cache , mode=Split.test , ) __UpperCamelCase, __UpperCamelCase, __UpperCamelCase = trainer.predict(_lowercase ) __UpperCamelCase, __UpperCamelCase = align_predictions(_lowercase , _lowercase ) __UpperCamelCase = os.path.join(training_args.output_dir , 'test_results.txt' ) if trainer.is_world_process_zero(): with open(_lowercase , 'w' ) as writer: for key, value in metrics.items(): logger.info(' %s = %s' , _lowercase , _lowercase ) writer.write('%s = %s\n' % (key, value) ) # Save predictions __UpperCamelCase = os.path.join(training_args.output_dir , 'test_predictions.txt' ) if trainer.is_world_process_zero(): with open(_lowercase , 'w' ) as writer: with open(os.path.join(data_args.data_dir , 'test.txt' ) , 'r' ) as f: token_classification_task.write_predictions_to_file(_lowercase , _lowercase , _lowercase ) return results def _A ( _lowercase ) -> Dict: """simple docstring""" main() if __name__ == "__main__": main()

import argparse from transformers import CLIPImageProcessor, CLIPVisionModelWithProjection from diffusers import UnCLIPImageVariationPipeline, UnCLIPPipeline if __name__ == "__main__": __snake_case = argparse.ArgumentParser() parser.add_argument('''--dump_path''', default=None, type=str, required=True, help='''Path to the output model.''') parser.add_argument( '''--txt2img_unclip''', default='''kakaobrain/karlo-v1-alpha''', type=str, required=False, help='''The pretrained txt2img unclip.''', ) __snake_case = parser.parse_args() __snake_case = UnCLIPPipeline.from_pretrained(args.txtaimg_unclip) __snake_case = CLIPImageProcessor() __snake_case = CLIPVisionModelWithProjection.from_pretrained('''openai/clip-vit-large-patch14''') __snake_case = UnCLIPImageVariationPipeline( decoder=txtaimg.decoder, text_encoder=txtaimg.text_encoder, tokenizer=txtaimg.tokenizer, text_proj=txtaimg.text_proj, feature_extractor=feature_extractor, image_encoder=image_encoder, super_res_first=txtaimg.super_res_first, super_res_last=txtaimg.super_res_last, decoder_scheduler=txtaimg.decoder_scheduler, super_res_scheduler=txtaimg.super_res_scheduler, ) imgaimg.save_pretrained(args.dump_path)

def _A ( _lowercase , _lowercase , _lowercase ) -> int: """simple docstring""" def count_of_possible_combinations(_lowercase ) -> int: if target < 0: return 0 if target == 0: return 1 return sum(count_of_possible_combinations(target - item ) for item in array ) return count_of_possible_combinations(_lowercase ) def _A ( _lowercase , _lowercase , _lowercase ) -> int: """simple docstring""" def count_of_possible_combinations_with_dp_array( _lowercase , _lowercase ) -> int: if target < 0: return 0 if target == 0: return 1 if dp_array[target] != -1: return dp_array[target] __UpperCamelCase = sum( count_of_possible_combinations_with_dp_array(target - item , _lowercase ) for item in array ) __UpperCamelCase = answer return answer __UpperCamelCase = [-1] * (target + 1) return count_of_possible_combinations_with_dp_array(_lowercase , _lowercase ) def _A ( _lowercase , _lowercase , _lowercase ) -> int: """simple docstring""" __UpperCamelCase = [0] * (target + 1) __UpperCamelCase = 1 for i in range(1 , target + 1 ): for j in range(_lowercase ): if i - array[j] >= 0: dp_array[i] += dp_array[i - array[j]] return dp_array[target] if __name__ == "__main__": import doctest doctest.testmod() __snake_case = 3 __snake_case = 5 __snake_case = [1, 2, 5] print(combination_sum_iv(n, array, target))

from typing import TYPE_CHECKING # rely on isort to merge the imports from ...utils import OptionalDependencyNotAvailable, _LazyModule, is_torch_available __snake_case = { '''configuration_autoformer''': [ '''AUTOFORMER_PRETRAINED_CONFIG_ARCHIVE_MAP''', '''AutoformerConfig''', ], } try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __snake_case = [ '''AUTOFORMER_PRETRAINED_MODEL_ARCHIVE_LIST''', '''AutoformerForPrediction''', '''AutoformerModel''', '''AutoformerPreTrainedModel''', ] if TYPE_CHECKING: from .configuration_autoformer import ( AUTOFORMER_PRETRAINED_CONFIG_ARCHIVE_MAP, AutoformerConfig, ) try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_autoformer import ( AUTOFORMER_PRETRAINED_MODEL_ARCHIVE_LIST, AutoformerForPrediction, AutoformerModel, AutoformerPreTrainedModel, ) else: import sys __snake_case = _LazyModule(__name__, globals()['''__file__'''], _import_structure, module_spec=__spec__)

import gc import unittest import numpy as np import torch from diffusers import AutoencoderKL, DDIMScheduler, DiTPipeline, DPMSolverMultistepScheduler, TransformeraDModel from diffusers.utils import is_xformers_available, load_numpy, slow, torch_device from diffusers.utils.testing_utils import enable_full_determinism, require_torch_gpu from ..pipeline_params import ( CLASS_CONDITIONED_IMAGE_GENERATION_BATCH_PARAMS, CLASS_CONDITIONED_IMAGE_GENERATION_PARAMS, ) from ..test_pipelines_common import PipelineTesterMixin enable_full_determinism() class __lowerCamelCase (_a , unittest.TestCase ): _lowercase = DiTPipeline _lowercase = CLASS_CONDITIONED_IMAGE_GENERATION_PARAMS _lowercase = PipelineTesterMixin.required_optional_params - { """latents""", """num_images_per_prompt""", """callback""", """callback_steps""", } _lowercase = CLASS_CONDITIONED_IMAGE_GENERATION_BATCH_PARAMS _lowercase = False def snake_case_ ( self: Any ): '''simple docstring''' torch.manual_seed(0 ) __UpperCamelCase = TransformeraDModel( sample_size=16,num_layers=2,patch_size=4,attention_head_dim=8,num_attention_heads=2,in_channels=4,out_channels=8,attention_bias=A_,activation_fn='gelu-approximate',num_embeds_ada_norm=1000,norm_type='ada_norm_zero',norm_elementwise_affine=A_,) __UpperCamelCase = AutoencoderKL() __UpperCamelCase = DDIMScheduler() __UpperCamelCase = {'transformer': transformer.eval(), 'vae': vae.eval(), 'scheduler': scheduler} return components def snake_case_ ( self: Optional[Any],A_: Any,A_: int=0 ): '''simple docstring''' if str(A_ ).startswith('mps' ): __UpperCamelCase = torch.manual_seed(A_ ) else: __UpperCamelCase = torch.Generator(device=A_ ).manual_seed(A_ ) __UpperCamelCase = { 'class_labels': [1], 'generator': generator, 'num_inference_steps': 2, 'output_type': 'numpy', } return inputs def snake_case_ ( self: Dict ): '''simple docstring''' __UpperCamelCase = 'cpu' __UpperCamelCase = self.get_dummy_components() __UpperCamelCase = self.pipeline_class(**A_ ) pipe.to(A_ ) pipe.set_progress_bar_config(disable=A_ ) __UpperCamelCase = self.get_dummy_inputs(A_ ) __UpperCamelCase = pipe(**A_ ).images __UpperCamelCase = image[0, -3:, -3:, -1] self.assertEqual(image.shape,(1, 16, 16, 3) ) __UpperCamelCase = np.array([0.2_9_4_6, 0.6_6_0_1, 0.4_3_2_9, 0.3_2_9_6, 0.4_1_4_4, 0.5_3_1_9, 0.7_2_7_3, 0.5_0_1_3, 0.4_4_5_7] ) __UpperCamelCase = np.abs(image_slice.flatten() - expected_slice ).max() self.assertLessEqual(A_,1E-3 ) def snake_case_ ( self: Union[str, Any] ): '''simple docstring''' self._test_inference_batch_single_identical(relax_max_difference=A_,expected_max_diff=1E-3 ) @unittest.skipIf( torch_device != 'cuda' or not is_xformers_available(),reason='XFormers attention is only available with CUDA and `xformers` installed',) def snake_case_ ( self: List[Any] ): '''simple docstring''' self._test_xformers_attention_forwardGenerator_pass(expected_max_diff=1E-3 ) @require_torch_gpu @slow class __lowerCamelCase (unittest.TestCase ): def snake_case_ ( self: str ): '''simple docstring''' super().tearDown() gc.collect() torch.cuda.empty_cache() def snake_case_ ( self: Union[str, Any] ): '''simple docstring''' __UpperCamelCase = torch.manual_seed(0 ) __UpperCamelCase = DiTPipeline.from_pretrained('facebook/DiT-XL-2-256' ) pipe.to('cuda' ) __UpperCamelCase = ['vase', 'umbrella', 'white shark', 'white wolf'] __UpperCamelCase = pipe.get_label_ids(A_ ) __UpperCamelCase = pipe(A_,generator=A_,num_inference_steps=40,output_type='np' ).images for word, image in zip(A_,A_ ): __UpperCamelCase = load_numpy( F'''https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main/dit/{word}.npy''' ) assert np.abs((expected_image - image).max() ) < 1E-2 def snake_case_ ( self: Union[str, Any] ): '''simple docstring''' __UpperCamelCase = DiTPipeline.from_pretrained('facebook/DiT-XL-2-512' ) __UpperCamelCase = DPMSolverMultistepScheduler.from_config(pipe.scheduler.config ) pipe.to('cuda' ) __UpperCamelCase = ['vase', 'umbrella'] __UpperCamelCase = pipe.get_label_ids(A_ ) __UpperCamelCase = torch.manual_seed(0 ) __UpperCamelCase = pipe(A_,generator=A_,num_inference_steps=25,output_type='np' ).images for word, image in zip(A_,A_ ): __UpperCamelCase = load_numpy( 'https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main' F'''/dit/{word}_512.npy''' ) assert np.abs((expected_image - image).max() ) < 1E-1

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 = ''' {0} = None ''' __snake_case = ''' class {0}(metaclass=DummyObject): _backends = {1} def __init__(self, *args, **kwargs): requires_backends(self, {1}) @classmethod def from_config(cls, *args, **kwargs): requires_backends(cls, {1}) @classmethod def from_pretrained(cls, *args, **kwargs): requires_backends(cls, {1}) ''' __snake_case = ''' def {0}(*args, **kwargs): requires_backends({0}, {1}) ''' def _A ( _lowercase ) -> int: """simple docstring""" __UpperCamelCase = _re_backend.findall(_lowercase ) if len(_lowercase ) == 0: return None return "_and_".join(_lowercase ) def _A ( ) -> Tuple: """simple docstring""" with open(os.path.join(_lowercase , '__init__.py' ) , 'r' , encoding='utf-8' , newline='\n' ) as f: __UpperCamelCase = f.readlines() # Get to the point we do the actual imports for type checking __UpperCamelCase = 0 __UpperCamelCase = {} # Go through the end of the file while line_index < len(_lowercase ): # If the line contains is_backend_available, we grab all objects associated with the `else` block __UpperCamelCase = find_backend(lines[line_index] ) if backend is not None: while not lines[line_index].startswith('else:' ): line_index += 1 line_index += 1 __UpperCamelCase = [] # Until we unindent, add backend objects to the list while line_index < len(_lowercase ) and len(lines[line_index] ) > 1: __UpperCamelCase = lines[line_index] __UpperCamelCase = _re_single_line_import.search(_lowercase ) 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(_lowercase ) > 0: __UpperCamelCase = objects else: line_index += 1 return backend_specific_objects def _A ( _lowercase , _lowercase ) -> Union[str, Any]: """simple docstring""" if name.isupper(): return DUMMY_CONSTANT.format(_lowercase ) elif name.islower(): return DUMMY_FUNCTION.format(_lowercase , _lowercase ) else: return DUMMY_CLASS.format(_lowercase , _lowercase ) def _A ( _lowercase=None ) -> Optional[Any]: """simple docstring""" if backend_specific_objects is None: __UpperCamelCase = read_init() # For special correspondence backend to module name as used in the function requires_modulename __UpperCamelCase = {} for backend, objects in backend_specific_objects.items(): __UpperCamelCase = '[' + ', '.join(f'''"{b}"''' for b in backend.split('_and_' ) ) + ']' __UpperCamelCase = '# 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(_lowercase , _lowercase ) for o in objects] ) __UpperCamelCase = dummy_file return dummy_files def _A ( _lowercase=False ) -> List[str]: """simple docstring""" __UpperCamelCase = create_dummy_files() # For special correspondence backend to shortcut as used in utils/dummy_xxx_objects.py __UpperCamelCase = {'torch': 'pt'} # Locate actual dummy modules and read their content. __UpperCamelCase = os.path.join(_lowercase , 'utils' ) __UpperCamelCase = { backend: os.path.join(_lowercase , f'''dummy_{short_names.get(_lowercase , _lowercase )}_objects.py''' ) for backend in dummy_files.keys() } __UpperCamelCase = {} for backend, file_path in dummy_file_paths.items(): if os.path.isfile(_lowercase ): with open(_lowercase , 'r' , encoding='utf-8' , newline='\n' ) as f: __UpperCamelCase = f.read() else: __UpperCamelCase = '' for backend in dummy_files.keys(): if dummy_files[backend] != actual_dummies[backend]: if overwrite: print( f'''Updating diffusers.utils.dummy_{short_names.get(_lowercase , _lowercase )}_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(_lowercase , _lowercase )}_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)

from typing import List, Optional, Tuple, Union import PIL import torch from torchvision import transforms from diffusers.pipeline_utils import DiffusionPipeline, ImagePipelineOutput from diffusers.schedulers import DDIMScheduler from diffusers.utils import randn_tensor __snake_case = transforms.Compose( [ transforms.Resize((2_5_6, 2_5_6)), transforms.ToTensor(), transforms.Normalize([0.5], [0.5]), ] ) def _A ( _lowercase ) -> List[Any]: """simple docstring""" if isinstance(_lowercase , torch.Tensor ): return image elif isinstance(_lowercase , PIL.Image.Image ): __UpperCamelCase = [image] __UpperCamelCase = [trans(img.convert('RGB' ) ) for img in image] __UpperCamelCase = torch.stack(_lowercase ) return image class __lowerCamelCase (_a ): def __init__( self: int,A_: Optional[int],A_: Optional[int] ): '''simple docstring''' super().__init__() # make sure scheduler can always be converted to DDIM __UpperCamelCase = DDIMScheduler.from_config(scheduler.config ) self.register_modules(unet=A_,scheduler=A_ ) def snake_case_ ( self: Optional[int],A_: Optional[Any] ): '''simple docstring''' if strength < 0 or strength > 1: raise ValueError(F'''The value of strength should in [0.0, 1.0] but is {strength}''' ) def snake_case_ ( self: int,A_: Optional[Any],A_: Any,A_: Optional[Any] ): '''simple docstring''' __UpperCamelCase = min(int(num_inference_steps * strength ),A_ ) __UpperCamelCase = max(num_inference_steps - init_timestep,0 ) __UpperCamelCase = self.scheduler.timesteps[t_start:] return timesteps, num_inference_steps - t_start def snake_case_ ( self: Optional[Any],A_: List[str],A_: Optional[Any],A_: Optional[Any],A_: Optional[int],A_: Optional[int],A_: Tuple=None ): '''simple docstring''' if not isinstance(A_,(torch.Tensor, PIL.Image.Image, list) ): raise ValueError( F'''`image` has to be of type `torch.Tensor`, `PIL.Image.Image` or list but is {type(A_ )}''' ) __UpperCamelCase = image.to(device=A_,dtype=A_ ) if isinstance(A_,A_ ) and len(A_ ) != batch_size: raise ValueError( F'''You have passed a list of generators of length {len(A_ )}, but requested an effective batch''' F''' size of {batch_size}. Make sure the batch size matches the length of the generators.''' ) __UpperCamelCase = init_latents.shape __UpperCamelCase = randn_tensor(A_,generator=A_,device=A_,dtype=A_ ) # get latents print('add noise to latents at timestep',A_ ) __UpperCamelCase = self.scheduler.add_noise(A_,A_,A_ ) __UpperCamelCase = init_latents return latents @torch.no_grad() def __call__( self: Any,A_: Union[torch.FloatTensor, PIL.Image.Image] = None,A_: float = 0.8,A_: int = 1,A_: Optional[Union[torch.Generator, List[torch.Generator]]] = None,A_: float = 0.0,A_: int = 50,A_: Optional[bool] = None,A_: Optional[str] = "pil",A_: bool = True,): '''simple docstring''' self.check_inputs(A_ ) # 2. Preprocess image __UpperCamelCase = preprocess(A_ ) # 3. set timesteps self.scheduler.set_timesteps(A_,device=self.device ) __UpperCamelCase, __UpperCamelCase = self.get_timesteps(A_,A_,self.device ) __UpperCamelCase = timesteps[:1].repeat(A_ ) # 4. Prepare latent variables __UpperCamelCase = self.prepare_latents(A_,A_,A_,self.unet.dtype,self.device,A_ ) __UpperCamelCase = latents # 5. Denoising loop for t in self.progress_bar(A_ ): # 1. predict noise model_output __UpperCamelCase = self.unet(A_,A_ ).sample # 2. predict previous mean of image x_t-1 and add variance depending on eta # eta corresponds to η in paper and should be between [0, 1] # do x_t -> x_t-1 __UpperCamelCase = self.scheduler.step( A_,A_,A_,eta=A_,use_clipped_model_output=A_,generator=A_,).prev_sample __UpperCamelCase = (image / 2 + 0.5).clamp(0,1 ) __UpperCamelCase = image.cpu().permute(0,2,3,1 ).numpy() if output_type == "pil": __UpperCamelCase = self.numpy_to_pil(A_ ) if not return_dict: return (image, latent_timestep.item()) return ImagePipelineOutput(images=A_ )

import string def _A ( _lowercase ) -> None: """simple docstring""" for key in range(len(string.ascii_uppercase ) ): __UpperCamelCase = '' for symbol in message: if symbol in string.ascii_uppercase: __UpperCamelCase = string.ascii_uppercase.find(_lowercase ) __UpperCamelCase = num - key if num < 0: __UpperCamelCase = num + len(string.ascii_uppercase ) __UpperCamelCase = translated + string.ascii_uppercase[num] else: __UpperCamelCase = translated + symbol print(f'''Decryption using Key #{key}: {translated}''' ) def _A ( ) -> None: """simple docstring""" __UpperCamelCase = input('Encrypted message: ' ) __UpperCamelCase = message.upper() decrypt(_lowercase ) if __name__ == "__main__": import doctest doctest.testmod() main()

from typing import Optional, Union import torch from torch import nn from ...configuration_utils import ConfigMixin, register_to_config from ...models.modeling_utils import ModelMixin class __lowerCamelCase (_a , _a ): @register_to_config def __init__( self: List[Any],A_: int = 768,): '''simple docstring''' super().__init__() __UpperCamelCase = nn.Parameter(torch.zeros(1,A_ ) ) __UpperCamelCase = nn.Parameter(torch.ones(1,A_ ) ) def snake_case_ ( self: Tuple,A_: Optional[Union[str, torch.device]] = None,A_: Optional[torch.dtype] = None,): '''simple docstring''' __UpperCamelCase = nn.Parameter(self.mean.to(A_ ).to(A_ ) ) __UpperCamelCase = nn.Parameter(self.std.to(A_ ).to(A_ ) ) return self def snake_case_ ( self: Any,A_: Union[str, Any] ): '''simple docstring''' __UpperCamelCase = (embeds - self.mean) * 1.0 / self.std return embeds def snake_case_ ( self: Optional[Any],A_: Optional[int] ): '''simple docstring''' __UpperCamelCase = (embeds * self.std) + self.mean return embeds

import gc import random import unittest import numpy as np import torch from PIL import Image from transformers import XLMRobertaTokenizerFast from diffusers import DDIMScheduler, KandinskyInpaintPipeline, KandinskyPriorPipeline, UNetaDConditionModel, VQModel from diffusers.pipelines.kandinsky.text_encoder import MCLIPConfig, MultilingualCLIP from diffusers.utils import floats_tensor, load_image, load_numpy, slow, torch_device from diffusers.utils.testing_utils import enable_full_determinism, require_torch_gpu from ..test_pipelines_common import PipelineTesterMixin, assert_mean_pixel_difference enable_full_determinism() class __lowerCamelCase (_a , unittest.TestCase ): _lowercase = KandinskyInpaintPipeline _lowercase = ["""prompt""", """image_embeds""", """negative_image_embeds""", """image""", """mask_image"""] _lowercase = [ """prompt""", """negative_prompt""", """image_embeds""", """negative_image_embeds""", """image""", """mask_image""", ] _lowercase = [ """generator""", """height""", """width""", """latents""", """guidance_scale""", """negative_prompt""", """num_inference_steps""", """return_dict""", """guidance_scale""", """num_images_per_prompt""", """output_type""", """return_dict""", ] _lowercase = False @property def snake_case_ ( self: int ): '''simple docstring''' return 32 @property def snake_case_ ( self: str ): '''simple docstring''' return 32 @property def snake_case_ ( self: Tuple ): '''simple docstring''' return self.time_input_dim @property def snake_case_ ( self: Union[str, Any] ): '''simple docstring''' return self.time_input_dim * 4 @property def snake_case_ ( self: Optional[int] ): '''simple docstring''' return 100 @property def snake_case_ ( self: str ): '''simple docstring''' __UpperCamelCase = XLMRobertaTokenizerFast.from_pretrained('YiYiXu/tiny-random-mclip-base' ) return tokenizer @property def snake_case_ ( self: Any ): '''simple docstring''' torch.manual_seed(0 ) __UpperCamelCase = MCLIPConfig( numDims=self.cross_attention_dim,transformerDimensions=self.text_embedder_hidden_size,hidden_size=self.text_embedder_hidden_size,intermediate_size=37,num_attention_heads=4,num_hidden_layers=5,vocab_size=1005,) __UpperCamelCase = MultilingualCLIP(A_ ) __UpperCamelCase = text_encoder.eval() return text_encoder @property def snake_case_ ( self: Any ): '''simple docstring''' torch.manual_seed(0 ) __UpperCamelCase = { 'in_channels': 9, # Out channels is double in channels because predicts mean and variance 'out_channels': 8, 'addition_embed_type': 'text_image', 'down_block_types': ('ResnetDownsampleBlock2D', 'SimpleCrossAttnDownBlock2D'), 'up_block_types': ('SimpleCrossAttnUpBlock2D', 'ResnetUpsampleBlock2D'), 'mid_block_type': 'UNetMidBlock2DSimpleCrossAttn', 'block_out_channels': (self.block_out_channels_a, self.block_out_channels_a * 2), 'layers_per_block': 1, 'encoder_hid_dim': self.text_embedder_hidden_size, 'encoder_hid_dim_type': 'text_image_proj', 'cross_attention_dim': self.cross_attention_dim, 'attention_head_dim': 4, 'resnet_time_scale_shift': 'scale_shift', 'class_embed_type': None, } __UpperCamelCase = UNetaDConditionModel(**A_ ) return model @property def snake_case_ ( self: str ): '''simple docstring''' return { "block_out_channels": [32, 64], "down_block_types": ["DownEncoderBlock2D", "AttnDownEncoderBlock2D"], "in_channels": 3, "latent_channels": 4, "layers_per_block": 1, "norm_num_groups": 8, "norm_type": "spatial", "num_vq_embeddings": 12, "out_channels": 3, "up_block_types": [ "AttnUpDecoderBlock2D", "UpDecoderBlock2D", ], "vq_embed_dim": 4, } @property def snake_case_ ( self: str ): '''simple docstring''' torch.manual_seed(0 ) __UpperCamelCase = VQModel(**self.dummy_movq_kwargs ) return model def snake_case_ ( self: Dict ): '''simple docstring''' __UpperCamelCase = self.dummy_text_encoder __UpperCamelCase = self.dummy_tokenizer __UpperCamelCase = self.dummy_unet __UpperCamelCase = self.dummy_movq __UpperCamelCase = DDIMScheduler( num_train_timesteps=1000,beta_schedule='linear',beta_start=0.0_0_0_8_5,beta_end=0.0_1_2,clip_sample=A_,set_alpha_to_one=A_,steps_offset=1,prediction_type='epsilon',thresholding=A_,) __UpperCamelCase = { 'text_encoder': text_encoder, 'tokenizer': tokenizer, 'unet': unet, 'scheduler': scheduler, 'movq': movq, } return components def snake_case_ ( self: Tuple,A_: Optional[int],A_: Dict=0 ): '''simple docstring''' __UpperCamelCase = floats_tensor((1, self.cross_attention_dim),rng=random.Random(A_ ) ).to(A_ ) __UpperCamelCase = floats_tensor((1, self.cross_attention_dim),rng=random.Random(seed + 1 ) ).to(A_ ) # create init_image __UpperCamelCase = floats_tensor((1, 3, 64, 64),rng=random.Random(A_ ) ).to(A_ ) __UpperCamelCase = image.cpu().permute(0,2,3,1 )[0] __UpperCamelCase = Image.fromarray(np.uinta(A_ ) ).convert('RGB' ).resize((256, 256) ) # create mask __UpperCamelCase = np.ones((64, 64),dtype=np.floataa ) __UpperCamelCase = 0 if str(A_ ).startswith('mps' ): __UpperCamelCase = torch.manual_seed(A_ ) else: __UpperCamelCase = torch.Generator(device=A_ ).manual_seed(A_ ) __UpperCamelCase = { 'prompt': 'horse', 'image': init_image, 'mask_image': mask, 'image_embeds': image_embeds, 'negative_image_embeds': negative_image_embeds, 'generator': generator, 'height': 64, 'width': 64, 'num_inference_steps': 2, 'guidance_scale': 4.0, 'output_type': 'np', } return inputs def snake_case_ ( self: Any ): '''simple docstring''' __UpperCamelCase = 'cpu' __UpperCamelCase = self.get_dummy_components() __UpperCamelCase = self.pipeline_class(**A_ ) __UpperCamelCase = pipe.to(A_ ) pipe.set_progress_bar_config(disable=A_ ) __UpperCamelCase = pipe(**self.get_dummy_inputs(A_ ) ) __UpperCamelCase = output.images __UpperCamelCase = pipe( **self.get_dummy_inputs(A_ ),return_dict=A_,)[0] __UpperCamelCase = image[0, -3:, -3:, -1] __UpperCamelCase = image_from_tuple[0, -3:, -3:, -1] print(F'''image.shape {image.shape}''' ) assert image.shape == (1, 64, 64, 3) __UpperCamelCase = np.array( [0.8_3_2_6_9_1_9, 0.7_3_7_9_0_4_6_7, 0.2_0_9_1_8_5_8_1, 0.9_3_0_9_6_1_2, 0.5_5_1_1_7_9_1, 0.4_3_7_1_3_3_2_8, 0.5_5_1_3_3_2_1, 0.4_9_9_2_2_9_3_4, 0.5_9_4_9_7_7_8_6] ) assert ( np.abs(image_slice.flatten() - expected_slice ).max() < 1E-2 ), F''' expected_slice {expected_slice}, but got {image_slice.flatten()}''' assert ( np.abs(image_from_tuple_slice.flatten() - expected_slice ).max() < 1E-2 ), F''' expected_slice {expected_slice}, but got {image_from_tuple_slice.flatten()}''' def snake_case_ ( self: Optional[Any] ): '''simple docstring''' super().test_inference_batch_single_identical(expected_max_diff=3E-3 ) @slow @require_torch_gpu class __lowerCamelCase (unittest.TestCase ): def snake_case_ ( self: Tuple ): '''simple docstring''' super().tearDown() gc.collect() torch.cuda.empty_cache() def snake_case_ ( self: Any ): '''simple docstring''' __UpperCamelCase = load_numpy( 'https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main' '/kandinsky/kandinsky_inpaint_cat_with_hat_fp16.npy' ) __UpperCamelCase = load_image( 'https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main' '/kandinsky/cat.png' ) __UpperCamelCase = np.ones((768, 768),dtype=np.floataa ) __UpperCamelCase = 0 __UpperCamelCase = 'a hat' __UpperCamelCase = KandinskyPriorPipeline.from_pretrained( 'kandinsky-community/kandinsky-2-1-prior',torch_dtype=torch.floataa ) pipe_prior.to(A_ ) __UpperCamelCase = KandinskyInpaintPipeline.from_pretrained( 'kandinsky-community/kandinsky-2-1-inpaint',torch_dtype=torch.floataa ) __UpperCamelCase = pipeline.to(A_ ) pipeline.set_progress_bar_config(disable=A_ ) __UpperCamelCase = torch.Generator(device='cpu' ).manual_seed(0 ) __UpperCamelCase, __UpperCamelCase = pipe_prior( A_,generator=A_,num_inference_steps=5,negative_prompt='',).to_tuple() __UpperCamelCase = pipeline( A_,image=A_,mask_image=A_,image_embeds=A_,negative_image_embeds=A_,generator=A_,num_inference_steps=100,height=768,width=768,output_type='np',) __UpperCamelCase = output.images[0] assert image.shape == (768, 768, 3) assert_mean_pixel_difference(A_,A_ )

import argparse from transformers import CLIPImageProcessor, CLIPVisionModelWithProjection from diffusers import UnCLIPImageVariationPipeline, UnCLIPPipeline if __name__ == "__main__": __snake_case = argparse.ArgumentParser() parser.add_argument('''--dump_path''', default=None, type=str, required=True, help='''Path to the output model.''') parser.add_argument( '''--txt2img_unclip''', default='''kakaobrain/karlo-v1-alpha''', type=str, required=False, help='''The pretrained txt2img unclip.''', ) __snake_case = parser.parse_args() __snake_case = UnCLIPPipeline.from_pretrained(args.txtaimg_unclip) __snake_case = CLIPImageProcessor() __snake_case = CLIPVisionModelWithProjection.from_pretrained('''openai/clip-vit-large-patch14''') __snake_case = UnCLIPImageVariationPipeline( decoder=txtaimg.decoder, text_encoder=txtaimg.text_encoder, tokenizer=txtaimg.tokenizer, text_proj=txtaimg.text_proj, feature_extractor=feature_extractor, image_encoder=image_encoder, super_res_first=txtaimg.super_res_first, super_res_last=txtaimg.super_res_last, decoder_scheduler=txtaimg.decoder_scheduler, super_res_scheduler=txtaimg.super_res_scheduler, ) imgaimg.save_pretrained(args.dump_path)

from typing import Any class __lowerCamelCase : def __init__( self: int,A_: Any ): '''simple docstring''' __UpperCamelCase = data __UpperCamelCase = None def __repr__( self: Any ): '''simple docstring''' return F'''Node({self.data})''' class __lowerCamelCase : def __init__( self: Union[str, Any] ): '''simple docstring''' __UpperCamelCase = None def __iter__( self: int ): '''simple docstring''' __UpperCamelCase = self.head while node: yield node.data __UpperCamelCase = node.next def __len__( self: List[str] ): '''simple docstring''' return sum(1 for _ in self ) def __repr__( self: Any ): '''simple docstring''' return "->".join([str(A_ ) for item in self] ) def __getitem__( self: int,A_: int ): '''simple docstring''' if not 0 <= index < len(self ): raise ValueError('list index out of range.' ) for i, node in enumerate(self ): if i == index: return node return None def __setitem__( self: int,A_: int,A_: Any ): '''simple docstring''' if not 0 <= index < len(self ): raise ValueError('list index out of range.' ) __UpperCamelCase = self.head for _ in range(A_ ): __UpperCamelCase = current.next __UpperCamelCase = data def snake_case_ ( self: Union[str, Any],A_: Any ): '''simple docstring''' self.insert_nth(len(self ),A_ ) def snake_case_ ( self: List[Any],A_: Any ): '''simple docstring''' self.insert_nth(0,A_ ) def snake_case_ ( self: Optional[Any],A_: int,A_: Any ): '''simple docstring''' if not 0 <= index <= len(self ): raise IndexError('list index out of range' ) __UpperCamelCase = Node(A_ ) if self.head is None: __UpperCamelCase = new_node elif index == 0: __UpperCamelCase = self.head # link new_node to head __UpperCamelCase = new_node else: __UpperCamelCase = self.head for _ in range(index - 1 ): __UpperCamelCase = temp.next __UpperCamelCase = temp.next __UpperCamelCase = new_node def snake_case_ ( self: str ): # print every node data '''simple docstring''' print(self ) def snake_case_ ( self: int ): '''simple docstring''' return self.delete_nth(0 ) def snake_case_ ( self: str ): # delete from tail '''simple docstring''' return self.delete_nth(len(self ) - 1 ) def snake_case_ ( self: Any,A_: int = 0 ): '''simple docstring''' if not 0 <= index <= len(self ) - 1: # test if index is valid raise IndexError('List index out of range.' ) __UpperCamelCase = self.head # default first node if index == 0: __UpperCamelCase = self.head.next else: __UpperCamelCase = self.head for _ in range(index - 1 ): __UpperCamelCase = temp.next __UpperCamelCase = temp.next __UpperCamelCase = temp.next.next return delete_node.data def snake_case_ ( self: Any ): '''simple docstring''' return self.head is None def snake_case_ ( self: Optional[int] ): '''simple docstring''' __UpperCamelCase = None __UpperCamelCase = self.head while current: # Store the current node's next node. __UpperCamelCase = current.next # Make the current node's next point backwards __UpperCamelCase = prev # Make the previous node be the current node __UpperCamelCase = current # Make the current node the next node (to progress iteration) __UpperCamelCase = next_node # Return prev in order to put the head at the end __UpperCamelCase = prev def _A ( ) -> None: """simple docstring""" __UpperCamelCase = LinkedList() assert linked_list.is_empty() is True assert str(_lowercase ) == "" try: linked_list.delete_head() raise AssertionError # This should not happen. except IndexError: assert True # This should happen. try: linked_list.delete_tail() raise AssertionError # This should not happen. except IndexError: assert True # This should happen. for i in range(10 ): assert len(_lowercase ) == i linked_list.insert_nth(_lowercase , i + 1 ) assert str(_lowercase ) == "->".join(str(_lowercase ) for i in range(1 , 11 ) ) linked_list.insert_head(0 ) linked_list.insert_tail(11 ) assert str(_lowercase ) == "->".join(str(_lowercase ) for i in range(0 , 12 ) ) assert linked_list.delete_head() == 0 assert linked_list.delete_nth(9 ) == 10 assert linked_list.delete_tail() == 11 assert len(_lowercase ) == 9 assert str(_lowercase ) == "->".join(str(_lowercase ) for i in range(1 , 10 ) ) assert all(linked_list[i] == i + 1 for i in range(0 , 9 ) ) is True for i in range(0 , 9 ): __UpperCamelCase = -i assert all(linked_list[i] == -i for i in range(0 , 9 ) ) is True linked_list.reverse() assert str(_lowercase ) == "->".join(str(_lowercase ) for i in range(-8 , 1 ) ) def _A ( ) -> None: """simple docstring""" __UpperCamelCase = [ -9, 1_00, Node(77_34_51_12 ), 'dlrow olleH', 7, 55_55, 0, -1_92.5_55_55, 'Hello, world!', 77.9, Node(10 ), None, None, 12.20, ] __UpperCamelCase = LinkedList() for i in test_input: linked_list.insert_tail(_lowercase ) # Check if it's empty or not assert linked_list.is_empty() is False assert ( str(_lowercase ) == "-9->100->Node(77345112)->dlrow olleH->7->5555->0->" "-192.55555->Hello, world!->77.9->Node(10)->None->None->12.2" ) # Delete the head __UpperCamelCase = linked_list.delete_head() assert result == -9 assert ( str(_lowercase ) == "100->Node(77345112)->dlrow olleH->7->5555->0->-192.55555->" "Hello, world!->77.9->Node(10)->None->None->12.2" ) # Delete the tail __UpperCamelCase = linked_list.delete_tail() assert result == 12.2 assert ( str(_lowercase ) == "100->Node(77345112)->dlrow olleH->7->5555->0->-192.55555->" "Hello, world!->77.9->Node(10)->None->None" ) # Delete a node in specific location in linked list __UpperCamelCase = linked_list.delete_nth(10 ) assert result is None assert ( str(_lowercase ) == "100->Node(77345112)->dlrow olleH->7->5555->0->-192.55555->" "Hello, world!->77.9->Node(10)->None" ) # Add a Node instance to its head linked_list.insert_head(Node('Hello again, world!' ) ) assert ( str(_lowercase ) == "Node(Hello again, world!)->100->Node(77345112)->dlrow olleH->" "7->5555->0->-192.55555->Hello, world!->77.9->Node(10)->None" ) # Add None to its tail linked_list.insert_tail(_lowercase ) assert ( str(_lowercase ) == "Node(Hello again, world!)->100->Node(77345112)->dlrow olleH->" "7->5555->0->-192.55555->Hello, world!->77.9->Node(10)->None->None" ) # Reverse the linked list linked_list.reverse() assert ( str(_lowercase ) == "None->None->Node(10)->77.9->Hello, world!->-192.55555->0->5555->" "7->dlrow olleH->Node(77345112)->100->Node(Hello again, world!)" ) def _A ( ) -> List[str]: """simple docstring""" from doctest import testmod testmod() __UpperCamelCase = LinkedList() linked_list.insert_head(input('Inserting 1st at head ' ).strip() ) linked_list.insert_head(input('Inserting 2nd at head ' ).strip() ) print('\nPrint list:' ) linked_list.print_list() linked_list.insert_tail(input('\nInserting 1st at tail ' ).strip() ) linked_list.insert_tail(input('Inserting 2nd at tail ' ).strip() ) print('\nPrint list:' ) linked_list.print_list() print('\nDelete head' ) linked_list.delete_head() print('Delete tail' ) linked_list.delete_tail() print('\nPrint list:' ) linked_list.print_list() print('\nReverse linked list' ) linked_list.reverse() print('\nPrint list:' ) linked_list.print_list() print('\nString representation of linked list:' ) print(_lowercase ) print('\nReading/changing Node data using indexing:' ) print(f'''Element at Position 1: {linked_list[1]}''' ) __UpperCamelCase = input('Enter New Value: ' ).strip() print('New list:' ) print(_lowercase ) print(f'''length of linked_list is : {len(_lowercase )}''' ) if __name__ == "__main__": main()

from pathlib import PurePosixPath from typing import Optional import fsspec from fsspec import AbstractFileSystem from huggingface_hub.hf_api import DatasetInfo from ..utils.file_utils import get_authentication_headers_for_url from ..utils.hub import hf_hub_url class __lowerCamelCase (_a ): _lowercase = """""" _lowercase = """hf-legacy""" # "hf://"" is reserved for hffs def __init__( self: Tuple,A_: Optional[DatasetInfo] = None,A_: Optional[str] = None,**A_: List[str],): '''simple docstring''' super().__init__(self,**A_ ) __UpperCamelCase = repo_info __UpperCamelCase = token __UpperCamelCase = None def snake_case_ ( self: Union[str, Any] ): '''simple docstring''' if self.dir_cache is None: __UpperCamelCase = {} for hf_file in self.repo_info.siblings: # TODO(QL): add sizes __UpperCamelCase = { 'name': hf_file.rfilename, 'size': None, 'type': 'file', } self.dir_cache.update( { str(A_ ): {'name': str(A_ ), 'size': None, 'type': 'directory'} for d in list(PurePosixPath(hf_file.rfilename ).parents )[:-1] } ) def snake_case_ ( self: Any,A_: str,A_: str = "rb",**A_: str,): '''simple docstring''' if not isinstance(self.repo_info,A_ ): raise NotImplementedError(F'''Open is only implemented for dataset repositories, but got {self.repo_info}''' ) __UpperCamelCase = hf_hub_url(self.repo_info.id,A_,revision=self.repo_info.sha ) return fsspec.open( A_,mode=A_,headers=get_authentication_headers_for_url(A_,use_auth_token=self.token ),client_kwargs={'trust_env': True},).open() def snake_case_ ( self: int,A_: Optional[int],**A_: Any ): '''simple docstring''' self._get_dirs() __UpperCamelCase = self._strip_protocol(A_ ) if path in self.dir_cache: return self.dir_cache[path] else: raise FileNotFoundError(A_ ) def snake_case_ ( self: List[Any],A_: Union[str, Any],A_: Any=False,**A_: Any ): '''simple docstring''' self._get_dirs() __UpperCamelCase = PurePosixPath(path.strip('/' ) ) __UpperCamelCase = {} for p, f in self.dir_cache.items(): __UpperCamelCase = PurePosixPath(p.strip('/' ) ) __UpperCamelCase = p.parent if root == path: __UpperCamelCase = f __UpperCamelCase = list(paths.values() ) if detail: return out else: return sorted(f['name'] for f in out )

from typing import TYPE_CHECKING from ...utils import ( OptionalDependencyNotAvailable, _LazyModule, is_flax_available, is_tf_available, is_torch_available, ) __snake_case = {'''configuration_unispeech''': ['''UNISPEECH_PRETRAINED_CONFIG_ARCHIVE_MAP''', '''UniSpeechConfig''']} try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __snake_case = [ '''UNISPEECH_PRETRAINED_MODEL_ARCHIVE_LIST''', '''UniSpeechForCTC''', '''UniSpeechForPreTraining''', '''UniSpeechForSequenceClassification''', '''UniSpeechModel''', '''UniSpeechPreTrainedModel''', ] if TYPE_CHECKING: from .configuration_unispeech import UNISPEECH_PRETRAINED_CONFIG_ARCHIVE_MAP, UniSpeechConfig try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_unispeech import ( UNISPEECH_PRETRAINED_MODEL_ARCHIVE_LIST, UniSpeechForCTC, UniSpeechForPreTraining, UniSpeechForSequenceClassification, UniSpeechModel, UniSpeechPreTrainedModel, ) else: import sys __snake_case = _LazyModule(__name__, globals()['''__file__'''], _import_structure, module_spec=__spec__)

from math import pi, sqrt def _A ( _lowercase ) -> float: """simple docstring""" if num <= 0: raise ValueError('math domain error' ) if num > 1_71.5: raise OverflowError('math range error' ) elif num - int(_lowercase ) not in (0, 0.5): raise NotImplementedError('num must be an integer or a half-integer' ) elif num == 0.5: return sqrt(_lowercase ) else: return 1.0 if num == 1 else (num - 1) * gamma(num - 1 ) def _A ( ) -> None: """simple docstring""" assert gamma(0.5 ) == sqrt(_lowercase ) assert gamma(1 ) == 1.0 assert gamma(2 ) == 1.0 if __name__ == "__main__": from doctest import testmod testmod() __snake_case = 1.0 while num: __snake_case = float(input('''Gamma of: ''')) print(f"""gamma({num}) = {gamma(num)}""") print('''\nEnter 0 to exit...''')

__snake_case = { '''a''': '''AAAAA''', '''b''': '''AAAAB''', '''c''': '''AAABA''', '''d''': '''AAABB''', '''e''': '''AABAA''', '''f''': '''AABAB''', '''g''': '''AABBA''', '''h''': '''AABBB''', '''i''': '''ABAAA''', '''j''': '''BBBAA''', '''k''': '''ABAAB''', '''l''': '''ABABA''', '''m''': '''ABABB''', '''n''': '''ABBAA''', '''o''': '''ABBAB''', '''p''': '''ABBBA''', '''q''': '''ABBBB''', '''r''': '''BAAAA''', '''s''': '''BAAAB''', '''t''': '''BAABA''', '''u''': '''BAABB''', '''v''': '''BBBAB''', '''w''': '''BABAA''', '''x''': '''BABAB''', '''y''': '''BABBA''', '''z''': '''BABBB''', ''' ''': ''' ''', } __snake_case = {value: key for key, value in encode_dict.items()} def _A ( _lowercase ) -> str: """simple docstring""" __UpperCamelCase = '' for letter in word.lower(): if letter.isalpha() or letter == " ": encoded += encode_dict[letter] else: raise Exception('encode() accepts only letters of the alphabet and spaces' ) return encoded def _A ( _lowercase ) -> str: """simple docstring""" if set(_lowercase ) - {"A", "B", " "} != set(): raise Exception('decode() accepts only \'A\', \'B\' and spaces' ) __UpperCamelCase = '' for word in coded.split(): while len(_lowercase ) != 0: decoded += decode_dict[word[:5]] __UpperCamelCase = word[5:] decoded += " " return decoded.strip() if __name__ == "__main__": from doctest import testmod testmod()

import datasets from .evaluate import evaluate __snake_case = '''\ @inproceedings{Rajpurkar2016SQuAD10, title={SQuAD: 100, 000+ Questions for Machine Comprehension of Text}, author={Pranav Rajpurkar and Jian Zhang and Konstantin Lopyrev and Percy Liang}, booktitle={EMNLP}, year={2016} } ''' __snake_case = ''' This metric wrap the official scoring script for version 1 of the Stanford Question Answering Dataset (SQuAD). Stanford Question Answering Dataset (SQuAD) is a reading comprehension dataset, consisting of questions posed by crowdworkers on a set of Wikipedia articles, where the answer to every question is a segment of text, or span, from the corresponding reading passage, or the question might be unanswerable. ''' __snake_case = ''' Computes SQuAD scores (F1 and EM). Args: predictions: List of question-answers dictionaries with the following key-values: - \'id\': id of the question-answer pair as given in the references (see below) - \'prediction_text\': the text of the answer references: List of question-answers dictionaries with the following key-values: - \'id\': id of the question-answer pair (see above), - \'answers\': a Dict in the SQuAD dataset format { \'text\': list of possible texts for the answer, as a list of strings \'answer_start\': list of start positions for the answer, as a list of ints } Note that answer_start values are not taken into account to compute the metric. Returns: \'exact_match\': Exact match (the normalized answer exactly match the gold answer) \'f1\': The F-score of predicted tokens versus the gold answer Examples: >>> predictions = [{\'prediction_text\': \'1976\', \'id\': \'56e10a3be3433e1400422b22\'}] >>> references = [{\'answers\': {\'answer_start\': [97], \'text\': [\'1976\']}, \'id\': \'56e10a3be3433e1400422b22\'}] >>> squad_metric = datasets.load_metric("squad") >>> results = squad_metric.compute(predictions=predictions, references=references) >>> print(results) {\'exact_match\': 100.0, \'f1\': 100.0} ''' @datasets.utils.file_utils.add_start_docstrings(_DESCRIPTION , _KWARGS_DESCRIPTION ) class __lowerCamelCase (datasets.Metric ): def snake_case_ ( self: Union[str, Any] ): '''simple docstring''' return datasets.MetricInfo( description=_DESCRIPTION,citation=_CITATION,inputs_description=_KWARGS_DESCRIPTION,features=datasets.Features( { 'predictions': {'id': datasets.Value('string' ), 'prediction_text': datasets.Value('string' )}, 'references': { 'id': datasets.Value('string' ), 'answers': datasets.features.Sequence( { 'text': datasets.Value('string' ), 'answer_start': datasets.Value('int32' ), } ), }, } ),codebase_urls=['https://rajpurkar.github.io/SQuAD-explorer/'],reference_urls=['https://rajpurkar.github.io/SQuAD-explorer/'],) def snake_case_ ( self: int,A_: int,A_: int ): '''simple docstring''' __UpperCamelCase = {prediction['id']: prediction['prediction_text'] for prediction in predictions} __UpperCamelCase = [ { 'paragraphs': [ { 'qas': [ { 'answers': [{'text': answer_text} for answer_text in ref['answers']['text']], 'id': ref['id'], } for ref in references ] } ] } ] __UpperCamelCase = evaluate(dataset=A_,predictions=A_ ) return score

from collections.abc import Generator from math import sin def _A ( _lowercase ) -> bytes: """simple docstring""" if len(_lowercase ) != 32: raise ValueError('Input must be of length 32' ) __UpperCamelCase = B'' for i in [3, 2, 1, 0]: little_endian += string_aa[8 * i : 8 * i + 8] return little_endian def _A ( _lowercase ) -> bytes: """simple docstring""" if i < 0: raise ValueError('Input must be non-negative' ) __UpperCamelCase = format(_lowercase , '08x' )[-8:] __UpperCamelCase = 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 ( _lowercase ) -> bytes: """simple docstring""" __UpperCamelCase = B'' for char in message: bit_string += format(_lowercase , '08b' ).encode('utf-8' ) __UpperCamelCase = format(len(_lowercase ) , '064b' ).encode('utf-8' ) # Pad bit_string to a multiple of 512 chars bit_string += b"1" while len(_lowercase ) % 5_12 != 4_48: bit_string += b"0" bit_string += to_little_endian(start_len[32:] ) + to_little_endian(start_len[:32] ) return bit_string def _A ( _lowercase ) -> Generator[list[int], None, None]: """simple docstring""" if len(_lowercase ) % 5_12 != 0: raise ValueError('Input must have length that\'s a multiple of 512' ) for pos in range(0 , len(_lowercase ) , 5_12 ): __UpperCamelCase = bit_string[pos : pos + 5_12] __UpperCamelCase = [] for i in range(0 , 5_12 , 32 ): block_words.append(int(to_little_endian(block[i : i + 32] ) , 2 ) ) yield block_words def _A ( _lowercase ) -> int: """simple docstring""" if i < 0: raise ValueError('Input must be non-negative' ) __UpperCamelCase = format(_lowercase , '032b' ) __UpperCamelCase = '' for c in i_str: new_str += "1" if c == "0" else "0" return int(_lowercase , 2 ) def _A ( _lowercase , _lowercase ) -> int: """simple docstring""" return (a + b) % 2**32 def _A ( _lowercase , _lowercase ) -> int: """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 ( _lowercase ) -> bytes: """simple docstring""" __UpperCamelCase = preprocess(_lowercase ) __UpperCamelCase = [int(2**32 * abs(sin(i + 1 ) ) ) for i in range(64 )] # Starting states __UpperCamelCase = 0X67_45_23_01 __UpperCamelCase = 0Xef_cd_ab_89 __UpperCamelCase = 0X98_ba_dc_fe __UpperCamelCase = 0X10_32_54_76 __UpperCamelCase = [ 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(_lowercase ): __UpperCamelCase = aa __UpperCamelCase = ba __UpperCamelCase = ca __UpperCamelCase = da # Hash current chunk for i in range(64 ): if i <= 15: # f = (b & c) | (not_32(b) & d) # Alternate definition for f __UpperCamelCase = d ^ (b & (c ^ d)) __UpperCamelCase = i elif i <= 31: # f = (d & b) | (not_32(d) & c) # Alternate definition for f __UpperCamelCase = c ^ (d & (b ^ c)) __UpperCamelCase = (5 * i + 1) % 16 elif i <= 47: __UpperCamelCase = b ^ c ^ d __UpperCamelCase = (3 * i + 5) % 16 else: __UpperCamelCase = c ^ (b | not_aa(_lowercase )) __UpperCamelCase = (7 * i) % 16 __UpperCamelCase = (f + a + added_consts[i] + block_words[g]) % 2**32 __UpperCamelCase = d __UpperCamelCase = c __UpperCamelCase = b __UpperCamelCase = sum_aa(_lowercase , left_rotate_aa(_lowercase , shift_amounts[i] ) ) # Add hashed chunk to running total __UpperCamelCase = sum_aa(_lowercase , _lowercase ) __UpperCamelCase = sum_aa(_lowercase , _lowercase ) __UpperCamelCase = sum_aa(_lowercase , _lowercase ) __UpperCamelCase = sum_aa(_lowercase , _lowercase ) __UpperCamelCase = reformat_hex(_lowercase ) + reformat_hex(_lowercase ) + reformat_hex(_lowercase ) + reformat_hex(_lowercase ) return digest if __name__ == "__main__": import doctest doctest.testmod()

# # This a `torch.distributed` diagnostics script that checks that all GPUs in the cluster (one or # many nodes) can talk to each other via nccl and allocate gpu memory. # # To run first adjust the number of processes and nodes: # # python -m torch.distributed.run --nproc_per_node 2 --nnodes 1 torch-distributed-gpu-test.py # # You may need to add --master_addr $MASTER_ADDR --master_port $MASTER_PORT if using a custom addr:port # # You can also use the rdzv API: --rdzv_endpoint $MASTER_ADDR:$MASTER_PORT --rdzv_backend c10d # # use torch.distributed.launch instead of torch.distributed.run for torch < 1.9 # # If you get a hanging in `barrier` calls you have some network issues, you may try to debug this with: # # NCCL_DEBUG=INFO python -m torch.distributed.run --nproc_per_node 2 --nnodes 1 torch-distributed-gpu-test.py # # which should tell you what's going on behind the scenes. # # # This script can be run via `srun` in the SLURM environment as well. Here is a SLURM script that # runs on 2 nodes of 4 gpus per node: # # #SBATCH --job-name=test-nodes # name # #SBATCH --nodes=2 # nodes # #SBATCH --ntasks-per-node=1 # crucial - only 1 task per dist per node! # #SBATCH --cpus-per-task=10 # number of cores per tasks # #SBATCH --gres=gpu:4 # number of gpus # #SBATCH --time 0:05:00 # maximum execution time (HH:MM:SS) # #SBATCH --output=%x-%j.out # output file name # # GPUS_PER_NODE=4 # MASTER_ADDR=$(scontrol show hostnames $SLURM_JOB_NODELIST | head -n 1) # MASTER_PORT=6000 # # srun --jobid $SLURM_JOBID bash -c 'python -m torch.distributed.run \ # --nproc_per_node $GPUS_PER_NODE --nnodes $SLURM_NNODES --node_rank $SLURM_PROCID \ # --master_addr $MASTER_ADDR --master_port $MASTER_PORT \ # torch-distributed-gpu-test.py' # import fcntl import os import socket import torch import torch.distributed as dist def _A ( *_lowercase ) -> Tuple: """simple docstring""" with open(_lowercase , 'r' ) as fh: fcntl.flock(_lowercase , fcntl.LOCK_EX ) try: print(*_lowercase ) finally: fcntl.flock(_lowercase , fcntl.LOCK_UN ) __snake_case = int(os.environ['''LOCAL_RANK''']) torch.cuda.set_device(local_rank) __snake_case = torch.device('''cuda''', local_rank) __snake_case = socket.gethostname() __snake_case = f"""[{hostname}-{local_rank}]""" try: # test distributed dist.init_process_group('''nccl''') dist.all_reduce(torch.ones(1).to(device), op=dist.ReduceOp.SUM) dist.barrier() # test cuda is available and can allocate memory torch.cuda.is_available() torch.ones(1).cuda(local_rank) # global rank __snake_case = dist.get_rank() __snake_case = dist.get_world_size() printflock(f"""{gpu} is OK (global rank: {rank}/{world_size})""") dist.barrier() if rank == 0: printflock(f"""pt={torch.__version__}, cuda={torch.version.cuda}, nccl={torch.cuda.nccl.version()}""") except Exception: printflock(f"""{gpu} is broken""") raise

from __future__ import annotations import time from math import sqrt # 1 for manhattan, 0 for euclidean __snake_case = 0 __snake_case = [ [0, 0, 0, 0, 0, 0, 0], [0, 1, 0, 0, 0, 0, 0], # 0 are free path whereas 1's are obstacles [0, 0, 0, 0, 0, 0, 0], [0, 0, 1, 0, 0, 0, 0], [1, 0, 1, 0, 0, 0, 0], [0, 0, 0, 0, 0, 0, 0], [0, 0, 0, 0, 1, 0, 0], ] __snake_case = [[-1, 0], [0, -1], [1, 0], [0, 1]] # up, left, down, right __snake_case = tuple[int, int] class __lowerCamelCase : def __init__( self: str,A_: int,A_: int,A_: int,A_: int,A_: int,A_: Node | None,): '''simple docstring''' __UpperCamelCase = pos_x __UpperCamelCase = pos_y __UpperCamelCase = (pos_y, pos_x) __UpperCamelCase = goal_x __UpperCamelCase = goal_y __UpperCamelCase = g_cost __UpperCamelCase = parent __UpperCamelCase = self.calculate_heuristic() __UpperCamelCase = self.g_cost + self.h_cost def snake_case_ ( self: str ): '''simple docstring''' __UpperCamelCase = self.pos_x - self.goal_x __UpperCamelCase = self.pos_y - self.goal_y if HEURISTIC == 1: return abs(A_ ) + abs(A_ ) else: return sqrt(dy**2 + dx**2 ) def __lt__( self: int,A_: Node ): '''simple docstring''' return self.f_cost < other.f_cost class __lowerCamelCase : def __init__( self: Any,A_: TPosition,A_: TPosition ): '''simple docstring''' __UpperCamelCase = Node(start[1],start[0],goal[1],goal[0],0,A_ ) __UpperCamelCase = Node(goal[1],goal[0],goal[1],goal[0],9_9999,A_ ) __UpperCamelCase = [self.start] __UpperCamelCase = [] __UpperCamelCase = False def snake_case_ ( self: Any ): '''simple docstring''' while self.open_nodes: # Open Nodes are sorted using __lt__ self.open_nodes.sort() __UpperCamelCase = self.open_nodes.pop(0 ) if current_node.pos == self.target.pos: return self.retrace_path(A_ ) self.closed_nodes.append(A_ ) __UpperCamelCase = self.get_successors(A_ ) for child_node in successors: if child_node in self.closed_nodes: continue if child_node not in self.open_nodes: self.open_nodes.append(A_ ) else: # retrieve the best current path __UpperCamelCase = self.open_nodes.pop(self.open_nodes.index(A_ ) ) if child_node.g_cost < better_node.g_cost: self.open_nodes.append(A_ ) else: self.open_nodes.append(A_ ) return [self.start.pos] def snake_case_ ( self: int,A_: Node ): '''simple docstring''' __UpperCamelCase = [] for action in delta: __UpperCamelCase = parent.pos_x + action[1] __UpperCamelCase = parent.pos_y + action[0] if not (0 <= pos_x <= len(grid[0] ) - 1 and 0 <= pos_y <= len(A_ ) - 1): continue if grid[pos_y][pos_x] != 0: continue successors.append( Node( A_,A_,self.target.pos_y,self.target.pos_x,parent.g_cost + 1,A_,) ) return successors def snake_case_ ( self: Any,A_: Node | None ): '''simple docstring''' __UpperCamelCase = node __UpperCamelCase = [] while current_node is not None: path.append((current_node.pos_y, current_node.pos_x) ) __UpperCamelCase = current_node.parent path.reverse() return path class __lowerCamelCase : def __init__( self: List[Any],A_: TPosition,A_: TPosition ): '''simple docstring''' __UpperCamelCase = AStar(A_,A_ ) __UpperCamelCase = AStar(A_,A_ ) __UpperCamelCase = False def snake_case_ ( self: Union[str, Any] ): '''simple docstring''' while self.fwd_astar.open_nodes or self.bwd_astar.open_nodes: self.fwd_astar.open_nodes.sort() self.bwd_astar.open_nodes.sort() __UpperCamelCase = self.fwd_astar.open_nodes.pop(0 ) __UpperCamelCase = self.bwd_astar.open_nodes.pop(0 ) if current_bwd_node.pos == current_fwd_node.pos: return self.retrace_bidirectional_path( A_,A_ ) self.fwd_astar.closed_nodes.append(A_ ) self.bwd_astar.closed_nodes.append(A_ ) __UpperCamelCase = current_bwd_node __UpperCamelCase = current_fwd_node __UpperCamelCase = { self.fwd_astar: self.fwd_astar.get_successors(A_ ), self.bwd_astar: self.bwd_astar.get_successors(A_ ), } for astar in [self.fwd_astar, self.bwd_astar]: for child_node in successors[astar]: if child_node in astar.closed_nodes: continue if child_node not in astar.open_nodes: astar.open_nodes.append(A_ ) else: # retrieve the best current path __UpperCamelCase = astar.open_nodes.pop( astar.open_nodes.index(A_ ) ) if child_node.g_cost < better_node.g_cost: astar.open_nodes.append(A_ ) else: astar.open_nodes.append(A_ ) return [self.fwd_astar.start.pos] def snake_case_ ( self: List[str],A_: Node,A_: Node ): '''simple docstring''' __UpperCamelCase = self.fwd_astar.retrace_path(A_ ) __UpperCamelCase = self.bwd_astar.retrace_path(A_ ) bwd_path.pop() bwd_path.reverse() __UpperCamelCase = fwd_path + bwd_path return path if __name__ == "__main__": # all coordinates are given in format [y,x] __snake_case = (0, 0) __snake_case = (len(grid) - 1, len(grid[0]) - 1) for elem in grid: print(elem) __snake_case = time.time() __snake_case = AStar(init, goal) __snake_case = a_star.search() __snake_case = time.time() - start_time print(f"""AStar execution time = {end_time:f} seconds""") __snake_case = time.time() __snake_case = BidirectionalAStar(init, goal) __snake_case = time.time() - bd_start_time print(f"""BidirectionalAStar execution time = {bd_end_time:f} seconds""")

import unittest import numpy as np from transformers.testing_utils import require_pytesseract, require_torch from transformers.utils import is_pytesseract_available, is_torch_available from ...test_image_processing_common import ImageProcessingSavingTestMixin, prepare_image_inputs if is_torch_available(): import torch if is_pytesseract_available(): from PIL import Image from transformers import LayoutLMvaImageProcessor class __lowerCamelCase (unittest.TestCase ): def __init__( self: List[Any],A_: Dict,A_: List[str]=7,A_: Dict=3,A_: int=18,A_: Optional[Any]=30,A_: Dict=400,A_: int=True,A_: Tuple=None,A_: Any=True,): '''simple docstring''' __UpperCamelCase = size if size is not None else {'height': 18, 'width': 18} __UpperCamelCase = parent __UpperCamelCase = batch_size __UpperCamelCase = num_channels __UpperCamelCase = image_size __UpperCamelCase = min_resolution __UpperCamelCase = max_resolution __UpperCamelCase = do_resize __UpperCamelCase = size __UpperCamelCase = apply_ocr def snake_case_ ( self: Dict ): '''simple docstring''' return {"do_resize": self.do_resize, "size": self.size, "apply_ocr": self.apply_ocr} @require_torch @require_pytesseract class __lowerCamelCase (_a , unittest.TestCase ): _lowercase = LayoutLMvaImageProcessor if is_pytesseract_available() else None def snake_case_ ( self: Tuple ): '''simple docstring''' __UpperCamelCase = LayoutLMvaImageProcessingTester(self ) @property def snake_case_ ( self: List[str] ): '''simple docstring''' return self.image_processor_tester.prepare_image_processor_dict() def snake_case_ ( self: List[Any] ): '''simple docstring''' __UpperCamelCase = self.image_processing_class(**self.image_processor_dict ) self.assertTrue(hasattr(A_,'do_resize' ) ) self.assertTrue(hasattr(A_,'size' ) ) self.assertTrue(hasattr(A_,'apply_ocr' ) ) def snake_case_ ( self: Union[str, Any] ): '''simple docstring''' __UpperCamelCase = self.image_processing_class.from_dict(self.image_processor_dict ) self.assertEqual(image_processor.size,{'height': 18, 'width': 18} ) __UpperCamelCase = self.image_processing_class.from_dict(self.image_processor_dict,size=42 ) self.assertEqual(image_processor.size,{'height': 42, 'width': 42} ) def snake_case_ ( self: Union[str, Any] ): '''simple docstring''' pass def snake_case_ ( self: Any ): '''simple docstring''' __UpperCamelCase = self.image_processing_class(**self.image_processor_dict ) # create random PIL images __UpperCamelCase = prepare_image_inputs(self.image_processor_tester,equal_resolution=A_ ) for image in image_inputs: self.assertIsInstance(A_,Image.Image ) # Test not batched input __UpperCamelCase = image_processing(image_inputs[0],return_tensors='pt' ) self.assertEqual( encoding.pixel_values.shape,( 1, self.image_processor_tester.num_channels, self.image_processor_tester.size['height'], self.image_processor_tester.size['width'], ),) self.assertIsInstance(encoding.words,A_ ) self.assertIsInstance(encoding.boxes,A_ ) # Test batched __UpperCamelCase = image_processing(A_,return_tensors='pt' ).pixel_values self.assertEqual( encoded_images.shape,( self.image_processor_tester.batch_size, self.image_processor_tester.num_channels, self.image_processor_tester.size['height'], self.image_processor_tester.size['width'], ),) def snake_case_ ( self: Optional[Any] ): '''simple docstring''' __UpperCamelCase = self.image_processing_class(**self.image_processor_dict ) # create random numpy tensors __UpperCamelCase = prepare_image_inputs(self.image_processor_tester,equal_resolution=A_,numpify=A_ ) for image in image_inputs: self.assertIsInstance(A_,np.ndarray ) # Test not batched input __UpperCamelCase = image_processing(image_inputs[0],return_tensors='pt' ).pixel_values self.assertEqual( encoded_images.shape,( 1, self.image_processor_tester.num_channels, self.image_processor_tester.size['height'], self.image_processor_tester.size['width'], ),) # Test batched __UpperCamelCase = image_processing(A_,return_tensors='pt' ).pixel_values self.assertEqual( encoded_images.shape,( self.image_processor_tester.batch_size, self.image_processor_tester.num_channels, self.image_processor_tester.size['height'], self.image_processor_tester.size['width'], ),) def snake_case_ ( self: Dict ): '''simple docstring''' __UpperCamelCase = self.image_processing_class(**self.image_processor_dict ) # create random PyTorch tensors __UpperCamelCase = prepare_image_inputs(self.image_processor_tester,equal_resolution=A_,torchify=A_ ) for image in image_inputs: self.assertIsInstance(A_,torch.Tensor ) # Test not batched input __UpperCamelCase = image_processing(image_inputs[0],return_tensors='pt' ).pixel_values self.assertEqual( encoded_images.shape,( 1, self.image_processor_tester.num_channels, self.image_processor_tester.size['height'], self.image_processor_tester.size['width'], ),) # Test batched __UpperCamelCase = image_processing(A_,return_tensors='pt' ).pixel_values self.assertEqual( encoded_images.shape,( self.image_processor_tester.batch_size, self.image_processor_tester.num_channels, self.image_processor_tester.size['height'], self.image_processor_tester.size['width'], ),) def snake_case_ ( self: Tuple ): '''simple docstring''' __UpperCamelCase = LayoutLMvaImageProcessor() from datasets import load_dataset __UpperCamelCase = load_dataset('hf-internal-testing/fixtures_docvqa',split='test' ) __UpperCamelCase = Image.open(ds[0]['file'] ).convert('RGB' ) __UpperCamelCase = image_processing(A_,return_tensors='pt' ) self.assertEqual(encoding.pixel_values.shape,(1, 3, 224, 224) ) self.assertEqual(len(encoding.words ),len(encoding.boxes ) ) # fmt: off # the words and boxes were obtained with Tesseract 4.1.1 __UpperCamelCase = [['11:14', 'to', '11:39', 'a.m', '11:39', 'to', '11:44', 'a.m.', '11:44', 'a.m.', 'to', '12:25', 'p.m.', '12:25', 'to', '12:58', 'p.m.', '12:58', 'to', '4:00', 'p.m.', '2:00', 'to', '5:00', 'p.m.', 'Coffee', 'Break', 'Coffee', 'will', 'be', 'served', 'for', 'men', 'and', 'women', 'in', 'the', 'lobby', 'adjacent', 'to', 'exhibit', 'area.', 'Please', 'move', 'into', 'exhibit', 'area.', '(Exhibits', 'Open)', 'TRRF', 'GENERAL', 'SESSION', '(PART', '|)', 'Presiding:', 'Lee', 'A.', 'Waller', 'TRRF', 'Vice', 'President', '“Introductory', 'Remarks”', 'Lee', 'A.', 'Waller,', 'TRRF', 'Vice', 'Presi-', 'dent', 'Individual', 'Interviews', 'with', 'TRRF', 'Public', 'Board', 'Members', 'and', 'Sci-', 'entific', 'Advisory', 'Council', 'Mem-', 'bers', 'Conducted', 'by', 'TRRF', 'Treasurer', 'Philip', 'G.', 'Kuehn', 'to', 'get', 'answers', 'which', 'the', 'public', 'refrigerated', 'warehousing', 'industry', 'is', 'looking', 'for.', 'Plus', 'questions', 'from', 'the', 'floor.', 'Dr.', 'Emil', 'M.', 'Mrak,', 'University', 'of', 'Cal-', 'ifornia,', 'Chairman,', 'TRRF', 'Board;', 'Sam', 'R.', 'Cecil,', 'University', 'of', 'Georgia', 'College', 'of', 'Agriculture;', 'Dr.', 'Stanley', 'Charm,', 'Tufts', 'University', 'School', 'of', 'Medicine;', 'Dr.', 'Robert', 'H.', 'Cotton,', 'ITT', 'Continental', 'Baking', 'Company;', 'Dr.', 'Owen', 'Fennema,', 'University', 'of', 'Wis-', 'consin;', 'Dr.', 'Robert', 'E.', 'Hardenburg,', 'USDA.', 'Questions', 'and', 'Answers', 'Exhibits', 'Open', 'Capt.', 'Jack', 'Stoney', 'Room', 'TRRF', 'Scientific', 'Advisory', 'Council', 'Meeting', 'Ballroom', 'Foyer']] # noqa: E231 __UpperCamelCase = [[[141, 57, 214, 69], [228, 58, 252, 69], [141, 75, 216, 88], [230, 79, 280, 88], [142, 260, 218, 273], [230, 261, 255, 273], [143, 279, 218, 290], [231, 282, 290, 291], [143, 342, 218, 354], [231, 345, 289, 355], [202, 362, 227, 373], [143, 379, 220, 392], [231, 382, 291, 394], [144, 714, 220, 726], [231, 715, 256, 726], [144, 732, 220, 745], [232, 736, 291, 747], [144, 769, 218, 782], [231, 770, 256, 782], [141, 788, 202, 801], [215, 791, 274, 804], [143, 826, 204, 838], [215, 826, 240, 838], [142, 844, 202, 857], [215, 847, 274, 859], [334, 57, 427, 69], [440, 57, 522, 69], [369, 75, 461, 88], [469, 75, 516, 88], [528, 76, 562, 88], [570, 76, 667, 88], [675, 75, 711, 87], [721, 79, 778, 88], [789, 75, 840, 88], [369, 97, 470, 107], [484, 94, 507, 106], [518, 94, 562, 107], [576, 94, 655, 110], [668, 94, 792, 109], [804, 95, 829, 107], [369, 113, 465, 125], [477, 116, 547, 125], [562, 113, 658, 125], [671, 116, 748, 125], [761, 113, 811, 125], [369, 131, 465, 143], [477, 133, 548, 143], [563, 130, 698, 145], [710, 130, 802, 146], [336, 171, 412, 183], [423, 171, 572, 183], [582, 170, 716, 184], [728, 171, 817, 187], [829, 171, 844, 186], [338, 197, 482, 212], [507, 196, 557, 209], [569, 196, 595, 208], [610, 196, 702, 209], [505, 214, 583, 226], [595, 214, 656, 227], [670, 215, 807, 227], [335, 259, 543, 274], [556, 259, 708, 272], [372, 279, 422, 291], [435, 279, 460, 291], [474, 279, 574, 292], [587, 278, 664, 291], [676, 278, 738, 291], [751, 279, 834, 291], [372, 298, 434, 310], [335, 341, 483, 354], [497, 341, 655, 354], [667, 341, 728, 354], [740, 341, 825, 354], [335, 360, 430, 372], [442, 360, 534, 372], [545, 359, 687, 372], [697, 360, 754, 372], [765, 360, 823, 373], [334, 378, 428, 391], [440, 378, 577, 394], [590, 378, 705, 391], [720, 378, 801, 391], [334, 397, 400, 409], [370, 416, 529, 429], [544, 416, 576, 432], [587, 416, 665, 428], [677, 416, 814, 429], [372, 435, 452, 450], [465, 434, 495, 447], [511, 434, 600, 447], [611, 436, 637, 447], [649, 436, 694, 451], [705, 438, 824, 447], [369, 453, 452, 466], [464, 454, 509, 466], [522, 453, 611, 469], [625, 453, 792, 469], [370, 472, 556, 488], [570, 472, 684, 487], [697, 472, 718, 485], [732, 472, 835, 488], [369, 490, 411, 503], [425, 490, 484, 503], [496, 490, 635, 506], [645, 490, 707, 503], [718, 491, 761, 503], [771, 490, 840, 503], [336, 510, 374, 521], [388, 510, 447, 522], [460, 510, 489, 521], [503, 510, 580, 522], [592, 509, 736, 525], [745, 509, 770, 522], [781, 509, 840, 522], [338, 528, 434, 541], [448, 528, 596, 541], [609, 527, 687, 540], [700, 528, 792, 541], [336, 546, 397, 559], [407, 546, 431, 559], [443, 546, 525, 560], [537, 546, 680, 562], [688, 546, 714, 559], [722, 546, 837, 562], [336, 565, 449, 581], [461, 565, 485, 577], [497, 565, 665, 581], [681, 565, 718, 577], [732, 565, 837, 580], [337, 584, 438, 597], [452, 583, 521, 596], [535, 584, 677, 599], [690, 583, 787, 596], [801, 583, 825, 596], [338, 602, 478, 615], [492, 602, 530, 614], [543, 602, 638, 615], [650, 602, 676, 614], [688, 602, 788, 615], [802, 602, 843, 614], [337, 621, 502, 633], [516, 621, 615, 637], [629, 621, 774, 636], [789, 621, 827, 633], [337, 639, 418, 652], [432, 640, 571, 653], [587, 639, 731, 655], [743, 639, 769, 652], [780, 639, 841, 652], [338, 658, 440, 673], [455, 658, 491, 670], [508, 658, 602, 671], [616, 658, 638, 670], [654, 658, 835, 674], [337, 677, 429, 689], [337, 714, 482, 726], [495, 714, 548, 726], [561, 714, 683, 726], [338, 770, 461, 782], [474, 769, 554, 785], [489, 788, 562, 803], [576, 788, 643, 801], [656, 787, 751, 804], [764, 788, 844, 801], [334, 825, 421, 838], [430, 824, 574, 838], [584, 824, 723, 841], [335, 844, 450, 857], [464, 843, 583, 860], [628, 862, 755, 875], [769, 861, 848, 878]]] # noqa: E231 # fmt: on self.assertListEqual(encoding.words,A_ ) self.assertListEqual(encoding.boxes,A_ ) # with apply_OCR = False __UpperCamelCase = LayoutLMvaImageProcessor(apply_ocr=A_ ) __UpperCamelCase = image_processing(A_,return_tensors='pt' ) self.assertEqual(encoding.pixel_values.shape,(1, 3, 224, 224) )

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 AutoFeatureExtractor, WavaVecaFeatureExtractor 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_feature_extraction import CustomFeatureExtractor # noqa E402 __snake_case = get_tests_dir('''fixtures''') class __lowerCamelCase (unittest.TestCase ): def snake_case_ ( self: int ): '''simple docstring''' __UpperCamelCase = mock.Mock() __UpperCamelCase = 500 __UpperCamelCase = {} __UpperCamelCase = HTTPError __UpperCamelCase = {} # Download this model to make sure it's in the cache. __UpperCamelCase = WavaVecaFeatureExtractor.from_pretrained('hf-internal-testing/tiny-random-wav2vec2' ) # 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: __UpperCamelCase = WavaVecaFeatureExtractor.from_pretrained('hf-internal-testing/tiny-random-wav2vec2' ) # This check we did call the fake head request mock_head.assert_called() def snake_case_ ( self: Dict ): '''simple docstring''' __UpperCamelCase = WavaVecaFeatureExtractor.from_pretrained( 'https://huggingface.co/hf-internal-testing/tiny-random-wav2vec2/resolve/main/preprocessor_config.json' ) @is_staging_test class __lowerCamelCase (unittest.TestCase ): @classmethod def snake_case_ ( cls: Tuple ): '''simple docstring''' __UpperCamelCase = TOKEN HfFolder.save_token(A_ ) @classmethod def snake_case_ ( cls: Tuple ): '''simple docstring''' try: delete_repo(token=cls._token,repo_id='test-feature-extractor' ) except HTTPError: pass try: delete_repo(token=cls._token,repo_id='valid_org/test-feature-extractor-org' ) except HTTPError: pass try: delete_repo(token=cls._token,repo_id='test-dynamic-feature-extractor' ) except HTTPError: pass def snake_case_ ( self: Tuple ): '''simple docstring''' __UpperCamelCase = WavaVecaFeatureExtractor.from_pretrained(A_ ) feature_extractor.push_to_hub('test-feature-extractor',use_auth_token=self._token ) __UpperCamelCase = WavaVecaFeatureExtractor.from_pretrained(F'''{USER}/test-feature-extractor''' ) for k, v in feature_extractor.__dict__.items(): self.assertEqual(A_,getattr(A_,A_ ) ) # Reset repo delete_repo(token=self._token,repo_id='test-feature-extractor' ) # Push to hub via save_pretrained with tempfile.TemporaryDirectory() as tmp_dir: feature_extractor.save_pretrained( A_,repo_id='test-feature-extractor',push_to_hub=A_,use_auth_token=self._token ) __UpperCamelCase = WavaVecaFeatureExtractor.from_pretrained(F'''{USER}/test-feature-extractor''' ) for k, v in feature_extractor.__dict__.items(): self.assertEqual(A_,getattr(A_,A_ ) ) def snake_case_ ( self: List[str] ): '''simple docstring''' __UpperCamelCase = WavaVecaFeatureExtractor.from_pretrained(A_ ) feature_extractor.push_to_hub('valid_org/test-feature-extractor',use_auth_token=self._token ) __UpperCamelCase = WavaVecaFeatureExtractor.from_pretrained('valid_org/test-feature-extractor' ) for k, v in feature_extractor.__dict__.items(): self.assertEqual(A_,getattr(A_,A_ ) ) # Reset repo delete_repo(token=self._token,repo_id='valid_org/test-feature-extractor' ) # Push to hub via save_pretrained with tempfile.TemporaryDirectory() as tmp_dir: feature_extractor.save_pretrained( A_,repo_id='valid_org/test-feature-extractor-org',push_to_hub=A_,use_auth_token=self._token ) __UpperCamelCase = WavaVecaFeatureExtractor.from_pretrained('valid_org/test-feature-extractor-org' ) for k, v in feature_extractor.__dict__.items(): self.assertEqual(A_,getattr(A_,A_ ) ) def snake_case_ ( self: int ): '''simple docstring''' CustomFeatureExtractor.register_for_auto_class() __UpperCamelCase = CustomFeatureExtractor.from_pretrained(A_ ) feature_extractor.push_to_hub('test-dynamic-feature-extractor',use_auth_token=self._token ) # This has added the proper auto_map field to the config self.assertDictEqual( feature_extractor.auto_map,{'AutoFeatureExtractor': 'custom_feature_extraction.CustomFeatureExtractor'},) __UpperCamelCase = AutoFeatureExtractor.from_pretrained( F'''{USER}/test-dynamic-feature-extractor''',trust_remote_code=A_ ) # Can't make an isinstance check because the new_feature_extractor is from the CustomFeatureExtractor class of a dynamic module self.assertEqual(new_feature_extractor.__class__.__name__,'CustomFeatureExtractor' )

import json from typing import List, Optional, Tuple from tokenizers import normalizers from ....tokenization_utils_fast import PreTrainedTokenizerFast from ....utils import logging from .tokenization_retribert import RetriBertTokenizer __snake_case = logging.get_logger(__name__) __snake_case = {'''vocab_file''': '''vocab.txt''', '''tokenizer_file''': '''tokenizer.json'''} __snake_case = { '''vocab_file''': { '''yjernite/retribert-base-uncased''': ( '''https://huggingface.co/yjernite/retribert-base-uncased/resolve/main/vocab.txt''' ), }, '''tokenizer_file''': { '''yjernite/retribert-base-uncased''': ( '''https://huggingface.co/yjernite/retribert-base-uncased/resolve/main/tokenizer.json''' ), }, } __snake_case = { '''yjernite/retribert-base-uncased''': 5_1_2, } __snake_case = { '''yjernite/retribert-base-uncased''': {'''do_lower_case''': True}, } class __lowerCamelCase (_a ): _lowercase = VOCAB_FILES_NAMES _lowercase = PRETRAINED_VOCAB_FILES_MAP _lowercase = PRETRAINED_POSITIONAL_EMBEDDINGS_SIZES _lowercase = PRETRAINED_INIT_CONFIGURATION _lowercase = RetriBertTokenizer _lowercase = ["""input_ids""", """attention_mask"""] def __init__( self: Optional[int],A_: int=None,A_: Optional[Any]=None,A_: List[Any]=True,A_: Any="[UNK]",A_: List[Any]="[SEP]",A_: Optional[Any]="[PAD]",A_: Dict="[CLS]",A_: Union[str, Any]="[MASK]",A_: Optional[Any]=True,A_: Dict=None,**A_: Dict,): '''simple docstring''' super().__init__( A_,tokenizer_file=A_,do_lower_case=A_,unk_token=A_,sep_token=A_,pad_token=A_,cls_token=A_,mask_token=A_,tokenize_chinese_chars=A_,strip_accents=A_,**A_,) __UpperCamelCase = json.loads(self.backend_tokenizer.normalizer.__getstate__() ) if ( normalizer_state.get('lowercase',A_ ) != do_lower_case or normalizer_state.get('strip_accents',A_ ) != strip_accents or normalizer_state.get('handle_chinese_chars',A_ ) != tokenize_chinese_chars ): __UpperCamelCase = getattr(A_,normalizer_state.pop('type' ) ) __UpperCamelCase = do_lower_case __UpperCamelCase = strip_accents __UpperCamelCase = tokenize_chinese_chars __UpperCamelCase = normalizer_class(**A_ ) __UpperCamelCase = do_lower_case def snake_case_ ( self: List[str],A_: Tuple,A_: List[Any]=None ): '''simple docstring''' __UpperCamelCase = [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 snake_case_ ( self: Optional[int],A_: List[int],A_: Optional[List[int]] = None ): '''simple docstring''' __UpperCamelCase = [self.sep_token_id] __UpperCamelCase = [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 snake_case_ ( self: str,A_: str,A_: Optional[str] = None ): '''simple docstring''' __UpperCamelCase = self._tokenizer.model.save(A_,name=A_ ) return tuple(A_ )

import argparse import json import os import evaluate import torch from datasets import load_dataset from torch.optim import AdamW from torch.utils.data import DataLoader from transformers import AutoModelForSequenceClassification, AutoTokenizer, get_linear_schedule_with_warmup, set_seed from accelerate import Accelerator, DistributedType from accelerate.utils.deepspeed import DummyOptim, DummyScheduler __snake_case = 1_6 __snake_case = 3_2 def _A ( _lowercase , _lowercase = 16 , _lowercase = "bert-base-cased" ) -> Union[str, Any]: """simple docstring""" __UpperCamelCase = AutoTokenizer.from_pretrained(_lowercase ) __UpperCamelCase = load_dataset('glue' , 'mrpc' ) def tokenize_function(_lowercase ): # max_length=None => use the model max length (it's actually the default) __UpperCamelCase = tokenizer(examples['sentence1'] , examples['sentence2'] , truncation=_lowercase , max_length=_lowercase ) return outputs # Apply the method we just defined to all the examples in all the splits of the dataset __UpperCamelCase = datasets.map( _lowercase , batched=_lowercase , remove_columns=['idx', 'sentence1', 'sentence2'] , load_from_cache_file=_lowercase ) # We also rename the 'label' column to 'labels' which is the expected name for labels by the models of the # transformers library __UpperCamelCase = tokenized_datasets.rename_column('label' , 'labels' ) def collate_fn(_lowercase ): # 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(_lowercase , padding='max_length' , max_length=1_28 , return_tensors='pt' ) return tokenizer.pad(_lowercase , padding='longest' , return_tensors='pt' ) # Instantiate dataloaders. __UpperCamelCase = DataLoader( tokenized_datasets['train'] , shuffle=_lowercase , collate_fn=_lowercase , batch_size=_lowercase ) __UpperCamelCase = DataLoader( tokenized_datasets['validation'] , shuffle=_lowercase , collate_fn=_lowercase , batch_size=_lowercase ) return train_dataloader, eval_dataloader def _A ( _lowercase , _lowercase ) -> int: """simple docstring""" __UpperCamelCase = Accelerator() # Sample hyper-parameters for learning rate, batch size, seed and a few other HPs __UpperCamelCase = config['lr'] __UpperCamelCase = int(config['num_epochs'] ) __UpperCamelCase = int(config['seed'] ) __UpperCamelCase = int(config['batch_size'] ) __UpperCamelCase = args.model_name_or_path set_seed(_lowercase ) __UpperCamelCase, __UpperCamelCase = get_dataloaders(_lowercase , _lowercase , _lowercase ) # Instantiate the model (we build the model here so that the seed also control new weights initialization) __UpperCamelCase = AutoModelForSequenceClassification.from_pretrained(_lowercase , return_dict=_lowercase ) # Instantiate optimizer __UpperCamelCase = ( AdamW if accelerator.state.deepspeed_plugin is None or 'optimizer' not in accelerator.state.deepspeed_plugin.deepspeed_config else DummyOptim ) __UpperCamelCase = optimizer_cls(params=model.parameters() , lr=_lowercase ) if accelerator.state.deepspeed_plugin is not None: __UpperCamelCase = accelerator.state.deepspeed_plugin.deepspeed_config[ 'gradient_accumulation_steps' ] else: __UpperCamelCase = 1 __UpperCamelCase = (len(_lowercase ) * num_epochs) // gradient_accumulation_steps # Instantiate scheduler if ( accelerator.state.deepspeed_plugin is None or "scheduler" not in accelerator.state.deepspeed_plugin.deepspeed_config ): __UpperCamelCase = get_linear_schedule_with_warmup( optimizer=_lowercase , num_warmup_steps=0 , num_training_steps=_lowercase , ) else: __UpperCamelCase = DummyScheduler(_lowercase , total_num_steps=_lowercase , warmup_num_steps=0 ) # Prepare everything # There is no specific order to remember, we just need to unpack the objects in the same order we gave them to the # prepare method. __UpperCamelCase, __UpperCamelCase, __UpperCamelCase, __UpperCamelCase, __UpperCamelCase = accelerator.prepare( _lowercase , _lowercase , _lowercase , _lowercase , _lowercase ) # We need to keep track of how many total steps we have iterated over __UpperCamelCase = 0 # We also need to keep track of the stating epoch so files are named properly __UpperCamelCase = 0 # Now we train the model __UpperCamelCase = evaluate.load('glue' , 'mrpc' ) __UpperCamelCase = 0 __UpperCamelCase = {} for epoch in range(_lowercase , _lowercase ): model.train() for step, batch in enumerate(_lowercase ): __UpperCamelCase = model(**_lowercase ) __UpperCamelCase = outputs.loss __UpperCamelCase = loss / gradient_accumulation_steps accelerator.backward(_lowercase ) if step % gradient_accumulation_steps == 0: optimizer.step() lr_scheduler.step() optimizer.zero_grad() overall_step += 1 model.eval() __UpperCamelCase = 0 for step, batch in enumerate(_lowercase ): # We could avoid this line since we set the accelerator with `device_placement=True`. batch.to(accelerator.device ) with torch.no_grad(): __UpperCamelCase = model(**_lowercase ) __UpperCamelCase = outputs.logits.argmax(dim=-1 ) # It is slightly faster to call this once, than multiple times __UpperCamelCase, __UpperCamelCase = accelerator.gather( (predictions, batch['labels']) ) # If we are in a multiprocess environment, the last batch has duplicates if accelerator.use_distributed: if step == len(_lowercase ) - 1: __UpperCamelCase = predictions[: len(eval_dataloader.dataset ) - samples_seen] __UpperCamelCase = references[: len(eval_dataloader.dataset ) - samples_seen] else: samples_seen += references.shape[0] metric.add_batch( predictions=_lowercase , references=_lowercase , ) __UpperCamelCase = metric.compute() # Use accelerator.print to print only on the main process. accelerator.print(f'''epoch {epoch}:''' , _lowercase ) __UpperCamelCase = eval_metric['accuracy'] if best_performance < eval_metric["accuracy"]: __UpperCamelCase = eval_metric['accuracy'] if args.performance_lower_bound is not None: assert ( args.performance_lower_bound <= best_performance ), f'''Best performance metric {best_performance} is lower than the lower bound {args.performance_lower_bound}''' accelerator.wait_for_everyone() if accelerator.is_main_process: with open(os.path.join(args.output_dir , 'all_results.json' ) , 'w' ) as f: json.dump(_lowercase , _lowercase ) def _A ( ) -> List[str]: """simple docstring""" __UpperCamelCase = argparse.ArgumentParser(description='Simple example of training script tracking peak GPU memory usage.' ) parser.add_argument( '--model_name_or_path' , type=_lowercase , default='bert-base-cased' , help='Path to pretrained model or model identifier from huggingface.co/models.' , required=_lowercase , ) parser.add_argument( '--output_dir' , type=_lowercase , default='.' , help='Optional save directory where all checkpoint folders will be stored. Default is the current working directory.' , ) parser.add_argument( '--performance_lower_bound' , type=_lowercase , default=_lowercase , help='Optional lower bound for the performance metric. If set, the training will throw error when the performance metric drops below this value.' , ) parser.add_argument( '--num_epochs' , type=_lowercase , default=3 , help='Number of train epochs.' , ) __UpperCamelCase = parser.parse_args() __UpperCamelCase = {'lr': 2e-5, 'num_epochs': args.num_epochs, 'seed': 42, 'batch_size': 16} training_function(_lowercase , _lowercase ) if __name__ == "__main__": main()

import torch from diffusers import StableDiffusionPipeline __snake_case = '''path-to-your-trained-model''' __snake_case = StableDiffusionPipeline.from_pretrained(model_id, torch_dtype=torch.floataa).to('''cuda''') __snake_case = '''A photo of sks dog in a bucket''' __snake_case = pipe(prompt, num_inference_steps=5_0, guidance_scale=7.5).images[0] image.save('''dog-bucket.png''')

from transformers import BertTokenizer, EncoderDecoderModel, SeqaSeqTrainer, SeqaSeqTrainingArguments from transformers.testing_utils import TestCasePlus, require_torch, slow from transformers.utils import is_datasets_available if is_datasets_available(): import datasets class __lowerCamelCase (_a ): @slow @require_torch def snake_case_ ( self: Union[str, Any] ): '''simple docstring''' __UpperCamelCase = EncoderDecoderModel.from_encoder_decoder_pretrained('prajjwal1/bert-tiny','prajjwal1/bert-tiny' ) __UpperCamelCase = BertTokenizer.from_pretrained('bert-base-uncased' ) __UpperCamelCase = bertabert.config.encoder.vocab_size __UpperCamelCase = tokenizer.sep_token_id __UpperCamelCase = tokenizer.cls_token_id __UpperCamelCase = 128 __UpperCamelCase = datasets.load_dataset('cnn_dailymail','3.0.0',split='train[:1%]' ) __UpperCamelCase = datasets.load_dataset('cnn_dailymail','3.0.0',split='validation[:1%]' ) __UpperCamelCase = train_dataset.select(range(32 ) ) __UpperCamelCase = val_dataset.select(range(16 ) ) __UpperCamelCase = 4 def _map_to_encoder_decoder_inputs(A_: Dict ): # Tokenizer will automatically set [BOS] <text> [EOS] __UpperCamelCase = tokenizer(batch['article'],padding='max_length',truncation=A_,max_length=512 ) __UpperCamelCase = tokenizer(batch['highlights'],padding='max_length',truncation=A_,max_length=128 ) __UpperCamelCase = inputs.input_ids __UpperCamelCase = inputs.attention_mask __UpperCamelCase = outputs.input_ids __UpperCamelCase = outputs.input_ids.copy() __UpperCamelCase = [ [-100 if token == tokenizer.pad_token_id else token for token in labels] for labels in batch['labels'] ] __UpperCamelCase = outputs.attention_mask assert all(len(A_ ) == 512 for x in inputs.input_ids ) assert all(len(A_ ) == 128 for x in outputs.input_ids ) return batch def _compute_metrics(A_: str ): __UpperCamelCase = pred.label_ids __UpperCamelCase = pred.predictions # all unnecessary tokens are removed __UpperCamelCase = tokenizer.batch_decode(A_,skip_special_tokens=A_ ) __UpperCamelCase = tokenizer.batch_decode(A_,skip_special_tokens=A_ ) __UpperCamelCase = sum([int(pred_str[i] == label_str[i] ) for i in range(len(A_ ) )] ) / len(A_ ) return {"accuracy": accuracy} # map train dataset __UpperCamelCase = train_dataset.map( _map_to_encoder_decoder_inputs,batched=A_,batch_size=A_,remove_columns=['article', 'highlights'],) train_dataset.set_format( type='torch',columns=['input_ids', 'attention_mask', 'decoder_input_ids', 'decoder_attention_mask', 'labels'],) # same for validation dataset __UpperCamelCase = val_dataset.map( _map_to_encoder_decoder_inputs,batched=A_,batch_size=A_,remove_columns=['article', 'highlights'],) val_dataset.set_format( type='torch',columns=['input_ids', 'attention_mask', 'decoder_input_ids', 'decoder_attention_mask', 'labels'],) __UpperCamelCase = self.get_auto_remove_tmp_dir() __UpperCamelCase = SeqaSeqTrainingArguments( output_dir=A_,per_device_train_batch_size=A_,per_device_eval_batch_size=A_,predict_with_generate=A_,evaluation_strategy='steps',do_train=A_,do_eval=A_,warmup_steps=0,eval_steps=2,logging_steps=2,) # instantiate trainer __UpperCamelCase = SeqaSeqTrainer( model=A_,args=A_,compute_metrics=_compute_metrics,train_dataset=A_,eval_dataset=A_,tokenizer=A_,) # start training trainer.train()

from ...configuration_utils import PretrainedConfig from ...utils import logging __snake_case = logging.get_logger(__name__) __snake_case = { '''google/fnet-base''': '''https://huggingface.co/google/fnet-base/resolve/main/config.json''', '''google/fnet-large''': '''https://huggingface.co/google/fnet-large/resolve/main/config.json''' # See all FNet models at https://huggingface.co/models?filter=fnet } class __lowerCamelCase (_a ): _lowercase = """fnet""" def __init__( self: Optional[Any],A_: str=3_2000,A_: Optional[Any]=768,A_: str=12,A_: List[str]=3072,A_: Union[str, Any]="gelu_new",A_: Optional[int]=0.1,A_: List[str]=512,A_: Optional[Any]=4,A_: Optional[int]=0.0_2,A_: Optional[Any]=1E-12,A_: int=False,A_: Any=512,A_: Optional[Any]=3,A_: List[Any]=1,A_: Tuple=2,**A_: Any,): '''simple docstring''' super().__init__(pad_token_id=A_,bos_token_id=A_,eos_token_id=A_,**A_ ) __UpperCamelCase = vocab_size __UpperCamelCase = max_position_embeddings __UpperCamelCase = hidden_size __UpperCamelCase = num_hidden_layers __UpperCamelCase = intermediate_size __UpperCamelCase = hidden_act __UpperCamelCase = hidden_dropout_prob __UpperCamelCase = initializer_range __UpperCamelCase = type_vocab_size __UpperCamelCase = layer_norm_eps __UpperCamelCase = use_tpu_fourier_optimizations __UpperCamelCase = tpu_short_seq_length

def _A ( _lowercase = 1_00 ) -> int: """simple docstring""" __UpperCamelCase = 0 __UpperCamelCase = 0 for i in range(1 , n + 1 ): sum_of_squares += i**2 sum_of_ints += i return sum_of_ints**2 - sum_of_squares if __name__ == "__main__": print(f"""{solution() = }""")

import warnings from ...processing_utils import ProcessorMixin from ...tokenization_utils_base import BatchEncoding class __lowerCamelCase (_a ): _lowercase = ["""image_processor""", """tokenizer"""] _lowercase = """CLIPImageProcessor""" _lowercase = ("""CLIPTokenizer""", """CLIPTokenizerFast""") def __init__( self: Tuple,A_: Dict=None,A_: Dict=None,**A_: str ): '''simple docstring''' __UpperCamelCase = None if "feature_extractor" in kwargs: warnings.warn( 'The `feature_extractor` argument is deprecated and will be removed in v5, use `image_processor`' ' instead.',A_,) __UpperCamelCase = kwargs.pop('feature_extractor' ) __UpperCamelCase = image_processor if image_processor is not None else feature_extractor if image_processor is None: raise ValueError('You need to specify an `image_processor`.' ) if tokenizer is None: raise ValueError('You need to specify a `tokenizer`.' ) super().__init__(A_,A_ ) def __call__( self: Optional[int],A_: Union[str, Any]=None,A_: int=None,A_: List[Any]=None,**A_: Optional[Any] ): '''simple docstring''' if text is None and images is None: raise ValueError('You have to specify either text or images. Both cannot be none.' ) if text is not None: __UpperCamelCase = self.tokenizer(A_,return_tensors=A_,**A_ ) if images is not None: __UpperCamelCase = self.image_processor(A_,return_tensors=A_,**A_ ) if text is not None and images is not None: __UpperCamelCase = image_features.pixel_values return encoding elif text is not None: return encoding else: return BatchEncoding(data=dict(**A_ ),tensor_type=A_ ) def snake_case_ ( self: Optional[int],*A_: Tuple,**A_: Union[str, Any] ): '''simple docstring''' return self.tokenizer.batch_decode(*A_,**A_ ) def snake_case_ ( self: Dict,*A_: int,**A_: List[Any] ): '''simple docstring''' return self.tokenizer.decode(*A_,**A_ ) @property def snake_case_ ( self: Any ): '''simple docstring''' __UpperCamelCase = self.tokenizer.model_input_names __UpperCamelCase = self.image_processor.model_input_names return list(dict.fromkeys(tokenizer_input_names + image_processor_input_names ) ) @property def snake_case_ ( self: Union[str, Any] ): '''simple docstring''' warnings.warn( '`feature_extractor_class` is deprecated and will be removed in v5. Use `image_processor_class` instead.',A_,) return self.image_processor_class @property def snake_case_ ( self: List[str] ): '''simple docstring''' warnings.warn( '`feature_extractor` is deprecated and will be removed in v5. Use `image_processor` instead.',A_,) return self.image_processor

def _A ( _lowercase , _lowercase ) -> int: """simple docstring""" return (pointa[0] - pointa[0]) ** 2 + (pointa[1] - pointa[1]) ** 2 def _A ( _lowercase , _lowercase=0 ) -> Dict: """simple docstring""" return sorted(_lowercase , key=lambda _lowercase : x[column] ) def _A ( _lowercase , _lowercase , _lowercase=float('inf' ) ) -> List[Any]: """simple docstring""" for i in range(points_counts - 1 ): for j in range(i + 1 , _lowercase ): __UpperCamelCase = euclidean_distance_sqr(points[i] , points[j] ) if current_dis < min_dis: __UpperCamelCase = current_dis return min_dis def _A ( _lowercase , _lowercase , _lowercase=float('inf' ) ) -> Tuple: """simple docstring""" for i in range(min(6 , points_counts - 1 ) , _lowercase ): for j in range(max(0 , i - 6 ) , _lowercase ): __UpperCamelCase = euclidean_distance_sqr(points[i] , points[j] ) if current_dis < min_dis: __UpperCamelCase = current_dis return min_dis def _A ( _lowercase , _lowercase , _lowercase ) -> Optional[Any]: """simple docstring""" if points_counts <= 3: return dis_between_closest_pair(_lowercase , _lowercase ) # recursion __UpperCamelCase = points_counts // 2 __UpperCamelCase = closest_pair_of_points_sqr( _lowercase , points_sorted_on_y[:mid] , _lowercase ) __UpperCamelCase = closest_pair_of_points_sqr( _lowercase , points_sorted_on_y[mid:] , points_counts - mid ) __UpperCamelCase = min(_lowercase , _lowercase ) __UpperCamelCase = [] for point in points_sorted_on_x: if abs(point[0] - points_sorted_on_x[mid][0] ) < closest_pair_dis: cross_strip.append(_lowercase ) __UpperCamelCase = dis_between_closest_in_strip( _lowercase , len(_lowercase ) , _lowercase ) return min(_lowercase , _lowercase ) def _A ( _lowercase , _lowercase ) -> Optional[int]: """simple docstring""" __UpperCamelCase = column_based_sort(_lowercase , column=0 ) __UpperCamelCase = column_based_sort(_lowercase , column=1 ) return ( closest_pair_of_points_sqr( _lowercase , _lowercase , _lowercase ) ) ** 0.5 if __name__ == "__main__": __snake_case = [(2, 3), (1_2, 3_0), (4_0, 5_0), (5, 1), (1_2, 1_0), (3, 4)] print('''Distance:''', closest_pair_of_points(points, len(points)))

import pytest import datasets # Import fixture modules as plugins __snake_case = ['''tests.fixtures.files''', '''tests.fixtures.hub''', '''tests.fixtures.fsspec'''] def _A ( _lowercase , _lowercase ) -> Tuple: """simple docstring""" for item in items: if any(marker in item.keywords for marker in ['integration', 'unit'] ): continue item.add_marker(pytest.mark.unit ) def _A ( _lowercase ) -> str: """simple docstring""" config.addinivalue_line('markers' , 'torchaudio_latest: mark test to run with torchaudio>=0.12' ) @pytest.fixture(autouse=_lowercase ) def _A ( _lowercase , _lowercase ) -> Any: """simple docstring""" __UpperCamelCase = tmp_path_factory.getbasetemp() / 'cache' __UpperCamelCase = test_hf_cache_home / 'datasets' __UpperCamelCase = test_hf_cache_home / 'metrics' __UpperCamelCase = test_hf_cache_home / 'modules' monkeypatch.setattr('datasets.config.HF_DATASETS_CACHE' , str(_lowercase ) ) monkeypatch.setattr('datasets.config.HF_METRICS_CACHE' , str(_lowercase ) ) monkeypatch.setattr('datasets.config.HF_MODULES_CACHE' , str(_lowercase ) ) __UpperCamelCase = test_hf_datasets_cache / 'downloads' monkeypatch.setattr('datasets.config.DOWNLOADED_DATASETS_PATH' , str(_lowercase ) ) __UpperCamelCase = test_hf_datasets_cache / 'downloads' / 'extracted' monkeypatch.setattr('datasets.config.EXTRACTED_DATASETS_PATH' , str(_lowercase ) ) @pytest.fixture(autouse=_lowercase , scope='session' ) def _A ( ) -> Dict: """simple docstring""" datasets.disable_progress_bar() @pytest.fixture(autouse=_lowercase ) def _A ( _lowercase ) -> Tuple: """simple docstring""" monkeypatch.setattr('datasets.config.HF_UPDATE_DOWNLOAD_COUNTS' , _lowercase ) @pytest.fixture def _A ( _lowercase ) -> Any: """simple docstring""" monkeypatch.setattr('sqlalchemy.util.deprecations.SILENCE_UBER_WARNING' , _lowercase )

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 = { '''bert-base-uncased''': '''https://huggingface.co/bert-base-uncased/resolve/main/config.json''', '''bert-large-uncased''': '''https://huggingface.co/bert-large-uncased/resolve/main/config.json''', '''bert-base-cased''': '''https://huggingface.co/bert-base-cased/resolve/main/config.json''', '''bert-large-cased''': '''https://huggingface.co/bert-large-cased/resolve/main/config.json''', '''bert-base-multilingual-uncased''': '''https://huggingface.co/bert-base-multilingual-uncased/resolve/main/config.json''', '''bert-base-multilingual-cased''': '''https://huggingface.co/bert-base-multilingual-cased/resolve/main/config.json''', '''bert-base-chinese''': '''https://huggingface.co/bert-base-chinese/resolve/main/config.json''', '''bert-base-german-cased''': '''https://huggingface.co/bert-base-german-cased/resolve/main/config.json''', '''bert-large-uncased-whole-word-masking''': ( '''https://huggingface.co/bert-large-uncased-whole-word-masking/resolve/main/config.json''' ), '''bert-large-cased-whole-word-masking''': ( '''https://huggingface.co/bert-large-cased-whole-word-masking/resolve/main/config.json''' ), '''bert-large-uncased-whole-word-masking-finetuned-squad''': ( '''https://huggingface.co/bert-large-uncased-whole-word-masking-finetuned-squad/resolve/main/config.json''' ), '''bert-large-cased-whole-word-masking-finetuned-squad''': ( '''https://huggingface.co/bert-large-cased-whole-word-masking-finetuned-squad/resolve/main/config.json''' ), '''bert-base-cased-finetuned-mrpc''': '''https://huggingface.co/bert-base-cased-finetuned-mrpc/resolve/main/config.json''', '''bert-base-german-dbmdz-cased''': '''https://huggingface.co/bert-base-german-dbmdz-cased/resolve/main/config.json''', '''bert-base-german-dbmdz-uncased''': '''https://huggingface.co/bert-base-german-dbmdz-uncased/resolve/main/config.json''', '''cl-tohoku/bert-base-japanese''': '''https://huggingface.co/cl-tohoku/bert-base-japanese/resolve/main/config.json''', '''cl-tohoku/bert-base-japanese-whole-word-masking''': ( '''https://huggingface.co/cl-tohoku/bert-base-japanese-whole-word-masking/resolve/main/config.json''' ), '''cl-tohoku/bert-base-japanese-char''': ( '''https://huggingface.co/cl-tohoku/bert-base-japanese-char/resolve/main/config.json''' ), '''cl-tohoku/bert-base-japanese-char-whole-word-masking''': ( '''https://huggingface.co/cl-tohoku/bert-base-japanese-char-whole-word-masking/resolve/main/config.json''' ), '''TurkuNLP/bert-base-finnish-cased-v1''': ( '''https://huggingface.co/TurkuNLP/bert-base-finnish-cased-v1/resolve/main/config.json''' ), '''TurkuNLP/bert-base-finnish-uncased-v1''': ( '''https://huggingface.co/TurkuNLP/bert-base-finnish-uncased-v1/resolve/main/config.json''' ), '''wietsedv/bert-base-dutch-cased''': '''https://huggingface.co/wietsedv/bert-base-dutch-cased/resolve/main/config.json''', # See all BERT models at https://huggingface.co/models?filter=bert } class __lowerCamelCase (_a ): _lowercase = """bert""" def __init__( self: Any,A_: Dict=3_0522,A_: Optional[Any]=768,A_: Union[str, Any]=12,A_: List[Any]=12,A_: Optional[int]=3072,A_: Union[str, Any]="gelu",A_: List[str]=0.1,A_: Dict=0.1,A_: Optional[int]=512,A_: Optional[Any]=2,A_: Union[str, Any]=0.0_2,A_: List[Any]=1E-12,A_: Optional[int]=0,A_: List[Any]="absolute",A_: str=True,A_: Union[str, Any]=None,**A_: int,): '''simple docstring''' super().__init__(pad_token_id=A_,**A_ ) __UpperCamelCase = vocab_size __UpperCamelCase = hidden_size __UpperCamelCase = num_hidden_layers __UpperCamelCase = num_attention_heads __UpperCamelCase = hidden_act __UpperCamelCase = intermediate_size __UpperCamelCase = hidden_dropout_prob __UpperCamelCase = attention_probs_dropout_prob __UpperCamelCase = max_position_embeddings __UpperCamelCase = type_vocab_size __UpperCamelCase = initializer_range __UpperCamelCase = layer_norm_eps __UpperCamelCase = position_embedding_type __UpperCamelCase = use_cache __UpperCamelCase = classifier_dropout class __lowerCamelCase (_a ): @property def snake_case_ ( self: Optional[int] ): '''simple docstring''' if self.task == "multiple-choice": __UpperCamelCase = {0: 'batch', 1: 'choice', 2: 'sequence'} else: __UpperCamelCase = {0: 'batch', 1: 'sequence'} return OrderedDict( [ ('input_ids', dynamic_axis), ('attention_mask', dynamic_axis), ('token_type_ids', dynamic_axis), ] )

import random import unittest import numpy as np import torch from transformers import CLIPTextConfig, CLIPTextModel, CLIPTokenizer from diffusers import ( AutoencoderKL, DDIMScheduler, UNetaDConditionModel, VideoToVideoSDPipeline, ) from diffusers.utils import floats_tensor, is_xformers_available, skip_mps from diffusers.utils.testing_utils import enable_full_determinism, slow, torch_device from ..pipeline_params import ( TEXT_GUIDED_IMAGE_VARIATION_BATCH_PARAMS, TEXT_GUIDED_IMAGE_VARIATION_PARAMS, ) from ..test_pipelines_common import PipelineTesterMixin enable_full_determinism() @skip_mps class __lowerCamelCase (_a , unittest.TestCase ): _lowercase = VideoToVideoSDPipeline _lowercase = TEXT_GUIDED_IMAGE_VARIATION_PARAMS.union({"""video"""} ) - {"""image""", """width""", """height"""} _lowercase = TEXT_GUIDED_IMAGE_VARIATION_BATCH_PARAMS.union({"""video"""} ) - {"""image"""} _lowercase = PipelineTesterMixin.required_optional_params - {"""latents"""} _lowercase = False # No `output_type`. _lowercase = frozenset( [ """num_inference_steps""", """generator""", """latents""", """return_dict""", """callback""", """callback_steps""", ] ) def snake_case_ ( self: List[str] ): '''simple docstring''' torch.manual_seed(0 ) __UpperCamelCase = UNetaDConditionModel( block_out_channels=(32, 64, 64, 64),layers_per_block=2,sample_size=32,in_channels=4,out_channels=4,down_block_types=('CrossAttnDownBlock3D', 'CrossAttnDownBlock3D', 'CrossAttnDownBlock3D', 'DownBlock3D'),up_block_types=('UpBlock3D', 'CrossAttnUpBlock3D', 'CrossAttnUpBlock3D', 'CrossAttnUpBlock3D'),cross_attention_dim=32,attention_head_dim=4,) __UpperCamelCase = DDIMScheduler( beta_start=0.0_0_0_8_5,beta_end=0.0_1_2,beta_schedule='scaled_linear',clip_sample=A_,set_alpha_to_one=A_,) torch.manual_seed(0 ) __UpperCamelCase = AutoencoderKL( block_out_channels=[32, 64],in_channels=3,out_channels=3,down_block_types=['DownEncoderBlock2D', 'DownEncoderBlock2D'],up_block_types=['UpDecoderBlock2D', 'UpDecoderBlock2D'],latent_channels=4,sample_size=128,) torch.manual_seed(0 ) __UpperCamelCase = 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,) __UpperCamelCase = CLIPTextModel(A_ ) __UpperCamelCase = CLIPTokenizer.from_pretrained('hf-internal-testing/tiny-random-clip' ) __UpperCamelCase = { 'unet': unet, 'scheduler': scheduler, 'vae': vae, 'text_encoder': text_encoder, 'tokenizer': tokenizer, } return components def snake_case_ ( self: Union[str, Any],A_: Any,A_: Any=0 ): '''simple docstring''' __UpperCamelCase = floats_tensor((1, 3, 3, 32, 32),rng=random.Random(A_ ) ).to(A_ ) if str(A_ ).startswith('mps' ): __UpperCamelCase = torch.manual_seed(A_ ) else: __UpperCamelCase = torch.Generator(device=A_ ).manual_seed(A_ ) __UpperCamelCase = { 'prompt': 'A painting of a squirrel eating a burger', 'video': video, 'generator': generator, 'num_inference_steps': 2, 'guidance_scale': 6.0, 'output_type': 'pt', } return inputs def snake_case_ ( self: Union[str, Any] ): '''simple docstring''' __UpperCamelCase = 'cpu' # ensure determinism for the device-dependent torch.Generator __UpperCamelCase = self.get_dummy_components() __UpperCamelCase = VideoToVideoSDPipeline(**A_ ) __UpperCamelCase = sd_pipe.to(A_ ) sd_pipe.set_progress_bar_config(disable=A_ ) __UpperCamelCase = self.get_dummy_inputs(A_ ) __UpperCamelCase = 'np' __UpperCamelCase = sd_pipe(**A_ ).frames __UpperCamelCase = frames[0][-3:, -3:, -1] assert frames[0].shape == (32, 32, 3) __UpperCamelCase = np.array([106, 117, 113, 174, 137, 112, 148, 151, 131] ) assert np.abs(image_slice.flatten() - expected_slice ).max() < 1E-2 @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: Any ): '''simple docstring''' self._test_xformers_attention_forwardGenerator_pass(test_mean_pixel_difference=A_,expected_max_diff=5E-3 ) @unittest.skip(reason='Batching needs to be properly figured out first for this pipeline.' ) def snake_case_ ( self: str ): '''simple docstring''' pass @unittest.skip(reason='Batching needs to be properly figured out first for this pipeline.' ) def snake_case_ ( self: Optional[Any] ): '''simple docstring''' pass @unittest.skip(reason='`num_images_per_prompt` argument is not supported for this pipeline.' ) def snake_case_ ( self: int ): '''simple docstring''' pass def snake_case_ ( self: Any ): '''simple docstring''' return super().test_progress_bar() @slow @skip_mps class __lowerCamelCase (unittest.TestCase ): def snake_case_ ( self: Tuple ): '''simple docstring''' __UpperCamelCase = VideoToVideoSDPipeline.from_pretrained('cerspense/zeroscope_v2_XL',torch_dtype=torch.floataa ) pipe.enable_model_cpu_offload() # 10 frames __UpperCamelCase = torch.Generator(device='cpu' ).manual_seed(0 ) __UpperCamelCase = torch.randn((1, 10, 3, 1024, 576),generator=A_ ) __UpperCamelCase = video.to('cuda' ) __UpperCamelCase = 'Spiderman is surfing' __UpperCamelCase = pipe(A_,video=A_,generator=A_,num_inference_steps=3,output_type='pt' ).frames __UpperCamelCase = np.array([-1.0_4_5_8_9_8_4, -1.1_2_7_9_2_9_7, -0.9_6_6_3_0_8_6, -0.9_1_5_0_3_9_0_6, -0.7_5_0_9_7_6_5_6] ) assert np.abs(video_frames.cpu().numpy()[0, 0, 0, 0, -5:] - expected_array ).sum() < 1E-2

def _A ( _lowercase ) -> int: """simple docstring""" assert column_title.isupper() __UpperCamelCase = 0 __UpperCamelCase = len(_lowercase ) - 1 __UpperCamelCase = 0 while index >= 0: __UpperCamelCase = (ord(column_title[index] ) - 64) * pow(26 , _lowercase ) answer += value power += 1 index -= 1 return answer if __name__ == "__main__": from doctest import testmod testmod()

from ...configuration_utils import PretrainedConfig from ...utils import logging __snake_case = logging.get_logger(__name__) __snake_case = { '''unc-nlp/lxmert-base-uncased''': '''https://huggingface.co/unc-nlp/lxmert-base-uncased/resolve/main/config.json''', } class __lowerCamelCase (_a ): _lowercase = """lxmert""" _lowercase = {} def __init__( self: Dict,A_: Optional[int]=3_0522,A_: List[Any]=768,A_: int=12,A_: Optional[int]=9500,A_: Optional[int]=1600,A_: List[str]=400,A_: Dict=3072,A_: Tuple="gelu",A_: Optional[int]=0.1,A_: str=0.1,A_: Optional[Any]=512,A_: List[Any]=2,A_: List[str]=0.0_2,A_: List[str]=1E-12,A_: Union[str, Any]=9,A_: Optional[int]=5,A_: Any=5,A_: Optional[Any]=2048,A_: Union[str, Any]=4,A_: Any=6.6_7,A_: Tuple=True,A_: List[str]=True,A_: Dict=True,A_: List[Any]=True,A_: List[str]=True,A_: Optional[Any]=True,A_: Optional[Any]=True,**A_: Dict,): '''simple docstring''' __UpperCamelCase = vocab_size __UpperCamelCase = hidden_size __UpperCamelCase = num_attention_heads __UpperCamelCase = hidden_act __UpperCamelCase = intermediate_size __UpperCamelCase = hidden_dropout_prob __UpperCamelCase = attention_probs_dropout_prob __UpperCamelCase = max_position_embeddings __UpperCamelCase = type_vocab_size __UpperCamelCase = initializer_range __UpperCamelCase = layer_norm_eps __UpperCamelCase = num_qa_labels __UpperCamelCase = num_object_labels __UpperCamelCase = num_attr_labels __UpperCamelCase = l_layers __UpperCamelCase = x_layers __UpperCamelCase = r_layers __UpperCamelCase = visual_feat_dim __UpperCamelCase = visual_pos_dim __UpperCamelCase = visual_loss_normalizer __UpperCamelCase = task_matched __UpperCamelCase = task_mask_lm __UpperCamelCase = task_obj_predict __UpperCamelCase = task_qa __UpperCamelCase = visual_obj_loss __UpperCamelCase = visual_attr_loss __UpperCamelCase = visual_feat_loss __UpperCamelCase = {'vision': r_layers, 'cross_encoder': x_layers, 'language': l_layers} super().__init__(**A_ )

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 from lavis.models import load_model_and_preprocess from PIL import Image from transformers import ( AutoTokenizer, BlipaConfig, BlipaForConditionalGeneration, BlipaProcessor, BlipaVisionConfig, BlipImageProcessor, OPTConfig, TaConfig, ) from transformers.utils.constants import OPENAI_CLIP_MEAN, OPENAI_CLIP_STD def _A ( ) -> int: """simple docstring""" __UpperCamelCase = 'https://storage.googleapis.com/sfr-vision-language-research/LAVIS/assets/merlion.png' __UpperCamelCase = Image.open(requests.get(_lowercase , stream=_lowercase ).raw ).convert('RGB' ) return image def _A ( _lowercase ) -> int: """simple docstring""" __UpperCamelCase = [] # 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.layernorm.weight') ) rename_keys.append(('Qformer.bert.embeddings.LayerNorm.bias', 'qformer.layernorm.bias') ) # fmt: on return rename_keys def _A ( _lowercase , _lowercase , _lowercase ) -> Optional[int]: """simple docstring""" __UpperCamelCase = dct.pop(_lowercase ) __UpperCamelCase = val def _A ( _lowercase , _lowercase ) -> int: """simple docstring""" for i in range(config.vision_config.num_hidden_layers ): # read in original q and v biases __UpperCamelCase = state_dict.pop(f'''visual_encoder.blocks.{i}.attn.q_bias''' ) __UpperCamelCase = state_dict.pop(f'''visual_encoder.blocks.{i}.attn.v_bias''' ) # next, set bias in the state dict __UpperCamelCase = torch.cat((q_bias, torch.zeros_like(_lowercase , requires_grad=_lowercase ), v_bias) ) __UpperCamelCase = qkv_bias def _A ( _lowercase , _lowercase ) -> Any: """simple docstring""" __UpperCamelCase = 3_64 if 'coco' in model_name else 2_24 __UpperCamelCase = BlipaVisionConfig(image_size=_lowercase ).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 "opt-2.7b" in model_name: __UpperCamelCase = OPTConfig.from_pretrained('facebook/opt-2.7b' , eos_token_id=_lowercase ).to_dict() elif "opt-6.7b" in model_name: __UpperCamelCase = OPTConfig.from_pretrained('facebook/opt-6.7b' , eos_token_id=_lowercase ).to_dict() elif "t5-xl" in model_name: __UpperCamelCase = TaConfig.from_pretrained('google/flan-t5-xl' , dense_act_fn='gelu' , bos_token_id=1 ).to_dict() elif "t5-xxl" in model_name: __UpperCamelCase = TaConfig.from_pretrained('google/flan-t5-xxl' , dense_act_fn='gelu' , bos_token_id=1 ).to_dict() __UpperCamelCase = BlipaConfig(vision_config=_lowercase , text_config=_lowercase ) return config, image_size @torch.no_grad() def _A ( _lowercase , _lowercase=None , _lowercase=False ) -> Union[str, Any]: """simple docstring""" __UpperCamelCase = ( AutoTokenizer.from_pretrained('facebook/opt-2.7b' ) if 'opt' in model_name else AutoTokenizer.from_pretrained('google/flan-t5-xl' ) ) __UpperCamelCase = tokenizer('\n' , add_special_tokens=_lowercase ).input_ids[0] __UpperCamelCase, __UpperCamelCase = get_blipa_config(_lowercase , eos_token_id=_lowercase ) __UpperCamelCase = BlipaForConditionalGeneration(_lowercase ).eval() __UpperCamelCase = { 'blip2-opt-2.7b': ('blip2_opt', 'pretrain_opt2.7b'), 'blip2-opt-6.7b': ('blip2_opt', 'pretrain_opt6.7b'), 'blip2-opt-2.7b-coco': ('blip2_opt', 'caption_coco_opt2.7b'), 'blip2-opt-6.7b-coco': ('blip2_opt', 'caption_coco_opt6.7b'), 'blip2-flan-t5-xl': ('blip2_t5', 'pretrain_flant5xl'), 'blip2-flan-t5-xl-coco': ('blip2_t5', 'caption_coco_flant5xl'), 'blip2-flan-t5-xxl': ('blip2_t5', 'pretrain_flant5xxl'), } __UpperCamelCase, __UpperCamelCase = model_name_to_original[model_name] # load original model print('Loading original model...' ) __UpperCamelCase = 'cuda' if torch.cuda.is_available() else 'cpu' __UpperCamelCase, __UpperCamelCase, __UpperCamelCase = load_model_and_preprocess( name=_lowercase , model_type=_lowercase , is_eval=_lowercase , device=_lowercase ) original_model.eval() print('Done!' ) # update state dict keys __UpperCamelCase = original_model.state_dict() __UpperCamelCase = create_rename_keys(_lowercase ) for src, dest in rename_keys: rename_key(_lowercase , _lowercase , _lowercase ) # some keys can be renamed efficiently for key, val in state_dict.copy().items(): __UpperCamelCase = state_dict.pop(_lowercase ) if key.startswith('Qformer.bert' ): __UpperCamelCase = key.replace('Qformer.bert' , 'qformer' ) if "attention.self" in key: __UpperCamelCase = key.replace('self' , 'attention' ) if "opt_proj" in key: __UpperCamelCase = key.replace('opt_proj' , 'language_projection' ) if "t5_proj" in key: __UpperCamelCase = key.replace('t5_proj' , 'language_projection' ) if key.startswith('opt' ): __UpperCamelCase = key.replace('opt' , 'language' ) if key.startswith('t5' ): __UpperCamelCase = key.replace('t5' , 'language' ) __UpperCamelCase = val # read in qv biases read_in_q_v_bias(_lowercase , _lowercase ) __UpperCamelCase, __UpperCamelCase = hf_model.load_state_dict(_lowercase , strict=_lowercase ) assert len(_lowercase ) == 0 assert unexpected_keys == ["qformer.embeddings.position_ids"] __UpperCamelCase = load_demo_image() __UpperCamelCase = vis_processors['eval'](_lowercase ).unsqueeze(0 ).to(_lowercase ) __UpperCamelCase = tokenizer(['\n'] , return_tensors='pt' ).input_ids.to(_lowercase ) # create processor __UpperCamelCase = BlipImageProcessor( size={'height': image_size, 'width': image_size} , image_mean=_lowercase , image_std=_lowercase ) __UpperCamelCase = BlipaProcessor(image_processor=_lowercase , tokenizer=_lowercase ) __UpperCamelCase = processor(images=_lowercase , return_tensors='pt' ).pixel_values.to(_lowercase ) # make sure processor creates exact same pixel values assert torch.allclose(_lowercase , _lowercase ) original_model.to(_lowercase ) hf_model.to(_lowercase ) with torch.no_grad(): if "opt" in model_name: __UpperCamelCase = original_model({'image': original_pixel_values, 'text_input': ['']} ).logits __UpperCamelCase = hf_model(_lowercase , _lowercase ).logits else: __UpperCamelCase = original_model( {'image': original_pixel_values, 'text_input': ['\n'], 'text_output': ['\n']} ).logits __UpperCamelCase = input_ids.masked_fill(input_ids == tokenizer.pad_token_id , -1_00 ) __UpperCamelCase = hf_model(_lowercase , _lowercase , labels=_lowercase ).logits assert original_logits.shape == logits.shape print('First values of original logits:' , original_logits[0, :3, :3] ) print('First values of HF logits:' , logits[0, :3, :3] ) # assert values if model_name == "blip2-flan-t5-xl": __UpperCamelCase = torch.tensor( [[-41.58_50, -4.44_40, -8.99_22], [-47.43_22, -5.91_43, -1.73_40]] , device=_lowercase ) assert torch.allclose(logits[0, :3, :3] , _lowercase , atol=1e-4 ) elif model_name == "blip2-flan-t5-xl-coco": __UpperCamelCase = torch.tensor( [[-57.01_09, -9.89_67, -12.62_80], [-68.65_78, -12.71_91, -10.50_65]] , device=_lowercase ) else: # cast to same type __UpperCamelCase = logits.dtype assert torch.allclose(original_logits.to(_lowercase ) , _lowercase , atol=1e-2 ) print('Looks ok!' ) print('Generating a caption...' ) __UpperCamelCase = '' __UpperCamelCase = tokenizer(_lowercase , return_tensors='pt' ).input_ids.to(_lowercase ) __UpperCamelCase = original_model.generate({'image': original_pixel_values} ) __UpperCamelCase = hf_model.generate( _lowercase , _lowercase , do_sample=_lowercase , num_beams=5 , max_length=30 , min_length=1 , top_p=0.9 , repetition_penalty=1.0 , length_penalty=1.0 , temperature=1 , ) print('Original generation:' , _lowercase ) __UpperCamelCase = input_ids.shape[1] __UpperCamelCase = processor.batch_decode(outputs[:, prompt_length:] , skip_special_tokens=_lowercase ) __UpperCamelCase = [text.strip() for text in output_text] print('HF generation:' , _lowercase ) if pytorch_dump_folder_path is not None: processor.save_pretrained(_lowercase ) hf_model.save_pretrained(_lowercase ) if push_to_hub: processor.push_to_hub(f'''nielsr/{model_name}''' ) hf_model.push_to_hub(f'''nielsr/{model_name}''' ) if __name__ == "__main__": __snake_case = argparse.ArgumentParser() __snake_case = [ '''blip2-opt-2.7b''', '''blip2-opt-6.7b''', '''blip2-opt-2.7b-coco''', '''blip2-opt-6.7b-coco''', '''blip2-flan-t5-xl''', '''blip2-flan-t5-xl-coco''', '''blip2-flan-t5-xxl''', ] parser.add_argument( '''--model_name''', default='''blip2-opt-2.7b''', 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)

def _A ( _lowercase = 1_00 ) -> int: """simple docstring""" __UpperCamelCase = 0 __UpperCamelCase = 0 for i in range(1 , n + 1 ): sum_of_squares += i**2 sum_of_ints += i return sum_of_ints**2 - sum_of_squares if __name__ == "__main__": print(f"""{solution() = }""")

import logging import os import sys from dataclasses import dataclass, field from importlib import import_module from typing import Dict, List, Optional, Tuple import numpy as np from seqeval.metrics import accuracy_score, fa_score, precision_score, recall_score from torch import nn from utils_ner import Split, TokenClassificationDataset, TokenClassificationTask import transformers from transformers import ( AutoConfig, AutoModelForTokenClassification, AutoTokenizer, DataCollatorWithPadding, EvalPrediction, HfArgumentParser, Trainer, TrainingArguments, set_seed, ) from transformers.trainer_utils import is_main_process __snake_case = logging.getLogger(__name__) @dataclass class __lowerCamelCase : _lowercase = field( metadata={"""help""": """Path to pretrained model or model identifier from huggingface.co/models"""} ) _lowercase = field( default=_a , metadata={"""help""": """Pretrained config name or path if not the same as model_name"""} ) _lowercase = field( default="""NER""" , metadata={"""help""": """Task type to fine tune in training (e.g. NER, POS, etc)"""} ) _lowercase = field( default=_a , metadata={"""help""": """Pretrained tokenizer name or path if not the same as model_name"""} ) _lowercase = field(default=_a , metadata={"""help""": """Set this flag to use fast tokenization."""} ) # If you want to tweak more attributes on your tokenizer, you should do it in a distinct script, # or just modify its tokenizer_config.json. _lowercase = field( default=_a , metadata={"""help""": """Where do you want to store the pretrained models downloaded from huggingface.co"""} , ) @dataclass class __lowerCamelCase : _lowercase = field( metadata={"""help""": """The input data dir. Should contain the .txt files for a CoNLL-2003-formatted task."""} ) _lowercase = field( default=_a , metadata={"""help""": """Path to a file containing all labels. If not specified, CoNLL-2003 labels are used."""} , ) _lowercase = field( default=128 , metadata={ """help""": ( """The maximum total input sequence length after tokenization. Sequences longer """ """than this will be truncated, sequences shorter will be padded.""" ) } , ) _lowercase = field( default=_a , metadata={"""help""": """Overwrite the cached training and evaluation sets"""} ) def _A ( ) -> str: """simple docstring""" __UpperCamelCase = HfArgumentParser((ModelArguments, DataTrainingArguments, TrainingArguments) ) if len(sys.argv ) == 2 and sys.argv[1].endswith('.json' ): # If we pass only one argument to the script and it's the path to a json file, # let's parse it to get our arguments. __UpperCamelCase, __UpperCamelCase, __UpperCamelCase = parser.parse_json_file(json_file=os.path.abspath(sys.argv[1] ) ) else: __UpperCamelCase, __UpperCamelCase, __UpperCamelCase = parser.parse_args_into_dataclasses() if ( os.path.exists(training_args.output_dir ) and os.listdir(training_args.output_dir ) and training_args.do_train and not training_args.overwrite_output_dir ): raise ValueError( f'''Output directory ({training_args.output_dir}) already exists and is not empty. Use''' ' --overwrite_output_dir to overcome.' ) __UpperCamelCase = import_module('tasks' ) try: __UpperCamelCase = getattr(_lowercase , model_args.task_type ) __UpperCamelCase = token_classification_task_clazz() except AttributeError: raise ValueError( f'''Task {model_args.task_type} needs to be defined as a TokenClassificationTask subclass in {module}. ''' f'''Available tasks classes are: {TokenClassificationTask.__subclasses__()}''' ) # Setup logging logging.basicConfig( format='%(asctime)s - %(levelname)s - %(name)s - %(message)s' , datefmt='%m/%d/%Y %H:%M:%S' , level=logging.INFO if training_args.local_rank in [-1, 0] else logging.WARN , ) logger.warning( 'Process rank: %s, device: %s, n_gpu: %s, distributed training: %s, 16-bits training: %s' , training_args.local_rank , training_args.device , training_args.n_gpu , bool(training_args.local_rank != -1 ) , training_args.fpaa , ) # Set the verbosity to info of the Transformers logger (on main process only): if is_main_process(training_args.local_rank ): transformers.utils.logging.set_verbosity_info() transformers.utils.logging.enable_default_handler() transformers.utils.logging.enable_explicit_format() logger.info('Training/evaluation parameters %s' , _lowercase ) # Set seed set_seed(training_args.seed ) # Prepare CONLL-2003 task __UpperCamelCase = token_classification_task.get_labels(data_args.labels ) __UpperCamelCase = dict(enumerate(_lowercase ) ) __UpperCamelCase = len(_lowercase ) # Load pretrained model and tokenizer # # Distributed training: # The .from_pretrained methods guarantee that only one local process can concurrently # download model & vocab. __UpperCamelCase = AutoConfig.from_pretrained( model_args.config_name if model_args.config_name else model_args.model_name_or_path , num_labels=_lowercase , idalabel=_lowercase , labelaid={label: i for i, label in enumerate(_lowercase )} , cache_dir=model_args.cache_dir , ) __UpperCamelCase = AutoTokenizer.from_pretrained( model_args.tokenizer_name if model_args.tokenizer_name else model_args.model_name_or_path , cache_dir=model_args.cache_dir , use_fast=model_args.use_fast , ) __UpperCamelCase = AutoModelForTokenClassification.from_pretrained( model_args.model_name_or_path , from_tf=bool('.ckpt' in model_args.model_name_or_path ) , config=_lowercase , cache_dir=model_args.cache_dir , ) # Get datasets __UpperCamelCase = ( TokenClassificationDataset( token_classification_task=_lowercase , data_dir=data_args.data_dir , tokenizer=_lowercase , labels=_lowercase , model_type=config.model_type , max_seq_length=data_args.max_seq_length , overwrite_cache=data_args.overwrite_cache , mode=Split.train , ) if training_args.do_train else None ) __UpperCamelCase = ( TokenClassificationDataset( token_classification_task=_lowercase , data_dir=data_args.data_dir , tokenizer=_lowercase , labels=_lowercase , model_type=config.model_type , max_seq_length=data_args.max_seq_length , overwrite_cache=data_args.overwrite_cache , mode=Split.dev , ) if training_args.do_eval else None ) def align_predictions(_lowercase , _lowercase ) -> Tuple[List[int], List[int]]: __UpperCamelCase = np.argmax(_lowercase , axis=2 ) __UpperCamelCase, __UpperCamelCase = preds.shape __UpperCamelCase = [[] for _ in range(_lowercase )] __UpperCamelCase = [[] for _ in range(_lowercase )] for i in range(_lowercase ): for j in range(_lowercase ): if label_ids[i, j] != nn.CrossEntropyLoss().ignore_index: out_label_list[i].append(label_map[label_ids[i][j]] ) preds_list[i].append(label_map[preds[i][j]] ) return preds_list, out_label_list def compute_metrics(_lowercase ) -> Dict: __UpperCamelCase, __UpperCamelCase = align_predictions(p.predictions , p.label_ids ) return { "accuracy_score": accuracy_score(_lowercase , _lowercase ), "precision": precision_score(_lowercase , _lowercase ), "recall": recall_score(_lowercase , _lowercase ), "f1": fa_score(_lowercase , _lowercase ), } # Data collator __UpperCamelCase = DataCollatorWithPadding(_lowercase , pad_to_multiple_of=8 ) if training_args.fpaa else None # Initialize our Trainer __UpperCamelCase = Trainer( model=_lowercase , args=_lowercase , train_dataset=_lowercase , eval_dataset=_lowercase , compute_metrics=_lowercase , data_collator=_lowercase , ) # Training if training_args.do_train: trainer.train( model_path=model_args.model_name_or_path if os.path.isdir(model_args.model_name_or_path ) else None ) trainer.save_model() # For convenience, we also re-save the tokenizer to the same directory, # so that you can share your model easily on huggingface.co/models =) if trainer.is_world_process_zero(): tokenizer.save_pretrained(training_args.output_dir ) # Evaluation __UpperCamelCase = {} if training_args.do_eval: logger.info('*** Evaluate ***' ) __UpperCamelCase = trainer.evaluate() __UpperCamelCase = os.path.join(training_args.output_dir , 'eval_results.txt' ) if trainer.is_world_process_zero(): with open(_lowercase , 'w' ) as writer: logger.info('***** Eval results *****' ) for key, value in result.items(): logger.info(' %s = %s' , _lowercase , _lowercase ) writer.write('%s = %s\n' % (key, value) ) results.update(_lowercase ) # Predict if training_args.do_predict: __UpperCamelCase = TokenClassificationDataset( token_classification_task=_lowercase , data_dir=data_args.data_dir , tokenizer=_lowercase , labels=_lowercase , model_type=config.model_type , max_seq_length=data_args.max_seq_length , overwrite_cache=data_args.overwrite_cache , mode=Split.test , ) __UpperCamelCase, __UpperCamelCase, __UpperCamelCase = trainer.predict(_lowercase ) __UpperCamelCase, __UpperCamelCase = align_predictions(_lowercase , _lowercase ) __UpperCamelCase = os.path.join(training_args.output_dir , 'test_results.txt' ) if trainer.is_world_process_zero(): with open(_lowercase , 'w' ) as writer: for key, value in metrics.items(): logger.info(' %s = %s' , _lowercase , _lowercase ) writer.write('%s = %s\n' % (key, value) ) # Save predictions __UpperCamelCase = os.path.join(training_args.output_dir , 'test_predictions.txt' ) if trainer.is_world_process_zero(): with open(_lowercase , 'w' ) as writer: with open(os.path.join(data_args.data_dir , 'test.txt' ) , 'r' ) as f: token_classification_task.write_predictions_to_file(_lowercase , _lowercase , _lowercase ) return results def _A ( _lowercase ) -> Dict: """simple docstring""" main() if __name__ == "__main__": main()

import os import sys import tempfile import torch from .state import AcceleratorState from .utils import PrecisionType, PrepareForLaunch, is_mps_available, patch_environment def _A ( _lowercase , _lowercase=() , _lowercase=None , _lowercase="no" , _lowercase="29500" ) -> Union[str, Any]: """simple docstring""" __UpperCamelCase = False __UpperCamelCase = False if any(key.startswith('KAGGLE' ) for key in os.environ.keys() ): __UpperCamelCase = True elif "IPython" in sys.modules: __UpperCamelCase = 'google.colab' in str(sys.modules['IPython'].get_ipython() ) try: __UpperCamelCase = PrecisionType(mixed_precision.lower() ) except ValueError: raise ValueError( f'''Unknown mixed_precision mode: {args.mixed_precision.lower()}. Choose between {PrecisionType.list()}.''' ) if (in_colab or in_kaggle) and (os.environ.get('TPU_NAME' , _lowercase ) is not None): # TPU launch import torch_xla.distributed.xla_multiprocessing as xmp if len(AcceleratorState._shared_state ) > 0: raise ValueError( 'To train on TPU in Colab or Kaggle Kernel, the `Accelerator` should only be initialized inside ' 'your training function. Restart your notebook and make sure no cells initializes an ' '`Accelerator`.' ) if num_processes is None: __UpperCamelCase = 8 __UpperCamelCase = PrepareForLaunch(_lowercase , distributed_type='TPU' ) print(f'''Launching a training on {num_processes} TPU cores.''' ) xmp.spawn(_lowercase , args=_lowercase , nprocs=_lowercase , start_method='fork' ) elif in_colab: # No need for a distributed launch otherwise as it's either CPU or one GPU. if torch.cuda.is_available(): print('Launching training on one GPU.' ) else: print('Launching training on one CPU.' ) function(*_lowercase ) else: if num_processes is None: raise ValueError( 'You have to specify the number of GPUs you would like to use, add `num_processes=...` to your call.' ) if num_processes > 1: # Multi-GPU launch from torch.multiprocessing import start_processes from torch.multiprocessing.spawn import ProcessRaisedException if len(AcceleratorState._shared_state ) > 0: raise ValueError( 'To launch a multi-GPU training from your notebook, the `Accelerator` should only be initialized ' 'inside your training function. Restart your notebook and make sure no cells initializes an ' '`Accelerator`.' ) if torch.cuda.is_initialized(): raise ValueError( 'To launch a multi-GPU training from your notebook, you need to avoid running any instruction ' 'using `torch.cuda` in any cell. Restart your notebook and make sure no cells use any CUDA ' 'function.' ) # torch.distributed will expect a few environment variable to be here. We set the ones common to each # process here (the other ones will be set be the launcher). with patch_environment( world_size=_lowercase , master_addr='127.0.01' , master_port=_lowercase , mixed_precision=_lowercase ): __UpperCamelCase = PrepareForLaunch(_lowercase , distributed_type='MULTI_GPU' ) print(f'''Launching training on {num_processes} GPUs.''' ) try: start_processes(_lowercase , args=_lowercase , nprocs=_lowercase , start_method='fork' ) except ProcessRaisedException as e: if "Cannot re-initialize CUDA in forked subprocess" in e.args[0]: raise RuntimeError( 'CUDA has been initialized before the `notebook_launcher` could create a forked subprocess. ' 'This likely stems from an outside import causing issues once the `notebook_launcher()` is called. ' 'Please review your imports and test them when running the `notebook_launcher()` to identify ' 'which one is problematic.' ) from e else: # No need for a distributed launch otherwise as it's either CPU, GPU or MPS. if is_mps_available(): __UpperCamelCase = '1' print('Launching training on MPS.' ) elif torch.cuda.is_available(): print('Launching training on one GPU.' ) else: print('Launching training on CPU.' ) function(*_lowercase ) def _A ( _lowercase , _lowercase=() , _lowercase=2 ) -> Dict: """simple docstring""" from torch.multiprocessing import start_processes with tempfile.NamedTemporaryFile() as tmp_file: # torch.distributed will expect a few environment variable to be here. We set the ones common to each # process here (the other ones will be set be the launcher). with patch_environment( world_size=_lowercase , master_addr='127.0.01' , master_port='29500' , accelerate_mixed_precision='no' , accelerate_debug_rdv_file=tmp_file.name , accelerate_use_cpu='yes' , ): __UpperCamelCase = PrepareForLaunch(_lowercase , debug=_lowercase ) start_processes(_lowercase , args=_lowercase , nprocs=_lowercase , start_method='fork' )

# # This a `torch.distributed` diagnostics script that checks that all GPUs in the cluster (one or # many nodes) can talk to each other via nccl and allocate gpu memory. # # To run first adjust the number of processes and nodes: # # python -m torch.distributed.run --nproc_per_node 2 --nnodes 1 torch-distributed-gpu-test.py # # You may need to add --master_addr $MASTER_ADDR --master_port $MASTER_PORT if using a custom addr:port # # You can also use the rdzv API: --rdzv_endpoint $MASTER_ADDR:$MASTER_PORT --rdzv_backend c10d # # use torch.distributed.launch instead of torch.distributed.run for torch < 1.9 # # If you get a hanging in `barrier` calls you have some network issues, you may try to debug this with: # # NCCL_DEBUG=INFO python -m torch.distributed.run --nproc_per_node 2 --nnodes 1 torch-distributed-gpu-test.py # # which should tell you what's going on behind the scenes. # # # This script can be run via `srun` in the SLURM environment as well. Here is a SLURM script that # runs on 2 nodes of 4 gpus per node: # # #SBATCH --job-name=test-nodes # name # #SBATCH --nodes=2 # nodes # #SBATCH --ntasks-per-node=1 # crucial - only 1 task per dist per node! # #SBATCH --cpus-per-task=10 # number of cores per tasks # #SBATCH --gres=gpu:4 # number of gpus # #SBATCH --time 0:05:00 # maximum execution time (HH:MM:SS) # #SBATCH --output=%x-%j.out # output file name # # GPUS_PER_NODE=4 # MASTER_ADDR=$(scontrol show hostnames $SLURM_JOB_NODELIST | head -n 1) # MASTER_PORT=6000 # # srun --jobid $SLURM_JOBID bash -c 'python -m torch.distributed.run \ # --nproc_per_node $GPUS_PER_NODE --nnodes $SLURM_NNODES --node_rank $SLURM_PROCID \ # --master_addr $MASTER_ADDR --master_port $MASTER_PORT \ # torch-distributed-gpu-test.py' # import fcntl import os import socket import torch import torch.distributed as dist def _A ( *_lowercase ) -> Tuple: """simple docstring""" with open(_lowercase , 'r' ) as fh: fcntl.flock(_lowercase , fcntl.LOCK_EX ) try: print(*_lowercase ) finally: fcntl.flock(_lowercase , fcntl.LOCK_UN ) __snake_case = int(os.environ['''LOCAL_RANK''']) torch.cuda.set_device(local_rank) __snake_case = torch.device('''cuda''', local_rank) __snake_case = socket.gethostname() __snake_case = f"""[{hostname}-{local_rank}]""" try: # test distributed dist.init_process_group('''nccl''') dist.all_reduce(torch.ones(1).to(device), op=dist.ReduceOp.SUM) dist.barrier() # test cuda is available and can allocate memory torch.cuda.is_available() torch.ones(1).cuda(local_rank) # global rank __snake_case = dist.get_rank() __snake_case = dist.get_world_size() printflock(f"""{gpu} is OK (global rank: {rank}/{world_size})""") dist.barrier() if rank == 0: printflock(f"""pt={torch.__version__}, cuda={torch.version.cuda}, nccl={torch.cuda.nccl.version()}""") except Exception: printflock(f"""{gpu} is broken""") raise

import warnings from ...configuration_utils import PretrainedConfig from ...utils import logging __snake_case = logging.get_logger(__name__) __snake_case = { '''xlnet-base-cased''': '''https://huggingface.co/xlnet-base-cased/resolve/main/config.json''', '''xlnet-large-cased''': '''https://huggingface.co/xlnet-large-cased/resolve/main/config.json''', } class __lowerCamelCase (_a ): _lowercase = """xlnet""" _lowercase = ["""mems"""] _lowercase = { """n_token""": """vocab_size""", # Backward compatibility """hidden_size""": """d_model""", """num_attention_heads""": """n_head""", """num_hidden_layers""": """n_layer""", } def __init__( self: Tuple,A_: Optional[int]=3_2000,A_: Tuple=1024,A_: List[Any]=24,A_: Union[str, Any]=16,A_: Union[str, Any]=4096,A_: Dict="gelu",A_: Dict=True,A_: str="bi",A_: Dict=0.0_2,A_: Optional[int]=1E-12,A_: Optional[Any]=0.1,A_: Union[str, Any]=512,A_: str=None,A_: Optional[Any]=True,A_: Union[str, Any]=False,A_: int=False,A_: List[str]=-1,A_: Any=False,A_: Dict="last",A_: int=True,A_: List[str]="tanh",A_: Optional[int]=0.1,A_: int=5,A_: Any=5,A_: Optional[int]=5,A_: Tuple=1,A_: List[str]=2,**A_: List[Any],): '''simple docstring''' __UpperCamelCase = vocab_size __UpperCamelCase = d_model __UpperCamelCase = n_layer __UpperCamelCase = n_head if d_model % n_head != 0: raise ValueError(F'''\'d_model % n_head\' ({d_model % n_head}) should be equal to 0''' ) if "d_head" in kwargs: if kwargs["d_head"] != d_model // n_head: raise ValueError( F'''`d_head` ({kwargs['d_head']}) should be equal to `d_model // n_head` ({d_model // n_head})''' ) __UpperCamelCase = d_model // n_head __UpperCamelCase = ff_activation __UpperCamelCase = d_inner __UpperCamelCase = untie_r __UpperCamelCase = attn_type __UpperCamelCase = initializer_range __UpperCamelCase = layer_norm_eps __UpperCamelCase = dropout __UpperCamelCase = mem_len __UpperCamelCase = reuse_len __UpperCamelCase = bi_data __UpperCamelCase = clamp_len __UpperCamelCase = same_length __UpperCamelCase = summary_type __UpperCamelCase = summary_use_proj __UpperCamelCase = summary_activation __UpperCamelCase = summary_last_dropout __UpperCamelCase = start_n_top __UpperCamelCase = end_n_top __UpperCamelCase = bos_token_id __UpperCamelCase = pad_token_id __UpperCamelCase = eos_token_id if "use_cache" in kwargs: warnings.warn( 'The `use_cache` argument is deprecated and will be removed in a future version, use `use_mems_eval`' ' instead.',A_,) __UpperCamelCase = kwargs['use_cache'] __UpperCamelCase = use_mems_eval __UpperCamelCase = use_mems_train super().__init__(pad_token_id=A_,bos_token_id=A_,eos_token_id=A_,**A_ ) @property def snake_case_ ( self: Tuple ): '''simple docstring''' logger.info(F'''The model {self.model_type} is one of the few models that has no sequence length limit.''' ) return -1 @max_position_embeddings.setter def snake_case_ ( self: int,A_: List[Any] ): '''simple docstring''' raise NotImplementedError( F'''The model {self.model_type} is one of the few models that has no sequence length limit.''' )

import pytest import datasets # Import fixture modules as plugins __snake_case = ['''tests.fixtures.files''', '''tests.fixtures.hub''', '''tests.fixtures.fsspec'''] def _A ( _lowercase , _lowercase ) -> Tuple: """simple docstring""" for item in items: if any(marker in item.keywords for marker in ['integration', 'unit'] ): continue item.add_marker(pytest.mark.unit ) def _A ( _lowercase ) -> str: """simple docstring""" config.addinivalue_line('markers' , 'torchaudio_latest: mark test to run with torchaudio>=0.12' ) @pytest.fixture(autouse=_lowercase ) def _A ( _lowercase , _lowercase ) -> Any: """simple docstring""" __UpperCamelCase = tmp_path_factory.getbasetemp() / 'cache' __UpperCamelCase = test_hf_cache_home / 'datasets' __UpperCamelCase = test_hf_cache_home / 'metrics' __UpperCamelCase = test_hf_cache_home / 'modules' monkeypatch.setattr('datasets.config.HF_DATASETS_CACHE' , str(_lowercase ) ) monkeypatch.setattr('datasets.config.HF_METRICS_CACHE' , str(_lowercase ) ) monkeypatch.setattr('datasets.config.HF_MODULES_CACHE' , str(_lowercase ) ) __UpperCamelCase = test_hf_datasets_cache / 'downloads' monkeypatch.setattr('datasets.config.DOWNLOADED_DATASETS_PATH' , str(_lowercase ) ) __UpperCamelCase = test_hf_datasets_cache / 'downloads' / 'extracted' monkeypatch.setattr('datasets.config.EXTRACTED_DATASETS_PATH' , str(_lowercase ) ) @pytest.fixture(autouse=_lowercase , scope='session' ) def _A ( ) -> Dict: """simple docstring""" datasets.disable_progress_bar() @pytest.fixture(autouse=_lowercase ) def _A ( _lowercase ) -> Tuple: """simple docstring""" monkeypatch.setattr('datasets.config.HF_UPDATE_DOWNLOAD_COUNTS' , _lowercase ) @pytest.fixture def _A ( _lowercase ) -> Any: """simple docstring""" monkeypatch.setattr('sqlalchemy.util.deprecations.SILENCE_UBER_WARNING' , _lowercase )

import importlib import json import os from collections import OrderedDict from typing import Dict, Optional, Union # Build the list of all feature extractors from ...configuration_utils import PretrainedConfig from ...dynamic_module_utils import get_class_from_dynamic_module, resolve_trust_remote_code from ...feature_extraction_utils import FeatureExtractionMixin from ...utils import CONFIG_NAME, FEATURE_EXTRACTOR_NAME, get_file_from_repo, logging from .auto_factory import _LazyAutoMapping from .configuration_auto import ( CONFIG_MAPPING_NAMES, AutoConfig, model_type_to_module_name, replace_list_option_in_docstrings, ) __snake_case = logging.get_logger(__name__) __snake_case = OrderedDict( [ ('''audio-spectrogram-transformer''', '''ASTFeatureExtractor'''), ('''beit''', '''BeitFeatureExtractor'''), ('''chinese_clip''', '''ChineseCLIPFeatureExtractor'''), ('''clap''', '''ClapFeatureExtractor'''), ('''clip''', '''CLIPFeatureExtractor'''), ('''clipseg''', '''ViTFeatureExtractor'''), ('''conditional_detr''', '''ConditionalDetrFeatureExtractor'''), ('''convnext''', '''ConvNextFeatureExtractor'''), ('''cvt''', '''ConvNextFeatureExtractor'''), ('''data2vec-audio''', '''Wav2Vec2FeatureExtractor'''), ('''data2vec-vision''', '''BeitFeatureExtractor'''), ('''deformable_detr''', '''DeformableDetrFeatureExtractor'''), ('''deit''', '''DeiTFeatureExtractor'''), ('''detr''', '''DetrFeatureExtractor'''), ('''dinat''', '''ViTFeatureExtractor'''), ('''donut-swin''', '''DonutFeatureExtractor'''), ('''dpt''', '''DPTFeatureExtractor'''), ('''encodec''', '''EncodecFeatureExtractor'''), ('''flava''', '''FlavaFeatureExtractor'''), ('''glpn''', '''GLPNFeatureExtractor'''), ('''groupvit''', '''CLIPFeatureExtractor'''), ('''hubert''', '''Wav2Vec2FeatureExtractor'''), ('''imagegpt''', '''ImageGPTFeatureExtractor'''), ('''layoutlmv2''', '''LayoutLMv2FeatureExtractor'''), ('''layoutlmv3''', '''LayoutLMv3FeatureExtractor'''), ('''levit''', '''LevitFeatureExtractor'''), ('''maskformer''', '''MaskFormerFeatureExtractor'''), ('''mctct''', '''MCTCTFeatureExtractor'''), ('''mobilenet_v1''', '''MobileNetV1FeatureExtractor'''), ('''mobilenet_v2''', '''MobileNetV2FeatureExtractor'''), ('''mobilevit''', '''MobileViTFeatureExtractor'''), ('''nat''', '''ViTFeatureExtractor'''), ('''owlvit''', '''OwlViTFeatureExtractor'''), ('''perceiver''', '''PerceiverFeatureExtractor'''), ('''poolformer''', '''PoolFormerFeatureExtractor'''), ('''regnet''', '''ConvNextFeatureExtractor'''), ('''resnet''', '''ConvNextFeatureExtractor'''), ('''segformer''', '''SegformerFeatureExtractor'''), ('''sew''', '''Wav2Vec2FeatureExtractor'''), ('''sew-d''', '''Wav2Vec2FeatureExtractor'''), ('''speech_to_text''', '''Speech2TextFeatureExtractor'''), ('''speecht5''', '''SpeechT5FeatureExtractor'''), ('''swiftformer''', '''ViTFeatureExtractor'''), ('''swin''', '''ViTFeatureExtractor'''), ('''swinv2''', '''ViTFeatureExtractor'''), ('''table-transformer''', '''DetrFeatureExtractor'''), ('''timesformer''', '''VideoMAEFeatureExtractor'''), ('''tvlt''', '''TvltFeatureExtractor'''), ('''unispeech''', '''Wav2Vec2FeatureExtractor'''), ('''unispeech-sat''', '''Wav2Vec2FeatureExtractor'''), ('''van''', '''ConvNextFeatureExtractor'''), ('''videomae''', '''VideoMAEFeatureExtractor'''), ('''vilt''', '''ViltFeatureExtractor'''), ('''vit''', '''ViTFeatureExtractor'''), ('''vit_mae''', '''ViTFeatureExtractor'''), ('''vit_msn''', '''ViTFeatureExtractor'''), ('''wav2vec2''', '''Wav2Vec2FeatureExtractor'''), ('''wav2vec2-conformer''', '''Wav2Vec2FeatureExtractor'''), ('''wavlm''', '''Wav2Vec2FeatureExtractor'''), ('''whisper''', '''WhisperFeatureExtractor'''), ('''xclip''', '''CLIPFeatureExtractor'''), ('''yolos''', '''YolosFeatureExtractor'''), ] ) __snake_case = _LazyAutoMapping(CONFIG_MAPPING_NAMES, FEATURE_EXTRACTOR_MAPPING_NAMES) def _A ( _lowercase ) -> str: """simple docstring""" for module_name, extractors in FEATURE_EXTRACTOR_MAPPING_NAMES.items(): if class_name in extractors: __UpperCamelCase = model_type_to_module_name(_lowercase ) __UpperCamelCase = importlib.import_module(f'''.{module_name}''' , 'transformers.models' ) try: return getattr(_lowercase , _lowercase ) except AttributeError: continue for _, extractor in FEATURE_EXTRACTOR_MAPPING._extra_content.items(): if getattr(_lowercase , '__name__' , _lowercase ) == class_name: return extractor # We did not fine the class, but maybe it's because a dep is missing. In that case, the class will be in the main # init and we return the proper dummy to get an appropriate error message. __UpperCamelCase = importlib.import_module('transformers' ) if hasattr(_lowercase , _lowercase ): return getattr(_lowercase , _lowercase ) return None def _A ( _lowercase , _lowercase = None , _lowercase = False , _lowercase = False , _lowercase = None , _lowercase = None , _lowercase = None , _lowercase = False , **_lowercase , ) -> Dict: """simple docstring""" __UpperCamelCase = get_file_from_repo( _lowercase , _lowercase , cache_dir=_lowercase , force_download=_lowercase , resume_download=_lowercase , proxies=_lowercase , use_auth_token=_lowercase , revision=_lowercase , local_files_only=_lowercase , ) if resolved_config_file is None: logger.info( 'Could not locate the feature extractor configuration file, will try to use the model config instead.' ) return {} with open(_lowercase , encoding='utf-8' ) as reader: return json.load(_lowercase ) class __lowerCamelCase : def __init__( self: Union[str, Any] ): '''simple docstring''' raise EnvironmentError( 'AutoFeatureExtractor is designed to be instantiated ' 'using the `AutoFeatureExtractor.from_pretrained(pretrained_model_name_or_path)` method.' ) @classmethod @replace_list_option_in_docstrings(A_ ) def snake_case_ ( cls: List[Any],A_: Dict,**A_: int ): '''simple docstring''' __UpperCamelCase = kwargs.pop('config',A_ ) __UpperCamelCase = kwargs.pop('trust_remote_code',A_ ) __UpperCamelCase = True __UpperCamelCase, __UpperCamelCase = FeatureExtractionMixin.get_feature_extractor_dict(A_,**A_ ) __UpperCamelCase = config_dict.get('feature_extractor_type',A_ ) __UpperCamelCase = None if "AutoFeatureExtractor" in config_dict.get('auto_map',{} ): __UpperCamelCase = config_dict['auto_map']['AutoFeatureExtractor'] # If we don't find the feature extractor class in the feature extractor config, let's try the model config. if feature_extractor_class is None and feature_extractor_auto_map is None: if not isinstance(A_,A_ ): __UpperCamelCase = AutoConfig.from_pretrained(A_,**A_ ) # It could be in `config.feature_extractor_type`` __UpperCamelCase = getattr(A_,'feature_extractor_type',A_ ) if hasattr(A_,'auto_map' ) and "AutoFeatureExtractor" in config.auto_map: __UpperCamelCase = config.auto_map['AutoFeatureExtractor'] if feature_extractor_class is not None: __UpperCamelCase = feature_extractor_class_from_name(A_ ) __UpperCamelCase = feature_extractor_auto_map is not None __UpperCamelCase = feature_extractor_class is not None or type(A_ ) in FEATURE_EXTRACTOR_MAPPING __UpperCamelCase = resolve_trust_remote_code( A_,A_,A_,A_ ) if has_remote_code and trust_remote_code: __UpperCamelCase = get_class_from_dynamic_module( A_,A_,**A_ ) __UpperCamelCase = kwargs.pop('code_revision',A_ ) if os.path.isdir(A_ ): feature_extractor_class.register_for_auto_class() return feature_extractor_class.from_dict(A_,**A_ ) elif feature_extractor_class is not None: return feature_extractor_class.from_dict(A_,**A_ ) # Last try: we use the FEATURE_EXTRACTOR_MAPPING. elif type(A_ ) in FEATURE_EXTRACTOR_MAPPING: __UpperCamelCase = FEATURE_EXTRACTOR_MAPPING[type(A_ )] return feature_extractor_class.from_dict(A_,**A_ ) raise ValueError( F'''Unrecognized feature extractor in {pretrained_model_name_or_path}. Should have a ''' F'''`feature_extractor_type` key in its {FEATURE_EXTRACTOR_NAME} of {CONFIG_NAME}, or one of the following ''' F'''`model_type` keys in its {CONFIG_NAME}: {', '.join(c for c in FEATURE_EXTRACTOR_MAPPING_NAMES.keys() )}''' ) @staticmethod def snake_case_ ( A_: Any,A_: Tuple ): '''simple docstring''' FEATURE_EXTRACTOR_MAPPING.register(A_,A_ )

import random import unittest import numpy as np import torch from transformers import CLIPTextConfig, CLIPTextModel, CLIPTokenizer from diffusers import ( AutoencoderKL, DDIMScheduler, UNetaDConditionModel, VideoToVideoSDPipeline, ) from diffusers.utils import floats_tensor, is_xformers_available, skip_mps from diffusers.utils.testing_utils import enable_full_determinism, slow, torch_device from ..pipeline_params import ( TEXT_GUIDED_IMAGE_VARIATION_BATCH_PARAMS, TEXT_GUIDED_IMAGE_VARIATION_PARAMS, ) from ..test_pipelines_common import PipelineTesterMixin enable_full_determinism() @skip_mps class __lowerCamelCase (_a , unittest.TestCase ): _lowercase = VideoToVideoSDPipeline _lowercase = TEXT_GUIDED_IMAGE_VARIATION_PARAMS.union({"""video"""} ) - {"""image""", """width""", """height"""} _lowercase = TEXT_GUIDED_IMAGE_VARIATION_BATCH_PARAMS.union({"""video"""} ) - {"""image"""} _lowercase = PipelineTesterMixin.required_optional_params - {"""latents"""} _lowercase = False # No `output_type`. _lowercase = frozenset( [ """num_inference_steps""", """generator""", """latents""", """return_dict""", """callback""", """callback_steps""", ] ) def snake_case_ ( self: List[str] ): '''simple docstring''' torch.manual_seed(0 ) __UpperCamelCase = UNetaDConditionModel( block_out_channels=(32, 64, 64, 64),layers_per_block=2,sample_size=32,in_channels=4,out_channels=4,down_block_types=('CrossAttnDownBlock3D', 'CrossAttnDownBlock3D', 'CrossAttnDownBlock3D', 'DownBlock3D'),up_block_types=('UpBlock3D', 'CrossAttnUpBlock3D', 'CrossAttnUpBlock3D', 'CrossAttnUpBlock3D'),cross_attention_dim=32,attention_head_dim=4,) __UpperCamelCase = DDIMScheduler( beta_start=0.0_0_0_8_5,beta_end=0.0_1_2,beta_schedule='scaled_linear',clip_sample=A_,set_alpha_to_one=A_,) torch.manual_seed(0 ) __UpperCamelCase = AutoencoderKL( block_out_channels=[32, 64],in_channels=3,out_channels=3,down_block_types=['DownEncoderBlock2D', 'DownEncoderBlock2D'],up_block_types=['UpDecoderBlock2D', 'UpDecoderBlock2D'],latent_channels=4,sample_size=128,) torch.manual_seed(0 ) __UpperCamelCase = 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,) __UpperCamelCase = CLIPTextModel(A_ ) __UpperCamelCase = CLIPTokenizer.from_pretrained('hf-internal-testing/tiny-random-clip' ) __UpperCamelCase = { 'unet': unet, 'scheduler': scheduler, 'vae': vae, 'text_encoder': text_encoder, 'tokenizer': tokenizer, } return components def snake_case_ ( self: Union[str, Any],A_: Any,A_: Any=0 ): '''simple docstring''' __UpperCamelCase = floats_tensor((1, 3, 3, 32, 32),rng=random.Random(A_ ) ).to(A_ ) if str(A_ ).startswith('mps' ): __UpperCamelCase = torch.manual_seed(A_ ) else: __UpperCamelCase = torch.Generator(device=A_ ).manual_seed(A_ ) __UpperCamelCase = { 'prompt': 'A painting of a squirrel eating a burger', 'video': video, 'generator': generator, 'num_inference_steps': 2, 'guidance_scale': 6.0, 'output_type': 'pt', } return inputs def snake_case_ ( self: Union[str, Any] ): '''simple docstring''' __UpperCamelCase = 'cpu' # ensure determinism for the device-dependent torch.Generator __UpperCamelCase = self.get_dummy_components() __UpperCamelCase = VideoToVideoSDPipeline(**A_ ) __UpperCamelCase = sd_pipe.to(A_ ) sd_pipe.set_progress_bar_config(disable=A_ ) __UpperCamelCase = self.get_dummy_inputs(A_ ) __UpperCamelCase = 'np' __UpperCamelCase = sd_pipe(**A_ ).frames __UpperCamelCase = frames[0][-3:, -3:, -1] assert frames[0].shape == (32, 32, 3) __UpperCamelCase = np.array([106, 117, 113, 174, 137, 112, 148, 151, 131] ) assert np.abs(image_slice.flatten() - expected_slice ).max() < 1E-2 @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: Any ): '''simple docstring''' self._test_xformers_attention_forwardGenerator_pass(test_mean_pixel_difference=A_,expected_max_diff=5E-3 ) @unittest.skip(reason='Batching needs to be properly figured out first for this pipeline.' ) def snake_case_ ( self: str ): '''simple docstring''' pass @unittest.skip(reason='Batching needs to be properly figured out first for this pipeline.' ) def snake_case_ ( self: Optional[Any] ): '''simple docstring''' pass @unittest.skip(reason='`num_images_per_prompt` argument is not supported for this pipeline.' ) def snake_case_ ( self: int ): '''simple docstring''' pass def snake_case_ ( self: Any ): '''simple docstring''' return super().test_progress_bar() @slow @skip_mps class __lowerCamelCase (unittest.TestCase ): def snake_case_ ( self: Tuple ): '''simple docstring''' __UpperCamelCase = VideoToVideoSDPipeline.from_pretrained('cerspense/zeroscope_v2_XL',torch_dtype=torch.floataa ) pipe.enable_model_cpu_offload() # 10 frames __UpperCamelCase = torch.Generator(device='cpu' ).manual_seed(0 ) __UpperCamelCase = torch.randn((1, 10, 3, 1024, 576),generator=A_ ) __UpperCamelCase = video.to('cuda' ) __UpperCamelCase = 'Spiderman is surfing' __UpperCamelCase = pipe(A_,video=A_,generator=A_,num_inference_steps=3,output_type='pt' ).frames __UpperCamelCase = np.array([-1.0_4_5_8_9_8_4, -1.1_2_7_9_2_9_7, -0.9_6_6_3_0_8_6, -0.9_1_5_0_3_9_0_6, -0.7_5_0_9_7_6_5_6] ) assert np.abs(video_frames.cpu().numpy()[0, 0, 0, 0, -5:] - expected_array ).sum() < 1E-2

import random import sys import numpy as np from matplotlib import pyplot as plt from matplotlib.colors import ListedColormap __snake_case = '''Usage of script: script_name <size_of_canvas:int>''' __snake_case = [0] * 1_0_0 + [1] * 1_0 random.shuffle(choice) def _A ( _lowercase ) -> list[list[bool]]: """simple docstring""" __UpperCamelCase = [[False for i in range(_lowercase )] for j in range(_lowercase )] return canvas def _A ( _lowercase ) -> None: """simple docstring""" for i, row in enumerate(_lowercase ): for j, _ in enumerate(_lowercase ): __UpperCamelCase = bool(random.getrandbits(1 ) ) def _A ( _lowercase ) -> list[list[bool]]: """simple docstring""" __UpperCamelCase = np.array(_lowercase ) __UpperCamelCase = np.array(create_canvas(current_canvas.shape[0] ) ) for r, row in enumerate(_lowercase ): for c, pt in enumerate(_lowercase ): __UpperCamelCase = __judge_point( _lowercase , current_canvas[r - 1 : r + 2, c - 1 : c + 2] ) __UpperCamelCase = next_gen_canvas del next_gen_canvas # cleaning memory as we move on. __UpperCamelCase = current_canvas.tolist() return return_canvas def _A ( _lowercase , _lowercase ) -> bool: """simple docstring""" __UpperCamelCase = 0 __UpperCamelCase = 0 # finding dead or alive neighbours count. for i in neighbours: for status in i: if status: alive += 1 else: dead += 1 # handling duplicate entry for focus pt. if pt: alive -= 1 else: dead -= 1 # running the rules of game here. __UpperCamelCase = pt if pt: if alive < 2: __UpperCamelCase = False elif alive == 2 or alive == 3: __UpperCamelCase = True elif alive > 3: __UpperCamelCase = False else: if alive == 3: __UpperCamelCase = True return state if __name__ == "__main__": if len(sys.argv) != 2: raise Exception(usage_doc) __snake_case = int(sys.argv[1]) # main working structure of this module. __snake_case = create_canvas(canvas_size) seed(c) __snake_case , __snake_case = plt.subplots() fig.show() __snake_case = ListedColormap(['''w''', '''k''']) try: while True: __snake_case = run(c) ax.matshow(c, cmap=cmap) fig.canvas.draw() ax.cla() except KeyboardInterrupt: # do nothing. pass

import argparse from transformers import CLIPImageProcessor, CLIPVisionModelWithProjection from diffusers import UnCLIPImageVariationPipeline, UnCLIPPipeline if __name__ == "__main__": __snake_case = argparse.ArgumentParser() parser.add_argument('''--dump_path''', default=None, type=str, required=True, help='''Path to the output model.''') parser.add_argument( '''--txt2img_unclip''', default='''kakaobrain/karlo-v1-alpha''', type=str, required=False, help='''The pretrained txt2img unclip.''', ) __snake_case = parser.parse_args() __snake_case = UnCLIPPipeline.from_pretrained(args.txtaimg_unclip) __snake_case = CLIPImageProcessor() __snake_case = CLIPVisionModelWithProjection.from_pretrained('''openai/clip-vit-large-patch14''') __snake_case = UnCLIPImageVariationPipeline( decoder=txtaimg.decoder, text_encoder=txtaimg.text_encoder, tokenizer=txtaimg.tokenizer, text_proj=txtaimg.text_proj, feature_extractor=feature_extractor, image_encoder=image_encoder, super_res_first=txtaimg.super_res_first, super_res_last=txtaimg.super_res_last, decoder_scheduler=txtaimg.decoder_scheduler, super_res_scheduler=txtaimg.super_res_scheduler, ) imgaimg.save_pretrained(args.dump_path)

import unittest from transformers import ( MODEL_FOR_SEQUENCE_CLASSIFICATION_MAPPING, TF_MODEL_FOR_SEQUENCE_CLASSIFICATION_MAPPING, Pipeline, ZeroShotClassificationPipeline, pipeline, ) from transformers.testing_utils import is_pipeline_test, nested_simplify, require_tf, require_torch, slow from .test_pipelines_common import ANY # These 2 model types require different inputs than those of the usual text models. __snake_case = {'''LayoutLMv2Config''', '''LayoutLMv3Config'''} @is_pipeline_test class __lowerCamelCase (unittest.TestCase ): _lowercase = MODEL_FOR_SEQUENCE_CLASSIFICATION_MAPPING _lowercase = TF_MODEL_FOR_SEQUENCE_CLASSIFICATION_MAPPING if model_mapping is not None: _lowercase = {config: model for config, model in model_mapping.items() if config.__name__ not in _TO_SKIP} if tf_model_mapping is not None: _lowercase = { config: model for config, model in tf_model_mapping.items() if config.__name__ not in _TO_SKIP } def snake_case_ ( self: Tuple,A_: List[str],A_: str,A_: str ): '''simple docstring''' __UpperCamelCase = ZeroShotClassificationPipeline( model=A_,tokenizer=A_,candidate_labels=['polics', 'health'] ) return classifier, ["Who are you voting for in 2020?", "My stomach hurts."] def snake_case_ ( self: Optional[Any],A_: Tuple,A_: List[Any] ): '''simple docstring''' __UpperCamelCase = classifier('Who are you voting for in 2020?',candidate_labels='politics' ) self.assertEqual(A_,{'sequence': ANY(A_ ), 'labels': [ANY(A_ )], 'scores': [ANY(A_ )]} ) # No kwarg __UpperCamelCase = classifier('Who are you voting for in 2020?',['politics'] ) self.assertEqual(A_,{'sequence': ANY(A_ ), 'labels': [ANY(A_ )], 'scores': [ANY(A_ )]} ) __UpperCamelCase = classifier('Who are you voting for in 2020?',candidate_labels=['politics'] ) self.assertEqual(A_,{'sequence': ANY(A_ ), 'labels': [ANY(A_ )], 'scores': [ANY(A_ )]} ) __UpperCamelCase = classifier('Who are you voting for in 2020?',candidate_labels='politics, public health' ) self.assertEqual( A_,{'sequence': ANY(A_ ), 'labels': [ANY(A_ ), ANY(A_ )], 'scores': [ANY(A_ ), ANY(A_ )]} ) self.assertAlmostEqual(sum(nested_simplify(outputs['scores'] ) ),1.0 ) __UpperCamelCase = classifier('Who are you voting for in 2020?',candidate_labels=['politics', 'public health'] ) self.assertEqual( A_,{'sequence': ANY(A_ ), 'labels': [ANY(A_ ), ANY(A_ )], 'scores': [ANY(A_ ), ANY(A_ )]} ) self.assertAlmostEqual(sum(nested_simplify(outputs['scores'] ) ),1.0 ) __UpperCamelCase = classifier( 'Who are you voting for in 2020?',candidate_labels='politics',hypothesis_template='This text is about {}' ) self.assertEqual(A_,{'sequence': ANY(A_ ), 'labels': [ANY(A_ )], 'scores': [ANY(A_ )]} ) # https://github.com/huggingface/transformers/issues/13846 __UpperCamelCase = classifier(['I am happy'],['positive', 'negative'] ) self.assertEqual( A_,[ {'sequence': ANY(A_ ), 'labels': [ANY(A_ ), ANY(A_ )], 'scores': [ANY(A_ ), ANY(A_ )]} for i in range(1 ) ],) __UpperCamelCase = classifier(['I am happy', 'I am sad'],['positive', 'negative'] ) self.assertEqual( A_,[ {'sequence': ANY(A_ ), 'labels': [ANY(A_ ), ANY(A_ )], 'scores': [ANY(A_ ), ANY(A_ )]} for i in range(2 ) ],) with self.assertRaises(A_ ): classifier('',candidate_labels='politics' ) with self.assertRaises(A_ ): classifier(A_,candidate_labels='politics' ) with self.assertRaises(A_ ): classifier('Who are you voting for in 2020?',candidate_labels='' ) with self.assertRaises(A_ ): classifier('Who are you voting for in 2020?',candidate_labels=A_ ) with self.assertRaises(A_ ): classifier( 'Who are you voting for in 2020?',candidate_labels='politics',hypothesis_template='Not formatting template',) with self.assertRaises(A_ ): classifier( 'Who are you voting for in 2020?',candidate_labels='politics',hypothesis_template=A_,) self.run_entailment_id(A_ ) def snake_case_ ( self: List[str],A_: Pipeline ): '''simple docstring''' __UpperCamelCase = zero_shot_classifier.model.config __UpperCamelCase = config.labelaid __UpperCamelCase = zero_shot_classifier.entailment_id __UpperCamelCase = {'LABEL_0': 0, 'LABEL_1': 1, 'LABEL_2': 2} self.assertEqual(zero_shot_classifier.entailment_id,-1 ) __UpperCamelCase = {'entailment': 0, 'neutral': 1, 'contradiction': 2} self.assertEqual(zero_shot_classifier.entailment_id,0 ) __UpperCamelCase = {'ENTAIL': 0, 'NON-ENTAIL': 1} self.assertEqual(zero_shot_classifier.entailment_id,0 ) __UpperCamelCase = {'ENTAIL': 2, 'NEUTRAL': 1, 'CONTR': 0} self.assertEqual(zero_shot_classifier.entailment_id,2 ) __UpperCamelCase = original_labelaid self.assertEqual(A_,zero_shot_classifier.entailment_id ) @require_torch def snake_case_ ( self: List[Any] ): '''simple docstring''' __UpperCamelCase = pipeline( 'zero-shot-classification',model='sshleifer/tiny-distilbert-base-cased-distilled-squad',framework='pt',) # There was a regression in 4.10 for this # Adding a test so we don't make the mistake again. # https://github.com/huggingface/transformers/issues/13381#issuecomment-912343499 zero_shot_classifier( 'Who are you voting for in 2020?' * 100,candidate_labels=['politics', 'public health', 'science'] ) @require_torch def snake_case_ ( self: str ): '''simple docstring''' __UpperCamelCase = pipeline( 'zero-shot-classification',model='sshleifer/tiny-distilbert-base-cased-distilled-squad',framework='pt',) __UpperCamelCase = zero_shot_classifier( 'Who are you voting for in 2020?',candidate_labels=['politics', 'public health', 'science'] ) self.assertEqual( nested_simplify(A_ ),{ 'sequence': 'Who are you voting for in 2020?', 'labels': ['science', 'public health', 'politics'], 'scores': [0.3_3_3, 0.3_3_3, 0.3_3_3], },) @require_tf def snake_case_ ( self: List[str] ): '''simple docstring''' __UpperCamelCase = pipeline( 'zero-shot-classification',model='sshleifer/tiny-distilbert-base-cased-distilled-squad',framework='tf',) __UpperCamelCase = zero_shot_classifier( 'Who are you voting for in 2020?',candidate_labels=['politics', 'public health', 'science'] ) self.assertEqual( nested_simplify(A_ ),{ 'sequence': 'Who are you voting for in 2020?', 'labels': ['science', 'public health', 'politics'], 'scores': [0.3_3_3, 0.3_3_3, 0.3_3_3], },) @slow @require_torch def snake_case_ ( self: Tuple ): '''simple docstring''' __UpperCamelCase = pipeline('zero-shot-classification',model='roberta-large-mnli',framework='pt' ) __UpperCamelCase = zero_shot_classifier( 'Who are you voting for in 2020?',candidate_labels=['politics', 'public health', 'science'] ) self.assertEqual( nested_simplify(A_ ),{ 'sequence': 'Who are you voting for in 2020?', 'labels': ['politics', 'public health', 'science'], 'scores': [0.9_7_6, 0.0_1_5, 0.0_0_9], },) __UpperCamelCase = zero_shot_classifier( 'The dominant sequence transduction models are based on complex recurrent or convolutional neural networks' ' in an encoder-decoder configuration. The best performing models also connect the encoder and decoder' ' through an attention mechanism. We propose a new simple network architecture, the Transformer, based' ' solely on attention mechanisms, dispensing with recurrence and convolutions entirely. Experiments on two' ' machine translation tasks show these models to be superior in quality while being more parallelizable' ' and requiring significantly less time to train. Our model achieves 28.4 BLEU on the WMT 2014' ' English-to-German translation task, improving over the existing best results, including ensembles by' ' over 2 BLEU. On the WMT 2014 English-to-French translation task, our model establishes a new' ' single-model state-of-the-art BLEU score of 41.8 after training for 3.5 days on eight GPUs, a small' ' fraction of the training costs of the best models from the literature. We show that the Transformer' ' generalizes well to other tasks by applying it successfully to English constituency parsing both with' ' large and limited training data.',candidate_labels=['machine learning', 'statistics', 'translation', 'vision'],multi_label=A_,) self.assertEqual( nested_simplify(A_ ),{ 'sequence': ( 'The dominant sequence transduction models are based on complex recurrent or convolutional neural' ' networks in an encoder-decoder configuration. The best performing models also connect the' ' encoder and decoder through an attention mechanism. We propose a new simple network' ' architecture, the Transformer, based solely on attention mechanisms, dispensing with recurrence' ' and convolutions entirely. Experiments on two machine translation tasks show these models to be' ' superior in quality while being more parallelizable and requiring significantly less time to' ' train. Our model achieves 28.4 BLEU on the WMT 2014 English-to-German translation task,' ' improving over the existing best results, including ensembles by over 2 BLEU. On the WMT 2014' ' English-to-French translation task, our model establishes a new single-model state-of-the-art' ' BLEU score of 41.8 after training for 3.5 days on eight GPUs, a small fraction of the training' ' costs of the best models from the literature. We show that the Transformer generalizes well to' ' other tasks by applying it successfully to English constituency parsing both with large and' ' limited training data.' ), 'labels': ['translation', 'machine learning', 'vision', 'statistics'], 'scores': [0.8_1_7, 0.7_1_3, 0.0_1_8, 0.0_1_8], },) @slow @require_tf def snake_case_ ( self: Tuple ): '''simple docstring''' __UpperCamelCase = pipeline('zero-shot-classification',model='roberta-large-mnli',framework='tf' ) __UpperCamelCase = zero_shot_classifier( 'Who are you voting for in 2020?',candidate_labels=['politics', 'public health', 'science'] ) self.assertEqual( nested_simplify(A_ ),{ 'sequence': 'Who are you voting for in 2020?', 'labels': ['politics', 'public health', 'science'], 'scores': [0.9_7_6, 0.0_1_5, 0.0_0_9], },) __UpperCamelCase = zero_shot_classifier( 'The dominant sequence transduction models are based on complex recurrent or convolutional neural networks' ' in an encoder-decoder configuration. The best performing models also connect the encoder and decoder' ' through an attention mechanism. We propose a new simple network architecture, the Transformer, based' ' solely on attention mechanisms, dispensing with recurrence and convolutions entirely. Experiments on two' ' machine translation tasks show these models to be superior in quality while being more parallelizable' ' and requiring significantly less time to train. Our model achieves 28.4 BLEU on the WMT 2014' ' English-to-German translation task, improving over the existing best results, including ensembles by' ' over 2 BLEU. On the WMT 2014 English-to-French translation task, our model establishes a new' ' single-model state-of-the-art BLEU score of 41.8 after training for 3.5 days on eight GPUs, a small' ' fraction of the training costs of the best models from the literature. We show that the Transformer' ' generalizes well to other tasks by applying it successfully to English constituency parsing both with' ' large and limited training data.',candidate_labels=['machine learning', 'statistics', 'translation', 'vision'],multi_label=A_,) self.assertEqual( nested_simplify(A_ ),{ 'sequence': ( 'The dominant sequence transduction models are based on complex recurrent or convolutional neural' ' networks in an encoder-decoder configuration. The best performing models also connect the' ' encoder and decoder through an attention mechanism. We propose a new simple network' ' architecture, the Transformer, based solely on attention mechanisms, dispensing with recurrence' ' and convolutions entirely. Experiments on two machine translation tasks show these models to be' ' superior in quality while being more parallelizable and requiring significantly less time to' ' train. Our model achieves 28.4 BLEU on the WMT 2014 English-to-German translation task,' ' improving over the existing best results, including ensembles by over 2 BLEU. On the WMT 2014' ' English-to-French translation task, our model establishes a new single-model state-of-the-art' ' BLEU score of 41.8 after training for 3.5 days on eight GPUs, a small fraction of the training' ' costs of the best models from the literature. We show that the Transformer generalizes well to' ' other tasks by applying it successfully to English constituency parsing both with large and' ' limited training data.' ), 'labels': ['translation', 'machine learning', 'vision', 'statistics'], 'scores': [0.8_1_7, 0.7_1_3, 0.0_1_8, 0.0_1_8], },)

from typing import TYPE_CHECKING # rely on isort to merge the imports from ...utils import OptionalDependencyNotAvailable, _LazyModule, is_torch_available __snake_case = { '''configuration_autoformer''': [ '''AUTOFORMER_PRETRAINED_CONFIG_ARCHIVE_MAP''', '''AutoformerConfig''', ], } try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __snake_case = [ '''AUTOFORMER_PRETRAINED_MODEL_ARCHIVE_LIST''', '''AutoformerForPrediction''', '''AutoformerModel''', '''AutoformerPreTrainedModel''', ] if TYPE_CHECKING: from .configuration_autoformer import ( AUTOFORMER_PRETRAINED_CONFIG_ARCHIVE_MAP, AutoformerConfig, ) try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_autoformer import ( AUTOFORMER_PRETRAINED_MODEL_ARCHIVE_LIST, AutoformerForPrediction, AutoformerModel, AutoformerPreTrainedModel, ) else: import sys __snake_case = _LazyModule(__name__, globals()['''__file__'''], _import_structure, module_spec=__spec__)

def _A ( _lowercase = 10_00 ) -> int: """simple docstring""" __UpperCamelCase = 3 __UpperCamelCase = 0 while a < n: if a % 3 == 0 or a % 5 == 0: result += a elif a % 15 == 0: result -= a a += 1 return result if __name__ == "__main__": print(f"""{solution() = }""")

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 = ''' {0} = None ''' __snake_case = ''' class {0}(metaclass=DummyObject): _backends = {1} def __init__(self, *args, **kwargs): requires_backends(self, {1}) @classmethod def from_config(cls, *args, **kwargs): requires_backends(cls, {1}) @classmethod def from_pretrained(cls, *args, **kwargs): requires_backends(cls, {1}) ''' __snake_case = ''' def {0}(*args, **kwargs): requires_backends({0}, {1}) ''' def _A ( _lowercase ) -> int: """simple docstring""" __UpperCamelCase = _re_backend.findall(_lowercase ) if len(_lowercase ) == 0: return None return "_and_".join(_lowercase ) def _A ( ) -> Tuple: """simple docstring""" with open(os.path.join(_lowercase , '__init__.py' ) , 'r' , encoding='utf-8' , newline='\n' ) as f: __UpperCamelCase = f.readlines() # Get to the point we do the actual imports for type checking __UpperCamelCase = 0 __UpperCamelCase = {} # Go through the end of the file while line_index < len(_lowercase ): # If the line contains is_backend_available, we grab all objects associated with the `else` block __UpperCamelCase = find_backend(lines[line_index] ) if backend is not None: while not lines[line_index].startswith('else:' ): line_index += 1 line_index += 1 __UpperCamelCase = [] # Until we unindent, add backend objects to the list while line_index < len(_lowercase ) and len(lines[line_index] ) > 1: __UpperCamelCase = lines[line_index] __UpperCamelCase = _re_single_line_import.search(_lowercase ) 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(_lowercase ) > 0: __UpperCamelCase = objects else: line_index += 1 return backend_specific_objects def _A ( _lowercase , _lowercase ) -> Union[str, Any]: """simple docstring""" if name.isupper(): return DUMMY_CONSTANT.format(_lowercase ) elif name.islower(): return DUMMY_FUNCTION.format(_lowercase , _lowercase ) else: return DUMMY_CLASS.format(_lowercase , _lowercase ) def _A ( _lowercase=None ) -> Optional[Any]: """simple docstring""" if backend_specific_objects is None: __UpperCamelCase = read_init() # For special correspondence backend to module name as used in the function requires_modulename __UpperCamelCase = {} for backend, objects in backend_specific_objects.items(): __UpperCamelCase = '[' + ', '.join(f'''"{b}"''' for b in backend.split('_and_' ) ) + ']' __UpperCamelCase = '# 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(_lowercase , _lowercase ) for o in objects] ) __UpperCamelCase = dummy_file return dummy_files def _A ( _lowercase=False ) -> List[str]: """simple docstring""" __UpperCamelCase = create_dummy_files() # For special correspondence backend to shortcut as used in utils/dummy_xxx_objects.py __UpperCamelCase = {'torch': 'pt'} # Locate actual dummy modules and read their content. __UpperCamelCase = os.path.join(_lowercase , 'utils' ) __UpperCamelCase = { backend: os.path.join(_lowercase , f'''dummy_{short_names.get(_lowercase , _lowercase )}_objects.py''' ) for backend in dummy_files.keys() } __UpperCamelCase = {} for backend, file_path in dummy_file_paths.items(): if os.path.isfile(_lowercase ): with open(_lowercase , 'r' , encoding='utf-8' , newline='\n' ) as f: __UpperCamelCase = f.read() else: __UpperCamelCase = '' for backend in dummy_files.keys(): if dummy_files[backend] != actual_dummies[backend]: if overwrite: print( f'''Updating diffusers.utils.dummy_{short_names.get(_lowercase , _lowercase )}_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(_lowercase , _lowercase )}_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)

from math import pow, sqrt def _A ( *_lowercase ) -> bool: """simple docstring""" __UpperCamelCase = len(_lowercase ) > 0 and all(value > 0.0 for value in values ) return result def _A ( _lowercase , _lowercase ) -> float | ValueError: """simple docstring""" return ( round(sqrt(molar_mass_a / molar_mass_a ) , 6 ) if validate(_lowercase , _lowercase ) else ValueError('Input Error: Molar mass values must greater than 0.' ) ) def _A ( _lowercase , _lowercase , _lowercase ) -> float | ValueError: """simple docstring""" return ( round(effusion_rate * sqrt(molar_mass_a / molar_mass_a ) , 6 ) if validate(_lowercase , _lowercase , _lowercase ) else ValueError( 'Input Error: Molar mass and effusion rate values must greater than 0.' ) ) def _A ( _lowercase , _lowercase , _lowercase ) -> float | ValueError: """simple docstring""" return ( round(effusion_rate / sqrt(molar_mass_a / molar_mass_a ) , 6 ) if validate(_lowercase , _lowercase , _lowercase ) else ValueError( 'Input Error: Molar mass and effusion rate values must greater than 0.' ) ) def _A ( _lowercase , _lowercase , _lowercase ) -> float | ValueError: """simple docstring""" return ( round(molar_mass / pow(effusion_rate_a / effusion_rate_a , 2 ) , 6 ) if validate(_lowercase , _lowercase , _lowercase ) else ValueError( 'Input Error: Molar mass and effusion rate values must greater than 0.' ) ) def _A ( _lowercase , _lowercase , _lowercase ) -> float | ValueError: """simple docstring""" return ( round(pow(effusion_rate_a / effusion_rate_a , 2 ) / molar_mass , 6 ) if validate(_lowercase , _lowercase , _lowercase ) else ValueError( 'Input Error: Molar mass and effusion rate values must greater than 0.' ) )

import string def _A ( _lowercase ) -> None: """simple docstring""" for key in range(len(string.ascii_uppercase ) ): __UpperCamelCase = '' for symbol in message: if symbol in string.ascii_uppercase: __UpperCamelCase = string.ascii_uppercase.find(_lowercase ) __UpperCamelCase = num - key if num < 0: __UpperCamelCase = num + len(string.ascii_uppercase ) __UpperCamelCase = translated + string.ascii_uppercase[num] else: __UpperCamelCase = translated + symbol print(f'''Decryption using Key #{key}: {translated}''' ) def _A ( ) -> None: """simple docstring""" __UpperCamelCase = input('Encrypted message: ' ) __UpperCamelCase = message.upper() decrypt(_lowercase ) if __name__ == "__main__": import doctest doctest.testmod() main()

import argparse import json from tqdm import tqdm def _A ( ) -> Optional[Any]: """simple docstring""" __UpperCamelCase = argparse.ArgumentParser() # Required parameters parser.add_argument( '--src_path' , type=_lowercase , default='biencoder-nq-dev.json' , help='Path to raw DPR training data' , ) parser.add_argument( '--evaluation_set' , type=_lowercase , help='where to store parsed evaluation_set file' , ) parser.add_argument( '--gold_data_path' , type=_lowercase , help='where to store parsed gold_data_path file' , ) __UpperCamelCase = parser.parse_args() with open(args.src_path , 'r' ) as src_file, open(args.evaluation_set , 'w' ) as eval_file, open( args.gold_data_path , 'w' ) as gold_file: __UpperCamelCase = json.load(_lowercase ) for dpr_record in tqdm(_lowercase ): __UpperCamelCase = dpr_record['question'] __UpperCamelCase = [context['title'] for context in dpr_record['positive_ctxs']] eval_file.write(question + '\n' ) gold_file.write('\t'.join(_lowercase ) + '\n' ) if __name__ == "__main__": main()

import gc import random import unittest import numpy as np import torch from PIL import Image from transformers import XLMRobertaTokenizerFast from diffusers import DDIMScheduler, KandinskyInpaintPipeline, KandinskyPriorPipeline, UNetaDConditionModel, VQModel from diffusers.pipelines.kandinsky.text_encoder import MCLIPConfig, MultilingualCLIP from diffusers.utils import floats_tensor, load_image, load_numpy, slow, torch_device from diffusers.utils.testing_utils import enable_full_determinism, require_torch_gpu from ..test_pipelines_common import PipelineTesterMixin, assert_mean_pixel_difference enable_full_determinism() class __lowerCamelCase (_a , unittest.TestCase ): _lowercase = KandinskyInpaintPipeline _lowercase = ["""prompt""", """image_embeds""", """negative_image_embeds""", """image""", """mask_image"""] _lowercase = [ """prompt""", """negative_prompt""", """image_embeds""", """negative_image_embeds""", """image""", """mask_image""", ] _lowercase = [ """generator""", """height""", """width""", """latents""", """guidance_scale""", """negative_prompt""", """num_inference_steps""", """return_dict""", """guidance_scale""", """num_images_per_prompt""", """output_type""", """return_dict""", ] _lowercase = False @property def snake_case_ ( self: int ): '''simple docstring''' return 32 @property def snake_case_ ( self: str ): '''simple docstring''' return 32 @property def snake_case_ ( self: Tuple ): '''simple docstring''' return self.time_input_dim @property def snake_case_ ( self: Union[str, Any] ): '''simple docstring''' return self.time_input_dim * 4 @property def snake_case_ ( self: Optional[int] ): '''simple docstring''' return 100 @property def snake_case_ ( self: str ): '''simple docstring''' __UpperCamelCase = XLMRobertaTokenizerFast.from_pretrained('YiYiXu/tiny-random-mclip-base' ) return tokenizer @property def snake_case_ ( self: Any ): '''simple docstring''' torch.manual_seed(0 ) __UpperCamelCase = MCLIPConfig( numDims=self.cross_attention_dim,transformerDimensions=self.text_embedder_hidden_size,hidden_size=self.text_embedder_hidden_size,intermediate_size=37,num_attention_heads=4,num_hidden_layers=5,vocab_size=1005,) __UpperCamelCase = MultilingualCLIP(A_ ) __UpperCamelCase = text_encoder.eval() return text_encoder @property def snake_case_ ( self: Any ): '''simple docstring''' torch.manual_seed(0 ) __UpperCamelCase = { 'in_channels': 9, # Out channels is double in channels because predicts mean and variance 'out_channels': 8, 'addition_embed_type': 'text_image', 'down_block_types': ('ResnetDownsampleBlock2D', 'SimpleCrossAttnDownBlock2D'), 'up_block_types': ('SimpleCrossAttnUpBlock2D', 'ResnetUpsampleBlock2D'), 'mid_block_type': 'UNetMidBlock2DSimpleCrossAttn', 'block_out_channels': (self.block_out_channels_a, self.block_out_channels_a * 2), 'layers_per_block': 1, 'encoder_hid_dim': self.text_embedder_hidden_size, 'encoder_hid_dim_type': 'text_image_proj', 'cross_attention_dim': self.cross_attention_dim, 'attention_head_dim': 4, 'resnet_time_scale_shift': 'scale_shift', 'class_embed_type': None, } __UpperCamelCase = UNetaDConditionModel(**A_ ) return model @property def snake_case_ ( self: str ): '''simple docstring''' return { "block_out_channels": [32, 64], "down_block_types": ["DownEncoderBlock2D", "AttnDownEncoderBlock2D"], "in_channels": 3, "latent_channels": 4, "layers_per_block": 1, "norm_num_groups": 8, "norm_type": "spatial", "num_vq_embeddings": 12, "out_channels": 3, "up_block_types": [ "AttnUpDecoderBlock2D", "UpDecoderBlock2D", ], "vq_embed_dim": 4, } @property def snake_case_ ( self: str ): '''simple docstring''' torch.manual_seed(0 ) __UpperCamelCase = VQModel(**self.dummy_movq_kwargs ) return model def snake_case_ ( self: Dict ): '''simple docstring''' __UpperCamelCase = self.dummy_text_encoder __UpperCamelCase = self.dummy_tokenizer __UpperCamelCase = self.dummy_unet __UpperCamelCase = self.dummy_movq __UpperCamelCase = DDIMScheduler( num_train_timesteps=1000,beta_schedule='linear',beta_start=0.0_0_0_8_5,beta_end=0.0_1_2,clip_sample=A_,set_alpha_to_one=A_,steps_offset=1,prediction_type='epsilon',thresholding=A_,) __UpperCamelCase = { 'text_encoder': text_encoder, 'tokenizer': tokenizer, 'unet': unet, 'scheduler': scheduler, 'movq': movq, } return components def snake_case_ ( self: Tuple,A_: Optional[int],A_: Dict=0 ): '''simple docstring''' __UpperCamelCase = floats_tensor((1, self.cross_attention_dim),rng=random.Random(A_ ) ).to(A_ ) __UpperCamelCase = floats_tensor((1, self.cross_attention_dim),rng=random.Random(seed + 1 ) ).to(A_ ) # create init_image __UpperCamelCase = floats_tensor((1, 3, 64, 64),rng=random.Random(A_ ) ).to(A_ ) __UpperCamelCase = image.cpu().permute(0,2,3,1 )[0] __UpperCamelCase = Image.fromarray(np.uinta(A_ ) ).convert('RGB' ).resize((256, 256) ) # create mask __UpperCamelCase = np.ones((64, 64),dtype=np.floataa ) __UpperCamelCase = 0 if str(A_ ).startswith('mps' ): __UpperCamelCase = torch.manual_seed(A_ ) else: __UpperCamelCase = torch.Generator(device=A_ ).manual_seed(A_ ) __UpperCamelCase = { 'prompt': 'horse', 'image': init_image, 'mask_image': mask, 'image_embeds': image_embeds, 'negative_image_embeds': negative_image_embeds, 'generator': generator, 'height': 64, 'width': 64, 'num_inference_steps': 2, 'guidance_scale': 4.0, 'output_type': 'np', } return inputs def snake_case_ ( self: Any ): '''simple docstring''' __UpperCamelCase = 'cpu' __UpperCamelCase = self.get_dummy_components() __UpperCamelCase = self.pipeline_class(**A_ ) __UpperCamelCase = pipe.to(A_ ) pipe.set_progress_bar_config(disable=A_ ) __UpperCamelCase = pipe(**self.get_dummy_inputs(A_ ) ) __UpperCamelCase = output.images __UpperCamelCase = pipe( **self.get_dummy_inputs(A_ ),return_dict=A_,)[0] __UpperCamelCase = image[0, -3:, -3:, -1] __UpperCamelCase = image_from_tuple[0, -3:, -3:, -1] print(F'''image.shape {image.shape}''' ) assert image.shape == (1, 64, 64, 3) __UpperCamelCase = np.array( [0.8_3_2_6_9_1_9, 0.7_3_7_9_0_4_6_7, 0.2_0_9_1_8_5_8_1, 0.9_3_0_9_6_1_2, 0.5_5_1_1_7_9_1, 0.4_3_7_1_3_3_2_8, 0.5_5_1_3_3_2_1, 0.4_9_9_2_2_9_3_4, 0.5_9_4_9_7_7_8_6] ) assert ( np.abs(image_slice.flatten() - expected_slice ).max() < 1E-2 ), F''' expected_slice {expected_slice}, but got {image_slice.flatten()}''' assert ( np.abs(image_from_tuple_slice.flatten() - expected_slice ).max() < 1E-2 ), F''' expected_slice {expected_slice}, but got {image_from_tuple_slice.flatten()}''' def snake_case_ ( self: Optional[Any] ): '''simple docstring''' super().test_inference_batch_single_identical(expected_max_diff=3E-3 ) @slow @require_torch_gpu class __lowerCamelCase (unittest.TestCase ): def snake_case_ ( self: Tuple ): '''simple docstring''' super().tearDown() gc.collect() torch.cuda.empty_cache() def snake_case_ ( self: Any ): '''simple docstring''' __UpperCamelCase = load_numpy( 'https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main' '/kandinsky/kandinsky_inpaint_cat_with_hat_fp16.npy' ) __UpperCamelCase = load_image( 'https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main' '/kandinsky/cat.png' ) __UpperCamelCase = np.ones((768, 768),dtype=np.floataa ) __UpperCamelCase = 0 __UpperCamelCase = 'a hat' __UpperCamelCase = KandinskyPriorPipeline.from_pretrained( 'kandinsky-community/kandinsky-2-1-prior',torch_dtype=torch.floataa ) pipe_prior.to(A_ ) __UpperCamelCase = KandinskyInpaintPipeline.from_pretrained( 'kandinsky-community/kandinsky-2-1-inpaint',torch_dtype=torch.floataa ) __UpperCamelCase = pipeline.to(A_ ) pipeline.set_progress_bar_config(disable=A_ ) __UpperCamelCase = torch.Generator(device='cpu' ).manual_seed(0 ) __UpperCamelCase, __UpperCamelCase = pipe_prior( A_,generator=A_,num_inference_steps=5,negative_prompt='',).to_tuple() __UpperCamelCase = pipeline( A_,image=A_,mask_image=A_,image_embeds=A_,negative_image_embeds=A_,generator=A_,num_inference_steps=100,height=768,width=768,output_type='np',) __UpperCamelCase = output.images[0] assert image.shape == (768, 768, 3) assert_mean_pixel_difference(A_,A_ )

from copy import deepcopy from typing import Optional, Union import numpy as np from ...processing_utils import ProcessorMixin from ...tokenization_utils_base import BatchEncoding from ...utils import TensorType, is_tf_available, is_torch_available if is_torch_available(): import torch if is_tf_available(): import tensorflow as tf class __lowerCamelCase (_a ): _lowercase = ["""image_processor"""] _lowercase = """SamImageProcessor""" def __init__( self: Dict,A_: Union[str, Any] ): '''simple docstring''' super().__init__(A_ ) __UpperCamelCase = self.image_processor __UpperCamelCase = -10 __UpperCamelCase = self.image_processor.size['longest_edge'] def __call__( self: Optional[Any],A_: Optional[int]=None,A_: int=None,A_: str=None,A_: str=None,A_: Optional[Union[str, TensorType]] = None,**A_: Optional[int],): '''simple docstring''' __UpperCamelCase = self.image_processor( A_,return_tensors=A_,**A_,) # pop arguments that are not used in the foward but used nevertheless __UpperCamelCase = encoding_image_processor['original_sizes'] if hasattr(A_,'numpy' ): # Checks if Torch or TF tensor __UpperCamelCase = original_sizes.numpy() __UpperCamelCase, __UpperCamelCase, __UpperCamelCase = self._check_and_preprocess_points( input_points=A_,input_labels=A_,input_boxes=A_,) __UpperCamelCase = self._normalize_and_convert( A_,A_,input_points=A_,input_labels=A_,input_boxes=A_,return_tensors=A_,) return encoding_image_processor def snake_case_ ( self: Tuple,A_: Any,A_: str,A_: Dict=None,A_: Dict=None,A_: int=None,A_: List[Any]="pt",): '''simple docstring''' if input_points is not None: if len(A_ ) != len(A_ ): __UpperCamelCase = [ self._normalize_coordinates(self.target_size,A_,original_sizes[0] ) for point in input_points ] else: __UpperCamelCase = [ self._normalize_coordinates(self.target_size,A_,A_ ) for point, original_size in zip(A_,A_ ) ] # check that all arrays have the same shape if not all(point.shape == input_points[0].shape for point in input_points ): if input_labels is not None: __UpperCamelCase, __UpperCamelCase = self._pad_points_and_labels(A_,A_ ) __UpperCamelCase = np.array(A_ ) if input_labels is not None: __UpperCamelCase = np.array(A_ ) if input_boxes is not None: if len(A_ ) != len(A_ ): __UpperCamelCase = [ self._normalize_coordinates(self.target_size,A_,original_sizes[0],is_bounding_box=A_ ) for box in input_boxes ] else: __UpperCamelCase = [ self._normalize_coordinates(self.target_size,A_,A_,is_bounding_box=A_ ) for box, original_size in zip(A_,A_ ) ] __UpperCamelCase = np.array(A_ ) if input_boxes is not None: if return_tensors == "pt": __UpperCamelCase = torch.from_numpy(A_ ) # boxes batch size of 1 by default __UpperCamelCase = input_boxes.unsqueeze(1 ) if len(input_boxes.shape ) != 3 else input_boxes elif return_tensors == "tf": __UpperCamelCase = tf.convert_to_tensor(A_ ) # boxes batch size of 1 by default __UpperCamelCase = tf.expand_dims(A_,1 ) if len(input_boxes.shape ) != 3 else input_boxes encoding_image_processor.update({'input_boxes': input_boxes} ) if input_points is not None: if return_tensors == "pt": __UpperCamelCase = torch.from_numpy(A_ ) # point batch size of 1 by default __UpperCamelCase = input_points.unsqueeze(1 ) if len(input_points.shape ) != 4 else input_points elif return_tensors == "tf": __UpperCamelCase = tf.convert_to_tensor(A_ ) # point batch size of 1 by default __UpperCamelCase = tf.expand_dims(A_,1 ) if len(input_points.shape ) != 4 else input_points encoding_image_processor.update({'input_points': input_points} ) if input_labels is not None: if return_tensors == "pt": __UpperCamelCase = torch.from_numpy(A_ ) # point batch size of 1 by default __UpperCamelCase = input_labels.unsqueeze(1 ) if len(input_labels.shape ) != 3 else input_labels elif return_tensors == "tf": __UpperCamelCase = tf.convert_to_tensor(A_ ) # point batch size of 1 by default __UpperCamelCase = tf.expand_dims(A_,1 ) if len(input_labels.shape ) != 3 else input_labels encoding_image_processor.update({'input_labels': input_labels} ) return encoding_image_processor def snake_case_ ( self: List[str],A_: int,A_: Optional[Any] ): '''simple docstring''' __UpperCamelCase = max([point.shape[0] for point in input_points] ) __UpperCamelCase = [] for i, point in enumerate(A_ ): if point.shape[0] != expected_nb_points: __UpperCamelCase = np.concatenate( [point, np.zeros((expected_nb_points - point.shape[0], 2) ) + self.point_pad_value],axis=0 ) __UpperCamelCase = np.append(input_labels[i],[self.point_pad_value] ) processed_input_points.append(A_ ) __UpperCamelCase = processed_input_points return input_points, input_labels def snake_case_ ( self: Optional[int],A_: int,A_: np.ndarray,A_: Union[str, Any],A_: int=False ): '''simple docstring''' __UpperCamelCase, __UpperCamelCase = original_size __UpperCamelCase, __UpperCamelCase = self.image_processor._get_preprocess_shape(A_,longest_edge=A_ ) __UpperCamelCase = deepcopy(A_ ).astype(A_ ) if is_bounding_box: __UpperCamelCase = coords.reshape(-1,2,2 ) __UpperCamelCase = coords[..., 0] * (new_w / old_w) __UpperCamelCase = coords[..., 1] * (new_h / old_h) if is_bounding_box: __UpperCamelCase = coords.reshape(-1,4 ) return coords def snake_case_ ( self: Dict,A_: Optional[Any]=None,A_: List[str]=None,A_: Tuple=None,): '''simple docstring''' if input_points is not None: if hasattr(A_,'numpy' ): # Checks for TF or Torch tensor __UpperCamelCase = input_points.numpy().tolist() if not isinstance(A_,A_ ) or not isinstance(input_points[0],A_ ): raise ValueError('Input points must be a list of list of floating points.' ) __UpperCamelCase = [np.array(A_ ) for input_point in input_points] else: __UpperCamelCase = None if input_labels is not None: if hasattr(A_,'numpy' ): __UpperCamelCase = input_labels.numpy().tolist() if not isinstance(A_,A_ ) or not isinstance(input_labels[0],A_ ): raise ValueError('Input labels must be a list of list integers.' ) __UpperCamelCase = [np.array(A_ ) for label in input_labels] else: __UpperCamelCase = None if input_boxes is not None: if hasattr(A_,'numpy' ): __UpperCamelCase = input_boxes.numpy().tolist() if ( not isinstance(A_,A_ ) or not isinstance(input_boxes[0],A_ ) or not isinstance(input_boxes[0][0],A_ ) ): raise ValueError('Input boxes must be a list of list of list of floating points.' ) __UpperCamelCase = [np.array(A_ ).astype(np.floataa ) for box in input_boxes] else: __UpperCamelCase = None return input_points, input_labels, input_boxes @property def snake_case_ ( self: List[str] ): '''simple docstring''' __UpperCamelCase = self.image_processor.model_input_names return list(dict.fromkeys(A_ ) ) def snake_case_ ( self: int,*A_: int,**A_: Tuple ): '''simple docstring''' return self.image_processor.post_process_masks(*A_,**A_ )

from typing import Any class __lowerCamelCase : def __init__( self: int,A_: Any ): '''simple docstring''' __UpperCamelCase = data __UpperCamelCase = None def __repr__( self: Any ): '''simple docstring''' return F'''Node({self.data})''' class __lowerCamelCase : def __init__( self: Union[str, Any] ): '''simple docstring''' __UpperCamelCase = None def __iter__( self: int ): '''simple docstring''' __UpperCamelCase = self.head while node: yield node.data __UpperCamelCase = node.next def __len__( self: List[str] ): '''simple docstring''' return sum(1 for _ in self ) def __repr__( self: Any ): '''simple docstring''' return "->".join([str(A_ ) for item in self] ) def __getitem__( self: int,A_: int ): '''simple docstring''' if not 0 <= index < len(self ): raise ValueError('list index out of range.' ) for i, node in enumerate(self ): if i == index: return node return None def __setitem__( self: int,A_: int,A_: Any ): '''simple docstring''' if not 0 <= index < len(self ): raise ValueError('list index out of range.' ) __UpperCamelCase = self.head for _ in range(A_ ): __UpperCamelCase = current.next __UpperCamelCase = data def snake_case_ ( self: Union[str, Any],A_: Any ): '''simple docstring''' self.insert_nth(len(self ),A_ ) def snake_case_ ( self: List[Any],A_: Any ): '''simple docstring''' self.insert_nth(0,A_ ) def snake_case_ ( self: Optional[Any],A_: int,A_: Any ): '''simple docstring''' if not 0 <= index <= len(self ): raise IndexError('list index out of range' ) __UpperCamelCase = Node(A_ ) if self.head is None: __UpperCamelCase = new_node elif index == 0: __UpperCamelCase = self.head # link new_node to head __UpperCamelCase = new_node else: __UpperCamelCase = self.head for _ in range(index - 1 ): __UpperCamelCase = temp.next __UpperCamelCase = temp.next __UpperCamelCase = new_node def snake_case_ ( self: str ): # print every node data '''simple docstring''' print(self ) def snake_case_ ( self: int ): '''simple docstring''' return self.delete_nth(0 ) def snake_case_ ( self: str ): # delete from tail '''simple docstring''' return self.delete_nth(len(self ) - 1 ) def snake_case_ ( self: Any,A_: int = 0 ): '''simple docstring''' if not 0 <= index <= len(self ) - 1: # test if index is valid raise IndexError('List index out of range.' ) __UpperCamelCase = self.head # default first node if index == 0: __UpperCamelCase = self.head.next else: __UpperCamelCase = self.head for _ in range(index - 1 ): __UpperCamelCase = temp.next __UpperCamelCase = temp.next __UpperCamelCase = temp.next.next return delete_node.data def snake_case_ ( self: Any ): '''simple docstring''' return self.head is None def snake_case_ ( self: Optional[int] ): '''simple docstring''' __UpperCamelCase = None __UpperCamelCase = self.head while current: # Store the current node's next node. __UpperCamelCase = current.next # Make the current node's next point backwards __UpperCamelCase = prev # Make the previous node be the current node __UpperCamelCase = current # Make the current node the next node (to progress iteration) __UpperCamelCase = next_node # Return prev in order to put the head at the end __UpperCamelCase = prev def _A ( ) -> None: """simple docstring""" __UpperCamelCase = LinkedList() assert linked_list.is_empty() is True assert str(_lowercase ) == "" try: linked_list.delete_head() raise AssertionError # This should not happen. except IndexError: assert True # This should happen. try: linked_list.delete_tail() raise AssertionError # This should not happen. except IndexError: assert True # This should happen. for i in range(10 ): assert len(_lowercase ) == i linked_list.insert_nth(_lowercase , i + 1 ) assert str(_lowercase ) == "->".join(str(_lowercase ) for i in range(1 , 11 ) ) linked_list.insert_head(0 ) linked_list.insert_tail(11 ) assert str(_lowercase ) == "->".join(str(_lowercase ) for i in range(0 , 12 ) ) assert linked_list.delete_head() == 0 assert linked_list.delete_nth(9 ) == 10 assert linked_list.delete_tail() == 11 assert len(_lowercase ) == 9 assert str(_lowercase ) == "->".join(str(_lowercase ) for i in range(1 , 10 ) ) assert all(linked_list[i] == i + 1 for i in range(0 , 9 ) ) is True for i in range(0 , 9 ): __UpperCamelCase = -i assert all(linked_list[i] == -i for i in range(0 , 9 ) ) is True linked_list.reverse() assert str(_lowercase ) == "->".join(str(_lowercase ) for i in range(-8 , 1 ) ) def _A ( ) -> None: """simple docstring""" __UpperCamelCase = [ -9, 1_00, Node(77_34_51_12 ), 'dlrow olleH', 7, 55_55, 0, -1_92.5_55_55, 'Hello, world!', 77.9, Node(10 ), None, None, 12.20, ] __UpperCamelCase = LinkedList() for i in test_input: linked_list.insert_tail(_lowercase ) # Check if it's empty or not assert linked_list.is_empty() is False assert ( str(_lowercase ) == "-9->100->Node(77345112)->dlrow olleH->7->5555->0->" "-192.55555->Hello, world!->77.9->Node(10)->None->None->12.2" ) # Delete the head __UpperCamelCase = linked_list.delete_head() assert result == -9 assert ( str(_lowercase ) == "100->Node(77345112)->dlrow olleH->7->5555->0->-192.55555->" "Hello, world!->77.9->Node(10)->None->None->12.2" ) # Delete the tail __UpperCamelCase = linked_list.delete_tail() assert result == 12.2 assert ( str(_lowercase ) == "100->Node(77345112)->dlrow olleH->7->5555->0->-192.55555->" "Hello, world!->77.9->Node(10)->None->None" ) # Delete a node in specific location in linked list __UpperCamelCase = linked_list.delete_nth(10 ) assert result is None assert ( str(_lowercase ) == "100->Node(77345112)->dlrow olleH->7->5555->0->-192.55555->" "Hello, world!->77.9->Node(10)->None" ) # Add a Node instance to its head linked_list.insert_head(Node('Hello again, world!' ) ) assert ( str(_lowercase ) == "Node(Hello again, world!)->100->Node(77345112)->dlrow olleH->" "7->5555->0->-192.55555->Hello, world!->77.9->Node(10)->None" ) # Add None to its tail linked_list.insert_tail(_lowercase ) assert ( str(_lowercase ) == "Node(Hello again, world!)->100->Node(77345112)->dlrow olleH->" "7->5555->0->-192.55555->Hello, world!->77.9->Node(10)->None->None" ) # Reverse the linked list linked_list.reverse() assert ( str(_lowercase ) == "None->None->Node(10)->77.9->Hello, world!->-192.55555->0->5555->" "7->dlrow olleH->Node(77345112)->100->Node(Hello again, world!)" ) def _A ( ) -> List[str]: """simple docstring""" from doctest import testmod testmod() __UpperCamelCase = LinkedList() linked_list.insert_head(input('Inserting 1st at head ' ).strip() ) linked_list.insert_head(input('Inserting 2nd at head ' ).strip() ) print('\nPrint list:' ) linked_list.print_list() linked_list.insert_tail(input('\nInserting 1st at tail ' ).strip() ) linked_list.insert_tail(input('Inserting 2nd at tail ' ).strip() ) print('\nPrint list:' ) linked_list.print_list() print('\nDelete head' ) linked_list.delete_head() print('Delete tail' ) linked_list.delete_tail() print('\nPrint list:' ) linked_list.print_list() print('\nReverse linked list' ) linked_list.reverse() print('\nPrint list:' ) linked_list.print_list() print('\nString representation of linked list:' ) print(_lowercase ) print('\nReading/changing Node data using indexing:' ) print(f'''Element at Position 1: {linked_list[1]}''' ) __UpperCamelCase = input('Enter New Value: ' ).strip() print('New list:' ) print(_lowercase ) print(f'''length of linked_list is : {len(_lowercase )}''' ) if __name__ == "__main__": main()

__snake_case = { '''Pillow''': '''Pillow''', '''accelerate''': '''accelerate>=0.11.0''', '''compel''': '''compel==0.1.8''', '''black''': '''black~=23.1''', '''datasets''': '''datasets''', '''filelock''': '''filelock''', '''flax''': '''flax>=0.4.1''', '''hf-doc-builder''': '''hf-doc-builder>=0.3.0''', '''huggingface-hub''': '''huggingface-hub>=0.13.2''', '''requests-mock''': '''requests-mock==1.10.0''', '''importlib_metadata''': '''importlib_metadata''', '''invisible-watermark''': '''invisible-watermark''', '''isort''': '''isort>=5.5.4''', '''jax''': '''jax>=0.2.8,!=0.3.2''', '''jaxlib''': '''jaxlib>=0.1.65''', '''Jinja2''': '''Jinja2''', '''k-diffusion''': '''k-diffusion>=0.0.12''', '''torchsde''': '''torchsde''', '''note_seq''': '''note_seq''', '''librosa''': '''librosa''', '''numpy''': '''numpy''', '''omegaconf''': '''omegaconf''', '''parameterized''': '''parameterized''', '''protobuf''': '''protobuf>=3.20.3,<4''', '''pytest''': '''pytest''', '''pytest-timeout''': '''pytest-timeout''', '''pytest-xdist''': '''pytest-xdist''', '''ruff''': '''ruff>=0.0.241''', '''safetensors''': '''safetensors''', '''sentencepiece''': '''sentencepiece>=0.1.91,!=0.1.92''', '''scipy''': '''scipy''', '''onnx''': '''onnx''', '''regex''': '''regex!=2019.12.17''', '''requests''': '''requests''', '''tensorboard''': '''tensorboard''', '''torch''': '''torch>=1.4''', '''torchvision''': '''torchvision''', '''transformers''': '''transformers>=4.25.1''', '''urllib3''': '''urllib3<=2.0.0''', }

from typing import TYPE_CHECKING from ...utils import ( OptionalDependencyNotAvailable, _LazyModule, is_flax_available, is_tf_available, is_torch_available, ) __snake_case = {'''configuration_unispeech''': ['''UNISPEECH_PRETRAINED_CONFIG_ARCHIVE_MAP''', '''UniSpeechConfig''']} try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __snake_case = [ '''UNISPEECH_PRETRAINED_MODEL_ARCHIVE_LIST''', '''UniSpeechForCTC''', '''UniSpeechForPreTraining''', '''UniSpeechForSequenceClassification''', '''UniSpeechModel''', '''UniSpeechPreTrainedModel''', ] if TYPE_CHECKING: from .configuration_unispeech import UNISPEECH_PRETRAINED_CONFIG_ARCHIVE_MAP, UniSpeechConfig try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_unispeech import ( UNISPEECH_PRETRAINED_MODEL_ARCHIVE_LIST, UniSpeechForCTC, UniSpeechForPreTraining, UniSpeechForSequenceClassification, UniSpeechModel, UniSpeechPreTrainedModel, ) else: import sys __snake_case = _LazyModule(__name__, globals()['''__file__'''], _import_structure, module_spec=__spec__)

from typing import TYPE_CHECKING from ...utils import ( OptionalDependencyNotAvailable, _LazyModule, is_tf_available, is_torch_available, is_vision_available, ) __snake_case = { '''configuration_mobilevit''': ['''MOBILEVIT_PRETRAINED_CONFIG_ARCHIVE_MAP''', '''MobileViTConfig''', '''MobileViTOnnxConfig'''], } try: if not is_vision_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __snake_case = ['''MobileViTFeatureExtractor'''] __snake_case = ['''MobileViTImageProcessor'''] try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __snake_case = [ '''MOBILEVIT_PRETRAINED_MODEL_ARCHIVE_LIST''', '''MobileViTForImageClassification''', '''MobileViTForSemanticSegmentation''', '''MobileViTModel''', '''MobileViTPreTrainedModel''', ] try: if not is_tf_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __snake_case = [ '''TF_MOBILEVIT_PRETRAINED_MODEL_ARCHIVE_LIST''', '''TFMobileViTForImageClassification''', '''TFMobileViTForSemanticSegmentation''', '''TFMobileViTModel''', '''TFMobileViTPreTrainedModel''', ] if TYPE_CHECKING: from .configuration_mobilevit import MOBILEVIT_PRETRAINED_CONFIG_ARCHIVE_MAP, MobileViTConfig, MobileViTOnnxConfig try: if not is_vision_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .feature_extraction_mobilevit import MobileViTFeatureExtractor from .image_processing_mobilevit import MobileViTImageProcessor try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_mobilevit import ( MOBILEVIT_PRETRAINED_MODEL_ARCHIVE_LIST, MobileViTForImageClassification, MobileViTForSemanticSegmentation, MobileViTModel, MobileViTPreTrainedModel, ) try: if not is_tf_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_tf_mobilevit import ( TF_MOBILEVIT_PRETRAINED_MODEL_ARCHIVE_LIST, TFMobileViTForImageClassification, TFMobileViTForSemanticSegmentation, TFMobileViTModel, TFMobileViTPreTrainedModel, ) else: import sys __snake_case = _LazyModule(__name__, globals()['''__file__'''], _import_structure, module_spec=__spec__)

__snake_case = { '''a''': '''AAAAA''', '''b''': '''AAAAB''', '''c''': '''AAABA''', '''d''': '''AAABB''', '''e''': '''AABAA''', '''f''': '''AABAB''', '''g''': '''AABBA''', '''h''': '''AABBB''', '''i''': '''ABAAA''', '''j''': '''BBBAA''', '''k''': '''ABAAB''', '''l''': '''ABABA''', '''m''': '''ABABB''', '''n''': '''ABBAA''', '''o''': '''ABBAB''', '''p''': '''ABBBA''', '''q''': '''ABBBB''', '''r''': '''BAAAA''', '''s''': '''BAAAB''', '''t''': '''BAABA''', '''u''': '''BAABB''', '''v''': '''BBBAB''', '''w''': '''BABAA''', '''x''': '''BABAB''', '''y''': '''BABBA''', '''z''': '''BABBB''', ''' ''': ''' ''', } __snake_case = {value: key for key, value in encode_dict.items()} def _A ( _lowercase ) -> str: """simple docstring""" __UpperCamelCase = '' for letter in word.lower(): if letter.isalpha() or letter == " ": encoded += encode_dict[letter] else: raise Exception('encode() accepts only letters of the alphabet and spaces' ) return encoded def _A ( _lowercase ) -> str: """simple docstring""" if set(_lowercase ) - {"A", "B", " "} != set(): raise Exception('decode() accepts only \'A\', \'B\' and spaces' ) __UpperCamelCase = '' for word in coded.split(): while len(_lowercase ) != 0: decoded += decode_dict[word[:5]] __UpperCamelCase = word[5:] decoded += " " return decoded.strip() if __name__ == "__main__": from doctest import testmod testmod()

import random import unittest import torch from diffusers import IFImgaImgSuperResolutionPipeline from diffusers.utils import floats_tensor from diffusers.utils.import_utils import is_xformers_available from diffusers.utils.testing_utils import skip_mps, torch_device from ..pipeline_params import TEXT_GUIDED_IMAGE_VARIATION_BATCH_PARAMS, TEXT_GUIDED_IMAGE_VARIATION_PARAMS from ..test_pipelines_common import PipelineTesterMixin from . import IFPipelineTesterMixin @skip_mps class __lowerCamelCase (_a , _a , unittest.TestCase ): _lowercase = IFImgaImgSuperResolutionPipeline _lowercase = TEXT_GUIDED_IMAGE_VARIATION_PARAMS - {"""width""", """height"""} _lowercase = TEXT_GUIDED_IMAGE_VARIATION_BATCH_PARAMS.union({"""original_image"""} ) _lowercase = PipelineTesterMixin.required_optional_params - {"""latents"""} def snake_case_ ( self: Any ): '''simple docstring''' return self._get_superresolution_dummy_components() def snake_case_ ( self: List[str],A_: int,A_: Union[str, Any]=0 ): '''simple docstring''' if str(A_ ).startswith('mps' ): __UpperCamelCase = torch.manual_seed(A_ ) else: __UpperCamelCase = torch.Generator(device=A_ ).manual_seed(A_ ) __UpperCamelCase = floats_tensor((1, 3, 32, 32),rng=random.Random(A_ ) ).to(A_ ) __UpperCamelCase = floats_tensor((1, 3, 16, 16),rng=random.Random(A_ ) ).to(A_ ) __UpperCamelCase = { 'prompt': 'A painting of a squirrel eating a burger', 'image': image, 'original_image': original_image, 'generator': generator, 'num_inference_steps': 2, 'output_type': 'numpy', } return inputs @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: int ): '''simple docstring''' self._test_xformers_attention_forwardGenerator_pass(expected_max_diff=1E-3 ) def snake_case_ ( self: Optional[int] ): '''simple docstring''' self._test_save_load_optional_components() @unittest.skipIf(torch_device != 'cuda',reason='float16 requires CUDA' ) def snake_case_ ( self: str ): '''simple docstring''' super().test_save_load_floataa(expected_max_diff=1E-1 ) def snake_case_ ( self: Any ): '''simple docstring''' self._test_attention_slicing_forward_pass(expected_max_diff=1E-2 ) def snake_case_ ( self: int ): '''simple docstring''' self._test_save_load_local() def snake_case_ ( self: Union[str, Any] ): '''simple docstring''' self._test_inference_batch_single_identical( expected_max_diff=1E-2,)

from collections.abc import Generator from math import sin def _A ( _lowercase ) -> bytes: """simple docstring""" if len(_lowercase ) != 32: raise ValueError('Input must be of length 32' ) __UpperCamelCase = B'' for i in [3, 2, 1, 0]: little_endian += string_aa[8 * i : 8 * i + 8] return little_endian def _A ( _lowercase ) -> bytes: """simple docstring""" if i < 0: raise ValueError('Input must be non-negative' ) __UpperCamelCase = format(_lowercase , '08x' )[-8:] __UpperCamelCase = 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 ( _lowercase ) -> bytes: """simple docstring""" __UpperCamelCase = B'' for char in message: bit_string += format(_lowercase , '08b' ).encode('utf-8' ) __UpperCamelCase = format(len(_lowercase ) , '064b' ).encode('utf-8' ) # Pad bit_string to a multiple of 512 chars bit_string += b"1" while len(_lowercase ) % 5_12 != 4_48: bit_string += b"0" bit_string += to_little_endian(start_len[32:] ) + to_little_endian(start_len[:32] ) return bit_string def _A ( _lowercase ) -> Generator[list[int], None, None]: """simple docstring""" if len(_lowercase ) % 5_12 != 0: raise ValueError('Input must have length that\'s a multiple of 512' ) for pos in range(0 , len(_lowercase ) , 5_12 ): __UpperCamelCase = bit_string[pos : pos + 5_12] __UpperCamelCase = [] for i in range(0 , 5_12 , 32 ): block_words.append(int(to_little_endian(block[i : i + 32] ) , 2 ) ) yield block_words def _A ( _lowercase ) -> int: """simple docstring""" if i < 0: raise ValueError('Input must be non-negative' ) __UpperCamelCase = format(_lowercase , '032b' ) __UpperCamelCase = '' for c in i_str: new_str += "1" if c == "0" else "0" return int(_lowercase , 2 ) def _A ( _lowercase , _lowercase ) -> int: """simple docstring""" return (a + b) % 2**32 def _A ( _lowercase , _lowercase ) -> int: """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 ( _lowercase ) -> bytes: """simple docstring""" __UpperCamelCase = preprocess(_lowercase ) __UpperCamelCase = [int(2**32 * abs(sin(i + 1 ) ) ) for i in range(64 )] # Starting states __UpperCamelCase = 0X67_45_23_01 __UpperCamelCase = 0Xef_cd_ab_89 __UpperCamelCase = 0X98_ba_dc_fe __UpperCamelCase = 0X10_32_54_76 __UpperCamelCase = [ 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(_lowercase ): __UpperCamelCase = aa __UpperCamelCase = ba __UpperCamelCase = ca __UpperCamelCase = da # Hash current chunk for i in range(64 ): if i <= 15: # f = (b & c) | (not_32(b) & d) # Alternate definition for f __UpperCamelCase = d ^ (b & (c ^ d)) __UpperCamelCase = i elif i <= 31: # f = (d & b) | (not_32(d) & c) # Alternate definition for f __UpperCamelCase = c ^ (d & (b ^ c)) __UpperCamelCase = (5 * i + 1) % 16 elif i <= 47: __UpperCamelCase = b ^ c ^ d __UpperCamelCase = (3 * i + 5) % 16 else: __UpperCamelCase = c ^ (b | not_aa(_lowercase )) __UpperCamelCase = (7 * i) % 16 __UpperCamelCase = (f + a + added_consts[i] + block_words[g]) % 2**32 __UpperCamelCase = d __UpperCamelCase = c __UpperCamelCase = b __UpperCamelCase = sum_aa(_lowercase , left_rotate_aa(_lowercase , shift_amounts[i] ) ) # Add hashed chunk to running total __UpperCamelCase = sum_aa(_lowercase , _lowercase ) __UpperCamelCase = sum_aa(_lowercase , _lowercase ) __UpperCamelCase = sum_aa(_lowercase , _lowercase ) __UpperCamelCase = sum_aa(_lowercase , _lowercase ) __UpperCamelCase = reformat_hex(_lowercase ) + reformat_hex(_lowercase ) + reformat_hex(_lowercase ) + reformat_hex(_lowercase ) return digest if __name__ == "__main__": import doctest doctest.testmod()

from __future__ import annotations import json import requests from bsa import BeautifulSoup from fake_useragent import UserAgent __snake_case = {'''UserAgent''': UserAgent().random} def _A ( _lowercase ) -> dict: """simple docstring""" __UpperCamelCase = script.contents[0] __UpperCamelCase = json.loads(data[data.find('{"config"' ) : -1] ) return info["entry_data"]["ProfilePage"][0]["graphql"]["user"] class __lowerCamelCase : def __init__( self: Tuple,A_: int ): '''simple docstring''' __UpperCamelCase = F'''https://www.instagram.com/{username}/''' __UpperCamelCase = self.get_json() def snake_case_ ( self: Union[str, Any] ): '''simple docstring''' __UpperCamelCase = requests.get(self.url,headers=A_ ).text __UpperCamelCase = BeautifulSoup(A_,'html.parser' ).find_all('script' ) try: return extract_user_profile(scripts[4] ) except (json.decoder.JSONDecodeError, KeyError): return extract_user_profile(scripts[3] ) def __repr__( self: List[Any] ): '''simple docstring''' return F'''{self.__class__.__name__}(\'{self.username}\')''' def __str__( self: str ): '''simple docstring''' return F'''{self.fullname} ({self.username}) is {self.biography}''' @property def snake_case_ ( self: Optional[int] ): '''simple docstring''' return self.user_data["username"] @property def snake_case_ ( self: Optional[Any] ): '''simple docstring''' return self.user_data["full_name"] @property def snake_case_ ( self: List[str] ): '''simple docstring''' return self.user_data["biography"] @property def snake_case_ ( self: str ): '''simple docstring''' return self.user_data["business_email"] @property def snake_case_ ( self: Dict ): '''simple docstring''' return self.user_data["external_url"] @property def snake_case_ ( self: str ): '''simple docstring''' return self.user_data["edge_followed_by"]["count"] @property def snake_case_ ( self: Tuple ): '''simple docstring''' return self.user_data["edge_follow"]["count"] @property def snake_case_ ( self: Optional[int] ): '''simple docstring''' return self.user_data["edge_owner_to_timeline_media"]["count"] @property def snake_case_ ( self: Any ): '''simple docstring''' return self.user_data["profile_pic_url_hd"] @property def snake_case_ ( self: Dict ): '''simple docstring''' return self.user_data["is_verified"] @property def snake_case_ ( self: int ): '''simple docstring''' return self.user_data["is_private"] def _A ( _lowercase = "github" ) -> None: """simple docstring""" import os if os.environ.get('CI' ): return # test failing on GitHub Actions __UpperCamelCase = InstagramUser(_lowercase ) assert instagram_user.user_data assert isinstance(instagram_user.user_data , _lowercase ) assert instagram_user.username == username if username != "github": return assert instagram_user.fullname == "GitHub" assert instagram_user.biography == "Built for developers." assert instagram_user.number_of_posts > 1_50 assert instagram_user.number_of_followers > 12_00_00 assert instagram_user.number_of_followings > 15 assert instagram_user.email == "support@github.com" assert instagram_user.website == "https://github.com/readme" assert instagram_user.profile_picture_url.startswith('https://instagram.' ) assert instagram_user.is_verified is True assert instagram_user.is_private is False if __name__ == "__main__": import doctest doctest.testmod() __snake_case = InstagramUser('''github''') print(instagram_user) print(f"""{instagram_user.number_of_posts = }""") print(f"""{instagram_user.number_of_followers = }""") print(f"""{instagram_user.number_of_followings = }""") print(f"""{instagram_user.email = }""") print(f"""{instagram_user.website = }""") print(f"""{instagram_user.profile_picture_url = }""") print(f"""{instagram_user.is_verified = }""") print(f"""{instagram_user.is_private = }""")

from __future__ import annotations import time from math import sqrt # 1 for manhattan, 0 for euclidean __snake_case = 0 __snake_case = [ [0, 0, 0, 0, 0, 0, 0], [0, 1, 0, 0, 0, 0, 0], # 0 are free path whereas 1's are obstacles [0, 0, 0, 0, 0, 0, 0], [0, 0, 1, 0, 0, 0, 0], [1, 0, 1, 0, 0, 0, 0], [0, 0, 0, 0, 0, 0, 0], [0, 0, 0, 0, 1, 0, 0], ] __snake_case = [[-1, 0], [0, -1], [1, 0], [0, 1]] # up, left, down, right __snake_case = tuple[int, int] class __lowerCamelCase : def __init__( self: str,A_: int,A_: int,A_: int,A_: int,A_: int,A_: Node | None,): '''simple docstring''' __UpperCamelCase = pos_x __UpperCamelCase = pos_y __UpperCamelCase = (pos_y, pos_x) __UpperCamelCase = goal_x __UpperCamelCase = goal_y __UpperCamelCase = g_cost __UpperCamelCase = parent __UpperCamelCase = self.calculate_heuristic() __UpperCamelCase = self.g_cost + self.h_cost def snake_case_ ( self: str ): '''simple docstring''' __UpperCamelCase = self.pos_x - self.goal_x __UpperCamelCase = self.pos_y - self.goal_y if HEURISTIC == 1: return abs(A_ ) + abs(A_ ) else: return sqrt(dy**2 + dx**2 ) def __lt__( self: int,A_: Node ): '''simple docstring''' return self.f_cost < other.f_cost class __lowerCamelCase : def __init__( self: Any,A_: TPosition,A_: TPosition ): '''simple docstring''' __UpperCamelCase = Node(start[1],start[0],goal[1],goal[0],0,A_ ) __UpperCamelCase = Node(goal[1],goal[0],goal[1],goal[0],9_9999,A_ ) __UpperCamelCase = [self.start] __UpperCamelCase = [] __UpperCamelCase = False def snake_case_ ( self: Any ): '''simple docstring''' while self.open_nodes: # Open Nodes are sorted using __lt__ self.open_nodes.sort() __UpperCamelCase = self.open_nodes.pop(0 ) if current_node.pos == self.target.pos: return self.retrace_path(A_ ) self.closed_nodes.append(A_ ) __UpperCamelCase = self.get_successors(A_ ) for child_node in successors: if child_node in self.closed_nodes: continue if child_node not in self.open_nodes: self.open_nodes.append(A_ ) else: # retrieve the best current path __UpperCamelCase = self.open_nodes.pop(self.open_nodes.index(A_ ) ) if child_node.g_cost < better_node.g_cost: self.open_nodes.append(A_ ) else: self.open_nodes.append(A_ ) return [self.start.pos] def snake_case_ ( self: int,A_: Node ): '''simple docstring''' __UpperCamelCase = [] for action in delta: __UpperCamelCase = parent.pos_x + action[1] __UpperCamelCase = parent.pos_y + action[0] if not (0 <= pos_x <= len(grid[0] ) - 1 and 0 <= pos_y <= len(A_ ) - 1): continue if grid[pos_y][pos_x] != 0: continue successors.append( Node( A_,A_,self.target.pos_y,self.target.pos_x,parent.g_cost + 1,A_,) ) return successors def snake_case_ ( self: Any,A_: Node | None ): '''simple docstring''' __UpperCamelCase = node __UpperCamelCase = [] while current_node is not None: path.append((current_node.pos_y, current_node.pos_x) ) __UpperCamelCase = current_node.parent path.reverse() return path class __lowerCamelCase : def __init__( self: List[Any],A_: TPosition,A_: TPosition ): '''simple docstring''' __UpperCamelCase = AStar(A_,A_ ) __UpperCamelCase = AStar(A_,A_ ) __UpperCamelCase = False def snake_case_ ( self: Union[str, Any] ): '''simple docstring''' while self.fwd_astar.open_nodes or self.bwd_astar.open_nodes: self.fwd_astar.open_nodes.sort() self.bwd_astar.open_nodes.sort() __UpperCamelCase = self.fwd_astar.open_nodes.pop(0 ) __UpperCamelCase = self.bwd_astar.open_nodes.pop(0 ) if current_bwd_node.pos == current_fwd_node.pos: return self.retrace_bidirectional_path( A_,A_ ) self.fwd_astar.closed_nodes.append(A_ ) self.bwd_astar.closed_nodes.append(A_ ) __UpperCamelCase = current_bwd_node __UpperCamelCase = current_fwd_node __UpperCamelCase = { self.fwd_astar: self.fwd_astar.get_successors(A_ ), self.bwd_astar: self.bwd_astar.get_successors(A_ ), } for astar in [self.fwd_astar, self.bwd_astar]: for child_node in successors[astar]: if child_node in astar.closed_nodes: continue if child_node not in astar.open_nodes: astar.open_nodes.append(A_ ) else: # retrieve the best current path __UpperCamelCase = astar.open_nodes.pop( astar.open_nodes.index(A_ ) ) if child_node.g_cost < better_node.g_cost: astar.open_nodes.append(A_ ) else: astar.open_nodes.append(A_ ) return [self.fwd_astar.start.pos] def snake_case_ ( self: List[str],A_: Node,A_: Node ): '''simple docstring''' __UpperCamelCase = self.fwd_astar.retrace_path(A_ ) __UpperCamelCase = self.bwd_astar.retrace_path(A_ ) bwd_path.pop() bwd_path.reverse() __UpperCamelCase = fwd_path + bwd_path return path if __name__ == "__main__": # all coordinates are given in format [y,x] __snake_case = (0, 0) __snake_case = (len(grid) - 1, len(grid[0]) - 1) for elem in grid: print(elem) __snake_case = time.time() __snake_case = AStar(init, goal) __snake_case = a_star.search() __snake_case = time.time() - start_time print(f"""AStar execution time = {end_time:f} seconds""") __snake_case = time.time() __snake_case = BidirectionalAStar(init, goal) __snake_case = time.time() - bd_start_time print(f"""BidirectionalAStar execution time = {bd_end_time:f} seconds""")

import pytest import datasets.config from datasets.utils.info_utils import is_small_dataset @pytest.mark.parametrize('dataset_size' , [None, 4_00 * 2**20, 6_00 * 2**20] ) @pytest.mark.parametrize('input_in_memory_max_size' , ['default', 0, 1_00 * 2**20, 9_00 * 2**20] ) def _A ( _lowercase , _lowercase , _lowercase ) -> Dict: """simple docstring""" if input_in_memory_max_size != "default": monkeypatch.setattr(datasets.config , 'IN_MEMORY_MAX_SIZE' , _lowercase ) __UpperCamelCase = datasets.config.IN_MEMORY_MAX_SIZE if input_in_memory_max_size == "default": assert in_memory_max_size == 0 else: assert in_memory_max_size == input_in_memory_max_size if dataset_size and in_memory_max_size: __UpperCamelCase = dataset_size < in_memory_max_size else: __UpperCamelCase = False __UpperCamelCase = is_small_dataset(_lowercase ) assert result == expected

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 AutoFeatureExtractor, WavaVecaFeatureExtractor 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_feature_extraction import CustomFeatureExtractor # noqa E402 __snake_case = get_tests_dir('''fixtures''') class __lowerCamelCase (unittest.TestCase ): def snake_case_ ( self: int ): '''simple docstring''' __UpperCamelCase = mock.Mock() __UpperCamelCase = 500 __UpperCamelCase = {} __UpperCamelCase = HTTPError __UpperCamelCase = {} # Download this model to make sure it's in the cache. __UpperCamelCase = WavaVecaFeatureExtractor.from_pretrained('hf-internal-testing/tiny-random-wav2vec2' ) # 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: __UpperCamelCase = WavaVecaFeatureExtractor.from_pretrained('hf-internal-testing/tiny-random-wav2vec2' ) # This check we did call the fake head request mock_head.assert_called() def snake_case_ ( self: Dict ): '''simple docstring''' __UpperCamelCase = WavaVecaFeatureExtractor.from_pretrained( 'https://huggingface.co/hf-internal-testing/tiny-random-wav2vec2/resolve/main/preprocessor_config.json' ) @is_staging_test class __lowerCamelCase (unittest.TestCase ): @classmethod def snake_case_ ( cls: Tuple ): '''simple docstring''' __UpperCamelCase = TOKEN HfFolder.save_token(A_ ) @classmethod def snake_case_ ( cls: Tuple ): '''simple docstring''' try: delete_repo(token=cls._token,repo_id='test-feature-extractor' ) except HTTPError: pass try: delete_repo(token=cls._token,repo_id='valid_org/test-feature-extractor-org' ) except HTTPError: pass try: delete_repo(token=cls._token,repo_id='test-dynamic-feature-extractor' ) except HTTPError: pass def snake_case_ ( self: Tuple ): '''simple docstring''' __UpperCamelCase = WavaVecaFeatureExtractor.from_pretrained(A_ ) feature_extractor.push_to_hub('test-feature-extractor',use_auth_token=self._token ) __UpperCamelCase = WavaVecaFeatureExtractor.from_pretrained(F'''{USER}/test-feature-extractor''' ) for k, v in feature_extractor.__dict__.items(): self.assertEqual(A_,getattr(A_,A_ ) ) # Reset repo delete_repo(token=self._token,repo_id='test-feature-extractor' ) # Push to hub via save_pretrained with tempfile.TemporaryDirectory() as tmp_dir: feature_extractor.save_pretrained( A_,repo_id='test-feature-extractor',push_to_hub=A_,use_auth_token=self._token ) __UpperCamelCase = WavaVecaFeatureExtractor.from_pretrained(F'''{USER}/test-feature-extractor''' ) for k, v in feature_extractor.__dict__.items(): self.assertEqual(A_,getattr(A_,A_ ) ) def snake_case_ ( self: List[str] ): '''simple docstring''' __UpperCamelCase = WavaVecaFeatureExtractor.from_pretrained(A_ ) feature_extractor.push_to_hub('valid_org/test-feature-extractor',use_auth_token=self._token ) __UpperCamelCase = WavaVecaFeatureExtractor.from_pretrained('valid_org/test-feature-extractor' ) for k, v in feature_extractor.__dict__.items(): self.assertEqual(A_,getattr(A_,A_ ) ) # Reset repo delete_repo(token=self._token,repo_id='valid_org/test-feature-extractor' ) # Push to hub via save_pretrained with tempfile.TemporaryDirectory() as tmp_dir: feature_extractor.save_pretrained( A_,repo_id='valid_org/test-feature-extractor-org',push_to_hub=A_,use_auth_token=self._token ) __UpperCamelCase = WavaVecaFeatureExtractor.from_pretrained('valid_org/test-feature-extractor-org' ) for k, v in feature_extractor.__dict__.items(): self.assertEqual(A_,getattr(A_,A_ ) ) def snake_case_ ( self: int ): '''simple docstring''' CustomFeatureExtractor.register_for_auto_class() __UpperCamelCase = CustomFeatureExtractor.from_pretrained(A_ ) feature_extractor.push_to_hub('test-dynamic-feature-extractor',use_auth_token=self._token ) # This has added the proper auto_map field to the config self.assertDictEqual( feature_extractor.auto_map,{'AutoFeatureExtractor': 'custom_feature_extraction.CustomFeatureExtractor'},) __UpperCamelCase = AutoFeatureExtractor.from_pretrained( F'''{USER}/test-dynamic-feature-extractor''',trust_remote_code=A_ ) # Can't make an isinstance check because the new_feature_extractor is from the CustomFeatureExtractor class of a dynamic module self.assertEqual(new_feature_extractor.__class__.__name__,'CustomFeatureExtractor' )

import warnings from ...utils import logging from .image_processing_glpn import GLPNImageProcessor __snake_case = logging.get_logger(__name__) class __lowerCamelCase (_a ): def __init__( self: List[str],*A_: Dict,**A_: Tuple ): '''simple docstring''' warnings.warn( 'The class GLPNFeatureExtractor is deprecated and will be removed in version 5 of Transformers. Please' ' use GLPNImageProcessor instead.',A_,) super().__init__(*A_,**A_ )

import argparse import json import os import evaluate import torch from datasets import load_dataset from torch.optim import AdamW from torch.utils.data import DataLoader from transformers import AutoModelForSequenceClassification, AutoTokenizer, get_linear_schedule_with_warmup, set_seed from accelerate import Accelerator, DistributedType from accelerate.utils.deepspeed import DummyOptim, DummyScheduler __snake_case = 1_6 __snake_case = 3_2 def _A ( _lowercase , _lowercase = 16 , _lowercase = "bert-base-cased" ) -> Union[str, Any]: """simple docstring""" __UpperCamelCase = AutoTokenizer.from_pretrained(_lowercase ) __UpperCamelCase = load_dataset('glue' , 'mrpc' ) def tokenize_function(_lowercase ): # max_length=None => use the model max length (it's actually the default) __UpperCamelCase = tokenizer(examples['sentence1'] , examples['sentence2'] , truncation=_lowercase , max_length=_lowercase ) return outputs # Apply the method we just defined to all the examples in all the splits of the dataset __UpperCamelCase = datasets.map( _lowercase , batched=_lowercase , remove_columns=['idx', 'sentence1', 'sentence2'] , load_from_cache_file=_lowercase ) # We also rename the 'label' column to 'labels' which is the expected name for labels by the models of the # transformers library __UpperCamelCase = tokenized_datasets.rename_column('label' , 'labels' ) def collate_fn(_lowercase ): # 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(_lowercase , padding='max_length' , max_length=1_28 , return_tensors='pt' ) return tokenizer.pad(_lowercase , padding='longest' , return_tensors='pt' ) # Instantiate dataloaders. __UpperCamelCase = DataLoader( tokenized_datasets['train'] , shuffle=_lowercase , collate_fn=_lowercase , batch_size=_lowercase ) __UpperCamelCase = DataLoader( tokenized_datasets['validation'] , shuffle=_lowercase , collate_fn=_lowercase , batch_size=_lowercase ) return train_dataloader, eval_dataloader def _A ( _lowercase , _lowercase ) -> int: """simple docstring""" __UpperCamelCase = Accelerator() # Sample hyper-parameters for learning rate, batch size, seed and a few other HPs __UpperCamelCase = config['lr'] __UpperCamelCase = int(config['num_epochs'] ) __UpperCamelCase = int(config['seed'] ) __UpperCamelCase = int(config['batch_size'] ) __UpperCamelCase = args.model_name_or_path set_seed(_lowercase ) __UpperCamelCase, __UpperCamelCase = get_dataloaders(_lowercase , _lowercase , _lowercase ) # Instantiate the model (we build the model here so that the seed also control new weights initialization) __UpperCamelCase = AutoModelForSequenceClassification.from_pretrained(_lowercase , return_dict=_lowercase ) # Instantiate optimizer __UpperCamelCase = ( AdamW if accelerator.state.deepspeed_plugin is None or 'optimizer' not in accelerator.state.deepspeed_plugin.deepspeed_config else DummyOptim ) __UpperCamelCase = optimizer_cls(params=model.parameters() , lr=_lowercase ) if accelerator.state.deepspeed_plugin is not None: __UpperCamelCase = accelerator.state.deepspeed_plugin.deepspeed_config[ 'gradient_accumulation_steps' ] else: __UpperCamelCase = 1 __UpperCamelCase = (len(_lowercase ) * num_epochs) // gradient_accumulation_steps # Instantiate scheduler if ( accelerator.state.deepspeed_plugin is None or "scheduler" not in accelerator.state.deepspeed_plugin.deepspeed_config ): __UpperCamelCase = get_linear_schedule_with_warmup( optimizer=_lowercase , num_warmup_steps=0 , num_training_steps=_lowercase , ) else: __UpperCamelCase = DummyScheduler(_lowercase , total_num_steps=_lowercase , warmup_num_steps=0 ) # Prepare everything # There is no specific order to remember, we just need to unpack the objects in the same order we gave them to the # prepare method. __UpperCamelCase, __UpperCamelCase, __UpperCamelCase, __UpperCamelCase, __UpperCamelCase = accelerator.prepare( _lowercase , _lowercase , _lowercase , _lowercase , _lowercase ) # We need to keep track of how many total steps we have iterated over __UpperCamelCase = 0 # We also need to keep track of the stating epoch so files are named properly __UpperCamelCase = 0 # Now we train the model __UpperCamelCase = evaluate.load('glue' , 'mrpc' ) __UpperCamelCase = 0 __UpperCamelCase = {} for epoch in range(_lowercase , _lowercase ): model.train() for step, batch in enumerate(_lowercase ): __UpperCamelCase = model(**_lowercase ) __UpperCamelCase = outputs.loss __UpperCamelCase = loss / gradient_accumulation_steps accelerator.backward(_lowercase ) if step % gradient_accumulation_steps == 0: optimizer.step() lr_scheduler.step() optimizer.zero_grad() overall_step += 1 model.eval() __UpperCamelCase = 0 for step, batch in enumerate(_lowercase ): # We could avoid this line since we set the accelerator with `device_placement=True`. batch.to(accelerator.device ) with torch.no_grad(): __UpperCamelCase = model(**_lowercase ) __UpperCamelCase = outputs.logits.argmax(dim=-1 ) # It is slightly faster to call this once, than multiple times __UpperCamelCase, __UpperCamelCase = accelerator.gather( (predictions, batch['labels']) ) # If we are in a multiprocess environment, the last batch has duplicates if accelerator.use_distributed: if step == len(_lowercase ) - 1: __UpperCamelCase = predictions[: len(eval_dataloader.dataset ) - samples_seen] __UpperCamelCase = references[: len(eval_dataloader.dataset ) - samples_seen] else: samples_seen += references.shape[0] metric.add_batch( predictions=_lowercase , references=_lowercase , ) __UpperCamelCase = metric.compute() # Use accelerator.print to print only on the main process. accelerator.print(f'''epoch {epoch}:''' , _lowercase ) __UpperCamelCase = eval_metric['accuracy'] if best_performance < eval_metric["accuracy"]: __UpperCamelCase = eval_metric['accuracy'] if args.performance_lower_bound is not None: assert ( args.performance_lower_bound <= best_performance ), f'''Best performance metric {best_performance} is lower than the lower bound {args.performance_lower_bound}''' accelerator.wait_for_everyone() if accelerator.is_main_process: with open(os.path.join(args.output_dir , 'all_results.json' ) , 'w' ) as f: json.dump(_lowercase , _lowercase ) def _A ( ) -> List[str]: """simple docstring""" __UpperCamelCase = argparse.ArgumentParser(description='Simple example of training script tracking peak GPU memory usage.' ) parser.add_argument( '--model_name_or_path' , type=_lowercase , default='bert-base-cased' , help='Path to pretrained model or model identifier from huggingface.co/models.' , required=_lowercase , ) parser.add_argument( '--output_dir' , type=_lowercase , default='.' , help='Optional save directory where all checkpoint folders will be stored. Default is the current working directory.' , ) parser.add_argument( '--performance_lower_bound' , type=_lowercase , default=_lowercase , help='Optional lower bound for the performance metric. If set, the training will throw error when the performance metric drops below this value.' , ) parser.add_argument( '--num_epochs' , type=_lowercase , default=3 , help='Number of train epochs.' , ) __UpperCamelCase = parser.parse_args() __UpperCamelCase = {'lr': 2e-5, 'num_epochs': args.num_epochs, 'seed': 42, 'batch_size': 16} training_function(_lowercase , _lowercase ) if __name__ == "__main__": main()

import os from shutil import copyfile from typing import Any, Dict, List, Optional, Tuple import sentencepiece as spm from ...tokenization_utils import PreTrainedTokenizer from ...utils import logging __snake_case = '''▁''' __snake_case = {'''vocab_file''': '''spiece.model'''} __snake_case = { '''vocab_file''': {'''google/pegasus-xsum''': '''https://huggingface.co/google/pegasus-xsum/resolve/main/spiece.model'''} } __snake_case = { '''google/pegasus-xsum''': 5_1_2, } __snake_case = logging.get_logger(__name__) class __lowerCamelCase (_a ): _lowercase = VOCAB_FILES_NAMES _lowercase = VOCAB_FILES_NAMES _lowercase = PRETRAINED_VOCAB_FILES_MAP _lowercase = PRETRAINED_POSITIONAL_EMBEDDINGS_SIZES _lowercase = ["""input_ids""", """attention_mask"""] def __init__( self: List[Any],A_: Dict,A_: Optional[int]="<pad>",A_: Tuple="</s>",A_: int="<unk>",A_: Tuple="<mask_2>",A_: Optional[int]="<mask_1>",A_: str=None,A_: List[Any]=103,A_: Optional[Dict[str, Any]] = None,**A_: Dict,): '''simple docstring''' __UpperCamelCase = offset if additional_special_tokens is not None: if not isinstance(A_,A_ ): raise TypeError( F'''additional_special_tokens should be of type {type(A_ )}, but is''' F''' {type(A_ )}''' ) __UpperCamelCase = ( ([mask_token_sent] + additional_special_tokens) if mask_token_sent not in additional_special_tokens and mask_token_sent is not None else additional_special_tokens ) # fill additional tokens with ..., <unk_token_102> in case not all additional tokens are already taken additional_special_tokens_extended += [ F'''<unk_{i}>''' for i in range(len(A_ ),self.offset - 1 ) ] if len(set(A_ ) ) != len(A_ ): raise ValueError( 'Please make sure that the provided additional_special_tokens do not contain an incorrectly' F''' shifted list of <unk_x> tokens. Found {additional_special_tokens_extended}.''' ) __UpperCamelCase = additional_special_tokens_extended else: __UpperCamelCase = [mask_token_sent] if mask_token_sent is not None else [] additional_special_tokens += [F'''<unk_{i}>''' for i in range(2,self.offset )] __UpperCamelCase = {} if sp_model_kwargs is None else sp_model_kwargs super().__init__( eos_token=A_,unk_token=A_,mask_token=A_,pad_token=A_,mask_token_sent=A_,offset=A_,additional_special_tokens=A_,sp_model_kwargs=self.sp_model_kwargs,**A_,) __UpperCamelCase = mask_token_sent __UpperCamelCase = vocab_file __UpperCamelCase = spm.SentencePieceProcessor(**self.sp_model_kwargs ) self.sp_model.Load(A_ ) # add special tokens to encoder dict __UpperCamelCase = { 0: self.pad_token, 1: self.eos_token, } if self.mask_token_sent is not None: self.encoder.update( { 2: self.mask_token_sent, 3: self.mask_token, } ) if self.offset > 0: # entries 2-104 are only used for pretraining and called <mask_1>, <mask_2>, unk_2, ...unk_102 # mask_token_sent is already added to list -> so start at 1 self.encoder.update({i + 3: additional_special_tokens[i] for i in range(1,self.offset - 1 )} ) __UpperCamelCase = {v: k for k, v in self.encoder.items()} @property def snake_case_ ( self: str ): '''simple docstring''' return len(self.sp_model ) + self.offset def snake_case_ ( self: List[str] ): '''simple docstring''' __UpperCamelCase = {self.convert_ids_to_tokens(A_ ): i for i in range(self.vocab_size )} vocab.update(self.added_tokens_encoder ) return vocab def __getstate__( self: Optional[Any] ): '''simple docstring''' __UpperCamelCase = self.__dict__.copy() __UpperCamelCase = None return state def __setstate__( self: Dict,A_: Optional[int] ): '''simple docstring''' __UpperCamelCase = d # for backward compatibility if not hasattr(self,'sp_model_kwargs' ): __UpperCamelCase = {} __UpperCamelCase = spm.SentencePieceProcessor(**self.sp_model_kwargs ) self.sp_model.Load(self.vocab_file ) def snake_case_ ( self: Optional[int],A_: str ): '''simple docstring''' return self.sp_model.encode(A_,out_type=A_ ) def snake_case_ ( self: str,A_: str ): '''simple docstring''' if token in self.decoder: return self.decoder[token] elif token in self.added_tokens_decoder: return self.added_tokens_decoder[token] __UpperCamelCase = self.sp_model.piece_to_id(A_ ) return sp_id + self.offset def snake_case_ ( self: Union[str, Any],A_: int ): '''simple docstring''' if index in self.encoder: return self.encoder[index] elif index in self.added_tokens_encoder: return self.added_tokens_encoder[index] else: __UpperCamelCase = self.sp_model.IdToPiece(index - self.offset ) return token def snake_case_ ( self: Union[str, Any],A_: List[Any] ): '''simple docstring''' __UpperCamelCase = [] __UpperCamelCase = '' for token in tokens: # make sure that special tokens are not decoded using sentencepiece model if token in self.all_special_tokens: out_string += self.sp_model.decode(A_ ) + token __UpperCamelCase = [] else: current_sub_tokens.append(A_ ) out_string += self.sp_model.decode(A_ ) return out_string.strip() def snake_case_ ( self: Dict,A_: Any=False ): '''simple docstring''' return 1 def snake_case_ ( self: Union[str, Any],A_: Dict ): '''simple docstring''' __UpperCamelCase = set(self.all_special_ids ) # call it once instead of inside list comp all_special_ids.remove(self.unk_token_id ) # <unk> is only sometimes special return [1 if x in all_special_ids else 0 for x in seq] def snake_case_ ( self: Optional[Any],A_: List,A_: Optional[List] = None,A_: bool = False ): '''simple docstring''' if already_has_special_tokens: return self._special_token_mask(A_ ) elif token_ids_a is None: return self._special_token_mask(A_ ) + [1] else: return self._special_token_mask(token_ids_a + token_ids_a ) + [1] def snake_case_ ( self: Optional[Any],A_: Optional[int],A_: Tuple=None ): '''simple docstring''' if token_ids_a is None: return token_ids_a + [self.eos_token_id] # We don't expect to process pairs, but leave the pair logic for API consistency return token_ids_a + token_ids_a + [self.eos_token_id] def snake_case_ ( self: List[str],A_: str,A_: Optional[str] = None ): '''simple docstring''' if not os.path.isdir(A_ ): logger.error(F'''Vocabulary path ({save_directory}) should be a directory''' ) return __UpperCamelCase = os.path.join( A_,(filename_prefix + '-' if filename_prefix else '') + VOCAB_FILES_NAMES['vocab_file'] ) if os.path.abspath(self.vocab_file ) != os.path.abspath(A_ ) and os.path.isfile(self.vocab_file ): copyfile(self.vocab_file,A_ ) elif not os.path.isfile(self.vocab_file ): with open(A_,'wb' ) as fi: __UpperCamelCase = self.sp_model.serialized_model_proto() fi.write(A_ ) return (out_vocab_file,)

from transformers import BertTokenizer, EncoderDecoderModel, SeqaSeqTrainer, SeqaSeqTrainingArguments from transformers.testing_utils import TestCasePlus, require_torch, slow from transformers.utils import is_datasets_available if is_datasets_available(): import datasets class __lowerCamelCase (_a ): @slow @require_torch def snake_case_ ( self: Union[str, Any] ): '''simple docstring''' __UpperCamelCase = EncoderDecoderModel.from_encoder_decoder_pretrained('prajjwal1/bert-tiny','prajjwal1/bert-tiny' ) __UpperCamelCase = BertTokenizer.from_pretrained('bert-base-uncased' ) __UpperCamelCase = bertabert.config.encoder.vocab_size __UpperCamelCase = tokenizer.sep_token_id __UpperCamelCase = tokenizer.cls_token_id __UpperCamelCase = 128 __UpperCamelCase = datasets.load_dataset('cnn_dailymail','3.0.0',split='train[:1%]' ) __UpperCamelCase = datasets.load_dataset('cnn_dailymail','3.0.0',split='validation[:1%]' ) __UpperCamelCase = train_dataset.select(range(32 ) ) __UpperCamelCase = val_dataset.select(range(16 ) ) __UpperCamelCase = 4 def _map_to_encoder_decoder_inputs(A_: Dict ): # Tokenizer will automatically set [BOS] <text> [EOS] __UpperCamelCase = tokenizer(batch['article'],padding='max_length',truncation=A_,max_length=512 ) __UpperCamelCase = tokenizer(batch['highlights'],padding='max_length',truncation=A_,max_length=128 ) __UpperCamelCase = inputs.input_ids __UpperCamelCase = inputs.attention_mask __UpperCamelCase = outputs.input_ids __UpperCamelCase = outputs.input_ids.copy() __UpperCamelCase = [ [-100 if token == tokenizer.pad_token_id else token for token in labels] for labels in batch['labels'] ] __UpperCamelCase = outputs.attention_mask assert all(len(A_ ) == 512 for x in inputs.input_ids ) assert all(len(A_ ) == 128 for x in outputs.input_ids ) return batch def _compute_metrics(A_: str ): __UpperCamelCase = pred.label_ids __UpperCamelCase = pred.predictions # all unnecessary tokens are removed __UpperCamelCase = tokenizer.batch_decode(A_,skip_special_tokens=A_ ) __UpperCamelCase = tokenizer.batch_decode(A_,skip_special_tokens=A_ ) __UpperCamelCase = sum([int(pred_str[i] == label_str[i] ) for i in range(len(A_ ) )] ) / len(A_ ) return {"accuracy": accuracy} # map train dataset __UpperCamelCase = train_dataset.map( _map_to_encoder_decoder_inputs,batched=A_,batch_size=A_,remove_columns=['article', 'highlights'],) train_dataset.set_format( type='torch',columns=['input_ids', 'attention_mask', 'decoder_input_ids', 'decoder_attention_mask', 'labels'],) # same for validation dataset __UpperCamelCase = val_dataset.map( _map_to_encoder_decoder_inputs,batched=A_,batch_size=A_,remove_columns=['article', 'highlights'],) val_dataset.set_format( type='torch',columns=['input_ids', 'attention_mask', 'decoder_input_ids', 'decoder_attention_mask', 'labels'],) __UpperCamelCase = self.get_auto_remove_tmp_dir() __UpperCamelCase = SeqaSeqTrainingArguments( output_dir=A_,per_device_train_batch_size=A_,per_device_eval_batch_size=A_,predict_with_generate=A_,evaluation_strategy='steps',do_train=A_,do_eval=A_,warmup_steps=0,eval_steps=2,logging_steps=2,) # instantiate trainer __UpperCamelCase = SeqaSeqTrainer( model=A_,args=A_,compute_metrics=_compute_metrics,train_dataset=A_,eval_dataset=A_,tokenizer=A_,) # start training trainer.train()

from functools import reduce __snake_case = ( '''73167176531330624919225119674426574742355349194934''' '''96983520312774506326239578318016984801869478851843''' '''85861560789112949495459501737958331952853208805511''' '''12540698747158523863050715693290963295227443043557''' '''66896648950445244523161731856403098711121722383113''' '''62229893423380308135336276614282806444486645238749''' '''30358907296290491560440772390713810515859307960866''' '''70172427121883998797908792274921901699720888093776''' '''65727333001053367881220235421809751254540594752243''' '''52584907711670556013604839586446706324415722155397''' '''53697817977846174064955149290862569321978468622482''' '''83972241375657056057490261407972968652414535100474''' '''82166370484403199890008895243450658541227588666881''' '''16427171479924442928230863465674813919123162824586''' '''17866458359124566529476545682848912883142607690042''' '''24219022671055626321111109370544217506941658960408''' '''07198403850962455444362981230987879927244284909188''' '''84580156166097919133875499200524063689912560717606''' '''05886116467109405077541002256983155200055935729725''' '''71636269561882670428252483600823257530420752963450''' ) def _A ( _lowercase = N ) -> int: """simple docstring""" return max( # mypy cannot properly interpret reduce int(reduce(lambda _lowercase , _lowercase : str(int(_lowercase ) * int(_lowercase ) ) , n[i : i + 13] ) ) for i in range(len(_lowercase ) - 12 ) ) if __name__ == "__main__": print(f"""{solution() = }""")

def _A ( _lowercase = 1_00 ) -> int: """simple docstring""" __UpperCamelCase = 0 __UpperCamelCase = 0 for i in range(1 , n + 1 ): sum_of_squares += i**2 sum_of_ints += i return sum_of_ints**2 - sum_of_squares if __name__ == "__main__": print(f"""{solution() = }""")

import inspect import unittest import numpy as np from tests.test_modeling_common import floats_tensor from transformers import DetrConfig, MaskFormerConfig, SwinConfig, is_torch_available, is_vision_available from transformers.testing_utils import require_torch, require_torch_multi_gpu, require_vision, slow, torch_device from transformers.utils import cached_property from ...test_configuration_common import ConfigTester from ...test_modeling_common import ModelTesterMixin from ...test_pipeline_mixin import PipelineTesterMixin if is_torch_available(): import torch from transformers import MaskFormerForInstanceSegmentation, MaskFormerModel if is_vision_available(): from transformers import MaskFormerImageProcessor if is_vision_available(): from PIL import Image class __lowerCamelCase : def __init__( self: Tuple,A_: List[str],A_: List[Any]=2,A_: Union[str, Any]=True,A_: Dict=False,A_: Union[str, Any]=10,A_: Any=3,A_: Any=32 * 4,A_: int=32 * 6,A_: Optional[int]=4,A_: List[str]=32,): '''simple docstring''' __UpperCamelCase = parent __UpperCamelCase = batch_size __UpperCamelCase = is_training __UpperCamelCase = use_auxiliary_loss __UpperCamelCase = num_queries __UpperCamelCase = num_channels __UpperCamelCase = min_size __UpperCamelCase = max_size __UpperCamelCase = num_labels __UpperCamelCase = mask_feature_size def snake_case_ ( self: str ): '''simple docstring''' __UpperCamelCase = floats_tensor([self.batch_size, self.num_channels, self.min_size, self.max_size] ).to( A_ ) __UpperCamelCase = torch.ones([self.batch_size, self.min_size, self.max_size],device=A_ ) __UpperCamelCase = ( torch.rand([self.batch_size, self.num_labels, self.min_size, self.max_size],device=A_ ) > 0.5 ).float() __UpperCamelCase = (torch.rand((self.batch_size, self.num_labels),device=A_ ) > 0.5).long() __UpperCamelCase = self.get_config() return config, pixel_values, pixel_mask, mask_labels, class_labels def snake_case_ ( self: Optional[Any] ): '''simple docstring''' return MaskFormerConfig.from_backbone_and_decoder_configs( backbone_config=SwinConfig( depths=[1, 1, 1, 1],),decoder_config=DetrConfig( decoder_ffn_dim=128,num_queries=self.num_queries,decoder_attention_heads=2,d_model=self.mask_feature_size,),mask_feature_size=self.mask_feature_size,fpn_feature_size=self.mask_feature_size,num_channels=self.num_channels,num_labels=self.num_labels,) def snake_case_ ( self: Union[str, Any] ): '''simple docstring''' __UpperCamelCase, __UpperCamelCase, __UpperCamelCase, __UpperCamelCase, __UpperCamelCase = self.prepare_config_and_inputs() __UpperCamelCase = {'pixel_values': pixel_values, 'pixel_mask': pixel_mask} return config, inputs_dict def snake_case_ ( self: int,A_: str,A_: Union[str, Any] ): '''simple docstring''' __UpperCamelCase = output.encoder_hidden_states __UpperCamelCase = output.pixel_decoder_hidden_states __UpperCamelCase = output.transformer_decoder_hidden_states self.parent.assertTrue(len(A_ ),len(config.backbone_config.depths ) ) self.parent.assertTrue(len(A_ ),len(config.backbone_config.depths ) ) self.parent.assertTrue(len(A_ ),config.decoder_config.decoder_layers ) def snake_case_ ( self: List[Any],A_: Dict,A_: Any,A_: Optional[int],A_: List[Any]=False ): '''simple docstring''' with torch.no_grad(): __UpperCamelCase = MaskFormerModel(config=A_ ) model.to(A_ ) model.eval() __UpperCamelCase = model(pixel_values=A_,pixel_mask=A_ ) __UpperCamelCase = model(A_,output_hidden_states=A_ ) # the correct shape of output.transformer_decoder_hidden_states ensure the correcteness of the # encoder and pixel decoder self.parent.assertEqual( output.transformer_decoder_last_hidden_state.shape,(self.batch_size, self.num_queries, self.mask_feature_size),) # let's ensure the other two hidden state exists self.parent.assertTrue(output.pixel_decoder_last_hidden_state is not None ) self.parent.assertTrue(output.encoder_last_hidden_state is not None ) if output_hidden_states: self.check_output_hidden_state(A_,A_ ) def snake_case_ ( self: List[str],A_: str,A_: List[Any],A_: List[str],A_: str,A_: Union[str, Any] ): '''simple docstring''' __UpperCamelCase = MaskFormerForInstanceSegmentation(config=A_ ) model.to(A_ ) model.eval() def comm_check_on_output(A_: Optional[int] ): # let's still check that all the required stuff is there self.parent.assertTrue(result.transformer_decoder_last_hidden_state is not None ) self.parent.assertTrue(result.pixel_decoder_last_hidden_state is not None ) self.parent.assertTrue(result.encoder_last_hidden_state is not None ) # okay, now we need to check the logits shape # due to the encoder compression, masks have a //4 spatial size self.parent.assertEqual( result.masks_queries_logits.shape,(self.batch_size, self.num_queries, self.min_size // 4, self.max_size // 4),) # + 1 for null class self.parent.assertEqual( result.class_queries_logits.shape,(self.batch_size, self.num_queries, self.num_labels + 1) ) with torch.no_grad(): __UpperCamelCase = model(pixel_values=A_,pixel_mask=A_ ) __UpperCamelCase = model(A_ ) comm_check_on_output(A_ ) __UpperCamelCase = model( pixel_values=A_,pixel_mask=A_,mask_labels=A_,class_labels=A_ ) comm_check_on_output(A_ ) self.parent.assertTrue(result.loss is not None ) self.parent.assertEqual(result.loss.shape,torch.Size([1] ) ) @require_torch class __lowerCamelCase (_a , _a , unittest.TestCase ): _lowercase = (MaskFormerModel, MaskFormerForInstanceSegmentation) if is_torch_available() else () _lowercase = ( {"""feature-extraction""": MaskFormerModel, """image-segmentation""": MaskFormerForInstanceSegmentation} if is_torch_available() else {} ) _lowercase = False _lowercase = False _lowercase = False _lowercase = False def snake_case_ ( self: Dict ): '''simple docstring''' __UpperCamelCase = MaskFormerModelTester(self ) __UpperCamelCase = ConfigTester(self,config_class=A_,has_text_modality=A_ ) def snake_case_ ( self: int ): '''simple docstring''' self.config_tester.run_common_tests() def snake_case_ ( self: List[str] ): '''simple docstring''' __UpperCamelCase, __UpperCamelCase = self.model_tester.prepare_config_and_inputs_for_common() self.model_tester.create_and_check_maskformer_model(A_,**A_,output_hidden_states=A_ ) def snake_case_ ( self: Union[str, Any] ): '''simple docstring''' __UpperCamelCase = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_maskformer_instance_segmentation_head_model(*A_ ) @unittest.skip(reason='MaskFormer does not use inputs_embeds' ) def snake_case_ ( self: Tuple ): '''simple docstring''' pass @unittest.skip(reason='MaskFormer does not have a get_input_embeddings method' ) def snake_case_ ( self: Tuple ): '''simple docstring''' pass @unittest.skip(reason='MaskFormer is not a generative model' ) def snake_case_ ( self: Any ): '''simple docstring''' pass @unittest.skip(reason='MaskFormer does not use token embeddings' ) def snake_case_ ( self: Tuple ): '''simple docstring''' pass @require_torch_multi_gpu @unittest.skip( reason='MaskFormer has some layers using `add_module` which doesn\'t work well with `nn.DataParallel`' ) def snake_case_ ( self: List[str] ): '''simple docstring''' pass @unittest.skip('Will be fixed soon by reducing the size of the model used for common tests.' ) def snake_case_ ( self: Any ): '''simple docstring''' pass def snake_case_ ( self: Optional[Any] ): '''simple docstring''' __UpperCamelCase, __UpperCamelCase = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: __UpperCamelCase = model_class(A_ ) __UpperCamelCase = inspect.signature(model.forward ) # signature.parameters is an OrderedDict => so arg_names order is deterministic __UpperCamelCase = [*signature.parameters.keys()] __UpperCamelCase = ['pixel_values'] self.assertListEqual(arg_names[:1],A_ ) @slow def snake_case_ ( self: Any ): '''simple docstring''' for model_name in ["facebook/maskformer-swin-small-coco"]: __UpperCamelCase = MaskFormerModel.from_pretrained(A_ ) self.assertIsNotNone(A_ ) def snake_case_ ( self: int ): '''simple docstring''' __UpperCamelCase = (self.model_tester.min_size,) * 2 __UpperCamelCase = { 'pixel_values': torch.randn((2, 3, *size),device=A_ ), 'mask_labels': torch.randn((2, 10, *size),device=A_ ), 'class_labels': torch.zeros(2,10,device=A_ ).long(), } __UpperCamelCase = MaskFormerForInstanceSegmentation(MaskFormerConfig() ).to(A_ ) __UpperCamelCase = model(**A_ ) self.assertTrue(outputs.loss is not None ) def snake_case_ ( self: Tuple ): '''simple docstring''' __UpperCamelCase, __UpperCamelCase = self.model_tester.prepare_config_and_inputs_for_common() self.model_tester.create_and_check_maskformer_model(A_,**A_,output_hidden_states=A_ ) def snake_case_ ( self: Any ): '''simple docstring''' __UpperCamelCase, __UpperCamelCase = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: __UpperCamelCase = model_class(A_ ).to(A_ ) __UpperCamelCase = model(**A_,output_attentions=A_ ) self.assertTrue(outputs.attentions is not None ) def snake_case_ ( self: Any ): '''simple docstring''' if not self.model_tester.is_training: return # only MaskFormerForInstanceSegmentation has the loss __UpperCamelCase = self.all_model_classes[1] __UpperCamelCase, __UpperCamelCase, __UpperCamelCase, __UpperCamelCase, __UpperCamelCase = self.model_tester.prepare_config_and_inputs() __UpperCamelCase = model_class(A_ ) model.to(A_ ) model.train() __UpperCamelCase = model(A_,mask_labels=A_,class_labels=A_ ).loss loss.backward() def snake_case_ ( self: List[Any] ): '''simple docstring''' __UpperCamelCase = self.all_model_classes[1] __UpperCamelCase, __UpperCamelCase, __UpperCamelCase, __UpperCamelCase, __UpperCamelCase = self.model_tester.prepare_config_and_inputs() __UpperCamelCase = True __UpperCamelCase = True __UpperCamelCase = model_class(A_ ) model.to(A_ ) model.train() __UpperCamelCase = model(A_,mask_labels=A_,class_labels=A_ ) __UpperCamelCase = outputs.encoder_hidden_states[0] encoder_hidden_states.retain_grad() __UpperCamelCase = outputs.pixel_decoder_hidden_states[0] pixel_decoder_hidden_states.retain_grad() # we requires_grad=True in inputs_embeds (line 2152), the original implementation don't __UpperCamelCase = outputs.transformer_decoder_hidden_states[0] transformer_decoder_hidden_states.retain_grad() __UpperCamelCase = outputs.attentions[0] attentions.retain_grad() outputs.loss.backward(retain_graph=A_ ) self.assertIsNotNone(encoder_hidden_states.grad ) self.assertIsNotNone(pixel_decoder_hidden_states.grad ) self.assertIsNotNone(transformer_decoder_hidden_states.grad ) self.assertIsNotNone(attentions.grad ) __snake_case = 1e-4 def _A ( ) -> str: """simple docstring""" __UpperCamelCase = Image.open('./tests/fixtures/tests_samples/COCO/000000039769.png' ) return image @require_vision @slow class __lowerCamelCase (unittest.TestCase ): @cached_property def snake_case_ ( self: Dict ): '''simple docstring''' return ( MaskFormerImageProcessor.from_pretrained('facebook/maskformer-swin-small-coco' ) if is_vision_available() else None ) def snake_case_ ( self: Dict ): '''simple docstring''' __UpperCamelCase = MaskFormerModel.from_pretrained('facebook/maskformer-swin-small-coco' ).to(A_ ) __UpperCamelCase = self.default_image_processor __UpperCamelCase = prepare_img() __UpperCamelCase = image_processor(A_,return_tensors='pt' ).to(A_ ) __UpperCamelCase = inputs['pixel_values'].shape # check size is divisible by 32 self.assertTrue((inputs_shape[-1] % 32) == 0 and (inputs_shape[-2] % 32) == 0 ) # check size self.assertEqual(A_,(1, 3, 800, 1088) ) with torch.no_grad(): __UpperCamelCase = model(**A_ ) __UpperCamelCase = torch.tensor( [[-0.0_4_8_2, 0.9_2_2_8, 0.4_9_5_1], [-0.2_5_4_7, 0.8_0_1_7, 0.8_5_2_7], [-0.0_0_6_9, 0.3_3_8_5, -0.0_0_8_9]] ).to(A_ ) self.assertTrue( torch.allclose( outputs.encoder_last_hidden_state[0, 0, :3, :3],A_,atol=A_ ) ) __UpperCamelCase = torch.tensor( [[-0.8_4_2_2, -0.8_4_3_4, -0.9_7_1_8], [-1.0_1_4_4, -0.5_5_6_5, -0.4_1_9_5], [-1.0_0_3_8, -0.4_4_8_4, -0.1_9_6_1]] ).to(A_ ) self.assertTrue( torch.allclose( outputs.pixel_decoder_last_hidden_state[0, 0, :3, :3],A_,atol=A_ ) ) __UpperCamelCase = torch.tensor( [[0.2_8_5_2, -0.0_1_5_9, 0.9_7_3_5], [0.6_2_5_4, 0.1_8_5_8, 0.8_5_2_9], [-0.0_6_8_0, -0.4_1_1_6, 1.8_4_1_3]] ).to(A_ ) self.assertTrue( torch.allclose( outputs.transformer_decoder_last_hidden_state[0, :3, :3],A_,atol=A_ ) ) def snake_case_ ( self: Optional[Any] ): '''simple docstring''' __UpperCamelCase = ( MaskFormerForInstanceSegmentation.from_pretrained('facebook/maskformer-swin-small-coco' ) .to(A_ ) .eval() ) __UpperCamelCase = self.default_image_processor __UpperCamelCase = prepare_img() __UpperCamelCase = image_processor(A_,return_tensors='pt' ).to(A_ ) __UpperCamelCase = inputs['pixel_values'].shape # check size is divisible by 32 self.assertTrue((inputs_shape[-1] % 32) == 0 and (inputs_shape[-2] % 32) == 0 ) # check size self.assertEqual(A_,(1, 3, 800, 1088) ) with torch.no_grad(): __UpperCamelCase = model(**A_ ) # masks_queries_logits __UpperCamelCase = outputs.masks_queries_logits self.assertEqual( masks_queries_logits.shape,(1, model.config.decoder_config.num_queries, inputs_shape[-2] // 4, inputs_shape[-1] // 4),) __UpperCamelCase = [ [-1.3_7_3_7_1_2_4, -1.7_7_2_4_9_3_7, -1.9_3_6_4_2_3_3], [-1.5_9_7_7_2_8_1, -1.9_8_6_7_9_3_9, -2.1_5_2_3_6_9_5], [-1.5_7_9_5_3_9_8, -1.9_2_6_9_8_3_2, -2.0_9_3_9_4_2], ] __UpperCamelCase = torch.tensor(A_ ).to(A_ ) self.assertTrue(torch.allclose(masks_queries_logits[0, 0, :3, :3],A_,atol=A_ ) ) # class_queries_logits __UpperCamelCase = outputs.class_queries_logits self.assertEqual( class_queries_logits.shape,(1, model.config.decoder_config.num_queries, model.config.num_labels + 1) ) __UpperCamelCase = torch.tensor( [ [1.6_512E00, -5.2_572E00, -3.3_519E00], [3.6_169E-02, -5.9_025E00, -2.9_313E00], [1.0_766E-04, -7.7_630E00, -5.1_263E00], ] ).to(A_ ) self.assertTrue(torch.allclose(outputs.class_queries_logits[0, :3, :3],A_,atol=A_ ) ) def snake_case_ ( self: List[str] ): '''simple docstring''' __UpperCamelCase = ( MaskFormerForInstanceSegmentation.from_pretrained('facebook/maskformer-resnet101-coco-stuff' ) .to(A_ ) .eval() ) __UpperCamelCase = self.default_image_processor __UpperCamelCase = prepare_img() __UpperCamelCase = image_processor(A_,return_tensors='pt' ).to(A_ ) __UpperCamelCase = inputs['pixel_values'].shape # check size is divisible by 32 self.assertTrue((inputs_shape[-1] % 32) == 0 and (inputs_shape[-2] % 32) == 0 ) # check size self.assertEqual(A_,(1, 3, 800, 1088) ) with torch.no_grad(): __UpperCamelCase = model(**A_ ) # masks_queries_logits __UpperCamelCase = outputs.masks_queries_logits self.assertEqual( masks_queries_logits.shape,(1, model.config.decoder_config.num_queries, inputs_shape[-2] // 4, inputs_shape[-1] // 4),) __UpperCamelCase = [[-0.9_0_4_6, -2.6_3_6_6, -4.6_0_6_2], [-3.4_1_7_9, -5.7_8_9_0, -8.8_0_5_7], [-4.9_1_7_9, -7.6_5_6_0, -1_0.7_7_1_1]] __UpperCamelCase = torch.tensor(A_ ).to(A_ ) self.assertTrue(torch.allclose(masks_queries_logits[0, 0, :3, :3],A_,atol=A_ ) ) # class_queries_logits __UpperCamelCase = outputs.class_queries_logits self.assertEqual( class_queries_logits.shape,(1, model.config.decoder_config.num_queries, model.config.num_labels + 1) ) __UpperCamelCase = torch.tensor( [[4.7_1_8_8, -3.2_5_8_5, -2.8_8_5_7], [6.6_8_7_1, -2.9_1_8_1, -1.2_4_8_7], [7.2_4_4_9, -2.2_7_6_4, -2.1_8_7_4]] ).to(A_ ) self.assertTrue(torch.allclose(outputs.class_queries_logits[0, :3, :3],A_,atol=A_ ) ) def snake_case_ ( self: str ): '''simple docstring''' __UpperCamelCase = ( MaskFormerForInstanceSegmentation.from_pretrained('facebook/maskformer-swin-small-coco' ) .to(A_ ) .eval() ) __UpperCamelCase = self.default_image_processor __UpperCamelCase = image_processor( [np.zeros((3, 800, 1333) ), np.zeros((3, 800, 1333) )],segmentation_maps=[np.zeros((384, 384) ).astype(np.floataa ), np.zeros((384, 384) ).astype(np.floataa )],return_tensors='pt',) __UpperCamelCase = inputs['pixel_values'].to(A_ ) __UpperCamelCase = [el.to(A_ ) for el in inputs['mask_labels']] __UpperCamelCase = [el.to(A_ ) for el in inputs['class_labels']] with torch.no_grad(): __UpperCamelCase = model(**A_ ) self.assertTrue(outputs.loss is not None )

def _A ( _lowercase , _lowercase ) -> int: """simple docstring""" return (pointa[0] - pointa[0]) ** 2 + (pointa[1] - pointa[1]) ** 2 def _A ( _lowercase , _lowercase=0 ) -> Dict: """simple docstring""" return sorted(_lowercase , key=lambda _lowercase : x[column] ) def _A ( _lowercase , _lowercase , _lowercase=float('inf' ) ) -> List[Any]: """simple docstring""" for i in range(points_counts - 1 ): for j in range(i + 1 , _lowercase ): __UpperCamelCase = euclidean_distance_sqr(points[i] , points[j] ) if current_dis < min_dis: __UpperCamelCase = current_dis return min_dis def _A ( _lowercase , _lowercase , _lowercase=float('inf' ) ) -> Tuple: """simple docstring""" for i in range(min(6 , points_counts - 1 ) , _lowercase ): for j in range(max(0 , i - 6 ) , _lowercase ): __UpperCamelCase = euclidean_distance_sqr(points[i] , points[j] ) if current_dis < min_dis: __UpperCamelCase = current_dis return min_dis def _A ( _lowercase , _lowercase , _lowercase ) -> Optional[Any]: """simple docstring""" if points_counts <= 3: return dis_between_closest_pair(_lowercase , _lowercase ) # recursion __UpperCamelCase = points_counts // 2 __UpperCamelCase = closest_pair_of_points_sqr( _lowercase , points_sorted_on_y[:mid] , _lowercase ) __UpperCamelCase = closest_pair_of_points_sqr( _lowercase , points_sorted_on_y[mid:] , points_counts - mid ) __UpperCamelCase = min(_lowercase , _lowercase ) __UpperCamelCase = [] for point in points_sorted_on_x: if abs(point[0] - points_sorted_on_x[mid][0] ) < closest_pair_dis: cross_strip.append(_lowercase ) __UpperCamelCase = dis_between_closest_in_strip( _lowercase , len(_lowercase ) , _lowercase ) return min(_lowercase , _lowercase ) def _A ( _lowercase , _lowercase ) -> Optional[int]: """simple docstring""" __UpperCamelCase = column_based_sort(_lowercase , column=0 ) __UpperCamelCase = column_based_sort(_lowercase , column=1 ) return ( closest_pair_of_points_sqr( _lowercase , _lowercase , _lowercase ) ) ** 0.5 if __name__ == "__main__": __snake_case = [(2, 3), (1_2, 3_0), (4_0, 5_0), (5, 1), (1_2, 1_0), (3, 4)] print('''Distance:''', closest_pair_of_points(points, len(points)))

from typing import Callable, List, Optional, Tuple, Union import torch from transformers import CLIPTextModel, CLIPTokenizer from ...configuration_utils import ConfigMixin, register_to_config from ...models import ModelMixin, TransformeraDModel, VQModel from ...schedulers import VQDiffusionScheduler from ...utils import logging from ..pipeline_utils import DiffusionPipeline, ImagePipelineOutput __snake_case = logging.get_logger(__name__) # pylint: disable=invalid-name class __lowerCamelCase (_a , _a ): @register_to_config def __init__( self: str,A_: bool,A_: Optional[int] = None,A_: Optional[int] = None ): '''simple docstring''' super().__init__() __UpperCamelCase = learnable if self.learnable: assert hidden_size is not None, "learnable=True requires `hidden_size` to be set" assert length is not None, "learnable=True requires `length` to be set" __UpperCamelCase = torch.zeros(A_,A_ ) else: __UpperCamelCase = None __UpperCamelCase = torch.nn.Parameter(A_ ) class __lowerCamelCase (_a ): _lowercase = 42 _lowercase = 42 _lowercase = 42 _lowercase = 42 _lowercase = 42 _lowercase = 42 def __init__( self: Any,A_: VQModel,A_: CLIPTextModel,A_: CLIPTokenizer,A_: TransformeraDModel,A_: VQDiffusionScheduler,A_: LearnedClassifierFreeSamplingEmbeddings,): '''simple docstring''' super().__init__() self.register_modules( vqvae=A_,transformer=A_,text_encoder=A_,tokenizer=A_,scheduler=A_,learned_classifier_free_sampling_embeddings=A_,) def snake_case_ ( self: Dict,A_: Optional[Any],A_: Any,A_: str ): '''simple docstring''' __UpperCamelCase = len(A_ ) if isinstance(A_,A_ ) else 1 # get prompt text embeddings __UpperCamelCase = self.tokenizer( A_,padding='max_length',max_length=self.tokenizer.model_max_length,return_tensors='pt',) __UpperCamelCase = text_inputs.input_ids if text_input_ids.shape[-1] > self.tokenizer.model_max_length: __UpperCamelCase = self.tokenizer.batch_decode(text_input_ids[:, self.tokenizer.model_max_length :] ) logger.warning( 'The following part of your input was truncated because CLIP can only handle sequences up to' F''' {self.tokenizer.model_max_length} tokens: {removed_text}''' ) __UpperCamelCase = text_input_ids[:, : self.tokenizer.model_max_length] __UpperCamelCase = self.text_encoder(text_input_ids.to(self.device ) )[0] # NOTE: This additional step of normalizing the text embeddings is from VQ-Diffusion. # While CLIP does normalize the pooled output of the text transformer when combining # the image and text embeddings, CLIP does not directly normalize the last hidden state. # # CLIP normalizing the pooled output. # https://github.com/huggingface/transformers/blob/d92e22d1f28324f513f3080e5c47c071a3916721/src/transformers/models/clip/modeling_clip.py#L1052-L1053 __UpperCamelCase = prompt_embeds / prompt_embeds.norm(dim=-1,keepdim=A_ ) # duplicate text embeddings for each generation per prompt __UpperCamelCase = prompt_embeds.repeat_interleave(A_,dim=0 ) if do_classifier_free_guidance: if self.learned_classifier_free_sampling_embeddings.learnable: __UpperCamelCase = self.learned_classifier_free_sampling_embeddings.embeddings __UpperCamelCase = negative_prompt_embeds.unsqueeze(0 ).repeat(A_,1,1 ) else: __UpperCamelCase = [''] * batch_size __UpperCamelCase = text_input_ids.shape[-1] __UpperCamelCase = self.tokenizer( A_,padding='max_length',max_length=A_,truncation=A_,return_tensors='pt',) __UpperCamelCase = self.text_encoder(uncond_input.input_ids.to(self.device ) )[0] # See comment for normalizing text embeddings __UpperCamelCase = negative_prompt_embeds / negative_prompt_embeds.norm(dim=-1,keepdim=A_ ) # duplicate unconditional embeddings for each generation per prompt, using mps friendly method __UpperCamelCase = negative_prompt_embeds.shape[1] __UpperCamelCase = negative_prompt_embeds.repeat(1,A_,1 ) __UpperCamelCase = negative_prompt_embeds.view(batch_size * num_images_per_prompt,A_,-1 ) # For classifier free guidance, we need to do two forward passes. # Here we concatenate the unconditional and text embeddings into a single batch # to avoid doing two forward passes __UpperCamelCase = torch.cat([negative_prompt_embeds, prompt_embeds] ) return prompt_embeds @torch.no_grad() def __call__( self: List[str],A_: Union[str, List[str]],A_: int = 100,A_: float = 5.0,A_: float = 1.0,A_: int = 1,A_: Optional[Union[torch.Generator, List[torch.Generator]]] = None,A_: Optional[torch.FloatTensor] = None,A_: Optional[str] = "pil",A_: bool = True,A_: Optional[Callable[[int, int, torch.FloatTensor], None]] = None,A_: int = 1,): '''simple docstring''' if isinstance(A_,A_ ): __UpperCamelCase = 1 elif isinstance(A_,A_ ): __UpperCamelCase = len(A_ ) else: raise ValueError(F'''`prompt` has to be of type `str` or `list` but is {type(A_ )}''' ) __UpperCamelCase = batch_size * num_images_per_prompt __UpperCamelCase = guidance_scale > 1.0 __UpperCamelCase = self._encode_prompt(A_,A_,A_ ) if (callback_steps is None) or ( callback_steps is not None and (not isinstance(A_,A_ ) or callback_steps <= 0) ): raise ValueError( F'''`callback_steps` has to be a positive integer but is {callback_steps} of type''' F''' {type(A_ )}.''' ) # get the initial completely masked latents unless the user supplied it __UpperCamelCase = (batch_size, self.transformer.num_latent_pixels) if latents is None: __UpperCamelCase = self.transformer.num_vector_embeds - 1 __UpperCamelCase = torch.full(A_,A_ ).to(self.device ) else: if latents.shape != latents_shape: raise ValueError(F'''Unexpected latents shape, got {latents.shape}, expected {latents_shape}''' ) if (latents < 0).any() or (latents >= self.transformer.num_vector_embeds).any(): raise ValueError( 'Unexpected latents value(s). All latents be valid embedding indices i.e. in the range 0,' F''' {self.transformer.num_vector_embeds - 1} (inclusive).''' ) __UpperCamelCase = latents.to(self.device ) # set timesteps self.scheduler.set_timesteps(A_,device=self.device ) __UpperCamelCase = self.scheduler.timesteps.to(self.device ) __UpperCamelCase = latents for i, t in enumerate(self.progress_bar(A_ ) ): # expand the sample if we are doing classifier free guidance __UpperCamelCase = torch.cat([sample] * 2 ) if do_classifier_free_guidance else sample # predict the un-noised image # model_output == `log_p_x_0` __UpperCamelCase = self.transformer(A_,encoder_hidden_states=A_,timestep=A_ ).sample if do_classifier_free_guidance: __UpperCamelCase, __UpperCamelCase = model_output.chunk(2 ) __UpperCamelCase = model_output_uncond + guidance_scale * (model_output_text - model_output_uncond) model_output -= torch.logsumexp(A_,dim=1,keepdim=A_ ) __UpperCamelCase = self.truncate(A_,A_ ) # remove `log(0)`'s (`-inf`s) __UpperCamelCase = model_output.clamp(-70 ) # compute the previous noisy sample x_t -> x_t-1 __UpperCamelCase = self.scheduler.step(A_,timestep=A_,sample=A_,generator=A_ ).prev_sample # call the callback, if provided if callback is not None and i % callback_steps == 0: callback(A_,A_,A_ ) __UpperCamelCase = self.vqvae.config.vq_embed_dim __UpperCamelCase = (batch_size, self.transformer.height, self.transformer.width, embedding_channels) __UpperCamelCase = self.vqvae.quantize.get_codebook_entry(A_,shape=A_ ) __UpperCamelCase = self.vqvae.decode(A_,force_not_quantize=A_ ).sample __UpperCamelCase = (image / 2 + 0.5).clamp(0,1 ) __UpperCamelCase = image.cpu().permute(0,2,3,1 ).numpy() if output_type == "pil": __UpperCamelCase = self.numpy_to_pil(A_ ) if not return_dict: return (image,) return ImagePipelineOutput(images=A_ ) def snake_case_ ( self: int,A_: torch.FloatTensor,A_: float ): '''simple docstring''' __UpperCamelCase, __UpperCamelCase = torch.sort(A_,1,descending=A_ ) __UpperCamelCase = torch.exp(A_ ) __UpperCamelCase = sorted_p_x_0.cumsum(dim=1 ) < truncation_rate # Ensure that at least the largest probability is not zeroed out __UpperCamelCase = torch.full_like(keep_mask[:, 0:1, :],A_ ) __UpperCamelCase = torch.cat((all_true, keep_mask),dim=1 ) __UpperCamelCase = keep_mask[:, :-1, :] __UpperCamelCase = keep_mask.gather(1,indices.argsort(1 ) ) __UpperCamelCase = log_p_x_0.clone() __UpperCamelCase = -torch.inf # -inf = log(0) return rv

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 = { '''bert-base-uncased''': '''https://huggingface.co/bert-base-uncased/resolve/main/config.json''', '''bert-large-uncased''': '''https://huggingface.co/bert-large-uncased/resolve/main/config.json''', '''bert-base-cased''': '''https://huggingface.co/bert-base-cased/resolve/main/config.json''', '''bert-large-cased''': '''https://huggingface.co/bert-large-cased/resolve/main/config.json''', '''bert-base-multilingual-uncased''': '''https://huggingface.co/bert-base-multilingual-uncased/resolve/main/config.json''', '''bert-base-multilingual-cased''': '''https://huggingface.co/bert-base-multilingual-cased/resolve/main/config.json''', '''bert-base-chinese''': '''https://huggingface.co/bert-base-chinese/resolve/main/config.json''', '''bert-base-german-cased''': '''https://huggingface.co/bert-base-german-cased/resolve/main/config.json''', '''bert-large-uncased-whole-word-masking''': ( '''https://huggingface.co/bert-large-uncased-whole-word-masking/resolve/main/config.json''' ), '''bert-large-cased-whole-word-masking''': ( '''https://huggingface.co/bert-large-cased-whole-word-masking/resolve/main/config.json''' ), '''bert-large-uncased-whole-word-masking-finetuned-squad''': ( '''https://huggingface.co/bert-large-uncased-whole-word-masking-finetuned-squad/resolve/main/config.json''' ), '''bert-large-cased-whole-word-masking-finetuned-squad''': ( '''https://huggingface.co/bert-large-cased-whole-word-masking-finetuned-squad/resolve/main/config.json''' ), '''bert-base-cased-finetuned-mrpc''': '''https://huggingface.co/bert-base-cased-finetuned-mrpc/resolve/main/config.json''', '''bert-base-german-dbmdz-cased''': '''https://huggingface.co/bert-base-german-dbmdz-cased/resolve/main/config.json''', '''bert-base-german-dbmdz-uncased''': '''https://huggingface.co/bert-base-german-dbmdz-uncased/resolve/main/config.json''', '''cl-tohoku/bert-base-japanese''': '''https://huggingface.co/cl-tohoku/bert-base-japanese/resolve/main/config.json''', '''cl-tohoku/bert-base-japanese-whole-word-masking''': ( '''https://huggingface.co/cl-tohoku/bert-base-japanese-whole-word-masking/resolve/main/config.json''' ), '''cl-tohoku/bert-base-japanese-char''': ( '''https://huggingface.co/cl-tohoku/bert-base-japanese-char/resolve/main/config.json''' ), '''cl-tohoku/bert-base-japanese-char-whole-word-masking''': ( '''https://huggingface.co/cl-tohoku/bert-base-japanese-char-whole-word-masking/resolve/main/config.json''' ), '''TurkuNLP/bert-base-finnish-cased-v1''': ( '''https://huggingface.co/TurkuNLP/bert-base-finnish-cased-v1/resolve/main/config.json''' ), '''TurkuNLP/bert-base-finnish-uncased-v1''': ( '''https://huggingface.co/TurkuNLP/bert-base-finnish-uncased-v1/resolve/main/config.json''' ), '''wietsedv/bert-base-dutch-cased''': '''https://huggingface.co/wietsedv/bert-base-dutch-cased/resolve/main/config.json''', # See all BERT models at https://huggingface.co/models?filter=bert } class __lowerCamelCase (_a ): _lowercase = """bert""" def __init__( self: Any,A_: Dict=3_0522,A_: Optional[Any]=768,A_: Union[str, Any]=12,A_: List[Any]=12,A_: Optional[int]=3072,A_: Union[str, Any]="gelu",A_: List[str]=0.1,A_: Dict=0.1,A_: Optional[int]=512,A_: Optional[Any]=2,A_: Union[str, Any]=0.0_2,A_: List[Any]=1E-12,A_: Optional[int]=0,A_: List[Any]="absolute",A_: str=True,A_: Union[str, Any]=None,**A_: int,): '''simple docstring''' super().__init__(pad_token_id=A_,**A_ ) __UpperCamelCase = vocab_size __UpperCamelCase = hidden_size __UpperCamelCase = num_hidden_layers __UpperCamelCase = num_attention_heads __UpperCamelCase = hidden_act __UpperCamelCase = intermediate_size __UpperCamelCase = hidden_dropout_prob __UpperCamelCase = attention_probs_dropout_prob __UpperCamelCase = max_position_embeddings __UpperCamelCase = type_vocab_size __UpperCamelCase = initializer_range __UpperCamelCase = layer_norm_eps __UpperCamelCase = position_embedding_type __UpperCamelCase = use_cache __UpperCamelCase = classifier_dropout class __lowerCamelCase (_a ): @property def snake_case_ ( self: Optional[int] ): '''simple docstring''' if self.task == "multiple-choice": __UpperCamelCase = {0: 'batch', 1: 'choice', 2: 'sequence'} else: __UpperCamelCase = {0: 'batch', 1: 'sequence'} return OrderedDict( [ ('input_ids', dynamic_axis), ('attention_mask', dynamic_axis), ('token_type_ids', dynamic_axis), ] )

import importlib import json import os import sys import tempfile import unittest from pathlib import Path import transformers import transformers.models.auto from transformers.models.auto.configuration_auto import CONFIG_MAPPING, AutoConfig from transformers.models.bert.configuration_bert import BertConfig from transformers.models.roberta.configuration_roberta import RobertaConfig from transformers.testing_utils import DUMMY_UNKNOWN_IDENTIFIER, get_tests_dir sys.path.append(str(Path(__file__).parent.parent.parent.parent / '''utils''')) from test_module.custom_configuration import CustomConfig # noqa E402 __snake_case = get_tests_dir('''fixtures/dummy-config.json''') class __lowerCamelCase (unittest.TestCase ): def snake_case_ ( self: Any ): '''simple docstring''' __UpperCamelCase = 0 def snake_case_ ( self: str ): '''simple docstring''' self.assertIsNotNone(transformers.models.auto.__spec__ ) self.assertIsNotNone(importlib.util.find_spec('transformers.models.auto' ) ) def snake_case_ ( self: List[Any] ): '''simple docstring''' __UpperCamelCase = AutoConfig.from_pretrained('bert-base-uncased' ) self.assertIsInstance(A_,A_ ) def snake_case_ ( self: Any ): '''simple docstring''' __UpperCamelCase = AutoConfig.from_pretrained(A_ ) self.assertIsInstance(A_,A_ ) def snake_case_ ( self: Any ): '''simple docstring''' __UpperCamelCase = AutoConfig.from_pretrained(A_ ) self.assertIsInstance(A_,A_ ) def snake_case_ ( self: Optional[int] ): '''simple docstring''' __UpperCamelCase = AutoConfig.for_model('roberta' ) self.assertIsInstance(A_,A_ ) def snake_case_ ( self: Union[str, Any] ): '''simple docstring''' with tempfile.TemporaryDirectory() as tmp_dir: # This model name contains bert and roberta, but roberta ends up being picked. __UpperCamelCase = os.path.join(A_,'fake-roberta' ) os.makedirs(A_,exist_ok=A_ ) with open(os.path.join(A_,'config.json' ),'w' ) as f: f.write(json.dumps({} ) ) __UpperCamelCase = AutoConfig.from_pretrained(A_ ) self.assertEqual(type(A_ ),A_ ) def snake_case_ ( self: List[str] ): '''simple docstring''' try: AutoConfig.register('custom',A_ ) # Wrong model type will raise an error with self.assertRaises(A_ ): AutoConfig.register('model',A_ ) # Trying to register something existing in the Transformers library will raise an error with self.assertRaises(A_ ): AutoConfig.register('bert',A_ ) # Now that the config is registered, it can be used as any other config with the auto-API __UpperCamelCase = CustomConfig() with tempfile.TemporaryDirectory() as tmp_dir: config.save_pretrained(A_ ) __UpperCamelCase = AutoConfig.from_pretrained(A_ ) self.assertIsInstance(A_,A_ ) finally: if "custom" in CONFIG_MAPPING._extra_content: del CONFIG_MAPPING._extra_content["custom"] def snake_case_ ( self: Dict ): '''simple docstring''' with self.assertRaisesRegex( A_,'bert-base is not a local folder and is not a valid model identifier' ): __UpperCamelCase = AutoConfig.from_pretrained('bert-base' ) def snake_case_ ( self: Dict ): '''simple docstring''' with self.assertRaisesRegex( A_,r'aaaaaa is not a valid git identifier \(branch name, tag name or commit id\)' ): __UpperCamelCase = AutoConfig.from_pretrained(A_,revision='aaaaaa' ) def snake_case_ ( self: Dict ): '''simple docstring''' with self.assertRaisesRegex( A_,'hf-internal-testing/no-config-test-repo does not appear to have a file named config.json.',): __UpperCamelCase = AutoConfig.from_pretrained('hf-internal-testing/no-config-test-repo' ) def snake_case_ ( self: List[str] ): '''simple docstring''' with self.assertRaises(A_ ): __UpperCamelCase = AutoConfig.from_pretrained('hf-internal-testing/test_dynamic_model' ) # If remote code is disabled, we can't load this config. with self.assertRaises(A_ ): __UpperCamelCase = AutoConfig.from_pretrained('hf-internal-testing/test_dynamic_model',trust_remote_code=A_ ) __UpperCamelCase = AutoConfig.from_pretrained('hf-internal-testing/test_dynamic_model',trust_remote_code=A_ ) self.assertEqual(config.__class__.__name__,'NewModelConfig' ) # Test config can be reloaded. with tempfile.TemporaryDirectory() as tmp_dir: config.save_pretrained(A_ ) __UpperCamelCase = AutoConfig.from_pretrained(A_,trust_remote_code=A_ ) self.assertEqual(reloaded_config.__class__.__name__,'NewModelConfig' ) def snake_case_ ( self: str ): '''simple docstring''' class __lowerCamelCase (_a ): _lowercase = """new-model""" try: AutoConfig.register('new-model',A_ ) # If remote code is not set, the default is to use local __UpperCamelCase = AutoConfig.from_pretrained('hf-internal-testing/test_dynamic_model' ) self.assertEqual(config.__class__.__name__,'NewModelConfigLocal' ) # If remote code is disabled, we load the local one. __UpperCamelCase = AutoConfig.from_pretrained('hf-internal-testing/test_dynamic_model',trust_remote_code=A_ ) self.assertEqual(config.__class__.__name__,'NewModelConfigLocal' ) # If remote is enabled, we load from the Hub __UpperCamelCase = AutoConfig.from_pretrained('hf-internal-testing/test_dynamic_model',trust_remote_code=A_ ) self.assertEqual(config.__class__.__name__,'NewModelConfig' ) finally: if "new-model" in CONFIG_MAPPING._extra_content: del CONFIG_MAPPING._extra_content["new-model"]

def _A ( _lowercase ) -> int: """simple docstring""" assert column_title.isupper() __UpperCamelCase = 0 __UpperCamelCase = len(_lowercase ) - 1 __UpperCamelCase = 0 while index >= 0: __UpperCamelCase = (ord(column_title[index] ) - 64) * pow(26 , _lowercase ) answer += value power += 1 index -= 1 return answer if __name__ == "__main__": from doctest import testmod testmod()

def _A ( _lowercase ) -> int: """simple docstring""" __UpperCamelCase = hex_num.strip() if not hex_num: raise ValueError('No value was passed to the function' ) __UpperCamelCase = hex_num[0] == '-' if is_negative: __UpperCamelCase = hex_num[1:] try: __UpperCamelCase = int(_lowercase , 16 ) except ValueError: raise ValueError('Invalid value was passed to the function' ) __UpperCamelCase = '' while int_num > 0: __UpperCamelCase = str(int_num % 2 ) + bin_str int_num >>= 1 return int(('-' + bin_str) if is_negative else bin_str ) if __name__ == "__main__": import doctest doctest.testmod()

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 from lavis.models import load_model_and_preprocess from PIL import Image from transformers import ( AutoTokenizer, BlipaConfig, BlipaForConditionalGeneration, BlipaProcessor, BlipaVisionConfig, BlipImageProcessor, OPTConfig, TaConfig, ) from transformers.utils.constants import OPENAI_CLIP_MEAN, OPENAI_CLIP_STD def _A ( ) -> int: """simple docstring""" __UpperCamelCase = 'https://storage.googleapis.com/sfr-vision-language-research/LAVIS/assets/merlion.png' __UpperCamelCase = Image.open(requests.get(_lowercase , stream=_lowercase ).raw ).convert('RGB' ) return image def _A ( _lowercase ) -> int: """simple docstring""" __UpperCamelCase = [] # 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.layernorm.weight') ) rename_keys.append(('Qformer.bert.embeddings.LayerNorm.bias', 'qformer.layernorm.bias') ) # fmt: on return rename_keys def _A ( _lowercase , _lowercase , _lowercase ) -> Optional[int]: """simple docstring""" __UpperCamelCase = dct.pop(_lowercase ) __UpperCamelCase = val def _A ( _lowercase , _lowercase ) -> int: """simple docstring""" for i in range(config.vision_config.num_hidden_layers ): # read in original q and v biases __UpperCamelCase = state_dict.pop(f'''visual_encoder.blocks.{i}.attn.q_bias''' ) __UpperCamelCase = state_dict.pop(f'''visual_encoder.blocks.{i}.attn.v_bias''' ) # next, set bias in the state dict __UpperCamelCase = torch.cat((q_bias, torch.zeros_like(_lowercase , requires_grad=_lowercase ), v_bias) ) __UpperCamelCase = qkv_bias def _A ( _lowercase , _lowercase ) -> Any: """simple docstring""" __UpperCamelCase = 3_64 if 'coco' in model_name else 2_24 __UpperCamelCase = BlipaVisionConfig(image_size=_lowercase ).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 "opt-2.7b" in model_name: __UpperCamelCase = OPTConfig.from_pretrained('facebook/opt-2.7b' , eos_token_id=_lowercase ).to_dict() elif "opt-6.7b" in model_name: __UpperCamelCase = OPTConfig.from_pretrained('facebook/opt-6.7b' , eos_token_id=_lowercase ).to_dict() elif "t5-xl" in model_name: __UpperCamelCase = TaConfig.from_pretrained('google/flan-t5-xl' , dense_act_fn='gelu' , bos_token_id=1 ).to_dict() elif "t5-xxl" in model_name: __UpperCamelCase = TaConfig.from_pretrained('google/flan-t5-xxl' , dense_act_fn='gelu' , bos_token_id=1 ).to_dict() __UpperCamelCase = BlipaConfig(vision_config=_lowercase , text_config=_lowercase ) return config, image_size @torch.no_grad() def _A ( _lowercase , _lowercase=None , _lowercase=False ) -> Union[str, Any]: """simple docstring""" __UpperCamelCase = ( AutoTokenizer.from_pretrained('facebook/opt-2.7b' ) if 'opt' in model_name else AutoTokenizer.from_pretrained('google/flan-t5-xl' ) ) __UpperCamelCase = tokenizer('\n' , add_special_tokens=_lowercase ).input_ids[0] __UpperCamelCase, __UpperCamelCase = get_blipa_config(_lowercase , eos_token_id=_lowercase ) __UpperCamelCase = BlipaForConditionalGeneration(_lowercase ).eval() __UpperCamelCase = { 'blip2-opt-2.7b': ('blip2_opt', 'pretrain_opt2.7b'), 'blip2-opt-6.7b': ('blip2_opt', 'pretrain_opt6.7b'), 'blip2-opt-2.7b-coco': ('blip2_opt', 'caption_coco_opt2.7b'), 'blip2-opt-6.7b-coco': ('blip2_opt', 'caption_coco_opt6.7b'), 'blip2-flan-t5-xl': ('blip2_t5', 'pretrain_flant5xl'), 'blip2-flan-t5-xl-coco': ('blip2_t5', 'caption_coco_flant5xl'), 'blip2-flan-t5-xxl': ('blip2_t5', 'pretrain_flant5xxl'), } __UpperCamelCase, __UpperCamelCase = model_name_to_original[model_name] # load original model print('Loading original model...' ) __UpperCamelCase = 'cuda' if torch.cuda.is_available() else 'cpu' __UpperCamelCase, __UpperCamelCase, __UpperCamelCase = load_model_and_preprocess( name=_lowercase , model_type=_lowercase , is_eval=_lowercase , device=_lowercase ) original_model.eval() print('Done!' ) # update state dict keys __UpperCamelCase = original_model.state_dict() __UpperCamelCase = create_rename_keys(_lowercase ) for src, dest in rename_keys: rename_key(_lowercase , _lowercase , _lowercase ) # some keys can be renamed efficiently for key, val in state_dict.copy().items(): __UpperCamelCase = state_dict.pop(_lowercase ) if key.startswith('Qformer.bert' ): __UpperCamelCase = key.replace('Qformer.bert' , 'qformer' ) if "attention.self" in key: __UpperCamelCase = key.replace('self' , 'attention' ) if "opt_proj" in key: __UpperCamelCase = key.replace('opt_proj' , 'language_projection' ) if "t5_proj" in key: __UpperCamelCase = key.replace('t5_proj' , 'language_projection' ) if key.startswith('opt' ): __UpperCamelCase = key.replace('opt' , 'language' ) if key.startswith('t5' ): __UpperCamelCase = key.replace('t5' , 'language' ) __UpperCamelCase = val # read in qv biases read_in_q_v_bias(_lowercase , _lowercase ) __UpperCamelCase, __UpperCamelCase = hf_model.load_state_dict(_lowercase , strict=_lowercase ) assert len(_lowercase ) == 0 assert unexpected_keys == ["qformer.embeddings.position_ids"] __UpperCamelCase = load_demo_image() __UpperCamelCase = vis_processors['eval'](_lowercase ).unsqueeze(0 ).to(_lowercase ) __UpperCamelCase = tokenizer(['\n'] , return_tensors='pt' ).input_ids.to(_lowercase ) # create processor __UpperCamelCase = BlipImageProcessor( size={'height': image_size, 'width': image_size} , image_mean=_lowercase , image_std=_lowercase ) __UpperCamelCase = BlipaProcessor(image_processor=_lowercase , tokenizer=_lowercase ) __UpperCamelCase = processor(images=_lowercase , return_tensors='pt' ).pixel_values.to(_lowercase ) # make sure processor creates exact same pixel values assert torch.allclose(_lowercase , _lowercase ) original_model.to(_lowercase ) hf_model.to(_lowercase ) with torch.no_grad(): if "opt" in model_name: __UpperCamelCase = original_model({'image': original_pixel_values, 'text_input': ['']} ).logits __UpperCamelCase = hf_model(_lowercase , _lowercase ).logits else: __UpperCamelCase = original_model( {'image': original_pixel_values, 'text_input': ['\n'], 'text_output': ['\n']} ).logits __UpperCamelCase = input_ids.masked_fill(input_ids == tokenizer.pad_token_id , -1_00 ) __UpperCamelCase = hf_model(_lowercase , _lowercase , labels=_lowercase ).logits assert original_logits.shape == logits.shape print('First values of original logits:' , original_logits[0, :3, :3] ) print('First values of HF logits:' , logits[0, :3, :3] ) # assert values if model_name == "blip2-flan-t5-xl": __UpperCamelCase = torch.tensor( [[-41.58_50, -4.44_40, -8.99_22], [-47.43_22, -5.91_43, -1.73_40]] , device=_lowercase ) assert torch.allclose(logits[0, :3, :3] , _lowercase , atol=1e-4 ) elif model_name == "blip2-flan-t5-xl-coco": __UpperCamelCase = torch.tensor( [[-57.01_09, -9.89_67, -12.62_80], [-68.65_78, -12.71_91, -10.50_65]] , device=_lowercase ) else: # cast to same type __UpperCamelCase = logits.dtype assert torch.allclose(original_logits.to(_lowercase ) , _lowercase , atol=1e-2 ) print('Looks ok!' ) print('Generating a caption...' ) __UpperCamelCase = '' __UpperCamelCase = tokenizer(_lowercase , return_tensors='pt' ).input_ids.to(_lowercase ) __UpperCamelCase = original_model.generate({'image': original_pixel_values} ) __UpperCamelCase = hf_model.generate( _lowercase , _lowercase , do_sample=_lowercase , num_beams=5 , max_length=30 , min_length=1 , top_p=0.9 , repetition_penalty=1.0 , length_penalty=1.0 , temperature=1 , ) print('Original generation:' , _lowercase ) __UpperCamelCase = input_ids.shape[1] __UpperCamelCase = processor.batch_decode(outputs[:, prompt_length:] , skip_special_tokens=_lowercase ) __UpperCamelCase = [text.strip() for text in output_text] print('HF generation:' , _lowercase ) if pytorch_dump_folder_path is not None: processor.save_pretrained(_lowercase ) hf_model.save_pretrained(_lowercase ) if push_to_hub: processor.push_to_hub(f'''nielsr/{model_name}''' ) hf_model.push_to_hub(f'''nielsr/{model_name}''' ) if __name__ == "__main__": __snake_case = argparse.ArgumentParser() __snake_case = [ '''blip2-opt-2.7b''', '''blip2-opt-6.7b''', '''blip2-opt-2.7b-coco''', '''blip2-opt-6.7b-coco''', '''blip2-flan-t5-xl''', '''blip2-flan-t5-xl-coco''', '''blip2-flan-t5-xxl''', ] parser.add_argument( '''--model_name''', default='''blip2-opt-2.7b''', 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)

import warnings from ...processing_utils import ProcessorMixin from ...tokenization_utils_base import BatchEncoding class __lowerCamelCase (_a ): _lowercase = ["""image_processor""", """tokenizer"""] _lowercase = """CLIPImageProcessor""" _lowercase = ("""XLMRobertaTokenizer""", """XLMRobertaTokenizerFast""") def __init__( self: List[str],A_: int=None,A_: str=None,**A_: Union[str, Any] ): '''simple docstring''' __UpperCamelCase = None if "feature_extractor" in kwargs: warnings.warn( 'The `feature_extractor` argument is deprecated and will be removed in v5, use `image_processor`' ' instead.',A_,) __UpperCamelCase = kwargs.pop('feature_extractor' ) __UpperCamelCase = image_processor if image_processor is not None else feature_extractor if image_processor is None: raise ValueError('You need to specify an `image_processor`.' ) if tokenizer is None: raise ValueError('You need to specify a `tokenizer`.' ) super().__init__(A_,A_ ) def __call__( self: Tuple,A_: Any=None,A_: str=None,A_: List[Any]=None,**A_: Tuple ): '''simple docstring''' if text is None and images is None: raise ValueError('You have to specify either text or images. Both cannot be none.' ) if text is not None: __UpperCamelCase = self.tokenizer(A_,return_tensors=A_,**A_ ) if images is not None: __UpperCamelCase = self.image_processor(A_,return_tensors=A_,**A_ ) if text is not None and images is not None: __UpperCamelCase = image_features.pixel_values return encoding elif text is not None: return encoding else: return BatchEncoding(data=dict(**A_ ),tensor_type=A_ ) def snake_case_ ( self: int,*A_: Dict,**A_: int ): '''simple docstring''' return self.tokenizer.batch_decode(*A_,**A_ ) def snake_case_ ( self: int,*A_: Union[str, Any],**A_: str ): '''simple docstring''' return self.tokenizer.decode(*A_,**A_ ) @property def snake_case_ ( self: Dict ): '''simple docstring''' __UpperCamelCase = self.tokenizer.model_input_names __UpperCamelCase = self.image_processor.model_input_names return list(dict.fromkeys(tokenizer_input_names + image_processor_input_names ) )

import logging import os import sys from dataclasses import dataclass, field from importlib import import_module from typing import Dict, List, Optional, Tuple import numpy as np from seqeval.metrics import accuracy_score, fa_score, precision_score, recall_score from torch import nn from utils_ner import Split, TokenClassificationDataset, TokenClassificationTask import transformers from transformers import ( AutoConfig, AutoModelForTokenClassification, AutoTokenizer, DataCollatorWithPadding, EvalPrediction, HfArgumentParser, Trainer, TrainingArguments, set_seed, ) from transformers.trainer_utils import is_main_process __snake_case = logging.getLogger(__name__) @dataclass class __lowerCamelCase : _lowercase = field( metadata={"""help""": """Path to pretrained model or model identifier from huggingface.co/models"""} ) _lowercase = field( default=_a , metadata={"""help""": """Pretrained config name or path if not the same as model_name"""} ) _lowercase = field( default="""NER""" , metadata={"""help""": """Task type to fine tune in training (e.g. NER, POS, etc)"""} ) _lowercase = field( default=_a , metadata={"""help""": """Pretrained tokenizer name or path if not the same as model_name"""} ) _lowercase = field(default=_a , metadata={"""help""": """Set this flag to use fast tokenization."""} ) # If you want to tweak more attributes on your tokenizer, you should do it in a distinct script, # or just modify its tokenizer_config.json. _lowercase = field( default=_a , metadata={"""help""": """Where do you want to store the pretrained models downloaded from huggingface.co"""} , ) @dataclass class __lowerCamelCase : _lowercase = field( metadata={"""help""": """The input data dir. Should contain the .txt files for a CoNLL-2003-formatted task."""} ) _lowercase = field( default=_a , metadata={"""help""": """Path to a file containing all labels. If not specified, CoNLL-2003 labels are used."""} , ) _lowercase = field( default=128 , metadata={ """help""": ( """The maximum total input sequence length after tokenization. Sequences longer """ """than this will be truncated, sequences shorter will be padded.""" ) } , ) _lowercase = field( default=_a , metadata={"""help""": """Overwrite the cached training and evaluation sets"""} ) def _A ( ) -> str: """simple docstring""" __UpperCamelCase = HfArgumentParser((ModelArguments, DataTrainingArguments, TrainingArguments) ) if len(sys.argv ) == 2 and sys.argv[1].endswith('.json' ): # If we pass only one argument to the script and it's the path to a json file, # let's parse it to get our arguments. __UpperCamelCase, __UpperCamelCase, __UpperCamelCase = parser.parse_json_file(json_file=os.path.abspath(sys.argv[1] ) ) else: __UpperCamelCase, __UpperCamelCase, __UpperCamelCase = parser.parse_args_into_dataclasses() if ( os.path.exists(training_args.output_dir ) and os.listdir(training_args.output_dir ) and training_args.do_train and not training_args.overwrite_output_dir ): raise ValueError( f'''Output directory ({training_args.output_dir}) already exists and is not empty. Use''' ' --overwrite_output_dir to overcome.' ) __UpperCamelCase = import_module('tasks' ) try: __UpperCamelCase = getattr(_lowercase , model_args.task_type ) __UpperCamelCase = token_classification_task_clazz() except AttributeError: raise ValueError( f'''Task {model_args.task_type} needs to be defined as a TokenClassificationTask subclass in {module}. ''' f'''Available tasks classes are: {TokenClassificationTask.__subclasses__()}''' ) # Setup logging logging.basicConfig( format='%(asctime)s - %(levelname)s - %(name)s - %(message)s' , datefmt='%m/%d/%Y %H:%M:%S' , level=logging.INFO if training_args.local_rank in [-1, 0] else logging.WARN , ) logger.warning( 'Process rank: %s, device: %s, n_gpu: %s, distributed training: %s, 16-bits training: %s' , training_args.local_rank , training_args.device , training_args.n_gpu , bool(training_args.local_rank != -1 ) , training_args.fpaa , ) # Set the verbosity to info of the Transformers logger (on main process only): if is_main_process(training_args.local_rank ): transformers.utils.logging.set_verbosity_info() transformers.utils.logging.enable_default_handler() transformers.utils.logging.enable_explicit_format() logger.info('Training/evaluation parameters %s' , _lowercase ) # Set seed set_seed(training_args.seed ) # Prepare CONLL-2003 task __UpperCamelCase = token_classification_task.get_labels(data_args.labels ) __UpperCamelCase = dict(enumerate(_lowercase ) ) __UpperCamelCase = len(_lowercase ) # Load pretrained model and tokenizer # # Distributed training: # The .from_pretrained methods guarantee that only one local process can concurrently # download model & vocab. __UpperCamelCase = AutoConfig.from_pretrained( model_args.config_name if model_args.config_name else model_args.model_name_or_path , num_labels=_lowercase , idalabel=_lowercase , labelaid={label: i for i, label in enumerate(_lowercase )} , cache_dir=model_args.cache_dir , ) __UpperCamelCase = AutoTokenizer.from_pretrained( model_args.tokenizer_name if model_args.tokenizer_name else model_args.model_name_or_path , cache_dir=model_args.cache_dir , use_fast=model_args.use_fast , ) __UpperCamelCase = AutoModelForTokenClassification.from_pretrained( model_args.model_name_or_path , from_tf=bool('.ckpt' in model_args.model_name_or_path ) , config=_lowercase , cache_dir=model_args.cache_dir , ) # Get datasets __UpperCamelCase = ( TokenClassificationDataset( token_classification_task=_lowercase , data_dir=data_args.data_dir , tokenizer=_lowercase , labels=_lowercase , model_type=config.model_type , max_seq_length=data_args.max_seq_length , overwrite_cache=data_args.overwrite_cache , mode=Split.train , ) if training_args.do_train else None ) __UpperCamelCase = ( TokenClassificationDataset( token_classification_task=_lowercase , data_dir=data_args.data_dir , tokenizer=_lowercase , labels=_lowercase , model_type=config.model_type , max_seq_length=data_args.max_seq_length , overwrite_cache=data_args.overwrite_cache , mode=Split.dev , ) if training_args.do_eval else None ) def align_predictions(_lowercase , _lowercase ) -> Tuple[List[int], List[int]]: __UpperCamelCase = np.argmax(_lowercase , axis=2 ) __UpperCamelCase, __UpperCamelCase = preds.shape __UpperCamelCase = [[] for _ in range(_lowercase )] __UpperCamelCase = [[] for _ in range(_lowercase )] for i in range(_lowercase ): for j in range(_lowercase ): if label_ids[i, j] != nn.CrossEntropyLoss().ignore_index: out_label_list[i].append(label_map[label_ids[i][j]] ) preds_list[i].append(label_map[preds[i][j]] ) return preds_list, out_label_list def compute_metrics(_lowercase ) -> Dict: __UpperCamelCase, __UpperCamelCase = align_predictions(p.predictions , p.label_ids ) return { "accuracy_score": accuracy_score(_lowercase , _lowercase ), "precision": precision_score(_lowercase , _lowercase ), "recall": recall_score(_lowercase , _lowercase ), "f1": fa_score(_lowercase , _lowercase ), } # Data collator __UpperCamelCase = DataCollatorWithPadding(_lowercase , pad_to_multiple_of=8 ) if training_args.fpaa else None # Initialize our Trainer __UpperCamelCase = Trainer( model=_lowercase , args=_lowercase , train_dataset=_lowercase , eval_dataset=_lowercase , compute_metrics=_lowercase , data_collator=_lowercase , ) # Training if training_args.do_train: trainer.train( model_path=model_args.model_name_or_path if os.path.isdir(model_args.model_name_or_path ) else None ) trainer.save_model() # For convenience, we also re-save the tokenizer to the same directory, # so that you can share your model easily on huggingface.co/models =) if trainer.is_world_process_zero(): tokenizer.save_pretrained(training_args.output_dir ) # Evaluation __UpperCamelCase = {} if training_args.do_eval: logger.info('*** Evaluate ***' ) __UpperCamelCase = trainer.evaluate() __UpperCamelCase = os.path.join(training_args.output_dir , 'eval_results.txt' ) if trainer.is_world_process_zero(): with open(_lowercase , 'w' ) as writer: logger.info('***** Eval results *****' ) for key, value in result.items(): logger.info(' %s = %s' , _lowercase , _lowercase ) writer.write('%s = %s\n' % (key, value) ) results.update(_lowercase ) # Predict if training_args.do_predict: __UpperCamelCase = TokenClassificationDataset( token_classification_task=_lowercase , data_dir=data_args.data_dir , tokenizer=_lowercase , labels=_lowercase , model_type=config.model_type , max_seq_length=data_args.max_seq_length , overwrite_cache=data_args.overwrite_cache , mode=Split.test , ) __UpperCamelCase, __UpperCamelCase, __UpperCamelCase = trainer.predict(_lowercase ) __UpperCamelCase, __UpperCamelCase = align_predictions(_lowercase , _lowercase ) __UpperCamelCase = os.path.join(training_args.output_dir , 'test_results.txt' ) if trainer.is_world_process_zero(): with open(_lowercase , 'w' ) as writer: for key, value in metrics.items(): logger.info(' %s = %s' , _lowercase , _lowercase ) writer.write('%s = %s\n' % (key, value) ) # Save predictions __UpperCamelCase = os.path.join(training_args.output_dir , 'test_predictions.txt' ) if trainer.is_world_process_zero(): with open(_lowercase , 'w' ) as writer: with open(os.path.join(data_args.data_dir , 'test.txt' ) , 'r' ) as f: token_classification_task.write_predictions_to_file(_lowercase , _lowercase , _lowercase ) return results def _A ( _lowercase ) -> Dict: """simple docstring""" main() if __name__ == "__main__": main()

from ...processing_utils import ProcessorMixin from ...tokenization_utils_base import BatchEncoding class __lowerCamelCase (_a ): _lowercase = ["""image_processor""", """tokenizer"""] _lowercase = """AutoImageProcessor""" _lowercase = """AutoTokenizer""" def __init__( self: int,A_: Any,A_: Tuple ): '''simple docstring''' super().__init__(A_,A_ ) __UpperCamelCase = self.image_processor def __call__( self: str,A_: Union[str, Any]=None,A_: Optional[int]=None,A_: Optional[int]=None,**A_: Union[str, Any] ): '''simple docstring''' if text is None and images is None: raise ValueError('You have to specify either text or images. Both cannot be none.' ) if text is not None: __UpperCamelCase = self.tokenizer(A_,return_tensors=A_,**A_ ) if images is not None: __UpperCamelCase = self.image_processor(A_,return_tensors=A_,**A_ ) if text is not None and images is not None: __UpperCamelCase = image_features.pixel_values return encoding elif text is not None: return encoding else: return BatchEncoding(data=dict(**A_ ),tensor_type=A_ ) def snake_case_ ( self: Dict,*A_: Optional[Any],**A_: Optional[int] ): '''simple docstring''' return self.tokenizer.batch_decode(*A_,**A_ ) def snake_case_ ( self: int,*A_: Union[str, Any],**A_: Tuple ): '''simple docstring''' return self.tokenizer.decode(*A_,**A_ ) @property def snake_case_ ( self: int ): '''simple docstring''' return ["input_ids", "attention_mask", "pixel_values"]

# # This a `torch.distributed` diagnostics script that checks that all GPUs in the cluster (one or # many nodes) can talk to each other via nccl and allocate gpu memory. # # To run first adjust the number of processes and nodes: # # python -m torch.distributed.run --nproc_per_node 2 --nnodes 1 torch-distributed-gpu-test.py # # You may need to add --master_addr $MASTER_ADDR --master_port $MASTER_PORT if using a custom addr:port # # You can also use the rdzv API: --rdzv_endpoint $MASTER_ADDR:$MASTER_PORT --rdzv_backend c10d # # use torch.distributed.launch instead of torch.distributed.run for torch < 1.9 # # If you get a hanging in `barrier` calls you have some network issues, you may try to debug this with: # # NCCL_DEBUG=INFO python -m torch.distributed.run --nproc_per_node 2 --nnodes 1 torch-distributed-gpu-test.py # # which should tell you what's going on behind the scenes. # # # This script can be run via `srun` in the SLURM environment as well. Here is a SLURM script that # runs on 2 nodes of 4 gpus per node: # # #SBATCH --job-name=test-nodes # name # #SBATCH --nodes=2 # nodes # #SBATCH --ntasks-per-node=1 # crucial - only 1 task per dist per node! # #SBATCH --cpus-per-task=10 # number of cores per tasks # #SBATCH --gres=gpu:4 # number of gpus # #SBATCH --time 0:05:00 # maximum execution time (HH:MM:SS) # #SBATCH --output=%x-%j.out # output file name # # GPUS_PER_NODE=4 # MASTER_ADDR=$(scontrol show hostnames $SLURM_JOB_NODELIST | head -n 1) # MASTER_PORT=6000 # # srun --jobid $SLURM_JOBID bash -c 'python -m torch.distributed.run \ # --nproc_per_node $GPUS_PER_NODE --nnodes $SLURM_NNODES --node_rank $SLURM_PROCID \ # --master_addr $MASTER_ADDR --master_port $MASTER_PORT \ # torch-distributed-gpu-test.py' # import fcntl import os import socket import torch import torch.distributed as dist def _A ( *_lowercase ) -> Tuple: """simple docstring""" with open(_lowercase , 'r' ) as fh: fcntl.flock(_lowercase , fcntl.LOCK_EX ) try: print(*_lowercase ) finally: fcntl.flock(_lowercase , fcntl.LOCK_UN ) __snake_case = int(os.environ['''LOCAL_RANK''']) torch.cuda.set_device(local_rank) __snake_case = torch.device('''cuda''', local_rank) __snake_case = socket.gethostname() __snake_case = f"""[{hostname}-{local_rank}]""" try: # test distributed dist.init_process_group('''nccl''') dist.all_reduce(torch.ones(1).to(device), op=dist.ReduceOp.SUM) dist.barrier() # test cuda is available and can allocate memory torch.cuda.is_available() torch.ones(1).cuda(local_rank) # global rank __snake_case = dist.get_rank() __snake_case = dist.get_world_size() printflock(f"""{gpu} is OK (global rank: {rank}/{world_size})""") dist.barrier() if rank == 0: printflock(f"""pt={torch.__version__}, cuda={torch.version.cuda}, nccl={torch.cuda.nccl.version()}""") except Exception: printflock(f"""{gpu} is broken""") raise

from __future__ import annotations class __lowerCamelCase : def __init__( self: Optional[int],A_: str,A_: str ): '''simple docstring''' __UpperCamelCase, __UpperCamelCase = text, pattern __UpperCamelCase, __UpperCamelCase = len(A_ ), len(A_ ) def snake_case_ ( self: Tuple,A_: str ): '''simple docstring''' for i in range(self.patLen - 1,-1,-1 ): if char == self.pattern[i]: return i return -1 def snake_case_ ( self: List[str],A_: int ): '''simple docstring''' for i in range(self.patLen - 1,-1,-1 ): if self.pattern[i] != self.text[current_pos + i]: return current_pos + i return -1 def snake_case_ ( self: Tuple ): '''simple docstring''' __UpperCamelCase = [] for i in range(self.textLen - self.patLen + 1 ): __UpperCamelCase = self.mismatch_in_text(A_ ) if mismatch_index == -1: positions.append(A_ ) else: __UpperCamelCase = self.match_in_pattern(self.text[mismatch_index] ) __UpperCamelCase = ( mismatch_index - match_index ) # shifting index lgtm [py/multiple-definition] return positions __snake_case = '''ABAABA''' __snake_case = '''AB''' __snake_case = BoyerMooreSearch(text, pattern) __snake_case = bms.bad_character_heuristic() if len(positions) == 0: print('''No match found''') else: print('''Pattern found in following positions: ''') print(positions)

import pytest import datasets # Import fixture modules as plugins __snake_case = ['''tests.fixtures.files''', '''tests.fixtures.hub''', '''tests.fixtures.fsspec'''] def _A ( _lowercase , _lowercase ) -> Tuple: """simple docstring""" for item in items: if any(marker in item.keywords for marker in ['integration', 'unit'] ): continue item.add_marker(pytest.mark.unit ) def _A ( _lowercase ) -> str: """simple docstring""" config.addinivalue_line('markers' , 'torchaudio_latest: mark test to run with torchaudio>=0.12' ) @pytest.fixture(autouse=_lowercase ) def _A ( _lowercase , _lowercase ) -> Any: """simple docstring""" __UpperCamelCase = tmp_path_factory.getbasetemp() / 'cache' __UpperCamelCase = test_hf_cache_home / 'datasets' __UpperCamelCase = test_hf_cache_home / 'metrics' __UpperCamelCase = test_hf_cache_home / 'modules' monkeypatch.setattr('datasets.config.HF_DATASETS_CACHE' , str(_lowercase ) ) monkeypatch.setattr('datasets.config.HF_METRICS_CACHE' , str(_lowercase ) ) monkeypatch.setattr('datasets.config.HF_MODULES_CACHE' , str(_lowercase ) ) __UpperCamelCase = test_hf_datasets_cache / 'downloads' monkeypatch.setattr('datasets.config.DOWNLOADED_DATASETS_PATH' , str(_lowercase ) ) __UpperCamelCase = test_hf_datasets_cache / 'downloads' / 'extracted' monkeypatch.setattr('datasets.config.EXTRACTED_DATASETS_PATH' , str(_lowercase ) ) @pytest.fixture(autouse=_lowercase , scope='session' ) def _A ( ) -> Dict: """simple docstring""" datasets.disable_progress_bar() @pytest.fixture(autouse=_lowercase ) def _A ( _lowercase ) -> Tuple: """simple docstring""" monkeypatch.setattr('datasets.config.HF_UPDATE_DOWNLOAD_COUNTS' , _lowercase ) @pytest.fixture def _A ( _lowercase ) -> Any: """simple docstring""" monkeypatch.setattr('sqlalchemy.util.deprecations.SILENCE_UBER_WARNING' , _lowercase )

import unittest import numpy as np def _A ( _lowercase , _lowercase , _lowercase , _lowercase = None , ) -> np.ndarray: """simple docstring""" __UpperCamelCase = np.shape(_lowercase ) __UpperCamelCase = np.shape(_lowercase ) __UpperCamelCase = np.shape(_lowercase ) if shape_a[0] != shape_b[0]: __UpperCamelCase = ( 'Expected the same number of rows for A and B. ' f'''Instead found A of size {shape_a} and B of size {shape_b}''' ) raise ValueError(_lowercase ) if shape_b[1] != shape_c[1]: __UpperCamelCase = ( 'Expected the same number of columns for B and C. ' f'''Instead found B of size {shape_b} and C of size {shape_c}''' ) raise ValueError(_lowercase ) __UpperCamelCase = pseudo_inv if a_inv is None: try: __UpperCamelCase = np.linalg.inv(_lowercase ) except np.linalg.LinAlgError: raise ValueError( 'Input matrix A is not invertible. Cannot compute Schur complement.' ) return mat_c - mat_b.T @ a_inv @ mat_b class __lowerCamelCase (unittest.TestCase ): def snake_case_ ( self: Optional[int] ): '''simple docstring''' __UpperCamelCase = np.array([[1, 2, 1], [2, 1, 2], [3, 2, 4]] ) __UpperCamelCase = np.array([[0, 3], [3, 0], [2, 3]] ) __UpperCamelCase = np.array([[2, 1], [6, 3]] ) __UpperCamelCase = schur_complement(A_,A_,A_ ) __UpperCamelCase = np.block([[a, b], [b.T, c]] ) __UpperCamelCase = np.linalg.det(A_ ) __UpperCamelCase = np.linalg.det(A_ ) __UpperCamelCase = np.linalg.det(A_ ) self.assertAlmostEqual(A_,det_a * det_s ) def snake_case_ ( self: Dict ): '''simple docstring''' __UpperCamelCase = np.array([[1, 2, 1], [2, 1, 2], [3, 2, 4]] ) __UpperCamelCase = np.array([[0, 3], [3, 0], [2, 3]] ) __UpperCamelCase = np.array([[2, 1], [6, 3]] ) with self.assertRaises(A_ ): schur_complement(A_,A_,A_ ) def snake_case_ ( self: Tuple ): '''simple docstring''' __UpperCamelCase = np.array([[1, 2, 1], [2, 1, 2], [3, 2, 4]] ) __UpperCamelCase = np.array([[0, 3], [3, 0], [2, 3]] ) __UpperCamelCase = np.array([[2, 1, 3], [6, 3, 5]] ) with self.assertRaises(A_ ): schur_complement(A_,A_,A_ ) if __name__ == "__main__": import doctest doctest.testmod() unittest.main()

import random import unittest import numpy as np import torch from transformers import CLIPTextConfig, CLIPTextModel, CLIPTokenizer from diffusers import ( AutoencoderKL, DDIMScheduler, UNetaDConditionModel, VideoToVideoSDPipeline, ) from diffusers.utils import floats_tensor, is_xformers_available, skip_mps from diffusers.utils.testing_utils import enable_full_determinism, slow, torch_device from ..pipeline_params import ( TEXT_GUIDED_IMAGE_VARIATION_BATCH_PARAMS, TEXT_GUIDED_IMAGE_VARIATION_PARAMS, ) from ..test_pipelines_common import PipelineTesterMixin enable_full_determinism() @skip_mps class __lowerCamelCase (_a , unittest.TestCase ): _lowercase = VideoToVideoSDPipeline _lowercase = TEXT_GUIDED_IMAGE_VARIATION_PARAMS.union({"""video"""} ) - {"""image""", """width""", """height"""} _lowercase = TEXT_GUIDED_IMAGE_VARIATION_BATCH_PARAMS.union({"""video"""} ) - {"""image"""} _lowercase = PipelineTesterMixin.required_optional_params - {"""latents"""} _lowercase = False # No `output_type`. _lowercase = frozenset( [ """num_inference_steps""", """generator""", """latents""", """return_dict""", """callback""", """callback_steps""", ] ) def snake_case_ ( self: List[str] ): '''simple docstring''' torch.manual_seed(0 ) __UpperCamelCase = UNetaDConditionModel( block_out_channels=(32, 64, 64, 64),layers_per_block=2,sample_size=32,in_channels=4,out_channels=4,down_block_types=('CrossAttnDownBlock3D', 'CrossAttnDownBlock3D', 'CrossAttnDownBlock3D', 'DownBlock3D'),up_block_types=('UpBlock3D', 'CrossAttnUpBlock3D', 'CrossAttnUpBlock3D', 'CrossAttnUpBlock3D'),cross_attention_dim=32,attention_head_dim=4,) __UpperCamelCase = DDIMScheduler( beta_start=0.0_0_0_8_5,beta_end=0.0_1_2,beta_schedule='scaled_linear',clip_sample=A_,set_alpha_to_one=A_,) torch.manual_seed(0 ) __UpperCamelCase = AutoencoderKL( block_out_channels=[32, 64],in_channels=3,out_channels=3,down_block_types=['DownEncoderBlock2D', 'DownEncoderBlock2D'],up_block_types=['UpDecoderBlock2D', 'UpDecoderBlock2D'],latent_channels=4,sample_size=128,) torch.manual_seed(0 ) __UpperCamelCase = 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,) __UpperCamelCase = CLIPTextModel(A_ ) __UpperCamelCase = CLIPTokenizer.from_pretrained('hf-internal-testing/tiny-random-clip' ) __UpperCamelCase = { 'unet': unet, 'scheduler': scheduler, 'vae': vae, 'text_encoder': text_encoder, 'tokenizer': tokenizer, } return components def snake_case_ ( self: Union[str, Any],A_: Any,A_: Any=0 ): '''simple docstring''' __UpperCamelCase = floats_tensor((1, 3, 3, 32, 32),rng=random.Random(A_ ) ).to(A_ ) if str(A_ ).startswith('mps' ): __UpperCamelCase = torch.manual_seed(A_ ) else: __UpperCamelCase = torch.Generator(device=A_ ).manual_seed(A_ ) __UpperCamelCase = { 'prompt': 'A painting of a squirrel eating a burger', 'video': video, 'generator': generator, 'num_inference_steps': 2, 'guidance_scale': 6.0, 'output_type': 'pt', } return inputs def snake_case_ ( self: Union[str, Any] ): '''simple docstring''' __UpperCamelCase = 'cpu' # ensure determinism for the device-dependent torch.Generator __UpperCamelCase = self.get_dummy_components() __UpperCamelCase = VideoToVideoSDPipeline(**A_ ) __UpperCamelCase = sd_pipe.to(A_ ) sd_pipe.set_progress_bar_config(disable=A_ ) __UpperCamelCase = self.get_dummy_inputs(A_ ) __UpperCamelCase = 'np' __UpperCamelCase = sd_pipe(**A_ ).frames __UpperCamelCase = frames[0][-3:, -3:, -1] assert frames[0].shape == (32, 32, 3) __UpperCamelCase = np.array([106, 117, 113, 174, 137, 112, 148, 151, 131] ) assert np.abs(image_slice.flatten() - expected_slice ).max() < 1E-2 @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: Any ): '''simple docstring''' self._test_xformers_attention_forwardGenerator_pass(test_mean_pixel_difference=A_,expected_max_diff=5E-3 ) @unittest.skip(reason='Batching needs to be properly figured out first for this pipeline.' ) def snake_case_ ( self: str ): '''simple docstring''' pass @unittest.skip(reason='Batching needs to be properly figured out first for this pipeline.' ) def snake_case_ ( self: Optional[Any] ): '''simple docstring''' pass @unittest.skip(reason='`num_images_per_prompt` argument is not supported for this pipeline.' ) def snake_case_ ( self: int ): '''simple docstring''' pass def snake_case_ ( self: Any ): '''simple docstring''' return super().test_progress_bar() @slow @skip_mps class __lowerCamelCase (unittest.TestCase ): def snake_case_ ( self: Tuple ): '''simple docstring''' __UpperCamelCase = VideoToVideoSDPipeline.from_pretrained('cerspense/zeroscope_v2_XL',torch_dtype=torch.floataa ) pipe.enable_model_cpu_offload() # 10 frames __UpperCamelCase = torch.Generator(device='cpu' ).manual_seed(0 ) __UpperCamelCase = torch.randn((1, 10, 3, 1024, 576),generator=A_ ) __UpperCamelCase = video.to('cuda' ) __UpperCamelCase = 'Spiderman is surfing' __UpperCamelCase = pipe(A_,video=A_,generator=A_,num_inference_steps=3,output_type='pt' ).frames __UpperCamelCase = np.array([-1.0_4_5_8_9_8_4, -1.1_2_7_9_2_9_7, -0.9_6_6_3_0_8_6, -0.9_1_5_0_3_9_0_6, -0.7_5_0_9_7_6_5_6] ) assert np.abs(video_frames.cpu().numpy()[0, 0, 0, 0, -5:] - expected_array ).sum() < 1E-2

import inspect import logging import os import random import shutil import tempfile import unittest import pytest import torch from torch import nn from torch.utils.data import DataLoader, TensorDataset from accelerate import Accelerator from accelerate.test_utils import execute_subprocess_async, require_cuda from accelerate.utils import ProjectConfiguration, set_seed __snake_case = logging.getLogger(__name__) def _A ( _lowercase=2 , _lowercase=3 , _lowercase=16 , _lowercase = 10 , _lowercase = 2 ) -> Any: """simple docstring""" def get_dataset(_lowercase ): __UpperCamelCase = torch.randn(batch_size * n_batches , 1 ) return TensorDataset(_lowercase , a * x + b + 0.1 * torch.randn(batch_size * n_batches , 1 ) ) __UpperCamelCase = get_dataset(_lowercase ) __UpperCamelCase = get_dataset(_lowercase ) __UpperCamelCase = DataLoader(_lowercase , shuffle=_lowercase , batch_size=_lowercase , num_workers=4 ) __UpperCamelCase = DataLoader(_lowercase , shuffle=_lowercase , batch_size=_lowercase , num_workers=4 ) return (train_dataloader, valid_dataloader) def _A ( _lowercase , _lowercase , _lowercase , _lowercase , _lowercase , _lowercase=None ) -> Optional[int]: """simple docstring""" __UpperCamelCase = [] for epoch in range(_lowercase ): # Train quickly model.train() for batch in dataloader: __UpperCamelCase, __UpperCamelCase = batch __UpperCamelCase = model(_lowercase ) __UpperCamelCase = torch.nn.functional.mse_loss(_lowercase , _lowercase ) accelerator.backward(_lowercase ) optimizer.step() optimizer.zero_grad() rands.append(random.random() ) # Introduce some randomness if scheduler is not None: scheduler.step() return rands class __lowerCamelCase (nn.Module ): def __init__( self: Optional[Any] ): '''simple docstring''' super().__init__() __UpperCamelCase = nn.Parameter(torch.randn(1 ) ) __UpperCamelCase = nn.Parameter(torch.randn(1 ) ) def snake_case_ ( self: Tuple,A_: Tuple ): '''simple docstring''' return x * self.a + self.b class __lowerCamelCase (unittest.TestCase ): def snake_case_ ( self: Dict ): '''simple docstring''' with tempfile.TemporaryDirectory() as tmpdir: set_seed(42 ) __UpperCamelCase = DummyModel() __UpperCamelCase = torch.optim.Adam(params=model.parameters(),lr=1E-3 ) __UpperCamelCase, __UpperCamelCase = dummy_dataloaders() __UpperCamelCase = ProjectConfiguration(total_limit=1,project_dir=A_,automatic_checkpoint_naming=A_ ) # Train baseline __UpperCamelCase = Accelerator(project_config=A_ ) __UpperCamelCase, __UpperCamelCase, __UpperCamelCase, __UpperCamelCase = accelerator.prepare( A_,A_,A_,A_ ) # Save initial accelerator.save_state() # Save second state accelerator.save_state() self.assertEqual(len(os.listdir(accelerator.project_dir ) ),1 ) def snake_case_ ( self: Any ): '''simple docstring''' with tempfile.TemporaryDirectory() as tmpdir: set_seed(42 ) __UpperCamelCase = DummyModel() __UpperCamelCase = torch.optim.Adam(params=model.parameters(),lr=1E-3 ) __UpperCamelCase, __UpperCamelCase = dummy_dataloaders() # Train baseline __UpperCamelCase = Accelerator() __UpperCamelCase, __UpperCamelCase, __UpperCamelCase, __UpperCamelCase = accelerator.prepare( A_,A_,A_,A_ ) # Save initial __UpperCamelCase = os.path.join(A_,'initial' ) accelerator.save_state(A_ ) ((__UpperCamelCase), (__UpperCamelCase)) = model.a.item(), model.b.item() __UpperCamelCase = optimizer.state_dict() __UpperCamelCase = train(3,A_,A_,A_,A_ ) ((__UpperCamelCase), (__UpperCamelCase)) = model.a.item(), model.b.item() __UpperCamelCase = optimizer.state_dict() # Train partially set_seed(42 ) __UpperCamelCase = DummyModel() __UpperCamelCase = torch.optim.Adam(params=model.parameters(),lr=1E-3 ) __UpperCamelCase, __UpperCamelCase = dummy_dataloaders() __UpperCamelCase = Accelerator() __UpperCamelCase, __UpperCamelCase, __UpperCamelCase, __UpperCamelCase = accelerator.prepare( A_,A_,A_,A_ ) accelerator.load_state(A_ ) ((__UpperCamelCase), (__UpperCamelCase)) = model.a.item(), model.b.item() __UpperCamelCase = optimizer.state_dict() self.assertEqual(A_,A_ ) self.assertEqual(A_,A_ ) self.assertEqual(A_,A_ ) __UpperCamelCase = train(2,A_,A_,A_,A_ ) # Save everything __UpperCamelCase = os.path.join(A_,'checkpoint' ) accelerator.save_state(A_ ) # Load everything back in and make sure all states work accelerator.load_state(A_ ) test_rands += train(1,A_,A_,A_,A_ ) ((__UpperCamelCase), (__UpperCamelCase)) = model.a.item(), model.b.item() __UpperCamelCase = optimizer.state_dict() self.assertEqual(A_,A_ ) self.assertEqual(A_,A_ ) self.assertEqual(A_,A_ ) self.assertEqual(A_,A_ ) def snake_case_ ( self: Optional[int] ): '''simple docstring''' with tempfile.TemporaryDirectory() as tmpdir: set_seed(42 ) __UpperCamelCase = DummyModel() __UpperCamelCase = torch.optim.Adam(params=model.parameters(),lr=1E-3 ) __UpperCamelCase, __UpperCamelCase = dummy_dataloaders() __UpperCamelCase = ProjectConfiguration(automatic_checkpoint_naming=A_ ) # Train baseline __UpperCamelCase = Accelerator(project_dir=A_,project_config=A_ ) __UpperCamelCase, __UpperCamelCase, __UpperCamelCase, __UpperCamelCase = accelerator.prepare( A_,A_,A_,A_ ) # Save initial accelerator.save_state() ((__UpperCamelCase), (__UpperCamelCase)) = model.a.item(), model.b.item() __UpperCamelCase = optimizer.state_dict() __UpperCamelCase = train(3,A_,A_,A_,A_ ) ((__UpperCamelCase), (__UpperCamelCase)) = model.a.item(), model.b.item() __UpperCamelCase = optimizer.state_dict() # Train partially set_seed(42 ) __UpperCamelCase = DummyModel() __UpperCamelCase = torch.optim.Adam(params=model.parameters(),lr=1E-3 ) __UpperCamelCase, __UpperCamelCase = dummy_dataloaders() __UpperCamelCase = ProjectConfiguration(iteration=1,automatic_checkpoint_naming=A_ ) __UpperCamelCase = Accelerator(project_dir=A_,project_config=A_ ) __UpperCamelCase, __UpperCamelCase, __UpperCamelCase, __UpperCamelCase = accelerator.prepare( A_,A_,A_,A_ ) accelerator.load_state(os.path.join(A_,'checkpoints','checkpoint_0' ) ) ((__UpperCamelCase), (__UpperCamelCase)) = model.a.item(), model.b.item() __UpperCamelCase = optimizer.state_dict() self.assertEqual(A_,A_ ) self.assertEqual(A_,A_ ) self.assertEqual(A_,A_ ) __UpperCamelCase = train(2,A_,A_,A_,A_ ) # Save everything accelerator.save_state() # Load everything back in and make sure all states work accelerator.load_state(os.path.join(A_,'checkpoints','checkpoint_1' ) ) test_rands += train(1,A_,A_,A_,A_ ) ((__UpperCamelCase), (__UpperCamelCase)) = model.a.item(), model.b.item() __UpperCamelCase = optimizer.state_dict() self.assertEqual(A_,A_ ) self.assertEqual(A_,A_ ) self.assertEqual(A_,A_ ) self.assertEqual(A_,A_ ) def snake_case_ ( self: Optional[int] ): '''simple docstring''' __UpperCamelCase = torch.tensor([1, 2, 3] ) __UpperCamelCase = torch.tensor([2, 3, 4] ) __UpperCamelCase = DummyModel() __UpperCamelCase = torch.optim.Adam(net.parameters() ) __UpperCamelCase = Accelerator() with self.assertRaises(A_ ) as ve: accelerator.register_for_checkpointing(A_,A_,A_,A_ ) __UpperCamelCase = str(ve.exception ) self.assertTrue('Item at index 0' in message ) self.assertTrue('Item at index 1' in message ) self.assertFalse('Item at index 2' in message ) self.assertFalse('Item at index 3' in message ) def snake_case_ ( self: Optional[int] ): '''simple docstring''' with tempfile.TemporaryDirectory() as tmpdir: set_seed(42 ) __UpperCamelCase = DummyModel() __UpperCamelCase = torch.optim.Adam(params=model.parameters(),lr=1E-3 ) __UpperCamelCase = torch.optim.lr_scheduler.StepLR(A_,step_size=1,gamma=0.9_9 ) __UpperCamelCase, __UpperCamelCase = dummy_dataloaders() __UpperCamelCase = ProjectConfiguration(automatic_checkpoint_naming=A_ ) # Train baseline __UpperCamelCase = Accelerator(project_dir=A_,project_config=A_ ) __UpperCamelCase, __UpperCamelCase, __UpperCamelCase, __UpperCamelCase, __UpperCamelCase = accelerator.prepare( A_,A_,A_,A_,A_ ) # Save initial accelerator.save_state() __UpperCamelCase = scheduler.state_dict() train(3,A_,A_,A_,A_,A_ ) self.assertNotEqual(A_,scheduler.state_dict() ) # Load everything back in and make sure all states work accelerator.load_state(os.path.join(A_,'checkpoints','checkpoint_0' ) ) self.assertEqual(A_,scheduler.state_dict() ) def snake_case_ ( self: str ): '''simple docstring''' with tempfile.TemporaryDirectory() as tmpdir: set_seed(42 ) __UpperCamelCase = DummyModel() __UpperCamelCase = ProjectConfiguration(automatic_checkpoint_naming=A_,total_limit=2 ) # Train baseline __UpperCamelCase = Accelerator(project_dir=A_,project_config=A_ ) __UpperCamelCase = accelerator.prepare(A_ ) # Save 3 states: for _ in range(11 ): accelerator.save_state() self.assertTrue(not os.path.exists(os.path.join(A_,'checkpoints','checkpoint_0' ) ) ) self.assertTrue(os.path.exists(os.path.join(A_,'checkpoints','checkpoint_9' ) ) ) self.assertTrue(os.path.exists(os.path.join(A_,'checkpoints','checkpoint_10' ) ) ) @require_cuda def snake_case_ ( self: Tuple ): '''simple docstring''' __UpperCamelCase = ['torchrun', F'''--nproc_per_node={torch.cuda.device_count()}''', inspect.getfile(self.__class__ )] execute_subprocess_async(A_,env=os.environ.copy() ) if __name__ == "__main__": __snake_case = '''/tmp/accelerate/state_checkpointing''' __snake_case = DummyModel() __snake_case = torch.optim.Adam(params=model.parameters(), lr=1e-3) __snake_case = torch.optim.lr_scheduler.StepLR(optimizer, step_size=1, gamma=0.99) __snake_case , __snake_case = dummy_dataloaders() __snake_case = ProjectConfiguration(automatic_checkpoint_naming=True) # Train baseline __snake_case = Accelerator(project_dir=savedir, project_config=project_config, mixed_precision='''no''') if accelerator.process_index == 0: if os.path.exists(savedir): shutil.rmtree(savedir) os.makedirs(savedir) __snake_case , __snake_case , __snake_case , __snake_case , __snake_case = accelerator.prepare( model, optimizer, train_dataloader, valid_dataloader, scheduler ) __snake_case , __snake_case = accelerator.prepare(model, optimizer) train(3, model, train_dataloader, optimizer, accelerator, scheduler) # Check that the intial optimizer is loaded on the GPU for group in optimizer.param_groups: __snake_case = group['''params'''][0].device break assert param_device.type == accelerator.device.type __snake_case = model.cpu() accelerator.wait_for_everyone() accelerator.save_state() accelerator.wait_for_everyone() # Check CPU state accelerator.load_state(os.path.join(savedir, '''checkpoints''', '''checkpoint_0'''), map_location='''cpu''') for group in optimizer.param_groups: __snake_case = group['''params'''][0].device break assert ( param_device.type == torch.device('''cpu''').type ), f"Loaded optimizer states did not match, expected to be loaded on the CPU but got {param_device}" # Check device state model.to(accelerator.device) accelerator.load_state(os.path.join(savedir, '''checkpoints''', '''checkpoint_0'''), map_location='''on_device''') for group in optimizer.param_groups: __snake_case = group['''params'''][0].device break assert ( param_device.type == accelerator.device.type ), f"Loaded optimizer states did not match, expected to be loaded on {accelerator.device} but got {param_device}" # Check error with pytest.raises(TypeError, match='''Unsupported optimizer map location passed'''): accelerator.load_state(os.path.join(savedir, '''checkpoints''', '''checkpoint_0'''), map_location='''invalid''') accelerator.wait_for_everyone() if accelerator.process_index == 0: shutil.rmtree(savedir) accelerator.wait_for_everyone()

import argparse from transformers import CLIPImageProcessor, CLIPVisionModelWithProjection from diffusers import UnCLIPImageVariationPipeline, UnCLIPPipeline if __name__ == "__main__": __snake_case = argparse.ArgumentParser() parser.add_argument('''--dump_path''', default=None, type=str, required=True, help='''Path to the output model.''') parser.add_argument( '''--txt2img_unclip''', default='''kakaobrain/karlo-v1-alpha''', type=str, required=False, help='''The pretrained txt2img unclip.''', ) __snake_case = parser.parse_args() __snake_case = UnCLIPPipeline.from_pretrained(args.txtaimg_unclip) __snake_case = CLIPImageProcessor() __snake_case = CLIPVisionModelWithProjection.from_pretrained('''openai/clip-vit-large-patch14''') __snake_case = UnCLIPImageVariationPipeline( decoder=txtaimg.decoder, text_encoder=txtaimg.text_encoder, tokenizer=txtaimg.tokenizer, text_proj=txtaimg.text_proj, feature_extractor=feature_extractor, image_encoder=image_encoder, super_res_first=txtaimg.super_res_first, super_res_last=txtaimg.super_res_last, decoder_scheduler=txtaimg.decoder_scheduler, super_res_scheduler=txtaimg.super_res_scheduler, ) imgaimg.save_pretrained(args.dump_path)

import copy import os import cva import numpy as np from matplotlib import pyplot as plt class __lowerCamelCase : def __init__( self: Any ): '''simple docstring''' __UpperCamelCase = '' __UpperCamelCase = '' __UpperCamelCase = [] __UpperCamelCase = 0 __UpperCamelCase = 256 __UpperCamelCase = 0 __UpperCamelCase = 0 __UpperCamelCase = 0 __UpperCamelCase = 0 def snake_case_ ( self: List[Any],A_: Union[str, Any] ): '''simple docstring''' __UpperCamelCase = cva.imread(A_,0 ) __UpperCamelCase = copy.deepcopy(self.img ) __UpperCamelCase, __UpperCamelCase, __UpperCamelCase = plt.hist(self.img.ravel(),256,[0, 256],label='x' ) __UpperCamelCase = np.sum(A_ ) for i in range(len(A_ ) ): __UpperCamelCase = x[i] / self.k self.sk += prk __UpperCamelCase = (self.L - 1) * self.sk if self.rem != 0: __UpperCamelCase = int(last % last ) __UpperCamelCase = int(last + 1 if self.rem >= 0.5 else last ) self.last_list.append(A_ ) __UpperCamelCase = int(np.ma.count(self.img ) / self.img[1].size ) __UpperCamelCase = self.img[1].size for i in range(self.number_of_cols ): for j in range(self.number_of_rows ): __UpperCamelCase = self.img[j][i] if num != self.last_list[num]: __UpperCamelCase = self.last_list[num] cva.imwrite('output_data/output.jpg',self.img ) def snake_case_ ( self: Dict ): '''simple docstring''' plt.hist(self.img.ravel(),256,[0, 256] ) def snake_case_ ( self: str ): '''simple docstring''' cva.imshow('Output-Image',self.img ) cva.imshow('Input-Image',self.original_image ) cva.waitKey(5000 ) cva.destroyAllWindows() if __name__ == "__main__": __snake_case = os.path.join(os.path.basename(__file__), '''image_data/input.jpg''') __snake_case = ConstantStretch() stretcher.stretch(file_path) stretcher.plot_histogram() stretcher.show_image()

from typing import TYPE_CHECKING # rely on isort to merge the imports from ...utils import OptionalDependencyNotAvailable, _LazyModule, is_torch_available __snake_case = { '''configuration_autoformer''': [ '''AUTOFORMER_PRETRAINED_CONFIG_ARCHIVE_MAP''', '''AutoformerConfig''', ], } try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __snake_case = [ '''AUTOFORMER_PRETRAINED_MODEL_ARCHIVE_LIST''', '''AutoformerForPrediction''', '''AutoformerModel''', '''AutoformerPreTrainedModel''', ] if TYPE_CHECKING: from .configuration_autoformer import ( AUTOFORMER_PRETRAINED_CONFIG_ARCHIVE_MAP, AutoformerConfig, ) try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_autoformer import ( AUTOFORMER_PRETRAINED_MODEL_ARCHIVE_LIST, AutoformerForPrediction, AutoformerModel, AutoformerPreTrainedModel, ) else: import sys __snake_case = _LazyModule(__name__, globals()['''__file__'''], _import_structure, module_spec=__spec__)

import os from dataclasses import dataclass, field from io import BytesIO from typing import TYPE_CHECKING, Any, ClassVar, Dict, Optional, Union import numpy as np import pyarrow as pa from .. import config from ..download.streaming_download_manager import xopen, xsplitext from ..table import array_cast from ..utils.py_utils import no_op_if_value_is_null, string_to_dict if TYPE_CHECKING: from .features import FeatureType __snake_case , __snake_case , __snake_case = False, False, False @dataclass class __lowerCamelCase : _lowercase = None _lowercase = True _lowercase = True _lowercase = None # Automatically constructed _lowercase = "dict" _lowercase = pa.struct({"""bytes""": pa.binary(), """path""": pa.string()} ) _lowercase = field(default="""Audio""" , init=_a , repr=_a ) def __call__( self: Optional[int] ): '''simple docstring''' return self.pa_type def snake_case_ ( self: Tuple,A_: Union[str, bytes, dict] ): '''simple docstring''' try: import soundfile as sf # soundfile is a dependency of librosa, needed to decode audio files. except ImportError as err: raise ImportError('To support encoding audio data, please install \'soundfile\'.' ) from err if isinstance(A_,A_ ): return {"bytes": None, "path": value} elif isinstance(A_,A_ ): return {"bytes": value, "path": None} elif "array" in value: # convert the audio array to wav bytes __UpperCamelCase = BytesIO() sf.write(A_,value['array'],value['sampling_rate'],format='wav' ) return {"bytes": buffer.getvalue(), "path": None} elif value.get('path' ) is not None and os.path.isfile(value['path'] ): # we set "bytes": None to not duplicate the data if they're already available locally if value["path"].endswith('pcm' ): # "PCM" only has raw audio bytes if value.get('sampling_rate' ) is None: # At least, If you want to convert "PCM-byte" to "WAV-byte", you have to know sampling rate raise KeyError('To use PCM files, please specify a \'sampling_rate\' in Audio object' ) if value.get('bytes' ): # If we already had PCM-byte, we don`t have to make "read file, make bytes" (just use it!) __UpperCamelCase = np.frombuffer(value['bytes'],dtype=np.intaa ).astype(np.floataa ) / 3_2767 else: __UpperCamelCase = np.memmap(value['path'],dtype='h',mode='r' ).astype(np.floataa ) / 3_2767 __UpperCamelCase = BytesIO(bytes() ) sf.write(A_,A_,value['sampling_rate'],format='wav' ) return {"bytes": buffer.getvalue(), "path": None} else: return {"bytes": None, "path": value.get('path' )} elif value.get('bytes' ) is not None or value.get('path' ) is not None: # store the audio bytes, and path is used to infer the audio format using the file extension return {"bytes": value.get('bytes' ), "path": value.get('path' )} else: raise ValueError( F'''An audio sample should have one of \'path\' or \'bytes\' but they are missing or None in {value}.''' ) def snake_case_ ( self: List[Any],A_: dict,A_: Optional[Dict[str, Union[str, bool, None]]] = None ): '''simple docstring''' if not self.decode: raise RuntimeError('Decoding is disabled for this feature. Please use Audio(decode=True) instead.' ) __UpperCamelCase, __UpperCamelCase = (value['path'], BytesIO(value['bytes'] )) if value['bytes'] is not None else (value['path'], None) if path is None and file is None: raise ValueError(F'''An audio sample should have one of \'path\' or \'bytes\' but both are None in {value}.''' ) try: import librosa import soundfile as sf except ImportError as err: raise ImportError('To support decoding audio files, please install \'librosa\' and \'soundfile\'.' ) from err __UpperCamelCase = xsplitext(A_ )[1][1:].lower() if path is not None else None if not config.IS_OPUS_SUPPORTED and audio_format == "opus": raise RuntimeError( 'Decoding \'opus\' files requires system library \'libsndfile\'>=1.0.31, ' 'You can try to update `soundfile` python library: `pip install "soundfile>=0.12.1"`. ' ) elif not config.IS_MP3_SUPPORTED and audio_format == "mp3": raise RuntimeError( 'Decoding \'mp3\' files requires system library \'libsndfile\'>=1.1.0, ' 'You can try to update `soundfile` python library: `pip install "soundfile>=0.12.1"`. ' ) if file is None: __UpperCamelCase = token_per_repo_id or {} __UpperCamelCase = path.split('::' )[-1] try: __UpperCamelCase = string_to_dict(A_,config.HUB_DATASETS_URL )['repo_id'] __UpperCamelCase = token_per_repo_id[repo_id] except (ValueError, KeyError): __UpperCamelCase = None with xopen(A_,'rb',use_auth_token=A_ ) as f: __UpperCamelCase, __UpperCamelCase = sf.read(A_ ) else: __UpperCamelCase, __UpperCamelCase = sf.read(A_ ) __UpperCamelCase = array.T if self.mono: __UpperCamelCase = librosa.to_mono(A_ ) if self.sampling_rate and self.sampling_rate != sampling_rate: __UpperCamelCase = librosa.resample(A_,orig_sr=A_,target_sr=self.sampling_rate ) __UpperCamelCase = self.sampling_rate return {"path": path, "array": array, "sampling_rate": sampling_rate} def snake_case_ ( self: List[Any] ): '''simple docstring''' from .features import Value if self.decode: raise ValueError('Cannot flatten a decoded Audio feature.' ) return { "bytes": Value('binary' ), "path": Value('string' ), } def snake_case_ ( self: str,A_: Union[pa.StringArray, pa.StructArray] ): '''simple docstring''' if pa.types.is_string(storage.type ): __UpperCamelCase = pa.array([None] * len(A_ ),type=pa.binary() ) __UpperCamelCase = pa.StructArray.from_arrays([bytes_array, storage],['bytes', 'path'],mask=storage.is_null() ) elif pa.types.is_binary(storage.type ): __UpperCamelCase = pa.array([None] * len(A_ ),type=pa.string() ) __UpperCamelCase = pa.StructArray.from_arrays([storage, path_array],['bytes', 'path'],mask=storage.is_null() ) elif pa.types.is_struct(storage.type ) and storage.type.get_all_field_indices('array' ): __UpperCamelCase = pa.array([Audio().encode_example(A_ ) if x is not None else None for x in storage.to_pylist()] ) elif pa.types.is_struct(storage.type ): if storage.type.get_field_index('bytes' ) >= 0: __UpperCamelCase = storage.field('bytes' ) else: __UpperCamelCase = pa.array([None] * len(A_ ),type=pa.binary() ) if storage.type.get_field_index('path' ) >= 0: __UpperCamelCase = storage.field('path' ) else: __UpperCamelCase = pa.array([None] * len(A_ ),type=pa.string() ) __UpperCamelCase = pa.StructArray.from_arrays([bytes_array, path_array],['bytes', 'path'],mask=storage.is_null() ) return array_cast(A_,self.pa_type ) def snake_case_ ( self: Optional[Any],A_: pa.StructArray ): '''simple docstring''' @no_op_if_value_is_null def path_to_bytes(A_: Union[str, Any] ): with xopen(A_,'rb' ) as f: __UpperCamelCase = f.read() return bytes_ __UpperCamelCase = pa.array( [ (path_to_bytes(x['path'] ) if x['bytes'] is None else x['bytes']) if x is not None else None for x in storage.to_pylist() ],type=pa.binary(),) __UpperCamelCase = pa.array( [os.path.basename(A_ ) if path is not None else None for path in storage.field('path' ).to_pylist()],type=pa.string(),) __UpperCamelCase = pa.StructArray.from_arrays([bytes_array, path_array],['bytes', 'path'],mask=bytes_array.is_null() ) return array_cast(A_,self.pa_type )

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 = ''' {0} = None ''' __snake_case = ''' class {0}(metaclass=DummyObject): _backends = {1} def __init__(self, *args, **kwargs): requires_backends(self, {1}) @classmethod def from_config(cls, *args, **kwargs): requires_backends(cls, {1}) @classmethod def from_pretrained(cls, *args, **kwargs): requires_backends(cls, {1}) ''' __snake_case = ''' def {0}(*args, **kwargs): requires_backends({0}, {1}) ''' def _A ( _lowercase ) -> int: """simple docstring""" __UpperCamelCase = _re_backend.findall(_lowercase ) if len(_lowercase ) == 0: return None return "_and_".join(_lowercase ) def _A ( ) -> Tuple: """simple docstring""" with open(os.path.join(_lowercase , '__init__.py' ) , 'r' , encoding='utf-8' , newline='\n' ) as f: __UpperCamelCase = f.readlines() # Get to the point we do the actual imports for type checking __UpperCamelCase = 0 __UpperCamelCase = {} # Go through the end of the file while line_index < len(_lowercase ): # If the line contains is_backend_available, we grab all objects associated with the `else` block __UpperCamelCase = find_backend(lines[line_index] ) if backend is not None: while not lines[line_index].startswith('else:' ): line_index += 1 line_index += 1 __UpperCamelCase = [] # Until we unindent, add backend objects to the list while line_index < len(_lowercase ) and len(lines[line_index] ) > 1: __UpperCamelCase = lines[line_index] __UpperCamelCase = _re_single_line_import.search(_lowercase ) 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(_lowercase ) > 0: __UpperCamelCase = objects else: line_index += 1 return backend_specific_objects def _A ( _lowercase , _lowercase ) -> Union[str, Any]: """simple docstring""" if name.isupper(): return DUMMY_CONSTANT.format(_lowercase ) elif name.islower(): return DUMMY_FUNCTION.format(_lowercase , _lowercase ) else: return DUMMY_CLASS.format(_lowercase , _lowercase ) def _A ( _lowercase=None ) -> Optional[Any]: """simple docstring""" if backend_specific_objects is None: __UpperCamelCase = read_init() # For special correspondence backend to module name as used in the function requires_modulename __UpperCamelCase = {} for backend, objects in backend_specific_objects.items(): __UpperCamelCase = '[' + ', '.join(f'''"{b}"''' for b in backend.split('_and_' ) ) + ']' __UpperCamelCase = '# 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(_lowercase , _lowercase ) for o in objects] ) __UpperCamelCase = dummy_file return dummy_files def _A ( _lowercase=False ) -> List[str]: """simple docstring""" __UpperCamelCase = create_dummy_files() # For special correspondence backend to shortcut as used in utils/dummy_xxx_objects.py __UpperCamelCase = {'torch': 'pt'} # Locate actual dummy modules and read their content. __UpperCamelCase = os.path.join(_lowercase , 'utils' ) __UpperCamelCase = { backend: os.path.join(_lowercase , f'''dummy_{short_names.get(_lowercase , _lowercase )}_objects.py''' ) for backend in dummy_files.keys() } __UpperCamelCase = {} for backend, file_path in dummy_file_paths.items(): if os.path.isfile(_lowercase ): with open(_lowercase , 'r' , encoding='utf-8' , newline='\n' ) as f: __UpperCamelCase = f.read() else: __UpperCamelCase = '' for backend in dummy_files.keys(): if dummy_files[backend] != actual_dummies[backend]: if overwrite: print( f'''Updating diffusers.utils.dummy_{short_names.get(_lowercase , _lowercase )}_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(_lowercase , _lowercase )}_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)

import dataclasses import re import string from typing import Any, Dict, Iterator, List, Mapping, Optional, Sequence, Tuple import numpy as np from . import residue_constants __snake_case = Mapping[str, np.ndarray] __snake_case = Mapping[str, Any] # Is a nested dict. __snake_case = 0.01 @dataclasses.dataclass(frozen=_a ) class __lowerCamelCase : _lowercase = 42 # [num_res, num_atom_type, 3] # Amino-acid type for each residue represented as an integer between 0 and # 20, where 20 is 'X'. _lowercase = 42 # [num_res] # Binary float mask to indicate presence of a particular atom. 1.0 if an atom # is present and 0.0 if not. This should be used for loss masking. _lowercase = 42 # [num_res, num_atom_type] # Residue index as used in PDB. It is not necessarily continuous or 0-indexed. _lowercase = 42 # [num_res] # B-factors, or temperature factors, of each residue (in sq. angstroms units), # representing the displacement of the residue from its ground truth mean # value. _lowercase = 42 # [num_res, num_atom_type] # Chain indices for multi-chain predictions _lowercase = None # Optional remark about the protein. Included as a comment in output PDB # files _lowercase = None # Templates used to generate this protein (prediction-only) _lowercase = None # Chain corresponding to each parent _lowercase = None def _A ( _lowercase ) -> Protein: """simple docstring""" __UpperCamelCase = r'(\[[A-Z]+\]\n)' __UpperCamelCase = [tag.strip() for tag in re.split(_lowercase , _lowercase ) if len(_lowercase ) > 0] __UpperCamelCase = zip(tags[0::2] , [l.split('\n' ) for l in tags[1::2]] ) __UpperCamelCase = ["N", "CA", "C"] __UpperCamelCase = None __UpperCamelCase = None __UpperCamelCase = None for g in groups: if "[PRIMARY]" == g[0]: __UpperCamelCase = g[1][0].strip() for i in range(len(_lowercase ) ): if seq[i] not in residue_constants.restypes: __UpperCamelCase = 'X' # FIXME: strings are immutable __UpperCamelCase = np.array( [residue_constants.restype_order.get(_lowercase , residue_constants.restype_num ) for res_symbol in seq] ) elif "[TERTIARY]" == g[0]: __UpperCamelCase = [] for axis in range(3 ): tertiary.append(list(map(_lowercase , g[1][axis].split() ) ) ) __UpperCamelCase = np.array(_lowercase ) __UpperCamelCase = np.zeros((len(tertiary[0] ) // 3, residue_constants.atom_type_num, 3) ).astype(np.floataa ) for i, atom in enumerate(_lowercase ): __UpperCamelCase = np.transpose(tertiary_np[:, i::3] ) atom_positions *= PICO_TO_ANGSTROM elif "[MASK]" == g[0]: __UpperCamelCase = np.array(list(map({'-': 0, '+': 1}.get , g[1][0].strip() ) ) ) __UpperCamelCase = np.zeros( ( len(_lowercase ), residue_constants.atom_type_num, ) ).astype(np.floataa ) for i, atom in enumerate(_lowercase ): __UpperCamelCase = 1 atom_mask *= mask[..., None] assert aatype is not None return Protein( atom_positions=_lowercase , atom_mask=_lowercase , aatype=_lowercase , residue_index=np.arange(len(_lowercase ) ) , b_factors=_lowercase , ) def _A ( _lowercase , _lowercase = 0 ) -> List[str]: """simple docstring""" __UpperCamelCase = [] __UpperCamelCase = prot.remark if remark is not None: pdb_headers.append(f'''REMARK {remark}''' ) __UpperCamelCase = prot.parents __UpperCamelCase = prot.parents_chain_index if parents is not None and parents_chain_index is not None: __UpperCamelCase = [p for i, p in zip(_lowercase , _lowercase ) if i == chain_id] if parents is None or len(_lowercase ) == 0: __UpperCamelCase = ['N/A'] pdb_headers.append(f'''PARENT {' '.join(_lowercase )}''' ) return pdb_headers def _A ( _lowercase , _lowercase ) -> str: """simple docstring""" __UpperCamelCase = [] __UpperCamelCase = pdb_str.split('\n' ) __UpperCamelCase = prot.remark if remark is not None: out_pdb_lines.append(f'''REMARK {remark}''' ) __UpperCamelCase = 42 if prot.parents is not None and len(prot.parents ) > 0: __UpperCamelCase = [] if prot.parents_chain_index is not None: __UpperCamelCase = {} for p, i in zip(prot.parents , prot.parents_chain_index ): parent_dict.setdefault(str(_lowercase ) , [] ) parent_dict[str(_lowercase )].append(_lowercase ) __UpperCamelCase = max([int(_lowercase ) for chain_idx in parent_dict] ) for i in range(max_idx + 1 ): __UpperCamelCase = parent_dict.get(str(_lowercase ) , ['N/A'] ) parents_per_chain.append(_lowercase ) else: parents_per_chain.append(list(prot.parents ) ) else: __UpperCamelCase = [['N/A']] def make_parent_line(_lowercase ) -> str: return f'''PARENT {' '.join(_lowercase )}''' out_pdb_lines.append(make_parent_line(parents_per_chain[0] ) ) __UpperCamelCase = 0 for i, l in enumerate(_lowercase ): if "PARENT" not in l and "REMARK" not in l: out_pdb_lines.append(_lowercase ) if "TER" in l and "END" not in lines[i + 1]: chain_counter += 1 if not chain_counter >= len(_lowercase ): __UpperCamelCase = parents_per_chain[chain_counter] else: __UpperCamelCase = ['N/A'] out_pdb_lines.append(make_parent_line(_lowercase ) ) return "\n".join(_lowercase ) def _A ( _lowercase ) -> str: """simple docstring""" __UpperCamelCase = residue_constants.restypes + ['X'] def res_atoa(_lowercase ) -> str: return residue_constants.restype_atoa.get(restypes[r] , 'UNK' ) __UpperCamelCase = residue_constants.atom_types __UpperCamelCase = [] __UpperCamelCase = prot.atom_mask __UpperCamelCase = prot.aatype __UpperCamelCase = prot.atom_positions __UpperCamelCase = prot.residue_index.astype(np.intaa ) __UpperCamelCase = prot.b_factors __UpperCamelCase = prot.chain_index if np.any(aatype > residue_constants.restype_num ): raise ValueError('Invalid aatypes.' ) __UpperCamelCase = get_pdb_headers(_lowercase ) if len(_lowercase ) > 0: pdb_lines.extend(_lowercase ) __UpperCamelCase = aatype.shape[0] __UpperCamelCase = 1 __UpperCamelCase = 0 __UpperCamelCase = string.ascii_uppercase __UpperCamelCase = None # Add all atom sites. for i in range(_lowercase ): __UpperCamelCase = res_atoa(aatype[i] ) for atom_name, pos, mask, b_factor in zip(_lowercase , atom_positions[i] , atom_mask[i] , b_factors[i] ): if mask < 0.5: continue __UpperCamelCase = 'ATOM' __UpperCamelCase = atom_name if len(_lowercase ) == 4 else f''' {atom_name}''' __UpperCamelCase = '' __UpperCamelCase = '' __UpperCamelCase = 1.00 __UpperCamelCase = atom_name[0] # Protein supports only C, N, O, S, this works. __UpperCamelCase = '' __UpperCamelCase = 'A' if chain_index is not None: __UpperCamelCase = chain_tags[chain_index[i]] # PDB is a columnar format, every space matters here! __UpperCamelCase = ( f'''{record_type:<6}{atom_index:>5} {name:<4}{alt_loc:>1}''' f'''{res_name_a:>3} {chain_tag:>1}''' f'''{residue_index[i]:>4}{insertion_code:>1} ''' f'''{pos[0]:>8.3f}{pos[1]:>8.3f}{pos[2]:>8.3f}''' f'''{occupancy:>6.2f}{b_factor:>6.2f} ''' f'''{element:>2}{charge:>2}''' ) pdb_lines.append(_lowercase ) atom_index += 1 __UpperCamelCase = i == n - 1 if chain_index is not None: if i != n - 1 and chain_index[i + 1] != prev_chain_index: __UpperCamelCase = True __UpperCamelCase = chain_index[i + 1] if should_terminate: # Close the chain. __UpperCamelCase = 'TER' __UpperCamelCase = ( f'''{chain_end:<6}{atom_index:>5} {res_atoa(aatype[i] ):>3} {chain_tag:>1}{residue_index[i]:>4}''' ) pdb_lines.append(_lowercase ) atom_index += 1 if i != n - 1: # "prev" is a misnomer here. This happens at the beginning of # each new chain. pdb_lines.extend(get_pdb_headers(_lowercase , _lowercase ) ) pdb_lines.append('END' ) pdb_lines.append('' ) return "\n".join(_lowercase ) def _A ( _lowercase ) -> np.ndarray: """simple docstring""" return residue_constants.STANDARD_ATOM_MASK[prot.aatype] def _A ( _lowercase , _lowercase , _lowercase = None , _lowercase = None , _lowercase = None , _lowercase = None , _lowercase = None , ) -> Protein: """simple docstring""" return Protein( aatype=features['aatype'] , atom_positions=result['final_atom_positions'] , atom_mask=result['final_atom_mask'] , residue_index=features['residue_index'] + 1 , b_factors=b_factors if b_factors is not None else np.zeros_like(result['final_atom_mask'] ) , chain_index=_lowercase , remark=_lowercase , parents=_lowercase , parents_chain_index=_lowercase , )

import string def _A ( _lowercase ) -> None: """simple docstring""" for key in range(len(string.ascii_uppercase ) ): __UpperCamelCase = '' for symbol in message: if symbol in string.ascii_uppercase: __UpperCamelCase = string.ascii_uppercase.find(_lowercase ) __UpperCamelCase = num - key if num < 0: __UpperCamelCase = num + len(string.ascii_uppercase ) __UpperCamelCase = translated + string.ascii_uppercase[num] else: __UpperCamelCase = translated + symbol print(f'''Decryption using Key #{key}: {translated}''' ) def _A ( ) -> None: """simple docstring""" __UpperCamelCase = input('Encrypted message: ' ) __UpperCamelCase = message.upper() decrypt(_lowercase ) if __name__ == "__main__": import doctest doctest.testmod() main()

import argparse from transformers import ( TapasConfig, TapasForMaskedLM, TapasForQuestionAnswering, TapasForSequenceClassification, TapasModel, TapasTokenizer, load_tf_weights_in_tapas, ) from transformers.utils import logging logging.set_verbosity_info() def __lowercase ( snake_case, snake_case, snake_case, snake_case, snake_case ): """simple docstring""" __magic_name__ :Tuple = TapasConfig.from_json_file(snake_case ) # set absolute/relative position embeddings parameter __magic_name__ :Optional[int] = reset_position_index_per_cell # set remaining parameters of TapasConfig as well as the model based on the task if task == "SQA": __magic_name__ :Any = TapasForQuestionAnswering(config=snake_case ) elif task == "WTQ": # run_task_main.py hparams __magic_name__ :Any = 4 __magic_name__ :int = True # hparam_utils.py hparams __magic_name__ :int = 0.66_4694 __magic_name__ :str = 0.20_7951 __magic_name__ :List[Any] = 0.12_1194 __magic_name__ :List[Any] = True __magic_name__ :int = True __magic_name__ :Tuple = False __magic_name__ :Tuple = 0.035_2513 __magic_name__ :str = TapasForQuestionAnswering(config=snake_case ) elif task == "WIKISQL_SUPERVISED": # run_task_main.py hparams __magic_name__ :Optional[Any] = 4 __magic_name__ :Union[str, Any] = False # hparam_utils.py hparams __magic_name__ :Optional[int] = 36.4519 __magic_name__ :Dict = 0.90_3421 __magic_name__ :Any = 222.088 __magic_name__ :str = True __magic_name__ :int = True __magic_name__ :int = True __magic_name__ :List[str] = 0.76_3141 __magic_name__ :Optional[Any] = TapasForQuestionAnswering(config=snake_case ) elif task == "TABFACT": __magic_name__ :str = TapasForSequenceClassification(config=snake_case ) elif task == "MLM": __magic_name__ :Any = TapasForMaskedLM(config=snake_case ) elif task == "INTERMEDIATE_PRETRAINING": __magic_name__ :str = TapasModel(config=snake_case ) else: raise ValueError(f'''Task {task} not supported.''' ) print(f'''Building PyTorch model from configuration: {config}''' ) # Load weights from tf checkpoint load_tf_weights_in_tapas(snake_case, snake_case, snake_case ) # Save pytorch-model (weights and configuration) print(f'''Save PyTorch model to {pytorch_dump_path}''' ) model.save_pretrained(snake_case ) # Save tokenizer files print(f'''Save tokenizer files to {pytorch_dump_path}''' ) __magic_name__ :List[Any] = TapasTokenizer(vocab_file=tf_checkpoint_path[:-1_0] + '''vocab.txt''', model_max_length=5_1_2 ) tokenizer.save_pretrained(snake_case ) print('''Used relative position embeddings:''', model.config.reset_position_index_per_cell ) if __name__ == "__main__": SCREAMING_SNAKE_CASE__ : Any = argparse.ArgumentParser() # Required parameters parser.add_argument( """--task""", default="""SQA""", type=str, help="""Model task for which to convert a checkpoint. Defaults to SQA.""" ) parser.add_argument( """--reset_position_index_per_cell""", default=False, action="""store_true""", help="""Whether to use relative position embeddings or not. Defaults to True.""", ) parser.add_argument( """--tf_checkpoint_path""", default=None, type=str, required=True, help="""Path to the TensorFlow checkpoint path.""" ) parser.add_argument( """--tapas_config_file""", default=None, type=str, required=True, help=( """The config json file corresponding to the pre-trained TAPAS model. \n""" """This specifies the model architecture.""" ), ) parser.add_argument( """--pytorch_dump_path""", default=None, type=str, required=True, help="""Path to the output PyTorch model.""" ) SCREAMING_SNAKE_CASE__ : int = parser.parse_args() convert_tf_checkpoint_to_pytorch( args.task, args.reset_position_index_per_cell, args.tf_checkpoint_path, args.tapas_config_file, args.pytorch_dump_path, )

import gc import random import unittest import numpy as np import torch from PIL import Image from transformers import XLMRobertaTokenizerFast from diffusers import DDIMScheduler, KandinskyInpaintPipeline, KandinskyPriorPipeline, UNetaDConditionModel, VQModel from diffusers.pipelines.kandinsky.text_encoder import MCLIPConfig, MultilingualCLIP from diffusers.utils import floats_tensor, load_image, load_numpy, slow, torch_device from diffusers.utils.testing_utils import enable_full_determinism, require_torch_gpu from ..test_pipelines_common import PipelineTesterMixin, assert_mean_pixel_difference enable_full_determinism() class __lowerCamelCase (_a , unittest.TestCase ): _lowercase = KandinskyInpaintPipeline _lowercase = ["""prompt""", """image_embeds""", """negative_image_embeds""", """image""", """mask_image"""] _lowercase = [ """prompt""", """negative_prompt""", """image_embeds""", """negative_image_embeds""", """image""", """mask_image""", ] _lowercase = [ """generator""", """height""", """width""", """latents""", """guidance_scale""", """negative_prompt""", """num_inference_steps""", """return_dict""", """guidance_scale""", """num_images_per_prompt""", """output_type""", """return_dict""", ] _lowercase = False @property def snake_case_ ( self: int ): '''simple docstring''' return 32 @property def snake_case_ ( self: str ): '''simple docstring''' return 32 @property def snake_case_ ( self: Tuple ): '''simple docstring''' return self.time_input_dim @property def snake_case_ ( self: Union[str, Any] ): '''simple docstring''' return self.time_input_dim * 4 @property def snake_case_ ( self: Optional[int] ): '''simple docstring''' return 100 @property def snake_case_ ( self: str ): '''simple docstring''' __UpperCamelCase = XLMRobertaTokenizerFast.from_pretrained('YiYiXu/tiny-random-mclip-base' ) return tokenizer @property def snake_case_ ( self: Any ): '''simple docstring''' torch.manual_seed(0 ) __UpperCamelCase = MCLIPConfig( numDims=self.cross_attention_dim,transformerDimensions=self.text_embedder_hidden_size,hidden_size=self.text_embedder_hidden_size,intermediate_size=37,num_attention_heads=4,num_hidden_layers=5,vocab_size=1005,) __UpperCamelCase = MultilingualCLIP(A_ ) __UpperCamelCase = text_encoder.eval() return text_encoder @property def snake_case_ ( self: Any ): '''simple docstring''' torch.manual_seed(0 ) __UpperCamelCase = { 'in_channels': 9, # Out channels is double in channels because predicts mean and variance 'out_channels': 8, 'addition_embed_type': 'text_image', 'down_block_types': ('ResnetDownsampleBlock2D', 'SimpleCrossAttnDownBlock2D'), 'up_block_types': ('SimpleCrossAttnUpBlock2D', 'ResnetUpsampleBlock2D'), 'mid_block_type': 'UNetMidBlock2DSimpleCrossAttn', 'block_out_channels': (self.block_out_channels_a, self.block_out_channels_a * 2), 'layers_per_block': 1, 'encoder_hid_dim': self.text_embedder_hidden_size, 'encoder_hid_dim_type': 'text_image_proj', 'cross_attention_dim': self.cross_attention_dim, 'attention_head_dim': 4, 'resnet_time_scale_shift': 'scale_shift', 'class_embed_type': None, } __UpperCamelCase = UNetaDConditionModel(**A_ ) return model @property def snake_case_ ( self: str ): '''simple docstring''' return { "block_out_channels": [32, 64], "down_block_types": ["DownEncoderBlock2D", "AttnDownEncoderBlock2D"], "in_channels": 3, "latent_channels": 4, "layers_per_block": 1, "norm_num_groups": 8, "norm_type": "spatial", "num_vq_embeddings": 12, "out_channels": 3, "up_block_types": [ "AttnUpDecoderBlock2D", "UpDecoderBlock2D", ], "vq_embed_dim": 4, } @property def snake_case_ ( self: str ): '''simple docstring''' torch.manual_seed(0 ) __UpperCamelCase = VQModel(**self.dummy_movq_kwargs ) return model def snake_case_ ( self: Dict ): '''simple docstring''' __UpperCamelCase = self.dummy_text_encoder __UpperCamelCase = self.dummy_tokenizer __UpperCamelCase = self.dummy_unet __UpperCamelCase = self.dummy_movq __UpperCamelCase = DDIMScheduler( num_train_timesteps=1000,beta_schedule='linear',beta_start=0.0_0_0_8_5,beta_end=0.0_1_2,clip_sample=A_,set_alpha_to_one=A_,steps_offset=1,prediction_type='epsilon',thresholding=A_,) __UpperCamelCase = { 'text_encoder': text_encoder, 'tokenizer': tokenizer, 'unet': unet, 'scheduler': scheduler, 'movq': movq, } return components def snake_case_ ( self: Tuple,A_: Optional[int],A_: Dict=0 ): '''simple docstring''' __UpperCamelCase = floats_tensor((1, self.cross_attention_dim),rng=random.Random(A_ ) ).to(A_ ) __UpperCamelCase = floats_tensor((1, self.cross_attention_dim),rng=random.Random(seed + 1 ) ).to(A_ ) # create init_image __UpperCamelCase = floats_tensor((1, 3, 64, 64),rng=random.Random(A_ ) ).to(A_ ) __UpperCamelCase = image.cpu().permute(0,2,3,1 )[0] __UpperCamelCase = Image.fromarray(np.uinta(A_ ) ).convert('RGB' ).resize((256, 256) ) # create mask __UpperCamelCase = np.ones((64, 64),dtype=np.floataa ) __UpperCamelCase = 0 if str(A_ ).startswith('mps' ): __UpperCamelCase = torch.manual_seed(A_ ) else: __UpperCamelCase = torch.Generator(device=A_ ).manual_seed(A_ ) __UpperCamelCase = { 'prompt': 'horse', 'image': init_image, 'mask_image': mask, 'image_embeds': image_embeds, 'negative_image_embeds': negative_image_embeds, 'generator': generator, 'height': 64, 'width': 64, 'num_inference_steps': 2, 'guidance_scale': 4.0, 'output_type': 'np', } return inputs def snake_case_ ( self: Any ): '''simple docstring''' __UpperCamelCase = 'cpu' __UpperCamelCase = self.get_dummy_components() __UpperCamelCase = self.pipeline_class(**A_ ) __UpperCamelCase = pipe.to(A_ ) pipe.set_progress_bar_config(disable=A_ ) __UpperCamelCase = pipe(**self.get_dummy_inputs(A_ ) ) __UpperCamelCase = output.images __UpperCamelCase = pipe( **self.get_dummy_inputs(A_ ),return_dict=A_,)[0] __UpperCamelCase = image[0, -3:, -3:, -1] __UpperCamelCase = image_from_tuple[0, -3:, -3:, -1] print(F'''image.shape {image.shape}''' ) assert image.shape == (1, 64, 64, 3) __UpperCamelCase = np.array( [0.8_3_2_6_9_1_9, 0.7_3_7_9_0_4_6_7, 0.2_0_9_1_8_5_8_1, 0.9_3_0_9_6_1_2, 0.5_5_1_1_7_9_1, 0.4_3_7_1_3_3_2_8, 0.5_5_1_3_3_2_1, 0.4_9_9_2_2_9_3_4, 0.5_9_4_9_7_7_8_6] ) assert ( np.abs(image_slice.flatten() - expected_slice ).max() < 1E-2 ), F''' expected_slice {expected_slice}, but got {image_slice.flatten()}''' assert ( np.abs(image_from_tuple_slice.flatten() - expected_slice ).max() < 1E-2 ), F''' expected_slice {expected_slice}, but got {image_from_tuple_slice.flatten()}''' def snake_case_ ( self: Optional[Any] ): '''simple docstring''' super().test_inference_batch_single_identical(expected_max_diff=3E-3 ) @slow @require_torch_gpu class __lowerCamelCase (unittest.TestCase ): def snake_case_ ( self: Tuple ): '''simple docstring''' super().tearDown() gc.collect() torch.cuda.empty_cache() def snake_case_ ( self: Any ): '''simple docstring''' __UpperCamelCase = load_numpy( 'https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main' '/kandinsky/kandinsky_inpaint_cat_with_hat_fp16.npy' ) __UpperCamelCase = load_image( 'https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main' '/kandinsky/cat.png' ) __UpperCamelCase = np.ones((768, 768),dtype=np.floataa ) __UpperCamelCase = 0 __UpperCamelCase = 'a hat' __UpperCamelCase = KandinskyPriorPipeline.from_pretrained( 'kandinsky-community/kandinsky-2-1-prior',torch_dtype=torch.floataa ) pipe_prior.to(A_ ) __UpperCamelCase = KandinskyInpaintPipeline.from_pretrained( 'kandinsky-community/kandinsky-2-1-inpaint',torch_dtype=torch.floataa ) __UpperCamelCase = pipeline.to(A_ ) pipeline.set_progress_bar_config(disable=A_ ) __UpperCamelCase = torch.Generator(device='cpu' ).manual_seed(0 ) __UpperCamelCase, __UpperCamelCase = pipe_prior( A_,generator=A_,num_inference_steps=5,negative_prompt='',).to_tuple() __UpperCamelCase = pipeline( A_,image=A_,mask_image=A_,image_embeds=A_,negative_image_embeds=A_,generator=A_,num_inference_steps=100,height=768,width=768,output_type='np',) __UpperCamelCase = output.images[0] assert image.shape == (768, 768, 3) assert_mean_pixel_difference(A_,A_ )

from __future__ import annotations def SCREAMING_SNAKE_CASE_ ( _snake_case :list[int] , _snake_case :int ) -> bool: if len(_snake_case ) == 0: return False _A = len(_snake_case ) // 2 if a_list[midpoint] == item: return True if item < a_list[midpoint]: return binary_search(a_list[:midpoint] , _snake_case ) else: return binary_search(a_list[midpoint + 1 :] , _snake_case ) if __name__ == "__main__": UpperCAmelCase_ = input("""Enter numbers separated by comma:\n""").strip() UpperCAmelCase_ = [int(item.strip()) for item in user_input.split(""",""")] UpperCAmelCase_ = int(input("""Enter the number to be found in the list:\n""").strip()) UpperCAmelCase_ = """""" if binary_search(sequence, target) else """not """ print(f'{target} was {not_str}found in {sequence}')

from typing import Any class __lowerCamelCase : def __init__( self: int,A_: Any ): '''simple docstring''' __UpperCamelCase = data __UpperCamelCase = None def __repr__( self: Any ): '''simple docstring''' return F'''Node({self.data})''' class __lowerCamelCase : def __init__( self: Union[str, Any] ): '''simple docstring''' __UpperCamelCase = None def __iter__( self: int ): '''simple docstring''' __UpperCamelCase = self.head while node: yield node.data __UpperCamelCase = node.next def __len__( self: List[str] ): '''simple docstring''' return sum(1 for _ in self ) def __repr__( self: Any ): '''simple docstring''' return "->".join([str(A_ ) for item in self] ) def __getitem__( self: int,A_: int ): '''simple docstring''' if not 0 <= index < len(self ): raise ValueError('list index out of range.' ) for i, node in enumerate(self ): if i == index: return node return None def __setitem__( self: int,A_: int,A_: Any ): '''simple docstring''' if not 0 <= index < len(self ): raise ValueError('list index out of range.' ) __UpperCamelCase = self.head for _ in range(A_ ): __UpperCamelCase = current.next __UpperCamelCase = data def snake_case_ ( self: Union[str, Any],A_: Any ): '''simple docstring''' self.insert_nth(len(self ),A_ ) def snake_case_ ( self: List[Any],A_: Any ): '''simple docstring''' self.insert_nth(0,A_ ) def snake_case_ ( self: Optional[Any],A_: int,A_: Any ): '''simple docstring''' if not 0 <= index <= len(self ): raise IndexError('list index out of range' ) __UpperCamelCase = Node(A_ ) if self.head is None: __UpperCamelCase = new_node elif index == 0: __UpperCamelCase = self.head # link new_node to head __UpperCamelCase = new_node else: __UpperCamelCase = self.head for _ in range(index - 1 ): __UpperCamelCase = temp.next __UpperCamelCase = temp.next __UpperCamelCase = new_node def snake_case_ ( self: str ): # print every node data '''simple docstring''' print(self ) def snake_case_ ( self: int ): '''simple docstring''' return self.delete_nth(0 ) def snake_case_ ( self: str ): # delete from tail '''simple docstring''' return self.delete_nth(len(self ) - 1 ) def snake_case_ ( self: Any,A_: int = 0 ): '''simple docstring''' if not 0 <= index <= len(self ) - 1: # test if index is valid raise IndexError('List index out of range.' ) __UpperCamelCase = self.head # default first node if index == 0: __UpperCamelCase = self.head.next else: __UpperCamelCase = self.head for _ in range(index - 1 ): __UpperCamelCase = temp.next __UpperCamelCase = temp.next __UpperCamelCase = temp.next.next return delete_node.data def snake_case_ ( self: Any ): '''simple docstring''' return self.head is None def snake_case_ ( self: Optional[int] ): '''simple docstring''' __UpperCamelCase = None __UpperCamelCase = self.head while current: # Store the current node's next node. __UpperCamelCase = current.next # Make the current node's next point backwards __UpperCamelCase = prev # Make the previous node be the current node __UpperCamelCase = current # Make the current node the next node (to progress iteration) __UpperCamelCase = next_node # Return prev in order to put the head at the end __UpperCamelCase = prev def _A ( ) -> None: """simple docstring""" __UpperCamelCase = LinkedList() assert linked_list.is_empty() is True assert str(_lowercase ) == "" try: linked_list.delete_head() raise AssertionError # This should not happen. except IndexError: assert True # This should happen. try: linked_list.delete_tail() raise AssertionError # This should not happen. except IndexError: assert True # This should happen. for i in range(10 ): assert len(_lowercase ) == i linked_list.insert_nth(_lowercase , i + 1 ) assert str(_lowercase ) == "->".join(str(_lowercase ) for i in range(1 , 11 ) ) linked_list.insert_head(0 ) linked_list.insert_tail(11 ) assert str(_lowercase ) == "->".join(str(_lowercase ) for i in range(0 , 12 ) ) assert linked_list.delete_head() == 0 assert linked_list.delete_nth(9 ) == 10 assert linked_list.delete_tail() == 11 assert len(_lowercase ) == 9 assert str(_lowercase ) == "->".join(str(_lowercase ) for i in range(1 , 10 ) ) assert all(linked_list[i] == i + 1 for i in range(0 , 9 ) ) is True for i in range(0 , 9 ): __UpperCamelCase = -i assert all(linked_list[i] == -i for i in range(0 , 9 ) ) is True linked_list.reverse() assert str(_lowercase ) == "->".join(str(_lowercase ) for i in range(-8 , 1 ) ) def _A ( ) -> None: """simple docstring""" __UpperCamelCase = [ -9, 1_00, Node(77_34_51_12 ), 'dlrow olleH', 7, 55_55, 0, -1_92.5_55_55, 'Hello, world!', 77.9, Node(10 ), None, None, 12.20, ] __UpperCamelCase = LinkedList() for i in test_input: linked_list.insert_tail(_lowercase ) # Check if it's empty or not assert linked_list.is_empty() is False assert ( str(_lowercase ) == "-9->100->Node(77345112)->dlrow olleH->7->5555->0->" "-192.55555->Hello, world!->77.9->Node(10)->None->None->12.2" ) # Delete the head __UpperCamelCase = linked_list.delete_head() assert result == -9 assert ( str(_lowercase ) == "100->Node(77345112)->dlrow olleH->7->5555->0->-192.55555->" "Hello, world!->77.9->Node(10)->None->None->12.2" ) # Delete the tail __UpperCamelCase = linked_list.delete_tail() assert result == 12.2 assert ( str(_lowercase ) == "100->Node(77345112)->dlrow olleH->7->5555->0->-192.55555->" "Hello, world!->77.9->Node(10)->None->None" ) # Delete a node in specific location in linked list __UpperCamelCase = linked_list.delete_nth(10 ) assert result is None assert ( str(_lowercase ) == "100->Node(77345112)->dlrow olleH->7->5555->0->-192.55555->" "Hello, world!->77.9->Node(10)->None" ) # Add a Node instance to its head linked_list.insert_head(Node('Hello again, world!' ) ) assert ( str(_lowercase ) == "Node(Hello again, world!)->100->Node(77345112)->dlrow olleH->" "7->5555->0->-192.55555->Hello, world!->77.9->Node(10)->None" ) # Add None to its tail linked_list.insert_tail(_lowercase ) assert ( str(_lowercase ) == "Node(Hello again, world!)->100->Node(77345112)->dlrow olleH->" "7->5555->0->-192.55555->Hello, world!->77.9->Node(10)->None->None" ) # Reverse the linked list linked_list.reverse() assert ( str(_lowercase ) == "None->None->Node(10)->77.9->Hello, world!->-192.55555->0->5555->" "7->dlrow olleH->Node(77345112)->100->Node(Hello again, world!)" ) def _A ( ) -> List[str]: """simple docstring""" from doctest import testmod testmod() __UpperCamelCase = LinkedList() linked_list.insert_head(input('Inserting 1st at head ' ).strip() ) linked_list.insert_head(input('Inserting 2nd at head ' ).strip() ) print('\nPrint list:' ) linked_list.print_list() linked_list.insert_tail(input('\nInserting 1st at tail ' ).strip() ) linked_list.insert_tail(input('Inserting 2nd at tail ' ).strip() ) print('\nPrint list:' ) linked_list.print_list() print('\nDelete head' ) linked_list.delete_head() print('Delete tail' ) linked_list.delete_tail() print('\nPrint list:' ) linked_list.print_list() print('\nReverse linked list' ) linked_list.reverse() print('\nPrint list:' ) linked_list.print_list() print('\nString representation of linked list:' ) print(_lowercase ) print('\nReading/changing Node data using indexing:' ) print(f'''Element at Position 1: {linked_list[1]}''' ) __UpperCamelCase = input('Enter New Value: ' ).strip() print('New list:' ) print(_lowercase ) print(f'''length of linked_list is : {len(_lowercase )}''' ) if __name__ == "__main__": main()

'''simple docstring''' import math import qiskit def A_( A : int = 1 , A : int = 1 , A : int = 1): if ( isinstance(A , A) or isinstance(A , A) or isinstance(A , A) ): raise TypeError('inputs must be integers.') if (input_a < 0) or (input_a < 0) or (carry_in < 0): raise ValueError('inputs must be positive.') if ( (math.floor(A) != input_a) or (math.floor(A) != input_a) or (math.floor(A) != carry_in) ): raise ValueError('inputs must be exact integers.') if (input_a > 2) or (input_a > 2) or (carry_in > 2): raise ValueError('inputs must be less or equal to 2.') # build registers UpperCamelCase = qiskit.QuantumRegister(4 , 'qr') UpperCamelCase = qiskit.ClassicalRegister(2 , 'cr') # list the entries UpperCamelCase = [input_a, input_a, carry_in] UpperCamelCase = qiskit.QuantumCircuit(A , A) for i in range(0 , 3): if entry[i] == 2: quantum_circuit.h(A) # for hadamard entries elif entry[i] == 1: quantum_circuit.x(A) # for 1 entries elif entry[i] == 0: quantum_circuit.i(A) # for 0 entries # build the circuit quantum_circuit.ccx(0 , 1 , 3) # ccx = toffoli gate quantum_circuit.cx(0 , 1) quantum_circuit.ccx(1 , 2 , 3) quantum_circuit.cx(1 , 2) quantum_circuit.cx(0 , 1) quantum_circuit.measure([2, 3] , A) # measure the last two qbits UpperCamelCase = qiskit.Aer.get_backend('aer_simulator') UpperCamelCase = qiskit.execute(A , A , shots=1000) return job.result().get_counts(A) if __name__ == "__main__": print(f"""Total sum count for state is: {quantum_full_adder(1, 1, 1)}""")

from typing import TYPE_CHECKING from ...utils import ( OptionalDependencyNotAvailable, _LazyModule, is_flax_available, is_tf_available, is_torch_available, ) __snake_case = {'''configuration_unispeech''': ['''UNISPEECH_PRETRAINED_CONFIG_ARCHIVE_MAP''', '''UniSpeechConfig''']} try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __snake_case = [ '''UNISPEECH_PRETRAINED_MODEL_ARCHIVE_LIST''', '''UniSpeechForCTC''', '''UniSpeechForPreTraining''', '''UniSpeechForSequenceClassification''', '''UniSpeechModel''', '''UniSpeechPreTrainedModel''', ] if TYPE_CHECKING: from .configuration_unispeech import UNISPEECH_PRETRAINED_CONFIG_ARCHIVE_MAP, UniSpeechConfig try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_unispeech import ( UNISPEECH_PRETRAINED_MODEL_ARCHIVE_LIST, UniSpeechForCTC, UniSpeechForPreTraining, UniSpeechForSequenceClassification, UniSpeechModel, UniSpeechPreTrainedModel, ) else: import sys __snake_case = _LazyModule(__name__, globals()['''__file__'''], _import_structure, module_spec=__spec__)

"""simple docstring""" import os import sys import unittest __UpperCamelCase : List[Any] = os.path.abspath(os.path.dirname(os.path.dirname(os.path.dirname(__file__)))) sys.path.append(os.path.join(git_repo_path, '''utils''')) import get_test_info # noqa: E402 from get_test_info import ( # noqa: E402 get_model_to_test_mapping, get_model_to_tester_mapping, get_test_to_tester_mapping, ) __UpperCamelCase : Dict = os.path.join('''tests''', '''models''', '''bert''', '''test_modeling_bert.py''') __UpperCamelCase : int = os.path.join('''tests''', '''models''', '''blip''', '''test_modeling_blip.py''') class a ( unittest.TestCase ): def UpperCamelCase__ ( self ): """simple docstring""" lowerCAmelCase = get_test_to_tester_mapping(_snake_case ) lowerCAmelCase = get_test_to_tester_mapping(_snake_case ) lowerCAmelCase = {'BertModelTest': 'BertModelTester'} lowerCAmelCase = { 'BlipModelTest': 'BlipModelTester', 'BlipTextImageModelTest': 'BlipTextImageModelsModelTester', 'BlipTextModelTest': 'BlipTextModelTester', 'BlipTextRetrievalModelTest': 'BlipTextRetrievalModelTester', 'BlipVQAModelTest': 'BlipVQAModelTester', 'BlipVisionModelTest': 'BlipVisionModelTester', } self.assertEqual(get_test_info.to_json(_snake_case ) , _snake_case ) self.assertEqual(get_test_info.to_json(_snake_case ) , _snake_case ) def UpperCamelCase__ ( self ): """simple docstring""" lowerCAmelCase = get_model_to_test_mapping(_snake_case ) lowerCAmelCase = get_model_to_test_mapping(_snake_case ) lowerCAmelCase = { 'BertForMaskedLM': ['BertModelTest'], 'BertForMultipleChoice': ['BertModelTest'], 'BertForNextSentencePrediction': ['BertModelTest'], 'BertForPreTraining': ['BertModelTest'], 'BertForQuestionAnswering': ['BertModelTest'], 'BertForSequenceClassification': ['BertModelTest'], 'BertForTokenClassification': ['BertModelTest'], 'BertLMHeadModel': ['BertModelTest'], 'BertModel': ['BertModelTest'], } lowerCAmelCase = { 'BlipForConditionalGeneration': ['BlipTextImageModelTest'], 'BlipForImageTextRetrieval': ['BlipTextRetrievalModelTest'], 'BlipForQuestionAnswering': ['BlipVQAModelTest'], 'BlipModel': ['BlipModelTest'], 'BlipTextModel': ['BlipTextModelTest'], 'BlipVisionModel': ['BlipVisionModelTest'], } self.assertEqual(get_test_info.to_json(_snake_case ) , _snake_case ) self.assertEqual(get_test_info.to_json(_snake_case ) , _snake_case ) def UpperCamelCase__ ( self ): """simple docstring""" lowerCAmelCase = get_model_to_tester_mapping(_snake_case ) lowerCAmelCase = get_model_to_tester_mapping(_snake_case ) lowerCAmelCase = { 'BertForMaskedLM': ['BertModelTester'], 'BertForMultipleChoice': ['BertModelTester'], 'BertForNextSentencePrediction': ['BertModelTester'], 'BertForPreTraining': ['BertModelTester'], 'BertForQuestionAnswering': ['BertModelTester'], 'BertForSequenceClassification': ['BertModelTester'], 'BertForTokenClassification': ['BertModelTester'], 'BertLMHeadModel': ['BertModelTester'], 'BertModel': ['BertModelTester'], } lowerCAmelCase = { 'BlipForConditionalGeneration': ['BlipTextImageModelsModelTester'], 'BlipForImageTextRetrieval': ['BlipTextRetrievalModelTester'], 'BlipForQuestionAnswering': ['BlipVQAModelTester'], 'BlipModel': ['BlipModelTester'], 'BlipTextModel': ['BlipTextModelTester'], 'BlipVisionModel': ['BlipVisionModelTester'], } self.assertEqual(get_test_info.to_json(_snake_case ) , _snake_case ) self.assertEqual(get_test_info.to_json(_snake_case ) , _snake_case )

__snake_case = { '''a''': '''AAAAA''', '''b''': '''AAAAB''', '''c''': '''AAABA''', '''d''': '''AAABB''', '''e''': '''AABAA''', '''f''': '''AABAB''', '''g''': '''AABBA''', '''h''': '''AABBB''', '''i''': '''ABAAA''', '''j''': '''BBBAA''', '''k''': '''ABAAB''', '''l''': '''ABABA''', '''m''': '''ABABB''', '''n''': '''ABBAA''', '''o''': '''ABBAB''', '''p''': '''ABBBA''', '''q''': '''ABBBB''', '''r''': '''BAAAA''', '''s''': '''BAAAB''', '''t''': '''BAABA''', '''u''': '''BAABB''', '''v''': '''BBBAB''', '''w''': '''BABAA''', '''x''': '''BABAB''', '''y''': '''BABBA''', '''z''': '''BABBB''', ''' ''': ''' ''', } __snake_case = {value: key for key, value in encode_dict.items()} def _A ( _lowercase ) -> str: """simple docstring""" __UpperCamelCase = '' for letter in word.lower(): if letter.isalpha() or letter == " ": encoded += encode_dict[letter] else: raise Exception('encode() accepts only letters of the alphabet and spaces' ) return encoded def _A ( _lowercase ) -> str: """simple docstring""" if set(_lowercase ) - {"A", "B", " "} != set(): raise Exception('decode() accepts only \'A\', \'B\' and spaces' ) __UpperCamelCase = '' for word in coded.split(): while len(_lowercase ) != 0: decoded += decode_dict[word[:5]] __UpperCamelCase = word[5:] decoded += " " return decoded.strip() if __name__ == "__main__": from doctest import testmod testmod()

'''simple docstring''' from collections import OrderedDict from typing import Mapping from ...configuration_utils import PretrainedConfig from ...onnx import OnnxConfig from ...utils import logging _lowercase = logging.get_logger(__name__) _lowercase = { """facebook/data2vec-text-base""": """https://huggingface.co/data2vec/resolve/main/config.json""", } class UpperCAmelCase_ ( _SCREAMING_SNAKE_CASE ): '''simple docstring''' _lowercase : List[Any] = '''data2vec-text''' def __init__( self , _lowercase=30_522 , _lowercase=768 , _lowercase=12 , _lowercase=12 , _lowercase=3_072 , _lowercase="gelu" , _lowercase=0.1 , _lowercase=0.1 , _lowercase=512 , _lowercase=2 , _lowercase=0.02 , _lowercase=1e-12 , _lowercase=1 , _lowercase=0 , _lowercase=2 , _lowercase="absolute" , _lowercase=True , _lowercase=None , **_lowercase , ): """simple docstring""" super().__init__(pad_token_id=_lowercase , bos_token_id=_lowercase , eos_token_id=_lowercase , **_lowercase ) _lowerCAmelCase = vocab_size _lowerCAmelCase = hidden_size _lowerCAmelCase = num_hidden_layers _lowerCAmelCase = num_attention_heads _lowerCAmelCase = hidden_act _lowerCAmelCase = intermediate_size _lowerCAmelCase = hidden_dropout_prob _lowerCAmelCase = attention_probs_dropout_prob _lowerCAmelCase = max_position_embeddings _lowerCAmelCase = type_vocab_size _lowerCAmelCase = initializer_range _lowerCAmelCase = layer_norm_eps _lowerCAmelCase = position_embedding_type _lowerCAmelCase = use_cache _lowerCAmelCase = classifier_dropout class UpperCAmelCase_ ( _SCREAMING_SNAKE_CASE ): '''simple docstring''' @property def _lowercase ( self ): """simple docstring""" if self.task == "multiple-choice": _lowerCAmelCase = {0: """batch""", 1: """choice""", 2: """sequence"""} else: _lowerCAmelCase = {0: """batch""", 1: """sequence"""} return OrderedDict( [ ("""input_ids""", dynamic_axis), ("""attention_mask""", dynamic_axis), ] )

from collections.abc import Generator from math import sin def _A ( _lowercase ) -> bytes: """simple docstring""" if len(_lowercase ) != 32: raise ValueError('Input must be of length 32' ) __UpperCamelCase = B'' for i in [3, 2, 1, 0]: little_endian += string_aa[8 * i : 8 * i + 8] return little_endian def _A ( _lowercase ) -> bytes: """simple docstring""" if i < 0: raise ValueError('Input must be non-negative' ) __UpperCamelCase = format(_lowercase , '08x' )[-8:] __UpperCamelCase = 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 ( _lowercase ) -> bytes: """simple docstring""" __UpperCamelCase = B'' for char in message: bit_string += format(_lowercase , '08b' ).encode('utf-8' ) __UpperCamelCase = format(len(_lowercase ) , '064b' ).encode('utf-8' ) # Pad bit_string to a multiple of 512 chars bit_string += b"1" while len(_lowercase ) % 5_12 != 4_48: bit_string += b"0" bit_string += to_little_endian(start_len[32:] ) + to_little_endian(start_len[:32] ) return bit_string def _A ( _lowercase ) -> Generator[list[int], None, None]: """simple docstring""" if len(_lowercase ) % 5_12 != 0: raise ValueError('Input must have length that\'s a multiple of 512' ) for pos in range(0 , len(_lowercase ) , 5_12 ): __UpperCamelCase = bit_string[pos : pos + 5_12] __UpperCamelCase = [] for i in range(0 , 5_12 , 32 ): block_words.append(int(to_little_endian(block[i : i + 32] ) , 2 ) ) yield block_words def _A ( _lowercase ) -> int: """simple docstring""" if i < 0: raise ValueError('Input must be non-negative' ) __UpperCamelCase = format(_lowercase , '032b' ) __UpperCamelCase = '' for c in i_str: new_str += "1" if c == "0" else "0" return int(_lowercase , 2 ) def _A ( _lowercase , _lowercase ) -> int: """simple docstring""" return (a + b) % 2**32 def _A ( _lowercase , _lowercase ) -> int: """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 ( _lowercase ) -> bytes: """simple docstring""" __UpperCamelCase = preprocess(_lowercase ) __UpperCamelCase = [int(2**32 * abs(sin(i + 1 ) ) ) for i in range(64 )] # Starting states __UpperCamelCase = 0X67_45_23_01 __UpperCamelCase = 0Xef_cd_ab_89 __UpperCamelCase = 0X98_ba_dc_fe __UpperCamelCase = 0X10_32_54_76 __UpperCamelCase = [ 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(_lowercase ): __UpperCamelCase = aa __UpperCamelCase = ba __UpperCamelCase = ca __UpperCamelCase = da # Hash current chunk for i in range(64 ): if i <= 15: # f = (b & c) | (not_32(b) & d) # Alternate definition for f __UpperCamelCase = d ^ (b & (c ^ d)) __UpperCamelCase = i elif i <= 31: # f = (d & b) | (not_32(d) & c) # Alternate definition for f __UpperCamelCase = c ^ (d & (b ^ c)) __UpperCamelCase = (5 * i + 1) % 16 elif i <= 47: __UpperCamelCase = b ^ c ^ d __UpperCamelCase = (3 * i + 5) % 16 else: __UpperCamelCase = c ^ (b | not_aa(_lowercase )) __UpperCamelCase = (7 * i) % 16 __UpperCamelCase = (f + a + added_consts[i] + block_words[g]) % 2**32 __UpperCamelCase = d __UpperCamelCase = c __UpperCamelCase = b __UpperCamelCase = sum_aa(_lowercase , left_rotate_aa(_lowercase , shift_amounts[i] ) ) # Add hashed chunk to running total __UpperCamelCase = sum_aa(_lowercase , _lowercase ) __UpperCamelCase = sum_aa(_lowercase , _lowercase ) __UpperCamelCase = sum_aa(_lowercase , _lowercase ) __UpperCamelCase = sum_aa(_lowercase , _lowercase ) __UpperCamelCase = reformat_hex(_lowercase ) + reformat_hex(_lowercase ) + reformat_hex(_lowercase ) + reformat_hex(_lowercase ) return digest if __name__ == "__main__": import doctest doctest.testmod()

import warnings from typing import List, Optional, Union from ...processing_utils import ProcessorMixin from ...tokenization_utils_base import BatchEncoding, PaddingStrategy, PreTokenizedInput, TextInput, TruncationStrategy from ...utils import TensorType class UpperCamelCase_ ( UpperCamelCase__ ): lowerCamelCase_ = ["image_processor", "tokenizer"] lowerCamelCase_ = "LayoutLMv3ImageProcessor" lowerCamelCase_ = ("LayoutLMv3Tokenizer", "LayoutLMv3TokenizerFast") def __init__( self :Dict , __A :Union[str, Any]=None , __A :Union[str, Any]=None , **__A :Any ) -> List[Any]: """simple docstring""" SCREAMING_SNAKE_CASE__ = None if "feature_extractor" in kwargs: warnings.warn( """The `feature_extractor` argument is deprecated and will be removed in v5, use `image_processor`""" """ instead.""" , __A , ) SCREAMING_SNAKE_CASE__ = kwargs.pop("""feature_extractor""" ) SCREAMING_SNAKE_CASE__ = image_processor if image_processor is not None else feature_extractor if image_processor is None: raise ValueError("""You need to specify an `image_processor`.""" ) if tokenizer is None: raise ValueError("""You need to specify a `tokenizer`.""" ) super().__init__(__A , __A ) def __call__( self :Dict , __A :List[str] , __A :Union[TextInput, PreTokenizedInput, List[TextInput], List[PreTokenizedInput]] = None , __A :Optional[Union[PreTokenizedInput, List[PreTokenizedInput]]] = None , __A :Union[List[List[int]], List[List[List[int]]]] = None , __A :Optional[Union[List[int], List[List[int]]]] = None , __A :bool = True , __A :Union[bool, str, PaddingStrategy] = False , __A :Union[bool, str, TruncationStrategy] = None , __A :Optional[int] = None , __A :int = 0 , __A :Optional[int] = None , __A :Optional[bool] = None , __A :Optional[bool] = None , __A :bool = False , __A :bool = False , __A :bool = False , __A :bool = False , __A :bool = True , __A :Optional[Union[str, TensorType]] = None , **__A :Optional[Any] , ) -> BatchEncoding: """simple docstring""" if self.image_processor.apply_ocr and (boxes is not None): raise ValueError( """You cannot provide bounding boxes if you initialized the image processor with apply_ocr set to True.""" ) if self.image_processor.apply_ocr and (word_labels is not None): raise ValueError( """You cannot provide word labels if you initialized the image processor with apply_ocr set to True.""" ) # first, apply the image processor SCREAMING_SNAKE_CASE__ = self.image_processor(images=__A , return_tensors=__A ) # second, apply the tokenizer if text is not None and self.image_processor.apply_ocr and text_pair is None: if isinstance(__A , __A ): SCREAMING_SNAKE_CASE__ = [text] # add batch dimension (as the image processor always adds a batch dimension) SCREAMING_SNAKE_CASE__ = features["""words"""] SCREAMING_SNAKE_CASE__ = self.tokenizer( text=text if text is not None else features["""words"""] , text_pair=text_pair if text_pair is not None else None , boxes=boxes if boxes is not None else features["""boxes"""] , word_labels=__A , add_special_tokens=__A , padding=__A , truncation=__A , max_length=__A , stride=__A , pad_to_multiple_of=__A , return_token_type_ids=__A , return_attention_mask=__A , return_overflowing_tokens=__A , return_special_tokens_mask=__A , return_offsets_mapping=__A , return_length=__A , verbose=__A , return_tensors=__A , **__A , ) # add pixel values SCREAMING_SNAKE_CASE__ = features.pop("""pixel_values""" ) if return_overflowing_tokens is True: SCREAMING_SNAKE_CASE__ = self.get_overflowing_images(__A , encoded_inputs["""overflow_to_sample_mapping"""] ) SCREAMING_SNAKE_CASE__ = images return encoded_inputs def _snake_case ( self :str , __A :Optional[int] , __A :int ) -> Any: """simple docstring""" SCREAMING_SNAKE_CASE__ = [] for sample_idx in overflow_to_sample_mapping: images_with_overflow.append(images[sample_idx] ) if len(__A ) != len(__A ): raise ValueError( """Expected length of images to be the same as the length of `overflow_to_sample_mapping`, but got""" f''' {len(__A )} and {len(__A )}''' ) return images_with_overflow def _snake_case ( self :List[Any] , *__A :int , **__A :Optional[int] ) -> Any: """simple docstring""" return self.tokenizer.batch_decode(*__A , **__A ) def _snake_case ( self :Tuple , *__A :int , **__A :str ) -> Optional[Any]: """simple docstring""" return self.tokenizer.decode(*__A , **__A ) @property def _snake_case ( self :str ) -> Tuple: """simple docstring""" return ["input_ids", "bbox", "attention_mask", "pixel_values"] @property def _snake_case ( self :List[Any] ) -> Optional[Any]: """simple docstring""" warnings.warn( """`feature_extractor_class` is deprecated and will be removed in v5. Use `image_processor_class` instead.""" , __A , ) return self.image_processor_class @property def _snake_case ( self :Dict ) -> Any: """simple docstring""" warnings.warn( """`feature_extractor` is deprecated and will be removed in v5. Use `image_processor` instead.""" , __A , ) return self.image_processor

from __future__ import annotations import time from math import sqrt # 1 for manhattan, 0 for euclidean __snake_case = 0 __snake_case = [ [0, 0, 0, 0, 0, 0, 0], [0, 1, 0, 0, 0, 0, 0], # 0 are free path whereas 1's are obstacles [0, 0, 0, 0, 0, 0, 0], [0, 0, 1, 0, 0, 0, 0], [1, 0, 1, 0, 0, 0, 0], [0, 0, 0, 0, 0, 0, 0], [0, 0, 0, 0, 1, 0, 0], ] __snake_case = [[-1, 0], [0, -1], [1, 0], [0, 1]] # up, left, down, right __snake_case = tuple[int, int] class __lowerCamelCase : def __init__( self: str,A_: int,A_: int,A_: int,A_: int,A_: int,A_: Node | None,): '''simple docstring''' __UpperCamelCase = pos_x __UpperCamelCase = pos_y __UpperCamelCase = (pos_y, pos_x) __UpperCamelCase = goal_x __UpperCamelCase = goal_y __UpperCamelCase = g_cost __UpperCamelCase = parent __UpperCamelCase = self.calculate_heuristic() __UpperCamelCase = self.g_cost + self.h_cost def snake_case_ ( self: str ): '''simple docstring''' __UpperCamelCase = self.pos_x - self.goal_x __UpperCamelCase = self.pos_y - self.goal_y if HEURISTIC == 1: return abs(A_ ) + abs(A_ ) else: return sqrt(dy**2 + dx**2 ) def __lt__( self: int,A_: Node ): '''simple docstring''' return self.f_cost < other.f_cost class __lowerCamelCase : def __init__( self: Any,A_: TPosition,A_: TPosition ): '''simple docstring''' __UpperCamelCase = Node(start[1],start[0],goal[1],goal[0],0,A_ ) __UpperCamelCase = Node(goal[1],goal[0],goal[1],goal[0],9_9999,A_ ) __UpperCamelCase = [self.start] __UpperCamelCase = [] __UpperCamelCase = False def snake_case_ ( self: Any ): '''simple docstring''' while self.open_nodes: # Open Nodes are sorted using __lt__ self.open_nodes.sort() __UpperCamelCase = self.open_nodes.pop(0 ) if current_node.pos == self.target.pos: return self.retrace_path(A_ ) self.closed_nodes.append(A_ ) __UpperCamelCase = self.get_successors(A_ ) for child_node in successors: if child_node in self.closed_nodes: continue if child_node not in self.open_nodes: self.open_nodes.append(A_ ) else: # retrieve the best current path __UpperCamelCase = self.open_nodes.pop(self.open_nodes.index(A_ ) ) if child_node.g_cost < better_node.g_cost: self.open_nodes.append(A_ ) else: self.open_nodes.append(A_ ) return [self.start.pos] def snake_case_ ( self: int,A_: Node ): '''simple docstring''' __UpperCamelCase = [] for action in delta: __UpperCamelCase = parent.pos_x + action[1] __UpperCamelCase = parent.pos_y + action[0] if not (0 <= pos_x <= len(grid[0] ) - 1 and 0 <= pos_y <= len(A_ ) - 1): continue if grid[pos_y][pos_x] != 0: continue successors.append( Node( A_,A_,self.target.pos_y,self.target.pos_x,parent.g_cost + 1,A_,) ) return successors def snake_case_ ( self: Any,A_: Node | None ): '''simple docstring''' __UpperCamelCase = node __UpperCamelCase = [] while current_node is not None: path.append((current_node.pos_y, current_node.pos_x) ) __UpperCamelCase = current_node.parent path.reverse() return path class __lowerCamelCase : def __init__( self: List[Any],A_: TPosition,A_: TPosition ): '''simple docstring''' __UpperCamelCase = AStar(A_,A_ ) __UpperCamelCase = AStar(A_,A_ ) __UpperCamelCase = False def snake_case_ ( self: Union[str, Any] ): '''simple docstring''' while self.fwd_astar.open_nodes or self.bwd_astar.open_nodes: self.fwd_astar.open_nodes.sort() self.bwd_astar.open_nodes.sort() __UpperCamelCase = self.fwd_astar.open_nodes.pop(0 ) __UpperCamelCase = self.bwd_astar.open_nodes.pop(0 ) if current_bwd_node.pos == current_fwd_node.pos: return self.retrace_bidirectional_path( A_,A_ ) self.fwd_astar.closed_nodes.append(A_ ) self.bwd_astar.closed_nodes.append(A_ ) __UpperCamelCase = current_bwd_node __UpperCamelCase = current_fwd_node __UpperCamelCase = { self.fwd_astar: self.fwd_astar.get_successors(A_ ), self.bwd_astar: self.bwd_astar.get_successors(A_ ), } for astar in [self.fwd_astar, self.bwd_astar]: for child_node in successors[astar]: if child_node in astar.closed_nodes: continue if child_node not in astar.open_nodes: astar.open_nodes.append(A_ ) else: # retrieve the best current path __UpperCamelCase = astar.open_nodes.pop( astar.open_nodes.index(A_ ) ) if child_node.g_cost < better_node.g_cost: astar.open_nodes.append(A_ ) else: astar.open_nodes.append(A_ ) return [self.fwd_astar.start.pos] def snake_case_ ( self: List[str],A_: Node,A_: Node ): '''simple docstring''' __UpperCamelCase = self.fwd_astar.retrace_path(A_ ) __UpperCamelCase = self.bwd_astar.retrace_path(A_ ) bwd_path.pop() bwd_path.reverse() __UpperCamelCase = fwd_path + bwd_path return path if __name__ == "__main__": # all coordinates are given in format [y,x] __snake_case = (0, 0) __snake_case = (len(grid) - 1, len(grid[0]) - 1) for elem in grid: print(elem) __snake_case = time.time() __snake_case = AStar(init, goal) __snake_case = a_star.search() __snake_case = time.time() - start_time print(f"""AStar execution time = {end_time:f} seconds""") __snake_case = time.time() __snake_case = BidirectionalAStar(init, goal) __snake_case = time.time() - bd_start_time print(f"""BidirectionalAStar execution time = {bd_end_time:f} seconds""")

"""simple docstring""" import inspect import unittest from datasets import load_dataset from packaging import version from transformers import BeitConfig from transformers.models.auto import get_values from transformers.testing_utils import require_torch, require_torch_multi_gpu, require_vision, slow, torch_device from transformers.utils import cached_property, is_torch_available, is_vision_available from ...test_configuration_common import ConfigTester from ...test_modeling_common import ModelTesterMixin, _config_zero_init, floats_tensor, ids_tensor from ...test_pipeline_mixin import PipelineTesterMixin if is_torch_available(): import torch from torch import nn from transformers import ( MODEL_MAPPING, BeitForImageClassification, BeitForMaskedImageModeling, BeitForSemanticSegmentation, BeitModel, ) from transformers.models.beit.modeling_beit import BEIT_PRETRAINED_MODEL_ARCHIVE_LIST if is_vision_available(): import PIL from PIL import Image from transformers import BeitImageProcessor class lowercase_ : '''simple docstring''' def __init__( self : List[Any] , _UpperCAmelCase : Optional[int] , _UpperCAmelCase : Optional[int]=100 , _UpperCAmelCase : Tuple=13 , _UpperCAmelCase : Dict=30 , _UpperCAmelCase : str=2 , _UpperCAmelCase : int=3 , _UpperCAmelCase : Any=True , _UpperCAmelCase : Any=True , _UpperCAmelCase : Union[str, Any]=32 , _UpperCAmelCase : str=4 , _UpperCAmelCase : Tuple=4 , _UpperCAmelCase : str=37 , _UpperCAmelCase : List[str]="gelu" , _UpperCAmelCase : Optional[Any]=0.1 , _UpperCAmelCase : List[str]=0.1 , _UpperCAmelCase : Union[str, Any]=10 , _UpperCAmelCase : int=0.02 , _UpperCAmelCase : List[str]=3 , _UpperCAmelCase : int=None , _UpperCAmelCase : Union[str, Any]=[0, 1, 2, 3] , ): _A = parent _A = 100 _A = batch_size _A = image_size _A = patch_size _A = num_channels _A = is_training _A = use_labels _A = hidden_size _A = num_hidden_layers _A = num_attention_heads _A = intermediate_size _A = hidden_act _A = hidden_dropout_prob _A = attention_probs_dropout_prob _A = type_sequence_label_size _A = initializer_range _A = scope _A = out_indices _A = num_labels # in BeiT, the seq length equals the number of patches + 1 (we add 1 for the [CLS] token) _A = (image_size // patch_size) ** 2 _A = num_patches + 1 def lowerCAmelCase_ ( self : Dict ): _A = floats_tensor([self.batch_size, self.num_channels, self.image_size, self.image_size] ) _A = None _A = None if self.use_labels: _A = ids_tensor([self.batch_size] , self.type_sequence_label_size ) _A = ids_tensor([self.batch_size, self.image_size, self.image_size] , self.num_labels ) _A = self.get_config() return config, pixel_values, labels, pixel_labels def lowerCAmelCase_ ( self : Tuple ): return BeitConfig( vocab_size=self.vocab_size , image_size=self.image_size , patch_size=self.patch_size , num_channels=self.num_channels , 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 , is_decoder=_UpperCAmelCase , initializer_range=self.initializer_range , out_indices=self.out_indices , ) def lowerCAmelCase_ ( self : str , _UpperCAmelCase : Dict , _UpperCAmelCase : Optional[Any] , _UpperCAmelCase : Tuple , _UpperCAmelCase : List[Any] ): _A = BeitModel(config=_UpperCAmelCase ) model.to(_UpperCAmelCase ) model.eval() _A = model(_UpperCAmelCase ) self.parent.assertEqual(result.last_hidden_state.shape , (self.batch_size, self.seq_length, self.hidden_size) ) def lowerCAmelCase_ ( self : Optional[Any] , _UpperCAmelCase : Optional[Any] , _UpperCAmelCase : str , _UpperCAmelCase : Any , _UpperCAmelCase : Union[str, Any] ): _A = BeitForMaskedImageModeling(config=_UpperCAmelCase ) model.to(_UpperCAmelCase ) model.eval() _A = model(_UpperCAmelCase ) self.parent.assertEqual(result.logits.shape , (self.batch_size, self.seq_length - 1, self.vocab_size) ) def lowerCAmelCase_ ( self : Optional[int] , _UpperCAmelCase : Dict , _UpperCAmelCase : Dict , _UpperCAmelCase : Any , _UpperCAmelCase : Any ): _A = self.type_sequence_label_size _A = BeitForImageClassification(_UpperCAmelCase ) model.to(_UpperCAmelCase ) model.eval() _A = model(_UpperCAmelCase , labels=_UpperCAmelCase ) self.parent.assertEqual(result.logits.shape , (self.batch_size, self.type_sequence_label_size) ) # test greyscale images _A = 1 _A = BeitForImageClassification(_UpperCAmelCase ) model.to(_UpperCAmelCase ) model.eval() _A = floats_tensor([self.batch_size, 1, self.image_size, self.image_size] ) _A = model(_UpperCAmelCase , labels=_UpperCAmelCase ) self.parent.assertEqual(result.logits.shape , (self.batch_size, self.type_sequence_label_size) ) def lowerCAmelCase_ ( self : List[Any] , _UpperCAmelCase : Optional[Any] , _UpperCAmelCase : Optional[int] , _UpperCAmelCase : Optional[Any] , _UpperCAmelCase : Dict ): _A = self.num_labels _A = BeitForSemanticSegmentation(_UpperCAmelCase ) model.to(_UpperCAmelCase ) model.eval() _A = model(_UpperCAmelCase ) self.parent.assertEqual( result.logits.shape , (self.batch_size, self.num_labels, self.image_size * 2, self.image_size * 2) ) _A = model(_UpperCAmelCase , labels=_UpperCAmelCase ) self.parent.assertEqual( result.logits.shape , (self.batch_size, self.num_labels, self.image_size * 2, self.image_size * 2) ) def lowerCAmelCase_ ( self : Tuple ): _A = self.prepare_config_and_inputs() _A , _A , _A , _A = config_and_inputs _A = {'pixel_values': pixel_values} return config, inputs_dict @require_torch class lowercase_ ( __lowerCAmelCase , __lowerCAmelCase , unittest.TestCase ): '''simple docstring''' UpperCAmelCase : Optional[int] = ( (BeitModel, BeitForImageClassification, BeitForMaskedImageModeling, BeitForSemanticSegmentation) if is_torch_available() else () ) UpperCAmelCase : Union[str, Any] = ( { '''feature-extraction''': BeitModel, '''image-classification''': BeitForImageClassification, '''image-segmentation''': BeitForSemanticSegmentation, } if is_torch_available() else {} ) UpperCAmelCase : Any = False UpperCAmelCase : Any = False UpperCAmelCase : List[str] = False def lowerCAmelCase_ ( self : List[str] ): _A = BeitModelTester(self ) _A = ConfigTester(self , config_class=_UpperCAmelCase , has_text_modality=_UpperCAmelCase , hidden_size=37 ) def lowerCAmelCase_ ( self : Any ): self.config_tester.run_common_tests() @unittest.skip(reason='BEiT does not use inputs_embeds' ) def lowerCAmelCase_ ( self : str ): pass @require_torch_multi_gpu @unittest.skip(reason='BEiT has some layers using `add_module` which doesn\'t work well with `nn.DataParallel`' ) def lowerCAmelCase_ ( self : Dict ): pass def lowerCAmelCase_ ( self : List[str] ): _A , _A = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: _A = model_class(_UpperCAmelCase ) self.assertIsInstance(model.get_input_embeddings() , (nn.Module) ) _A = model.get_output_embeddings() self.assertTrue(x is None or isinstance(_UpperCAmelCase , nn.Linear ) ) def lowerCAmelCase_ ( self : Optional[Any] ): _A , _A = self.model_tester.prepare_config_and_inputs_for_common() for model_class in self.all_model_classes: _A = model_class(_UpperCAmelCase ) _A = inspect.signature(model.forward ) # signature.parameters is an OrderedDict => so arg_names order is deterministic _A = [*signature.parameters.keys()] _A = ['pixel_values'] self.assertListEqual(arg_names[:1] , _UpperCAmelCase ) def lowerCAmelCase_ ( self : List[str] ): _A = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_model(*_UpperCAmelCase ) def lowerCAmelCase_ ( self : Any ): _A = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_for_masked_lm(*_UpperCAmelCase ) def lowerCAmelCase_ ( self : Optional[Any] ): _A = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_for_image_classification(*_UpperCAmelCase ) def lowerCAmelCase_ ( self : Tuple ): _A = self.model_tester.prepare_config_and_inputs() self.model_tester.create_and_check_for_semantic_segmentation(*_UpperCAmelCase ) def lowerCAmelCase_ ( self : Any ): if not self.model_tester.is_training: return _A , _A = self.model_tester.prepare_config_and_inputs_for_common() _A = True for model_class in self.all_model_classes: # we don't test BeitForMaskedImageModeling if model_class in [*get_values(_UpperCAmelCase ), BeitForMaskedImageModeling]: continue _A = model_class(_UpperCAmelCase ) model.to(_UpperCAmelCase ) model.train() _A = self._prepare_for_class(_UpperCAmelCase , _UpperCAmelCase , return_labels=_UpperCAmelCase ) _A = model(**_UpperCAmelCase ).loss loss.backward() def lowerCAmelCase_ ( self : Optional[int] ): _A , _A = self.model_tester.prepare_config_and_inputs_for_common() if not self.model_tester.is_training: return _A = False _A = True for model_class in self.all_model_classes: # we don't test BeitForMaskedImageModeling if ( model_class in [*get_values(_UpperCAmelCase ), BeitForMaskedImageModeling] or not model_class.supports_gradient_checkpointing ): continue _A = model_class(_UpperCAmelCase ) model.gradient_checkpointing_enable() model.to(_UpperCAmelCase ) model.train() _A = self._prepare_for_class(_UpperCAmelCase , _UpperCAmelCase , return_labels=_UpperCAmelCase ) _A = model(**_UpperCAmelCase ).loss loss.backward() def lowerCAmelCase_ ( self : Any ): _A , _A = self.model_tester.prepare_config_and_inputs_for_common() _A = _config_zero_init(_UpperCAmelCase ) for model_class in self.all_model_classes: _A = model_class(config=_UpperCAmelCase ) for name, param in model.named_parameters(): # we skip lambda parameters as these require special initial values # determined by config.layer_scale_init_value if "lambda" in name: continue if param.requires_grad: self.assertIn( ((param.data.mean() * 1E9).round() / 1E9).item() , [0.0, 1.0] , msg=F'''Parameter {name} of model {model_class} seems not properly initialized''' , ) @slow def lowerCAmelCase_ ( self : Optional[Any] ): for model_name in BEIT_PRETRAINED_MODEL_ARCHIVE_LIST[:1]: _A = BeitModel.from_pretrained(_UpperCAmelCase ) self.assertIsNotNone(_UpperCAmelCase ) def _snake_case ( ) -> int: '''simple docstring''' _A = Image.open('./tests/fixtures/tests_samples/COCO/000000039769.png' ) return image @require_torch @require_vision class lowercase_ ( unittest.TestCase ): '''simple docstring''' @cached_property def lowerCAmelCase_ ( self : Optional[Any] ): return BeitImageProcessor.from_pretrained('microsoft/beit-base-patch16-224' ) if is_vision_available() else None @slow def lowerCAmelCase_ ( self : Any ): _A = BeitForMaskedImageModeling.from_pretrained('microsoft/beit-base-patch16-224-pt22k' ).to(_UpperCAmelCase ) _A = self.default_image_processor _A = prepare_img() _A = image_processor(images=_UpperCAmelCase , return_tensors='pt' ).pixel_values.to(_UpperCAmelCase ) # prepare bool_masked_pos _A = torch.ones((1, 196) , dtype=torch.bool ).to(_UpperCAmelCase ) # forward pass with torch.no_grad(): _A = model(pixel_values=_UpperCAmelCase , bool_masked_pos=_UpperCAmelCase ) _A = outputs.logits # verify the logits _A = torch.Size((1, 196, 8_192) ) self.assertEqual(logits.shape , _UpperCAmelCase ) _A = torch.tensor( [[-3.2437, 0.5072, -13.9174], [-3.2456, 0.4948, -13.9401], [-3.2033, 0.5121, -13.8550]] ).to(_UpperCAmelCase ) self.assertTrue(torch.allclose(logits[bool_masked_pos][:3, :3] , _UpperCAmelCase , atol=1E-2 ) ) @slow def lowerCAmelCase_ ( self : Optional[Any] ): _A = BeitForImageClassification.from_pretrained('microsoft/beit-base-patch16-224' ).to(_UpperCAmelCase ) _A = self.default_image_processor _A = prepare_img() _A = image_processor(images=_UpperCAmelCase , return_tensors='pt' ).to(_UpperCAmelCase ) # forward pass with torch.no_grad(): _A = model(**_UpperCAmelCase ) _A = outputs.logits # verify the logits _A = torch.Size((1, 1_000) ) self.assertEqual(logits.shape , _UpperCAmelCase ) _A = torch.tensor([-1.2385, -1.0987, -1.0108] ).to(_UpperCAmelCase ) self.assertTrue(torch.allclose(logits[0, :3] , _UpperCAmelCase , atol=1E-4 ) ) _A = 281 self.assertEqual(logits.argmax(-1 ).item() , _UpperCAmelCase ) @slow def lowerCAmelCase_ ( self : Dict ): _A = BeitForImageClassification.from_pretrained('microsoft/beit-large-patch16-224-pt22k-ft22k' ).to( _UpperCAmelCase ) _A = self.default_image_processor _A = prepare_img() _A = image_processor(images=_UpperCAmelCase , return_tensors='pt' ).to(_UpperCAmelCase ) # forward pass with torch.no_grad(): _A = model(**_UpperCAmelCase ) _A = outputs.logits # verify the logits _A = torch.Size((1, 21_841) ) self.assertEqual(logits.shape , _UpperCAmelCase ) _A = torch.tensor([1.6881, -0.2787, 0.5901] ).to(_UpperCAmelCase ) self.assertTrue(torch.allclose(logits[0, :3] , _UpperCAmelCase , atol=1E-4 ) ) _A = 2_396 self.assertEqual(logits.argmax(-1 ).item() , _UpperCAmelCase ) @slow def lowerCAmelCase_ ( self : Dict ): _A = BeitForSemanticSegmentation.from_pretrained('microsoft/beit-base-finetuned-ade-640-640' ) _A = model.to(_UpperCAmelCase ) _A = BeitImageProcessor(do_resize=_UpperCAmelCase , size=640 , do_center_crop=_UpperCAmelCase ) _A = load_dataset('hf-internal-testing/fixtures_ade20k' , split='test' ) _A = Image.open(ds[0]['file'] ) _A = image_processor(images=_UpperCAmelCase , return_tensors='pt' ).to(_UpperCAmelCase ) # forward pass with torch.no_grad(): _A = model(**_UpperCAmelCase ) _A = outputs.logits # verify the logits _A = torch.Size((1, 150, 160, 160) ) self.assertEqual(logits.shape , _UpperCAmelCase ) _A = version.parse(PIL.__version__ ) < version.parse('9.0.0' ) if is_pillow_less_than_a: _A = torch.tensor( [ [[-4.9225, -2.3954, -3.0522], [-2.8822, -1.0046, -1.7561], [-2.9549, -1.3228, -2.1347]], [[-5.8168, -3.4129, -4.0778], [-3.8651, -2.2214, -3.0277], [-3.8356, -2.4643, -3.3535]], [[-0.0078, 3.9952, 4.0754], [2.9856, 4.6944, 5.0035], [3.2413, 4.7813, 4.9969]], ] , device=_UpperCAmelCase , ) else: _A = torch.tensor( [ [[-4.8960, -2.3688, -3.0355], [-2.8478, -0.9836, -1.7418], [-2.9449, -1.3332, -2.1456]], [[-5.8081, -3.4124, -4.1006], [-3.8561, -2.2081, -3.0323], [-3.8365, -2.4601, -3.3669]], [[-0.0309, 3.9868, 4.0540], [2.9640, 4.6877, 4.9976], [3.2081, 4.7690, 4.9942]], ] , device=_UpperCAmelCase , ) self.assertTrue(torch.allclose(logits[0, :3, :3, :3] , _UpperCAmelCase , atol=1E-4 ) ) @slow def lowerCAmelCase_ ( self : List[Any] ): _A = BeitForSemanticSegmentation.from_pretrained('microsoft/beit-base-finetuned-ade-640-640' ) _A = model.to(_UpperCAmelCase ) _A = BeitImageProcessor(do_resize=_UpperCAmelCase , size=640 , do_center_crop=_UpperCAmelCase ) _A = load_dataset('hf-internal-testing/fixtures_ade20k' , split='test' ) _A = Image.open(ds[0]['file'] ) _A = image_processor(images=_UpperCAmelCase , return_tensors='pt' ).to(_UpperCAmelCase ) # forward pass with torch.no_grad(): _A = model(**_UpperCAmelCase ) _A = outputs.logits.detach().cpu() _A = image_processor.post_process_semantic_segmentation(outputs=_UpperCAmelCase , target_sizes=[(500, 300)] ) _A = torch.Size((500, 300) ) self.assertEqual(segmentation[0].shape , _UpperCAmelCase ) _A = image_processor.post_process_semantic_segmentation(outputs=_UpperCAmelCase ) _A = torch.Size((160, 160) ) self.assertEqual(segmentation[0].shape , _UpperCAmelCase )

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 AutoFeatureExtractor, WavaVecaFeatureExtractor 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_feature_extraction import CustomFeatureExtractor # noqa E402 __snake_case = get_tests_dir('''fixtures''') class __lowerCamelCase (unittest.TestCase ): def snake_case_ ( self: int ): '''simple docstring''' __UpperCamelCase = mock.Mock() __UpperCamelCase = 500 __UpperCamelCase = {} __UpperCamelCase = HTTPError __UpperCamelCase = {} # Download this model to make sure it's in the cache. __UpperCamelCase = WavaVecaFeatureExtractor.from_pretrained('hf-internal-testing/tiny-random-wav2vec2' ) # 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: __UpperCamelCase = WavaVecaFeatureExtractor.from_pretrained('hf-internal-testing/tiny-random-wav2vec2' ) # This check we did call the fake head request mock_head.assert_called() def snake_case_ ( self: Dict ): '''simple docstring''' __UpperCamelCase = WavaVecaFeatureExtractor.from_pretrained( 'https://huggingface.co/hf-internal-testing/tiny-random-wav2vec2/resolve/main/preprocessor_config.json' ) @is_staging_test class __lowerCamelCase (unittest.TestCase ): @classmethod def snake_case_ ( cls: Tuple ): '''simple docstring''' __UpperCamelCase = TOKEN HfFolder.save_token(A_ ) @classmethod def snake_case_ ( cls: Tuple ): '''simple docstring''' try: delete_repo(token=cls._token,repo_id='test-feature-extractor' ) except HTTPError: pass try: delete_repo(token=cls._token,repo_id='valid_org/test-feature-extractor-org' ) except HTTPError: pass try: delete_repo(token=cls._token,repo_id='test-dynamic-feature-extractor' ) except HTTPError: pass def snake_case_ ( self: Tuple ): '''simple docstring''' __UpperCamelCase = WavaVecaFeatureExtractor.from_pretrained(A_ ) feature_extractor.push_to_hub('test-feature-extractor',use_auth_token=self._token ) __UpperCamelCase = WavaVecaFeatureExtractor.from_pretrained(F'''{USER}/test-feature-extractor''' ) for k, v in feature_extractor.__dict__.items(): self.assertEqual(A_,getattr(A_,A_ ) ) # Reset repo delete_repo(token=self._token,repo_id='test-feature-extractor' ) # Push to hub via save_pretrained with tempfile.TemporaryDirectory() as tmp_dir: feature_extractor.save_pretrained( A_,repo_id='test-feature-extractor',push_to_hub=A_,use_auth_token=self._token ) __UpperCamelCase = WavaVecaFeatureExtractor.from_pretrained(F'''{USER}/test-feature-extractor''' ) for k, v in feature_extractor.__dict__.items(): self.assertEqual(A_,getattr(A_,A_ ) ) def snake_case_ ( self: List[str] ): '''simple docstring''' __UpperCamelCase = WavaVecaFeatureExtractor.from_pretrained(A_ ) feature_extractor.push_to_hub('valid_org/test-feature-extractor',use_auth_token=self._token ) __UpperCamelCase = WavaVecaFeatureExtractor.from_pretrained('valid_org/test-feature-extractor' ) for k, v in feature_extractor.__dict__.items(): self.assertEqual(A_,getattr(A_,A_ ) ) # Reset repo delete_repo(token=self._token,repo_id='valid_org/test-feature-extractor' ) # Push to hub via save_pretrained with tempfile.TemporaryDirectory() as tmp_dir: feature_extractor.save_pretrained( A_,repo_id='valid_org/test-feature-extractor-org',push_to_hub=A_,use_auth_token=self._token ) __UpperCamelCase = WavaVecaFeatureExtractor.from_pretrained('valid_org/test-feature-extractor-org' ) for k, v in feature_extractor.__dict__.items(): self.assertEqual(A_,getattr(A_,A_ ) ) def snake_case_ ( self: int ): '''simple docstring''' CustomFeatureExtractor.register_for_auto_class() __UpperCamelCase = CustomFeatureExtractor.from_pretrained(A_ ) feature_extractor.push_to_hub('test-dynamic-feature-extractor',use_auth_token=self._token ) # This has added the proper auto_map field to the config self.assertDictEqual( feature_extractor.auto_map,{'AutoFeatureExtractor': 'custom_feature_extraction.CustomFeatureExtractor'},) __UpperCamelCase = AutoFeatureExtractor.from_pretrained( F'''{USER}/test-dynamic-feature-extractor''',trust_remote_code=A_ ) # Can't make an isinstance check because the new_feature_extractor is from the CustomFeatureExtractor class of a dynamic module self.assertEqual(new_feature_extractor.__class__.__name__,'CustomFeatureExtractor' )

'''simple docstring''' from dataclasses import dataclass from typing import Optional, Tuple, Union import torch import torch.nn as nn from ..configuration_utils import ConfigMixin, register_to_config from ..utils import BaseOutput, apply_forward_hook from .modeling_utils import ModelMixin from .vae import Decoder, DecoderOutput, Encoder, VectorQuantizer @dataclass class SCREAMING_SNAKE_CASE (a__ ): lowerCAmelCase = 42 class SCREAMING_SNAKE_CASE (a__ , a__ ): @register_to_config def __init__( self , _UpperCAmelCase = 3 , _UpperCAmelCase = 3 , _UpperCAmelCase = ("DownEncoderBlock2D",) , _UpperCAmelCase = ("UpDecoderBlock2D",) , _UpperCAmelCase = (64,) , _UpperCAmelCase = 1 , _UpperCAmelCase = "silu" , _UpperCAmelCase = 3 , _UpperCAmelCase = 32 , _UpperCAmelCase = 256 , _UpperCAmelCase = 32 , _UpperCAmelCase = None , _UpperCAmelCase = 0.18215 , _UpperCAmelCase = "group" , ): '''simple docstring''' super().__init__() # pass init params to Encoder __A : Optional[int] = Encoder( in_channels=_UpperCAmelCase , out_channels=_UpperCAmelCase , down_block_types=_UpperCAmelCase , block_out_channels=_UpperCAmelCase , layers_per_block=_UpperCAmelCase , act_fn=_UpperCAmelCase , norm_num_groups=_UpperCAmelCase , double_z=_UpperCAmelCase , ) __A : Dict = vq_embed_dim if vq_embed_dim is not None else latent_channels __A : Union[str, Any] = nn.Convad(_UpperCAmelCase , _UpperCAmelCase , 1) __A : List[Any] = VectorQuantizer(_UpperCAmelCase , _UpperCAmelCase , beta=0.25 , remap=_UpperCAmelCase , sane_index_shape=_UpperCAmelCase) __A : Dict = nn.Convad(_UpperCAmelCase , _UpperCAmelCase , 1) # pass init params to Decoder __A : Any = Decoder( in_channels=_UpperCAmelCase , out_channels=_UpperCAmelCase , up_block_types=_UpperCAmelCase , block_out_channels=_UpperCAmelCase , layers_per_block=_UpperCAmelCase , act_fn=_UpperCAmelCase , norm_num_groups=_UpperCAmelCase , norm_type=_UpperCAmelCase , ) @apply_forward_hook def SCREAMING_SNAKE_CASE ( self , _UpperCAmelCase , _UpperCAmelCase = True): '''simple docstring''' __A : Optional[int] = self.encoder(_UpperCAmelCase) __A : str = self.quant_conv(_UpperCAmelCase) if not return_dict: return (h,) return VQEncoderOutput(latents=_UpperCAmelCase) @apply_forward_hook def SCREAMING_SNAKE_CASE ( self , _UpperCAmelCase , _UpperCAmelCase = False , _UpperCAmelCase = True): '''simple docstring''' if not force_not_quantize: __A ,__A ,__A : Dict = self.quantize(_UpperCAmelCase) else: __A : int = h __A : List[Any] = self.post_quant_conv(_UpperCAmelCase) __A : Union[str, Any] = self.decoder(_UpperCAmelCase , quant if self.config.norm_type == 'spatial' else None) if not return_dict: return (dec,) return DecoderOutput(sample=_UpperCAmelCase) def SCREAMING_SNAKE_CASE ( self , _UpperCAmelCase , _UpperCAmelCase = True): '''simple docstring''' __A : Any = sample __A : Optional[int] = self.encode(_UpperCAmelCase).latents __A : Union[str, Any] = self.decode(_UpperCAmelCase).sample if not return_dict: return (dec,) return DecoderOutput(sample=_UpperCAmelCase)

import argparse import json import os import evaluate import torch from datasets import load_dataset from torch.optim import AdamW from torch.utils.data import DataLoader from transformers import AutoModelForSequenceClassification, AutoTokenizer, get_linear_schedule_with_warmup, set_seed from accelerate import Accelerator, DistributedType from accelerate.utils.deepspeed import DummyOptim, DummyScheduler __snake_case = 1_6 __snake_case = 3_2 def _A ( _lowercase , _lowercase = 16 , _lowercase = "bert-base-cased" ) -> Union[str, Any]: """simple docstring""" __UpperCamelCase = AutoTokenizer.from_pretrained(_lowercase ) __UpperCamelCase = load_dataset('glue' , 'mrpc' ) def tokenize_function(_lowercase ): # max_length=None => use the model max length (it's actually the default) __UpperCamelCase = tokenizer(examples['sentence1'] , examples['sentence2'] , truncation=_lowercase , max_length=_lowercase ) return outputs # Apply the method we just defined to all the examples in all the splits of the dataset __UpperCamelCase = datasets.map( _lowercase , batched=_lowercase , remove_columns=['idx', 'sentence1', 'sentence2'] , load_from_cache_file=_lowercase ) # We also rename the 'label' column to 'labels' which is the expected name for labels by the models of the # transformers library __UpperCamelCase = tokenized_datasets.rename_column('label' , 'labels' ) def collate_fn(_lowercase ): # 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(_lowercase , padding='max_length' , max_length=1_28 , return_tensors='pt' ) return tokenizer.pad(_lowercase , padding='longest' , return_tensors='pt' ) # Instantiate dataloaders. __UpperCamelCase = DataLoader( tokenized_datasets['train'] , shuffle=_lowercase , collate_fn=_lowercase , batch_size=_lowercase ) __UpperCamelCase = DataLoader( tokenized_datasets['validation'] , shuffle=_lowercase , collate_fn=_lowercase , batch_size=_lowercase ) return train_dataloader, eval_dataloader def _A ( _lowercase , _lowercase ) -> int: """simple docstring""" __UpperCamelCase = Accelerator() # Sample hyper-parameters for learning rate, batch size, seed and a few other HPs __UpperCamelCase = config['lr'] __UpperCamelCase = int(config['num_epochs'] ) __UpperCamelCase = int(config['seed'] ) __UpperCamelCase = int(config['batch_size'] ) __UpperCamelCase = args.model_name_or_path set_seed(_lowercase ) __UpperCamelCase, __UpperCamelCase = get_dataloaders(_lowercase , _lowercase , _lowercase ) # Instantiate the model (we build the model here so that the seed also control new weights initialization) __UpperCamelCase = AutoModelForSequenceClassification.from_pretrained(_lowercase , return_dict=_lowercase ) # Instantiate optimizer __UpperCamelCase = ( AdamW if accelerator.state.deepspeed_plugin is None or 'optimizer' not in accelerator.state.deepspeed_plugin.deepspeed_config else DummyOptim ) __UpperCamelCase = optimizer_cls(params=model.parameters() , lr=_lowercase ) if accelerator.state.deepspeed_plugin is not None: __UpperCamelCase = accelerator.state.deepspeed_plugin.deepspeed_config[ 'gradient_accumulation_steps' ] else: __UpperCamelCase = 1 __UpperCamelCase = (len(_lowercase ) * num_epochs) // gradient_accumulation_steps # Instantiate scheduler if ( accelerator.state.deepspeed_plugin is None or "scheduler" not in accelerator.state.deepspeed_plugin.deepspeed_config ): __UpperCamelCase = get_linear_schedule_with_warmup( optimizer=_lowercase , num_warmup_steps=0 , num_training_steps=_lowercase , ) else: __UpperCamelCase = DummyScheduler(_lowercase , total_num_steps=_lowercase , warmup_num_steps=0 ) # Prepare everything # There is no specific order to remember, we just need to unpack the objects in the same order we gave them to the # prepare method. __UpperCamelCase, __UpperCamelCase, __UpperCamelCase, __UpperCamelCase, __UpperCamelCase = accelerator.prepare( _lowercase , _lowercase , _lowercase , _lowercase , _lowercase ) # We need to keep track of how many total steps we have iterated over __UpperCamelCase = 0 # We also need to keep track of the stating epoch so files are named properly __UpperCamelCase = 0 # Now we train the model __UpperCamelCase = evaluate.load('glue' , 'mrpc' ) __UpperCamelCase = 0 __UpperCamelCase = {} for epoch in range(_lowercase , _lowercase ): model.train() for step, batch in enumerate(_lowercase ): __UpperCamelCase = model(**_lowercase ) __UpperCamelCase = outputs.loss __UpperCamelCase = loss / gradient_accumulation_steps accelerator.backward(_lowercase ) if step % gradient_accumulation_steps == 0: optimizer.step() lr_scheduler.step() optimizer.zero_grad() overall_step += 1 model.eval() __UpperCamelCase = 0 for step, batch in enumerate(_lowercase ): # We could avoid this line since we set the accelerator with `device_placement=True`. batch.to(accelerator.device ) with torch.no_grad(): __UpperCamelCase = model(**_lowercase ) __UpperCamelCase = outputs.logits.argmax(dim=-1 ) # It is slightly faster to call this once, than multiple times __UpperCamelCase, __UpperCamelCase = accelerator.gather( (predictions, batch['labels']) ) # If we are in a multiprocess environment, the last batch has duplicates if accelerator.use_distributed: if step == len(_lowercase ) - 1: __UpperCamelCase = predictions[: len(eval_dataloader.dataset ) - samples_seen] __UpperCamelCase = references[: len(eval_dataloader.dataset ) - samples_seen] else: samples_seen += references.shape[0] metric.add_batch( predictions=_lowercase , references=_lowercase , ) __UpperCamelCase = metric.compute() # Use accelerator.print to print only on the main process. accelerator.print(f'''epoch {epoch}:''' , _lowercase ) __UpperCamelCase = eval_metric['accuracy'] if best_performance < eval_metric["accuracy"]: __UpperCamelCase = eval_metric['accuracy'] if args.performance_lower_bound is not None: assert ( args.performance_lower_bound <= best_performance ), f'''Best performance metric {best_performance} is lower than the lower bound {args.performance_lower_bound}''' accelerator.wait_for_everyone() if accelerator.is_main_process: with open(os.path.join(args.output_dir , 'all_results.json' ) , 'w' ) as f: json.dump(_lowercase , _lowercase ) def _A ( ) -> List[str]: """simple docstring""" __UpperCamelCase = argparse.ArgumentParser(description='Simple example of training script tracking peak GPU memory usage.' ) parser.add_argument( '--model_name_or_path' , type=_lowercase , default='bert-base-cased' , help='Path to pretrained model or model identifier from huggingface.co/models.' , required=_lowercase , ) parser.add_argument( '--output_dir' , type=_lowercase , default='.' , help='Optional save directory where all checkpoint folders will be stored. Default is the current working directory.' , ) parser.add_argument( '--performance_lower_bound' , type=_lowercase , default=_lowercase , help='Optional lower bound for the performance metric. If set, the training will throw error when the performance metric drops below this value.' , ) parser.add_argument( '--num_epochs' , type=_lowercase , default=3 , help='Number of train epochs.' , ) __UpperCamelCase = parser.parse_args() __UpperCamelCase = {'lr': 2e-5, 'num_epochs': args.num_epochs, 'seed': 42, 'batch_size': 16} training_function(_lowercase , _lowercase ) if __name__ == "__main__": main()

from ....utils import logging SCREAMING_SNAKE_CASE__ = logging.get_logger(__name__) class __lowerCAmelCase ( UpperCAmelCase_ ): """simple docstring""" def __init__( self : List[Any] , _snake_case : str , _snake_case : List[Any]=None , _snake_case : Union[str, Any]=20_48 ): """simple docstring""" A__ = config.__dict__ A__ = modal_hidden_size if num_labels: A__ = num_labels

from transformers import BertTokenizer, EncoderDecoderModel, SeqaSeqTrainer, SeqaSeqTrainingArguments from transformers.testing_utils import TestCasePlus, require_torch, slow from transformers.utils import is_datasets_available if is_datasets_available(): import datasets class __lowerCamelCase (_a ): @slow @require_torch def snake_case_ ( self: Union[str, Any] ): '''simple docstring''' __UpperCamelCase = EncoderDecoderModel.from_encoder_decoder_pretrained('prajjwal1/bert-tiny','prajjwal1/bert-tiny' ) __UpperCamelCase = BertTokenizer.from_pretrained('bert-base-uncased' ) __UpperCamelCase = bertabert.config.encoder.vocab_size __UpperCamelCase = tokenizer.sep_token_id __UpperCamelCase = tokenizer.cls_token_id __UpperCamelCase = 128 __UpperCamelCase = datasets.load_dataset('cnn_dailymail','3.0.0',split='train[:1%]' ) __UpperCamelCase = datasets.load_dataset('cnn_dailymail','3.0.0',split='validation[:1%]' ) __UpperCamelCase = train_dataset.select(range(32 ) ) __UpperCamelCase = val_dataset.select(range(16 ) ) __UpperCamelCase = 4 def _map_to_encoder_decoder_inputs(A_: Dict ): # Tokenizer will automatically set [BOS] <text> [EOS] __UpperCamelCase = tokenizer(batch['article'],padding='max_length',truncation=A_,max_length=512 ) __UpperCamelCase = tokenizer(batch['highlights'],padding='max_length',truncation=A_,max_length=128 ) __UpperCamelCase = inputs.input_ids __UpperCamelCase = inputs.attention_mask __UpperCamelCase = outputs.input_ids __UpperCamelCase = outputs.input_ids.copy() __UpperCamelCase = [ [-100 if token == tokenizer.pad_token_id else token for token in labels] for labels in batch['labels'] ] __UpperCamelCase = outputs.attention_mask assert all(len(A_ ) == 512 for x in inputs.input_ids ) assert all(len(A_ ) == 128 for x in outputs.input_ids ) return batch def _compute_metrics(A_: str ): __UpperCamelCase = pred.label_ids __UpperCamelCase = pred.predictions # all unnecessary tokens are removed __UpperCamelCase = tokenizer.batch_decode(A_,skip_special_tokens=A_ ) __UpperCamelCase = tokenizer.batch_decode(A_,skip_special_tokens=A_ ) __UpperCamelCase = sum([int(pred_str[i] == label_str[i] ) for i in range(len(A_ ) )] ) / len(A_ ) return {"accuracy": accuracy} # map train dataset __UpperCamelCase = train_dataset.map( _map_to_encoder_decoder_inputs,batched=A_,batch_size=A_,remove_columns=['article', 'highlights'],) train_dataset.set_format( type='torch',columns=['input_ids', 'attention_mask', 'decoder_input_ids', 'decoder_attention_mask', 'labels'],) # same for validation dataset __UpperCamelCase = val_dataset.map( _map_to_encoder_decoder_inputs,batched=A_,batch_size=A_,remove_columns=['article', 'highlights'],) val_dataset.set_format( type='torch',columns=['input_ids', 'attention_mask', 'decoder_input_ids', 'decoder_attention_mask', 'labels'],) __UpperCamelCase = self.get_auto_remove_tmp_dir() __UpperCamelCase = SeqaSeqTrainingArguments( output_dir=A_,per_device_train_batch_size=A_,per_device_eval_batch_size=A_,predict_with_generate=A_,evaluation_strategy='steps',do_train=A_,do_eval=A_,warmup_steps=0,eval_steps=2,logging_steps=2,) # instantiate trainer __UpperCamelCase = SeqaSeqTrainer( model=A_,args=A_,compute_metrics=_compute_metrics,train_dataset=A_,eval_dataset=A_,tokenizer=A_,) # start training trainer.train()

from collections import OrderedDict from typing import Mapping from ...configuration_utils import PretrainedConfig from ...onnx import OnnxConfig from ...utils import logging _lowerCAmelCase = logging.get_logger(__name__) _lowerCAmelCase = { "kssteven/ibert-roberta-base": "https://huggingface.co/kssteven/ibert-roberta-base/resolve/main/config.json", "kssteven/ibert-roberta-large": "https://huggingface.co/kssteven/ibert-roberta-large/resolve/main/config.json", "kssteven/ibert-roberta-large-mnli": ( "https://huggingface.co/kssteven/ibert-roberta-large-mnli/resolve/main/config.json" ), } class lowerCAmelCase_ ( __lowercase ): UpperCAmelCase = "ibert" def __init__( self : str , _A : Any=3_0522 , _A : List[Any]=768 , _A : Any=12 , _A : Union[str, Any]=12 , _A : Union[str, Any]=3072 , _A : Optional[int]="gelu" , _A : int=0.1 , _A : Tuple=0.1 , _A : int=512 , _A : int=2 , _A : Union[str, Any]=0.02 , _A : Dict=1e-12 , _A : Tuple=1 , _A : str=0 , _A : Dict=2 , _A : Union[str, Any]="absolute" , _A : Optional[int]=False , _A : List[Any]="none" , **_A : Dict , ): super().__init__(pad_token_id=_A , bos_token_id=_A , eos_token_id=_A , **_A ) _UpperCamelCase = vocab_size _UpperCamelCase = hidden_size _UpperCamelCase = num_hidden_layers _UpperCamelCase = num_attention_heads _UpperCamelCase = hidden_act _UpperCamelCase = intermediate_size _UpperCamelCase = hidden_dropout_prob _UpperCamelCase = attention_probs_dropout_prob _UpperCamelCase = max_position_embeddings _UpperCamelCase = type_vocab_size _UpperCamelCase = initializer_range _UpperCamelCase = layer_norm_eps _UpperCamelCase = position_embedding_type _UpperCamelCase = quant_mode _UpperCamelCase = force_dequant class lowerCAmelCase_ ( __lowercase ): @property def UpperCamelCase_ ( self : Tuple ): if self.task == "multiple-choice": _UpperCamelCase = {0: '''batch''', 1: '''choice''', 2: '''sequence'''} else: _UpperCamelCase = {0: '''batch''', 1: '''sequence'''} return OrderedDict( [ ('''input_ids''', dynamic_axis), ('''attention_mask''', dynamic_axis), ] )

def _A ( _lowercase = 1_00 ) -> int: """simple docstring""" __UpperCamelCase = 0 __UpperCamelCase = 0 for i in range(1 , n + 1 ): sum_of_squares += i**2 sum_of_ints += i return sum_of_ints**2 - sum_of_squares if __name__ == "__main__": print(f"""{solution() = }""")

'''simple docstring''' import torch from diffusers import DDPMScheduler from .test_schedulers import SchedulerCommonTest class __A ( A ): '''simple docstring''' __lowerCamelCase : List[Any] = (DDPMScheduler,) def a__ (self , **A ) -> Optional[int]: """simple docstring""" _a = { '''num_train_timesteps''': 1_000, '''beta_start''': 0.0001, '''beta_end''': 0.02, '''beta_schedule''': '''linear''', '''variance_type''': '''fixed_small''', '''clip_sample''': True, } config.update(**A ) return config def a__ (self ) -> Union[str, Any]: """simple docstring""" for timesteps in [1, 5, 100, 1_000]: self.check_over_configs(num_train_timesteps=A ) def a__ (self ) -> Union[str, Any]: """simple docstring""" for beta_start, beta_end in zip([0.0001, 0.001, 0.01, 0.1] , [0.002, 0.02, 0.2, 2] ): self.check_over_configs(beta_start=A , beta_end=A ) def a__ (self ) -> int: """simple docstring""" for schedule in ["linear", "squaredcos_cap_v2"]: self.check_over_configs(beta_schedule=A ) def a__ (self ) -> str: """simple docstring""" for variance in ["fixed_small", "fixed_large", "other"]: self.check_over_configs(variance_type=A ) def a__ (self ) -> Any: """simple docstring""" for clip_sample in [True, False]: self.check_over_configs(clip_sample=A ) def a__ (self ) -> str: """simple docstring""" self.check_over_configs(thresholding=A ) for threshold in [0.5, 1.0, 2.0]: for prediction_type in ["epsilon", "sample", "v_prediction"]: self.check_over_configs( thresholding=A , prediction_type=A , sample_max_value=A , ) def a__ (self ) -> str: """simple docstring""" for prediction_type in ["epsilon", "sample", "v_prediction"]: self.check_over_configs(prediction_type=A ) def a__ (self ) -> int: """simple docstring""" for t in [0, 500, 999]: self.check_over_forward(time_step=A ) def a__ (self ) -> List[str]: """simple docstring""" _a = self.scheduler_classes[0] _a = self.get_scheduler_config() _a = scheduler_class(**A ) assert torch.sum(torch.abs(scheduler._get_variance(0 ) - 0.0 ) ) < 1E-5 assert torch.sum(torch.abs(scheduler._get_variance(487 ) - 0.00979 ) ) < 1E-5 assert torch.sum(torch.abs(scheduler._get_variance(999 ) - 0.02 ) ) < 1E-5 def a__ (self ) -> Optional[Any]: """simple docstring""" _a = self.scheduler_classes[0] _a = self.get_scheduler_config() _a = scheduler_class(**A ) _a = len(A ) _a = self.dummy_model() _a = self.dummy_sample_deter _a = torch.manual_seed(0 ) for t in reversed(range(A ) ): # 1. predict noise residual _a = model(A , A ) # 2. predict previous mean of sample x_t-1 _a = scheduler.step(A , A , A , generator=A ).prev_sample # if t > 0: # noise = self.dummy_sample_deter # variance = scheduler.get_variance(t) ** (0.5) * noise # # sample = pred_prev_sample + variance _a = pred_prev_sample _a = torch.sum(torch.abs(A ) ) _a = torch.mean(torch.abs(A ) ) assert abs(result_sum.item() - 258.9606 ) < 1E-2 assert abs(result_mean.item() - 0.3372 ) < 1E-3 def a__ (self ) -> Dict: """simple docstring""" _a = self.scheduler_classes[0] _a = self.get_scheduler_config(prediction_type='''v_prediction''' ) _a = scheduler_class(**A ) _a = len(A ) _a = self.dummy_model() _a = self.dummy_sample_deter _a = torch.manual_seed(0 ) for t in reversed(range(A ) ): # 1. predict noise residual _a = model(A , A ) # 2. predict previous mean of sample x_t-1 _a = scheduler.step(A , A , A , generator=A ).prev_sample # if t > 0: # noise = self.dummy_sample_deter # variance = scheduler.get_variance(t) ** (0.5) * noise # # sample = pred_prev_sample + variance _a = pred_prev_sample _a = torch.sum(torch.abs(A ) ) _a = torch.mean(torch.abs(A ) ) assert abs(result_sum.item() - 202.0296 ) < 1E-2 assert abs(result_mean.item() - 0.2631 ) < 1E-3 def a__ (self ) -> Optional[int]: """simple docstring""" _a = self.scheduler_classes[0] _a = self.get_scheduler_config() _a = scheduler_class(**A ) _a = [100, 87, 50, 1, 0] scheduler.set_timesteps(timesteps=A ) _a = scheduler.timesteps for i, timestep in enumerate(A ): if i == len(A ) - 1: _a = -1 else: _a = timesteps[i + 1] _a = scheduler.previous_timestep(A ) _a = prev_t.item() self.assertEqual(A , A ) def a__ (self ) -> Optional[Any]: """simple docstring""" _a = self.scheduler_classes[0] _a = self.get_scheduler_config() _a = scheduler_class(**A ) _a = [100, 87, 50, 51, 0] with self.assertRaises(A , msg='''`custom_timesteps` must be in descending order.''' ): scheduler.set_timesteps(timesteps=A ) def a__ (self ) -> Tuple: """simple docstring""" _a = self.scheduler_classes[0] _a = self.get_scheduler_config() _a = scheduler_class(**A ) _a = [100, 87, 50, 1, 0] _a = len(A ) with self.assertRaises(A , msg='''Can only pass one of `num_inference_steps` or `custom_timesteps`.''' ): scheduler.set_timesteps(num_inference_steps=A , timesteps=A ) def a__ (self ) -> str: """simple docstring""" _a = self.scheduler_classes[0] _a = self.get_scheduler_config() _a = scheduler_class(**A ) _a = [scheduler.config.num_train_timesteps] with self.assertRaises( A , msg='''`timesteps` must start before `self.config.train_timesteps`: {scheduler.config.num_train_timesteps}}''' , ): scheduler.set_timesteps(timesteps=A )

def _A ( _lowercase , _lowercase ) -> int: """simple docstring""" return (pointa[0] - pointa[0]) ** 2 + (pointa[1] - pointa[1]) ** 2 def _A ( _lowercase , _lowercase=0 ) -> Dict: """simple docstring""" return sorted(_lowercase , key=lambda _lowercase : x[column] ) def _A ( _lowercase , _lowercase , _lowercase=float('inf' ) ) -> List[Any]: """simple docstring""" for i in range(points_counts - 1 ): for j in range(i + 1 , _lowercase ): __UpperCamelCase = euclidean_distance_sqr(points[i] , points[j] ) if current_dis < min_dis: __UpperCamelCase = current_dis return min_dis def _A ( _lowercase , _lowercase , _lowercase=float('inf' ) ) -> Tuple: """simple docstring""" for i in range(min(6 , points_counts - 1 ) , _lowercase ): for j in range(max(0 , i - 6 ) , _lowercase ): __UpperCamelCase = euclidean_distance_sqr(points[i] , points[j] ) if current_dis < min_dis: __UpperCamelCase = current_dis return min_dis def _A ( _lowercase , _lowercase , _lowercase ) -> Optional[Any]: """simple docstring""" if points_counts <= 3: return dis_between_closest_pair(_lowercase , _lowercase ) # recursion __UpperCamelCase = points_counts // 2 __UpperCamelCase = closest_pair_of_points_sqr( _lowercase , points_sorted_on_y[:mid] , _lowercase ) __UpperCamelCase = closest_pair_of_points_sqr( _lowercase , points_sorted_on_y[mid:] , points_counts - mid ) __UpperCamelCase = min(_lowercase , _lowercase ) __UpperCamelCase = [] for point in points_sorted_on_x: if abs(point[0] - points_sorted_on_x[mid][0] ) < closest_pair_dis: cross_strip.append(_lowercase ) __UpperCamelCase = dis_between_closest_in_strip( _lowercase , len(_lowercase ) , _lowercase ) return min(_lowercase , _lowercase ) def _A ( _lowercase , _lowercase ) -> Optional[int]: """simple docstring""" __UpperCamelCase = column_based_sort(_lowercase , column=0 ) __UpperCamelCase = column_based_sort(_lowercase , column=1 ) return ( closest_pair_of_points_sqr( _lowercase , _lowercase , _lowercase ) ) ** 0.5 if __name__ == "__main__": __snake_case = [(2, 3), (1_2, 3_0), (4_0, 5_0), (5, 1), (1_2, 1_0), (3, 4)] print('''Distance:''', closest_pair_of_points(points, len(points)))

import json import os import unittest from transformers.models.roc_bert.tokenization_roc_bert import ( VOCAB_FILES_NAMES, RoCBertBasicTokenizer, RoCBertTokenizer, RoCBertWordpieceTokenizer, _is_control, _is_punctuation, _is_whitespace, ) from transformers.testing_utils import require_tokenizers, slow from ...test_tokenization_common import TokenizerTesterMixin, filter_non_english @require_tokenizers class _snake_case ( UpperCAmelCase_ , unittest.TestCase ): __lowerCAmelCase : Union[str, Any] = RoCBertTokenizer __lowerCAmelCase : Union[str, Any] = None __lowerCAmelCase : str = False __lowerCAmelCase : List[Any] = True __lowerCAmelCase : Optional[int] = filter_non_english def lowercase__ ( self): '''simple docstring''' super().setUp() lowercase__ : Optional[int] = ["""[UNK]""", """[CLS]""", """[SEP]""", """[PAD]""", """[MASK]""", """你""", """好""", """是""", """谁""", """a""", """b""", """c""", """d"""] lowercase__ : Dict = {} lowercase__ : Tuple = {} for i, value in enumerate(SCREAMING_SNAKE_CASE_): lowercase__ : Tuple = i lowercase__ : Any = i lowercase__ : str = os.path.join(self.tmpdirname , VOCAB_FILES_NAMES["""vocab_file"""]) lowercase__ : Union[str, Any] = os.path.join(self.tmpdirname , VOCAB_FILES_NAMES["""word_shape_file"""]) lowercase__ : Tuple = os.path.join(self.tmpdirname , VOCAB_FILES_NAMES["""word_pronunciation_file"""]) with open(self.vocab_file , """w""" , encoding="""utf-8""") as vocab_writer: vocab_writer.write("""""".join([x + """\n""" for x in vocab_tokens])) with open(self.word_shape_file , """w""" , encoding="""utf-8""") as word_shape_writer: json.dump(SCREAMING_SNAKE_CASE_ , SCREAMING_SNAKE_CASE_ , ensure_ascii=SCREAMING_SNAKE_CASE_) with open(self.word_pronunciation_file , """w""" , encoding="""utf-8""") as word_pronunciation_writer: json.dump(SCREAMING_SNAKE_CASE_ , SCREAMING_SNAKE_CASE_ , ensure_ascii=SCREAMING_SNAKE_CASE_) def lowercase__ ( self): '''simple docstring''' lowercase__ : Dict = self.tokenizer_class(self.vocab_file , self.word_shape_file , self.word_pronunciation_file) lowercase__ : Optional[int] = tokenizer.tokenize("""你好[SEP]你是谁""") self.assertListEqual(SCREAMING_SNAKE_CASE_ , ["""你""", """好""", """[SEP]""", """你""", """是""", """谁"""]) self.assertListEqual(tokenizer.convert_tokens_to_ids(SCREAMING_SNAKE_CASE_) , [5, 6, 2, 5, 7, 8]) self.assertListEqual(tokenizer.convert_tokens_to_shape_ids(SCREAMING_SNAKE_CASE_) , [5, 6, 2, 5, 7, 8]) self.assertListEqual(tokenizer.convert_tokens_to_pronunciation_ids(SCREAMING_SNAKE_CASE_) , [5, 6, 2, 5, 7, 8]) def lowercase__ ( self): '''simple docstring''' lowercase__ : int = RoCBertBasicTokenizer() self.assertListEqual(tokenizer.tokenize("""ah\u535A\u63A8zz""") , ["""ah""", """\u535A""", """\u63A8""", """zz"""]) def lowercase__ ( self): '''simple docstring''' lowercase__ : Dict = RoCBertBasicTokenizer(do_lower_case=SCREAMING_SNAKE_CASE_) self.assertListEqual( tokenizer.tokenize(""" \tHeLLo!how \n Are yoU? """) , ["""hello""", """!""", """how""", """are""", """you""", """?"""]) self.assertListEqual(tokenizer.tokenize("""H\u00E9llo""") , ["""hello"""]) def lowercase__ ( self): '''simple docstring''' lowercase__ : Any = RoCBertBasicTokenizer(do_lower_case=SCREAMING_SNAKE_CASE_ , strip_accents=SCREAMING_SNAKE_CASE_) self.assertListEqual( tokenizer.tokenize(""" \tHäLLo!how \n Are yoU? """) , ["""hällo""", """!""", """how""", """are""", """you""", """?"""]) self.assertListEqual(tokenizer.tokenize("""H\u00E9llo""") , ["""h\u00E9llo"""]) def lowercase__ ( self): '''simple docstring''' lowercase__ : Optional[Any] = RoCBertBasicTokenizer(do_lower_case=SCREAMING_SNAKE_CASE_ , strip_accents=SCREAMING_SNAKE_CASE_) self.assertListEqual( tokenizer.tokenize(""" \tHäLLo!how \n Are yoU? """) , ["""hallo""", """!""", """how""", """are""", """you""", """?"""]) self.assertListEqual(tokenizer.tokenize("""H\u00E9llo""") , ["""hello"""]) def lowercase__ ( self): '''simple docstring''' lowercase__ : Optional[Any] = RoCBertBasicTokenizer(do_lower_case=SCREAMING_SNAKE_CASE_) self.assertListEqual( tokenizer.tokenize(""" \tHäLLo!how \n Are yoU? """) , ["""hallo""", """!""", """how""", """are""", """you""", """?"""]) self.assertListEqual(tokenizer.tokenize("""H\u00E9llo""") , ["""hello"""]) def lowercase__ ( self): '''simple docstring''' lowercase__ : Union[str, Any] = RoCBertBasicTokenizer(do_lower_case=SCREAMING_SNAKE_CASE_) self.assertListEqual( tokenizer.tokenize(""" \tHeLLo!how \n Are yoU? """) , ["""HeLLo""", """!""", """how""", """Are""", """yoU""", """?"""]) def lowercase__ ( self): '''simple docstring''' lowercase__ : str = RoCBertBasicTokenizer(do_lower_case=SCREAMING_SNAKE_CASE_ , strip_accents=SCREAMING_SNAKE_CASE_) self.assertListEqual( tokenizer.tokenize(""" \tHäLLo!how \n Are yoU? """) , ["""HäLLo""", """!""", """how""", """Are""", """yoU""", """?"""]) def lowercase__ ( self): '''simple docstring''' lowercase__ : Tuple = RoCBertBasicTokenizer(do_lower_case=SCREAMING_SNAKE_CASE_ , strip_accents=SCREAMING_SNAKE_CASE_) self.assertListEqual( tokenizer.tokenize(""" \tHäLLo!how \n Are yoU? """) , ["""HaLLo""", """!""", """how""", """Are""", """yoU""", """?"""]) def lowercase__ ( self): '''simple docstring''' lowercase__ : Dict = RoCBertBasicTokenizer(do_lower_case=SCREAMING_SNAKE_CASE_ , never_split=["""[UNK]"""]) self.assertListEqual( tokenizer.tokenize(""" \tHeLLo!how \n Are yoU? [UNK]""") , ["""HeLLo""", """!""", """how""", """Are""", """yoU""", """?""", """[UNK]"""]) def lowercase__ ( self): '''simple docstring''' lowercase__ : Optional[int] = ["""[UNK]""", """[CLS]""", """[SEP]""", """want""", """##want""", """##ed""", """wa""", """un""", """runn""", """##ing"""] lowercase__ : Optional[int] = {} for i, token in enumerate(SCREAMING_SNAKE_CASE_): lowercase__ : Optional[Any] = i lowercase__ : Union[str, Any] = RoCBertWordpieceTokenizer(vocab=SCREAMING_SNAKE_CASE_ , unk_token="""[UNK]""") self.assertListEqual(tokenizer.tokenize("""""") , []) self.assertListEqual(tokenizer.tokenize("""unwanted running""") , ["""un""", """##want""", """##ed""", """runn""", """##ing"""]) self.assertListEqual(tokenizer.tokenize("""unwantedX running""") , ["""[UNK]""", """runn""", """##ing"""]) def lowercase__ ( 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 lowercase__ ( 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 lowercase__ ( 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 lowercase__ ( self): '''simple docstring''' lowercase__ : Union[str, Any] = self.get_tokenizer() # Example taken from the issue https://github.com/huggingface/tokenizers/issues/340 self.assertListEqual([tokenizer.tokenize(SCREAMING_SNAKE_CASE_) for t in ["""Test""", """\xad""", """test"""]] , [["""[UNK]"""], [], ["""[UNK]"""]]) if self.test_rust_tokenizer: lowercase__ : int = self.get_rust_tokenizer() self.assertListEqual( [rust_tokenizer.tokenize(SCREAMING_SNAKE_CASE_) for t in ["""Test""", """\xad""", """test"""]] , [["""[UNK]"""], [], ["""[UNK]"""]]) def lowercase__ ( self): '''simple docstring''' for tokenizer, pretrained_name, kwargs in self.tokenizers_list: with self.subTest(f'{tokenizer.__class__.__name__} ({pretrained_name})'): lowercase__ : str = self.rust_tokenizer_class.from_pretrained(SCREAMING_SNAKE_CASE_ , **SCREAMING_SNAKE_CASE_) lowercase__ : Optional[int] = f'A, naïve {tokenizer_r.mask_token} AllenNLP sentence.' lowercase__ : List[str] = tokenizer_r.encode_plus( SCREAMING_SNAKE_CASE_ , return_attention_mask=SCREAMING_SNAKE_CASE_ , return_token_type_ids=SCREAMING_SNAKE_CASE_ , return_offsets_mapping=SCREAMING_SNAKE_CASE_ , add_special_tokens=SCREAMING_SNAKE_CASE_ , ) lowercase__ : str = tokenizer_r.do_lower_case if hasattr(SCREAMING_SNAKE_CASE_ , """do_lower_case""") else False lowercase__ : Optional[Any] = ( [ ((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 lowercase__ ( self): '''simple docstring''' lowercase__ : Any = ["""的""", """人""", """有"""] lowercase__ : List[str] = """""".join(SCREAMING_SNAKE_CASE_) for tokenizer, pretrained_name, kwargs in self.tokenizers_list: with self.subTest(f'{tokenizer.__class__.__name__} ({pretrained_name})'): lowercase__ : Union[str, Any] = True lowercase__ : Tuple = self.tokenizer_class.from_pretrained(SCREAMING_SNAKE_CASE_ , **SCREAMING_SNAKE_CASE_) lowercase__ : List[Any] = self.rust_tokenizer_class.from_pretrained(SCREAMING_SNAKE_CASE_ , **SCREAMING_SNAKE_CASE_) lowercase__ : Optional[Any] = tokenizer_p.encode(SCREAMING_SNAKE_CASE_ , add_special_tokens=SCREAMING_SNAKE_CASE_) lowercase__ : str = tokenizer_r.encode(SCREAMING_SNAKE_CASE_ , add_special_tokens=SCREAMING_SNAKE_CASE_) lowercase__ : List[str] = tokenizer_r.convert_ids_to_tokens(SCREAMING_SNAKE_CASE_) lowercase__ : List[str] = tokenizer_p.convert_ids_to_tokens(SCREAMING_SNAKE_CASE_) # it is expected that each Chinese character is not preceded by "##" self.assertListEqual(SCREAMING_SNAKE_CASE_ , SCREAMING_SNAKE_CASE_) self.assertListEqual(SCREAMING_SNAKE_CASE_ , SCREAMING_SNAKE_CASE_) lowercase__ : Any = False lowercase__ : Optional[Any] = self.rust_tokenizer_class.from_pretrained(SCREAMING_SNAKE_CASE_ , **SCREAMING_SNAKE_CASE_) lowercase__ : Optional[Any] = self.tokenizer_class.from_pretrained(SCREAMING_SNAKE_CASE_ , **SCREAMING_SNAKE_CASE_) lowercase__ : Optional[int] = tokenizer_r.encode(SCREAMING_SNAKE_CASE_ , add_special_tokens=SCREAMING_SNAKE_CASE_) lowercase__ : Tuple = tokenizer_p.encode(SCREAMING_SNAKE_CASE_ , add_special_tokens=SCREAMING_SNAKE_CASE_) lowercase__ : Tuple = tokenizer_r.convert_ids_to_tokens(SCREAMING_SNAKE_CASE_) lowercase__ : Optional[Any] = tokenizer_p.convert_ids_to_tokens(SCREAMING_SNAKE_CASE_) # it is expected that only the first Chinese character is not preceded by "##". lowercase__ : Any = [ f'##{token}' if idx != 0 else token for idx, token in enumerate(SCREAMING_SNAKE_CASE_) ] self.assertListEqual(SCREAMING_SNAKE_CASE_ , SCREAMING_SNAKE_CASE_) self.assertListEqual(SCREAMING_SNAKE_CASE_ , SCREAMING_SNAKE_CASE_) @slow def lowercase__ ( self): '''simple docstring''' lowercase__ : Dict = self.tokenizer_class(self.vocab_file , self.word_shape_file , self.word_pronunciation_file) lowercase__ : Optional[Any] = tokenizer.encode("""你好""" , add_special_tokens=SCREAMING_SNAKE_CASE_) lowercase__ : Any = tokenizer.encode("""你是谁""" , add_special_tokens=SCREAMING_SNAKE_CASE_) lowercase__ : Optional[Any] = tokenizer.build_inputs_with_special_tokens(SCREAMING_SNAKE_CASE_) lowercase__ : Tuple = tokenizer.build_inputs_with_special_tokens(SCREAMING_SNAKE_CASE_ , SCREAMING_SNAKE_CASE_) assert encoded_sentence == [1] + text + [2] assert encoded_pair == [1] + text + [2] + text_a + [2] def lowercase__ ( self): '''simple docstring''' lowercase__ : Optional[int] = self.get_tokenizers(do_lower_case=SCREAMING_SNAKE_CASE_) for tokenizer in tokenizers: with self.subTest(f'{tokenizer.__class__.__name__}'): lowercase__ : Optional[int] = """你好，你是谁""" lowercase__ : List[Any] = tokenizer.tokenize(SCREAMING_SNAKE_CASE_) lowercase__ : Union[str, Any] = tokenizer.convert_tokens_to_ids(SCREAMING_SNAKE_CASE_) lowercase__ : Tuple = tokenizer.convert_tokens_to_shape_ids(SCREAMING_SNAKE_CASE_) lowercase__ : List[str] = tokenizer.convert_tokens_to_pronunciation_ids(SCREAMING_SNAKE_CASE_) lowercase__ : Any = tokenizer.prepare_for_model( SCREAMING_SNAKE_CASE_ , SCREAMING_SNAKE_CASE_ , SCREAMING_SNAKE_CASE_ , add_special_tokens=SCREAMING_SNAKE_CASE_) lowercase__ : Dict = tokenizer.encode_plus(SCREAMING_SNAKE_CASE_ , add_special_tokens=SCREAMING_SNAKE_CASE_) self.assertEqual(SCREAMING_SNAKE_CASE_ , SCREAMING_SNAKE_CASE_)

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 = { '''bert-base-uncased''': '''https://huggingface.co/bert-base-uncased/resolve/main/config.json''', '''bert-large-uncased''': '''https://huggingface.co/bert-large-uncased/resolve/main/config.json''', '''bert-base-cased''': '''https://huggingface.co/bert-base-cased/resolve/main/config.json''', '''bert-large-cased''': '''https://huggingface.co/bert-large-cased/resolve/main/config.json''', '''bert-base-multilingual-uncased''': '''https://huggingface.co/bert-base-multilingual-uncased/resolve/main/config.json''', '''bert-base-multilingual-cased''': '''https://huggingface.co/bert-base-multilingual-cased/resolve/main/config.json''', '''bert-base-chinese''': '''https://huggingface.co/bert-base-chinese/resolve/main/config.json''', '''bert-base-german-cased''': '''https://huggingface.co/bert-base-german-cased/resolve/main/config.json''', '''bert-large-uncased-whole-word-masking''': ( '''https://huggingface.co/bert-large-uncased-whole-word-masking/resolve/main/config.json''' ), '''bert-large-cased-whole-word-masking''': ( '''https://huggingface.co/bert-large-cased-whole-word-masking/resolve/main/config.json''' ), '''bert-large-uncased-whole-word-masking-finetuned-squad''': ( '''https://huggingface.co/bert-large-uncased-whole-word-masking-finetuned-squad/resolve/main/config.json''' ), '''bert-large-cased-whole-word-masking-finetuned-squad''': ( '''https://huggingface.co/bert-large-cased-whole-word-masking-finetuned-squad/resolve/main/config.json''' ), '''bert-base-cased-finetuned-mrpc''': '''https://huggingface.co/bert-base-cased-finetuned-mrpc/resolve/main/config.json''', '''bert-base-german-dbmdz-cased''': '''https://huggingface.co/bert-base-german-dbmdz-cased/resolve/main/config.json''', '''bert-base-german-dbmdz-uncased''': '''https://huggingface.co/bert-base-german-dbmdz-uncased/resolve/main/config.json''', '''cl-tohoku/bert-base-japanese''': '''https://huggingface.co/cl-tohoku/bert-base-japanese/resolve/main/config.json''', '''cl-tohoku/bert-base-japanese-whole-word-masking''': ( '''https://huggingface.co/cl-tohoku/bert-base-japanese-whole-word-masking/resolve/main/config.json''' ), '''cl-tohoku/bert-base-japanese-char''': ( '''https://huggingface.co/cl-tohoku/bert-base-japanese-char/resolve/main/config.json''' ), '''cl-tohoku/bert-base-japanese-char-whole-word-masking''': ( '''https://huggingface.co/cl-tohoku/bert-base-japanese-char-whole-word-masking/resolve/main/config.json''' ), '''TurkuNLP/bert-base-finnish-cased-v1''': ( '''https://huggingface.co/TurkuNLP/bert-base-finnish-cased-v1/resolve/main/config.json''' ), '''TurkuNLP/bert-base-finnish-uncased-v1''': ( '''https://huggingface.co/TurkuNLP/bert-base-finnish-uncased-v1/resolve/main/config.json''' ), '''wietsedv/bert-base-dutch-cased''': '''https://huggingface.co/wietsedv/bert-base-dutch-cased/resolve/main/config.json''', # See all BERT models at https://huggingface.co/models?filter=bert } class __lowerCamelCase (_a ): _lowercase = """bert""" def __init__( self: Any,A_: Dict=3_0522,A_: Optional[Any]=768,A_: Union[str, Any]=12,A_: List[Any]=12,A_: Optional[int]=3072,A_: Union[str, Any]="gelu",A_: List[str]=0.1,A_: Dict=0.1,A_: Optional[int]=512,A_: Optional[Any]=2,A_: Union[str, Any]=0.0_2,A_: List[Any]=1E-12,A_: Optional[int]=0,A_: List[Any]="absolute",A_: str=True,A_: Union[str, Any]=None,**A_: int,): '''simple docstring''' super().__init__(pad_token_id=A_,**A_ ) __UpperCamelCase = vocab_size __UpperCamelCase = hidden_size __UpperCamelCase = num_hidden_layers __UpperCamelCase = num_attention_heads __UpperCamelCase = hidden_act __UpperCamelCase = intermediate_size __UpperCamelCase = hidden_dropout_prob __UpperCamelCase = attention_probs_dropout_prob __UpperCamelCase = max_position_embeddings __UpperCamelCase = type_vocab_size __UpperCamelCase = initializer_range __UpperCamelCase = layer_norm_eps __UpperCamelCase = position_embedding_type __UpperCamelCase = use_cache __UpperCamelCase = classifier_dropout class __lowerCamelCase (_a ): @property def snake_case_ ( self: Optional[int] ): '''simple docstring''' if self.task == "multiple-choice": __UpperCamelCase = {0: 'batch', 1: 'choice', 2: 'sequence'} else: __UpperCamelCase = {0: 'batch', 1: 'sequence'} return OrderedDict( [ ('input_ids', dynamic_axis), ('attention_mask', dynamic_axis), ('token_type_ids', dynamic_axis), ] )

'''simple docstring''' # Lint as: python3 import dataclasses import re from dataclasses import dataclass from functools import total_ordering from typing import Optional, Union A__ : Any = re.compile(R"""^(?P<major>\d+)""" R"""\.(?P<minor>\d+)""" R"""\.(?P<patch>\d+)$""") @total_ordering @dataclass class UpperCAmelCase_ : """simple docstring""" lowerCamelCase : str lowerCamelCase : Optional[str] = None lowerCamelCase : Optional[Union[str, int]] = None lowerCamelCase : Optional[Union[str, int]] = None lowerCamelCase : Optional[Union[str, int]] = None def lowercase_ ( self ) -> List[str]: __lowerCamelCase , __lowerCamelCase , __lowerCamelCase : List[Any] = _str_to_version_tuple(self.version_str ) def __repr__( self ) -> Any: return f'{self.tuple[0]}.{self.tuple[1]}.{self.tuple[2]}' @property def lowercase_ ( self ) -> int: return self.major, self.minor, self.patch def lowercase_ ( self , SCREAMING_SNAKE_CASE_ ) -> List[Any]: if isinstance(SCREAMING_SNAKE_CASE_ , SCREAMING_SNAKE_CASE_ ): return Version(SCREAMING_SNAKE_CASE_ ) elif isinstance(SCREAMING_SNAKE_CASE_ , SCREAMING_SNAKE_CASE_ ): return other raise TypeError(f'{other} (type {type(SCREAMING_SNAKE_CASE_ )}) cannot be compared to version.' ) def __eq__( self , SCREAMING_SNAKE_CASE_ ) -> Optional[Any]: try: __lowerCamelCase : Union[str, Any] = self._validate_operand(SCREAMING_SNAKE_CASE_ ) except (TypeError, ValueError): return False else: return self.tuple == other.tuple def __lt__( self , SCREAMING_SNAKE_CASE_ ) -> List[Any]: __lowerCamelCase : List[Any] = self._validate_operand(SCREAMING_SNAKE_CASE_ ) return self.tuple < other.tuple def __hash__( self ) -> List[str]: return hash(_version_tuple_to_str(self.tuple ) ) @classmethod def lowercase_ ( cls , SCREAMING_SNAKE_CASE_ ) -> List[str]: __lowerCamelCase : str = {f.name for f in dataclasses.fields(cls )} return cls(**{k: v for k, v in dic.items() if k in field_names} ) def lowercase_ ( self ) -> str: return self.version_str def UpperCAmelCase__ ( UpperCAmelCase_ : Union[str, Any] ) -> str: __lowerCamelCase : str = _VERSION_REG.match(UpperCAmelCase_ ) if not res: raise ValueError(F'Invalid version \'{version_str}\'. Format should be x.y.z with {{x,y,z}} being digits.' ) return tuple(int(UpperCAmelCase_ ) for v in [res.group('major' ), res.group('minor' ), res.group('patch' )] ) def UpperCAmelCase__ ( UpperCAmelCase_ : List[str] ) -> Dict: return ".".join(str(UpperCAmelCase_ ) for v in version_tuple )

def _A ( _lowercase ) -> int: """simple docstring""" assert column_title.isupper() __UpperCamelCase = 0 __UpperCamelCase = len(_lowercase ) - 1 __UpperCamelCase = 0 while index >= 0: __UpperCamelCase = (ord(column_title[index] ) - 64) * pow(26 , _lowercase ) answer += value power += 1 index -= 1 return answer if __name__ == "__main__": from doctest import testmod testmod()

def __UpperCAmelCase ( __a : int ,__a : int ) -> str: """simple docstring""" if not isinstance(__a ,__a ): raise ValueError('''iterations must be defined as integers''' ) if not isinstance(__a ,__a ) or not number >= 1: raise ValueError( '''starting number must be and integer and be more than 0''' ) if not iterations >= 1: raise ValueError('''Iterations must be done more than 0 times to play FizzBuzz''' ) _a : List[Any] = '''''' while number <= iterations: if number % 3 == 0: out += "Fizz" if number % 5 == 0: out += "Buzz" if 0 not in (number % 3, number % 5): out += str(__a ) # print(out) number += 1 out += " " return out if __name__ == "__main__": import doctest doctest.testmod()

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 from lavis.models import load_model_and_preprocess from PIL import Image from transformers import ( AutoTokenizer, BlipaConfig, BlipaForConditionalGeneration, BlipaProcessor, BlipaVisionConfig, BlipImageProcessor, OPTConfig, TaConfig, ) from transformers.utils.constants import OPENAI_CLIP_MEAN, OPENAI_CLIP_STD def _A ( ) -> int: """simple docstring""" __UpperCamelCase = 'https://storage.googleapis.com/sfr-vision-language-research/LAVIS/assets/merlion.png' __UpperCamelCase = Image.open(requests.get(_lowercase , stream=_lowercase ).raw ).convert('RGB' ) return image def _A ( _lowercase ) -> int: """simple docstring""" __UpperCamelCase = [] # 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.layernorm.weight') ) rename_keys.append(('Qformer.bert.embeddings.LayerNorm.bias', 'qformer.layernorm.bias') ) # fmt: on return rename_keys def _A ( _lowercase , _lowercase , _lowercase ) -> Optional[int]: """simple docstring""" __UpperCamelCase = dct.pop(_lowercase ) __UpperCamelCase = val def _A ( _lowercase , _lowercase ) -> int: """simple docstring""" for i in range(config.vision_config.num_hidden_layers ): # read in original q and v biases __UpperCamelCase = state_dict.pop(f'''visual_encoder.blocks.{i}.attn.q_bias''' ) __UpperCamelCase = state_dict.pop(f'''visual_encoder.blocks.{i}.attn.v_bias''' ) # next, set bias in the state dict __UpperCamelCase = torch.cat((q_bias, torch.zeros_like(_lowercase , requires_grad=_lowercase ), v_bias) ) __UpperCamelCase = qkv_bias def _A ( _lowercase , _lowercase ) -> Any: """simple docstring""" __UpperCamelCase = 3_64 if 'coco' in model_name else 2_24 __UpperCamelCase = BlipaVisionConfig(image_size=_lowercase ).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 "opt-2.7b" in model_name: __UpperCamelCase = OPTConfig.from_pretrained('facebook/opt-2.7b' , eos_token_id=_lowercase ).to_dict() elif "opt-6.7b" in model_name: __UpperCamelCase = OPTConfig.from_pretrained('facebook/opt-6.7b' , eos_token_id=_lowercase ).to_dict() elif "t5-xl" in model_name: __UpperCamelCase = TaConfig.from_pretrained('google/flan-t5-xl' , dense_act_fn='gelu' , bos_token_id=1 ).to_dict() elif "t5-xxl" in model_name: __UpperCamelCase = TaConfig.from_pretrained('google/flan-t5-xxl' , dense_act_fn='gelu' , bos_token_id=1 ).to_dict() __UpperCamelCase = BlipaConfig(vision_config=_lowercase , text_config=_lowercase ) return config, image_size @torch.no_grad() def _A ( _lowercase , _lowercase=None , _lowercase=False ) -> Union[str, Any]: """simple docstring""" __UpperCamelCase = ( AutoTokenizer.from_pretrained('facebook/opt-2.7b' ) if 'opt' in model_name else AutoTokenizer.from_pretrained('google/flan-t5-xl' ) ) __UpperCamelCase = tokenizer('\n' , add_special_tokens=_lowercase ).input_ids[0] __UpperCamelCase, __UpperCamelCase = get_blipa_config(_lowercase , eos_token_id=_lowercase ) __UpperCamelCase = BlipaForConditionalGeneration(_lowercase ).eval() __UpperCamelCase = { 'blip2-opt-2.7b': ('blip2_opt', 'pretrain_opt2.7b'), 'blip2-opt-6.7b': ('blip2_opt', 'pretrain_opt6.7b'), 'blip2-opt-2.7b-coco': ('blip2_opt', 'caption_coco_opt2.7b'), 'blip2-opt-6.7b-coco': ('blip2_opt', 'caption_coco_opt6.7b'), 'blip2-flan-t5-xl': ('blip2_t5', 'pretrain_flant5xl'), 'blip2-flan-t5-xl-coco': ('blip2_t5', 'caption_coco_flant5xl'), 'blip2-flan-t5-xxl': ('blip2_t5', 'pretrain_flant5xxl'), } __UpperCamelCase, __UpperCamelCase = model_name_to_original[model_name] # load original model print('Loading original model...' ) __UpperCamelCase = 'cuda' if torch.cuda.is_available() else 'cpu' __UpperCamelCase, __UpperCamelCase, __UpperCamelCase = load_model_and_preprocess( name=_lowercase , model_type=_lowercase , is_eval=_lowercase , device=_lowercase ) original_model.eval() print('Done!' ) # update state dict keys __UpperCamelCase = original_model.state_dict() __UpperCamelCase = create_rename_keys(_lowercase ) for src, dest in rename_keys: rename_key(_lowercase , _lowercase , _lowercase ) # some keys can be renamed efficiently for key, val in state_dict.copy().items(): __UpperCamelCase = state_dict.pop(_lowercase ) if key.startswith('Qformer.bert' ): __UpperCamelCase = key.replace('Qformer.bert' , 'qformer' ) if "attention.self" in key: __UpperCamelCase = key.replace('self' , 'attention' ) if "opt_proj" in key: __UpperCamelCase = key.replace('opt_proj' , 'language_projection' ) if "t5_proj" in key: __UpperCamelCase = key.replace('t5_proj' , 'language_projection' ) if key.startswith('opt' ): __UpperCamelCase = key.replace('opt' , 'language' ) if key.startswith('t5' ): __UpperCamelCase = key.replace('t5' , 'language' ) __UpperCamelCase = val # read in qv biases read_in_q_v_bias(_lowercase , _lowercase ) __UpperCamelCase, __UpperCamelCase = hf_model.load_state_dict(_lowercase , strict=_lowercase ) assert len(_lowercase ) == 0 assert unexpected_keys == ["qformer.embeddings.position_ids"] __UpperCamelCase = load_demo_image() __UpperCamelCase = vis_processors['eval'](_lowercase ).unsqueeze(0 ).to(_lowercase ) __UpperCamelCase = tokenizer(['\n'] , return_tensors='pt' ).input_ids.to(_lowercase ) # create processor __UpperCamelCase = BlipImageProcessor( size={'height': image_size, 'width': image_size} , image_mean=_lowercase , image_std=_lowercase ) __UpperCamelCase = BlipaProcessor(image_processor=_lowercase , tokenizer=_lowercase ) __UpperCamelCase = processor(images=_lowercase , return_tensors='pt' ).pixel_values.to(_lowercase ) # make sure processor creates exact same pixel values assert torch.allclose(_lowercase , _lowercase ) original_model.to(_lowercase ) hf_model.to(_lowercase ) with torch.no_grad(): if "opt" in model_name: __UpperCamelCase = original_model({'image': original_pixel_values, 'text_input': ['']} ).logits __UpperCamelCase = hf_model(_lowercase , _lowercase ).logits else: __UpperCamelCase = original_model( {'image': original_pixel_values, 'text_input': ['\n'], 'text_output': ['\n']} ).logits __UpperCamelCase = input_ids.masked_fill(input_ids == tokenizer.pad_token_id , -1_00 ) __UpperCamelCase = hf_model(_lowercase , _lowercase , labels=_lowercase ).logits assert original_logits.shape == logits.shape print('First values of original logits:' , original_logits[0, :3, :3] ) print('First values of HF logits:' , logits[0, :3, :3] ) # assert values if model_name == "blip2-flan-t5-xl": __UpperCamelCase = torch.tensor( [[-41.58_50, -4.44_40, -8.99_22], [-47.43_22, -5.91_43, -1.73_40]] , device=_lowercase ) assert torch.allclose(logits[0, :3, :3] , _lowercase , atol=1e-4 ) elif model_name == "blip2-flan-t5-xl-coco": __UpperCamelCase = torch.tensor( [[-57.01_09, -9.89_67, -12.62_80], [-68.65_78, -12.71_91, -10.50_65]] , device=_lowercase ) else: # cast to same type __UpperCamelCase = logits.dtype assert torch.allclose(original_logits.to(_lowercase ) , _lowercase , atol=1e-2 ) print('Looks ok!' ) print('Generating a caption...' ) __UpperCamelCase = '' __UpperCamelCase = tokenizer(_lowercase , return_tensors='pt' ).input_ids.to(_lowercase ) __UpperCamelCase = original_model.generate({'image': original_pixel_values} ) __UpperCamelCase = hf_model.generate( _lowercase , _lowercase , do_sample=_lowercase , num_beams=5 , max_length=30 , min_length=1 , top_p=0.9 , repetition_penalty=1.0 , length_penalty=1.0 , temperature=1 , ) print('Original generation:' , _lowercase ) __UpperCamelCase = input_ids.shape[1] __UpperCamelCase = processor.batch_decode(outputs[:, prompt_length:] , skip_special_tokens=_lowercase ) __UpperCamelCase = [text.strip() for text in output_text] print('HF generation:' , _lowercase ) if pytorch_dump_folder_path is not None: processor.save_pretrained(_lowercase ) hf_model.save_pretrained(_lowercase ) if push_to_hub: processor.push_to_hub(f'''nielsr/{model_name}''' ) hf_model.push_to_hub(f'''nielsr/{model_name}''' ) if __name__ == "__main__": __snake_case = argparse.ArgumentParser() __snake_case = [ '''blip2-opt-2.7b''', '''blip2-opt-6.7b''', '''blip2-opt-2.7b-coco''', '''blip2-opt-6.7b-coco''', '''blip2-flan-t5-xl''', '''blip2-flan-t5-xl-coco''', '''blip2-flan-t5-xxl''', ] parser.add_argument( '''--model_name''', default='''blip2-opt-2.7b''', 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)

from __future__ import annotations def UpperCamelCase ( __magic_name__ : list[int] , __magic_name__ : int ) -> list[int]: """simple docstring""" lowercase__ = 0 lowercase__ = len(__magic_name__ ) - 1 while i < j: if nums[i] + nums[j] == target: return [i, j] elif nums[i] + nums[j] < target: lowercase__ = i + 1 else: lowercase__ = j - 1 return [] if __name__ == "__main__": import doctest doctest.testmod() print(F'{two_pointer([2, 7, 1_1, 1_5], 9) = }')

import logging import os import sys from dataclasses import dataclass, field from importlib import import_module from typing import Dict, List, Optional, Tuple import numpy as np from seqeval.metrics import accuracy_score, fa_score, precision_score, recall_score from torch import nn from utils_ner import Split, TokenClassificationDataset, TokenClassificationTask import transformers from transformers import ( AutoConfig, AutoModelForTokenClassification, AutoTokenizer, DataCollatorWithPadding, EvalPrediction, HfArgumentParser, Trainer, TrainingArguments, set_seed, ) from transformers.trainer_utils import is_main_process __snake_case = logging.getLogger(__name__) @dataclass class __lowerCamelCase : _lowercase = field( metadata={"""help""": """Path to pretrained model or model identifier from huggingface.co/models"""} ) _lowercase = field( default=_a , metadata={"""help""": """Pretrained config name or path if not the same as model_name"""} ) _lowercase = field( default="""NER""" , metadata={"""help""": """Task type to fine tune in training (e.g. NER, POS, etc)"""} ) _lowercase = field( default=_a , metadata={"""help""": """Pretrained tokenizer name or path if not the same as model_name"""} ) _lowercase = field(default=_a , metadata={"""help""": """Set this flag to use fast tokenization."""} ) # If you want to tweak more attributes on your tokenizer, you should do it in a distinct script, # or just modify its tokenizer_config.json. _lowercase = field( default=_a , metadata={"""help""": """Where do you want to store the pretrained models downloaded from huggingface.co"""} , ) @dataclass class __lowerCamelCase : _lowercase = field( metadata={"""help""": """The input data dir. Should contain the .txt files for a CoNLL-2003-formatted task."""} ) _lowercase = field( default=_a , metadata={"""help""": """Path to a file containing all labels. If not specified, CoNLL-2003 labels are used."""} , ) _lowercase = field( default=128 , metadata={ """help""": ( """The maximum total input sequence length after tokenization. Sequences longer """ """than this will be truncated, sequences shorter will be padded.""" ) } , ) _lowercase = field( default=_a , metadata={"""help""": """Overwrite the cached training and evaluation sets"""} ) def _A ( ) -> str: """simple docstring""" __UpperCamelCase = HfArgumentParser((ModelArguments, DataTrainingArguments, TrainingArguments) ) if len(sys.argv ) == 2 and sys.argv[1].endswith('.json' ): # If we pass only one argument to the script and it's the path to a json file, # let's parse it to get our arguments. __UpperCamelCase, __UpperCamelCase, __UpperCamelCase = parser.parse_json_file(json_file=os.path.abspath(sys.argv[1] ) ) else: __UpperCamelCase, __UpperCamelCase, __UpperCamelCase = parser.parse_args_into_dataclasses() if ( os.path.exists(training_args.output_dir ) and os.listdir(training_args.output_dir ) and training_args.do_train and not training_args.overwrite_output_dir ): raise ValueError( f'''Output directory ({training_args.output_dir}) already exists and is not empty. Use''' ' --overwrite_output_dir to overcome.' ) __UpperCamelCase = import_module('tasks' ) try: __UpperCamelCase = getattr(_lowercase , model_args.task_type ) __UpperCamelCase = token_classification_task_clazz() except AttributeError: raise ValueError( f'''Task {model_args.task_type} needs to be defined as a TokenClassificationTask subclass in {module}. ''' f'''Available tasks classes are: {TokenClassificationTask.__subclasses__()}''' ) # Setup logging logging.basicConfig( format='%(asctime)s - %(levelname)s - %(name)s - %(message)s' , datefmt='%m/%d/%Y %H:%M:%S' , level=logging.INFO if training_args.local_rank in [-1, 0] else logging.WARN , ) logger.warning( 'Process rank: %s, device: %s, n_gpu: %s, distributed training: %s, 16-bits training: %s' , training_args.local_rank , training_args.device , training_args.n_gpu , bool(training_args.local_rank != -1 ) , training_args.fpaa , ) # Set the verbosity to info of the Transformers logger (on main process only): if is_main_process(training_args.local_rank ): transformers.utils.logging.set_verbosity_info() transformers.utils.logging.enable_default_handler() transformers.utils.logging.enable_explicit_format() logger.info('Training/evaluation parameters %s' , _lowercase ) # Set seed set_seed(training_args.seed ) # Prepare CONLL-2003 task __UpperCamelCase = token_classification_task.get_labels(data_args.labels ) __UpperCamelCase = dict(enumerate(_lowercase ) ) __UpperCamelCase = len(_lowercase ) # Load pretrained model and tokenizer # # Distributed training: # The .from_pretrained methods guarantee that only one local process can concurrently # download model & vocab. __UpperCamelCase = AutoConfig.from_pretrained( model_args.config_name if model_args.config_name else model_args.model_name_or_path , num_labels=_lowercase , idalabel=_lowercase , labelaid={label: i for i, label in enumerate(_lowercase )} , cache_dir=model_args.cache_dir , ) __UpperCamelCase = AutoTokenizer.from_pretrained( model_args.tokenizer_name if model_args.tokenizer_name else model_args.model_name_or_path , cache_dir=model_args.cache_dir , use_fast=model_args.use_fast , ) __UpperCamelCase = AutoModelForTokenClassification.from_pretrained( model_args.model_name_or_path , from_tf=bool('.ckpt' in model_args.model_name_or_path ) , config=_lowercase , cache_dir=model_args.cache_dir , ) # Get datasets __UpperCamelCase = ( TokenClassificationDataset( token_classification_task=_lowercase , data_dir=data_args.data_dir , tokenizer=_lowercase , labels=_lowercase , model_type=config.model_type , max_seq_length=data_args.max_seq_length , overwrite_cache=data_args.overwrite_cache , mode=Split.train , ) if training_args.do_train else None ) __UpperCamelCase = ( TokenClassificationDataset( token_classification_task=_lowercase , data_dir=data_args.data_dir , tokenizer=_lowercase , labels=_lowercase , model_type=config.model_type , max_seq_length=data_args.max_seq_length , overwrite_cache=data_args.overwrite_cache , mode=Split.dev , ) if training_args.do_eval else None ) def align_predictions(_lowercase , _lowercase ) -> Tuple[List[int], List[int]]: __UpperCamelCase = np.argmax(_lowercase , axis=2 ) __UpperCamelCase, __UpperCamelCase = preds.shape __UpperCamelCase = [[] for _ in range(_lowercase )] __UpperCamelCase = [[] for _ in range(_lowercase )] for i in range(_lowercase ): for j in range(_lowercase ): if label_ids[i, j] != nn.CrossEntropyLoss().ignore_index: out_label_list[i].append(label_map[label_ids[i][j]] ) preds_list[i].append(label_map[preds[i][j]] ) return preds_list, out_label_list def compute_metrics(_lowercase ) -> Dict: __UpperCamelCase, __UpperCamelCase = align_predictions(p.predictions , p.label_ids ) return { "accuracy_score": accuracy_score(_lowercase , _lowercase ), "precision": precision_score(_lowercase , _lowercase ), "recall": recall_score(_lowercase , _lowercase ), "f1": fa_score(_lowercase , _lowercase ), } # Data collator __UpperCamelCase = DataCollatorWithPadding(_lowercase , pad_to_multiple_of=8 ) if training_args.fpaa else None # Initialize our Trainer __UpperCamelCase = Trainer( model=_lowercase , args=_lowercase , train_dataset=_lowercase , eval_dataset=_lowercase , compute_metrics=_lowercase , data_collator=_lowercase , ) # Training if training_args.do_train: trainer.train( model_path=model_args.model_name_or_path if os.path.isdir(model_args.model_name_or_path ) else None ) trainer.save_model() # For convenience, we also re-save the tokenizer to the same directory, # so that you can share your model easily on huggingface.co/models =) if trainer.is_world_process_zero(): tokenizer.save_pretrained(training_args.output_dir ) # Evaluation __UpperCamelCase = {} if training_args.do_eval: logger.info('*** Evaluate ***' ) __UpperCamelCase = trainer.evaluate() __UpperCamelCase = os.path.join(training_args.output_dir , 'eval_results.txt' ) if trainer.is_world_process_zero(): with open(_lowercase , 'w' ) as writer: logger.info('***** Eval results *****' ) for key, value in result.items(): logger.info(' %s = %s' , _lowercase , _lowercase ) writer.write('%s = %s\n' % (key, value) ) results.update(_lowercase ) # Predict if training_args.do_predict: __UpperCamelCase = TokenClassificationDataset( token_classification_task=_lowercase , data_dir=data_args.data_dir , tokenizer=_lowercase , labels=_lowercase , model_type=config.model_type , max_seq_length=data_args.max_seq_length , overwrite_cache=data_args.overwrite_cache , mode=Split.test , ) __UpperCamelCase, __UpperCamelCase, __UpperCamelCase = trainer.predict(_lowercase ) __UpperCamelCase, __UpperCamelCase = align_predictions(_lowercase , _lowercase ) __UpperCamelCase = os.path.join(training_args.output_dir , 'test_results.txt' ) if trainer.is_world_process_zero(): with open(_lowercase , 'w' ) as writer: for key, value in metrics.items(): logger.info(' %s = %s' , _lowercase , _lowercase ) writer.write('%s = %s\n' % (key, value) ) # Save predictions __UpperCamelCase = os.path.join(training_args.output_dir , 'test_predictions.txt' ) if trainer.is_world_process_zero(): with open(_lowercase , 'w' ) as writer: with open(os.path.join(data_args.data_dir , 'test.txt' ) , 'r' ) as f: token_classification_task.write_predictions_to_file(_lowercase , _lowercase , _lowercase ) return results def _A ( _lowercase ) -> Dict: """simple docstring""" main() if __name__ == "__main__": main()

# Lint as: python3 import sys from collections.abc import Mapping from typing import TYPE_CHECKING, Dict, Optional import numpy as np import pyarrow as pa from .. import config from ..utils.logging import get_logger from ..utils.py_utils import map_nested from .formatting import TensorFormatter if TYPE_CHECKING: import jax import jaxlib __A : List[str] = get_logger() __A : Optional[dict] = None class _SCREAMING_SNAKE_CASE ( TensorFormatter[Mapping, "jax.Array", Mapping] ): '''simple docstring''' def __init__( self : Tuple , __lowerCamelCase : Tuple=None , __lowerCamelCase : int=None , **__lowerCamelCase : Dict ): super().__init__(features=__lowerCamelCase ) import jax from jaxlib.xla_client import Device if isinstance(__lowerCamelCase , __lowerCamelCase ): raise ValueError( f"Expected {device} to be a `str` not {type(__lowerCamelCase )}, as `jaxlib.xla_extension.Device` " "is not serializable neither with `pickle` nor with `dill`. Instead you can surround " "the device with `str()` to get its string identifier that will be internally mapped " "to the actual `jaxlib.xla_extension.Device`." ) SCREAMING_SNAKE_CASE = device if isinstance(__lowerCamelCase , __lowerCamelCase ) else str(jax.devices()[0] ) # using global variable since `jaxlib.xla_extension.Device` is not serializable neither # with `pickle` nor with `dill`, so we need to use a global variable instead global DEVICE_MAPPING if DEVICE_MAPPING is None: SCREAMING_SNAKE_CASE = self._map_devices_to_str() if self.device not in list(DEVICE_MAPPING.keys() ): logger.warning( f"Device with string identifier {self.device} not listed among the available " f"devices: {list(DEVICE_MAPPING.keys() )}, so falling back to the default " f"device: {str(jax.devices()[0] )}." ) SCREAMING_SNAKE_CASE = str(jax.devices()[0] ) SCREAMING_SNAKE_CASE = jnp_array_kwargs @staticmethod def _snake_case ( ): import jax return {str(__lowerCamelCase ): device for device in jax.devices()} def _snake_case ( self : Any , __lowerCamelCase : List[Any] ): import jax import jax.numpy as jnp if isinstance(__lowerCamelCase , __lowerCamelCase ) and column: if all( isinstance(__lowerCamelCase , jax.Array ) and x.shape == column[0].shape and x.dtype == column[0].dtype for x in column ): return jnp.stack(__lowerCamelCase , axis=0 ) return column def _snake_case ( self : int , __lowerCamelCase : Dict ): import jax import jax.numpy as jnp if isinstance(__lowerCamelCase , (str, bytes, type(__lowerCamelCase )) ): return value elif isinstance(__lowerCamelCase , (np.character, np.ndarray) ) and np.issubdtype(value.dtype , np.character ): return value.tolist() SCREAMING_SNAKE_CASE = {} if isinstance(__lowerCamelCase , (np.number, np.ndarray) ) and np.issubdtype(value.dtype , np.integer ): # the default int precision depends on the jax config # see https://jax.readthedocs.io/en/latest/notebooks/Common_Gotchas_in_JAX.html#double-64bit-precision if jax.config.jax_enable_xaa: SCREAMING_SNAKE_CASE = {"dtype": jnp.intaa} else: SCREAMING_SNAKE_CASE = {"dtype": jnp.intaa} elif isinstance(__lowerCamelCase , (np.number, np.ndarray) ) and np.issubdtype(value.dtype , np.floating ): SCREAMING_SNAKE_CASE = {"dtype": jnp.floataa} elif config.PIL_AVAILABLE and "PIL" in sys.modules: import PIL.Image if isinstance(__lowerCamelCase , PIL.Image.Image ): SCREAMING_SNAKE_CASE = np.asarray(__lowerCamelCase ) # using global variable since `jaxlib.xla_extension.Device` is not serializable neither # with `pickle` nor with `dill`, so we need to use a global variable instead global DEVICE_MAPPING if DEVICE_MAPPING is None: SCREAMING_SNAKE_CASE = self._map_devices_to_str() with jax.default_device(DEVICE_MAPPING[self.device] ): # calling jnp.array on a np.ndarray does copy the data # see https://github.com/google/jax/issues/4486 return jnp.array(__lowerCamelCase , **{**default_dtype, **self.jnp_array_kwargs} ) def _snake_case ( self : List[Any] , __lowerCamelCase : int ): import jax # support for torch, tf, jax etc. if config.TORCH_AVAILABLE and "torch" in sys.modules: import torch if isinstance(__lowerCamelCase , torch.Tensor ): return self._tensorize(data_struct.detach().cpu().numpy()[()] ) if hasattr(__lowerCamelCase , "__array__" ) and not isinstance(__lowerCamelCase , jax.Array ): SCREAMING_SNAKE_CASE = data_struct.__array__() # support for nested types like struct of list of struct if isinstance(__lowerCamelCase , np.ndarray ): if data_struct.dtype == object: # jax arrays cannot be instantied from an array of objects return self._consolidate([self.recursive_tensorize(__lowerCamelCase ) for substruct in data_struct] ) elif isinstance(__lowerCamelCase , (list, tuple) ): return self._consolidate([self.recursive_tensorize(__lowerCamelCase ) for substruct in data_struct] ) return self._tensorize(__lowerCamelCase ) def _snake_case ( self : Union[str, Any] , __lowerCamelCase : dict ): return map_nested(self._recursive_tensorize , __lowerCamelCase , map_list=__lowerCamelCase ) def _snake_case ( self : int , __lowerCamelCase : pa.Table ): SCREAMING_SNAKE_CASE = self.numpy_arrow_extractor().extract_row(__lowerCamelCase ) SCREAMING_SNAKE_CASE = self.python_features_decoder.decode_row(__lowerCamelCase ) return self.recursive_tensorize(__lowerCamelCase ) def _snake_case ( self : int , __lowerCamelCase : pa.Table ): SCREAMING_SNAKE_CASE = self.numpy_arrow_extractor().extract_column(__lowerCamelCase ) SCREAMING_SNAKE_CASE = self.python_features_decoder.decode_column(__lowerCamelCase , pa_table.column_names[0] ) SCREAMING_SNAKE_CASE = self.recursive_tensorize(__lowerCamelCase ) SCREAMING_SNAKE_CASE = self._consolidate(__lowerCamelCase ) return column def _snake_case ( self : int , __lowerCamelCase : pa.Table ): SCREAMING_SNAKE_CASE = self.numpy_arrow_extractor().extract_batch(__lowerCamelCase ) SCREAMING_SNAKE_CASE = self.python_features_decoder.decode_batch(__lowerCamelCase ) SCREAMING_SNAKE_CASE = self.recursive_tensorize(__lowerCamelCase ) for column_name in batch: SCREAMING_SNAKE_CASE = self._consolidate(batch[column_name] ) return batch

# # This a `torch.distributed` diagnostics script that checks that all GPUs in the cluster (one or # many nodes) can talk to each other via nccl and allocate gpu memory. # # To run first adjust the number of processes and nodes: # # python -m torch.distributed.run --nproc_per_node 2 --nnodes 1 torch-distributed-gpu-test.py # # You may need to add --master_addr $MASTER_ADDR --master_port $MASTER_PORT if using a custom addr:port # # You can also use the rdzv API: --rdzv_endpoint $MASTER_ADDR:$MASTER_PORT --rdzv_backend c10d # # use torch.distributed.launch instead of torch.distributed.run for torch < 1.9 # # If you get a hanging in `barrier` calls you have some network issues, you may try to debug this with: # # NCCL_DEBUG=INFO python -m torch.distributed.run --nproc_per_node 2 --nnodes 1 torch-distributed-gpu-test.py # # which should tell you what's going on behind the scenes. # # # This script can be run via `srun` in the SLURM environment as well. Here is a SLURM script that # runs on 2 nodes of 4 gpus per node: # # #SBATCH --job-name=test-nodes # name # #SBATCH --nodes=2 # nodes # #SBATCH --ntasks-per-node=1 # crucial - only 1 task per dist per node! # #SBATCH --cpus-per-task=10 # number of cores per tasks # #SBATCH --gres=gpu:4 # number of gpus # #SBATCH --time 0:05:00 # maximum execution time (HH:MM:SS) # #SBATCH --output=%x-%j.out # output file name # # GPUS_PER_NODE=4 # MASTER_ADDR=$(scontrol show hostnames $SLURM_JOB_NODELIST | head -n 1) # MASTER_PORT=6000 # # srun --jobid $SLURM_JOBID bash -c 'python -m torch.distributed.run \ # --nproc_per_node $GPUS_PER_NODE --nnodes $SLURM_NNODES --node_rank $SLURM_PROCID \ # --master_addr $MASTER_ADDR --master_port $MASTER_PORT \ # torch-distributed-gpu-test.py' # import fcntl import os import socket import torch import torch.distributed as dist def _A ( *_lowercase ) -> Tuple: """simple docstring""" with open(_lowercase , 'r' ) as fh: fcntl.flock(_lowercase , fcntl.LOCK_EX ) try: print(*_lowercase ) finally: fcntl.flock(_lowercase , fcntl.LOCK_UN ) __snake_case = int(os.environ['''LOCAL_RANK''']) torch.cuda.set_device(local_rank) __snake_case = torch.device('''cuda''', local_rank) __snake_case = socket.gethostname() __snake_case = f"""[{hostname}-{local_rank}]""" try: # test distributed dist.init_process_group('''nccl''') dist.all_reduce(torch.ones(1).to(device), op=dist.ReduceOp.SUM) dist.barrier() # test cuda is available and can allocate memory torch.cuda.is_available() torch.ones(1).cuda(local_rank) # global rank __snake_case = dist.get_rank() __snake_case = dist.get_world_size() printflock(f"""{gpu} is OK (global rank: {rank}/{world_size})""") dist.barrier() if rank == 0: printflock(f"""pt={torch.__version__}, cuda={torch.version.cuda}, nccl={torch.cuda.nccl.version()}""") except Exception: printflock(f"""{gpu} is broken""") raise

UpperCAmelCase_ : Optional[int] = { 0: '''0''', 1: '''1''', 2: '''2''', 3: '''3''', 4: '''4''', 5: '''5''', 6: '''6''', 7: '''7''', 8: '''8''', 9: '''9''', 10: '''a''', 11: '''b''', 12: '''c''', 13: '''d''', 14: '''e''', 15: '''f''', } def __SCREAMING_SNAKE_CASE ( a__ : float ) -> str: assert type(a__ ) in (int, float) and decimal == int(a__ ) __A : List[str] = int(a__ ) __A : List[Any] = """""" __A : int = False if decimal < 0: __A : Tuple = True decimal *= -1 while decimal > 0: __A , __A : List[Any] = divmod(a__ ,16 ) __A : Union[str, Any] = values[remainder] + hexadecimal __A : Optional[Any] = """0x""" + hexadecimal if negative: __A : Tuple = """-""" + hexadecimal return hexadecimal if __name__ == "__main__": import doctest doctest.testmod()

import pytest import datasets # Import fixture modules as plugins __snake_case = ['''tests.fixtures.files''', '''tests.fixtures.hub''', '''tests.fixtures.fsspec'''] def _A ( _lowercase , _lowercase ) -> Tuple: """simple docstring""" for item in items: if any(marker in item.keywords for marker in ['integration', 'unit'] ): continue item.add_marker(pytest.mark.unit ) def _A ( _lowercase ) -> str: """simple docstring""" config.addinivalue_line('markers' , 'torchaudio_latest: mark test to run with torchaudio>=0.12' ) @pytest.fixture(autouse=_lowercase ) def _A ( _lowercase , _lowercase ) -> Any: """simple docstring""" __UpperCamelCase = tmp_path_factory.getbasetemp() / 'cache' __UpperCamelCase = test_hf_cache_home / 'datasets' __UpperCamelCase = test_hf_cache_home / 'metrics' __UpperCamelCase = test_hf_cache_home / 'modules' monkeypatch.setattr('datasets.config.HF_DATASETS_CACHE' , str(_lowercase ) ) monkeypatch.setattr('datasets.config.HF_METRICS_CACHE' , str(_lowercase ) ) monkeypatch.setattr('datasets.config.HF_MODULES_CACHE' , str(_lowercase ) ) __UpperCamelCase = test_hf_datasets_cache / 'downloads' monkeypatch.setattr('datasets.config.DOWNLOADED_DATASETS_PATH' , str(_lowercase ) ) __UpperCamelCase = test_hf_datasets_cache / 'downloads' / 'extracted' monkeypatch.setattr('datasets.config.EXTRACTED_DATASETS_PATH' , str(_lowercase ) ) @pytest.fixture(autouse=_lowercase , scope='session' ) def _A ( ) -> Dict: """simple docstring""" datasets.disable_progress_bar() @pytest.fixture(autouse=_lowercase ) def _A ( _lowercase ) -> Tuple: """simple docstring""" monkeypatch.setattr('datasets.config.HF_UPDATE_DOWNLOAD_COUNTS' , _lowercase ) @pytest.fixture def _A ( _lowercase ) -> Any: """simple docstring""" monkeypatch.setattr('sqlalchemy.util.deprecations.SILENCE_UBER_WARNING' , _lowercase )

'''simple docstring''' import argparse import json import os import re import torch from transformers import BloomConfig, BloomModel from transformers.file_utils import CONFIG_NAME, WEIGHTS_NAME from transformers.utils import logging logging.set_verbosity_info() _SCREAMING_SNAKE_CASE = [ "word_embeddings_layernorm.weight", "word_embeddings_layernorm.bias", "input_layernorm.weight", "input_layernorm.bias", "post_attention_layernorm.weight", "post_attention_layernorm.bias", "self_attention.dense.bias", "mlp.dense_4h_to_h.bias", "ln_f.weight", "ln_f.bias", ] _SCREAMING_SNAKE_CASE = [ "mlp.dense_4h_to_h.weight", "self_attention.dense.weight", ] def __a(SCREAMING_SNAKE_CASE_ : List[Any] , SCREAMING_SNAKE_CASE_ : Any ): '''simple docstring''' _lowerCAmelCase = { "word_embeddings.weight": "word_embeddings.weight", "word_embeddings.norm.weight": "word_embeddings_layernorm.weight", "word_embeddings.norm.bias": "word_embeddings_layernorm.bias", "weight": "ln_f.weight", "bias": "ln_f.bias", } if key in layer_rename_map: return layer_rename_map[key] # Handle transformer blocks _lowerCAmelCase = int(re.match(R".*layer_(\d*).*" , SCREAMING_SNAKE_CASE_ )[1] ) layer_number -= 3 return F'''h.{layer_number}.''' + key def __a(SCREAMING_SNAKE_CASE_ : Dict ): '''simple docstring''' if dtype == torch.bool: return 1 / 8 _lowerCAmelCase = re.search(R"[^\d](\d+)$" , str(SCREAMING_SNAKE_CASE_ ) ) if bit_search is None: raise ValueError(F'''`dtype` is not a valid dtype: {dtype}.''' ) _lowerCAmelCase = int(bit_search.groups()[0] ) return bit_size // 8 def __a(SCREAMING_SNAKE_CASE_ : Optional[Any] , SCREAMING_SNAKE_CASE_ : Dict , SCREAMING_SNAKE_CASE_ : Union[str, Any] , SCREAMING_SNAKE_CASE_ : Optional[int] , SCREAMING_SNAKE_CASE_ : List[Any] ): '''simple docstring''' if bloom_config_file == "": _lowerCAmelCase = BloomConfig() else: _lowerCAmelCase = BloomConfig.from_json_file(SCREAMING_SNAKE_CASE_ ) if shard_model: _lowerCAmelCase = os.listdir(SCREAMING_SNAKE_CASE_ ) _lowerCAmelCase = sorted(filter(lambda SCREAMING_SNAKE_CASE_ : s.startswith("layer" ) and "model_00" in s , SCREAMING_SNAKE_CASE_ ) ) _lowerCAmelCase = {"weight_map": {}, "metadata": {}} _lowerCAmelCase = 0 _lowerCAmelCase = None _lowerCAmelCase = BloomConfig() for j, file in enumerate(SCREAMING_SNAKE_CASE_ ): print("Processing file: {}".format(SCREAMING_SNAKE_CASE_ ) ) _lowerCAmelCase = None for i in range(SCREAMING_SNAKE_CASE_ ): # load all TP files _lowerCAmelCase = file.replace("model_00" , F'''model_0{i}''' ) _lowerCAmelCase = torch.load(os.path.join(SCREAMING_SNAKE_CASE_ , SCREAMING_SNAKE_CASE_ ) , map_location="cpu" ) # Rename keys in the transformers names _lowerCAmelCase = list(temp.keys() ) for key in keys: _lowerCAmelCase = temp.pop(SCREAMING_SNAKE_CASE_ ) if tensors is None: _lowerCAmelCase = temp else: for key in tensors.keys(): if any(key.endswith(SCREAMING_SNAKE_CASE_ ) for end in WEIGHTS_TO_AVERAGE_ENDSWITH ): # We average (sum and then divide) some weights accross TP ranks (see https://github.com/bigscience-workshop/Megatron-DeepSpeed/blob/olruwase/sync_layer_norms/megatron/training.py#L425) tensors[key] += temp[key] else: # Some weights are RowParallelLinear in Megatron-Deepspeed, others are ColumnParallel _lowerCAmelCase = 1 if any(text in key for text in WEIGHTS_WITH_ROW_PARALLELISM_CONTAIN ) else 0 # We concatenate these weights accross TP ranks _lowerCAmelCase = torch.cat([tensors[key], temp[key]] , dim=SCREAMING_SNAKE_CASE_ ) # Divide by the number of TP the weights we want to average for key in tensors.keys(): if any(key.endswith(SCREAMING_SNAKE_CASE_ ) for end in WEIGHTS_TO_AVERAGE_ENDSWITH ): _lowerCAmelCase = tensors[key] / pretraining_tp torch.save( SCREAMING_SNAKE_CASE_ , os.path.join( SCREAMING_SNAKE_CASE_ , "pytorch_model_{}-of-{}.bin".format(str(j + 1 ).zfill(5 ) , str(len(SCREAMING_SNAKE_CASE_ ) ).zfill(5 ) ) , ) , ) for key in tensors.keys(): _lowerCAmelCase = tensors[key] total_size += value.numel() * get_dtype_size(value.dtype ) if key not in index_dict["weight_map"]: _lowerCAmelCase = "pytorch_model_{}-of-{}.bin".format( str(j + 1 ).zfill(5 ) , str(len(SCREAMING_SNAKE_CASE_ ) ).zfill(5 ) ) _lowerCAmelCase = BloomConfig() _lowerCAmelCase = pytorch_dump_folder_path + "/" + CONFIG_NAME _lowerCAmelCase = total_size with open(SCREAMING_SNAKE_CASE_ , "w" , encoding="utf-8" ) as f: f.write(config.to_json_string() ) with open(os.path.join(SCREAMING_SNAKE_CASE_ , WEIGHTS_NAME + ".index.json" ) , "w" , encoding="utf-8" ) as f: _lowerCAmelCase = json.dumps(SCREAMING_SNAKE_CASE_ , indent=2 , sort_keys=SCREAMING_SNAKE_CASE_ ) + "\n" f.write(SCREAMING_SNAKE_CASE_ ) else: _lowerCAmelCase = BloomModel(SCREAMING_SNAKE_CASE_ ) _lowerCAmelCase = os.listdir(SCREAMING_SNAKE_CASE_ ) _lowerCAmelCase = sorted(filter(lambda SCREAMING_SNAKE_CASE_ : s.startswith("layer" ) and "model_00" in s , SCREAMING_SNAKE_CASE_ ) ) _lowerCAmelCase = None for i, file in enumerate(SCREAMING_SNAKE_CASE_ ): _lowerCAmelCase = None for i in range(SCREAMING_SNAKE_CASE_ ): # load all TP files _lowerCAmelCase = file.replace("model_00" , F'''model_0{i}''' ) _lowerCAmelCase = torch.load(os.path.join(SCREAMING_SNAKE_CASE_ , SCREAMING_SNAKE_CASE_ ) , map_location="cpu" ) # Rename keys in the transformers names _lowerCAmelCase = list(temp.keys() ) for key in keys: _lowerCAmelCase = temp.pop(SCREAMING_SNAKE_CASE_ ) if tensors is None: _lowerCAmelCase = temp else: for key in tensors.keys(): # We average (sum and then divide) some weights accross TP ranks (see https://github.com/bigscience-workshop/Megatron-DeepSpeed/blob/olruwase/sync_layer_norms/megatron/training.py#L425) if any(key.endswith(SCREAMING_SNAKE_CASE_ ) for end in WEIGHTS_TO_AVERAGE_ENDSWITH ): tensors[key] += temp[key] else: # Some weights are RowParallelLinear in Megatron-Deepspeed, others are ColumnParallel _lowerCAmelCase = 1 if any(text in key for text in WEIGHTS_WITH_ROW_PARALLELISM_CONTAIN ) else 0 # We concatenate these weights accross TP ranks _lowerCAmelCase = torch.cat([tensors[key], temp[key]] , dim=SCREAMING_SNAKE_CASE_ ) # Divide by the number of TP the weights we want to average for key in tensors.keys(): if any(key.endswith(SCREAMING_SNAKE_CASE_ ) for end in WEIGHTS_TO_AVERAGE_ENDSWITH ): _lowerCAmelCase = tensors[key] / pretraining_tp _lowerCAmelCase = model.load_state_dict(SCREAMING_SNAKE_CASE_ , strict=SCREAMING_SNAKE_CASE_ ) assert not other_keys.unexpected_keys, F'''The keys {other_keys.unexpected_keys} are unexpected''' if missing_keys is None: _lowerCAmelCase = set(other_keys.missing_keys ) else: _lowerCAmelCase = missing_keys.intersection(set(other_keys.missing_keys ) ) assert not missing_keys, F'''The keys {missing_keys} are missing''' # Save pytorch-model os.makedirs(SCREAMING_SNAKE_CASE_ , exist_ok=SCREAMING_SNAKE_CASE_ ) _lowerCAmelCase = pytorch_dump_folder_path + "/" + WEIGHTS_NAME _lowerCAmelCase = pytorch_dump_folder_path + "/" + CONFIG_NAME print(F'''Save PyTorch model to {pytorch_weights_dump_path} with dtype {config.torch_dtype}''' ) if config.torch_dtype is not None: _lowerCAmelCase = model.to(config.torch_dtype ) torch.save(model.state_dict() , SCREAMING_SNAKE_CASE_ ) print(F'''Save configuration file to {pytorch_config_dump_path}''' ) with open(SCREAMING_SNAKE_CASE_ , "w" , encoding="utf-8" ) as f: f.write(config.to_json_string() ) if __name__ == "__main__": _SCREAMING_SNAKE_CASE = argparse.ArgumentParser() # Required parameters parser.add_argument( "--bloom_checkpoint_path", default=None, type=str, required=True, help="Path to the Megatron-LM checkpoint path.", ) parser.add_argument( "--pytorch_dump_folder_path", default=None, type=str, required=True, help="Path to the output PyTorch model." ) parser.add_argument( "--bloom_config_file", default="", type=str, help=( "An optional config json file corresponding to the pre-trained model. \n" "This specifies the model architecture." ), ) parser.add_argument( "--shard_model", action="store_true", help="An optional setting to shard the output model \nThis enables sharding the converted checkpoint", ) parser.add_argument( "--pretraining_tp", default=4, type=int, help="Pretraining TP rank that has been used when training the model in Megatron-LM \n", ) _SCREAMING_SNAKE_CASE = parser.parse_args() convert_bloom_checkpoint_to_pytorch( args.bloom_checkpoint_path, args.bloom_config_file, args.pytorch_dump_folder_path, args.shard_model, args.pretraining_tp, )

import random import unittest import numpy as np import torch from transformers import CLIPTextConfig, CLIPTextModel, CLIPTokenizer from diffusers import ( AutoencoderKL, DDIMScheduler, UNetaDConditionModel, VideoToVideoSDPipeline, ) from diffusers.utils import floats_tensor, is_xformers_available, skip_mps from diffusers.utils.testing_utils import enable_full_determinism, slow, torch_device from ..pipeline_params import ( TEXT_GUIDED_IMAGE_VARIATION_BATCH_PARAMS, TEXT_GUIDED_IMAGE_VARIATION_PARAMS, ) from ..test_pipelines_common import PipelineTesterMixin enable_full_determinism() @skip_mps class __lowerCamelCase (_a , unittest.TestCase ): _lowercase = VideoToVideoSDPipeline _lowercase = TEXT_GUIDED_IMAGE_VARIATION_PARAMS.union({"""video"""} ) - {"""image""", """width""", """height"""} _lowercase = TEXT_GUIDED_IMAGE_VARIATION_BATCH_PARAMS.union({"""video"""} ) - {"""image"""} _lowercase = PipelineTesterMixin.required_optional_params - {"""latents"""} _lowercase = False # No `output_type`. _lowercase = frozenset( [ """num_inference_steps""", """generator""", """latents""", """return_dict""", """callback""", """callback_steps""", ] ) def snake_case_ ( self: List[str] ): '''simple docstring''' torch.manual_seed(0 ) __UpperCamelCase = UNetaDConditionModel( block_out_channels=(32, 64, 64, 64),layers_per_block=2,sample_size=32,in_channels=4,out_channels=4,down_block_types=('CrossAttnDownBlock3D', 'CrossAttnDownBlock3D', 'CrossAttnDownBlock3D', 'DownBlock3D'),up_block_types=('UpBlock3D', 'CrossAttnUpBlock3D', 'CrossAttnUpBlock3D', 'CrossAttnUpBlock3D'),cross_attention_dim=32,attention_head_dim=4,) __UpperCamelCase = DDIMScheduler( beta_start=0.0_0_0_8_5,beta_end=0.0_1_2,beta_schedule='scaled_linear',clip_sample=A_,set_alpha_to_one=A_,) torch.manual_seed(0 ) __UpperCamelCase = AutoencoderKL( block_out_channels=[32, 64],in_channels=3,out_channels=3,down_block_types=['DownEncoderBlock2D', 'DownEncoderBlock2D'],up_block_types=['UpDecoderBlock2D', 'UpDecoderBlock2D'],latent_channels=4,sample_size=128,) torch.manual_seed(0 ) __UpperCamelCase = 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,) __UpperCamelCase = CLIPTextModel(A_ ) __UpperCamelCase = CLIPTokenizer.from_pretrained('hf-internal-testing/tiny-random-clip' ) __UpperCamelCase = { 'unet': unet, 'scheduler': scheduler, 'vae': vae, 'text_encoder': text_encoder, 'tokenizer': tokenizer, } return components def snake_case_ ( self: Union[str, Any],A_: Any,A_: Any=0 ): '''simple docstring''' __UpperCamelCase = floats_tensor((1, 3, 3, 32, 32),rng=random.Random(A_ ) ).to(A_ ) if str(A_ ).startswith('mps' ): __UpperCamelCase = torch.manual_seed(A_ ) else: __UpperCamelCase = torch.Generator(device=A_ ).manual_seed(A_ ) __UpperCamelCase = { 'prompt': 'A painting of a squirrel eating a burger', 'video': video, 'generator': generator, 'num_inference_steps': 2, 'guidance_scale': 6.0, 'output_type': 'pt', } return inputs def snake_case_ ( self: Union[str, Any] ): '''simple docstring''' __UpperCamelCase = 'cpu' # ensure determinism for the device-dependent torch.Generator __UpperCamelCase = self.get_dummy_components() __UpperCamelCase = VideoToVideoSDPipeline(**A_ ) __UpperCamelCase = sd_pipe.to(A_ ) sd_pipe.set_progress_bar_config(disable=A_ ) __UpperCamelCase = self.get_dummy_inputs(A_ ) __UpperCamelCase = 'np' __UpperCamelCase = sd_pipe(**A_ ).frames __UpperCamelCase = frames[0][-3:, -3:, -1] assert frames[0].shape == (32, 32, 3) __UpperCamelCase = np.array([106, 117, 113, 174, 137, 112, 148, 151, 131] ) assert np.abs(image_slice.flatten() - expected_slice ).max() < 1E-2 @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: Any ): '''simple docstring''' self._test_xformers_attention_forwardGenerator_pass(test_mean_pixel_difference=A_,expected_max_diff=5E-3 ) @unittest.skip(reason='Batching needs to be properly figured out first for this pipeline.' ) def snake_case_ ( self: str ): '''simple docstring''' pass @unittest.skip(reason='Batching needs to be properly figured out first for this pipeline.' ) def snake_case_ ( self: Optional[Any] ): '''simple docstring''' pass @unittest.skip(reason='`num_images_per_prompt` argument is not supported for this pipeline.' ) def snake_case_ ( self: int ): '''simple docstring''' pass def snake_case_ ( self: Any ): '''simple docstring''' return super().test_progress_bar() @slow @skip_mps class __lowerCamelCase (unittest.TestCase ): def snake_case_ ( self: Tuple ): '''simple docstring''' __UpperCamelCase = VideoToVideoSDPipeline.from_pretrained('cerspense/zeroscope_v2_XL',torch_dtype=torch.floataa ) pipe.enable_model_cpu_offload() # 10 frames __UpperCamelCase = torch.Generator(device='cpu' ).manual_seed(0 ) __UpperCamelCase = torch.randn((1, 10, 3, 1024, 576),generator=A_ ) __UpperCamelCase = video.to('cuda' ) __UpperCamelCase = 'Spiderman is surfing' __UpperCamelCase = pipe(A_,video=A_,generator=A_,num_inference_steps=3,output_type='pt' ).frames __UpperCamelCase = np.array([-1.0_4_5_8_9_8_4, -1.1_2_7_9_2_9_7, -0.9_6_6_3_0_8_6, -0.9_1_5_0_3_9_0_6, -0.7_5_0_9_7_6_5_6] ) assert np.abs(video_frames.cpu().numpy()[0, 0, 0, 0, -5:] - expected_array ).sum() < 1E-2

"""simple docstring""" 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( lowerCamelCase , unittest.TestCase ): lowercase__ = MobileBertTokenizer lowercase__ = MobileBertTokenizerFast lowercase__ = True lowercase__ = True lowercase__ = filter_non_english lowercase__ = 'google/mobilebert-uncased' def UpperCAmelCase ( self) -> Tuple: '''simple docstring''' super().setUp() _UpperCamelCase = [ '''[UNK]''', '''[CLS]''', '''[SEP]''', '''[PAD]''', '''[MASK]''', '''want''', '''##want''', '''##ed''', '''wa''', '''un''', '''runn''', '''##ing''', ''',''', '''low''', '''lowest''', ] _UpperCamelCase = os.path.join(self.tmpdirname , VOCAB_FILES_NAMES['''vocab_file''']) with open(self.vocab_file , '''w''' , encoding='''utf-8''') as vocab_writer: vocab_writer.write(''''''.join([x + '''\n''' for x in vocab_tokens])) _UpperCamelCase = [ (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 UpperCAmelCase ( self , __a) -> List[str]: '''simple docstring''' _UpperCamelCase = '''UNwant\u00E9d,running''' _UpperCamelCase = '''unwanted, running''' return input_text, output_text def UpperCAmelCase ( self) -> Any: '''simple docstring''' _UpperCamelCase = self.tokenizer_class(self.vocab_file) _UpperCamelCase = 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 UpperCAmelCase ( self) -> Dict: '''simple docstring''' if not self.test_rust_tokenizer: return _UpperCamelCase = self.get_tokenizer() _UpperCamelCase = self.get_rust_tokenizer() _UpperCamelCase = '''UNwant\u00E9d,running''' _UpperCamelCase = tokenizer.tokenize(__a) _UpperCamelCase = rust_tokenizer.tokenize(__a) self.assertListEqual(__a , __a) _UpperCamelCase = tokenizer.encode(__a , add_special_tokens=__a) _UpperCamelCase = rust_tokenizer.encode(__a , add_special_tokens=__a) self.assertListEqual(__a , __a) _UpperCamelCase = self.get_rust_tokenizer() _UpperCamelCase = tokenizer.encode(__a) _UpperCamelCase = rust_tokenizer.encode(__a) self.assertListEqual(__a , __a) # With lower casing _UpperCamelCase = self.get_tokenizer(do_lower_case=__a) _UpperCamelCase = self.get_rust_tokenizer(do_lower_case=__a) _UpperCamelCase = '''UNwant\u00E9d,running''' _UpperCamelCase = tokenizer.tokenize(__a) _UpperCamelCase = rust_tokenizer.tokenize(__a) self.assertListEqual(__a , __a) _UpperCamelCase = tokenizer.encode(__a , add_special_tokens=__a) _UpperCamelCase = rust_tokenizer.encode(__a , add_special_tokens=__a) self.assertListEqual(__a , __a) _UpperCamelCase = self.get_rust_tokenizer() _UpperCamelCase = tokenizer.encode(__a) _UpperCamelCase = rust_tokenizer.encode(__a) self.assertListEqual(__a , __a) def UpperCAmelCase ( self) -> Optional[Any]: '''simple docstring''' _UpperCamelCase = BasicTokenizer() self.assertListEqual(tokenizer.tokenize('''ah\u535A\u63A8zz''') , ['''ah''', '''\u535A''', '''\u63A8''', '''zz''']) def UpperCAmelCase ( self) -> Dict: '''simple docstring''' _UpperCamelCase = 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 UpperCAmelCase ( self) -> Union[str, Any]: '''simple docstring''' _UpperCamelCase = 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 UpperCAmelCase ( self) -> List[Any]: '''simple docstring''' _UpperCamelCase = 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 UpperCAmelCase ( self) -> Optional[int]: '''simple docstring''' _UpperCamelCase = 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 UpperCAmelCase ( self) -> Dict: '''simple docstring''' _UpperCamelCase = BasicTokenizer(do_lower_case=__a) self.assertListEqual( tokenizer.tokenize(''' \tHeLLo!how \n Are yoU? ''') , ['''HeLLo''', '''!''', '''how''', '''Are''', '''yoU''', '''?''']) def UpperCAmelCase ( self) -> List[Any]: '''simple docstring''' _UpperCamelCase = BasicTokenizer(do_lower_case=__a , strip_accents=__a) self.assertListEqual( tokenizer.tokenize(''' \tHäLLo!how \n Are yoU? ''') , ['''HäLLo''', '''!''', '''how''', '''Are''', '''yoU''', '''?''']) def UpperCAmelCase ( self) -> Tuple: '''simple docstring''' _UpperCamelCase = BasicTokenizer(do_lower_case=__a , strip_accents=__a) self.assertListEqual( tokenizer.tokenize(''' \tHäLLo!how \n Are yoU? ''') , ['''HaLLo''', '''!''', '''how''', '''Are''', '''yoU''', '''?''']) def UpperCAmelCase ( self) -> Optional[int]: '''simple docstring''' _UpperCamelCase = BasicTokenizer(do_lower_case=__a , never_split=['''[UNK]''']) self.assertListEqual( tokenizer.tokenize(''' \tHeLLo!how \n Are yoU? [UNK]''') , ['''HeLLo''', '''!''', '''how''', '''Are''', '''yoU''', '''?''', '''[UNK]''']) def UpperCAmelCase ( self) -> Optional[int]: '''simple docstring''' _UpperCamelCase = ['''[UNK]''', '''[CLS]''', '''[SEP]''', '''want''', '''##want''', '''##ed''', '''wa''', '''un''', '''runn''', '''##ing'''] _UpperCamelCase = {} for i, token in enumerate(__a): _UpperCamelCase = i _UpperCamelCase = 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 UpperCAmelCase ( self) -> List[str]: '''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 UpperCAmelCase ( self) -> Optional[Any]: '''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 UpperCAmelCase ( self) -> Optional[Any]: '''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 UpperCAmelCase ( self) -> List[Any]: '''simple docstring''' _UpperCamelCase = self.get_tokenizer() _UpperCamelCase = 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 UpperCAmelCase ( self) -> Optional[Any]: '''simple docstring''' _UpperCamelCase = self.tokenizer_class.from_pretrained('''google/mobilebert-uncased''') _UpperCamelCase = tokenizer.encode('''sequence builders''' , add_special_tokens=__a) _UpperCamelCase = tokenizer.encode('''multi-sequence build''' , add_special_tokens=__a) _UpperCamelCase = tokenizer.build_inputs_with_special_tokens(__a) _UpperCamelCase = tokenizer.build_inputs_with_special_tokens(__a , __a) assert encoded_sentence == [1_01] + text + [1_02] assert encoded_pair == [1_01] + text + [1_02] + text_a + [1_02] def UpperCAmelCase ( self) -> List[str]: '''simple docstring''' for tokenizer, pretrained_name, kwargs in self.tokenizers_list: with self.subTest(F'''{tokenizer.__class__.__name__} ({pretrained_name})'''): _UpperCamelCase = self.rust_tokenizer_class.from_pretrained(__a , **__a) _UpperCamelCase = F'''A, naïve {tokenizer_r.mask_token} AllenNLP sentence.''' _UpperCamelCase = tokenizer_r.encode_plus( __a , return_attention_mask=__a , return_token_type_ids=__a , return_offsets_mapping=__a , add_special_tokens=__a , ) _UpperCamelCase = tokenizer_r.do_lower_case if hasattr(__a , '''do_lower_case''') else False _UpperCamelCase = ( [ ((0, 0), tokenizer_r.cls_token), ((0, 1), '''A'''), ((1, 2), ''','''), ((3, 5), '''na'''), ((5, 6), '''##ï'''), ((6, 8), '''##ve'''), ((9, 15), tokenizer_r.mask_token), ((16, 21), '''Allen'''), ((21, 23), '''##NL'''), ((23, 24), '''##P'''), ((25, 33), '''sentence'''), ((33, 34), '''.'''), ((0, 0), tokenizer_r.sep_token), ] if not do_lower_case else [ ((0, 0), tokenizer_r.cls_token), ((0, 1), '''a'''), ((1, 2), ''','''), ((3, 8), '''naive'''), ((9, 15), tokenizer_r.mask_token), ((16, 21), '''allen'''), ((21, 23), '''##nl'''), ((23, 24), '''##p'''), ((25, 33), '''sentence'''), ((33, 34), '''.'''), ((0, 0), tokenizer_r.sep_token), ] ) self.assertEqual( [e[1] for e in expected_results] , tokenizer_r.convert_ids_to_tokens(tokens['''input_ids'''])) self.assertEqual([e[0] for e in expected_results] , tokens['''offset_mapping''']) def UpperCAmelCase ( self) -> Optional[int]: '''simple docstring''' _UpperCamelCase = ['''的''', '''人''', '''有'''] _UpperCamelCase = ''''''.join(__a) for tokenizer, pretrained_name, kwargs in self.tokenizers_list: with self.subTest(F'''{tokenizer.__class__.__name__} ({pretrained_name})'''): _UpperCamelCase = True _UpperCamelCase = self.tokenizer_class.from_pretrained(__a , **__a) _UpperCamelCase = self.rust_tokenizer_class.from_pretrained(__a , **__a) _UpperCamelCase = tokenizer_p.encode(__a , add_special_tokens=__a) _UpperCamelCase = tokenizer_r.encode(__a , add_special_tokens=__a) _UpperCamelCase = tokenizer_r.convert_ids_to_tokens(__a) _UpperCamelCase = 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) _UpperCamelCase = False _UpperCamelCase = self.rust_tokenizer_class.from_pretrained(__a , **__a) _UpperCamelCase = self.tokenizer_class.from_pretrained(__a , **__a) _UpperCamelCase = tokenizer_r.encode(__a , add_special_tokens=__a) _UpperCamelCase = tokenizer_p.encode(__a , add_special_tokens=__a) _UpperCamelCase = tokenizer_r.convert_ids_to_tokens(__a) _UpperCamelCase = tokenizer_p.convert_ids_to_tokens(__a) # it is expected that only the first Chinese character is not preceded by "##". _UpperCamelCase = [ F'''##{token}''' if idx != 0 else token for idx, token in enumerate(__a) ] self.assertListEqual(__a , __a) self.assertListEqual(__a , __a)

import argparse from transformers import CLIPImageProcessor, CLIPVisionModelWithProjection from diffusers import UnCLIPImageVariationPipeline, UnCLIPPipeline if __name__ == "__main__": __snake_case = argparse.ArgumentParser() parser.add_argument('''--dump_path''', default=None, type=str, required=True, help='''Path to the output model.''') parser.add_argument( '''--txt2img_unclip''', default='''kakaobrain/karlo-v1-alpha''', type=str, required=False, help='''The pretrained txt2img unclip.''', ) __snake_case = parser.parse_args() __snake_case = UnCLIPPipeline.from_pretrained(args.txtaimg_unclip) __snake_case = CLIPImageProcessor() __snake_case = CLIPVisionModelWithProjection.from_pretrained('''openai/clip-vit-large-patch14''') __snake_case = UnCLIPImageVariationPipeline( decoder=txtaimg.decoder, text_encoder=txtaimg.text_encoder, tokenizer=txtaimg.tokenizer, text_proj=txtaimg.text_proj, feature_extractor=feature_extractor, image_encoder=image_encoder, super_res_first=txtaimg.super_res_first, super_res_last=txtaimg.super_res_last, decoder_scheduler=txtaimg.decoder_scheduler, super_res_scheduler=txtaimg.super_res_scheduler, ) imgaimg.save_pretrained(args.dump_path)

import unittest from transformers import BertGenerationTokenizer from transformers.testing_utils import get_tests_dir, require_sentencepiece, require_torch, slow from transformers.utils import cached_property from ...test_tokenization_common import TokenizerTesterMixin _lowerCAmelCase: Tuple = '▁' _lowerCAmelCase: List[str] = get_tests_dir('fixtures/test_sentencepiece.model') @require_sentencepiece class lowercase_ (lowercase__ , unittest.TestCase ): snake_case =BertGenerationTokenizer snake_case =False snake_case =True def __UpperCamelCase ( self) -> Union[str, Any]: super().setUp() a__ =BertGenerationTokenizer(lowercase_ , keep_accents=lowercase_) tokenizer.save_pretrained(self.tmpdirname) def __UpperCamelCase ( self) -> List[Any]: a__ ='<s>' a__ =1 self.assertEqual(self.get_tokenizer()._convert_token_to_id(lowercase_) , lowercase_) self.assertEqual(self.get_tokenizer()._convert_id_to_token(lowercase_) , lowercase_) def __UpperCamelCase ( self) -> List[str]: a__ =list(self.get_tokenizer().get_vocab().keys()) self.assertEqual(vocab_keys[0] , '<unk>') self.assertEqual(vocab_keys[1] , '<s>') self.assertEqual(vocab_keys[-1] , '<pad>') self.assertEqual(len(lowercase_) , 1002) def __UpperCamelCase ( self) -> Optional[int]: self.assertEqual(self.get_tokenizer().vocab_size , 1000) def __UpperCamelCase ( self) -> Optional[Any]: a__ =BertGenerationTokenizer(lowercase_ , keep_accents=lowercase_) a__ =tokenizer.tokenize('This is a test') self.assertListEqual(lowercase_ , ['▁This', '▁is', '▁a', '▁t', 'est']) self.assertListEqual( tokenizer.convert_tokens_to_ids(lowercase_) , [285, 46, 10, 170, 382] , ) a__ =tokenizer.tokenize('I was born in 92000, and this is falsé.') self.assertListEqual( lowercase_ , [ SPIECE_UNDERLINE + 'I', SPIECE_UNDERLINE + 'was', SPIECE_UNDERLINE + 'b', 'or', 'n', SPIECE_UNDERLINE + 'in', SPIECE_UNDERLINE + '', '9', '2', '0', '0', '0', ',', SPIECE_UNDERLINE + 'and', SPIECE_UNDERLINE + 'this', SPIECE_UNDERLINE + 'is', SPIECE_UNDERLINE + 'f', 'al', 's', 'é', '.', ] , ) a__ =tokenizer.convert_tokens_to_ids(lowercase_) self.assertListEqual( lowercase_ , [8, 21, 84, 55, 24, 19, 7, 0, 602, 347, 347, 347, 3, 12, 66, 46, 72, 80, 6, 0, 4] , ) a__ =tokenizer.convert_ids_to_tokens(lowercase_) self.assertListEqual( lowercase_ , [ SPIECE_UNDERLINE + 'I', SPIECE_UNDERLINE + 'was', SPIECE_UNDERLINE + 'b', 'or', 'n', SPIECE_UNDERLINE + 'in', SPIECE_UNDERLINE + '', '<unk>', '2', '0', '0', '0', ',', SPIECE_UNDERLINE + 'and', SPIECE_UNDERLINE + 'this', SPIECE_UNDERLINE + 'is', SPIECE_UNDERLINE + 'f', 'al', 's', '<unk>', '.', ] , ) @cached_property def __UpperCamelCase ( self) -> Optional[Any]: return BertGenerationTokenizer.from_pretrained('google/bert_for_seq_generation_L-24_bbc_encoder') @slow def __UpperCamelCase ( self) -> Optional[Any]: a__ ='Hello World!' a__ =[18536, 2260, 101] self.assertListEqual(lowercase_ , self.big_tokenizer.encode(lowercase_)) @slow def __UpperCamelCase ( self) -> Optional[int]: a__ =( 'This is a very long text with a lot of weird characters, such as: . , ~ ? ( ) " [ ] ! : - . Also we will' ' add words that should not exsist and be tokenized to <unk>, such as saoneuhaoesuth' ) a__ =[ 871, 419, 358, 946, 991, 2521, 452, 358, 1357, 387, 7751, 3536, 112, 985, 456, 126, 865, 938, 5400, 5734, 458, 1368, 467, 786, 2462, 5246, 1159, 633, 865, 4519, 457, 582, 852, 2557, 427, 916, 508, 405, 34324, 497, 391, 408, 11342, 1244, 385, 100, 938, 985, 456, 574, 362, 12597, 3200, 3129, 1172, ] self.assertListEqual(lowercase_ , self.big_tokenizer.encode(lowercase_)) @require_torch @slow def __UpperCamelCase ( self) -> Optional[Any]: import torch from transformers import BertGenerationConfig, BertGenerationEncoder # Build sequence a__ =list(self.big_tokenizer.get_vocab().keys())[:10] a__ =' '.join(lowercase_) a__ =self.big_tokenizer.encode_plus(lowercase_ , return_tensors='pt' , return_token_type_ids=lowercase_) a__ =self.big_tokenizer.batch_encode_plus( [sequence + ' ' + sequence] , return_tensors='pt' , return_token_type_ids=lowercase_) a__ =BertGenerationConfig() a__ =BertGenerationEncoder(lowercase_) assert model.get_input_embeddings().weight.shape[0] >= self.big_tokenizer.vocab_size with torch.no_grad(): model(**lowercase_) model(**lowercase_) @slow def __UpperCamelCase ( self) -> List[Any]: # fmt: off a__ ={'input_ids': [[39286, 458, 36335, 2001, 456, 13073, 13266, 455, 113, 7746, 1741, 11157, 391, 13073, 13266, 455, 113, 3967, 35412, 113, 4936, 109, 3870, 2377, 113, 30084, 45720, 458, 134, 17496, 112, 503, 11672, 113, 118, 112, 5665, 13347, 38687, 112, 1496, 31389, 112, 3268, 47264, 134, 962, 112, 16377, 8035, 23130, 430, 12169, 15518, 28592, 458, 146, 41697, 109, 391, 12169, 15518, 16689, 458, 146, 41358, 109, 452, 726, 4034, 111, 763, 35412, 5082, 388, 1903, 111, 9051, 391, 2870, 48918, 1900, 1123, 550, 998, 112, 9586, 15985, 455, 391, 410, 22955, 37636, 114], [448, 17496, 419, 3663, 385, 763, 113, 27533, 2870, 3283, 13043, 1639, 24713, 523, 656, 24013, 18550, 2521, 517, 27014, 21244, 420, 1212, 1465, 391, 927, 4833, 388, 578, 11786, 114, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0], [484, 2169, 7687, 21932, 18146, 726, 363, 17032, 3391, 114, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0]], 'attention_mask': [[1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1], [1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0], [1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 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=lowercase_ , model_name='google/bert_for_seq_generation_L-24_bbc_encoder' , revision='c817d1fd1be2ffa69431227a1fe320544943d4db' , )

from typing import TYPE_CHECKING # rely on isort to merge the imports from ...utils import OptionalDependencyNotAvailable, _LazyModule, is_torch_available __snake_case = { '''configuration_autoformer''': [ '''AUTOFORMER_PRETRAINED_CONFIG_ARCHIVE_MAP''', '''AutoformerConfig''', ], } try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __snake_case = [ '''AUTOFORMER_PRETRAINED_MODEL_ARCHIVE_LIST''', '''AutoformerForPrediction''', '''AutoformerModel''', '''AutoformerPreTrainedModel''', ] if TYPE_CHECKING: from .configuration_autoformer import ( AUTOFORMER_PRETRAINED_CONFIG_ARCHIVE_MAP, AutoformerConfig, ) try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_autoformer import ( AUTOFORMER_PRETRAINED_MODEL_ARCHIVE_LIST, AutoformerForPrediction, AutoformerModel, AutoformerPreTrainedModel, ) else: import sys __snake_case = _LazyModule(__name__, globals()['''__file__'''], _import_structure, module_spec=__spec__)

def lowerCAmelCase_ ( lowerCamelCase ): if not numbers: return 0 if not isinstance(lowerCamelCase , (list, tuple) ) or not all( isinstance(lowerCamelCase , lowerCamelCase ) for number in numbers ): raise ValueError("""numbers must be an iterable of integers""" ) __magic_name__ : List[Any] =numbers[0] for i in range(1 , len(lowerCamelCase ) ): # update the maximum and minimum subarray products __magic_name__ : Dict =numbers[i] if number < 0: __magic_name__ , __magic_name__ : str =min_till_now, max_till_now __magic_name__ : Union[str, Any] =max(lowerCamelCase , max_till_now * number ) __magic_name__ : Optional[Any] =min(lowerCamelCase , min_till_now * number ) # update the maximum product found till now __magic_name__ : Union[str, Any] =max(lowerCamelCase , lowerCamelCase ) return max_prod

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 = ''' {0} = None ''' __snake_case = ''' class {0}(metaclass=DummyObject): _backends = {1} def __init__(self, *args, **kwargs): requires_backends(self, {1}) @classmethod def from_config(cls, *args, **kwargs): requires_backends(cls, {1}) @classmethod def from_pretrained(cls, *args, **kwargs): requires_backends(cls, {1}) ''' __snake_case = ''' def {0}(*args, **kwargs): requires_backends({0}, {1}) ''' def _A ( _lowercase ) -> int: """simple docstring""" __UpperCamelCase = _re_backend.findall(_lowercase ) if len(_lowercase ) == 0: return None return "_and_".join(_lowercase ) def _A ( ) -> Tuple: """simple docstring""" with open(os.path.join(_lowercase , '__init__.py' ) , 'r' , encoding='utf-8' , newline='\n' ) as f: __UpperCamelCase = f.readlines() # Get to the point we do the actual imports for type checking __UpperCamelCase = 0 __UpperCamelCase = {} # Go through the end of the file while line_index < len(_lowercase ): # If the line contains is_backend_available, we grab all objects associated with the `else` block __UpperCamelCase = find_backend(lines[line_index] ) if backend is not None: while not lines[line_index].startswith('else:' ): line_index += 1 line_index += 1 __UpperCamelCase = [] # Until we unindent, add backend objects to the list while line_index < len(_lowercase ) and len(lines[line_index] ) > 1: __UpperCamelCase = lines[line_index] __UpperCamelCase = _re_single_line_import.search(_lowercase ) 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(_lowercase ) > 0: __UpperCamelCase = objects else: line_index += 1 return backend_specific_objects def _A ( _lowercase , _lowercase ) -> Union[str, Any]: """simple docstring""" if name.isupper(): return DUMMY_CONSTANT.format(_lowercase ) elif name.islower(): return DUMMY_FUNCTION.format(_lowercase , _lowercase ) else: return DUMMY_CLASS.format(_lowercase , _lowercase ) def _A ( _lowercase=None ) -> Optional[Any]: """simple docstring""" if backend_specific_objects is None: __UpperCamelCase = read_init() # For special correspondence backend to module name as used in the function requires_modulename __UpperCamelCase = {} for backend, objects in backend_specific_objects.items(): __UpperCamelCase = '[' + ', '.join(f'''"{b}"''' for b in backend.split('_and_' ) ) + ']' __UpperCamelCase = '# 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(_lowercase , _lowercase ) for o in objects] ) __UpperCamelCase = dummy_file return dummy_files def _A ( _lowercase=False ) -> List[str]: """simple docstring""" __UpperCamelCase = create_dummy_files() # For special correspondence backend to shortcut as used in utils/dummy_xxx_objects.py __UpperCamelCase = {'torch': 'pt'} # Locate actual dummy modules and read their content. __UpperCamelCase = os.path.join(_lowercase , 'utils' ) __UpperCamelCase = { backend: os.path.join(_lowercase , f'''dummy_{short_names.get(_lowercase , _lowercase )}_objects.py''' ) for backend in dummy_files.keys() } __UpperCamelCase = {} for backend, file_path in dummy_file_paths.items(): if os.path.isfile(_lowercase ): with open(_lowercase , 'r' , encoding='utf-8' , newline='\n' ) as f: __UpperCamelCase = f.read() else: __UpperCamelCase = '' for backend in dummy_files.keys(): if dummy_files[backend] != actual_dummies[backend]: if overwrite: print( f'''Updating diffusers.utils.dummy_{short_names.get(_lowercase , _lowercase )}_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(_lowercase , _lowercase )}_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)

'''simple docstring''' def snake_case_ (UpperCamelCase : int ): '''simple docstring''' if num <= 0: raise ValueError('''Input must be a positive integer''' ) _a = [True] * (num + 1) _a = 2 while p * p <= num: if primes[p]: for i in range(p * p , num + 1 , UpperCamelCase ): _a = False p += 1 return [prime for prime in range(2 , num + 1 ) if primes[prime]] if __name__ == "__main__": import doctest doctest.testmod() _snake_case : Optional[Any] = int(input('Enter a positive integer: ').strip()) print(prime_sieve_eratosthenes(user_num))

import string def _A ( _lowercase ) -> None: """simple docstring""" for key in range(len(string.ascii_uppercase ) ): __UpperCamelCase = '' for symbol in message: if symbol in string.ascii_uppercase: __UpperCamelCase = string.ascii_uppercase.find(_lowercase ) __UpperCamelCase = num - key if num < 0: __UpperCamelCase = num + len(string.ascii_uppercase ) __UpperCamelCase = translated + string.ascii_uppercase[num] else: __UpperCamelCase = translated + symbol print(f'''Decryption using Key #{key}: {translated}''' ) def _A ( ) -> None: """simple docstring""" __UpperCamelCase = input('Encrypted message: ' ) __UpperCamelCase = message.upper() decrypt(_lowercase ) if __name__ == "__main__": import doctest doctest.testmod() main()

import gc import unittest from diffusers import FlaxDPMSolverMultistepScheduler, FlaxStableDiffusionPipeline from diffusers.utils import is_flax_available, slow from diffusers.utils.testing_utils import require_flax if is_flax_available(): import jax import jax.numpy as jnp from flax.jax_utils import replicate from flax.training.common_utils import shard @slow @require_flax class _a ( unittest.TestCase ): """simple docstring""" def _UpperCAmelCase ( self ) -> Union[str, Any]: # clean up the VRAM after each test super().tearDown() gc.collect() def _UpperCAmelCase ( self ) -> Optional[int]: UpperCamelCase_ , UpperCamelCase_ = FlaxStableDiffusionPipeline.from_pretrained( 'stabilityai/stable-diffusion-2' , revision='bf16' , dtype=jnp.bfloataa , ) UpperCamelCase_ = 'A painting of a squirrel eating a burger' UpperCamelCase_ = jax.device_count() UpperCamelCase_ = num_samples * [prompt] UpperCamelCase_ = sd_pipe.prepare_inputs(_UpperCAmelCase ) UpperCamelCase_ = replicate(_UpperCAmelCase ) UpperCamelCase_ = shard(_UpperCAmelCase ) UpperCamelCase_ = jax.random.PRNGKey(0 ) UpperCamelCase_ = jax.random.split(_UpperCAmelCase , jax.device_count() ) UpperCamelCase_ = sd_pipe(_UpperCAmelCase , _UpperCAmelCase , _UpperCAmelCase , num_inference_steps=25 , jit=_UpperCAmelCase )[0] assert images.shape == (jax.device_count(), 1, 768, 768, 3) UpperCamelCase_ = images.reshape((images.shape[0] * images.shape[1],) + images.shape[-3:] ) UpperCamelCase_ = images[0, 253:256, 253:256, -1] UpperCamelCase_ = jnp.asarray(jax.device_get(image_slice.flatten() ) ) UpperCamelCase_ = jnp.array([0.4_2_3_8, 0.4_4_1_4, 0.4_3_9_5, 0.4_4_5_3, 0.4_6_2_9, 0.4_5_9_0, 0.4_5_3_1, 0.4_5_5_0_8, 0.4_5_1_2] ) print(f"""output_slice: {output_slice}""" ) assert jnp.abs(output_slice - expected_slice ).max() < 1e-2 def _UpperCAmelCase ( self ) -> Union[str, Any]: UpperCamelCase_ = 'stabilityai/stable-diffusion-2' UpperCamelCase_ , UpperCamelCase_ = FlaxDPMSolverMultistepScheduler.from_pretrained(_UpperCAmelCase , subfolder='scheduler' ) UpperCamelCase_ , UpperCamelCase_ = FlaxStableDiffusionPipeline.from_pretrained( _UpperCAmelCase , scheduler=_UpperCAmelCase , revision='bf16' , dtype=jnp.bfloataa , ) UpperCamelCase_ = scheduler_params UpperCamelCase_ = 'A painting of a squirrel eating a burger' UpperCamelCase_ = jax.device_count() UpperCamelCase_ = num_samples * [prompt] UpperCamelCase_ = sd_pipe.prepare_inputs(_UpperCAmelCase ) UpperCamelCase_ = replicate(_UpperCAmelCase ) UpperCamelCase_ = shard(_UpperCAmelCase ) UpperCamelCase_ = jax.random.PRNGKey(0 ) UpperCamelCase_ = jax.random.split(_UpperCAmelCase , jax.device_count() ) UpperCamelCase_ = sd_pipe(_UpperCAmelCase , _UpperCAmelCase , _UpperCAmelCase , num_inference_steps=25 , jit=_UpperCAmelCase )[0] assert images.shape == (jax.device_count(), 1, 768, 768, 3) UpperCamelCase_ = images.reshape((images.shape[0] * images.shape[1],) + images.shape[-3:] ) UpperCamelCase_ = images[0, 253:256, 253:256, -1] UpperCamelCase_ = jnp.asarray(jax.device_get(image_slice.flatten() ) ) UpperCamelCase_ = jnp.array([0.4_3_3_6, 0.4_2_9_6_9, 0.4_4_5_3, 0.4_1_9_9, 0.4_2_9_7, 0.4_5_3_1, 0.4_4_3_4, 0.4_4_3_4, 0.4_2_9_7] ) print(f"""output_slice: {output_slice}""" ) assert jnp.abs(output_slice - expected_slice ).max() < 1e-2

import gc import random import unittest import numpy as np import torch from PIL import Image from transformers import XLMRobertaTokenizerFast from diffusers import DDIMScheduler, KandinskyInpaintPipeline, KandinskyPriorPipeline, UNetaDConditionModel, VQModel from diffusers.pipelines.kandinsky.text_encoder import MCLIPConfig, MultilingualCLIP from diffusers.utils import floats_tensor, load_image, load_numpy, slow, torch_device from diffusers.utils.testing_utils import enable_full_determinism, require_torch_gpu from ..test_pipelines_common import PipelineTesterMixin, assert_mean_pixel_difference enable_full_determinism() class __lowerCamelCase (_a , unittest.TestCase ): _lowercase = KandinskyInpaintPipeline _lowercase = ["""prompt""", """image_embeds""", """negative_image_embeds""", """image""", """mask_image"""] _lowercase = [ """prompt""", """negative_prompt""", """image_embeds""", """negative_image_embeds""", """image""", """mask_image""", ] _lowercase = [ """generator""", """height""", """width""", """latents""", """guidance_scale""", """negative_prompt""", """num_inference_steps""", """return_dict""", """guidance_scale""", """num_images_per_prompt""", """output_type""", """return_dict""", ] _lowercase = False @property def snake_case_ ( self: int ): '''simple docstring''' return 32 @property def snake_case_ ( self: str ): '''simple docstring''' return 32 @property def snake_case_ ( self: Tuple ): '''simple docstring''' return self.time_input_dim @property def snake_case_ ( self: Union[str, Any] ): '''simple docstring''' return self.time_input_dim * 4 @property def snake_case_ ( self: Optional[int] ): '''simple docstring''' return 100 @property def snake_case_ ( self: str ): '''simple docstring''' __UpperCamelCase = XLMRobertaTokenizerFast.from_pretrained('YiYiXu/tiny-random-mclip-base' ) return tokenizer @property def snake_case_ ( self: Any ): '''simple docstring''' torch.manual_seed(0 ) __UpperCamelCase = MCLIPConfig( numDims=self.cross_attention_dim,transformerDimensions=self.text_embedder_hidden_size,hidden_size=self.text_embedder_hidden_size,intermediate_size=37,num_attention_heads=4,num_hidden_layers=5,vocab_size=1005,) __UpperCamelCase = MultilingualCLIP(A_ ) __UpperCamelCase = text_encoder.eval() return text_encoder @property def snake_case_ ( self: Any ): '''simple docstring''' torch.manual_seed(0 ) __UpperCamelCase = { 'in_channels': 9, # Out channels is double in channels because predicts mean and variance 'out_channels': 8, 'addition_embed_type': 'text_image', 'down_block_types': ('ResnetDownsampleBlock2D', 'SimpleCrossAttnDownBlock2D'), 'up_block_types': ('SimpleCrossAttnUpBlock2D', 'ResnetUpsampleBlock2D'), 'mid_block_type': 'UNetMidBlock2DSimpleCrossAttn', 'block_out_channels': (self.block_out_channels_a, self.block_out_channels_a * 2), 'layers_per_block': 1, 'encoder_hid_dim': self.text_embedder_hidden_size, 'encoder_hid_dim_type': 'text_image_proj', 'cross_attention_dim': self.cross_attention_dim, 'attention_head_dim': 4, 'resnet_time_scale_shift': 'scale_shift', 'class_embed_type': None, } __UpperCamelCase = UNetaDConditionModel(**A_ ) return model @property def snake_case_ ( self: str ): '''simple docstring''' return { "block_out_channels": [32, 64], "down_block_types": ["DownEncoderBlock2D", "AttnDownEncoderBlock2D"], "in_channels": 3, "latent_channels": 4, "layers_per_block": 1, "norm_num_groups": 8, "norm_type": "spatial", "num_vq_embeddings": 12, "out_channels": 3, "up_block_types": [ "AttnUpDecoderBlock2D", "UpDecoderBlock2D", ], "vq_embed_dim": 4, } @property def snake_case_ ( self: str ): '''simple docstring''' torch.manual_seed(0 ) __UpperCamelCase = VQModel(**self.dummy_movq_kwargs ) return model def snake_case_ ( self: Dict ): '''simple docstring''' __UpperCamelCase = self.dummy_text_encoder __UpperCamelCase = self.dummy_tokenizer __UpperCamelCase = self.dummy_unet __UpperCamelCase = self.dummy_movq __UpperCamelCase = DDIMScheduler( num_train_timesteps=1000,beta_schedule='linear',beta_start=0.0_0_0_8_5,beta_end=0.0_1_2,clip_sample=A_,set_alpha_to_one=A_,steps_offset=1,prediction_type='epsilon',thresholding=A_,) __UpperCamelCase = { 'text_encoder': text_encoder, 'tokenizer': tokenizer, 'unet': unet, 'scheduler': scheduler, 'movq': movq, } return components def snake_case_ ( self: Tuple,A_: Optional[int],A_: Dict=0 ): '''simple docstring''' __UpperCamelCase = floats_tensor((1, self.cross_attention_dim),rng=random.Random(A_ ) ).to(A_ ) __UpperCamelCase = floats_tensor((1, self.cross_attention_dim),rng=random.Random(seed + 1 ) ).to(A_ ) # create init_image __UpperCamelCase = floats_tensor((1, 3, 64, 64),rng=random.Random(A_ ) ).to(A_ ) __UpperCamelCase = image.cpu().permute(0,2,3,1 )[0] __UpperCamelCase = Image.fromarray(np.uinta(A_ ) ).convert('RGB' ).resize((256, 256) ) # create mask __UpperCamelCase = np.ones((64, 64),dtype=np.floataa ) __UpperCamelCase = 0 if str(A_ ).startswith('mps' ): __UpperCamelCase = torch.manual_seed(A_ ) else: __UpperCamelCase = torch.Generator(device=A_ ).manual_seed(A_ ) __UpperCamelCase = { 'prompt': 'horse', 'image': init_image, 'mask_image': mask, 'image_embeds': image_embeds, 'negative_image_embeds': negative_image_embeds, 'generator': generator, 'height': 64, 'width': 64, 'num_inference_steps': 2, 'guidance_scale': 4.0, 'output_type': 'np', } return inputs def snake_case_ ( self: Any ): '''simple docstring''' __UpperCamelCase = 'cpu' __UpperCamelCase = self.get_dummy_components() __UpperCamelCase = self.pipeline_class(**A_ ) __UpperCamelCase = pipe.to(A_ ) pipe.set_progress_bar_config(disable=A_ ) __UpperCamelCase = pipe(**self.get_dummy_inputs(A_ ) ) __UpperCamelCase = output.images __UpperCamelCase = pipe( **self.get_dummy_inputs(A_ ),return_dict=A_,)[0] __UpperCamelCase = image[0, -3:, -3:, -1] __UpperCamelCase = image_from_tuple[0, -3:, -3:, -1] print(F'''image.shape {image.shape}''' ) assert image.shape == (1, 64, 64, 3) __UpperCamelCase = np.array( [0.8_3_2_6_9_1_9, 0.7_3_7_9_0_4_6_7, 0.2_0_9_1_8_5_8_1, 0.9_3_0_9_6_1_2, 0.5_5_1_1_7_9_1, 0.4_3_7_1_3_3_2_8, 0.5_5_1_3_3_2_1, 0.4_9_9_2_2_9_3_4, 0.5_9_4_9_7_7_8_6] ) assert ( np.abs(image_slice.flatten() - expected_slice ).max() < 1E-2 ), F''' expected_slice {expected_slice}, but got {image_slice.flatten()}''' assert ( np.abs(image_from_tuple_slice.flatten() - expected_slice ).max() < 1E-2 ), F''' expected_slice {expected_slice}, but got {image_from_tuple_slice.flatten()}''' def snake_case_ ( self: Optional[Any] ): '''simple docstring''' super().test_inference_batch_single_identical(expected_max_diff=3E-3 ) @slow @require_torch_gpu class __lowerCamelCase (unittest.TestCase ): def snake_case_ ( self: Tuple ): '''simple docstring''' super().tearDown() gc.collect() torch.cuda.empty_cache() def snake_case_ ( self: Any ): '''simple docstring''' __UpperCamelCase = load_numpy( 'https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main' '/kandinsky/kandinsky_inpaint_cat_with_hat_fp16.npy' ) __UpperCamelCase = load_image( 'https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main' '/kandinsky/cat.png' ) __UpperCamelCase = np.ones((768, 768),dtype=np.floataa ) __UpperCamelCase = 0 __UpperCamelCase = 'a hat' __UpperCamelCase = KandinskyPriorPipeline.from_pretrained( 'kandinsky-community/kandinsky-2-1-prior',torch_dtype=torch.floataa ) pipe_prior.to(A_ ) __UpperCamelCase = KandinskyInpaintPipeline.from_pretrained( 'kandinsky-community/kandinsky-2-1-inpaint',torch_dtype=torch.floataa ) __UpperCamelCase = pipeline.to(A_ ) pipeline.set_progress_bar_config(disable=A_ ) __UpperCamelCase = torch.Generator(device='cpu' ).manual_seed(0 ) __UpperCamelCase, __UpperCamelCase = pipe_prior( A_,generator=A_,num_inference_steps=5,negative_prompt='',).to_tuple() __UpperCamelCase = pipeline( A_,image=A_,mask_image=A_,image_embeds=A_,negative_image_embeds=A_,generator=A_,num_inference_steps=100,height=768,width=768,output_type='np',) __UpperCamelCase = output.images[0] assert image.shape == (768, 768, 3) assert_mean_pixel_difference(A_,A_ )

'''simple docstring''' import warnings from ...utils import logging from .image_processing_deformable_detr import DeformableDetrImageProcessor UpperCAmelCase_ : Any = logging.get_logger(__name__) class lowerCAmelCase ( __lowerCAmelCase): def __init__( self , *__SCREAMING_SNAKE_CASE , **__SCREAMING_SNAKE_CASE ) -> None: '''simple docstring''' warnings.warn( '''The class DeformableDetrFeatureExtractor is deprecated and will be removed in version 5 of Transformers.''' ''' Please use DeformableDetrImageProcessor instead.''' , __SCREAMING_SNAKE_CASE , ) super().__init__(*__SCREAMING_SNAKE_CASE , **__SCREAMING_SNAKE_CASE )

from typing import Any class __lowerCamelCase : def __init__( self: int,A_: Any ): '''simple docstring''' __UpperCamelCase = data __UpperCamelCase = None def __repr__( self: Any ): '''simple docstring''' return F'''Node({self.data})''' class __lowerCamelCase : def __init__( self: Union[str, Any] ): '''simple docstring''' __UpperCamelCase = None def __iter__( self: int ): '''simple docstring''' __UpperCamelCase = self.head while node: yield node.data __UpperCamelCase = node.next def __len__( self: List[str] ): '''simple docstring''' return sum(1 for _ in self ) def __repr__( self: Any ): '''simple docstring''' return "->".join([str(A_ ) for item in self] ) def __getitem__( self: int,A_: int ): '''simple docstring''' if not 0 <= index < len(self ): raise ValueError('list index out of range.' ) for i, node in enumerate(self ): if i == index: return node return None def __setitem__( self: int,A_: int,A_: Any ): '''simple docstring''' if not 0 <= index < len(self ): raise ValueError('list index out of range.' ) __UpperCamelCase = self.head for _ in range(A_ ): __UpperCamelCase = current.next __UpperCamelCase = data def snake_case_ ( self: Union[str, Any],A_: Any ): '''simple docstring''' self.insert_nth(len(self ),A_ ) def snake_case_ ( self: List[Any],A_: Any ): '''simple docstring''' self.insert_nth(0,A_ ) def snake_case_ ( self: Optional[Any],A_: int,A_: Any ): '''simple docstring''' if not 0 <= index <= len(self ): raise IndexError('list index out of range' ) __UpperCamelCase = Node(A_ ) if self.head is None: __UpperCamelCase = new_node elif index == 0: __UpperCamelCase = self.head # link new_node to head __UpperCamelCase = new_node else: __UpperCamelCase = self.head for _ in range(index - 1 ): __UpperCamelCase = temp.next __UpperCamelCase = temp.next __UpperCamelCase = new_node def snake_case_ ( self: str ): # print every node data '''simple docstring''' print(self ) def snake_case_ ( self: int ): '''simple docstring''' return self.delete_nth(0 ) def snake_case_ ( self: str ): # delete from tail '''simple docstring''' return self.delete_nth(len(self ) - 1 ) def snake_case_ ( self: Any,A_: int = 0 ): '''simple docstring''' if not 0 <= index <= len(self ) - 1: # test if index is valid raise IndexError('List index out of range.' ) __UpperCamelCase = self.head # default first node if index == 0: __UpperCamelCase = self.head.next else: __UpperCamelCase = self.head for _ in range(index - 1 ): __UpperCamelCase = temp.next __UpperCamelCase = temp.next __UpperCamelCase = temp.next.next return delete_node.data def snake_case_ ( self: Any ): '''simple docstring''' return self.head is None def snake_case_ ( self: Optional[int] ): '''simple docstring''' __UpperCamelCase = None __UpperCamelCase = self.head while current: # Store the current node's next node. __UpperCamelCase = current.next # Make the current node's next point backwards __UpperCamelCase = prev # Make the previous node be the current node __UpperCamelCase = current # Make the current node the next node (to progress iteration) __UpperCamelCase = next_node # Return prev in order to put the head at the end __UpperCamelCase = prev def _A ( ) -> None: """simple docstring""" __UpperCamelCase = LinkedList() assert linked_list.is_empty() is True assert str(_lowercase ) == "" try: linked_list.delete_head() raise AssertionError # This should not happen. except IndexError: assert True # This should happen. try: linked_list.delete_tail() raise AssertionError # This should not happen. except IndexError: assert True # This should happen. for i in range(10 ): assert len(_lowercase ) == i linked_list.insert_nth(_lowercase , i + 1 ) assert str(_lowercase ) == "->".join(str(_lowercase ) for i in range(1 , 11 ) ) linked_list.insert_head(0 ) linked_list.insert_tail(11 ) assert str(_lowercase ) == "->".join(str(_lowercase ) for i in range(0 , 12 ) ) assert linked_list.delete_head() == 0 assert linked_list.delete_nth(9 ) == 10 assert linked_list.delete_tail() == 11 assert len(_lowercase ) == 9 assert str(_lowercase ) == "->".join(str(_lowercase ) for i in range(1 , 10 ) ) assert all(linked_list[i] == i + 1 for i in range(0 , 9 ) ) is True for i in range(0 , 9 ): __UpperCamelCase = -i assert all(linked_list[i] == -i for i in range(0 , 9 ) ) is True linked_list.reverse() assert str(_lowercase ) == "->".join(str(_lowercase ) for i in range(-8 , 1 ) ) def _A ( ) -> None: """simple docstring""" __UpperCamelCase = [ -9, 1_00, Node(77_34_51_12 ), 'dlrow olleH', 7, 55_55, 0, -1_92.5_55_55, 'Hello, world!', 77.9, Node(10 ), None, None, 12.20, ] __UpperCamelCase = LinkedList() for i in test_input: linked_list.insert_tail(_lowercase ) # Check if it's empty or not assert linked_list.is_empty() is False assert ( str(_lowercase ) == "-9->100->Node(77345112)->dlrow olleH->7->5555->0->" "-192.55555->Hello, world!->77.9->Node(10)->None->None->12.2" ) # Delete the head __UpperCamelCase = linked_list.delete_head() assert result == -9 assert ( str(_lowercase ) == "100->Node(77345112)->dlrow olleH->7->5555->0->-192.55555->" "Hello, world!->77.9->Node(10)->None->None->12.2" ) # Delete the tail __UpperCamelCase = linked_list.delete_tail() assert result == 12.2 assert ( str(_lowercase ) == "100->Node(77345112)->dlrow olleH->7->5555->0->-192.55555->" "Hello, world!->77.9->Node(10)->None->None" ) # Delete a node in specific location in linked list __UpperCamelCase = linked_list.delete_nth(10 ) assert result is None assert ( str(_lowercase ) == "100->Node(77345112)->dlrow olleH->7->5555->0->-192.55555->" "Hello, world!->77.9->Node(10)->None" ) # Add a Node instance to its head linked_list.insert_head(Node('Hello again, world!' ) ) assert ( str(_lowercase ) == "Node(Hello again, world!)->100->Node(77345112)->dlrow olleH->" "7->5555->0->-192.55555->Hello, world!->77.9->Node(10)->None" ) # Add None to its tail linked_list.insert_tail(_lowercase ) assert ( str(_lowercase ) == "Node(Hello again, world!)->100->Node(77345112)->dlrow olleH->" "7->5555->0->-192.55555->Hello, world!->77.9->Node(10)->None->None" ) # Reverse the linked list linked_list.reverse() assert ( str(_lowercase ) == "None->None->Node(10)->77.9->Hello, world!->-192.55555->0->5555->" "7->dlrow olleH->Node(77345112)->100->Node(Hello again, world!)" ) def _A ( ) -> List[str]: """simple docstring""" from doctest import testmod testmod() __UpperCamelCase = LinkedList() linked_list.insert_head(input('Inserting 1st at head ' ).strip() ) linked_list.insert_head(input('Inserting 2nd at head ' ).strip() ) print('\nPrint list:' ) linked_list.print_list() linked_list.insert_tail(input('\nInserting 1st at tail ' ).strip() ) linked_list.insert_tail(input('Inserting 2nd at tail ' ).strip() ) print('\nPrint list:' ) linked_list.print_list() print('\nDelete head' ) linked_list.delete_head() print('Delete tail' ) linked_list.delete_tail() print('\nPrint list:' ) linked_list.print_list() print('\nReverse linked list' ) linked_list.reverse() print('\nPrint list:' ) linked_list.print_list() print('\nString representation of linked list:' ) print(_lowercase ) print('\nReading/changing Node data using indexing:' ) print(f'''Element at Position 1: {linked_list[1]}''' ) __UpperCamelCase = input('Enter New Value: ' ).strip() print('New list:' ) print(_lowercase ) print(f'''length of linked_list is : {len(_lowercase )}''' ) if __name__ == "__main__": main()

import collections from typing import List, Optional, Union from ...tokenization_utils_base import BatchEncoding from ...utils import TensorType, add_end_docstrings, add_start_docstrings, logging from ..bert.tokenization_bert import BertTokenizer a_ = logging.get_logger(__name__) a_ = {'vocab_file': 'vocab.txt', 'tokenizer_file': 'tokenizer.json'} a_ = { 'vocab_file': { 'facebook/dpr-ctx_encoder-single-nq-base': ( 'https://huggingface.co/facebook/dpr-ctx_encoder-single-nq-base/resolve/main/vocab.txt' ), 'facebook/dpr-ctx_encoder-multiset-base': ( 'https://huggingface.co/facebook/dpr-ctx_encoder-multiset-base/resolve/main/vocab.txt' ), }, 'tokenizer_file': { 'facebook/dpr-ctx_encoder-single-nq-base': ( 'https://huggingface.co/facebook/dpr-ctx_encoder-single-nq-base/resolve/main/tokenizer.json' ), 'facebook/dpr-ctx_encoder-multiset-base': ( 'https://huggingface.co/facebook/dpr-ctx_encoder-multiset-base/resolve/main/tokenizer.json' ), }, } a_ = { 'vocab_file': { 'facebook/dpr-question_encoder-single-nq-base': ( 'https://huggingface.co/facebook/dpr-question_encoder-single-nq-base/resolve/main/vocab.txt' ), 'facebook/dpr-question_encoder-multiset-base': ( 'https://huggingface.co/facebook/dpr-question_encoder-multiset-base/resolve/main/vocab.txt' ), }, 'tokenizer_file': { 'facebook/dpr-question_encoder-single-nq-base': ( 'https://huggingface.co/facebook/dpr-question_encoder-single-nq-base/resolve/main/tokenizer.json' ), 'facebook/dpr-question_encoder-multiset-base': ( 'https://huggingface.co/facebook/dpr-question_encoder-multiset-base/resolve/main/tokenizer.json' ), }, } a_ = { 'vocab_file': { 'facebook/dpr-reader-single-nq-base': ( 'https://huggingface.co/facebook/dpr-reader-single-nq-base/resolve/main/vocab.txt' ), 'facebook/dpr-reader-multiset-base': ( 'https://huggingface.co/facebook/dpr-reader-multiset-base/resolve/main/vocab.txt' ), }, 'tokenizer_file': { 'facebook/dpr-reader-single-nq-base': ( 'https://huggingface.co/facebook/dpr-reader-single-nq-base/resolve/main/tokenizer.json' ), 'facebook/dpr-reader-multiset-base': ( 'https://huggingface.co/facebook/dpr-reader-multiset-base/resolve/main/tokenizer.json' ), }, } a_ = { 'facebook/dpr-ctx_encoder-single-nq-base': 512, 'facebook/dpr-ctx_encoder-multiset-base': 512, } a_ = { 'facebook/dpr-question_encoder-single-nq-base': 512, 'facebook/dpr-question_encoder-multiset-base': 512, } a_ = { 'facebook/dpr-reader-single-nq-base': 512, 'facebook/dpr-reader-multiset-base': 512, } a_ = { 'facebook/dpr-ctx_encoder-single-nq-base': {'do_lower_case': True}, 'facebook/dpr-ctx_encoder-multiset-base': {'do_lower_case': True}, } a_ = { 'facebook/dpr-question_encoder-single-nq-base': {'do_lower_case': True}, 'facebook/dpr-question_encoder-multiset-base': {'do_lower_case': True}, } a_ = { 'facebook/dpr-reader-single-nq-base': {'do_lower_case': True}, 'facebook/dpr-reader-multiset-base': {'do_lower_case': True}, } class _UpperCamelCase ( __A ): '''simple docstring''' lowerCamelCase__ =VOCAB_FILES_NAMES lowerCamelCase__ =CONTEXT_ENCODER_PRETRAINED_VOCAB_FILES_MAP lowerCamelCase__ =CONTEXT_ENCODER_PRETRAINED_POSITIONAL_EMBEDDINGS_SIZES lowerCamelCase__ =CONTEXT_ENCODER_PRETRAINED_INIT_CONFIGURATION class _UpperCamelCase ( __A ): '''simple docstring''' lowerCamelCase__ =VOCAB_FILES_NAMES lowerCamelCase__ =QUESTION_ENCODER_PRETRAINED_VOCAB_FILES_MAP lowerCamelCase__ =QUESTION_ENCODER_PRETRAINED_POSITIONAL_EMBEDDINGS_SIZES lowerCamelCase__ =QUESTION_ENCODER_PRETRAINED_INIT_CONFIGURATION a_ = collections.namedtuple( 'DPRSpanPrediction', ['span_score', 'relevance_score', 'doc_id', 'start_index', 'end_index', 'text'] ) a_ = collections.namedtuple('DPRReaderOutput', ['start_logits', 'end_logits', 'relevance_logits']) a_ = r'\n Return a dictionary with the token ids of the input strings and other information to give to `.decode_best_spans`.\n It converts the strings of a question and different passages (title and text) in a sequence of IDs (integers),\n using the tokenizer and vocabulary. The resulting `input_ids` is a matrix of size `(n_passages, sequence_length)`\n with the format:\n\n ```\n [CLS] <question token ids> [SEP] <titles ids> [SEP] <texts ids>\n ```\n\n Args:\n questions (`str` or `List[str]`):\n The questions to be encoded. You can specify one question for many passages. In this case, the question\n will be duplicated like `[questions] * n_passages`. Otherwise you have to specify as many questions as in\n `titles` or `texts`.\n titles (`str` or `List[str]`):\n The passages titles to be encoded. This can be a string or a list of strings if there are several passages.\n texts (`str` or `List[str]`):\n The passages texts to be encoded. This can be a string or a list of strings if there are several passages.\n padding (`bool`, `str` or [`~utils.PaddingStrategy`], *optional*, defaults to `False`):\n Activates and controls padding. Accepts the following values:\n\n - `True` or `\'longest\'`: Pad to the longest sequence in the batch (or no padding if only a single sequence\n if provided).\n - `\'max_length\'`: Pad to a maximum length specified with the argument `max_length` or to the maximum\n acceptable input length for the model if that argument is not provided.\n - `False` or `\'do_not_pad\'` (default): No padding (i.e., can output a batch with sequences of different\n lengths).\n truncation (`bool`, `str` or [`~tokenization_utils_base.TruncationStrategy`], *optional*, defaults to `False`):\n Activates and controls truncation. Accepts the following values:\n\n - `True` or `\'longest_first\'`: Truncate to a maximum length specified with the argument `max_length` or to\n the maximum acceptable input length for the model if that argument is not provided. This will truncate\n token by token, removing a token from the longest sequence in the pair if a pair of sequences (or a batch\n of pairs) is provided.\n - `\'only_first\'`: Truncate to a maximum length specified with the argument `max_length` or to the maximum\n acceptable input length for the model if that argument is not provided. This will only truncate the first\n sequence of a pair if a pair of sequences (or a batch of pairs) is provided.\n - `\'only_second\'`: Truncate to a maximum length specified with the argument `max_length` or to the maximum\n acceptable input length for the model if that argument is not provided. This will only truncate the\n second sequence of a pair if a pair of sequences (or a batch of pairs) is provided.\n - `False` or `\'do_not_truncate\'` (default): No truncation (i.e., can output batch with sequence lengths\n greater than the model maximum admissible input size).\n max_length (`int`, *optional*):\n Controls the maximum length to use by one of the truncation/padding parameters.\n\n If left unset or set to `None`, this will use the predefined model maximum length if a maximum length\n is required by one of the truncation/padding parameters. If the model has no specific maximum input\n length (like XLNet) truncation/padding to a maximum length will be deactivated.\n return_tensors (`str` or [`~utils.TensorType`], *optional*):\n If set, will return tensors instead of list of python integers. Acceptable values are:\n\n - `\'tf\'`: Return TensorFlow `tf.constant` objects.\n - `\'pt\'`: Return PyTorch `torch.Tensor` objects.\n - `\'np\'`: Return Numpy `np.ndarray` objects.\n return_attention_mask (`bool`, *optional*):\n Whether or not to return the attention mask. If not set, will return the attention mask according to the\n specific tokenizer\'s default, defined by the `return_outputs` attribute.\n\n [What are attention masks?](../glossary#attention-mask)\n\n Returns:\n `Dict[str, List[List[int]]]`: A dictionary with the following keys:\n\n - `input_ids`: List of token ids to be fed to a model.\n - `attention_mask`: List of indices specifying which tokens should be attended to by the model.\n ' @add_start_docstrings(__A ) class _UpperCamelCase : '''simple docstring''' def __call__( self : Union[str, Any] , a : str , a : Optional[str] = None , a : Optional[str] = None , a : Union[bool, str] = False , a : Union[bool, str] = False , a : Optional[int] = None , a : Optional[Union[str, TensorType]] = None , a : Optional[bool] = None , **a : Any , ) -> BatchEncoding: """simple docstring""" if titles is None and texts is None: return super().__call__( a , padding=a , truncation=a , max_length=a , return_tensors=a , return_attention_mask=a , **a , ) elif titles is None or texts is None: SCREAMING_SNAKE_CASE : Tuple = titles if texts is None else texts return super().__call__( a , a , padding=a , truncation=a , max_length=a , return_tensors=a , return_attention_mask=a , **a , ) SCREAMING_SNAKE_CASE : Dict = titles if not isinstance(a , a ) else [titles] SCREAMING_SNAKE_CASE : Optional[int] = texts if not isinstance(a , a ) else [texts] SCREAMING_SNAKE_CASE : str = len(a ) SCREAMING_SNAKE_CASE : Optional[Any] = questions if not isinstance(a , a ) else [questions] * n_passages if len(a ) != len(a ): raise ValueError( F"There should be as many titles than texts but got {len(a )} titles and {len(a )} texts." ) SCREAMING_SNAKE_CASE : Tuple = super().__call__(a , a , padding=a , truncation=a )["input_ids"] SCREAMING_SNAKE_CASE : Optional[int] = super().__call__(a , add_special_tokens=a , padding=a , truncation=a )["input_ids"] SCREAMING_SNAKE_CASE : int = { "input_ids": [ (encoded_question_and_title + encoded_text)[:max_length] if max_length is not None and truncation else encoded_question_and_title + encoded_text for encoded_question_and_title, encoded_text in zip(a , a ) ] } if return_attention_mask is not False: SCREAMING_SNAKE_CASE : Optional[Any] = [] for input_ids in encoded_inputs["input_ids"]: attention_mask.append([int(input_id != self.pad_token_id ) for input_id in input_ids] ) SCREAMING_SNAKE_CASE : Dict = attention_mask return self.pad(a , padding=a , max_length=a , return_tensors=a ) def __UpperCamelCase ( self : List[str] , a : BatchEncoding , a : DPRReaderOutput , a : int = 16 , a : int = 64 , a : int = 4 , ) -> List[DPRSpanPrediction]: """simple docstring""" SCREAMING_SNAKE_CASE : Union[str, Any] = reader_input["input_ids"] SCREAMING_SNAKE_CASE ,SCREAMING_SNAKE_CASE ,SCREAMING_SNAKE_CASE : List[Any] = reader_output[:3] SCREAMING_SNAKE_CASE : Any = len(a ) SCREAMING_SNAKE_CASE : Any = sorted(range(a ) , reverse=a , key=relevance_logits.__getitem__ ) SCREAMING_SNAKE_CASE : List[DPRReaderOutput] = [] for doc_id in sorted_docs: SCREAMING_SNAKE_CASE : Union[str, Any] = list(input_ids[doc_id] ) # assuming question & title information is at the beginning of the sequence SCREAMING_SNAKE_CASE : Tuple = sequence_ids.index(self.sep_token_id , 2 ) + 1 # second sep id if sequence_ids[-1] == self.pad_token_id: SCREAMING_SNAKE_CASE : Union[str, Any] = sequence_ids.index(self.pad_token_id ) else: SCREAMING_SNAKE_CASE : Optional[int] = len(a ) SCREAMING_SNAKE_CASE : Union[str, Any] = self._get_best_spans( start_logits=start_logits[doc_id][passage_offset:sequence_len] , end_logits=end_logits[doc_id][passage_offset:sequence_len] , max_answer_length=a , top_spans=a , ) for start_index, end_index in best_spans: start_index += passage_offset end_index += passage_offset nbest_spans_predictions.append( DPRSpanPrediction( span_score=start_logits[doc_id][start_index] + end_logits[doc_id][end_index] , relevance_score=relevance_logits[doc_id] , doc_id=a , start_index=a , end_index=a , text=self.decode(sequence_ids[start_index : end_index + 1] ) , ) ) if len(a ) >= num_spans: break return nbest_spans_predictions[:num_spans] def __UpperCamelCase ( self : str , a : List[int] , a : List[int] , a : int , a : int , ) -> List[DPRSpanPrediction]: """simple docstring""" SCREAMING_SNAKE_CASE : Tuple = [] for start_index, start_score in enumerate(a ): for answer_length, end_score in enumerate(end_logits[start_index : start_index + max_answer_length] ): scores.append(((start_index, start_index + answer_length), start_score + end_score) ) SCREAMING_SNAKE_CASE : Tuple = sorted(a , key=lambda a : x[1] , reverse=a ) SCREAMING_SNAKE_CASE : str = [] for (start_index, end_index), score in scores: if start_index > end_index: raise ValueError(F"Wrong span indices: [{start_index}:{end_index}]" ) SCREAMING_SNAKE_CASE : int = end_index - start_index + 1 if length > max_answer_length: raise ValueError(F"Span is too long: {length} > {max_answer_length}" ) if any( start_index <= prev_start_index <= prev_end_index <= end_index or prev_start_index <= start_index <= end_index <= prev_end_index for (prev_start_index, prev_end_index) in chosen_span_intervals ): continue chosen_span_intervals.append((start_index, end_index) ) if len(a ) == top_spans: break return chosen_span_intervals @add_end_docstrings(__A ) class _UpperCamelCase ( __A , __A ): '''simple docstring''' lowerCamelCase__ =VOCAB_FILES_NAMES lowerCamelCase__ =READER_PRETRAINED_VOCAB_FILES_MAP lowerCamelCase__ =READER_PRETRAINED_POSITIONAL_EMBEDDINGS_SIZES lowerCamelCase__ =READER_PRETRAINED_INIT_CONFIGURATION lowerCamelCase__ =['input_ids', 'attention_mask']

from typing import TYPE_CHECKING from ...utils import ( OptionalDependencyNotAvailable, _LazyModule, is_flax_available, is_tf_available, is_torch_available, ) __snake_case = {'''configuration_unispeech''': ['''UNISPEECH_PRETRAINED_CONFIG_ARCHIVE_MAP''', '''UniSpeechConfig''']} try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __snake_case = [ '''UNISPEECH_PRETRAINED_MODEL_ARCHIVE_LIST''', '''UniSpeechForCTC''', '''UniSpeechForPreTraining''', '''UniSpeechForSequenceClassification''', '''UniSpeechModel''', '''UniSpeechPreTrainedModel''', ] if TYPE_CHECKING: from .configuration_unispeech import UNISPEECH_PRETRAINED_CONFIG_ARCHIVE_MAP, UniSpeechConfig try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_unispeech import ( UNISPEECH_PRETRAINED_MODEL_ARCHIVE_LIST, UniSpeechForCTC, UniSpeechForPreTraining, UniSpeechForSequenceClassification, UniSpeechModel, UniSpeechPreTrainedModel, ) else: import sys __snake_case = _LazyModule(__name__, globals()['''__file__'''], _import_structure, module_spec=__spec__)

'''simple docstring''' from typing import TYPE_CHECKING from ...utils import ( OptionalDependencyNotAvailable, _LazyModule, is_flax_available, is_tf_available, is_tokenizers_available, is_torch_available, ) __UpperCamelCase = { "configuration_roberta": ["ROBERTA_PRETRAINED_CONFIG_ARCHIVE_MAP", "RobertaConfig", "RobertaOnnxConfig"], "tokenization_roberta": ["RobertaTokenizer"], } try: if not is_tokenizers_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __UpperCamelCase = ["RobertaTokenizerFast"] try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __UpperCamelCase = [ "ROBERTA_PRETRAINED_MODEL_ARCHIVE_LIST", "RobertaForCausalLM", "RobertaForMaskedLM", "RobertaForMultipleChoice", "RobertaForQuestionAnswering", "RobertaForSequenceClassification", "RobertaForTokenClassification", "RobertaModel", "RobertaPreTrainedModel", ] try: if not is_tf_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __UpperCamelCase = [ "TF_ROBERTA_PRETRAINED_MODEL_ARCHIVE_LIST", "TFRobertaForCausalLM", "TFRobertaForMaskedLM", "TFRobertaForMultipleChoice", "TFRobertaForQuestionAnswering", "TFRobertaForSequenceClassification", "TFRobertaForTokenClassification", "TFRobertaMainLayer", "TFRobertaModel", "TFRobertaPreTrainedModel", ] try: if not is_flax_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: __UpperCamelCase = [ "FlaxRobertaForCausalLM", "FlaxRobertaForMaskedLM", "FlaxRobertaForMultipleChoice", "FlaxRobertaForQuestionAnswering", "FlaxRobertaForSequenceClassification", "FlaxRobertaForTokenClassification", "FlaxRobertaModel", "FlaxRobertaPreTrainedModel", ] if TYPE_CHECKING: from .configuration_roberta import ROBERTA_PRETRAINED_CONFIG_ARCHIVE_MAP, RobertaConfig, RobertaOnnxConfig from .tokenization_roberta import RobertaTokenizer try: if not is_tokenizers_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .tokenization_roberta_fast import RobertaTokenizerFast try: if not is_torch_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_roberta import ( ROBERTA_PRETRAINED_MODEL_ARCHIVE_LIST, RobertaForCausalLM, RobertaForMaskedLM, RobertaForMultipleChoice, RobertaForQuestionAnswering, RobertaForSequenceClassification, RobertaForTokenClassification, RobertaModel, RobertaPreTrainedModel, ) try: if not is_tf_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_tf_roberta import ( TF_ROBERTA_PRETRAINED_MODEL_ARCHIVE_LIST, TFRobertaForCausalLM, TFRobertaForMaskedLM, TFRobertaForMultipleChoice, TFRobertaForQuestionAnswering, TFRobertaForSequenceClassification, TFRobertaForTokenClassification, TFRobertaMainLayer, TFRobertaModel, TFRobertaPreTrainedModel, ) try: if not is_flax_available(): raise OptionalDependencyNotAvailable() except OptionalDependencyNotAvailable: pass else: from .modeling_flax_roberta import ( FlaxRobertaForCausalLM, FlaxRobertaForMaskedLM, FlaxRobertaForMultipleChoice, FlaxRobertaForQuestionAnswering, FlaxRobertaForSequenceClassification, FlaxRobertaForTokenClassification, FlaxRobertaModel, FlaxRobertaPreTrainedModel, ) else: import sys __UpperCamelCase = _LazyModule(__name__, globals()["__file__"], _import_structure, module_spec=__spec__)

__snake_case = { '''a''': '''AAAAA''', '''b''': '''AAAAB''', '''c''': '''AAABA''', '''d''': '''AAABB''', '''e''': '''AABAA''', '''f''': '''AABAB''', '''g''': '''AABBA''', '''h''': '''AABBB''', '''i''': '''ABAAA''', '''j''': '''BBBAA''', '''k''': '''ABAAB''', '''l''': '''ABABA''', '''m''': '''ABABB''', '''n''': '''ABBAA''', '''o''': '''ABBAB''', '''p''': '''ABBBA''', '''q''': '''ABBBB''', '''r''': '''BAAAA''', '''s''': '''BAAAB''', '''t''': '''BAABA''', '''u''': '''BAABB''', '''v''': '''BBBAB''', '''w''': '''BABAA''', '''x''': '''BABAB''', '''y''': '''BABBA''', '''z''': '''BABBB''', ''' ''': ''' ''', } __snake_case = {value: key for key, value in encode_dict.items()} def _A ( _lowercase ) -> str: """simple docstring""" __UpperCamelCase = '' for letter in word.lower(): if letter.isalpha() or letter == " ": encoded += encode_dict[letter] else: raise Exception('encode() accepts only letters of the alphabet and spaces' ) return encoded def _A ( _lowercase ) -> str: """simple docstring""" if set(_lowercase ) - {"A", "B", " "} != set(): raise Exception('decode() accepts only \'A\', \'B\' and spaces' ) __UpperCamelCase = '' for word in coded.split(): while len(_lowercase ) != 0: decoded += decode_dict[word[:5]] __UpperCamelCase = word[5:] decoded += " " return decoded.strip() if __name__ == "__main__": from doctest import testmod testmod()

import importlib import os import fsspec import pytest from fsspec import register_implementation from fsspec.registry import _registry as _fsspec_registry from datasets.filesystems import COMPRESSION_FILESYSTEMS, HfFileSystem, extract_path_from_uri, is_remote_filesystem from .utils import require_lza, require_zstandard def __lowerCAmelCase( _SCREAMING_SNAKE_CASE ) -> int: """simple docstring""" assert "mock" in _fsspec_registry assert "bz2" in _fsspec_registry def __lowerCAmelCase( ) -> Optional[int]: """simple docstring""" assert "mock" not in _fsspec_registry assert "bz2" in _fsspec_registry def __lowerCAmelCase( ) -> List[str]: """simple docstring""" _A = 'mock-s3-bucket' _A = F"s3://{mock_bucket}" _A = extract_path_from_uri(_SCREAMING_SNAKE_CASE ) assert dataset_path.startswith('s3://' ) is False _A = './local/path' _A = extract_path_from_uri(_SCREAMING_SNAKE_CASE ) assert dataset_path == new_dataset_path def __lowerCAmelCase( _SCREAMING_SNAKE_CASE ) -> List[str]: """simple docstring""" _A = is_remote_filesystem(_SCREAMING_SNAKE_CASE ) assert is_remote is True _A = fsspec.filesystem('file' ) _A = is_remote_filesystem(_SCREAMING_SNAKE_CASE ) assert is_remote is False @pytest.mark.parametrize('compression_fs_class' , _SCREAMING_SNAKE_CASE ) def __lowerCAmelCase( _SCREAMING_SNAKE_CASE , _SCREAMING_SNAKE_CASE , _SCREAMING_SNAKE_CASE , _SCREAMING_SNAKE_CASE , _SCREAMING_SNAKE_CASE , _SCREAMING_SNAKE_CASE , _SCREAMING_SNAKE_CASE ) -> List[Any]: """simple docstring""" _A = {'gzip': gz_file, 'xz': xz_file, 'zstd': zstd_file, 'bz2': bza_file, 'lz4': lza_file} _A = input_paths[compression_fs_class.protocol] if input_path is None: _A = F"for '{compression_fs_class.protocol}' compression protocol, " if compression_fs_class.protocol == "lz4": reason += require_lza.kwargs["reason"] elif compression_fs_class.protocol == "zstd": reason += require_zstandard.kwargs["reason"] pytest.skip(_SCREAMING_SNAKE_CASE ) _A = fsspec.filesystem(compression_fs_class.protocol , fo=_SCREAMING_SNAKE_CASE ) assert isinstance(_SCREAMING_SNAKE_CASE , _SCREAMING_SNAKE_CASE ) _A = os.path.basename(_SCREAMING_SNAKE_CASE ) _A = expected_filename[: expected_filename.rindex('.' )] assert fs.glob('*' ) == [expected_filename] with fs.open(_SCREAMING_SNAKE_CASE , 'r' , encoding='utf-8' ) as f, open(_SCREAMING_SNAKE_CASE , encoding='utf-8' ) as expected_file: assert f.read() == expected_file.read() @pytest.mark.parametrize('protocol' , ['zip', 'gzip'] ) def __lowerCAmelCase( _SCREAMING_SNAKE_CASE , _SCREAMING_SNAKE_CASE , _SCREAMING_SNAKE_CASE ) -> Optional[int]: """simple docstring""" _A = {'zip': zip_jsonl_path, 'gzip': jsonl_gz_path} _A = compressed_file_paths[protocol] _A = 'dataset.jsonl' _A = F"{protocol}://{member_file_path}::{compressed_file_path}" _A, *_A = fsspec.get_fs_token_paths(_SCREAMING_SNAKE_CASE ) assert fs.isfile(_SCREAMING_SNAKE_CASE ) assert not fs.isfile('non_existing_' + member_file_path ) @pytest.mark.integration def __lowerCAmelCase( _SCREAMING_SNAKE_CASE , _SCREAMING_SNAKE_CASE , _SCREAMING_SNAKE_CASE , _SCREAMING_SNAKE_CASE ) -> List[Any]: """simple docstring""" _A = hf_api.dataset_info(_SCREAMING_SNAKE_CASE , token=_SCREAMING_SNAKE_CASE ) _A = HfFileSystem(repo_info=_SCREAMING_SNAKE_CASE , token=_SCREAMING_SNAKE_CASE ) assert sorted(hffs.glob('*' ) ) == [".gitattributes", "data"] assert hffs.isdir('data' ) assert hffs.isfile('.gitattributes' ) and hffs.isfile('data/text_data.txt' ) with open(_SCREAMING_SNAKE_CASE ) as f: assert hffs.open('data/text_data.txt' , 'r' ).read() == f.read() def __lowerCAmelCase( ) -> str: """simple docstring""" _A = 'bz2' # Import module import datasets.filesystems # Overwrite protocol and reload register_implementation(_SCREAMING_SNAKE_CASE , _SCREAMING_SNAKE_CASE , clobber=_SCREAMING_SNAKE_CASE ) with pytest.warns(_SCREAMING_SNAKE_CASE ) as warning_info: importlib.reload(datasets.filesystems ) assert len(_SCREAMING_SNAKE_CASE ) == 1 assert ( str(warning_info[0].message ) == F"A filesystem protocol was already set for {protocol} and will be overwritten." )

from collections.abc import Generator from math import sin def _A ( _lowercase ) -> bytes: """simple docstring""" if len(_lowercase ) != 32: raise ValueError('Input must be of length 32' ) __UpperCamelCase = B'' for i in [3, 2, 1, 0]: little_endian += string_aa[8 * i : 8 * i + 8] return little_endian def _A ( _lowercase ) -> bytes: """simple docstring""" if i < 0: raise ValueError('Input must be non-negative' ) __UpperCamelCase = format(_lowercase , '08x' )[-8:] __UpperCamelCase = 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 ( _lowercase ) -> bytes: """simple docstring""" __UpperCamelCase = B'' for char in message: bit_string += format(_lowercase , '08b' ).encode('utf-8' ) __UpperCamelCase = format(len(_lowercase ) , '064b' ).encode('utf-8' ) # Pad bit_string to a multiple of 512 chars bit_string += b"1" while len(_lowercase ) % 5_12 != 4_48: bit_string += b"0" bit_string += to_little_endian(start_len[32:] ) + to_little_endian(start_len[:32] ) return bit_string def _A ( _lowercase ) -> Generator[list[int], None, None]: """simple docstring""" if len(_lowercase ) % 5_12 != 0: raise ValueError('Input must have length that\'s a multiple of 512' ) for pos in range(0 , len(_lowercase ) , 5_12 ): __UpperCamelCase = bit_string[pos : pos + 5_12] __UpperCamelCase = [] for i in range(0 , 5_12 , 32 ): block_words.append(int(to_little_endian(block[i : i + 32] ) , 2 ) ) yield block_words def _A ( _lowercase ) -> int: """simple docstring""" if i < 0: raise ValueError('Input must be non-negative' ) __UpperCamelCase = format(_lowercase , '032b' ) __UpperCamelCase = '' for c in i_str: new_str += "1" if c == "0" else "0" return int(_lowercase , 2 ) def _A ( _lowercase , _lowercase ) -> int: """simple docstring""" return (a + b) % 2**32 def _A ( _lowercase , _lowercase ) -> int: """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 ( _lowercase ) -> bytes: """simple docstring""" __UpperCamelCase = preprocess(_lowercase ) __UpperCamelCase = [int(2**32 * abs(sin(i + 1 ) ) ) for i in range(64 )] # Starting states __UpperCamelCase = 0X67_45_23_01 __UpperCamelCase = 0Xef_cd_ab_89 __UpperCamelCase = 0X98_ba_dc_fe __UpperCamelCase = 0X10_32_54_76 __UpperCamelCase = [ 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(_lowercase ): __UpperCamelCase = aa __UpperCamelCase = ba __UpperCamelCase = ca __UpperCamelCase = da # Hash current chunk for i in range(64 ): if i <= 15: # f = (b & c) | (not_32(b) & d) # Alternate definition for f __UpperCamelCase = d ^ (b & (c ^ d)) __UpperCamelCase = i elif i <= 31: # f = (d & b) | (not_32(d) & c) # Alternate definition for f __UpperCamelCase = c ^ (d & (b ^ c)) __UpperCamelCase = (5 * i + 1) % 16 elif i <= 47: __UpperCamelCase = b ^ c ^ d __UpperCamelCase = (3 * i + 5) % 16 else: __UpperCamelCase = c ^ (b | not_aa(_lowercase )) __UpperCamelCase = (7 * i) % 16 __UpperCamelCase = (f + a + added_consts[i] + block_words[g]) % 2**32 __UpperCamelCase = d __UpperCamelCase = c __UpperCamelCase = b __UpperCamelCase = sum_aa(_lowercase , left_rotate_aa(_lowercase , shift_amounts[i] ) ) # Add hashed chunk to running total __UpperCamelCase = sum_aa(_lowercase , _lowercase ) __UpperCamelCase = sum_aa(_lowercase , _lowercase ) __UpperCamelCase = sum_aa(_lowercase , _lowercase ) __UpperCamelCase = sum_aa(_lowercase , _lowercase ) __UpperCamelCase = reformat_hex(_lowercase ) + reformat_hex(_lowercase ) + reformat_hex(_lowercase ) + reformat_hex(_lowercase ) return digest if __name__ == "__main__": import doctest doctest.testmod()

'''simple docstring''' import argparse import os import torch from transformers import FlavaConfig, FlavaForPreTraining from transformers.models.flava.convert_dalle_to_flava_codebook import convert_dalle_checkpoint def lowercase__( __UpperCamelCase: Any ): """simple docstring""" return sum(param.float().sum() if 'encoder.embeddings' not in key else 0 for key, param in state_dict.items() ) def lowercase__( __UpperCamelCase: str ,__UpperCamelCase: List[Any] ): """simple docstring""" SCREAMING_SNAKE_CASE : Dict = {} for key, value in state_dict.items(): if "text_encoder.embeddings" in key or "image_encoder.embeddings" in key: continue SCREAMING_SNAKE_CASE : List[Any] = key.replace('heads.cmd.mim_head.cls.predictions' ,'mmm_image_head' ) SCREAMING_SNAKE_CASE : int = key.replace('heads.cmd.mlm_head.cls.predictions' ,'mmm_text_head' ) SCREAMING_SNAKE_CASE : str = key.replace('heads.cmd.itm_head.cls' ,'itm_head' ) SCREAMING_SNAKE_CASE : Dict = key.replace('heads.cmd.itm_head.pooler' ,'itm_head.pooler' ) SCREAMING_SNAKE_CASE : Dict = key.replace('heads.cmd.clip_head.logit_scale' ,'flava.logit_scale' ) SCREAMING_SNAKE_CASE : List[Any] = key.replace('heads.fairseq_mlm.cls.predictions' ,'mlm_head' ) SCREAMING_SNAKE_CASE : Union[str, Any] = key.replace('heads.imagenet.mim_head.cls.predictions' ,'mim_head' ) SCREAMING_SNAKE_CASE : List[Any] = key.replace('mm_text_projection' ,'flava.text_to_mm_projection' ) SCREAMING_SNAKE_CASE : List[str] = key.replace('mm_image_projection' ,'flava.image_to_mm_projection' ) SCREAMING_SNAKE_CASE : Optional[Any] = key.replace('image_encoder.module' ,'flava.image_model' ) SCREAMING_SNAKE_CASE : Optional[int] = key.replace('text_encoder.module' ,'flava.text_model' ) SCREAMING_SNAKE_CASE : Dict = key.replace('mm_encoder.module.encoder.cls_token' ,'flava.multimodal_model.cls_token' ) SCREAMING_SNAKE_CASE : Optional[int] = key.replace('mm_encoder.module' ,'flava.multimodal_model' ) SCREAMING_SNAKE_CASE : Optional[Any] = key.replace('text_projection' ,'flava.text_projection' ) SCREAMING_SNAKE_CASE : Optional[int] = key.replace('image_projection' ,'flava.image_projection' ) SCREAMING_SNAKE_CASE : Dict = value.float() for key, value in codebook_state_dict.items(): SCREAMING_SNAKE_CASE : int = value return upgrade @torch.no_grad() def lowercase__( __UpperCamelCase: Union[str, Any] ,__UpperCamelCase: str ,__UpperCamelCase: Any ,__UpperCamelCase: Optional[int]=None ): """simple docstring""" if config_path is not None: SCREAMING_SNAKE_CASE : int = FlavaConfig.from_pretrained(__UpperCamelCase ) else: SCREAMING_SNAKE_CASE : Union[str, Any] = FlavaConfig() SCREAMING_SNAKE_CASE : str = FlavaForPreTraining(__UpperCamelCase ).eval() SCREAMING_SNAKE_CASE : int = convert_dalle_checkpoint(__UpperCamelCase ,__UpperCamelCase ,save_checkpoint=__UpperCamelCase ) if os.path.exists(__UpperCamelCase ): SCREAMING_SNAKE_CASE : int = torch.load(__UpperCamelCase ,map_location='cpu' ) else: SCREAMING_SNAKE_CASE : Optional[Any] = torch.hub.load_state_dict_from_url(__UpperCamelCase ,map_location='cpu' ) SCREAMING_SNAKE_CASE : int = upgrade_state_dict(__UpperCamelCase ,__UpperCamelCase ) hf_model.load_state_dict(__UpperCamelCase ) SCREAMING_SNAKE_CASE : Optional[Any] = hf_model.state_dict() SCREAMING_SNAKE_CASE : Optional[int] = count_parameters(__UpperCamelCase ) SCREAMING_SNAKE_CASE : int = count_parameters(__UpperCamelCase ) + count_parameters(__UpperCamelCase ) assert torch.allclose(__UpperCamelCase ,__UpperCamelCase ,atol=1e-3 ) hf_model.save_pretrained(__UpperCamelCase ) if __name__ == "__main__": UpperCamelCase_ = argparse.ArgumentParser() parser.add_argument("--pytorch_dump_folder_path", default=None, type=str, help="Path to the output PyTorch model.") parser.add_argument("--checkpoint_path", default=None, type=str, help="Path to flava checkpoint") parser.add_argument("--codebook_path", default=None, type=str, help="Path to flava codebook checkpoint") parser.add_argument("--config_path", default=None, type=str, help="Path to hf config.json of model to convert") UpperCamelCase_ = parser.parse_args() convert_flava_checkpoint(args.checkpoint_path, args.codebook_path, args.pytorch_dump_folder_path, args.config_path)

from __future__ import annotations import time from math import sqrt # 1 for manhattan, 0 for euclidean __snake_case = 0 __snake_case = [ [0, 0, 0, 0, 0, 0, 0], [0, 1, 0, 0, 0, 0, 0], # 0 are free path whereas 1's are obstacles [0, 0, 0, 0, 0, 0, 0], [0, 0, 1, 0, 0, 0, 0], [1, 0, 1, 0, 0, 0, 0], [0, 0, 0, 0, 0, 0, 0], [0, 0, 0, 0, 1, 0, 0], ] __snake_case = [[-1, 0], [0, -1], [1, 0], [0, 1]] # up, left, down, right __snake_case = tuple[int, int] class __lowerCamelCase : def __init__( self: str,A_: int,A_: int,A_: int,A_: int,A_: int,A_: Node | None,): '''simple docstring''' __UpperCamelCase = pos_x __UpperCamelCase = pos_y __UpperCamelCase = (pos_y, pos_x) __UpperCamelCase = goal_x __UpperCamelCase = goal_y __UpperCamelCase = g_cost __UpperCamelCase = parent __UpperCamelCase = self.calculate_heuristic() __UpperCamelCase = self.g_cost + self.h_cost def snake_case_ ( self: str ): '''simple docstring''' __UpperCamelCase = self.pos_x - self.goal_x __UpperCamelCase = self.pos_y - self.goal_y if HEURISTIC == 1: return abs(A_ ) + abs(A_ ) else: return sqrt(dy**2 + dx**2 ) def __lt__( self: int,A_: Node ): '''simple docstring''' return self.f_cost < other.f_cost class __lowerCamelCase : def __init__( self: Any,A_: TPosition,A_: TPosition ): '''simple docstring''' __UpperCamelCase = Node(start[1],start[0],goal[1],goal[0],0,A_ ) __UpperCamelCase = Node(goal[1],goal[0],goal[1],goal[0],9_9999,A_ ) __UpperCamelCase = [self.start] __UpperCamelCase = [] __UpperCamelCase = False def snake_case_ ( self: Any ): '''simple docstring''' while self.open_nodes: # Open Nodes are sorted using __lt__ self.open_nodes.sort() __UpperCamelCase = self.open_nodes.pop(0 ) if current_node.pos == self.target.pos: return self.retrace_path(A_ ) self.closed_nodes.append(A_ ) __UpperCamelCase = self.get_successors(A_ ) for child_node in successors: if child_node in self.closed_nodes: continue if child_node not in self.open_nodes: self.open_nodes.append(A_ ) else: # retrieve the best current path __UpperCamelCase = self.open_nodes.pop(self.open_nodes.index(A_ ) ) if child_node.g_cost < better_node.g_cost: self.open_nodes.append(A_ ) else: self.open_nodes.append(A_ ) return [self.start.pos] def snake_case_ ( self: int,A_: Node ): '''simple docstring''' __UpperCamelCase = [] for action in delta: __UpperCamelCase = parent.pos_x + action[1] __UpperCamelCase = parent.pos_y + action[0] if not (0 <= pos_x <= len(grid[0] ) - 1 and 0 <= pos_y <= len(A_ ) - 1): continue if grid[pos_y][pos_x] != 0: continue successors.append( Node( A_,A_,self.target.pos_y,self.target.pos_x,parent.g_cost + 1,A_,) ) return successors def snake_case_ ( self: Any,A_: Node | None ): '''simple docstring''' __UpperCamelCase = node __UpperCamelCase = [] while current_node is not None: path.append((current_node.pos_y, current_node.pos_x) ) __UpperCamelCase = current_node.parent path.reverse() return path class __lowerCamelCase : def __init__( self: List[Any],A_: TPosition,A_: TPosition ): '''simple docstring''' __UpperCamelCase = AStar(A_,A_ ) __UpperCamelCase = AStar(A_,A_ ) __UpperCamelCase = False def snake_case_ ( self: Union[str, Any] ): '''simple docstring''' while self.fwd_astar.open_nodes or self.bwd_astar.open_nodes: self.fwd_astar.open_nodes.sort() self.bwd_astar.open_nodes.sort() __UpperCamelCase = self.fwd_astar.open_nodes.pop(0 ) __UpperCamelCase = self.bwd_astar.open_nodes.pop(0 ) if current_bwd_node.pos == current_fwd_node.pos: return self.retrace_bidirectional_path( A_,A_ ) self.fwd_astar.closed_nodes.append(A_ ) self.bwd_astar.closed_nodes.append(A_ ) __UpperCamelCase = current_bwd_node __UpperCamelCase = current_fwd_node __UpperCamelCase = { self.fwd_astar: self.fwd_astar.get_successors(A_ ), self.bwd_astar: self.bwd_astar.get_successors(A_ ), } for astar in [self.fwd_astar, self.bwd_astar]: for child_node in successors[astar]: if child_node in astar.closed_nodes: continue if child_node not in astar.open_nodes: astar.open_nodes.append(A_ ) else: # retrieve the best current path __UpperCamelCase = astar.open_nodes.pop( astar.open_nodes.index(A_ ) ) if child_node.g_cost < better_node.g_cost: astar.open_nodes.append(A_ ) else: astar.open_nodes.append(A_ ) return [self.fwd_astar.start.pos] def snake_case_ ( self: List[str],A_: Node,A_: Node ): '''simple docstring''' __UpperCamelCase = self.fwd_astar.retrace_path(A_ ) __UpperCamelCase = self.bwd_astar.retrace_path(A_ ) bwd_path.pop() bwd_path.reverse() __UpperCamelCase = fwd_path + bwd_path return path if __name__ == "__main__": # all coordinates are given in format [y,x] __snake_case = (0, 0) __snake_case = (len(grid) - 1, len(grid[0]) - 1) for elem in grid: print(elem) __snake_case = time.time() __snake_case = AStar(init, goal) __snake_case = a_star.search() __snake_case = time.time() - start_time print(f"""AStar execution time = {end_time:f} seconds""") __snake_case = time.time() __snake_case = BidirectionalAStar(init, goal) __snake_case = time.time() - bd_start_time print(f"""BidirectionalAStar execution time = {bd_end_time:f} seconds""")

"""simple docstring""" from jiwer import compute_measures import datasets A_ = """\ @inproceedings{inproceedings, author = {Morris, Andrew and Maier, Viktoria and Green, Phil}, year = {2004}, month = {01}, pages = {}, title = {From WER and RIL to MER and WIL: improved evaluation measures for connected speech recognition.} } """ A_ = """\ Word error rate (WER) is a common metric of the performance of an automatic speech recognition system. The general difficulty of measuring performance lies in the fact that the recognized word sequence can have a different length from the reference word sequence (supposedly the correct one). The WER is derived from the Levenshtein distance, working at the word level instead of the phoneme level. The WER is a valuable tool for comparing different systems as well as for evaluating improvements within one system. This kind of measurement, however, provides no details on the nature of translation errors and further work is therefore required to identify the main source(s) of error and to focus any research effort. This problem is solved by first aligning the recognized word sequence with the reference (spoken) word sequence using dynamic string alignment. Examination of this issue is seen through a theory called the power law that states the correlation between perplexity and word error rate. Word error rate can then be computed as: WER = (S + D + I) / N = (S + D + I) / (S + D + C) where S is the number of substitutions, D is the number of deletions, I is the number of insertions, C is the number of correct words, N is the number of words in the reference (N=S+D+C). This value indicates the average number of errors per reference word. The lower the value, the better the performance of the ASR system with a WER of 0 being a perfect score. """ A_ = """ Compute WER score of transcribed segments against references. Args: references: List of references for each speech input. predictions: List of transcriptions to score. concatenate_texts (bool, default=False): Whether to concatenate all input texts or compute WER iteratively. Returns: (float): the word error rate Examples: >>> predictions = [\"this is the prediction\", \"there is an other sample\"] >>> references = [\"this is the reference\", \"there is another one\"] >>> wer = datasets.load_metric(\"wer\") >>> wer_score = wer.compute(predictions=predictions, references=references) >>> print(wer_score) 0.5 """ @datasets.utils.file_utils.add_start_docstrings(_DESCRIPTION , _KWARGS_DESCRIPTION ) class __lowerCamelCase ( datasets.Metric ): def UpperCAmelCase__ ( self ): 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/jitsi/jiwer/'''] , reference_urls=[ '''https://en.wikipedia.org/wiki/Word_error_rate''', ] , ) def UpperCAmelCase__ ( self , UpperCAmelCase=None , UpperCAmelCase=None , UpperCAmelCase=False ): if concatenate_texts: return compute_measures(UpperCAmelCase , UpperCAmelCase )["wer"] else: lowerCamelCase_ = 0 lowerCamelCase_ = 0 for prediction, reference in zip(UpperCAmelCase , UpperCAmelCase ): lowerCamelCase_ = compute_measures(UpperCAmelCase , UpperCAmelCase ) incorrect += measures["substitutions"] + measures["deletions"] + measures["insertions"] total += measures["substitutions"] + measures["deletions"] + measures["hits"] return incorrect / total

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 AutoFeatureExtractor, WavaVecaFeatureExtractor 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_feature_extraction import CustomFeatureExtractor # noqa E402 __snake_case = get_tests_dir('''fixtures''') class __lowerCamelCase (unittest.TestCase ): def snake_case_ ( self: int ): '''simple docstring''' __UpperCamelCase = mock.Mock() __UpperCamelCase = 500 __UpperCamelCase = {} __UpperCamelCase = HTTPError __UpperCamelCase = {} # Download this model to make sure it's in the cache. __UpperCamelCase = WavaVecaFeatureExtractor.from_pretrained('hf-internal-testing/tiny-random-wav2vec2' ) # 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: __UpperCamelCase = WavaVecaFeatureExtractor.from_pretrained('hf-internal-testing/tiny-random-wav2vec2' ) # This check we did call the fake head request mock_head.assert_called() def snake_case_ ( self: Dict ): '''simple docstring''' __UpperCamelCase = WavaVecaFeatureExtractor.from_pretrained( 'https://huggingface.co/hf-internal-testing/tiny-random-wav2vec2/resolve/main/preprocessor_config.json' ) @is_staging_test class __lowerCamelCase (unittest.TestCase ): @classmethod def snake_case_ ( cls: Tuple ): '''simple docstring''' __UpperCamelCase = TOKEN HfFolder.save_token(A_ ) @classmethod def snake_case_ ( cls: Tuple ): '''simple docstring''' try: delete_repo(token=cls._token,repo_id='test-feature-extractor' ) except HTTPError: pass try: delete_repo(token=cls._token,repo_id='valid_org/test-feature-extractor-org' ) except HTTPError: pass try: delete_repo(token=cls._token,repo_id='test-dynamic-feature-extractor' ) except HTTPError: pass def snake_case_ ( self: Tuple ): '''simple docstring''' __UpperCamelCase = WavaVecaFeatureExtractor.from_pretrained(A_ ) feature_extractor.push_to_hub('test-feature-extractor',use_auth_token=self._token ) __UpperCamelCase = WavaVecaFeatureExtractor.from_pretrained(F'''{USER}/test-feature-extractor''' ) for k, v in feature_extractor.__dict__.items(): self.assertEqual(A_,getattr(A_,A_ ) ) # Reset repo delete_repo(token=self._token,repo_id='test-feature-extractor' ) # Push to hub via save_pretrained with tempfile.TemporaryDirectory() as tmp_dir: feature_extractor.save_pretrained( A_,repo_id='test-feature-extractor',push_to_hub=A_,use_auth_token=self._token ) __UpperCamelCase = WavaVecaFeatureExtractor.from_pretrained(F'''{USER}/test-feature-extractor''' ) for k, v in feature_extractor.__dict__.items(): self.assertEqual(A_,getattr(A_,A_ ) ) def snake_case_ ( self: List[str] ): '''simple docstring''' __UpperCamelCase = WavaVecaFeatureExtractor.from_pretrained(A_ ) feature_extractor.push_to_hub('valid_org/test-feature-extractor',use_auth_token=self._token ) __UpperCamelCase = WavaVecaFeatureExtractor.from_pretrained('valid_org/test-feature-extractor' ) for k, v in feature_extractor.__dict__.items(): self.assertEqual(A_,getattr(A_,A_ ) ) # Reset repo delete_repo(token=self._token,repo_id='valid_org/test-feature-extractor' ) # Push to hub via save_pretrained with tempfile.TemporaryDirectory() as tmp_dir: feature_extractor.save_pretrained( A_,repo_id='valid_org/test-feature-extractor-org',push_to_hub=A_,use_auth_token=self._token ) __UpperCamelCase = WavaVecaFeatureExtractor.from_pretrained('valid_org/test-feature-extractor-org' ) for k, v in feature_extractor.__dict__.items(): self.assertEqual(A_,getattr(A_,A_ ) ) def snake_case_ ( self: int ): '''simple docstring''' CustomFeatureExtractor.register_for_auto_class() __UpperCamelCase = CustomFeatureExtractor.from_pretrained(A_ ) feature_extractor.push_to_hub('test-dynamic-feature-extractor',use_auth_token=self._token ) # This has added the proper auto_map field to the config self.assertDictEqual( feature_extractor.auto_map,{'AutoFeatureExtractor': 'custom_feature_extraction.CustomFeatureExtractor'},) __UpperCamelCase = AutoFeatureExtractor.from_pretrained( F'''{USER}/test-dynamic-feature-extractor''',trust_remote_code=A_ ) # Can't make an isinstance check because the new_feature_extractor is from the CustomFeatureExtractor class of a dynamic module self.assertEqual(new_feature_extractor.__class__.__name__,'CustomFeatureExtractor' )

import warnings from ...utils import logging from .image_processing_deformable_detr import DeformableDetrImageProcessor __a = logging.get_logger(__name__) class __a( _a ): """simple docstring""" def __init__( self ,*_SCREAMING_SNAKE_CASE ,**_SCREAMING_SNAKE_CASE ) -> None: warnings.warn( '''The class DeformableDetrFeatureExtractor is deprecated and will be removed in version 5 of Transformers.''' ''' Please use DeformableDetrImageProcessor instead.''' ,_SCREAMING_SNAKE_CASE ,) super().__init__(*_SCREAMING_SNAKE_CASE ,**_SCREAMING_SNAKE_CASE )

import argparse import json import os import evaluate import torch from datasets import load_dataset from torch.optim import AdamW from torch.utils.data import DataLoader from transformers import AutoModelForSequenceClassification, AutoTokenizer, get_linear_schedule_with_warmup, set_seed from accelerate import Accelerator, DistributedType from accelerate.utils.deepspeed import DummyOptim, DummyScheduler __snake_case = 1_6 __snake_case = 3_2 def _A ( _lowercase , _lowercase = 16 , _lowercase = "bert-base-cased" ) -> Union[str, Any]: """simple docstring""" __UpperCamelCase = AutoTokenizer.from_pretrained(_lowercase ) __UpperCamelCase = load_dataset('glue' , 'mrpc' ) def tokenize_function(_lowercase ): # max_length=None => use the model max length (it's actually the default) __UpperCamelCase = tokenizer(examples['sentence1'] , examples['sentence2'] , truncation=_lowercase , max_length=_lowercase ) return outputs # Apply the method we just defined to all the examples in all the splits of the dataset __UpperCamelCase = datasets.map( _lowercase , batched=_lowercase , remove_columns=['idx', 'sentence1', 'sentence2'] , load_from_cache_file=_lowercase ) # We also rename the 'label' column to 'labels' which is the expected name for labels by the models of the # transformers library __UpperCamelCase = tokenized_datasets.rename_column('label' , 'labels' ) def collate_fn(_lowercase ): # 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(_lowercase , padding='max_length' , max_length=1_28 , return_tensors='pt' ) return tokenizer.pad(_lowercase , padding='longest' , return_tensors='pt' ) # Instantiate dataloaders. __UpperCamelCase = DataLoader( tokenized_datasets['train'] , shuffle=_lowercase , collate_fn=_lowercase , batch_size=_lowercase ) __UpperCamelCase = DataLoader( tokenized_datasets['validation'] , shuffle=_lowercase , collate_fn=_lowercase , batch_size=_lowercase ) return train_dataloader, eval_dataloader def _A ( _lowercase , _lowercase ) -> int: """simple docstring""" __UpperCamelCase = Accelerator() # Sample hyper-parameters for learning rate, batch size, seed and a few other HPs __UpperCamelCase = config['lr'] __UpperCamelCase = int(config['num_epochs'] ) __UpperCamelCase = int(config['seed'] ) __UpperCamelCase = int(config['batch_size'] ) __UpperCamelCase = args.model_name_or_path set_seed(_lowercase ) __UpperCamelCase, __UpperCamelCase = get_dataloaders(_lowercase , _lowercase , _lowercase ) # Instantiate the model (we build the model here so that the seed also control new weights initialization) __UpperCamelCase = AutoModelForSequenceClassification.from_pretrained(_lowercase , return_dict=_lowercase ) # Instantiate optimizer __UpperCamelCase = ( AdamW if accelerator.state.deepspeed_plugin is None or 'optimizer' not in accelerator.state.deepspeed_plugin.deepspeed_config else DummyOptim ) __UpperCamelCase = optimizer_cls(params=model.parameters() , lr=_lowercase ) if accelerator.state.deepspeed_plugin is not None: __UpperCamelCase = accelerator.state.deepspeed_plugin.deepspeed_config[ 'gradient_accumulation_steps' ] else: __UpperCamelCase = 1 __UpperCamelCase = (len(_lowercase ) * num_epochs) // gradient_accumulation_steps # Instantiate scheduler if ( accelerator.state.deepspeed_plugin is None or "scheduler" not in accelerator.state.deepspeed_plugin.deepspeed_config ): __UpperCamelCase = get_linear_schedule_with_warmup( optimizer=_lowercase , num_warmup_steps=0 , num_training_steps=_lowercase , ) else: __UpperCamelCase = DummyScheduler(_lowercase , total_num_steps=_lowercase , warmup_num_steps=0 ) # Prepare everything # There is no specific order to remember, we just need to unpack the objects in the same order we gave them to the # prepare method. __UpperCamelCase, __UpperCamelCase, __UpperCamelCase, __UpperCamelCase, __UpperCamelCase = accelerator.prepare( _lowercase , _lowercase , _lowercase , _lowercase , _lowercase ) # We need to keep track of how many total steps we have iterated over __UpperCamelCase = 0 # We also need to keep track of the stating epoch so files are named properly __UpperCamelCase = 0 # Now we train the model __UpperCamelCase = evaluate.load('glue' , 'mrpc' ) __UpperCamelCase = 0 __UpperCamelCase = {} for epoch in range(_lowercase , _lowercase ): model.train() for step, batch in enumerate(_lowercase ): __UpperCamelCase = model(**_lowercase ) __UpperCamelCase = outputs.loss __UpperCamelCase = loss / gradient_accumulation_steps accelerator.backward(_lowercase ) if step % gradient_accumulation_steps == 0: optimizer.step() lr_scheduler.step() optimizer.zero_grad() overall_step += 1 model.eval() __UpperCamelCase = 0 for step, batch in enumerate(_lowercase ): # We could avoid this line since we set the accelerator with `device_placement=True`. batch.to(accelerator.device ) with torch.no_grad(): __UpperCamelCase = model(**_lowercase ) __UpperCamelCase = outputs.logits.argmax(dim=-1 ) # It is slightly faster to call this once, than multiple times __UpperCamelCase, __UpperCamelCase = accelerator.gather( (predictions, batch['labels']) ) # If we are in a multiprocess environment, the last batch has duplicates if accelerator.use_distributed: if step == len(_lowercase ) - 1: __UpperCamelCase = predictions[: len(eval_dataloader.dataset ) - samples_seen] __UpperCamelCase = references[: len(eval_dataloader.dataset ) - samples_seen] else: samples_seen += references.shape[0] metric.add_batch( predictions=_lowercase , references=_lowercase , ) __UpperCamelCase = metric.compute() # Use accelerator.print to print only on the main process. accelerator.print(f'''epoch {epoch}:''' , _lowercase ) __UpperCamelCase = eval_metric['accuracy'] if best_performance < eval_metric["accuracy"]: __UpperCamelCase = eval_metric['accuracy'] if args.performance_lower_bound is not None: assert ( args.performance_lower_bound <= best_performance ), f'''Best performance metric {best_performance} is lower than the lower bound {args.performance_lower_bound}''' accelerator.wait_for_everyone() if accelerator.is_main_process: with open(os.path.join(args.output_dir , 'all_results.json' ) , 'w' ) as f: json.dump(_lowercase , _lowercase ) def _A ( ) -> List[str]: """simple docstring""" __UpperCamelCase = argparse.ArgumentParser(description='Simple example of training script tracking peak GPU memory usage.' ) parser.add_argument( '--model_name_or_path' , type=_lowercase , default='bert-base-cased' , help='Path to pretrained model or model identifier from huggingface.co/models.' , required=_lowercase , ) parser.add_argument( '--output_dir' , type=_lowercase , default='.' , help='Optional save directory where all checkpoint folders will be stored. Default is the current working directory.' , ) parser.add_argument( '--performance_lower_bound' , type=_lowercase , default=_lowercase , help='Optional lower bound for the performance metric. If set, the training will throw error when the performance metric drops below this value.' , ) parser.add_argument( '--num_epochs' , type=_lowercase , default=3 , help='Number of train epochs.' , ) __UpperCamelCase = parser.parse_args() __UpperCamelCase = {'lr': 2e-5, 'num_epochs': args.num_epochs, 'seed': 42, 'batch_size': 16} training_function(_lowercase , _lowercase ) if __name__ == "__main__": main()

import pytest from datasets.parallel import ParallelBackendConfig, parallel_backend from datasets.utils.py_utils import map_nested from .utils import require_dill_gt_0_3_2, require_joblibspark, require_not_windows def UpperCAmelCase_ ( __UpperCAmelCase : str ) -> Tuple: # picklable for multiprocessing return i + 1 @require_dill_gt_0_3_2 @require_joblibspark @require_not_windows def UpperCAmelCase_ ( ) -> str: with parallel_backend('spark' ): assert ParallelBackendConfig.backend_name == "spark" SCREAMING_SNAKE_CASE_ = [1, 2, 3] with pytest.raises(__UpperCAmelCase ): with parallel_backend('unsupported backend' ): map_nested(__UpperCAmelCase , __UpperCAmelCase , num_proc=2 ) with pytest.raises(__UpperCAmelCase ): with parallel_backend('unsupported backend' ): map_nested(__UpperCAmelCase , __UpperCAmelCase , num_proc=-1 ) @require_dill_gt_0_3_2 @require_joblibspark @require_not_windows @pytest.mark.parametrize('num_proc' , [2, -1] ) def UpperCAmelCase_ ( __UpperCAmelCase : Tuple ) -> List[Any]: SCREAMING_SNAKE_CASE_ = [1, 2] SCREAMING_SNAKE_CASE_ = {'a': 1, 'b': 2} SCREAMING_SNAKE_CASE_ = {'a': [1, 2], 'b': [3, 4]} SCREAMING_SNAKE_CASE_ = {'a': {'1': 1}, 'b': 2} SCREAMING_SNAKE_CASE_ = {'a': 1, 'b': 2, 'c': 3, 'd': 4} SCREAMING_SNAKE_CASE_ = [2, 3] SCREAMING_SNAKE_CASE_ = {'a': 2, 'b': 3} SCREAMING_SNAKE_CASE_ = {'a': [2, 3], 'b': [4, 5]} SCREAMING_SNAKE_CASE_ = {'a': {'1': 2}, 'b': 3} SCREAMING_SNAKE_CASE_ = {'a': 2, 'b': 3, 'c': 4, 'd': 5} with parallel_backend('spark' ): assert map_nested(__UpperCAmelCase , __UpperCAmelCase , num_proc=__UpperCAmelCase ) == expected_map_nested_sa assert map_nested(__UpperCAmelCase , __UpperCAmelCase , num_proc=__UpperCAmelCase ) == expected_map_nested_sa assert map_nested(__UpperCAmelCase , __UpperCAmelCase , num_proc=__UpperCAmelCase ) == expected_map_nested_sa assert map_nested(__UpperCAmelCase , __UpperCAmelCase , num_proc=__UpperCAmelCase ) == expected_map_nested_sa assert map_nested(__UpperCAmelCase , __UpperCAmelCase , num_proc=__UpperCAmelCase ) == expected_map_nested_sa

from transformers import BertTokenizer, EncoderDecoderModel, SeqaSeqTrainer, SeqaSeqTrainingArguments from transformers.testing_utils import TestCasePlus, require_torch, slow from transformers.utils import is_datasets_available if is_datasets_available(): import datasets class __lowerCamelCase (_a ): @slow @require_torch def snake_case_ ( self: Union[str, Any] ): '''simple docstring''' __UpperCamelCase = EncoderDecoderModel.from_encoder_decoder_pretrained('prajjwal1/bert-tiny','prajjwal1/bert-tiny' ) __UpperCamelCase = BertTokenizer.from_pretrained('bert-base-uncased' ) __UpperCamelCase = bertabert.config.encoder.vocab_size __UpperCamelCase = tokenizer.sep_token_id __UpperCamelCase = tokenizer.cls_token_id __UpperCamelCase = 128 __UpperCamelCase = datasets.load_dataset('cnn_dailymail','3.0.0',split='train[:1%]' ) __UpperCamelCase = datasets.load_dataset('cnn_dailymail','3.0.0',split='validation[:1%]' ) __UpperCamelCase = train_dataset.select(range(32 ) ) __UpperCamelCase = val_dataset.select(range(16 ) ) __UpperCamelCase = 4 def _map_to_encoder_decoder_inputs(A_: Dict ): # Tokenizer will automatically set [BOS] <text> [EOS] __UpperCamelCase = tokenizer(batch['article'],padding='max_length',truncation=A_,max_length=512 ) __UpperCamelCase = tokenizer(batch['highlights'],padding='max_length',truncation=A_,max_length=128 ) __UpperCamelCase = inputs.input_ids __UpperCamelCase = inputs.attention_mask __UpperCamelCase = outputs.input_ids __UpperCamelCase = outputs.input_ids.copy() __UpperCamelCase = [ [-100 if token == tokenizer.pad_token_id else token for token in labels] for labels in batch['labels'] ] __UpperCamelCase = outputs.attention_mask assert all(len(A_ ) == 512 for x in inputs.input_ids ) assert all(len(A_ ) == 128 for x in outputs.input_ids ) return batch def _compute_metrics(A_: str ): __UpperCamelCase = pred.label_ids __UpperCamelCase = pred.predictions # all unnecessary tokens are removed __UpperCamelCase = tokenizer.batch_decode(A_,skip_special_tokens=A_ ) __UpperCamelCase = tokenizer.batch_decode(A_,skip_special_tokens=A_ ) __UpperCamelCase = sum([int(pred_str[i] == label_str[i] ) for i in range(len(A_ ) )] ) / len(A_ ) return {"accuracy": accuracy} # map train dataset __UpperCamelCase = train_dataset.map( _map_to_encoder_decoder_inputs,batched=A_,batch_size=A_,remove_columns=['article', 'highlights'],) train_dataset.set_format( type='torch',columns=['input_ids', 'attention_mask', 'decoder_input_ids', 'decoder_attention_mask', 'labels'],) # same for validation dataset __UpperCamelCase = val_dataset.map( _map_to_encoder_decoder_inputs,batched=A_,batch_size=A_,remove_columns=['article', 'highlights'],) val_dataset.set_format( type='torch',columns=['input_ids', 'attention_mask', 'decoder_input_ids', 'decoder_attention_mask', 'labels'],) __UpperCamelCase = self.get_auto_remove_tmp_dir() __UpperCamelCase = SeqaSeqTrainingArguments( output_dir=A_,per_device_train_batch_size=A_,per_device_eval_batch_size=A_,predict_with_generate=A_,evaluation_strategy='steps',do_train=A_,do_eval=A_,warmup_steps=0,eval_steps=2,logging_steps=2,) # instantiate trainer __UpperCamelCase = SeqaSeqTrainer( model=A_,args=A_,compute_metrics=_compute_metrics,train_dataset=A_,eval_dataset=A_,tokenizer=A_,) # start training trainer.train()

UpperCAmelCase_ = "ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789+/" def A__ ( SCREAMING_SNAKE_CASE_ : bytes ) -> bytes: """simple docstring""" if not isinstance(SCREAMING_SNAKE_CASE_ , SCREAMING_SNAKE_CASE_ ): _UpperCAmelCase = F'''a bytes-like object is required, not \'{data.__class__.__name__}\'''' raise TypeError(SCREAMING_SNAKE_CASE_ ) _UpperCAmelCase = ''''''.join(bin(SCREAMING_SNAKE_CASE_ )[2:].zfill(8 ) for byte in data ) _UpperCAmelCase = len(SCREAMING_SNAKE_CASE_ ) % 6 != 0 if padding_needed: # The padding that will be added later _UpperCAmelCase = B'''=''' * ((6 - len(SCREAMING_SNAKE_CASE_ ) % 6) // 2) # Append binary_stream with arbitrary binary digits (0's by default) to make its # length a multiple of 6. binary_stream += "0" * (6 - len(SCREAMING_SNAKE_CASE_ ) % 6) else: _UpperCAmelCase = B'''''' # Encode every 6 binary digits to their corresponding Base64 character return ( "".join( B64_CHARSET[int(binary_stream[index : index + 6] , 2 )] for index in range(0 , len(SCREAMING_SNAKE_CASE_ ) , 6 ) ).encode() + padding ) def A__ ( SCREAMING_SNAKE_CASE_ : str ) -> bytes: """simple docstring""" if not isinstance(SCREAMING_SNAKE_CASE_ , SCREAMING_SNAKE_CASE_ ) and not isinstance(SCREAMING_SNAKE_CASE_ , SCREAMING_SNAKE_CASE_ ): _UpperCAmelCase = ( '''argument should be a bytes-like object or ASCII string, ''' F'''not \'{encoded_data.__class__.__name__}\'''' ) raise TypeError(SCREAMING_SNAKE_CASE_ ) # In case encoded_data is a bytes-like object, make sure it contains only # ASCII characters so we convert it to a string object if isinstance(SCREAMING_SNAKE_CASE_ , SCREAMING_SNAKE_CASE_ ): try: _UpperCAmelCase = encoded_data.decode('''utf-8''' ) except UnicodeDecodeError: raise ValueError('''base64 encoded data should only contain ASCII characters''' ) _UpperCAmelCase = encoded_data.count('''=''' ) # Check if the encoded string contains non base64 characters if padding: assert all( char in B64_CHARSET for char in encoded_data[:-padding] ), "Invalid base64 character(s) found." else: assert all( char in B64_CHARSET for char in encoded_data ), "Invalid base64 character(s) found." # Check the padding assert len(SCREAMING_SNAKE_CASE_ ) % 4 == 0 and padding < 3, "Incorrect padding" if padding: # Remove padding if there is one _UpperCAmelCase = encoded_data[:-padding] _UpperCAmelCase = ''''''.join( bin(B64_CHARSET.index(SCREAMING_SNAKE_CASE_ ) )[2:].zfill(6 ) for char in encoded_data )[: -padding * 2] else: _UpperCAmelCase = ''''''.join( bin(B64_CHARSET.index(SCREAMING_SNAKE_CASE_ ) )[2:].zfill(6 ) for char in encoded_data ) _UpperCAmelCase = [ int(binary_stream[index : index + 8] , 2 ) for index in range(0 , len(SCREAMING_SNAKE_CASE_ ) , 8 ) ] return bytes(SCREAMING_SNAKE_CASE_ ) if __name__ == "__main__": import doctest doctest.testmod()

def _A ( _lowercase = 1_00 ) -> int: """simple docstring""" __UpperCamelCase = 0 __UpperCamelCase = 0 for i in range(1 , n + 1 ): sum_of_squares += i**2 sum_of_ints += i return sum_of_ints**2 - sum_of_squares if __name__ == "__main__": print(f"""{solution() = }""")

import argparse import torch from torch import nn from transformers import MaMaaaConfig, MaMaaaForConditionalGeneration def SCREAMING_SNAKE_CASE ( __lowerCAmelCase ) -> Any: snake_case__ = [ '''encoder.version''', '''decoder.version''', '''model.encoder.version''', '''model.decoder.version''', '''decoder.output_projection.weight''', '''_float_tensor''', '''encoder.embed_positions._float_tensor''', '''decoder.embed_positions._float_tensor''', ] for k in ignore_keys: state_dict.pop(__lowerCAmelCase , __lowerCAmelCase ) def SCREAMING_SNAKE_CASE ( __lowerCAmelCase ) -> str: snake_case__ , snake_case__ = emb.weight.shape snake_case__ = nn.Linear(__lowerCAmelCase , __lowerCAmelCase , bias=__lowerCAmelCase ) snake_case__ = emb.weight.data return lin_layer def SCREAMING_SNAKE_CASE ( __lowerCAmelCase ) -> Dict: snake_case__ = torch.load(__lowerCAmelCase , map_location='''cpu''' ) snake_case__ = mam_aaa['''args'''] or mam_aaa['''cfg''']['''model'''] snake_case__ = mam_aaa['''model'''] remove_ignore_keys_(__lowerCAmelCase ) snake_case__ = state_dict['''encoder.embed_tokens.weight'''].shape[0] snake_case__ = MaMaaaConfig( vocab_size=__lowerCAmelCase , max_position_embeddings=1024 , encoder_layers=args.encoder_layers , decoder_layers=args.decoder_layers , encoder_attention_heads=args.encoder_attention_heads , decoder_attention_heads=args.decoder_attention_heads , encoder_ffn_dim=args.encoder_ffn_embed_dim , decoder_ffn_dim=args.decoder_ffn_embed_dim , d_model=args.encoder_embed_dim , encoder_layerdrop=args.encoder_layerdrop , decoder_layerdrop=args.decoder_layerdrop , dropout=args.dropout , attention_dropout=args.attention_dropout , activation_dropout=args.activation_dropout , activation_function='''relu''' , ) snake_case__ = state_dict['''decoder.embed_tokens.weight'''] snake_case__ = MaMaaaForConditionalGeneration(__lowerCAmelCase ) model.model.load_state_dict(__lowerCAmelCase , strict=__lowerCAmelCase ) snake_case__ = make_linear_from_emb(model.model.shared ) return model if __name__ == "__main__": lowerCamelCase__ : Optional[int] = argparse.ArgumentParser() # Required parameters parser.add_argument("""fairseq_path""", type=str, help="""path to a model.pt on local filesystem.""") parser.add_argument("""pytorch_dump_folder_path""", default=None, type=str, help="""Path to the output PyTorch model.""") lowerCamelCase__ : Optional[int] = parser.parse_args() lowerCamelCase__ : List[str] = convert_fairseq_mamaaa_checkpoint_from_disk(args.fairseq_pathß) model.save_pretrained(args.pytorch_dump_folder_path)

def _A ( _lowercase , _lowercase ) -> int: """simple docstring""" return (pointa[0] - pointa[0]) ** 2 + (pointa[1] - pointa[1]) ** 2 def _A ( _lowercase , _lowercase=0 ) -> Dict: """simple docstring""" return sorted(_lowercase , key=lambda _lowercase : x[column] ) def _A ( _lowercase , _lowercase , _lowercase=float('inf' ) ) -> List[Any]: """simple docstring""" for i in range(points_counts - 1 ): for j in range(i + 1 , _lowercase ): __UpperCamelCase = euclidean_distance_sqr(points[i] , points[j] ) if current_dis < min_dis: __UpperCamelCase = current_dis return min_dis def _A ( _lowercase , _lowercase , _lowercase=float('inf' ) ) -> Tuple: """simple docstring""" for i in range(min(6 , points_counts - 1 ) , _lowercase ): for j in range(max(0 , i - 6 ) , _lowercase ): __UpperCamelCase = euclidean_distance_sqr(points[i] , points[j] ) if current_dis < min_dis: __UpperCamelCase = current_dis return min_dis def _A ( _lowercase , _lowercase , _lowercase ) -> Optional[Any]: """simple docstring""" if points_counts <= 3: return dis_between_closest_pair(_lowercase , _lowercase ) # recursion __UpperCamelCase = points_counts // 2 __UpperCamelCase = closest_pair_of_points_sqr( _lowercase , points_sorted_on_y[:mid] , _lowercase ) __UpperCamelCase = closest_pair_of_points_sqr( _lowercase , points_sorted_on_y[mid:] , points_counts - mid ) __UpperCamelCase = min(_lowercase , _lowercase ) __UpperCamelCase = [] for point in points_sorted_on_x: if abs(point[0] - points_sorted_on_x[mid][0] ) < closest_pair_dis: cross_strip.append(_lowercase ) __UpperCamelCase = dis_between_closest_in_strip( _lowercase , len(_lowercase ) , _lowercase ) return min(_lowercase , _lowercase ) def _A ( _lowercase , _lowercase ) -> Optional[int]: """simple docstring""" __UpperCamelCase = column_based_sort(_lowercase , column=0 ) __UpperCamelCase = column_based_sort(_lowercase , column=1 ) return ( closest_pair_of_points_sqr( _lowercase , _lowercase , _lowercase ) ) ** 0.5 if __name__ == "__main__": __snake_case = [(2, 3), (1_2, 3_0), (4_0, 5_0), (5, 1), (1_2, 1_0), (3, 4)] print('''Distance:''', closest_pair_of_points(points, len(points)))

"""simple docstring""" import json import os import re import shutil import tempfile import unittest from typing import Tuple from transformers import AddedToken, BatchEncoding, PerceiverTokenizer from transformers.utils import cached_property, is_tf_available, is_torch_available from ...test_tokenization_common import TokenizerTesterMixin if is_torch_available(): SCREAMING_SNAKE_CASE_ = 'pt' elif is_tf_available(): SCREAMING_SNAKE_CASE_ = 'tf' else: SCREAMING_SNAKE_CASE_ = 'jax' class snake_case_ ( lowerCamelCase_ , unittest.TestCase ): """simple docstring""" A_ = PerceiverTokenizer A_ = False def UpperCAmelCase__ ( self) -> Optional[int]: super().setUp() UpperCamelCase = PerceiverTokenizer() tokenizer.save_pretrained(self.tmpdirname) @cached_property def UpperCAmelCase__ ( self) -> Any: return PerceiverTokenizer.from_pretrained('''deepmind/language-perceiver''') def UpperCAmelCase__ ( self , **lowerCamelCase_) -> PerceiverTokenizer: return self.tokenizer_class.from_pretrained(self.tmpdirname , **lowerCamelCase_) def UpperCAmelCase__ ( self , lowerCamelCase_ , lowerCamelCase_=False , lowerCamelCase_=2_0 , lowerCamelCase_=5) -> Tuple[str, list]: # XXX The default common tokenizer tests assume that every ID is decodable on its own. # This assumption is invalid for Perceiver because single bytes might not be # valid utf-8 (byte 128 for instance). # Here we're overriding the smallest possible method to provide # a clean sequence without making the same assumption. UpperCamelCase = [] for i in range(len(lowerCamelCase_)): try: UpperCamelCase = tokenizer.decode([i] , clean_up_tokenization_spaces=lowerCamelCase_) except UnicodeDecodeError: pass toks.append((i, tok)) UpperCamelCase = list(filter(lambda lowerCamelCase_: re.match(R'''^[ a-zA-Z]+$''' , t[1]) , lowerCamelCase_)) UpperCamelCase = list(filter(lambda lowerCamelCase_: [t[0]] == tokenizer.encode(t[1] , add_special_tokens=lowerCamelCase_) , lowerCamelCase_)) if max_length is not None and len(lowerCamelCase_) > max_length: UpperCamelCase = toks[:max_length] if min_length is not None and len(lowerCamelCase_) < min_length and len(lowerCamelCase_) > 0: while len(lowerCamelCase_) < min_length: UpperCamelCase = toks + toks # toks_str = [t[1] for t in toks] UpperCamelCase = [t[0] for t in toks] # Ensure consistency UpperCamelCase = tokenizer.decode(lowerCamelCase_ , clean_up_tokenization_spaces=lowerCamelCase_) if " " not in output_txt and len(lowerCamelCase_) > 1: UpperCamelCase = ( tokenizer.decode([toks_ids[0]] , clean_up_tokenization_spaces=lowerCamelCase_) + ''' ''' + tokenizer.decode(toks_ids[1:] , clean_up_tokenization_spaces=lowerCamelCase_) ) if with_prefix_space: UpperCamelCase = ''' ''' + output_txt UpperCamelCase = tokenizer.encode(lowerCamelCase_ , add_special_tokens=lowerCamelCase_) return output_txt, output_ids def UpperCAmelCase__ ( self) -> int: UpperCamelCase = self.perceiver_tokenizer UpperCamelCase = '''Unicode €.''' UpperCamelCase = tokenizer(lowerCamelCase_) UpperCamelCase = [4, 9_1, 1_1_6, 1_1_1, 1_0_5, 1_1_7, 1_0_6, 1_0_7, 3_8, 2_3_2, 1_3_6, 1_7_8, 5_2, 5] self.assertEqual(encoded['''input_ids'''] , lowerCamelCase_) # decoding UpperCamelCase = tokenizer.decode(lowerCamelCase_) self.assertEqual(lowerCamelCase_ , '''[CLS]Unicode €.[SEP]''') UpperCamelCase = tokenizer('''e è é ê ë''') UpperCamelCase = [4, 1_0_7, 3_8, 2_0_1, 1_7_4, 3_8, 2_0_1, 1_7_5, 3_8, 2_0_1, 1_7_6, 3_8, 2_0_1, 1_7_7, 5] self.assertEqual(encoded['''input_ids'''] , lowerCamelCase_) # decoding UpperCamelCase = tokenizer.decode(lowerCamelCase_) self.assertEqual(lowerCamelCase_ , '''[CLS]e è é ê ë[SEP]''') # encode/decode, but with `encode` instead of `__call__` self.assertEqual(tokenizer.decode(tokenizer.encode('''e è é ê ë''')) , '''[CLS]e è é ê ë[SEP]''') def UpperCAmelCase__ ( self) -> Union[str, Any]: UpperCamelCase = self.perceiver_tokenizer UpperCamelCase = ['''A long paragraph for summarization.''', '''Another paragraph for summarization.'''] # fmt: off UpperCamelCase = [4, 7_1, 3_8, 1_1_4, 1_1_7, 1_1_6, 1_0_9, 3_8, 1_1_8, 1_0_3, 1_2_0, 1_0_3, 1_0_9, 1_2_0, 1_0_3, 1_1_8, 1_1_0, 3_8, 1_0_8, 1_1_7, 1_2_0, 3_8, 1_2_1, 1_2_3, 1_1_5, 1_1_5, 1_0_3, 1_2_0, 1_1_1, 1_2_8, 1_0_3, 1_2_2, 1_1_1, 1_1_7, 1_1_6, 5_2, 5, 0] # fmt: on UpperCamelCase = tokenizer(lowerCamelCase_ , padding=lowerCamelCase_ , return_tensors=lowerCamelCase_) self.assertIsInstance(lowerCamelCase_ , lowerCamelCase_) if FRAMEWORK != "jax": UpperCamelCase = list(batch.input_ids.numpy()[0]) else: UpperCamelCase = list(batch.input_ids.tolist()[0]) self.assertListEqual(lowerCamelCase_ , lowerCamelCase_) self.assertEqual((2, 3_8) , batch.input_ids.shape) self.assertEqual((2, 3_8) , batch.attention_mask.shape) def UpperCAmelCase__ ( self) -> List[str]: UpperCamelCase = self.perceiver_tokenizer UpperCamelCase = ['''A long paragraph for summarization.''', '''Another paragraph for summarization.'''] UpperCamelCase = tokenizer(lowerCamelCase_ , padding=lowerCamelCase_ , return_tensors=lowerCamelCase_) # check if input_ids are returned and no decoder_input_ids self.assertIn('''input_ids''' , lowerCamelCase_) self.assertIn('''attention_mask''' , lowerCamelCase_) self.assertNotIn('''decoder_input_ids''' , lowerCamelCase_) self.assertNotIn('''decoder_attention_mask''' , lowerCamelCase_) def UpperCAmelCase__ ( self) -> Any: UpperCamelCase = self.perceiver_tokenizer UpperCamelCase = [ '''Summary of the text.''', '''Another summary.''', ] UpperCamelCase = tokenizer( text_target=lowerCamelCase_ , max_length=3_2 , padding='''max_length''' , truncation=lowerCamelCase_ , return_tensors=lowerCamelCase_) self.assertEqual(3_2 , targets['''input_ids'''].shape[1]) def UpperCAmelCase__ ( self) -> Optional[int]: # safety check on max_len default value so we are sure the test works UpperCamelCase = self.get_tokenizers() for tokenizer in tokenizers: with self.subTest(F'{tokenizer.__class__.__name__}'): self.assertNotEqual(tokenizer.model_max_length , 4_2) # Now let's start the test UpperCamelCase = self.get_tokenizers() for tokenizer in tokenizers: with self.subTest(F'{tokenizer.__class__.__name__}'): # Isolate this from the other tests because we save additional tokens/etc UpperCamelCase = tempfile.mkdtemp() UpperCamelCase = ''' He is very happy, UNwant\u00E9d,running''' UpperCamelCase = tokenizer.encode(lowerCamelCase_ , add_special_tokens=lowerCamelCase_) tokenizer.save_pretrained(lowerCamelCase_) UpperCamelCase = tokenizer.__class__.from_pretrained(lowerCamelCase_) UpperCamelCase = after_tokenizer.encode(lowerCamelCase_ , add_special_tokens=lowerCamelCase_) self.assertListEqual(lowerCamelCase_ , lowerCamelCase_) shutil.rmtree(lowerCamelCase_) UpperCamelCase = self.get_tokenizers(model_max_length=4_2) for tokenizer in tokenizers: with self.subTest(F'{tokenizer.__class__.__name__}'): # Isolate this from the other tests because we save additional tokens/etc UpperCamelCase = tempfile.mkdtemp() UpperCamelCase = ''' He is very happy, UNwant\u00E9d,running''' tokenizer.add_tokens(['''bim''', '''bambam''']) UpperCamelCase = tokenizer.additional_special_tokens additional_special_tokens.append('''new_additional_special_token''') tokenizer.add_special_tokens({'''additional_special_tokens''': additional_special_tokens}) UpperCamelCase = tokenizer.encode(lowerCamelCase_ , add_special_tokens=lowerCamelCase_) tokenizer.save_pretrained(lowerCamelCase_) UpperCamelCase = tokenizer.__class__.from_pretrained(lowerCamelCase_) UpperCamelCase = after_tokenizer.encode(lowerCamelCase_ , add_special_tokens=lowerCamelCase_) self.assertListEqual(lowerCamelCase_ , lowerCamelCase_) self.assertIn('''new_additional_special_token''' , after_tokenizer.additional_special_tokens) self.assertEqual(after_tokenizer.model_max_length , 4_2) UpperCamelCase = tokenizer.__class__.from_pretrained(lowerCamelCase_ , model_max_length=4_3) self.assertEqual(tokenizer.model_max_length , 4_3) shutil.rmtree(lowerCamelCase_) def UpperCAmelCase__ ( self) -> str: UpperCamelCase = [] if self.test_slow_tokenizer: tokenizer_list.append((self.tokenizer_class, self.get_tokenizer())) if self.test_rust_tokenizer: tokenizer_list.append((self.rust_tokenizer_class, self.get_rust_tokenizer())) for tokenizer_class, tokenizer_utils in tokenizer_list: with tempfile.TemporaryDirectory() as tmp_dir: tokenizer_utils.save_pretrained(lowerCamelCase_) with open(os.path.join(lowerCamelCase_ , '''special_tokens_map.json''') , encoding='''utf-8''') as json_file: UpperCamelCase = json.load(lowerCamelCase_) with open(os.path.join(lowerCamelCase_ , '''tokenizer_config.json''') , encoding='''utf-8''') as json_file: UpperCamelCase = json.load(lowerCamelCase_) UpperCamelCase = [F'<extra_id_{i}>' for i in range(1_2_5)] UpperCamelCase = added_tokens_extra_ids + [ '''an_additional_special_token''' ] UpperCamelCase = added_tokens_extra_ids + [ '''an_additional_special_token''' ] with open(os.path.join(lowerCamelCase_ , '''special_tokens_map.json''') , '''w''' , encoding='''utf-8''') as outfile: json.dump(lowerCamelCase_ , lowerCamelCase_) with open(os.path.join(lowerCamelCase_ , '''tokenizer_config.json''') , '''w''' , encoding='''utf-8''') as outfile: json.dump(lowerCamelCase_ , lowerCamelCase_) # the following checks allow us to verify that our test works as expected, i.e. that the tokenizer takes # into account the new value of additional_special_tokens given in the "tokenizer_config.json" and # "special_tokens_map.json" files UpperCamelCase = tokenizer_class.from_pretrained( lowerCamelCase_ , ) self.assertIn( '''an_additional_special_token''' , tokenizer_without_change_in_init.additional_special_tokens) self.assertEqual( ['''an_additional_special_token'''] , tokenizer_without_change_in_init.convert_ids_to_tokens( tokenizer_without_change_in_init.convert_tokens_to_ids(['''an_additional_special_token'''])) , ) # Now we test that we can change the value of additional_special_tokens in the from_pretrained UpperCamelCase = added_tokens_extra_ids + [AddedToken('''a_new_additional_special_token''' , lstrip=lowerCamelCase_)] UpperCamelCase = tokenizer_class.from_pretrained( lowerCamelCase_ , additional_special_tokens=lowerCamelCase_ , ) self.assertIn('''a_new_additional_special_token''' , tokenizer.additional_special_tokens) self.assertEqual( ['''a_new_additional_special_token'''] , tokenizer.convert_ids_to_tokens( tokenizer.convert_tokens_to_ids(['''a_new_additional_special_token'''])) , ) def UpperCAmelCase__ ( self) -> Any: UpperCamelCase = self.perceiver_tokenizer self.assertEqual(tokenizer.decode([1_7_8]) , '''�''') def UpperCAmelCase__ ( self) -> Optional[Any]: pass def UpperCAmelCase__ ( self) -> Union[str, Any]: pass def UpperCAmelCase__ ( self) -> List[Any]: pass def UpperCAmelCase__ ( self) -> Tuple: pass def UpperCAmelCase__ ( self) -> Optional[int]: # The default common tokenizer tests uses invalid tokens for Perceiver that can only accept one-character # strings and special added tokens as tokens UpperCamelCase = self.get_tokenizers(fast=lowerCamelCase_ , do_lower_case=lowerCamelCase_) for tokenizer in tokenizers: with self.subTest(F'{tokenizer.__class__.__name__}'): UpperCamelCase = ['''[CLS]''', '''t''', '''h''', '''i''', '''s''', ''' ''', '''i''', '''s''', ''' ''', '''a''', ''' ''', '''t''', '''e''', '''s''', '''t''', '''[SEP]'''] UpperCamelCase = tokenizer.convert_tokens_to_string(lowerCamelCase_) self.assertIsInstance(lowerCamelCase_ , lowerCamelCase_)

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 = { '''bert-base-uncased''': '''https://huggingface.co/bert-base-uncased/resolve/main/config.json''', '''bert-large-uncased''': '''https://huggingface.co/bert-large-uncased/resolve/main/config.json''', '''bert-base-cased''': '''https://huggingface.co/bert-base-cased/resolve/main/config.json''', '''bert-large-cased''': '''https://huggingface.co/bert-large-cased/resolve/main/config.json''', '''bert-base-multilingual-uncased''': '''https://huggingface.co/bert-base-multilingual-uncased/resolve/main/config.json''', '''bert-base-multilingual-cased''': '''https://huggingface.co/bert-base-multilingual-cased/resolve/main/config.json''', '''bert-base-chinese''': '''https://huggingface.co/bert-base-chinese/resolve/main/config.json''', '''bert-base-german-cased''': '''https://huggingface.co/bert-base-german-cased/resolve/main/config.json''', '''bert-large-uncased-whole-word-masking''': ( '''https://huggingface.co/bert-large-uncased-whole-word-masking/resolve/main/config.json''' ), '''bert-large-cased-whole-word-masking''': ( '''https://huggingface.co/bert-large-cased-whole-word-masking/resolve/main/config.json''' ), '''bert-large-uncased-whole-word-masking-finetuned-squad''': ( '''https://huggingface.co/bert-large-uncased-whole-word-masking-finetuned-squad/resolve/main/config.json''' ), '''bert-large-cased-whole-word-masking-finetuned-squad''': ( '''https://huggingface.co/bert-large-cased-whole-word-masking-finetuned-squad/resolve/main/config.json''' ), '''bert-base-cased-finetuned-mrpc''': '''https://huggingface.co/bert-base-cased-finetuned-mrpc/resolve/main/config.json''', '''bert-base-german-dbmdz-cased''': '''https://huggingface.co/bert-base-german-dbmdz-cased/resolve/main/config.json''', '''bert-base-german-dbmdz-uncased''': '''https://huggingface.co/bert-base-german-dbmdz-uncased/resolve/main/config.json''', '''cl-tohoku/bert-base-japanese''': '''https://huggingface.co/cl-tohoku/bert-base-japanese/resolve/main/config.json''', '''cl-tohoku/bert-base-japanese-whole-word-masking''': ( '''https://huggingface.co/cl-tohoku/bert-base-japanese-whole-word-masking/resolve/main/config.json''' ), '''cl-tohoku/bert-base-japanese-char''': ( '''https://huggingface.co/cl-tohoku/bert-base-japanese-char/resolve/main/config.json''' ), '''cl-tohoku/bert-base-japanese-char-whole-word-masking''': ( '''https://huggingface.co/cl-tohoku/bert-base-japanese-char-whole-word-masking/resolve/main/config.json''' ), '''TurkuNLP/bert-base-finnish-cased-v1''': ( '''https://huggingface.co/TurkuNLP/bert-base-finnish-cased-v1/resolve/main/config.json''' ), '''TurkuNLP/bert-base-finnish-uncased-v1''': ( '''https://huggingface.co/TurkuNLP/bert-base-finnish-uncased-v1/resolve/main/config.json''' ), '''wietsedv/bert-base-dutch-cased''': '''https://huggingface.co/wietsedv/bert-base-dutch-cased/resolve/main/config.json''', # See all BERT models at https://huggingface.co/models?filter=bert } class __lowerCamelCase (_a ): _lowercase = """bert""" def __init__( self: Any,A_: Dict=3_0522,A_: Optional[Any]=768,A_: Union[str, Any]=12,A_: List[Any]=12,A_: Optional[int]=3072,A_: Union[str, Any]="gelu",A_: List[str]=0.1,A_: Dict=0.1,A_: Optional[int]=512,A_: Optional[Any]=2,A_: Union[str, Any]=0.0_2,A_: List[Any]=1E-12,A_: Optional[int]=0,A_: List[Any]="absolute",A_: str=True,A_: Union[str, Any]=None,**A_: int,): '''simple docstring''' super().__init__(pad_token_id=A_,**A_ ) __UpperCamelCase = vocab_size __UpperCamelCase = hidden_size __UpperCamelCase = num_hidden_layers __UpperCamelCase = num_attention_heads __UpperCamelCase = hidden_act __UpperCamelCase = intermediate_size __UpperCamelCase = hidden_dropout_prob __UpperCamelCase = attention_probs_dropout_prob __UpperCamelCase = max_position_embeddings __UpperCamelCase = type_vocab_size __UpperCamelCase = initializer_range __UpperCamelCase = layer_norm_eps __UpperCamelCase = position_embedding_type __UpperCamelCase = use_cache __UpperCamelCase = classifier_dropout class __lowerCamelCase (_a ): @property def snake_case_ ( self: Optional[int] ): '''simple docstring''' if self.task == "multiple-choice": __UpperCamelCase = {0: 'batch', 1: 'choice', 2: 'sequence'} else: __UpperCamelCase = {0: 'batch', 1: 'sequence'} return OrderedDict( [ ('input_ids', dynamic_axis), ('attention_mask', dynamic_axis), ('token_type_ids', dynamic_axis), ] )

import argparse import re import torch from CLAP import create_model from transformers import AutoFeatureExtractor, ClapConfig, ClapModel a_ :Tuple = { 'text_branch': 'text_model', 'audio_branch': 'audio_model.audio_encoder', 'attn': 'attention.self', 'self.proj': 'output.dense', 'attention.self_mask': 'attn_mask', 'mlp.fc1': 'intermediate.dense', 'mlp.fc2': 'output.dense', 'norm1': 'layernorm_before', 'norm2': 'layernorm_after', 'bn0': 'batch_norm', } a_ :List[str] = AutoFeatureExtractor.from_pretrained('laion/clap-htsat-unfused', truncation='rand_trunc') def a ( A__ , A__=False ) -> List[str]: '''simple docstring''' SCREAMING_SNAKE_CASE__ , SCREAMING_SNAKE_CASE__ : Optional[int] = create_model( '''HTSAT-tiny''' , '''roberta''' , A__ , precision='''fp32''' , device='''cuda:0''' if torch.cuda.is_available() else '''cpu''' , enable_fusion=A__ , fusion_type='''aff_2d''' if enable_fusion else None , ) return model, model_cfg def a ( A__ ) -> Union[str, Any]: '''simple docstring''' SCREAMING_SNAKE_CASE__ : Dict = {} SCREAMING_SNAKE_CASE__ : Optional[int] = r'''.*sequential.(\d+).*''' SCREAMING_SNAKE_CASE__ : Any = r'''.*_projection.(\d+).*''' for key, value in state_dict.items(): # check if any key needs to be modified for key_to_modify, new_key in KEYS_TO_MODIFY_MAPPING.items(): if key_to_modify in key: SCREAMING_SNAKE_CASE__ : Dict = key.replace(A__ , A__ ) if re.match(A__ , A__ ): # replace sequential layers with list SCREAMING_SNAKE_CASE__ : Union[str, Any] = re.match(A__ , A__ ).group(1 ) SCREAMING_SNAKE_CASE__ : Optional[Any] = key.replace(f"""sequential.{sequential_layer}.""" , f"""layers.{int(A__ )//3}.linear.""" ) elif re.match(A__ , A__ ): SCREAMING_SNAKE_CASE__ : Optional[int] = int(re.match(A__ , A__ ).group(1 ) ) # Because in CLAP they use `nn.Sequential`... SCREAMING_SNAKE_CASE__ : Optional[int] = 1 if projecton_layer == 0 else 2 SCREAMING_SNAKE_CASE__ : Optional[int] = key.replace(f"""_projection.{projecton_layer}.""" , f"""_projection.linear{transformers_projection_layer}.""" ) if "audio" and "qkv" in key: # split qkv into query key and value SCREAMING_SNAKE_CASE__ : Optional[int] = value SCREAMING_SNAKE_CASE__ : Tuple = mixed_qkv.size(0 ) // 3 SCREAMING_SNAKE_CASE__ : Optional[int] = mixed_qkv[:qkv_dim] SCREAMING_SNAKE_CASE__ : Tuple = mixed_qkv[qkv_dim : qkv_dim * 2] SCREAMING_SNAKE_CASE__ : Optional[Any] = mixed_qkv[qkv_dim * 2 :] SCREAMING_SNAKE_CASE__ : str = query_layer SCREAMING_SNAKE_CASE__ : Dict = key_layer SCREAMING_SNAKE_CASE__ : Union[str, Any] = value_layer else: SCREAMING_SNAKE_CASE__ : List[Any] = value return model_state_dict def a ( A__ , A__ , A__ , A__=False ) -> List[Any]: '''simple docstring''' SCREAMING_SNAKE_CASE__ , SCREAMING_SNAKE_CASE__ : str = init_clap(A__ , enable_fusion=A__ ) clap_model.eval() SCREAMING_SNAKE_CASE__ : int = clap_model.state_dict() SCREAMING_SNAKE_CASE__ : Optional[Any] = rename_state_dict(A__ ) SCREAMING_SNAKE_CASE__ : str = ClapConfig() SCREAMING_SNAKE_CASE__ : List[Any] = enable_fusion SCREAMING_SNAKE_CASE__ : List[Any] = ClapModel(A__ ) # ignore the spectrogram embedding layer model.load_state_dict(A__ , strict=A__ ) model.save_pretrained(A__ ) transformers_config.save_pretrained(A__ ) if __name__ == "__main__": a_ :List[Any] = argparse.ArgumentParser() parser.add_argument('--pytorch_dump_folder_path', default=None, type=str, help='Path to the output PyTorch model.') parser.add_argument('--checkpoint_path', default=None, type=str, help='Path to fairseq checkpoint') parser.add_argument('--config_path', default=None, type=str, help='Path to hf config.json of model to convert') parser.add_argument('--enable_fusion', action='store_true', help='Whether to enable fusion or not') a_ :Any = parser.parse_args() convert_clap_checkpoint(args.checkpoint_path, args.pytorch_dump_folder_path, args.config_path, args.enable_fusion)

def _A ( _lowercase ) -> int: """simple docstring""" assert column_title.isupper() __UpperCamelCase = 0 __UpperCamelCase = len(_lowercase ) - 1 __UpperCamelCase = 0 while index >= 0: __UpperCamelCase = (ord(column_title[index] ) - 64) * pow(26 , _lowercase ) answer += value power += 1 index -= 1 return answer if __name__ == "__main__": from doctest import testmod testmod()

import argparse import numpy as np import torch from transformers import SpeechTaHifiGan, SpeechTaHifiGanConfig, logging logging.set_verbosity_info() __lowercase : Tuple = logging.get_logger('''transformers.models.speecht5''') def lowercase ( __A : Dict , __A : Union[str, Any] , __A : int ) -> Any: '''simple docstring''' hf_model.apply_weight_norm() snake_case : Any = checkpoint["""input_conv.weight_g"""] snake_case : Any = checkpoint["""input_conv.weight_v"""] snake_case : Optional[Any] = checkpoint["""input_conv.bias"""] for i in range(len(config.upsample_rates ) ): snake_case : Optional[Any] = checkpoint[f"""upsamples.{i}.1.weight_g"""] snake_case : List[str] = checkpoint[f"""upsamples.{i}.1.weight_v"""] snake_case : Any = checkpoint[f"""upsamples.{i}.1.bias"""] for i in range(len(config.upsample_rates ) * len(config.resblock_kernel_sizes ) ): for j in range(len(config.resblock_dilation_sizes ) ): snake_case : Any = checkpoint[f"""blocks.{i}.convs1.{j}.1.weight_g"""] snake_case : Union[str, Any] = checkpoint[f"""blocks.{i}.convs1.{j}.1.weight_v"""] snake_case : str = checkpoint[f"""blocks.{i}.convs1.{j}.1.bias"""] snake_case : Any = checkpoint[f"""blocks.{i}.convs2.{j}.1.weight_g"""] snake_case : List[Any] = checkpoint[f"""blocks.{i}.convs2.{j}.1.weight_v"""] snake_case : str = checkpoint[f"""blocks.{i}.convs2.{j}.1.bias"""] snake_case : Union[str, Any] = checkpoint["""output_conv.1.weight_g"""] snake_case : Tuple = checkpoint["""output_conv.1.weight_v"""] snake_case : Dict = checkpoint["""output_conv.1.bias"""] hf_model.remove_weight_norm() @torch.no_grad() def lowercase ( __A : List[Any] , __A : Optional[Any] , __A : List[str] , __A : Optional[Any]=None , __A : List[str]=None , ) -> str: '''simple docstring''' if config_path is not None: snake_case : str = SpeechTaHifiGanConfig.from_pretrained(__A ) else: snake_case : Tuple = SpeechTaHifiGanConfig() snake_case : Optional[Any] = SpeechTaHifiGan(__A ) snake_case : str = torch.load(__A ) load_weights(orig_checkpoint["""model"""]["""generator"""] , __A , __A ) snake_case : List[Any] = np.load(__A ) snake_case : Tuple = stats[0].reshape(-1 ) snake_case : str = stats[1].reshape(-1 ) snake_case : Optional[int] = torch.from_numpy(__A ).float() snake_case : Tuple = torch.from_numpy(__A ).float() model.save_pretrained(__A ) if repo_id: print("""Pushing to the hub...""" ) model.push_to_hub(__A ) if __name__ == "__main__": __lowercase : str = argparse.ArgumentParser() parser.add_argument('''--checkpoint_path''', required=True, default=None, type=str, help='''Path to original checkpoint''') parser.add_argument('''--stats_path''', required=True, default=None, type=str, help='''Path to stats.npy file''') parser.add_argument('''--config_path''', default=None, type=str, help='''Path to hf config.json of model to convert''') parser.add_argument( '''--pytorch_dump_folder_path''', required=True, default=None, type=str, help='''Path to the output PyTorch model.''' ) parser.add_argument( '''--push_to_hub''', default=None, type=str, help='''Where to upload the converted model on the 🤗 hub.''' ) __lowercase : List[str] = parser.parse_args() convert_hifigan_checkpoint( args.checkpoint_path, args.stats_path, args.pytorch_dump_folder_path, args.config_path, args.push_to_hub, )

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 from lavis.models import load_model_and_preprocess from PIL import Image from transformers import ( AutoTokenizer, BlipaConfig, BlipaForConditionalGeneration, BlipaProcessor, BlipaVisionConfig, BlipImageProcessor, OPTConfig, TaConfig, ) from transformers.utils.constants import OPENAI_CLIP_MEAN, OPENAI_CLIP_STD def _A ( ) -> int: """simple docstring""" __UpperCamelCase = 'https://storage.googleapis.com/sfr-vision-language-research/LAVIS/assets/merlion.png' __UpperCamelCase = Image.open(requests.get(_lowercase , stream=_lowercase ).raw ).convert('RGB' ) return image def _A ( _lowercase ) -> int: """simple docstring""" __UpperCamelCase = [] # 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.layernorm.weight') ) rename_keys.append(('Qformer.bert.embeddings.LayerNorm.bias', 'qformer.layernorm.bias') ) # fmt: on return rename_keys def _A ( _lowercase , _lowercase , _lowercase ) -> Optional[int]: """simple docstring""" __UpperCamelCase = dct.pop(_lowercase ) __UpperCamelCase = val def _A ( _lowercase , _lowercase ) -> int: """simple docstring""" for i in range(config.vision_config.num_hidden_layers ): # read in original q and v biases __UpperCamelCase = state_dict.pop(f'''visual_encoder.blocks.{i}.attn.q_bias''' ) __UpperCamelCase = state_dict.pop(f'''visual_encoder.blocks.{i}.attn.v_bias''' ) # next, set bias in the state dict __UpperCamelCase = torch.cat((q_bias, torch.zeros_like(_lowercase , requires_grad=_lowercase ), v_bias) ) __UpperCamelCase = qkv_bias def _A ( _lowercase , _lowercase ) -> Any: """simple docstring""" __UpperCamelCase = 3_64 if 'coco' in model_name else 2_24 __UpperCamelCase = BlipaVisionConfig(image_size=_lowercase ).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 "opt-2.7b" in model_name: __UpperCamelCase = OPTConfig.from_pretrained('facebook/opt-2.7b' , eos_token_id=_lowercase ).to_dict() elif "opt-6.7b" in model_name: __UpperCamelCase = OPTConfig.from_pretrained('facebook/opt-6.7b' , eos_token_id=_lowercase ).to_dict() elif "t5-xl" in model_name: __UpperCamelCase = TaConfig.from_pretrained('google/flan-t5-xl' , dense_act_fn='gelu' , bos_token_id=1 ).to_dict() elif "t5-xxl" in model_name: __UpperCamelCase = TaConfig.from_pretrained('google/flan-t5-xxl' , dense_act_fn='gelu' , bos_token_id=1 ).to_dict() __UpperCamelCase = BlipaConfig(vision_config=_lowercase , text_config=_lowercase ) return config, image_size @torch.no_grad() def _A ( _lowercase , _lowercase=None , _lowercase=False ) -> Union[str, Any]: """simple docstring""" __UpperCamelCase = ( AutoTokenizer.from_pretrained('facebook/opt-2.7b' ) if 'opt' in model_name else AutoTokenizer.from_pretrained('google/flan-t5-xl' ) ) __UpperCamelCase = tokenizer('\n' , add_special_tokens=_lowercase ).input_ids[0] __UpperCamelCase, __UpperCamelCase = get_blipa_config(_lowercase , eos_token_id=_lowercase ) __UpperCamelCase = BlipaForConditionalGeneration(_lowercase ).eval() __UpperCamelCase = { 'blip2-opt-2.7b': ('blip2_opt', 'pretrain_opt2.7b'), 'blip2-opt-6.7b': ('blip2_opt', 'pretrain_opt6.7b'), 'blip2-opt-2.7b-coco': ('blip2_opt', 'caption_coco_opt2.7b'), 'blip2-opt-6.7b-coco': ('blip2_opt', 'caption_coco_opt6.7b'), 'blip2-flan-t5-xl': ('blip2_t5', 'pretrain_flant5xl'), 'blip2-flan-t5-xl-coco': ('blip2_t5', 'caption_coco_flant5xl'), 'blip2-flan-t5-xxl': ('blip2_t5', 'pretrain_flant5xxl'), } __UpperCamelCase, __UpperCamelCase = model_name_to_original[model_name] # load original model print('Loading original model...' ) __UpperCamelCase = 'cuda' if torch.cuda.is_available() else 'cpu' __UpperCamelCase, __UpperCamelCase, __UpperCamelCase = load_model_and_preprocess( name=_lowercase , model_type=_lowercase , is_eval=_lowercase , device=_lowercase ) original_model.eval() print('Done!' ) # update state dict keys __UpperCamelCase = original_model.state_dict() __UpperCamelCase = create_rename_keys(_lowercase ) for src, dest in rename_keys: rename_key(_lowercase , _lowercase , _lowercase ) # some keys can be renamed efficiently for key, val in state_dict.copy().items(): __UpperCamelCase = state_dict.pop(_lowercase ) if key.startswith('Qformer.bert' ): __UpperCamelCase = key.replace('Qformer.bert' , 'qformer' ) if "attention.self" in key: __UpperCamelCase = key.replace('self' , 'attention' ) if "opt_proj" in key: __UpperCamelCase = key.replace('opt_proj' , 'language_projection' ) if "t5_proj" in key: __UpperCamelCase = key.replace('t5_proj' , 'language_projection' ) if key.startswith('opt' ): __UpperCamelCase = key.replace('opt' , 'language' ) if key.startswith('t5' ): __UpperCamelCase = key.replace('t5' , 'language' ) __UpperCamelCase = val # read in qv biases read_in_q_v_bias(_lowercase , _lowercase ) __UpperCamelCase, __UpperCamelCase = hf_model.load_state_dict(_lowercase , strict=_lowercase ) assert len(_lowercase ) == 0 assert unexpected_keys == ["qformer.embeddings.position_ids"] __UpperCamelCase = load_demo_image() __UpperCamelCase = vis_processors['eval'](_lowercase ).unsqueeze(0 ).to(_lowercase ) __UpperCamelCase = tokenizer(['\n'] , return_tensors='pt' ).input_ids.to(_lowercase ) # create processor __UpperCamelCase = BlipImageProcessor( size={'height': image_size, 'width': image_size} , image_mean=_lowercase , image_std=_lowercase ) __UpperCamelCase = BlipaProcessor(image_processor=_lowercase , tokenizer=_lowercase ) __UpperCamelCase = processor(images=_lowercase , return_tensors='pt' ).pixel_values.to(_lowercase ) # make sure processor creates exact same pixel values assert torch.allclose(_lowercase , _lowercase ) original_model.to(_lowercase ) hf_model.to(_lowercase ) with torch.no_grad(): if "opt" in model_name: __UpperCamelCase = original_model({'image': original_pixel_values, 'text_input': ['']} ).logits __UpperCamelCase = hf_model(_lowercase , _lowercase ).logits else: __UpperCamelCase = original_model( {'image': original_pixel_values, 'text_input': ['\n'], 'text_output': ['\n']} ).logits __UpperCamelCase = input_ids.masked_fill(input_ids == tokenizer.pad_token_id , -1_00 ) __UpperCamelCase = hf_model(_lowercase , _lowercase , labels=_lowercase ).logits assert original_logits.shape == logits.shape print('First values of original logits:' , original_logits[0, :3, :3] ) print('First values of HF logits:' , logits[0, :3, :3] ) # assert values if model_name == "blip2-flan-t5-xl": __UpperCamelCase = torch.tensor( [[-41.58_50, -4.44_40, -8.99_22], [-47.43_22, -5.91_43, -1.73_40]] , device=_lowercase ) assert torch.allclose(logits[0, :3, :3] , _lowercase , atol=1e-4 ) elif model_name == "blip2-flan-t5-xl-coco": __UpperCamelCase = torch.tensor( [[-57.01_09, -9.89_67, -12.62_80], [-68.65_78, -12.71_91, -10.50_65]] , device=_lowercase ) else: # cast to same type __UpperCamelCase = logits.dtype assert torch.allclose(original_logits.to(_lowercase ) , _lowercase , atol=1e-2 ) print('Looks ok!' ) print('Generating a caption...' ) __UpperCamelCase = '' __UpperCamelCase = tokenizer(_lowercase , return_tensors='pt' ).input_ids.to(_lowercase ) __UpperCamelCase = original_model.generate({'image': original_pixel_values} ) __UpperCamelCase = hf_model.generate( _lowercase , _lowercase , do_sample=_lowercase , num_beams=5 , max_length=30 , min_length=1 , top_p=0.9 , repetition_penalty=1.0 , length_penalty=1.0 , temperature=1 , ) print('Original generation:' , _lowercase ) __UpperCamelCase = input_ids.shape[1] __UpperCamelCase = processor.batch_decode(outputs[:, prompt_length:] , skip_special_tokens=_lowercase ) __UpperCamelCase = [text.strip() for text in output_text] print('HF generation:' , _lowercase ) if pytorch_dump_folder_path is not None: processor.save_pretrained(_lowercase ) hf_model.save_pretrained(_lowercase ) if push_to_hub: processor.push_to_hub(f'''nielsr/{model_name}''' ) hf_model.push_to_hub(f'''nielsr/{model_name}''' ) if __name__ == "__main__": __snake_case = argparse.ArgumentParser() __snake_case = [ '''blip2-opt-2.7b''', '''blip2-opt-6.7b''', '''blip2-opt-2.7b-coco''', '''blip2-opt-6.7b-coco''', '''blip2-flan-t5-xl''', '''blip2-flan-t5-xl-coco''', '''blip2-flan-t5-xxl''', ] parser.add_argument( '''--model_name''', default='''blip2-opt-2.7b''', 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)

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 UpperCamelCase : List[str] = logging.get_logger(__name__) UpperCamelCase : Any = {"""vocab_file""": """vocab.json""", """merges_file""": """merges.txt""", """tokenizer_file""": """tokenizer.json"""} UpperCamelCase : str = { """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""", }, } UpperCamelCase : Optional[int] = { """gpt2""": 1024, """gpt2-medium""": 1024, """gpt2-large""": 1024, """gpt2-xl""": 1024, """distilgpt2""": 1024, } class A__ ( A__ ): """simple docstring""" _lowercase = VOCAB_FILES_NAMES _lowercase = PRETRAINED_VOCAB_FILES_MAP _lowercase = PRETRAINED_POSITIONAL_EMBEDDINGS_SIZES _lowercase = ['input_ids', 'attention_mask'] _lowercase = GPTaTokenizer def __init__( self : Optional[Any] , lowerCamelCase__ : List[str]=None , lowerCamelCase__ : Union[str, Any]=None , lowerCamelCase__ : Optional[int]=None , lowerCamelCase__ : Any="<|endoftext|>" , lowerCamelCase__ : Dict="<|endoftext|>" , lowerCamelCase__ : Tuple="<|endoftext|>" , lowerCamelCase__ : str=False , **lowerCamelCase__ : Any , ): super().__init__( lowerCamelCase__ , lowerCamelCase__ , tokenizer_file=lowerCamelCase__ , unk_token=lowerCamelCase__ , bos_token=lowerCamelCase__ , eos_token=lowerCamelCase__ , add_prefix_space=lowerCamelCase__ , **lowerCamelCase__ , ) a__ : Dict = kwargs.pop("add_bos_token" , lowerCamelCase__ ) a__ : Dict = json.loads(self.backend_tokenizer.pre_tokenizer.__getstate__() ) if pre_tok_state.get("add_prefix_space" , lowerCamelCase__ ) != add_prefix_space: a__ : Optional[int] = getattr(lowerCamelCase__ , pre_tok_state.pop("type" ) ) a__ : List[str] = add_prefix_space a__ : Union[str, Any] = pre_tok_class(**lowerCamelCase__ ) a__ : int = add_prefix_space def _UpperCamelCase( self : Union[str, Any] , *lowerCamelCase__ : Union[str, Any] , **lowerCamelCase__ : Optional[int] ): a__ : str = kwargs.get("is_split_into_words" , lowerCamelCase__ ) 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(*lowerCamelCase__ , **lowerCamelCase__ ) def _UpperCamelCase( self : Optional[Any] , *lowerCamelCase__ : int , **lowerCamelCase__ : Optional[Any] ): a__ : Any = kwargs.get("is_split_into_words" , lowerCamelCase__ ) 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(*lowerCamelCase__ , **lowerCamelCase__ ) def _UpperCamelCase( self : Optional[Any] , lowerCamelCase__ : str , lowerCamelCase__ : Optional[str] = None ): a__ : List[str] = self._tokenizer.model.save(lowerCamelCase__ , name=lowerCamelCase__ ) return tuple(lowerCamelCase__ ) def _UpperCamelCase( self : Any , lowerCamelCase__ : "Conversation" ): a__ : Tuple = [] for is_user, text in conversation.iter_texts(): input_ids.extend(self.encode(lowerCamelCase__ , add_special_tokens=lowerCamelCase__ ) + [self.eos_token_id] ) if len(lowerCamelCase__ ) > self.model_max_length: a__ : Optional[int] = input_ids[-self.model_max_length :] return input_ids

import logging import os import sys from dataclasses import dataclass, field from importlib import import_module from typing import Dict, List, Optional, Tuple import numpy as np from seqeval.metrics import accuracy_score, fa_score, precision_score, recall_score from torch import nn from utils_ner import Split, TokenClassificationDataset, TokenClassificationTask import transformers from transformers import ( AutoConfig, AutoModelForTokenClassification, AutoTokenizer, DataCollatorWithPadding, EvalPrediction, HfArgumentParser, Trainer, TrainingArguments, set_seed, ) from transformers.trainer_utils import is_main_process __snake_case = logging.getLogger(__name__) @dataclass class __lowerCamelCase : _lowercase = field( metadata={"""help""": """Path to pretrained model or model identifier from huggingface.co/models"""} ) _lowercase = field( default=_a , metadata={"""help""": """Pretrained config name or path if not the same as model_name"""} ) _lowercase = field( default="""NER""" , metadata={"""help""": """Task type to fine tune in training (e.g. NER, POS, etc)"""} ) _lowercase = field( default=_a , metadata={"""help""": """Pretrained tokenizer name or path if not the same as model_name"""} ) _lowercase = field(default=_a , metadata={"""help""": """Set this flag to use fast tokenization."""} ) # If you want to tweak more attributes on your tokenizer, you should do it in a distinct script, # or just modify its tokenizer_config.json. _lowercase = field( default=_a , metadata={"""help""": """Where do you want to store the pretrained models downloaded from huggingface.co"""} , ) @dataclass class __lowerCamelCase : _lowercase = field( metadata={"""help""": """The input data dir. Should contain the .txt files for a CoNLL-2003-formatted task."""} ) _lowercase = field( default=_a , metadata={"""help""": """Path to a file containing all labels. If not specified, CoNLL-2003 labels are used."""} , ) _lowercase = field( default=128 , metadata={ """help""": ( """The maximum total input sequence length after tokenization. Sequences longer """ """than this will be truncated, sequences shorter will be padded.""" ) } , ) _lowercase = field( default=_a , metadata={"""help""": """Overwrite the cached training and evaluation sets"""} ) def _A ( ) -> str: """simple docstring""" __UpperCamelCase = HfArgumentParser((ModelArguments, DataTrainingArguments, TrainingArguments) ) if len(sys.argv ) == 2 and sys.argv[1].endswith('.json' ): # If we pass only one argument to the script and it's the path to a json file, # let's parse it to get our arguments. __UpperCamelCase, __UpperCamelCase, __UpperCamelCase = parser.parse_json_file(json_file=os.path.abspath(sys.argv[1] ) ) else: __UpperCamelCase, __UpperCamelCase, __UpperCamelCase = parser.parse_args_into_dataclasses() if ( os.path.exists(training_args.output_dir ) and os.listdir(training_args.output_dir ) and training_args.do_train and not training_args.overwrite_output_dir ): raise ValueError( f'''Output directory ({training_args.output_dir}) already exists and is not empty. Use''' ' --overwrite_output_dir to overcome.' ) __UpperCamelCase = import_module('tasks' ) try: __UpperCamelCase = getattr(_lowercase , model_args.task_type ) __UpperCamelCase = token_classification_task_clazz() except AttributeError: raise ValueError( f'''Task {model_args.task_type} needs to be defined as a TokenClassificationTask subclass in {module}. ''' f'''Available tasks classes are: {TokenClassificationTask.__subclasses__()}''' ) # Setup logging logging.basicConfig( format='%(asctime)s - %(levelname)s - %(name)s - %(message)s' , datefmt='%m/%d/%Y %H:%M:%S' , level=logging.INFO if training_args.local_rank in [-1, 0] else logging.WARN , ) logger.warning( 'Process rank: %s, device: %s, n_gpu: %s, distributed training: %s, 16-bits training: %s' , training_args.local_rank , training_args.device , training_args.n_gpu , bool(training_args.local_rank != -1 ) , training_args.fpaa , ) # Set the verbosity to info of the Transformers logger (on main process only): if is_main_process(training_args.local_rank ): transformers.utils.logging.set_verbosity_info() transformers.utils.logging.enable_default_handler() transformers.utils.logging.enable_explicit_format() logger.info('Training/evaluation parameters %s' , _lowercase ) # Set seed set_seed(training_args.seed ) # Prepare CONLL-2003 task __UpperCamelCase = token_classification_task.get_labels(data_args.labels ) __UpperCamelCase = dict(enumerate(_lowercase ) ) __UpperCamelCase = len(_lowercase ) # Load pretrained model and tokenizer # # Distributed training: # The .from_pretrained methods guarantee that only one local process can concurrently # download model & vocab. __UpperCamelCase = AutoConfig.from_pretrained( model_args.config_name if model_args.config_name else model_args.model_name_or_path , num_labels=_lowercase , idalabel=_lowercase , labelaid={label: i for i, label in enumerate(_lowercase )} , cache_dir=model_args.cache_dir , ) __UpperCamelCase = AutoTokenizer.from_pretrained( model_args.tokenizer_name if model_args.tokenizer_name else model_args.model_name_or_path , cache_dir=model_args.cache_dir , use_fast=model_args.use_fast , ) __UpperCamelCase = AutoModelForTokenClassification.from_pretrained( model_args.model_name_or_path , from_tf=bool('.ckpt' in model_args.model_name_or_path ) , config=_lowercase , cache_dir=model_args.cache_dir , ) # Get datasets __UpperCamelCase = ( TokenClassificationDataset( token_classification_task=_lowercase , data_dir=data_args.data_dir , tokenizer=_lowercase , labels=_lowercase , model_type=config.model_type , max_seq_length=data_args.max_seq_length , overwrite_cache=data_args.overwrite_cache , mode=Split.train , ) if training_args.do_train else None ) __UpperCamelCase = ( TokenClassificationDataset( token_classification_task=_lowercase , data_dir=data_args.data_dir , tokenizer=_lowercase , labels=_lowercase , model_type=config.model_type , max_seq_length=data_args.max_seq_length , overwrite_cache=data_args.overwrite_cache , mode=Split.dev , ) if training_args.do_eval else None ) def align_predictions(_lowercase , _lowercase ) -> Tuple[List[int], List[int]]: __UpperCamelCase = np.argmax(_lowercase , axis=2 ) __UpperCamelCase, __UpperCamelCase = preds.shape __UpperCamelCase = [[] for _ in range(_lowercase )] __UpperCamelCase = [[] for _ in range(_lowercase )] for i in range(_lowercase ): for j in range(_lowercase ): if label_ids[i, j] != nn.CrossEntropyLoss().ignore_index: out_label_list[i].append(label_map[label_ids[i][j]] ) preds_list[i].append(label_map[preds[i][j]] ) return preds_list, out_label_list def compute_metrics(_lowercase ) -> Dict: __UpperCamelCase, __UpperCamelCase = align_predictions(p.predictions , p.label_ids ) return { "accuracy_score": accuracy_score(_lowercase , _lowercase ), "precision": precision_score(_lowercase , _lowercase ), "recall": recall_score(_lowercase , _lowercase ), "f1": fa_score(_lowercase , _lowercase ), } # Data collator __UpperCamelCase = DataCollatorWithPadding(_lowercase , pad_to_multiple_of=8 ) if training_args.fpaa else None # Initialize our Trainer __UpperCamelCase = Trainer( model=_lowercase , args=_lowercase , train_dataset=_lowercase , eval_dataset=_lowercase , compute_metrics=_lowercase , data_collator=_lowercase , ) # Training if training_args.do_train: trainer.train( model_path=model_args.model_name_or_path if os.path.isdir(model_args.model_name_or_path ) else None ) trainer.save_model() # For convenience, we also re-save the tokenizer to the same directory, # so that you can share your model easily on huggingface.co/models =) if trainer.is_world_process_zero(): tokenizer.save_pretrained(training_args.output_dir ) # Evaluation __UpperCamelCase = {} if training_args.do_eval: logger.info('*** Evaluate ***' ) __UpperCamelCase = trainer.evaluate() __UpperCamelCase = os.path.join(training_args.output_dir , 'eval_results.txt' ) if trainer.is_world_process_zero(): with open(_lowercase , 'w' ) as writer: logger.info('***** Eval results *****' ) for key, value in result.items(): logger.info(' %s = %s' , _lowercase , _lowercase ) writer.write('%s = %s\n' % (key, value) ) results.update(_lowercase ) # Predict if training_args.do_predict: __UpperCamelCase = TokenClassificationDataset( token_classification_task=_lowercase , data_dir=data_args.data_dir , tokenizer=_lowercase , labels=_lowercase , model_type=config.model_type , max_seq_length=data_args.max_seq_length , overwrite_cache=data_args.overwrite_cache , mode=Split.test , ) __UpperCamelCase, __UpperCamelCase, __UpperCamelCase = trainer.predict(_lowercase ) __UpperCamelCase, __UpperCamelCase = align_predictions(_lowercase , _lowercase ) __UpperCamelCase = os.path.join(training_args.output_dir , 'test_results.txt' ) if trainer.is_world_process_zero(): with open(_lowercase , 'w' ) as writer: for key, value in metrics.items(): logger.info(' %s = %s' , _lowercase , _lowercase ) writer.write('%s = %s\n' % (key, value) ) # Save predictions __UpperCamelCase = os.path.join(training_args.output_dir , 'test_predictions.txt' ) if trainer.is_world_process_zero(): with open(_lowercase , 'w' ) as writer: with open(os.path.join(data_args.data_dir , 'test.txt' ) , 'r' ) as f: token_classification_task.write_predictions_to_file(_lowercase , _lowercase , _lowercase ) return results def _A ( _lowercase ) -> Dict: """simple docstring""" main() if __name__ == "__main__": main()

'''simple docstring''' def UpperCamelCase__ ( __magic_name__ : str , __magic_name__ : list[str] ) -> str: '''simple docstring''' snake_case__ : List[Any] = """""" for word_or_phrase in separated: if not isinstance(__magic_name__ , __magic_name__ ): raise Exception("""join() accepts only strings to be joined""" ) joined += word_or_phrase + separator return joined.strip(__magic_name__ ) if __name__ == "__main__": from doctest import testmod testmod()

# # This a `torch.distributed` diagnostics script that checks that all GPUs in the cluster (one or # many nodes) can talk to each other via nccl and allocate gpu memory. # # To run first adjust the number of processes and nodes: # # python -m torch.distributed.run --nproc_per_node 2 --nnodes 1 torch-distributed-gpu-test.py # # You may need to add --master_addr $MASTER_ADDR --master_port $MASTER_PORT if using a custom addr:port # # You can also use the rdzv API: --rdzv_endpoint $MASTER_ADDR:$MASTER_PORT --rdzv_backend c10d # # use torch.distributed.launch instead of torch.distributed.run for torch < 1.9 # # If you get a hanging in `barrier` calls you have some network issues, you may try to debug this with: # # NCCL_DEBUG=INFO python -m torch.distributed.run --nproc_per_node 2 --nnodes 1 torch-distributed-gpu-test.py # # which should tell you what's going on behind the scenes. # # # This script can be run via `srun` in the SLURM environment as well. Here is a SLURM script that # runs on 2 nodes of 4 gpus per node: # # #SBATCH --job-name=test-nodes # name # #SBATCH --nodes=2 # nodes # #SBATCH --ntasks-per-node=1 # crucial - only 1 task per dist per node! # #SBATCH --cpus-per-task=10 # number of cores per tasks # #SBATCH --gres=gpu:4 # number of gpus # #SBATCH --time 0:05:00 # maximum execution time (HH:MM:SS) # #SBATCH --output=%x-%j.out # output file name # # GPUS_PER_NODE=4 # MASTER_ADDR=$(scontrol show hostnames $SLURM_JOB_NODELIST | head -n 1) # MASTER_PORT=6000 # # srun --jobid $SLURM_JOBID bash -c 'python -m torch.distributed.run \ # --nproc_per_node $GPUS_PER_NODE --nnodes $SLURM_NNODES --node_rank $SLURM_PROCID \ # --master_addr $MASTER_ADDR --master_port $MASTER_PORT \ # torch-distributed-gpu-test.py' # import fcntl import os import socket import torch import torch.distributed as dist def _A ( *_lowercase ) -> Tuple: """simple docstring""" with open(_lowercase , 'r' ) as fh: fcntl.flock(_lowercase , fcntl.LOCK_EX ) try: print(*_lowercase ) finally: fcntl.flock(_lowercase , fcntl.LOCK_UN ) __snake_case = int(os.environ['''LOCAL_RANK''']) torch.cuda.set_device(local_rank) __snake_case = torch.device('''cuda''', local_rank) __snake_case = socket.gethostname() __snake_case = f"""[{hostname}-{local_rank}]""" try: # test distributed dist.init_process_group('''nccl''') dist.all_reduce(torch.ones(1).to(device), op=dist.ReduceOp.SUM) dist.barrier() # test cuda is available and can allocate memory torch.cuda.is_available() torch.ones(1).cuda(local_rank) # global rank __snake_case = dist.get_rank() __snake_case = dist.get_world_size() printflock(f"""{gpu} is OK (global rank: {rank}/{world_size})""") dist.barrier() if rank == 0: printflock(f"""pt={torch.__version__}, cuda={torch.version.cuda}, nccl={torch.cuda.nccl.version()}""") except Exception: printflock(f"""{gpu} is broken""") raise

from __future__ import annotations def __SCREAMING_SNAKE_CASE (SCREAMING_SNAKE_CASE__ ): snake_case_ = len(SCREAMING_SNAKE_CASE__ ) // 2 # choose the middle 3 elements snake_case_ = lst[m - 1 : m + 2] # if middle element is peak if three[1] > three[0] and three[1] > three[2]: return three[1] # if increasing, recurse on right elif three[0] < three[2]: if len(lst[:m] ) == 2: m -= 1 return peak(lst[m:] ) # decreasing else: if len(lst[:m] ) == 2: m += 1 return peak(lst[:m] ) if __name__ == "__main__": import doctest doctest.testmod()

import pytest import datasets # Import fixture modules as plugins __snake_case = ['''tests.fixtures.files''', '''tests.fixtures.hub''', '''tests.fixtures.fsspec'''] def _A ( _lowercase , _lowercase ) -> Tuple: """simple docstring""" for item in items: if any(marker in item.keywords for marker in ['integration', 'unit'] ): continue item.add_marker(pytest.mark.unit ) def _A ( _lowercase ) -> str: """simple docstring""" config.addinivalue_line('markers' , 'torchaudio_latest: mark test to run with torchaudio>=0.12' ) @pytest.fixture(autouse=_lowercase ) def _A ( _lowercase , _lowercase ) -> Any: """simple docstring""" __UpperCamelCase = tmp_path_factory.getbasetemp() / 'cache' __UpperCamelCase = test_hf_cache_home / 'datasets' __UpperCamelCase = test_hf_cache_home / 'metrics' __UpperCamelCase = test_hf_cache_home / 'modules' monkeypatch.setattr('datasets.config.HF_DATASETS_CACHE' , str(_lowercase ) ) monkeypatch.setattr('datasets.config.HF_METRICS_CACHE' , str(_lowercase ) ) monkeypatch.setattr('datasets.config.HF_MODULES_CACHE' , str(_lowercase ) ) __UpperCamelCase = test_hf_datasets_cache / 'downloads' monkeypatch.setattr('datasets.config.DOWNLOADED_DATASETS_PATH' , str(_lowercase ) ) __UpperCamelCase = test_hf_datasets_cache / 'downloads' / 'extracted' monkeypatch.setattr('datasets.config.EXTRACTED_DATASETS_PATH' , str(_lowercase ) ) @pytest.fixture(autouse=_lowercase , scope='session' ) def _A ( ) -> Dict: """simple docstring""" datasets.disable_progress_bar() @pytest.fixture(autouse=_lowercase ) def _A ( _lowercase ) -> Tuple: """simple docstring""" monkeypatch.setattr('datasets.config.HF_UPDATE_DOWNLOAD_COUNTS' , _lowercase ) @pytest.fixture def _A ( _lowercase ) -> Any: """simple docstring""" monkeypatch.setattr('sqlalchemy.util.deprecations.SILENCE_UBER_WARNING' , _lowercase )

from __future__ import annotations import math import numpy as np from numpy.linalg import norm def UpperCamelCase ( snake_case__ : np.ndarray , snake_case__ : np.ndarray ) -> float: return math.sqrt(sum(pow(a - b , 2 ) for a, b in zip(snake_case__ , snake_case__ ) ) ) def UpperCamelCase ( snake_case__ : np.ndarray , snake_case__ : np.ndarray ) -> list[list[list[float] | float]]: if dataset.ndim != value_array.ndim: UpperCamelCase : int = ( 'Wrong input data\'s dimensions... ' F"""dataset : {dataset.ndim}, value_array : {value_array.ndim}""" ) raise ValueError(snake_case__ ) try: if dataset.shape[1] != value_array.shape[1]: UpperCamelCase : str = ( 'Wrong input data\'s shape... ' F"""dataset : {dataset.shape[1]}, value_array : {value_array.shape[1]}""" ) raise ValueError(snake_case__ ) except IndexError: if dataset.ndim != value_array.ndim: raise TypeError('Wrong shape' ) if dataset.dtype != value_array.dtype: UpperCamelCase : Dict = ( 'Input data have different datatype... ' F"""dataset : {dataset.dtype}, value_array : {value_array.dtype}""" ) raise TypeError(snake_case__ ) UpperCamelCase : List[Any] = [] for value in value_array: UpperCamelCase : Optional[Any] = euclidean(snake_case__ , dataset[0] ) UpperCamelCase : Dict = dataset[0].tolist() for dataset_value in dataset[1:]: UpperCamelCase : Union[str, Any] = euclidean(snake_case__ , snake_case__ ) if dist > temp_dist: UpperCamelCase : str = temp_dist UpperCamelCase : List[str] = dataset_value.tolist() answer.append([vector, dist] ) return answer def UpperCamelCase ( snake_case__ : np.ndarray , snake_case__ : np.ndarray ) -> float: return np.dot(snake_case__ , snake_case__ ) / (norm(snake_case__ ) * norm(snake_case__ )) if __name__ == "__main__": import doctest doctest.testmod()

import random import unittest import numpy as np import torch from transformers import CLIPTextConfig, CLIPTextModel, CLIPTokenizer from diffusers import ( AutoencoderKL, DDIMScheduler, UNetaDConditionModel, VideoToVideoSDPipeline, ) from diffusers.utils import floats_tensor, is_xformers_available, skip_mps from diffusers.utils.testing_utils import enable_full_determinism, slow, torch_device from ..pipeline_params import ( TEXT_GUIDED_IMAGE_VARIATION_BATCH_PARAMS, TEXT_GUIDED_IMAGE_VARIATION_PARAMS, ) from ..test_pipelines_common import PipelineTesterMixin enable_full_determinism() @skip_mps class __lowerCamelCase (_a , unittest.TestCase ): _lowercase = VideoToVideoSDPipeline _lowercase = TEXT_GUIDED_IMAGE_VARIATION_PARAMS.union({"""video"""} ) - {"""image""", """width""", """height"""} _lowercase = TEXT_GUIDED_IMAGE_VARIATION_BATCH_PARAMS.union({"""video"""} ) - {"""image"""} _lowercase = PipelineTesterMixin.required_optional_params - {"""latents"""} _lowercase = False # No `output_type`. _lowercase = frozenset( [ """num_inference_steps""", """generator""", """latents""", """return_dict""", """callback""", """callback_steps""", ] ) def snake_case_ ( self: List[str] ): '''simple docstring''' torch.manual_seed(0 ) __UpperCamelCase = UNetaDConditionModel( block_out_channels=(32, 64, 64, 64),layers_per_block=2,sample_size=32,in_channels=4,out_channels=4,down_block_types=('CrossAttnDownBlock3D', 'CrossAttnDownBlock3D', 'CrossAttnDownBlock3D', 'DownBlock3D'),up_block_types=('UpBlock3D', 'CrossAttnUpBlock3D', 'CrossAttnUpBlock3D', 'CrossAttnUpBlock3D'),cross_attention_dim=32,attention_head_dim=4,) __UpperCamelCase = DDIMScheduler( beta_start=0.0_0_0_8_5,beta_end=0.0_1_2,beta_schedule='scaled_linear',clip_sample=A_,set_alpha_to_one=A_,) torch.manual_seed(0 ) __UpperCamelCase = AutoencoderKL( block_out_channels=[32, 64],in_channels=3,out_channels=3,down_block_types=['DownEncoderBlock2D', 'DownEncoderBlock2D'],up_block_types=['UpDecoderBlock2D', 'UpDecoderBlock2D'],latent_channels=4,sample_size=128,) torch.manual_seed(0 ) __UpperCamelCase = 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,) __UpperCamelCase = CLIPTextModel(A_ ) __UpperCamelCase = CLIPTokenizer.from_pretrained('hf-internal-testing/tiny-random-clip' ) __UpperCamelCase = { 'unet': unet, 'scheduler': scheduler, 'vae': vae, 'text_encoder': text_encoder, 'tokenizer': tokenizer, } return components def snake_case_ ( self: Union[str, Any],A_: Any,A_: Any=0 ): '''simple docstring''' __UpperCamelCase = floats_tensor((1, 3, 3, 32, 32),rng=random.Random(A_ ) ).to(A_ ) if str(A_ ).startswith('mps' ): __UpperCamelCase = torch.manual_seed(A_ ) else: __UpperCamelCase = torch.Generator(device=A_ ).manual_seed(A_ ) __UpperCamelCase = { 'prompt': 'A painting of a squirrel eating a burger', 'video': video, 'generator': generator, 'num_inference_steps': 2, 'guidance_scale': 6.0, 'output_type': 'pt', } return inputs def snake_case_ ( self: Union[str, Any] ): '''simple docstring''' __UpperCamelCase = 'cpu' # ensure determinism for the device-dependent torch.Generator __UpperCamelCase = self.get_dummy_components() __UpperCamelCase = VideoToVideoSDPipeline(**A_ ) __UpperCamelCase = sd_pipe.to(A_ ) sd_pipe.set_progress_bar_config(disable=A_ ) __UpperCamelCase = self.get_dummy_inputs(A_ ) __UpperCamelCase = 'np' __UpperCamelCase = sd_pipe(**A_ ).frames __UpperCamelCase = frames[0][-3:, -3:, -1] assert frames[0].shape == (32, 32, 3) __UpperCamelCase = np.array([106, 117, 113, 174, 137, 112, 148, 151, 131] ) assert np.abs(image_slice.flatten() - expected_slice ).max() < 1E-2 @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: Any ): '''simple docstring''' self._test_xformers_attention_forwardGenerator_pass(test_mean_pixel_difference=A_,expected_max_diff=5E-3 ) @unittest.skip(reason='Batching needs to be properly figured out first for this pipeline.' ) def snake_case_ ( self: str ): '''simple docstring''' pass @unittest.skip(reason='Batching needs to be properly figured out first for this pipeline.' ) def snake_case_ ( self: Optional[Any] ): '''simple docstring''' pass @unittest.skip(reason='`num_images_per_prompt` argument is not supported for this pipeline.' ) def snake_case_ ( self: int ): '''simple docstring''' pass def snake_case_ ( self: Any ): '''simple docstring''' return super().test_progress_bar() @slow @skip_mps class __lowerCamelCase (unittest.TestCase ): def snake_case_ ( self: Tuple ): '''simple docstring''' __UpperCamelCase = VideoToVideoSDPipeline.from_pretrained('cerspense/zeroscope_v2_XL',torch_dtype=torch.floataa ) pipe.enable_model_cpu_offload() # 10 frames __UpperCamelCase = torch.Generator(device='cpu' ).manual_seed(0 ) __UpperCamelCase = torch.randn((1, 10, 3, 1024, 576),generator=A_ ) __UpperCamelCase = video.to('cuda' ) __UpperCamelCase = 'Spiderman is surfing' __UpperCamelCase = pipe(A_,video=A_,generator=A_,num_inference_steps=3,output_type='pt' ).frames __UpperCamelCase = np.array([-1.0_4_5_8_9_8_4, -1.1_2_7_9_2_9_7, -0.9_6_6_3_0_8_6, -0.9_1_5_0_3_9_0_6, -0.7_5_0_9_7_6_5_6] ) assert np.abs(video_frames.cpu().numpy()[0, 0, 0, 0, -5:] - expected_array ).sum() < 1E-2