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from argparse import ArgumentParser
from datasets.commands.convert import ConvertCommand
from datasets.commands.dummy_data import DummyDataCommand
from datasets.commands.env import EnvironmentCommand
from datasets.commands.run_beam import RunBeamCommand
from datasets.commands.test import TestCommand
from datasets.utils.logging import set_verbosity_info
def UpperCamelCase ( __lowerCamelCase : List[Any] ):
return {key.lstrip("-" ): value for key, value in zip(unknown_args[::2] , unknown_args[1::2] )}
def UpperCamelCase ( ):
snake_case : Optional[int] = ArgumentParser(
"HuggingFace Datasets CLI tool" , usage="datasets-cli <command> [<args>]" , allow_abbrev=__lowerCamelCase )
snake_case : Optional[int] = parser.add_subparsers(help="datasets-cli command helpers" )
set_verbosity_info()
# Register commands
ConvertCommand.register_subcommand(__lowerCamelCase )
EnvironmentCommand.register_subcommand(__lowerCamelCase )
TestCommand.register_subcommand(__lowerCamelCase )
RunBeamCommand.register_subcommand(__lowerCamelCase )
DummyDataCommand.register_subcommand(__lowerCamelCase )
# Parse args
snake_case , snake_case : Any = parser.parse_known_args()
if not hasattr(__lowerCamelCase , "func" ):
parser.print_help()
exit(1 )
snake_case : Union[str, Any] = parse_unknown_args(__lowerCamelCase )
# Run
snake_case : str = args.func(__lowerCamelCase , **__lowerCamelCase )
service.run()
if __name__ == "__main__":
main()
| 59
|
import argparse
import json
from dataclasses import dataclass, field
from functools import partial
from pathlib import Path
from typing import Callable, Dict, List, Tuple
import timm
import torch
import torch.nn as nn
from classy_vision.models.regnet import RegNet, RegNetParams, RegNetYaagf, RegNetYaagf, RegNetYaaagf
from huggingface_hub import cached_download, hf_hub_url
from torch import Tensor
from vissl.models.model_helpers import get_trunk_forward_outputs
from transformers import AutoImageProcessor, RegNetConfig, RegNetForImageClassification, RegNetModel
from transformers.utils import logging
logging.set_verbosity_info()
__lowerCamelCase = logging.get_logger()
@dataclass
class UpperCAmelCase :
A__ : nn.Module
A__ : List[nn.Module] = field(default_factory=A_ )
A__ : list = field(default_factory=A_ )
def _SCREAMING_SNAKE_CASE (self : Optional[Any] , snake_case__ : Optional[Any] , snake_case__ : Tensor , snake_case__ : Tensor ) -> Optional[Any]:
'''simple docstring'''
snake_case : List[str] = len(list(m.modules() ) ) == 1 or isinstance(snake_case__ , nn.Convad ) or isinstance(snake_case__ , nn.BatchNormad )
if has_not_submodules:
self.traced.append(snake_case__ )
def __call__(self : List[Any] , snake_case__ : Tensor ) -> List[Any]:
'''simple docstring'''
for m in self.module.modules():
self.handles.append(m.register_forward_hook(self._forward_hook ) )
self.module(snake_case__ )
[x.remove() for x in self.handles]
return self
@property
def _SCREAMING_SNAKE_CASE (self : int ) -> Optional[int]:
'''simple docstring'''
return list(filter(lambda snake_case__ : len(list(x.state_dict().keys() ) ) > 0 , self.traced ) )
@dataclass
class UpperCAmelCase :
A__ : nn.Module
A__ : nn.Module
A__ : int = 1
A__ : List = field(default_factory=A_ )
A__ : List = field(default_factory=A_ )
A__ : bool = True
def __call__(self : List[Any] , snake_case__ : Tensor ) -> Any:
'''simple docstring'''
snake_case : str = Tracker(self.dest )(snake_case__ ).parametrized
snake_case : Optional[int] = Tracker(self.src )(snake_case__ ).parametrized
snake_case : List[str] = list(filter(lambda snake_case__ : type(snake_case__ ) not in self.src_skip , snake_case__ ) )
snake_case : Optional[Any] = list(filter(lambda snake_case__ : type(snake_case__ ) not in self.dest_skip , snake_case__ ) )
if len(snake_case__ ) != len(snake_case__ ) and self.raise_if_mismatch:
raise Exception(
f"""Numbers of operations are different. Source module has {len(snake_case__ )} operations while"""
f""" destination module has {len(snake_case__ )}.""" )
for dest_m, src_m in zip(snake_case__ , snake_case__ ):
dest_m.load_state_dict(src_m.state_dict() )
if self.verbose == 1:
print(f"""Transfered from={src_m} to={dest_m}""" )
class UpperCAmelCase ( nn.Module ):
def __init__(self : Tuple , snake_case__ : nn.Module ) -> Optional[Any]:
'''simple docstring'''
super().__init__()
snake_case : List[Tuple[str, nn.Module]] = []
# - get the stem
feature_blocks.append(("conv1", model.stem) )
# - get all the feature blocks
for k, v in model.trunk_output.named_children():
assert k.startswith("block" ), f"""Unexpected layer name {k}"""
snake_case : Union[str, Any] = len(snake_case__ ) + 1
feature_blocks.append((f"""res{block_index}""", v) )
snake_case : Optional[Any] = nn.ModuleDict(snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Tuple , snake_case__ : Tensor ) -> Dict:
'''simple docstring'''
return get_trunk_forward_outputs(
snake_case__ , out_feat_keys=snake_case__ , feature_blocks=self._feature_blocks , )
class UpperCAmelCase ( A_ ):
def _SCREAMING_SNAKE_CASE (self : Any , snake_case__ : str ) -> str:
'''simple docstring'''
snake_case : List[Any] = x.split("-" )
return x_split[0] + x_split[1] + "_" + "".join(x_split[2:] )
def __getitem__(self : Optional[int] , snake_case__ : str ) -> Callable[[], Tuple[nn.Module, Dict]]:
'''simple docstring'''
if x not in self:
snake_case : Dict = self.convert_name_to_timm(snake_case__ )
snake_case : Union[str, Any] = partial(lambda: (timm.create_model(snake_case__ , pretrained=snake_case__ ).eval(), None) )
else:
snake_case : List[str] = super().__getitem__(snake_case__ )
return val
class UpperCAmelCase ( A_ ):
def __getitem__(self : Dict , snake_case__ : str ) -> Callable[[], nn.Module]:
'''simple docstring'''
if "seer" in x and "in1k" not in x:
snake_case : str = RegNetModel
else:
snake_case : Optional[Any] = RegNetForImageClassification
return val
def UpperCamelCase ( __lowerCamelCase : Union[str, Any] , __lowerCamelCase : Union[str, Any] , __lowerCamelCase : List[Tuple[str, str]] ):
for from_key, to_key in keys:
snake_case : str = from_state_dict[from_key].clone()
print(f"""Copied key={from_key} to={to_key}""" )
return to_state_dict
def UpperCamelCase ( __lowerCamelCase : str , __lowerCamelCase : Callable[[], nn.Module] , __lowerCamelCase : Callable[[], nn.Module] , __lowerCamelCase : RegNetConfig , __lowerCamelCase : Path , __lowerCamelCase : bool = True , ):
print(f"""Converting {name}...""" )
with torch.no_grad():
snake_case , snake_case : int = from_model_func()
snake_case : str = our_model_func(__lowerCamelCase ).eval()
snake_case : int = ModuleTransfer(src=__lowerCamelCase , dest=__lowerCamelCase , raise_if_mismatch=__lowerCamelCase )
snake_case : Dict = torch.randn((1, 3, 224, 224) )
module_transfer(__lowerCamelCase )
if from_state_dict is not None:
snake_case : str = []
# for seer - in1k finetuned we have to manually copy the head
if "seer" in name and "in1k" in name:
snake_case : Tuple = [("0.clf.0.weight", "classifier.1.weight"), ("0.clf.0.bias", "classifier.1.bias")]
snake_case : Optional[Any] = manually_copy_vissl_head(__lowerCamelCase , our_model.state_dict() , __lowerCamelCase )
our_model.load_state_dict(__lowerCamelCase )
snake_case : Any = our_model(__lowerCamelCase , output_hidden_states=__lowerCamelCase )
snake_case : Union[str, Any] = (
our_outputs.logits if isinstance(__lowerCamelCase , __lowerCamelCase ) else our_outputs.last_hidden_state
)
snake_case : Union[str, Any] = from_model(__lowerCamelCase )
snake_case : Dict = from_output[-1] if type(__lowerCamelCase ) is list else from_output
# now since I don't want to use any config files, vissl seer model doesn't actually have an head, so let's just check the last hidden state
if "seer" in name and "in1k" in name:
snake_case : Any = our_outputs.hidden_states[-1]
assert torch.allclose(__lowerCamelCase , __lowerCamelCase ), "The model logits don't match the original one."
if push_to_hub:
our_model.push_to_hub(
repo_path_or_name=save_directory / name , commit_message="Add model" , use_temp_dir=__lowerCamelCase , )
snake_case : List[str] = 224 if "seer" not in name else 384
# we can use the convnext one
snake_case : int = AutoImageProcessor.from_pretrained("facebook/convnext-base-224-22k-1k" , size=__lowerCamelCase )
image_processor.push_to_hub(
repo_path_or_name=save_directory / name , commit_message="Add image processor" , use_temp_dir=__lowerCamelCase , )
print(f"""Pushed {name}""" )
def UpperCamelCase ( __lowerCamelCase : Path , __lowerCamelCase : str = None , __lowerCamelCase : bool = True ):
snake_case : Union[str, Any] = "imagenet-1k-id2label.json"
snake_case : List[str] = 1000
snake_case : List[str] = (1, num_labels)
snake_case : Any = "huggingface/label-files"
snake_case : List[str] = num_labels
snake_case : Optional[Any] = json.load(open(cached_download(hf_hub_url(__lowerCamelCase , __lowerCamelCase , repo_type="dataset" ) ) , "r" ) )
snake_case : List[Any] = {int(__lowerCamelCase ): v for k, v in idalabel.items()}
snake_case : str = idalabel
snake_case : List[Any] = {v: k for k, v in idalabel.items()}
snake_case : Dict = partial(__lowerCamelCase , num_labels=__lowerCamelCase , idalabel=__lowerCamelCase , labelaid=__lowerCamelCase )
snake_case : Optional[Any] = {
"regnet-x-002": ImageNetPreTrainedConfig(
depths=[1, 1, 4, 7] , hidden_sizes=[24, 56, 152, 368] , groups_width=8 , layer_type="x" ),
"regnet-x-004": ImageNetPreTrainedConfig(
depths=[1, 2, 7, 12] , hidden_sizes=[32, 64, 160, 384] , groups_width=16 , layer_type="x" ),
"regnet-x-006": ImageNetPreTrainedConfig(
depths=[1, 3, 5, 7] , hidden_sizes=[48, 96, 240, 528] , groups_width=24 , layer_type="x" ),
"regnet-x-008": ImageNetPreTrainedConfig(
depths=[1, 3, 7, 5] , hidden_sizes=[64, 128, 288, 672] , groups_width=16 , layer_type="x" ),
"regnet-x-016": ImageNetPreTrainedConfig(
depths=[2, 4, 10, 2] , hidden_sizes=[72, 168, 408, 912] , groups_width=24 , layer_type="x" ),
"regnet-x-032": ImageNetPreTrainedConfig(
depths=[2, 6, 15, 2] , hidden_sizes=[96, 192, 432, 1008] , groups_width=48 , layer_type="x" ),
"regnet-x-040": ImageNetPreTrainedConfig(
depths=[2, 5, 14, 2] , hidden_sizes=[80, 240, 560, 1360] , groups_width=40 , layer_type="x" ),
"regnet-x-064": ImageNetPreTrainedConfig(
depths=[2, 4, 10, 1] , hidden_sizes=[168, 392, 784, 1624] , groups_width=56 , layer_type="x" ),
"regnet-x-080": ImageNetPreTrainedConfig(
depths=[2, 5, 15, 1] , hidden_sizes=[80, 240, 720, 1920] , groups_width=120 , layer_type="x" ),
"regnet-x-120": ImageNetPreTrainedConfig(
depths=[2, 5, 11, 1] , hidden_sizes=[224, 448, 896, 2240] , groups_width=112 , layer_type="x" ),
"regnet-x-160": ImageNetPreTrainedConfig(
depths=[2, 6, 13, 1] , hidden_sizes=[256, 512, 896, 2048] , groups_width=128 , layer_type="x" ),
"regnet-x-320": ImageNetPreTrainedConfig(
depths=[2, 7, 13, 1] , hidden_sizes=[336, 672, 1344, 2520] , groups_width=168 , layer_type="x" ),
# y variant
"regnet-y-002": ImageNetPreTrainedConfig(depths=[1, 1, 4, 7] , hidden_sizes=[24, 56, 152, 368] , groups_width=8 ),
"regnet-y-004": ImageNetPreTrainedConfig(
depths=[1, 3, 6, 6] , hidden_sizes=[48, 104, 208, 440] , groups_width=8 ),
"regnet-y-006": ImageNetPreTrainedConfig(
depths=[1, 3, 7, 4] , hidden_sizes=[48, 112, 256, 608] , groups_width=16 ),
"regnet-y-008": ImageNetPreTrainedConfig(
depths=[1, 3, 8, 2] , hidden_sizes=[64, 128, 320, 768] , groups_width=16 ),
"regnet-y-016": ImageNetPreTrainedConfig(
depths=[2, 6, 17, 2] , hidden_sizes=[48, 120, 336, 888] , groups_width=24 ),
"regnet-y-032": ImageNetPreTrainedConfig(
depths=[2, 5, 13, 1] , hidden_sizes=[72, 216, 576, 1512] , groups_width=24 ),
"regnet-y-040": ImageNetPreTrainedConfig(
depths=[2, 6, 12, 2] , hidden_sizes=[128, 192, 512, 1088] , groups_width=64 ),
"regnet-y-064": ImageNetPreTrainedConfig(
depths=[2, 7, 14, 2] , hidden_sizes=[144, 288, 576, 1296] , groups_width=72 ),
"regnet-y-080": ImageNetPreTrainedConfig(
depths=[2, 4, 10, 1] , hidden_sizes=[168, 448, 896, 2016] , groups_width=56 ),
"regnet-y-120": ImageNetPreTrainedConfig(
depths=[2, 5, 11, 1] , hidden_sizes=[224, 448, 896, 2240] , groups_width=112 ),
"regnet-y-160": ImageNetPreTrainedConfig(
depths=[2, 4, 11, 1] , hidden_sizes=[224, 448, 1232, 3024] , groups_width=112 ),
"regnet-y-320": ImageNetPreTrainedConfig(
depths=[2, 5, 12, 1] , hidden_sizes=[232, 696, 1392, 3712] , groups_width=232 ),
# models created by SEER -> https://arxiv.org/abs/2202.08360
"regnet-y-320-seer": RegNetConfig(depths=[2, 5, 12, 1] , hidden_sizes=[232, 696, 1392, 3712] , groups_width=232 ),
"regnet-y-640-seer": RegNetConfig(depths=[2, 5, 12, 1] , hidden_sizes=[328, 984, 1968, 4920] , groups_width=328 ),
"regnet-y-1280-seer": RegNetConfig(
depths=[2, 7, 17, 1] , hidden_sizes=[528, 1056, 2904, 7392] , groups_width=264 ),
"regnet-y-2560-seer": RegNetConfig(
depths=[3, 7, 16, 1] , hidden_sizes=[640, 1696, 2544, 5088] , groups_width=640 ),
"regnet-y-10b-seer": ImageNetPreTrainedConfig(
depths=[2, 7, 17, 1] , hidden_sizes=[2020, 4040, 11110, 28280] , groups_width=1010 ),
# finetuned on imagenet
"regnet-y-320-seer-in1k": ImageNetPreTrainedConfig(
depths=[2, 5, 12, 1] , hidden_sizes=[232, 696, 1392, 3712] , groups_width=232 ),
"regnet-y-640-seer-in1k": ImageNetPreTrainedConfig(
depths=[2, 5, 12, 1] , hidden_sizes=[328, 984, 1968, 4920] , groups_width=328 ),
"regnet-y-1280-seer-in1k": ImageNetPreTrainedConfig(
depths=[2, 7, 17, 1] , hidden_sizes=[528, 1056, 2904, 7392] , groups_width=264 ),
"regnet-y-2560-seer-in1k": ImageNetPreTrainedConfig(
depths=[3, 7, 16, 1] , hidden_sizes=[640, 1696, 2544, 5088] , groups_width=640 ),
"regnet-y-10b-seer-in1k": ImageNetPreTrainedConfig(
depths=[2, 7, 17, 1] , hidden_sizes=[2020, 4040, 11110, 28280] , groups_width=1010 ),
}
snake_case : Union[str, Any] = NameToOurModelFuncMap()
snake_case : str = NameToFromModelFuncMap()
# add seer weights logic
def load_using_classy_vision(__lowerCamelCase : str , __lowerCamelCase : Callable[[], nn.Module] ) -> Tuple[nn.Module, Dict]:
snake_case : List[Any] = torch.hub.load_state_dict_from_url(__lowerCamelCase , model_dir=str(__lowerCamelCase ) , map_location="cpu" )
snake_case : Dict = model_func()
# check if we have a head, if yes add it
snake_case : str = files["classy_state_dict"]["base_model"]["model"]
snake_case : Dict = model_state_dict["trunk"]
model.load_state_dict(__lowerCamelCase )
return model.eval(), model_state_dict["heads"]
# pretrained
snake_case : List[Any] = partial(
__lowerCamelCase , "https://dl.fbaipublicfiles.com/vissl/model_zoo/seer_regnet32d/seer_regnet32gf_model_iteration244000.torch" , lambda: FakeRegNetVisslWrapper(RegNetYaagf() ) , )
snake_case : Optional[int] = partial(
__lowerCamelCase , "https://dl.fbaipublicfiles.com/vissl/model_zoo/seer_regnet64/seer_regnet64gf_model_final_checkpoint_phase0.torch" , lambda: FakeRegNetVisslWrapper(RegNetYaagf() ) , )
snake_case : List[str] = partial(
__lowerCamelCase , "https://dl.fbaipublicfiles.com/vissl/model_zoo/swav_ig1b_regnet128Gf_cnstant_bs32_node16_sinkhorn10_proto16k_syncBN64_warmup8k/model_final_checkpoint_phase0.torch" , lambda: FakeRegNetVisslWrapper(RegNetYaaagf() ) , )
snake_case : Tuple = partial(
__lowerCamelCase , "https://dl.fbaipublicfiles.com/vissl/model_zoo/seer_regnet10B/model_iteration124500_conso.torch" , lambda: FakeRegNetVisslWrapper(
RegNet(RegNetParams(depth=27 , group_width=1010 , w_a=1744 , w_a=620.83 , w_m=2.52 ) ) ) , )
# IN1K finetuned
snake_case : List[Any] = partial(
__lowerCamelCase , "https://dl.fbaipublicfiles.com/vissl/model_zoo/seer_finetuned/seer_regnet32_finetuned_in1k_model_final_checkpoint_phase78.torch" , lambda: FakeRegNetVisslWrapper(RegNetYaagf() ) , )
snake_case : Tuple = partial(
__lowerCamelCase , "https://dl.fbaipublicfiles.com/vissl/model_zoo/seer_finetuned/seer_regnet64_finetuned_in1k_model_final_checkpoint_phase78.torch" , lambda: FakeRegNetVisslWrapper(RegNetYaagf() ) , )
snake_case : str = partial(
__lowerCamelCase , "https://dl.fbaipublicfiles.com/vissl/model_zoo/seer_finetuned/seer_regnet128_finetuned_in1k_model_final_checkpoint_phase78.torch" , lambda: FakeRegNetVisslWrapper(RegNetYaaagf() ) , )
snake_case : Dict = partial(
__lowerCamelCase , "https://dl.fbaipublicfiles.com/vissl/model_zoo/seer_finetuned/seer_10b_finetuned_in1k_model_phase28_conso.torch" , lambda: FakeRegNetVisslWrapper(
RegNet(RegNetParams(depth=27 , group_width=1010 , w_a=1744 , w_a=620.83 , w_m=2.52 ) ) ) , )
if model_name:
convert_weight_and_push(
__lowerCamelCase , names_to_from_model_map[model_name] , names_to_ours_model_map[model_name] , names_to_config[model_name] , __lowerCamelCase , __lowerCamelCase , )
else:
for model_name, config in names_to_config.items():
convert_weight_and_push(
__lowerCamelCase , names_to_from_model_map[model_name] , names_to_ours_model_map[model_name] , __lowerCamelCase , __lowerCamelCase , __lowerCamelCase , )
return config, expected_shape
if __name__ == "__main__":
__lowerCamelCase = argparse.ArgumentParser()
# Required parameters
parser.add_argument(
"""--model_name""",
default=None,
type=str,
help=(
"""The name of the model you wish to convert, it must be one of the supported regnet* architecture,"""
""" currently: regnetx-*, regnety-*. If `None`, all of them will the converted."""
),
)
parser.add_argument(
"""--pytorch_dump_folder_path""",
default=None,
type=Path,
required=True,
help="""Path to the output PyTorch model directory.""",
)
parser.add_argument(
"""--push_to_hub""",
default=True,
type=bool,
required=False,
help="""If True, push model and image processor to the hub.""",
)
__lowerCamelCase = parser.parse_args()
__lowerCamelCase = args.pytorch_dump_folder_path
pytorch_dump_folder_path.mkdir(exist_ok=True, parents=True)
convert_weights_and_push(pytorch_dump_folder_path, args.model_name, args.push_to_hub)
| 59
| 1
|
import re
from pathlib import Path
from unittest import TestCase
import pytest
@pytest.mark.integration
class UpperCAmelCase ( A_ ):
def _SCREAMING_SNAKE_CASE (self : Optional[Any] , snake_case__ : str ) -> Optional[Any]:
'''simple docstring'''
with open(snake_case__ , encoding="utf-8" ) as input_file:
snake_case : Dict = re.compile(R"(?!.*\b(?:encoding|rb|w|wb|w+|wb+|ab|ab+)\b)(?<=\s)(open)\((.*)\)" )
snake_case : Union[str, Any] = input_file.read()
snake_case : str = regexp.search(snake_case__ )
return match
def _SCREAMING_SNAKE_CASE (self : Dict , snake_case__ : str ) -> Dict:
'''simple docstring'''
with open(snake_case__ , encoding="utf-8" ) as input_file:
snake_case : List[str] = re.compile(R"#[^\r\n]*print\(|\"[^\r\n]*print\(|\"\"\".*?print\(.*?\"\"\"|(print\()" , re.DOTALL )
snake_case : int = input_file.read()
# use `re.finditer` to handle the case where the ignored groups would be matched first by `re.search`
snake_case : List[Any] = regexp.finditer(snake_case__ )
snake_case : int = [match for match in matches if match is not None and match.group(1 ) is not None]
return matches[0] if matches else None
def _SCREAMING_SNAKE_CASE (self : Tuple ) -> List[str]:
'''simple docstring'''
snake_case : List[Any] = Path("./datasets" )
snake_case : Union[str, Any] = list(dataset_paths.absolute().glob("**/*.py" ) )
for dataset in dataset_files:
if self._no_encoding_on_file_open(str(snake_case__ ) ):
raise AssertionError(f"""open(...) must use utf-8 encoding in {dataset}""" )
def _SCREAMING_SNAKE_CASE (self : Tuple ) -> Any:
'''simple docstring'''
snake_case : List[str] = Path("./datasets" )
snake_case : Optional[int] = list(dataset_paths.absolute().glob("**/*.py" ) )
for dataset in dataset_files:
if self._no_print_statements(str(snake_case__ ) ):
raise AssertionError(f"""print statement found in {dataset}. Use datasets.logger/logging instead.""" )
| 59
|
import warnings
from typing import Dict
import numpy as np
from ..utils import ExplicitEnum, add_end_docstrings, is_tf_available, is_torch_available
from .base import PIPELINE_INIT_ARGS, GenericTensor, Pipeline
if is_tf_available():
from ..models.auto.modeling_tf_auto import TF_MODEL_FOR_SEQUENCE_CLASSIFICATION_MAPPING
if is_torch_available():
from ..models.auto.modeling_auto import MODEL_FOR_SEQUENCE_CLASSIFICATION_MAPPING
def UpperCamelCase ( __lowerCamelCase : List[Any] ):
return 1.0 / (1.0 + np.exp(-_outputs ))
def UpperCamelCase ( __lowerCamelCase : int ):
snake_case : Tuple = np.max(_outputs , axis=-1 , keepdims=__lowerCamelCase )
snake_case : int = np.exp(_outputs - maxes )
return shifted_exp / shifted_exp.sum(axis=-1 , keepdims=__lowerCamelCase )
class UpperCAmelCase ( A_ ):
A__ : Any = "sigmoid"
A__ : str = "softmax"
A__ : int = "none"
@add_end_docstrings(
A_ ,r"\n return_all_scores (`bool`, *optional*, defaults to `False`):\n Whether to return all prediction scores or just the one of the predicted class.\n function_to_apply (`str`, *optional*, defaults to `\"default\"`):\n The function to apply to the model outputs in order to retrieve the scores. Accepts four different values:\n\n - `\"default\"`: if the model has a single label, will apply the sigmoid function on the output. If the model\n has several labels, will apply the softmax function on the output.\n - `\"sigmoid\"`: Applies the sigmoid function on the output.\n - `\"softmax\"`: Applies the softmax function on the output.\n - `\"none\"`: Does not apply any function on the output.\n " ,)
class UpperCAmelCase ( A_ ):
A__ : int = False
A__ : Union[str, Any] = ClassificationFunction.NONE
def __init__(self : List[str] , **snake_case__ : int ) -> str:
'''simple docstring'''
super().__init__(**snake_case__ )
self.check_model_type(
TF_MODEL_FOR_SEQUENCE_CLASSIFICATION_MAPPING
if self.framework == "tf"
else MODEL_FOR_SEQUENCE_CLASSIFICATION_MAPPING )
def _SCREAMING_SNAKE_CASE (self : List[Any] , snake_case__ : List[str]=None , snake_case__ : Optional[Any]=None , snake_case__ : Union[str, Any]="" , **snake_case__ : List[str] ) -> Union[str, Any]:
'''simple docstring'''
snake_case : Dict = tokenizer_kwargs
snake_case : List[Any] = {}
if hasattr(self.model.config , "return_all_scores" ) and return_all_scores is None:
snake_case : Optional[int] = self.model.config.return_all_scores
if isinstance(snake_case__ , snake_case__ ) or top_k is None:
snake_case : List[Any] = top_k
snake_case : str = False
elif return_all_scores is not None:
warnings.warn(
"`return_all_scores` is now deprecated, if want a similar functionality use `top_k=None` instead of"
" `return_all_scores=True` or `top_k=1` instead of `return_all_scores=False`." , snake_case__ , )
if return_all_scores:
snake_case : List[str] = None
else:
snake_case : Optional[int] = 1
if isinstance(snake_case__ , snake_case__ ):
snake_case : Dict = ClassificationFunction[function_to_apply.upper()]
if function_to_apply is not None:
snake_case : Optional[int] = function_to_apply
return preprocess_params, {}, postprocess_params
def __call__(self : Dict , *snake_case__ : List[str] , **snake_case__ : int ) -> Optional[int]:
'''simple docstring'''
snake_case : Optional[int] = super().__call__(*snake_case__ , **snake_case__ )
# TODO try and retrieve it in a nicer way from _sanitize_parameters.
snake_case : Tuple = "top_k" not in kwargs
if isinstance(args[0] , snake_case__ ) and _legacy:
# This pipeline is odd, and return a list when single item is run
return [result]
else:
return result
def _SCREAMING_SNAKE_CASE (self : Dict , snake_case__ : Tuple , **snake_case__ : Union[str, Any] ) -> Dict[str, GenericTensor]:
'''simple docstring'''
snake_case : int = self.framework
if isinstance(snake_case__ , snake_case__ ):
return self.tokenizer(**snake_case__ , return_tensors=snake_case__ , **snake_case__ )
elif isinstance(snake_case__ , snake_case__ ) and len(snake_case__ ) == 1 and isinstance(inputs[0] , snake_case__ ) and len(inputs[0] ) == 2:
# It used to be valid to use a list of list of list for text pairs, keeping this path for BC
return self.tokenizer(
text=inputs[0][0] , text_pair=inputs[0][1] , return_tensors=snake_case__ , **snake_case__ )
elif isinstance(snake_case__ , snake_case__ ):
# This is likely an invalid usage of the pipeline attempting to pass text pairs.
raise ValueError(
"The pipeline received invalid inputs, if you are trying to send text pairs, you can try to send a"
" dictionary `{\"text\": \"My text\", \"text_pair\": \"My pair\"}` in order to send a text pair." )
return self.tokenizer(snake_case__ , return_tensors=snake_case__ , **snake_case__ )
def _SCREAMING_SNAKE_CASE (self : int , snake_case__ : Union[str, Any] ) -> int:
'''simple docstring'''
return self.model(**snake_case__ )
def _SCREAMING_SNAKE_CASE (self : List[str] , snake_case__ : Optional[Any] , snake_case__ : List[str]=None , snake_case__ : Dict=1 , snake_case__ : Tuple=True ) -> str:
'''simple docstring'''
if function_to_apply is None:
if self.model.config.problem_type == "multi_label_classification" or self.model.config.num_labels == 1:
snake_case : Tuple = ClassificationFunction.SIGMOID
elif self.model.config.problem_type == "single_label_classification" or self.model.config.num_labels > 1:
snake_case : Tuple = ClassificationFunction.SOFTMAX
elif hasattr(self.model.config , "function_to_apply" ) and function_to_apply is None:
snake_case : Tuple = self.model.config.function_to_apply
else:
snake_case : int = ClassificationFunction.NONE
snake_case : Any = model_outputs["logits"][0]
snake_case : List[str] = outputs.numpy()
if function_to_apply == ClassificationFunction.SIGMOID:
snake_case : Optional[Any] = sigmoid(snake_case__ )
elif function_to_apply == ClassificationFunction.SOFTMAX:
snake_case : Union[str, Any] = softmax(snake_case__ )
elif function_to_apply == ClassificationFunction.NONE:
snake_case : Optional[Any] = outputs
else:
raise ValueError(f"""Unrecognized `function_to_apply` argument: {function_to_apply}""" )
if top_k == 1 and _legacy:
return {"label": self.model.config.idalabel[scores.argmax().item()], "score": scores.max().item()}
snake_case : Optional[int] = [
{"label": self.model.config.idalabel[i], "score": score.item()} for i, score in enumerate(snake_case__ )
]
if not _legacy:
dict_scores.sort(key=lambda snake_case__ : x["score"] , reverse=snake_case__ )
if top_k is not None:
snake_case : Optional[int] = dict_scores[:top_k]
return dict_scores
| 59
| 1
|
import gc
import unittest
from diffusers import FlaxStableDiffusionInpaintPipeline
from diffusers.utils import is_flax_available, load_image, slow
from diffusers.utils.testing_utils import require_flax
if is_flax_available():
import jax
import jax.numpy as jnp
from flax.jax_utils import replicate
from flax.training.common_utils import shard
@slow
@require_flax
class UpperCAmelCase ( unittest.TestCase ):
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> Tuple:
'''simple docstring'''
super().tearDown()
gc.collect()
def _SCREAMING_SNAKE_CASE (self : Any ) -> Optional[int]:
'''simple docstring'''
snake_case : List[Any] = load_image(
"https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main"
"/sd2-inpaint/init_image.png" )
snake_case : List[Any] = load_image(
"https://huggingface.co/datasets/hf-internal-testing/diffusers-images/resolve/main/sd2-inpaint/mask.png" )
snake_case : Tuple = "xvjiarui/stable-diffusion-2-inpainting"
snake_case , snake_case : Dict = FlaxStableDiffusionInpaintPipeline.from_pretrained(snake_case__ , safety_checker=snake_case__ )
snake_case : Tuple = "Face of a yellow cat, high resolution, sitting on a park bench"
snake_case : Optional[Any] = jax.random.PRNGKey(0 )
snake_case : List[str] = 50
snake_case : Tuple = jax.device_count()
snake_case : Optional[Any] = num_samples * [prompt]
snake_case : List[str] = num_samples * [init_image]
snake_case : str = num_samples * [mask_image]
snake_case , snake_case , snake_case : int = pipeline.prepare_inputs(snake_case__ , snake_case__ , snake_case__ )
# shard inputs and rng
snake_case : Tuple = replicate(snake_case__ )
snake_case : Optional[Any] = jax.random.split(snake_case__ , jax.device_count() )
snake_case : Union[str, Any] = shard(snake_case__ )
snake_case : Union[str, Any] = shard(snake_case__ )
snake_case : List[str] = shard(snake_case__ )
snake_case : int = pipeline(
snake_case__ , snake_case__ , snake_case__ , snake_case__ , snake_case__ , snake_case__ , jit=snake_case__ )
snake_case : List[str] = output.images.reshape(snake_case__ , 5_12 , 5_12 , 3 )
snake_case : List[Any] = images[0, 2_53:2_56, 2_53:2_56, -1]
snake_case : List[str] = jnp.asarray(jax.device_get(image_slice.flatten() ) )
snake_case : Any = jnp.array(
[0.3611307, 0.37649736, 0.3757408, 0.38213953, 0.39295167, 0.3841631, 0.41554978, 0.4137475, 0.4217084] )
print(f"""output_slice: {output_slice}""" )
assert jnp.abs(output_slice - expected_slice ).max() < 1e-2
| 59
|
from __future__ import annotations
__lowerCamelCase = list[list[int]]
# assigning initial values to the grid
__lowerCamelCase = [
[3, 0, 6, 5, 0, 8, 4, 0, 0],
[5, 2, 0, 0, 0, 0, 0, 0, 0],
[0, 8, 7, 0, 0, 0, 0, 3, 1],
[0, 0, 3, 0, 1, 0, 0, 8, 0],
[9, 0, 0, 8, 6, 3, 0, 0, 5],
[0, 5, 0, 0, 9, 0, 6, 0, 0],
[1, 3, 0, 0, 0, 0, 2, 5, 0],
[0, 0, 0, 0, 0, 0, 0, 7, 4],
[0, 0, 5, 2, 0, 6, 3, 0, 0],
]
# a grid with no solution
__lowerCamelCase = [
[5, 0, 6, 5, 0, 8, 4, 0, 3],
[5, 2, 0, 0, 0, 0, 0, 0, 2],
[1, 8, 7, 0, 0, 0, 0, 3, 1],
[0, 0, 3, 0, 1, 0, 0, 8, 0],
[9, 0, 0, 8, 6, 3, 0, 0, 5],
[0, 5, 0, 0, 9, 0, 6, 0, 0],
[1, 3, 0, 0, 0, 0, 2, 5, 0],
[0, 0, 0, 0, 0, 0, 0, 7, 4],
[0, 0, 5, 2, 0, 6, 3, 0, 0],
]
def UpperCamelCase ( __lowerCamelCase : Matrix , __lowerCamelCase : int , __lowerCamelCase : int , __lowerCamelCase : int ):
for i in range(9 ):
if grid[row][i] == n or grid[i][column] == n:
return False
for i in range(3 ):
for j in range(3 ):
if grid[(row - row % 3) + i][(column - column % 3) + j] == n:
return False
return True
def UpperCamelCase ( __lowerCamelCase : Matrix ):
for i in range(9 ):
for j in range(9 ):
if grid[i][j] == 0:
return i, j
return None
def UpperCamelCase ( __lowerCamelCase : Matrix ):
if location := find_empty_location(__lowerCamelCase ):
snake_case , snake_case : Union[str, Any] = location
else:
# If the location is ``None``, then the grid is solved.
return grid
for digit in range(1 , 10 ):
if is_safe(__lowerCamelCase , __lowerCamelCase , __lowerCamelCase , __lowerCamelCase ):
snake_case : List[Any] = digit
if sudoku(__lowerCamelCase ) is not None:
return grid
snake_case : Union[str, Any] = 0
return None
def UpperCamelCase ( __lowerCamelCase : Matrix ):
for row in grid:
for cell in row:
print(__lowerCamelCase , end=" " )
print()
if __name__ == "__main__":
# make a copy of grid so that you can compare with the unmodified grid
for example_grid in (initial_grid, no_solution):
print("""\nExample grid:\n""" + """=""" * 20)
print_solution(example_grid)
print("""\nExample grid solution:""")
__lowerCamelCase = sudoku(example_grid)
if solution is not None:
print_solution(solution)
else:
print("""Cannot find a solution.""")
| 59
| 1
|
import logging
import numpy as np
import pytest
from scipy.linalg import eigh
logging.basicConfig(level=logging.INFO, format="""%(message)s""")
def UpperCamelCase ( __lowerCamelCase : np.ndarray ):
return input_array.reshape((input_array.size, 1) )
def UpperCamelCase ( __lowerCamelCase : np.ndarray , __lowerCamelCase : np.ndarray , __lowerCamelCase : int ):
snake_case : Any = np.nan
for i in range(__lowerCamelCase ):
snake_case : List[str] = features[:, labels == i]
snake_case : Dict = data.mean(1 )
# Centralize the data of class i
snake_case : Optional[Any] = data - column_reshape(__lowerCamelCase )
if i > 0:
# If covariance_sum is not None
covariance_sum += np.dot(__lowerCamelCase , centered_data.T )
else:
# If covariance_sum is np.nan (i.e. first loop)
snake_case : Optional[Any] = np.dot(__lowerCamelCase , centered_data.T )
return covariance_sum / features.shape[1]
def UpperCamelCase ( __lowerCamelCase : np.ndarray , __lowerCamelCase : np.ndarray , __lowerCamelCase : int ):
snake_case : Optional[Any] = features.mean(1 )
snake_case : Tuple = np.nan
for i in range(__lowerCamelCase ):
snake_case : Tuple = features[:, labels == i]
snake_case : Tuple = data.shape[1]
snake_case : List[str] = data.mean(1 )
if i > 0:
# If covariance_sum is not None
covariance_sum += device_data * np.dot(
column_reshape(__lowerCamelCase ) - column_reshape(__lowerCamelCase ) , (column_reshape(__lowerCamelCase ) - column_reshape(__lowerCamelCase )).T , )
else:
# If covariance_sum is np.nan (i.e. first loop)
snake_case : Optional[int] = device_data * np.dot(
column_reshape(__lowerCamelCase ) - column_reshape(__lowerCamelCase ) , (column_reshape(__lowerCamelCase ) - column_reshape(__lowerCamelCase )).T , )
return covariance_sum / features.shape[1]
def UpperCamelCase ( __lowerCamelCase : np.ndarray , __lowerCamelCase : int ):
# Check if the features have been loaded
if features.any():
snake_case : Tuple = features.mean(1 )
# Center the dataset
snake_case : List[str] = features - np.reshape(__lowerCamelCase , (data_mean.size, 1) )
snake_case : Optional[Any] = np.dot(__lowerCamelCase , centered_data.T ) / features.shape[1]
snake_case , snake_case : Dict = np.linalg.eigh(__lowerCamelCase )
# Take all the columns in the reverse order (-1), and then takes only the first
snake_case : Optional[Any] = eigenvectors[:, ::-1][:, 0:dimensions]
# Project the database on the new space
snake_case : Union[str, Any] = np.dot(filtered_eigenvectors.T , __lowerCamelCase )
logging.info("Principal Component Analysis computed" )
return projected_data
else:
logging.basicConfig(level=logging.ERROR , format="%(message)s" , force=__lowerCamelCase )
logging.error("Dataset empty" )
raise AssertionError
def UpperCamelCase ( __lowerCamelCase : np.ndarray , __lowerCamelCase : np.ndarray , __lowerCamelCase : int , __lowerCamelCase : int ):
assert classes > dimensions
# Check if features have been already loaded
if features.any:
snake_case , snake_case : str = eigh(
covariance_between_classes(__lowerCamelCase , __lowerCamelCase , __lowerCamelCase ) , covariance_within_classes(__lowerCamelCase , __lowerCamelCase , __lowerCamelCase ) , )
snake_case : str = eigenvectors[:, ::-1][:, :dimensions]
snake_case , snake_case , snake_case : int = np.linalg.svd(__lowerCamelCase )
snake_case : List[Any] = svd_matrix[:, 0:dimensions]
snake_case : Optional[Any] = np.dot(filtered_svd_matrix.T , __lowerCamelCase )
logging.info("Linear Discriminant Analysis computed" )
return projected_data
else:
logging.basicConfig(level=logging.ERROR , format="%(message)s" , force=__lowerCamelCase )
logging.error("Dataset empty" )
raise AssertionError
def UpperCamelCase ( ):
# Create dummy dataset with 2 classes and 3 features
snake_case : str = np.array([[1, 2, 3, 4, 5], [2, 3, 4, 5, 6], [3, 4, 5, 6, 7]] )
snake_case : Union[str, Any] = np.array([0, 0, 0, 1, 1] )
snake_case : List[Any] = 2
snake_case : Any = 2
# Assert that the function raises an AssertionError if dimensions > classes
with pytest.raises(__lowerCamelCase ) as error_info:
snake_case : str = linear_discriminant_analysis(
__lowerCamelCase , __lowerCamelCase , __lowerCamelCase , __lowerCamelCase )
if isinstance(__lowerCamelCase , np.ndarray ):
raise AssertionError(
"Did not raise AssertionError for dimensions > classes" )
assert error_info.type is AssertionError
def UpperCamelCase ( ):
snake_case : List[str] = np.array([[1, 2, 3], [4, 5, 6], [7, 8, 9]] )
snake_case : List[str] = 2
snake_case : int = np.array([[6.9282_0323, 8.6602_5404, 10.3923_0485], [3.0, 3.0, 3.0]] )
with pytest.raises(__lowerCamelCase ) as error_info:
snake_case : Union[str, Any] = principal_component_analysis(__lowerCamelCase , __lowerCamelCase )
if not np.allclose(__lowerCamelCase , __lowerCamelCase ):
raise AssertionError
assert error_info.type is AssertionError
if __name__ == "__main__":
import doctest
doctest.testmod()
| 59
|
import logging
import numpy as np
import pytest
from scipy.linalg import eigh
logging.basicConfig(level=logging.INFO, format="""%(message)s""")
def UpperCamelCase ( __lowerCamelCase : np.ndarray ):
return input_array.reshape((input_array.size, 1) )
def UpperCamelCase ( __lowerCamelCase : np.ndarray , __lowerCamelCase : np.ndarray , __lowerCamelCase : int ):
snake_case : Any = np.nan
for i in range(__lowerCamelCase ):
snake_case : List[str] = features[:, labels == i]
snake_case : Dict = data.mean(1 )
# Centralize the data of class i
snake_case : Optional[Any] = data - column_reshape(__lowerCamelCase )
if i > 0:
# If covariance_sum is not None
covariance_sum += np.dot(__lowerCamelCase , centered_data.T )
else:
# If covariance_sum is np.nan (i.e. first loop)
snake_case : Optional[Any] = np.dot(__lowerCamelCase , centered_data.T )
return covariance_sum / features.shape[1]
def UpperCamelCase ( __lowerCamelCase : np.ndarray , __lowerCamelCase : np.ndarray , __lowerCamelCase : int ):
snake_case : Optional[Any] = features.mean(1 )
snake_case : Tuple = np.nan
for i in range(__lowerCamelCase ):
snake_case : Tuple = features[:, labels == i]
snake_case : Tuple = data.shape[1]
snake_case : List[str] = data.mean(1 )
if i > 0:
# If covariance_sum is not None
covariance_sum += device_data * np.dot(
column_reshape(__lowerCamelCase ) - column_reshape(__lowerCamelCase ) , (column_reshape(__lowerCamelCase ) - column_reshape(__lowerCamelCase )).T , )
else:
# If covariance_sum is np.nan (i.e. first loop)
snake_case : Optional[int] = device_data * np.dot(
column_reshape(__lowerCamelCase ) - column_reshape(__lowerCamelCase ) , (column_reshape(__lowerCamelCase ) - column_reshape(__lowerCamelCase )).T , )
return covariance_sum / features.shape[1]
def UpperCamelCase ( __lowerCamelCase : np.ndarray , __lowerCamelCase : int ):
# Check if the features have been loaded
if features.any():
snake_case : Tuple = features.mean(1 )
# Center the dataset
snake_case : List[str] = features - np.reshape(__lowerCamelCase , (data_mean.size, 1) )
snake_case : Optional[Any] = np.dot(__lowerCamelCase , centered_data.T ) / features.shape[1]
snake_case , snake_case : Dict = np.linalg.eigh(__lowerCamelCase )
# Take all the columns in the reverse order (-1), and then takes only the first
snake_case : Optional[Any] = eigenvectors[:, ::-1][:, 0:dimensions]
# Project the database on the new space
snake_case : Union[str, Any] = np.dot(filtered_eigenvectors.T , __lowerCamelCase )
logging.info("Principal Component Analysis computed" )
return projected_data
else:
logging.basicConfig(level=logging.ERROR , format="%(message)s" , force=__lowerCamelCase )
logging.error("Dataset empty" )
raise AssertionError
def UpperCamelCase ( __lowerCamelCase : np.ndarray , __lowerCamelCase : np.ndarray , __lowerCamelCase : int , __lowerCamelCase : int ):
assert classes > dimensions
# Check if features have been already loaded
if features.any:
snake_case , snake_case : str = eigh(
covariance_between_classes(__lowerCamelCase , __lowerCamelCase , __lowerCamelCase ) , covariance_within_classes(__lowerCamelCase , __lowerCamelCase , __lowerCamelCase ) , )
snake_case : str = eigenvectors[:, ::-1][:, :dimensions]
snake_case , snake_case , snake_case : int = np.linalg.svd(__lowerCamelCase )
snake_case : List[Any] = svd_matrix[:, 0:dimensions]
snake_case : Optional[Any] = np.dot(filtered_svd_matrix.T , __lowerCamelCase )
logging.info("Linear Discriminant Analysis computed" )
return projected_data
else:
logging.basicConfig(level=logging.ERROR , format="%(message)s" , force=__lowerCamelCase )
logging.error("Dataset empty" )
raise AssertionError
def UpperCamelCase ( ):
# Create dummy dataset with 2 classes and 3 features
snake_case : str = np.array([[1, 2, 3, 4, 5], [2, 3, 4, 5, 6], [3, 4, 5, 6, 7]] )
snake_case : Union[str, Any] = np.array([0, 0, 0, 1, 1] )
snake_case : List[Any] = 2
snake_case : Any = 2
# Assert that the function raises an AssertionError if dimensions > classes
with pytest.raises(__lowerCamelCase ) as error_info:
snake_case : str = linear_discriminant_analysis(
__lowerCamelCase , __lowerCamelCase , __lowerCamelCase , __lowerCamelCase )
if isinstance(__lowerCamelCase , np.ndarray ):
raise AssertionError(
"Did not raise AssertionError for dimensions > classes" )
assert error_info.type is AssertionError
def UpperCamelCase ( ):
snake_case : List[str] = np.array([[1, 2, 3], [4, 5, 6], [7, 8, 9]] )
snake_case : List[str] = 2
snake_case : int = np.array([[6.9282_0323, 8.6602_5404, 10.3923_0485], [3.0, 3.0, 3.0]] )
with pytest.raises(__lowerCamelCase ) as error_info:
snake_case : Union[str, Any] = principal_component_analysis(__lowerCamelCase , __lowerCamelCase )
if not np.allclose(__lowerCamelCase , __lowerCamelCase ):
raise AssertionError
assert error_info.type is AssertionError
if __name__ == "__main__":
import doctest
doctest.testmod()
| 59
| 1
|
from typing import TYPE_CHECKING
from ...utils import OptionalDependencyNotAvailable, _LazyModule, is_torch_available
__lowerCamelCase = {
"""configuration_jukebox""": [
"""JUKEBOX_PRETRAINED_CONFIG_ARCHIVE_MAP""",
"""JukeboxConfig""",
"""JukeboxPriorConfig""",
"""JukeboxVQVAEConfig""",
],
"""tokenization_jukebox""": ["""JukeboxTokenizer"""],
}
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = [
"""JUKEBOX_PRETRAINED_MODEL_ARCHIVE_LIST""",
"""JukeboxModel""",
"""JukeboxPreTrainedModel""",
"""JukeboxVQVAE""",
"""JukeboxPrior""",
]
if TYPE_CHECKING:
from .configuration_jukebox import (
JUKEBOX_PRETRAINED_CONFIG_ARCHIVE_MAP,
JukeboxConfig,
JukeboxPriorConfig,
JukeboxVQVAEConfig,
)
from .tokenization_jukebox import JukeboxTokenizer
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_jukebox import (
JUKEBOX_PRETRAINED_MODEL_ARCHIVE_LIST,
JukeboxModel,
JukeboxPreTrainedModel,
JukeboxPrior,
JukeboxVQVAE,
)
else:
import sys
__lowerCamelCase = _LazyModule(__name__, globals()["""__file__"""], _import_structure, module_spec=__spec__)
| 59
|
import pytest
from datasets import inspect_metric, list_metrics, load_metric
@pytest.fixture
def UpperCamelCase ( __lowerCamelCase : Optional[int] ):
monkeypatch.setattr("datasets.utils.deprecation_utils._emitted_deprecation_warnings" , set() )
@pytest.fixture
def UpperCamelCase ( __lowerCamelCase : str ):
class UpperCAmelCase :
def __init__(self : Optional[int] , snake_case__ : str ) -> Any:
'''simple docstring'''
snake_case : List[str] = metric_id
class UpperCAmelCase :
A__ : List[str] = [MetricMock(A_ ) for metric_id in ["accuracy", "mse", "precision", "codeparrot/apps_metric"]]
def _SCREAMING_SNAKE_CASE (self : int ) -> List[str]:
'''simple docstring'''
return self._metrics
monkeypatch.setattr("datasets.inspect.huggingface_hub" , HfhMock() )
@pytest.mark.parametrize(
"func, args" , [(load_metric, ("metrics/mse",)), (list_metrics, ()), (inspect_metric, ("metrics/mse", "tmp_path"))] )
def UpperCamelCase ( __lowerCamelCase : Optional[int] , __lowerCamelCase : Any , __lowerCamelCase : Any , __lowerCamelCase : int , __lowerCamelCase : Any ):
if "tmp_path" in args:
snake_case : str = tuple(arg if arg != "tmp_path" else tmp_path for arg in args )
with pytest.warns(__lowerCamelCase , match="https://huggingface.co/docs/evaluate" ):
func(*__lowerCamelCase )
| 59
| 1
|
from dataclasses import dataclass
from enum import Enum
from typing import List, Optional, Union
import numpy as np
import PIL
from PIL import Image
from ...utils import BaseOutput, is_torch_available, is_transformers_available
@dataclass
class UpperCAmelCase ( A_ ):
A__ : Union[List[PIL.Image.Image], np.ndarray]
A__ : Optional[List[bool]]
if is_transformers_available() and is_torch_available():
from .pipeline_semantic_stable_diffusion import SemanticStableDiffusionPipeline
| 59
|
import argparse
import dataclasses
import json
import logging
import os
import shutil
from typing import List, Optional
import datasets
from accelerate import Accelerator
from datasets import load_dataset
from finetuning import finetune
from tqdm.auto import tqdm
import transformers
from transformers import AutoConfig, set_seed
from transformers.trainer_utils import IntervalStrategy
__lowerCamelCase = logging.getLogger(__name__)
__lowerCamelCase = """pytorch_model.bin"""
@dataclasses.dataclass
class UpperCAmelCase :
A__ : str = dataclasses.field(
metadata={"help": "Path to pretrained model or model identifier from huggingface.co/models."} )
A__ : Optional[str] = dataclasses.field(
default=A_ ,metadata={"help": "Where do you want to store the pretrained models downloaded from huggingface.co."} ,)
@dataclasses.dataclass
class UpperCAmelCase :
A__ : str = dataclasses.field(metadata={"help": "A csv or a json file containing the training data."} )
A__ : str = dataclasses.field(metadata={"help": "A csv or a json file containing the data to predict on."} )
A__ : Optional[str] = dataclasses.field(
default=A_ ,metadata={"help": "A csv or a json file containing the validation data."} )
A__ : Optional[str] = dataclasses.field(
default=A_ ,metadata={"help": "The name of the task to train on."} ,)
A__ : Optional[List[str]] = dataclasses.field(
default=A_ ,metadata={"help": "The list of labels for the task."} )
@dataclasses.dataclass
class UpperCAmelCase :
A__ : str = dataclasses.field(
metadata={"help": "The output directory where the model predictions and checkpoints will be written."} )
A__ : Optional[str] = dataclasses.field(
default="accuracy" ,metadata={"help": "The evaluation metric used for the task."} )
A__ : Optional[str] = dataclasses.field(
default="no" ,metadata={
"help": "The evaluation strategy to adopt during training. Possible values are: [\"no\", \"step\", \"epoch]"
} ,)
A__ : Optional[int] = dataclasses.field(
default=10 ,metadata={"help": "Number of evaluation calls with no improvement after which training will be stopped."} ,)
A__ : Optional[float] = dataclasses.field(
default=0.0 ,metadata={
"help": "How much the specified evaluation metric must improve to satisfy early stopping conditions."
} ,)
A__ : Optional[bool] = dataclasses.field(
default=A_ ,metadata={"help": "Whether to filter the pseudo-labeled data based on the confidence score."} ,)
A__ : Optional[bool] = dataclasses.field(
default=A_ ,metadata={"help": "Whether to filter the pseudo-labeled data based on the validation performance."} ,)
A__ : Optional[bool] = dataclasses.field(
default=A_ ,metadata={"help": "Whether to fine-tune on labeled data after pseudo training."} ,)
A__ : Optional[float] = dataclasses.field(
default=0.0 ,metadata={"help": "Confidence threshold for pseudo-labeled data filtering."} ,)
A__ : Optional[int] = dataclasses.field(
default=1_00 ,metadata={"help": "Number of evaluation calls with no improvement after which training will be stopped."} ,)
A__ : Optional[int] = dataclasses.field(
default=A_ ,metadata={"help": "Random seed for initialization."} ,)
def UpperCamelCase ( __lowerCamelCase : int , __lowerCamelCase : Tuple , __lowerCamelCase : Union[str, Any] , __lowerCamelCase : Tuple , __lowerCamelCase : Dict , __lowerCamelCase : Optional[int] ):
snake_case : Tuple = datasets.concatenate_datasets([infer_input, infer_output] , axis=1 )
if args.do_filter_by_confidence:
snake_case : Optional[int] = dataset.filter(lambda __lowerCamelCase : example["probability"] > args.confidence_threshold )
if args.do_filter_by_val_performance:
assert eval_result >= 0.0 and eval_result <= 1.0
snake_case : int = int(eval_result * len(__lowerCamelCase ) )
print(__lowerCamelCase )
snake_case : List[str] = dataset.sort("probability" , reverse=__lowerCamelCase )
snake_case : Tuple = dataset.select(range(__lowerCamelCase ) )
snake_case : List[Any] = dataset.remove_columns(["label", "probability"] )
snake_case : Any = dataset.rename_column("prediction" , "label" )
snake_case : str = dataset.map(lambda __lowerCamelCase : {"label": idalabel[example["label"]]} )
snake_case : List[str] = dataset.shuffle(seed=args.seed )
snake_case : int = os.path.join(__lowerCamelCase , f"""train_pseudo.{args.data_file_extension}""" )
if args.data_file_extension == "csv":
dataset.to_csv(__lowerCamelCase , index=__lowerCamelCase )
else:
dataset.to_json(__lowerCamelCase )
def UpperCamelCase ( __lowerCamelCase : Optional[int] , __lowerCamelCase : str , __lowerCamelCase : Optional[int] , __lowerCamelCase : Tuple , **__lowerCamelCase : List[Any] ):
snake_case : int = Accelerator()
# Make one log on every process with the configuration for debugging.
logging.basicConfig(
format="%(asctime)s - %(levelname)s - %(name)s - %(message)s" , datefmt="%m/%d/%Y %H:%M:%S" , level=logging.INFO , )
logger.info(accelerator.state )
# Setup logging, we only want one process per machine to log things on the
# screen. accelerator.is_local_main_process is only True for one process per
# machine.
logger.setLevel(logging.INFO if accelerator.is_local_main_process else logging.ERROR )
if accelerator.is_local_main_process:
datasets.utils.logging.set_verbosity_warning()
transformers.utils.logging.set_verbosity_info()
else:
datasets.utils.logging.set_verbosity_error()
transformers.utils.logging.set_verbosity_error()
snake_case : Dict = STModelArguments(model_name_or_path=__lowerCamelCase )
snake_case : Tuple = STDataArguments(train_file=__lowerCamelCase , infer_file=__lowerCamelCase )
snake_case : str = STTrainingArguments(output_dir=__lowerCamelCase )
snake_case : int = argparse.Namespace()
for arg_class in (model_args, data_args, training_args):
for key, value in vars(__lowerCamelCase ).items():
setattr(__lowerCamelCase , __lowerCamelCase , __lowerCamelCase )
for key, value in kwargs.items():
if hasattr(__lowerCamelCase , __lowerCamelCase ):
setattr(__lowerCamelCase , __lowerCamelCase , __lowerCamelCase )
# Sanity checks
snake_case : List[str] = {}
snake_case : Optional[int] = None
# You need to provide the training data and the data to predict on
assert args.train_file is not None
assert args.infer_file is not None
snake_case : str = args.train_file
snake_case : Tuple = args.infer_file
if args.evaluation_strategy != IntervalStrategy.NO.value:
assert args.eval_file is not None
snake_case : Tuple = args.eval_file
for key in data_files:
snake_case : List[Any] = data_files[key].split("." )[-1]
assert extension in ["csv", "json"], f"""`{key}_file` should be a csv or a json file."""
if args.data_file_extension is None:
snake_case : Union[str, Any] = extension
else:
assert extension == args.data_file_extension, f"""`{key}_file` should be a {args.data_file_extension} file`."""
assert (
args.eval_metric in datasets.list_metrics()
), f"""{args.eval_metric} not in the list of supported metrics {datasets.list_metrics()}."""
# If passed along, set the training seed now.
if args.seed is not None:
set_seed(args.seed )
logger.info("Creating the initial data directory for self-training..." )
snake_case : List[Any] = f"""{args.output_dir}/self-train_iter-{{}}""".format
snake_case : Optional[int] = data_dir_format(0 )
if accelerator.is_main_process:
if args.output_dir is not None:
os.makedirs(args.output_dir , exist_ok=__lowerCamelCase )
os.makedirs(__lowerCamelCase , exist_ok=__lowerCamelCase )
accelerator.wait_for_everyone()
snake_case : Dict = None
snake_case : Union[str, Any] = None
snake_case : Tuple = 0
snake_case : List[Any] = False
# Show the progress bar
snake_case : List[Any] = tqdm(range(args.max_selftrain_iterations ) , disable=not accelerator.is_local_main_process )
# Self-train
for iteration in range(0 , int(args.max_selftrain_iterations ) ):
snake_case : str = data_dir_format(__lowerCamelCase )
assert os.path.exists(__lowerCamelCase )
# Stage 1: initial fine-tuning for iteration = 0 or pseudo-training for
# iteration > 0
snake_case : Dict = os.path.join(__lowerCamelCase , "stage-1" )
snake_case : Optional[Any] = {
"accelerator": accelerator,
"model_name_or_path": args.model_name_or_path,
"cache_dir": args.cache_dir,
"do_train": True,
"train_file": data_files["train"] if iteration == 0 else data_files["train_pseudo"],
"do_eval": True if args.eval_file is not None else False,
"eval_file": data_files["eval"],
"do_predict": True,
"infer_file": data_files["infer"],
"task_name": args.task_name,
"label_list": args.label_list,
"output_dir": current_output_dir,
"eval_metric": args.eval_metric,
"evaluation_strategy": args.evaluation_strategy,
"early_stopping_patience": args.early_stopping_patience,
"early_stopping_threshold": args.early_stopping_threshold,
"seed": args.seed,
}
# Add additional training arguments
for key, value in kwargs.items():
if key not in arguments_dict and not hasattr(__lowerCamelCase , __lowerCamelCase ):
arguments_dict.update({key: value} )
snake_case : int = os.path.join(__lowerCamelCase , "best-checkpoint" , __lowerCamelCase )
if os.path.exists(__lowerCamelCase ):
logger.info(
"Found existing model checkpoint at %s. Skipping self-training: iteration: %d, stage: 1." , __lowerCamelCase , __lowerCamelCase , )
else:
logger.info("***** Running self-training: iteration: %d, stage: 1 *****" , __lowerCamelCase )
finetune(**__lowerCamelCase )
accelerator.wait_for_everyone()
assert os.path.exists(__lowerCamelCase )
logger.info("Self-training job completed: iteration: %d, stage: 1." , __lowerCamelCase )
if iteration > 0 and args.finetune_on_labeled_data:
# Stage 2 (optional): fine-tuning on the original labeled data
snake_case : str = os.path.join(__lowerCamelCase , "best-checkpoint" )
snake_case : Dict = os.path.join(__lowerCamelCase , "stage-2" )
# Update arguments_dict
snake_case : List[str] = model_path
snake_case : Optional[Any] = data_files["train"]
snake_case : Optional[Any] = current_output_dir
snake_case : Union[str, Any] = os.path.join(__lowerCamelCase , "best-checkpoint" , __lowerCamelCase )
if os.path.exists(__lowerCamelCase ):
logger.info(
"Found existing model checkpoint at %s. Skipping self-training: iteration: %d, stage: 2." , __lowerCamelCase , __lowerCamelCase , )
else:
logger.info("***** Running self-training: iteration: %d, stage: 2 *****" , __lowerCamelCase )
finetune(**__lowerCamelCase )
accelerator.wait_for_everyone()
assert os.path.exists(__lowerCamelCase )
logger.info("Self-training job completed: iteration: %d, stage: 2." , __lowerCamelCase )
snake_case : int = iteration
snake_case : Tuple = data_dir_format(iteration + 1 )
snake_case : Tuple = AutoConfig.from_pretrained(os.path.join(__lowerCamelCase , "best-checkpoint" ) )
snake_case : Optional[int] = config.idalabel
snake_case : List[Any] = os.path.join(__lowerCamelCase , "eval_results_best-checkpoint.json" )
snake_case : Union[str, Any] = os.path.join(__lowerCamelCase , "test_results_best-checkpoint.json" )
assert os.path.exists(__lowerCamelCase )
with open(__lowerCamelCase , "r" ) as f:
snake_case : Dict = float(json.load(__lowerCamelCase )[args.eval_metric] )
snake_case : Optional[int] = os.path.join(__lowerCamelCase , "infer_output_best-checkpoint.csv" )
assert os.path.exists(__lowerCamelCase )
# Loading the dataset from local csv or json files.
snake_case : Optional[Any] = load_dataset(args.data_file_extension , data_files={"data": data_files["infer"]} )["data"]
snake_case : Dict = load_dataset("csv" , data_files={"data": infer_output_file} )["data"]
if accelerator.is_main_process:
os.makedirs(__lowerCamelCase , exist_ok=__lowerCamelCase )
shutil.copy(__lowerCamelCase , os.path.join(__lowerCamelCase , f"""eval_results_iter-{iteration}.json""" ) )
if os.path.exists(__lowerCamelCase ):
shutil.copy(__lowerCamelCase , os.path.join(__lowerCamelCase , f"""test_results_iter-{iteration}.json""" ) )
create_pseudo_labeled_data(__lowerCamelCase , __lowerCamelCase , __lowerCamelCase , __lowerCamelCase , __lowerCamelCase , __lowerCamelCase )
accelerator.wait_for_everyone()
snake_case : str = os.path.join(__lowerCamelCase , f"""train_pseudo.{args.data_file_extension}""" )
if args.evaluation_strategy != IntervalStrategy.NO.value:
snake_case : List[Any] = eval_result
if best_iteration is None:
snake_case : List[Any] = new_iteration
snake_case : int = new_eval_result
else:
if new_eval_result - best_eval_result > args.early_stopping_threshold:
snake_case : int = new_iteration
snake_case : Union[str, Any] = new_eval_result
snake_case : str = 0
else:
if new_eval_result == best_eval_result:
snake_case : Any = new_iteration
snake_case : Union[str, Any] = new_eval_result
early_stopping_patience_counter += 1
if early_stopping_patience_counter >= args.early_stopping_patience:
snake_case : Tuple = True
progress_bar.update(1 )
if should_training_stop:
break
if best_iteration is not None:
# Save the best iteration
logger.info("Best iteration: %d" , __lowerCamelCase )
logger.info("Best evaluation result: %s = %f" , args.eval_metric , __lowerCamelCase )
accelerator.wait_for_everyone()
if accelerator.is_main_process:
shutil.copy(
os.path.join(__lowerCamelCase , f"""eval_results_iter-{iteration}.json""" ) , os.path.join(__lowerCamelCase , "eval_results_best-iteration.json" ) , )
else:
# Assume that the last iteration is the best
logger.info("Best iteration: %d" , args.max_selftrain_iterations - 1 )
logger.info("Best evaluation result: %s = %f" , args.eval_metric , __lowerCamelCase )
accelerator.wait_for_everyone()
if accelerator.is_main_process:
shutil.copy(
os.path.join(__lowerCamelCase , f"""eval_results_iter-{args.max_selftrain_iterations - 1}.json""" ) , os.path.join(__lowerCamelCase , "eval_results_best-iteration.json" ) , )
| 59
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|
import fire
from transformers import AutoConfig, AutoModelForSeqaSeqLM, AutoTokenizer
def UpperCamelCase ( __lowerCamelCase : str , __lowerCamelCase : str , **__lowerCamelCase : Optional[int] ):
snake_case : int = AutoConfig.from_pretrained(__lowerCamelCase , **__lowerCamelCase )
snake_case : Any = AutoModelForSeqaSeqLM.from_config(__lowerCamelCase )
model.save_pretrained(__lowerCamelCase )
AutoTokenizer.from_pretrained(__lowerCamelCase ).save_pretrained(__lowerCamelCase )
return model
if __name__ == "__main__":
fire.Fire(save_randomly_initialized_version)
| 59
|
from typing import TYPE_CHECKING
from ...utils import (
OptionalDependencyNotAvailable,
_LazyModule,
is_flax_available,
is_sentencepiece_available,
is_tf_available,
is_tokenizers_available,
is_torch_available,
)
__lowerCamelCase = {"""configuration_xglm""": ["""XGLM_PRETRAINED_CONFIG_ARCHIVE_MAP""", """XGLMConfig"""]}
try:
if not is_sentencepiece_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = ["""XGLMTokenizer"""]
try:
if not is_tokenizers_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = ["""XGLMTokenizerFast"""]
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = [
"""XGLM_PRETRAINED_MODEL_ARCHIVE_LIST""",
"""XGLMForCausalLM""",
"""XGLMModel""",
"""XGLMPreTrainedModel""",
]
try:
if not is_flax_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = [
"""FlaxXGLMForCausalLM""",
"""FlaxXGLMModel""",
"""FlaxXGLMPreTrainedModel""",
]
try:
if not is_tf_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = [
"""TF_XGLM_PRETRAINED_MODEL_ARCHIVE_LIST""",
"""TFXGLMForCausalLM""",
"""TFXGLMModel""",
"""TFXGLMPreTrainedModel""",
]
if TYPE_CHECKING:
from .configuration_xglm import XGLM_PRETRAINED_CONFIG_ARCHIVE_MAP, XGLMConfig
try:
if not is_sentencepiece_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .tokenization_xglm import XGLMTokenizer
try:
if not is_tokenizers_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .tokenization_xglm_fast import XGLMTokenizerFast
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_xglm import XGLM_PRETRAINED_MODEL_ARCHIVE_LIST, XGLMForCausalLM, XGLMModel, XGLMPreTrainedModel
try:
if not is_flax_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_flax_xglm import FlaxXGLMForCausalLM, FlaxXGLMModel, FlaxXGLMPreTrainedModel
try:
if not is_tf_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_tf_xglm import (
TF_XGLM_PRETRAINED_MODEL_ARCHIVE_LIST,
TFXGLMForCausalLM,
TFXGLMModel,
TFXGLMPreTrainedModel,
)
else:
import sys
__lowerCamelCase = _LazyModule(__name__, globals()["""__file__"""], _import_structure)
| 59
| 1
|
import copy
import os
import cva
import numpy as np
from matplotlib import pyplot as plt
class UpperCAmelCase :
def __init__(self : List[str] ) -> Any:
'''simple docstring'''
snake_case : Tuple = ""
snake_case : str = ""
snake_case : Dict = []
snake_case : str = 0
snake_case : Tuple = 2_56
snake_case : Optional[Any] = 0
snake_case : Union[str, Any] = 0
snake_case : Any = 0
snake_case : Union[str, Any] = 0
def _SCREAMING_SNAKE_CASE (self : List[Any] , snake_case__ : Tuple ) -> List[Any]:
'''simple docstring'''
snake_case : Optional[Any] = cva.imread(snake_case__ , 0 )
snake_case : Union[str, Any] = copy.deepcopy(self.img )
snake_case , snake_case , snake_case : Tuple = plt.hist(self.img.ravel() , 2_56 , [0, 2_56] , label="x" )
snake_case : Any = np.sum(snake_case__ )
for i in range(len(snake_case__ ) ):
snake_case : Union[str, Any] = x[i] / self.k
self.sk += prk
snake_case : Optional[Any] = (self.L - 1) * self.sk
if self.rem != 0:
snake_case : List[str] = int(last % last )
snake_case : List[str] = int(last + 1 if self.rem >= 0.5 else last )
self.last_list.append(snake_case__ )
snake_case : int = int(np.ma.count(self.img ) / self.img[1].size )
snake_case : Optional[int] = self.img[1].size
for i in range(self.number_of_cols ):
for j in range(self.number_of_rows ):
snake_case : Union[str, Any] = self.img[j][i]
if num != self.last_list[num]:
snake_case : Dict = self.last_list[num]
cva.imwrite("output_data/output.jpg" , self.img )
def _SCREAMING_SNAKE_CASE (self : List[Any] ) -> List[Any]:
'''simple docstring'''
plt.hist(self.img.ravel() , 2_56 , [0, 2_56] )
def _SCREAMING_SNAKE_CASE (self : str ) -> int:
'''simple docstring'''
cva.imshow("Output-Image" , self.img )
cva.imshow("Input-Image" , self.original_image )
cva.waitKey(50_00 )
cva.destroyAllWindows()
if __name__ == "__main__":
__lowerCamelCase = os.path.join(os.path.basename(__file__), """image_data/input.jpg""")
__lowerCamelCase = ConstantStretch()
stretcher.stretch(file_path)
stretcher.plot_histogram()
stretcher.show_image()
| 59
|
from ...configuration_utils import PretrainedConfig
from ...utils import logging
__lowerCamelCase = logging.get_logger(__name__)
__lowerCamelCase = {
# See all MEGATRON_BERT models at https://huggingface.co/models?filter=bert
}
class UpperCAmelCase ( A_ ):
A__ : List[str] = "megatron-bert"
def __init__(self : Optional[int] , snake_case__ : List[str]=2_90_56 , snake_case__ : List[Any]=10_24 , snake_case__ : str=24 , snake_case__ : Tuple=16 , snake_case__ : Union[str, Any]=40_96 , snake_case__ : str="gelu" , snake_case__ : str=0.1 , snake_case__ : Optional[int]=0.1 , snake_case__ : Tuple=5_12 , snake_case__ : Union[str, Any]=2 , snake_case__ : Dict=0.02 , snake_case__ : List[Any]=1e-12 , snake_case__ : int=0 , snake_case__ : Tuple="absolute" , snake_case__ : Any=True , **snake_case__ : Union[str, Any] , ) -> Optional[Any]:
'''simple docstring'''
super().__init__(pad_token_id=snake_case__ , **snake_case__ )
snake_case : Tuple = vocab_size
snake_case : str = hidden_size
snake_case : str = num_hidden_layers
snake_case : str = num_attention_heads
snake_case : Optional[int] = hidden_act
snake_case : int = intermediate_size
snake_case : List[str] = hidden_dropout_prob
snake_case : Union[str, Any] = attention_probs_dropout_prob
snake_case : Dict = max_position_embeddings
snake_case : List[str] = type_vocab_size
snake_case : List[str] = initializer_range
snake_case : Tuple = layer_norm_eps
snake_case : int = position_embedding_type
snake_case : str = use_cache
| 59
| 1
|
from unittest import TestCase
from datasets import Sequence, Value
from datasets.arrow_dataset import Dataset
class UpperCAmelCase ( A_ ):
def _SCREAMING_SNAKE_CASE (self : str ) -> List[Any]:
'''simple docstring'''
return [
{"col_1": 3, "col_2": "a"},
{"col_1": 2, "col_2": "b"},
{"col_1": 1, "col_2": "c"},
{"col_1": 0, "col_2": "d"},
]
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> Tuple:
'''simple docstring'''
snake_case : List[Any] = {"col_1": [3, 2, 1, 0], "col_2": ["a", "b", "c", "d"]}
return Dataset.from_dict(snake_case__ )
def _SCREAMING_SNAKE_CASE (self : int ) -> Union[str, Any]:
'''simple docstring'''
snake_case : Tuple = self._create_example_records()
snake_case : Tuple = Dataset.from_list(snake_case__ )
self.assertListEqual(dset.column_names , ["col_1", "col_2"] )
for i, r in enumerate(snake_case__ ):
self.assertDictEqual(snake_case__ , example_records[i] )
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> Optional[Any]:
'''simple docstring'''
snake_case : Any = self._create_example_records()
snake_case : Union[str, Any] = Dataset.from_list(snake_case__ )
snake_case : Tuple = Dataset.from_dict({k: [r[k] for r in example_records] for k in example_records[0]} )
self.assertEqual(dset.info , dset_from_dict.info )
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> str: # checks what happens with missing columns
'''simple docstring'''
snake_case : str = [{"col_1": 1}, {"col_2": "x"}]
snake_case : str = Dataset.from_list(snake_case__ )
self.assertDictEqual(dset[0] , {"col_1": 1} )
self.assertDictEqual(dset[1] , {"col_1": None} ) # NB: first record is used for columns
def _SCREAMING_SNAKE_CASE (self : str ) -> List[Any]: # checks if the type can be inferred from the second record
'''simple docstring'''
snake_case : Optional[Any] = [{"col_1": []}, {"col_1": [1, 2]}]
snake_case : str = Dataset.from_list(snake_case__ )
self.assertEqual(dset.info.features["col_1"] , Sequence(Value("int64" ) ) )
def _SCREAMING_SNAKE_CASE (self : Union[str, Any] ) -> List[str]:
'''simple docstring'''
snake_case : List[Any] = Dataset.from_list([] )
self.assertEqual(len(snake_case__ ) , 0 )
self.assertListEqual(dset.column_names , [] )
| 59
|
import gc
import unittest
from parameterized import parameterized
from diffusers import FlaxUNetaDConditionModel
from diffusers.utils import is_flax_available
from diffusers.utils.testing_utils import load_hf_numpy, require_flax, slow
if is_flax_available():
import jax
import jax.numpy as jnp
@slow
@require_flax
class UpperCAmelCase ( unittest.TestCase ):
def _SCREAMING_SNAKE_CASE (self : str , snake_case__ : Union[str, Any] , snake_case__ : List[str] ) -> List[str]:
'''simple docstring'''
return f"""gaussian_noise_s={seed}_shape={'_'.join([str(snake_case__ ) for s in shape] )}.npy"""
def _SCREAMING_SNAKE_CASE (self : Tuple ) -> int:
'''simple docstring'''
super().tearDown()
gc.collect()
def _SCREAMING_SNAKE_CASE (self : str , snake_case__ : Optional[Any]=0 , snake_case__ : Any=(4, 4, 64, 64) , snake_case__ : List[Any]=False ) -> int:
'''simple docstring'''
snake_case : Optional[Any] = jnp.bfloataa if fpaa else jnp.floataa
snake_case : Optional[int] = jnp.array(load_hf_numpy(self.get_file_format(snake_case__ , snake_case__ ) ) , dtype=snake_case__ )
return image
def _SCREAMING_SNAKE_CASE (self : Optional[int] , snake_case__ : Tuple=False , snake_case__ : List[Any]="CompVis/stable-diffusion-v1-4" ) -> List[Any]:
'''simple docstring'''
snake_case : List[str] = jnp.bfloataa if fpaa else jnp.floataa
snake_case : str = "bf16" if fpaa else None
snake_case , snake_case : Optional[int] = FlaxUNetaDConditionModel.from_pretrained(
snake_case__ , subfolder="unet" , dtype=snake_case__ , revision=snake_case__ )
return model, params
def _SCREAMING_SNAKE_CASE (self : List[str] , snake_case__ : Union[str, Any]=0 , snake_case__ : Union[str, Any]=(4, 77, 7_68) , snake_case__ : Dict=False ) -> List[str]:
'''simple docstring'''
snake_case : Any = jnp.bfloataa if fpaa else jnp.floataa
snake_case : Any = jnp.array(load_hf_numpy(self.get_file_format(snake_case__ , snake_case__ ) ) , dtype=snake_case__ )
return hidden_states
@parameterized.expand(
[
# fmt: off
[83, 4, [-0.2323, -0.1304, 0.0813, -0.3093, -0.0919, -0.1571, -0.1125, -0.5806]],
[17, 0.55, [-0.0831, -0.2443, 0.0901, -0.0919, 0.3396, 0.0103, -0.3743, 0.0701]],
[8, 0.89, [-0.4863, 0.0859, 0.0875, -0.1658, 0.9199, -0.0114, 0.4839, 0.4639]],
[3, 10_00, [-0.5649, 0.2402, -0.5518, 0.1248, 1.1328, -0.2443, -0.0325, -1.0078]],
# fmt: on
] )
def _SCREAMING_SNAKE_CASE (self : Optional[int] , snake_case__ : int , snake_case__ : Optional[int] , snake_case__ : Dict ) -> List[str]:
'''simple docstring'''
snake_case , snake_case : List[str] = self.get_unet_model(model_id="CompVis/stable-diffusion-v1-4" , fpaa=snake_case__ )
snake_case : Union[str, Any] = self.get_latents(snake_case__ , fpaa=snake_case__ )
snake_case : List[str] = self.get_encoder_hidden_states(snake_case__ , fpaa=snake_case__ )
snake_case : Dict = model.apply(
{"params": params} , snake_case__ , jnp.array(snake_case__ , dtype=jnp.intaa ) , encoder_hidden_states=snake_case__ , ).sample
assert sample.shape == latents.shape
snake_case : Optional[Any] = jnp.asarray(jax.device_get((sample[-1, -2:, -2:, :2].flatten()) ) , dtype=jnp.floataa )
snake_case : Optional[int] = jnp.array(snake_case__ , dtype=jnp.floataa )
# Found torch (float16) and flax (bfloat16) outputs to be within this tolerance, in the same hardware
assert jnp.allclose(snake_case__ , snake_case__ , atol=1e-2 )
@parameterized.expand(
[
# fmt: off
[83, 4, [0.1514, 0.0807, 0.1624, 0.1016, -0.1896, 0.0263, 0.0677, 0.2310]],
[17, 0.55, [0.1164, -0.0216, 0.0170, 0.1589, -0.3120, 0.1005, -0.0581, -0.1458]],
[8, 0.89, [-0.1758, -0.0169, 0.1004, -0.1411, 0.1312, 0.1103, -0.1996, 0.2139]],
[3, 10_00, [0.1214, 0.0352, -0.0731, -0.1562, -0.0994, -0.0906, -0.2340, -0.0539]],
# fmt: on
] )
def _SCREAMING_SNAKE_CASE (self : Optional[int] , snake_case__ : Optional[int] , snake_case__ : str , snake_case__ : Tuple ) -> str:
'''simple docstring'''
snake_case , snake_case : List[Any] = self.get_unet_model(model_id="stabilityai/stable-diffusion-2" , fpaa=snake_case__ )
snake_case : List[str] = self.get_latents(snake_case__ , shape=(4, 4, 96, 96) , fpaa=snake_case__ )
snake_case : Union[str, Any] = self.get_encoder_hidden_states(snake_case__ , shape=(4, 77, 10_24) , fpaa=snake_case__ )
snake_case : Optional[int] = model.apply(
{"params": params} , snake_case__ , jnp.array(snake_case__ , dtype=jnp.intaa ) , encoder_hidden_states=snake_case__ , ).sample
assert sample.shape == latents.shape
snake_case : int = jnp.asarray(jax.device_get((sample[-1, -2:, -2:, :2].flatten()) ) , dtype=jnp.floataa )
snake_case : Dict = jnp.array(snake_case__ , dtype=jnp.floataa )
# Found torch (float16) and flax (bfloat16) outputs to be within this tolerance, on the same hardware
assert jnp.allclose(snake_case__ , snake_case__ , atol=1e-2 )
| 59
| 1
|
def UpperCamelCase ( __lowerCamelCase : int , __lowerCamelCase : int ):
if b == 0:
return 1
if (b % 2) == 0:
return actual_power(__lowerCamelCase , int(b / 2 ) ) * actual_power(__lowerCamelCase , int(b / 2 ) )
else:
return a * actual_power(__lowerCamelCase , int(b / 2 ) ) * actual_power(__lowerCamelCase , int(b / 2 ) )
def UpperCamelCase ( __lowerCamelCase : int , __lowerCamelCase : int ):
if b < 0:
return 1 / actual_power(__lowerCamelCase , __lowerCamelCase )
return actual_power(__lowerCamelCase , __lowerCamelCase )
if __name__ == "__main__":
print(power(-2, -3))
| 59
|
import argparse
import re
from typing import Dict
import torch
from datasets import Audio, Dataset, load_dataset, load_metric
from transformers import AutoFeatureExtractor, pipeline
def UpperCamelCase ( __lowerCamelCase : Dataset , __lowerCamelCase : Dict[str, str] ):
snake_case : int = args.log_outputs
snake_case : Dict = "_".join(args.dataset.split("/" ) + [args.config, args.split] )
# load metric
snake_case : List[str] = load_metric("wer" )
snake_case : Tuple = load_metric("cer" )
# compute metrics
snake_case : List[Any] = wer.compute(references=result["target"] , predictions=result["prediction"] )
snake_case : int = cer.compute(references=result["target"] , predictions=result["prediction"] )
# print & log results
snake_case : int = f"""WER: {wer_result}\nCER: {cer_result}"""
print(__lowerCamelCase )
with open(f"""{dataset_id}_eval_results.txt""" , "w" ) as f:
f.write(__lowerCamelCase )
# log all results in text file. Possibly interesting for analysis
if log_outputs is not None:
snake_case : int = f"""log_{dataset_id}_predictions.txt"""
snake_case : List[Any] = f"""log_{dataset_id}_targets.txt"""
with open(__lowerCamelCase , "w" ) as p, open(__lowerCamelCase , "w" ) as t:
# mapping function to write output
def write_to_file(__lowerCamelCase : str , __lowerCamelCase : Optional[int] ):
p.write(f"""{i}""" + "\n" )
p.write(batch["prediction"] + "\n" )
t.write(f"""{i}""" + "\n" )
t.write(batch["target"] + "\n" )
result.map(__lowerCamelCase , with_indices=__lowerCamelCase )
def UpperCamelCase ( __lowerCamelCase : str ):
snake_case : List[Any] = "[,?.!\-\;\:\"“%‘”�—’…–]" # noqa: W605 IMPORTANT: this should correspond to the chars that were ignored during training
snake_case : List[Any] = re.sub(__lowerCamelCase , "" , text.lower() )
# In addition, we can normalize the target text, e.g. removing new lines characters etc...
# note that order is important here!
snake_case : Optional[Any] = ["\n\n", "\n", " ", " "]
for t in token_sequences_to_ignore:
snake_case : Dict = " ".join(text.split(__lowerCamelCase ) )
return text
def UpperCamelCase ( __lowerCamelCase : int ):
# load dataset
snake_case : str = load_dataset(args.dataset , args.config , split=args.split , use_auth_token=__lowerCamelCase )
# for testing: only process the first two examples as a test
# dataset = dataset.select(range(10))
# load processor
snake_case : List[Any] = AutoFeatureExtractor.from_pretrained(args.model_id )
snake_case : Union[str, Any] = feature_extractor.sampling_rate
# resample audio
snake_case : Union[str, Any] = dataset.cast_column("audio" , Audio(sampling_rate=__lowerCamelCase ) )
# load eval pipeline
if args.device is None:
snake_case : List[str] = 0 if torch.cuda.is_available() else -1
snake_case : str = pipeline("automatic-speech-recognition" , model=args.model_id , device=args.device )
# map function to decode audio
def map_to_pred(__lowerCamelCase : int ):
snake_case : Dict = asr(
batch["audio"]["array"] , chunk_length_s=args.chunk_length_s , stride_length_s=args.stride_length_s )
snake_case : str = prediction["text"]
snake_case : Tuple = normalize_text(batch["sentence"] )
return batch
# run inference on all examples
snake_case : Dict = dataset.map(__lowerCamelCase , remove_columns=dataset.column_names )
# compute and log_results
# do not change function below
log_results(__lowerCamelCase , __lowerCamelCase )
if __name__ == "__main__":
__lowerCamelCase = argparse.ArgumentParser()
parser.add_argument(
"""--model_id""", type=str, required=True, help="""Model identifier. Should be loadable with 🤗 Transformers"""
)
parser.add_argument(
"""--dataset""",
type=str,
required=True,
help="""Dataset name to evaluate the `model_id`. Should be loadable with 🤗 Datasets""",
)
parser.add_argument(
"""--config""", type=str, required=True, help="""Config of the dataset. *E.g.* `'en'` for Common Voice"""
)
parser.add_argument("""--split""", type=str, required=True, help="""Split of the dataset. *E.g.* `'test'`""")
parser.add_argument(
"""--chunk_length_s""", type=float, default=None, help="""Chunk length in seconds. Defaults to 5 seconds."""
)
parser.add_argument(
"""--stride_length_s""", type=float, default=None, help="""Stride of the audio chunks. Defaults to 1 second."""
)
parser.add_argument(
"""--log_outputs""", action="""store_true""", help="""If defined, write outputs to log file for analysis."""
)
parser.add_argument(
"""--device""",
type=int,
default=None,
help="""The device to run the pipeline on. -1 for CPU (default), 0 for the first GPU and so on.""",
)
__lowerCamelCase = parser.parse_args()
main(args)
| 59
| 1
|
import os
from glob import glob
import imageio
import torch
import torchvision
import wandb
from img_processing import custom_to_pil, loop_post_process, preprocess, preprocess_vqgan
from loaders import load_vqgan
from PIL import Image
from torch import nn
from transformers import CLIPModel, CLIPTokenizerFast
from utils import get_device, get_timestamp, show_pil
class UpperCAmelCase :
def __init__(self : List[str] , snake_case__ : str = "cpu" , snake_case__ : str = "openai/clip-vit-large-patch14" ) -> None:
'''simple docstring'''
snake_case : int = device
snake_case : str = CLIPTokenizerFast.from_pretrained(snake_case__ )
snake_case : List[Any] = [0.48145466, 0.4578275, 0.40821073]
snake_case : Optional[int] = [0.26862954, 0.26130258, 0.27577711]
snake_case : List[Any] = torchvision.transforms.Normalize(self.image_mean , self.image_std )
snake_case : List[str] = torchvision.transforms.Resize(2_24 )
snake_case : List[Any] = torchvision.transforms.CenterCrop(2_24 )
def _SCREAMING_SNAKE_CASE (self : Optional[int] , snake_case__ : Union[str, Any] ) -> Optional[Any]:
'''simple docstring'''
snake_case : List[str] = self.resize(snake_case__ )
snake_case : Union[str, Any] = self.center_crop(snake_case__ )
snake_case : str = self.normalize(snake_case__ )
return images
def __call__(self : Optional[int] , snake_case__ : Optional[int]=None , snake_case__ : List[Any]=None , **snake_case__ : int ) -> List[Any]:
'''simple docstring'''
snake_case : Dict = self.tokenizer(text=snake_case__ , **snake_case__ )
snake_case : str = self.preprocess_img(snake_case__ )
snake_case : Any = {key: value.to(self.device ) for (key, value) in encoding.items()}
return encoding
class UpperCAmelCase ( nn.Module ):
def __init__(self : int , snake_case__ : Tuple=10 , snake_case__ : List[str]=0.01 , snake_case__ : Dict=None , snake_case__ : List[str]=None , snake_case__ : Dict=None , snake_case__ : Optional[Any]=None , snake_case__ : Union[str, Any]=None , snake_case__ : Dict=None , snake_case__ : Any=False , snake_case__ : Optional[Any]=True , snake_case__ : Any="image" , snake_case__ : str=True , snake_case__ : Any=False , snake_case__ : List[str]=False , snake_case__ : Optional[Any]=False , ) -> None:
'''simple docstring'''
super().__init__()
snake_case : List[str] = None
snake_case : Optional[int] = device if device else get_device()
if vqgan:
snake_case : List[Any] = vqgan
else:
snake_case : Tuple = load_vqgan(self.device , conf_path=snake_case__ , ckpt_path=snake_case__ )
self.vqgan.eval()
if clip:
snake_case : Any = clip
else:
snake_case : Optional[Any] = CLIPModel.from_pretrained("openai/clip-vit-base-patch32" )
self.clip.to(self.device )
snake_case : Optional[Any] = ProcessorGradientFlow(device=self.device )
snake_case : Optional[int] = iterations
snake_case : str = lr
snake_case : List[Any] = log
snake_case : Optional[int] = make_grid
snake_case : str = return_val
snake_case : List[Any] = quantize
snake_case : List[str] = self.vqgan.decoder.z_shape
def _SCREAMING_SNAKE_CASE (self : Optional[int] , snake_case__ : Dict=None , snake_case__ : Tuple=None , snake_case__ : Any=5 , snake_case__ : Optional[Any]=True ) -> Any:
'''simple docstring'''
snake_case : List[Any] = []
if output_path is None:
snake_case : List[Any] = "./animation.gif"
if input_path is None:
snake_case : Any = self.save_path
snake_case : int = sorted(glob(input_path + "/*" ) )
if not len(snake_case__ ):
raise ValueError(
"No images found in save path, aborting (did you pass save_intermediate=True to the generate"
" function?)" )
if len(snake_case__ ) == 1:
print("Only one image found in save path, (did you pass save_intermediate=True to the generate function?)" )
snake_case : List[Any] = total_duration / len(snake_case__ )
snake_case : Union[str, Any] = [frame_duration] * len(snake_case__ )
if extend_frames:
snake_case : Union[str, Any] = 1.5
snake_case : int = 3
for file_name in paths:
if file_name.endswith(".png" ):
images.append(imageio.imread(snake_case__ ) )
imageio.mimsave(snake_case__ , snake_case__ , duration=snake_case__ )
print(f"""gif saved to {output_path}""" )
def _SCREAMING_SNAKE_CASE (self : str , snake_case__ : str=None , snake_case__ : List[Any]=None ) -> Union[str, Any]:
'''simple docstring'''
if not (path or img):
raise ValueError("Input either path or tensor" )
if img is not None:
raise NotImplementedError
snake_case : Optional[Any] = preprocess(Image.open(snake_case__ ) , target_image_size=2_56 ).to(self.device )
snake_case : Any = preprocess_vqgan(snake_case__ )
snake_case , *snake_case : str = self.vqgan.encode(snake_case__ )
return z
def _SCREAMING_SNAKE_CASE (self : List[str] , snake_case__ : Tuple ) -> Optional[Any]:
'''simple docstring'''
snake_case : Dict = self.latent.detach().requires_grad_()
snake_case : Optional[int] = base_latent + transform_vector
if self.quantize:
snake_case , *snake_case : Any = self.vqgan.quantize(snake_case__ )
else:
snake_case : Union[str, Any] = trans_latent
return self.vqgan.decode(snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Dict , snake_case__ : str , snake_case__ : Optional[int] , snake_case__ : Optional[int]=None ) -> str:
'''simple docstring'''
snake_case : Any = self.clip_preprocessor(text=snake_case__ , images=snake_case__ , return_tensors="pt" , padding=snake_case__ )
snake_case : Optional[int] = self.clip(**snake_case__ )
snake_case : List[Any] = clip_outputs.logits_per_image
if weights is not None:
snake_case : Any = similarity_logits * weights
return similarity_logits.sum()
def _SCREAMING_SNAKE_CASE (self : Union[str, Any] , snake_case__ : Optional[Any] , snake_case__ : Optional[Any] , snake_case__ : Dict ) -> Optional[Any]:
'''simple docstring'''
snake_case : Any = self._get_clip_similarity(pos_prompts["prompts"] , snake_case__ , weights=(1 / pos_prompts["weights"]) )
if neg_prompts:
snake_case : Union[str, Any] = self._get_clip_similarity(neg_prompts["prompts"] , snake_case__ , weights=neg_prompts["weights"] )
else:
snake_case : Union[str, Any] = torch.tensor([1] , device=self.device )
snake_case : List[Any] = -torch.log(snake_case__ ) + torch.log(snake_case__ )
return loss
def _SCREAMING_SNAKE_CASE (self : Optional[Any] , snake_case__ : Union[str, Any] , snake_case__ : str , snake_case__ : Optional[Any] ) -> str:
'''simple docstring'''
snake_case : Union[str, Any] = torch.randn_like(self.latent , requires_grad=snake_case__ , device=self.device )
snake_case : Optional[int] = torch.optim.Adam([vector] , lr=self.lr )
for i in range(self.iterations ):
optim.zero_grad()
snake_case : Dict = self._add_vector(snake_case__ )
snake_case : Union[str, Any] = loop_post_process(snake_case__ )
snake_case : List[str] = self._get_CLIP_loss(snake_case__ , snake_case__ , snake_case__ )
print("CLIP loss" , snake_case__ )
if self.log:
wandb.log({"CLIP Loss": clip_loss} )
clip_loss.backward(retain_graph=snake_case__ )
optim.step()
if self.return_val == "image":
yield custom_to_pil(transformed_img[0] )
else:
yield vector
def _SCREAMING_SNAKE_CASE (self : Optional[int] , snake_case__ : str , snake_case__ : Union[str, Any] , snake_case__ : Optional[int] ) -> List[Any]:
'''simple docstring'''
wandb.init(reinit=snake_case__ , project="face-editor" )
wandb.config.update({"Positive Prompts": positive_prompts} )
wandb.config.update({"Negative Prompts": negative_prompts} )
wandb.config.update({"lr": self.lr, "iterations": self.iterations} )
if image_path:
snake_case : Optional[Any] = Image.open(snake_case__ )
snake_case : Dict = image.resize((2_56, 2_56) )
wandb.log("Original Image" , wandb.Image(snake_case__ ) )
def _SCREAMING_SNAKE_CASE (self : Dict , snake_case__ : Union[str, Any] ) -> Optional[int]:
'''simple docstring'''
if not prompts:
return []
snake_case : Tuple = []
snake_case : List[str] = []
if isinstance(snake_case__ , snake_case__ ):
snake_case : Union[str, Any] = [prompt.strip() for prompt in prompts.split("|" )]
for prompt in prompts:
if isinstance(snake_case__ , (tuple, list) ):
snake_case : Tuple = prompt[0]
snake_case : Optional[int] = float(prompt[1] )
elif ":" in prompt:
snake_case , snake_case : Optional[int] = prompt.split(":" )
snake_case : List[str] = float(snake_case__ )
else:
snake_case : Optional[Any] = prompt
snake_case : Tuple = 1.0
processed_prompts.append(snake_case__ )
weights.append(snake_case__ )
return {
"prompts": processed_prompts,
"weights": torch.tensor(snake_case__ , device=self.device ),
}
def _SCREAMING_SNAKE_CASE (self : Dict , snake_case__ : Dict , snake_case__ : Union[str, Any]=None , snake_case__ : str=None , snake_case__ : Union[str, Any]=True , snake_case__ : Any=False , snake_case__ : List[Any]=True , snake_case__ : List[Any]=True , snake_case__ : Dict=None , ) -> Any:
'''simple docstring'''
if image_path:
snake_case : List[Any] = self._get_latent(snake_case__ )
else:
snake_case : Optional[int] = torch.randn(self.latent_dim , device=self.device )
if self.log:
self._init_logging(snake_case__ , snake_case__ , snake_case__ )
assert pos_prompts, "You must provide at least one positive prompt."
snake_case : Optional[Any] = self.process_prompts(snake_case__ )
snake_case : List[Any] = self.process_prompts(snake_case__ )
if save_final and save_path is None:
snake_case : Tuple = os.path.join("./outputs/" , "_".join(pos_prompts["prompts"] ) )
if not os.path.exists(snake_case__ ):
os.makedirs(snake_case__ )
else:
snake_case : int = save_path + "_" + get_timestamp()
os.makedirs(snake_case__ )
snake_case : Tuple = save_path
snake_case : str = self.vqgan.decode(self.latent )[0]
if show_intermediate:
print("Original Image" )
show_pil(custom_to_pil(snake_case__ ) )
snake_case : List[str] = loop_post_process(snake_case__ )
for iter, transformed_img in enumerate(self._optimize_CLIP(snake_case__ , snake_case__ , snake_case__ ) ):
if show_intermediate:
show_pil(snake_case__ )
if save_intermediate:
transformed_img.save(os.path.join(self.save_path , f"""iter_{iter:03d}.png""" ) )
if self.log:
wandb.log({"Image": wandb.Image(snake_case__ )} )
if show_final:
show_pil(snake_case__ )
if save_final:
transformed_img.save(os.path.join(self.save_path , f"""iter_{iter:03d}_final.png""" ) )
| 59
|
from typing import Optional, Tuple, Union
import flax
import flax.linen as nn
import jax
import jax.numpy as jnp
from flax.core.frozen_dict import FrozenDict
from ..configuration_utils import ConfigMixin, flax_register_to_config
from ..utils import BaseOutput
from .embeddings_flax import FlaxTimestepEmbedding, FlaxTimesteps
from .modeling_flax_utils import FlaxModelMixin
from .unet_ad_blocks_flax import (
FlaxCrossAttnDownBlockaD,
FlaxCrossAttnUpBlockaD,
FlaxDownBlockaD,
FlaxUNetMidBlockaDCrossAttn,
FlaxUpBlockaD,
)
@flax.struct.dataclass
class UpperCAmelCase ( A_ ):
A__ : jnp.ndarray
@flax_register_to_config
class UpperCAmelCase ( nn.Module ,A_ ,A_ ):
A__ : int = 32
A__ : int = 4
A__ : int = 4
A__ : Tuple[str] = (
"CrossAttnDownBlock2D",
"CrossAttnDownBlock2D",
"CrossAttnDownBlock2D",
"DownBlock2D",
)
A__ : Tuple[str] = ("UpBlock2D", "CrossAttnUpBlock2D", "CrossAttnUpBlock2D", "CrossAttnUpBlock2D")
A__ : Union[bool, Tuple[bool]] = False
A__ : Tuple[int] = (3_20, 6_40, 12_80, 12_80)
A__ : int = 2
A__ : Union[int, Tuple[int]] = 8
A__ : Optional[Union[int, Tuple[int]]] = None
A__ : int = 12_80
A__ : float = 0.0
A__ : bool = False
A__ : jnp.dtype = jnp.floataa
A__ : bool = True
A__ : int = 0
A__ : bool = False
def _SCREAMING_SNAKE_CASE (self : Optional[int] , snake_case__ : jax.random.KeyArray ) -> FrozenDict:
'''simple docstring'''
snake_case : Dict = (1, self.in_channels, self.sample_size, self.sample_size)
snake_case : Any = jnp.zeros(snake_case__ , dtype=jnp.floataa )
snake_case : List[str] = jnp.ones((1,) , dtype=jnp.intaa )
snake_case : str = jnp.zeros((1, 1, self.cross_attention_dim) , dtype=jnp.floataa )
snake_case , snake_case : Optional[int] = jax.random.split(snake_case__ )
snake_case : Union[str, Any] = {"params": params_rng, "dropout": dropout_rng}
return self.init(snake_case__ , snake_case__ , snake_case__ , snake_case__ )["params"]
def _SCREAMING_SNAKE_CASE (self : str ) -> Tuple:
'''simple docstring'''
snake_case : str = self.block_out_channels
snake_case : Optional[Any] = block_out_channels[0] * 4
if self.num_attention_heads is not None:
raise ValueError(
"At the moment it is not possible to define the number of attention heads via `num_attention_heads` because of a naming issue as described in https://github.com/huggingface/diffusers/issues/2011#issuecomment-1547958131. Passing `num_attention_heads` will only be supported in diffusers v0.19." )
# If `num_attention_heads` is not defined (which is the case for most models)
# it will default to `attention_head_dim`. This looks weird upon first reading it and it is.
# The reason for this behavior is to correct for incorrectly named variables that were introduced
# when this library was created. The incorrect naming was only discovered much later in https://github.com/huggingface/diffusers/issues/2011#issuecomment-1547958131
# Changing `attention_head_dim` to `num_attention_heads` for 40,000+ configurations is too backwards breaking
# which is why we correct for the naming here.
snake_case : Tuple = self.num_attention_heads or self.attention_head_dim
# input
snake_case : Tuple = nn.Conv(
block_out_channels[0] , kernel_size=(3, 3) , strides=(1, 1) , padding=((1, 1), (1, 1)) , dtype=self.dtype , )
# time
snake_case : Union[str, Any] = FlaxTimesteps(
block_out_channels[0] , flip_sin_to_cos=self.flip_sin_to_cos , freq_shift=self.config.freq_shift )
snake_case : Dict = FlaxTimestepEmbedding(snake_case__ , dtype=self.dtype )
snake_case : List[str] = self.only_cross_attention
if isinstance(snake_case__ , snake_case__ ):
snake_case : List[Any] = (only_cross_attention,) * len(self.down_block_types )
if isinstance(snake_case__ , snake_case__ ):
snake_case : List[Any] = (num_attention_heads,) * len(self.down_block_types )
# down
snake_case : List[Any] = []
snake_case : Optional[int] = block_out_channels[0]
for i, down_block_type in enumerate(self.down_block_types ):
snake_case : List[Any] = output_channel
snake_case : Dict = block_out_channels[i]
snake_case : Optional[Any] = i == len(snake_case__ ) - 1
if down_block_type == "CrossAttnDownBlock2D":
snake_case : List[Any] = FlaxCrossAttnDownBlockaD(
in_channels=snake_case__ , out_channels=snake_case__ , dropout=self.dropout , num_layers=self.layers_per_block , num_attention_heads=num_attention_heads[i] , add_downsample=not is_final_block , use_linear_projection=self.use_linear_projection , only_cross_attention=only_cross_attention[i] , use_memory_efficient_attention=self.use_memory_efficient_attention , dtype=self.dtype , )
else:
snake_case : Union[str, Any] = FlaxDownBlockaD(
in_channels=snake_case__ , out_channels=snake_case__ , dropout=self.dropout , num_layers=self.layers_per_block , add_downsample=not is_final_block , dtype=self.dtype , )
down_blocks.append(snake_case__ )
snake_case : Dict = down_blocks
# mid
snake_case : Optional[int] = FlaxUNetMidBlockaDCrossAttn(
in_channels=block_out_channels[-1] , dropout=self.dropout , num_attention_heads=num_attention_heads[-1] , use_linear_projection=self.use_linear_projection , use_memory_efficient_attention=self.use_memory_efficient_attention , dtype=self.dtype , )
# up
snake_case : Optional[Any] = []
snake_case : Optional[int] = list(reversed(snake_case__ ) )
snake_case : Dict = list(reversed(snake_case__ ) )
snake_case : Tuple = list(reversed(snake_case__ ) )
snake_case : Optional[Any] = reversed_block_out_channels[0]
for i, up_block_type in enumerate(self.up_block_types ):
snake_case : Optional[int] = output_channel
snake_case : List[Any] = reversed_block_out_channels[i]
snake_case : Union[str, Any] = reversed_block_out_channels[min(i + 1 , len(snake_case__ ) - 1 )]
snake_case : int = i == len(snake_case__ ) - 1
if up_block_type == "CrossAttnUpBlock2D":
snake_case : Any = FlaxCrossAttnUpBlockaD(
in_channels=snake_case__ , out_channels=snake_case__ , prev_output_channel=snake_case__ , num_layers=self.layers_per_block + 1 , num_attention_heads=reversed_num_attention_heads[i] , add_upsample=not is_final_block , dropout=self.dropout , use_linear_projection=self.use_linear_projection , only_cross_attention=only_cross_attention[i] , use_memory_efficient_attention=self.use_memory_efficient_attention , dtype=self.dtype , )
else:
snake_case : Optional[int] = FlaxUpBlockaD(
in_channels=snake_case__ , out_channels=snake_case__ , prev_output_channel=snake_case__ , num_layers=self.layers_per_block + 1 , add_upsample=not is_final_block , dropout=self.dropout , dtype=self.dtype , )
up_blocks.append(snake_case__ )
snake_case : Optional[int] = output_channel
snake_case : Tuple = up_blocks
# out
snake_case : Optional[int] = nn.GroupNorm(num_groups=32 , epsilon=1e-5 )
snake_case : List[str] = nn.Conv(
self.out_channels , kernel_size=(3, 3) , strides=(1, 1) , padding=((1, 1), (1, 1)) , dtype=self.dtype , )
def __call__(self : Dict , snake_case__ : Dict , snake_case__ : Dict , snake_case__ : Optional[int] , snake_case__ : Tuple=None , snake_case__ : Union[str, Any]=None , snake_case__ : bool = True , snake_case__ : bool = False , ) -> Union[FlaxUNetaDConditionOutput, Tuple]:
'''simple docstring'''
if not isinstance(snake_case__ , jnp.ndarray ):
snake_case : List[Any] = jnp.array([timesteps] , dtype=jnp.intaa )
elif isinstance(snake_case__ , jnp.ndarray ) and len(timesteps.shape ) == 0:
snake_case : Any = timesteps.astype(dtype=jnp.floataa )
snake_case : int = jnp.expand_dims(snake_case__ , 0 )
snake_case : str = self.time_proj(snake_case__ )
snake_case : str = self.time_embedding(snake_case__ )
# 2. pre-process
snake_case : int = jnp.transpose(snake_case__ , (0, 2, 3, 1) )
snake_case : List[Any] = self.conv_in(snake_case__ )
# 3. down
snake_case : Optional[int] = (sample,)
for down_block in self.down_blocks:
if isinstance(snake_case__ , snake_case__ ):
snake_case , snake_case : List[Any] = down_block(snake_case__ , snake_case__ , snake_case__ , deterministic=not train )
else:
snake_case , snake_case : str = down_block(snake_case__ , snake_case__ , deterministic=not train )
down_block_res_samples += res_samples
if down_block_additional_residuals is not None:
snake_case : Tuple = ()
for down_block_res_sample, down_block_additional_residual in zip(
snake_case__ , snake_case__ ):
down_block_res_sample += down_block_additional_residual
new_down_block_res_samples += (down_block_res_sample,)
snake_case : Optional[int] = new_down_block_res_samples
# 4. mid
snake_case : Optional[int] = self.mid_block(snake_case__ , snake_case__ , snake_case__ , deterministic=not train )
if mid_block_additional_residual is not None:
sample += mid_block_additional_residual
# 5. up
for up_block in self.up_blocks:
snake_case : int = down_block_res_samples[-(self.layers_per_block + 1) :]
snake_case : Optional[Any] = down_block_res_samples[: -(self.layers_per_block + 1)]
if isinstance(snake_case__ , snake_case__ ):
snake_case : Optional[Any] = up_block(
snake_case__ , temb=snake_case__ , encoder_hidden_states=snake_case__ , res_hidden_states_tuple=snake_case__ , deterministic=not train , )
else:
snake_case : Dict = up_block(snake_case__ , temb=snake_case__ , res_hidden_states_tuple=snake_case__ , deterministic=not train )
# 6. post-process
snake_case : List[str] = self.conv_norm_out(snake_case__ )
snake_case : Any = nn.silu(snake_case__ )
snake_case : Optional[int] = self.conv_out(snake_case__ )
snake_case : Union[str, Any] = jnp.transpose(snake_case__ , (0, 3, 1, 2) )
if not return_dict:
return (sample,)
return FlaxUNetaDConditionOutput(sample=snake_case__ )
| 59
| 1
|
import argparse
import logging
import os
import re
import tensorflow as tf
from transformers import (
AutoConfig,
AutoTokenizer,
DataCollatorForLanguageModeling,
PushToHubCallback,
TFAutoModelForMaskedLM,
create_optimizer,
)
__lowerCamelCase = logging.getLogger(__name__)
__lowerCamelCase = tf.data.AUTOTUNE
def UpperCamelCase ( ):
snake_case : Optional[int] = argparse.ArgumentParser(description="Train a masked language model on TPU." )
parser.add_argument(
"--pretrained_model_config" , type=__lowerCamelCase , default="roberta-base" , help="The model config to use. Note that we don't copy the model's weights, only the config!" , )
parser.add_argument(
"--tokenizer" , type=__lowerCamelCase , default="unigram-tokenizer-wikitext" , help="The name of the tokenizer to load. We use the pretrained tokenizer to initialize the model's vocab size." , )
parser.add_argument(
"--per_replica_batch_size" , type=__lowerCamelCase , default=8 , help="Batch size per TPU core." , )
parser.add_argument(
"--no_tpu" , action="store_true" , help="If set, run on CPU and don't try to initialize a TPU. Useful for debugging on non-TPU instances." , )
parser.add_argument(
"--tpu_name" , type=__lowerCamelCase , help="Name of TPU resource to initialize. Should be blank on Colab, and 'local' on TPU VMs." , default="local" , )
parser.add_argument(
"--tpu_zone" , type=__lowerCamelCase , help="Google cloud zone that TPU resource is located in. Only used for non-Colab TPU nodes." , )
parser.add_argument(
"--gcp_project" , type=__lowerCamelCase , help="Google cloud project name. Only used for non-Colab TPU nodes." )
parser.add_argument(
"--bfloat16" , action="store_true" , help="Use mixed-precision bfloat16 for training. This is the recommended lower-precision format for TPU." , )
parser.add_argument(
"--train_dataset" , type=__lowerCamelCase , help="Path to training dataset to load. If the path begins with `gs://`"
" then the dataset will be loaded from a Google Cloud Storage bucket." , )
parser.add_argument(
"--shuffle_buffer_size" , type=__lowerCamelCase , default=2**18 , help="Size of the shuffle buffer (in samples)" , )
parser.add_argument(
"--eval_dataset" , type=__lowerCamelCase , help="Path to evaluation dataset to load. If the path begins with `gs://`"
" then the dataset will be loaded from a Google Cloud Storage bucket." , )
parser.add_argument(
"--num_epochs" , type=__lowerCamelCase , default=1 , help="Number of epochs to train for." , )
parser.add_argument(
"--learning_rate" , type=__lowerCamelCase , default=1E-4 , help="Learning rate to use for training." , )
parser.add_argument(
"--weight_decay_rate" , type=__lowerCamelCase , default=1E-3 , help="Weight decay rate to use for training." , )
parser.add_argument(
"--max_length" , type=__lowerCamelCase , default=512 , help="Maximum length of tokenized sequences. Should match the setting used in prepare_tfrecord_shards.py" , )
parser.add_argument(
"--mlm_probability" , type=__lowerCamelCase , default=0.15 , help="Fraction of tokens to mask during training." , )
parser.add_argument("--output_dir" , type=__lowerCamelCase , required=__lowerCamelCase , help="Path to save model checkpoints to." )
parser.add_argument("--hub_model_id" , type=__lowerCamelCase , help="Model ID to upload to on the Hugging Face Hub." )
snake_case : str = parser.parse_args()
return args
def UpperCamelCase ( __lowerCamelCase : List[str] ):
try:
if args.tpu_name:
snake_case : List[str] = tf.distribute.cluster_resolver.TPUClusterResolver(
args.tpu_name , zone=args.tpu_zone , project=args.gcp_project )
else:
snake_case : List[str] = tf.distribute.cluster_resolver.TPUClusterResolver()
except ValueError:
raise RuntimeError(
"Couldn't connect to TPU! Most likely you need to specify --tpu_name, --tpu_zone, or "
"--gcp_project. When running on a TPU VM, use --tpu_name local." )
tf.config.experimental_connect_to_cluster(__lowerCamelCase )
tf.tpu.experimental.initialize_tpu_system(__lowerCamelCase )
return tpu
def UpperCamelCase ( __lowerCamelCase : int ):
snake_case : Union[str, Any] = 0
for file in file_list:
snake_case : Dict = file.split("/" )[-1]
snake_case : int = re.search(r"-\d+-(\d+)\.tfrecord" , __lowerCamelCase ).group(1 )
snake_case : Tuple = int(__lowerCamelCase )
num_samples += sample_count
return num_samples
def UpperCamelCase ( __lowerCamelCase : str , __lowerCamelCase : List[Any] , __lowerCamelCase : Tuple , __lowerCamelCase : Tuple , __lowerCamelCase : Optional[Any] , __lowerCamelCase : int=None ):
snake_case : Union[str, Any] = count_samples(__lowerCamelCase )
snake_case : Any = tf.data.Dataset.from_tensor_slices(__lowerCamelCase )
if shuffle:
snake_case : Any = dataset.shuffle(len(__lowerCamelCase ) )
snake_case : Optional[Any] = tf.data.TFRecordDataset(__lowerCamelCase , num_parallel_reads=__lowerCamelCase )
# TF can't infer the total sample count because it doesn't read all the records yet, so we assert it here
snake_case : Any = dataset.apply(tf.data.experimental.assert_cardinality(__lowerCamelCase ) )
snake_case : List[Any] = dataset.map(__lowerCamelCase , num_parallel_calls=__lowerCamelCase )
if shuffle:
assert shuffle_buffer_size is not None
snake_case : Optional[int] = dataset.shuffle(args.shuffle_buffer_size )
snake_case : List[str] = dataset.batch(__lowerCamelCase , drop_remainder=__lowerCamelCase )
snake_case : Optional[Any] = dataset.map(__lowerCamelCase , num_parallel_calls=__lowerCamelCase )
snake_case : Any = dataset.prefetch(__lowerCamelCase )
return dataset
def UpperCamelCase ( __lowerCamelCase : List[Any] ):
if not args.no_tpu:
snake_case : Tuple = initialize_tpu(__lowerCamelCase )
snake_case : int = tf.distribute.TPUStrategy(__lowerCamelCase )
else:
snake_case : List[str] = tf.distribute.OneDeviceStrategy(device="/gpu:0" )
if args.bfloataa:
tf.keras.mixed_precision.set_global_policy("mixed_bfloat16" )
snake_case : Tuple = AutoTokenizer.from_pretrained(args.tokenizer )
snake_case : Optional[Any] = AutoConfig.from_pretrained(args.pretrained_model_config )
snake_case : Dict = tokenizer.vocab_size
snake_case : int = tf.io.gfile.glob(os.path.join(args.train_dataset , "*.tfrecord" ) )
if not training_records:
raise ValueError(f"""No .tfrecord files found in {args.train_dataset}.""" )
snake_case : Any = tf.io.gfile.glob(os.path.join(args.eval_dataset , "*.tfrecord" ) )
if not eval_records:
raise ValueError(f"""No .tfrecord files found in {args.eval_dataset}.""" )
snake_case : List[Any] = count_samples(__lowerCamelCase )
snake_case : List[Any] = num_train_samples // (args.per_replica_batch_size * strategy.num_replicas_in_sync)
snake_case : Dict = steps_per_epoch * args.num_epochs
with strategy.scope():
snake_case : List[str] = TFAutoModelForMaskedLM.from_config(__lowerCamelCase )
model(model.dummy_inputs ) # Pass some dummy inputs through the model to ensure all the weights are built
snake_case , snake_case : Dict = create_optimizer(
num_train_steps=__lowerCamelCase , num_warmup_steps=total_train_steps // 20 , init_lr=args.learning_rate , weight_decay_rate=args.weight_decay_rate , )
# Transformers models compute the right loss for their task by default when labels are passed, and will
# use this for training unless you specify your own loss function in compile().
model.compile(optimizer=__lowerCamelCase , metrics=["accuracy"] )
def decode_fn(__lowerCamelCase : List[Any] ):
snake_case : List[Any] = {
"input_ids": tf.io.FixedLenFeature(dtype=tf.intaa , shape=(args.max_length,) ),
"attention_mask": tf.io.FixedLenFeature(dtype=tf.intaa , shape=(args.max_length,) ),
}
return tf.io.parse_single_example(__lowerCamelCase , __lowerCamelCase )
# Many of the data collators in Transformers are TF-compilable when return_tensors == "tf", so we can
# use their methods in our data pipeline.
snake_case : Tuple = DataCollatorForLanguageModeling(
tokenizer=__lowerCamelCase , mlm_probability=args.mlm_probability , mlm=__lowerCamelCase , return_tensors="tf" )
def mask_with_collator(__lowerCamelCase : str ):
# TF really needs an isin() function
snake_case : List[str] = (
~tf.cast(batch["attention_mask"] , tf.bool )
| (batch["input_ids"] == tokenizer.cls_token_id)
| (batch["input_ids"] == tokenizer.sep_token_id)
)
snake_case , snake_case : List[Any] = data_collator.tf_mask_tokens(
batch["input_ids"] , vocab_size=len(__lowerCamelCase ) , mask_token_id=tokenizer.mask_token_id , special_tokens_mask=__lowerCamelCase , )
return batch
snake_case : Optional[Any] = args.per_replica_batch_size * strategy.num_replicas_in_sync
snake_case : Any = prepare_dataset(
__lowerCamelCase , decode_fn=__lowerCamelCase , mask_fn=__lowerCamelCase , batch_size=__lowerCamelCase , shuffle=__lowerCamelCase , shuffle_buffer_size=args.shuffle_buffer_size , )
snake_case : List[Any] = prepare_dataset(
__lowerCamelCase , decode_fn=__lowerCamelCase , mask_fn=__lowerCamelCase , batch_size=__lowerCamelCase , shuffle=__lowerCamelCase , )
snake_case : Dict = []
if args.hub_model_id:
callbacks.append(
PushToHubCallback(output_dir=args.output_dir , hub_model_id=args.hub_model_id , tokenizer=__lowerCamelCase ) )
model.fit(
__lowerCamelCase , validation_data=__lowerCamelCase , epochs=args.num_epochs , callbacks=__lowerCamelCase , )
model.save_pretrained(args.output_dir )
if __name__ == "__main__":
__lowerCamelCase = parse_args()
main(args)
| 59
|
__lowerCamelCase = {
"joule": 1.0,
"kilojoule": 10_00,
"megajoule": 1_00_00_00,
"gigajoule": 10_00_00_00_00,
"wattsecond": 1.0,
"watthour": 36_00,
"kilowatthour": 3_60_00_00,
"newtonmeter": 1.0,
"calorie_nutr": 41_86.8,
"kilocalorie_nutr": 4_18_68_00.00,
"electronvolt": 1.602_176_634e-19,
"britishthermalunit_it": 10_55.0_55_85,
"footpound": 1.35_5818,
}
def UpperCamelCase ( __lowerCamelCase : str , __lowerCamelCase : str , __lowerCamelCase : float ):
if to_type not in ENERGY_CONVERSION or from_type not in ENERGY_CONVERSION:
snake_case : List[Any] = (
f"""Incorrect 'from_type' or 'to_type' value: {from_type!r}, {to_type!r}\n"""
f"""Valid values are: {', '.join(__lowerCamelCase )}"""
)
raise ValueError(__lowerCamelCase )
return value * ENERGY_CONVERSION[from_type] / ENERGY_CONVERSION[to_type]
if __name__ == "__main__":
import doctest
doctest.testmod()
| 59
| 1
|
import math
def UpperCamelCase ( __lowerCamelCase : float , __lowerCamelCase : float ):
if initial_intensity < 0:
raise ValueError("The value of intensity cannot be negative" )
# handling of negative values of initial intensity
if angle < 0 or angle > 360:
raise ValueError("In Malus Law, the angle is in the range 0-360 degrees" )
# handling of values out of allowed range
return initial_intensity * (math.cos(math.radians(__lowerCamelCase ) ) ** 2)
if __name__ == "__main__":
import doctest
doctest.testmod(name="""malus_law""")
| 59
|
import logging
import os
from dataclasses import dataclass, field
from typing import Dict, Optional
import datasets
import numpy as np
import tensorflow as tf
from transformers import (
AutoConfig,
AutoTokenizer,
EvalPrediction,
HfArgumentParser,
PreTrainedTokenizer,
TFAutoModelForSequenceClassification,
TFTrainer,
TFTrainingArguments,
)
from transformers.utils import logging as hf_logging
hf_logging.set_verbosity_info()
hf_logging.enable_default_handler()
hf_logging.enable_explicit_format()
def UpperCamelCase ( __lowerCamelCase : str , __lowerCamelCase : str , __lowerCamelCase : str , __lowerCamelCase : PreTrainedTokenizer , __lowerCamelCase : int , __lowerCamelCase : Optional[int] = None , ):
snake_case : int = {}
if train_file is not None:
snake_case : List[Any] = [train_file]
if eval_file is not None:
snake_case : Optional[int] = [eval_file]
if test_file is not None:
snake_case : Any = [test_file]
snake_case : int = datasets.load_dataset("csv" , data_files=__lowerCamelCase )
snake_case : str = list(ds[list(files.keys() )[0]].features.keys() )
snake_case : int = features_name.pop(__lowerCamelCase )
snake_case : str = list(set(ds[list(files.keys() )[0]][label_name] ) )
snake_case : str = {label: i for i, label in enumerate(__lowerCamelCase )}
snake_case : List[Any] = tokenizer.model_input_names
snake_case : List[Any] = {}
if len(__lowerCamelCase ) == 1:
for k in files.keys():
snake_case : Tuple = ds[k].map(
lambda __lowerCamelCase : tokenizer.batch_encode_plus(
example[features_name[0]] , truncation=__lowerCamelCase , max_length=__lowerCamelCase , padding="max_length" ) , batched=__lowerCamelCase , )
elif len(__lowerCamelCase ) == 2:
for k in files.keys():
snake_case : List[Any] = ds[k].map(
lambda __lowerCamelCase : tokenizer.batch_encode_plus(
(example[features_name[0]], example[features_name[1]]) , truncation=__lowerCamelCase , max_length=__lowerCamelCase , padding="max_length" , ) , batched=__lowerCamelCase , )
def gen_train():
for ex in transformed_ds[datasets.Split.TRAIN]:
snake_case : Dict = {k: v for k, v in ex.items() if k in input_names}
snake_case : Union[str, Any] = labelaid[ex[label_name]]
yield (d, label)
def gen_val():
for ex in transformed_ds[datasets.Split.VALIDATION]:
snake_case : str = {k: v for k, v in ex.items() if k in input_names}
snake_case : Any = labelaid[ex[label_name]]
yield (d, label)
def gen_test():
for ex in transformed_ds[datasets.Split.TEST]:
snake_case : str = {k: v for k, v in ex.items() if k in input_names}
snake_case : List[str] = labelaid[ex[label_name]]
yield (d, label)
snake_case : int = (
tf.data.Dataset.from_generator(
__lowerCamelCase , ({k: tf.intaa for k in input_names}, tf.intaa) , ({k: tf.TensorShape([None] ) for k in input_names}, tf.TensorShape([] )) , )
if datasets.Split.TRAIN in transformed_ds
else None
)
if train_ds is not None:
snake_case : Optional[Any] = train_ds.apply(tf.data.experimental.assert_cardinality(len(ds[datasets.Split.TRAIN] ) ) )
snake_case : Tuple = (
tf.data.Dataset.from_generator(
__lowerCamelCase , ({k: tf.intaa for k in input_names}, tf.intaa) , ({k: tf.TensorShape([None] ) for k in input_names}, tf.TensorShape([] )) , )
if datasets.Split.VALIDATION in transformed_ds
else None
)
if val_ds is not None:
snake_case : List[str] = val_ds.apply(tf.data.experimental.assert_cardinality(len(ds[datasets.Split.VALIDATION] ) ) )
snake_case : Optional[int] = (
tf.data.Dataset.from_generator(
__lowerCamelCase , ({k: tf.intaa for k in input_names}, tf.intaa) , ({k: tf.TensorShape([None] ) for k in input_names}, tf.TensorShape([] )) , )
if datasets.Split.TEST in transformed_ds
else None
)
if test_ds is not None:
snake_case : str = test_ds.apply(tf.data.experimental.assert_cardinality(len(ds[datasets.Split.TEST] ) ) )
return train_ds, val_ds, test_ds, labelaid
__lowerCamelCase = logging.getLogger(__name__)
@dataclass
class UpperCAmelCase :
A__ : int = field(metadata={"help": "Which column contains the label"} )
A__ : str = field(default=A_ ,metadata={"help": "The path of the training file"} )
A__ : Optional[str] = field(default=A_ ,metadata={"help": "The path of the development file"} )
A__ : Optional[str] = field(default=A_ ,metadata={"help": "The path of the test file"} )
A__ : int = field(
default=1_28 ,metadata={
"help": (
"The maximum total input sequence length after tokenization. Sequences longer "
"than this will be truncated, sequences shorter will be padded."
)
} ,)
A__ : bool = field(
default=A_ ,metadata={"help": "Overwrite the cached training and evaluation sets"} )
@dataclass
class UpperCAmelCase :
A__ : str = field(
metadata={"help": "Path to pretrained model or model identifier from huggingface.co/models"} )
A__ : Optional[str] = field(
default=A_ ,metadata={"help": "Pretrained config name or path if not the same as model_name"} )
A__ : Optional[str] = field(
default=A_ ,metadata={"help": "Pretrained tokenizer name or path if not the same as model_name"} )
A__ : bool = 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.
A__ : Optional[str] = field(
default=A_ ,metadata={"help": "Where do you want to store the pretrained models downloaded from huggingface.co"} ,)
def UpperCamelCase ( ):
# See all possible arguments in src/transformers/training_args.py
# or by passing the --help flag to this script.
# We now keep distinct sets of args, for a cleaner separation of concerns.
snake_case : List[Any] = HfArgumentParser((ModelArguments, DataTrainingArguments, TFTrainingArguments) )
snake_case , snake_case , snake_case : int = parser.parse_args_into_dataclasses()
if (
os.path.exists(training_args.output_dir )
and os.listdir(training_args.output_dir )
and training_args.do_train
and not training_args.overwrite_output_dir
):
raise ValueError(
f"""Output directory ({training_args.output_dir}) already exists and is not empty. Use"""
" --overwrite_output_dir to overcome." )
# Setup logging
logging.basicConfig(
format="%(asctime)s - %(levelname)s - %(name)s - %(message)s" , datefmt="%m/%d/%Y %H:%M:%S" , level=logging.INFO , )
logger.info(
f"""n_replicas: {training_args.n_replicas}, distributed training: {bool(training_args.n_replicas > 1 )}, """
f"""16-bits training: {training_args.fpaa}""" )
logger.info(f"""Training/evaluation parameters {training_args}""" )
# Load pretrained model and tokenizer
#
# Distributed training:
# The .from_pretrained methods guarantee that only one local process can concurrently
# download model & vocab.
snake_case : Tuple = AutoTokenizer.from_pretrained(
model_args.tokenizer_name if model_args.tokenizer_name else model_args.model_name_or_path , cache_dir=model_args.cache_dir , )
snake_case , snake_case , snake_case , snake_case : Tuple = get_tfds(
train_file=data_args.train_file , eval_file=data_args.dev_file , test_file=data_args.test_file , tokenizer=__lowerCamelCase , label_column_id=data_args.label_column_id , max_seq_length=data_args.max_seq_length , )
snake_case : Optional[Any] = AutoConfig.from_pretrained(
model_args.config_name if model_args.config_name else model_args.model_name_or_path , num_labels=len(__lowerCamelCase ) , labelaid=__lowerCamelCase , idalabel={id: label for label, id in labelaid.items()} , finetuning_task="text-classification" , cache_dir=model_args.cache_dir , )
with training_args.strategy.scope():
snake_case : int = TFAutoModelForSequenceClassification.from_pretrained(
model_args.model_name_or_path , from_pt=bool(".bin" in model_args.model_name_or_path ) , config=__lowerCamelCase , cache_dir=model_args.cache_dir , )
def compute_metrics(__lowerCamelCase : EvalPrediction ) -> Dict:
snake_case : Optional[int] = np.argmax(p.predictions , axis=1 )
return {"acc": (preds == p.label_ids).mean()}
# Initialize our Trainer
snake_case : int = TFTrainer(
model=__lowerCamelCase , args=__lowerCamelCase , train_dataset=__lowerCamelCase , eval_dataset=__lowerCamelCase , compute_metrics=__lowerCamelCase , )
# Training
if training_args.do_train:
trainer.train()
trainer.save_model()
tokenizer.save_pretrained(training_args.output_dir )
# Evaluation
snake_case : int = {}
if training_args.do_eval:
logger.info("*** Evaluate ***" )
snake_case : Any = trainer.evaluate()
snake_case : List[Any] = os.path.join(training_args.output_dir , "eval_results.txt" )
with open(__lowerCamelCase , "w" ) as writer:
logger.info("***** Eval results *****" )
for key, value in result.items():
logger.info(f""" {key} = {value}""" )
writer.write(f"""{key} = {value}\n""" )
results.update(__lowerCamelCase )
return results
if __name__ == "__main__":
main()
| 59
| 1
|
import argparse
from typing import Dict
import tensorflow as tf
import torch
from tqdm import tqdm
from transformers import BigBirdPegasusConfig, BigBirdPegasusForConditionalGeneration
__lowerCamelCase = [
# tf -> hf
("""/""", """."""),
("""layer_""", """layers."""),
("""kernel""", """weight"""),
("""beta""", """bias"""),
("""gamma""", """weight"""),
("""pegasus""", """model"""),
]
__lowerCamelCase = [
(""".output.dense""", """.fc2"""),
("""intermediate.LayerNorm""", """final_layer_norm"""),
("""intermediate.dense""", """fc1"""),
]
__lowerCamelCase = (
INIT_COMMON
+ [
("""attention.self.LayerNorm""", """self_attn_layer_norm"""),
("""attention.output.dense""", """self_attn.out_proj"""),
("""attention.self""", """self_attn"""),
("""attention.encdec.LayerNorm""", """encoder_attn_layer_norm"""),
("""attention.encdec_output.dense""", """encoder_attn.out_proj"""),
("""attention.encdec""", """encoder_attn"""),
("""key""", """k_proj"""),
("""value""", """v_proj"""),
("""query""", """q_proj"""),
("""decoder.LayerNorm""", """decoder.layernorm_embedding"""),
]
+ END_COMMON
)
__lowerCamelCase = (
INIT_COMMON
+ [
("""embeddings.word_embeddings""", """shared.weight"""),
("""embeddings.position_embeddings""", """embed_positions.weight"""),
("""attention.self.LayerNorm""", """self_attn_layer_norm"""),
("""attention.output.dense""", """self_attn.output"""),
("""attention.self""", """self_attn.self"""),
("""encoder.LayerNorm""", """encoder.layernorm_embedding"""),
]
+ END_COMMON
)
__lowerCamelCase = [
"""encdec/key/bias""",
"""encdec/query/bias""",
"""encdec/value/bias""",
"""self/key/bias""",
"""self/query/bias""",
"""self/value/bias""",
"""encdec_output/dense/bias""",
"""attention/output/dense/bias""",
]
def UpperCamelCase ( __lowerCamelCase : Any , __lowerCamelCase : Tuple ):
for tf_name, hf_name in patterns:
snake_case : Union[str, Any] = k.replace(__lowerCamelCase , __lowerCamelCase )
return k
def UpperCamelCase ( __lowerCamelCase : dict , __lowerCamelCase : dict ):
snake_case : Dict = BigBirdPegasusConfig(**__lowerCamelCase )
snake_case : List[Any] = BigBirdPegasusForConditionalGeneration(__lowerCamelCase )
snake_case : List[Any] = torch_model.state_dict()
snake_case : Any = {}
# separating decoder weights
snake_case : Tuple = {k: tf_weights[k] for k in tf_weights if k.startswith("pegasus/decoder" )}
snake_case : str = {k: tf_weights[k] for k in tf_weights if not k.startswith("pegasus/decoder" )}
for k, v in tqdm(decoder_weights.items() , "tf -> hf conversion" ):
snake_case : Any = [k.endswith(__lowerCamelCase ) for ending in KEYS_TO_IGNORE]
if any(__lowerCamelCase ):
continue
snake_case : Union[str, Any] = DECODER_PATTERNS
snake_case : str = rename_state_dict_key(__lowerCamelCase , __lowerCamelCase )
if new_k not in state_dict:
raise ValueError(f"""could not find new key {new_k} in state dict. (converted from {k})""" )
if any(True if i in k else False for i in ["dense", "query", "key", "value"] ):
snake_case : Optional[Any] = v.T
snake_case : Optional[Any] = torch.from_numpy(__lowerCamelCase )
assert v.shape == state_dict[new_k].shape, f"""{new_k}, {k}, {v.shape}, {state_dict[new_k].shape}"""
for k, v in tqdm(remaining_weights.items() , "tf -> hf conversion" ):
snake_case : Tuple = [k.endswith(__lowerCamelCase ) for ending in KEYS_TO_IGNORE]
if any(__lowerCamelCase ):
continue
snake_case : Dict = REMAINING_PATTERNS
snake_case : List[str] = rename_state_dict_key(__lowerCamelCase , __lowerCamelCase )
if new_k not in state_dict and k != "pegasus/embeddings/position_embeddings":
raise ValueError(f"""could not find new key {new_k} in state dict. (converted from {k})""" )
if any(True if i in k else False for i in ["dense", "query", "key", "value"] ):
snake_case : str = v.T
snake_case : int = torch.from_numpy(__lowerCamelCase )
if k != "pegasus/embeddings/position_embeddings":
assert v.shape == state_dict[new_k].shape, f"""{new_k}, {k}, {v.shape}, {state_dict[new_k].shape}"""
snake_case : Optional[Any] = mapping["model.embed_positions.weight"]
snake_case : List[str] = mapping.pop("model.embed_positions.weight" )
snake_case , snake_case : List[Any] = torch_model.load_state_dict(__lowerCamelCase , strict=__lowerCamelCase )
snake_case : Optional[int] = [
k
for k in missing
if k
not in [
"final_logits_bias",
"model.encoder.embed_tokens.weight",
"model.decoder.embed_tokens.weight",
"lm_head.weight",
]
]
assert unexpected_missing == [], f"""no matches found for the following torch keys {unexpected_missing}"""
assert extra == [], f"""no matches found for the following tf keys {extra}"""
return torch_model
def UpperCamelCase ( __lowerCamelCase : str ):
snake_case : Optional[Any] = tf.train.list_variables(__lowerCamelCase )
snake_case : List[str] = {}
snake_case : List[str] = ["global_step"]
for name, shape in tqdm(__lowerCamelCase , desc="converting tf checkpoint to dict" ):
snake_case : str = any(pat in name for pat in ignore_name )
if skip_key:
continue
snake_case : Union[str, Any] = tf.train.load_variable(__lowerCamelCase , __lowerCamelCase )
snake_case : Union[str, Any] = array
return tf_weights
def UpperCamelCase ( __lowerCamelCase : str , __lowerCamelCase : str , __lowerCamelCase : dict ):
snake_case : str = get_tf_weights_as_numpy(__lowerCamelCase )
snake_case : Optional[Any] = convert_bigbird_pegasus(__lowerCamelCase , __lowerCamelCase )
torch_model.save_pretrained(__lowerCamelCase )
if __name__ == "__main__":
__lowerCamelCase = argparse.ArgumentParser()
parser.add_argument("""--tf_ckpt_path""", type=str, help="""passed to tf.train.list_variables""")
parser.add_argument("""--save_dir""", default=None, type=str, help="""Path to the output PyTorch model.""")
__lowerCamelCase = parser.parse_args()
__lowerCamelCase = {}
convert_bigbird_pegasus_ckpt_to_pytorch(args.tf_ckpt_path, args.save_dir, config_update=config_update)
| 59
|
import json
import os
import shutil
import tempfile
import unittest
import numpy as np
from transformers import BertTokenizerFast
from transformers.models.bert.tokenization_bert import VOCAB_FILES_NAMES, BertTokenizer
from transformers.testing_utils import require_tokenizers, require_vision
from transformers.utils import IMAGE_PROCESSOR_NAME, is_vision_available
if is_vision_available():
from PIL import Image
from transformers import VisionTextDualEncoderProcessor, ViTImageProcessor
@require_tokenizers
@require_vision
class UpperCAmelCase ( unittest.TestCase ):
def _SCREAMING_SNAKE_CASE (self : Any ) -> List[str]:
'''simple docstring'''
snake_case : int = tempfile.mkdtemp()
# fmt: off
snake_case : Optional[int] = ["[UNK]", "[CLS]", "[SEP]", "[PAD]", "[MASK]", "want", "##want", "##ed", "wa", "un", "runn", "##ing", ",", "low", "lowest"]
# fmt: on
snake_case : List[str] = os.path.join(self.tmpdirname , VOCAB_FILES_NAMES["vocab_file"] )
with open(self.vocab_file , "w" , encoding="utf-8" ) as vocab_writer:
vocab_writer.write("".join([x + "\n" for x in vocab_tokens] ) )
snake_case : int = {
"do_resize": True,
"size": {"height": 18, "width": 18},
"do_normalize": True,
"image_mean": [0.5, 0.5, 0.5],
"image_std": [0.5, 0.5, 0.5],
}
snake_case : Optional[Any] = os.path.join(self.tmpdirname , snake_case__ )
with open(self.image_processor_file , "w" , encoding="utf-8" ) as fp:
json.dump(snake_case__ , snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Optional[Any] , **snake_case__ : str ) -> Optional[int]:
'''simple docstring'''
return BertTokenizer.from_pretrained(self.tmpdirname , **snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Optional[Any] , **snake_case__ : List[str] ) -> int:
'''simple docstring'''
return ViTImageProcessor.from_pretrained(self.tmpdirname , **snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> Dict:
'''simple docstring'''
shutil.rmtree(self.tmpdirname )
def _SCREAMING_SNAKE_CASE (self : Dict ) -> str:
'''simple docstring'''
snake_case : List[Any] = [np.random.randint(2_55 , size=(3, 30, 4_00) , dtype=np.uinta )]
snake_case : Optional[int] = [Image.fromarray(np.moveaxis(snake_case__ , 0 , -1 ) ) for x in image_inputs]
return image_inputs
def _SCREAMING_SNAKE_CASE (self : Union[str, Any] ) -> Union[str, Any]:
'''simple docstring'''
snake_case : Dict = self.get_tokenizer()
snake_case : Optional[Any] = self.get_image_processor()
snake_case : Optional[Any] = VisionTextDualEncoderProcessor(tokenizer=snake_case__ , image_processor=snake_case__ )
processor.save_pretrained(self.tmpdirname )
snake_case : Any = VisionTextDualEncoderProcessor.from_pretrained(self.tmpdirname )
self.assertEqual(processor.tokenizer.get_vocab() , tokenizer.get_vocab() )
self.assertIsInstance(processor.tokenizer , (BertTokenizer, BertTokenizerFast) )
self.assertEqual(processor.image_processor.to_json_string() , image_processor.to_json_string() )
self.assertIsInstance(processor.image_processor , snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Any ) -> Optional[Any]:
'''simple docstring'''
snake_case : str = VisionTextDualEncoderProcessor(
tokenizer=self.get_tokenizer() , image_processor=self.get_image_processor() )
processor.save_pretrained(self.tmpdirname )
snake_case : Optional[int] = self.get_tokenizer(bos_token="(BOS)" , eos_token="(EOS)" )
snake_case : Tuple = self.get_image_processor(do_normalize=snake_case__ , padding_value=1.0 )
snake_case : List[str] = VisionTextDualEncoderProcessor.from_pretrained(
self.tmpdirname , bos_token="(BOS)" , eos_token="(EOS)" , do_normalize=snake_case__ , padding_value=1.0 )
self.assertEqual(processor.tokenizer.get_vocab() , tokenizer_add_kwargs.get_vocab() )
self.assertIsInstance(processor.tokenizer , (BertTokenizer, BertTokenizerFast) )
self.assertEqual(processor.image_processor.to_json_string() , image_processor_add_kwargs.to_json_string() )
self.assertIsInstance(processor.image_processor , snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Union[str, Any] ) -> int:
'''simple docstring'''
snake_case : str = self.get_image_processor()
snake_case : Optional[int] = self.get_tokenizer()
snake_case : List[Any] = VisionTextDualEncoderProcessor(tokenizer=snake_case__ , image_processor=snake_case__ )
snake_case : Optional[Any] = self.prepare_image_inputs()
snake_case : str = image_processor(snake_case__ , return_tensors="np" )
snake_case : Any = processor(images=snake_case__ , return_tensors="np" )
for key in input_feat_extract.keys():
self.assertAlmostEqual(input_feat_extract[key].sum() , input_processor[key].sum() , delta=1e-2 )
def _SCREAMING_SNAKE_CASE (self : Tuple ) -> Optional[Any]:
'''simple docstring'''
snake_case : Dict = self.get_image_processor()
snake_case : int = self.get_tokenizer()
snake_case : Any = VisionTextDualEncoderProcessor(tokenizer=snake_case__ , image_processor=snake_case__ )
snake_case : Tuple = "lower newer"
snake_case : Tuple = processor(text=snake_case__ )
snake_case : Union[str, Any] = tokenizer(snake_case__ )
for key in encoded_tok.keys():
self.assertListEqual(encoded_tok[key] , encoded_processor[key] )
def _SCREAMING_SNAKE_CASE (self : Dict ) -> Optional[int]:
'''simple docstring'''
snake_case : List[Any] = self.get_image_processor()
snake_case : Dict = self.get_tokenizer()
snake_case : Dict = VisionTextDualEncoderProcessor(tokenizer=snake_case__ , image_processor=snake_case__ )
snake_case : int = "lower newer"
snake_case : Dict = self.prepare_image_inputs()
snake_case : Union[str, Any] = processor(text=snake_case__ , images=snake_case__ )
self.assertListEqual(list(inputs.keys() ) , ["input_ids", "token_type_ids", "attention_mask", "pixel_values"] )
# test if it raises when no input is passed
with self.assertRaises(snake_case__ ):
processor()
def _SCREAMING_SNAKE_CASE (self : str ) -> Tuple:
'''simple docstring'''
snake_case : Tuple = self.get_image_processor()
snake_case : Optional[Any] = self.get_tokenizer()
snake_case : Tuple = VisionTextDualEncoderProcessor(tokenizer=snake_case__ , image_processor=snake_case__ )
snake_case : List[str] = [[1, 4, 5, 8, 1, 0, 8], [3, 4, 3, 1, 1, 8, 9]]
snake_case : List[Any] = processor.batch_decode(snake_case__ )
snake_case : Union[str, Any] = tokenizer.batch_decode(snake_case__ )
self.assertListEqual(snake_case__ , snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> List[str]:
'''simple docstring'''
snake_case : str = self.get_image_processor()
snake_case : Union[str, Any] = self.get_tokenizer()
snake_case : Any = VisionTextDualEncoderProcessor(tokenizer=snake_case__ , image_processor=snake_case__ )
snake_case : Optional[Any] = "lower newer"
snake_case : List[Any] = self.prepare_image_inputs()
snake_case : Tuple = processor(text=snake_case__ , images=snake_case__ )
self.assertListEqual(list(inputs.keys() ) , processor.model_input_names )
| 59
| 1
|
from __future__ import annotations
import queue
class UpperCAmelCase :
def __init__(self : Union[str, Any] , snake_case__ : int ) -> Optional[int]:
'''simple docstring'''
snake_case : int = data
snake_case : Optional[Any] = None
snake_case : Optional[Any] = None
def UpperCamelCase ( ):
print("\n********Press N to stop entering at any point of time********\n" )
snake_case : Union[str, Any] = input("Enter the value of the root node: " ).strip().lower()
snake_case : queue.Queue = queue.Queue()
snake_case : Union[str, Any] = TreeNode(int(__lowerCamelCase ) )
q.put(__lowerCamelCase )
while not q.empty():
snake_case : Optional[Any] = q.get()
snake_case : Optional[int] = f"""Enter the left node of {node_found.data}: """
snake_case : Any = input(__lowerCamelCase ).strip().lower() or "n"
if check == "n":
return tree_node
snake_case : int = TreeNode(int(__lowerCamelCase ) )
snake_case : Tuple = left_node
q.put(__lowerCamelCase )
snake_case : Dict = f"""Enter the right node of {node_found.data}: """
snake_case : str = input(__lowerCamelCase ).strip().lower() or "n"
if check == "n":
return tree_node
snake_case : Any = TreeNode(int(__lowerCamelCase ) )
snake_case : List[Any] = right_node
q.put(__lowerCamelCase )
raise
def UpperCamelCase ( __lowerCamelCase : TreeNode ):
if not isinstance(__lowerCamelCase , __lowerCamelCase ) or not node:
return
print(node.data , end="," )
pre_order(node.left )
pre_order(node.right )
def UpperCamelCase ( __lowerCamelCase : TreeNode ):
if not isinstance(__lowerCamelCase , __lowerCamelCase ) or not node:
return
in_order(node.left )
print(node.data , end="," )
in_order(node.right )
def UpperCamelCase ( __lowerCamelCase : TreeNode ):
if not isinstance(__lowerCamelCase , __lowerCamelCase ) or not node:
return
post_order(node.left )
post_order(node.right )
print(node.data , end="," )
def UpperCamelCase ( __lowerCamelCase : TreeNode ):
if not isinstance(__lowerCamelCase , __lowerCamelCase ) or not node:
return
snake_case : queue.Queue = queue.Queue()
q.put(__lowerCamelCase )
while not q.empty():
snake_case : int = q.get()
print(node_dequeued.data , end="," )
if node_dequeued.left:
q.put(node_dequeued.left )
if node_dequeued.right:
q.put(node_dequeued.right )
def UpperCamelCase ( __lowerCamelCase : TreeNode ):
if not isinstance(__lowerCamelCase , __lowerCamelCase ) or not node:
return
snake_case : queue.Queue = queue.Queue()
q.put(__lowerCamelCase )
while not q.empty():
snake_case : Dict = []
while not q.empty():
snake_case : Optional[Any] = q.get()
print(node_dequeued.data , end="," )
if node_dequeued.left:
list_.append(node_dequeued.left )
if node_dequeued.right:
list_.append(node_dequeued.right )
print()
for node in list_:
q.put(__lowerCamelCase )
def UpperCamelCase ( __lowerCamelCase : TreeNode ):
if not isinstance(__lowerCamelCase , __lowerCamelCase ) or not node:
return
snake_case : list[TreeNode] = []
snake_case : Tuple = node
while n or stack:
while n: # start from root node, find its left child
print(n.data , end="," )
stack.append(__lowerCamelCase )
snake_case : Dict = n.left
# end of while means current node doesn't have left child
snake_case : Optional[int] = stack.pop()
# start to traverse its right child
snake_case : List[Any] = n.right
def UpperCamelCase ( __lowerCamelCase : TreeNode ):
if not isinstance(__lowerCamelCase , __lowerCamelCase ) or not node:
return
snake_case : list[TreeNode] = []
snake_case : Dict = node
while n or stack:
while n:
stack.append(__lowerCamelCase )
snake_case : List[Any] = n.left
snake_case : List[Any] = stack.pop()
print(n.data , end="," )
snake_case : str = n.right
def UpperCamelCase ( __lowerCamelCase : TreeNode ):
if not isinstance(__lowerCamelCase , __lowerCamelCase ) or not node:
return
snake_case , snake_case : List[Any] = [], []
snake_case : Any = node
stacka.append(__lowerCamelCase )
while stacka: # to find the reversed order of post order, store it in stack2
snake_case : Optional[Any] = stacka.pop()
if n.left:
stacka.append(n.left )
if n.right:
stacka.append(n.right )
stacka.append(__lowerCamelCase )
while stacka: # pop up from stack2 will be the post order
print(stacka.pop().data , end="," )
def UpperCamelCase ( __lowerCamelCase : str = "" , __lowerCamelCase : Tuple=50 , __lowerCamelCase : int="*" ):
if not s:
return "\n" + width * char
snake_case , snake_case : Optional[Any] = divmod(width - len(__lowerCamelCase ) - 2 , 2 )
return f"""{left * char} {s} {(left + extra) * char}"""
if __name__ == "__main__":
import doctest
doctest.testmod()
print(prompt("""Binary Tree Traversals"""))
__lowerCamelCase = build_tree()
print(prompt("""Pre Order Traversal"""))
pre_order(node)
print(prompt() + """\n""")
print(prompt("""In Order Traversal"""))
in_order(node)
print(prompt() + """\n""")
print(prompt("""Post Order Traversal"""))
post_order(node)
print(prompt() + """\n""")
print(prompt("""Level Order Traversal"""))
level_order(node)
print(prompt() + """\n""")
print(prompt("""Actual Level Order Traversal"""))
level_order_actual(node)
print("""*""" * 50 + """\n""")
print(prompt("""Pre Order Traversal - Iteration Version"""))
pre_order_iter(node)
print(prompt() + """\n""")
print(prompt("""In Order Traversal - Iteration Version"""))
in_order_iter(node)
print(prompt() + """\n""")
print(prompt("""Post Order Traversal - Iteration Version"""))
post_order_iter(node)
print(prompt())
| 59
|
from typing import TYPE_CHECKING
from ...utils import OptionalDependencyNotAvailable, _LazyModule, is_tokenizers_available, is_torch_available
__lowerCamelCase = {
"""configuration_biogpt""": ["""BIOGPT_PRETRAINED_CONFIG_ARCHIVE_MAP""", """BioGptConfig"""],
"""tokenization_biogpt""": ["""BioGptTokenizer"""],
}
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = [
"""BIOGPT_PRETRAINED_MODEL_ARCHIVE_LIST""",
"""BioGptForCausalLM""",
"""BioGptForTokenClassification""",
"""BioGptForSequenceClassification""",
"""BioGptModel""",
"""BioGptPreTrainedModel""",
]
if TYPE_CHECKING:
from .configuration_biogpt import BIOGPT_PRETRAINED_CONFIG_ARCHIVE_MAP, BioGptConfig
from .tokenization_biogpt import BioGptTokenizer
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_biogpt import (
BIOGPT_PRETRAINED_MODEL_ARCHIVE_LIST,
BioGptForCausalLM,
BioGptForSequenceClassification,
BioGptForTokenClassification,
BioGptModel,
BioGptPreTrainedModel,
)
else:
import sys
__lowerCamelCase = _LazyModule(__name__, globals()["""__file__"""], _import_structure, module_spec=__spec__)
| 59
| 1
|
import gc
import unittest
import numpy as np
import torch
from diffusers import (
AudioDiffusionPipeline,
AutoencoderKL,
DDIMScheduler,
DDPMScheduler,
DiffusionPipeline,
Mel,
UNetaDConditionModel,
UNetaDModel,
)
from diffusers.utils import slow, torch_device
from diffusers.utils.testing_utils import enable_full_determinism, require_torch_gpu
enable_full_determinism()
class UpperCAmelCase ( unittest.TestCase ):
def _SCREAMING_SNAKE_CASE (self : Any ) -> List[str]:
'''simple docstring'''
super().tearDown()
gc.collect()
torch.cuda.empty_cache()
@property
def _SCREAMING_SNAKE_CASE (self : Tuple ) -> Tuple:
'''simple docstring'''
torch.manual_seed(0 )
snake_case : List[Any] = UNetaDModel(
sample_size=(32, 64) , in_channels=1 , out_channels=1 , layers_per_block=2 , block_out_channels=(1_28, 1_28) , down_block_types=("AttnDownBlock2D", "DownBlock2D") , up_block_types=("UpBlock2D", "AttnUpBlock2D") , )
return model
@property
def _SCREAMING_SNAKE_CASE (self : List[Any] ) -> Union[str, Any]:
'''simple docstring'''
torch.manual_seed(0 )
snake_case : Union[str, Any] = UNetaDConditionModel(
sample_size=(64, 32) , in_channels=1 , out_channels=1 , layers_per_block=2 , block_out_channels=(1_28, 1_28) , down_block_types=("CrossAttnDownBlock2D", "DownBlock2D") , up_block_types=("UpBlock2D", "CrossAttnUpBlock2D") , cross_attention_dim=10 , )
return model
@property
def _SCREAMING_SNAKE_CASE (self : int ) -> int:
'''simple docstring'''
torch.manual_seed(0 )
snake_case : str = AutoencoderKL(
sample_size=(1_28, 64) , in_channels=1 , out_channels=1 , latent_channels=1 , layers_per_block=2 , block_out_channels=(1_28, 1_28) , down_block_types=("DownEncoderBlock2D", "DownEncoderBlock2D") , up_block_types=("UpDecoderBlock2D", "UpDecoderBlock2D") , )
snake_case : Optional[Any] = UNetaDModel(
sample_size=(64, 32) , in_channels=1 , out_channels=1 , layers_per_block=2 , block_out_channels=(1_28, 1_28) , down_block_types=("AttnDownBlock2D", "DownBlock2D") , up_block_types=("UpBlock2D", "AttnUpBlock2D") , )
return vqvae, unet
@slow
def _SCREAMING_SNAKE_CASE (self : List[Any] ) -> int:
'''simple docstring'''
snake_case : Optional[Any] = "cpu" # ensure determinism for the device-dependent torch.Generator
snake_case : List[str] = Mel(
x_res=self.dummy_unet.config.sample_size[1] , y_res=self.dummy_unet.config.sample_size[0] , )
snake_case : List[str] = DDPMScheduler()
snake_case : Any = AudioDiffusionPipeline(vqvae=snake_case__ , unet=self.dummy_unet , mel=snake_case__ , scheduler=snake_case__ )
snake_case : Optional[Any] = pipe.to(snake_case__ )
pipe.set_progress_bar_config(disable=snake_case__ )
snake_case : str = torch.Generator(device=snake_case__ ).manual_seed(42 )
snake_case : Optional[Any] = pipe(generator=snake_case__ , steps=4 )
snake_case : Optional[Any] = output.audios[0]
snake_case : Optional[Any] = output.images[0]
snake_case : str = torch.Generator(device=snake_case__ ).manual_seed(42 )
snake_case : Optional[Any] = pipe(generator=snake_case__ , steps=4 , return_dict=snake_case__ )
snake_case : Optional[Any] = output[0][0]
assert audio.shape == (1, (self.dummy_unet.config.sample_size[1] - 1) * mel.hop_length)
assert (
image.height == self.dummy_unet.config.sample_size[0]
and image.width == self.dummy_unet.config.sample_size[1]
)
snake_case : Optional[int] = np.frombuffer(image.tobytes() , dtype="uint8" )[:10]
snake_case : Optional[Any] = np.frombuffer(image_from_tuple.tobytes() , dtype="uint8" )[:10]
snake_case : str = np.array([69, 2_55, 2_55, 2_55, 0, 0, 77, 1_81, 12, 1_27] )
assert np.abs(image_slice.flatten() - expected_slice ).max() == 0
assert np.abs(image_from_tuple_slice.flatten() - expected_slice ).max() == 0
snake_case : Dict = Mel(
x_res=self.dummy_vqvae_and_unet[0].config.sample_size[1] , y_res=self.dummy_vqvae_and_unet[0].config.sample_size[0] , )
snake_case : Optional[Any] = DDIMScheduler()
snake_case : List[str] = self.dummy_vqvae_and_unet
snake_case : List[Any] = AudioDiffusionPipeline(
vqvae=self.dummy_vqvae_and_unet[0] , unet=dummy_vqvae_and_unet[1] , mel=snake_case__ , scheduler=snake_case__ )
snake_case : Dict = pipe.to(snake_case__ )
pipe.set_progress_bar_config(disable=snake_case__ )
np.random.seed(0 )
snake_case : Dict = np.random.uniform(-1 , 1 , ((dummy_vqvae_and_unet[0].config.sample_size[1] - 1) * mel.hop_length,) )
snake_case : Optional[int] = torch.Generator(device=snake_case__ ).manual_seed(42 )
snake_case : Dict = pipe(raw_audio=snake_case__ , generator=snake_case__ , start_step=5 , steps=10 )
snake_case : List[Any] = output.images[0]
assert (
image.height == self.dummy_vqvae_and_unet[0].config.sample_size[0]
and image.width == self.dummy_vqvae_and_unet[0].config.sample_size[1]
)
snake_case : Dict = np.frombuffer(image.tobytes() , dtype="uint8" )[:10]
snake_case : List[str] = np.array([1_20, 1_17, 1_10, 1_09, 1_38, 1_67, 1_38, 1_48, 1_32, 1_21] )
assert np.abs(image_slice.flatten() - expected_slice ).max() == 0
snake_case : int = self.dummy_unet_condition
snake_case : Optional[Any] = AudioDiffusionPipeline(
vqvae=self.dummy_vqvae_and_unet[0] , unet=snake_case__ , mel=snake_case__ , scheduler=snake_case__ )
snake_case : int = pipe.to(snake_case__ )
pipe.set_progress_bar_config(disable=snake_case__ )
np.random.seed(0 )
snake_case : Dict = torch.rand((1, 1, 10) )
snake_case : Union[str, Any] = pipe(generator=snake_case__ , encoding=snake_case__ )
snake_case : str = output.images[0]
snake_case : Optional[Any] = np.frombuffer(image.tobytes() , dtype="uint8" )[:10]
snake_case : int = np.array([1_07, 1_03, 1_20, 1_27, 1_42, 1_22, 1_13, 1_22, 97, 1_11] )
assert np.abs(image_slice.flatten() - expected_slice ).max() == 0
@slow
@require_torch_gpu
class UpperCAmelCase ( unittest.TestCase ):
def _SCREAMING_SNAKE_CASE (self : str ) -> List[str]:
'''simple docstring'''
super().tearDown()
gc.collect()
torch.cuda.empty_cache()
def _SCREAMING_SNAKE_CASE (self : Dict ) -> Optional[Any]:
'''simple docstring'''
snake_case : Union[str, Any] = torch_device
snake_case : str = DiffusionPipeline.from_pretrained("teticio/audio-diffusion-ddim-256" )
snake_case : Optional[Any] = pipe.to(snake_case__ )
pipe.set_progress_bar_config(disable=snake_case__ )
snake_case : List[str] = torch.Generator(device=snake_case__ ).manual_seed(42 )
snake_case : str = pipe(generator=snake_case__ )
snake_case : Optional[int] = output.audios[0]
snake_case : Optional[Any] = output.images[0]
assert audio.shape == (1, (pipe.unet.config.sample_size[1] - 1) * pipe.mel.hop_length)
assert image.height == pipe.unet.config.sample_size[0] and image.width == pipe.unet.config.sample_size[1]
snake_case : Tuple = np.frombuffer(image.tobytes() , dtype="uint8" )[:10]
snake_case : Union[str, Any] = np.array([1_51, 1_67, 1_54, 1_44, 1_22, 1_34, 1_21, 1_05, 70, 26] )
assert np.abs(image_slice.flatten() - expected_slice ).max() == 0
| 59
|
import collections
import inspect
import unittest
from typing import Dict, List, Tuple
from transformers import MaskFormerSwinConfig
from transformers.testing_utils import require_torch, require_torch_multi_gpu, torch_device
from transformers.utils import is_torch_available
from ...test_backbone_common import BackboneTesterMixin
from ...test_configuration_common import ConfigTester
from ...test_modeling_common import ModelTesterMixin, floats_tensor, ids_tensor
from ...test_pipeline_mixin import PipelineTesterMixin
if is_torch_available():
import torch
from torch import nn
from transformers import MaskFormerSwinBackbone
from transformers.models.maskformer import MaskFormerSwinModel
class UpperCAmelCase :
def __init__(self : Dict , snake_case__ : Dict , snake_case__ : Any=13 , snake_case__ : Any=32 , snake_case__ : Optional[Any]=2 , snake_case__ : Union[str, Any]=3 , snake_case__ : List[Any]=16 , snake_case__ : int=[1, 2, 1] , snake_case__ : Dict=[2, 2, 4] , snake_case__ : Dict=2 , snake_case__ : Tuple=2.0 , snake_case__ : Optional[int]=True , snake_case__ : Union[str, Any]=0.0 , snake_case__ : Any=0.0 , snake_case__ : Union[str, Any]=0.1 , snake_case__ : int="gelu" , snake_case__ : Optional[int]=False , snake_case__ : List[Any]=True , snake_case__ : List[str]=0.02 , snake_case__ : int=1e-5 , snake_case__ : List[str]=True , snake_case__ : Union[str, Any]=None , snake_case__ : List[Any]=True , snake_case__ : Optional[Any]=10 , snake_case__ : Optional[Any]=8 , snake_case__ : Any=["stage1", "stage2", "stage3"] , snake_case__ : Tuple=[1, 2, 3] , ) -> Union[str, Any]:
'''simple docstring'''
snake_case : Any = parent
snake_case : Optional[int] = batch_size
snake_case : Union[str, Any] = image_size
snake_case : Dict = patch_size
snake_case : Optional[Any] = num_channels
snake_case : Union[str, Any] = embed_dim
snake_case : int = depths
snake_case : List[str] = num_heads
snake_case : Union[str, Any] = window_size
snake_case : Union[str, Any] = mlp_ratio
snake_case : List[Any] = qkv_bias
snake_case : List[Any] = hidden_dropout_prob
snake_case : Union[str, Any] = attention_probs_dropout_prob
snake_case : Union[str, Any] = drop_path_rate
snake_case : int = hidden_act
snake_case : Optional[int] = use_absolute_embeddings
snake_case : int = patch_norm
snake_case : Union[str, Any] = layer_norm_eps
snake_case : Any = initializer_range
snake_case : Optional[Any] = is_training
snake_case : Tuple = scope
snake_case : Optional[int] = use_labels
snake_case : Optional[Any] = type_sequence_label_size
snake_case : Union[str, Any] = encoder_stride
snake_case : Any = out_features
snake_case : Tuple = out_indices
def _SCREAMING_SNAKE_CASE (self : Optional[Any] ) -> Dict:
'''simple docstring'''
snake_case : Optional[Any] = floats_tensor([self.batch_size, self.num_channels, self.image_size, self.image_size] )
snake_case : int = None
if self.use_labels:
snake_case : Tuple = ids_tensor([self.batch_size] , self.type_sequence_label_size )
snake_case : Dict = self.get_config()
return config, pixel_values, labels
def _SCREAMING_SNAKE_CASE (self : List[str] ) -> int:
'''simple docstring'''
return MaskFormerSwinConfig(
image_size=self.image_size , patch_size=self.patch_size , num_channels=self.num_channels , embed_dim=self.embed_dim , depths=self.depths , num_heads=self.num_heads , window_size=self.window_size , mlp_ratio=self.mlp_ratio , qkv_bias=self.qkv_bias , hidden_dropout_prob=self.hidden_dropout_prob , attention_probs_dropout_prob=self.attention_probs_dropout_prob , drop_path_rate=self.drop_path_rate , hidden_act=self.hidden_act , use_absolute_embeddings=self.use_absolute_embeddings , path_norm=self.patch_norm , layer_norm_eps=self.layer_norm_eps , initializer_range=self.initializer_range , encoder_stride=self.encoder_stride , out_features=self.out_features , out_indices=self.out_indices , )
def _SCREAMING_SNAKE_CASE (self : Tuple , snake_case__ : List[Any] , snake_case__ : List[str] , snake_case__ : Tuple ) -> Optional[Any]:
'''simple docstring'''
snake_case : Union[str, Any] = MaskFormerSwinModel(config=snake_case__ )
model.to(snake_case__ )
model.eval()
snake_case : List[Any] = model(snake_case__ )
snake_case : Dict = ((config.image_size // config.patch_size) ** 2) // (4 ** (len(config.depths ) - 1))
snake_case : int = int(config.embed_dim * 2 ** (len(config.depths ) - 1) )
self.parent.assertEqual(result.last_hidden_state.shape , (self.batch_size, expected_seq_len, expected_dim) )
def _SCREAMING_SNAKE_CASE (self : List[str] , snake_case__ : Union[str, Any] , snake_case__ : List[Any] , snake_case__ : Union[str, Any] ) -> str:
'''simple docstring'''
snake_case : Optional[int] = MaskFormerSwinBackbone(config=snake_case__ )
model.to(snake_case__ )
model.eval()
snake_case : List[Any] = model(snake_case__ )
# verify feature maps
self.parent.assertEqual(len(result.feature_maps ) , len(config.out_features ) )
self.parent.assertListEqual(list(result.feature_maps[0].shape ) , [13, 16, 16, 16] )
# verify channels
self.parent.assertEqual(len(model.channels ) , len(config.out_features ) )
self.parent.assertListEqual(model.channels , [16, 32, 64] )
# verify ValueError
with self.parent.assertRaises(snake_case__ ):
snake_case : Tuple = ["stem"]
snake_case : List[Any] = MaskFormerSwinBackbone(config=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : List[Any] ) -> List[Any]:
'''simple docstring'''
snake_case : Union[str, Any] = self.prepare_config_and_inputs()
snake_case , snake_case , snake_case : List[Any] = config_and_inputs
snake_case : int = {"pixel_values": pixel_values}
return config, inputs_dict
@require_torch
class UpperCAmelCase ( A_ ,A_ ,unittest.TestCase ):
A__ : List[str] = (
(
MaskFormerSwinModel,
MaskFormerSwinBackbone,
)
if is_torch_available()
else ()
)
A__ : str = {"feature-extraction": MaskFormerSwinModel} if is_torch_available() else {}
A__ : Optional[Any] = False
A__ : List[Any] = False
A__ : List[str] = False
A__ : List[str] = False
A__ : Union[str, Any] = False
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> List[str]:
'''simple docstring'''
snake_case : str = MaskFormerSwinModelTester(self )
snake_case : Optional[int] = ConfigTester(self , config_class=snake_case__ , embed_dim=37 )
@require_torch_multi_gpu
@unittest.skip(
reason=(
"`MaskFormerSwinModel` outputs `hidden_states_spatial_dimensions` which doesn't work well with"
" `nn.DataParallel`"
) )
def _SCREAMING_SNAKE_CASE (self : str ) -> Optional[Any]:
'''simple docstring'''
pass
def _SCREAMING_SNAKE_CASE (self : str ) -> List[str]:
'''simple docstring'''
self.create_and_test_config_common_properties()
self.config_tester.create_and_test_config_to_json_string()
self.config_tester.create_and_test_config_to_json_file()
self.config_tester.create_and_test_config_from_and_save_pretrained()
self.config_tester.create_and_test_config_with_num_labels()
self.config_tester.check_config_can_be_init_without_params()
self.config_tester.check_config_arguments_init()
def _SCREAMING_SNAKE_CASE (self : Tuple ) -> List[Any]:
'''simple docstring'''
return
def _SCREAMING_SNAKE_CASE (self : Dict ) -> str:
'''simple docstring'''
snake_case : str = self.model_tester.prepare_config_and_inputs()
self.model_tester.create_and_check_model(*snake_case__ )
def _SCREAMING_SNAKE_CASE (self : int ) -> Dict:
'''simple docstring'''
snake_case : Any = self.model_tester.prepare_config_and_inputs()
self.model_tester.create_and_check_backbone(*snake_case__ )
@unittest.skip("Swin does not use inputs_embeds" )
def _SCREAMING_SNAKE_CASE (self : int ) -> Any:
'''simple docstring'''
pass
@unittest.skip("Swin does not support feedforward chunking" )
def _SCREAMING_SNAKE_CASE (self : List[str] ) -> Dict:
'''simple docstring'''
pass
def _SCREAMING_SNAKE_CASE (self : Optional[Any] ) -> List[str]:
'''simple docstring'''
snake_case , snake_case : Any = self.model_tester.prepare_config_and_inputs_for_common()
for model_class in self.all_model_classes:
snake_case : int = model_class(snake_case__ )
self.assertIsInstance(model.get_input_embeddings() , (nn.Module) )
snake_case : List[Any] = model.get_output_embeddings()
self.assertTrue(x is None or isinstance(snake_case__ , nn.Linear ) )
def _SCREAMING_SNAKE_CASE (self : Optional[Any] ) -> Dict:
'''simple docstring'''
snake_case , snake_case : str = self.model_tester.prepare_config_and_inputs_for_common()
for model_class in self.all_model_classes:
snake_case : str = model_class(snake_case__ )
snake_case : Optional[int] = inspect.signature(model.forward )
# signature.parameters is an OrderedDict => so arg_names order is deterministic
snake_case : Optional[Any] = [*signature.parameters.keys()]
snake_case : Tuple = ["pixel_values"]
self.assertListEqual(arg_names[:1] , snake_case__ )
@unittest.skip(reason="MaskFormerSwin is only used as backbone and doesn't support output_attentions" )
def _SCREAMING_SNAKE_CASE (self : List[Any] ) -> str:
'''simple docstring'''
pass
@unittest.skip(reason="MaskFormerSwin is only used as an internal backbone" )
def _SCREAMING_SNAKE_CASE (self : Tuple ) -> Any:
'''simple docstring'''
pass
def _SCREAMING_SNAKE_CASE (self : Optional[Any] , snake_case__ : List[Any] , snake_case__ : str , snake_case__ : List[Any] , snake_case__ : Tuple ) -> Optional[int]:
'''simple docstring'''
snake_case : Tuple = model_class(snake_case__ )
model.to(snake_case__ )
model.eval()
with torch.no_grad():
snake_case : Any = model(**self._prepare_for_class(snake_case__ , snake_case__ ) )
snake_case : int = outputs.hidden_states
snake_case : Union[str, Any] = getattr(
self.model_tester , "expected_num_hidden_layers" , len(self.model_tester.depths ) + 1 )
self.assertEqual(len(snake_case__ ) , snake_case__ )
# Swin has a different seq_length
snake_case : Any = (
config.patch_size
if isinstance(config.patch_size , collections.abc.Iterable )
else (config.patch_size, config.patch_size)
)
snake_case : Tuple = (image_size[1] // patch_size[1]) * (image_size[0] // patch_size[0])
self.assertListEqual(
list(hidden_states[0].shape[-2:] ) , [num_patches, self.model_tester.embed_dim] , )
def _SCREAMING_SNAKE_CASE (self : Dict ) -> Union[str, Any]:
'''simple docstring'''
snake_case , snake_case : List[Any] = self.model_tester.prepare_config_and_inputs_for_common()
snake_case : int = (
self.model_tester.image_size
if isinstance(self.model_tester.image_size , collections.abc.Iterable )
else (self.model_tester.image_size, self.model_tester.image_size)
)
for model_class in self.all_model_classes:
snake_case : int = True
self.check_hidden_states_output(snake_case__ , snake_case__ , snake_case__ , snake_case__ )
# check that output_hidden_states also work using config
del inputs_dict["output_hidden_states"]
snake_case : Dict = True
self.check_hidden_states_output(snake_case__ , snake_case__ , snake_case__ , snake_case__ )
def _SCREAMING_SNAKE_CASE (self : int ) -> Any:
'''simple docstring'''
snake_case , snake_case : Union[str, Any] = self.model_tester.prepare_config_and_inputs_for_common()
snake_case : Any = 3
snake_case : List[str] = (
self.model_tester.image_size
if isinstance(self.model_tester.image_size , collections.abc.Iterable )
else (self.model_tester.image_size, self.model_tester.image_size)
)
snake_case : Tuple = (
config.patch_size
if isinstance(config.patch_size , collections.abc.Iterable )
else (config.patch_size, config.patch_size)
)
snake_case : str = image_size[0] + patch_size[0] - (image_size[0] % patch_size[0])
snake_case : str = image_size[1] + patch_size[1] - (image_size[1] % patch_size[1])
for model_class in self.all_model_classes:
snake_case : str = True
self.check_hidden_states_output(snake_case__ , snake_case__ , snake_case__ , (padded_height, padded_width) )
# check that output_hidden_states also work using config
del inputs_dict["output_hidden_states"]
snake_case : Optional[Any] = True
self.check_hidden_states_output(snake_case__ , snake_case__ , snake_case__ , (padded_height, padded_width) )
@unittest.skip(reason="MaskFormerSwin doesn't have pretrained checkpoints" )
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> str:
'''simple docstring'''
pass
@unittest.skip(reason="This will be fixed once MaskFormerSwin is replaced by native Swin" )
def _SCREAMING_SNAKE_CASE (self : str ) -> int:
'''simple docstring'''
pass
@unittest.skip(reason="This will be fixed once MaskFormerSwin is replaced by native Swin" )
def _SCREAMING_SNAKE_CASE (self : int ) -> str:
'''simple docstring'''
pass
def _SCREAMING_SNAKE_CASE (self : Any ) -> Any:
'''simple docstring'''
snake_case , snake_case : List[Any] = self.model_tester.prepare_config_and_inputs_for_common()
def set_nan_tensor_to_zero(snake_case__ : Union[str, Any] ):
snake_case : Any = 0
return t
def check_equivalence(snake_case__ : Union[str, Any] , snake_case__ : int , snake_case__ : List[str] , snake_case__ : Optional[int]={} ):
with torch.no_grad():
snake_case : Optional[Any] = model(**snake_case__ , return_dict=snake_case__ , **snake_case__ )
snake_case : Tuple = model(**snake_case__ , return_dict=snake_case__ , **snake_case__ ).to_tuple()
def recursive_check(snake_case__ : List[str] , snake_case__ : Optional[Any] ):
if isinstance(snake_case__ , (List, Tuple) ):
for tuple_iterable_value, dict_iterable_value in zip(snake_case__ , snake_case__ ):
recursive_check(snake_case__ , snake_case__ )
elif isinstance(snake_case__ , snake_case__ ):
for tuple_iterable_value, dict_iterable_value in zip(
tuple_object.values() , dict_object.values() ):
recursive_check(snake_case__ , snake_case__ )
elif tuple_object is None:
return
else:
self.assertTrue(
torch.allclose(
set_nan_tensor_to_zero(snake_case__ ) , set_nan_tensor_to_zero(snake_case__ ) , atol=1e-5 ) , msg=(
"Tuple and dict output are not equal. Difference:"
f""" {torch.max(torch.abs(tuple_object - dict_object ) )}. Tuple has `nan`:"""
f""" {torch.isnan(snake_case__ ).any()} and `inf`: {torch.isinf(snake_case__ )}. Dict has"""
f""" `nan`: {torch.isnan(snake_case__ ).any()} and `inf`: {torch.isinf(snake_case__ )}."""
) , )
recursive_check(snake_case__ , snake_case__ )
for model_class in self.all_model_classes:
snake_case : Optional[int] = model_class(snake_case__ )
model.to(snake_case__ )
model.eval()
snake_case : Union[str, Any] = self._prepare_for_class(snake_case__ , snake_case__ )
snake_case : Tuple = self._prepare_for_class(snake_case__ , snake_case__ )
check_equivalence(snake_case__ , snake_case__ , snake_case__ )
snake_case : Tuple = self._prepare_for_class(snake_case__ , snake_case__ , return_labels=snake_case__ )
snake_case : Optional[Any] = self._prepare_for_class(snake_case__ , snake_case__ , return_labels=snake_case__ )
check_equivalence(snake_case__ , snake_case__ , snake_case__ )
snake_case : Dict = self._prepare_for_class(snake_case__ , snake_case__ )
snake_case : List[Any] = self._prepare_for_class(snake_case__ , snake_case__ )
check_equivalence(snake_case__ , snake_case__ , snake_case__ , {"output_hidden_states": True} )
snake_case : Any = self._prepare_for_class(snake_case__ , snake_case__ , return_labels=snake_case__ )
snake_case : List[str] = self._prepare_for_class(snake_case__ , snake_case__ , return_labels=snake_case__ )
check_equivalence(snake_case__ , snake_case__ , snake_case__ , {"output_hidden_states": True} )
@require_torch
class UpperCAmelCase ( unittest.TestCase ,A_ ):
A__ : int = (MaskFormerSwinBackbone,) if is_torch_available() else ()
A__ : int = MaskFormerSwinConfig
def _SCREAMING_SNAKE_CASE (self : List[Any] ) -> Any:
'''simple docstring'''
snake_case : Union[str, Any] = MaskFormerSwinModelTester(self )
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> Optional[Any]:
'''simple docstring'''
snake_case , snake_case : Dict = self.model_tester.prepare_config_and_inputs_for_common()
snake_case : Optional[int] = inputs_dict["pixel_values"].shape[0]
for backbone_class in self.all_model_classes:
snake_case : Optional[int] = backbone_class(snake_case__ )
backbone.to(snake_case__ )
backbone.eval()
snake_case : Union[str, Any] = backbone(**snake_case__ )
# Test default outputs and verify feature maps
self.assertIsInstance(outputs.feature_maps , snake_case__ )
self.assertTrue(len(outputs.feature_maps ) == len(backbone.channels ) )
for feature_map, n_channels in zip(outputs.feature_maps , backbone.channels ):
self.assertTrue(feature_map.shape[:2] , (batch_size, n_channels) )
self.assertIsNone(outputs.hidden_states )
self.assertIsNone(outputs.attentions )
# Test output_hidden_states=True
snake_case : Optional[int] = backbone(**snake_case__ , output_hidden_states=snake_case__ )
self.assertIsNotNone(outputs.hidden_states )
self.assertTrue(len(outputs.hidden_states ) , len(backbone.stage_names ) )
# We skip the stem layer
for hidden_states, n_channels in zip(outputs.hidden_states[1:] , backbone.channels ):
for hidden_state in hidden_states:
# Hidden states are in the format (batch_size, (height * width), n_channels)
snake_case , snake_case , snake_case : Dict = hidden_state.shape
self.assertTrue((h_batch_size, h_n_channels) , (batch_size, n_channels) )
# Test output_attentions=True
if self.has_attentions:
snake_case : Optional[Any] = backbone(**snake_case__ , output_attentions=snake_case__ )
self.assertIsNotNone(outputs.attentions )
| 59
| 1
|
from __future__ import annotations
def UpperCamelCase ( __lowerCamelCase : dict , __lowerCamelCase : str ):
snake_case , snake_case : Union[str, Any] = set(__lowerCamelCase ), [start]
while stack:
snake_case : str = stack.pop()
explored.add(__lowerCamelCase )
# Differences from BFS:
# 1) pop last element instead of first one
# 2) add adjacent elements to stack without exploring them
for adj in reversed(graph[v] ):
if adj not in explored:
stack.append(__lowerCamelCase )
return explored
__lowerCamelCase = {
"""A""": ["""B""", """C""", """D"""],
"""B""": ["""A""", """D""", """E"""],
"""C""": ["""A""", """F"""],
"""D""": ["""B""", """D"""],
"""E""": ["""B""", """F"""],
"""F""": ["""C""", """E""", """G"""],
"""G""": ["""F"""],
}
if __name__ == "__main__":
import doctest
doctest.testmod()
print(depth_first_search(G, """A"""))
| 59
|
from typing import Dict
import numpy as np
import torch
from . import residue_constants as rc
from .tensor_utils import tensor_tree_map, tree_map
def UpperCamelCase ( __lowerCamelCase : Dict[str, torch.Tensor] ):
snake_case : List[str] = []
snake_case : Optional[int] = []
snake_case : Any = []
for rt in rc.restypes:
snake_case : List[Any] = rc.restype_name_to_atomaa_names[rc.restype_atoa[rt]]
restype_atomaa_to_atomaa_list.append([(rc.atom_order[name] if name else 0) for name in atom_names] )
snake_case : str = {name: i for i, name in enumerate(__lowerCamelCase )}
restype_atomaa_to_atomaa_list.append(
[(atom_name_to_idxaa[name] if name in atom_name_to_idxaa else 0) for name in rc.atom_types] )
restype_atomaa_mask_list.append([(1.0 if name else 0.0) for name in atom_names] )
# Add dummy mapping for restype 'UNK'
restype_atomaa_to_atomaa_list.append([0] * 14 )
restype_atomaa_to_atomaa_list.append([0] * 37 )
restype_atomaa_mask_list.append([0.0] * 14 )
snake_case : Optional[Any] = torch.tensor(
__lowerCamelCase , dtype=torch.intaa , device=protein["aatype"].device , )
snake_case : List[Any] = torch.tensor(
__lowerCamelCase , dtype=torch.intaa , device=protein["aatype"].device , )
snake_case : int = torch.tensor(
__lowerCamelCase , dtype=torch.floataa , device=protein["aatype"].device , )
snake_case : int = protein["aatype"].to(torch.long )
# create the mapping for (residx, atom14) --> atom37, i.e. an array
# with shape (num_res, 14) containing the atom37 indices for this protein
snake_case : List[Any] = restype_atomaa_to_atomaa[protein_aatype]
snake_case : str = restype_atomaa_mask[protein_aatype]
snake_case : str = residx_atomaa_mask
snake_case : Any = residx_atomaa_to_atomaa.long()
# create the gather indices for mapping back
snake_case : List[str] = restype_atomaa_to_atomaa[protein_aatype]
snake_case : List[Any] = residx_atomaa_to_atomaa.long()
# create the corresponding mask
snake_case : Union[str, Any] = torch.zeros([21, 37] , dtype=torch.floataa , device=protein["aatype"].device )
for restype, restype_letter in enumerate(rc.restypes ):
snake_case : Optional[int] = rc.restype_atoa[restype_letter]
snake_case : Any = rc.residue_atoms[restype_name]
for atom_name in atom_names:
snake_case : List[Any] = rc.atom_order[atom_name]
snake_case : Optional[Any] = 1
snake_case : List[Any] = restype_atomaa_mask[protein_aatype]
snake_case : int = residx_atomaa_mask
return protein
def UpperCamelCase ( __lowerCamelCase : Dict[str, torch.Tensor] ):
snake_case : Dict = tree_map(lambda __lowerCamelCase : torch.tensor(__lowerCamelCase , device=batch["aatype"].device ) , __lowerCamelCase , np.ndarray )
snake_case : List[str] = tensor_tree_map(lambda __lowerCamelCase : np.array(__lowerCamelCase ) , make_atomaa_masks(__lowerCamelCase ) )
return out
| 59
| 1
|
import asyncio
import os
import re
import sys
import tempfile
import unittest
from contextlib import contextmanager
from copy import deepcopy
from distutils.util import strtobool
from enum import Enum
from importlib.util import find_spec
from pathlib import Path
from unittest.mock import patch
import pyarrow as pa
import pytest
import requests
from packaging import version
from datasets import config
if config.PY_VERSION < version.parse("""3.8"""):
import importlib_metadata
else:
import importlib.metadata as importlib_metadata
def UpperCamelCase ( __lowerCamelCase : Dict , __lowerCamelCase : str=False ):
try:
snake_case : Union[str, Any] = os.environ[key]
except KeyError:
# KEY isn't set, default to `default`.
snake_case : Tuple = default
else:
# KEY is set, convert it to True or False.
try:
snake_case : Optional[Any] = strtobool(__lowerCamelCase )
except ValueError:
# More values are supported, but let's keep the message simple.
raise ValueError(f"""If set, {key} must be yes or no.""" )
return _value
__lowerCamelCase = parse_flag_from_env("""RUN_SLOW""", default=False)
__lowerCamelCase = parse_flag_from_env("""RUN_REMOTE""", default=False)
__lowerCamelCase = parse_flag_from_env("""RUN_LOCAL""", default=True)
__lowerCamelCase = parse_flag_from_env("""RUN_PACKAGED""", default=True)
# Compression
__lowerCamelCase = pytest.mark.skipif(not config.LZ4_AVAILABLE, reason="""test requires lz4""")
__lowerCamelCase = pytest.mark.skipif(not config.PY7ZR_AVAILABLE, reason="""test requires py7zr""")
__lowerCamelCase = pytest.mark.skipif(not config.ZSTANDARD_AVAILABLE, reason="""test requires zstandard""")
# Audio
__lowerCamelCase = pytest.mark.skipif(
# On Windows and OS X, soundfile installs sndfile
find_spec("""soundfile""") is None or version.parse(importlib_metadata.version("""soundfile""")) < version.parse("""0.12.0"""),
reason="""test requires sndfile>=0.12.1: 'pip install \"soundfile>=0.12.1\"'; """,
)
# Beam
__lowerCamelCase = pytest.mark.skipif(
not config.BEAM_AVAILABLE or config.DILL_VERSION >= version.parse("""0.3.2"""),
reason="""test requires apache-beam and a compatible dill version""",
)
# Dill-cloudpickle compatibility
__lowerCamelCase = pytest.mark.skipif(
config.DILL_VERSION <= version.parse("""0.3.2"""),
reason="""test requires dill>0.3.2 for cloudpickle compatibility""",
)
# Windows
__lowerCamelCase = pytest.mark.skipif(
sys.platform == """win32""",
reason="""test should not be run on Windows""",
)
def UpperCamelCase ( __lowerCamelCase : Tuple ):
try:
import faiss # noqa
except ImportError:
snake_case : int = unittest.skip("test requires faiss" )(__lowerCamelCase )
return test_case
def UpperCamelCase ( __lowerCamelCase : Dict ):
try:
import regex # noqa
except ImportError:
snake_case : Optional[Any] = unittest.skip("test requires regex" )(__lowerCamelCase )
return test_case
def UpperCamelCase ( __lowerCamelCase : Tuple ):
try:
import elasticsearch # noqa
except ImportError:
snake_case : Optional[Any] = unittest.skip("test requires elasticsearch" )(__lowerCamelCase )
return test_case
def UpperCamelCase ( __lowerCamelCase : List[str] ):
try:
import sqlalchemy # noqa
except ImportError:
snake_case : Any = unittest.skip("test requires sqlalchemy" )(__lowerCamelCase )
return test_case
def UpperCamelCase ( __lowerCamelCase : Optional[int] ):
if not config.TORCH_AVAILABLE:
snake_case : Any = unittest.skip("test requires PyTorch" )(__lowerCamelCase )
return test_case
def UpperCamelCase ( __lowerCamelCase : Tuple ):
if not config.TF_AVAILABLE:
snake_case : int = unittest.skip("test requires TensorFlow" )(__lowerCamelCase )
return test_case
def UpperCamelCase ( __lowerCamelCase : Union[str, Any] ):
if not config.JAX_AVAILABLE:
snake_case : List[Any] = unittest.skip("test requires JAX" )(__lowerCamelCase )
return test_case
def UpperCamelCase ( __lowerCamelCase : Dict ):
if not config.PIL_AVAILABLE:
snake_case : List[str] = unittest.skip("test requires Pillow" )(__lowerCamelCase )
return test_case
def UpperCamelCase ( __lowerCamelCase : Optional[int] ):
try:
import transformers # noqa F401
except ImportError:
return unittest.skip("test requires transformers" )(__lowerCamelCase )
else:
return test_case
def UpperCamelCase ( __lowerCamelCase : List[str] ):
try:
import tiktoken # noqa F401
except ImportError:
return unittest.skip("test requires tiktoken" )(__lowerCamelCase )
else:
return test_case
def UpperCamelCase ( __lowerCamelCase : Tuple ):
try:
import spacy # noqa F401
except ImportError:
return unittest.skip("test requires spacy" )(__lowerCamelCase )
else:
return test_case
def UpperCamelCase ( __lowerCamelCase : Optional[int] ):
def _require_spacy_model(__lowerCamelCase : Optional[Any] ):
try:
import spacy # noqa F401
spacy.load(__lowerCamelCase )
except ImportError:
return unittest.skip("test requires spacy" )(__lowerCamelCase )
except OSError:
return unittest.skip("test requires spacy model '{}'".format(__lowerCamelCase ) )(__lowerCamelCase )
else:
return test_case
return _require_spacy_model
def UpperCamelCase ( __lowerCamelCase : Dict ):
try:
import pyspark # noqa F401
except ImportError:
return unittest.skip("test requires pyspark" )(__lowerCamelCase )
else:
return test_case
def UpperCamelCase ( __lowerCamelCase : int ):
try:
import joblibspark # noqa F401
except ImportError:
return unittest.skip("test requires joblibspark" )(__lowerCamelCase )
else:
return test_case
def UpperCamelCase ( __lowerCamelCase : Dict ):
if not _run_slow_tests or _run_slow_tests == 0:
snake_case : Union[str, Any] = unittest.skip("test is slow" )(__lowerCamelCase )
return test_case
def UpperCamelCase ( __lowerCamelCase : Union[str, Any] ):
if not _run_local_tests or _run_local_tests == 0:
snake_case : List[str] = unittest.skip("test is local" )(__lowerCamelCase )
return test_case
def UpperCamelCase ( __lowerCamelCase : Dict ):
if not _run_packaged_tests or _run_packaged_tests == 0:
snake_case : Tuple = unittest.skip("test is packaged" )(__lowerCamelCase )
return test_case
def UpperCamelCase ( __lowerCamelCase : Any ):
if not _run_remote_tests or _run_remote_tests == 0:
snake_case : int = unittest.skip("test requires remote" )(__lowerCamelCase )
return test_case
def UpperCamelCase ( *__lowerCamelCase : Dict ):
def decorate(cls : Union[str, Any] ):
for name, fn in cls.__dict__.items():
if callable(__lowerCamelCase ) and name.startswith("test" ):
for decorator in decorators:
snake_case : Optional[int] = decorator(__lowerCamelCase )
setattr(cls , __lowerCamelCase , __lowerCamelCase )
return cls
return decorate
class UpperCAmelCase ( A_ ):
pass
class UpperCAmelCase ( A_ ):
A__ : str = 0
A__ : Optional[Any] = 1
A__ : Optional[Any] = 2
@contextmanager
def UpperCamelCase ( __lowerCamelCase : Tuple=OfflineSimulationMode.CONNECTION_FAILS , __lowerCamelCase : Tuple=1E-16 ):
snake_case : Dict = requests.Session().request
def timeout_request(__lowerCamelCase : Dict , __lowerCamelCase : List[str] , __lowerCamelCase : List[Any] , **__lowerCamelCase : List[Any] ):
# Change the url to an invalid url so that the connection hangs
snake_case : Union[str, Any] = "https://10.255.255.1"
if kwargs.get("timeout" ) is None:
raise RequestWouldHangIndefinitelyError(
f"""Tried a call to {url} in offline mode with no timeout set. Please set a timeout.""" )
snake_case : Optional[Any] = timeout
try:
return online_request(__lowerCamelCase , __lowerCamelCase , **__lowerCamelCase )
except Exception as e:
# The following changes in the error are just here to make the offline timeout error prettier
snake_case : Union[str, Any] = url
snake_case : Union[str, Any] = e.args[0]
snake_case : Optional[int] = (max_retry_error.args[0].replace("10.255.255.1" , f"""OfflineMock[{url}]""" ),)
snake_case : Any = (max_retry_error,)
raise
def raise_connection_error(__lowerCamelCase : Tuple , __lowerCamelCase : Optional[Any] , **__lowerCamelCase : List[Any] ):
raise requests.ConnectionError("Offline mode is enabled." , request=__lowerCamelCase )
if mode is OfflineSimulationMode.CONNECTION_FAILS:
with patch("requests.Session.send" , __lowerCamelCase ):
yield
elif mode is OfflineSimulationMode.CONNECTION_TIMES_OUT:
# inspired from https://stackoverflow.com/a/904609
with patch("requests.Session.request" , __lowerCamelCase ):
yield
elif mode is OfflineSimulationMode.HF_DATASETS_OFFLINE_SET_TO_1:
with patch("datasets.config.HF_DATASETS_OFFLINE" , __lowerCamelCase ):
yield
else:
raise ValueError("Please use a value from the OfflineSimulationMode enum." )
@contextmanager
def UpperCamelCase ( *__lowerCamelCase : Any , **__lowerCamelCase : Optional[Any] ):
snake_case : str = str(Path().resolve() )
with tempfile.TemporaryDirectory(*__lowerCamelCase , **__lowerCamelCase ) as tmp_dir:
try:
os.chdir(__lowerCamelCase )
yield
finally:
os.chdir(__lowerCamelCase )
@contextmanager
def UpperCamelCase ( ):
import gc
gc.collect()
snake_case : Optional[int] = pa.total_allocated_bytes()
yield
assert pa.total_allocated_bytes() - previous_allocated_memory > 0, "Arrow memory didn't increase."
@contextmanager
def UpperCamelCase ( ):
import gc
gc.collect()
snake_case : Optional[int] = pa.total_allocated_bytes()
yield
assert pa.total_allocated_bytes() - previous_allocated_memory <= 0, "Arrow memory wasn't expected to increase."
def UpperCamelCase ( __lowerCamelCase : List[Any] , __lowerCamelCase : Dict ):
return deepcopy(__lowerCamelCase ).integers(0 , 100 , 10 ).tolist() == deepcopy(__lowerCamelCase ).integers(0 , 100 , 10 ).tolist()
def UpperCamelCase ( __lowerCamelCase : Dict ):
import decorator
from requests.exceptions import HTTPError
def _wrapper(__lowerCamelCase : Optional[int] , *__lowerCamelCase : int , **__lowerCamelCase : int ):
try:
return func(*__lowerCamelCase , **__lowerCamelCase )
except HTTPError as err:
if str(__lowerCamelCase ).startswith("500" ) or str(__lowerCamelCase ).startswith("502" ):
pytest.xfail(str(__lowerCamelCase ) )
raise err
return decorator.decorator(_wrapper , __lowerCamelCase )
class UpperCAmelCase :
def __init__(self : Dict , snake_case__ : List[str] , snake_case__ : int , snake_case__ : Any ) -> Optional[int]:
'''simple docstring'''
snake_case : List[str] = returncode
snake_case : str = stdout
snake_case : Union[str, Any] = stderr
async def UpperCamelCase ( __lowerCamelCase : Optional[Any] , __lowerCamelCase : Dict ):
while True:
snake_case : Any = await stream.readline()
if line:
callback(__lowerCamelCase )
else:
break
async def UpperCamelCase ( __lowerCamelCase : List[str] , __lowerCamelCase : int=None , __lowerCamelCase : Tuple=None , __lowerCamelCase : Optional[Any]=None , __lowerCamelCase : str=False , __lowerCamelCase : int=False ):
if echo:
print("\nRunning: " , " ".join(__lowerCamelCase ) )
snake_case : List[str] = await asyncio.create_subprocess_exec(
cmd[0] , *cmd[1:] , stdin=__lowerCamelCase , stdout=asyncio.subprocess.PIPE , stderr=asyncio.subprocess.PIPE , env=__lowerCamelCase , )
# note: there is a warning for a possible deadlock when using `wait` with huge amounts of data in the pipe
# https://docs.python.org/3/library/asyncio-subprocess.html#asyncio.asyncio.subprocess.Process.wait
#
# If it starts hanging, will need to switch to the following code. The problem is that no data
# will be seen until it's done and if it hangs for example there will be no debug info.
# out, err = await p.communicate()
# return _RunOutput(p.returncode, out, err)
snake_case : Dict = []
snake_case : Optional[Any] = []
def tee(__lowerCamelCase : Union[str, Any] , __lowerCamelCase : str , __lowerCamelCase : Optional[Any] , __lowerCamelCase : int="" ):
snake_case : Dict = line.decode("utf-8" ).rstrip()
sink.append(__lowerCamelCase )
if not quiet:
print(__lowerCamelCase , __lowerCamelCase , file=__lowerCamelCase )
# XXX: the timeout doesn't seem to make any difference here
await asyncio.wait(
[
_read_stream(p.stdout , lambda __lowerCamelCase : tee(__lowerCamelCase , __lowerCamelCase , sys.stdout , label="stdout:" ) ),
_read_stream(p.stderr , lambda __lowerCamelCase : tee(__lowerCamelCase , __lowerCamelCase , sys.stderr , label="stderr:" ) ),
] , timeout=__lowerCamelCase , )
return _RunOutput(await p.wait() , __lowerCamelCase , __lowerCamelCase )
def UpperCamelCase ( __lowerCamelCase : Optional[Any] , __lowerCamelCase : Optional[int]=None , __lowerCamelCase : Any=None , __lowerCamelCase : int=180 , __lowerCamelCase : List[str]=False , __lowerCamelCase : int=True ):
snake_case : Optional[int] = asyncio.get_event_loop()
snake_case : List[str] = loop.run_until_complete(
_stream_subprocess(__lowerCamelCase , env=__lowerCamelCase , stdin=__lowerCamelCase , timeout=__lowerCamelCase , quiet=__lowerCamelCase , echo=__lowerCamelCase ) )
snake_case : Union[str, Any] = " ".join(__lowerCamelCase )
if result.returncode > 0:
snake_case : Any = "\n".join(result.stderr )
raise RuntimeError(
f"""'{cmd_str}' failed with returncode {result.returncode}\n\n"""
f"""The combined stderr from workers follows:\n{stderr}""" )
# check that the subprocess actually did run and produced some output, should the test rely on
# the remote side to do the testing
if not result.stdout and not result.stderr:
raise RuntimeError(f"""'{cmd_str}' produced no output.""" )
return result
def UpperCamelCase ( ):
snake_case : List[Any] = os.environ.get("PYTEST_XDIST_WORKER" , "gw0" )
snake_case : List[str] = re.sub(r"^gw" , "" , __lowerCamelCase , 0 , re.M )
return int(__lowerCamelCase )
def UpperCamelCase ( ):
snake_case : Any = 29500
snake_case : Dict = pytest_xdist_worker_id()
return port + uniq_delta
| 59
|
import json
from typing import List, Optional, Tuple
from tokenizers import normalizers
from ...tokenization_utils_fast import PreTrainedTokenizerFast
from .tokenization_lxmert import LxmertTokenizer
__lowerCamelCase = {"""vocab_file""": """vocab.txt""", """tokenizer_file""": """tokenizer.json"""}
__lowerCamelCase = {
"""vocab_file""": {
"""unc-nlp/lxmert-base-uncased""": """https://huggingface.co/unc-nlp/lxmert-base-uncased/resolve/main/vocab.txt""",
},
"""tokenizer_file""": {
"""unc-nlp/lxmert-base-uncased""": (
"""https://huggingface.co/unc-nlp/lxmert-base-uncased/resolve/main/tokenizer.json"""
),
},
}
__lowerCamelCase = {
"""unc-nlp/lxmert-base-uncased""": 5_12,
}
__lowerCamelCase = {
"""unc-nlp/lxmert-base-uncased""": {"""do_lower_case""": True},
}
class UpperCAmelCase ( A_ ):
A__ : Any = VOCAB_FILES_NAMES
A__ : Optional[int] = PRETRAINED_VOCAB_FILES_MAP
A__ : Tuple = PRETRAINED_INIT_CONFIGURATION
A__ : Tuple = PRETRAINED_POSITIONAL_EMBEDDINGS_SIZES
A__ : List[Any] = LxmertTokenizer
def __init__(self : Dict , snake_case__ : Tuple=None , snake_case__ : Optional[Any]=None , snake_case__ : Optional[Any]=True , snake_case__ : Tuple="[UNK]" , snake_case__ : Optional[Any]="[SEP]" , snake_case__ : Optional[Any]="[PAD]" , snake_case__ : List[Any]="[CLS]" , snake_case__ : Tuple="[MASK]" , snake_case__ : Dict=True , snake_case__ : Union[str, Any]=None , **snake_case__ : Dict , ) -> Optional[int]:
'''simple docstring'''
super().__init__(
snake_case__ , tokenizer_file=snake_case__ , do_lower_case=snake_case__ , unk_token=snake_case__ , sep_token=snake_case__ , pad_token=snake_case__ , cls_token=snake_case__ , mask_token=snake_case__ , tokenize_chinese_chars=snake_case__ , strip_accents=snake_case__ , **snake_case__ , )
snake_case : int = json.loads(self.backend_tokenizer.normalizer.__getstate__() )
if (
normalizer_state.get("lowercase" , snake_case__ ) != do_lower_case
or normalizer_state.get("strip_accents" , snake_case__ ) != strip_accents
or normalizer_state.get("handle_chinese_chars" , snake_case__ ) != tokenize_chinese_chars
):
snake_case : Union[str, Any] = getattr(snake_case__ , normalizer_state.pop("type" ) )
snake_case : str = do_lower_case
snake_case : List[Any] = strip_accents
snake_case : Optional[int] = tokenize_chinese_chars
snake_case : int = normalizer_class(**snake_case__ )
snake_case : Optional[Any] = do_lower_case
def _SCREAMING_SNAKE_CASE (self : Union[str, Any] , snake_case__ : Optional[Any] , snake_case__ : Dict=None ) -> Any:
'''simple docstring'''
snake_case : Optional[int] = [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 _SCREAMING_SNAKE_CASE (self : Optional[int] , snake_case__ : List[int] , snake_case__ : Optional[List[int]] = None ) -> List[int]:
'''simple docstring'''
snake_case : Optional[Any] = [self.sep_token_id]
snake_case : Optional[Any] = [self.cls_token_id]
if token_ids_a is None:
return len(cls + token_ids_a + sep ) * [0]
return len(cls + token_ids_a + sep ) * [0] + len(token_ids_a + sep ) * [1]
def _SCREAMING_SNAKE_CASE (self : Any , snake_case__ : str , snake_case__ : Optional[str] = None ) -> Tuple[str]:
'''simple docstring'''
snake_case : List[Any] = self._tokenizer.model.save(snake_case__ , name=snake_case__ )
return tuple(snake_case__ )
| 59
| 1
|
def UpperCamelCase ( __lowerCamelCase : int , __lowerCamelCase : list ):
_enforce_args(__lowerCamelCase , __lowerCamelCase )
if n == 0:
return 0
snake_case : Optional[int] = float("-inf" )
for i in range(1 , n + 1 ):
snake_case : str = max(
__lowerCamelCase , prices[i - 1] + naive_cut_rod_recursive(n - i , __lowerCamelCase ) )
return max_revue
def UpperCamelCase ( __lowerCamelCase : int , __lowerCamelCase : list ):
_enforce_args(__lowerCamelCase , __lowerCamelCase )
snake_case : List[str] = [float("-inf" ) for _ in range(n + 1 )]
return _top_down_cut_rod_recursive(__lowerCamelCase , __lowerCamelCase , __lowerCamelCase )
def UpperCamelCase ( __lowerCamelCase : int , __lowerCamelCase : list , __lowerCamelCase : list ):
if max_rev[n] >= 0:
return max_rev[n]
elif n == 0:
return 0
else:
snake_case : str = float("-inf" )
for i in range(1 , n + 1 ):
snake_case : Optional[int] = max(
__lowerCamelCase , prices[i - 1] + _top_down_cut_rod_recursive(n - i , __lowerCamelCase , __lowerCamelCase ) , )
snake_case : Any = max_revenue
return max_rev[n]
def UpperCamelCase ( __lowerCamelCase : int , __lowerCamelCase : list ):
_enforce_args(__lowerCamelCase , __lowerCamelCase )
# length(max_rev) = n + 1, to accommodate for the revenue obtainable from a rod of
# length 0.
snake_case : Any = [float("-inf" ) for _ in range(n + 1 )]
snake_case : str = 0
for i in range(1 , n + 1 ):
snake_case : Union[str, Any] = max_rev[i]
for j in range(1 , i + 1 ):
snake_case : Tuple = max(__lowerCamelCase , prices[j - 1] + max_rev[i - j] )
snake_case : Optional[Any] = max_revenue_i
return max_rev[n]
def UpperCamelCase ( __lowerCamelCase : int , __lowerCamelCase : list ):
if n < 0:
snake_case : int = f"""n must be greater than or equal to 0. Got n = {n}"""
raise ValueError(__lowerCamelCase )
if n > len(__lowerCamelCase ):
snake_case : List[Any] = (
"Each integral piece of rod must have a corresponding price. "
f"""Got n = {n} but length of prices = {len(__lowerCamelCase )}"""
)
raise ValueError(__lowerCamelCase )
def UpperCamelCase ( ):
snake_case : int = [6, 10, 12, 15, 20, 23]
snake_case : Any = len(__lowerCamelCase )
# the best revenue comes from cutting the rod into 6 pieces, each
# of length 1 resulting in a revenue of 6 * 6 = 36.
snake_case : Optional[Any] = 36
snake_case : Tuple = top_down_cut_rod(__lowerCamelCase , __lowerCamelCase )
snake_case : List[str] = bottom_up_cut_rod(__lowerCamelCase , __lowerCamelCase )
snake_case : Union[str, Any] = naive_cut_rod_recursive(__lowerCamelCase , __lowerCamelCase )
assert expected_max_revenue == max_rev_top_down
assert max_rev_top_down == max_rev_bottom_up
assert max_rev_bottom_up == max_rev_naive
if __name__ == "__main__":
main()
| 59
|
import torch
from diffusers import DDIMParallelScheduler
from .test_schedulers import SchedulerCommonTest
class UpperCAmelCase ( A_ ):
A__ : Dict = (DDIMParallelScheduler,)
A__ : Tuple = (("eta", 0.0), ("num_inference_steps", 50))
def _SCREAMING_SNAKE_CASE (self : Tuple , **snake_case__ : Optional[int] ) -> Optional[Any]:
'''simple docstring'''
snake_case : Any = {
"num_train_timesteps": 10_00,
"beta_start": 0.0001,
"beta_end": 0.02,
"beta_schedule": "linear",
"clip_sample": True,
}
config.update(**snake_case__ )
return config
def _SCREAMING_SNAKE_CASE (self : Dict , **snake_case__ : Optional[int] ) -> Any:
'''simple docstring'''
snake_case : List[Any] = self.scheduler_classes[0]
snake_case : Any = self.get_scheduler_config(**snake_case__ )
snake_case : Any = scheduler_class(**snake_case__ )
snake_case , snake_case : Union[str, Any] = 10, 0.0
snake_case : List[Any] = self.dummy_model()
snake_case : Any = self.dummy_sample_deter
scheduler.set_timesteps(snake_case__ )
for t in scheduler.timesteps:
snake_case : Optional[int] = model(snake_case__ , snake_case__ )
snake_case : List[str] = scheduler.step(snake_case__ , snake_case__ , snake_case__ , snake_case__ ).prev_sample
return sample
def _SCREAMING_SNAKE_CASE (self : Union[str, Any] ) -> str:
'''simple docstring'''
for timesteps in [1_00, 5_00, 10_00]:
self.check_over_configs(num_train_timesteps=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : str ) -> int:
'''simple docstring'''
for steps_offset in [0, 1]:
self.check_over_configs(steps_offset=snake_case__ )
snake_case : Optional[int] = self.scheduler_classes[0]
snake_case : Optional[int] = self.get_scheduler_config(steps_offset=1 )
snake_case : Union[str, Any] = scheduler_class(**snake_case__ )
scheduler.set_timesteps(5 )
assert torch.equal(scheduler.timesteps , torch.LongTensor([8_01, 6_01, 4_01, 2_01, 1] ) )
def _SCREAMING_SNAKE_CASE (self : int ) -> Tuple:
'''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=snake_case__ , beta_end=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Union[str, Any] ) -> Union[str, Any]:
'''simple docstring'''
for schedule in ["linear", "squaredcos_cap_v2"]:
self.check_over_configs(beta_schedule=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : str ) -> Dict:
'''simple docstring'''
for prediction_type in ["epsilon", "v_prediction"]:
self.check_over_configs(prediction_type=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Optional[Any] ) -> List[str]:
'''simple docstring'''
for clip_sample in [True, False]:
self.check_over_configs(clip_sample=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : List[Any] ) -> List[Any]:
'''simple docstring'''
for timestep_spacing in ["trailing", "leading"]:
self.check_over_configs(timestep_spacing=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> List[Any]:
'''simple docstring'''
for rescale_betas_zero_snr in [True, False]:
self.check_over_configs(rescale_betas_zero_snr=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Optional[Any] ) -> Optional[Any]:
'''simple docstring'''
self.check_over_configs(thresholding=snake_case__ )
for threshold in [0.5, 1.0, 2.0]:
for prediction_type in ["epsilon", "v_prediction"]:
self.check_over_configs(
thresholding=snake_case__ , prediction_type=snake_case__ , sample_max_value=snake_case__ , )
def _SCREAMING_SNAKE_CASE (self : Any ) -> Any:
'''simple docstring'''
for t in [1, 10, 49]:
self.check_over_forward(time_step=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> Any:
'''simple docstring'''
for t, num_inference_steps in zip([1, 10, 50] , [10, 50, 5_00] ):
self.check_over_forward(time_step=snake_case__ , num_inference_steps=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : List[str] ) -> Optional[Any]:
'''simple docstring'''
for t, eta in zip([1, 10, 49] , [0.0, 0.5, 1.0] ):
self.check_over_forward(time_step=snake_case__ , eta=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Optional[Any] ) -> Optional[int]:
'''simple docstring'''
snake_case : Dict = self.scheduler_classes[0]
snake_case : Tuple = self.get_scheduler_config()
snake_case : Dict = scheduler_class(**snake_case__ )
assert torch.sum(torch.abs(scheduler._get_variance(0 , 0 ) - 0.0 ) ) < 1e-5
assert torch.sum(torch.abs(scheduler._get_variance(4_20 , 4_00 ) - 0.14771 ) ) < 1e-5
assert torch.sum(torch.abs(scheduler._get_variance(9_80 , 9_60 ) - 0.32460 ) ) < 1e-5
assert torch.sum(torch.abs(scheduler._get_variance(0 , 0 ) - 0.0 ) ) < 1e-5
assert torch.sum(torch.abs(scheduler._get_variance(4_87 , 4_86 ) - 0.00979 ) ) < 1e-5
assert torch.sum(torch.abs(scheduler._get_variance(9_99 , 9_98 ) - 0.02 ) ) < 1e-5
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> Dict:
'''simple docstring'''
snake_case : Union[str, Any] = self.scheduler_classes[0]
snake_case : List[Any] = self.get_scheduler_config()
snake_case : int = scheduler_class(**snake_case__ )
snake_case , snake_case : Any = 10, 0.0
scheduler.set_timesteps(snake_case__ )
snake_case : Optional[Any] = self.dummy_model()
snake_case : str = self.dummy_sample_deter
snake_case : Dict = self.dummy_sample_deter + 0.1
snake_case : Dict = self.dummy_sample_deter - 0.1
snake_case : Optional[Any] = samplea.shape[0]
snake_case : str = torch.stack([samplea, samplea, samplea] , dim=0 )
snake_case : Tuple = torch.arange(snake_case__ )[0:3, None].repeat(1 , snake_case__ )
snake_case : Tuple = model(samples.flatten(0 , 1 ) , timesteps.flatten(0 , 1 ) )
snake_case : List[str] = scheduler.batch_step_no_noise(snake_case__ , timesteps.flatten(0 , 1 ) , samples.flatten(0 , 1 ) , snake_case__ )
snake_case : Dict = torch.sum(torch.abs(snake_case__ ) )
snake_case : List[Any] = torch.mean(torch.abs(snake_case__ ) )
assert abs(result_sum.item() - 1147.7904 ) < 1e-2
assert abs(result_mean.item() - 0.4982 ) < 1e-3
def _SCREAMING_SNAKE_CASE (self : Optional[Any] ) -> Optional[Any]:
'''simple docstring'''
snake_case : List[Any] = self.full_loop()
snake_case : Optional[Any] = torch.sum(torch.abs(snake_case__ ) )
snake_case : List[Any] = torch.mean(torch.abs(snake_case__ ) )
assert abs(result_sum.item() - 172.0067 ) < 1e-2
assert abs(result_mean.item() - 0.223967 ) < 1e-3
def _SCREAMING_SNAKE_CASE (self : str ) -> Union[str, Any]:
'''simple docstring'''
snake_case : Dict = self.full_loop(prediction_type="v_prediction" )
snake_case : int = torch.sum(torch.abs(snake_case__ ) )
snake_case : Optional[int] = torch.mean(torch.abs(snake_case__ ) )
assert abs(result_sum.item() - 52.5302 ) < 1e-2
assert abs(result_mean.item() - 0.0684 ) < 1e-3
def _SCREAMING_SNAKE_CASE (self : Any ) -> Optional[Any]:
'''simple docstring'''
snake_case : Dict = self.full_loop(set_alpha_to_one=snake_case__ , beta_start=0.01 )
snake_case : str = torch.sum(torch.abs(snake_case__ ) )
snake_case : Optional[Any] = torch.mean(torch.abs(snake_case__ ) )
assert abs(result_sum.item() - 149.8295 ) < 1e-2
assert abs(result_mean.item() - 0.1951 ) < 1e-3
def _SCREAMING_SNAKE_CASE (self : int ) -> Optional[Any]:
'''simple docstring'''
snake_case : int = self.full_loop(set_alpha_to_one=snake_case__ , beta_start=0.01 )
snake_case : Tuple = torch.sum(torch.abs(snake_case__ ) )
snake_case : List[Any] = torch.mean(torch.abs(snake_case__ ) )
assert abs(result_sum.item() - 149.0784 ) < 1e-2
assert abs(result_mean.item() - 0.1941 ) < 1e-3
| 59
| 1
|
from typing import TYPE_CHECKING
from ...utils import OptionalDependencyNotAvailable, _LazyModule, is_tokenizers_available
__lowerCamelCase = {"""tokenization_herbert""": ["""HerbertTokenizer"""]}
try:
if not is_tokenizers_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = ["""HerbertTokenizerFast"""]
if TYPE_CHECKING:
from .tokenization_herbert import HerbertTokenizer
try:
if not is_tokenizers_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .tokenization_herbert_fast import HerbertTokenizerFast
else:
import sys
__lowerCamelCase = _LazyModule(__name__, globals()["""__file__"""], _import_structure, module_spec=__spec__)
| 59
|
def UpperCamelCase ( __lowerCamelCase : str , __lowerCamelCase : int ):
snake_case : list[list[str]] = [[] for _ in range(__lowerCamelCase )]
snake_case : int = key - 1
if key <= 0:
raise ValueError("Height of grid can't be 0 or negative" )
if key == 1 or len(__lowerCamelCase ) <= key:
return input_string
for position, character in enumerate(__lowerCamelCase ):
snake_case : Any = position % (lowest * 2) # puts it in bounds
snake_case : Optional[int] = min(__lowerCamelCase , lowest * 2 - num ) # creates zigzag pattern
temp_grid[num].append(__lowerCamelCase )
snake_case : List[str] = ["".join(__lowerCamelCase ) for row in temp_grid]
snake_case : Tuple = "".join(__lowerCamelCase )
return output_string
def UpperCamelCase ( __lowerCamelCase : str , __lowerCamelCase : int ):
snake_case : Dict = []
snake_case : Union[str, Any] = key - 1
if key <= 0:
raise ValueError("Height of grid can't be 0 or negative" )
if key == 1:
return input_string
snake_case : list[list[str]] = [[] for _ in range(__lowerCamelCase )] # generates template
for position in range(len(__lowerCamelCase ) ):
snake_case : List[str] = position % (lowest * 2) # puts it in bounds
snake_case : Optional[int] = min(__lowerCamelCase , lowest * 2 - num ) # creates zigzag pattern
temp_grid[num].append("*" )
snake_case : Tuple = 0
for row in temp_grid: # fills in the characters
snake_case : Union[str, Any] = input_string[counter : counter + len(__lowerCamelCase )]
grid.append(list(__lowerCamelCase ) )
counter += len(__lowerCamelCase )
snake_case : str = "" # reads as zigzag
for position in range(len(__lowerCamelCase ) ):
snake_case : Optional[int] = position % (lowest * 2) # puts it in bounds
snake_case : Tuple = min(__lowerCamelCase , lowest * 2 - num ) # creates zigzag pattern
output_string += grid[num][0]
grid[num].pop(0 )
return output_string
def UpperCamelCase ( __lowerCamelCase : str ):
snake_case : Tuple = {}
for key_guess in range(1 , len(__lowerCamelCase ) ): # tries every key
snake_case : Any = decrypt(__lowerCamelCase , __lowerCamelCase )
return results
if __name__ == "__main__":
import doctest
doctest.testmod()
| 59
| 1
|
import argparse
import glob
import logging
import os
import time
from argparse import Namespace
import numpy as np
import torch
from lightning_base import BaseTransformer, add_generic_args, generic_train
from torch.utils.data import DataLoader, TensorDataset
from transformers import glue_compute_metrics as compute_metrics
from transformers import glue_convert_examples_to_features as convert_examples_to_features
from transformers import glue_output_modes, glue_tasks_num_labels
from transformers import glue_processors as processors
__lowerCamelCase = logging.getLogger(__name__)
class UpperCAmelCase ( A_ ):
A__ : int = "sequence-classification"
def __init__(self : List[str] , snake_case__ : str ) -> Dict:
'''simple docstring'''
if type(snake_case__ ) == dict:
snake_case : Dict = Namespace(**snake_case__ )
snake_case : Dict = glue_output_modes[hparams.task]
snake_case : Union[str, Any] = glue_tasks_num_labels[hparams.task]
super().__init__(snake_case__ , snake_case__ , self.mode )
def _SCREAMING_SNAKE_CASE (self : Tuple , **snake_case__ : Optional[Any] ) -> Union[str, Any]:
'''simple docstring'''
return self.model(**snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Union[str, Any] , snake_case__ : List[str] , snake_case__ : List[Any] ) -> str:
'''simple docstring'''
snake_case : Union[str, Any] = {"input_ids": batch[0], "attention_mask": batch[1], "labels": batch[3]}
if self.config.model_type not in ["distilbert", "bart"]:
snake_case : Union[str, Any] = batch[2] if self.config.model_type in ["bert", "xlnet", "albert"] else None
snake_case : str = self(**snake_case__ )
snake_case : List[str] = outputs[0]
snake_case : List[str] = self.trainer.lr_schedulers[0]["scheduler"]
snake_case : Union[str, Any] = {"loss": loss, "rate": lr_scheduler.get_last_lr()[-1]}
return {"loss": loss, "log": tensorboard_logs}
def _SCREAMING_SNAKE_CASE (self : Dict ) -> Optional[int]:
'''simple docstring'''
snake_case : Optional[Any] = self.hparams
snake_case : Union[str, Any] = processors[args.task]()
snake_case : Union[str, Any] = processor.get_labels()
for mode in ["train", "dev"]:
snake_case : str = self._feature_file(snake_case__ )
if os.path.exists(snake_case__ ) and not args.overwrite_cache:
logger.info("Loading features from cached file %s" , snake_case__ )
else:
logger.info("Creating features from dataset file at %s" , args.data_dir )
snake_case : Union[str, Any] = (
processor.get_dev_examples(args.data_dir )
if mode == "dev"
else processor.get_train_examples(args.data_dir )
)
snake_case : Optional[int] = convert_examples_to_features(
snake_case__ , self.tokenizer , max_length=args.max_seq_length , label_list=self.labels , output_mode=args.glue_output_mode , )
logger.info("Saving features into cached file %s" , snake_case__ )
torch.save(snake_case__ , snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Dict , snake_case__ : str , snake_case__ : int , snake_case__ : bool = False ) -> DataLoader:
'''simple docstring'''
snake_case : Dict = "dev" if mode == "test" else mode
snake_case : Any = self._feature_file(snake_case__ )
logger.info("Loading features from cached file %s" , snake_case__ )
snake_case : Any = torch.load(snake_case__ )
snake_case : Any = torch.tensor([f.input_ids for f in features] , dtype=torch.long )
snake_case : str = torch.tensor([f.attention_mask for f in features] , dtype=torch.long )
snake_case : int = torch.tensor([f.token_type_ids for f in features] , dtype=torch.long )
if self.hparams.glue_output_mode == "classification":
snake_case : List[str] = torch.tensor([f.label for f in features] , dtype=torch.long )
elif self.hparams.glue_output_mode == "regression":
snake_case : Dict = torch.tensor([f.label for f in features] , dtype=torch.float )
return DataLoader(
TensorDataset(snake_case__ , snake_case__ , snake_case__ , snake_case__ ) , batch_size=snake_case__ , shuffle=snake_case__ , )
def _SCREAMING_SNAKE_CASE (self : str , snake_case__ : int , snake_case__ : Tuple ) -> str:
'''simple docstring'''
snake_case : str = {"input_ids": batch[0], "attention_mask": batch[1], "labels": batch[3]}
if self.config.model_type not in ["distilbert", "bart"]:
snake_case : List[Any] = batch[2] if self.config.model_type in ["bert", "xlnet", "albert"] else None
snake_case : Dict = self(**snake_case__ )
snake_case , snake_case : Union[str, Any] = outputs[:2]
snake_case : Union[str, Any] = logits.detach().cpu().numpy()
snake_case : Dict = inputs["labels"].detach().cpu().numpy()
return {"val_loss": tmp_eval_loss.detach().cpu(), "pred": preds, "target": out_label_ids}
def _SCREAMING_SNAKE_CASE (self : List[Any] , snake_case__ : Optional[int] ) -> tuple:
'''simple docstring'''
snake_case : int = torch.stack([x["val_loss"] for x in outputs] ).mean().detach().cpu().item()
snake_case : Optional[int] = np.concatenate([x["pred"] for x in outputs] , axis=0 )
if self.hparams.glue_output_mode == "classification":
snake_case : int = np.argmax(snake_case__ , axis=1 )
elif self.hparams.glue_output_mode == "regression":
snake_case : int = np.squeeze(snake_case__ )
snake_case : Dict = np.concatenate([x["target"] for x in outputs] , axis=0 )
snake_case : List[str] = [[] for _ in range(out_label_ids.shape[0] )]
snake_case : Optional[int] = [[] for _ in range(out_label_ids.shape[0] )]
snake_case : str = {**{"val_loss": val_loss_mean}, **compute_metrics(self.hparams.task , snake_case__ , snake_case__ )}
snake_case : Any = dict(results.items() )
snake_case : List[Any] = results
return ret, preds_list, out_label_list
def _SCREAMING_SNAKE_CASE (self : Union[str, Any] , snake_case__ : list ) -> dict:
'''simple docstring'''
snake_case , snake_case , snake_case : Union[str, Any] = self._eval_end(snake_case__ )
snake_case : List[str] = ret["log"]
return {"val_loss": logs["val_loss"], "log": logs, "progress_bar": logs}
def _SCREAMING_SNAKE_CASE (self : int , snake_case__ : Any ) -> dict:
'''simple docstring'''
snake_case , snake_case , snake_case : Optional[int] = self._eval_end(snake_case__ )
snake_case : List[Any] = ret["log"]
# `val_loss` is the key returned by `self._eval_end()` but actually refers to `test_loss`
return {"avg_test_loss": logs["val_loss"], "log": logs, "progress_bar": logs}
@staticmethod
def _SCREAMING_SNAKE_CASE (snake_case__ : List[Any] , snake_case__ : List[str] ) -> str:
'''simple docstring'''
BaseTransformer.add_model_specific_args(snake_case__ , snake_case__ )
parser.add_argument(
"--max_seq_length" , default=1_28 , type=snake_case__ , help=(
"The maximum total input sequence length after tokenization. Sequences longer "
"than this will be truncated, sequences shorter will be padded."
) , )
parser.add_argument(
"--task" , default="" , type=snake_case__ , required=snake_case__ , help="The GLUE task to run" , )
parser.add_argument(
"--gpus" , default=0 , type=snake_case__ , help="The number of GPUs allocated for this, it is by default 0 meaning none" , )
parser.add_argument(
"--overwrite_cache" , action="store_true" , help="Overwrite the cached training and evaluation sets" )
return parser
def UpperCamelCase ( ):
snake_case : int = argparse.ArgumentParser()
add_generic_args(__lowerCamelCase , os.getcwd() )
snake_case : Tuple = GLUETransformer.add_model_specific_args(__lowerCamelCase , os.getcwd() )
snake_case : Dict = parser.parse_args()
# If output_dir not provided, a folder will be generated in pwd
if args.output_dir is None:
snake_case : int = os.path.join(
"./results" , f"""{args.task}_{time.strftime('%Y%m%d_%H%M%S' )}""" , )
os.makedirs(args.output_dir )
snake_case : Optional[int] = GLUETransformer(__lowerCamelCase )
snake_case : str = generic_train(__lowerCamelCase , __lowerCamelCase )
# Optionally, predict on dev set and write to output_dir
if args.do_predict:
snake_case : str = sorted(glob.glob(os.path.join(args.output_dir , "checkpoint-epoch=*.ckpt" ) , recursive=__lowerCamelCase ) )
snake_case : List[str] = model.load_from_checkpoint(checkpoints[-1] )
return trainer.test(__lowerCamelCase )
if __name__ == "__main__":
main()
| 59
|
from typing import TYPE_CHECKING
from ...utils import (
OptionalDependencyNotAvailable,
_LazyModule,
is_flax_available,
is_sentencepiece_available,
is_tf_available,
is_tokenizers_available,
is_torch_available,
)
if is_sentencepiece_available():
from ..ta.tokenization_ta import TaTokenizer
else:
from ...utils.dummy_sentencepiece_objects import TaTokenizer
__lowerCamelCase = TaTokenizer
if is_tokenizers_available():
from ..ta.tokenization_ta_fast import TaTokenizerFast
else:
from ...utils.dummy_tokenizers_objects import TaTokenizerFast
__lowerCamelCase = TaTokenizerFast
__lowerCamelCase = {"""configuration_mt5""": ["""MT5Config""", """MT5OnnxConfig"""]}
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = [
"""MT5EncoderModel""",
"""MT5ForConditionalGeneration""",
"""MT5ForQuestionAnswering""",
"""MT5Model""",
"""MT5PreTrainedModel""",
"""MT5Stack""",
]
try:
if not is_tf_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = ["""TFMT5EncoderModel""", """TFMT5ForConditionalGeneration""", """TFMT5Model"""]
try:
if not is_flax_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = ["""FlaxMT5EncoderModel""", """FlaxMT5ForConditionalGeneration""", """FlaxMT5Model"""]
if TYPE_CHECKING:
from .configuration_mta import MTaConfig, MTaOnnxConfig
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_mta import (
MTaEncoderModel,
MTaForConditionalGeneration,
MTaForQuestionAnswering,
MTaModel,
MTaPreTrainedModel,
MTaStack,
)
try:
if not is_tf_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_tf_mta import TFMTaEncoderModel, TFMTaForConditionalGeneration, TFMTaModel
try:
if not is_flax_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_flax_mta import FlaxMTaEncoderModel, FlaxMTaForConditionalGeneration, FlaxMTaModel
else:
import sys
__lowerCamelCase = _LazyModule(
__name__,
globals()["""__file__"""],
_import_structure,
extra_objects={"""MT5Tokenizer""": MTaTokenizer, """MT5TokenizerFast""": MTaTokenizerFast},
module_spec=__spec__,
)
| 59
| 1
|
import math
import unittest
def UpperCamelCase ( __lowerCamelCase : int ):
assert isinstance(__lowerCamelCase , __lowerCamelCase ) and (
number >= 0
), "'number' must been an int and positive"
if 1 < number < 4:
# 2 and 3 are primes
return True
elif number < 2 or number % 2 == 0 or number % 3 == 0:
# Negatives, 0, 1, all even numbers, all multiples of 3 are not primes
return False
# All primes number are in format of 6k +/- 1
for i in range(5 , int(math.sqrt(__lowerCamelCase ) + 1 ) , 6 ):
if number % i == 0 or number % (i + 2) == 0:
return False
return True
class UpperCAmelCase ( unittest.TestCase ):
def _SCREAMING_SNAKE_CASE (self : Optional[Any] ) -> Any:
'''simple docstring'''
self.assertTrue(is_prime(2 ) )
self.assertTrue(is_prime(3 ) )
self.assertTrue(is_prime(5 ) )
self.assertTrue(is_prime(7 ) )
self.assertTrue(is_prime(11 ) )
self.assertTrue(is_prime(13 ) )
self.assertTrue(is_prime(17 ) )
self.assertTrue(is_prime(19 ) )
self.assertTrue(is_prime(23 ) )
self.assertTrue(is_prime(29 ) )
def _SCREAMING_SNAKE_CASE (self : int ) -> List[str]:
'''simple docstring'''
with self.assertRaises(snake_case__ ):
is_prime(-19 )
self.assertFalse(
is_prime(0 ) , "Zero doesn't have any positive factors, primes must have exactly two." , )
self.assertFalse(
is_prime(1 ) , "One only has 1 positive factor, primes must have exactly two." , )
self.assertFalse(is_prime(2 * 2 ) )
self.assertFalse(is_prime(2 * 3 ) )
self.assertFalse(is_prime(3 * 3 ) )
self.assertFalse(is_prime(3 * 5 ) )
self.assertFalse(is_prime(3 * 5 * 7 ) )
if __name__ == "__main__":
unittest.main()
| 59
|
import os
import shutil
from pathlib import Path
from typing import Optional, Union
import numpy as np
from huggingface_hub import hf_hub_download
from ..utils import ONNX_EXTERNAL_WEIGHTS_NAME, ONNX_WEIGHTS_NAME, is_onnx_available, logging
if is_onnx_available():
import onnxruntime as ort
__lowerCamelCase = logging.get_logger(__name__)
__lowerCamelCase = {
"""tensor(bool)""": np.bool_,
"""tensor(int8)""": np.inta,
"""tensor(uint8)""": np.uinta,
"""tensor(int16)""": np.intaa,
"""tensor(uint16)""": np.uintaa,
"""tensor(int32)""": np.intaa,
"""tensor(uint32)""": np.uintaa,
"""tensor(int64)""": np.intaa,
"""tensor(uint64)""": np.uintaa,
"""tensor(float16)""": np.floataa,
"""tensor(float)""": np.floataa,
"""tensor(double)""": np.floataa,
}
class UpperCAmelCase :
def __init__(self : Optional[Any] , snake_case__ : Optional[Any]=None , **snake_case__ : Optional[Any] ) -> List[str]:
'''simple docstring'''
logger.info("`diffusers.OnnxRuntimeModel` is experimental and might change in the future." )
snake_case : Optional[Any] = model
snake_case : Dict = kwargs.get("model_save_dir" , snake_case__ )
snake_case : int = kwargs.get("latest_model_name" , snake_case__ )
def __call__(self : Tuple , **snake_case__ : str ) -> List[str]:
'''simple docstring'''
snake_case : Union[str, Any] = {k: np.array(snake_case__ ) for k, v in kwargs.items()}
return self.model.run(snake_case__ , snake_case__ )
@staticmethod
def _SCREAMING_SNAKE_CASE (snake_case__ : Union[str, Path] , snake_case__ : Optional[int]=None , snake_case__ : Optional[int]=None ) -> Any:
'''simple docstring'''
if provider is None:
logger.info("No onnxruntime provider specified, using CPUExecutionProvider" )
snake_case : Optional[int] = "CPUExecutionProvider"
return ort.InferenceSession(snake_case__ , providers=[provider] , sess_options=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : List[Any] , snake_case__ : Union[str, Path] , snake_case__ : Optional[str] = None , **snake_case__ : Any ) -> List[Any]:
'''simple docstring'''
snake_case : Tuple = file_name if file_name is not None else ONNX_WEIGHTS_NAME
snake_case : Any = self.model_save_dir.joinpath(self.latest_model_name )
snake_case : str = Path(snake_case__ ).joinpath(snake_case__ )
try:
shutil.copyfile(snake_case__ , snake_case__ )
except shutil.SameFileError:
pass
# copy external weights (for models >2GB)
snake_case : List[str] = self.model_save_dir.joinpath(snake_case__ )
if src_path.exists():
snake_case : Tuple = Path(snake_case__ ).joinpath(snake_case__ )
try:
shutil.copyfile(snake_case__ , snake_case__ )
except shutil.SameFileError:
pass
def _SCREAMING_SNAKE_CASE (self : str , snake_case__ : Union[str, os.PathLike] , **snake_case__ : Optional[int] , ) -> str:
'''simple docstring'''
if os.path.isfile(snake_case__ ):
logger.error(f"""Provided path ({save_directory}) should be a directory, not a file""" )
return
os.makedirs(snake_case__ , exist_ok=snake_case__ )
# saving model weights/files
self._save_pretrained(snake_case__ , **snake_case__ )
@classmethod
def _SCREAMING_SNAKE_CASE (cls : Tuple , snake_case__ : Union[str, Path] , snake_case__ : Optional[Union[bool, str, None]] = None , snake_case__ : Optional[Union[str, None]] = None , snake_case__ : bool = False , snake_case__ : Optional[str] = None , snake_case__ : Optional[str] = None , snake_case__ : Optional[str] = None , snake_case__ : Optional["ort.SessionOptions"] = None , **snake_case__ : Tuple , ) -> Tuple:
'''simple docstring'''
snake_case : List[str] = file_name if file_name is not None else ONNX_WEIGHTS_NAME
# load model from local directory
if os.path.isdir(snake_case__ ):
snake_case : Any = OnnxRuntimeModel.load_model(
os.path.join(snake_case__ , snake_case__ ) , provider=snake_case__ , sess_options=snake_case__ )
snake_case : Union[str, Any] = Path(snake_case__ )
# load model from hub
else:
# download model
snake_case : Dict = hf_hub_download(
repo_id=snake_case__ , filename=snake_case__ , use_auth_token=snake_case__ , revision=snake_case__ , cache_dir=snake_case__ , force_download=snake_case__ , )
snake_case : List[Any] = Path(snake_case__ ).parent
snake_case : Union[str, Any] = Path(snake_case__ ).name
snake_case : Dict = OnnxRuntimeModel.load_model(snake_case__ , provider=snake_case__ , sess_options=snake_case__ )
return cls(model=snake_case__ , **snake_case__ )
@classmethod
def _SCREAMING_SNAKE_CASE (cls : Optional[Any] , snake_case__ : Union[str, Path] , snake_case__ : bool = True , snake_case__ : Optional[str] = None , snake_case__ : Optional[str] = None , **snake_case__ : Dict , ) -> Union[str, Any]:
'''simple docstring'''
snake_case : Dict = None
if len(str(snake_case__ ).split("@" ) ) == 2:
snake_case , snake_case : int = model_id.split("@" )
return cls._from_pretrained(
model_id=snake_case__ , revision=snake_case__ , cache_dir=snake_case__ , force_download=snake_case__ , use_auth_token=snake_case__ , **snake_case__ , )
| 59
| 1
|
import argparse
import logging
import os
import datasets
import tensorflow as tf
from transformers import AutoTokenizer
__lowerCamelCase = logging.getLogger(__name__)
def UpperCamelCase ( ):
snake_case : Tuple = argparse.ArgumentParser(
description="Prepare TFRecord shards from pre-tokenized samples of the wikitext dataset." )
parser.add_argument(
"--dataset_name" , type=__lowerCamelCase , default="wikitext" , help="Name of the training. Explore datasets at: hf.co/datasets." , )
parser.add_argument(
"--dataset_config" , type=__lowerCamelCase , default="wikitext-103-raw-v1" , help="Configuration name of the dataset." )
parser.add_argument(
"--tokenizer_name_or_path" , type=__lowerCamelCase , default="sayakpaul/unigram-tokenizer-wikitext" , help="Tokenizer identifier. Can be a local filepath or a Hub identifier." , )
parser.add_argument(
"--shard_size" , type=__lowerCamelCase , default=1000 , help="Number of entries to go in a single shard." , )
parser.add_argument("--split" , type=__lowerCamelCase , default="train" , choices=["train", "test", "validation"] )
parser.add_argument(
"--limit" , default=__lowerCamelCase , type=__lowerCamelCase , help="Limit the number of shards (used for debugging)." , )
parser.add_argument(
"--max_length" , type=__lowerCamelCase , default=512 , help="Maximum sequence length. For training on TPUs, it helps to have a maximum"
" sequence length that is a multiple of 8." , )
parser.add_argument(
"--output_dir" , default="tf-tpu" , type=__lowerCamelCase , help="Output directory where the TFRecord shards will be saved. If the"
" path is appended with `gs://` ('gs://tf-tpu', for example) then the TFRecord"
" shards will be directly saved to a Google Cloud Storage bucket." , )
snake_case : Dict = parser.parse_args()
return args
def UpperCamelCase ( __lowerCamelCase : Union[str, Any] ):
def fn(__lowerCamelCase : Union[str, Any] ):
return tokenizer(examples["text"] )
return fn
def UpperCamelCase ( __lowerCamelCase : Optional[int] ):
snake_case : Optional[int] = []
for i in range(len(tokenized_data["input_ids"] ) ):
snake_case : str = {
"input_ids": tf.train.Feature(intaa_list=tf.train.IntaaList(value=tokenized_data["input_ids"][i] ) ),
"attention_mask": tf.train.Feature(
intaa_list=tf.train.IntaaList(value=tokenized_data["attention_mask"][i] ) ),
}
snake_case : Optional[int] = tf.train.Features(feature=__lowerCamelCase )
snake_case : List[str] = tf.train.Example(features=__lowerCamelCase )
snake_case : Union[str, Any] = example.SerializeToString()
records.append(__lowerCamelCase )
return records
def UpperCamelCase ( __lowerCamelCase : List[Any] ):
snake_case : Any = datasets.load_dataset(args.dataset_name , args.dataset_config , split=args.split )
if args.limit is not None:
snake_case : Optional[Any] = min(len(__lowerCamelCase ) , args.limit )
snake_case : Tuple = dataset.select(range(__lowerCamelCase ) )
print(f"""Limiting the dataset to {args.limit} entries.""" )
snake_case : Tuple = AutoTokenizer.from_pretrained(args.tokenizer_name_or_path )
# Handle output directory creation.
# For serializing into a Google Cloud Storage Bucket, one needs to first
# create a bucket.
if "gs" not in args.output_dir:
if not os.path.exists(args.output_dir ):
os.makedirs(args.output_dir )
snake_case : List[Any] = os.path.join(args.output_dir , args.split )
if not os.path.exists(__lowerCamelCase ):
os.makedirs(__lowerCamelCase )
else:
snake_case : Tuple = os.path.join(args.output_dir , args.split )
# Tokenize the whole dataset at once.
snake_case : Any = tokenize_function(__lowerCamelCase )
snake_case : Optional[Any] = dataset.map(__lowerCamelCase , batched=__lowerCamelCase , num_proc=4 , remove_columns=["text"] )
# We need to concatenate all our texts together, and then split the result
# into chunks of a fixed size, which we will call block_size. To do this, we
# will use the map method again, with the option batched=True. When we use batched=True,
# the function we pass to map() will be passed multiple inputs at once, allowing us
# to group them into more or fewer examples than we had in the input.
# This allows us to create our new fixed-length samples. The advantage of this
# method is that we don't lose a whole lot of content from the dataset compared to the
# case where we simply tokenize with a pre-defined max_length.
def group_texts(__lowerCamelCase : List[str] ):
# Concatenate all texts.
snake_case : Optional[Any] = {k: sum(examples[k] , [] ) for k in examples.keys()}
snake_case : str = len(concatenated_examples[list(examples.keys() )[0]] )
# We drop the small remainder, though you could add padding instead if the model supports it
# In this, as in all things, we advise you to follow your heart 🫀
snake_case : Any = (total_length // args.max_length) * args.max_length
# Split by chunks of max_len.
snake_case : Union[str, Any] = {
k: [t[i : i + args.max_length] for i in range(0 , __lowerCamelCase , args.max_length )]
for k, t in concatenated_examples.items()
}
return result
snake_case : Any = dataset_tokenized.map(__lowerCamelCase , batched=__lowerCamelCase , batch_size=1000 , num_proc=4 )
snake_case : Dict = 0
snake_case : Optional[int] = 0
for shard in range(0 , len(__lowerCamelCase ) , args.shard_size ):
snake_case : int = grouped_dataset[shard : shard + args.shard_size]
snake_case : Any = len(dataset_snapshot["input_ids"] )
snake_case : List[Any] = os.path.join(__lowerCamelCase , f"""dataset-{shard_count}-{records_containing}.tfrecord""" )
snake_case : Tuple = get_serialized_examples(__lowerCamelCase )
with tf.io.TFRecordWriter(__lowerCamelCase ) as out_file:
for i in range(len(__lowerCamelCase ) ):
snake_case : Dict = serialized_examples[i]
out_file.write(__lowerCamelCase )
print("Wrote file {} containing {} records".format(__lowerCamelCase , __lowerCamelCase ) )
shard_count += 1
total_records += records_containing
with open(f"""split-{args.split}-records-count.txt""" , "w" ) as f:
print(f"""Total {args.split} records: {total_records}""" , file=__lowerCamelCase )
if __name__ == "__main__":
__lowerCamelCase = parse_args()
main(args)
| 59
|
import argparse
import json
from dataclasses import dataclass, field
from functools import partial
from pathlib import Path
from typing import Callable, Dict, List, Tuple
import timm
import torch
import torch.nn as nn
from classy_vision.models.regnet import RegNet, RegNetParams, RegNetYaagf, RegNetYaagf, RegNetYaaagf
from huggingface_hub import cached_download, hf_hub_url
from torch import Tensor
from vissl.models.model_helpers import get_trunk_forward_outputs
from transformers import AutoImageProcessor, RegNetConfig, RegNetForImageClassification, RegNetModel
from transformers.utils import logging
logging.set_verbosity_info()
__lowerCamelCase = logging.get_logger()
@dataclass
class UpperCAmelCase :
A__ : nn.Module
A__ : List[nn.Module] = field(default_factory=A_ )
A__ : list = field(default_factory=A_ )
def _SCREAMING_SNAKE_CASE (self : Optional[Any] , snake_case__ : Optional[Any] , snake_case__ : Tensor , snake_case__ : Tensor ) -> Optional[Any]:
'''simple docstring'''
snake_case : List[str] = len(list(m.modules() ) ) == 1 or isinstance(snake_case__ , nn.Convad ) or isinstance(snake_case__ , nn.BatchNormad )
if has_not_submodules:
self.traced.append(snake_case__ )
def __call__(self : List[Any] , snake_case__ : Tensor ) -> List[Any]:
'''simple docstring'''
for m in self.module.modules():
self.handles.append(m.register_forward_hook(self._forward_hook ) )
self.module(snake_case__ )
[x.remove() for x in self.handles]
return self
@property
def _SCREAMING_SNAKE_CASE (self : int ) -> Optional[int]:
'''simple docstring'''
return list(filter(lambda snake_case__ : len(list(x.state_dict().keys() ) ) > 0 , self.traced ) )
@dataclass
class UpperCAmelCase :
A__ : nn.Module
A__ : nn.Module
A__ : int = 1
A__ : List = field(default_factory=A_ )
A__ : List = field(default_factory=A_ )
A__ : bool = True
def __call__(self : List[Any] , snake_case__ : Tensor ) -> Any:
'''simple docstring'''
snake_case : str = Tracker(self.dest )(snake_case__ ).parametrized
snake_case : Optional[int] = Tracker(self.src )(snake_case__ ).parametrized
snake_case : List[str] = list(filter(lambda snake_case__ : type(snake_case__ ) not in self.src_skip , snake_case__ ) )
snake_case : Optional[Any] = list(filter(lambda snake_case__ : type(snake_case__ ) not in self.dest_skip , snake_case__ ) )
if len(snake_case__ ) != len(snake_case__ ) and self.raise_if_mismatch:
raise Exception(
f"""Numbers of operations are different. Source module has {len(snake_case__ )} operations while"""
f""" destination module has {len(snake_case__ )}.""" )
for dest_m, src_m in zip(snake_case__ , snake_case__ ):
dest_m.load_state_dict(src_m.state_dict() )
if self.verbose == 1:
print(f"""Transfered from={src_m} to={dest_m}""" )
class UpperCAmelCase ( nn.Module ):
def __init__(self : Tuple , snake_case__ : nn.Module ) -> Optional[Any]:
'''simple docstring'''
super().__init__()
snake_case : List[Tuple[str, nn.Module]] = []
# - get the stem
feature_blocks.append(("conv1", model.stem) )
# - get all the feature blocks
for k, v in model.trunk_output.named_children():
assert k.startswith("block" ), f"""Unexpected layer name {k}"""
snake_case : Union[str, Any] = len(snake_case__ ) + 1
feature_blocks.append((f"""res{block_index}""", v) )
snake_case : Optional[Any] = nn.ModuleDict(snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Tuple , snake_case__ : Tensor ) -> Dict:
'''simple docstring'''
return get_trunk_forward_outputs(
snake_case__ , out_feat_keys=snake_case__ , feature_blocks=self._feature_blocks , )
class UpperCAmelCase ( A_ ):
def _SCREAMING_SNAKE_CASE (self : Any , snake_case__ : str ) -> str:
'''simple docstring'''
snake_case : List[Any] = x.split("-" )
return x_split[0] + x_split[1] + "_" + "".join(x_split[2:] )
def __getitem__(self : Optional[int] , snake_case__ : str ) -> Callable[[], Tuple[nn.Module, Dict]]:
'''simple docstring'''
if x not in self:
snake_case : Dict = self.convert_name_to_timm(snake_case__ )
snake_case : Union[str, Any] = partial(lambda: (timm.create_model(snake_case__ , pretrained=snake_case__ ).eval(), None) )
else:
snake_case : List[str] = super().__getitem__(snake_case__ )
return val
class UpperCAmelCase ( A_ ):
def __getitem__(self : Dict , snake_case__ : str ) -> Callable[[], nn.Module]:
'''simple docstring'''
if "seer" in x and "in1k" not in x:
snake_case : str = RegNetModel
else:
snake_case : Optional[Any] = RegNetForImageClassification
return val
def UpperCamelCase ( __lowerCamelCase : Union[str, Any] , __lowerCamelCase : Union[str, Any] , __lowerCamelCase : List[Tuple[str, str]] ):
for from_key, to_key in keys:
snake_case : str = from_state_dict[from_key].clone()
print(f"""Copied key={from_key} to={to_key}""" )
return to_state_dict
def UpperCamelCase ( __lowerCamelCase : str , __lowerCamelCase : Callable[[], nn.Module] , __lowerCamelCase : Callable[[], nn.Module] , __lowerCamelCase : RegNetConfig , __lowerCamelCase : Path , __lowerCamelCase : bool = True , ):
print(f"""Converting {name}...""" )
with torch.no_grad():
snake_case , snake_case : int = from_model_func()
snake_case : str = our_model_func(__lowerCamelCase ).eval()
snake_case : int = ModuleTransfer(src=__lowerCamelCase , dest=__lowerCamelCase , raise_if_mismatch=__lowerCamelCase )
snake_case : Dict = torch.randn((1, 3, 224, 224) )
module_transfer(__lowerCamelCase )
if from_state_dict is not None:
snake_case : str = []
# for seer - in1k finetuned we have to manually copy the head
if "seer" in name and "in1k" in name:
snake_case : Tuple = [("0.clf.0.weight", "classifier.1.weight"), ("0.clf.0.bias", "classifier.1.bias")]
snake_case : Optional[Any] = manually_copy_vissl_head(__lowerCamelCase , our_model.state_dict() , __lowerCamelCase )
our_model.load_state_dict(__lowerCamelCase )
snake_case : Any = our_model(__lowerCamelCase , output_hidden_states=__lowerCamelCase )
snake_case : Union[str, Any] = (
our_outputs.logits if isinstance(__lowerCamelCase , __lowerCamelCase ) else our_outputs.last_hidden_state
)
snake_case : Union[str, Any] = from_model(__lowerCamelCase )
snake_case : Dict = from_output[-1] if type(__lowerCamelCase ) is list else from_output
# now since I don't want to use any config files, vissl seer model doesn't actually have an head, so let's just check the last hidden state
if "seer" in name and "in1k" in name:
snake_case : Any = our_outputs.hidden_states[-1]
assert torch.allclose(__lowerCamelCase , __lowerCamelCase ), "The model logits don't match the original one."
if push_to_hub:
our_model.push_to_hub(
repo_path_or_name=save_directory / name , commit_message="Add model" , use_temp_dir=__lowerCamelCase , )
snake_case : List[str] = 224 if "seer" not in name else 384
# we can use the convnext one
snake_case : int = AutoImageProcessor.from_pretrained("facebook/convnext-base-224-22k-1k" , size=__lowerCamelCase )
image_processor.push_to_hub(
repo_path_or_name=save_directory / name , commit_message="Add image processor" , use_temp_dir=__lowerCamelCase , )
print(f"""Pushed {name}""" )
def UpperCamelCase ( __lowerCamelCase : Path , __lowerCamelCase : str = None , __lowerCamelCase : bool = True ):
snake_case : Union[str, Any] = "imagenet-1k-id2label.json"
snake_case : List[str] = 1000
snake_case : List[str] = (1, num_labels)
snake_case : Any = "huggingface/label-files"
snake_case : List[str] = num_labels
snake_case : Optional[Any] = json.load(open(cached_download(hf_hub_url(__lowerCamelCase , __lowerCamelCase , repo_type="dataset" ) ) , "r" ) )
snake_case : List[Any] = {int(__lowerCamelCase ): v for k, v in idalabel.items()}
snake_case : str = idalabel
snake_case : List[Any] = {v: k for k, v in idalabel.items()}
snake_case : Dict = partial(__lowerCamelCase , num_labels=__lowerCamelCase , idalabel=__lowerCamelCase , labelaid=__lowerCamelCase )
snake_case : Optional[Any] = {
"regnet-x-002": ImageNetPreTrainedConfig(
depths=[1, 1, 4, 7] , hidden_sizes=[24, 56, 152, 368] , groups_width=8 , layer_type="x" ),
"regnet-x-004": ImageNetPreTrainedConfig(
depths=[1, 2, 7, 12] , hidden_sizes=[32, 64, 160, 384] , groups_width=16 , layer_type="x" ),
"regnet-x-006": ImageNetPreTrainedConfig(
depths=[1, 3, 5, 7] , hidden_sizes=[48, 96, 240, 528] , groups_width=24 , layer_type="x" ),
"regnet-x-008": ImageNetPreTrainedConfig(
depths=[1, 3, 7, 5] , hidden_sizes=[64, 128, 288, 672] , groups_width=16 , layer_type="x" ),
"regnet-x-016": ImageNetPreTrainedConfig(
depths=[2, 4, 10, 2] , hidden_sizes=[72, 168, 408, 912] , groups_width=24 , layer_type="x" ),
"regnet-x-032": ImageNetPreTrainedConfig(
depths=[2, 6, 15, 2] , hidden_sizes=[96, 192, 432, 1008] , groups_width=48 , layer_type="x" ),
"regnet-x-040": ImageNetPreTrainedConfig(
depths=[2, 5, 14, 2] , hidden_sizes=[80, 240, 560, 1360] , groups_width=40 , layer_type="x" ),
"regnet-x-064": ImageNetPreTrainedConfig(
depths=[2, 4, 10, 1] , hidden_sizes=[168, 392, 784, 1624] , groups_width=56 , layer_type="x" ),
"regnet-x-080": ImageNetPreTrainedConfig(
depths=[2, 5, 15, 1] , hidden_sizes=[80, 240, 720, 1920] , groups_width=120 , layer_type="x" ),
"regnet-x-120": ImageNetPreTrainedConfig(
depths=[2, 5, 11, 1] , hidden_sizes=[224, 448, 896, 2240] , groups_width=112 , layer_type="x" ),
"regnet-x-160": ImageNetPreTrainedConfig(
depths=[2, 6, 13, 1] , hidden_sizes=[256, 512, 896, 2048] , groups_width=128 , layer_type="x" ),
"regnet-x-320": ImageNetPreTrainedConfig(
depths=[2, 7, 13, 1] , hidden_sizes=[336, 672, 1344, 2520] , groups_width=168 , layer_type="x" ),
# y variant
"regnet-y-002": ImageNetPreTrainedConfig(depths=[1, 1, 4, 7] , hidden_sizes=[24, 56, 152, 368] , groups_width=8 ),
"regnet-y-004": ImageNetPreTrainedConfig(
depths=[1, 3, 6, 6] , hidden_sizes=[48, 104, 208, 440] , groups_width=8 ),
"regnet-y-006": ImageNetPreTrainedConfig(
depths=[1, 3, 7, 4] , hidden_sizes=[48, 112, 256, 608] , groups_width=16 ),
"regnet-y-008": ImageNetPreTrainedConfig(
depths=[1, 3, 8, 2] , hidden_sizes=[64, 128, 320, 768] , groups_width=16 ),
"regnet-y-016": ImageNetPreTrainedConfig(
depths=[2, 6, 17, 2] , hidden_sizes=[48, 120, 336, 888] , groups_width=24 ),
"regnet-y-032": ImageNetPreTrainedConfig(
depths=[2, 5, 13, 1] , hidden_sizes=[72, 216, 576, 1512] , groups_width=24 ),
"regnet-y-040": ImageNetPreTrainedConfig(
depths=[2, 6, 12, 2] , hidden_sizes=[128, 192, 512, 1088] , groups_width=64 ),
"regnet-y-064": ImageNetPreTrainedConfig(
depths=[2, 7, 14, 2] , hidden_sizes=[144, 288, 576, 1296] , groups_width=72 ),
"regnet-y-080": ImageNetPreTrainedConfig(
depths=[2, 4, 10, 1] , hidden_sizes=[168, 448, 896, 2016] , groups_width=56 ),
"regnet-y-120": ImageNetPreTrainedConfig(
depths=[2, 5, 11, 1] , hidden_sizes=[224, 448, 896, 2240] , groups_width=112 ),
"regnet-y-160": ImageNetPreTrainedConfig(
depths=[2, 4, 11, 1] , hidden_sizes=[224, 448, 1232, 3024] , groups_width=112 ),
"regnet-y-320": ImageNetPreTrainedConfig(
depths=[2, 5, 12, 1] , hidden_sizes=[232, 696, 1392, 3712] , groups_width=232 ),
# models created by SEER -> https://arxiv.org/abs/2202.08360
"regnet-y-320-seer": RegNetConfig(depths=[2, 5, 12, 1] , hidden_sizes=[232, 696, 1392, 3712] , groups_width=232 ),
"regnet-y-640-seer": RegNetConfig(depths=[2, 5, 12, 1] , hidden_sizes=[328, 984, 1968, 4920] , groups_width=328 ),
"regnet-y-1280-seer": RegNetConfig(
depths=[2, 7, 17, 1] , hidden_sizes=[528, 1056, 2904, 7392] , groups_width=264 ),
"regnet-y-2560-seer": RegNetConfig(
depths=[3, 7, 16, 1] , hidden_sizes=[640, 1696, 2544, 5088] , groups_width=640 ),
"regnet-y-10b-seer": ImageNetPreTrainedConfig(
depths=[2, 7, 17, 1] , hidden_sizes=[2020, 4040, 11110, 28280] , groups_width=1010 ),
# finetuned on imagenet
"regnet-y-320-seer-in1k": ImageNetPreTrainedConfig(
depths=[2, 5, 12, 1] , hidden_sizes=[232, 696, 1392, 3712] , groups_width=232 ),
"regnet-y-640-seer-in1k": ImageNetPreTrainedConfig(
depths=[2, 5, 12, 1] , hidden_sizes=[328, 984, 1968, 4920] , groups_width=328 ),
"regnet-y-1280-seer-in1k": ImageNetPreTrainedConfig(
depths=[2, 7, 17, 1] , hidden_sizes=[528, 1056, 2904, 7392] , groups_width=264 ),
"regnet-y-2560-seer-in1k": ImageNetPreTrainedConfig(
depths=[3, 7, 16, 1] , hidden_sizes=[640, 1696, 2544, 5088] , groups_width=640 ),
"regnet-y-10b-seer-in1k": ImageNetPreTrainedConfig(
depths=[2, 7, 17, 1] , hidden_sizes=[2020, 4040, 11110, 28280] , groups_width=1010 ),
}
snake_case : Union[str, Any] = NameToOurModelFuncMap()
snake_case : str = NameToFromModelFuncMap()
# add seer weights logic
def load_using_classy_vision(__lowerCamelCase : str , __lowerCamelCase : Callable[[], nn.Module] ) -> Tuple[nn.Module, Dict]:
snake_case : List[Any] = torch.hub.load_state_dict_from_url(__lowerCamelCase , model_dir=str(__lowerCamelCase ) , map_location="cpu" )
snake_case : Dict = model_func()
# check if we have a head, if yes add it
snake_case : str = files["classy_state_dict"]["base_model"]["model"]
snake_case : Dict = model_state_dict["trunk"]
model.load_state_dict(__lowerCamelCase )
return model.eval(), model_state_dict["heads"]
# pretrained
snake_case : List[Any] = partial(
__lowerCamelCase , "https://dl.fbaipublicfiles.com/vissl/model_zoo/seer_regnet32d/seer_regnet32gf_model_iteration244000.torch" , lambda: FakeRegNetVisslWrapper(RegNetYaagf() ) , )
snake_case : Optional[int] = partial(
__lowerCamelCase , "https://dl.fbaipublicfiles.com/vissl/model_zoo/seer_regnet64/seer_regnet64gf_model_final_checkpoint_phase0.torch" , lambda: FakeRegNetVisslWrapper(RegNetYaagf() ) , )
snake_case : List[str] = partial(
__lowerCamelCase , "https://dl.fbaipublicfiles.com/vissl/model_zoo/swav_ig1b_regnet128Gf_cnstant_bs32_node16_sinkhorn10_proto16k_syncBN64_warmup8k/model_final_checkpoint_phase0.torch" , lambda: FakeRegNetVisslWrapper(RegNetYaaagf() ) , )
snake_case : Tuple = partial(
__lowerCamelCase , "https://dl.fbaipublicfiles.com/vissl/model_zoo/seer_regnet10B/model_iteration124500_conso.torch" , lambda: FakeRegNetVisslWrapper(
RegNet(RegNetParams(depth=27 , group_width=1010 , w_a=1744 , w_a=620.83 , w_m=2.52 ) ) ) , )
# IN1K finetuned
snake_case : List[Any] = partial(
__lowerCamelCase , "https://dl.fbaipublicfiles.com/vissl/model_zoo/seer_finetuned/seer_regnet32_finetuned_in1k_model_final_checkpoint_phase78.torch" , lambda: FakeRegNetVisslWrapper(RegNetYaagf() ) , )
snake_case : Tuple = partial(
__lowerCamelCase , "https://dl.fbaipublicfiles.com/vissl/model_zoo/seer_finetuned/seer_regnet64_finetuned_in1k_model_final_checkpoint_phase78.torch" , lambda: FakeRegNetVisslWrapper(RegNetYaagf() ) , )
snake_case : str = partial(
__lowerCamelCase , "https://dl.fbaipublicfiles.com/vissl/model_zoo/seer_finetuned/seer_regnet128_finetuned_in1k_model_final_checkpoint_phase78.torch" , lambda: FakeRegNetVisslWrapper(RegNetYaaagf() ) , )
snake_case : Dict = partial(
__lowerCamelCase , "https://dl.fbaipublicfiles.com/vissl/model_zoo/seer_finetuned/seer_10b_finetuned_in1k_model_phase28_conso.torch" , lambda: FakeRegNetVisslWrapper(
RegNet(RegNetParams(depth=27 , group_width=1010 , w_a=1744 , w_a=620.83 , w_m=2.52 ) ) ) , )
if model_name:
convert_weight_and_push(
__lowerCamelCase , names_to_from_model_map[model_name] , names_to_ours_model_map[model_name] , names_to_config[model_name] , __lowerCamelCase , __lowerCamelCase , )
else:
for model_name, config in names_to_config.items():
convert_weight_and_push(
__lowerCamelCase , names_to_from_model_map[model_name] , names_to_ours_model_map[model_name] , __lowerCamelCase , __lowerCamelCase , __lowerCamelCase , )
return config, expected_shape
if __name__ == "__main__":
__lowerCamelCase = argparse.ArgumentParser()
# Required parameters
parser.add_argument(
"""--model_name""",
default=None,
type=str,
help=(
"""The name of the model you wish to convert, it must be one of the supported regnet* architecture,"""
""" currently: regnetx-*, regnety-*. If `None`, all of them will the converted."""
),
)
parser.add_argument(
"""--pytorch_dump_folder_path""",
default=None,
type=Path,
required=True,
help="""Path to the output PyTorch model directory.""",
)
parser.add_argument(
"""--push_to_hub""",
default=True,
type=bool,
required=False,
help="""If True, push model and image processor to the hub.""",
)
__lowerCamelCase = parser.parse_args()
__lowerCamelCase = args.pytorch_dump_folder_path
pytorch_dump_folder_path.mkdir(exist_ok=True, parents=True)
convert_weights_and_push(pytorch_dump_folder_path, args.model_name, args.push_to_hub)
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| 1
|
import argparse
import os
import torch
from transformers.utils import WEIGHTS_NAME
__lowerCamelCase = ["""small""", """medium""", """large"""]
__lowerCamelCase = """lm_head.decoder.weight"""
__lowerCamelCase = """lm_head.weight"""
def UpperCamelCase ( __lowerCamelCase : str , __lowerCamelCase : str ):
snake_case : Optional[int] = torch.load(__lowerCamelCase )
snake_case : Any = d.pop(__lowerCamelCase )
os.makedirs(__lowerCamelCase , exist_ok=__lowerCamelCase )
torch.save(__lowerCamelCase , os.path.join(__lowerCamelCase , __lowerCamelCase ) )
if __name__ == "__main__":
__lowerCamelCase = argparse.ArgumentParser()
parser.add_argument("""--dialogpt_path""", default=""".""", type=str)
__lowerCamelCase = parser.parse_args()
for MODEL in DIALOGPT_MODELS:
__lowerCamelCase = os.path.join(args.dialogpt_path, F'{MODEL}_ft.pkl')
__lowerCamelCase = F'./DialoGPT-{MODEL}'
convert_dialogpt_checkpoint(
checkpoint_path,
pytorch_dump_folder_path,
)
| 59
|
import warnings
from typing import Dict
import numpy as np
from ..utils import ExplicitEnum, add_end_docstrings, is_tf_available, is_torch_available
from .base import PIPELINE_INIT_ARGS, GenericTensor, Pipeline
if is_tf_available():
from ..models.auto.modeling_tf_auto import TF_MODEL_FOR_SEQUENCE_CLASSIFICATION_MAPPING
if is_torch_available():
from ..models.auto.modeling_auto import MODEL_FOR_SEQUENCE_CLASSIFICATION_MAPPING
def UpperCamelCase ( __lowerCamelCase : List[Any] ):
return 1.0 / (1.0 + np.exp(-_outputs ))
def UpperCamelCase ( __lowerCamelCase : int ):
snake_case : Tuple = np.max(_outputs , axis=-1 , keepdims=__lowerCamelCase )
snake_case : int = np.exp(_outputs - maxes )
return shifted_exp / shifted_exp.sum(axis=-1 , keepdims=__lowerCamelCase )
class UpperCAmelCase ( A_ ):
A__ : Any = "sigmoid"
A__ : str = "softmax"
A__ : int = "none"
@add_end_docstrings(
A_ ,r"\n return_all_scores (`bool`, *optional*, defaults to `False`):\n Whether to return all prediction scores or just the one of the predicted class.\n function_to_apply (`str`, *optional*, defaults to `\"default\"`):\n The function to apply to the model outputs in order to retrieve the scores. Accepts four different values:\n\n - `\"default\"`: if the model has a single label, will apply the sigmoid function on the output. If the model\n has several labels, will apply the softmax function on the output.\n - `\"sigmoid\"`: Applies the sigmoid function on the output.\n - `\"softmax\"`: Applies the softmax function on the output.\n - `\"none\"`: Does not apply any function on the output.\n " ,)
class UpperCAmelCase ( A_ ):
A__ : int = False
A__ : Union[str, Any] = ClassificationFunction.NONE
def __init__(self : List[str] , **snake_case__ : int ) -> str:
'''simple docstring'''
super().__init__(**snake_case__ )
self.check_model_type(
TF_MODEL_FOR_SEQUENCE_CLASSIFICATION_MAPPING
if self.framework == "tf"
else MODEL_FOR_SEQUENCE_CLASSIFICATION_MAPPING )
def _SCREAMING_SNAKE_CASE (self : List[Any] , snake_case__ : List[str]=None , snake_case__ : Optional[Any]=None , snake_case__ : Union[str, Any]="" , **snake_case__ : List[str] ) -> Union[str, Any]:
'''simple docstring'''
snake_case : Dict = tokenizer_kwargs
snake_case : List[Any] = {}
if hasattr(self.model.config , "return_all_scores" ) and return_all_scores is None:
snake_case : Optional[int] = self.model.config.return_all_scores
if isinstance(snake_case__ , snake_case__ ) or top_k is None:
snake_case : List[Any] = top_k
snake_case : str = False
elif return_all_scores is not None:
warnings.warn(
"`return_all_scores` is now deprecated, if want a similar functionality use `top_k=None` instead of"
" `return_all_scores=True` or `top_k=1` instead of `return_all_scores=False`." , snake_case__ , )
if return_all_scores:
snake_case : List[str] = None
else:
snake_case : Optional[int] = 1
if isinstance(snake_case__ , snake_case__ ):
snake_case : Dict = ClassificationFunction[function_to_apply.upper()]
if function_to_apply is not None:
snake_case : Optional[int] = function_to_apply
return preprocess_params, {}, postprocess_params
def __call__(self : Dict , *snake_case__ : List[str] , **snake_case__ : int ) -> Optional[int]:
'''simple docstring'''
snake_case : Optional[int] = super().__call__(*snake_case__ , **snake_case__ )
# TODO try and retrieve it in a nicer way from _sanitize_parameters.
snake_case : Tuple = "top_k" not in kwargs
if isinstance(args[0] , snake_case__ ) and _legacy:
# This pipeline is odd, and return a list when single item is run
return [result]
else:
return result
def _SCREAMING_SNAKE_CASE (self : Dict , snake_case__ : Tuple , **snake_case__ : Union[str, Any] ) -> Dict[str, GenericTensor]:
'''simple docstring'''
snake_case : int = self.framework
if isinstance(snake_case__ , snake_case__ ):
return self.tokenizer(**snake_case__ , return_tensors=snake_case__ , **snake_case__ )
elif isinstance(snake_case__ , snake_case__ ) and len(snake_case__ ) == 1 and isinstance(inputs[0] , snake_case__ ) and len(inputs[0] ) == 2:
# It used to be valid to use a list of list of list for text pairs, keeping this path for BC
return self.tokenizer(
text=inputs[0][0] , text_pair=inputs[0][1] , return_tensors=snake_case__ , **snake_case__ )
elif isinstance(snake_case__ , snake_case__ ):
# This is likely an invalid usage of the pipeline attempting to pass text pairs.
raise ValueError(
"The pipeline received invalid inputs, if you are trying to send text pairs, you can try to send a"
" dictionary `{\"text\": \"My text\", \"text_pair\": \"My pair\"}` in order to send a text pair." )
return self.tokenizer(snake_case__ , return_tensors=snake_case__ , **snake_case__ )
def _SCREAMING_SNAKE_CASE (self : int , snake_case__ : Union[str, Any] ) -> int:
'''simple docstring'''
return self.model(**snake_case__ )
def _SCREAMING_SNAKE_CASE (self : List[str] , snake_case__ : Optional[Any] , snake_case__ : List[str]=None , snake_case__ : Dict=1 , snake_case__ : Tuple=True ) -> str:
'''simple docstring'''
if function_to_apply is None:
if self.model.config.problem_type == "multi_label_classification" or self.model.config.num_labels == 1:
snake_case : Tuple = ClassificationFunction.SIGMOID
elif self.model.config.problem_type == "single_label_classification" or self.model.config.num_labels > 1:
snake_case : Tuple = ClassificationFunction.SOFTMAX
elif hasattr(self.model.config , "function_to_apply" ) and function_to_apply is None:
snake_case : Tuple = self.model.config.function_to_apply
else:
snake_case : int = ClassificationFunction.NONE
snake_case : Any = model_outputs["logits"][0]
snake_case : List[str] = outputs.numpy()
if function_to_apply == ClassificationFunction.SIGMOID:
snake_case : Optional[Any] = sigmoid(snake_case__ )
elif function_to_apply == ClassificationFunction.SOFTMAX:
snake_case : Union[str, Any] = softmax(snake_case__ )
elif function_to_apply == ClassificationFunction.NONE:
snake_case : Optional[Any] = outputs
else:
raise ValueError(f"""Unrecognized `function_to_apply` argument: {function_to_apply}""" )
if top_k == 1 and _legacy:
return {"label": self.model.config.idalabel[scores.argmax().item()], "score": scores.max().item()}
snake_case : Optional[int] = [
{"label": self.model.config.idalabel[i], "score": score.item()} for i, score in enumerate(snake_case__ )
]
if not _legacy:
dict_scores.sort(key=lambda snake_case__ : x["score"] , reverse=snake_case__ )
if top_k is not None:
snake_case : Optional[int] = dict_scores[:top_k]
return dict_scores
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| 1
|
from __future__ import annotations
from collections import namedtuple
from dataclasses import dataclass
@dataclass
class UpperCAmelCase :
A__ : int
A__ : TreeNode | None = None
A__ : TreeNode | None = None
__lowerCamelCase = namedtuple("""CoinsDistribResult""", """moves excess""")
def UpperCamelCase ( __lowerCamelCase : TreeNode | None ):
if root is None:
return 0
# Validation
def count_nodes(__lowerCamelCase : TreeNode | None ) -> int:
if node is None:
return 0
return count_nodes(node.left ) + count_nodes(node.right ) + 1
def count_coins(__lowerCamelCase : TreeNode | None ) -> int:
if node is None:
return 0
return count_coins(node.left ) + count_coins(node.right ) + node.data
if count_nodes(__lowerCamelCase ) != count_coins(__lowerCamelCase ):
raise ValueError("The nodes number should be same as the number of coins" )
# Main calculation
def get_distrib(__lowerCamelCase : TreeNode | None ) -> CoinsDistribResult:
if node is None:
return CoinsDistribResult(0 , 1 )
snake_case , snake_case : List[str] = get_distrib(node.left )
snake_case , snake_case : List[str] = get_distrib(node.right )
snake_case : List[str] = 1 - left_distrib_excess
snake_case : int = 1 - right_distrib_excess
snake_case : List[str] = (
left_distrib_moves
+ right_distrib_moves
+ abs(__lowerCamelCase )
+ abs(__lowerCamelCase )
)
snake_case : Tuple = node.data - coins_to_left - coins_to_right
return CoinsDistribResult(__lowerCamelCase , __lowerCamelCase )
return get_distrib(__lowerCamelCase )[0]
if __name__ == "__main__":
import doctest
doctest.testmod()
| 59
|
from __future__ import annotations
__lowerCamelCase = list[list[int]]
# assigning initial values to the grid
__lowerCamelCase = [
[3, 0, 6, 5, 0, 8, 4, 0, 0],
[5, 2, 0, 0, 0, 0, 0, 0, 0],
[0, 8, 7, 0, 0, 0, 0, 3, 1],
[0, 0, 3, 0, 1, 0, 0, 8, 0],
[9, 0, 0, 8, 6, 3, 0, 0, 5],
[0, 5, 0, 0, 9, 0, 6, 0, 0],
[1, 3, 0, 0, 0, 0, 2, 5, 0],
[0, 0, 0, 0, 0, 0, 0, 7, 4],
[0, 0, 5, 2, 0, 6, 3, 0, 0],
]
# a grid with no solution
__lowerCamelCase = [
[5, 0, 6, 5, 0, 8, 4, 0, 3],
[5, 2, 0, 0, 0, 0, 0, 0, 2],
[1, 8, 7, 0, 0, 0, 0, 3, 1],
[0, 0, 3, 0, 1, 0, 0, 8, 0],
[9, 0, 0, 8, 6, 3, 0, 0, 5],
[0, 5, 0, 0, 9, 0, 6, 0, 0],
[1, 3, 0, 0, 0, 0, 2, 5, 0],
[0, 0, 0, 0, 0, 0, 0, 7, 4],
[0, 0, 5, 2, 0, 6, 3, 0, 0],
]
def UpperCamelCase ( __lowerCamelCase : Matrix , __lowerCamelCase : int , __lowerCamelCase : int , __lowerCamelCase : int ):
for i in range(9 ):
if grid[row][i] == n or grid[i][column] == n:
return False
for i in range(3 ):
for j in range(3 ):
if grid[(row - row % 3) + i][(column - column % 3) + j] == n:
return False
return True
def UpperCamelCase ( __lowerCamelCase : Matrix ):
for i in range(9 ):
for j in range(9 ):
if grid[i][j] == 0:
return i, j
return None
def UpperCamelCase ( __lowerCamelCase : Matrix ):
if location := find_empty_location(__lowerCamelCase ):
snake_case , snake_case : Union[str, Any] = location
else:
# If the location is ``None``, then the grid is solved.
return grid
for digit in range(1 , 10 ):
if is_safe(__lowerCamelCase , __lowerCamelCase , __lowerCamelCase , __lowerCamelCase ):
snake_case : List[Any] = digit
if sudoku(__lowerCamelCase ) is not None:
return grid
snake_case : Union[str, Any] = 0
return None
def UpperCamelCase ( __lowerCamelCase : Matrix ):
for row in grid:
for cell in row:
print(__lowerCamelCase , end=" " )
print()
if __name__ == "__main__":
# make a copy of grid so that you can compare with the unmodified grid
for example_grid in (initial_grid, no_solution):
print("""\nExample grid:\n""" + """=""" * 20)
print_solution(example_grid)
print("""\nExample grid solution:""")
__lowerCamelCase = sudoku(example_grid)
if solution is not None:
print_solution(solution)
else:
print("""Cannot find a solution.""")
| 59
| 1
|
from collections import defaultdict
from graphs.minimum_spanning_tree_prims import prisms_algorithm as mst
def UpperCamelCase ( ):
snake_case , snake_case : Union[str, Any] = 9, 14 # noqa: F841
snake_case : int = [
[0, 1, 4],
[0, 7, 8],
[1, 2, 8],
[7, 8, 7],
[7, 6, 1],
[2, 8, 2],
[8, 6, 6],
[2, 3, 7],
[2, 5, 4],
[6, 5, 2],
[3, 5, 14],
[3, 4, 9],
[5, 4, 10],
[1, 7, 11],
]
snake_case : int = defaultdict(__lowerCamelCase )
for nodea, nodea, cost in edges:
adjancency[nodea].append([nodea, cost] )
adjancency[nodea].append([nodea, cost] )
snake_case : Any = mst(__lowerCamelCase )
snake_case : Optional[Any] = [
[7, 6, 1],
[2, 8, 2],
[6, 5, 2],
[0, 1, 4],
[2, 5, 4],
[2, 3, 7],
[0, 7, 8],
[3, 4, 9],
]
for answer in expected:
snake_case : Union[str, Any] = tuple(answer[:2] )
snake_case : Tuple = tuple(edge[::-1] )
assert edge in result or reverse in result
| 59
|
import logging
import numpy as np
import pytest
from scipy.linalg import eigh
logging.basicConfig(level=logging.INFO, format="""%(message)s""")
def UpperCamelCase ( __lowerCamelCase : np.ndarray ):
return input_array.reshape((input_array.size, 1) )
def UpperCamelCase ( __lowerCamelCase : np.ndarray , __lowerCamelCase : np.ndarray , __lowerCamelCase : int ):
snake_case : Any = np.nan
for i in range(__lowerCamelCase ):
snake_case : List[str] = features[:, labels == i]
snake_case : Dict = data.mean(1 )
# Centralize the data of class i
snake_case : Optional[Any] = data - column_reshape(__lowerCamelCase )
if i > 0:
# If covariance_sum is not None
covariance_sum += np.dot(__lowerCamelCase , centered_data.T )
else:
# If covariance_sum is np.nan (i.e. first loop)
snake_case : Optional[Any] = np.dot(__lowerCamelCase , centered_data.T )
return covariance_sum / features.shape[1]
def UpperCamelCase ( __lowerCamelCase : np.ndarray , __lowerCamelCase : np.ndarray , __lowerCamelCase : int ):
snake_case : Optional[Any] = features.mean(1 )
snake_case : Tuple = np.nan
for i in range(__lowerCamelCase ):
snake_case : Tuple = features[:, labels == i]
snake_case : Tuple = data.shape[1]
snake_case : List[str] = data.mean(1 )
if i > 0:
# If covariance_sum is not None
covariance_sum += device_data * np.dot(
column_reshape(__lowerCamelCase ) - column_reshape(__lowerCamelCase ) , (column_reshape(__lowerCamelCase ) - column_reshape(__lowerCamelCase )).T , )
else:
# If covariance_sum is np.nan (i.e. first loop)
snake_case : Optional[int] = device_data * np.dot(
column_reshape(__lowerCamelCase ) - column_reshape(__lowerCamelCase ) , (column_reshape(__lowerCamelCase ) - column_reshape(__lowerCamelCase )).T , )
return covariance_sum / features.shape[1]
def UpperCamelCase ( __lowerCamelCase : np.ndarray , __lowerCamelCase : int ):
# Check if the features have been loaded
if features.any():
snake_case : Tuple = features.mean(1 )
# Center the dataset
snake_case : List[str] = features - np.reshape(__lowerCamelCase , (data_mean.size, 1) )
snake_case : Optional[Any] = np.dot(__lowerCamelCase , centered_data.T ) / features.shape[1]
snake_case , snake_case : Dict = np.linalg.eigh(__lowerCamelCase )
# Take all the columns in the reverse order (-1), and then takes only the first
snake_case : Optional[Any] = eigenvectors[:, ::-1][:, 0:dimensions]
# Project the database on the new space
snake_case : Union[str, Any] = np.dot(filtered_eigenvectors.T , __lowerCamelCase )
logging.info("Principal Component Analysis computed" )
return projected_data
else:
logging.basicConfig(level=logging.ERROR , format="%(message)s" , force=__lowerCamelCase )
logging.error("Dataset empty" )
raise AssertionError
def UpperCamelCase ( __lowerCamelCase : np.ndarray , __lowerCamelCase : np.ndarray , __lowerCamelCase : int , __lowerCamelCase : int ):
assert classes > dimensions
# Check if features have been already loaded
if features.any:
snake_case , snake_case : str = eigh(
covariance_between_classes(__lowerCamelCase , __lowerCamelCase , __lowerCamelCase ) , covariance_within_classes(__lowerCamelCase , __lowerCamelCase , __lowerCamelCase ) , )
snake_case : str = eigenvectors[:, ::-1][:, :dimensions]
snake_case , snake_case , snake_case : int = np.linalg.svd(__lowerCamelCase )
snake_case : List[Any] = svd_matrix[:, 0:dimensions]
snake_case : Optional[Any] = np.dot(filtered_svd_matrix.T , __lowerCamelCase )
logging.info("Linear Discriminant Analysis computed" )
return projected_data
else:
logging.basicConfig(level=logging.ERROR , format="%(message)s" , force=__lowerCamelCase )
logging.error("Dataset empty" )
raise AssertionError
def UpperCamelCase ( ):
# Create dummy dataset with 2 classes and 3 features
snake_case : str = np.array([[1, 2, 3, 4, 5], [2, 3, 4, 5, 6], [3, 4, 5, 6, 7]] )
snake_case : Union[str, Any] = np.array([0, 0, 0, 1, 1] )
snake_case : List[Any] = 2
snake_case : Any = 2
# Assert that the function raises an AssertionError if dimensions > classes
with pytest.raises(__lowerCamelCase ) as error_info:
snake_case : str = linear_discriminant_analysis(
__lowerCamelCase , __lowerCamelCase , __lowerCamelCase , __lowerCamelCase )
if isinstance(__lowerCamelCase , np.ndarray ):
raise AssertionError(
"Did not raise AssertionError for dimensions > classes" )
assert error_info.type is AssertionError
def UpperCamelCase ( ):
snake_case : List[str] = np.array([[1, 2, 3], [4, 5, 6], [7, 8, 9]] )
snake_case : List[str] = 2
snake_case : int = np.array([[6.9282_0323, 8.6602_5404, 10.3923_0485], [3.0, 3.0, 3.0]] )
with pytest.raises(__lowerCamelCase ) as error_info:
snake_case : Union[str, Any] = principal_component_analysis(__lowerCamelCase , __lowerCamelCase )
if not np.allclose(__lowerCamelCase , __lowerCamelCase ):
raise AssertionError
assert error_info.type is AssertionError
if __name__ == "__main__":
import doctest
doctest.testmod()
| 59
| 1
|
from typing import TYPE_CHECKING
from ...utils import (
OptionalDependencyNotAvailable,
_LazyModule,
is_flax_available,
is_sentencepiece_available,
is_tf_available,
is_tokenizers_available,
is_torch_available,
)
__lowerCamelCase = {
"""configuration_xlm_roberta""": [
"""XLM_ROBERTA_PRETRAINED_CONFIG_ARCHIVE_MAP""",
"""XLMRobertaConfig""",
"""XLMRobertaOnnxConfig""",
],
}
try:
if not is_sentencepiece_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = ["""XLMRobertaTokenizer"""]
try:
if not is_tokenizers_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = ["""XLMRobertaTokenizerFast"""]
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = [
"""XLM_ROBERTA_PRETRAINED_MODEL_ARCHIVE_LIST""",
"""XLMRobertaForCausalLM""",
"""XLMRobertaForMaskedLM""",
"""XLMRobertaForMultipleChoice""",
"""XLMRobertaForQuestionAnswering""",
"""XLMRobertaForSequenceClassification""",
"""XLMRobertaForTokenClassification""",
"""XLMRobertaModel""",
"""XLMRobertaPreTrainedModel""",
]
try:
if not is_tf_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = [
"""TF_XLM_ROBERTA_PRETRAINED_MODEL_ARCHIVE_LIST""",
"""TFXLMRobertaForCausalLM""",
"""TFXLMRobertaForMaskedLM""",
"""TFXLMRobertaForMultipleChoice""",
"""TFXLMRobertaForQuestionAnswering""",
"""TFXLMRobertaForSequenceClassification""",
"""TFXLMRobertaForTokenClassification""",
"""TFXLMRobertaModel""",
"""TFXLMRobertaPreTrainedModel""",
]
try:
if not is_flax_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = [
"""FLAX_XLM_ROBERTA_PRETRAINED_MODEL_ARCHIVE_LIST""",
"""FlaxXLMRobertaForMaskedLM""",
"""FlaxXLMRobertaForCausalLM""",
"""FlaxXLMRobertaForMultipleChoice""",
"""FlaxXLMRobertaForQuestionAnswering""",
"""FlaxXLMRobertaForSequenceClassification""",
"""FlaxXLMRobertaForTokenClassification""",
"""FlaxXLMRobertaModel""",
"""FlaxXLMRobertaPreTrainedModel""",
]
if TYPE_CHECKING:
from .configuration_xlm_roberta import (
XLM_ROBERTA_PRETRAINED_CONFIG_ARCHIVE_MAP,
XLMRobertaConfig,
XLMRobertaOnnxConfig,
)
try:
if not is_sentencepiece_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .tokenization_xlm_roberta import XLMRobertaTokenizer
try:
if not is_tokenizers_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .tokenization_xlm_roberta_fast import XLMRobertaTokenizerFast
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_xlm_roberta import (
XLM_ROBERTA_PRETRAINED_MODEL_ARCHIVE_LIST,
XLMRobertaForCausalLM,
XLMRobertaForMaskedLM,
XLMRobertaForMultipleChoice,
XLMRobertaForQuestionAnswering,
XLMRobertaForSequenceClassification,
XLMRobertaForTokenClassification,
XLMRobertaModel,
XLMRobertaPreTrainedModel,
)
try:
if not is_tf_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_tf_xlm_roberta import (
TF_XLM_ROBERTA_PRETRAINED_MODEL_ARCHIVE_LIST,
TFXLMRobertaForCausalLM,
TFXLMRobertaForMaskedLM,
TFXLMRobertaForMultipleChoice,
TFXLMRobertaForQuestionAnswering,
TFXLMRobertaForSequenceClassification,
TFXLMRobertaForTokenClassification,
TFXLMRobertaModel,
TFXLMRobertaPreTrainedModel,
)
try:
if not is_flax_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_flax_xlm_roberta import (
FLAX_XLM_ROBERTA_PRETRAINED_MODEL_ARCHIVE_LIST,
FlaxXLMRobertaForCausalLM,
FlaxXLMRobertaForMaskedLM,
FlaxXLMRobertaForMultipleChoice,
FlaxXLMRobertaForQuestionAnswering,
FlaxXLMRobertaForSequenceClassification,
FlaxXLMRobertaForTokenClassification,
FlaxXLMRobertaModel,
FlaxXLMRobertaPreTrainedModel,
)
else:
import sys
__lowerCamelCase = _LazyModule(__name__, globals()["""__file__"""], _import_structure, module_spec=__spec__)
| 59
|
import pytest
from datasets import inspect_metric, list_metrics, load_metric
@pytest.fixture
def UpperCamelCase ( __lowerCamelCase : Optional[int] ):
monkeypatch.setattr("datasets.utils.deprecation_utils._emitted_deprecation_warnings" , set() )
@pytest.fixture
def UpperCamelCase ( __lowerCamelCase : str ):
class UpperCAmelCase :
def __init__(self : Optional[int] , snake_case__ : str ) -> Any:
'''simple docstring'''
snake_case : List[str] = metric_id
class UpperCAmelCase :
A__ : List[str] = [MetricMock(A_ ) for metric_id in ["accuracy", "mse", "precision", "codeparrot/apps_metric"]]
def _SCREAMING_SNAKE_CASE (self : int ) -> List[str]:
'''simple docstring'''
return self._metrics
monkeypatch.setattr("datasets.inspect.huggingface_hub" , HfhMock() )
@pytest.mark.parametrize(
"func, args" , [(load_metric, ("metrics/mse",)), (list_metrics, ()), (inspect_metric, ("metrics/mse", "tmp_path"))] )
def UpperCamelCase ( __lowerCamelCase : Optional[int] , __lowerCamelCase : Any , __lowerCamelCase : Any , __lowerCamelCase : int , __lowerCamelCase : Any ):
if "tmp_path" in args:
snake_case : str = tuple(arg if arg != "tmp_path" else tmp_path for arg in args )
with pytest.warns(__lowerCamelCase , match="https://huggingface.co/docs/evaluate" ):
func(*__lowerCamelCase )
| 59
| 1
|
from typing import Dict, List, Optional, Union
import numpy as np
from ...image_processing_utils import BaseImageProcessor, BatchFeature, get_size_dict
from ...image_transforms import (
center_crop,
get_resize_output_image_size,
normalize,
rescale,
resize,
to_channel_dimension_format,
)
from ...image_utils import (
IMAGENET_STANDARD_MEAN,
IMAGENET_STANDARD_STD,
ChannelDimension,
ImageInput,
PILImageResampling,
is_valid_image,
to_numpy_array,
valid_images,
)
from ...utils import TensorType, is_vision_available, logging
if is_vision_available():
import PIL
__lowerCamelCase = logging.get_logger(__name__)
def UpperCamelCase ( __lowerCamelCase : int ):
if isinstance(__lowerCamelCase , (list, tuple) ) and isinstance(videos[0] , (list, tuple) ) and is_valid_image(videos[0][0] ):
return videos
elif isinstance(__lowerCamelCase , (list, tuple) ) and is_valid_image(videos[0] ):
return [videos]
elif is_valid_image(__lowerCamelCase ):
return [[videos]]
raise ValueError(f"""Could not make batched video from {videos}""" )
class UpperCAmelCase ( A_ ):
A__ : int = ["pixel_values"]
def __init__(self : Any , snake_case__ : bool = True , snake_case__ : Dict[str, int] = None , snake_case__ : PILImageResampling = PILImageResampling.BILINEAR , snake_case__ : bool = True , snake_case__ : Dict[str, int] = None , snake_case__ : bool = True , snake_case__ : Union[int, float] = 1 / 2_55 , snake_case__ : bool = True , snake_case__ : Optional[Union[float, List[float]]] = None , snake_case__ : Optional[Union[float, List[float]]] = None , **snake_case__ : int , ) -> None:
'''simple docstring'''
super().__init__(**snake_case__ )
snake_case : Dict = size if size is not None else {"shortest_edge": 2_24}
snake_case : Optional[Any] = get_size_dict(snake_case__ , default_to_square=snake_case__ )
snake_case : Optional[Any] = crop_size if crop_size is not None else {"height": 2_24, "width": 2_24}
snake_case : str = get_size_dict(snake_case__ , param_name="crop_size" )
snake_case : Any = do_resize
snake_case : Optional[Any] = size
snake_case : Tuple = do_center_crop
snake_case : Dict = crop_size
snake_case : Tuple = resample
snake_case : Dict = do_rescale
snake_case : Any = rescale_factor
snake_case : Optional[int] = do_normalize
snake_case : List[str] = image_mean if image_mean is not None else IMAGENET_STANDARD_MEAN
snake_case : List[str] = image_std if image_std is not None else IMAGENET_STANDARD_STD
def _SCREAMING_SNAKE_CASE (self : Tuple , snake_case__ : np.ndarray , snake_case__ : Dict[str, int] , snake_case__ : PILImageResampling = PILImageResampling.BILINEAR , snake_case__ : Optional[Union[str, ChannelDimension]] = None , **snake_case__ : Union[str, Any] , ) -> np.ndarray:
'''simple docstring'''
snake_case : Optional[int] = get_size_dict(snake_case__ , default_to_square=snake_case__ )
if "shortest_edge" in size:
snake_case : Union[str, Any] = get_resize_output_image_size(snake_case__ , size["shortest_edge"] , default_to_square=snake_case__ )
elif "height" in size and "width" in size:
snake_case : Optional[int] = (size["height"], size["width"])
else:
raise ValueError(f"""Size must have 'height' and 'width' or 'shortest_edge' as keys. Got {size.keys()}""" )
return resize(snake_case__ , size=snake_case__ , resample=snake_case__ , data_format=snake_case__ , **snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Tuple , snake_case__ : np.ndarray , snake_case__ : Dict[str, int] , snake_case__ : Optional[Union[str, ChannelDimension]] = None , **snake_case__ : Any , ) -> np.ndarray:
'''simple docstring'''
snake_case : Optional[Any] = get_size_dict(snake_case__ )
if "height" not in size or "width" not in size:
raise ValueError(f"""Size must have 'height' and 'width' as keys. Got {size.keys()}""" )
return center_crop(snake_case__ , size=(size["height"], size["width"]) , data_format=snake_case__ , **snake_case__ )
def _SCREAMING_SNAKE_CASE (self : int , snake_case__ : np.ndarray , snake_case__ : Union[int, float] , snake_case__ : Optional[Union[str, ChannelDimension]] = None , **snake_case__ : List[str] , ) -> List[str]:
'''simple docstring'''
return rescale(snake_case__ , scale=snake_case__ , data_format=snake_case__ , **snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Optional[Any] , snake_case__ : np.ndarray , snake_case__ : Union[float, List[float]] , snake_case__ : Union[float, List[float]] , snake_case__ : Optional[Union[str, ChannelDimension]] = None , **snake_case__ : List[str] , ) -> np.ndarray:
'''simple docstring'''
return normalize(snake_case__ , mean=snake_case__ , std=snake_case__ , data_format=snake_case__ , **snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Optional[Any] , snake_case__ : ImageInput , snake_case__ : bool = None , snake_case__ : Dict[str, int] = None , snake_case__ : PILImageResampling = None , snake_case__ : bool = None , snake_case__ : Dict[str, int] = None , snake_case__ : bool = None , snake_case__ : float = None , snake_case__ : bool = None , snake_case__ : Optional[Union[float, List[float]]] = None , snake_case__ : Optional[Union[float, List[float]]] = None , snake_case__ : Optional[ChannelDimension] = ChannelDimension.FIRST , ) -> np.ndarray:
'''simple docstring'''
if do_resize and size is None or resample is None:
raise ValueError("Size and resample must be specified if do_resize is True." )
if do_center_crop and crop_size is None:
raise ValueError("Crop size must be specified if do_center_crop is True." )
if do_rescale and rescale_factor is None:
raise ValueError("Rescale factor must be specified if do_rescale is True." )
if do_normalize and (image_mean is None or image_std is None):
raise ValueError("Image mean and std must be specified if do_normalize is True." )
# All transformations expect numpy arrays.
snake_case : List[Any] = to_numpy_array(snake_case__ )
if do_resize:
snake_case : int = self.resize(image=snake_case__ , size=snake_case__ , resample=snake_case__ )
if do_center_crop:
snake_case : List[str] = self.center_crop(snake_case__ , size=snake_case__ )
if do_rescale:
snake_case : int = self.rescale(image=snake_case__ , scale=snake_case__ )
if do_normalize:
snake_case : Union[str, Any] = self.normalize(image=snake_case__ , mean=snake_case__ , std=snake_case__ )
snake_case : List[str] = to_channel_dimension_format(snake_case__ , snake_case__ )
return image
def _SCREAMING_SNAKE_CASE (self : Dict , snake_case__ : ImageInput , snake_case__ : bool = None , snake_case__ : Dict[str, int] = None , snake_case__ : PILImageResampling = None , snake_case__ : bool = None , snake_case__ : Dict[str, int] = None , snake_case__ : bool = None , snake_case__ : float = None , snake_case__ : bool = None , snake_case__ : Optional[Union[float, List[float]]] = None , snake_case__ : Optional[Union[float, List[float]]] = None , snake_case__ : Optional[Union[str, TensorType]] = None , snake_case__ : ChannelDimension = ChannelDimension.FIRST , **snake_case__ : List[Any] , ) -> PIL.Image.Image:
'''simple docstring'''
snake_case : Union[str, Any] = do_resize if do_resize is not None else self.do_resize
snake_case : Union[str, Any] = resample if resample is not None else self.resample
snake_case : List[str] = do_center_crop if do_center_crop is not None else self.do_center_crop
snake_case : Dict = do_rescale if do_rescale is not None else self.do_rescale
snake_case : List[Any] = rescale_factor if rescale_factor is not None else self.rescale_factor
snake_case : Any = do_normalize if do_normalize is not None else self.do_normalize
snake_case : Tuple = image_mean if image_mean is not None else self.image_mean
snake_case : Tuple = image_std if image_std is not None else self.image_std
snake_case : Dict = size if size is not None else self.size
snake_case : Any = get_size_dict(snake_case__ , default_to_square=snake_case__ )
snake_case : Union[str, Any] = crop_size if crop_size is not None else self.crop_size
snake_case : List[Any] = get_size_dict(snake_case__ , param_name="crop_size" )
if not valid_images(snake_case__ ):
raise ValueError(
"Invalid image type. Must be of type PIL.Image.Image, numpy.ndarray, "
"torch.Tensor, tf.Tensor or jax.ndarray." )
snake_case : Tuple = make_batched(snake_case__ )
snake_case : Optional[Any] = [
[
self._preprocess_image(
image=snake_case__ , do_resize=snake_case__ , size=snake_case__ , resample=snake_case__ , do_center_crop=snake_case__ , crop_size=snake_case__ , do_rescale=snake_case__ , rescale_factor=snake_case__ , do_normalize=snake_case__ , image_mean=snake_case__ , image_std=snake_case__ , data_format=snake_case__ , )
for img in video
]
for video in videos
]
snake_case : List[str] = {"pixel_values": videos}
return BatchFeature(data=snake_case__ , tensor_type=snake_case__ )
| 59
|
import argparse
import dataclasses
import json
import logging
import os
import shutil
from typing import List, Optional
import datasets
from accelerate import Accelerator
from datasets import load_dataset
from finetuning import finetune
from tqdm.auto import tqdm
import transformers
from transformers import AutoConfig, set_seed
from transformers.trainer_utils import IntervalStrategy
__lowerCamelCase = logging.getLogger(__name__)
__lowerCamelCase = """pytorch_model.bin"""
@dataclasses.dataclass
class UpperCAmelCase :
A__ : str = dataclasses.field(
metadata={"help": "Path to pretrained model or model identifier from huggingface.co/models."} )
A__ : Optional[str] = dataclasses.field(
default=A_ ,metadata={"help": "Where do you want to store the pretrained models downloaded from huggingface.co."} ,)
@dataclasses.dataclass
class UpperCAmelCase :
A__ : str = dataclasses.field(metadata={"help": "A csv or a json file containing the training data."} )
A__ : str = dataclasses.field(metadata={"help": "A csv or a json file containing the data to predict on."} )
A__ : Optional[str] = dataclasses.field(
default=A_ ,metadata={"help": "A csv or a json file containing the validation data."} )
A__ : Optional[str] = dataclasses.field(
default=A_ ,metadata={"help": "The name of the task to train on."} ,)
A__ : Optional[List[str]] = dataclasses.field(
default=A_ ,metadata={"help": "The list of labels for the task."} )
@dataclasses.dataclass
class UpperCAmelCase :
A__ : str = dataclasses.field(
metadata={"help": "The output directory where the model predictions and checkpoints will be written."} )
A__ : Optional[str] = dataclasses.field(
default="accuracy" ,metadata={"help": "The evaluation metric used for the task."} )
A__ : Optional[str] = dataclasses.field(
default="no" ,metadata={
"help": "The evaluation strategy to adopt during training. Possible values are: [\"no\", \"step\", \"epoch]"
} ,)
A__ : Optional[int] = dataclasses.field(
default=10 ,metadata={"help": "Number of evaluation calls with no improvement after which training will be stopped."} ,)
A__ : Optional[float] = dataclasses.field(
default=0.0 ,metadata={
"help": "How much the specified evaluation metric must improve to satisfy early stopping conditions."
} ,)
A__ : Optional[bool] = dataclasses.field(
default=A_ ,metadata={"help": "Whether to filter the pseudo-labeled data based on the confidence score."} ,)
A__ : Optional[bool] = dataclasses.field(
default=A_ ,metadata={"help": "Whether to filter the pseudo-labeled data based on the validation performance."} ,)
A__ : Optional[bool] = dataclasses.field(
default=A_ ,metadata={"help": "Whether to fine-tune on labeled data after pseudo training."} ,)
A__ : Optional[float] = dataclasses.field(
default=0.0 ,metadata={"help": "Confidence threshold for pseudo-labeled data filtering."} ,)
A__ : Optional[int] = dataclasses.field(
default=1_00 ,metadata={"help": "Number of evaluation calls with no improvement after which training will be stopped."} ,)
A__ : Optional[int] = dataclasses.field(
default=A_ ,metadata={"help": "Random seed for initialization."} ,)
def UpperCamelCase ( __lowerCamelCase : int , __lowerCamelCase : Tuple , __lowerCamelCase : Union[str, Any] , __lowerCamelCase : Tuple , __lowerCamelCase : Dict , __lowerCamelCase : Optional[int] ):
snake_case : Tuple = datasets.concatenate_datasets([infer_input, infer_output] , axis=1 )
if args.do_filter_by_confidence:
snake_case : Optional[int] = dataset.filter(lambda __lowerCamelCase : example["probability"] > args.confidence_threshold )
if args.do_filter_by_val_performance:
assert eval_result >= 0.0 and eval_result <= 1.0
snake_case : int = int(eval_result * len(__lowerCamelCase ) )
print(__lowerCamelCase )
snake_case : List[str] = dataset.sort("probability" , reverse=__lowerCamelCase )
snake_case : Tuple = dataset.select(range(__lowerCamelCase ) )
snake_case : List[Any] = dataset.remove_columns(["label", "probability"] )
snake_case : Any = dataset.rename_column("prediction" , "label" )
snake_case : str = dataset.map(lambda __lowerCamelCase : {"label": idalabel[example["label"]]} )
snake_case : List[str] = dataset.shuffle(seed=args.seed )
snake_case : int = os.path.join(__lowerCamelCase , f"""train_pseudo.{args.data_file_extension}""" )
if args.data_file_extension == "csv":
dataset.to_csv(__lowerCamelCase , index=__lowerCamelCase )
else:
dataset.to_json(__lowerCamelCase )
def UpperCamelCase ( __lowerCamelCase : Optional[int] , __lowerCamelCase : str , __lowerCamelCase : Optional[int] , __lowerCamelCase : Tuple , **__lowerCamelCase : List[Any] ):
snake_case : int = Accelerator()
# Make one log on every process with the configuration for debugging.
logging.basicConfig(
format="%(asctime)s - %(levelname)s - %(name)s - %(message)s" , datefmt="%m/%d/%Y %H:%M:%S" , level=logging.INFO , )
logger.info(accelerator.state )
# Setup logging, we only want one process per machine to log things on the
# screen. accelerator.is_local_main_process is only True for one process per
# machine.
logger.setLevel(logging.INFO if accelerator.is_local_main_process else logging.ERROR )
if accelerator.is_local_main_process:
datasets.utils.logging.set_verbosity_warning()
transformers.utils.logging.set_verbosity_info()
else:
datasets.utils.logging.set_verbosity_error()
transformers.utils.logging.set_verbosity_error()
snake_case : Dict = STModelArguments(model_name_or_path=__lowerCamelCase )
snake_case : Tuple = STDataArguments(train_file=__lowerCamelCase , infer_file=__lowerCamelCase )
snake_case : str = STTrainingArguments(output_dir=__lowerCamelCase )
snake_case : int = argparse.Namespace()
for arg_class in (model_args, data_args, training_args):
for key, value in vars(__lowerCamelCase ).items():
setattr(__lowerCamelCase , __lowerCamelCase , __lowerCamelCase )
for key, value in kwargs.items():
if hasattr(__lowerCamelCase , __lowerCamelCase ):
setattr(__lowerCamelCase , __lowerCamelCase , __lowerCamelCase )
# Sanity checks
snake_case : List[str] = {}
snake_case : Optional[int] = None
# You need to provide the training data and the data to predict on
assert args.train_file is not None
assert args.infer_file is not None
snake_case : str = args.train_file
snake_case : Tuple = args.infer_file
if args.evaluation_strategy != IntervalStrategy.NO.value:
assert args.eval_file is not None
snake_case : Tuple = args.eval_file
for key in data_files:
snake_case : List[Any] = data_files[key].split("." )[-1]
assert extension in ["csv", "json"], f"""`{key}_file` should be a csv or a json file."""
if args.data_file_extension is None:
snake_case : Union[str, Any] = extension
else:
assert extension == args.data_file_extension, f"""`{key}_file` should be a {args.data_file_extension} file`."""
assert (
args.eval_metric in datasets.list_metrics()
), f"""{args.eval_metric} not in the list of supported metrics {datasets.list_metrics()}."""
# If passed along, set the training seed now.
if args.seed is not None:
set_seed(args.seed )
logger.info("Creating the initial data directory for self-training..." )
snake_case : List[Any] = f"""{args.output_dir}/self-train_iter-{{}}""".format
snake_case : Optional[int] = data_dir_format(0 )
if accelerator.is_main_process:
if args.output_dir is not None:
os.makedirs(args.output_dir , exist_ok=__lowerCamelCase )
os.makedirs(__lowerCamelCase , exist_ok=__lowerCamelCase )
accelerator.wait_for_everyone()
snake_case : Dict = None
snake_case : Union[str, Any] = None
snake_case : Tuple = 0
snake_case : List[Any] = False
# Show the progress bar
snake_case : List[Any] = tqdm(range(args.max_selftrain_iterations ) , disable=not accelerator.is_local_main_process )
# Self-train
for iteration in range(0 , int(args.max_selftrain_iterations ) ):
snake_case : str = data_dir_format(__lowerCamelCase )
assert os.path.exists(__lowerCamelCase )
# Stage 1: initial fine-tuning for iteration = 0 or pseudo-training for
# iteration > 0
snake_case : Dict = os.path.join(__lowerCamelCase , "stage-1" )
snake_case : Optional[Any] = {
"accelerator": accelerator,
"model_name_or_path": args.model_name_or_path,
"cache_dir": args.cache_dir,
"do_train": True,
"train_file": data_files["train"] if iteration == 0 else data_files["train_pseudo"],
"do_eval": True if args.eval_file is not None else False,
"eval_file": data_files["eval"],
"do_predict": True,
"infer_file": data_files["infer"],
"task_name": args.task_name,
"label_list": args.label_list,
"output_dir": current_output_dir,
"eval_metric": args.eval_metric,
"evaluation_strategy": args.evaluation_strategy,
"early_stopping_patience": args.early_stopping_patience,
"early_stopping_threshold": args.early_stopping_threshold,
"seed": args.seed,
}
# Add additional training arguments
for key, value in kwargs.items():
if key not in arguments_dict and not hasattr(__lowerCamelCase , __lowerCamelCase ):
arguments_dict.update({key: value} )
snake_case : int = os.path.join(__lowerCamelCase , "best-checkpoint" , __lowerCamelCase )
if os.path.exists(__lowerCamelCase ):
logger.info(
"Found existing model checkpoint at %s. Skipping self-training: iteration: %d, stage: 1." , __lowerCamelCase , __lowerCamelCase , )
else:
logger.info("***** Running self-training: iteration: %d, stage: 1 *****" , __lowerCamelCase )
finetune(**__lowerCamelCase )
accelerator.wait_for_everyone()
assert os.path.exists(__lowerCamelCase )
logger.info("Self-training job completed: iteration: %d, stage: 1." , __lowerCamelCase )
if iteration > 0 and args.finetune_on_labeled_data:
# Stage 2 (optional): fine-tuning on the original labeled data
snake_case : str = os.path.join(__lowerCamelCase , "best-checkpoint" )
snake_case : Dict = os.path.join(__lowerCamelCase , "stage-2" )
# Update arguments_dict
snake_case : List[str] = model_path
snake_case : Optional[Any] = data_files["train"]
snake_case : Optional[Any] = current_output_dir
snake_case : Union[str, Any] = os.path.join(__lowerCamelCase , "best-checkpoint" , __lowerCamelCase )
if os.path.exists(__lowerCamelCase ):
logger.info(
"Found existing model checkpoint at %s. Skipping self-training: iteration: %d, stage: 2." , __lowerCamelCase , __lowerCamelCase , )
else:
logger.info("***** Running self-training: iteration: %d, stage: 2 *****" , __lowerCamelCase )
finetune(**__lowerCamelCase )
accelerator.wait_for_everyone()
assert os.path.exists(__lowerCamelCase )
logger.info("Self-training job completed: iteration: %d, stage: 2." , __lowerCamelCase )
snake_case : int = iteration
snake_case : Tuple = data_dir_format(iteration + 1 )
snake_case : Tuple = AutoConfig.from_pretrained(os.path.join(__lowerCamelCase , "best-checkpoint" ) )
snake_case : Optional[int] = config.idalabel
snake_case : List[Any] = os.path.join(__lowerCamelCase , "eval_results_best-checkpoint.json" )
snake_case : Union[str, Any] = os.path.join(__lowerCamelCase , "test_results_best-checkpoint.json" )
assert os.path.exists(__lowerCamelCase )
with open(__lowerCamelCase , "r" ) as f:
snake_case : Dict = float(json.load(__lowerCamelCase )[args.eval_metric] )
snake_case : Optional[int] = os.path.join(__lowerCamelCase , "infer_output_best-checkpoint.csv" )
assert os.path.exists(__lowerCamelCase )
# Loading the dataset from local csv or json files.
snake_case : Optional[Any] = load_dataset(args.data_file_extension , data_files={"data": data_files["infer"]} )["data"]
snake_case : Dict = load_dataset("csv" , data_files={"data": infer_output_file} )["data"]
if accelerator.is_main_process:
os.makedirs(__lowerCamelCase , exist_ok=__lowerCamelCase )
shutil.copy(__lowerCamelCase , os.path.join(__lowerCamelCase , f"""eval_results_iter-{iteration}.json""" ) )
if os.path.exists(__lowerCamelCase ):
shutil.copy(__lowerCamelCase , os.path.join(__lowerCamelCase , f"""test_results_iter-{iteration}.json""" ) )
create_pseudo_labeled_data(__lowerCamelCase , __lowerCamelCase , __lowerCamelCase , __lowerCamelCase , __lowerCamelCase , __lowerCamelCase )
accelerator.wait_for_everyone()
snake_case : str = os.path.join(__lowerCamelCase , f"""train_pseudo.{args.data_file_extension}""" )
if args.evaluation_strategy != IntervalStrategy.NO.value:
snake_case : List[Any] = eval_result
if best_iteration is None:
snake_case : List[Any] = new_iteration
snake_case : int = new_eval_result
else:
if new_eval_result - best_eval_result > args.early_stopping_threshold:
snake_case : int = new_iteration
snake_case : Union[str, Any] = new_eval_result
snake_case : str = 0
else:
if new_eval_result == best_eval_result:
snake_case : Any = new_iteration
snake_case : Union[str, Any] = new_eval_result
early_stopping_patience_counter += 1
if early_stopping_patience_counter >= args.early_stopping_patience:
snake_case : Tuple = True
progress_bar.update(1 )
if should_training_stop:
break
if best_iteration is not None:
# Save the best iteration
logger.info("Best iteration: %d" , __lowerCamelCase )
logger.info("Best evaluation result: %s = %f" , args.eval_metric , __lowerCamelCase )
accelerator.wait_for_everyone()
if accelerator.is_main_process:
shutil.copy(
os.path.join(__lowerCamelCase , f"""eval_results_iter-{iteration}.json""" ) , os.path.join(__lowerCamelCase , "eval_results_best-iteration.json" ) , )
else:
# Assume that the last iteration is the best
logger.info("Best iteration: %d" , args.max_selftrain_iterations - 1 )
logger.info("Best evaluation result: %s = %f" , args.eval_metric , __lowerCamelCase )
accelerator.wait_for_everyone()
if accelerator.is_main_process:
shutil.copy(
os.path.join(__lowerCamelCase , f"""eval_results_iter-{args.max_selftrain_iterations - 1}.json""" ) , os.path.join(__lowerCamelCase , "eval_results_best-iteration.json" ) , )
| 59
| 1
|
import os
import pytest
import yaml
from datasets.features.features import Features, Value
from datasets.info import DatasetInfo, DatasetInfosDict
@pytest.mark.parametrize(
"files" , [
["full:README.md", "dataset_infos.json"],
["empty:README.md", "dataset_infos.json"],
["dataset_infos.json"],
["full:README.md"],
] , )
def UpperCamelCase ( __lowerCamelCase : Dict , __lowerCamelCase : Tuple ):
snake_case : Dict = tmp_path_factory.mktemp("dset_infos_dir" )
if "full:README.md" in files:
with open(dataset_infos_dir / "README.md" , "w" ) as f:
f.write("---\ndataset_info:\n dataset_size: 42\n---" )
if "empty:README.md" in files:
with open(dataset_infos_dir / "README.md" , "w" ) as f:
f.write("" )
# we want to support dataset_infos.json for backward compatibility
if "dataset_infos.json" in files:
with open(dataset_infos_dir / "dataset_infos.json" , "w" ) as f:
f.write("{\"default\": {\"dataset_size\": 42}}" )
snake_case : Union[str, Any] = DatasetInfosDict.from_directory(__lowerCamelCase )
assert dataset_infos
assert dataset_infos["default"].dataset_size == 42
@pytest.mark.parametrize(
"dataset_info" , [
DatasetInfo(),
DatasetInfo(
description="foo" , features=Features({"a": Value("int32" )} ) , builder_name="builder" , config_name="config" , version="1.0.0" , splits=[{"name": "train"}] , download_size=42 , ),
] , )
def UpperCamelCase ( __lowerCamelCase : Optional[int] , __lowerCamelCase : DatasetInfo ):
snake_case : Union[str, Any] = str(__lowerCamelCase )
dataset_info.write_to_directory(__lowerCamelCase )
snake_case : Optional[Any] = DatasetInfo.from_directory(__lowerCamelCase )
assert dataset_info == reloaded
assert os.path.exists(os.path.join(__lowerCamelCase , "dataset_info.json" ) )
def UpperCamelCase ( ):
snake_case : Tuple = DatasetInfo(
description="foo" , citation="bar" , homepage="https://foo.bar" , license="CC0" , features=Features({"a": Value("int32" )} ) , post_processed={} , supervised_keys=() , task_templates=[] , builder_name="builder" , config_name="config" , version="1.0.0" , splits=[{"name": "train", "num_examples": 42}] , download_checksums={} , download_size=1337 , post_processing_size=442 , dataset_size=1234 , size_in_bytes=1337 + 442 + 1234 , )
snake_case : List[str] = dataset_info._to_yaml_dict()
assert sorted(__lowerCamelCase ) == sorted(DatasetInfo._INCLUDED_INFO_IN_YAML )
for key in DatasetInfo._INCLUDED_INFO_IN_YAML:
assert key in dataset_info_yaml_dict
assert isinstance(dataset_info_yaml_dict[key] , (list, dict, int, str) )
snake_case : str = yaml.safe_dump(__lowerCamelCase )
snake_case : str = yaml.safe_load(__lowerCamelCase )
assert dataset_info_yaml_dict == reloaded
def UpperCamelCase ( ):
snake_case : Any = DatasetInfo()
snake_case : Union[str, Any] = dataset_info._to_yaml_dict()
assert dataset_info_yaml_dict == {}
@pytest.mark.parametrize(
"dataset_infos_dict" , [
DatasetInfosDict(),
DatasetInfosDict({"default": DatasetInfo()} ),
DatasetInfosDict({"my_config_name": DatasetInfo()} ),
DatasetInfosDict(
{
"default": DatasetInfo(
description="foo" , features=Features({"a": Value("int32" )} ) , builder_name="builder" , config_name="config" , version="1.0.0" , splits=[{"name": "train"}] , download_size=42 , )
} ),
DatasetInfosDict(
{
"v1": DatasetInfo(dataset_size=42 ),
"v2": DatasetInfo(dataset_size=1337 ),
} ),
] , )
def UpperCamelCase ( __lowerCamelCase : int , __lowerCamelCase : DatasetInfosDict ):
snake_case : Union[str, Any] = str(__lowerCamelCase )
dataset_infos_dict.write_to_directory(__lowerCamelCase )
snake_case : Optional[int] = DatasetInfosDict.from_directory(__lowerCamelCase )
# the config_name of the dataset_infos_dict take over the attribute
for config_name, dataset_info in dataset_infos_dict.items():
snake_case : List[str] = config_name
# the yaml representation doesn't include fields like description or citation
# so we just test that we can recover what we can from the yaml
snake_case : int = DatasetInfo._from_yaml_dict(dataset_info._to_yaml_dict() )
assert dataset_infos_dict == reloaded
if dataset_infos_dict:
assert os.path.exists(os.path.join(__lowerCamelCase , "README.md" ) )
| 59
|
from typing import TYPE_CHECKING
from ...utils import (
OptionalDependencyNotAvailable,
_LazyModule,
is_flax_available,
is_sentencepiece_available,
is_tf_available,
is_tokenizers_available,
is_torch_available,
)
__lowerCamelCase = {"""configuration_xglm""": ["""XGLM_PRETRAINED_CONFIG_ARCHIVE_MAP""", """XGLMConfig"""]}
try:
if not is_sentencepiece_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = ["""XGLMTokenizer"""]
try:
if not is_tokenizers_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = ["""XGLMTokenizerFast"""]
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = [
"""XGLM_PRETRAINED_MODEL_ARCHIVE_LIST""",
"""XGLMForCausalLM""",
"""XGLMModel""",
"""XGLMPreTrainedModel""",
]
try:
if not is_flax_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = [
"""FlaxXGLMForCausalLM""",
"""FlaxXGLMModel""",
"""FlaxXGLMPreTrainedModel""",
]
try:
if not is_tf_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = [
"""TF_XGLM_PRETRAINED_MODEL_ARCHIVE_LIST""",
"""TFXGLMForCausalLM""",
"""TFXGLMModel""",
"""TFXGLMPreTrainedModel""",
]
if TYPE_CHECKING:
from .configuration_xglm import XGLM_PRETRAINED_CONFIG_ARCHIVE_MAP, XGLMConfig
try:
if not is_sentencepiece_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .tokenization_xglm import XGLMTokenizer
try:
if not is_tokenizers_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .tokenization_xglm_fast import XGLMTokenizerFast
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_xglm import XGLM_PRETRAINED_MODEL_ARCHIVE_LIST, XGLMForCausalLM, XGLMModel, XGLMPreTrainedModel
try:
if not is_flax_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_flax_xglm import FlaxXGLMForCausalLM, FlaxXGLMModel, FlaxXGLMPreTrainedModel
try:
if not is_tf_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_tf_xglm import (
TF_XGLM_PRETRAINED_MODEL_ARCHIVE_LIST,
TFXGLMForCausalLM,
TFXGLMModel,
TFXGLMPreTrainedModel,
)
else:
import sys
__lowerCamelCase = _LazyModule(__name__, globals()["""__file__"""], _import_structure)
| 59
| 1
|
from ...utils import (
OptionalDependencyNotAvailable,
is_torch_available,
is_transformers_available,
is_transformers_version,
)
try:
if not (is_transformers_available() and is_torch_available() and is_transformers_version(""">=""", """4.25.0""")):
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
from ...utils.dummy_torch_and_transformers_objects import (
VersatileDiffusionDualGuidedPipeline,
VersatileDiffusionImageVariationPipeline,
VersatileDiffusionPipeline,
VersatileDiffusionTextToImagePipeline,
)
else:
from .modeling_text_unet import UNetFlatConditionModel
from .pipeline_versatile_diffusion import VersatileDiffusionPipeline
from .pipeline_versatile_diffusion_dual_guided import VersatileDiffusionDualGuidedPipeline
from .pipeline_versatile_diffusion_image_variation import VersatileDiffusionImageVariationPipeline
from .pipeline_versatile_diffusion_text_to_image import VersatileDiffusionTextToImagePipeline
| 59
|
from ...configuration_utils import PretrainedConfig
from ...utils import logging
__lowerCamelCase = logging.get_logger(__name__)
__lowerCamelCase = {
# See all MEGATRON_BERT models at https://huggingface.co/models?filter=bert
}
class UpperCAmelCase ( A_ ):
A__ : List[str] = "megatron-bert"
def __init__(self : Optional[int] , snake_case__ : List[str]=2_90_56 , snake_case__ : List[Any]=10_24 , snake_case__ : str=24 , snake_case__ : Tuple=16 , snake_case__ : Union[str, Any]=40_96 , snake_case__ : str="gelu" , snake_case__ : str=0.1 , snake_case__ : Optional[int]=0.1 , snake_case__ : Tuple=5_12 , snake_case__ : Union[str, Any]=2 , snake_case__ : Dict=0.02 , snake_case__ : List[Any]=1e-12 , snake_case__ : int=0 , snake_case__ : Tuple="absolute" , snake_case__ : Any=True , **snake_case__ : Union[str, Any] , ) -> Optional[Any]:
'''simple docstring'''
super().__init__(pad_token_id=snake_case__ , **snake_case__ )
snake_case : Tuple = vocab_size
snake_case : str = hidden_size
snake_case : str = num_hidden_layers
snake_case : str = num_attention_heads
snake_case : Optional[int] = hidden_act
snake_case : int = intermediate_size
snake_case : List[str] = hidden_dropout_prob
snake_case : Union[str, Any] = attention_probs_dropout_prob
snake_case : Dict = max_position_embeddings
snake_case : List[str] = type_vocab_size
snake_case : List[str] = initializer_range
snake_case : Tuple = layer_norm_eps
snake_case : int = position_embedding_type
snake_case : str = use_cache
| 59
| 1
|
import collections
import inspect
import unittest
from typing import Dict, List, Tuple
from transformers import MaskFormerSwinConfig
from transformers.testing_utils import require_torch, require_torch_multi_gpu, torch_device
from transformers.utils import is_torch_available
from ...test_backbone_common import BackboneTesterMixin
from ...test_configuration_common import ConfigTester
from ...test_modeling_common import ModelTesterMixin, floats_tensor, ids_tensor
from ...test_pipeline_mixin import PipelineTesterMixin
if is_torch_available():
import torch
from torch import nn
from transformers import MaskFormerSwinBackbone
from transformers.models.maskformer import MaskFormerSwinModel
class UpperCAmelCase :
def __init__(self : Dict , snake_case__ : Dict , snake_case__ : Any=13 , snake_case__ : Any=32 , snake_case__ : Optional[Any]=2 , snake_case__ : Union[str, Any]=3 , snake_case__ : List[Any]=16 , snake_case__ : int=[1, 2, 1] , snake_case__ : Dict=[2, 2, 4] , snake_case__ : Dict=2 , snake_case__ : Tuple=2.0 , snake_case__ : Optional[int]=True , snake_case__ : Union[str, Any]=0.0 , snake_case__ : Any=0.0 , snake_case__ : Union[str, Any]=0.1 , snake_case__ : int="gelu" , snake_case__ : Optional[int]=False , snake_case__ : List[Any]=True , snake_case__ : List[str]=0.02 , snake_case__ : int=1e-5 , snake_case__ : List[str]=True , snake_case__ : Union[str, Any]=None , snake_case__ : List[Any]=True , snake_case__ : Optional[Any]=10 , snake_case__ : Optional[Any]=8 , snake_case__ : Any=["stage1", "stage2", "stage3"] , snake_case__ : Tuple=[1, 2, 3] , ) -> Union[str, Any]:
'''simple docstring'''
snake_case : Any = parent
snake_case : Optional[int] = batch_size
snake_case : Union[str, Any] = image_size
snake_case : Dict = patch_size
snake_case : Optional[Any] = num_channels
snake_case : Union[str, Any] = embed_dim
snake_case : int = depths
snake_case : List[str] = num_heads
snake_case : Union[str, Any] = window_size
snake_case : Union[str, Any] = mlp_ratio
snake_case : List[Any] = qkv_bias
snake_case : List[Any] = hidden_dropout_prob
snake_case : Union[str, Any] = attention_probs_dropout_prob
snake_case : Union[str, Any] = drop_path_rate
snake_case : int = hidden_act
snake_case : Optional[int] = use_absolute_embeddings
snake_case : int = patch_norm
snake_case : Union[str, Any] = layer_norm_eps
snake_case : Any = initializer_range
snake_case : Optional[Any] = is_training
snake_case : Tuple = scope
snake_case : Optional[int] = use_labels
snake_case : Optional[Any] = type_sequence_label_size
snake_case : Union[str, Any] = encoder_stride
snake_case : Any = out_features
snake_case : Tuple = out_indices
def _SCREAMING_SNAKE_CASE (self : Optional[Any] ) -> Dict:
'''simple docstring'''
snake_case : Optional[Any] = floats_tensor([self.batch_size, self.num_channels, self.image_size, self.image_size] )
snake_case : int = None
if self.use_labels:
snake_case : Tuple = ids_tensor([self.batch_size] , self.type_sequence_label_size )
snake_case : Dict = self.get_config()
return config, pixel_values, labels
def _SCREAMING_SNAKE_CASE (self : List[str] ) -> int:
'''simple docstring'''
return MaskFormerSwinConfig(
image_size=self.image_size , patch_size=self.patch_size , num_channels=self.num_channels , embed_dim=self.embed_dim , depths=self.depths , num_heads=self.num_heads , window_size=self.window_size , mlp_ratio=self.mlp_ratio , qkv_bias=self.qkv_bias , hidden_dropout_prob=self.hidden_dropout_prob , attention_probs_dropout_prob=self.attention_probs_dropout_prob , drop_path_rate=self.drop_path_rate , hidden_act=self.hidden_act , use_absolute_embeddings=self.use_absolute_embeddings , path_norm=self.patch_norm , layer_norm_eps=self.layer_norm_eps , initializer_range=self.initializer_range , encoder_stride=self.encoder_stride , out_features=self.out_features , out_indices=self.out_indices , )
def _SCREAMING_SNAKE_CASE (self : Tuple , snake_case__ : List[Any] , snake_case__ : List[str] , snake_case__ : Tuple ) -> Optional[Any]:
'''simple docstring'''
snake_case : Union[str, Any] = MaskFormerSwinModel(config=snake_case__ )
model.to(snake_case__ )
model.eval()
snake_case : List[Any] = model(snake_case__ )
snake_case : Dict = ((config.image_size // config.patch_size) ** 2) // (4 ** (len(config.depths ) - 1))
snake_case : int = int(config.embed_dim * 2 ** (len(config.depths ) - 1) )
self.parent.assertEqual(result.last_hidden_state.shape , (self.batch_size, expected_seq_len, expected_dim) )
def _SCREAMING_SNAKE_CASE (self : List[str] , snake_case__ : Union[str, Any] , snake_case__ : List[Any] , snake_case__ : Union[str, Any] ) -> str:
'''simple docstring'''
snake_case : Optional[int] = MaskFormerSwinBackbone(config=snake_case__ )
model.to(snake_case__ )
model.eval()
snake_case : List[Any] = model(snake_case__ )
# verify feature maps
self.parent.assertEqual(len(result.feature_maps ) , len(config.out_features ) )
self.parent.assertListEqual(list(result.feature_maps[0].shape ) , [13, 16, 16, 16] )
# verify channels
self.parent.assertEqual(len(model.channels ) , len(config.out_features ) )
self.parent.assertListEqual(model.channels , [16, 32, 64] )
# verify ValueError
with self.parent.assertRaises(snake_case__ ):
snake_case : Tuple = ["stem"]
snake_case : List[Any] = MaskFormerSwinBackbone(config=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : List[Any] ) -> List[Any]:
'''simple docstring'''
snake_case : Union[str, Any] = self.prepare_config_and_inputs()
snake_case , snake_case , snake_case : List[Any] = config_and_inputs
snake_case : int = {"pixel_values": pixel_values}
return config, inputs_dict
@require_torch
class UpperCAmelCase ( A_ ,A_ ,unittest.TestCase ):
A__ : List[str] = (
(
MaskFormerSwinModel,
MaskFormerSwinBackbone,
)
if is_torch_available()
else ()
)
A__ : str = {"feature-extraction": MaskFormerSwinModel} if is_torch_available() else {}
A__ : Optional[Any] = False
A__ : List[Any] = False
A__ : List[str] = False
A__ : List[str] = False
A__ : Union[str, Any] = False
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> List[str]:
'''simple docstring'''
snake_case : str = MaskFormerSwinModelTester(self )
snake_case : Optional[int] = ConfigTester(self , config_class=snake_case__ , embed_dim=37 )
@require_torch_multi_gpu
@unittest.skip(
reason=(
"`MaskFormerSwinModel` outputs `hidden_states_spatial_dimensions` which doesn't work well with"
" `nn.DataParallel`"
) )
def _SCREAMING_SNAKE_CASE (self : str ) -> Optional[Any]:
'''simple docstring'''
pass
def _SCREAMING_SNAKE_CASE (self : str ) -> List[str]:
'''simple docstring'''
self.create_and_test_config_common_properties()
self.config_tester.create_and_test_config_to_json_string()
self.config_tester.create_and_test_config_to_json_file()
self.config_tester.create_and_test_config_from_and_save_pretrained()
self.config_tester.create_and_test_config_with_num_labels()
self.config_tester.check_config_can_be_init_without_params()
self.config_tester.check_config_arguments_init()
def _SCREAMING_SNAKE_CASE (self : Tuple ) -> List[Any]:
'''simple docstring'''
return
def _SCREAMING_SNAKE_CASE (self : Dict ) -> str:
'''simple docstring'''
snake_case : str = self.model_tester.prepare_config_and_inputs()
self.model_tester.create_and_check_model(*snake_case__ )
def _SCREAMING_SNAKE_CASE (self : int ) -> Dict:
'''simple docstring'''
snake_case : Any = self.model_tester.prepare_config_and_inputs()
self.model_tester.create_and_check_backbone(*snake_case__ )
@unittest.skip("Swin does not use inputs_embeds" )
def _SCREAMING_SNAKE_CASE (self : int ) -> Any:
'''simple docstring'''
pass
@unittest.skip("Swin does not support feedforward chunking" )
def _SCREAMING_SNAKE_CASE (self : List[str] ) -> Dict:
'''simple docstring'''
pass
def _SCREAMING_SNAKE_CASE (self : Optional[Any] ) -> List[str]:
'''simple docstring'''
snake_case , snake_case : Any = self.model_tester.prepare_config_and_inputs_for_common()
for model_class in self.all_model_classes:
snake_case : int = model_class(snake_case__ )
self.assertIsInstance(model.get_input_embeddings() , (nn.Module) )
snake_case : List[Any] = model.get_output_embeddings()
self.assertTrue(x is None or isinstance(snake_case__ , nn.Linear ) )
def _SCREAMING_SNAKE_CASE (self : Optional[Any] ) -> Dict:
'''simple docstring'''
snake_case , snake_case : str = self.model_tester.prepare_config_and_inputs_for_common()
for model_class in self.all_model_classes:
snake_case : str = model_class(snake_case__ )
snake_case : Optional[int] = inspect.signature(model.forward )
# signature.parameters is an OrderedDict => so arg_names order is deterministic
snake_case : Optional[Any] = [*signature.parameters.keys()]
snake_case : Tuple = ["pixel_values"]
self.assertListEqual(arg_names[:1] , snake_case__ )
@unittest.skip(reason="MaskFormerSwin is only used as backbone and doesn't support output_attentions" )
def _SCREAMING_SNAKE_CASE (self : List[Any] ) -> str:
'''simple docstring'''
pass
@unittest.skip(reason="MaskFormerSwin is only used as an internal backbone" )
def _SCREAMING_SNAKE_CASE (self : Tuple ) -> Any:
'''simple docstring'''
pass
def _SCREAMING_SNAKE_CASE (self : Optional[Any] , snake_case__ : List[Any] , snake_case__ : str , snake_case__ : List[Any] , snake_case__ : Tuple ) -> Optional[int]:
'''simple docstring'''
snake_case : Tuple = model_class(snake_case__ )
model.to(snake_case__ )
model.eval()
with torch.no_grad():
snake_case : Any = model(**self._prepare_for_class(snake_case__ , snake_case__ ) )
snake_case : int = outputs.hidden_states
snake_case : Union[str, Any] = getattr(
self.model_tester , "expected_num_hidden_layers" , len(self.model_tester.depths ) + 1 )
self.assertEqual(len(snake_case__ ) , snake_case__ )
# Swin has a different seq_length
snake_case : Any = (
config.patch_size
if isinstance(config.patch_size , collections.abc.Iterable )
else (config.patch_size, config.patch_size)
)
snake_case : Tuple = (image_size[1] // patch_size[1]) * (image_size[0] // patch_size[0])
self.assertListEqual(
list(hidden_states[0].shape[-2:] ) , [num_patches, self.model_tester.embed_dim] , )
def _SCREAMING_SNAKE_CASE (self : Dict ) -> Union[str, Any]:
'''simple docstring'''
snake_case , snake_case : List[Any] = self.model_tester.prepare_config_and_inputs_for_common()
snake_case : int = (
self.model_tester.image_size
if isinstance(self.model_tester.image_size , collections.abc.Iterable )
else (self.model_tester.image_size, self.model_tester.image_size)
)
for model_class in self.all_model_classes:
snake_case : int = True
self.check_hidden_states_output(snake_case__ , snake_case__ , snake_case__ , snake_case__ )
# check that output_hidden_states also work using config
del inputs_dict["output_hidden_states"]
snake_case : Dict = True
self.check_hidden_states_output(snake_case__ , snake_case__ , snake_case__ , snake_case__ )
def _SCREAMING_SNAKE_CASE (self : int ) -> Any:
'''simple docstring'''
snake_case , snake_case : Union[str, Any] = self.model_tester.prepare_config_and_inputs_for_common()
snake_case : Any = 3
snake_case : List[str] = (
self.model_tester.image_size
if isinstance(self.model_tester.image_size , collections.abc.Iterable )
else (self.model_tester.image_size, self.model_tester.image_size)
)
snake_case : Tuple = (
config.patch_size
if isinstance(config.patch_size , collections.abc.Iterable )
else (config.patch_size, config.patch_size)
)
snake_case : str = image_size[0] + patch_size[0] - (image_size[0] % patch_size[0])
snake_case : str = image_size[1] + patch_size[1] - (image_size[1] % patch_size[1])
for model_class in self.all_model_classes:
snake_case : str = True
self.check_hidden_states_output(snake_case__ , snake_case__ , snake_case__ , (padded_height, padded_width) )
# check that output_hidden_states also work using config
del inputs_dict["output_hidden_states"]
snake_case : Optional[Any] = True
self.check_hidden_states_output(snake_case__ , snake_case__ , snake_case__ , (padded_height, padded_width) )
@unittest.skip(reason="MaskFormerSwin doesn't have pretrained checkpoints" )
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> str:
'''simple docstring'''
pass
@unittest.skip(reason="This will be fixed once MaskFormerSwin is replaced by native Swin" )
def _SCREAMING_SNAKE_CASE (self : str ) -> int:
'''simple docstring'''
pass
@unittest.skip(reason="This will be fixed once MaskFormerSwin is replaced by native Swin" )
def _SCREAMING_SNAKE_CASE (self : int ) -> str:
'''simple docstring'''
pass
def _SCREAMING_SNAKE_CASE (self : Any ) -> Any:
'''simple docstring'''
snake_case , snake_case : List[Any] = self.model_tester.prepare_config_and_inputs_for_common()
def set_nan_tensor_to_zero(snake_case__ : Union[str, Any] ):
snake_case : Any = 0
return t
def check_equivalence(snake_case__ : Union[str, Any] , snake_case__ : int , snake_case__ : List[str] , snake_case__ : Optional[int]={} ):
with torch.no_grad():
snake_case : Optional[Any] = model(**snake_case__ , return_dict=snake_case__ , **snake_case__ )
snake_case : Tuple = model(**snake_case__ , return_dict=snake_case__ , **snake_case__ ).to_tuple()
def recursive_check(snake_case__ : List[str] , snake_case__ : Optional[Any] ):
if isinstance(snake_case__ , (List, Tuple) ):
for tuple_iterable_value, dict_iterable_value in zip(snake_case__ , snake_case__ ):
recursive_check(snake_case__ , snake_case__ )
elif isinstance(snake_case__ , snake_case__ ):
for tuple_iterable_value, dict_iterable_value in zip(
tuple_object.values() , dict_object.values() ):
recursive_check(snake_case__ , snake_case__ )
elif tuple_object is None:
return
else:
self.assertTrue(
torch.allclose(
set_nan_tensor_to_zero(snake_case__ ) , set_nan_tensor_to_zero(snake_case__ ) , atol=1e-5 ) , msg=(
"Tuple and dict output are not equal. Difference:"
f""" {torch.max(torch.abs(tuple_object - dict_object ) )}. Tuple has `nan`:"""
f""" {torch.isnan(snake_case__ ).any()} and `inf`: {torch.isinf(snake_case__ )}. Dict has"""
f""" `nan`: {torch.isnan(snake_case__ ).any()} and `inf`: {torch.isinf(snake_case__ )}."""
) , )
recursive_check(snake_case__ , snake_case__ )
for model_class in self.all_model_classes:
snake_case : Optional[int] = model_class(snake_case__ )
model.to(snake_case__ )
model.eval()
snake_case : Union[str, Any] = self._prepare_for_class(snake_case__ , snake_case__ )
snake_case : Tuple = self._prepare_for_class(snake_case__ , snake_case__ )
check_equivalence(snake_case__ , snake_case__ , snake_case__ )
snake_case : Tuple = self._prepare_for_class(snake_case__ , snake_case__ , return_labels=snake_case__ )
snake_case : Optional[Any] = self._prepare_for_class(snake_case__ , snake_case__ , return_labels=snake_case__ )
check_equivalence(snake_case__ , snake_case__ , snake_case__ )
snake_case : Dict = self._prepare_for_class(snake_case__ , snake_case__ )
snake_case : List[Any] = self._prepare_for_class(snake_case__ , snake_case__ )
check_equivalence(snake_case__ , snake_case__ , snake_case__ , {"output_hidden_states": True} )
snake_case : Any = self._prepare_for_class(snake_case__ , snake_case__ , return_labels=snake_case__ )
snake_case : List[str] = self._prepare_for_class(snake_case__ , snake_case__ , return_labels=snake_case__ )
check_equivalence(snake_case__ , snake_case__ , snake_case__ , {"output_hidden_states": True} )
@require_torch
class UpperCAmelCase ( unittest.TestCase ,A_ ):
A__ : int = (MaskFormerSwinBackbone,) if is_torch_available() else ()
A__ : int = MaskFormerSwinConfig
def _SCREAMING_SNAKE_CASE (self : List[Any] ) -> Any:
'''simple docstring'''
snake_case : Union[str, Any] = MaskFormerSwinModelTester(self )
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> Optional[Any]:
'''simple docstring'''
snake_case , snake_case : Dict = self.model_tester.prepare_config_and_inputs_for_common()
snake_case : Optional[int] = inputs_dict["pixel_values"].shape[0]
for backbone_class in self.all_model_classes:
snake_case : Optional[int] = backbone_class(snake_case__ )
backbone.to(snake_case__ )
backbone.eval()
snake_case : Union[str, Any] = backbone(**snake_case__ )
# Test default outputs and verify feature maps
self.assertIsInstance(outputs.feature_maps , snake_case__ )
self.assertTrue(len(outputs.feature_maps ) == len(backbone.channels ) )
for feature_map, n_channels in zip(outputs.feature_maps , backbone.channels ):
self.assertTrue(feature_map.shape[:2] , (batch_size, n_channels) )
self.assertIsNone(outputs.hidden_states )
self.assertIsNone(outputs.attentions )
# Test output_hidden_states=True
snake_case : Optional[int] = backbone(**snake_case__ , output_hidden_states=snake_case__ )
self.assertIsNotNone(outputs.hidden_states )
self.assertTrue(len(outputs.hidden_states ) , len(backbone.stage_names ) )
# We skip the stem layer
for hidden_states, n_channels in zip(outputs.hidden_states[1:] , backbone.channels ):
for hidden_state in hidden_states:
# Hidden states are in the format (batch_size, (height * width), n_channels)
snake_case , snake_case , snake_case : Dict = hidden_state.shape
self.assertTrue((h_batch_size, h_n_channels) , (batch_size, n_channels) )
# Test output_attentions=True
if self.has_attentions:
snake_case : Optional[Any] = backbone(**snake_case__ , output_attentions=snake_case__ )
self.assertIsNotNone(outputs.attentions )
| 59
|
import gc
import unittest
from parameterized import parameterized
from diffusers import FlaxUNetaDConditionModel
from diffusers.utils import is_flax_available
from diffusers.utils.testing_utils import load_hf_numpy, require_flax, slow
if is_flax_available():
import jax
import jax.numpy as jnp
@slow
@require_flax
class UpperCAmelCase ( unittest.TestCase ):
def _SCREAMING_SNAKE_CASE (self : str , snake_case__ : Union[str, Any] , snake_case__ : List[str] ) -> List[str]:
'''simple docstring'''
return f"""gaussian_noise_s={seed}_shape={'_'.join([str(snake_case__ ) for s in shape] )}.npy"""
def _SCREAMING_SNAKE_CASE (self : Tuple ) -> int:
'''simple docstring'''
super().tearDown()
gc.collect()
def _SCREAMING_SNAKE_CASE (self : str , snake_case__ : Optional[Any]=0 , snake_case__ : Any=(4, 4, 64, 64) , snake_case__ : List[Any]=False ) -> int:
'''simple docstring'''
snake_case : Optional[Any] = jnp.bfloataa if fpaa else jnp.floataa
snake_case : Optional[int] = jnp.array(load_hf_numpy(self.get_file_format(snake_case__ , snake_case__ ) ) , dtype=snake_case__ )
return image
def _SCREAMING_SNAKE_CASE (self : Optional[int] , snake_case__ : Tuple=False , snake_case__ : List[Any]="CompVis/stable-diffusion-v1-4" ) -> List[Any]:
'''simple docstring'''
snake_case : List[str] = jnp.bfloataa if fpaa else jnp.floataa
snake_case : str = "bf16" if fpaa else None
snake_case , snake_case : Optional[int] = FlaxUNetaDConditionModel.from_pretrained(
snake_case__ , subfolder="unet" , dtype=snake_case__ , revision=snake_case__ )
return model, params
def _SCREAMING_SNAKE_CASE (self : List[str] , snake_case__ : Union[str, Any]=0 , snake_case__ : Union[str, Any]=(4, 77, 7_68) , snake_case__ : Dict=False ) -> List[str]:
'''simple docstring'''
snake_case : Any = jnp.bfloataa if fpaa else jnp.floataa
snake_case : Any = jnp.array(load_hf_numpy(self.get_file_format(snake_case__ , snake_case__ ) ) , dtype=snake_case__ )
return hidden_states
@parameterized.expand(
[
# fmt: off
[83, 4, [-0.2323, -0.1304, 0.0813, -0.3093, -0.0919, -0.1571, -0.1125, -0.5806]],
[17, 0.55, [-0.0831, -0.2443, 0.0901, -0.0919, 0.3396, 0.0103, -0.3743, 0.0701]],
[8, 0.89, [-0.4863, 0.0859, 0.0875, -0.1658, 0.9199, -0.0114, 0.4839, 0.4639]],
[3, 10_00, [-0.5649, 0.2402, -0.5518, 0.1248, 1.1328, -0.2443, -0.0325, -1.0078]],
# fmt: on
] )
def _SCREAMING_SNAKE_CASE (self : Optional[int] , snake_case__ : int , snake_case__ : Optional[int] , snake_case__ : Dict ) -> List[str]:
'''simple docstring'''
snake_case , snake_case : List[str] = self.get_unet_model(model_id="CompVis/stable-diffusion-v1-4" , fpaa=snake_case__ )
snake_case : Union[str, Any] = self.get_latents(snake_case__ , fpaa=snake_case__ )
snake_case : List[str] = self.get_encoder_hidden_states(snake_case__ , fpaa=snake_case__ )
snake_case : Dict = model.apply(
{"params": params} , snake_case__ , jnp.array(snake_case__ , dtype=jnp.intaa ) , encoder_hidden_states=snake_case__ , ).sample
assert sample.shape == latents.shape
snake_case : Optional[Any] = jnp.asarray(jax.device_get((sample[-1, -2:, -2:, :2].flatten()) ) , dtype=jnp.floataa )
snake_case : Optional[int] = jnp.array(snake_case__ , dtype=jnp.floataa )
# Found torch (float16) and flax (bfloat16) outputs to be within this tolerance, in the same hardware
assert jnp.allclose(snake_case__ , snake_case__ , atol=1e-2 )
@parameterized.expand(
[
# fmt: off
[83, 4, [0.1514, 0.0807, 0.1624, 0.1016, -0.1896, 0.0263, 0.0677, 0.2310]],
[17, 0.55, [0.1164, -0.0216, 0.0170, 0.1589, -0.3120, 0.1005, -0.0581, -0.1458]],
[8, 0.89, [-0.1758, -0.0169, 0.1004, -0.1411, 0.1312, 0.1103, -0.1996, 0.2139]],
[3, 10_00, [0.1214, 0.0352, -0.0731, -0.1562, -0.0994, -0.0906, -0.2340, -0.0539]],
# fmt: on
] )
def _SCREAMING_SNAKE_CASE (self : Optional[int] , snake_case__ : Optional[int] , snake_case__ : str , snake_case__ : Tuple ) -> str:
'''simple docstring'''
snake_case , snake_case : List[Any] = self.get_unet_model(model_id="stabilityai/stable-diffusion-2" , fpaa=snake_case__ )
snake_case : List[str] = self.get_latents(snake_case__ , shape=(4, 4, 96, 96) , fpaa=snake_case__ )
snake_case : Union[str, Any] = self.get_encoder_hidden_states(snake_case__ , shape=(4, 77, 10_24) , fpaa=snake_case__ )
snake_case : Optional[int] = model.apply(
{"params": params} , snake_case__ , jnp.array(snake_case__ , dtype=jnp.intaa ) , encoder_hidden_states=snake_case__ , ).sample
assert sample.shape == latents.shape
snake_case : int = jnp.asarray(jax.device_get((sample[-1, -2:, -2:, :2].flatten()) ) , dtype=jnp.floataa )
snake_case : Dict = jnp.array(snake_case__ , dtype=jnp.floataa )
# Found torch (float16) and flax (bfloat16) outputs to be within this tolerance, on the same hardware
assert jnp.allclose(snake_case__ , snake_case__ , atol=1e-2 )
| 59
| 1
|
import inspect
import os
import unittest
from pathlib import Path
import torch
import accelerate
from accelerate.test_utils import execute_subprocess_async
from accelerate.test_utils.testing import run_command
class UpperCAmelCase ( unittest.TestCase ):
A__ : List[str] = inspect.getfile(accelerate.test_utils )
A__ : List[str] = os.path.sep.join(mod_file.split(os.path.sep )[:-1] + ["scripts", "test_cli.py"] )
A__ : Tuple = ["accelerate", "launch"]
A__ : int = Path.home() / ".cache/huggingface/accelerate"
A__ : Tuple = "default_config.yaml"
A__ : List[Any] = config_folder / config_file
A__ : List[Any] = config_folder / "_default_config.yaml"
A__ : List[str] = Path("tests/test_configs" )
@classmethod
def _SCREAMING_SNAKE_CASE (cls : Union[str, Any] ) -> Optional[int]:
'''simple docstring'''
if cls.config_path.is_file():
cls.config_path.rename(cls.changed_path )
@classmethod
def _SCREAMING_SNAKE_CASE (cls : Optional[Any] ) -> Optional[int]:
'''simple docstring'''
if cls.changed_path.is_file():
cls.changed_path.rename(cls.config_path )
def _SCREAMING_SNAKE_CASE (self : str ) -> Dict:
'''simple docstring'''
snake_case : int = self.base_cmd
if torch.cuda.is_available() and (torch.cuda.device_count() > 1):
cmd += ["--multi_gpu"]
execute_subprocess_async(cmd + [self.test_file_path] , env=os.environ.copy() )
def _SCREAMING_SNAKE_CASE (self : List[str] ) -> Tuple:
'''simple docstring'''
for config in sorted(self.test_config_path.glob("**/*.yaml" ) ):
with self.subTest(config_file=snake_case__ ):
execute_subprocess_async(
self.base_cmd + ["--config_file", str(snake_case__ ), self.test_file_path] , env=os.environ.copy() )
def _SCREAMING_SNAKE_CASE (self : Union[str, Any] ) -> Dict:
'''simple docstring'''
execute_subprocess_async(["accelerate", "test"] , env=os.environ.copy() )
class UpperCAmelCase ( unittest.TestCase ):
A__ : List[Any] = "test-tpu"
A__ : int = "us-central1-a"
A__ : Any = "ls"
A__ : int = ["accelerate", "tpu-config"]
A__ : Dict = "cd /usr/share"
A__ : List[Any] = "tests/test_samples/test_command_file.sh"
A__ : Optional[int] = "Running gcloud compute tpus tpu-vm ssh"
def _SCREAMING_SNAKE_CASE (self : Optional[Any] ) -> int:
'''simple docstring'''
snake_case : List[str] = run_command(
self.cmd
+ ["--command", self.command, "--tpu_zone", self.tpu_zone, "--tpu_name", self.tpu_name, "--debug"] , return_stdout=snake_case__ , )
self.assertIn(
f"""{self.gcloud} test-tpu --zone us-central1-a --command {self.base_output}; ls --worker all""" , snake_case__ , )
def _SCREAMING_SNAKE_CASE (self : Optional[Any] ) -> Any:
'''simple docstring'''
snake_case : Tuple = run_command(
self.cmd
+ [
"--config_file",
"tests/test_configs/0_12_0.yaml",
"--command",
self.command,
"--tpu_zone",
self.tpu_zone,
"--tpu_name",
self.tpu_name,
"--debug",
] , return_stdout=snake_case__ , )
self.assertIn(
f"""{self.gcloud} test-tpu --zone us-central1-a --command {self.base_output}; ls --worker all""" , snake_case__ , )
def _SCREAMING_SNAKE_CASE (self : Any ) -> int:
'''simple docstring'''
snake_case : Any = run_command(
self.cmd + ["--config_file", "tests/test_configs/latest.yaml", "--debug"] , return_stdout=snake_case__ )
self.assertIn(
f"""{self.gcloud} test-tpu --zone us-central1-a --command {self.base_output}; echo \"hello world\"; echo \"this is a second command\" --worker all""" , snake_case__ , )
def _SCREAMING_SNAKE_CASE (self : List[Any] ) -> Optional[int]:
'''simple docstring'''
snake_case : str = run_command(
self.cmd + ["--config_file", "tests/test_configs/latest.yaml", "--command", self.command, "--debug"] , return_stdout=snake_case__ , )
self.assertIn(
f"""{self.gcloud} test-tpu --zone us-central1-a --command {self.base_output}; ls --worker all""" , snake_case__ , )
def _SCREAMING_SNAKE_CASE (self : int ) -> Dict:
'''simple docstring'''
snake_case : Union[str, Any] = run_command(
self.cmd
+ [
"--config_file",
"tests/test_configs/latest.yaml",
"--command",
self.command,
"--command",
"echo \"Hello World\"",
"--debug",
] , return_stdout=snake_case__ , )
self.assertIn(
f"""{self.gcloud} test-tpu --zone us-central1-a --command {self.base_output}; ls; echo \"Hello World\" --worker all""" , snake_case__ , )
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> List[str]:
'''simple docstring'''
snake_case : List[Any] = run_command(
self.cmd
+ ["--config_file", "tests/test_configs/latest.yaml", "--command_file", self.command_file, "--debug"] , return_stdout=snake_case__ , )
self.assertIn(
f"""{self.gcloud} test-tpu --zone us-central1-a --command {self.base_output}; echo \"hello world\"; echo \"this is a second command\" --worker all""" , snake_case__ , )
def _SCREAMING_SNAKE_CASE (self : Optional[Any] ) -> Tuple:
'''simple docstring'''
snake_case : Any = run_command(
self.cmd
+ [
"--config_file",
"tests/test_configs/0_12_0.yaml",
"--command_file",
self.command_file,
"--tpu_zone",
self.tpu_zone,
"--tpu_name",
self.tpu_name,
"--debug",
] , return_stdout=snake_case__ , )
self.assertIn(
f"""{self.gcloud} test-tpu --zone us-central1-a --command {self.base_output}; echo \"hello world\"; echo \"this is a second command\" --worker all""" , snake_case__ , )
def _SCREAMING_SNAKE_CASE (self : List[str] ) -> Optional[int]:
'''simple docstring'''
snake_case : List[Any] = run_command(
self.cmd + ["--config_file", "tests/test_configs/latest.yaml", "--install_accelerate", "--debug"] , return_stdout=snake_case__ , )
self.assertIn(
f"""{self.gcloud} test-tpu --zone us-central1-a --command {self.base_output}; pip install accelerate -U; echo \"hello world\"; echo \"this is a second command\" --worker all""" , snake_case__ , )
def _SCREAMING_SNAKE_CASE (self : List[Any] ) -> Optional[int]:
'''simple docstring'''
snake_case : Optional[Any] = run_command(
self.cmd
+ [
"--config_file",
"tests/test_configs/latest.yaml",
"--install_accelerate",
"--accelerate_version",
"12.0.0",
"--debug",
] , return_stdout=snake_case__ , )
self.assertIn(
f"""{self.gcloud} test-tpu --zone us-central1-a --command {self.base_output}; pip install accelerate==12.0.0; echo \"hello world\"; echo \"this is a second command\" --worker all""" , snake_case__ , )
| 59
|
import argparse
import re
from typing import Dict
import torch
from datasets import Audio, Dataset, load_dataset, load_metric
from transformers import AutoFeatureExtractor, pipeline
def UpperCamelCase ( __lowerCamelCase : Dataset , __lowerCamelCase : Dict[str, str] ):
snake_case : int = args.log_outputs
snake_case : Dict = "_".join(args.dataset.split("/" ) + [args.config, args.split] )
# load metric
snake_case : List[str] = load_metric("wer" )
snake_case : Tuple = load_metric("cer" )
# compute metrics
snake_case : List[Any] = wer.compute(references=result["target"] , predictions=result["prediction"] )
snake_case : int = cer.compute(references=result["target"] , predictions=result["prediction"] )
# print & log results
snake_case : int = f"""WER: {wer_result}\nCER: {cer_result}"""
print(__lowerCamelCase )
with open(f"""{dataset_id}_eval_results.txt""" , "w" ) as f:
f.write(__lowerCamelCase )
# log all results in text file. Possibly interesting for analysis
if log_outputs is not None:
snake_case : int = f"""log_{dataset_id}_predictions.txt"""
snake_case : List[Any] = f"""log_{dataset_id}_targets.txt"""
with open(__lowerCamelCase , "w" ) as p, open(__lowerCamelCase , "w" ) as t:
# mapping function to write output
def write_to_file(__lowerCamelCase : str , __lowerCamelCase : Optional[int] ):
p.write(f"""{i}""" + "\n" )
p.write(batch["prediction"] + "\n" )
t.write(f"""{i}""" + "\n" )
t.write(batch["target"] + "\n" )
result.map(__lowerCamelCase , with_indices=__lowerCamelCase )
def UpperCamelCase ( __lowerCamelCase : str ):
snake_case : List[Any] = "[,?.!\-\;\:\"“%‘”�—’…–]" # noqa: W605 IMPORTANT: this should correspond to the chars that were ignored during training
snake_case : List[Any] = re.sub(__lowerCamelCase , "" , text.lower() )
# In addition, we can normalize the target text, e.g. removing new lines characters etc...
# note that order is important here!
snake_case : Optional[Any] = ["\n\n", "\n", " ", " "]
for t in token_sequences_to_ignore:
snake_case : Dict = " ".join(text.split(__lowerCamelCase ) )
return text
def UpperCamelCase ( __lowerCamelCase : int ):
# load dataset
snake_case : str = load_dataset(args.dataset , args.config , split=args.split , use_auth_token=__lowerCamelCase )
# for testing: only process the first two examples as a test
# dataset = dataset.select(range(10))
# load processor
snake_case : List[Any] = AutoFeatureExtractor.from_pretrained(args.model_id )
snake_case : Union[str, Any] = feature_extractor.sampling_rate
# resample audio
snake_case : Union[str, Any] = dataset.cast_column("audio" , Audio(sampling_rate=__lowerCamelCase ) )
# load eval pipeline
if args.device is None:
snake_case : List[str] = 0 if torch.cuda.is_available() else -1
snake_case : str = pipeline("automatic-speech-recognition" , model=args.model_id , device=args.device )
# map function to decode audio
def map_to_pred(__lowerCamelCase : int ):
snake_case : Dict = asr(
batch["audio"]["array"] , chunk_length_s=args.chunk_length_s , stride_length_s=args.stride_length_s )
snake_case : str = prediction["text"]
snake_case : Tuple = normalize_text(batch["sentence"] )
return batch
# run inference on all examples
snake_case : Dict = dataset.map(__lowerCamelCase , remove_columns=dataset.column_names )
# compute and log_results
# do not change function below
log_results(__lowerCamelCase , __lowerCamelCase )
if __name__ == "__main__":
__lowerCamelCase = argparse.ArgumentParser()
parser.add_argument(
"""--model_id""", type=str, required=True, help="""Model identifier. Should be loadable with 🤗 Transformers"""
)
parser.add_argument(
"""--dataset""",
type=str,
required=True,
help="""Dataset name to evaluate the `model_id`. Should be loadable with 🤗 Datasets""",
)
parser.add_argument(
"""--config""", type=str, required=True, help="""Config of the dataset. *E.g.* `'en'` for Common Voice"""
)
parser.add_argument("""--split""", type=str, required=True, help="""Split of the dataset. *E.g.* `'test'`""")
parser.add_argument(
"""--chunk_length_s""", type=float, default=None, help="""Chunk length in seconds. Defaults to 5 seconds."""
)
parser.add_argument(
"""--stride_length_s""", type=float, default=None, help="""Stride of the audio chunks. Defaults to 1 second."""
)
parser.add_argument(
"""--log_outputs""", action="""store_true""", help="""If defined, write outputs to log file for analysis."""
)
parser.add_argument(
"""--device""",
type=int,
default=None,
help="""The device to run the pipeline on. -1 for CPU (default), 0 for the first GPU and so on.""",
)
__lowerCamelCase = parser.parse_args()
main(args)
| 59
| 1
|
import unittest
from transformers import BertGenerationConfig, is_torch_available
from transformers.testing_utils import require_torch, slow, torch_device
from ...generation.test_utils import GenerationTesterMixin
from ...test_configuration_common import ConfigTester
from ...test_modeling_common import ModelTesterMixin, floats_tensor, ids_tensor, random_attention_mask
from ...test_pipeline_mixin import PipelineTesterMixin
if is_torch_available():
import torch
from transformers import BertGenerationDecoder, BertGenerationEncoder
class UpperCAmelCase :
def __init__(self : Tuple , snake_case__ : int , snake_case__ : Optional[int]=13 , snake_case__ : List[Any]=7 , snake_case__ : Tuple=True , snake_case__ : List[Any]=True , snake_case__ : Union[str, Any]=99 , snake_case__ : Any=32 , snake_case__ : Optional[Any]=5 , snake_case__ : Any=4 , snake_case__ : str=37 , snake_case__ : Optional[int]="gelu" , snake_case__ : List[Any]=0.1 , snake_case__ : List[str]=0.1 , snake_case__ : int=50 , snake_case__ : List[Any]=0.02 , snake_case__ : Any=True , snake_case__ : List[Any]=None , ) -> Tuple:
'''simple docstring'''
snake_case : Optional[Any] = parent
snake_case : Optional[int] = batch_size
snake_case : Optional[int] = seq_length
snake_case : List[Any] = is_training
snake_case : List[Any] = use_input_mask
snake_case : Optional[int] = vocab_size
snake_case : Optional[int] = hidden_size
snake_case : List[Any] = num_hidden_layers
snake_case : List[str] = num_attention_heads
snake_case : Optional[Any] = intermediate_size
snake_case : Optional[Any] = hidden_act
snake_case : str = hidden_dropout_prob
snake_case : Optional[Any] = attention_probs_dropout_prob
snake_case : Union[str, Any] = max_position_embeddings
snake_case : List[str] = initializer_range
snake_case : Optional[Any] = use_labels
snake_case : Dict = scope
def _SCREAMING_SNAKE_CASE (self : int ) -> List[Any]:
'''simple docstring'''
snake_case : Tuple = ids_tensor([self.batch_size, self.seq_length] , self.vocab_size )
snake_case : List[Any] = None
if self.use_input_mask:
snake_case : int = random_attention_mask([self.batch_size, self.seq_length] )
if self.use_labels:
snake_case : str = ids_tensor([self.batch_size, self.seq_length] , self.vocab_size )
snake_case : Optional[Any] = self.get_config()
return config, input_ids, input_mask, token_labels
def _SCREAMING_SNAKE_CASE (self : int ) -> int:
'''simple docstring'''
return BertGenerationConfig(
vocab_size=self.vocab_size , hidden_size=self.hidden_size , num_hidden_layers=self.num_hidden_layers , num_attention_heads=self.num_attention_heads , intermediate_size=self.intermediate_size , hidden_act=self.hidden_act , hidden_dropout_prob=self.hidden_dropout_prob , attention_probs_dropout_prob=self.attention_probs_dropout_prob , max_position_embeddings=self.max_position_embeddings , is_decoder=snake_case__ , initializer_range=self.initializer_range , )
def _SCREAMING_SNAKE_CASE (self : List[str] ) -> Dict:
'''simple docstring'''
(
(
snake_case
) , (
snake_case
) , (
snake_case
) , (
snake_case
) ,
) : Tuple = self.prepare_config_and_inputs()
snake_case : Any = True
snake_case : List[str] = floats_tensor([self.batch_size, self.seq_length, self.hidden_size] )
snake_case : Optional[int] = ids_tensor([self.batch_size, self.seq_length] , vocab_size=2 )
return (
config,
input_ids,
input_mask,
token_labels,
encoder_hidden_states,
encoder_attention_mask,
)
def _SCREAMING_SNAKE_CASE (self : List[Any] , snake_case__ : str , snake_case__ : str , snake_case__ : Tuple , snake_case__ : int , **snake_case__ : int , ) -> str:
'''simple docstring'''
snake_case : int = BertGenerationEncoder(config=snake_case__ )
model.to(snake_case__ )
model.eval()
snake_case : str = model(snake_case__ , attention_mask=snake_case__ )
snake_case : List[Any] = model(snake_case__ )
self.parent.assertEqual(result.last_hidden_state.shape , (self.batch_size, self.seq_length, self.hidden_size) )
def _SCREAMING_SNAKE_CASE (self : int , snake_case__ : Tuple , snake_case__ : Optional[Any] , snake_case__ : Optional[int] , snake_case__ : str , snake_case__ : Optional[Any] , snake_case__ : int , **snake_case__ : Optional[Any] , ) -> Optional[Any]:
'''simple docstring'''
snake_case : str = True
snake_case : int = BertGenerationEncoder(config=snake_case__ )
model.to(snake_case__ )
model.eval()
snake_case : Dict = model(
snake_case__ , attention_mask=snake_case__ , encoder_hidden_states=snake_case__ , encoder_attention_mask=snake_case__ , )
snake_case : Optional[Any] = model(
snake_case__ , attention_mask=snake_case__ , encoder_hidden_states=snake_case__ , )
self.parent.assertEqual(result.last_hidden_state.shape , (self.batch_size, self.seq_length, self.hidden_size) )
def _SCREAMING_SNAKE_CASE (self : int , snake_case__ : Optional[Any] , snake_case__ : Any , snake_case__ : Dict , snake_case__ : Any , snake_case__ : Union[str, Any] , snake_case__ : str , **snake_case__ : str , ) -> Dict:
'''simple docstring'''
snake_case : Optional[int] = True
snake_case : Union[str, Any] = True
snake_case : Optional[int] = BertGenerationDecoder(config=snake_case__ ).to(snake_case__ ).eval()
# first forward pass
snake_case : Optional[Any] = model(
snake_case__ , attention_mask=snake_case__ , encoder_hidden_states=snake_case__ , encoder_attention_mask=snake_case__ , use_cache=snake_case__ , )
snake_case : Any = outputs.past_key_values
# create hypothetical multiple next token and extent to next_input_ids
snake_case : Any = ids_tensor((self.batch_size, 3) , config.vocab_size )
snake_case : Optional[Any] = ids_tensor((self.batch_size, 3) , vocab_size=2 )
# append to next input_ids and
snake_case : List[Any] = torch.cat([input_ids, next_tokens] , dim=-1 )
snake_case : Optional[Any] = torch.cat([input_mask, next_mask] , dim=-1 )
snake_case : Tuple = model(
snake_case__ , attention_mask=snake_case__ , encoder_hidden_states=snake_case__ , encoder_attention_mask=snake_case__ , output_hidden_states=snake_case__ , )["hidden_states"][0]
snake_case : Dict = model(
snake_case__ , attention_mask=snake_case__ , encoder_hidden_states=snake_case__ , encoder_attention_mask=snake_case__ , past_key_values=snake_case__ , output_hidden_states=snake_case__ , )["hidden_states"][0]
# select random slice
snake_case : Tuple = ids_tensor((1,) , output_from_past.shape[-1] ).item()
snake_case : Optional[Any] = output_from_no_past[:, -3:, random_slice_idx].detach()
snake_case : Optional[Any] = output_from_past[:, :, random_slice_idx].detach()
self.parent.assertTrue(output_from_past_slice.shape[1] == next_tokens.shape[1] )
# test that outputs are equal for slice
self.parent.assertTrue(torch.allclose(snake_case__ , snake_case__ , atol=1e-3 ) )
def _SCREAMING_SNAKE_CASE (self : Tuple , snake_case__ : Tuple , snake_case__ : Dict , snake_case__ : Tuple , snake_case__ : Optional[Any] , *snake_case__ : List[Any] , ) -> str:
'''simple docstring'''
snake_case : str = BertGenerationDecoder(snake_case__ )
model.to(snake_case__ )
model.eval()
snake_case : Optional[Any] = model(snake_case__ , attention_mask=snake_case__ , labels=snake_case__ )
self.parent.assertEqual(result.logits.shape , (self.batch_size, self.seq_length, self.vocab_size) )
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> Optional[int]:
'''simple docstring'''
snake_case , snake_case , snake_case , snake_case : List[Any] = self.prepare_config_and_inputs()
snake_case : Dict = {"input_ids": input_ids, "attention_mask": input_mask}
return config, inputs_dict
@require_torch
class UpperCAmelCase ( A_ ,A_ ,A_ ,unittest.TestCase ):
A__ : str = (BertGenerationEncoder, BertGenerationDecoder) if is_torch_available() else ()
A__ : Any = (BertGenerationDecoder,) if is_torch_available() else ()
A__ : str = (
{"feature-extraction": BertGenerationEncoder, "text-generation": BertGenerationDecoder}
if is_torch_available()
else {}
)
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> Any:
'''simple docstring'''
snake_case : Dict = BertGenerationEncoderTester(self )
snake_case : List[Any] = ConfigTester(self , config_class=snake_case__ , hidden_size=37 )
def _SCREAMING_SNAKE_CASE (self : int ) -> List[Any]:
'''simple docstring'''
self.config_tester.run_common_tests()
def _SCREAMING_SNAKE_CASE (self : Dict ) -> Any:
'''simple docstring'''
snake_case : Tuple = self.model_tester.prepare_config_and_inputs()
self.model_tester.create_and_check_model(*snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Tuple ) -> int:
'''simple docstring'''
snake_case , snake_case , snake_case , snake_case : Union[str, Any] = self.model_tester.prepare_config_and_inputs()
snake_case : List[Any] = "bert"
self.model_tester.create_and_check_model(snake_case__ , snake_case__ , snake_case__ , snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Union[str, Any] ) -> int:
'''simple docstring'''
snake_case : List[str] = self.model_tester.prepare_config_and_inputs_for_decoder()
self.model_tester.create_and_check_model_as_decoder(*snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Any ) -> Dict:
'''simple docstring'''
snake_case : Tuple = self.model_tester.prepare_config_and_inputs_for_decoder()
self.model_tester.create_and_check_decoder_model_past_large_inputs(*snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Dict ) -> Any:
'''simple docstring'''
(
(
snake_case
) , (
snake_case
) , (
snake_case
) , (
snake_case
) , (
snake_case
) , (
snake_case
) ,
) : Union[str, Any] = self.model_tester.prepare_config_and_inputs_for_decoder()
snake_case : Dict = None
self.model_tester.create_and_check_model_as_decoder(
snake_case__ , snake_case__ , snake_case__ , snake_case__ , snake_case__ , snake_case__ , )
def _SCREAMING_SNAKE_CASE (self : int ) -> int:
'''simple docstring'''
snake_case : List[Any] = self.model_tester.prepare_config_and_inputs_for_decoder()
self.model_tester.create_and_check_for_causal_lm(*snake_case__ )
@slow
def _SCREAMING_SNAKE_CASE (self : Optional[Any] ) -> Tuple:
'''simple docstring'''
snake_case : Optional[int] = BertGenerationEncoder.from_pretrained("google/bert_for_seq_generation_L-24_bbc_encoder" )
self.assertIsNotNone(snake_case__ )
@require_torch
class UpperCAmelCase ( unittest.TestCase ):
@slow
def _SCREAMING_SNAKE_CASE (self : Tuple ) -> Any:
'''simple docstring'''
snake_case : Tuple = BertGenerationEncoder.from_pretrained("google/bert_for_seq_generation_L-24_bbc_encoder" )
snake_case : Dict = torch.tensor([[1_01, 75_92, 10_10, 20_26, 38_99, 20_03, 1_01_40, 1_02]] )
with torch.no_grad():
snake_case : List[str] = model(snake_case__ )[0]
snake_case : List[str] = torch.Size([1, 8, 10_24] )
self.assertEqual(output.shape , snake_case__ )
snake_case : int = torch.tensor(
[[[0.1775, 0.0083, -0.0321], [1.6002, 0.1287, 0.3912], [2.1473, 0.5791, 0.6066]]] )
self.assertTrue(torch.allclose(output[:, :3, :3] , snake_case__ , atol=1e-4 ) )
@require_torch
class UpperCAmelCase ( unittest.TestCase ):
@slow
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> Tuple:
'''simple docstring'''
snake_case : List[Any] = BertGenerationDecoder.from_pretrained("google/bert_for_seq_generation_L-24_bbc_encoder" )
snake_case : List[str] = torch.tensor([[1_01, 75_92, 10_10, 20_26, 38_99, 20_03, 1_01_40, 1_02]] )
with torch.no_grad():
snake_case : List[Any] = model(snake_case__ )[0]
snake_case : List[Any] = torch.Size([1, 8, 5_03_58] )
self.assertEqual(output.shape , snake_case__ )
snake_case : Union[str, Any] = torch.tensor(
[[[-0.5788, -2.5994, -3.7054], [0.0438, 4.7997, 1.8795], [1.5862, 6.6409, 4.4638]]] )
self.assertTrue(torch.allclose(output[:, :3, :3] , snake_case__ , atol=1e-4 ) )
| 59
|
from typing import Optional, Tuple, Union
import flax
import flax.linen as nn
import jax
import jax.numpy as jnp
from flax.core.frozen_dict import FrozenDict
from ..configuration_utils import ConfigMixin, flax_register_to_config
from ..utils import BaseOutput
from .embeddings_flax import FlaxTimestepEmbedding, FlaxTimesteps
from .modeling_flax_utils import FlaxModelMixin
from .unet_ad_blocks_flax import (
FlaxCrossAttnDownBlockaD,
FlaxCrossAttnUpBlockaD,
FlaxDownBlockaD,
FlaxUNetMidBlockaDCrossAttn,
FlaxUpBlockaD,
)
@flax.struct.dataclass
class UpperCAmelCase ( A_ ):
A__ : jnp.ndarray
@flax_register_to_config
class UpperCAmelCase ( nn.Module ,A_ ,A_ ):
A__ : int = 32
A__ : int = 4
A__ : int = 4
A__ : Tuple[str] = (
"CrossAttnDownBlock2D",
"CrossAttnDownBlock2D",
"CrossAttnDownBlock2D",
"DownBlock2D",
)
A__ : Tuple[str] = ("UpBlock2D", "CrossAttnUpBlock2D", "CrossAttnUpBlock2D", "CrossAttnUpBlock2D")
A__ : Union[bool, Tuple[bool]] = False
A__ : Tuple[int] = (3_20, 6_40, 12_80, 12_80)
A__ : int = 2
A__ : Union[int, Tuple[int]] = 8
A__ : Optional[Union[int, Tuple[int]]] = None
A__ : int = 12_80
A__ : float = 0.0
A__ : bool = False
A__ : jnp.dtype = jnp.floataa
A__ : bool = True
A__ : int = 0
A__ : bool = False
def _SCREAMING_SNAKE_CASE (self : Optional[int] , snake_case__ : jax.random.KeyArray ) -> FrozenDict:
'''simple docstring'''
snake_case : Dict = (1, self.in_channels, self.sample_size, self.sample_size)
snake_case : Any = jnp.zeros(snake_case__ , dtype=jnp.floataa )
snake_case : List[str] = jnp.ones((1,) , dtype=jnp.intaa )
snake_case : str = jnp.zeros((1, 1, self.cross_attention_dim) , dtype=jnp.floataa )
snake_case , snake_case : Optional[int] = jax.random.split(snake_case__ )
snake_case : Union[str, Any] = {"params": params_rng, "dropout": dropout_rng}
return self.init(snake_case__ , snake_case__ , snake_case__ , snake_case__ )["params"]
def _SCREAMING_SNAKE_CASE (self : str ) -> Tuple:
'''simple docstring'''
snake_case : str = self.block_out_channels
snake_case : Optional[Any] = block_out_channels[0] * 4
if self.num_attention_heads is not None:
raise ValueError(
"At the moment it is not possible to define the number of attention heads via `num_attention_heads` because of a naming issue as described in https://github.com/huggingface/diffusers/issues/2011#issuecomment-1547958131. Passing `num_attention_heads` will only be supported in diffusers v0.19." )
# If `num_attention_heads` is not defined (which is the case for most models)
# it will default to `attention_head_dim`. This looks weird upon first reading it and it is.
# The reason for this behavior is to correct for incorrectly named variables that were introduced
# when this library was created. The incorrect naming was only discovered much later in https://github.com/huggingface/diffusers/issues/2011#issuecomment-1547958131
# Changing `attention_head_dim` to `num_attention_heads` for 40,000+ configurations is too backwards breaking
# which is why we correct for the naming here.
snake_case : Tuple = self.num_attention_heads or self.attention_head_dim
# input
snake_case : Tuple = nn.Conv(
block_out_channels[0] , kernel_size=(3, 3) , strides=(1, 1) , padding=((1, 1), (1, 1)) , dtype=self.dtype , )
# time
snake_case : Union[str, Any] = FlaxTimesteps(
block_out_channels[0] , flip_sin_to_cos=self.flip_sin_to_cos , freq_shift=self.config.freq_shift )
snake_case : Dict = FlaxTimestepEmbedding(snake_case__ , dtype=self.dtype )
snake_case : List[str] = self.only_cross_attention
if isinstance(snake_case__ , snake_case__ ):
snake_case : List[Any] = (only_cross_attention,) * len(self.down_block_types )
if isinstance(snake_case__ , snake_case__ ):
snake_case : List[Any] = (num_attention_heads,) * len(self.down_block_types )
# down
snake_case : List[Any] = []
snake_case : Optional[int] = block_out_channels[0]
for i, down_block_type in enumerate(self.down_block_types ):
snake_case : List[Any] = output_channel
snake_case : Dict = block_out_channels[i]
snake_case : Optional[Any] = i == len(snake_case__ ) - 1
if down_block_type == "CrossAttnDownBlock2D":
snake_case : List[Any] = FlaxCrossAttnDownBlockaD(
in_channels=snake_case__ , out_channels=snake_case__ , dropout=self.dropout , num_layers=self.layers_per_block , num_attention_heads=num_attention_heads[i] , add_downsample=not is_final_block , use_linear_projection=self.use_linear_projection , only_cross_attention=only_cross_attention[i] , use_memory_efficient_attention=self.use_memory_efficient_attention , dtype=self.dtype , )
else:
snake_case : Union[str, Any] = FlaxDownBlockaD(
in_channels=snake_case__ , out_channels=snake_case__ , dropout=self.dropout , num_layers=self.layers_per_block , add_downsample=not is_final_block , dtype=self.dtype , )
down_blocks.append(snake_case__ )
snake_case : Dict = down_blocks
# mid
snake_case : Optional[int] = FlaxUNetMidBlockaDCrossAttn(
in_channels=block_out_channels[-1] , dropout=self.dropout , num_attention_heads=num_attention_heads[-1] , use_linear_projection=self.use_linear_projection , use_memory_efficient_attention=self.use_memory_efficient_attention , dtype=self.dtype , )
# up
snake_case : Optional[Any] = []
snake_case : Optional[int] = list(reversed(snake_case__ ) )
snake_case : Dict = list(reversed(snake_case__ ) )
snake_case : Tuple = list(reversed(snake_case__ ) )
snake_case : Optional[Any] = reversed_block_out_channels[0]
for i, up_block_type in enumerate(self.up_block_types ):
snake_case : Optional[int] = output_channel
snake_case : List[Any] = reversed_block_out_channels[i]
snake_case : Union[str, Any] = reversed_block_out_channels[min(i + 1 , len(snake_case__ ) - 1 )]
snake_case : int = i == len(snake_case__ ) - 1
if up_block_type == "CrossAttnUpBlock2D":
snake_case : Any = FlaxCrossAttnUpBlockaD(
in_channels=snake_case__ , out_channels=snake_case__ , prev_output_channel=snake_case__ , num_layers=self.layers_per_block + 1 , num_attention_heads=reversed_num_attention_heads[i] , add_upsample=not is_final_block , dropout=self.dropout , use_linear_projection=self.use_linear_projection , only_cross_attention=only_cross_attention[i] , use_memory_efficient_attention=self.use_memory_efficient_attention , dtype=self.dtype , )
else:
snake_case : Optional[int] = FlaxUpBlockaD(
in_channels=snake_case__ , out_channels=snake_case__ , prev_output_channel=snake_case__ , num_layers=self.layers_per_block + 1 , add_upsample=not is_final_block , dropout=self.dropout , dtype=self.dtype , )
up_blocks.append(snake_case__ )
snake_case : Optional[int] = output_channel
snake_case : Tuple = up_blocks
# out
snake_case : Optional[int] = nn.GroupNorm(num_groups=32 , epsilon=1e-5 )
snake_case : List[str] = nn.Conv(
self.out_channels , kernel_size=(3, 3) , strides=(1, 1) , padding=((1, 1), (1, 1)) , dtype=self.dtype , )
def __call__(self : Dict , snake_case__ : Dict , snake_case__ : Dict , snake_case__ : Optional[int] , snake_case__ : Tuple=None , snake_case__ : Union[str, Any]=None , snake_case__ : bool = True , snake_case__ : bool = False , ) -> Union[FlaxUNetaDConditionOutput, Tuple]:
'''simple docstring'''
if not isinstance(snake_case__ , jnp.ndarray ):
snake_case : List[Any] = jnp.array([timesteps] , dtype=jnp.intaa )
elif isinstance(snake_case__ , jnp.ndarray ) and len(timesteps.shape ) == 0:
snake_case : Any = timesteps.astype(dtype=jnp.floataa )
snake_case : int = jnp.expand_dims(snake_case__ , 0 )
snake_case : str = self.time_proj(snake_case__ )
snake_case : str = self.time_embedding(snake_case__ )
# 2. pre-process
snake_case : int = jnp.transpose(snake_case__ , (0, 2, 3, 1) )
snake_case : List[Any] = self.conv_in(snake_case__ )
# 3. down
snake_case : Optional[int] = (sample,)
for down_block in self.down_blocks:
if isinstance(snake_case__ , snake_case__ ):
snake_case , snake_case : List[Any] = down_block(snake_case__ , snake_case__ , snake_case__ , deterministic=not train )
else:
snake_case , snake_case : str = down_block(snake_case__ , snake_case__ , deterministic=not train )
down_block_res_samples += res_samples
if down_block_additional_residuals is not None:
snake_case : Tuple = ()
for down_block_res_sample, down_block_additional_residual in zip(
snake_case__ , snake_case__ ):
down_block_res_sample += down_block_additional_residual
new_down_block_res_samples += (down_block_res_sample,)
snake_case : Optional[int] = new_down_block_res_samples
# 4. mid
snake_case : Optional[int] = self.mid_block(snake_case__ , snake_case__ , snake_case__ , deterministic=not train )
if mid_block_additional_residual is not None:
sample += mid_block_additional_residual
# 5. up
for up_block in self.up_blocks:
snake_case : int = down_block_res_samples[-(self.layers_per_block + 1) :]
snake_case : Optional[Any] = down_block_res_samples[: -(self.layers_per_block + 1)]
if isinstance(snake_case__ , snake_case__ ):
snake_case : Optional[Any] = up_block(
snake_case__ , temb=snake_case__ , encoder_hidden_states=snake_case__ , res_hidden_states_tuple=snake_case__ , deterministic=not train , )
else:
snake_case : Dict = up_block(snake_case__ , temb=snake_case__ , res_hidden_states_tuple=snake_case__ , deterministic=not train )
# 6. post-process
snake_case : List[str] = self.conv_norm_out(snake_case__ )
snake_case : Any = nn.silu(snake_case__ )
snake_case : Optional[int] = self.conv_out(snake_case__ )
snake_case : Union[str, Any] = jnp.transpose(snake_case__ , (0, 3, 1, 2) )
if not return_dict:
return (sample,)
return FlaxUNetaDConditionOutput(sample=snake_case__ )
| 59
| 1
|
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
__lowerCamelCase = logging.get_logger(__name__)
__lowerCamelCase = {"""vocab_file""": """spiece.model"""}
__lowerCamelCase = {
"""vocab_file""": {
"""bert_for_seq_generation""": (
"""https://huggingface.co/google/bert_for_seq_generation_L-24_bbc_encoder/resolve/main/spiece.model"""
),
}
}
__lowerCamelCase = {"""bert_for_seq_generation""": 5_12}
class UpperCAmelCase ( A_ ):
A__ : Tuple = VOCAB_FILES_NAMES
A__ : Optional[Any] = PRETRAINED_VOCAB_FILES_MAP
A__ : Tuple = PRETRAINED_POSITIONAL_EMBEDDINGS_SIZES
A__ : List[int] = []
A__ : str = ["input_ids", "attention_mask"]
def __init__(self : List[Any] , snake_case__ : str , snake_case__ : Optional[int]="<s>" , snake_case__ : List[Any]="</s>" , snake_case__ : Tuple="<unk>" , snake_case__ : List[Any]="<pad>" , snake_case__ : List[str]="<::::>" , snake_case__ : Optional[Dict[str, Any]] = None , **snake_case__ : Dict , ) -> None:
'''simple docstring'''
snake_case : str = {} if sp_model_kwargs is None else sp_model_kwargs
# Add extra_ids to the special token list
super().__init__(
bos_token=snake_case__ , eos_token=snake_case__ , unk_token=snake_case__ , pad_token=snake_case__ , sep_token=snake_case__ , sp_model_kwargs=self.sp_model_kwargs , **snake_case__ , )
snake_case : Tuple = vocab_file
snake_case : Optional[int] = spm.SentencePieceProcessor(**self.sp_model_kwargs )
self.sp_model.Load(snake_case__ )
@property
def _SCREAMING_SNAKE_CASE (self : List[str] ) -> int:
'''simple docstring'''
return self.sp_model.get_piece_size()
def _SCREAMING_SNAKE_CASE (self : Union[str, Any] ) -> Union[str, Any]:
'''simple docstring'''
snake_case : Tuple = {self.convert_ids_to_tokens(snake_case__ ): i for i in range(self.vocab_size )}
vocab.update(self.added_tokens_encoder )
return vocab
def __getstate__(self : Optional[Any] ) -> Optional[int]:
'''simple docstring'''
snake_case : List[Any] = self.__dict__.copy()
snake_case : int = None
return state
def __setstate__(self : List[Any] , snake_case__ : Dict ) -> Optional[int]:
'''simple docstring'''
snake_case : Union[str, Any] = d
# for backward compatibility
if not hasattr(self , "sp_model_kwargs" ):
snake_case : Optional[Any] = {}
snake_case : Tuple = spm.SentencePieceProcessor(**self.sp_model_kwargs )
self.sp_model.Load(self.vocab_file )
def _SCREAMING_SNAKE_CASE (self : List[str] , snake_case__ : str ) -> List[str]:
'''simple docstring'''
return self.sp_model.encode(snake_case__ , out_type=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Union[str, Any] , snake_case__ : List[str] ) -> str:
'''simple docstring'''
return self.sp_model.piece_to_id(snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Optional[Any] , snake_case__ : Dict ) -> Tuple:
'''simple docstring'''
snake_case : List[str] = self.sp_model.IdToPiece(snake_case__ )
return token
def _SCREAMING_SNAKE_CASE (self : Optional[int] , snake_case__ : Optional[Any] ) -> Union[str, Any]:
'''simple docstring'''
snake_case : str = []
snake_case : Tuple = ""
for token in tokens:
# make sure that special tokens are not decoded using sentencepiece model
if token in self.all_special_tokens:
out_string += self.sp_model.decode(snake_case__ ) + token
snake_case : str = []
else:
current_sub_tokens.append(snake_case__ )
out_string += self.sp_model.decode(snake_case__ )
return out_string.strip()
def _SCREAMING_SNAKE_CASE (self : str , snake_case__ : str , snake_case__ : Optional[str] = None ) -> Tuple[str]:
'''simple docstring'''
if not os.path.isdir(snake_case__ ):
logger.error(f"""Vocabulary path ({save_directory}) should be a directory""" )
return
snake_case : List[Any] = os.path.join(
snake_case__ , (filename_prefix + "-" if filename_prefix else "") + VOCAB_FILES_NAMES["vocab_file"] )
if os.path.abspath(self.vocab_file ) != os.path.abspath(snake_case__ ) and os.path.isfile(self.vocab_file ):
copyfile(self.vocab_file , snake_case__ )
elif not os.path.isfile(self.vocab_file ):
with open(snake_case__ , "wb" ) as fi:
snake_case : int = self.sp_model.serialized_model_proto()
fi.write(snake_case__ )
return (out_vocab_file,)
| 59
|
__lowerCamelCase = {
"joule": 1.0,
"kilojoule": 10_00,
"megajoule": 1_00_00_00,
"gigajoule": 10_00_00_00_00,
"wattsecond": 1.0,
"watthour": 36_00,
"kilowatthour": 3_60_00_00,
"newtonmeter": 1.0,
"calorie_nutr": 41_86.8,
"kilocalorie_nutr": 4_18_68_00.00,
"electronvolt": 1.602_176_634e-19,
"britishthermalunit_it": 10_55.0_55_85,
"footpound": 1.35_5818,
}
def UpperCamelCase ( __lowerCamelCase : str , __lowerCamelCase : str , __lowerCamelCase : float ):
if to_type not in ENERGY_CONVERSION or from_type not in ENERGY_CONVERSION:
snake_case : List[Any] = (
f"""Incorrect 'from_type' or 'to_type' value: {from_type!r}, {to_type!r}\n"""
f"""Valid values are: {', '.join(__lowerCamelCase )}"""
)
raise ValueError(__lowerCamelCase )
return value * ENERGY_CONVERSION[from_type] / ENERGY_CONVERSION[to_type]
if __name__ == "__main__":
import doctest
doctest.testmod()
| 59
| 1
|
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
__lowerCamelCase = logging.get_logger(__name__) # pylint: disable=invalid-name
class UpperCAmelCase ( A_ ,A_ ):
@register_to_config
def __init__(self : Dict , snake_case__ : bool , snake_case__ : Optional[int] = None , snake_case__ : Optional[int] = None ) -> List[Any]:
'''simple docstring'''
super().__init__()
snake_case : Optional[int] = 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"
snake_case : Optional[int] = torch.zeros(snake_case__ , snake_case__ )
else:
snake_case : Any = None
snake_case : Optional[Any] = torch.nn.Parameter(snake_case__ )
class UpperCAmelCase ( A_ ):
A__ : VQModel
A__ : CLIPTextModel
A__ : CLIPTokenizer
A__ : TransformeraDModel
A__ : LearnedClassifierFreeSamplingEmbeddings
A__ : VQDiffusionScheduler
def __init__(self : str , snake_case__ : VQModel , snake_case__ : CLIPTextModel , snake_case__ : CLIPTokenizer , snake_case__ : TransformeraDModel , snake_case__ : VQDiffusionScheduler , snake_case__ : LearnedClassifierFreeSamplingEmbeddings , ) -> List[Any]:
'''simple docstring'''
super().__init__()
self.register_modules(
vqvae=snake_case__ , transformer=snake_case__ , text_encoder=snake_case__ , tokenizer=snake_case__ , scheduler=snake_case__ , learned_classifier_free_sampling_embeddings=snake_case__ , )
def _SCREAMING_SNAKE_CASE (self : str , snake_case__ : Any , snake_case__ : int , snake_case__ : Union[str, Any] ) -> Union[str, Any]:
'''simple docstring'''
snake_case : List[str] = len(snake_case__ ) if isinstance(snake_case__ , snake_case__ ) else 1
# get prompt text embeddings
snake_case : Optional[Any] = self.tokenizer(
snake_case__ , padding="max_length" , max_length=self.tokenizer.model_max_length , return_tensors="pt" , )
snake_case : Dict = text_inputs.input_ids
if text_input_ids.shape[-1] > self.tokenizer.model_max_length:
snake_case : List[str] = self.tokenizer.batch_decode(text_input_ids[:, self.tokenizer.model_max_length :] )
logger.warning(
"The following part of your input was truncated because CLIP can only handle sequences up to"
f""" {self.tokenizer.model_max_length} tokens: {removed_text}""" )
snake_case : str = text_input_ids[:, : self.tokenizer.model_max_length]
snake_case : str = 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
snake_case : Dict = prompt_embeds / prompt_embeds.norm(dim=-1 , keepdim=snake_case__ )
# duplicate text embeddings for each generation per prompt
snake_case : Dict = prompt_embeds.repeat_interleave(snake_case__ , dim=0 )
if do_classifier_free_guidance:
if self.learned_classifier_free_sampling_embeddings.learnable:
snake_case : Optional[int] = self.learned_classifier_free_sampling_embeddings.embeddings
snake_case : Any = negative_prompt_embeds.unsqueeze(0 ).repeat(snake_case__ , 1 , 1 )
else:
snake_case : Optional[int] = [""] * batch_size
snake_case : int = text_input_ids.shape[-1]
snake_case : Any = self.tokenizer(
snake_case__ , padding="max_length" , max_length=snake_case__ , truncation=snake_case__ , return_tensors="pt" , )
snake_case : Union[str, Any] = self.text_encoder(uncond_input.input_ids.to(self.device ) )[0]
# See comment for normalizing text embeddings
snake_case : Optional[Any] = negative_prompt_embeds / negative_prompt_embeds.norm(dim=-1 , keepdim=snake_case__ )
# duplicate unconditional embeddings for each generation per prompt, using mps friendly method
snake_case : Dict = negative_prompt_embeds.shape[1]
snake_case : Any = negative_prompt_embeds.repeat(1 , snake_case__ , 1 )
snake_case : List[Any] = negative_prompt_embeds.view(batch_size * num_images_per_prompt , snake_case__ , -1 )
# For classifier free guidance, we need to do two forward passes.
# Here we concatenate the unconditional and text embeddings into a single batch
# to avoid doing two forward passes
snake_case : Tuple = torch.cat([negative_prompt_embeds, prompt_embeds] )
return prompt_embeds
@torch.no_grad()
def __call__(self : Any , snake_case__ : Union[str, List[str]] , snake_case__ : int = 1_00 , snake_case__ : float = 5.0 , snake_case__ : float = 1.0 , snake_case__ : int = 1 , snake_case__ : Optional[Union[torch.Generator, List[torch.Generator]]] = None , snake_case__ : Optional[torch.FloatTensor] = None , snake_case__ : Optional[str] = "pil" , snake_case__ : bool = True , snake_case__ : Optional[Callable[[int, int, torch.FloatTensor], None]] = None , snake_case__ : int = 1 , ) -> Union[ImagePipelineOutput, Tuple]:
'''simple docstring'''
if isinstance(snake_case__ , snake_case__ ):
snake_case : Optional[Any] = 1
elif isinstance(snake_case__ , snake_case__ ):
snake_case : int = len(snake_case__ )
else:
raise ValueError(f"""`prompt` has to be of type `str` or `list` but is {type(snake_case__ )}""" )
snake_case : List[str] = batch_size * num_images_per_prompt
snake_case : Union[str, Any] = guidance_scale > 1.0
snake_case : Optional[int] = self._encode_prompt(snake_case__ , snake_case__ , snake_case__ )
if (callback_steps is None) or (
callback_steps is not None and (not isinstance(snake_case__ , snake_case__ ) or callback_steps <= 0)
):
raise ValueError(
f"""`callback_steps` has to be a positive integer but is {callback_steps} of type"""
f""" {type(snake_case__ )}.""" )
# get the initial completely masked latents unless the user supplied it
snake_case : Tuple = (batch_size, self.transformer.num_latent_pixels)
if latents is None:
snake_case : Optional[int] = self.transformer.num_vector_embeds - 1
snake_case : Optional[int] = torch.full(snake_case__ , snake_case__ ).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).""" )
snake_case : List[str] = latents.to(self.device )
# set timesteps
self.scheduler.set_timesteps(snake_case__ , device=self.device )
snake_case : Optional[int] = self.scheduler.timesteps.to(self.device )
snake_case : List[str] = latents
for i, t in enumerate(self.progress_bar(snake_case__ ) ):
# expand the sample if we are doing classifier free guidance
snake_case : List[Any] = torch.cat([sample] * 2 ) if do_classifier_free_guidance else sample
# predict the un-noised image
# model_output == `log_p_x_0`
snake_case : Tuple = self.transformer(snake_case__ , encoder_hidden_states=snake_case__ , timestep=snake_case__ ).sample
if do_classifier_free_guidance:
snake_case , snake_case : Optional[Any] = model_output.chunk(2 )
snake_case : List[Any] = model_output_uncond + guidance_scale * (model_output_text - model_output_uncond)
model_output -= torch.logsumexp(snake_case__ , dim=1 , keepdim=snake_case__ )
snake_case : Tuple = self.truncate(snake_case__ , snake_case__ )
# remove `log(0)`'s (`-inf`s)
snake_case : List[str] = model_output.clamp(-70 )
# compute the previous noisy sample x_t -> x_t-1
snake_case : int = self.scheduler.step(snake_case__ , timestep=snake_case__ , sample=snake_case__ , generator=snake_case__ ).prev_sample
# call the callback, if provided
if callback is not None and i % callback_steps == 0:
callback(snake_case__ , snake_case__ , snake_case__ )
snake_case : List[Any] = self.vqvae.config.vq_embed_dim
snake_case : List[str] = (batch_size, self.transformer.height, self.transformer.width, embedding_channels)
snake_case : List[str] = self.vqvae.quantize.get_codebook_entry(snake_case__ , shape=snake_case__ )
snake_case : Optional[Any] = self.vqvae.decode(snake_case__ , force_not_quantize=snake_case__ ).sample
snake_case : Tuple = (image / 2 + 0.5).clamp(0 , 1 )
snake_case : Tuple = image.cpu().permute(0 , 2 , 3 , 1 ).numpy()
if output_type == "pil":
snake_case : int = self.numpy_to_pil(snake_case__ )
if not return_dict:
return (image,)
return ImagePipelineOutput(images=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : List[Any] , snake_case__ : torch.FloatTensor , snake_case__ : float ) -> torch.FloatTensor:
'''simple docstring'''
snake_case , snake_case : Optional[int] = torch.sort(snake_case__ , 1 , descending=snake_case__ )
snake_case : List[Any] = torch.exp(snake_case__ )
snake_case : List[Any] = sorted_p_x_0.cumsum(dim=1 ) < truncation_rate
# Ensure that at least the largest probability is not zeroed out
snake_case : Optional[Any] = torch.full_like(keep_mask[:, 0:1, :] , snake_case__ )
snake_case : List[Any] = torch.cat((all_true, keep_mask) , dim=1 )
snake_case : str = keep_mask[:, :-1, :]
snake_case : Tuple = keep_mask.gather(1 , indices.argsort(1 ) )
snake_case : Any = log_p_x_0.clone()
snake_case : List[Any] = -torch.inf # -inf = log(0)
return rv
| 59
|
import logging
import os
from dataclasses import dataclass, field
from typing import Dict, Optional
import datasets
import numpy as np
import tensorflow as tf
from transformers import (
AutoConfig,
AutoTokenizer,
EvalPrediction,
HfArgumentParser,
PreTrainedTokenizer,
TFAutoModelForSequenceClassification,
TFTrainer,
TFTrainingArguments,
)
from transformers.utils import logging as hf_logging
hf_logging.set_verbosity_info()
hf_logging.enable_default_handler()
hf_logging.enable_explicit_format()
def UpperCamelCase ( __lowerCamelCase : str , __lowerCamelCase : str , __lowerCamelCase : str , __lowerCamelCase : PreTrainedTokenizer , __lowerCamelCase : int , __lowerCamelCase : Optional[int] = None , ):
snake_case : int = {}
if train_file is not None:
snake_case : List[Any] = [train_file]
if eval_file is not None:
snake_case : Optional[int] = [eval_file]
if test_file is not None:
snake_case : Any = [test_file]
snake_case : int = datasets.load_dataset("csv" , data_files=__lowerCamelCase )
snake_case : str = list(ds[list(files.keys() )[0]].features.keys() )
snake_case : int = features_name.pop(__lowerCamelCase )
snake_case : str = list(set(ds[list(files.keys() )[0]][label_name] ) )
snake_case : str = {label: i for i, label in enumerate(__lowerCamelCase )}
snake_case : List[Any] = tokenizer.model_input_names
snake_case : List[Any] = {}
if len(__lowerCamelCase ) == 1:
for k in files.keys():
snake_case : Tuple = ds[k].map(
lambda __lowerCamelCase : tokenizer.batch_encode_plus(
example[features_name[0]] , truncation=__lowerCamelCase , max_length=__lowerCamelCase , padding="max_length" ) , batched=__lowerCamelCase , )
elif len(__lowerCamelCase ) == 2:
for k in files.keys():
snake_case : List[Any] = ds[k].map(
lambda __lowerCamelCase : tokenizer.batch_encode_plus(
(example[features_name[0]], example[features_name[1]]) , truncation=__lowerCamelCase , max_length=__lowerCamelCase , padding="max_length" , ) , batched=__lowerCamelCase , )
def gen_train():
for ex in transformed_ds[datasets.Split.TRAIN]:
snake_case : Dict = {k: v for k, v in ex.items() if k in input_names}
snake_case : Union[str, Any] = labelaid[ex[label_name]]
yield (d, label)
def gen_val():
for ex in transformed_ds[datasets.Split.VALIDATION]:
snake_case : str = {k: v for k, v in ex.items() if k in input_names}
snake_case : Any = labelaid[ex[label_name]]
yield (d, label)
def gen_test():
for ex in transformed_ds[datasets.Split.TEST]:
snake_case : str = {k: v for k, v in ex.items() if k in input_names}
snake_case : List[str] = labelaid[ex[label_name]]
yield (d, label)
snake_case : int = (
tf.data.Dataset.from_generator(
__lowerCamelCase , ({k: tf.intaa for k in input_names}, tf.intaa) , ({k: tf.TensorShape([None] ) for k in input_names}, tf.TensorShape([] )) , )
if datasets.Split.TRAIN in transformed_ds
else None
)
if train_ds is not None:
snake_case : Optional[Any] = train_ds.apply(tf.data.experimental.assert_cardinality(len(ds[datasets.Split.TRAIN] ) ) )
snake_case : Tuple = (
tf.data.Dataset.from_generator(
__lowerCamelCase , ({k: tf.intaa for k in input_names}, tf.intaa) , ({k: tf.TensorShape([None] ) for k in input_names}, tf.TensorShape([] )) , )
if datasets.Split.VALIDATION in transformed_ds
else None
)
if val_ds is not None:
snake_case : List[str] = val_ds.apply(tf.data.experimental.assert_cardinality(len(ds[datasets.Split.VALIDATION] ) ) )
snake_case : Optional[int] = (
tf.data.Dataset.from_generator(
__lowerCamelCase , ({k: tf.intaa for k in input_names}, tf.intaa) , ({k: tf.TensorShape([None] ) for k in input_names}, tf.TensorShape([] )) , )
if datasets.Split.TEST in transformed_ds
else None
)
if test_ds is not None:
snake_case : str = test_ds.apply(tf.data.experimental.assert_cardinality(len(ds[datasets.Split.TEST] ) ) )
return train_ds, val_ds, test_ds, labelaid
__lowerCamelCase = logging.getLogger(__name__)
@dataclass
class UpperCAmelCase :
A__ : int = field(metadata={"help": "Which column contains the label"} )
A__ : str = field(default=A_ ,metadata={"help": "The path of the training file"} )
A__ : Optional[str] = field(default=A_ ,metadata={"help": "The path of the development file"} )
A__ : Optional[str] = field(default=A_ ,metadata={"help": "The path of the test file"} )
A__ : int = field(
default=1_28 ,metadata={
"help": (
"The maximum total input sequence length after tokenization. Sequences longer "
"than this will be truncated, sequences shorter will be padded."
)
} ,)
A__ : bool = field(
default=A_ ,metadata={"help": "Overwrite the cached training and evaluation sets"} )
@dataclass
class UpperCAmelCase :
A__ : str = field(
metadata={"help": "Path to pretrained model or model identifier from huggingface.co/models"} )
A__ : Optional[str] = field(
default=A_ ,metadata={"help": "Pretrained config name or path if not the same as model_name"} )
A__ : Optional[str] = field(
default=A_ ,metadata={"help": "Pretrained tokenizer name or path if not the same as model_name"} )
A__ : bool = 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.
A__ : Optional[str] = field(
default=A_ ,metadata={"help": "Where do you want to store the pretrained models downloaded from huggingface.co"} ,)
def UpperCamelCase ( ):
# See all possible arguments in src/transformers/training_args.py
# or by passing the --help flag to this script.
# We now keep distinct sets of args, for a cleaner separation of concerns.
snake_case : List[Any] = HfArgumentParser((ModelArguments, DataTrainingArguments, TFTrainingArguments) )
snake_case , snake_case , snake_case : int = parser.parse_args_into_dataclasses()
if (
os.path.exists(training_args.output_dir )
and os.listdir(training_args.output_dir )
and training_args.do_train
and not training_args.overwrite_output_dir
):
raise ValueError(
f"""Output directory ({training_args.output_dir}) already exists and is not empty. Use"""
" --overwrite_output_dir to overcome." )
# Setup logging
logging.basicConfig(
format="%(asctime)s - %(levelname)s - %(name)s - %(message)s" , datefmt="%m/%d/%Y %H:%M:%S" , level=logging.INFO , )
logger.info(
f"""n_replicas: {training_args.n_replicas}, distributed training: {bool(training_args.n_replicas > 1 )}, """
f"""16-bits training: {training_args.fpaa}""" )
logger.info(f"""Training/evaluation parameters {training_args}""" )
# Load pretrained model and tokenizer
#
# Distributed training:
# The .from_pretrained methods guarantee that only one local process can concurrently
# download model & vocab.
snake_case : Tuple = AutoTokenizer.from_pretrained(
model_args.tokenizer_name if model_args.tokenizer_name else model_args.model_name_or_path , cache_dir=model_args.cache_dir , )
snake_case , snake_case , snake_case , snake_case : Tuple = get_tfds(
train_file=data_args.train_file , eval_file=data_args.dev_file , test_file=data_args.test_file , tokenizer=__lowerCamelCase , label_column_id=data_args.label_column_id , max_seq_length=data_args.max_seq_length , )
snake_case : Optional[Any] = AutoConfig.from_pretrained(
model_args.config_name if model_args.config_name else model_args.model_name_or_path , num_labels=len(__lowerCamelCase ) , labelaid=__lowerCamelCase , idalabel={id: label for label, id in labelaid.items()} , finetuning_task="text-classification" , cache_dir=model_args.cache_dir , )
with training_args.strategy.scope():
snake_case : int = TFAutoModelForSequenceClassification.from_pretrained(
model_args.model_name_or_path , from_pt=bool(".bin" in model_args.model_name_or_path ) , config=__lowerCamelCase , cache_dir=model_args.cache_dir , )
def compute_metrics(__lowerCamelCase : EvalPrediction ) -> Dict:
snake_case : Optional[int] = np.argmax(p.predictions , axis=1 )
return {"acc": (preds == p.label_ids).mean()}
# Initialize our Trainer
snake_case : int = TFTrainer(
model=__lowerCamelCase , args=__lowerCamelCase , train_dataset=__lowerCamelCase , eval_dataset=__lowerCamelCase , compute_metrics=__lowerCamelCase , )
# Training
if training_args.do_train:
trainer.train()
trainer.save_model()
tokenizer.save_pretrained(training_args.output_dir )
# Evaluation
snake_case : int = {}
if training_args.do_eval:
logger.info("*** Evaluate ***" )
snake_case : Any = trainer.evaluate()
snake_case : List[Any] = os.path.join(training_args.output_dir , "eval_results.txt" )
with open(__lowerCamelCase , "w" ) as writer:
logger.info("***** Eval results *****" )
for key, value in result.items():
logger.info(f""" {key} = {value}""" )
writer.write(f"""{key} = {value}\n""" )
results.update(__lowerCamelCase )
return results
if __name__ == "__main__":
main()
| 59
| 1
|
from typing import Dict, List
from nltk.translate import gleu_score
import datasets
from datasets import MetricInfo
__lowerCamelCase = """\
@misc{wu2016googles,
title={Google's Neural Machine Translation System: Bridging the Gap between Human and Machine Translation},
author={Yonghui Wu and Mike Schuster and Zhifeng Chen and Quoc V. Le and Mohammad Norouzi and Wolfgang Macherey
and Maxim Krikun and Yuan Cao and Qin Gao and Klaus Macherey and Jeff Klingner and Apurva Shah and Melvin
Johnson and Xiaobing Liu and Łukasz Kaiser and Stephan Gouws and Yoshikiyo Kato and Taku Kudo and Hideto
Kazawa and Keith Stevens and George Kurian and Nishant Patil and Wei Wang and Cliff Young and
Jason Smith and Jason Riesa and Alex Rudnick and Oriol Vinyals and Greg Corrado and Macduff Hughes
and Jeffrey Dean},
year={2016},
eprint={1609.08144},
archivePrefix={arXiv},
primaryClass={cs.CL}
}
"""
__lowerCamelCase = """\
The BLEU score has some undesirable properties when used for single
sentences, as it was designed to be a corpus measure. We therefore
use a slightly different score for our RL experiments which we call
the 'GLEU score'. For the GLEU score, we record all sub-sequences of
1, 2, 3 or 4 tokens in output and target sequence (n-grams). We then
compute a recall, which is the ratio of the number of matching n-grams
to the number of total n-grams in the target (ground truth) sequence,
and a precision, which is the ratio of the number of matching n-grams
to the number of total n-grams in the generated output sequence. Then
GLEU score is simply the minimum of recall and precision. This GLEU
score's range is always between 0 (no matches) and 1 (all match) and
it is symmetrical when switching output and target. According to
our experiments, GLEU score correlates quite well with the BLEU
metric on a corpus level but does not have its drawbacks for our per
sentence reward objective.
"""
__lowerCamelCase = """\
Computes corpus-level Google BLEU (GLEU) score of translated segments against one or more references.
Instead of averaging the sentence level GLEU scores (i.e. macro-average precision), Wu et al. (2016) sum up the matching
tokens and the max of hypothesis and reference tokens for each sentence, then compute using the aggregate values.
Args:
predictions (list of str): list of translations to score.
Each translation should be tokenized into a list of tokens.
references (list of list of str): list of lists of references for each translation.
Each reference should be tokenized into a list of tokens.
min_len (int): The minimum order of n-gram this function should extract. Defaults to 1.
max_len (int): The maximum order of n-gram this function should extract. Defaults to 4.
Returns:
'google_bleu': google_bleu score
Examples:
Example 1:
>>> hyp1 = ['It', 'is', 'a', 'guide', 'to', 'action', 'which',
... 'ensures', 'that', 'the', 'rubber', 'duck', 'always',
... 'disobeys', 'the', 'commands', 'of', 'the', 'cat']
>>> ref1a = ['It', 'is', 'the', 'guiding', 'principle', 'which',
... 'guarantees', 'the', 'rubber', 'duck', 'forces', 'never',
... 'being', 'under', 'the', 'command', 'of', 'the', 'cat']
>>> hyp2 = ['he', 'read', 'the', 'book', 'because', 'he', 'was',
... 'interested', 'in', 'world', 'history']
>>> ref2a = ['he', 'was', 'interested', 'in', 'world', 'history',
... 'because', 'he', 'read', 'the', 'book']
>>> list_of_references = [[ref1a], [ref2a]]
>>> hypotheses = [hyp1, hyp2]
>>> google_bleu = datasets.load_metric(\"google_bleu\")
>>> results = google_bleu.compute(predictions=hypotheses, references=list_of_references)
>>> print(round(results[\"google_bleu\"], 2))
0.44
Example 2:
>>> hyp1 = ['It', 'is', 'a', 'guide', 'to', 'action', 'which',
... 'ensures', 'that', 'the', 'rubber', 'duck', 'always',
... 'disobeys', 'the', 'commands', 'of', 'the', 'cat']
>>> ref1a = ['It', 'is', 'the', 'guiding', 'principle', 'which',
... 'guarantees', 'the', 'rubber', 'duck', 'forces', 'never',
... 'being', 'under', 'the', 'command', 'of', 'the', 'cat']
>>> ref1b = ['It', 'is', 'a', 'guide', 'to', 'action', 'that',
... 'ensures', 'that', 'the', 'rubber', 'duck', 'will', 'never',
... 'heed', 'the', 'cat', 'commands']
>>> ref1c = ['It', 'is', 'the', 'practical', 'guide', 'for', 'the',
... 'rubber', 'duck', 'army', 'never', 'to', 'heed', 'the', 'directions',
... 'of', 'the', 'cat']
>>> hyp2 = ['he', 'read', 'the', 'book', 'because', 'he', 'was',
... 'interested', 'in', 'world', 'history']
>>> ref2a = ['he', 'was', 'interested', 'in', 'world', 'history',
... 'because', 'he', 'read', 'the', 'book']
>>> list_of_references = [[ref1a, ref1b, ref1c], [ref2a]]
>>> hypotheses = [hyp1, hyp2]
>>> google_bleu = datasets.load_metric(\"google_bleu\")
>>> results = google_bleu.compute(predictions=hypotheses, references=list_of_references)
>>> print(round(results[\"google_bleu\"], 2))
0.61
Example 3:
>>> hyp1 = ['It', 'is', 'a', 'guide', 'to', 'action', 'which',
... 'ensures', 'that', 'the', 'rubber', 'duck', 'always',
... 'disobeys', 'the', 'commands', 'of', 'the', 'cat']
>>> ref1a = ['It', 'is', 'the', 'guiding', 'principle', 'which',
... 'guarantees', 'the', 'rubber', 'duck', 'forces', 'never',
... 'being', 'under', 'the', 'command', 'of', 'the', 'cat']
>>> ref1b = ['It', 'is', 'a', 'guide', 'to', 'action', 'that',
... 'ensures', 'that', 'the', 'rubber', 'duck', 'will', 'never',
... 'heed', 'the', 'cat', 'commands']
>>> ref1c = ['It', 'is', 'the', 'practical', 'guide', 'for', 'the',
... 'rubber', 'duck', 'army', 'never', 'to', 'heed', 'the', 'directions',
... 'of', 'the', 'cat']
>>> hyp2 = ['he', 'read', 'the', 'book', 'because', 'he', 'was',
... 'interested', 'in', 'world', 'history']
>>> ref2a = ['he', 'was', 'interested', 'in', 'world', 'history',
... 'because', 'he', 'read', 'the', 'book']
>>> list_of_references = [[ref1a, ref1b, ref1c], [ref2a]]
>>> hypotheses = [hyp1, hyp2]
>>> google_bleu = datasets.load_metric(\"google_bleu\")
>>> results = google_bleu.compute(predictions=hypotheses, references=list_of_references, min_len=2)
>>> print(round(results[\"google_bleu\"], 2))
0.53
Example 4:
>>> hyp1 = ['It', 'is', 'a', 'guide', 'to', 'action', 'which',
... 'ensures', 'that', 'the', 'rubber', 'duck', 'always',
... 'disobeys', 'the', 'commands', 'of', 'the', 'cat']
>>> ref1a = ['It', 'is', 'the', 'guiding', 'principle', 'which',
... 'guarantees', 'the', 'rubber', 'duck', 'forces', 'never',
... 'being', 'under', 'the', 'command', 'of', 'the', 'cat']
>>> ref1b = ['It', 'is', 'a', 'guide', 'to', 'action', 'that',
... 'ensures', 'that', 'the', 'rubber', 'duck', 'will', 'never',
... 'heed', 'the', 'cat', 'commands']
>>> ref1c = ['It', 'is', 'the', 'practical', 'guide', 'for', 'the',
... 'rubber', 'duck', 'army', 'never', 'to', 'heed', 'the', 'directions',
... 'of', 'the', 'cat']
>>> hyp2 = ['he', 'read', 'the', 'book', 'because', 'he', 'was',
... 'interested', 'in', 'world', 'history']
>>> ref2a = ['he', 'was', 'interested', 'in', 'world', 'history',
... 'because', 'he', 'read', 'the', 'book']
>>> list_of_references = [[ref1a, ref1b, ref1c], [ref2a]]
>>> hypotheses = [hyp1, hyp2]
>>> google_bleu = datasets.load_metric(\"google_bleu\")
>>> results = google_bleu.compute(predictions=hypotheses,references=list_of_references, min_len=2, max_len=6)
>>> print(round(results[\"google_bleu\"], 2))
0.4
"""
@datasets.utils.file_utils.add_start_docstrings(_DESCRIPTION ,_KWARGS_DESCRIPTION )
class UpperCAmelCase ( datasets.Metric ):
def _SCREAMING_SNAKE_CASE (self : Optional[Any] ) -> MetricInfo:
'''simple docstring'''
return datasets.MetricInfo(
description=_DESCRIPTION , citation=_CITATION , inputs_description=_KWARGS_DESCRIPTION , features=datasets.Features(
{
"predictions": datasets.Sequence(datasets.Value("string" , id="token" ) , id="sequence" ),
"references": datasets.Sequence(
datasets.Sequence(datasets.Value("string" , id="token" ) , id="sequence" ) , id="references" ),
} ) , )
def _SCREAMING_SNAKE_CASE (self : int , snake_case__ : List[List[List[str]]] , snake_case__ : List[List[str]] , snake_case__ : int = 1 , snake_case__ : int = 4 , ) -> Dict[str, float]:
'''simple docstring'''
return {
"google_bleu": gleu_score.corpus_gleu(
list_of_references=snake_case__ , hypotheses=snake_case__ , min_len=snake_case__ , max_len=snake_case__ )
}
| 59
|
import json
import os
import shutil
import tempfile
import unittest
import numpy as np
from transformers import BertTokenizerFast
from transformers.models.bert.tokenization_bert import VOCAB_FILES_NAMES, BertTokenizer
from transformers.testing_utils import require_tokenizers, require_vision
from transformers.utils import IMAGE_PROCESSOR_NAME, is_vision_available
if is_vision_available():
from PIL import Image
from transformers import VisionTextDualEncoderProcessor, ViTImageProcessor
@require_tokenizers
@require_vision
class UpperCAmelCase ( unittest.TestCase ):
def _SCREAMING_SNAKE_CASE (self : Any ) -> List[str]:
'''simple docstring'''
snake_case : int = tempfile.mkdtemp()
# fmt: off
snake_case : Optional[int] = ["[UNK]", "[CLS]", "[SEP]", "[PAD]", "[MASK]", "want", "##want", "##ed", "wa", "un", "runn", "##ing", ",", "low", "lowest"]
# fmt: on
snake_case : List[str] = os.path.join(self.tmpdirname , VOCAB_FILES_NAMES["vocab_file"] )
with open(self.vocab_file , "w" , encoding="utf-8" ) as vocab_writer:
vocab_writer.write("".join([x + "\n" for x in vocab_tokens] ) )
snake_case : int = {
"do_resize": True,
"size": {"height": 18, "width": 18},
"do_normalize": True,
"image_mean": [0.5, 0.5, 0.5],
"image_std": [0.5, 0.5, 0.5],
}
snake_case : Optional[Any] = os.path.join(self.tmpdirname , snake_case__ )
with open(self.image_processor_file , "w" , encoding="utf-8" ) as fp:
json.dump(snake_case__ , snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Optional[Any] , **snake_case__ : str ) -> Optional[int]:
'''simple docstring'''
return BertTokenizer.from_pretrained(self.tmpdirname , **snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Optional[Any] , **snake_case__ : List[str] ) -> int:
'''simple docstring'''
return ViTImageProcessor.from_pretrained(self.tmpdirname , **snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> Dict:
'''simple docstring'''
shutil.rmtree(self.tmpdirname )
def _SCREAMING_SNAKE_CASE (self : Dict ) -> str:
'''simple docstring'''
snake_case : List[Any] = [np.random.randint(2_55 , size=(3, 30, 4_00) , dtype=np.uinta )]
snake_case : Optional[int] = [Image.fromarray(np.moveaxis(snake_case__ , 0 , -1 ) ) for x in image_inputs]
return image_inputs
def _SCREAMING_SNAKE_CASE (self : Union[str, Any] ) -> Union[str, Any]:
'''simple docstring'''
snake_case : Dict = self.get_tokenizer()
snake_case : Optional[Any] = self.get_image_processor()
snake_case : Optional[Any] = VisionTextDualEncoderProcessor(tokenizer=snake_case__ , image_processor=snake_case__ )
processor.save_pretrained(self.tmpdirname )
snake_case : Any = VisionTextDualEncoderProcessor.from_pretrained(self.tmpdirname )
self.assertEqual(processor.tokenizer.get_vocab() , tokenizer.get_vocab() )
self.assertIsInstance(processor.tokenizer , (BertTokenizer, BertTokenizerFast) )
self.assertEqual(processor.image_processor.to_json_string() , image_processor.to_json_string() )
self.assertIsInstance(processor.image_processor , snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Any ) -> Optional[Any]:
'''simple docstring'''
snake_case : str = VisionTextDualEncoderProcessor(
tokenizer=self.get_tokenizer() , image_processor=self.get_image_processor() )
processor.save_pretrained(self.tmpdirname )
snake_case : Optional[int] = self.get_tokenizer(bos_token="(BOS)" , eos_token="(EOS)" )
snake_case : Tuple = self.get_image_processor(do_normalize=snake_case__ , padding_value=1.0 )
snake_case : List[str] = VisionTextDualEncoderProcessor.from_pretrained(
self.tmpdirname , bos_token="(BOS)" , eos_token="(EOS)" , do_normalize=snake_case__ , padding_value=1.0 )
self.assertEqual(processor.tokenizer.get_vocab() , tokenizer_add_kwargs.get_vocab() )
self.assertIsInstance(processor.tokenizer , (BertTokenizer, BertTokenizerFast) )
self.assertEqual(processor.image_processor.to_json_string() , image_processor_add_kwargs.to_json_string() )
self.assertIsInstance(processor.image_processor , snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Union[str, Any] ) -> int:
'''simple docstring'''
snake_case : str = self.get_image_processor()
snake_case : Optional[int] = self.get_tokenizer()
snake_case : List[Any] = VisionTextDualEncoderProcessor(tokenizer=snake_case__ , image_processor=snake_case__ )
snake_case : Optional[Any] = self.prepare_image_inputs()
snake_case : str = image_processor(snake_case__ , return_tensors="np" )
snake_case : Any = processor(images=snake_case__ , return_tensors="np" )
for key in input_feat_extract.keys():
self.assertAlmostEqual(input_feat_extract[key].sum() , input_processor[key].sum() , delta=1e-2 )
def _SCREAMING_SNAKE_CASE (self : Tuple ) -> Optional[Any]:
'''simple docstring'''
snake_case : Dict = self.get_image_processor()
snake_case : int = self.get_tokenizer()
snake_case : Any = VisionTextDualEncoderProcessor(tokenizer=snake_case__ , image_processor=snake_case__ )
snake_case : Tuple = "lower newer"
snake_case : Tuple = processor(text=snake_case__ )
snake_case : Union[str, Any] = tokenizer(snake_case__ )
for key in encoded_tok.keys():
self.assertListEqual(encoded_tok[key] , encoded_processor[key] )
def _SCREAMING_SNAKE_CASE (self : Dict ) -> Optional[int]:
'''simple docstring'''
snake_case : List[Any] = self.get_image_processor()
snake_case : Dict = self.get_tokenizer()
snake_case : Dict = VisionTextDualEncoderProcessor(tokenizer=snake_case__ , image_processor=snake_case__ )
snake_case : int = "lower newer"
snake_case : Dict = self.prepare_image_inputs()
snake_case : Union[str, Any] = processor(text=snake_case__ , images=snake_case__ )
self.assertListEqual(list(inputs.keys() ) , ["input_ids", "token_type_ids", "attention_mask", "pixel_values"] )
# test if it raises when no input is passed
with self.assertRaises(snake_case__ ):
processor()
def _SCREAMING_SNAKE_CASE (self : str ) -> Tuple:
'''simple docstring'''
snake_case : Tuple = self.get_image_processor()
snake_case : Optional[Any] = self.get_tokenizer()
snake_case : Tuple = VisionTextDualEncoderProcessor(tokenizer=snake_case__ , image_processor=snake_case__ )
snake_case : List[str] = [[1, 4, 5, 8, 1, 0, 8], [3, 4, 3, 1, 1, 8, 9]]
snake_case : List[Any] = processor.batch_decode(snake_case__ )
snake_case : Union[str, Any] = tokenizer.batch_decode(snake_case__ )
self.assertListEqual(snake_case__ , snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> List[str]:
'''simple docstring'''
snake_case : str = self.get_image_processor()
snake_case : Union[str, Any] = self.get_tokenizer()
snake_case : Any = VisionTextDualEncoderProcessor(tokenizer=snake_case__ , image_processor=snake_case__ )
snake_case : Optional[Any] = "lower newer"
snake_case : List[Any] = self.prepare_image_inputs()
snake_case : Tuple = processor(text=snake_case__ , images=snake_case__ )
self.assertListEqual(list(inputs.keys() ) , processor.model_input_names )
| 59
| 1
|
from scipy.stats import spearmanr
import datasets
__lowerCamelCase = """
The Spearman rank-order correlation coefficient is a measure of the
relationship between two datasets. Like other correlation coefficients,
this one varies between -1 and +1 with 0 implying no correlation.
Positive correlations imply that as data in dataset x increases, so
does data in dataset y. Negative correlations imply that as x increases,
y decreases. Correlations of -1 or +1 imply an exact monotonic relationship.
Unlike the Pearson correlation, the Spearman correlation does not
assume that both datasets are normally distributed.
The p-value roughly indicates the probability of an uncorrelated system
producing datasets that have a Spearman correlation at least as extreme
as the one computed from these datasets. The p-values are not entirely
reliable but are probably reasonable for datasets larger than 500 or so.
"""
__lowerCamelCase = """
Args:
predictions (`List[float]`): Predicted labels, as returned by a model.
references (`List[float]`): Ground truth labels.
return_pvalue (`bool`): If `True`, returns the p-value. If `False`, returns
only the spearmanr score. Defaults to `False`.
Returns:
spearmanr (`float`): Spearman correlation coefficient.
p-value (`float`): p-value. **Note**: is only returned if `return_pvalue=True` is input.
Examples:
Example 1:
>>> spearmanr_metric = datasets.load_metric(\"spearmanr\")
>>> results = spearmanr_metric.compute(references=[1, 2, 3, 4, 5], predictions=[10, 9, 2.5, 6, 4])
>>> print(results)
{'spearmanr': -0.7}
Example 2:
>>> spearmanr_metric = datasets.load_metric(\"spearmanr\")
>>> results = spearmanr_metric.compute(references=[1, 2, 3, 4, 5],
... predictions=[10, 9, 2.5, 6, 4],
... return_pvalue=True)
>>> print(results['spearmanr'])
-0.7
>>> print(round(results['spearmanr_pvalue'], 2))
0.19
"""
__lowerCamelCase = R"""\
@book{kokoska2000crc,
title={CRC standard probability and statistics tables and formulae},
author={Kokoska, Stephen and Zwillinger, Daniel},
year={2000},
publisher={Crc Press}
}
@article{2020SciPy-NMeth,
author = {Virtanen, Pauli and Gommers, Ralf and Oliphant, Travis E. and
Haberland, Matt and Reddy, Tyler and Cournapeau, David and
Burovski, Evgeni and Peterson, Pearu and Weckesser, Warren and
Bright, Jonathan and {van der Walt}, St{\'e}fan J. and
Brett, Matthew and Wilson, Joshua and Millman, K. Jarrod and
Mayorov, Nikolay and Nelson, Andrew R. J. and Jones, Eric and
Kern, Robert and Larson, Eric and Carey, C J and
Polat, {\.I}lhan and Feng, Yu and Moore, Eric W. and
{VanderPlas}, Jake and Laxalde, Denis and Perktold, Josef and
Cimrman, Robert and Henriksen, Ian and Quintero, E. A. and
Harris, Charles R. and Archibald, Anne M. and
Ribeiro, Ant{\^o}nio H. and Pedregosa, Fabian and
{van Mulbregt}, Paul and {SciPy 1.0 Contributors}},
title = {{{SciPy} 1.0: Fundamental Algorithms for Scientific
Computing in Python}},
journal = {Nature Methods},
year = {2020},
volume = {17},
pages = {261--272},
adsurl = {https://rdcu.be/b08Wh},
doi = {10.1038/s41592-019-0686-2},
}
"""
@datasets.utils.file_utils.add_start_docstrings(_DESCRIPTION ,_KWARGS_DESCRIPTION )
class UpperCAmelCase ( datasets.Metric ):
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> Dict:
'''simple docstring'''
return datasets.MetricInfo(
description=_DESCRIPTION , citation=_CITATION , inputs_description=_KWARGS_DESCRIPTION , features=datasets.Features(
{
"predictions": datasets.Value("float" ),
"references": datasets.Value("float" ),
} ) , reference_urls=["https://docs.scipy.org/doc/scipy/reference/generated/scipy.stats.spearmanr.html"] , )
def _SCREAMING_SNAKE_CASE (self : int , snake_case__ : Tuple , snake_case__ : str , snake_case__ : Dict=False ) -> int:
'''simple docstring'''
snake_case : List[Any] = spearmanr(snake_case__ , snake_case__ )
if return_pvalue:
return {"spearmanr": results[0], "spearmanr_pvalue": results[1]}
else:
return {"spearmanr": results[0]}
| 59
|
from typing import TYPE_CHECKING
from ...utils import OptionalDependencyNotAvailable, _LazyModule, is_tokenizers_available, is_torch_available
__lowerCamelCase = {
"""configuration_biogpt""": ["""BIOGPT_PRETRAINED_CONFIG_ARCHIVE_MAP""", """BioGptConfig"""],
"""tokenization_biogpt""": ["""BioGptTokenizer"""],
}
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = [
"""BIOGPT_PRETRAINED_MODEL_ARCHIVE_LIST""",
"""BioGptForCausalLM""",
"""BioGptForTokenClassification""",
"""BioGptForSequenceClassification""",
"""BioGptModel""",
"""BioGptPreTrainedModel""",
]
if TYPE_CHECKING:
from .configuration_biogpt import BIOGPT_PRETRAINED_CONFIG_ARCHIVE_MAP, BioGptConfig
from .tokenization_biogpt import BioGptTokenizer
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_biogpt import (
BIOGPT_PRETRAINED_MODEL_ARCHIVE_LIST,
BioGptForCausalLM,
BioGptForSequenceClassification,
BioGptForTokenClassification,
BioGptModel,
BioGptPreTrainedModel,
)
else:
import sys
__lowerCamelCase = _LazyModule(__name__, globals()["""__file__"""], _import_structure, module_spec=__spec__)
| 59
| 1
|
from argparse import ArgumentParser
from ..pipelines import Pipeline, PipelineDataFormat, get_supported_tasks, pipeline
from ..utils import logging
from . import BaseTransformersCLICommand
__lowerCamelCase = logging.get_logger(__name__) # pylint: disable=invalid-name
def UpperCamelCase ( __lowerCamelCase : str ):
if not path:
return "pipe"
for ext in PipelineDataFormat.SUPPORTED_FORMATS:
if path.endswith(__lowerCamelCase ):
return ext
raise Exception(
f"""Unable to determine file format from file extension {path}. """
f"""Please provide the format through --format {PipelineDataFormat.SUPPORTED_FORMATS}""" )
def UpperCamelCase ( __lowerCamelCase : Tuple ):
snake_case : Any = pipeline(
task=args.task , model=args.model if args.model else None , config=args.config , tokenizer=args.tokenizer , device=args.device , )
snake_case : int = try_infer_format_from_ext(args.input ) if args.format == "infer" else args.format
snake_case : Optional[int] = PipelineDataFormat.from_str(
format=__lowerCamelCase , output_path=args.output , input_path=args.input , column=args.column if args.column else nlp.default_input_names , overwrite=args.overwrite , )
return RunCommand(__lowerCamelCase , __lowerCamelCase )
class UpperCAmelCase ( A_ ):
def __init__(self : str , snake_case__ : Pipeline , snake_case__ : PipelineDataFormat ) -> Dict:
'''simple docstring'''
snake_case : int = nlp
snake_case : Union[str, Any] = reader
@staticmethod
def _SCREAMING_SNAKE_CASE (snake_case__ : ArgumentParser ) -> Optional[Any]:
'''simple docstring'''
snake_case : Dict = parser.add_parser("run" , help="Run a pipeline through the CLI" )
run_parser.add_argument("--task" , choices=get_supported_tasks() , help="Task to run" )
run_parser.add_argument("--input" , type=snake_case__ , help="Path to the file to use for inference" )
run_parser.add_argument("--output" , type=snake_case__ , help="Path to the file that will be used post to write results." )
run_parser.add_argument("--model" , type=snake_case__ , help="Name or path to the model to instantiate." )
run_parser.add_argument("--config" , type=snake_case__ , help="Name or path to the model's config to instantiate." )
run_parser.add_argument(
"--tokenizer" , type=snake_case__ , help="Name of the tokenizer to use. (default: same as the model name)" )
run_parser.add_argument(
"--column" , type=snake_case__ , help="Name of the column to use as input. (For multi columns input as QA use column1,columns2)" , )
run_parser.add_argument(
"--format" , type=snake_case__ , default="infer" , choices=PipelineDataFormat.SUPPORTED_FORMATS , help="Input format to read from" , )
run_parser.add_argument(
"--device" , type=snake_case__ , default=-1 , help="Indicate the device to run onto, -1 indicates CPU, >= 0 indicates GPU (default: -1)" , )
run_parser.add_argument("--overwrite" , action="store_true" , help="Allow overwriting the output file." )
run_parser.set_defaults(func=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Any ) -> Optional[Any]:
'''simple docstring'''
snake_case , snake_case : List[str] = self._nlp, []
for entry in self._reader:
snake_case : Optional[Any] = nlp(**snake_case__ ) if self._reader.is_multi_columns else nlp(snake_case__ )
if isinstance(snake_case__ , snake_case__ ):
outputs.append(snake_case__ )
else:
outputs += output
# Saving data
if self._nlp.binary_output:
snake_case : str = self._reader.save_binary(snake_case__ )
logger.warning(f"""Current pipeline requires output to be in binary format, saving at {binary_path}""" )
else:
self._reader.save(snake_case__ )
| 59
|
import collections
import inspect
import unittest
from typing import Dict, List, Tuple
from transformers import MaskFormerSwinConfig
from transformers.testing_utils import require_torch, require_torch_multi_gpu, torch_device
from transformers.utils import is_torch_available
from ...test_backbone_common import BackboneTesterMixin
from ...test_configuration_common import ConfigTester
from ...test_modeling_common import ModelTesterMixin, floats_tensor, ids_tensor
from ...test_pipeline_mixin import PipelineTesterMixin
if is_torch_available():
import torch
from torch import nn
from transformers import MaskFormerSwinBackbone
from transformers.models.maskformer import MaskFormerSwinModel
class UpperCAmelCase :
def __init__(self : Dict , snake_case__ : Dict , snake_case__ : Any=13 , snake_case__ : Any=32 , snake_case__ : Optional[Any]=2 , snake_case__ : Union[str, Any]=3 , snake_case__ : List[Any]=16 , snake_case__ : int=[1, 2, 1] , snake_case__ : Dict=[2, 2, 4] , snake_case__ : Dict=2 , snake_case__ : Tuple=2.0 , snake_case__ : Optional[int]=True , snake_case__ : Union[str, Any]=0.0 , snake_case__ : Any=0.0 , snake_case__ : Union[str, Any]=0.1 , snake_case__ : int="gelu" , snake_case__ : Optional[int]=False , snake_case__ : List[Any]=True , snake_case__ : List[str]=0.02 , snake_case__ : int=1e-5 , snake_case__ : List[str]=True , snake_case__ : Union[str, Any]=None , snake_case__ : List[Any]=True , snake_case__ : Optional[Any]=10 , snake_case__ : Optional[Any]=8 , snake_case__ : Any=["stage1", "stage2", "stage3"] , snake_case__ : Tuple=[1, 2, 3] , ) -> Union[str, Any]:
'''simple docstring'''
snake_case : Any = parent
snake_case : Optional[int] = batch_size
snake_case : Union[str, Any] = image_size
snake_case : Dict = patch_size
snake_case : Optional[Any] = num_channels
snake_case : Union[str, Any] = embed_dim
snake_case : int = depths
snake_case : List[str] = num_heads
snake_case : Union[str, Any] = window_size
snake_case : Union[str, Any] = mlp_ratio
snake_case : List[Any] = qkv_bias
snake_case : List[Any] = hidden_dropout_prob
snake_case : Union[str, Any] = attention_probs_dropout_prob
snake_case : Union[str, Any] = drop_path_rate
snake_case : int = hidden_act
snake_case : Optional[int] = use_absolute_embeddings
snake_case : int = patch_norm
snake_case : Union[str, Any] = layer_norm_eps
snake_case : Any = initializer_range
snake_case : Optional[Any] = is_training
snake_case : Tuple = scope
snake_case : Optional[int] = use_labels
snake_case : Optional[Any] = type_sequence_label_size
snake_case : Union[str, Any] = encoder_stride
snake_case : Any = out_features
snake_case : Tuple = out_indices
def _SCREAMING_SNAKE_CASE (self : Optional[Any] ) -> Dict:
'''simple docstring'''
snake_case : Optional[Any] = floats_tensor([self.batch_size, self.num_channels, self.image_size, self.image_size] )
snake_case : int = None
if self.use_labels:
snake_case : Tuple = ids_tensor([self.batch_size] , self.type_sequence_label_size )
snake_case : Dict = self.get_config()
return config, pixel_values, labels
def _SCREAMING_SNAKE_CASE (self : List[str] ) -> int:
'''simple docstring'''
return MaskFormerSwinConfig(
image_size=self.image_size , patch_size=self.patch_size , num_channels=self.num_channels , embed_dim=self.embed_dim , depths=self.depths , num_heads=self.num_heads , window_size=self.window_size , mlp_ratio=self.mlp_ratio , qkv_bias=self.qkv_bias , hidden_dropout_prob=self.hidden_dropout_prob , attention_probs_dropout_prob=self.attention_probs_dropout_prob , drop_path_rate=self.drop_path_rate , hidden_act=self.hidden_act , use_absolute_embeddings=self.use_absolute_embeddings , path_norm=self.patch_norm , layer_norm_eps=self.layer_norm_eps , initializer_range=self.initializer_range , encoder_stride=self.encoder_stride , out_features=self.out_features , out_indices=self.out_indices , )
def _SCREAMING_SNAKE_CASE (self : Tuple , snake_case__ : List[Any] , snake_case__ : List[str] , snake_case__ : Tuple ) -> Optional[Any]:
'''simple docstring'''
snake_case : Union[str, Any] = MaskFormerSwinModel(config=snake_case__ )
model.to(snake_case__ )
model.eval()
snake_case : List[Any] = model(snake_case__ )
snake_case : Dict = ((config.image_size // config.patch_size) ** 2) // (4 ** (len(config.depths ) - 1))
snake_case : int = int(config.embed_dim * 2 ** (len(config.depths ) - 1) )
self.parent.assertEqual(result.last_hidden_state.shape , (self.batch_size, expected_seq_len, expected_dim) )
def _SCREAMING_SNAKE_CASE (self : List[str] , snake_case__ : Union[str, Any] , snake_case__ : List[Any] , snake_case__ : Union[str, Any] ) -> str:
'''simple docstring'''
snake_case : Optional[int] = MaskFormerSwinBackbone(config=snake_case__ )
model.to(snake_case__ )
model.eval()
snake_case : List[Any] = model(snake_case__ )
# verify feature maps
self.parent.assertEqual(len(result.feature_maps ) , len(config.out_features ) )
self.parent.assertListEqual(list(result.feature_maps[0].shape ) , [13, 16, 16, 16] )
# verify channels
self.parent.assertEqual(len(model.channels ) , len(config.out_features ) )
self.parent.assertListEqual(model.channels , [16, 32, 64] )
# verify ValueError
with self.parent.assertRaises(snake_case__ ):
snake_case : Tuple = ["stem"]
snake_case : List[Any] = MaskFormerSwinBackbone(config=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : List[Any] ) -> List[Any]:
'''simple docstring'''
snake_case : Union[str, Any] = self.prepare_config_and_inputs()
snake_case , snake_case , snake_case : List[Any] = config_and_inputs
snake_case : int = {"pixel_values": pixel_values}
return config, inputs_dict
@require_torch
class UpperCAmelCase ( A_ ,A_ ,unittest.TestCase ):
A__ : List[str] = (
(
MaskFormerSwinModel,
MaskFormerSwinBackbone,
)
if is_torch_available()
else ()
)
A__ : str = {"feature-extraction": MaskFormerSwinModel} if is_torch_available() else {}
A__ : Optional[Any] = False
A__ : List[Any] = False
A__ : List[str] = False
A__ : List[str] = False
A__ : Union[str, Any] = False
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> List[str]:
'''simple docstring'''
snake_case : str = MaskFormerSwinModelTester(self )
snake_case : Optional[int] = ConfigTester(self , config_class=snake_case__ , embed_dim=37 )
@require_torch_multi_gpu
@unittest.skip(
reason=(
"`MaskFormerSwinModel` outputs `hidden_states_spatial_dimensions` which doesn't work well with"
" `nn.DataParallel`"
) )
def _SCREAMING_SNAKE_CASE (self : str ) -> Optional[Any]:
'''simple docstring'''
pass
def _SCREAMING_SNAKE_CASE (self : str ) -> List[str]:
'''simple docstring'''
self.create_and_test_config_common_properties()
self.config_tester.create_and_test_config_to_json_string()
self.config_tester.create_and_test_config_to_json_file()
self.config_tester.create_and_test_config_from_and_save_pretrained()
self.config_tester.create_and_test_config_with_num_labels()
self.config_tester.check_config_can_be_init_without_params()
self.config_tester.check_config_arguments_init()
def _SCREAMING_SNAKE_CASE (self : Tuple ) -> List[Any]:
'''simple docstring'''
return
def _SCREAMING_SNAKE_CASE (self : Dict ) -> str:
'''simple docstring'''
snake_case : str = self.model_tester.prepare_config_and_inputs()
self.model_tester.create_and_check_model(*snake_case__ )
def _SCREAMING_SNAKE_CASE (self : int ) -> Dict:
'''simple docstring'''
snake_case : Any = self.model_tester.prepare_config_and_inputs()
self.model_tester.create_and_check_backbone(*snake_case__ )
@unittest.skip("Swin does not use inputs_embeds" )
def _SCREAMING_SNAKE_CASE (self : int ) -> Any:
'''simple docstring'''
pass
@unittest.skip("Swin does not support feedforward chunking" )
def _SCREAMING_SNAKE_CASE (self : List[str] ) -> Dict:
'''simple docstring'''
pass
def _SCREAMING_SNAKE_CASE (self : Optional[Any] ) -> List[str]:
'''simple docstring'''
snake_case , snake_case : Any = self.model_tester.prepare_config_and_inputs_for_common()
for model_class in self.all_model_classes:
snake_case : int = model_class(snake_case__ )
self.assertIsInstance(model.get_input_embeddings() , (nn.Module) )
snake_case : List[Any] = model.get_output_embeddings()
self.assertTrue(x is None or isinstance(snake_case__ , nn.Linear ) )
def _SCREAMING_SNAKE_CASE (self : Optional[Any] ) -> Dict:
'''simple docstring'''
snake_case , snake_case : str = self.model_tester.prepare_config_and_inputs_for_common()
for model_class in self.all_model_classes:
snake_case : str = model_class(snake_case__ )
snake_case : Optional[int] = inspect.signature(model.forward )
# signature.parameters is an OrderedDict => so arg_names order is deterministic
snake_case : Optional[Any] = [*signature.parameters.keys()]
snake_case : Tuple = ["pixel_values"]
self.assertListEqual(arg_names[:1] , snake_case__ )
@unittest.skip(reason="MaskFormerSwin is only used as backbone and doesn't support output_attentions" )
def _SCREAMING_SNAKE_CASE (self : List[Any] ) -> str:
'''simple docstring'''
pass
@unittest.skip(reason="MaskFormerSwin is only used as an internal backbone" )
def _SCREAMING_SNAKE_CASE (self : Tuple ) -> Any:
'''simple docstring'''
pass
def _SCREAMING_SNAKE_CASE (self : Optional[Any] , snake_case__ : List[Any] , snake_case__ : str , snake_case__ : List[Any] , snake_case__ : Tuple ) -> Optional[int]:
'''simple docstring'''
snake_case : Tuple = model_class(snake_case__ )
model.to(snake_case__ )
model.eval()
with torch.no_grad():
snake_case : Any = model(**self._prepare_for_class(snake_case__ , snake_case__ ) )
snake_case : int = outputs.hidden_states
snake_case : Union[str, Any] = getattr(
self.model_tester , "expected_num_hidden_layers" , len(self.model_tester.depths ) + 1 )
self.assertEqual(len(snake_case__ ) , snake_case__ )
# Swin has a different seq_length
snake_case : Any = (
config.patch_size
if isinstance(config.patch_size , collections.abc.Iterable )
else (config.patch_size, config.patch_size)
)
snake_case : Tuple = (image_size[1] // patch_size[1]) * (image_size[0] // patch_size[0])
self.assertListEqual(
list(hidden_states[0].shape[-2:] ) , [num_patches, self.model_tester.embed_dim] , )
def _SCREAMING_SNAKE_CASE (self : Dict ) -> Union[str, Any]:
'''simple docstring'''
snake_case , snake_case : List[Any] = self.model_tester.prepare_config_and_inputs_for_common()
snake_case : int = (
self.model_tester.image_size
if isinstance(self.model_tester.image_size , collections.abc.Iterable )
else (self.model_tester.image_size, self.model_tester.image_size)
)
for model_class in self.all_model_classes:
snake_case : int = True
self.check_hidden_states_output(snake_case__ , snake_case__ , snake_case__ , snake_case__ )
# check that output_hidden_states also work using config
del inputs_dict["output_hidden_states"]
snake_case : Dict = True
self.check_hidden_states_output(snake_case__ , snake_case__ , snake_case__ , snake_case__ )
def _SCREAMING_SNAKE_CASE (self : int ) -> Any:
'''simple docstring'''
snake_case , snake_case : Union[str, Any] = self.model_tester.prepare_config_and_inputs_for_common()
snake_case : Any = 3
snake_case : List[str] = (
self.model_tester.image_size
if isinstance(self.model_tester.image_size , collections.abc.Iterable )
else (self.model_tester.image_size, self.model_tester.image_size)
)
snake_case : Tuple = (
config.patch_size
if isinstance(config.patch_size , collections.abc.Iterable )
else (config.patch_size, config.patch_size)
)
snake_case : str = image_size[0] + patch_size[0] - (image_size[0] % patch_size[0])
snake_case : str = image_size[1] + patch_size[1] - (image_size[1] % patch_size[1])
for model_class in self.all_model_classes:
snake_case : str = True
self.check_hidden_states_output(snake_case__ , snake_case__ , snake_case__ , (padded_height, padded_width) )
# check that output_hidden_states also work using config
del inputs_dict["output_hidden_states"]
snake_case : Optional[Any] = True
self.check_hidden_states_output(snake_case__ , snake_case__ , snake_case__ , (padded_height, padded_width) )
@unittest.skip(reason="MaskFormerSwin doesn't have pretrained checkpoints" )
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> str:
'''simple docstring'''
pass
@unittest.skip(reason="This will be fixed once MaskFormerSwin is replaced by native Swin" )
def _SCREAMING_SNAKE_CASE (self : str ) -> int:
'''simple docstring'''
pass
@unittest.skip(reason="This will be fixed once MaskFormerSwin is replaced by native Swin" )
def _SCREAMING_SNAKE_CASE (self : int ) -> str:
'''simple docstring'''
pass
def _SCREAMING_SNAKE_CASE (self : Any ) -> Any:
'''simple docstring'''
snake_case , snake_case : List[Any] = self.model_tester.prepare_config_and_inputs_for_common()
def set_nan_tensor_to_zero(snake_case__ : Union[str, Any] ):
snake_case : Any = 0
return t
def check_equivalence(snake_case__ : Union[str, Any] , snake_case__ : int , snake_case__ : List[str] , snake_case__ : Optional[int]={} ):
with torch.no_grad():
snake_case : Optional[Any] = model(**snake_case__ , return_dict=snake_case__ , **snake_case__ )
snake_case : Tuple = model(**snake_case__ , return_dict=snake_case__ , **snake_case__ ).to_tuple()
def recursive_check(snake_case__ : List[str] , snake_case__ : Optional[Any] ):
if isinstance(snake_case__ , (List, Tuple) ):
for tuple_iterable_value, dict_iterable_value in zip(snake_case__ , snake_case__ ):
recursive_check(snake_case__ , snake_case__ )
elif isinstance(snake_case__ , snake_case__ ):
for tuple_iterable_value, dict_iterable_value in zip(
tuple_object.values() , dict_object.values() ):
recursive_check(snake_case__ , snake_case__ )
elif tuple_object is None:
return
else:
self.assertTrue(
torch.allclose(
set_nan_tensor_to_zero(snake_case__ ) , set_nan_tensor_to_zero(snake_case__ ) , atol=1e-5 ) , msg=(
"Tuple and dict output are not equal. Difference:"
f""" {torch.max(torch.abs(tuple_object - dict_object ) )}. Tuple has `nan`:"""
f""" {torch.isnan(snake_case__ ).any()} and `inf`: {torch.isinf(snake_case__ )}. Dict has"""
f""" `nan`: {torch.isnan(snake_case__ ).any()} and `inf`: {torch.isinf(snake_case__ )}."""
) , )
recursive_check(snake_case__ , snake_case__ )
for model_class in self.all_model_classes:
snake_case : Optional[int] = model_class(snake_case__ )
model.to(snake_case__ )
model.eval()
snake_case : Union[str, Any] = self._prepare_for_class(snake_case__ , snake_case__ )
snake_case : Tuple = self._prepare_for_class(snake_case__ , snake_case__ )
check_equivalence(snake_case__ , snake_case__ , snake_case__ )
snake_case : Tuple = self._prepare_for_class(snake_case__ , snake_case__ , return_labels=snake_case__ )
snake_case : Optional[Any] = self._prepare_for_class(snake_case__ , snake_case__ , return_labels=snake_case__ )
check_equivalence(snake_case__ , snake_case__ , snake_case__ )
snake_case : Dict = self._prepare_for_class(snake_case__ , snake_case__ )
snake_case : List[Any] = self._prepare_for_class(snake_case__ , snake_case__ )
check_equivalence(snake_case__ , snake_case__ , snake_case__ , {"output_hidden_states": True} )
snake_case : Any = self._prepare_for_class(snake_case__ , snake_case__ , return_labels=snake_case__ )
snake_case : List[str] = self._prepare_for_class(snake_case__ , snake_case__ , return_labels=snake_case__ )
check_equivalence(snake_case__ , snake_case__ , snake_case__ , {"output_hidden_states": True} )
@require_torch
class UpperCAmelCase ( unittest.TestCase ,A_ ):
A__ : int = (MaskFormerSwinBackbone,) if is_torch_available() else ()
A__ : int = MaskFormerSwinConfig
def _SCREAMING_SNAKE_CASE (self : List[Any] ) -> Any:
'''simple docstring'''
snake_case : Union[str, Any] = MaskFormerSwinModelTester(self )
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> Optional[Any]:
'''simple docstring'''
snake_case , snake_case : Dict = self.model_tester.prepare_config_and_inputs_for_common()
snake_case : Optional[int] = inputs_dict["pixel_values"].shape[0]
for backbone_class in self.all_model_classes:
snake_case : Optional[int] = backbone_class(snake_case__ )
backbone.to(snake_case__ )
backbone.eval()
snake_case : Union[str, Any] = backbone(**snake_case__ )
# Test default outputs and verify feature maps
self.assertIsInstance(outputs.feature_maps , snake_case__ )
self.assertTrue(len(outputs.feature_maps ) == len(backbone.channels ) )
for feature_map, n_channels in zip(outputs.feature_maps , backbone.channels ):
self.assertTrue(feature_map.shape[:2] , (batch_size, n_channels) )
self.assertIsNone(outputs.hidden_states )
self.assertIsNone(outputs.attentions )
# Test output_hidden_states=True
snake_case : Optional[int] = backbone(**snake_case__ , output_hidden_states=snake_case__ )
self.assertIsNotNone(outputs.hidden_states )
self.assertTrue(len(outputs.hidden_states ) , len(backbone.stage_names ) )
# We skip the stem layer
for hidden_states, n_channels in zip(outputs.hidden_states[1:] , backbone.channels ):
for hidden_state in hidden_states:
# Hidden states are in the format (batch_size, (height * width), n_channels)
snake_case , snake_case , snake_case : Dict = hidden_state.shape
self.assertTrue((h_batch_size, h_n_channels) , (batch_size, n_channels) )
# Test output_attentions=True
if self.has_attentions:
snake_case : Optional[Any] = backbone(**snake_case__ , output_attentions=snake_case__ )
self.assertIsNotNone(outputs.attentions )
| 59
| 1
|
from __future__ import annotations
from sys import maxsize
from typing import Generic, TypeVar
__lowerCamelCase = TypeVar("""T""")
def UpperCamelCase ( __lowerCamelCase : int ):
return (position - 1) // 2
def UpperCamelCase ( __lowerCamelCase : int ):
return (2 * position) + 1
def UpperCamelCase ( __lowerCamelCase : int ):
return (2 * position) + 2
class UpperCAmelCase ( Generic[T] ):
def __init__(self : Optional[Any] ) -> None:
'''simple docstring'''
snake_case : list[tuple[T, int]] = []
snake_case : dict[T, int] = {}
snake_case : int = 0
def __len__(self : int ) -> int:
'''simple docstring'''
return self.elements
def __repr__(self : Tuple ) -> str:
'''simple docstring'''
return str(self.heap )
def _SCREAMING_SNAKE_CASE (self : Tuple ) -> bool:
'''simple docstring'''
return self.elements == 0
def _SCREAMING_SNAKE_CASE (self : Optional[Any] , snake_case__ : T , snake_case__ : int ) -> None:
'''simple docstring'''
self.heap.append((elem, weight) )
snake_case : Dict = self.elements
self.elements += 1
self._bubble_up(snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> T:
'''simple docstring'''
if self.elements > 1:
self._swap_nodes(0 , self.elements - 1 )
snake_case , snake_case : Dict = self.heap.pop()
del self.position_map[elem]
self.elements -= 1
if self.elements > 0:
snake_case , snake_case : List[Any] = self.heap[0]
self._bubble_down(snake_case__ )
return elem
def _SCREAMING_SNAKE_CASE (self : Optional[int] , snake_case__ : T , snake_case__ : int ) -> None:
'''simple docstring'''
snake_case : int = self.position_map[elem]
snake_case : Tuple = (elem, weight)
if position > 0:
snake_case : str = get_parent_position(snake_case__ )
snake_case , snake_case : List[Any] = self.heap[parent_position]
if parent_weight > weight:
self._bubble_up(snake_case__ )
else:
self._bubble_down(snake_case__ )
else:
self._bubble_down(snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Any , snake_case__ : T ) -> None:
'''simple docstring'''
snake_case : Optional[int] = self.position_map[elem]
if curr_pos == 0:
return None
snake_case : List[str] = get_parent_position(snake_case__ )
snake_case , snake_case : str = self.heap[curr_pos]
snake_case , snake_case : Any = self.heap[parent_position]
if parent_weight > weight:
self._swap_nodes(snake_case__ , snake_case__ )
return self._bubble_up(snake_case__ )
return None
def _SCREAMING_SNAKE_CASE (self : List[Any] , snake_case__ : T ) -> None:
'''simple docstring'''
snake_case : Dict = self.position_map[elem]
snake_case , snake_case : Any = self.heap[curr_pos]
snake_case : List[str] = get_child_left_position(snake_case__ )
snake_case : Tuple = get_child_right_position(snake_case__ )
if child_left_position < self.elements and child_right_position < self.elements:
snake_case , snake_case : List[Any] = self.heap[child_left_position]
snake_case , snake_case : Union[str, Any] = self.heap[child_right_position]
if child_right_weight < child_left_weight and child_right_weight < weight:
self._swap_nodes(snake_case__ , snake_case__ )
return self._bubble_down(snake_case__ )
if child_left_position < self.elements:
snake_case , snake_case : List[Any] = self.heap[child_left_position]
if child_left_weight < weight:
self._swap_nodes(snake_case__ , snake_case__ )
return self._bubble_down(snake_case__ )
else:
return None
if child_right_position < self.elements:
snake_case , snake_case : Optional[Any] = self.heap[child_right_position]
if child_right_weight < weight:
self._swap_nodes(snake_case__ , snake_case__ )
return self._bubble_down(snake_case__ )
return None
def _SCREAMING_SNAKE_CASE (self : Optional[int] , snake_case__ : int , snake_case__ : int ) -> None:
'''simple docstring'''
snake_case : int = self.heap[nodea_pos][0]
snake_case : List[str] = self.heap[nodea_pos][0]
snake_case , snake_case : List[str] = (
self.heap[nodea_pos],
self.heap[nodea_pos],
)
snake_case : Dict = nodea_pos
snake_case : Optional[Any] = nodea_pos
class UpperCAmelCase ( Generic[T] ):
def __init__(self : Optional[int] ) -> None:
'''simple docstring'''
snake_case : dict[T, dict[T, int]] = {}
snake_case : int = 0
def __repr__(self : Any ) -> str:
'''simple docstring'''
return str(self.connections )
def __len__(self : Tuple ) -> int:
'''simple docstring'''
return self.nodes
def _SCREAMING_SNAKE_CASE (self : Optional[int] , snake_case__ : T ) -> None:
'''simple docstring'''
if node not in self.connections:
snake_case : Union[str, Any] = {}
self.nodes += 1
def _SCREAMING_SNAKE_CASE (self : str , snake_case__ : T , snake_case__ : T , snake_case__ : int ) -> None:
'''simple docstring'''
self.add_node(snake_case__ )
self.add_node(snake_case__ )
snake_case : List[str] = weight
snake_case : List[Any] = weight
def UpperCamelCase ( __lowerCamelCase : GraphUndirectedWeighted[T] , ):
snake_case : dict[T, int] = {node: maxsize for node in graph.connections}
snake_case : dict[T, T | None] = {node: None for node in graph.connections}
snake_case : MinPriorityQueue[T] = MinPriorityQueue()
for node, weight in dist.items():
priority_queue.push(__lowerCamelCase , __lowerCamelCase )
if priority_queue.is_empty():
return dist, parent
# initialization
snake_case : int = priority_queue.extract_min()
snake_case : str = 0
for neighbour in graph.connections[node]:
if dist[neighbour] > dist[node] + graph.connections[node][neighbour]:
snake_case : Optional[Any] = dist[node] + graph.connections[node][neighbour]
priority_queue.update_key(__lowerCamelCase , dist[neighbour] )
snake_case : int = node
# running prim's algorithm
while not priority_queue.is_empty():
snake_case : Dict = priority_queue.extract_min()
for neighbour in graph.connections[node]:
if dist[neighbour] > dist[node] + graph.connections[node][neighbour]:
snake_case : Dict = dist[node] + graph.connections[node][neighbour]
priority_queue.update_key(__lowerCamelCase , dist[neighbour] )
snake_case : List[Any] = node
return dist, parent
| 59
|
from typing import Dict
import numpy as np
import torch
from . import residue_constants as rc
from .tensor_utils import tensor_tree_map, tree_map
def UpperCamelCase ( __lowerCamelCase : Dict[str, torch.Tensor] ):
snake_case : List[str] = []
snake_case : Optional[int] = []
snake_case : Any = []
for rt in rc.restypes:
snake_case : List[Any] = rc.restype_name_to_atomaa_names[rc.restype_atoa[rt]]
restype_atomaa_to_atomaa_list.append([(rc.atom_order[name] if name else 0) for name in atom_names] )
snake_case : str = {name: i for i, name in enumerate(__lowerCamelCase )}
restype_atomaa_to_atomaa_list.append(
[(atom_name_to_idxaa[name] if name in atom_name_to_idxaa else 0) for name in rc.atom_types] )
restype_atomaa_mask_list.append([(1.0 if name else 0.0) for name in atom_names] )
# Add dummy mapping for restype 'UNK'
restype_atomaa_to_atomaa_list.append([0] * 14 )
restype_atomaa_to_atomaa_list.append([0] * 37 )
restype_atomaa_mask_list.append([0.0] * 14 )
snake_case : Optional[Any] = torch.tensor(
__lowerCamelCase , dtype=torch.intaa , device=protein["aatype"].device , )
snake_case : List[Any] = torch.tensor(
__lowerCamelCase , dtype=torch.intaa , device=protein["aatype"].device , )
snake_case : int = torch.tensor(
__lowerCamelCase , dtype=torch.floataa , device=protein["aatype"].device , )
snake_case : int = protein["aatype"].to(torch.long )
# create the mapping for (residx, atom14) --> atom37, i.e. an array
# with shape (num_res, 14) containing the atom37 indices for this protein
snake_case : List[Any] = restype_atomaa_to_atomaa[protein_aatype]
snake_case : str = restype_atomaa_mask[protein_aatype]
snake_case : str = residx_atomaa_mask
snake_case : Any = residx_atomaa_to_atomaa.long()
# create the gather indices for mapping back
snake_case : List[str] = restype_atomaa_to_atomaa[protein_aatype]
snake_case : List[Any] = residx_atomaa_to_atomaa.long()
# create the corresponding mask
snake_case : Union[str, Any] = torch.zeros([21, 37] , dtype=torch.floataa , device=protein["aatype"].device )
for restype, restype_letter in enumerate(rc.restypes ):
snake_case : Optional[int] = rc.restype_atoa[restype_letter]
snake_case : Any = rc.residue_atoms[restype_name]
for atom_name in atom_names:
snake_case : List[Any] = rc.atom_order[atom_name]
snake_case : Optional[Any] = 1
snake_case : List[Any] = restype_atomaa_mask[protein_aatype]
snake_case : int = residx_atomaa_mask
return protein
def UpperCamelCase ( __lowerCamelCase : Dict[str, torch.Tensor] ):
snake_case : Dict = tree_map(lambda __lowerCamelCase : torch.tensor(__lowerCamelCase , device=batch["aatype"].device ) , __lowerCamelCase , np.ndarray )
snake_case : List[str] = tensor_tree_map(lambda __lowerCamelCase : np.array(__lowerCamelCase ) , make_atomaa_masks(__lowerCamelCase ) )
return out
| 59
| 1
|
import math
from dataclasses import dataclass
from typing import Optional, Tuple, Union
import numpy as np
import torch
from ..configuration_utils import ConfigMixin, register_to_config
from ..utils import BaseOutput, randn_tensor
from .scheduling_utils import SchedulerMixin
@dataclass
# Copied from diffusers.schedulers.scheduling_ddpm.DDPMSchedulerOutput with DDPM->UnCLIP
class UpperCAmelCase ( A_ ):
A__ : torch.FloatTensor
A__ : Optional[torch.FloatTensor] = None
def UpperCamelCase ( __lowerCamelCase : Tuple , __lowerCamelCase : Tuple=0.999 , __lowerCamelCase : Optional[Any]="cosine" , ):
if alpha_transform_type == "cosine":
def alpha_bar_fn(__lowerCamelCase : List[Any] ):
return math.cos((t + 0.008) / 1.008 * math.pi / 2 ) ** 2
elif alpha_transform_type == "exp":
def alpha_bar_fn(__lowerCamelCase : Any ):
return math.exp(t * -12.0 )
else:
raise ValueError(f"""Unsupported alpha_tranform_type: {alpha_transform_type}""" )
snake_case : Optional[Any] = []
for i in range(__lowerCamelCase ):
snake_case : List[str] = i / num_diffusion_timesteps
snake_case : List[Any] = (i + 1) / num_diffusion_timesteps
betas.append(min(1 - alpha_bar_fn(__lowerCamelCase ) / alpha_bar_fn(__lowerCamelCase ) , __lowerCamelCase ) )
return torch.tensor(__lowerCamelCase , dtype=torch.floataa )
class UpperCAmelCase ( A_ ,A_ ):
@register_to_config
def __init__(self : str , snake_case__ : int = 10_00 , snake_case__ : str = "fixed_small_log" , snake_case__ : bool = True , snake_case__ : Optional[float] = 1.0 , snake_case__ : str = "epsilon" , snake_case__ : str = "squaredcos_cap_v2" , ) -> List[str]:
'''simple docstring'''
if beta_schedule != "squaredcos_cap_v2":
raise ValueError("UnCLIPScheduler only supports `beta_schedule`: 'squaredcos_cap_v2'" )
snake_case : Union[str, Any] = betas_for_alpha_bar(snake_case__ )
snake_case : str = 1.0 - self.betas
snake_case : Optional[Any] = torch.cumprod(self.alphas , dim=0 )
snake_case : str = torch.tensor(1.0 )
# standard deviation of the initial noise distribution
snake_case : Optional[Any] = 1.0
# setable values
snake_case : Optional[Any] = None
snake_case : List[str] = torch.from_numpy(np.arange(0 , snake_case__ )[::-1].copy() )
snake_case : str = variance_type
def _SCREAMING_SNAKE_CASE (self : int , snake_case__ : torch.FloatTensor , snake_case__ : Optional[int] = None ) -> torch.FloatTensor:
'''simple docstring'''
return sample
def _SCREAMING_SNAKE_CASE (self : Optional[int] , snake_case__ : int , snake_case__ : Union[str, torch.device] = None ) -> int:
'''simple docstring'''
snake_case : int = num_inference_steps
snake_case : Tuple = (self.config.num_train_timesteps - 1) / (self.num_inference_steps - 1)
snake_case : Union[str, Any] = (np.arange(0 , snake_case__ ) * step_ratio).round()[::-1].copy().astype(np.intaa )
snake_case : List[str] = torch.from_numpy(snake_case__ ).to(snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Optional[int] , snake_case__ : Dict , snake_case__ : Union[str, Any]=None , snake_case__ : Optional[Any]=None , snake_case__ : Tuple=None ) -> Union[str, Any]:
'''simple docstring'''
if prev_timestep is None:
snake_case : Optional[int] = t - 1
snake_case : Union[str, Any] = self.alphas_cumprod[t]
snake_case : int = self.alphas_cumprod[prev_timestep] if prev_timestep >= 0 else self.one
snake_case : Union[str, Any] = 1 - alpha_prod_t
snake_case : int = 1 - alpha_prod_t_prev
if prev_timestep == t - 1:
snake_case : List[str] = self.betas[t]
else:
snake_case : Any = 1 - alpha_prod_t / alpha_prod_t_prev
# For t > 0, compute predicted variance βt (see formula (6) and (7) from https://arxiv.org/pdf/2006.11239.pdf)
# and sample from it to get previous sample
# x_{t-1} ~ N(pred_prev_sample, variance) == add variance to pred_sample
snake_case : str = beta_prod_t_prev / beta_prod_t * beta
if variance_type is None:
snake_case : int = self.config.variance_type
# hacks - were probably added for training stability
if variance_type == "fixed_small_log":
snake_case : Union[str, Any] = torch.log(torch.clamp(snake_case__ , min=1e-20 ) )
snake_case : Any = torch.exp(0.5 * variance )
elif variance_type == "learned_range":
# NOTE difference with DDPM scheduler
snake_case : Union[str, Any] = variance.log()
snake_case : Union[str, Any] = beta.log()
snake_case : Optional[Any] = (predicted_variance + 1) / 2
snake_case : Dict = frac * max_log + (1 - frac) * min_log
return variance
def _SCREAMING_SNAKE_CASE (self : List[str] , snake_case__ : torch.FloatTensor , snake_case__ : int , snake_case__ : torch.FloatTensor , snake_case__ : Optional[int] = None , snake_case__ : int=None , snake_case__ : bool = True , ) -> Union[UnCLIPSchedulerOutput, Tuple]:
'''simple docstring'''
snake_case : Tuple = timestep
if model_output.shape[1] == sample.shape[1] * 2 and self.variance_type == "learned_range":
snake_case , snake_case : int = torch.split(snake_case__ , sample.shape[1] , dim=1 )
else:
snake_case : List[Any] = None
# 1. compute alphas, betas
if prev_timestep is None:
snake_case : Any = t - 1
snake_case : int = self.alphas_cumprod[t]
snake_case : Tuple = self.alphas_cumprod[prev_timestep] if prev_timestep >= 0 else self.one
snake_case : str = 1 - alpha_prod_t
snake_case : Tuple = 1 - alpha_prod_t_prev
if prev_timestep == t - 1:
snake_case : int = self.betas[t]
snake_case : Union[str, Any] = self.alphas[t]
else:
snake_case : str = 1 - alpha_prod_t / alpha_prod_t_prev
snake_case : List[str] = 1 - beta
# 2. compute predicted original sample from predicted noise also called
# "predicted x_0" of formula (15) from https://arxiv.org/pdf/2006.11239.pdf
if self.config.prediction_type == "epsilon":
snake_case : Optional[int] = (sample - beta_prod_t ** 0.5 * model_output) / alpha_prod_t ** 0.5
elif self.config.prediction_type == "sample":
snake_case : Any = model_output
else:
raise ValueError(
f"""prediction_type given as {self.config.prediction_type} must be one of `epsilon` or `sample`"""
" for the UnCLIPScheduler." )
# 3. Clip "predicted x_0"
if self.config.clip_sample:
snake_case : List[Any] = torch.clamp(
snake_case__ , -self.config.clip_sample_range , self.config.clip_sample_range )
# 4. Compute coefficients for pred_original_sample x_0 and current sample x_t
# See formula (7) from https://arxiv.org/pdf/2006.11239.pdf
snake_case : Union[str, Any] = (alpha_prod_t_prev ** 0.5 * beta) / beta_prod_t
snake_case : str = alpha ** 0.5 * beta_prod_t_prev / beta_prod_t
# 5. Compute predicted previous sample µ_t
# See formula (7) from https://arxiv.org/pdf/2006.11239.pdf
snake_case : int = pred_original_sample_coeff * pred_original_sample + current_sample_coeff * sample
# 6. Add noise
snake_case : Tuple = 0
if t > 0:
snake_case : Optional[int] = randn_tensor(
model_output.shape , dtype=model_output.dtype , generator=snake_case__ , device=model_output.device )
snake_case : str = self._get_variance(
snake_case__ , predicted_variance=snake_case__ , prev_timestep=snake_case__ , )
if self.variance_type == "fixed_small_log":
snake_case : Optional[Any] = variance
elif self.variance_type == "learned_range":
snake_case : Optional[Any] = (0.5 * variance).exp()
else:
raise ValueError(
f"""variance_type given as {self.variance_type} must be one of `fixed_small_log` or `learned_range`"""
" for the UnCLIPScheduler." )
snake_case : Any = variance * variance_noise
snake_case : Tuple = pred_prev_sample + variance
if not return_dict:
return (pred_prev_sample,)
return UnCLIPSchedulerOutput(prev_sample=snake_case__ , pred_original_sample=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Dict , snake_case__ : torch.FloatTensor , snake_case__ : torch.FloatTensor , snake_case__ : torch.IntTensor , ) -> torch.FloatTensor:
'''simple docstring'''
snake_case : Optional[Any] = self.alphas_cumprod.to(device=original_samples.device , dtype=original_samples.dtype )
snake_case : List[Any] = timesteps.to(original_samples.device )
snake_case : Optional[int] = alphas_cumprod[timesteps] ** 0.5
snake_case : List[Any] = sqrt_alpha_prod.flatten()
while len(sqrt_alpha_prod.shape ) < len(original_samples.shape ):
snake_case : Tuple = sqrt_alpha_prod.unsqueeze(-1 )
snake_case : List[Any] = (1 - alphas_cumprod[timesteps]) ** 0.5
snake_case : str = sqrt_one_minus_alpha_prod.flatten()
while len(sqrt_one_minus_alpha_prod.shape ) < len(original_samples.shape ):
snake_case : Optional[Any] = sqrt_one_minus_alpha_prod.unsqueeze(-1 )
snake_case : List[Any] = sqrt_alpha_prod * original_samples + sqrt_one_minus_alpha_prod * noise
return noisy_samples
| 59
|
import json
from typing import List, Optional, Tuple
from tokenizers import normalizers
from ...tokenization_utils_fast import PreTrainedTokenizerFast
from .tokenization_lxmert import LxmertTokenizer
__lowerCamelCase = {"""vocab_file""": """vocab.txt""", """tokenizer_file""": """tokenizer.json"""}
__lowerCamelCase = {
"""vocab_file""": {
"""unc-nlp/lxmert-base-uncased""": """https://huggingface.co/unc-nlp/lxmert-base-uncased/resolve/main/vocab.txt""",
},
"""tokenizer_file""": {
"""unc-nlp/lxmert-base-uncased""": (
"""https://huggingface.co/unc-nlp/lxmert-base-uncased/resolve/main/tokenizer.json"""
),
},
}
__lowerCamelCase = {
"""unc-nlp/lxmert-base-uncased""": 5_12,
}
__lowerCamelCase = {
"""unc-nlp/lxmert-base-uncased""": {"""do_lower_case""": True},
}
class UpperCAmelCase ( A_ ):
A__ : Any = VOCAB_FILES_NAMES
A__ : Optional[int] = PRETRAINED_VOCAB_FILES_MAP
A__ : Tuple = PRETRAINED_INIT_CONFIGURATION
A__ : Tuple = PRETRAINED_POSITIONAL_EMBEDDINGS_SIZES
A__ : List[Any] = LxmertTokenizer
def __init__(self : Dict , snake_case__ : Tuple=None , snake_case__ : Optional[Any]=None , snake_case__ : Optional[Any]=True , snake_case__ : Tuple="[UNK]" , snake_case__ : Optional[Any]="[SEP]" , snake_case__ : Optional[Any]="[PAD]" , snake_case__ : List[Any]="[CLS]" , snake_case__ : Tuple="[MASK]" , snake_case__ : Dict=True , snake_case__ : Union[str, Any]=None , **snake_case__ : Dict , ) -> Optional[int]:
'''simple docstring'''
super().__init__(
snake_case__ , tokenizer_file=snake_case__ , do_lower_case=snake_case__ , unk_token=snake_case__ , sep_token=snake_case__ , pad_token=snake_case__ , cls_token=snake_case__ , mask_token=snake_case__ , tokenize_chinese_chars=snake_case__ , strip_accents=snake_case__ , **snake_case__ , )
snake_case : int = json.loads(self.backend_tokenizer.normalizer.__getstate__() )
if (
normalizer_state.get("lowercase" , snake_case__ ) != do_lower_case
or normalizer_state.get("strip_accents" , snake_case__ ) != strip_accents
or normalizer_state.get("handle_chinese_chars" , snake_case__ ) != tokenize_chinese_chars
):
snake_case : Union[str, Any] = getattr(snake_case__ , normalizer_state.pop("type" ) )
snake_case : str = do_lower_case
snake_case : List[Any] = strip_accents
snake_case : Optional[int] = tokenize_chinese_chars
snake_case : int = normalizer_class(**snake_case__ )
snake_case : Optional[Any] = do_lower_case
def _SCREAMING_SNAKE_CASE (self : Union[str, Any] , snake_case__ : Optional[Any] , snake_case__ : Dict=None ) -> Any:
'''simple docstring'''
snake_case : Optional[int] = [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 _SCREAMING_SNAKE_CASE (self : Optional[int] , snake_case__ : List[int] , snake_case__ : Optional[List[int]] = None ) -> List[int]:
'''simple docstring'''
snake_case : Optional[Any] = [self.sep_token_id]
snake_case : Optional[Any] = [self.cls_token_id]
if token_ids_a is None:
return len(cls + token_ids_a + sep ) * [0]
return len(cls + token_ids_a + sep ) * [0] + len(token_ids_a + sep ) * [1]
def _SCREAMING_SNAKE_CASE (self : Any , snake_case__ : str , snake_case__ : Optional[str] = None ) -> Tuple[str]:
'''simple docstring'''
snake_case : List[Any] = self._tokenizer.model.save(snake_case__ , name=snake_case__ )
return tuple(snake_case__ )
| 59
| 1
|
from typing import TYPE_CHECKING
from ...utils import (
OptionalDependencyNotAvailable,
_LazyModule,
is_tokenizers_available,
is_torch_available,
is_vision_available,
)
__lowerCamelCase = {
"""configuration_perceiver""": ["""PERCEIVER_PRETRAINED_CONFIG_ARCHIVE_MAP""", """PerceiverConfig""", """PerceiverOnnxConfig"""],
"""tokenization_perceiver""": ["""PerceiverTokenizer"""],
}
try:
if not is_vision_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = ["""PerceiverFeatureExtractor"""]
__lowerCamelCase = ["""PerceiverImageProcessor"""]
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = [
"""PERCEIVER_PRETRAINED_MODEL_ARCHIVE_LIST""",
"""PerceiverForImageClassificationConvProcessing""",
"""PerceiverForImageClassificationFourier""",
"""PerceiverForImageClassificationLearned""",
"""PerceiverForMaskedLM""",
"""PerceiverForMultimodalAutoencoding""",
"""PerceiverForOpticalFlow""",
"""PerceiverForSequenceClassification""",
"""PerceiverLayer""",
"""PerceiverModel""",
"""PerceiverPreTrainedModel""",
]
if TYPE_CHECKING:
from .configuration_perceiver import PERCEIVER_PRETRAINED_CONFIG_ARCHIVE_MAP, PerceiverConfig, PerceiverOnnxConfig
from .tokenization_perceiver import PerceiverTokenizer
try:
if not is_vision_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .feature_extraction_perceiver import PerceiverFeatureExtractor
from .image_processing_perceiver import PerceiverImageProcessor
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_perceiver import (
PERCEIVER_PRETRAINED_MODEL_ARCHIVE_LIST,
PerceiverForImageClassificationConvProcessing,
PerceiverForImageClassificationFourier,
PerceiverForImageClassificationLearned,
PerceiverForMaskedLM,
PerceiverForMultimodalAutoencoding,
PerceiverForOpticalFlow,
PerceiverForSequenceClassification,
PerceiverLayer,
PerceiverModel,
PerceiverPreTrainedModel,
)
else:
import sys
__lowerCamelCase = _LazyModule(__name__, globals()["""__file__"""], _import_structure, module_spec=__spec__)
| 59
|
import torch
from diffusers import DDIMParallelScheduler
from .test_schedulers import SchedulerCommonTest
class UpperCAmelCase ( A_ ):
A__ : Dict = (DDIMParallelScheduler,)
A__ : Tuple = (("eta", 0.0), ("num_inference_steps", 50))
def _SCREAMING_SNAKE_CASE (self : Tuple , **snake_case__ : Optional[int] ) -> Optional[Any]:
'''simple docstring'''
snake_case : Any = {
"num_train_timesteps": 10_00,
"beta_start": 0.0001,
"beta_end": 0.02,
"beta_schedule": "linear",
"clip_sample": True,
}
config.update(**snake_case__ )
return config
def _SCREAMING_SNAKE_CASE (self : Dict , **snake_case__ : Optional[int] ) -> Any:
'''simple docstring'''
snake_case : List[Any] = self.scheduler_classes[0]
snake_case : Any = self.get_scheduler_config(**snake_case__ )
snake_case : Any = scheduler_class(**snake_case__ )
snake_case , snake_case : Union[str, Any] = 10, 0.0
snake_case : List[Any] = self.dummy_model()
snake_case : Any = self.dummy_sample_deter
scheduler.set_timesteps(snake_case__ )
for t in scheduler.timesteps:
snake_case : Optional[int] = model(snake_case__ , snake_case__ )
snake_case : List[str] = scheduler.step(snake_case__ , snake_case__ , snake_case__ , snake_case__ ).prev_sample
return sample
def _SCREAMING_SNAKE_CASE (self : Union[str, Any] ) -> str:
'''simple docstring'''
for timesteps in [1_00, 5_00, 10_00]:
self.check_over_configs(num_train_timesteps=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : str ) -> int:
'''simple docstring'''
for steps_offset in [0, 1]:
self.check_over_configs(steps_offset=snake_case__ )
snake_case : Optional[int] = self.scheduler_classes[0]
snake_case : Optional[int] = self.get_scheduler_config(steps_offset=1 )
snake_case : Union[str, Any] = scheduler_class(**snake_case__ )
scheduler.set_timesteps(5 )
assert torch.equal(scheduler.timesteps , torch.LongTensor([8_01, 6_01, 4_01, 2_01, 1] ) )
def _SCREAMING_SNAKE_CASE (self : int ) -> Tuple:
'''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=snake_case__ , beta_end=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Union[str, Any] ) -> Union[str, Any]:
'''simple docstring'''
for schedule in ["linear", "squaredcos_cap_v2"]:
self.check_over_configs(beta_schedule=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : str ) -> Dict:
'''simple docstring'''
for prediction_type in ["epsilon", "v_prediction"]:
self.check_over_configs(prediction_type=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Optional[Any] ) -> List[str]:
'''simple docstring'''
for clip_sample in [True, False]:
self.check_over_configs(clip_sample=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : List[Any] ) -> List[Any]:
'''simple docstring'''
for timestep_spacing in ["trailing", "leading"]:
self.check_over_configs(timestep_spacing=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> List[Any]:
'''simple docstring'''
for rescale_betas_zero_snr in [True, False]:
self.check_over_configs(rescale_betas_zero_snr=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Optional[Any] ) -> Optional[Any]:
'''simple docstring'''
self.check_over_configs(thresholding=snake_case__ )
for threshold in [0.5, 1.0, 2.0]:
for prediction_type in ["epsilon", "v_prediction"]:
self.check_over_configs(
thresholding=snake_case__ , prediction_type=snake_case__ , sample_max_value=snake_case__ , )
def _SCREAMING_SNAKE_CASE (self : Any ) -> Any:
'''simple docstring'''
for t in [1, 10, 49]:
self.check_over_forward(time_step=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> Any:
'''simple docstring'''
for t, num_inference_steps in zip([1, 10, 50] , [10, 50, 5_00] ):
self.check_over_forward(time_step=snake_case__ , num_inference_steps=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : List[str] ) -> Optional[Any]:
'''simple docstring'''
for t, eta in zip([1, 10, 49] , [0.0, 0.5, 1.0] ):
self.check_over_forward(time_step=snake_case__ , eta=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Optional[Any] ) -> Optional[int]:
'''simple docstring'''
snake_case : Dict = self.scheduler_classes[0]
snake_case : Tuple = self.get_scheduler_config()
snake_case : Dict = scheduler_class(**snake_case__ )
assert torch.sum(torch.abs(scheduler._get_variance(0 , 0 ) - 0.0 ) ) < 1e-5
assert torch.sum(torch.abs(scheduler._get_variance(4_20 , 4_00 ) - 0.14771 ) ) < 1e-5
assert torch.sum(torch.abs(scheduler._get_variance(9_80 , 9_60 ) - 0.32460 ) ) < 1e-5
assert torch.sum(torch.abs(scheduler._get_variance(0 , 0 ) - 0.0 ) ) < 1e-5
assert torch.sum(torch.abs(scheduler._get_variance(4_87 , 4_86 ) - 0.00979 ) ) < 1e-5
assert torch.sum(torch.abs(scheduler._get_variance(9_99 , 9_98 ) - 0.02 ) ) < 1e-5
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> Dict:
'''simple docstring'''
snake_case : Union[str, Any] = self.scheduler_classes[0]
snake_case : List[Any] = self.get_scheduler_config()
snake_case : int = scheduler_class(**snake_case__ )
snake_case , snake_case : Any = 10, 0.0
scheduler.set_timesteps(snake_case__ )
snake_case : Optional[Any] = self.dummy_model()
snake_case : str = self.dummy_sample_deter
snake_case : Dict = self.dummy_sample_deter + 0.1
snake_case : Dict = self.dummy_sample_deter - 0.1
snake_case : Optional[Any] = samplea.shape[0]
snake_case : str = torch.stack([samplea, samplea, samplea] , dim=0 )
snake_case : Tuple = torch.arange(snake_case__ )[0:3, None].repeat(1 , snake_case__ )
snake_case : Tuple = model(samples.flatten(0 , 1 ) , timesteps.flatten(0 , 1 ) )
snake_case : List[str] = scheduler.batch_step_no_noise(snake_case__ , timesteps.flatten(0 , 1 ) , samples.flatten(0 , 1 ) , snake_case__ )
snake_case : Dict = torch.sum(torch.abs(snake_case__ ) )
snake_case : List[Any] = torch.mean(torch.abs(snake_case__ ) )
assert abs(result_sum.item() - 1147.7904 ) < 1e-2
assert abs(result_mean.item() - 0.4982 ) < 1e-3
def _SCREAMING_SNAKE_CASE (self : Optional[Any] ) -> Optional[Any]:
'''simple docstring'''
snake_case : List[Any] = self.full_loop()
snake_case : Optional[Any] = torch.sum(torch.abs(snake_case__ ) )
snake_case : List[Any] = torch.mean(torch.abs(snake_case__ ) )
assert abs(result_sum.item() - 172.0067 ) < 1e-2
assert abs(result_mean.item() - 0.223967 ) < 1e-3
def _SCREAMING_SNAKE_CASE (self : str ) -> Union[str, Any]:
'''simple docstring'''
snake_case : Dict = self.full_loop(prediction_type="v_prediction" )
snake_case : int = torch.sum(torch.abs(snake_case__ ) )
snake_case : Optional[int] = torch.mean(torch.abs(snake_case__ ) )
assert abs(result_sum.item() - 52.5302 ) < 1e-2
assert abs(result_mean.item() - 0.0684 ) < 1e-3
def _SCREAMING_SNAKE_CASE (self : Any ) -> Optional[Any]:
'''simple docstring'''
snake_case : Dict = self.full_loop(set_alpha_to_one=snake_case__ , beta_start=0.01 )
snake_case : str = torch.sum(torch.abs(snake_case__ ) )
snake_case : Optional[Any] = torch.mean(torch.abs(snake_case__ ) )
assert abs(result_sum.item() - 149.8295 ) < 1e-2
assert abs(result_mean.item() - 0.1951 ) < 1e-3
def _SCREAMING_SNAKE_CASE (self : int ) -> Optional[Any]:
'''simple docstring'''
snake_case : int = self.full_loop(set_alpha_to_one=snake_case__ , beta_start=0.01 )
snake_case : Tuple = torch.sum(torch.abs(snake_case__ ) )
snake_case : List[Any] = torch.mean(torch.abs(snake_case__ ) )
assert abs(result_sum.item() - 149.0784 ) < 1e-2
assert abs(result_mean.item() - 0.1941 ) < 1e-3
| 59
| 1
|
import inspect
import os
import torch
from transformers import AutoModel
from transformers.testing_utils import mockenv_context
from transformers.trainer_utils import set_seed
import accelerate
from accelerate.accelerator import Accelerator
from accelerate.state import AcceleratorState
from accelerate.test_utils.testing import (
AccelerateTestCase,
TempDirTestCase,
execute_subprocess_async,
require_cuda,
require_fsdp,
require_multi_gpu,
slow,
)
from accelerate.utils.constants import (
FSDP_AUTO_WRAP_POLICY,
FSDP_BACKWARD_PREFETCH,
FSDP_SHARDING_STRATEGY,
FSDP_STATE_DICT_TYPE,
)
from accelerate.utils.dataclasses import FullyShardedDataParallelPlugin
from accelerate.utils.other import patch_environment
set_seed(42)
__lowerCamelCase = """bert-base-cased"""
__lowerCamelCase = """fp16"""
__lowerCamelCase = """bf16"""
__lowerCamelCase = [FPaa, BFaa]
@require_fsdp
@require_cuda
class UpperCAmelCase ( A_ ):
def _SCREAMING_SNAKE_CASE (self : Tuple ) -> int:
'''simple docstring'''
super().setUp()
snake_case : Optional[Any] = dict(
ACCELERATE_USE_FSDP="true" , MASTER_ADDR="localhost" , MASTER_PORT="10999" , RANK="0" , LOCAL_RANK="0" , WORLD_SIZE="1" , )
def _SCREAMING_SNAKE_CASE (self : int ) -> Optional[int]:
'''simple docstring'''
from torch.distributed.fsdp.fully_sharded_data_parallel import ShardingStrategy
for i, strategy in enumerate(snake_case__ ):
snake_case : Union[str, Any] = self.dist_env.copy()
snake_case : List[Any] = f"""{i + 1}"""
snake_case : str = strategy
with mockenv_context(**snake_case__ ):
snake_case : int = FullyShardedDataParallelPlugin()
self.assertEqual(fsdp_plugin.sharding_strategy , ShardingStrategy(i + 1 ) )
def _SCREAMING_SNAKE_CASE (self : Union[str, Any] ) -> Any:
'''simple docstring'''
from torch.distributed.fsdp.fully_sharded_data_parallel import BackwardPrefetch
for i, prefetch_policy in enumerate(snake_case__ ):
snake_case : Optional[int] = self.dist_env.copy()
snake_case : str = prefetch_policy
with mockenv_context(**snake_case__ ):
snake_case : Optional[Any] = FullyShardedDataParallelPlugin()
if prefetch_policy == "NO_PREFETCH":
self.assertIsNone(fsdp_plugin.backward_prefetch )
else:
self.assertEqual(fsdp_plugin.backward_prefetch , BackwardPrefetch(i + 1 ) )
def _SCREAMING_SNAKE_CASE (self : List[str] ) -> Tuple:
'''simple docstring'''
from torch.distributed.fsdp.fully_sharded_data_parallel import StateDictType
for i, state_dict_type in enumerate(snake_case__ ):
snake_case : int = self.dist_env.copy()
snake_case : Any = state_dict_type
with mockenv_context(**snake_case__ ):
snake_case : Union[str, Any] = FullyShardedDataParallelPlugin()
self.assertEqual(fsdp_plugin.state_dict_type , StateDictType(i + 1 ) )
if state_dict_type == "FULL_STATE_DICT":
self.assertTrue(fsdp_plugin.state_dict_config.offload_to_cpu )
self.assertTrue(fsdp_plugin.state_dict_config.ranka_only )
def _SCREAMING_SNAKE_CASE (self : str ) -> List[str]:
'''simple docstring'''
snake_case : Tuple = AutoModel.from_pretrained(snake_case__ )
for policy in FSDP_AUTO_WRAP_POLICY:
snake_case : Optional[int] = self.dist_env.copy()
snake_case : List[str] = policy
if policy == "TRANSFORMER_BASED_WRAP":
snake_case : Union[str, Any] = "BertLayer"
elif policy == "SIZE_BASED_WRAP":
snake_case : Union[str, Any] = "2000"
with mockenv_context(**snake_case__ ):
snake_case : int = FullyShardedDataParallelPlugin()
fsdp_plugin.set_auto_wrap_policy(snake_case__ )
if policy == "NO_WRAP":
self.assertIsNone(fsdp_plugin.auto_wrap_policy )
else:
self.assertIsNotNone(fsdp_plugin.auto_wrap_policy )
snake_case : List[Any] = self.dist_env.copy()
snake_case : int = "TRANSFORMER_BASED_WRAP"
snake_case : Dict = "T5Layer"
with mockenv_context(**snake_case__ ):
snake_case : str = FullyShardedDataParallelPlugin()
with self.assertRaises(snake_case__ ) as cm:
fsdp_plugin.set_auto_wrap_policy(snake_case__ )
self.assertTrue("Could not find the transformer layer class to wrap in the model." in str(cm.exception ) )
snake_case : Any = self.dist_env.copy()
snake_case : Tuple = "SIZE_BASED_WRAP"
snake_case : Optional[int] = "0"
with mockenv_context(**snake_case__ ):
snake_case : Tuple = FullyShardedDataParallelPlugin()
fsdp_plugin.set_auto_wrap_policy(snake_case__ )
self.assertIsNone(fsdp_plugin.auto_wrap_policy )
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> Optional[Any]:
'''simple docstring'''
from torch.distributed.fsdp.fully_sharded_data_parallel import MixedPrecision
from torch.distributed.fsdp.sharded_grad_scaler import ShardedGradScaler
for mp_dtype in dtypes:
snake_case : List[str] = self.dist_env.copy()
snake_case : Optional[Any] = mp_dtype
with mockenv_context(**snake_case__ ):
snake_case : int = Accelerator()
if mp_dtype == "fp16":
snake_case : int = torch.floataa
elif mp_dtype == "bf16":
snake_case : Tuple = torch.bfloataa
snake_case : Dict = MixedPrecision(param_dtype=snake_case__ , reduce_dtype=snake_case__ , buffer_dtype=snake_case__ )
self.assertEqual(accelerator.state.fsdp_plugin.mixed_precision_policy , snake_case__ )
if mp_dtype == FPaa:
self.assertTrue(isinstance(accelerator.scaler , snake_case__ ) )
elif mp_dtype == BFaa:
self.assertIsNone(accelerator.scaler )
AcceleratorState._reset_state(snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Any ) -> int:
'''simple docstring'''
from torch.distributed.fsdp.fully_sharded_data_parallel import CPUOffload
for flag in [True, False]:
snake_case : Optional[int] = self.dist_env.copy()
snake_case : Optional[int] = str(snake_case__ ).lower()
with mockenv_context(**snake_case__ ):
snake_case : int = FullyShardedDataParallelPlugin()
self.assertEqual(fsdp_plugin.cpu_offload , CPUOffload(offload_params=snake_case__ ) )
@require_fsdp
@require_multi_gpu
@slow
class UpperCAmelCase ( A_ ):
def _SCREAMING_SNAKE_CASE (self : Union[str, Any] ) -> int:
'''simple docstring'''
super().setUp()
snake_case : int = 0.82
snake_case : Optional[int] = [
"fsdp_shard_grad_op_transformer_based_wrap",
"fsdp_full_shard_transformer_based_wrap",
]
snake_case : List[str] = {
"multi_gpu_fp16": 32_00,
"fsdp_shard_grad_op_transformer_based_wrap_fp16": 20_00,
"fsdp_full_shard_transformer_based_wrap_fp16": 19_00,
# Disabling below test as it overwhelms the RAM memory usage
# on CI self-hosted runner leading to tests getting killed.
# "fsdp_full_shard_cpu_offload_transformer_based_wrap_fp32": 1500, # fp16 was leading to indefinite hang
}
snake_case : Tuple = 1_60
snake_case : List[str] = 1_60
snake_case : List[Any] = inspect.getfile(accelerate.test_utils )
snake_case : int = os.path.sep.join(mod_file.split(os.path.sep )[:-1] + ["scripts", "external_deps"] )
def _SCREAMING_SNAKE_CASE (self : int ) -> Union[str, Any]:
'''simple docstring'''
snake_case : Tuple = os.path.join(self.test_scripts_folder , "test_performance.py" )
snake_case : Optional[Any] = ["accelerate", "launch", "--num_processes=2", "--num_machines=1", "--machine_rank=0", "--use_fsdp"]
for config in self.performance_configs:
snake_case : Optional[int] = cmd.copy()
for i, strategy in enumerate(snake_case__ ):
if strategy.lower() in config:
cmd_config.append(f"""--fsdp_sharding_strategy={i+1}""" )
break
if "fp32" in config:
cmd_config.append("--mixed_precision=no" )
else:
cmd_config.append("--mixed_precision=fp16" )
if "cpu_offload" in config:
cmd_config.append("--fsdp_offload_params=True" )
for policy in FSDP_AUTO_WRAP_POLICY:
if policy.lower() in config:
cmd_config.append(f"""--fsdp_auto_wrap_policy={policy}""" )
break
if policy == "TRANSFORMER_BASED_WRAP":
cmd_config.append("--fsdp_transformer_layer_cls_to_wrap=BertLayer" )
elif policy == "SIZE_BASED_WRAP":
cmd_config.append("--fsdp_min_num_params=2000" )
cmd_config.extend(
[
self.test_file_path,
f"""--output_dir={self.tmpdir}""",
f"""--performance_lower_bound={self.performance_lower_bound}""",
] )
with patch_environment(omp_num_threads=1 ):
execute_subprocess_async(snake_case__ , env=os.environ.copy() )
def _SCREAMING_SNAKE_CASE (self : str ) -> Optional[Any]:
'''simple docstring'''
snake_case : Union[str, Any] = os.path.join(self.test_scripts_folder , "test_checkpointing.py" )
snake_case : str = [
"accelerate",
"launch",
"--num_processes=2",
"--num_machines=1",
"--machine_rank=0",
"--use_fsdp",
"--mixed_precision=fp16",
"--fsdp_transformer_layer_cls_to_wrap=BertLayer",
]
for i, strategy in enumerate(snake_case__ ):
snake_case : List[str] = cmd.copy()
cmd_config.append(f"""--fsdp_sharding_strategy={i+1}""" )
if strategy != "FULL_SHARD":
continue
snake_case : List[Any] = len(snake_case__ )
for state_dict_type in FSDP_STATE_DICT_TYPE:
snake_case : Optional[int] = cmd_config[:state_dict_config_index]
cmd_config.append(f"""--fsdp_state_dict_type={state_dict_type}""" )
cmd_config.extend(
[
self.test_file_path,
f"""--output_dir={self.tmpdir}""",
"--partial_train_epoch=1",
] )
with patch_environment(omp_num_threads=1 ):
execute_subprocess_async(snake_case__ , env=os.environ.copy() )
snake_case : Optional[Any] = cmd_config[:-1]
snake_case : Optional[Any] = os.path.join(self.tmpdir , "epoch_0" )
cmd_config.extend(
[
f"""--resume_from_checkpoint={resume_from_checkpoint}""",
] )
with patch_environment(omp_num_threads=1 ):
execute_subprocess_async(snake_case__ , env=os.environ.copy() )
def _SCREAMING_SNAKE_CASE (self : Optional[Any] ) -> str:
'''simple docstring'''
snake_case : Optional[int] = os.path.join(self.test_scripts_folder , "test_peak_memory_usage.py" )
snake_case : Optional[Any] = [
"accelerate",
"launch",
"--num_processes=2",
"--num_machines=1",
"--machine_rank=0",
]
for spec, peak_mem_upper_bound in self.peak_memory_usage_upper_bound.items():
snake_case : Optional[int] = cmd.copy()
if "fp16" in spec:
cmd_config.extend(["--mixed_precision=fp16"] )
else:
cmd_config.extend(["--mixed_precision=no"] )
if "multi_gpu" in spec:
continue
else:
cmd_config.extend(["--use_fsdp"] )
for i, strategy in enumerate(snake_case__ ):
if strategy.lower() in spec:
cmd_config.append(f"""--fsdp_sharding_strategy={i+1}""" )
break
if "cpu_offload" in spec:
cmd_config.append("--fsdp_offload_params=True" )
for policy in FSDP_AUTO_WRAP_POLICY:
if policy.lower() in spec:
cmd_config.append(f"""--fsdp_auto_wrap_policy={policy}""" )
break
if policy == "TRANSFORMER_BASED_WRAP":
cmd_config.append("--fsdp_transformer_layer_cls_to_wrap=BertLayer" )
elif policy == "SIZE_BASED_WRAP":
cmd_config.append("--fsdp_min_num_params=2000" )
cmd_config.extend(
[
self.test_file_path,
f"""--output_dir={self.tmpdir}""",
f"""--peak_memory_upper_bound={peak_mem_upper_bound}""",
f"""--n_train={self.n_train}""",
f"""--n_val={self.n_val}""",
] )
with patch_environment(omp_num_threads=1 ):
execute_subprocess_async(snake_case__ , env=os.environ.copy() )
| 59
|
def UpperCamelCase ( __lowerCamelCase : str , __lowerCamelCase : int ):
snake_case : list[list[str]] = [[] for _ in range(__lowerCamelCase )]
snake_case : int = key - 1
if key <= 0:
raise ValueError("Height of grid can't be 0 or negative" )
if key == 1 or len(__lowerCamelCase ) <= key:
return input_string
for position, character in enumerate(__lowerCamelCase ):
snake_case : Any = position % (lowest * 2) # puts it in bounds
snake_case : Optional[int] = min(__lowerCamelCase , lowest * 2 - num ) # creates zigzag pattern
temp_grid[num].append(__lowerCamelCase )
snake_case : List[str] = ["".join(__lowerCamelCase ) for row in temp_grid]
snake_case : Tuple = "".join(__lowerCamelCase )
return output_string
def UpperCamelCase ( __lowerCamelCase : str , __lowerCamelCase : int ):
snake_case : Dict = []
snake_case : Union[str, Any] = key - 1
if key <= 0:
raise ValueError("Height of grid can't be 0 or negative" )
if key == 1:
return input_string
snake_case : list[list[str]] = [[] for _ in range(__lowerCamelCase )] # generates template
for position in range(len(__lowerCamelCase ) ):
snake_case : List[str] = position % (lowest * 2) # puts it in bounds
snake_case : Optional[int] = min(__lowerCamelCase , lowest * 2 - num ) # creates zigzag pattern
temp_grid[num].append("*" )
snake_case : Tuple = 0
for row in temp_grid: # fills in the characters
snake_case : Union[str, Any] = input_string[counter : counter + len(__lowerCamelCase )]
grid.append(list(__lowerCamelCase ) )
counter += len(__lowerCamelCase )
snake_case : str = "" # reads as zigzag
for position in range(len(__lowerCamelCase ) ):
snake_case : Optional[int] = position % (lowest * 2) # puts it in bounds
snake_case : Tuple = min(__lowerCamelCase , lowest * 2 - num ) # creates zigzag pattern
output_string += grid[num][0]
grid[num].pop(0 )
return output_string
def UpperCamelCase ( __lowerCamelCase : str ):
snake_case : Tuple = {}
for key_guess in range(1 , len(__lowerCamelCase ) ): # tries every key
snake_case : Any = decrypt(__lowerCamelCase , __lowerCamelCase )
return results
if __name__ == "__main__":
import doctest
doctest.testmod()
| 59
| 1
|
from __future__ import annotations
def UpperCamelCase ( __lowerCamelCase : list[int] , __lowerCamelCase : int ):
snake_case : list[list[int]] = []
snake_case : list[int] = []
snake_case : Optional[Any] = 0
snake_case : Optional[Any] = sum(__lowerCamelCase )
create_state_space_tree(__lowerCamelCase , __lowerCamelCase , __lowerCamelCase , __lowerCamelCase , __lowerCamelCase , __lowerCamelCase )
return result
def UpperCamelCase ( __lowerCamelCase : list[int] , __lowerCamelCase : int , __lowerCamelCase : int , __lowerCamelCase : list[int] , __lowerCamelCase : list[list[int]] , __lowerCamelCase : int , ):
if sum(__lowerCamelCase ) > max_sum or (remaining_nums_sum + sum(__lowerCamelCase )) < max_sum:
return
if sum(__lowerCamelCase ) == max_sum:
result.append(__lowerCamelCase )
return
for index in range(__lowerCamelCase , len(__lowerCamelCase ) ):
create_state_space_tree(
__lowerCamelCase , __lowerCamelCase , index + 1 , [*path, nums[index]] , __lowerCamelCase , remaining_nums_sum - nums[index] , )
__lowerCamelCase = [3, 34, 4, 12, 5, 2]
__lowerCamelCase = 9
__lowerCamelCase = generate_sum_of_subsets_soln(nums, max_sum)
print(*result)
| 59
|
from typing import TYPE_CHECKING
from ...utils import (
OptionalDependencyNotAvailable,
_LazyModule,
is_flax_available,
is_sentencepiece_available,
is_tf_available,
is_tokenizers_available,
is_torch_available,
)
if is_sentencepiece_available():
from ..ta.tokenization_ta import TaTokenizer
else:
from ...utils.dummy_sentencepiece_objects import TaTokenizer
__lowerCamelCase = TaTokenizer
if is_tokenizers_available():
from ..ta.tokenization_ta_fast import TaTokenizerFast
else:
from ...utils.dummy_tokenizers_objects import TaTokenizerFast
__lowerCamelCase = TaTokenizerFast
__lowerCamelCase = {"""configuration_mt5""": ["""MT5Config""", """MT5OnnxConfig"""]}
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = [
"""MT5EncoderModel""",
"""MT5ForConditionalGeneration""",
"""MT5ForQuestionAnswering""",
"""MT5Model""",
"""MT5PreTrainedModel""",
"""MT5Stack""",
]
try:
if not is_tf_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = ["""TFMT5EncoderModel""", """TFMT5ForConditionalGeneration""", """TFMT5Model"""]
try:
if not is_flax_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = ["""FlaxMT5EncoderModel""", """FlaxMT5ForConditionalGeneration""", """FlaxMT5Model"""]
if TYPE_CHECKING:
from .configuration_mta import MTaConfig, MTaOnnxConfig
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_mta import (
MTaEncoderModel,
MTaForConditionalGeneration,
MTaForQuestionAnswering,
MTaModel,
MTaPreTrainedModel,
MTaStack,
)
try:
if not is_tf_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_tf_mta import TFMTaEncoderModel, TFMTaForConditionalGeneration, TFMTaModel
try:
if not is_flax_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_flax_mta import FlaxMTaEncoderModel, FlaxMTaForConditionalGeneration, FlaxMTaModel
else:
import sys
__lowerCamelCase = _LazyModule(
__name__,
globals()["""__file__"""],
_import_structure,
extra_objects={"""MT5Tokenizer""": MTaTokenizer, """MT5TokenizerFast""": MTaTokenizerFast},
module_spec=__spec__,
)
| 59
| 1
|
import json
import os
import shutil
import tempfile
import unittest
import numpy as np
from transformers import BertTokenizerFast
from transformers.models.bert.tokenization_bert import VOCAB_FILES_NAMES, BertTokenizer
from transformers.testing_utils import require_tokenizers, require_vision
from transformers.utils import IMAGE_PROCESSOR_NAME, is_vision_available
if is_vision_available():
from PIL import Image
from transformers import VisionTextDualEncoderProcessor, ViTImageProcessor
@require_tokenizers
@require_vision
class UpperCAmelCase ( unittest.TestCase ):
def _SCREAMING_SNAKE_CASE (self : Any ) -> List[str]:
'''simple docstring'''
snake_case : int = tempfile.mkdtemp()
# fmt: off
snake_case : Optional[int] = ["[UNK]", "[CLS]", "[SEP]", "[PAD]", "[MASK]", "want", "##want", "##ed", "wa", "un", "runn", "##ing", ",", "low", "lowest"]
# fmt: on
snake_case : List[str] = os.path.join(self.tmpdirname , VOCAB_FILES_NAMES["vocab_file"] )
with open(self.vocab_file , "w" , encoding="utf-8" ) as vocab_writer:
vocab_writer.write("".join([x + "\n" for x in vocab_tokens] ) )
snake_case : int = {
"do_resize": True,
"size": {"height": 18, "width": 18},
"do_normalize": True,
"image_mean": [0.5, 0.5, 0.5],
"image_std": [0.5, 0.5, 0.5],
}
snake_case : Optional[Any] = os.path.join(self.tmpdirname , snake_case__ )
with open(self.image_processor_file , "w" , encoding="utf-8" ) as fp:
json.dump(snake_case__ , snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Optional[Any] , **snake_case__ : str ) -> Optional[int]:
'''simple docstring'''
return BertTokenizer.from_pretrained(self.tmpdirname , **snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Optional[Any] , **snake_case__ : List[str] ) -> int:
'''simple docstring'''
return ViTImageProcessor.from_pretrained(self.tmpdirname , **snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> Dict:
'''simple docstring'''
shutil.rmtree(self.tmpdirname )
def _SCREAMING_SNAKE_CASE (self : Dict ) -> str:
'''simple docstring'''
snake_case : List[Any] = [np.random.randint(2_55 , size=(3, 30, 4_00) , dtype=np.uinta )]
snake_case : Optional[int] = [Image.fromarray(np.moveaxis(snake_case__ , 0 , -1 ) ) for x in image_inputs]
return image_inputs
def _SCREAMING_SNAKE_CASE (self : Union[str, Any] ) -> Union[str, Any]:
'''simple docstring'''
snake_case : Dict = self.get_tokenizer()
snake_case : Optional[Any] = self.get_image_processor()
snake_case : Optional[Any] = VisionTextDualEncoderProcessor(tokenizer=snake_case__ , image_processor=snake_case__ )
processor.save_pretrained(self.tmpdirname )
snake_case : Any = VisionTextDualEncoderProcessor.from_pretrained(self.tmpdirname )
self.assertEqual(processor.tokenizer.get_vocab() , tokenizer.get_vocab() )
self.assertIsInstance(processor.tokenizer , (BertTokenizer, BertTokenizerFast) )
self.assertEqual(processor.image_processor.to_json_string() , image_processor.to_json_string() )
self.assertIsInstance(processor.image_processor , snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Any ) -> Optional[Any]:
'''simple docstring'''
snake_case : str = VisionTextDualEncoderProcessor(
tokenizer=self.get_tokenizer() , image_processor=self.get_image_processor() )
processor.save_pretrained(self.tmpdirname )
snake_case : Optional[int] = self.get_tokenizer(bos_token="(BOS)" , eos_token="(EOS)" )
snake_case : Tuple = self.get_image_processor(do_normalize=snake_case__ , padding_value=1.0 )
snake_case : List[str] = VisionTextDualEncoderProcessor.from_pretrained(
self.tmpdirname , bos_token="(BOS)" , eos_token="(EOS)" , do_normalize=snake_case__ , padding_value=1.0 )
self.assertEqual(processor.tokenizer.get_vocab() , tokenizer_add_kwargs.get_vocab() )
self.assertIsInstance(processor.tokenizer , (BertTokenizer, BertTokenizerFast) )
self.assertEqual(processor.image_processor.to_json_string() , image_processor_add_kwargs.to_json_string() )
self.assertIsInstance(processor.image_processor , snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Union[str, Any] ) -> int:
'''simple docstring'''
snake_case : str = self.get_image_processor()
snake_case : Optional[int] = self.get_tokenizer()
snake_case : List[Any] = VisionTextDualEncoderProcessor(tokenizer=snake_case__ , image_processor=snake_case__ )
snake_case : Optional[Any] = self.prepare_image_inputs()
snake_case : str = image_processor(snake_case__ , return_tensors="np" )
snake_case : Any = processor(images=snake_case__ , return_tensors="np" )
for key in input_feat_extract.keys():
self.assertAlmostEqual(input_feat_extract[key].sum() , input_processor[key].sum() , delta=1e-2 )
def _SCREAMING_SNAKE_CASE (self : Tuple ) -> Optional[Any]:
'''simple docstring'''
snake_case : Dict = self.get_image_processor()
snake_case : int = self.get_tokenizer()
snake_case : Any = VisionTextDualEncoderProcessor(tokenizer=snake_case__ , image_processor=snake_case__ )
snake_case : Tuple = "lower newer"
snake_case : Tuple = processor(text=snake_case__ )
snake_case : Union[str, Any] = tokenizer(snake_case__ )
for key in encoded_tok.keys():
self.assertListEqual(encoded_tok[key] , encoded_processor[key] )
def _SCREAMING_SNAKE_CASE (self : Dict ) -> Optional[int]:
'''simple docstring'''
snake_case : List[Any] = self.get_image_processor()
snake_case : Dict = self.get_tokenizer()
snake_case : Dict = VisionTextDualEncoderProcessor(tokenizer=snake_case__ , image_processor=snake_case__ )
snake_case : int = "lower newer"
snake_case : Dict = self.prepare_image_inputs()
snake_case : Union[str, Any] = processor(text=snake_case__ , images=snake_case__ )
self.assertListEqual(list(inputs.keys() ) , ["input_ids", "token_type_ids", "attention_mask", "pixel_values"] )
# test if it raises when no input is passed
with self.assertRaises(snake_case__ ):
processor()
def _SCREAMING_SNAKE_CASE (self : str ) -> Tuple:
'''simple docstring'''
snake_case : Tuple = self.get_image_processor()
snake_case : Optional[Any] = self.get_tokenizer()
snake_case : Tuple = VisionTextDualEncoderProcessor(tokenizer=snake_case__ , image_processor=snake_case__ )
snake_case : List[str] = [[1, 4, 5, 8, 1, 0, 8], [3, 4, 3, 1, 1, 8, 9]]
snake_case : List[Any] = processor.batch_decode(snake_case__ )
snake_case : Union[str, Any] = tokenizer.batch_decode(snake_case__ )
self.assertListEqual(snake_case__ , snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> List[str]:
'''simple docstring'''
snake_case : str = self.get_image_processor()
snake_case : Union[str, Any] = self.get_tokenizer()
snake_case : Any = VisionTextDualEncoderProcessor(tokenizer=snake_case__ , image_processor=snake_case__ )
snake_case : Optional[Any] = "lower newer"
snake_case : List[Any] = self.prepare_image_inputs()
snake_case : Tuple = processor(text=snake_case__ , images=snake_case__ )
self.assertListEqual(list(inputs.keys() ) , processor.model_input_names )
| 59
|
import os
import shutil
from pathlib import Path
from typing import Optional, Union
import numpy as np
from huggingface_hub import hf_hub_download
from ..utils import ONNX_EXTERNAL_WEIGHTS_NAME, ONNX_WEIGHTS_NAME, is_onnx_available, logging
if is_onnx_available():
import onnxruntime as ort
__lowerCamelCase = logging.get_logger(__name__)
__lowerCamelCase = {
"""tensor(bool)""": np.bool_,
"""tensor(int8)""": np.inta,
"""tensor(uint8)""": np.uinta,
"""tensor(int16)""": np.intaa,
"""tensor(uint16)""": np.uintaa,
"""tensor(int32)""": np.intaa,
"""tensor(uint32)""": np.uintaa,
"""tensor(int64)""": np.intaa,
"""tensor(uint64)""": np.uintaa,
"""tensor(float16)""": np.floataa,
"""tensor(float)""": np.floataa,
"""tensor(double)""": np.floataa,
}
class UpperCAmelCase :
def __init__(self : Optional[Any] , snake_case__ : Optional[Any]=None , **snake_case__ : Optional[Any] ) -> List[str]:
'''simple docstring'''
logger.info("`diffusers.OnnxRuntimeModel` is experimental and might change in the future." )
snake_case : Optional[Any] = model
snake_case : Dict = kwargs.get("model_save_dir" , snake_case__ )
snake_case : int = kwargs.get("latest_model_name" , snake_case__ )
def __call__(self : Tuple , **snake_case__ : str ) -> List[str]:
'''simple docstring'''
snake_case : Union[str, Any] = {k: np.array(snake_case__ ) for k, v in kwargs.items()}
return self.model.run(snake_case__ , snake_case__ )
@staticmethod
def _SCREAMING_SNAKE_CASE (snake_case__ : Union[str, Path] , snake_case__ : Optional[int]=None , snake_case__ : Optional[int]=None ) -> Any:
'''simple docstring'''
if provider is None:
logger.info("No onnxruntime provider specified, using CPUExecutionProvider" )
snake_case : Optional[int] = "CPUExecutionProvider"
return ort.InferenceSession(snake_case__ , providers=[provider] , sess_options=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : List[Any] , snake_case__ : Union[str, Path] , snake_case__ : Optional[str] = None , **snake_case__ : Any ) -> List[Any]:
'''simple docstring'''
snake_case : Tuple = file_name if file_name is not None else ONNX_WEIGHTS_NAME
snake_case : Any = self.model_save_dir.joinpath(self.latest_model_name )
snake_case : str = Path(snake_case__ ).joinpath(snake_case__ )
try:
shutil.copyfile(snake_case__ , snake_case__ )
except shutil.SameFileError:
pass
# copy external weights (for models >2GB)
snake_case : List[str] = self.model_save_dir.joinpath(snake_case__ )
if src_path.exists():
snake_case : Tuple = Path(snake_case__ ).joinpath(snake_case__ )
try:
shutil.copyfile(snake_case__ , snake_case__ )
except shutil.SameFileError:
pass
def _SCREAMING_SNAKE_CASE (self : str , snake_case__ : Union[str, os.PathLike] , **snake_case__ : Optional[int] , ) -> str:
'''simple docstring'''
if os.path.isfile(snake_case__ ):
logger.error(f"""Provided path ({save_directory}) should be a directory, not a file""" )
return
os.makedirs(snake_case__ , exist_ok=snake_case__ )
# saving model weights/files
self._save_pretrained(snake_case__ , **snake_case__ )
@classmethod
def _SCREAMING_SNAKE_CASE (cls : Tuple , snake_case__ : Union[str, Path] , snake_case__ : Optional[Union[bool, str, None]] = None , snake_case__ : Optional[Union[str, None]] = None , snake_case__ : bool = False , snake_case__ : Optional[str] = None , snake_case__ : Optional[str] = None , snake_case__ : Optional[str] = None , snake_case__ : Optional["ort.SessionOptions"] = None , **snake_case__ : Tuple , ) -> Tuple:
'''simple docstring'''
snake_case : List[str] = file_name if file_name is not None else ONNX_WEIGHTS_NAME
# load model from local directory
if os.path.isdir(snake_case__ ):
snake_case : Any = OnnxRuntimeModel.load_model(
os.path.join(snake_case__ , snake_case__ ) , provider=snake_case__ , sess_options=snake_case__ )
snake_case : Union[str, Any] = Path(snake_case__ )
# load model from hub
else:
# download model
snake_case : Dict = hf_hub_download(
repo_id=snake_case__ , filename=snake_case__ , use_auth_token=snake_case__ , revision=snake_case__ , cache_dir=snake_case__ , force_download=snake_case__ , )
snake_case : List[Any] = Path(snake_case__ ).parent
snake_case : Union[str, Any] = Path(snake_case__ ).name
snake_case : Dict = OnnxRuntimeModel.load_model(snake_case__ , provider=snake_case__ , sess_options=snake_case__ )
return cls(model=snake_case__ , **snake_case__ )
@classmethod
def _SCREAMING_SNAKE_CASE (cls : Optional[Any] , snake_case__ : Union[str, Path] , snake_case__ : bool = True , snake_case__ : Optional[str] = None , snake_case__ : Optional[str] = None , **snake_case__ : Dict , ) -> Union[str, Any]:
'''simple docstring'''
snake_case : Dict = None
if len(str(snake_case__ ).split("@" ) ) == 2:
snake_case , snake_case : int = model_id.split("@" )
return cls._from_pretrained(
model_id=snake_case__ , revision=snake_case__ , cache_dir=snake_case__ , force_download=snake_case__ , use_auth_token=snake_case__ , **snake_case__ , )
| 59
| 1
|
from __future__ import annotations
import inspect
import unittest
import numpy as np
from transformers import ResNetConfig
from transformers.testing_utils import require_tf, require_vision, slow
from transformers.utils import cached_property, is_tf_available, is_vision_available
from ...test_configuration_common import ConfigTester
from ...test_modeling_tf_common import TFModelTesterMixin, floats_tensor, ids_tensor
from ...test_pipeline_mixin import PipelineTesterMixin
if is_tf_available():
import tensorflow as tf
from transformers import TFResNetForImageClassification, TFResNetModel
from transformers.models.resnet.modeling_tf_resnet import TF_RESNET_PRETRAINED_MODEL_ARCHIVE_LIST
if is_vision_available():
from PIL import Image
from transformers import AutoImageProcessor
class UpperCAmelCase :
def __init__(self : List[str] , snake_case__ : str , snake_case__ : List[str]=3 , snake_case__ : int=32 , snake_case__ : Optional[int]=3 , snake_case__ : Tuple=10 , snake_case__ : Dict=[10, 20, 30, 40] , snake_case__ : List[Any]=[1, 1, 2, 1] , snake_case__ : Optional[Any]=True , snake_case__ : Dict=True , snake_case__ : Tuple="relu" , snake_case__ : Optional[int]=3 , snake_case__ : Any=None , ) -> int:
'''simple docstring'''
snake_case : Optional[int] = parent
snake_case : List[str] = batch_size
snake_case : Optional[Any] = image_size
snake_case : str = num_channels
snake_case : Dict = embeddings_size
snake_case : List[str] = hidden_sizes
snake_case : List[Any] = depths
snake_case : Union[str, Any] = is_training
snake_case : List[Any] = use_labels
snake_case : Optional[Any] = hidden_act
snake_case : Union[str, Any] = num_labels
snake_case : Union[str, Any] = scope
snake_case : List[str] = len(snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Dict ) -> Optional[int]:
'''simple docstring'''
snake_case : Tuple = floats_tensor([self.batch_size, self.num_channels, self.image_size, self.image_size] )
snake_case : Tuple = None
if self.use_labels:
snake_case : Tuple = ids_tensor([self.batch_size] , self.num_labels )
snake_case : Union[str, Any] = self.get_config()
return config, pixel_values, labels
def _SCREAMING_SNAKE_CASE (self : Tuple ) -> Dict:
'''simple docstring'''
return ResNetConfig(
num_channels=self.num_channels , embeddings_size=self.embeddings_size , hidden_sizes=self.hidden_sizes , depths=self.depths , hidden_act=self.hidden_act , num_labels=self.num_labels , image_size=self.image_size , )
def _SCREAMING_SNAKE_CASE (self : Optional[Any] , snake_case__ : Optional[int] , snake_case__ : str , snake_case__ : Dict ) -> List[str]:
'''simple docstring'''
snake_case : int = TFResNetModel(config=snake_case__ )
snake_case : List[str] = model(snake_case__ )
# expected last hidden states: B, C, H // 32, W // 32
self.parent.assertEqual(
result.last_hidden_state.shape , (self.batch_size, self.hidden_sizes[-1], self.image_size // 32, self.image_size // 32) , )
def _SCREAMING_SNAKE_CASE (self : Optional[Any] , snake_case__ : Any , snake_case__ : Dict , snake_case__ : str ) -> List[str]:
'''simple docstring'''
snake_case : Optional[int] = self.num_labels
snake_case : Dict = TFResNetForImageClassification(snake_case__ )
snake_case : List[Any] = model(snake_case__ , labels=snake_case__ )
self.parent.assertEqual(result.logits.shape , (self.batch_size, self.num_labels) )
def _SCREAMING_SNAKE_CASE (self : str ) -> Optional[Any]:
'''simple docstring'''
snake_case : int = self.prepare_config_and_inputs()
snake_case , snake_case , snake_case : Tuple = config_and_inputs
snake_case : Optional[int] = {"pixel_values": pixel_values}
return config, inputs_dict
@require_tf
class UpperCAmelCase ( A_ ,A_ ,unittest.TestCase ):
A__ : Optional[int] = (TFResNetModel, TFResNetForImageClassification) if is_tf_available() else ()
A__ : Optional[Any] = (
{"feature-extraction": TFResNetModel, "image-classification": TFResNetForImageClassification}
if is_tf_available()
else {}
)
A__ : Union[str, Any] = False
A__ : Union[str, Any] = False
A__ : List[Any] = False
A__ : Tuple = False
A__ : Optional[Any] = False
def _SCREAMING_SNAKE_CASE (self : Union[str, Any] ) -> List[str]:
'''simple docstring'''
snake_case : int = TFResNetModelTester(self )
snake_case : Optional[int] = ConfigTester(self , config_class=snake_case__ , has_text_modality=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : int ) -> int:
'''simple docstring'''
self.create_and_test_config_common_properties()
self.config_tester.create_and_test_config_to_json_string()
self.config_tester.create_and_test_config_to_json_file()
self.config_tester.create_and_test_config_from_and_save_pretrained()
self.config_tester.create_and_test_config_with_num_labels()
self.config_tester.check_config_can_be_init_without_params()
self.config_tester.check_config_arguments_init()
def _SCREAMING_SNAKE_CASE (self : str ) -> Union[str, Any]:
'''simple docstring'''
return
@unittest.skip(reason="ResNet does not use inputs_embeds" )
def _SCREAMING_SNAKE_CASE (self : Tuple ) -> List[str]:
'''simple docstring'''
pass
@unittest.skip(reason="ResNet does not support input and output embeddings" )
def _SCREAMING_SNAKE_CASE (self : Optional[Any] ) -> str:
'''simple docstring'''
pass
def _SCREAMING_SNAKE_CASE (self : Union[str, Any] ) -> Tuple:
'''simple docstring'''
snake_case , snake_case : List[Any] = self.model_tester.prepare_config_and_inputs_for_common()
for model_class in self.all_model_classes:
snake_case : Dict = model_class(snake_case__ )
snake_case : Optional[int] = inspect.signature(model.call )
# signature.parameters is an OrderedDict => so arg_names order is deterministic
snake_case : Union[str, Any] = [*signature.parameters.keys()]
snake_case : Tuple = ["pixel_values"]
self.assertListEqual(arg_names[:1] , snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Any ) -> Tuple:
'''simple docstring'''
snake_case : Union[str, Any] = self.model_tester.prepare_config_and_inputs()
self.model_tester.create_and_check_model(*snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> Optional[Any]:
'''simple docstring'''
def check_hidden_states_output(snake_case__ : Union[str, Any] , snake_case__ : str , snake_case__ : List[str] ):
snake_case : Dict = model_class(snake_case__ )
snake_case : Optional[int] = model(**self._prepare_for_class(snake_case__ , snake_case__ ) )
snake_case : Tuple = outputs.encoder_hidden_states if config.is_encoder_decoder else outputs.hidden_states
snake_case : Optional[Any] = self.model_tester.num_stages
self.assertEqual(len(snake_case__ ) , expected_num_stages + 1 )
# ResNet's feature maps are of shape (batch_size, num_channels, height, width)
self.assertListEqual(
list(hidden_states[0].shape[-2:] ) , [self.model_tester.image_size // 4, self.model_tester.image_size // 4] , )
snake_case , snake_case : Union[str, Any] = self.model_tester.prepare_config_and_inputs_for_common()
snake_case : Tuple = ["basic", "bottleneck"]
for model_class in self.all_model_classes:
for layer_type in layers_type:
snake_case : Any = layer_type
snake_case : Tuple = True
check_hidden_states_output(snake_case__ , snake_case__ , snake_case__ )
# check that output_hidden_states also work using config
del inputs_dict["output_hidden_states"]
snake_case : str = True
check_hidden_states_output(snake_case__ , snake_case__ , snake_case__ )
def _SCREAMING_SNAKE_CASE (self : List[Any] ) -> List[Any]:
'''simple docstring'''
snake_case : int = self.model_tester.prepare_config_and_inputs()
self.model_tester.create_and_check_for_image_classification(*snake_case__ )
@slow
def _SCREAMING_SNAKE_CASE (self : Any ) -> Any:
'''simple docstring'''
for model_name in TF_RESNET_PRETRAINED_MODEL_ARCHIVE_LIST[:1]:
snake_case : str = TFResNetModel.from_pretrained(snake_case__ )
self.assertIsNotNone(snake_case__ )
def UpperCamelCase ( ):
snake_case : str = Image.open("./tests/fixtures/tests_samples/COCO/000000039769.png" )
return image
@require_tf
@require_vision
class UpperCAmelCase ( unittest.TestCase ):
@cached_property
def _SCREAMING_SNAKE_CASE (self : int ) -> Optional[Any]:
'''simple docstring'''
return (
AutoImageProcessor.from_pretrained(TF_RESNET_PRETRAINED_MODEL_ARCHIVE_LIST[0] )
if is_vision_available()
else None
)
@slow
def _SCREAMING_SNAKE_CASE (self : Optional[Any] ) -> Any:
'''simple docstring'''
snake_case : List[Any] = TFResNetForImageClassification.from_pretrained(TF_RESNET_PRETRAINED_MODEL_ARCHIVE_LIST[0] )
snake_case : List[Any] = self.default_image_processor
snake_case : Tuple = prepare_img()
snake_case : Optional[Any] = image_processor(images=snake_case__ , return_tensors="tf" )
# forward pass
snake_case : Any = model(**snake_case__ )
# verify the logits
snake_case : Any = tf.TensorShape((1, 10_00) )
self.assertEqual(outputs.logits.shape , snake_case__ )
snake_case : List[str] = tf.constant([-11.1069, -9.7877, -8.3777] )
self.assertTrue(np.allclose(outputs.logits[0, :3].numpy() , snake_case__ , atol=1e-4 ) )
| 59
|
import argparse
import json
from dataclasses import dataclass, field
from functools import partial
from pathlib import Path
from typing import Callable, Dict, List, Tuple
import timm
import torch
import torch.nn as nn
from classy_vision.models.regnet import RegNet, RegNetParams, RegNetYaagf, RegNetYaagf, RegNetYaaagf
from huggingface_hub import cached_download, hf_hub_url
from torch import Tensor
from vissl.models.model_helpers import get_trunk_forward_outputs
from transformers import AutoImageProcessor, RegNetConfig, RegNetForImageClassification, RegNetModel
from transformers.utils import logging
logging.set_verbosity_info()
__lowerCamelCase = logging.get_logger()
@dataclass
class UpperCAmelCase :
A__ : nn.Module
A__ : List[nn.Module] = field(default_factory=A_ )
A__ : list = field(default_factory=A_ )
def _SCREAMING_SNAKE_CASE (self : Optional[Any] , snake_case__ : Optional[Any] , snake_case__ : Tensor , snake_case__ : Tensor ) -> Optional[Any]:
'''simple docstring'''
snake_case : List[str] = len(list(m.modules() ) ) == 1 or isinstance(snake_case__ , nn.Convad ) or isinstance(snake_case__ , nn.BatchNormad )
if has_not_submodules:
self.traced.append(snake_case__ )
def __call__(self : List[Any] , snake_case__ : Tensor ) -> List[Any]:
'''simple docstring'''
for m in self.module.modules():
self.handles.append(m.register_forward_hook(self._forward_hook ) )
self.module(snake_case__ )
[x.remove() for x in self.handles]
return self
@property
def _SCREAMING_SNAKE_CASE (self : int ) -> Optional[int]:
'''simple docstring'''
return list(filter(lambda snake_case__ : len(list(x.state_dict().keys() ) ) > 0 , self.traced ) )
@dataclass
class UpperCAmelCase :
A__ : nn.Module
A__ : nn.Module
A__ : int = 1
A__ : List = field(default_factory=A_ )
A__ : List = field(default_factory=A_ )
A__ : bool = True
def __call__(self : List[Any] , snake_case__ : Tensor ) -> Any:
'''simple docstring'''
snake_case : str = Tracker(self.dest )(snake_case__ ).parametrized
snake_case : Optional[int] = Tracker(self.src )(snake_case__ ).parametrized
snake_case : List[str] = list(filter(lambda snake_case__ : type(snake_case__ ) not in self.src_skip , snake_case__ ) )
snake_case : Optional[Any] = list(filter(lambda snake_case__ : type(snake_case__ ) not in self.dest_skip , snake_case__ ) )
if len(snake_case__ ) != len(snake_case__ ) and self.raise_if_mismatch:
raise Exception(
f"""Numbers of operations are different. Source module has {len(snake_case__ )} operations while"""
f""" destination module has {len(snake_case__ )}.""" )
for dest_m, src_m in zip(snake_case__ , snake_case__ ):
dest_m.load_state_dict(src_m.state_dict() )
if self.verbose == 1:
print(f"""Transfered from={src_m} to={dest_m}""" )
class UpperCAmelCase ( nn.Module ):
def __init__(self : Tuple , snake_case__ : nn.Module ) -> Optional[Any]:
'''simple docstring'''
super().__init__()
snake_case : List[Tuple[str, nn.Module]] = []
# - get the stem
feature_blocks.append(("conv1", model.stem) )
# - get all the feature blocks
for k, v in model.trunk_output.named_children():
assert k.startswith("block" ), f"""Unexpected layer name {k}"""
snake_case : Union[str, Any] = len(snake_case__ ) + 1
feature_blocks.append((f"""res{block_index}""", v) )
snake_case : Optional[Any] = nn.ModuleDict(snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Tuple , snake_case__ : Tensor ) -> Dict:
'''simple docstring'''
return get_trunk_forward_outputs(
snake_case__ , out_feat_keys=snake_case__ , feature_blocks=self._feature_blocks , )
class UpperCAmelCase ( A_ ):
def _SCREAMING_SNAKE_CASE (self : Any , snake_case__ : str ) -> str:
'''simple docstring'''
snake_case : List[Any] = x.split("-" )
return x_split[0] + x_split[1] + "_" + "".join(x_split[2:] )
def __getitem__(self : Optional[int] , snake_case__ : str ) -> Callable[[], Tuple[nn.Module, Dict]]:
'''simple docstring'''
if x not in self:
snake_case : Dict = self.convert_name_to_timm(snake_case__ )
snake_case : Union[str, Any] = partial(lambda: (timm.create_model(snake_case__ , pretrained=snake_case__ ).eval(), None) )
else:
snake_case : List[str] = super().__getitem__(snake_case__ )
return val
class UpperCAmelCase ( A_ ):
def __getitem__(self : Dict , snake_case__ : str ) -> Callable[[], nn.Module]:
'''simple docstring'''
if "seer" in x and "in1k" not in x:
snake_case : str = RegNetModel
else:
snake_case : Optional[Any] = RegNetForImageClassification
return val
def UpperCamelCase ( __lowerCamelCase : Union[str, Any] , __lowerCamelCase : Union[str, Any] , __lowerCamelCase : List[Tuple[str, str]] ):
for from_key, to_key in keys:
snake_case : str = from_state_dict[from_key].clone()
print(f"""Copied key={from_key} to={to_key}""" )
return to_state_dict
def UpperCamelCase ( __lowerCamelCase : str , __lowerCamelCase : Callable[[], nn.Module] , __lowerCamelCase : Callable[[], nn.Module] , __lowerCamelCase : RegNetConfig , __lowerCamelCase : Path , __lowerCamelCase : bool = True , ):
print(f"""Converting {name}...""" )
with torch.no_grad():
snake_case , snake_case : int = from_model_func()
snake_case : str = our_model_func(__lowerCamelCase ).eval()
snake_case : int = ModuleTransfer(src=__lowerCamelCase , dest=__lowerCamelCase , raise_if_mismatch=__lowerCamelCase )
snake_case : Dict = torch.randn((1, 3, 224, 224) )
module_transfer(__lowerCamelCase )
if from_state_dict is not None:
snake_case : str = []
# for seer - in1k finetuned we have to manually copy the head
if "seer" in name and "in1k" in name:
snake_case : Tuple = [("0.clf.0.weight", "classifier.1.weight"), ("0.clf.0.bias", "classifier.1.bias")]
snake_case : Optional[Any] = manually_copy_vissl_head(__lowerCamelCase , our_model.state_dict() , __lowerCamelCase )
our_model.load_state_dict(__lowerCamelCase )
snake_case : Any = our_model(__lowerCamelCase , output_hidden_states=__lowerCamelCase )
snake_case : Union[str, Any] = (
our_outputs.logits if isinstance(__lowerCamelCase , __lowerCamelCase ) else our_outputs.last_hidden_state
)
snake_case : Union[str, Any] = from_model(__lowerCamelCase )
snake_case : Dict = from_output[-1] if type(__lowerCamelCase ) is list else from_output
# now since I don't want to use any config files, vissl seer model doesn't actually have an head, so let's just check the last hidden state
if "seer" in name and "in1k" in name:
snake_case : Any = our_outputs.hidden_states[-1]
assert torch.allclose(__lowerCamelCase , __lowerCamelCase ), "The model logits don't match the original one."
if push_to_hub:
our_model.push_to_hub(
repo_path_or_name=save_directory / name , commit_message="Add model" , use_temp_dir=__lowerCamelCase , )
snake_case : List[str] = 224 if "seer" not in name else 384
# we can use the convnext one
snake_case : int = AutoImageProcessor.from_pretrained("facebook/convnext-base-224-22k-1k" , size=__lowerCamelCase )
image_processor.push_to_hub(
repo_path_or_name=save_directory / name , commit_message="Add image processor" , use_temp_dir=__lowerCamelCase , )
print(f"""Pushed {name}""" )
def UpperCamelCase ( __lowerCamelCase : Path , __lowerCamelCase : str = None , __lowerCamelCase : bool = True ):
snake_case : Union[str, Any] = "imagenet-1k-id2label.json"
snake_case : List[str] = 1000
snake_case : List[str] = (1, num_labels)
snake_case : Any = "huggingface/label-files"
snake_case : List[str] = num_labels
snake_case : Optional[Any] = json.load(open(cached_download(hf_hub_url(__lowerCamelCase , __lowerCamelCase , repo_type="dataset" ) ) , "r" ) )
snake_case : List[Any] = {int(__lowerCamelCase ): v for k, v in idalabel.items()}
snake_case : str = idalabel
snake_case : List[Any] = {v: k for k, v in idalabel.items()}
snake_case : Dict = partial(__lowerCamelCase , num_labels=__lowerCamelCase , idalabel=__lowerCamelCase , labelaid=__lowerCamelCase )
snake_case : Optional[Any] = {
"regnet-x-002": ImageNetPreTrainedConfig(
depths=[1, 1, 4, 7] , hidden_sizes=[24, 56, 152, 368] , groups_width=8 , layer_type="x" ),
"regnet-x-004": ImageNetPreTrainedConfig(
depths=[1, 2, 7, 12] , hidden_sizes=[32, 64, 160, 384] , groups_width=16 , layer_type="x" ),
"regnet-x-006": ImageNetPreTrainedConfig(
depths=[1, 3, 5, 7] , hidden_sizes=[48, 96, 240, 528] , groups_width=24 , layer_type="x" ),
"regnet-x-008": ImageNetPreTrainedConfig(
depths=[1, 3, 7, 5] , hidden_sizes=[64, 128, 288, 672] , groups_width=16 , layer_type="x" ),
"regnet-x-016": ImageNetPreTrainedConfig(
depths=[2, 4, 10, 2] , hidden_sizes=[72, 168, 408, 912] , groups_width=24 , layer_type="x" ),
"regnet-x-032": ImageNetPreTrainedConfig(
depths=[2, 6, 15, 2] , hidden_sizes=[96, 192, 432, 1008] , groups_width=48 , layer_type="x" ),
"regnet-x-040": ImageNetPreTrainedConfig(
depths=[2, 5, 14, 2] , hidden_sizes=[80, 240, 560, 1360] , groups_width=40 , layer_type="x" ),
"regnet-x-064": ImageNetPreTrainedConfig(
depths=[2, 4, 10, 1] , hidden_sizes=[168, 392, 784, 1624] , groups_width=56 , layer_type="x" ),
"regnet-x-080": ImageNetPreTrainedConfig(
depths=[2, 5, 15, 1] , hidden_sizes=[80, 240, 720, 1920] , groups_width=120 , layer_type="x" ),
"regnet-x-120": ImageNetPreTrainedConfig(
depths=[2, 5, 11, 1] , hidden_sizes=[224, 448, 896, 2240] , groups_width=112 , layer_type="x" ),
"regnet-x-160": ImageNetPreTrainedConfig(
depths=[2, 6, 13, 1] , hidden_sizes=[256, 512, 896, 2048] , groups_width=128 , layer_type="x" ),
"regnet-x-320": ImageNetPreTrainedConfig(
depths=[2, 7, 13, 1] , hidden_sizes=[336, 672, 1344, 2520] , groups_width=168 , layer_type="x" ),
# y variant
"regnet-y-002": ImageNetPreTrainedConfig(depths=[1, 1, 4, 7] , hidden_sizes=[24, 56, 152, 368] , groups_width=8 ),
"regnet-y-004": ImageNetPreTrainedConfig(
depths=[1, 3, 6, 6] , hidden_sizes=[48, 104, 208, 440] , groups_width=8 ),
"regnet-y-006": ImageNetPreTrainedConfig(
depths=[1, 3, 7, 4] , hidden_sizes=[48, 112, 256, 608] , groups_width=16 ),
"regnet-y-008": ImageNetPreTrainedConfig(
depths=[1, 3, 8, 2] , hidden_sizes=[64, 128, 320, 768] , groups_width=16 ),
"regnet-y-016": ImageNetPreTrainedConfig(
depths=[2, 6, 17, 2] , hidden_sizes=[48, 120, 336, 888] , groups_width=24 ),
"regnet-y-032": ImageNetPreTrainedConfig(
depths=[2, 5, 13, 1] , hidden_sizes=[72, 216, 576, 1512] , groups_width=24 ),
"regnet-y-040": ImageNetPreTrainedConfig(
depths=[2, 6, 12, 2] , hidden_sizes=[128, 192, 512, 1088] , groups_width=64 ),
"regnet-y-064": ImageNetPreTrainedConfig(
depths=[2, 7, 14, 2] , hidden_sizes=[144, 288, 576, 1296] , groups_width=72 ),
"regnet-y-080": ImageNetPreTrainedConfig(
depths=[2, 4, 10, 1] , hidden_sizes=[168, 448, 896, 2016] , groups_width=56 ),
"regnet-y-120": ImageNetPreTrainedConfig(
depths=[2, 5, 11, 1] , hidden_sizes=[224, 448, 896, 2240] , groups_width=112 ),
"regnet-y-160": ImageNetPreTrainedConfig(
depths=[2, 4, 11, 1] , hidden_sizes=[224, 448, 1232, 3024] , groups_width=112 ),
"regnet-y-320": ImageNetPreTrainedConfig(
depths=[2, 5, 12, 1] , hidden_sizes=[232, 696, 1392, 3712] , groups_width=232 ),
# models created by SEER -> https://arxiv.org/abs/2202.08360
"regnet-y-320-seer": RegNetConfig(depths=[2, 5, 12, 1] , hidden_sizes=[232, 696, 1392, 3712] , groups_width=232 ),
"regnet-y-640-seer": RegNetConfig(depths=[2, 5, 12, 1] , hidden_sizes=[328, 984, 1968, 4920] , groups_width=328 ),
"regnet-y-1280-seer": RegNetConfig(
depths=[2, 7, 17, 1] , hidden_sizes=[528, 1056, 2904, 7392] , groups_width=264 ),
"regnet-y-2560-seer": RegNetConfig(
depths=[3, 7, 16, 1] , hidden_sizes=[640, 1696, 2544, 5088] , groups_width=640 ),
"regnet-y-10b-seer": ImageNetPreTrainedConfig(
depths=[2, 7, 17, 1] , hidden_sizes=[2020, 4040, 11110, 28280] , groups_width=1010 ),
# finetuned on imagenet
"regnet-y-320-seer-in1k": ImageNetPreTrainedConfig(
depths=[2, 5, 12, 1] , hidden_sizes=[232, 696, 1392, 3712] , groups_width=232 ),
"regnet-y-640-seer-in1k": ImageNetPreTrainedConfig(
depths=[2, 5, 12, 1] , hidden_sizes=[328, 984, 1968, 4920] , groups_width=328 ),
"regnet-y-1280-seer-in1k": ImageNetPreTrainedConfig(
depths=[2, 7, 17, 1] , hidden_sizes=[528, 1056, 2904, 7392] , groups_width=264 ),
"regnet-y-2560-seer-in1k": ImageNetPreTrainedConfig(
depths=[3, 7, 16, 1] , hidden_sizes=[640, 1696, 2544, 5088] , groups_width=640 ),
"regnet-y-10b-seer-in1k": ImageNetPreTrainedConfig(
depths=[2, 7, 17, 1] , hidden_sizes=[2020, 4040, 11110, 28280] , groups_width=1010 ),
}
snake_case : Union[str, Any] = NameToOurModelFuncMap()
snake_case : str = NameToFromModelFuncMap()
# add seer weights logic
def load_using_classy_vision(__lowerCamelCase : str , __lowerCamelCase : Callable[[], nn.Module] ) -> Tuple[nn.Module, Dict]:
snake_case : List[Any] = torch.hub.load_state_dict_from_url(__lowerCamelCase , model_dir=str(__lowerCamelCase ) , map_location="cpu" )
snake_case : Dict = model_func()
# check if we have a head, if yes add it
snake_case : str = files["classy_state_dict"]["base_model"]["model"]
snake_case : Dict = model_state_dict["trunk"]
model.load_state_dict(__lowerCamelCase )
return model.eval(), model_state_dict["heads"]
# pretrained
snake_case : List[Any] = partial(
__lowerCamelCase , "https://dl.fbaipublicfiles.com/vissl/model_zoo/seer_regnet32d/seer_regnet32gf_model_iteration244000.torch" , lambda: FakeRegNetVisslWrapper(RegNetYaagf() ) , )
snake_case : Optional[int] = partial(
__lowerCamelCase , "https://dl.fbaipublicfiles.com/vissl/model_zoo/seer_regnet64/seer_regnet64gf_model_final_checkpoint_phase0.torch" , lambda: FakeRegNetVisslWrapper(RegNetYaagf() ) , )
snake_case : List[str] = partial(
__lowerCamelCase , "https://dl.fbaipublicfiles.com/vissl/model_zoo/swav_ig1b_regnet128Gf_cnstant_bs32_node16_sinkhorn10_proto16k_syncBN64_warmup8k/model_final_checkpoint_phase0.torch" , lambda: FakeRegNetVisslWrapper(RegNetYaaagf() ) , )
snake_case : Tuple = partial(
__lowerCamelCase , "https://dl.fbaipublicfiles.com/vissl/model_zoo/seer_regnet10B/model_iteration124500_conso.torch" , lambda: FakeRegNetVisslWrapper(
RegNet(RegNetParams(depth=27 , group_width=1010 , w_a=1744 , w_a=620.83 , w_m=2.52 ) ) ) , )
# IN1K finetuned
snake_case : List[Any] = partial(
__lowerCamelCase , "https://dl.fbaipublicfiles.com/vissl/model_zoo/seer_finetuned/seer_regnet32_finetuned_in1k_model_final_checkpoint_phase78.torch" , lambda: FakeRegNetVisslWrapper(RegNetYaagf() ) , )
snake_case : Tuple = partial(
__lowerCamelCase , "https://dl.fbaipublicfiles.com/vissl/model_zoo/seer_finetuned/seer_regnet64_finetuned_in1k_model_final_checkpoint_phase78.torch" , lambda: FakeRegNetVisslWrapper(RegNetYaagf() ) , )
snake_case : str = partial(
__lowerCamelCase , "https://dl.fbaipublicfiles.com/vissl/model_zoo/seer_finetuned/seer_regnet128_finetuned_in1k_model_final_checkpoint_phase78.torch" , lambda: FakeRegNetVisslWrapper(RegNetYaaagf() ) , )
snake_case : Dict = partial(
__lowerCamelCase , "https://dl.fbaipublicfiles.com/vissl/model_zoo/seer_finetuned/seer_10b_finetuned_in1k_model_phase28_conso.torch" , lambda: FakeRegNetVisslWrapper(
RegNet(RegNetParams(depth=27 , group_width=1010 , w_a=1744 , w_a=620.83 , w_m=2.52 ) ) ) , )
if model_name:
convert_weight_and_push(
__lowerCamelCase , names_to_from_model_map[model_name] , names_to_ours_model_map[model_name] , names_to_config[model_name] , __lowerCamelCase , __lowerCamelCase , )
else:
for model_name, config in names_to_config.items():
convert_weight_and_push(
__lowerCamelCase , names_to_from_model_map[model_name] , names_to_ours_model_map[model_name] , __lowerCamelCase , __lowerCamelCase , __lowerCamelCase , )
return config, expected_shape
if __name__ == "__main__":
__lowerCamelCase = argparse.ArgumentParser()
# Required parameters
parser.add_argument(
"""--model_name""",
default=None,
type=str,
help=(
"""The name of the model you wish to convert, it must be one of the supported regnet* architecture,"""
""" currently: regnetx-*, regnety-*. If `None`, all of them will the converted."""
),
)
parser.add_argument(
"""--pytorch_dump_folder_path""",
default=None,
type=Path,
required=True,
help="""Path to the output PyTorch model directory.""",
)
parser.add_argument(
"""--push_to_hub""",
default=True,
type=bool,
required=False,
help="""If True, push model and image processor to the hub.""",
)
__lowerCamelCase = parser.parse_args()
__lowerCamelCase = args.pytorch_dump_folder_path
pytorch_dump_folder_path.mkdir(exist_ok=True, parents=True)
convert_weights_and_push(pytorch_dump_folder_path, args.model_name, args.push_to_hub)
| 59
| 1
|
import logging
from transformers.configuration_utils import PretrainedConfig
__lowerCamelCase = logging.getLogger(__name__)
class UpperCAmelCase ( A_ ):
A__ : int = "masked_bert"
def __init__(self : Dict , snake_case__ : Optional[Any]=3_05_22 , snake_case__ : int=7_68 , snake_case__ : Union[str, Any]=12 , snake_case__ : List[str]=12 , snake_case__ : Optional[Any]=30_72 , snake_case__ : Union[str, Any]="gelu" , snake_case__ : str=0.1 , snake_case__ : Optional[int]=0.1 , snake_case__ : List[str]=5_12 , snake_case__ : Tuple=2 , snake_case__ : Optional[Any]=0.02 , snake_case__ : List[Any]=1e-12 , snake_case__ : Optional[int]=0 , snake_case__ : Dict="topK" , snake_case__ : Any="constant" , snake_case__ : Tuple=0.0 , **snake_case__ : Dict , ) -> Tuple:
'''simple docstring'''
super().__init__(pad_token_id=snake_case__ , **snake_case__ )
snake_case : Any = vocab_size
snake_case : int = hidden_size
snake_case : Dict = num_hidden_layers
snake_case : Optional[int] = num_attention_heads
snake_case : int = hidden_act
snake_case : Tuple = intermediate_size
snake_case : Any = hidden_dropout_prob
snake_case : Optional[Any] = attention_probs_dropout_prob
snake_case : Dict = max_position_embeddings
snake_case : Any = type_vocab_size
snake_case : List[Any] = initializer_range
snake_case : List[Any] = layer_norm_eps
snake_case : Tuple = pruning_method
snake_case : Tuple = mask_init
snake_case : Optional[int] = mask_scale
| 59
|
import warnings
from typing import Dict
import numpy as np
from ..utils import ExplicitEnum, add_end_docstrings, is_tf_available, is_torch_available
from .base import PIPELINE_INIT_ARGS, GenericTensor, Pipeline
if is_tf_available():
from ..models.auto.modeling_tf_auto import TF_MODEL_FOR_SEQUENCE_CLASSIFICATION_MAPPING
if is_torch_available():
from ..models.auto.modeling_auto import MODEL_FOR_SEQUENCE_CLASSIFICATION_MAPPING
def UpperCamelCase ( __lowerCamelCase : List[Any] ):
return 1.0 / (1.0 + np.exp(-_outputs ))
def UpperCamelCase ( __lowerCamelCase : int ):
snake_case : Tuple = np.max(_outputs , axis=-1 , keepdims=__lowerCamelCase )
snake_case : int = np.exp(_outputs - maxes )
return shifted_exp / shifted_exp.sum(axis=-1 , keepdims=__lowerCamelCase )
class UpperCAmelCase ( A_ ):
A__ : Any = "sigmoid"
A__ : str = "softmax"
A__ : int = "none"
@add_end_docstrings(
A_ ,r"\n return_all_scores (`bool`, *optional*, defaults to `False`):\n Whether to return all prediction scores or just the one of the predicted class.\n function_to_apply (`str`, *optional*, defaults to `\"default\"`):\n The function to apply to the model outputs in order to retrieve the scores. Accepts four different values:\n\n - `\"default\"`: if the model has a single label, will apply the sigmoid function on the output. If the model\n has several labels, will apply the softmax function on the output.\n - `\"sigmoid\"`: Applies the sigmoid function on the output.\n - `\"softmax\"`: Applies the softmax function on the output.\n - `\"none\"`: Does not apply any function on the output.\n " ,)
class UpperCAmelCase ( A_ ):
A__ : int = False
A__ : Union[str, Any] = ClassificationFunction.NONE
def __init__(self : List[str] , **snake_case__ : int ) -> str:
'''simple docstring'''
super().__init__(**snake_case__ )
self.check_model_type(
TF_MODEL_FOR_SEQUENCE_CLASSIFICATION_MAPPING
if self.framework == "tf"
else MODEL_FOR_SEQUENCE_CLASSIFICATION_MAPPING )
def _SCREAMING_SNAKE_CASE (self : List[Any] , snake_case__ : List[str]=None , snake_case__ : Optional[Any]=None , snake_case__ : Union[str, Any]="" , **snake_case__ : List[str] ) -> Union[str, Any]:
'''simple docstring'''
snake_case : Dict = tokenizer_kwargs
snake_case : List[Any] = {}
if hasattr(self.model.config , "return_all_scores" ) and return_all_scores is None:
snake_case : Optional[int] = self.model.config.return_all_scores
if isinstance(snake_case__ , snake_case__ ) or top_k is None:
snake_case : List[Any] = top_k
snake_case : str = False
elif return_all_scores is not None:
warnings.warn(
"`return_all_scores` is now deprecated, if want a similar functionality use `top_k=None` instead of"
" `return_all_scores=True` or `top_k=1` instead of `return_all_scores=False`." , snake_case__ , )
if return_all_scores:
snake_case : List[str] = None
else:
snake_case : Optional[int] = 1
if isinstance(snake_case__ , snake_case__ ):
snake_case : Dict = ClassificationFunction[function_to_apply.upper()]
if function_to_apply is not None:
snake_case : Optional[int] = function_to_apply
return preprocess_params, {}, postprocess_params
def __call__(self : Dict , *snake_case__ : List[str] , **snake_case__ : int ) -> Optional[int]:
'''simple docstring'''
snake_case : Optional[int] = super().__call__(*snake_case__ , **snake_case__ )
# TODO try and retrieve it in a nicer way from _sanitize_parameters.
snake_case : Tuple = "top_k" not in kwargs
if isinstance(args[0] , snake_case__ ) and _legacy:
# This pipeline is odd, and return a list when single item is run
return [result]
else:
return result
def _SCREAMING_SNAKE_CASE (self : Dict , snake_case__ : Tuple , **snake_case__ : Union[str, Any] ) -> Dict[str, GenericTensor]:
'''simple docstring'''
snake_case : int = self.framework
if isinstance(snake_case__ , snake_case__ ):
return self.tokenizer(**snake_case__ , return_tensors=snake_case__ , **snake_case__ )
elif isinstance(snake_case__ , snake_case__ ) and len(snake_case__ ) == 1 and isinstance(inputs[0] , snake_case__ ) and len(inputs[0] ) == 2:
# It used to be valid to use a list of list of list for text pairs, keeping this path for BC
return self.tokenizer(
text=inputs[0][0] , text_pair=inputs[0][1] , return_tensors=snake_case__ , **snake_case__ )
elif isinstance(snake_case__ , snake_case__ ):
# This is likely an invalid usage of the pipeline attempting to pass text pairs.
raise ValueError(
"The pipeline received invalid inputs, if you are trying to send text pairs, you can try to send a"
" dictionary `{\"text\": \"My text\", \"text_pair\": \"My pair\"}` in order to send a text pair." )
return self.tokenizer(snake_case__ , return_tensors=snake_case__ , **snake_case__ )
def _SCREAMING_SNAKE_CASE (self : int , snake_case__ : Union[str, Any] ) -> int:
'''simple docstring'''
return self.model(**snake_case__ )
def _SCREAMING_SNAKE_CASE (self : List[str] , snake_case__ : Optional[Any] , snake_case__ : List[str]=None , snake_case__ : Dict=1 , snake_case__ : Tuple=True ) -> str:
'''simple docstring'''
if function_to_apply is None:
if self.model.config.problem_type == "multi_label_classification" or self.model.config.num_labels == 1:
snake_case : Tuple = ClassificationFunction.SIGMOID
elif self.model.config.problem_type == "single_label_classification" or self.model.config.num_labels > 1:
snake_case : Tuple = ClassificationFunction.SOFTMAX
elif hasattr(self.model.config , "function_to_apply" ) and function_to_apply is None:
snake_case : Tuple = self.model.config.function_to_apply
else:
snake_case : int = ClassificationFunction.NONE
snake_case : Any = model_outputs["logits"][0]
snake_case : List[str] = outputs.numpy()
if function_to_apply == ClassificationFunction.SIGMOID:
snake_case : Optional[Any] = sigmoid(snake_case__ )
elif function_to_apply == ClassificationFunction.SOFTMAX:
snake_case : Union[str, Any] = softmax(snake_case__ )
elif function_to_apply == ClassificationFunction.NONE:
snake_case : Optional[Any] = outputs
else:
raise ValueError(f"""Unrecognized `function_to_apply` argument: {function_to_apply}""" )
if top_k == 1 and _legacy:
return {"label": self.model.config.idalabel[scores.argmax().item()], "score": scores.max().item()}
snake_case : Optional[int] = [
{"label": self.model.config.idalabel[i], "score": score.item()} for i, score in enumerate(snake_case__ )
]
if not _legacy:
dict_scores.sort(key=lambda snake_case__ : x["score"] , reverse=snake_case__ )
if top_k is not None:
snake_case : Optional[int] = dict_scores[:top_k]
return dict_scores
| 59
| 1
|
from __future__ import annotations
__lowerCamelCase = 8.988e9 # units = N * m^s * C^-2
def UpperCamelCase ( __lowerCamelCase : float , __lowerCamelCase : float , __lowerCamelCase : float , __lowerCamelCase : float ):
snake_case : Tuple = abs(chargea * chargea )
if (force, chargea, chargea, distance).count(0 ) != 1:
raise ValueError("One and only one argument must be 0" )
if distance < 0:
raise ValueError("Distance cannot be negative" )
if force == 0:
snake_case : Any = COULOMBS_CONSTANT * charge_product / (distance**2)
return {"force": force}
elif chargea == 0:
snake_case : Tuple = abs(__lowerCamelCase ) * (distance**2) / (COULOMBS_CONSTANT * chargea)
return {"charge1": chargea}
elif chargea == 0:
snake_case : List[str] = abs(__lowerCamelCase ) * (distance**2) / (COULOMBS_CONSTANT * chargea)
return {"charge2": chargea}
elif distance == 0:
snake_case : Tuple = (COULOMBS_CONSTANT * charge_product / abs(__lowerCamelCase )) ** 0.5
return {"distance": distance}
raise ValueError("Exactly one argument must be 0" )
if __name__ == "__main__":
import doctest
doctest.testmod()
| 59
|
from __future__ import annotations
__lowerCamelCase = list[list[int]]
# assigning initial values to the grid
__lowerCamelCase = [
[3, 0, 6, 5, 0, 8, 4, 0, 0],
[5, 2, 0, 0, 0, 0, 0, 0, 0],
[0, 8, 7, 0, 0, 0, 0, 3, 1],
[0, 0, 3, 0, 1, 0, 0, 8, 0],
[9, 0, 0, 8, 6, 3, 0, 0, 5],
[0, 5, 0, 0, 9, 0, 6, 0, 0],
[1, 3, 0, 0, 0, 0, 2, 5, 0],
[0, 0, 0, 0, 0, 0, 0, 7, 4],
[0, 0, 5, 2, 0, 6, 3, 0, 0],
]
# a grid with no solution
__lowerCamelCase = [
[5, 0, 6, 5, 0, 8, 4, 0, 3],
[5, 2, 0, 0, 0, 0, 0, 0, 2],
[1, 8, 7, 0, 0, 0, 0, 3, 1],
[0, 0, 3, 0, 1, 0, 0, 8, 0],
[9, 0, 0, 8, 6, 3, 0, 0, 5],
[0, 5, 0, 0, 9, 0, 6, 0, 0],
[1, 3, 0, 0, 0, 0, 2, 5, 0],
[0, 0, 0, 0, 0, 0, 0, 7, 4],
[0, 0, 5, 2, 0, 6, 3, 0, 0],
]
def UpperCamelCase ( __lowerCamelCase : Matrix , __lowerCamelCase : int , __lowerCamelCase : int , __lowerCamelCase : int ):
for i in range(9 ):
if grid[row][i] == n or grid[i][column] == n:
return False
for i in range(3 ):
for j in range(3 ):
if grid[(row - row % 3) + i][(column - column % 3) + j] == n:
return False
return True
def UpperCamelCase ( __lowerCamelCase : Matrix ):
for i in range(9 ):
for j in range(9 ):
if grid[i][j] == 0:
return i, j
return None
def UpperCamelCase ( __lowerCamelCase : Matrix ):
if location := find_empty_location(__lowerCamelCase ):
snake_case , snake_case : Union[str, Any] = location
else:
# If the location is ``None``, then the grid is solved.
return grid
for digit in range(1 , 10 ):
if is_safe(__lowerCamelCase , __lowerCamelCase , __lowerCamelCase , __lowerCamelCase ):
snake_case : List[Any] = digit
if sudoku(__lowerCamelCase ) is not None:
return grid
snake_case : Union[str, Any] = 0
return None
def UpperCamelCase ( __lowerCamelCase : Matrix ):
for row in grid:
for cell in row:
print(__lowerCamelCase , end=" " )
print()
if __name__ == "__main__":
# make a copy of grid so that you can compare with the unmodified grid
for example_grid in (initial_grid, no_solution):
print("""\nExample grid:\n""" + """=""" * 20)
print_solution(example_grid)
print("""\nExample grid solution:""")
__lowerCamelCase = sudoku(example_grid)
if solution is not None:
print_solution(solution)
else:
print("""Cannot find a solution.""")
| 59
| 1
|
import csv
import tweepy
# Twitter API credentials
__lowerCamelCase = """"""
__lowerCamelCase = """"""
__lowerCamelCase = """"""
__lowerCamelCase = """"""
def UpperCamelCase ( __lowerCamelCase : str ):
# authorize twitter, initialize tweepy
snake_case : Optional[Any] = tweepy.OAuthHandler(__lowerCamelCase , __lowerCamelCase )
auth.set_access_token(__lowerCamelCase , __lowerCamelCase )
snake_case : int = tweepy.API(__lowerCamelCase )
# initialize a list to hold all the tweepy Tweets
snake_case : Union[str, Any] = []
# make initial request for most recent tweets (200 is the maximum allowed count)
snake_case : Dict = api.user_timeline(screen_name=__lowerCamelCase , count=200 )
# save most recent tweets
alltweets.extend(__lowerCamelCase )
# save the id of the oldest tweet less one
snake_case : Tuple = alltweets[-1].id - 1
# keep grabbing tweets until there are no tweets left to grab
while len(__lowerCamelCase ) > 0:
print(f"""getting tweets before {oldest}""" )
# all subsequent requests use the max_id param to prevent duplicates
snake_case : List[Any] = api.user_timeline(
screen_name=__lowerCamelCase , count=200 , max_id=__lowerCamelCase )
# save most recent tweets
alltweets.extend(__lowerCamelCase )
# update the id of the oldest tweet less one
snake_case : List[Any] = alltweets[-1].id - 1
print(f"""...{len(__lowerCamelCase )} tweets downloaded so far""" )
# transform the tweepy tweets into a 2D array that will populate the csv
snake_case : Optional[Any] = [[tweet.id_str, tweet.created_at, tweet.text] for tweet in alltweets]
# write the csv
with open(f"""new_{screen_name}_tweets.csv""" , "w" ) as f:
snake_case : str = csv.writer(__lowerCamelCase )
writer.writerow(["id", "created_at", "text"] )
writer.writerows(__lowerCamelCase )
if __name__ == "__main__":
# pass in the username of the account you want to download
get_all_tweets("""FirePing32""")
| 59
|
import logging
import numpy as np
import pytest
from scipy.linalg import eigh
logging.basicConfig(level=logging.INFO, format="""%(message)s""")
def UpperCamelCase ( __lowerCamelCase : np.ndarray ):
return input_array.reshape((input_array.size, 1) )
def UpperCamelCase ( __lowerCamelCase : np.ndarray , __lowerCamelCase : np.ndarray , __lowerCamelCase : int ):
snake_case : Any = np.nan
for i in range(__lowerCamelCase ):
snake_case : List[str] = features[:, labels == i]
snake_case : Dict = data.mean(1 )
# Centralize the data of class i
snake_case : Optional[Any] = data - column_reshape(__lowerCamelCase )
if i > 0:
# If covariance_sum is not None
covariance_sum += np.dot(__lowerCamelCase , centered_data.T )
else:
# If covariance_sum is np.nan (i.e. first loop)
snake_case : Optional[Any] = np.dot(__lowerCamelCase , centered_data.T )
return covariance_sum / features.shape[1]
def UpperCamelCase ( __lowerCamelCase : np.ndarray , __lowerCamelCase : np.ndarray , __lowerCamelCase : int ):
snake_case : Optional[Any] = features.mean(1 )
snake_case : Tuple = np.nan
for i in range(__lowerCamelCase ):
snake_case : Tuple = features[:, labels == i]
snake_case : Tuple = data.shape[1]
snake_case : List[str] = data.mean(1 )
if i > 0:
# If covariance_sum is not None
covariance_sum += device_data * np.dot(
column_reshape(__lowerCamelCase ) - column_reshape(__lowerCamelCase ) , (column_reshape(__lowerCamelCase ) - column_reshape(__lowerCamelCase )).T , )
else:
# If covariance_sum is np.nan (i.e. first loop)
snake_case : Optional[int] = device_data * np.dot(
column_reshape(__lowerCamelCase ) - column_reshape(__lowerCamelCase ) , (column_reshape(__lowerCamelCase ) - column_reshape(__lowerCamelCase )).T , )
return covariance_sum / features.shape[1]
def UpperCamelCase ( __lowerCamelCase : np.ndarray , __lowerCamelCase : int ):
# Check if the features have been loaded
if features.any():
snake_case : Tuple = features.mean(1 )
# Center the dataset
snake_case : List[str] = features - np.reshape(__lowerCamelCase , (data_mean.size, 1) )
snake_case : Optional[Any] = np.dot(__lowerCamelCase , centered_data.T ) / features.shape[1]
snake_case , snake_case : Dict = np.linalg.eigh(__lowerCamelCase )
# Take all the columns in the reverse order (-1), and then takes only the first
snake_case : Optional[Any] = eigenvectors[:, ::-1][:, 0:dimensions]
# Project the database on the new space
snake_case : Union[str, Any] = np.dot(filtered_eigenvectors.T , __lowerCamelCase )
logging.info("Principal Component Analysis computed" )
return projected_data
else:
logging.basicConfig(level=logging.ERROR , format="%(message)s" , force=__lowerCamelCase )
logging.error("Dataset empty" )
raise AssertionError
def UpperCamelCase ( __lowerCamelCase : np.ndarray , __lowerCamelCase : np.ndarray , __lowerCamelCase : int , __lowerCamelCase : int ):
assert classes > dimensions
# Check if features have been already loaded
if features.any:
snake_case , snake_case : str = eigh(
covariance_between_classes(__lowerCamelCase , __lowerCamelCase , __lowerCamelCase ) , covariance_within_classes(__lowerCamelCase , __lowerCamelCase , __lowerCamelCase ) , )
snake_case : str = eigenvectors[:, ::-1][:, :dimensions]
snake_case , snake_case , snake_case : int = np.linalg.svd(__lowerCamelCase )
snake_case : List[Any] = svd_matrix[:, 0:dimensions]
snake_case : Optional[Any] = np.dot(filtered_svd_matrix.T , __lowerCamelCase )
logging.info("Linear Discriminant Analysis computed" )
return projected_data
else:
logging.basicConfig(level=logging.ERROR , format="%(message)s" , force=__lowerCamelCase )
logging.error("Dataset empty" )
raise AssertionError
def UpperCamelCase ( ):
# Create dummy dataset with 2 classes and 3 features
snake_case : str = np.array([[1, 2, 3, 4, 5], [2, 3, 4, 5, 6], [3, 4, 5, 6, 7]] )
snake_case : Union[str, Any] = np.array([0, 0, 0, 1, 1] )
snake_case : List[Any] = 2
snake_case : Any = 2
# Assert that the function raises an AssertionError if dimensions > classes
with pytest.raises(__lowerCamelCase ) as error_info:
snake_case : str = linear_discriminant_analysis(
__lowerCamelCase , __lowerCamelCase , __lowerCamelCase , __lowerCamelCase )
if isinstance(__lowerCamelCase , np.ndarray ):
raise AssertionError(
"Did not raise AssertionError for dimensions > classes" )
assert error_info.type is AssertionError
def UpperCamelCase ( ):
snake_case : List[str] = np.array([[1, 2, 3], [4, 5, 6], [7, 8, 9]] )
snake_case : List[str] = 2
snake_case : int = np.array([[6.9282_0323, 8.6602_5404, 10.3923_0485], [3.0, 3.0, 3.0]] )
with pytest.raises(__lowerCamelCase ) as error_info:
snake_case : Union[str, Any] = principal_component_analysis(__lowerCamelCase , __lowerCamelCase )
if not np.allclose(__lowerCamelCase , __lowerCamelCase ):
raise AssertionError
assert error_info.type is AssertionError
if __name__ == "__main__":
import doctest
doctest.testmod()
| 59
| 1
|
import pytest
from datasets import inspect_metric, list_metrics, load_metric
@pytest.fixture
def UpperCamelCase ( __lowerCamelCase : Optional[int] ):
monkeypatch.setattr("datasets.utils.deprecation_utils._emitted_deprecation_warnings" , set() )
@pytest.fixture
def UpperCamelCase ( __lowerCamelCase : str ):
class UpperCAmelCase :
def __init__(self : Optional[int] , snake_case__ : str ) -> Any:
'''simple docstring'''
snake_case : List[str] = metric_id
class UpperCAmelCase :
A__ : List[str] = [MetricMock(A_ ) for metric_id in ["accuracy", "mse", "precision", "codeparrot/apps_metric"]]
def _SCREAMING_SNAKE_CASE (self : int ) -> List[str]:
'''simple docstring'''
return self._metrics
monkeypatch.setattr("datasets.inspect.huggingface_hub" , HfhMock() )
@pytest.mark.parametrize(
"func, args" , [(load_metric, ("metrics/mse",)), (list_metrics, ()), (inspect_metric, ("metrics/mse", "tmp_path"))] )
def UpperCamelCase ( __lowerCamelCase : Optional[int] , __lowerCamelCase : Any , __lowerCamelCase : Any , __lowerCamelCase : int , __lowerCamelCase : Any ):
if "tmp_path" in args:
snake_case : str = tuple(arg if arg != "tmp_path" else tmp_path for arg in args )
with pytest.warns(__lowerCamelCase , match="https://huggingface.co/docs/evaluate" ):
func(*__lowerCamelCase )
| 59
|
import pytest
from datasets import inspect_metric, list_metrics, load_metric
@pytest.fixture
def UpperCamelCase ( __lowerCamelCase : Optional[int] ):
monkeypatch.setattr("datasets.utils.deprecation_utils._emitted_deprecation_warnings" , set() )
@pytest.fixture
def UpperCamelCase ( __lowerCamelCase : str ):
class UpperCAmelCase :
def __init__(self : Optional[int] , snake_case__ : str ) -> Any:
'''simple docstring'''
snake_case : List[str] = metric_id
class UpperCAmelCase :
A__ : List[str] = [MetricMock(A_ ) for metric_id in ["accuracy", "mse", "precision", "codeparrot/apps_metric"]]
def _SCREAMING_SNAKE_CASE (self : int ) -> List[str]:
'''simple docstring'''
return self._metrics
monkeypatch.setattr("datasets.inspect.huggingface_hub" , HfhMock() )
@pytest.mark.parametrize(
"func, args" , [(load_metric, ("metrics/mse",)), (list_metrics, ()), (inspect_metric, ("metrics/mse", "tmp_path"))] )
def UpperCamelCase ( __lowerCamelCase : Optional[int] , __lowerCamelCase : Any , __lowerCamelCase : Any , __lowerCamelCase : int , __lowerCamelCase : Any ):
if "tmp_path" in args:
snake_case : str = tuple(arg if arg != "tmp_path" else tmp_path for arg in args )
with pytest.warns(__lowerCamelCase , match="https://huggingface.co/docs/evaluate" ):
func(*__lowerCamelCase )
| 59
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|
# A Bipartite Graph is a graph whose vertices can be divided into two independent sets,
# U and V such that every edge (u, v) either connects a vertex from U to V or a vertex
# from V to U. In other words, for every edge (u, v), either u belongs to U and v to V,
# or u belongs to V and v to U. We can also say that there is no edge that connects
# vertices of same set.
def UpperCamelCase ( __lowerCamelCase : Dict ):
snake_case : Union[str, Any] = [False] * len(__lowerCamelCase )
snake_case : Union[str, Any] = [-1] * len(__lowerCamelCase )
def dfs(__lowerCamelCase : Tuple , __lowerCamelCase : str ):
snake_case : str = True
snake_case : int = c
for u in graph[v]:
if not visited[u]:
dfs(__lowerCamelCase , 1 - c )
for i in range(len(__lowerCamelCase ) ):
if not visited[i]:
dfs(__lowerCamelCase , 0 )
for i in range(len(__lowerCamelCase ) ):
for j in graph[i]:
if color[i] == color[j]:
return False
return True
# Adjacency list of graph
__lowerCamelCase = {0: [1, 3], 1: [0, 2], 2: [1, 3], 3: [0, 2], 4: []}
print(check_bipartite_dfs(graph))
| 59
|
import argparse
import dataclasses
import json
import logging
import os
import shutil
from typing import List, Optional
import datasets
from accelerate import Accelerator
from datasets import load_dataset
from finetuning import finetune
from tqdm.auto import tqdm
import transformers
from transformers import AutoConfig, set_seed
from transformers.trainer_utils import IntervalStrategy
__lowerCamelCase = logging.getLogger(__name__)
__lowerCamelCase = """pytorch_model.bin"""
@dataclasses.dataclass
class UpperCAmelCase :
A__ : str = dataclasses.field(
metadata={"help": "Path to pretrained model or model identifier from huggingface.co/models."} )
A__ : Optional[str] = dataclasses.field(
default=A_ ,metadata={"help": "Where do you want to store the pretrained models downloaded from huggingface.co."} ,)
@dataclasses.dataclass
class UpperCAmelCase :
A__ : str = dataclasses.field(metadata={"help": "A csv or a json file containing the training data."} )
A__ : str = dataclasses.field(metadata={"help": "A csv or a json file containing the data to predict on."} )
A__ : Optional[str] = dataclasses.field(
default=A_ ,metadata={"help": "A csv or a json file containing the validation data."} )
A__ : Optional[str] = dataclasses.field(
default=A_ ,metadata={"help": "The name of the task to train on."} ,)
A__ : Optional[List[str]] = dataclasses.field(
default=A_ ,metadata={"help": "The list of labels for the task."} )
@dataclasses.dataclass
class UpperCAmelCase :
A__ : str = dataclasses.field(
metadata={"help": "The output directory where the model predictions and checkpoints will be written."} )
A__ : Optional[str] = dataclasses.field(
default="accuracy" ,metadata={"help": "The evaluation metric used for the task."} )
A__ : Optional[str] = dataclasses.field(
default="no" ,metadata={
"help": "The evaluation strategy to adopt during training. Possible values are: [\"no\", \"step\", \"epoch]"
} ,)
A__ : Optional[int] = dataclasses.field(
default=10 ,metadata={"help": "Number of evaluation calls with no improvement after which training will be stopped."} ,)
A__ : Optional[float] = dataclasses.field(
default=0.0 ,metadata={
"help": "How much the specified evaluation metric must improve to satisfy early stopping conditions."
} ,)
A__ : Optional[bool] = dataclasses.field(
default=A_ ,metadata={"help": "Whether to filter the pseudo-labeled data based on the confidence score."} ,)
A__ : Optional[bool] = dataclasses.field(
default=A_ ,metadata={"help": "Whether to filter the pseudo-labeled data based on the validation performance."} ,)
A__ : Optional[bool] = dataclasses.field(
default=A_ ,metadata={"help": "Whether to fine-tune on labeled data after pseudo training."} ,)
A__ : Optional[float] = dataclasses.field(
default=0.0 ,metadata={"help": "Confidence threshold for pseudo-labeled data filtering."} ,)
A__ : Optional[int] = dataclasses.field(
default=1_00 ,metadata={"help": "Number of evaluation calls with no improvement after which training will be stopped."} ,)
A__ : Optional[int] = dataclasses.field(
default=A_ ,metadata={"help": "Random seed for initialization."} ,)
def UpperCamelCase ( __lowerCamelCase : int , __lowerCamelCase : Tuple , __lowerCamelCase : Union[str, Any] , __lowerCamelCase : Tuple , __lowerCamelCase : Dict , __lowerCamelCase : Optional[int] ):
snake_case : Tuple = datasets.concatenate_datasets([infer_input, infer_output] , axis=1 )
if args.do_filter_by_confidence:
snake_case : Optional[int] = dataset.filter(lambda __lowerCamelCase : example["probability"] > args.confidence_threshold )
if args.do_filter_by_val_performance:
assert eval_result >= 0.0 and eval_result <= 1.0
snake_case : int = int(eval_result * len(__lowerCamelCase ) )
print(__lowerCamelCase )
snake_case : List[str] = dataset.sort("probability" , reverse=__lowerCamelCase )
snake_case : Tuple = dataset.select(range(__lowerCamelCase ) )
snake_case : List[Any] = dataset.remove_columns(["label", "probability"] )
snake_case : Any = dataset.rename_column("prediction" , "label" )
snake_case : str = dataset.map(lambda __lowerCamelCase : {"label": idalabel[example["label"]]} )
snake_case : List[str] = dataset.shuffle(seed=args.seed )
snake_case : int = os.path.join(__lowerCamelCase , f"""train_pseudo.{args.data_file_extension}""" )
if args.data_file_extension == "csv":
dataset.to_csv(__lowerCamelCase , index=__lowerCamelCase )
else:
dataset.to_json(__lowerCamelCase )
def UpperCamelCase ( __lowerCamelCase : Optional[int] , __lowerCamelCase : str , __lowerCamelCase : Optional[int] , __lowerCamelCase : Tuple , **__lowerCamelCase : List[Any] ):
snake_case : int = Accelerator()
# Make one log on every process with the configuration for debugging.
logging.basicConfig(
format="%(asctime)s - %(levelname)s - %(name)s - %(message)s" , datefmt="%m/%d/%Y %H:%M:%S" , level=logging.INFO , )
logger.info(accelerator.state )
# Setup logging, we only want one process per machine to log things on the
# screen. accelerator.is_local_main_process is only True for one process per
# machine.
logger.setLevel(logging.INFO if accelerator.is_local_main_process else logging.ERROR )
if accelerator.is_local_main_process:
datasets.utils.logging.set_verbosity_warning()
transformers.utils.logging.set_verbosity_info()
else:
datasets.utils.logging.set_verbosity_error()
transformers.utils.logging.set_verbosity_error()
snake_case : Dict = STModelArguments(model_name_or_path=__lowerCamelCase )
snake_case : Tuple = STDataArguments(train_file=__lowerCamelCase , infer_file=__lowerCamelCase )
snake_case : str = STTrainingArguments(output_dir=__lowerCamelCase )
snake_case : int = argparse.Namespace()
for arg_class in (model_args, data_args, training_args):
for key, value in vars(__lowerCamelCase ).items():
setattr(__lowerCamelCase , __lowerCamelCase , __lowerCamelCase )
for key, value in kwargs.items():
if hasattr(__lowerCamelCase , __lowerCamelCase ):
setattr(__lowerCamelCase , __lowerCamelCase , __lowerCamelCase )
# Sanity checks
snake_case : List[str] = {}
snake_case : Optional[int] = None
# You need to provide the training data and the data to predict on
assert args.train_file is not None
assert args.infer_file is not None
snake_case : str = args.train_file
snake_case : Tuple = args.infer_file
if args.evaluation_strategy != IntervalStrategy.NO.value:
assert args.eval_file is not None
snake_case : Tuple = args.eval_file
for key in data_files:
snake_case : List[Any] = data_files[key].split("." )[-1]
assert extension in ["csv", "json"], f"""`{key}_file` should be a csv or a json file."""
if args.data_file_extension is None:
snake_case : Union[str, Any] = extension
else:
assert extension == args.data_file_extension, f"""`{key}_file` should be a {args.data_file_extension} file`."""
assert (
args.eval_metric in datasets.list_metrics()
), f"""{args.eval_metric} not in the list of supported metrics {datasets.list_metrics()}."""
# If passed along, set the training seed now.
if args.seed is not None:
set_seed(args.seed )
logger.info("Creating the initial data directory for self-training..." )
snake_case : List[Any] = f"""{args.output_dir}/self-train_iter-{{}}""".format
snake_case : Optional[int] = data_dir_format(0 )
if accelerator.is_main_process:
if args.output_dir is not None:
os.makedirs(args.output_dir , exist_ok=__lowerCamelCase )
os.makedirs(__lowerCamelCase , exist_ok=__lowerCamelCase )
accelerator.wait_for_everyone()
snake_case : Dict = None
snake_case : Union[str, Any] = None
snake_case : Tuple = 0
snake_case : List[Any] = False
# Show the progress bar
snake_case : List[Any] = tqdm(range(args.max_selftrain_iterations ) , disable=not accelerator.is_local_main_process )
# Self-train
for iteration in range(0 , int(args.max_selftrain_iterations ) ):
snake_case : str = data_dir_format(__lowerCamelCase )
assert os.path.exists(__lowerCamelCase )
# Stage 1: initial fine-tuning for iteration = 0 or pseudo-training for
# iteration > 0
snake_case : Dict = os.path.join(__lowerCamelCase , "stage-1" )
snake_case : Optional[Any] = {
"accelerator": accelerator,
"model_name_or_path": args.model_name_or_path,
"cache_dir": args.cache_dir,
"do_train": True,
"train_file": data_files["train"] if iteration == 0 else data_files["train_pseudo"],
"do_eval": True if args.eval_file is not None else False,
"eval_file": data_files["eval"],
"do_predict": True,
"infer_file": data_files["infer"],
"task_name": args.task_name,
"label_list": args.label_list,
"output_dir": current_output_dir,
"eval_metric": args.eval_metric,
"evaluation_strategy": args.evaluation_strategy,
"early_stopping_patience": args.early_stopping_patience,
"early_stopping_threshold": args.early_stopping_threshold,
"seed": args.seed,
}
# Add additional training arguments
for key, value in kwargs.items():
if key not in arguments_dict and not hasattr(__lowerCamelCase , __lowerCamelCase ):
arguments_dict.update({key: value} )
snake_case : int = os.path.join(__lowerCamelCase , "best-checkpoint" , __lowerCamelCase )
if os.path.exists(__lowerCamelCase ):
logger.info(
"Found existing model checkpoint at %s. Skipping self-training: iteration: %d, stage: 1." , __lowerCamelCase , __lowerCamelCase , )
else:
logger.info("***** Running self-training: iteration: %d, stage: 1 *****" , __lowerCamelCase )
finetune(**__lowerCamelCase )
accelerator.wait_for_everyone()
assert os.path.exists(__lowerCamelCase )
logger.info("Self-training job completed: iteration: %d, stage: 1." , __lowerCamelCase )
if iteration > 0 and args.finetune_on_labeled_data:
# Stage 2 (optional): fine-tuning on the original labeled data
snake_case : str = os.path.join(__lowerCamelCase , "best-checkpoint" )
snake_case : Dict = os.path.join(__lowerCamelCase , "stage-2" )
# Update arguments_dict
snake_case : List[str] = model_path
snake_case : Optional[Any] = data_files["train"]
snake_case : Optional[Any] = current_output_dir
snake_case : Union[str, Any] = os.path.join(__lowerCamelCase , "best-checkpoint" , __lowerCamelCase )
if os.path.exists(__lowerCamelCase ):
logger.info(
"Found existing model checkpoint at %s. Skipping self-training: iteration: %d, stage: 2." , __lowerCamelCase , __lowerCamelCase , )
else:
logger.info("***** Running self-training: iteration: %d, stage: 2 *****" , __lowerCamelCase )
finetune(**__lowerCamelCase )
accelerator.wait_for_everyone()
assert os.path.exists(__lowerCamelCase )
logger.info("Self-training job completed: iteration: %d, stage: 2." , __lowerCamelCase )
snake_case : int = iteration
snake_case : Tuple = data_dir_format(iteration + 1 )
snake_case : Tuple = AutoConfig.from_pretrained(os.path.join(__lowerCamelCase , "best-checkpoint" ) )
snake_case : Optional[int] = config.idalabel
snake_case : List[Any] = os.path.join(__lowerCamelCase , "eval_results_best-checkpoint.json" )
snake_case : Union[str, Any] = os.path.join(__lowerCamelCase , "test_results_best-checkpoint.json" )
assert os.path.exists(__lowerCamelCase )
with open(__lowerCamelCase , "r" ) as f:
snake_case : Dict = float(json.load(__lowerCamelCase )[args.eval_metric] )
snake_case : Optional[int] = os.path.join(__lowerCamelCase , "infer_output_best-checkpoint.csv" )
assert os.path.exists(__lowerCamelCase )
# Loading the dataset from local csv or json files.
snake_case : Optional[Any] = load_dataset(args.data_file_extension , data_files={"data": data_files["infer"]} )["data"]
snake_case : Dict = load_dataset("csv" , data_files={"data": infer_output_file} )["data"]
if accelerator.is_main_process:
os.makedirs(__lowerCamelCase , exist_ok=__lowerCamelCase )
shutil.copy(__lowerCamelCase , os.path.join(__lowerCamelCase , f"""eval_results_iter-{iteration}.json""" ) )
if os.path.exists(__lowerCamelCase ):
shutil.copy(__lowerCamelCase , os.path.join(__lowerCamelCase , f"""test_results_iter-{iteration}.json""" ) )
create_pseudo_labeled_data(__lowerCamelCase , __lowerCamelCase , __lowerCamelCase , __lowerCamelCase , __lowerCamelCase , __lowerCamelCase )
accelerator.wait_for_everyone()
snake_case : str = os.path.join(__lowerCamelCase , f"""train_pseudo.{args.data_file_extension}""" )
if args.evaluation_strategy != IntervalStrategy.NO.value:
snake_case : List[Any] = eval_result
if best_iteration is None:
snake_case : List[Any] = new_iteration
snake_case : int = new_eval_result
else:
if new_eval_result - best_eval_result > args.early_stopping_threshold:
snake_case : int = new_iteration
snake_case : Union[str, Any] = new_eval_result
snake_case : str = 0
else:
if new_eval_result == best_eval_result:
snake_case : Any = new_iteration
snake_case : Union[str, Any] = new_eval_result
early_stopping_patience_counter += 1
if early_stopping_patience_counter >= args.early_stopping_patience:
snake_case : Tuple = True
progress_bar.update(1 )
if should_training_stop:
break
if best_iteration is not None:
# Save the best iteration
logger.info("Best iteration: %d" , __lowerCamelCase )
logger.info("Best evaluation result: %s = %f" , args.eval_metric , __lowerCamelCase )
accelerator.wait_for_everyone()
if accelerator.is_main_process:
shutil.copy(
os.path.join(__lowerCamelCase , f"""eval_results_iter-{iteration}.json""" ) , os.path.join(__lowerCamelCase , "eval_results_best-iteration.json" ) , )
else:
# Assume that the last iteration is the best
logger.info("Best iteration: %d" , args.max_selftrain_iterations - 1 )
logger.info("Best evaluation result: %s = %f" , args.eval_metric , __lowerCamelCase )
accelerator.wait_for_everyone()
if accelerator.is_main_process:
shutil.copy(
os.path.join(__lowerCamelCase , f"""eval_results_iter-{args.max_selftrain_iterations - 1}.json""" ) , os.path.join(__lowerCamelCase , "eval_results_best-iteration.json" ) , )
| 59
| 1
|
import pprint
import requests
__lowerCamelCase = """https://zenquotes.io/api"""
def UpperCamelCase ( ):
return requests.get(API_ENDPOINT_URL + "/today" ).json()
def UpperCamelCase ( ):
return requests.get(API_ENDPOINT_URL + "/random" ).json()
if __name__ == "__main__":
__lowerCamelCase = random_quotes()
pprint.pprint(response)
| 59
|
from typing import TYPE_CHECKING
from ...utils import (
OptionalDependencyNotAvailable,
_LazyModule,
is_flax_available,
is_sentencepiece_available,
is_tf_available,
is_tokenizers_available,
is_torch_available,
)
__lowerCamelCase = {"""configuration_xglm""": ["""XGLM_PRETRAINED_CONFIG_ARCHIVE_MAP""", """XGLMConfig"""]}
try:
if not is_sentencepiece_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = ["""XGLMTokenizer"""]
try:
if not is_tokenizers_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = ["""XGLMTokenizerFast"""]
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = [
"""XGLM_PRETRAINED_MODEL_ARCHIVE_LIST""",
"""XGLMForCausalLM""",
"""XGLMModel""",
"""XGLMPreTrainedModel""",
]
try:
if not is_flax_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = [
"""FlaxXGLMForCausalLM""",
"""FlaxXGLMModel""",
"""FlaxXGLMPreTrainedModel""",
]
try:
if not is_tf_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = [
"""TF_XGLM_PRETRAINED_MODEL_ARCHIVE_LIST""",
"""TFXGLMForCausalLM""",
"""TFXGLMModel""",
"""TFXGLMPreTrainedModel""",
]
if TYPE_CHECKING:
from .configuration_xglm import XGLM_PRETRAINED_CONFIG_ARCHIVE_MAP, XGLMConfig
try:
if not is_sentencepiece_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .tokenization_xglm import XGLMTokenizer
try:
if not is_tokenizers_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .tokenization_xglm_fast import XGLMTokenizerFast
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_xglm import XGLM_PRETRAINED_MODEL_ARCHIVE_LIST, XGLMForCausalLM, XGLMModel, XGLMPreTrainedModel
try:
if not is_flax_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_flax_xglm import FlaxXGLMForCausalLM, FlaxXGLMModel, FlaxXGLMPreTrainedModel
try:
if not is_tf_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_tf_xglm import (
TF_XGLM_PRETRAINED_MODEL_ARCHIVE_LIST,
TFXGLMForCausalLM,
TFXGLMModel,
TFXGLMPreTrainedModel,
)
else:
import sys
__lowerCamelCase = _LazyModule(__name__, globals()["""__file__"""], _import_structure)
| 59
| 1
|
import importlib
import inspect
import json
import os
import re
import shutil
import sys
from pathlib import Path
from typing import Dict, Optional, Union
from urllib import request
from huggingface_hub import HfFolder, cached_download, hf_hub_download, model_info
from packaging import version
from .. import __version__
from . import DIFFUSERS_DYNAMIC_MODULE_NAME, HF_MODULES_CACHE, logging
__lowerCamelCase = (
"""https://raw.githubusercontent.com/huggingface/diffusers/{revision}/examples/community/{pipeline}.py"""
)
__lowerCamelCase = logging.get_logger(__name__) # pylint: disable=invalid-name
def UpperCamelCase ( ):
snake_case : Optional[Any] = "https://pypi.org/pypi/diffusers/json"
snake_case : List[str] = json.loads(request.urlopen(__lowerCamelCase ).read() )["releases"].keys()
return sorted(__lowerCamelCase , key=lambda __lowerCamelCase : version.Version(__lowerCamelCase ) )
def UpperCamelCase ( ):
# This function has already been executed if HF_MODULES_CACHE already is in the Python path.
if HF_MODULES_CACHE in sys.path:
return
sys.path.append(__lowerCamelCase )
os.makedirs(__lowerCamelCase , exist_ok=__lowerCamelCase )
snake_case : int = Path(__lowerCamelCase ) / "__init__.py"
if not init_path.exists():
init_path.touch()
def UpperCamelCase ( __lowerCamelCase : Union[str, os.PathLike] ):
init_hf_modules()
snake_case : Union[str, Any] = Path(__lowerCamelCase ) / name
# If the parent module does not exist yet, recursively create it.
if not dynamic_module_path.parent.exists():
create_dynamic_module(dynamic_module_path.parent )
os.makedirs(__lowerCamelCase , exist_ok=__lowerCamelCase )
snake_case : Dict = dynamic_module_path / "__init__.py"
if not init_path.exists():
init_path.touch()
def UpperCamelCase ( __lowerCamelCase : Union[str, Any] ):
with open(__lowerCamelCase , "r" , encoding="utf-8" ) as f:
snake_case : Tuple = f.read()
# Imports of the form `import .xxx`
snake_case : Any = re.findall("^\s*import\s+\.(\S+)\s*$" , __lowerCamelCase , flags=re.MULTILINE )
# Imports of the form `from .xxx import yyy`
relative_imports += re.findall("^\s*from\s+\.(\S+)\s+import" , __lowerCamelCase , flags=re.MULTILINE )
# Unique-ify
return list(set(__lowerCamelCase ) )
def UpperCamelCase ( __lowerCamelCase : int ):
snake_case : Union[str, Any] = False
snake_case : str = [module_file]
snake_case : str = []
# Let's recurse through all relative imports
while not no_change:
snake_case : int = []
for f in files_to_check:
new_imports.extend(get_relative_imports(__lowerCamelCase ) )
snake_case : Any = Path(__lowerCamelCase ).parent
snake_case : str = [str(module_path / m ) for m in new_imports]
snake_case : Tuple = [f for f in new_import_files if f not in all_relative_imports]
snake_case : Optional[int] = [f"""{f}.py""" for f in new_import_files]
snake_case : Optional[Any] = len(__lowerCamelCase ) == 0
all_relative_imports.extend(__lowerCamelCase )
return all_relative_imports
def UpperCamelCase ( __lowerCamelCase : Union[str, Any] ):
with open(__lowerCamelCase , "r" , encoding="utf-8" ) as f:
snake_case : int = f.read()
# Imports of the form `import xxx`
snake_case : Union[str, Any] = re.findall("^\s*import\s+(\S+)\s*$" , __lowerCamelCase , flags=re.MULTILINE )
# Imports of the form `from xxx import yyy`
imports += re.findall("^\s*from\s+(\S+)\s+import" , __lowerCamelCase , flags=re.MULTILINE )
# Only keep the top-level module
snake_case : Dict = [imp.split("." )[0] for imp in imports if not imp.startswith("." )]
# Unique-ify and test we got them all
snake_case : Optional[Any] = list(set(__lowerCamelCase ) )
snake_case : Union[str, Any] = []
for imp in imports:
try:
importlib.import_module(__lowerCamelCase )
except ImportError:
missing_packages.append(__lowerCamelCase )
if len(__lowerCamelCase ) > 0:
raise ImportError(
"This modeling file requires the following packages that were not found in your environment: "
f"""{', '.join(__lowerCamelCase )}. Run `pip install {' '.join(__lowerCamelCase )}`""" )
return get_relative_imports(__lowerCamelCase )
def UpperCamelCase ( __lowerCamelCase : int , __lowerCamelCase : Any ):
snake_case : List[str] = module_path.replace(os.path.sep , "." )
snake_case : List[Any] = importlib.import_module(__lowerCamelCase )
if class_name is None:
return find_pipeline_class(__lowerCamelCase )
return getattr(__lowerCamelCase , __lowerCamelCase )
def UpperCamelCase ( __lowerCamelCase : List[str] ):
from ..pipelines import DiffusionPipeline
snake_case : List[str] = dict(inspect.getmembers(__lowerCamelCase , inspect.isclass ) )
snake_case : str = None
for cls_name, cls in cls_members.items():
if (
cls_name != DiffusionPipeline.__name__
and issubclass(cls , __lowerCamelCase )
and cls.__module__.split("." )[0] != "diffusers"
):
if pipeline_class is not None:
raise ValueError(
f"""Multiple classes that inherit from {DiffusionPipeline.__name__} have been found:"""
f""" {pipeline_class.__name__}, and {cls_name}. Please make sure to define only one in"""
f""" {loaded_module}.""" )
snake_case : Dict = cls
return pipeline_class
def UpperCamelCase ( __lowerCamelCase : Union[str, os.PathLike] , __lowerCamelCase : str , __lowerCamelCase : Optional[Union[str, os.PathLike]] = None , __lowerCamelCase : bool = False , __lowerCamelCase : bool = False , __lowerCamelCase : Optional[Dict[str, str]] = None , __lowerCamelCase : Optional[Union[bool, str]] = None , __lowerCamelCase : Optional[str] = None , __lowerCamelCase : bool = False , ):
snake_case : List[str] = str(__lowerCamelCase )
snake_case : Optional[Any] = os.path.join(__lowerCamelCase , __lowerCamelCase )
if os.path.isfile(__lowerCamelCase ):
snake_case : Optional[int] = module_file_or_url
snake_case : List[str] = "local"
elif pretrained_model_name_or_path.count("/" ) == 0:
snake_case : Optional[Any] = get_diffusers_versions()
# cut ".dev0"
snake_case : str = "v" + ".".join(__version__.split("." )[:3] )
# retrieve github version that matches
if revision is None:
snake_case : Dict = latest_version if latest_version[1:] in available_versions else "main"
logger.info(f"""Defaulting to latest_version: {revision}.""" )
elif revision in available_versions:
snake_case : Dict = f"""v{revision}"""
elif revision == "main":
snake_case : str = revision
else:
raise ValueError(
f"""`custom_revision`: {revision} does not exist. Please make sure to choose one of"""
f""" {', '.join(available_versions + ['main'] )}.""" )
# community pipeline on GitHub
snake_case : Any = COMMUNITY_PIPELINES_URL.format(revision=__lowerCamelCase , pipeline=__lowerCamelCase )
try:
snake_case : List[Any] = cached_download(
__lowerCamelCase , cache_dir=__lowerCamelCase , force_download=__lowerCamelCase , proxies=__lowerCamelCase , resume_download=__lowerCamelCase , local_files_only=__lowerCamelCase , use_auth_token=__lowerCamelCase , )
snake_case : Tuple = "git"
snake_case : Optional[int] = pretrained_model_name_or_path + ".py"
except EnvironmentError:
logger.error(f"""Could not locate the {module_file} inside {pretrained_model_name_or_path}.""" )
raise
else:
try:
# Load from URL or cache if already cached
snake_case : List[Any] = hf_hub_download(
__lowerCamelCase , __lowerCamelCase , cache_dir=__lowerCamelCase , force_download=__lowerCamelCase , proxies=__lowerCamelCase , resume_download=__lowerCamelCase , local_files_only=__lowerCamelCase , use_auth_token=__lowerCamelCase , )
snake_case : Union[str, Any] = os.path.join("local" , "--".join(pretrained_model_name_or_path.split("/" ) ) )
except EnvironmentError:
logger.error(f"""Could not locate the {module_file} inside {pretrained_model_name_or_path}.""" )
raise
# Check we have all the requirements in our environment
snake_case : List[str] = check_imports(__lowerCamelCase )
# Now we move the module inside our cached dynamic modules.
snake_case : Tuple = DIFFUSERS_DYNAMIC_MODULE_NAME + os.path.sep + submodule
create_dynamic_module(__lowerCamelCase )
snake_case : Union[str, Any] = Path(__lowerCamelCase ) / full_submodule
if submodule == "local" or submodule == "git":
# We always copy local files (we could hash the file to see if there was a change, and give them the name of
# that hash, to only copy when there is a modification but it seems overkill for now).
# The only reason we do the copy is to avoid putting too many folders in sys.path.
shutil.copy(__lowerCamelCase , submodule_path / module_file )
for module_needed in modules_needed:
snake_case : str = f"""{module_needed}.py"""
shutil.copy(os.path.join(__lowerCamelCase , __lowerCamelCase ) , submodule_path / module_needed )
else:
# Get the commit hash
# TODO: we will get this info in the etag soon, so retrieve it from there and not here.
if isinstance(__lowerCamelCase , __lowerCamelCase ):
snake_case : Any = use_auth_token
elif use_auth_token is True:
snake_case : Dict = HfFolder.get_token()
else:
snake_case : Optional[Any] = None
snake_case : Optional[Any] = model_info(__lowerCamelCase , revision=__lowerCamelCase , token=__lowerCamelCase ).sha
# The module file will end up being placed in a subfolder with the git hash of the repo. This way we get the
# benefit of versioning.
snake_case : Any = submodule_path / commit_hash
snake_case : List[Any] = full_submodule + os.path.sep + commit_hash
create_dynamic_module(__lowerCamelCase )
if not (submodule_path / module_file).exists():
shutil.copy(__lowerCamelCase , submodule_path / module_file )
# Make sure we also have every file with relative
for module_needed in modules_needed:
if not (submodule_path / module_needed).exists():
get_cached_module_file(
__lowerCamelCase , f"""{module_needed}.py""" , cache_dir=__lowerCamelCase , force_download=__lowerCamelCase , resume_download=__lowerCamelCase , proxies=__lowerCamelCase , use_auth_token=__lowerCamelCase , revision=__lowerCamelCase , local_files_only=__lowerCamelCase , )
return os.path.join(__lowerCamelCase , __lowerCamelCase )
def UpperCamelCase ( __lowerCamelCase : Union[str, os.PathLike] , __lowerCamelCase : str , __lowerCamelCase : Optional[str] = None , __lowerCamelCase : Optional[Union[str, os.PathLike]] = None , __lowerCamelCase : bool = False , __lowerCamelCase : bool = False , __lowerCamelCase : Optional[Dict[str, str]] = None , __lowerCamelCase : Optional[Union[bool, str]] = None , __lowerCamelCase : Optional[str] = None , __lowerCamelCase : bool = False , **__lowerCamelCase : Tuple , ):
snake_case : int = get_cached_module_file(
__lowerCamelCase , __lowerCamelCase , cache_dir=__lowerCamelCase , force_download=__lowerCamelCase , resume_download=__lowerCamelCase , proxies=__lowerCamelCase , use_auth_token=__lowerCamelCase , revision=__lowerCamelCase , local_files_only=__lowerCamelCase , )
return get_class_in_module(__lowerCamelCase , final_module.replace(".py" , "" ) )
| 59
|
from ...configuration_utils import PretrainedConfig
from ...utils import logging
__lowerCamelCase = logging.get_logger(__name__)
__lowerCamelCase = {
# See all MEGATRON_BERT models at https://huggingface.co/models?filter=bert
}
class UpperCAmelCase ( A_ ):
A__ : List[str] = "megatron-bert"
def __init__(self : Optional[int] , snake_case__ : List[str]=2_90_56 , snake_case__ : List[Any]=10_24 , snake_case__ : str=24 , snake_case__ : Tuple=16 , snake_case__ : Union[str, Any]=40_96 , snake_case__ : str="gelu" , snake_case__ : str=0.1 , snake_case__ : Optional[int]=0.1 , snake_case__ : Tuple=5_12 , snake_case__ : Union[str, Any]=2 , snake_case__ : Dict=0.02 , snake_case__ : List[Any]=1e-12 , snake_case__ : int=0 , snake_case__ : Tuple="absolute" , snake_case__ : Any=True , **snake_case__ : Union[str, Any] , ) -> Optional[Any]:
'''simple docstring'''
super().__init__(pad_token_id=snake_case__ , **snake_case__ )
snake_case : Tuple = vocab_size
snake_case : str = hidden_size
snake_case : str = num_hidden_layers
snake_case : str = num_attention_heads
snake_case : Optional[int] = hidden_act
snake_case : int = intermediate_size
snake_case : List[str] = hidden_dropout_prob
snake_case : Union[str, Any] = attention_probs_dropout_prob
snake_case : Dict = max_position_embeddings
snake_case : List[str] = type_vocab_size
snake_case : List[str] = initializer_range
snake_case : Tuple = layer_norm_eps
snake_case : int = position_embedding_type
snake_case : str = use_cache
| 59
| 1
|
import argparse
import json
from pathlib import Path
import requests
import torch
from huggingface_hub import cached_download, hf_hub_url
from PIL import Image
from transformers import DPTConfig, DPTForDepthEstimation, DPTForSemanticSegmentation, DPTImageProcessor
from transformers.utils import logging
logging.set_verbosity_info()
__lowerCamelCase = logging.get_logger(__name__)
def UpperCamelCase ( __lowerCamelCase : Tuple ):
snake_case : List[str] = DPTConfig(embedding_type="hybrid" )
if "large" in checkpoint_url:
snake_case : List[str] = 1024
snake_case : Optional[int] = 4096
snake_case : int = 24
snake_case : Any = 16
snake_case : int = [5, 11, 17, 23]
snake_case : Tuple = [256, 512, 1024, 1024]
snake_case : int = (1, 384, 384)
if "nyu" or "midas" in checkpoint_url:
snake_case : List[str] = 768
snake_case : Tuple = [1, 1, 1, 0.5]
snake_case : Any = [256, 512, 768, 768]
snake_case : Dict = 150
snake_case : Optional[int] = 16
snake_case : str = (1, 384, 384)
snake_case : List[Any] = False
snake_case : List[str] = "project"
if "ade" in checkpoint_url:
snake_case : Any = True
snake_case : Dict = 768
snake_case : Dict = [1, 1, 1, 0.5]
snake_case : int = 150
snake_case : Union[str, Any] = 16
snake_case : int = "huggingface/label-files"
snake_case : Optional[Any] = "ade20k-id2label.json"
snake_case : Optional[int] = json.load(open(cached_download(hf_hub_url(__lowerCamelCase , __lowerCamelCase , repo_type="dataset" ) ) , "r" ) )
snake_case : Optional[Any] = {int(__lowerCamelCase ): v for k, v in idalabel.items()}
snake_case : Tuple = idalabel
snake_case : Dict = {v: k for k, v in idalabel.items()}
snake_case : List[str] = [1, 150, 480, 480]
return config, expected_shape
def UpperCamelCase ( __lowerCamelCase : str ):
snake_case : Optional[Any] = ["pretrained.model.head.weight", "pretrained.model.head.bias"]
for k in ignore_keys:
state_dict.pop(__lowerCamelCase , __lowerCamelCase )
def UpperCamelCase ( __lowerCamelCase : Optional[Any] ):
if (
"pretrained.model" in name
and "cls_token" not in name
and "pos_embed" not in name
and "patch_embed" not in name
):
snake_case : List[Any] = name.replace("pretrained.model" , "dpt.encoder" )
if "pretrained.model" in name:
snake_case : Any = name.replace("pretrained.model" , "dpt.embeddings" )
if "patch_embed" in name:
snake_case : str = name.replace("patch_embed" , "" )
if "pos_embed" in name:
snake_case : int = name.replace("pos_embed" , "position_embeddings" )
if "attn.proj" in name:
snake_case : List[Any] = name.replace("attn.proj" , "attention.output.dense" )
if "proj" in name and "project" not in name:
snake_case : List[str] = name.replace("proj" , "projection" )
if "blocks" in name:
snake_case : Optional[Any] = name.replace("blocks" , "layer" )
if "mlp.fc1" in name:
snake_case : str = name.replace("mlp.fc1" , "intermediate.dense" )
if "mlp.fc2" in name:
snake_case : List[Any] = name.replace("mlp.fc2" , "output.dense" )
if "norm1" in name and "backbone" not in name:
snake_case : int = name.replace("norm1" , "layernorm_before" )
if "norm2" in name and "backbone" not in name:
snake_case : Dict = name.replace("norm2" , "layernorm_after" )
if "scratch.output_conv" in name:
snake_case : Optional[int] = name.replace("scratch.output_conv" , "head" )
if "scratch" in name:
snake_case : str = name.replace("scratch" , "neck" )
if "layer1_rn" in name:
snake_case : Any = name.replace("layer1_rn" , "convs.0" )
if "layer2_rn" in name:
snake_case : Any = name.replace("layer2_rn" , "convs.1" )
if "layer3_rn" in name:
snake_case : Dict = name.replace("layer3_rn" , "convs.2" )
if "layer4_rn" in name:
snake_case : List[Any] = name.replace("layer4_rn" , "convs.3" )
if "refinenet" in name:
snake_case : str = int(name[len("neck.refinenet" ) : len("neck.refinenet" ) + 1] )
# tricky here: we need to map 4 to 0, 3 to 1, 2 to 2 and 1 to 3
snake_case : Optional[Any] = name.replace(f"""refinenet{layer_idx}""" , f"""fusion_stage.layers.{abs(layer_idx-4 )}""" )
if "out_conv" in name:
snake_case : Any = name.replace("out_conv" , "projection" )
if "resConfUnit1" in name:
snake_case : List[str] = name.replace("resConfUnit1" , "residual_layer1" )
if "resConfUnit2" in name:
snake_case : Union[str, Any] = name.replace("resConfUnit2" , "residual_layer2" )
if "conv1" in name:
snake_case : str = name.replace("conv1" , "convolution1" )
if "conv2" in name:
snake_case : Dict = name.replace("conv2" , "convolution2" )
# readout blocks
if "pretrained.act_postprocess1.0.project.0" in name:
snake_case : Dict = name.replace("pretrained.act_postprocess1.0.project.0" , "neck.reassemble_stage.readout_projects.0.0" )
if "pretrained.act_postprocess2.0.project.0" in name:
snake_case : List[Any] = name.replace("pretrained.act_postprocess2.0.project.0" , "neck.reassemble_stage.readout_projects.1.0" )
if "pretrained.act_postprocess3.0.project.0" in name:
snake_case : Optional[Any] = name.replace("pretrained.act_postprocess3.0.project.0" , "neck.reassemble_stage.readout_projects.2.0" )
if "pretrained.act_postprocess4.0.project.0" in name:
snake_case : str = name.replace("pretrained.act_postprocess4.0.project.0" , "neck.reassemble_stage.readout_projects.3.0" )
# resize blocks
if "pretrained.act_postprocess1.3" in name:
snake_case : List[Any] = name.replace("pretrained.act_postprocess1.3" , "neck.reassemble_stage.layers.0.projection" )
if "pretrained.act_postprocess1.4" in name:
snake_case : List[Any] = name.replace("pretrained.act_postprocess1.4" , "neck.reassemble_stage.layers.0.resize" )
if "pretrained.act_postprocess2.3" in name:
snake_case : List[str] = name.replace("pretrained.act_postprocess2.3" , "neck.reassemble_stage.layers.1.projection" )
if "pretrained.act_postprocess2.4" in name:
snake_case : Any = name.replace("pretrained.act_postprocess2.4" , "neck.reassemble_stage.layers.1.resize" )
if "pretrained.act_postprocess3.3" in name:
snake_case : Optional[int] = name.replace("pretrained.act_postprocess3.3" , "neck.reassemble_stage.layers.2.projection" )
if "pretrained.act_postprocess4.3" in name:
snake_case : Dict = name.replace("pretrained.act_postprocess4.3" , "neck.reassemble_stage.layers.3.projection" )
if "pretrained.act_postprocess4.4" in name:
snake_case : Optional[int] = name.replace("pretrained.act_postprocess4.4" , "neck.reassemble_stage.layers.3.resize" )
if "pretrained" in name:
snake_case : List[str] = name.replace("pretrained" , "dpt" )
if "bn" in name:
snake_case : Any = name.replace("bn" , "batch_norm" )
if "head" in name:
snake_case : str = name.replace("head" , "head.head" )
if "encoder.norm" in name:
snake_case : Dict = name.replace("encoder.norm" , "layernorm" )
if "auxlayer" in name:
snake_case : Dict = name.replace("auxlayer" , "auxiliary_head.head" )
if "backbone" in name:
snake_case : Dict = name.replace("backbone" , "backbone.bit.encoder" )
if ".." in name:
snake_case : int = name.replace(".." , "." )
if "stem.conv" in name:
snake_case : List[Any] = name.replace("stem.conv" , "bit.embedder.convolution" )
if "blocks" in name:
snake_case : Union[str, Any] = name.replace("blocks" , "layers" )
if "convolution" in name and "backbone" in name:
snake_case : List[str] = name.replace("convolution" , "conv" )
if "layer" in name and "backbone" in name:
snake_case : str = name.replace("layer" , "layers" )
if "backbone.bit.encoder.bit" in name:
snake_case : Any = name.replace("backbone.bit.encoder.bit" , "backbone.bit" )
if "embedder.conv" in name:
snake_case : int = name.replace("embedder.conv" , "embedder.convolution" )
if "backbone.bit.encoder.stem.norm" in name:
snake_case : str = name.replace("backbone.bit.encoder.stem.norm" , "backbone.bit.embedder.norm" )
return name
def UpperCamelCase ( __lowerCamelCase : int , __lowerCamelCase : Tuple ):
for i in range(config.num_hidden_layers ):
# read in weights + bias of input projection layer (in timm, this is a single matrix + bias)
snake_case : List[str] = state_dict.pop(f"""dpt.encoder.layer.{i}.attn.qkv.weight""" )
snake_case : Tuple = state_dict.pop(f"""dpt.encoder.layer.{i}.attn.qkv.bias""" )
# next, add query, keys and values (in that order) to the state dict
snake_case : List[str] = in_proj_weight[: config.hidden_size, :]
snake_case : Dict = in_proj_bias[: config.hidden_size]
snake_case : Any = in_proj_weight[
config.hidden_size : config.hidden_size * 2, :
]
snake_case : Any = in_proj_bias[
config.hidden_size : config.hidden_size * 2
]
snake_case : int = in_proj_weight[
-config.hidden_size :, :
]
snake_case : Dict = in_proj_bias[-config.hidden_size :]
def UpperCamelCase ( ):
snake_case : Any = "http://images.cocodataset.org/val2017/000000039769.jpg"
snake_case : Union[str, Any] = Image.open(requests.get(__lowerCamelCase , stream=__lowerCamelCase ).raw )
return im
@torch.no_grad()
def UpperCamelCase ( __lowerCamelCase : str , __lowerCamelCase : Union[str, Any] , __lowerCamelCase : int , __lowerCamelCase : int , __lowerCamelCase : List[str] ):
snake_case , snake_case : Any = get_dpt_config(__lowerCamelCase )
# load original state_dict from URL
# state_dict = torch.hub.load_state_dict_from_url(checkpoint_url, map_location="cpu")
snake_case : str = torch.load(__lowerCamelCase , map_location="cpu" )
# remove certain keys
remove_ignore_keys_(__lowerCamelCase )
# rename keys
for key in state_dict.copy().keys():
snake_case : Optional[Any] = state_dict.pop(__lowerCamelCase )
snake_case : Optional[int] = val
# read in qkv matrices
read_in_q_k_v(__lowerCamelCase , __lowerCamelCase )
# load HuggingFace model
snake_case : Union[str, Any] = DPTForSemanticSegmentation(__lowerCamelCase ) if "ade" in checkpoint_url else DPTForDepthEstimation(__lowerCamelCase )
model.load_state_dict(__lowerCamelCase )
model.eval()
# Check outputs on an image
snake_case : Tuple = 480 if "ade" in checkpoint_url else 384
snake_case : Tuple = DPTImageProcessor(size=__lowerCamelCase )
snake_case : int = prepare_img()
snake_case : Tuple = image_processor(__lowerCamelCase , return_tensors="pt" )
# forward pass
snake_case : Tuple = model(**__lowerCamelCase ).logits if "ade" in checkpoint_url else model(**__lowerCamelCase ).predicted_depth
if show_prediction:
snake_case : List[Any] = (
torch.nn.functional.interpolate(
outputs.unsqueeze(1 ) , size=(image.size[1], image.size[0]) , mode="bicubic" , align_corners=__lowerCamelCase , )
.squeeze()
.cpu()
.numpy()
)
Image.fromarray((prediction / prediction.max()) * 255 ).show()
if pytorch_dump_folder_path is not None:
Path(__lowerCamelCase ).mkdir(exist_ok=__lowerCamelCase )
print(f"""Saving model to {pytorch_dump_folder_path}""" )
model.save_pretrained(__lowerCamelCase )
print(f"""Saving image processor to {pytorch_dump_folder_path}""" )
image_processor.save_pretrained(__lowerCamelCase )
if push_to_hub:
model.push_to_hub("ybelkada/dpt-hybrid-midas" )
image_processor.push_to_hub("ybelkada/dpt-hybrid-midas" )
if __name__ == "__main__":
__lowerCamelCase = argparse.ArgumentParser()
# Required parameters
parser.add_argument(
"""--checkpoint_url""",
default="""https://github.com/intel-isl/DPT/releases/download/1_0/dpt_large-midas-2f21e586.pt""",
type=str,
help="""URL of the original DPT checkpoint you'd like to convert.""",
)
parser.add_argument(
"""--pytorch_dump_folder_path""",
default=None,
type=str,
required=False,
help="""Path to the output PyTorch model directory.""",
)
parser.add_argument(
"""--push_to_hub""",
action="""store_true""",
)
parser.add_argument(
"""--model_name""",
default="""dpt-large""",
type=str,
help="""Name of the model, in case you're pushing to the hub.""",
)
parser.add_argument(
"""--show_prediction""",
action="""store_true""",
)
__lowerCamelCase = parser.parse_args()
convert_dpt_checkpoint(
args.checkpoint_url, args.pytorch_dump_folder_path, args.push_to_hub, args.model_name, args.show_prediction
)
| 59
|
import gc
import unittest
from parameterized import parameterized
from diffusers import FlaxUNetaDConditionModel
from diffusers.utils import is_flax_available
from diffusers.utils.testing_utils import load_hf_numpy, require_flax, slow
if is_flax_available():
import jax
import jax.numpy as jnp
@slow
@require_flax
class UpperCAmelCase ( unittest.TestCase ):
def _SCREAMING_SNAKE_CASE (self : str , snake_case__ : Union[str, Any] , snake_case__ : List[str] ) -> List[str]:
'''simple docstring'''
return f"""gaussian_noise_s={seed}_shape={'_'.join([str(snake_case__ ) for s in shape] )}.npy"""
def _SCREAMING_SNAKE_CASE (self : Tuple ) -> int:
'''simple docstring'''
super().tearDown()
gc.collect()
def _SCREAMING_SNAKE_CASE (self : str , snake_case__ : Optional[Any]=0 , snake_case__ : Any=(4, 4, 64, 64) , snake_case__ : List[Any]=False ) -> int:
'''simple docstring'''
snake_case : Optional[Any] = jnp.bfloataa if fpaa else jnp.floataa
snake_case : Optional[int] = jnp.array(load_hf_numpy(self.get_file_format(snake_case__ , snake_case__ ) ) , dtype=snake_case__ )
return image
def _SCREAMING_SNAKE_CASE (self : Optional[int] , snake_case__ : Tuple=False , snake_case__ : List[Any]="CompVis/stable-diffusion-v1-4" ) -> List[Any]:
'''simple docstring'''
snake_case : List[str] = jnp.bfloataa if fpaa else jnp.floataa
snake_case : str = "bf16" if fpaa else None
snake_case , snake_case : Optional[int] = FlaxUNetaDConditionModel.from_pretrained(
snake_case__ , subfolder="unet" , dtype=snake_case__ , revision=snake_case__ )
return model, params
def _SCREAMING_SNAKE_CASE (self : List[str] , snake_case__ : Union[str, Any]=0 , snake_case__ : Union[str, Any]=(4, 77, 7_68) , snake_case__ : Dict=False ) -> List[str]:
'''simple docstring'''
snake_case : Any = jnp.bfloataa if fpaa else jnp.floataa
snake_case : Any = jnp.array(load_hf_numpy(self.get_file_format(snake_case__ , snake_case__ ) ) , dtype=snake_case__ )
return hidden_states
@parameterized.expand(
[
# fmt: off
[83, 4, [-0.2323, -0.1304, 0.0813, -0.3093, -0.0919, -0.1571, -0.1125, -0.5806]],
[17, 0.55, [-0.0831, -0.2443, 0.0901, -0.0919, 0.3396, 0.0103, -0.3743, 0.0701]],
[8, 0.89, [-0.4863, 0.0859, 0.0875, -0.1658, 0.9199, -0.0114, 0.4839, 0.4639]],
[3, 10_00, [-0.5649, 0.2402, -0.5518, 0.1248, 1.1328, -0.2443, -0.0325, -1.0078]],
# fmt: on
] )
def _SCREAMING_SNAKE_CASE (self : Optional[int] , snake_case__ : int , snake_case__ : Optional[int] , snake_case__ : Dict ) -> List[str]:
'''simple docstring'''
snake_case , snake_case : List[str] = self.get_unet_model(model_id="CompVis/stable-diffusion-v1-4" , fpaa=snake_case__ )
snake_case : Union[str, Any] = self.get_latents(snake_case__ , fpaa=snake_case__ )
snake_case : List[str] = self.get_encoder_hidden_states(snake_case__ , fpaa=snake_case__ )
snake_case : Dict = model.apply(
{"params": params} , snake_case__ , jnp.array(snake_case__ , dtype=jnp.intaa ) , encoder_hidden_states=snake_case__ , ).sample
assert sample.shape == latents.shape
snake_case : Optional[Any] = jnp.asarray(jax.device_get((sample[-1, -2:, -2:, :2].flatten()) ) , dtype=jnp.floataa )
snake_case : Optional[int] = jnp.array(snake_case__ , dtype=jnp.floataa )
# Found torch (float16) and flax (bfloat16) outputs to be within this tolerance, in the same hardware
assert jnp.allclose(snake_case__ , snake_case__ , atol=1e-2 )
@parameterized.expand(
[
# fmt: off
[83, 4, [0.1514, 0.0807, 0.1624, 0.1016, -0.1896, 0.0263, 0.0677, 0.2310]],
[17, 0.55, [0.1164, -0.0216, 0.0170, 0.1589, -0.3120, 0.1005, -0.0581, -0.1458]],
[8, 0.89, [-0.1758, -0.0169, 0.1004, -0.1411, 0.1312, 0.1103, -0.1996, 0.2139]],
[3, 10_00, [0.1214, 0.0352, -0.0731, -0.1562, -0.0994, -0.0906, -0.2340, -0.0539]],
# fmt: on
] )
def _SCREAMING_SNAKE_CASE (self : Optional[int] , snake_case__ : Optional[int] , snake_case__ : str , snake_case__ : Tuple ) -> str:
'''simple docstring'''
snake_case , snake_case : List[Any] = self.get_unet_model(model_id="stabilityai/stable-diffusion-2" , fpaa=snake_case__ )
snake_case : List[str] = self.get_latents(snake_case__ , shape=(4, 4, 96, 96) , fpaa=snake_case__ )
snake_case : Union[str, Any] = self.get_encoder_hidden_states(snake_case__ , shape=(4, 77, 10_24) , fpaa=snake_case__ )
snake_case : Optional[int] = model.apply(
{"params": params} , snake_case__ , jnp.array(snake_case__ , dtype=jnp.intaa ) , encoder_hidden_states=snake_case__ , ).sample
assert sample.shape == latents.shape
snake_case : int = jnp.asarray(jax.device_get((sample[-1, -2:, -2:, :2].flatten()) ) , dtype=jnp.floataa )
snake_case : Dict = jnp.array(snake_case__ , dtype=jnp.floataa )
# Found torch (float16) and flax (bfloat16) outputs to be within this tolerance, on the same hardware
assert jnp.allclose(snake_case__ , snake_case__ , atol=1e-2 )
| 59
| 1
|
import torch
import torch.nn as nn
from transformers.modeling_utils import ModuleUtilsMixin
from transformers.models.ta.modeling_ta import TaBlock, TaConfig, TaLayerNorm
from ...configuration_utils import ConfigMixin, register_to_config
from ...models import ModelMixin
class UpperCAmelCase ( A_ ,A_ ,A_ ):
@register_to_config
def __init__(self : str , snake_case__ : int , snake_case__ : int , snake_case__ : int , snake_case__ : float , snake_case__ : int , snake_case__ : int , snake_case__ : int , snake_case__ : int , snake_case__ : str , snake_case__ : bool = False , ) -> Optional[int]:
'''simple docstring'''
super().__init__()
snake_case : List[Any] = nn.Embedding(snake_case__ , snake_case__ )
snake_case : Tuple = nn.Embedding(snake_case__ , snake_case__ )
snake_case : Dict = False
snake_case : Optional[Any] = nn.Dropout(p=snake_case__ )
snake_case : Dict = TaConfig(
vocab_size=snake_case__ , d_model=snake_case__ , num_heads=snake_case__ , d_kv=snake_case__ , d_ff=snake_case__ , dropout_rate=snake_case__ , feed_forward_proj=snake_case__ , is_decoder=snake_case__ , is_encoder_decoder=snake_case__ , )
snake_case : List[Any] = nn.ModuleList()
for lyr_num in range(snake_case__ ):
snake_case : List[str] = TaBlock(snake_case__ )
self.encoders.append(snake_case__ )
snake_case : Dict = TaLayerNorm(snake_case__ )
snake_case : str = nn.Dropout(p=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : str , snake_case__ : Optional[int] , snake_case__ : Optional[int] ) -> Optional[Any]:
'''simple docstring'''
snake_case : Any = self.token_embedder(snake_case__ )
snake_case : Union[str, Any] = encoder_input_tokens.shape[1]
snake_case : Optional[int] = torch.arange(snake_case__ , device=encoder_input_tokens.device )
x += self.position_encoding(snake_case__ )
snake_case : str = self.dropout_pre(snake_case__ )
# inverted the attention mask
snake_case : Optional[int] = encoder_input_tokens.size()
snake_case : Optional[int] = self.get_extended_attention_mask(snake_case__ , snake_case__ )
for lyr in self.encoders:
snake_case : int = lyr(snake_case__ , snake_case__ )[0]
snake_case : Optional[int] = self.layer_norm(snake_case__ )
return self.dropout_post(snake_case__ ), encoder_inputs_mask
| 59
|
import argparse
import re
from typing import Dict
import torch
from datasets import Audio, Dataset, load_dataset, load_metric
from transformers import AutoFeatureExtractor, pipeline
def UpperCamelCase ( __lowerCamelCase : Dataset , __lowerCamelCase : Dict[str, str] ):
snake_case : int = args.log_outputs
snake_case : Dict = "_".join(args.dataset.split("/" ) + [args.config, args.split] )
# load metric
snake_case : List[str] = load_metric("wer" )
snake_case : Tuple = load_metric("cer" )
# compute metrics
snake_case : List[Any] = wer.compute(references=result["target"] , predictions=result["prediction"] )
snake_case : int = cer.compute(references=result["target"] , predictions=result["prediction"] )
# print & log results
snake_case : int = f"""WER: {wer_result}\nCER: {cer_result}"""
print(__lowerCamelCase )
with open(f"""{dataset_id}_eval_results.txt""" , "w" ) as f:
f.write(__lowerCamelCase )
# log all results in text file. Possibly interesting for analysis
if log_outputs is not None:
snake_case : int = f"""log_{dataset_id}_predictions.txt"""
snake_case : List[Any] = f"""log_{dataset_id}_targets.txt"""
with open(__lowerCamelCase , "w" ) as p, open(__lowerCamelCase , "w" ) as t:
# mapping function to write output
def write_to_file(__lowerCamelCase : str , __lowerCamelCase : Optional[int] ):
p.write(f"""{i}""" + "\n" )
p.write(batch["prediction"] + "\n" )
t.write(f"""{i}""" + "\n" )
t.write(batch["target"] + "\n" )
result.map(__lowerCamelCase , with_indices=__lowerCamelCase )
def UpperCamelCase ( __lowerCamelCase : str ):
snake_case : List[Any] = "[,?.!\-\;\:\"“%‘”�—’…–]" # noqa: W605 IMPORTANT: this should correspond to the chars that were ignored during training
snake_case : List[Any] = re.sub(__lowerCamelCase , "" , text.lower() )
# In addition, we can normalize the target text, e.g. removing new lines characters etc...
# note that order is important here!
snake_case : Optional[Any] = ["\n\n", "\n", " ", " "]
for t in token_sequences_to_ignore:
snake_case : Dict = " ".join(text.split(__lowerCamelCase ) )
return text
def UpperCamelCase ( __lowerCamelCase : int ):
# load dataset
snake_case : str = load_dataset(args.dataset , args.config , split=args.split , use_auth_token=__lowerCamelCase )
# for testing: only process the first two examples as a test
# dataset = dataset.select(range(10))
# load processor
snake_case : List[Any] = AutoFeatureExtractor.from_pretrained(args.model_id )
snake_case : Union[str, Any] = feature_extractor.sampling_rate
# resample audio
snake_case : Union[str, Any] = dataset.cast_column("audio" , Audio(sampling_rate=__lowerCamelCase ) )
# load eval pipeline
if args.device is None:
snake_case : List[str] = 0 if torch.cuda.is_available() else -1
snake_case : str = pipeline("automatic-speech-recognition" , model=args.model_id , device=args.device )
# map function to decode audio
def map_to_pred(__lowerCamelCase : int ):
snake_case : Dict = asr(
batch["audio"]["array"] , chunk_length_s=args.chunk_length_s , stride_length_s=args.stride_length_s )
snake_case : str = prediction["text"]
snake_case : Tuple = normalize_text(batch["sentence"] )
return batch
# run inference on all examples
snake_case : Dict = dataset.map(__lowerCamelCase , remove_columns=dataset.column_names )
# compute and log_results
# do not change function below
log_results(__lowerCamelCase , __lowerCamelCase )
if __name__ == "__main__":
__lowerCamelCase = argparse.ArgumentParser()
parser.add_argument(
"""--model_id""", type=str, required=True, help="""Model identifier. Should be loadable with 🤗 Transformers"""
)
parser.add_argument(
"""--dataset""",
type=str,
required=True,
help="""Dataset name to evaluate the `model_id`. Should be loadable with 🤗 Datasets""",
)
parser.add_argument(
"""--config""", type=str, required=True, help="""Config of the dataset. *E.g.* `'en'` for Common Voice"""
)
parser.add_argument("""--split""", type=str, required=True, help="""Split of the dataset. *E.g.* `'test'`""")
parser.add_argument(
"""--chunk_length_s""", type=float, default=None, help="""Chunk length in seconds. Defaults to 5 seconds."""
)
parser.add_argument(
"""--stride_length_s""", type=float, default=None, help="""Stride of the audio chunks. Defaults to 1 second."""
)
parser.add_argument(
"""--log_outputs""", action="""store_true""", help="""If defined, write outputs to log file for analysis."""
)
parser.add_argument(
"""--device""",
type=int,
default=None,
help="""The device to run the pipeline on. -1 for CPU (default), 0 for the first GPU and so on.""",
)
__lowerCamelCase = parser.parse_args()
main(args)
| 59
| 1
|
from __future__ import annotations
from typing import Any
class UpperCAmelCase :
def __init__(self : str , snake_case__ : int ) -> None:
'''simple docstring'''
snake_case : str = num_of_nodes
snake_case : list[list[int]] = []
snake_case : dict[int, int] = {}
def _SCREAMING_SNAKE_CASE (self : Dict , snake_case__ : int , snake_case__ : int , snake_case__ : int ) -> None:
'''simple docstring'''
self.m_edges.append([u_node, v_node, weight] )
def _SCREAMING_SNAKE_CASE (self : List[Any] , snake_case__ : int ) -> int:
'''simple docstring'''
if self.m_component[u_node] == u_node:
return u_node
return self.find_component(self.m_component[u_node] )
def _SCREAMING_SNAKE_CASE (self : List[str] , snake_case__ : int ) -> None:
'''simple docstring'''
if self.m_component[u_node] != u_node:
for k in self.m_component:
snake_case : Union[str, Any] = self.find_component(snake_case__ )
def _SCREAMING_SNAKE_CASE (self : str , snake_case__ : list[int] , snake_case__ : int , snake_case__ : int ) -> None:
'''simple docstring'''
if component_size[u_node] <= component_size[v_node]:
snake_case : Any = v_node
component_size[v_node] += component_size[u_node]
self.set_component(snake_case__ )
elif component_size[u_node] >= component_size[v_node]:
snake_case : List[Any] = self.find_component(snake_case__ )
component_size[u_node] += component_size[v_node]
self.set_component(snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Optional[Any] ) -> None:
'''simple docstring'''
snake_case : Dict = []
snake_case : Any = 0
snake_case : list[Any] = [-1] * self.m_num_of_nodes
# A list of components (initialized to all of the nodes)
for node in range(self.m_num_of_nodes ):
self.m_component.update({node: node} )
component_size.append(1 )
snake_case : str = self.m_num_of_nodes
while num_of_components > 1:
for edge in self.m_edges:
snake_case , snake_case , snake_case : Dict = edge
snake_case : List[str] = self.m_component[u]
snake_case : Union[str, Any] = self.m_component[v]
if u_component != v_component:
for component in (u_component, v_component):
if (
minimum_weight_edge[component] == -1
or minimum_weight_edge[component][2] > w
):
snake_case : Optional[Any] = [u, v, w]
for edge in minimum_weight_edge:
if isinstance(snake_case__ , snake_case__ ):
snake_case , snake_case , snake_case : List[str] = edge
snake_case : Tuple = self.m_component[u]
snake_case : Dict = self.m_component[v]
if u_component != v_component:
mst_weight += w
self.union(snake_case__ , snake_case__ , snake_case__ )
print(f"""Added edge [{u} - {v}]\nAdded weight: {w}\n""" )
num_of_components -= 1
snake_case : Any = [-1] * self.m_num_of_nodes
print(f"""The total weight of the minimal spanning tree is: {mst_weight}""" )
def UpperCamelCase ( ):
pass
if __name__ == "__main__":
import doctest
doctest.testmod()
| 59
|
from typing import Optional, Tuple, Union
import flax
import flax.linen as nn
import jax
import jax.numpy as jnp
from flax.core.frozen_dict import FrozenDict
from ..configuration_utils import ConfigMixin, flax_register_to_config
from ..utils import BaseOutput
from .embeddings_flax import FlaxTimestepEmbedding, FlaxTimesteps
from .modeling_flax_utils import FlaxModelMixin
from .unet_ad_blocks_flax import (
FlaxCrossAttnDownBlockaD,
FlaxCrossAttnUpBlockaD,
FlaxDownBlockaD,
FlaxUNetMidBlockaDCrossAttn,
FlaxUpBlockaD,
)
@flax.struct.dataclass
class UpperCAmelCase ( A_ ):
A__ : jnp.ndarray
@flax_register_to_config
class UpperCAmelCase ( nn.Module ,A_ ,A_ ):
A__ : int = 32
A__ : int = 4
A__ : int = 4
A__ : Tuple[str] = (
"CrossAttnDownBlock2D",
"CrossAttnDownBlock2D",
"CrossAttnDownBlock2D",
"DownBlock2D",
)
A__ : Tuple[str] = ("UpBlock2D", "CrossAttnUpBlock2D", "CrossAttnUpBlock2D", "CrossAttnUpBlock2D")
A__ : Union[bool, Tuple[bool]] = False
A__ : Tuple[int] = (3_20, 6_40, 12_80, 12_80)
A__ : int = 2
A__ : Union[int, Tuple[int]] = 8
A__ : Optional[Union[int, Tuple[int]]] = None
A__ : int = 12_80
A__ : float = 0.0
A__ : bool = False
A__ : jnp.dtype = jnp.floataa
A__ : bool = True
A__ : int = 0
A__ : bool = False
def _SCREAMING_SNAKE_CASE (self : Optional[int] , snake_case__ : jax.random.KeyArray ) -> FrozenDict:
'''simple docstring'''
snake_case : Dict = (1, self.in_channels, self.sample_size, self.sample_size)
snake_case : Any = jnp.zeros(snake_case__ , dtype=jnp.floataa )
snake_case : List[str] = jnp.ones((1,) , dtype=jnp.intaa )
snake_case : str = jnp.zeros((1, 1, self.cross_attention_dim) , dtype=jnp.floataa )
snake_case , snake_case : Optional[int] = jax.random.split(snake_case__ )
snake_case : Union[str, Any] = {"params": params_rng, "dropout": dropout_rng}
return self.init(snake_case__ , snake_case__ , snake_case__ , snake_case__ )["params"]
def _SCREAMING_SNAKE_CASE (self : str ) -> Tuple:
'''simple docstring'''
snake_case : str = self.block_out_channels
snake_case : Optional[Any] = block_out_channels[0] * 4
if self.num_attention_heads is not None:
raise ValueError(
"At the moment it is not possible to define the number of attention heads via `num_attention_heads` because of a naming issue as described in https://github.com/huggingface/diffusers/issues/2011#issuecomment-1547958131. Passing `num_attention_heads` will only be supported in diffusers v0.19." )
# If `num_attention_heads` is not defined (which is the case for most models)
# it will default to `attention_head_dim`. This looks weird upon first reading it and it is.
# The reason for this behavior is to correct for incorrectly named variables that were introduced
# when this library was created. The incorrect naming was only discovered much later in https://github.com/huggingface/diffusers/issues/2011#issuecomment-1547958131
# Changing `attention_head_dim` to `num_attention_heads` for 40,000+ configurations is too backwards breaking
# which is why we correct for the naming here.
snake_case : Tuple = self.num_attention_heads or self.attention_head_dim
# input
snake_case : Tuple = nn.Conv(
block_out_channels[0] , kernel_size=(3, 3) , strides=(1, 1) , padding=((1, 1), (1, 1)) , dtype=self.dtype , )
# time
snake_case : Union[str, Any] = FlaxTimesteps(
block_out_channels[0] , flip_sin_to_cos=self.flip_sin_to_cos , freq_shift=self.config.freq_shift )
snake_case : Dict = FlaxTimestepEmbedding(snake_case__ , dtype=self.dtype )
snake_case : List[str] = self.only_cross_attention
if isinstance(snake_case__ , snake_case__ ):
snake_case : List[Any] = (only_cross_attention,) * len(self.down_block_types )
if isinstance(snake_case__ , snake_case__ ):
snake_case : List[Any] = (num_attention_heads,) * len(self.down_block_types )
# down
snake_case : List[Any] = []
snake_case : Optional[int] = block_out_channels[0]
for i, down_block_type in enumerate(self.down_block_types ):
snake_case : List[Any] = output_channel
snake_case : Dict = block_out_channels[i]
snake_case : Optional[Any] = i == len(snake_case__ ) - 1
if down_block_type == "CrossAttnDownBlock2D":
snake_case : List[Any] = FlaxCrossAttnDownBlockaD(
in_channels=snake_case__ , out_channels=snake_case__ , dropout=self.dropout , num_layers=self.layers_per_block , num_attention_heads=num_attention_heads[i] , add_downsample=not is_final_block , use_linear_projection=self.use_linear_projection , only_cross_attention=only_cross_attention[i] , use_memory_efficient_attention=self.use_memory_efficient_attention , dtype=self.dtype , )
else:
snake_case : Union[str, Any] = FlaxDownBlockaD(
in_channels=snake_case__ , out_channels=snake_case__ , dropout=self.dropout , num_layers=self.layers_per_block , add_downsample=not is_final_block , dtype=self.dtype , )
down_blocks.append(snake_case__ )
snake_case : Dict = down_blocks
# mid
snake_case : Optional[int] = FlaxUNetMidBlockaDCrossAttn(
in_channels=block_out_channels[-1] , dropout=self.dropout , num_attention_heads=num_attention_heads[-1] , use_linear_projection=self.use_linear_projection , use_memory_efficient_attention=self.use_memory_efficient_attention , dtype=self.dtype , )
# up
snake_case : Optional[Any] = []
snake_case : Optional[int] = list(reversed(snake_case__ ) )
snake_case : Dict = list(reversed(snake_case__ ) )
snake_case : Tuple = list(reversed(snake_case__ ) )
snake_case : Optional[Any] = reversed_block_out_channels[0]
for i, up_block_type in enumerate(self.up_block_types ):
snake_case : Optional[int] = output_channel
snake_case : List[Any] = reversed_block_out_channels[i]
snake_case : Union[str, Any] = reversed_block_out_channels[min(i + 1 , len(snake_case__ ) - 1 )]
snake_case : int = i == len(snake_case__ ) - 1
if up_block_type == "CrossAttnUpBlock2D":
snake_case : Any = FlaxCrossAttnUpBlockaD(
in_channels=snake_case__ , out_channels=snake_case__ , prev_output_channel=snake_case__ , num_layers=self.layers_per_block + 1 , num_attention_heads=reversed_num_attention_heads[i] , add_upsample=not is_final_block , dropout=self.dropout , use_linear_projection=self.use_linear_projection , only_cross_attention=only_cross_attention[i] , use_memory_efficient_attention=self.use_memory_efficient_attention , dtype=self.dtype , )
else:
snake_case : Optional[int] = FlaxUpBlockaD(
in_channels=snake_case__ , out_channels=snake_case__ , prev_output_channel=snake_case__ , num_layers=self.layers_per_block + 1 , add_upsample=not is_final_block , dropout=self.dropout , dtype=self.dtype , )
up_blocks.append(snake_case__ )
snake_case : Optional[int] = output_channel
snake_case : Tuple = up_blocks
# out
snake_case : Optional[int] = nn.GroupNorm(num_groups=32 , epsilon=1e-5 )
snake_case : List[str] = nn.Conv(
self.out_channels , kernel_size=(3, 3) , strides=(1, 1) , padding=((1, 1), (1, 1)) , dtype=self.dtype , )
def __call__(self : Dict , snake_case__ : Dict , snake_case__ : Dict , snake_case__ : Optional[int] , snake_case__ : Tuple=None , snake_case__ : Union[str, Any]=None , snake_case__ : bool = True , snake_case__ : bool = False , ) -> Union[FlaxUNetaDConditionOutput, Tuple]:
'''simple docstring'''
if not isinstance(snake_case__ , jnp.ndarray ):
snake_case : List[Any] = jnp.array([timesteps] , dtype=jnp.intaa )
elif isinstance(snake_case__ , jnp.ndarray ) and len(timesteps.shape ) == 0:
snake_case : Any = timesteps.astype(dtype=jnp.floataa )
snake_case : int = jnp.expand_dims(snake_case__ , 0 )
snake_case : str = self.time_proj(snake_case__ )
snake_case : str = self.time_embedding(snake_case__ )
# 2. pre-process
snake_case : int = jnp.transpose(snake_case__ , (0, 2, 3, 1) )
snake_case : List[Any] = self.conv_in(snake_case__ )
# 3. down
snake_case : Optional[int] = (sample,)
for down_block in self.down_blocks:
if isinstance(snake_case__ , snake_case__ ):
snake_case , snake_case : List[Any] = down_block(snake_case__ , snake_case__ , snake_case__ , deterministic=not train )
else:
snake_case , snake_case : str = down_block(snake_case__ , snake_case__ , deterministic=not train )
down_block_res_samples += res_samples
if down_block_additional_residuals is not None:
snake_case : Tuple = ()
for down_block_res_sample, down_block_additional_residual in zip(
snake_case__ , snake_case__ ):
down_block_res_sample += down_block_additional_residual
new_down_block_res_samples += (down_block_res_sample,)
snake_case : Optional[int] = new_down_block_res_samples
# 4. mid
snake_case : Optional[int] = self.mid_block(snake_case__ , snake_case__ , snake_case__ , deterministic=not train )
if mid_block_additional_residual is not None:
sample += mid_block_additional_residual
# 5. up
for up_block in self.up_blocks:
snake_case : int = down_block_res_samples[-(self.layers_per_block + 1) :]
snake_case : Optional[Any] = down_block_res_samples[: -(self.layers_per_block + 1)]
if isinstance(snake_case__ , snake_case__ ):
snake_case : Optional[Any] = up_block(
snake_case__ , temb=snake_case__ , encoder_hidden_states=snake_case__ , res_hidden_states_tuple=snake_case__ , deterministic=not train , )
else:
snake_case : Dict = up_block(snake_case__ , temb=snake_case__ , res_hidden_states_tuple=snake_case__ , deterministic=not train )
# 6. post-process
snake_case : List[str] = self.conv_norm_out(snake_case__ )
snake_case : Any = nn.silu(snake_case__ )
snake_case : Optional[int] = self.conv_out(snake_case__ )
snake_case : Union[str, Any] = jnp.transpose(snake_case__ , (0, 3, 1, 2) )
if not return_dict:
return (sample,)
return FlaxUNetaDConditionOutput(sample=snake_case__ )
| 59
| 1
|
from collections.abc import Callable
def UpperCamelCase ( __lowerCamelCase : Callable[[float], float] , __lowerCamelCase : float , __lowerCamelCase : float ):
snake_case : float = a
snake_case : float = b
if function(__lowerCamelCase ) == 0: # one of the a or b is a root for the function
return a
elif function(__lowerCamelCase ) == 0:
return b
elif (
function(__lowerCamelCase ) * function(__lowerCamelCase ) > 0
): # if none of these are root and they are both positive or negative,
# then this algorithm can't find the root
raise ValueError("could not find root in given interval." )
else:
snake_case : float = start + (end - start) / 2.0
while abs(start - mid ) > 10**-7: # until precisely equals to 10^-7
if function(__lowerCamelCase ) == 0:
return mid
elif function(__lowerCamelCase ) * function(__lowerCamelCase ) < 0:
snake_case : Optional[int] = mid
else:
snake_case : Optional[int] = mid
snake_case : str = start + (end - start) / 2.0
return mid
def UpperCamelCase ( __lowerCamelCase : float ):
return x**3 - 2 * x - 5
if __name__ == "__main__":
print(bisection(f, 1, 10_00))
import doctest
doctest.testmod()
| 59
|
__lowerCamelCase = {
"joule": 1.0,
"kilojoule": 10_00,
"megajoule": 1_00_00_00,
"gigajoule": 10_00_00_00_00,
"wattsecond": 1.0,
"watthour": 36_00,
"kilowatthour": 3_60_00_00,
"newtonmeter": 1.0,
"calorie_nutr": 41_86.8,
"kilocalorie_nutr": 4_18_68_00.00,
"electronvolt": 1.602_176_634e-19,
"britishthermalunit_it": 10_55.0_55_85,
"footpound": 1.35_5818,
}
def UpperCamelCase ( __lowerCamelCase : str , __lowerCamelCase : str , __lowerCamelCase : float ):
if to_type not in ENERGY_CONVERSION or from_type not in ENERGY_CONVERSION:
snake_case : List[Any] = (
f"""Incorrect 'from_type' or 'to_type' value: {from_type!r}, {to_type!r}\n"""
f"""Valid values are: {', '.join(__lowerCamelCase )}"""
)
raise ValueError(__lowerCamelCase )
return value * ENERGY_CONVERSION[from_type] / ENERGY_CONVERSION[to_type]
if __name__ == "__main__":
import doctest
doctest.testmod()
| 59
| 1
|
import json
import unittest
import numpy as np
from huggingface_hub import hf_hub_download
from transformers.testing_utils import require_torch, require_vision
from transformers.utils import is_torch_available, is_vision_available
from ...test_image_processing_common import ImageProcessingSavingTestMixin, prepare_image_inputs
if is_torch_available():
import torch
if is_vision_available():
from transformers import OneFormerImageProcessor
from transformers.models.oneformer.image_processing_oneformer import binary_mask_to_rle
from transformers.models.oneformer.modeling_oneformer import OneFormerForUniversalSegmentationOutput
if is_vision_available():
from PIL import Image
def UpperCamelCase ( __lowerCamelCase : List[Any] , __lowerCamelCase : Dict="shi-labs/oneformer_demo" ):
with open(hf_hub_download(__lowerCamelCase , __lowerCamelCase , repo_type="dataset" ) , "r" ) as f:
snake_case : Optional[int] = json.load(__lowerCamelCase )
snake_case : Optional[int] = {}
snake_case : Any = []
snake_case : List[str] = []
for key, info in class_info.items():
snake_case : Union[str, Any] = info["name"]
class_names.append(info["name"] )
if info["isthing"]:
thing_ids.append(int(__lowerCamelCase ) )
snake_case : List[Any] = thing_ids
snake_case : Optional[Any] = class_names
return metadata
class UpperCAmelCase ( unittest.TestCase ):
def __init__(self : Union[str, Any] , snake_case__ : Dict , snake_case__ : Optional[Any]=7 , snake_case__ : str=3 , snake_case__ : Optional[Any]=30 , snake_case__ : Union[str, Any]=4_00 , snake_case__ : List[Any]=None , snake_case__ : Any=True , snake_case__ : Optional[int]=True , snake_case__ : str=[0.5, 0.5, 0.5] , snake_case__ : Optional[int]=[0.5, 0.5, 0.5] , snake_case__ : List[str]=10 , snake_case__ : int=False , snake_case__ : str=2_55 , snake_case__ : List[Any]="shi-labs/oneformer_demo" , snake_case__ : Optional[Any]="ade20k_panoptic.json" , snake_case__ : str=10 , ) -> Tuple:
'''simple docstring'''
snake_case : int = parent
snake_case : List[Any] = batch_size
snake_case : str = num_channels
snake_case : Dict = min_resolution
snake_case : int = max_resolution
snake_case : Dict = do_resize
snake_case : Union[str, Any] = {"shortest_edge": 32, "longest_edge": 13_33} if size is None else size
snake_case : Optional[int] = do_normalize
snake_case : Optional[int] = image_mean
snake_case : Dict = image_std
snake_case : List[str] = class_info_file
snake_case : int = prepare_metadata(snake_case__ , snake_case__ )
snake_case : Optional[int] = num_text
snake_case : Any = repo_path
# for the post_process_functions
snake_case : Optional[int] = 2
snake_case : Optional[int] = 10
snake_case : List[str] = 10
snake_case : Optional[int] = 3
snake_case : Union[str, Any] = 4
snake_case : str = num_labels
snake_case : Optional[Any] = do_reduce_labels
snake_case : int = ignore_index
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> Dict:
'''simple docstring'''
return {
"do_resize": self.do_resize,
"size": self.size,
"do_normalize": self.do_normalize,
"image_mean": self.image_mean,
"image_std": self.image_std,
"num_labels": self.num_labels,
"do_reduce_labels": self.do_reduce_labels,
"ignore_index": self.ignore_index,
"class_info_file": self.class_info_file,
"metadata": self.metadata,
"num_text": self.num_text,
}
def _SCREAMING_SNAKE_CASE (self : List[str] , snake_case__ : str , snake_case__ : Optional[int]=False ) -> Tuple:
'''simple docstring'''
if not batched:
snake_case : Union[str, Any] = image_inputs[0]
if isinstance(snake_case__ , Image.Image ):
snake_case , snake_case : List[Any] = image.size
else:
snake_case , snake_case : Dict = image.shape[1], image.shape[2]
if w < h:
snake_case : int = int(self.size["shortest_edge"] * h / w )
snake_case : str = self.size["shortest_edge"]
elif w > h:
snake_case : int = self.size["shortest_edge"]
snake_case : List[str] = int(self.size["shortest_edge"] * w / h )
else:
snake_case : Dict = self.size["shortest_edge"]
snake_case : Optional[Any] = self.size["shortest_edge"]
else:
snake_case : List[Any] = []
for image in image_inputs:
snake_case , snake_case : List[Any] = self.get_expected_values([image] )
expected_values.append((expected_height, expected_width) )
snake_case : Union[str, Any] = max(snake_case__ , key=lambda snake_case__ : item[0] )[0]
snake_case : int = max(snake_case__ , key=lambda snake_case__ : item[1] )[1]
return expected_height, expected_width
def _SCREAMING_SNAKE_CASE (self : Any ) -> List[Any]:
'''simple docstring'''
return OneFormerForUniversalSegmentationOutput(
# +1 for null class
class_queries_logits=torch.randn((self.batch_size, self.num_queries, self.num_classes + 1) ) , masks_queries_logits=torch.randn((self.batch_size, self.num_queries, self.height, self.width) ) , )
@require_torch
@require_vision
class UpperCAmelCase ( A_ ,unittest.TestCase ):
A__ : str = OneFormerImageProcessor if (is_vision_available() and is_torch_available()) else None
# only for test_image_processing_common.test_image_proc_to_json_string
A__ : Tuple = image_processing_class
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> Tuple:
'''simple docstring'''
snake_case : Tuple = OneFormerImageProcessorTester(self )
@property
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> Optional[int]:
'''simple docstring'''
return self.image_processing_tester.prepare_image_processor_dict()
def _SCREAMING_SNAKE_CASE (self : Optional[Any] ) -> List[str]:
'''simple docstring'''
snake_case : str = self.image_processing_class(**self.image_processor_dict )
self.assertTrue(hasattr(snake_case__ , "image_mean" ) )
self.assertTrue(hasattr(snake_case__ , "image_std" ) )
self.assertTrue(hasattr(snake_case__ , "do_normalize" ) )
self.assertTrue(hasattr(snake_case__ , "do_resize" ) )
self.assertTrue(hasattr(snake_case__ , "size" ) )
self.assertTrue(hasattr(snake_case__ , "ignore_index" ) )
self.assertTrue(hasattr(snake_case__ , "class_info_file" ) )
self.assertTrue(hasattr(snake_case__ , "num_text" ) )
self.assertTrue(hasattr(snake_case__ , "repo_path" ) )
self.assertTrue(hasattr(snake_case__ , "metadata" ) )
self.assertTrue(hasattr(snake_case__ , "do_reduce_labels" ) )
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> str:
'''simple docstring'''
pass
def _SCREAMING_SNAKE_CASE (self : Dict ) -> Any:
'''simple docstring'''
snake_case : Optional[int] = self.image_processing_class(**self.image_processor_dict )
# create random PIL images
snake_case : Dict = prepare_image_inputs(self.image_processing_tester , equal_resolution=snake_case__ )
for image in image_inputs:
self.assertIsInstance(snake_case__ , Image.Image )
# Test not batched input
snake_case : Optional[int] = image_processor(image_inputs[0] , ["semantic"] , return_tensors="pt" ).pixel_values
snake_case , snake_case : Optional[Any] = self.image_processing_tester.get_expected_values(snake_case__ )
self.assertEqual(
encoded_images.shape , (1, self.image_processing_tester.num_channels, expected_height, expected_width) , )
# Test batched
snake_case , snake_case : Optional[int] = self.image_processing_tester.get_expected_values(snake_case__ , batched=snake_case__ )
snake_case : str = image_processor(
snake_case__ , ["semantic"] * len(snake_case__ ) , return_tensors="pt" ).pixel_values
self.assertEqual(
encoded_images.shape , (
self.image_processing_tester.batch_size,
self.image_processing_tester.num_channels,
expected_height,
expected_width,
) , )
def _SCREAMING_SNAKE_CASE (self : Union[str, Any] ) -> Tuple:
'''simple docstring'''
snake_case : Union[str, Any] = self.image_processing_class(**self.image_processor_dict )
# create random numpy tensors
snake_case : List[str] = prepare_image_inputs(self.image_processing_tester , equal_resolution=snake_case__ , numpify=snake_case__ )
for image in image_inputs:
self.assertIsInstance(snake_case__ , np.ndarray )
# Test not batched input
snake_case : Union[str, Any] = image_processor(image_inputs[0] , ["semantic"] , return_tensors="pt" ).pixel_values
snake_case , snake_case : int = self.image_processing_tester.get_expected_values(snake_case__ )
self.assertEqual(
encoded_images.shape , (1, self.image_processing_tester.num_channels, expected_height, expected_width) , )
# Test batched
snake_case , snake_case : Union[str, Any] = self.image_processing_tester.get_expected_values(snake_case__ , batched=snake_case__ )
snake_case : Optional[int] = image_processor(
snake_case__ , ["semantic"] * len(snake_case__ ) , return_tensors="pt" ).pixel_values
self.assertEqual(
encoded_images.shape , (
self.image_processing_tester.batch_size,
self.image_processing_tester.num_channels,
expected_height,
expected_width,
) , )
def _SCREAMING_SNAKE_CASE (self : Union[str, Any] ) -> List[Any]:
'''simple docstring'''
snake_case : Union[str, Any] = self.image_processing_class(**self.image_processor_dict )
# create random PyTorch tensors
snake_case : Any = prepare_image_inputs(self.image_processing_tester , equal_resolution=snake_case__ , torchify=snake_case__ )
for image in image_inputs:
self.assertIsInstance(snake_case__ , torch.Tensor )
# Test not batched input
snake_case : Any = image_processor(image_inputs[0] , ["semantic"] , return_tensors="pt" ).pixel_values
snake_case , snake_case : Union[str, Any] = self.image_processing_tester.get_expected_values(snake_case__ )
self.assertEqual(
encoded_images.shape , (1, self.image_processing_tester.num_channels, expected_height, expected_width) , )
# Test batched
snake_case , snake_case : Optional[int] = self.image_processing_tester.get_expected_values(snake_case__ , batched=snake_case__ )
snake_case : List[str] = image_processor(
snake_case__ , ["semantic"] * len(snake_case__ ) , return_tensors="pt" ).pixel_values
self.assertEqual(
encoded_images.shape , (
self.image_processing_tester.batch_size,
self.image_processing_tester.num_channels,
expected_height,
expected_width,
) , )
def _SCREAMING_SNAKE_CASE (self : Dict , snake_case__ : Dict=False , snake_case__ : Union[str, Any]=False , snake_case__ : str="np" ) -> Optional[int]:
'''simple docstring'''
snake_case : Optional[int] = self.image_processing_class(**self.image_processor_dict )
# prepare image and target
snake_case : int = self.image_processing_tester.num_labels
snake_case : Tuple = None
snake_case : List[str] = None
snake_case : Optional[int] = prepare_image_inputs(self.image_processing_tester , equal_resolution=snake_case__ )
if with_segmentation_maps:
snake_case : List[str] = num_labels
if is_instance_map:
snake_case : int = list(range(snake_case__ ) ) * 2
snake_case : Union[str, Any] = dict(enumerate(snake_case__ ) )
snake_case : Optional[Any] = [
np.random.randint(0 , high * 2 , (img.size[1], img.size[0]) ).astype(np.uinta ) for img in image_inputs
]
if segmentation_type == "pil":
snake_case : List[str] = [Image.fromarray(snake_case__ ) for annotation in annotations]
snake_case : Dict = image_processor(
snake_case__ , ["semantic"] * len(snake_case__ ) , snake_case__ , return_tensors="pt" , instance_id_to_semantic_id=snake_case__ , pad_and_return_pixel_mask=snake_case__ , )
return inputs
def _SCREAMING_SNAKE_CASE (self : int ) -> Dict:
'''simple docstring'''
pass
def _SCREAMING_SNAKE_CASE (self : Any ) -> Dict:
'''simple docstring'''
def common(snake_case__ : List[str]=False , snake_case__ : Optional[Any]=None ):
snake_case : Dict = self.comm_get_image_processor_inputs(
with_segmentation_maps=snake_case__ , is_instance_map=snake_case__ , segmentation_type=snake_case__ )
snake_case : List[str] = inputs["mask_labels"]
snake_case : Tuple = inputs["class_labels"]
snake_case : Dict = inputs["pixel_values"]
snake_case : Tuple = inputs["text_inputs"]
# check the batch_size
for mask_label, class_label, text_input in zip(snake_case__ , snake_case__ , snake_case__ ):
self.assertEqual(mask_label.shape[0] , class_label.shape[0] )
# this ensure padding has happened
self.assertEqual(mask_label.shape[1:] , pixel_values.shape[2:] )
self.assertEqual(len(snake_case__ ) , self.image_processing_tester.num_text )
common()
common(is_instance_map=snake_case__ )
common(is_instance_map=snake_case__ , segmentation_type="pil" )
common(is_instance_map=snake_case__ , segmentation_type="pil" )
def _SCREAMING_SNAKE_CASE (self : List[Any] ) -> Union[str, Any]:
'''simple docstring'''
snake_case : Any = np.zeros((20, 50) )
snake_case : List[str] = 1
snake_case : List[str] = 1
snake_case : Optional[Any] = 1
snake_case : int = binary_mask_to_rle(snake_case__ )
self.assertEqual(len(snake_case__ ) , 4 )
self.assertEqual(rle[0] , 21 )
self.assertEqual(rle[1] , 45 )
def _SCREAMING_SNAKE_CASE (self : Optional[Any] ) -> int:
'''simple docstring'''
snake_case : int = self.image_processing_class(
num_labels=self.image_processing_tester.num_classes , max_seq_length=77 , task_seq_length=77 , class_info_file="ade20k_panoptic.json" , num_text=self.image_processing_tester.num_text , repo_path="shi-labs/oneformer_demo" , )
snake_case : Optional[int] = self.image_processing_tester.get_fake_oneformer_outputs()
snake_case : Tuple = fature_extractor.post_process_semantic_segmentation(snake_case__ )
self.assertEqual(len(snake_case__ ) , self.image_processing_tester.batch_size )
self.assertEqual(
segmentation[0].shape , (
self.image_processing_tester.height,
self.image_processing_tester.width,
) , )
snake_case : Union[str, Any] = [(1, 4) for i in range(self.image_processing_tester.batch_size )]
snake_case : Optional[int] = fature_extractor.post_process_semantic_segmentation(snake_case__ , target_sizes=snake_case__ )
self.assertEqual(segmentation[0].shape , target_sizes[0] )
def _SCREAMING_SNAKE_CASE (self : Tuple ) -> List[str]:
'''simple docstring'''
snake_case : str = self.image_processing_class(
num_labels=self.image_processing_tester.num_classes , max_seq_length=77 , task_seq_length=77 , class_info_file="ade20k_panoptic.json" , num_text=self.image_processing_tester.num_text , repo_path="shi-labs/oneformer_demo" , )
snake_case : int = self.image_processing_tester.get_fake_oneformer_outputs()
snake_case : List[str] = image_processor.post_process_instance_segmentation(snake_case__ , threshold=0 )
self.assertTrue(len(snake_case__ ) == self.image_processing_tester.batch_size )
for el in segmentation:
self.assertTrue("segmentation" in el )
self.assertTrue("segments_info" in el )
self.assertEqual(type(el["segments_info"] ) , snake_case__ )
self.assertEqual(
el["segmentation"].shape , (self.image_processing_tester.height, self.image_processing_tester.width) )
def _SCREAMING_SNAKE_CASE (self : str ) -> str:
'''simple docstring'''
snake_case : Tuple = self.image_processing_class(
num_labels=self.image_processing_tester.num_classes , max_seq_length=77 , task_seq_length=77 , class_info_file="ade20k_panoptic.json" , num_text=self.image_processing_tester.num_text , repo_path="shi-labs/oneformer_demo" , )
snake_case : Dict = self.image_processing_tester.get_fake_oneformer_outputs()
snake_case : List[Any] = image_processor.post_process_panoptic_segmentation(snake_case__ , threshold=0 )
self.assertTrue(len(snake_case__ ) == self.image_processing_tester.batch_size )
for el in segmentation:
self.assertTrue("segmentation" in el )
self.assertTrue("segments_info" in el )
self.assertEqual(type(el["segments_info"] ) , snake_case__ )
self.assertEqual(
el["segmentation"].shape , (self.image_processing_tester.height, self.image_processing_tester.width) )
| 59
|
import logging
import os
from dataclasses import dataclass, field
from typing import Dict, Optional
import datasets
import numpy as np
import tensorflow as tf
from transformers import (
AutoConfig,
AutoTokenizer,
EvalPrediction,
HfArgumentParser,
PreTrainedTokenizer,
TFAutoModelForSequenceClassification,
TFTrainer,
TFTrainingArguments,
)
from transformers.utils import logging as hf_logging
hf_logging.set_verbosity_info()
hf_logging.enable_default_handler()
hf_logging.enable_explicit_format()
def UpperCamelCase ( __lowerCamelCase : str , __lowerCamelCase : str , __lowerCamelCase : str , __lowerCamelCase : PreTrainedTokenizer , __lowerCamelCase : int , __lowerCamelCase : Optional[int] = None , ):
snake_case : int = {}
if train_file is not None:
snake_case : List[Any] = [train_file]
if eval_file is not None:
snake_case : Optional[int] = [eval_file]
if test_file is not None:
snake_case : Any = [test_file]
snake_case : int = datasets.load_dataset("csv" , data_files=__lowerCamelCase )
snake_case : str = list(ds[list(files.keys() )[0]].features.keys() )
snake_case : int = features_name.pop(__lowerCamelCase )
snake_case : str = list(set(ds[list(files.keys() )[0]][label_name] ) )
snake_case : str = {label: i for i, label in enumerate(__lowerCamelCase )}
snake_case : List[Any] = tokenizer.model_input_names
snake_case : List[Any] = {}
if len(__lowerCamelCase ) == 1:
for k in files.keys():
snake_case : Tuple = ds[k].map(
lambda __lowerCamelCase : tokenizer.batch_encode_plus(
example[features_name[0]] , truncation=__lowerCamelCase , max_length=__lowerCamelCase , padding="max_length" ) , batched=__lowerCamelCase , )
elif len(__lowerCamelCase ) == 2:
for k in files.keys():
snake_case : List[Any] = ds[k].map(
lambda __lowerCamelCase : tokenizer.batch_encode_plus(
(example[features_name[0]], example[features_name[1]]) , truncation=__lowerCamelCase , max_length=__lowerCamelCase , padding="max_length" , ) , batched=__lowerCamelCase , )
def gen_train():
for ex in transformed_ds[datasets.Split.TRAIN]:
snake_case : Dict = {k: v for k, v in ex.items() if k in input_names}
snake_case : Union[str, Any] = labelaid[ex[label_name]]
yield (d, label)
def gen_val():
for ex in transformed_ds[datasets.Split.VALIDATION]:
snake_case : str = {k: v for k, v in ex.items() if k in input_names}
snake_case : Any = labelaid[ex[label_name]]
yield (d, label)
def gen_test():
for ex in transformed_ds[datasets.Split.TEST]:
snake_case : str = {k: v for k, v in ex.items() if k in input_names}
snake_case : List[str] = labelaid[ex[label_name]]
yield (d, label)
snake_case : int = (
tf.data.Dataset.from_generator(
__lowerCamelCase , ({k: tf.intaa for k in input_names}, tf.intaa) , ({k: tf.TensorShape([None] ) for k in input_names}, tf.TensorShape([] )) , )
if datasets.Split.TRAIN in transformed_ds
else None
)
if train_ds is not None:
snake_case : Optional[Any] = train_ds.apply(tf.data.experimental.assert_cardinality(len(ds[datasets.Split.TRAIN] ) ) )
snake_case : Tuple = (
tf.data.Dataset.from_generator(
__lowerCamelCase , ({k: tf.intaa for k in input_names}, tf.intaa) , ({k: tf.TensorShape([None] ) for k in input_names}, tf.TensorShape([] )) , )
if datasets.Split.VALIDATION in transformed_ds
else None
)
if val_ds is not None:
snake_case : List[str] = val_ds.apply(tf.data.experimental.assert_cardinality(len(ds[datasets.Split.VALIDATION] ) ) )
snake_case : Optional[int] = (
tf.data.Dataset.from_generator(
__lowerCamelCase , ({k: tf.intaa for k in input_names}, tf.intaa) , ({k: tf.TensorShape([None] ) for k in input_names}, tf.TensorShape([] )) , )
if datasets.Split.TEST in transformed_ds
else None
)
if test_ds is not None:
snake_case : str = test_ds.apply(tf.data.experimental.assert_cardinality(len(ds[datasets.Split.TEST] ) ) )
return train_ds, val_ds, test_ds, labelaid
__lowerCamelCase = logging.getLogger(__name__)
@dataclass
class UpperCAmelCase :
A__ : int = field(metadata={"help": "Which column contains the label"} )
A__ : str = field(default=A_ ,metadata={"help": "The path of the training file"} )
A__ : Optional[str] = field(default=A_ ,metadata={"help": "The path of the development file"} )
A__ : Optional[str] = field(default=A_ ,metadata={"help": "The path of the test file"} )
A__ : int = field(
default=1_28 ,metadata={
"help": (
"The maximum total input sequence length after tokenization. Sequences longer "
"than this will be truncated, sequences shorter will be padded."
)
} ,)
A__ : bool = field(
default=A_ ,metadata={"help": "Overwrite the cached training and evaluation sets"} )
@dataclass
class UpperCAmelCase :
A__ : str = field(
metadata={"help": "Path to pretrained model or model identifier from huggingface.co/models"} )
A__ : Optional[str] = field(
default=A_ ,metadata={"help": "Pretrained config name or path if not the same as model_name"} )
A__ : Optional[str] = field(
default=A_ ,metadata={"help": "Pretrained tokenizer name or path if not the same as model_name"} )
A__ : bool = 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.
A__ : Optional[str] = field(
default=A_ ,metadata={"help": "Where do you want to store the pretrained models downloaded from huggingface.co"} ,)
def UpperCamelCase ( ):
# See all possible arguments in src/transformers/training_args.py
# or by passing the --help flag to this script.
# We now keep distinct sets of args, for a cleaner separation of concerns.
snake_case : List[Any] = HfArgumentParser((ModelArguments, DataTrainingArguments, TFTrainingArguments) )
snake_case , snake_case , snake_case : int = parser.parse_args_into_dataclasses()
if (
os.path.exists(training_args.output_dir )
and os.listdir(training_args.output_dir )
and training_args.do_train
and not training_args.overwrite_output_dir
):
raise ValueError(
f"""Output directory ({training_args.output_dir}) already exists and is not empty. Use"""
" --overwrite_output_dir to overcome." )
# Setup logging
logging.basicConfig(
format="%(asctime)s - %(levelname)s - %(name)s - %(message)s" , datefmt="%m/%d/%Y %H:%M:%S" , level=logging.INFO , )
logger.info(
f"""n_replicas: {training_args.n_replicas}, distributed training: {bool(training_args.n_replicas > 1 )}, """
f"""16-bits training: {training_args.fpaa}""" )
logger.info(f"""Training/evaluation parameters {training_args}""" )
# Load pretrained model and tokenizer
#
# Distributed training:
# The .from_pretrained methods guarantee that only one local process can concurrently
# download model & vocab.
snake_case : Tuple = AutoTokenizer.from_pretrained(
model_args.tokenizer_name if model_args.tokenizer_name else model_args.model_name_or_path , cache_dir=model_args.cache_dir , )
snake_case , snake_case , snake_case , snake_case : Tuple = get_tfds(
train_file=data_args.train_file , eval_file=data_args.dev_file , test_file=data_args.test_file , tokenizer=__lowerCamelCase , label_column_id=data_args.label_column_id , max_seq_length=data_args.max_seq_length , )
snake_case : Optional[Any] = AutoConfig.from_pretrained(
model_args.config_name if model_args.config_name else model_args.model_name_or_path , num_labels=len(__lowerCamelCase ) , labelaid=__lowerCamelCase , idalabel={id: label for label, id in labelaid.items()} , finetuning_task="text-classification" , cache_dir=model_args.cache_dir , )
with training_args.strategy.scope():
snake_case : int = TFAutoModelForSequenceClassification.from_pretrained(
model_args.model_name_or_path , from_pt=bool(".bin" in model_args.model_name_or_path ) , config=__lowerCamelCase , cache_dir=model_args.cache_dir , )
def compute_metrics(__lowerCamelCase : EvalPrediction ) -> Dict:
snake_case : Optional[int] = np.argmax(p.predictions , axis=1 )
return {"acc": (preds == p.label_ids).mean()}
# Initialize our Trainer
snake_case : int = TFTrainer(
model=__lowerCamelCase , args=__lowerCamelCase , train_dataset=__lowerCamelCase , eval_dataset=__lowerCamelCase , compute_metrics=__lowerCamelCase , )
# Training
if training_args.do_train:
trainer.train()
trainer.save_model()
tokenizer.save_pretrained(training_args.output_dir )
# Evaluation
snake_case : int = {}
if training_args.do_eval:
logger.info("*** Evaluate ***" )
snake_case : Any = trainer.evaluate()
snake_case : List[Any] = os.path.join(training_args.output_dir , "eval_results.txt" )
with open(__lowerCamelCase , "w" ) as writer:
logger.info("***** Eval results *****" )
for key, value in result.items():
logger.info(f""" {key} = {value}""" )
writer.write(f"""{key} = {value}\n""" )
results.update(__lowerCamelCase )
return results
if __name__ == "__main__":
main()
| 59
| 1
|
def UpperCamelCase ( __lowerCamelCase : str ):
if not all(char in "01" for char in bin_string ):
raise ValueError("Non-binary value was passed to the function" )
if not bin_string:
raise ValueError("Empty string was passed to the function" )
snake_case : Tuple = ""
while len(__lowerCamelCase ) % 3 != 0:
snake_case : Any = "0" + bin_string
snake_case : Any = [
bin_string[index : index + 3]
for index in range(len(__lowerCamelCase ) )
if index % 3 == 0
]
for bin_group in bin_string_in_3_list:
snake_case : Union[str, Any] = 0
for index, val in enumerate(__lowerCamelCase ):
oct_val += int(2 ** (2 - index) * int(__lowerCamelCase ) )
oct_string += str(__lowerCamelCase )
return oct_string
if __name__ == "__main__":
from doctest import testmod
testmod()
| 59
|
import json
import os
import shutil
import tempfile
import unittest
import numpy as np
from transformers import BertTokenizerFast
from transformers.models.bert.tokenization_bert import VOCAB_FILES_NAMES, BertTokenizer
from transformers.testing_utils import require_tokenizers, require_vision
from transformers.utils import IMAGE_PROCESSOR_NAME, is_vision_available
if is_vision_available():
from PIL import Image
from transformers import VisionTextDualEncoderProcessor, ViTImageProcessor
@require_tokenizers
@require_vision
class UpperCAmelCase ( unittest.TestCase ):
def _SCREAMING_SNAKE_CASE (self : Any ) -> List[str]:
'''simple docstring'''
snake_case : int = tempfile.mkdtemp()
# fmt: off
snake_case : Optional[int] = ["[UNK]", "[CLS]", "[SEP]", "[PAD]", "[MASK]", "want", "##want", "##ed", "wa", "un", "runn", "##ing", ",", "low", "lowest"]
# fmt: on
snake_case : List[str] = os.path.join(self.tmpdirname , VOCAB_FILES_NAMES["vocab_file"] )
with open(self.vocab_file , "w" , encoding="utf-8" ) as vocab_writer:
vocab_writer.write("".join([x + "\n" for x in vocab_tokens] ) )
snake_case : int = {
"do_resize": True,
"size": {"height": 18, "width": 18},
"do_normalize": True,
"image_mean": [0.5, 0.5, 0.5],
"image_std": [0.5, 0.5, 0.5],
}
snake_case : Optional[Any] = os.path.join(self.tmpdirname , snake_case__ )
with open(self.image_processor_file , "w" , encoding="utf-8" ) as fp:
json.dump(snake_case__ , snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Optional[Any] , **snake_case__ : str ) -> Optional[int]:
'''simple docstring'''
return BertTokenizer.from_pretrained(self.tmpdirname , **snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Optional[Any] , **snake_case__ : List[str] ) -> int:
'''simple docstring'''
return ViTImageProcessor.from_pretrained(self.tmpdirname , **snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> Dict:
'''simple docstring'''
shutil.rmtree(self.tmpdirname )
def _SCREAMING_SNAKE_CASE (self : Dict ) -> str:
'''simple docstring'''
snake_case : List[Any] = [np.random.randint(2_55 , size=(3, 30, 4_00) , dtype=np.uinta )]
snake_case : Optional[int] = [Image.fromarray(np.moveaxis(snake_case__ , 0 , -1 ) ) for x in image_inputs]
return image_inputs
def _SCREAMING_SNAKE_CASE (self : Union[str, Any] ) -> Union[str, Any]:
'''simple docstring'''
snake_case : Dict = self.get_tokenizer()
snake_case : Optional[Any] = self.get_image_processor()
snake_case : Optional[Any] = VisionTextDualEncoderProcessor(tokenizer=snake_case__ , image_processor=snake_case__ )
processor.save_pretrained(self.tmpdirname )
snake_case : Any = VisionTextDualEncoderProcessor.from_pretrained(self.tmpdirname )
self.assertEqual(processor.tokenizer.get_vocab() , tokenizer.get_vocab() )
self.assertIsInstance(processor.tokenizer , (BertTokenizer, BertTokenizerFast) )
self.assertEqual(processor.image_processor.to_json_string() , image_processor.to_json_string() )
self.assertIsInstance(processor.image_processor , snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Any ) -> Optional[Any]:
'''simple docstring'''
snake_case : str = VisionTextDualEncoderProcessor(
tokenizer=self.get_tokenizer() , image_processor=self.get_image_processor() )
processor.save_pretrained(self.tmpdirname )
snake_case : Optional[int] = self.get_tokenizer(bos_token="(BOS)" , eos_token="(EOS)" )
snake_case : Tuple = self.get_image_processor(do_normalize=snake_case__ , padding_value=1.0 )
snake_case : List[str] = VisionTextDualEncoderProcessor.from_pretrained(
self.tmpdirname , bos_token="(BOS)" , eos_token="(EOS)" , do_normalize=snake_case__ , padding_value=1.0 )
self.assertEqual(processor.tokenizer.get_vocab() , tokenizer_add_kwargs.get_vocab() )
self.assertIsInstance(processor.tokenizer , (BertTokenizer, BertTokenizerFast) )
self.assertEqual(processor.image_processor.to_json_string() , image_processor_add_kwargs.to_json_string() )
self.assertIsInstance(processor.image_processor , snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Union[str, Any] ) -> int:
'''simple docstring'''
snake_case : str = self.get_image_processor()
snake_case : Optional[int] = self.get_tokenizer()
snake_case : List[Any] = VisionTextDualEncoderProcessor(tokenizer=snake_case__ , image_processor=snake_case__ )
snake_case : Optional[Any] = self.prepare_image_inputs()
snake_case : str = image_processor(snake_case__ , return_tensors="np" )
snake_case : Any = processor(images=snake_case__ , return_tensors="np" )
for key in input_feat_extract.keys():
self.assertAlmostEqual(input_feat_extract[key].sum() , input_processor[key].sum() , delta=1e-2 )
def _SCREAMING_SNAKE_CASE (self : Tuple ) -> Optional[Any]:
'''simple docstring'''
snake_case : Dict = self.get_image_processor()
snake_case : int = self.get_tokenizer()
snake_case : Any = VisionTextDualEncoderProcessor(tokenizer=snake_case__ , image_processor=snake_case__ )
snake_case : Tuple = "lower newer"
snake_case : Tuple = processor(text=snake_case__ )
snake_case : Union[str, Any] = tokenizer(snake_case__ )
for key in encoded_tok.keys():
self.assertListEqual(encoded_tok[key] , encoded_processor[key] )
def _SCREAMING_SNAKE_CASE (self : Dict ) -> Optional[int]:
'''simple docstring'''
snake_case : List[Any] = self.get_image_processor()
snake_case : Dict = self.get_tokenizer()
snake_case : Dict = VisionTextDualEncoderProcessor(tokenizer=snake_case__ , image_processor=snake_case__ )
snake_case : int = "lower newer"
snake_case : Dict = self.prepare_image_inputs()
snake_case : Union[str, Any] = processor(text=snake_case__ , images=snake_case__ )
self.assertListEqual(list(inputs.keys() ) , ["input_ids", "token_type_ids", "attention_mask", "pixel_values"] )
# test if it raises when no input is passed
with self.assertRaises(snake_case__ ):
processor()
def _SCREAMING_SNAKE_CASE (self : str ) -> Tuple:
'''simple docstring'''
snake_case : Tuple = self.get_image_processor()
snake_case : Optional[Any] = self.get_tokenizer()
snake_case : Tuple = VisionTextDualEncoderProcessor(tokenizer=snake_case__ , image_processor=snake_case__ )
snake_case : List[str] = [[1, 4, 5, 8, 1, 0, 8], [3, 4, 3, 1, 1, 8, 9]]
snake_case : List[Any] = processor.batch_decode(snake_case__ )
snake_case : Union[str, Any] = tokenizer.batch_decode(snake_case__ )
self.assertListEqual(snake_case__ , snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> List[str]:
'''simple docstring'''
snake_case : str = self.get_image_processor()
snake_case : Union[str, Any] = self.get_tokenizer()
snake_case : Any = VisionTextDualEncoderProcessor(tokenizer=snake_case__ , image_processor=snake_case__ )
snake_case : Optional[Any] = "lower newer"
snake_case : List[Any] = self.prepare_image_inputs()
snake_case : Tuple = processor(text=snake_case__ , images=snake_case__ )
self.assertListEqual(list(inputs.keys() ) , processor.model_input_names )
| 59
| 1
|
from manim import *
class UpperCAmelCase ( A_ ):
def _SCREAMING_SNAKE_CASE (self : List[str] ) -> Optional[int]:
'''simple docstring'''
snake_case : Dict = Rectangle(height=0.5 , width=0.5 )
snake_case : Optional[Any] = Rectangle(height=0.46 , width=0.46 ).set_stroke(width=0 )
snake_case : List[str] = [mem.copy() for i in range(6 )]
snake_case : Any = [mem.copy() for i in range(6 )]
snake_case : Dict = VGroup(*snake_case__ ).arrange(snake_case__ , buff=0 )
snake_case : Union[str, Any] = VGroup(*snake_case__ ).arrange(snake_case__ , buff=0 )
snake_case : Any = VGroup(snake_case__ , snake_case__ ).arrange(snake_case__ , buff=0 )
snake_case : Dict = Text("CPU" , font_size=24 )
snake_case : Optional[Any] = Group(snake_case__ , snake_case__ ).arrange(snake_case__ , buff=0.5 , aligned_edge=snake_case__ )
cpu.move_to([-2.5, -0.5, 0] )
self.add(snake_case__ )
snake_case : Any = [mem.copy() for i in range(1 )]
snake_case : str = VGroup(*snake_case__ ).arrange(snake_case__ , buff=0 )
snake_case : Tuple = Text("GPU" , font_size=24 )
snake_case : List[Any] = Group(snake_case__ , snake_case__ ).arrange(snake_case__ , buff=0.5 , aligned_edge=snake_case__ )
gpu.align_to(snake_case__ , snake_case__ )
gpu.set_x(gpu.get_x() - 1 )
self.add(snake_case__ )
snake_case : Any = [mem.copy() for i in range(6 )]
snake_case : Tuple = VGroup(*snake_case__ ).arrange(snake_case__ , buff=0 )
snake_case : int = Text("Model" , font_size=24 )
snake_case : List[str] = Group(snake_case__ , snake_case__ ).arrange(snake_case__ , buff=0.5 , aligned_edge=snake_case__ )
model.move_to([3, -1.0, 0] )
self.play(
Create(snake_case__ , run_time=1 ) , Create(snake_case__ , run_time=1 ) , Create(snake_case__ , run_time=1 ) , )
snake_case : List[str] = MarkupText(
f"""First, an empty model skeleton is loaded\ninto <span fgcolor='{YELLOW}'>memory</span> without using much RAM.""" , font_size=24 , )
snake_case : List[str] = Square(side_length=2.2 )
key.move_to([-5, 2, 0] )
snake_case : Optional[int] = MarkupText(
f"""<b>Key:</b>\n\n<span fgcolor='{YELLOW}'>●</span> Empty Model""" , font_size=18 , )
key_text.move_to([-5, 2.4, 0] )
step_a.move_to([2, 2, 0] )
self.play(Write(snake_case__ , run_time=2.5 ) , Write(snake_case__ ) , Write(snake_case__ ) )
self.add(snake_case__ )
snake_case : str = []
snake_case : str = []
snake_case : Dict = []
for i, rect in enumerate(snake_case__ ):
snake_case : int = Rectangle(height=0.46 , width=0.46 ).set_stroke(width=0.0 ).set_fill(snake_case__ , opacity=0.7 )
cpu_target.move_to(snake_case__ )
cpu_target.generate_target()
snake_case : Optional[int] = 0.46 / 4
snake_case : int = 0.46 / 3
if i == 0:
cpu_target.target.next_to(cpu_left_col_base[0].get_corner(DOWN + LEFT ) , buff=0.02 , direction=snake_case__ )
cpu_target.target.set_x(cpu_target.target.get_x() + 0.1 )
elif i == 3:
cpu_target.target.next_to(cpu_targs[0].target , direction=snake_case__ , buff=0.0 )
else:
cpu_target.target.next_to(cpu_targs[i - 1].target , direction=snake_case__ , buff=0.0 )
cpu_targs.append(snake_case__ )
first_animations.append(rect.animate(run_time=0.5 ).set_stroke(snake_case__ ) )
second_animations.append(MoveToTarget(snake_case__ , run_time=1.5 ) )
self.play(*snake_case__ )
self.play(*snake_case__ )
self.wait()
| 59
|
from typing import TYPE_CHECKING
from ...utils import OptionalDependencyNotAvailable, _LazyModule, is_tokenizers_available, is_torch_available
__lowerCamelCase = {
"""configuration_biogpt""": ["""BIOGPT_PRETRAINED_CONFIG_ARCHIVE_MAP""", """BioGptConfig"""],
"""tokenization_biogpt""": ["""BioGptTokenizer"""],
}
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = [
"""BIOGPT_PRETRAINED_MODEL_ARCHIVE_LIST""",
"""BioGptForCausalLM""",
"""BioGptForTokenClassification""",
"""BioGptForSequenceClassification""",
"""BioGptModel""",
"""BioGptPreTrainedModel""",
]
if TYPE_CHECKING:
from .configuration_biogpt import BIOGPT_PRETRAINED_CONFIG_ARCHIVE_MAP, BioGptConfig
from .tokenization_biogpt import BioGptTokenizer
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_biogpt import (
BIOGPT_PRETRAINED_MODEL_ARCHIVE_LIST,
BioGptForCausalLM,
BioGptForSequenceClassification,
BioGptForTokenClassification,
BioGptModel,
BioGptPreTrainedModel,
)
else:
import sys
__lowerCamelCase = _LazyModule(__name__, globals()["""__file__"""], _import_structure, module_spec=__spec__)
| 59
| 1
|
__lowerCamelCase = {
"joule": 1.0,
"kilojoule": 10_00,
"megajoule": 1_00_00_00,
"gigajoule": 10_00_00_00_00,
"wattsecond": 1.0,
"watthour": 36_00,
"kilowatthour": 3_60_00_00,
"newtonmeter": 1.0,
"calorie_nutr": 41_86.8,
"kilocalorie_nutr": 4_18_68_00.00,
"electronvolt": 1.602_176_634e-19,
"britishthermalunit_it": 10_55.0_55_85,
"footpound": 1.35_5818,
}
def UpperCamelCase ( __lowerCamelCase : str , __lowerCamelCase : str , __lowerCamelCase : float ):
if to_type not in ENERGY_CONVERSION or from_type not in ENERGY_CONVERSION:
snake_case : List[Any] = (
f"""Incorrect 'from_type' or 'to_type' value: {from_type!r}, {to_type!r}\n"""
f"""Valid values are: {', '.join(__lowerCamelCase )}"""
)
raise ValueError(__lowerCamelCase )
return value * ENERGY_CONVERSION[from_type] / ENERGY_CONVERSION[to_type]
if __name__ == "__main__":
import doctest
doctest.testmod()
| 59
|
import collections
import inspect
import unittest
from typing import Dict, List, Tuple
from transformers import MaskFormerSwinConfig
from transformers.testing_utils import require_torch, require_torch_multi_gpu, torch_device
from transformers.utils import is_torch_available
from ...test_backbone_common import BackboneTesterMixin
from ...test_configuration_common import ConfigTester
from ...test_modeling_common import ModelTesterMixin, floats_tensor, ids_tensor
from ...test_pipeline_mixin import PipelineTesterMixin
if is_torch_available():
import torch
from torch import nn
from transformers import MaskFormerSwinBackbone
from transformers.models.maskformer import MaskFormerSwinModel
class UpperCAmelCase :
def __init__(self : Dict , snake_case__ : Dict , snake_case__ : Any=13 , snake_case__ : Any=32 , snake_case__ : Optional[Any]=2 , snake_case__ : Union[str, Any]=3 , snake_case__ : List[Any]=16 , snake_case__ : int=[1, 2, 1] , snake_case__ : Dict=[2, 2, 4] , snake_case__ : Dict=2 , snake_case__ : Tuple=2.0 , snake_case__ : Optional[int]=True , snake_case__ : Union[str, Any]=0.0 , snake_case__ : Any=0.0 , snake_case__ : Union[str, Any]=0.1 , snake_case__ : int="gelu" , snake_case__ : Optional[int]=False , snake_case__ : List[Any]=True , snake_case__ : List[str]=0.02 , snake_case__ : int=1e-5 , snake_case__ : List[str]=True , snake_case__ : Union[str, Any]=None , snake_case__ : List[Any]=True , snake_case__ : Optional[Any]=10 , snake_case__ : Optional[Any]=8 , snake_case__ : Any=["stage1", "stage2", "stage3"] , snake_case__ : Tuple=[1, 2, 3] , ) -> Union[str, Any]:
'''simple docstring'''
snake_case : Any = parent
snake_case : Optional[int] = batch_size
snake_case : Union[str, Any] = image_size
snake_case : Dict = patch_size
snake_case : Optional[Any] = num_channels
snake_case : Union[str, Any] = embed_dim
snake_case : int = depths
snake_case : List[str] = num_heads
snake_case : Union[str, Any] = window_size
snake_case : Union[str, Any] = mlp_ratio
snake_case : List[Any] = qkv_bias
snake_case : List[Any] = hidden_dropout_prob
snake_case : Union[str, Any] = attention_probs_dropout_prob
snake_case : Union[str, Any] = drop_path_rate
snake_case : int = hidden_act
snake_case : Optional[int] = use_absolute_embeddings
snake_case : int = patch_norm
snake_case : Union[str, Any] = layer_norm_eps
snake_case : Any = initializer_range
snake_case : Optional[Any] = is_training
snake_case : Tuple = scope
snake_case : Optional[int] = use_labels
snake_case : Optional[Any] = type_sequence_label_size
snake_case : Union[str, Any] = encoder_stride
snake_case : Any = out_features
snake_case : Tuple = out_indices
def _SCREAMING_SNAKE_CASE (self : Optional[Any] ) -> Dict:
'''simple docstring'''
snake_case : Optional[Any] = floats_tensor([self.batch_size, self.num_channels, self.image_size, self.image_size] )
snake_case : int = None
if self.use_labels:
snake_case : Tuple = ids_tensor([self.batch_size] , self.type_sequence_label_size )
snake_case : Dict = self.get_config()
return config, pixel_values, labels
def _SCREAMING_SNAKE_CASE (self : List[str] ) -> int:
'''simple docstring'''
return MaskFormerSwinConfig(
image_size=self.image_size , patch_size=self.patch_size , num_channels=self.num_channels , embed_dim=self.embed_dim , depths=self.depths , num_heads=self.num_heads , window_size=self.window_size , mlp_ratio=self.mlp_ratio , qkv_bias=self.qkv_bias , hidden_dropout_prob=self.hidden_dropout_prob , attention_probs_dropout_prob=self.attention_probs_dropout_prob , drop_path_rate=self.drop_path_rate , hidden_act=self.hidden_act , use_absolute_embeddings=self.use_absolute_embeddings , path_norm=self.patch_norm , layer_norm_eps=self.layer_norm_eps , initializer_range=self.initializer_range , encoder_stride=self.encoder_stride , out_features=self.out_features , out_indices=self.out_indices , )
def _SCREAMING_SNAKE_CASE (self : Tuple , snake_case__ : List[Any] , snake_case__ : List[str] , snake_case__ : Tuple ) -> Optional[Any]:
'''simple docstring'''
snake_case : Union[str, Any] = MaskFormerSwinModel(config=snake_case__ )
model.to(snake_case__ )
model.eval()
snake_case : List[Any] = model(snake_case__ )
snake_case : Dict = ((config.image_size // config.patch_size) ** 2) // (4 ** (len(config.depths ) - 1))
snake_case : int = int(config.embed_dim * 2 ** (len(config.depths ) - 1) )
self.parent.assertEqual(result.last_hidden_state.shape , (self.batch_size, expected_seq_len, expected_dim) )
def _SCREAMING_SNAKE_CASE (self : List[str] , snake_case__ : Union[str, Any] , snake_case__ : List[Any] , snake_case__ : Union[str, Any] ) -> str:
'''simple docstring'''
snake_case : Optional[int] = MaskFormerSwinBackbone(config=snake_case__ )
model.to(snake_case__ )
model.eval()
snake_case : List[Any] = model(snake_case__ )
# verify feature maps
self.parent.assertEqual(len(result.feature_maps ) , len(config.out_features ) )
self.parent.assertListEqual(list(result.feature_maps[0].shape ) , [13, 16, 16, 16] )
# verify channels
self.parent.assertEqual(len(model.channels ) , len(config.out_features ) )
self.parent.assertListEqual(model.channels , [16, 32, 64] )
# verify ValueError
with self.parent.assertRaises(snake_case__ ):
snake_case : Tuple = ["stem"]
snake_case : List[Any] = MaskFormerSwinBackbone(config=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : List[Any] ) -> List[Any]:
'''simple docstring'''
snake_case : Union[str, Any] = self.prepare_config_and_inputs()
snake_case , snake_case , snake_case : List[Any] = config_and_inputs
snake_case : int = {"pixel_values": pixel_values}
return config, inputs_dict
@require_torch
class UpperCAmelCase ( A_ ,A_ ,unittest.TestCase ):
A__ : List[str] = (
(
MaskFormerSwinModel,
MaskFormerSwinBackbone,
)
if is_torch_available()
else ()
)
A__ : str = {"feature-extraction": MaskFormerSwinModel} if is_torch_available() else {}
A__ : Optional[Any] = False
A__ : List[Any] = False
A__ : List[str] = False
A__ : List[str] = False
A__ : Union[str, Any] = False
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> List[str]:
'''simple docstring'''
snake_case : str = MaskFormerSwinModelTester(self )
snake_case : Optional[int] = ConfigTester(self , config_class=snake_case__ , embed_dim=37 )
@require_torch_multi_gpu
@unittest.skip(
reason=(
"`MaskFormerSwinModel` outputs `hidden_states_spatial_dimensions` which doesn't work well with"
" `nn.DataParallel`"
) )
def _SCREAMING_SNAKE_CASE (self : str ) -> Optional[Any]:
'''simple docstring'''
pass
def _SCREAMING_SNAKE_CASE (self : str ) -> List[str]:
'''simple docstring'''
self.create_and_test_config_common_properties()
self.config_tester.create_and_test_config_to_json_string()
self.config_tester.create_and_test_config_to_json_file()
self.config_tester.create_and_test_config_from_and_save_pretrained()
self.config_tester.create_and_test_config_with_num_labels()
self.config_tester.check_config_can_be_init_without_params()
self.config_tester.check_config_arguments_init()
def _SCREAMING_SNAKE_CASE (self : Tuple ) -> List[Any]:
'''simple docstring'''
return
def _SCREAMING_SNAKE_CASE (self : Dict ) -> str:
'''simple docstring'''
snake_case : str = self.model_tester.prepare_config_and_inputs()
self.model_tester.create_and_check_model(*snake_case__ )
def _SCREAMING_SNAKE_CASE (self : int ) -> Dict:
'''simple docstring'''
snake_case : Any = self.model_tester.prepare_config_and_inputs()
self.model_tester.create_and_check_backbone(*snake_case__ )
@unittest.skip("Swin does not use inputs_embeds" )
def _SCREAMING_SNAKE_CASE (self : int ) -> Any:
'''simple docstring'''
pass
@unittest.skip("Swin does not support feedforward chunking" )
def _SCREAMING_SNAKE_CASE (self : List[str] ) -> Dict:
'''simple docstring'''
pass
def _SCREAMING_SNAKE_CASE (self : Optional[Any] ) -> List[str]:
'''simple docstring'''
snake_case , snake_case : Any = self.model_tester.prepare_config_and_inputs_for_common()
for model_class in self.all_model_classes:
snake_case : int = model_class(snake_case__ )
self.assertIsInstance(model.get_input_embeddings() , (nn.Module) )
snake_case : List[Any] = model.get_output_embeddings()
self.assertTrue(x is None or isinstance(snake_case__ , nn.Linear ) )
def _SCREAMING_SNAKE_CASE (self : Optional[Any] ) -> Dict:
'''simple docstring'''
snake_case , snake_case : str = self.model_tester.prepare_config_and_inputs_for_common()
for model_class in self.all_model_classes:
snake_case : str = model_class(snake_case__ )
snake_case : Optional[int] = inspect.signature(model.forward )
# signature.parameters is an OrderedDict => so arg_names order is deterministic
snake_case : Optional[Any] = [*signature.parameters.keys()]
snake_case : Tuple = ["pixel_values"]
self.assertListEqual(arg_names[:1] , snake_case__ )
@unittest.skip(reason="MaskFormerSwin is only used as backbone and doesn't support output_attentions" )
def _SCREAMING_SNAKE_CASE (self : List[Any] ) -> str:
'''simple docstring'''
pass
@unittest.skip(reason="MaskFormerSwin is only used as an internal backbone" )
def _SCREAMING_SNAKE_CASE (self : Tuple ) -> Any:
'''simple docstring'''
pass
def _SCREAMING_SNAKE_CASE (self : Optional[Any] , snake_case__ : List[Any] , snake_case__ : str , snake_case__ : List[Any] , snake_case__ : Tuple ) -> Optional[int]:
'''simple docstring'''
snake_case : Tuple = model_class(snake_case__ )
model.to(snake_case__ )
model.eval()
with torch.no_grad():
snake_case : Any = model(**self._prepare_for_class(snake_case__ , snake_case__ ) )
snake_case : int = outputs.hidden_states
snake_case : Union[str, Any] = getattr(
self.model_tester , "expected_num_hidden_layers" , len(self.model_tester.depths ) + 1 )
self.assertEqual(len(snake_case__ ) , snake_case__ )
# Swin has a different seq_length
snake_case : Any = (
config.patch_size
if isinstance(config.patch_size , collections.abc.Iterable )
else (config.patch_size, config.patch_size)
)
snake_case : Tuple = (image_size[1] // patch_size[1]) * (image_size[0] // patch_size[0])
self.assertListEqual(
list(hidden_states[0].shape[-2:] ) , [num_patches, self.model_tester.embed_dim] , )
def _SCREAMING_SNAKE_CASE (self : Dict ) -> Union[str, Any]:
'''simple docstring'''
snake_case , snake_case : List[Any] = self.model_tester.prepare_config_and_inputs_for_common()
snake_case : int = (
self.model_tester.image_size
if isinstance(self.model_tester.image_size , collections.abc.Iterable )
else (self.model_tester.image_size, self.model_tester.image_size)
)
for model_class in self.all_model_classes:
snake_case : int = True
self.check_hidden_states_output(snake_case__ , snake_case__ , snake_case__ , snake_case__ )
# check that output_hidden_states also work using config
del inputs_dict["output_hidden_states"]
snake_case : Dict = True
self.check_hidden_states_output(snake_case__ , snake_case__ , snake_case__ , snake_case__ )
def _SCREAMING_SNAKE_CASE (self : int ) -> Any:
'''simple docstring'''
snake_case , snake_case : Union[str, Any] = self.model_tester.prepare_config_and_inputs_for_common()
snake_case : Any = 3
snake_case : List[str] = (
self.model_tester.image_size
if isinstance(self.model_tester.image_size , collections.abc.Iterable )
else (self.model_tester.image_size, self.model_tester.image_size)
)
snake_case : Tuple = (
config.patch_size
if isinstance(config.patch_size , collections.abc.Iterable )
else (config.patch_size, config.patch_size)
)
snake_case : str = image_size[0] + patch_size[0] - (image_size[0] % patch_size[0])
snake_case : str = image_size[1] + patch_size[1] - (image_size[1] % patch_size[1])
for model_class in self.all_model_classes:
snake_case : str = True
self.check_hidden_states_output(snake_case__ , snake_case__ , snake_case__ , (padded_height, padded_width) )
# check that output_hidden_states also work using config
del inputs_dict["output_hidden_states"]
snake_case : Optional[Any] = True
self.check_hidden_states_output(snake_case__ , snake_case__ , snake_case__ , (padded_height, padded_width) )
@unittest.skip(reason="MaskFormerSwin doesn't have pretrained checkpoints" )
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> str:
'''simple docstring'''
pass
@unittest.skip(reason="This will be fixed once MaskFormerSwin is replaced by native Swin" )
def _SCREAMING_SNAKE_CASE (self : str ) -> int:
'''simple docstring'''
pass
@unittest.skip(reason="This will be fixed once MaskFormerSwin is replaced by native Swin" )
def _SCREAMING_SNAKE_CASE (self : int ) -> str:
'''simple docstring'''
pass
def _SCREAMING_SNAKE_CASE (self : Any ) -> Any:
'''simple docstring'''
snake_case , snake_case : List[Any] = self.model_tester.prepare_config_and_inputs_for_common()
def set_nan_tensor_to_zero(snake_case__ : Union[str, Any] ):
snake_case : Any = 0
return t
def check_equivalence(snake_case__ : Union[str, Any] , snake_case__ : int , snake_case__ : List[str] , snake_case__ : Optional[int]={} ):
with torch.no_grad():
snake_case : Optional[Any] = model(**snake_case__ , return_dict=snake_case__ , **snake_case__ )
snake_case : Tuple = model(**snake_case__ , return_dict=snake_case__ , **snake_case__ ).to_tuple()
def recursive_check(snake_case__ : List[str] , snake_case__ : Optional[Any] ):
if isinstance(snake_case__ , (List, Tuple) ):
for tuple_iterable_value, dict_iterable_value in zip(snake_case__ , snake_case__ ):
recursive_check(snake_case__ , snake_case__ )
elif isinstance(snake_case__ , snake_case__ ):
for tuple_iterable_value, dict_iterable_value in zip(
tuple_object.values() , dict_object.values() ):
recursive_check(snake_case__ , snake_case__ )
elif tuple_object is None:
return
else:
self.assertTrue(
torch.allclose(
set_nan_tensor_to_zero(snake_case__ ) , set_nan_tensor_to_zero(snake_case__ ) , atol=1e-5 ) , msg=(
"Tuple and dict output are not equal. Difference:"
f""" {torch.max(torch.abs(tuple_object - dict_object ) )}. Tuple has `nan`:"""
f""" {torch.isnan(snake_case__ ).any()} and `inf`: {torch.isinf(snake_case__ )}. Dict has"""
f""" `nan`: {torch.isnan(snake_case__ ).any()} and `inf`: {torch.isinf(snake_case__ )}."""
) , )
recursive_check(snake_case__ , snake_case__ )
for model_class in self.all_model_classes:
snake_case : Optional[int] = model_class(snake_case__ )
model.to(snake_case__ )
model.eval()
snake_case : Union[str, Any] = self._prepare_for_class(snake_case__ , snake_case__ )
snake_case : Tuple = self._prepare_for_class(snake_case__ , snake_case__ )
check_equivalence(snake_case__ , snake_case__ , snake_case__ )
snake_case : Tuple = self._prepare_for_class(snake_case__ , snake_case__ , return_labels=snake_case__ )
snake_case : Optional[Any] = self._prepare_for_class(snake_case__ , snake_case__ , return_labels=snake_case__ )
check_equivalence(snake_case__ , snake_case__ , snake_case__ )
snake_case : Dict = self._prepare_for_class(snake_case__ , snake_case__ )
snake_case : List[Any] = self._prepare_for_class(snake_case__ , snake_case__ )
check_equivalence(snake_case__ , snake_case__ , snake_case__ , {"output_hidden_states": True} )
snake_case : Any = self._prepare_for_class(snake_case__ , snake_case__ , return_labels=snake_case__ )
snake_case : List[str] = self._prepare_for_class(snake_case__ , snake_case__ , return_labels=snake_case__ )
check_equivalence(snake_case__ , snake_case__ , snake_case__ , {"output_hidden_states": True} )
@require_torch
class UpperCAmelCase ( unittest.TestCase ,A_ ):
A__ : int = (MaskFormerSwinBackbone,) if is_torch_available() else ()
A__ : int = MaskFormerSwinConfig
def _SCREAMING_SNAKE_CASE (self : List[Any] ) -> Any:
'''simple docstring'''
snake_case : Union[str, Any] = MaskFormerSwinModelTester(self )
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> Optional[Any]:
'''simple docstring'''
snake_case , snake_case : Dict = self.model_tester.prepare_config_and_inputs_for_common()
snake_case : Optional[int] = inputs_dict["pixel_values"].shape[0]
for backbone_class in self.all_model_classes:
snake_case : Optional[int] = backbone_class(snake_case__ )
backbone.to(snake_case__ )
backbone.eval()
snake_case : Union[str, Any] = backbone(**snake_case__ )
# Test default outputs and verify feature maps
self.assertIsInstance(outputs.feature_maps , snake_case__ )
self.assertTrue(len(outputs.feature_maps ) == len(backbone.channels ) )
for feature_map, n_channels in zip(outputs.feature_maps , backbone.channels ):
self.assertTrue(feature_map.shape[:2] , (batch_size, n_channels) )
self.assertIsNone(outputs.hidden_states )
self.assertIsNone(outputs.attentions )
# Test output_hidden_states=True
snake_case : Optional[int] = backbone(**snake_case__ , output_hidden_states=snake_case__ )
self.assertIsNotNone(outputs.hidden_states )
self.assertTrue(len(outputs.hidden_states ) , len(backbone.stage_names ) )
# We skip the stem layer
for hidden_states, n_channels in zip(outputs.hidden_states[1:] , backbone.channels ):
for hidden_state in hidden_states:
# Hidden states are in the format (batch_size, (height * width), n_channels)
snake_case , snake_case , snake_case : Dict = hidden_state.shape
self.assertTrue((h_batch_size, h_n_channels) , (batch_size, n_channels) )
# Test output_attentions=True
if self.has_attentions:
snake_case : Optional[Any] = backbone(**snake_case__ , output_attentions=snake_case__ )
self.assertIsNotNone(outputs.attentions )
| 59
| 1
|
from ...configuration_utils import PretrainedConfig
class UpperCAmelCase ( A_ ):
A__ : Optional[Any] = "bert-generation"
def __init__(self : Dict , snake_case__ : int=5_03_58 , snake_case__ : int=10_24 , snake_case__ : int=24 , snake_case__ : Any=16 , snake_case__ : List[str]=40_96 , snake_case__ : List[Any]="gelu" , snake_case__ : Dict=0.1 , snake_case__ : List[Any]=0.1 , snake_case__ : Dict=5_12 , snake_case__ : Dict=0.02 , snake_case__ : Optional[Any]=1e-12 , snake_case__ : List[Any]=0 , snake_case__ : Dict=2 , snake_case__ : Optional[int]=1 , snake_case__ : str="absolute" , snake_case__ : Any=True , **snake_case__ : str , ) -> Optional[Any]:
'''simple docstring'''
super().__init__(pad_token_id=snake_case__ , bos_token_id=snake_case__ , eos_token_id=snake_case__ , **snake_case__ )
snake_case : Dict = vocab_size
snake_case : List[str] = hidden_size
snake_case : Any = num_hidden_layers
snake_case : Any = num_attention_heads
snake_case : Tuple = hidden_act
snake_case : Optional[Any] = intermediate_size
snake_case : int = hidden_dropout_prob
snake_case : Optional[int] = attention_probs_dropout_prob
snake_case : List[str] = max_position_embeddings
snake_case : Dict = initializer_range
snake_case : Optional[Any] = layer_norm_eps
snake_case : Optional[Any] = position_embedding_type
snake_case : Dict = use_cache
| 59
|
from typing import Dict
import numpy as np
import torch
from . import residue_constants as rc
from .tensor_utils import tensor_tree_map, tree_map
def UpperCamelCase ( __lowerCamelCase : Dict[str, torch.Tensor] ):
snake_case : List[str] = []
snake_case : Optional[int] = []
snake_case : Any = []
for rt in rc.restypes:
snake_case : List[Any] = rc.restype_name_to_atomaa_names[rc.restype_atoa[rt]]
restype_atomaa_to_atomaa_list.append([(rc.atom_order[name] if name else 0) for name in atom_names] )
snake_case : str = {name: i for i, name in enumerate(__lowerCamelCase )}
restype_atomaa_to_atomaa_list.append(
[(atom_name_to_idxaa[name] if name in atom_name_to_idxaa else 0) for name in rc.atom_types] )
restype_atomaa_mask_list.append([(1.0 if name else 0.0) for name in atom_names] )
# Add dummy mapping for restype 'UNK'
restype_atomaa_to_atomaa_list.append([0] * 14 )
restype_atomaa_to_atomaa_list.append([0] * 37 )
restype_atomaa_mask_list.append([0.0] * 14 )
snake_case : Optional[Any] = torch.tensor(
__lowerCamelCase , dtype=torch.intaa , device=protein["aatype"].device , )
snake_case : List[Any] = torch.tensor(
__lowerCamelCase , dtype=torch.intaa , device=protein["aatype"].device , )
snake_case : int = torch.tensor(
__lowerCamelCase , dtype=torch.floataa , device=protein["aatype"].device , )
snake_case : int = protein["aatype"].to(torch.long )
# create the mapping for (residx, atom14) --> atom37, i.e. an array
# with shape (num_res, 14) containing the atom37 indices for this protein
snake_case : List[Any] = restype_atomaa_to_atomaa[protein_aatype]
snake_case : str = restype_atomaa_mask[protein_aatype]
snake_case : str = residx_atomaa_mask
snake_case : Any = residx_atomaa_to_atomaa.long()
# create the gather indices for mapping back
snake_case : List[str] = restype_atomaa_to_atomaa[protein_aatype]
snake_case : List[Any] = residx_atomaa_to_atomaa.long()
# create the corresponding mask
snake_case : Union[str, Any] = torch.zeros([21, 37] , dtype=torch.floataa , device=protein["aatype"].device )
for restype, restype_letter in enumerate(rc.restypes ):
snake_case : Optional[int] = rc.restype_atoa[restype_letter]
snake_case : Any = rc.residue_atoms[restype_name]
for atom_name in atom_names:
snake_case : List[Any] = rc.atom_order[atom_name]
snake_case : Optional[Any] = 1
snake_case : List[Any] = restype_atomaa_mask[protein_aatype]
snake_case : int = residx_atomaa_mask
return protein
def UpperCamelCase ( __lowerCamelCase : Dict[str, torch.Tensor] ):
snake_case : Dict = tree_map(lambda __lowerCamelCase : torch.tensor(__lowerCamelCase , device=batch["aatype"].device ) , __lowerCamelCase , np.ndarray )
snake_case : List[str] = tensor_tree_map(lambda __lowerCamelCase : np.array(__lowerCamelCase ) , make_atomaa_masks(__lowerCamelCase ) )
return out
| 59
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|
import unittest
import numpy as np
import torch
from .utils_summarization import build_mask, compute_token_type_ids, process_story, truncate_or_pad
class UpperCAmelCase ( unittest.TestCase ):
def _SCREAMING_SNAKE_CASE (self : List[str] ) -> Dict:
'''simple docstring'''
snake_case : Tuple = 10
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> Tuple:
'''simple docstring'''
snake_case : List[Any] = [1, 2, 3, 4]
snake_case : Optional[Any] = [1, 2, 3, 4, 0, 0, 0, 0, 0, 0]
self.assertEqual(truncate_or_pad(snake_case__ , self.block_size , 0 ) , snake_case__ )
def _SCREAMING_SNAKE_CASE (self : List[str] ) -> List[Any]:
'''simple docstring'''
snake_case : str = [1, 2, 3, 4, 5, 6, 7, 8, 9, 10]
snake_case : List[str] = [1, 2, 3, 4, 5, 6, 7, 8, 9, 10]
self.assertEqual(truncate_or_pad(snake_case__ , self.block_size , 0 ) , snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Optional[Any] ) -> Dict:
'''simple docstring'''
snake_case : str = [1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13]
snake_case : str = [1, 2, 3, 4, 5, 6, 7, 8, 9, 10]
self.assertEqual(truncate_or_pad(snake_case__ , self.block_size , 0 ) , snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Any ) -> Tuple:
'''simple docstring'''
snake_case : Optional[Any] = "It was the year of Our Lord one thousand seven hundred and\n seventy-five.\n\nSpiritual revelations were conceded to England at that\n favoured period, as at this."
snake_case , snake_case : int = process_story(snake_case__ )
self.assertEqual(snake_case__ , [] )
def _SCREAMING_SNAKE_CASE (self : int ) -> Any:
'''simple docstring'''
snake_case : List[str] = ""
snake_case , snake_case : Any = process_story(snake_case__ )
self.assertEqual(snake_case__ , [] )
self.assertEqual(snake_case__ , [] )
def _SCREAMING_SNAKE_CASE (self : Union[str, Any] ) -> List[str]:
'''simple docstring'''
snake_case : Union[str, Any] = (
"It was the year of Our Lord one thousand seven hundred and "
"seventy-five\n\nSpiritual revelations were conceded to England "
"at that favoured period, as at this.\n@highlight\n\nIt was the best of times"
)
snake_case , snake_case : Dict = process_story(snake_case__ )
snake_case : Union[str, Any] = [
"It was the year of Our Lord one thousand seven hundred and seventy-five.",
"Spiritual revelations were conceded to England at that favoured period, as at this.",
]
self.assertEqual(snake_case__ , snake_case__ )
snake_case : Union[str, Any] = ["It was the best of times."]
self.assertEqual(snake_case__ , snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Dict ) -> List[str]:
'''simple docstring'''
snake_case : int = torch.tensor([1, 2, 3, 4] )
snake_case : Tuple = torch.tensor([1, 1, 1, 1] )
np.testing.assert_array_equal(build_mask(snake_case__ , 0 ).numpy() , expected.numpy() )
def _SCREAMING_SNAKE_CASE (self : Union[str, Any] ) -> List[Any]:
'''simple docstring'''
snake_case : List[Any] = torch.tensor([1, 2, 3, 4, 23, 23, 23] )
snake_case : int = torch.tensor([1, 1, 1, 1, 0, 0, 0] )
np.testing.assert_array_equal(build_mask(snake_case__ , 23 ).numpy() , expected.numpy() )
def _SCREAMING_SNAKE_CASE (self : List[str] ) -> Tuple:
'''simple docstring'''
snake_case : int = torch.tensor([8, 2, 3, 4, 1, 1, 1] )
snake_case : int = torch.tensor([1, 1, 1, 1, 0, 0, 0] )
np.testing.assert_array_equal(build_mask(snake_case__ , 1 ).numpy() , expected.numpy() )
def _SCREAMING_SNAKE_CASE (self : Union[str, Any] ) -> Optional[Any]:
'''simple docstring'''
snake_case : Dict = 1_01
snake_case : Union[str, Any] = torch.tensor([[1, 2, 3, 4, 5, 6], [1, 2, 3, 1_01, 5, 6], [1, 1_01, 3, 4, 1_01, 6]] )
snake_case : Any = torch.tensor([[1, 1, 1, 1, 1, 1], [1, 1, 1, 0, 0, 0], [1, 0, 0, 0, 1, 1]] )
snake_case : int = compute_token_type_ids(snake_case__ , snake_case__ )
np.testing.assert_array_equal(snake_case__ , snake_case__ )
| 59
|
import json
from typing import List, Optional, Tuple
from tokenizers import normalizers
from ...tokenization_utils_fast import PreTrainedTokenizerFast
from .tokenization_lxmert import LxmertTokenizer
__lowerCamelCase = {"""vocab_file""": """vocab.txt""", """tokenizer_file""": """tokenizer.json"""}
__lowerCamelCase = {
"""vocab_file""": {
"""unc-nlp/lxmert-base-uncased""": """https://huggingface.co/unc-nlp/lxmert-base-uncased/resolve/main/vocab.txt""",
},
"""tokenizer_file""": {
"""unc-nlp/lxmert-base-uncased""": (
"""https://huggingface.co/unc-nlp/lxmert-base-uncased/resolve/main/tokenizer.json"""
),
},
}
__lowerCamelCase = {
"""unc-nlp/lxmert-base-uncased""": 5_12,
}
__lowerCamelCase = {
"""unc-nlp/lxmert-base-uncased""": {"""do_lower_case""": True},
}
class UpperCAmelCase ( A_ ):
A__ : Any = VOCAB_FILES_NAMES
A__ : Optional[int] = PRETRAINED_VOCAB_FILES_MAP
A__ : Tuple = PRETRAINED_INIT_CONFIGURATION
A__ : Tuple = PRETRAINED_POSITIONAL_EMBEDDINGS_SIZES
A__ : List[Any] = LxmertTokenizer
def __init__(self : Dict , snake_case__ : Tuple=None , snake_case__ : Optional[Any]=None , snake_case__ : Optional[Any]=True , snake_case__ : Tuple="[UNK]" , snake_case__ : Optional[Any]="[SEP]" , snake_case__ : Optional[Any]="[PAD]" , snake_case__ : List[Any]="[CLS]" , snake_case__ : Tuple="[MASK]" , snake_case__ : Dict=True , snake_case__ : Union[str, Any]=None , **snake_case__ : Dict , ) -> Optional[int]:
'''simple docstring'''
super().__init__(
snake_case__ , tokenizer_file=snake_case__ , do_lower_case=snake_case__ , unk_token=snake_case__ , sep_token=snake_case__ , pad_token=snake_case__ , cls_token=snake_case__ , mask_token=snake_case__ , tokenize_chinese_chars=snake_case__ , strip_accents=snake_case__ , **snake_case__ , )
snake_case : int = json.loads(self.backend_tokenizer.normalizer.__getstate__() )
if (
normalizer_state.get("lowercase" , snake_case__ ) != do_lower_case
or normalizer_state.get("strip_accents" , snake_case__ ) != strip_accents
or normalizer_state.get("handle_chinese_chars" , snake_case__ ) != tokenize_chinese_chars
):
snake_case : Union[str, Any] = getattr(snake_case__ , normalizer_state.pop("type" ) )
snake_case : str = do_lower_case
snake_case : List[Any] = strip_accents
snake_case : Optional[int] = tokenize_chinese_chars
snake_case : int = normalizer_class(**snake_case__ )
snake_case : Optional[Any] = do_lower_case
def _SCREAMING_SNAKE_CASE (self : Union[str, Any] , snake_case__ : Optional[Any] , snake_case__ : Dict=None ) -> Any:
'''simple docstring'''
snake_case : Optional[int] = [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 _SCREAMING_SNAKE_CASE (self : Optional[int] , snake_case__ : List[int] , snake_case__ : Optional[List[int]] = None ) -> List[int]:
'''simple docstring'''
snake_case : Optional[Any] = [self.sep_token_id]
snake_case : Optional[Any] = [self.cls_token_id]
if token_ids_a is None:
return len(cls + token_ids_a + sep ) * [0]
return len(cls + token_ids_a + sep ) * [0] + len(token_ids_a + sep ) * [1]
def _SCREAMING_SNAKE_CASE (self : Any , snake_case__ : str , snake_case__ : Optional[str] = None ) -> Tuple[str]:
'''simple docstring'''
snake_case : List[Any] = self._tokenizer.model.save(snake_case__ , name=snake_case__ )
return tuple(snake_case__ )
| 59
| 1
|
from __future__ import annotations
def UpperCamelCase ( __lowerCamelCase : list , __lowerCamelCase : int , __lowerCamelCase : int , __lowerCamelCase : int ):
snake_case : Union[str, Any] = []
snake_case , snake_case : str = input_list[low:mid], input_list[mid : high + 1]
while left and right:
result.append((left if left[0] <= right[0] else right).pop(0 ) )
snake_case : List[str] = result + left + right
return input_list
def UpperCamelCase ( __lowerCamelCase : list ):
if len(__lowerCamelCase ) <= 1:
return input_list
snake_case : str = list(__lowerCamelCase )
# iteration for two-way merging
snake_case : List[Any] = 2
while p <= len(__lowerCamelCase ):
# getting low, high and middle value for merge-sort of single list
for i in range(0 , len(__lowerCamelCase ) , __lowerCamelCase ):
snake_case : List[Any] = i
snake_case : Dict = i + p - 1
snake_case : List[str] = (low + high + 1) // 2
snake_case : Optional[int] = merge(__lowerCamelCase , __lowerCamelCase , __lowerCamelCase , __lowerCamelCase )
# final merge of last two parts
if p * 2 >= len(__lowerCamelCase ):
snake_case : List[str] = i
snake_case : str = merge(__lowerCamelCase , 0 , __lowerCamelCase , len(__lowerCamelCase ) - 1 )
break
p *= 2
return input_list
if __name__ == "__main__":
__lowerCamelCase = input("""Enter numbers separated by a comma:\n""").strip()
if user_input == "":
__lowerCamelCase = []
else:
__lowerCamelCase = [int(item.strip()) for item in user_input.split(""",""")]
print(iter_merge_sort(unsorted))
| 59
|
import torch
from diffusers import DDIMParallelScheduler
from .test_schedulers import SchedulerCommonTest
class UpperCAmelCase ( A_ ):
A__ : Dict = (DDIMParallelScheduler,)
A__ : Tuple = (("eta", 0.0), ("num_inference_steps", 50))
def _SCREAMING_SNAKE_CASE (self : Tuple , **snake_case__ : Optional[int] ) -> Optional[Any]:
'''simple docstring'''
snake_case : Any = {
"num_train_timesteps": 10_00,
"beta_start": 0.0001,
"beta_end": 0.02,
"beta_schedule": "linear",
"clip_sample": True,
}
config.update(**snake_case__ )
return config
def _SCREAMING_SNAKE_CASE (self : Dict , **snake_case__ : Optional[int] ) -> Any:
'''simple docstring'''
snake_case : List[Any] = self.scheduler_classes[0]
snake_case : Any = self.get_scheduler_config(**snake_case__ )
snake_case : Any = scheduler_class(**snake_case__ )
snake_case , snake_case : Union[str, Any] = 10, 0.0
snake_case : List[Any] = self.dummy_model()
snake_case : Any = self.dummy_sample_deter
scheduler.set_timesteps(snake_case__ )
for t in scheduler.timesteps:
snake_case : Optional[int] = model(snake_case__ , snake_case__ )
snake_case : List[str] = scheduler.step(snake_case__ , snake_case__ , snake_case__ , snake_case__ ).prev_sample
return sample
def _SCREAMING_SNAKE_CASE (self : Union[str, Any] ) -> str:
'''simple docstring'''
for timesteps in [1_00, 5_00, 10_00]:
self.check_over_configs(num_train_timesteps=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : str ) -> int:
'''simple docstring'''
for steps_offset in [0, 1]:
self.check_over_configs(steps_offset=snake_case__ )
snake_case : Optional[int] = self.scheduler_classes[0]
snake_case : Optional[int] = self.get_scheduler_config(steps_offset=1 )
snake_case : Union[str, Any] = scheduler_class(**snake_case__ )
scheduler.set_timesteps(5 )
assert torch.equal(scheduler.timesteps , torch.LongTensor([8_01, 6_01, 4_01, 2_01, 1] ) )
def _SCREAMING_SNAKE_CASE (self : int ) -> Tuple:
'''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=snake_case__ , beta_end=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Union[str, Any] ) -> Union[str, Any]:
'''simple docstring'''
for schedule in ["linear", "squaredcos_cap_v2"]:
self.check_over_configs(beta_schedule=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : str ) -> Dict:
'''simple docstring'''
for prediction_type in ["epsilon", "v_prediction"]:
self.check_over_configs(prediction_type=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Optional[Any] ) -> List[str]:
'''simple docstring'''
for clip_sample in [True, False]:
self.check_over_configs(clip_sample=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : List[Any] ) -> List[Any]:
'''simple docstring'''
for timestep_spacing in ["trailing", "leading"]:
self.check_over_configs(timestep_spacing=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> List[Any]:
'''simple docstring'''
for rescale_betas_zero_snr in [True, False]:
self.check_over_configs(rescale_betas_zero_snr=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Optional[Any] ) -> Optional[Any]:
'''simple docstring'''
self.check_over_configs(thresholding=snake_case__ )
for threshold in [0.5, 1.0, 2.0]:
for prediction_type in ["epsilon", "v_prediction"]:
self.check_over_configs(
thresholding=snake_case__ , prediction_type=snake_case__ , sample_max_value=snake_case__ , )
def _SCREAMING_SNAKE_CASE (self : Any ) -> Any:
'''simple docstring'''
for t in [1, 10, 49]:
self.check_over_forward(time_step=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> Any:
'''simple docstring'''
for t, num_inference_steps in zip([1, 10, 50] , [10, 50, 5_00] ):
self.check_over_forward(time_step=snake_case__ , num_inference_steps=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : List[str] ) -> Optional[Any]:
'''simple docstring'''
for t, eta in zip([1, 10, 49] , [0.0, 0.5, 1.0] ):
self.check_over_forward(time_step=snake_case__ , eta=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Optional[Any] ) -> Optional[int]:
'''simple docstring'''
snake_case : Dict = self.scheduler_classes[0]
snake_case : Tuple = self.get_scheduler_config()
snake_case : Dict = scheduler_class(**snake_case__ )
assert torch.sum(torch.abs(scheduler._get_variance(0 , 0 ) - 0.0 ) ) < 1e-5
assert torch.sum(torch.abs(scheduler._get_variance(4_20 , 4_00 ) - 0.14771 ) ) < 1e-5
assert torch.sum(torch.abs(scheduler._get_variance(9_80 , 9_60 ) - 0.32460 ) ) < 1e-5
assert torch.sum(torch.abs(scheduler._get_variance(0 , 0 ) - 0.0 ) ) < 1e-5
assert torch.sum(torch.abs(scheduler._get_variance(4_87 , 4_86 ) - 0.00979 ) ) < 1e-5
assert torch.sum(torch.abs(scheduler._get_variance(9_99 , 9_98 ) - 0.02 ) ) < 1e-5
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> Dict:
'''simple docstring'''
snake_case : Union[str, Any] = self.scheduler_classes[0]
snake_case : List[Any] = self.get_scheduler_config()
snake_case : int = scheduler_class(**snake_case__ )
snake_case , snake_case : Any = 10, 0.0
scheduler.set_timesteps(snake_case__ )
snake_case : Optional[Any] = self.dummy_model()
snake_case : str = self.dummy_sample_deter
snake_case : Dict = self.dummy_sample_deter + 0.1
snake_case : Dict = self.dummy_sample_deter - 0.1
snake_case : Optional[Any] = samplea.shape[0]
snake_case : str = torch.stack([samplea, samplea, samplea] , dim=0 )
snake_case : Tuple = torch.arange(snake_case__ )[0:3, None].repeat(1 , snake_case__ )
snake_case : Tuple = model(samples.flatten(0 , 1 ) , timesteps.flatten(0 , 1 ) )
snake_case : List[str] = scheduler.batch_step_no_noise(snake_case__ , timesteps.flatten(0 , 1 ) , samples.flatten(0 , 1 ) , snake_case__ )
snake_case : Dict = torch.sum(torch.abs(snake_case__ ) )
snake_case : List[Any] = torch.mean(torch.abs(snake_case__ ) )
assert abs(result_sum.item() - 1147.7904 ) < 1e-2
assert abs(result_mean.item() - 0.4982 ) < 1e-3
def _SCREAMING_SNAKE_CASE (self : Optional[Any] ) -> Optional[Any]:
'''simple docstring'''
snake_case : List[Any] = self.full_loop()
snake_case : Optional[Any] = torch.sum(torch.abs(snake_case__ ) )
snake_case : List[Any] = torch.mean(torch.abs(snake_case__ ) )
assert abs(result_sum.item() - 172.0067 ) < 1e-2
assert abs(result_mean.item() - 0.223967 ) < 1e-3
def _SCREAMING_SNAKE_CASE (self : str ) -> Union[str, Any]:
'''simple docstring'''
snake_case : Dict = self.full_loop(prediction_type="v_prediction" )
snake_case : int = torch.sum(torch.abs(snake_case__ ) )
snake_case : Optional[int] = torch.mean(torch.abs(snake_case__ ) )
assert abs(result_sum.item() - 52.5302 ) < 1e-2
assert abs(result_mean.item() - 0.0684 ) < 1e-3
def _SCREAMING_SNAKE_CASE (self : Any ) -> Optional[Any]:
'''simple docstring'''
snake_case : Dict = self.full_loop(set_alpha_to_one=snake_case__ , beta_start=0.01 )
snake_case : str = torch.sum(torch.abs(snake_case__ ) )
snake_case : Optional[Any] = torch.mean(torch.abs(snake_case__ ) )
assert abs(result_sum.item() - 149.8295 ) < 1e-2
assert abs(result_mean.item() - 0.1951 ) < 1e-3
def _SCREAMING_SNAKE_CASE (self : int ) -> Optional[Any]:
'''simple docstring'''
snake_case : int = self.full_loop(set_alpha_to_one=snake_case__ , beta_start=0.01 )
snake_case : Tuple = torch.sum(torch.abs(snake_case__ ) )
snake_case : List[Any] = torch.mean(torch.abs(snake_case__ ) )
assert abs(result_sum.item() - 149.0784 ) < 1e-2
assert abs(result_mean.item() - 0.1941 ) < 1e-3
| 59
| 1
|
import pytest
from datasets.utils.sharding import _distribute_shards, _number_of_shards_in_gen_kwargs, _split_gen_kwargs
@pytest.mark.parametrize(
"kwargs, expected" , [
({"num_shards": 0, "max_num_jobs": 1}, []),
({"num_shards": 10, "max_num_jobs": 1}, [range(10 )]),
({"num_shards": 10, "max_num_jobs": 10}, [range(__lowerCamelCase , i + 1 ) for i in range(10 )]),
({"num_shards": 1, "max_num_jobs": 10}, [range(1 )]),
({"num_shards": 10, "max_num_jobs": 3}, [range(0 , 4 ), range(4 , 7 ), range(7 , 10 )]),
({"num_shards": 3, "max_num_jobs": 10}, [range(0 , 1 ), range(1 , 2 ), range(2 , 3 )]),
] , )
def UpperCamelCase ( __lowerCamelCase : Optional[Any] , __lowerCamelCase : Any ):
snake_case : Union[str, Any] = _distribute_shards(**__lowerCamelCase )
assert out == expected
@pytest.mark.parametrize(
"gen_kwargs, max_num_jobs, expected" , [
({"foo": 0}, 10, [{"foo": 0}]),
({"shards": [0, 1, 2, 3]}, 1, [{"shards": [0, 1, 2, 3]}]),
({"shards": [0, 1, 2, 3]}, 4, [{"shards": [0]}, {"shards": [1]}, {"shards": [2]}, {"shards": [3]}]),
({"shards": [0, 1]}, 4, [{"shards": [0]}, {"shards": [1]}]),
({"shards": [0, 1, 2, 3]}, 2, [{"shards": [0, 1]}, {"shards": [2, 3]}]),
] , )
def UpperCamelCase ( __lowerCamelCase : Dict , __lowerCamelCase : str , __lowerCamelCase : Dict ):
snake_case : str = _split_gen_kwargs(__lowerCamelCase , __lowerCamelCase )
assert out == expected
@pytest.mark.parametrize(
"gen_kwargs, expected" , [
({"foo": 0}, 1),
({"shards": [0]}, 1),
({"shards": [0, 1, 2, 3]}, 4),
({"shards": [0, 1, 2, 3], "foo": 0}, 4),
({"shards": [0, 1, 2, 3], "other": (0, 1)}, 4),
({"shards": [0, 1, 2, 3], "shards2": [0, 1]}, RuntimeError),
] , )
def UpperCamelCase ( __lowerCamelCase : Union[str, Any] , __lowerCamelCase : Optional[int] ):
if expected is RuntimeError:
with pytest.raises(__lowerCamelCase ):
_number_of_shards_in_gen_kwargs(__lowerCamelCase )
else:
snake_case : Optional[Any] = _number_of_shards_in_gen_kwargs(__lowerCamelCase )
assert out == expected
| 59
|
def UpperCamelCase ( __lowerCamelCase : str , __lowerCamelCase : int ):
snake_case : list[list[str]] = [[] for _ in range(__lowerCamelCase )]
snake_case : int = key - 1
if key <= 0:
raise ValueError("Height of grid can't be 0 or negative" )
if key == 1 or len(__lowerCamelCase ) <= key:
return input_string
for position, character in enumerate(__lowerCamelCase ):
snake_case : Any = position % (lowest * 2) # puts it in bounds
snake_case : Optional[int] = min(__lowerCamelCase , lowest * 2 - num ) # creates zigzag pattern
temp_grid[num].append(__lowerCamelCase )
snake_case : List[str] = ["".join(__lowerCamelCase ) for row in temp_grid]
snake_case : Tuple = "".join(__lowerCamelCase )
return output_string
def UpperCamelCase ( __lowerCamelCase : str , __lowerCamelCase : int ):
snake_case : Dict = []
snake_case : Union[str, Any] = key - 1
if key <= 0:
raise ValueError("Height of grid can't be 0 or negative" )
if key == 1:
return input_string
snake_case : list[list[str]] = [[] for _ in range(__lowerCamelCase )] # generates template
for position in range(len(__lowerCamelCase ) ):
snake_case : List[str] = position % (lowest * 2) # puts it in bounds
snake_case : Optional[int] = min(__lowerCamelCase , lowest * 2 - num ) # creates zigzag pattern
temp_grid[num].append("*" )
snake_case : Tuple = 0
for row in temp_grid: # fills in the characters
snake_case : Union[str, Any] = input_string[counter : counter + len(__lowerCamelCase )]
grid.append(list(__lowerCamelCase ) )
counter += len(__lowerCamelCase )
snake_case : str = "" # reads as zigzag
for position in range(len(__lowerCamelCase ) ):
snake_case : Optional[int] = position % (lowest * 2) # puts it in bounds
snake_case : Tuple = min(__lowerCamelCase , lowest * 2 - num ) # creates zigzag pattern
output_string += grid[num][0]
grid[num].pop(0 )
return output_string
def UpperCamelCase ( __lowerCamelCase : str ):
snake_case : Tuple = {}
for key_guess in range(1 , len(__lowerCamelCase ) ): # tries every key
snake_case : Any = decrypt(__lowerCamelCase , __lowerCamelCase )
return results
if __name__ == "__main__":
import doctest
doctest.testmod()
| 59
| 1
|
from __future__ import annotations
from collections.abc import Callable
from typing import Generic, TypeVar
__lowerCamelCase = TypeVar("""T""")
__lowerCamelCase = TypeVar("""U""")
class UpperCAmelCase ( Generic[T, U] ):
def __init__(self : Dict , snake_case__ : T | None , snake_case__ : U | None ) -> List[str]:
'''simple docstring'''
snake_case : Any = key
snake_case : int = val
snake_case : DoubleLinkedListNode[T, U] | None = None
snake_case : DoubleLinkedListNode[T, U] | None = None
def __repr__(self : List[Any] ) -> str:
'''simple docstring'''
return (
f"""Node: key: {self.key}, val: {self.val}, """
f"""has next: {bool(self.next )}, has prev: {bool(self.prev )}"""
)
class UpperCAmelCase ( Generic[T, U] ):
def __init__(self : List[Any] ) -> None:
'''simple docstring'''
snake_case : DoubleLinkedListNode[T, U] = DoubleLinkedListNode(snake_case__ , snake_case__ )
snake_case : DoubleLinkedListNode[T, U] = DoubleLinkedListNode(snake_case__ , snake_case__ )
snake_case , snake_case : Optional[int] = self.rear, self.head
def __repr__(self : int ) -> str:
'''simple docstring'''
snake_case : Dict = ["DoubleLinkedList"]
snake_case : Optional[int] = self.head
while node.next is not None:
rep.append(str(snake_case__ ) )
snake_case : List[str] = node.next
rep.append(str(self.rear ) )
return ",\n ".join(snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Optional[Any] , snake_case__ : DoubleLinkedListNode[T, U] ) -> None:
'''simple docstring'''
snake_case : Any = self.rear.prev
# All nodes other than self.head are guaranteed to have non-None previous
assert previous is not None
snake_case : str = node
snake_case : Any = previous
snake_case : str = node
snake_case : Dict = self.rear
def _SCREAMING_SNAKE_CASE (self : Optional[Any] , snake_case__ : DoubleLinkedListNode[T, U] ) -> DoubleLinkedListNode[T, U] | None:
'''simple docstring'''
if node.prev is None or node.next is None:
return None
snake_case : Any = node.next
snake_case : int = node.prev
snake_case : str = None
snake_case : str = None
return node
class UpperCAmelCase ( Generic[T, U] ):
A__ : dict[Callable[[T], U], LRUCache[T, U]] = {}
def __init__(self : Union[str, Any] , snake_case__ : int ) -> List[Any]:
'''simple docstring'''
snake_case : DoubleLinkedList[T, U] = DoubleLinkedList()
snake_case : Tuple = capacity
snake_case : Dict = 0
snake_case : Tuple = 0
snake_case : int = 0
snake_case : dict[T, DoubleLinkedListNode[T, U]] = {}
def __repr__(self : Optional[Any] ) -> str:
'''simple docstring'''
return (
f"""CacheInfo(hits={self.hits}, misses={self.miss}, """
f"""capacity={self.capacity}, current size={self.num_keys})"""
)
def __contains__(self : Dict , snake_case__ : T ) -> bool:
'''simple docstring'''
return key in self.cache
def _SCREAMING_SNAKE_CASE (self : Tuple , snake_case__ : T ) -> U | None:
'''simple docstring'''
if key in self.cache:
self.hits += 1
snake_case : DoubleLinkedListNode[T, U] = self.cache[key]
snake_case : Any = self.list.remove(self.cache[key] )
assert node == value_node
# node is guaranteed not None because it is in self.cache
assert node is not None
self.list.add(snake_case__ )
return node.val
self.miss += 1
return None
def _SCREAMING_SNAKE_CASE (self : int , snake_case__ : T , snake_case__ : U ) -> None:
'''simple docstring'''
if key not in self.cache:
if self.num_keys >= self.capacity:
# delete first node (oldest) when over capacity
snake_case : Optional[int] = self.list.head.next
# guaranteed to have a non-None first node when num_keys > 0
# explain to type checker via assertions
assert first_node is not None
assert first_node.key is not None
assert (
self.list.remove(snake_case__ ) is not None
) # node guaranteed to be in list assert node.key is not None
del self.cache[first_node.key]
self.num_keys -= 1
snake_case : Tuple = DoubleLinkedListNode(snake_case__ , snake_case__ )
self.list.add(self.cache[key] )
self.num_keys += 1
else:
# bump node to the end of the list, update value
snake_case : str = self.list.remove(self.cache[key] )
assert node is not None # node guaranteed to be in list
snake_case : str = value
self.list.add(snake_case__ )
@classmethod
def _SCREAMING_SNAKE_CASE (cls : List[str] , snake_case__ : int = 1_28 ) -> Callable[[Callable[[T], U]], Callable[..., U]]:
'''simple docstring'''
def cache_decorator_inner(snake_case__ : Callable[[T], U] ) -> Callable[..., U]:
def cache_decorator_wrapper(*snake_case__ : T ) -> U:
if func not in cls.decorator_function_to_instance_map:
snake_case : Optional[int] = LRUCache(snake_case__ )
snake_case : Any = cls.decorator_function_to_instance_map[func].get(args[0] )
if result is None:
snake_case : Tuple = func(*snake_case__ )
cls.decorator_function_to_instance_map[func].put(args[0] , snake_case__ )
return result
def cache_info() -> LRUCache[T, U]:
return cls.decorator_function_to_instance_map[func]
setattr(snake_case__ , "cache_info" , snake_case__ ) # noqa: B010
return cache_decorator_wrapper
return cache_decorator_inner
if __name__ == "__main__":
import doctest
doctest.testmod()
| 59
|
from typing import TYPE_CHECKING
from ...utils import (
OptionalDependencyNotAvailable,
_LazyModule,
is_flax_available,
is_sentencepiece_available,
is_tf_available,
is_tokenizers_available,
is_torch_available,
)
if is_sentencepiece_available():
from ..ta.tokenization_ta import TaTokenizer
else:
from ...utils.dummy_sentencepiece_objects import TaTokenizer
__lowerCamelCase = TaTokenizer
if is_tokenizers_available():
from ..ta.tokenization_ta_fast import TaTokenizerFast
else:
from ...utils.dummy_tokenizers_objects import TaTokenizerFast
__lowerCamelCase = TaTokenizerFast
__lowerCamelCase = {"""configuration_mt5""": ["""MT5Config""", """MT5OnnxConfig"""]}
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = [
"""MT5EncoderModel""",
"""MT5ForConditionalGeneration""",
"""MT5ForQuestionAnswering""",
"""MT5Model""",
"""MT5PreTrainedModel""",
"""MT5Stack""",
]
try:
if not is_tf_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = ["""TFMT5EncoderModel""", """TFMT5ForConditionalGeneration""", """TFMT5Model"""]
try:
if not is_flax_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = ["""FlaxMT5EncoderModel""", """FlaxMT5ForConditionalGeneration""", """FlaxMT5Model"""]
if TYPE_CHECKING:
from .configuration_mta import MTaConfig, MTaOnnxConfig
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_mta import (
MTaEncoderModel,
MTaForConditionalGeneration,
MTaForQuestionAnswering,
MTaModel,
MTaPreTrainedModel,
MTaStack,
)
try:
if not is_tf_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_tf_mta import TFMTaEncoderModel, TFMTaForConditionalGeneration, TFMTaModel
try:
if not is_flax_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_flax_mta import FlaxMTaEncoderModel, FlaxMTaForConditionalGeneration, FlaxMTaModel
else:
import sys
__lowerCamelCase = _LazyModule(
__name__,
globals()["""__file__"""],
_import_structure,
extra_objects={"""MT5Tokenizer""": MTaTokenizer, """MT5TokenizerFast""": MTaTokenizerFast},
module_spec=__spec__,
)
| 59
| 1
|
from ...configuration_utils import PretrainedConfig
from ...utils import logging
from ...utils.backbone_utils import BackboneConfigMixin, get_aligned_output_features_output_indices
__lowerCamelCase = logging.get_logger(__name__)
__lowerCamelCase = {
"""shi-labs/dinat-mini-in1k-224""": """https://huggingface.co/shi-labs/dinat-mini-in1k-224/resolve/main/config.json""",
# See all Dinat models at https://huggingface.co/models?filter=dinat
}
class UpperCAmelCase ( A_ ,A_ ):
A__ : str = "dinat"
A__ : List[str] = {
"num_attention_heads": "num_heads",
"num_hidden_layers": "num_layers",
}
def __init__(self : Optional[int] , snake_case__ : List[str]=4 , snake_case__ : str=3 , snake_case__ : Any=64 , snake_case__ : int=[3, 4, 6, 5] , snake_case__ : List[Any]=[2, 4, 8, 16] , snake_case__ : Tuple=7 , snake_case__ : Optional[Any]=[[1, 8, 1], [1, 4, 1, 4], [1, 2, 1, 2, 1, 2], [1, 1, 1, 1, 1]] , snake_case__ : Dict=3.0 , snake_case__ : str=True , snake_case__ : List[Any]=0.0 , snake_case__ : Any=0.0 , snake_case__ : Optional[int]=0.1 , snake_case__ : Any="gelu" , snake_case__ : str=0.02 , snake_case__ : str=1e-5 , snake_case__ : Optional[Any]=0.0 , snake_case__ : List[str]=None , snake_case__ : Optional[Any]=None , **snake_case__ : int , ) -> str:
'''simple docstring'''
super().__init__(**snake_case__ )
snake_case : Optional[int] = patch_size
snake_case : Any = num_channels
snake_case : List[str] = embed_dim
snake_case : List[str] = depths
snake_case : Any = len(snake_case__ )
snake_case : Optional[Any] = num_heads
snake_case : str = kernel_size
snake_case : Union[str, Any] = dilations
snake_case : Tuple = mlp_ratio
snake_case : Dict = qkv_bias
snake_case : List[Any] = hidden_dropout_prob
snake_case : str = attention_probs_dropout_prob
snake_case : Optional[Any] = drop_path_rate
snake_case : Optional[int] = hidden_act
snake_case : str = layer_norm_eps
snake_case : Optional[int] = initializer_range
# we set the hidden_size attribute in order to make Dinat work with VisionEncoderDecoderModel
# this indicates the channel dimension after the last stage of the model
snake_case : Any = int(embed_dim * 2 ** (len(snake_case__ ) - 1) )
snake_case : Any = layer_scale_init_value
snake_case : List[Any] = ["stem"] + [f"""stage{idx}""" for idx in range(1 , len(snake_case__ ) + 1 )]
snake_case , snake_case : Optional[Any] = get_aligned_output_features_output_indices(
out_features=snake_case__ , out_indices=snake_case__ , stage_names=self.stage_names )
| 59
|
import os
import shutil
from pathlib import Path
from typing import Optional, Union
import numpy as np
from huggingface_hub import hf_hub_download
from ..utils import ONNX_EXTERNAL_WEIGHTS_NAME, ONNX_WEIGHTS_NAME, is_onnx_available, logging
if is_onnx_available():
import onnxruntime as ort
__lowerCamelCase = logging.get_logger(__name__)
__lowerCamelCase = {
"""tensor(bool)""": np.bool_,
"""tensor(int8)""": np.inta,
"""tensor(uint8)""": np.uinta,
"""tensor(int16)""": np.intaa,
"""tensor(uint16)""": np.uintaa,
"""tensor(int32)""": np.intaa,
"""tensor(uint32)""": np.uintaa,
"""tensor(int64)""": np.intaa,
"""tensor(uint64)""": np.uintaa,
"""tensor(float16)""": np.floataa,
"""tensor(float)""": np.floataa,
"""tensor(double)""": np.floataa,
}
class UpperCAmelCase :
def __init__(self : Optional[Any] , snake_case__ : Optional[Any]=None , **snake_case__ : Optional[Any] ) -> List[str]:
'''simple docstring'''
logger.info("`diffusers.OnnxRuntimeModel` is experimental and might change in the future." )
snake_case : Optional[Any] = model
snake_case : Dict = kwargs.get("model_save_dir" , snake_case__ )
snake_case : int = kwargs.get("latest_model_name" , snake_case__ )
def __call__(self : Tuple , **snake_case__ : str ) -> List[str]:
'''simple docstring'''
snake_case : Union[str, Any] = {k: np.array(snake_case__ ) for k, v in kwargs.items()}
return self.model.run(snake_case__ , snake_case__ )
@staticmethod
def _SCREAMING_SNAKE_CASE (snake_case__ : Union[str, Path] , snake_case__ : Optional[int]=None , snake_case__ : Optional[int]=None ) -> Any:
'''simple docstring'''
if provider is None:
logger.info("No onnxruntime provider specified, using CPUExecutionProvider" )
snake_case : Optional[int] = "CPUExecutionProvider"
return ort.InferenceSession(snake_case__ , providers=[provider] , sess_options=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : List[Any] , snake_case__ : Union[str, Path] , snake_case__ : Optional[str] = None , **snake_case__ : Any ) -> List[Any]:
'''simple docstring'''
snake_case : Tuple = file_name if file_name is not None else ONNX_WEIGHTS_NAME
snake_case : Any = self.model_save_dir.joinpath(self.latest_model_name )
snake_case : str = Path(snake_case__ ).joinpath(snake_case__ )
try:
shutil.copyfile(snake_case__ , snake_case__ )
except shutil.SameFileError:
pass
# copy external weights (for models >2GB)
snake_case : List[str] = self.model_save_dir.joinpath(snake_case__ )
if src_path.exists():
snake_case : Tuple = Path(snake_case__ ).joinpath(snake_case__ )
try:
shutil.copyfile(snake_case__ , snake_case__ )
except shutil.SameFileError:
pass
def _SCREAMING_SNAKE_CASE (self : str , snake_case__ : Union[str, os.PathLike] , **snake_case__ : Optional[int] , ) -> str:
'''simple docstring'''
if os.path.isfile(snake_case__ ):
logger.error(f"""Provided path ({save_directory}) should be a directory, not a file""" )
return
os.makedirs(snake_case__ , exist_ok=snake_case__ )
# saving model weights/files
self._save_pretrained(snake_case__ , **snake_case__ )
@classmethod
def _SCREAMING_SNAKE_CASE (cls : Tuple , snake_case__ : Union[str, Path] , snake_case__ : Optional[Union[bool, str, None]] = None , snake_case__ : Optional[Union[str, None]] = None , snake_case__ : bool = False , snake_case__ : Optional[str] = None , snake_case__ : Optional[str] = None , snake_case__ : Optional[str] = None , snake_case__ : Optional["ort.SessionOptions"] = None , **snake_case__ : Tuple , ) -> Tuple:
'''simple docstring'''
snake_case : List[str] = file_name if file_name is not None else ONNX_WEIGHTS_NAME
# load model from local directory
if os.path.isdir(snake_case__ ):
snake_case : Any = OnnxRuntimeModel.load_model(
os.path.join(snake_case__ , snake_case__ ) , provider=snake_case__ , sess_options=snake_case__ )
snake_case : Union[str, Any] = Path(snake_case__ )
# load model from hub
else:
# download model
snake_case : Dict = hf_hub_download(
repo_id=snake_case__ , filename=snake_case__ , use_auth_token=snake_case__ , revision=snake_case__ , cache_dir=snake_case__ , force_download=snake_case__ , )
snake_case : List[Any] = Path(snake_case__ ).parent
snake_case : Union[str, Any] = Path(snake_case__ ).name
snake_case : Dict = OnnxRuntimeModel.load_model(snake_case__ , provider=snake_case__ , sess_options=snake_case__ )
return cls(model=snake_case__ , **snake_case__ )
@classmethod
def _SCREAMING_SNAKE_CASE (cls : Optional[Any] , snake_case__ : Union[str, Path] , snake_case__ : bool = True , snake_case__ : Optional[str] = None , snake_case__ : Optional[str] = None , **snake_case__ : Dict , ) -> Union[str, Any]:
'''simple docstring'''
snake_case : Dict = None
if len(str(snake_case__ ).split("@" ) ) == 2:
snake_case , snake_case : int = model_id.split("@" )
return cls._from_pretrained(
model_id=snake_case__ , revision=snake_case__ , cache_dir=snake_case__ , force_download=snake_case__ , use_auth_token=snake_case__ , **snake_case__ , )
| 59
| 1
|
import math
def UpperCamelCase ( __lowerCamelCase : list , __lowerCamelCase : int = 0 , __lowerCamelCase : int = 0 ):
snake_case : List[str] = end or len(__lowerCamelCase )
for i in range(__lowerCamelCase , __lowerCamelCase ):
snake_case : Tuple = i
snake_case : Optional[int] = array[i]
while temp_index != start and temp_index_value < array[temp_index - 1]:
snake_case : Tuple = array[temp_index - 1]
temp_index -= 1
snake_case : Dict = temp_index_value
return array
def UpperCamelCase ( __lowerCamelCase : list , __lowerCamelCase : int , __lowerCamelCase : int ): # Max Heap
snake_case : Union[str, Any] = index
snake_case : Any = 2 * index + 1 # Left Node
snake_case : Any = 2 * index + 2 # Right Node
if left_index < heap_size and array[largest] < array[left_index]:
snake_case : Dict = left_index
if right_index < heap_size and array[largest] < array[right_index]:
snake_case : List[str] = right_index
if largest != index:
snake_case , snake_case : Any = array[largest], array[index]
heapify(__lowerCamelCase , __lowerCamelCase , __lowerCamelCase )
def UpperCamelCase ( __lowerCamelCase : list ):
snake_case : Optional[int] = len(__lowerCamelCase )
for i in range(n // 2 , -1 , -1 ):
heapify(__lowerCamelCase , __lowerCamelCase , __lowerCamelCase )
for i in range(n - 1 , 0 , -1 ):
snake_case , snake_case : Any = array[0], array[i]
heapify(__lowerCamelCase , 0 , __lowerCamelCase )
return array
def UpperCamelCase ( __lowerCamelCase : list , __lowerCamelCase : int , __lowerCamelCase : int , __lowerCamelCase : int ):
if (array[first_index] > array[middle_index]) != (
array[first_index] > array[last_index]
):
return array[first_index]
elif (array[middle_index] > array[first_index]) != (
array[middle_index] > array[last_index]
):
return array[middle_index]
else:
return array[last_index]
def UpperCamelCase ( __lowerCamelCase : list , __lowerCamelCase : int , __lowerCamelCase : int , __lowerCamelCase : int ):
snake_case : Tuple = low
snake_case : List[str] = high
while True:
while array[i] < pivot:
i += 1
j -= 1
while pivot < array[j]:
j -= 1
if i >= j:
return i
snake_case , snake_case : List[Any] = array[j], array[i]
i += 1
def UpperCamelCase ( __lowerCamelCase : list ):
if len(__lowerCamelCase ) == 0:
return array
snake_case : Tuple = 2 * math.ceil(math.loga(len(__lowerCamelCase ) ) )
snake_case : Optional[int] = 16
return intro_sort(__lowerCamelCase , 0 , len(__lowerCamelCase ) , __lowerCamelCase , __lowerCamelCase )
def UpperCamelCase ( __lowerCamelCase : list , __lowerCamelCase : int , __lowerCamelCase : int , __lowerCamelCase : int , __lowerCamelCase : int ):
while end - start > size_threshold:
if max_depth == 0:
return heap_sort(__lowerCamelCase )
max_depth -= 1
snake_case : Tuple = median_of_a(__lowerCamelCase , __lowerCamelCase , start + ((end - start) // 2) + 1 , end - 1 )
snake_case : Optional[int] = partition(__lowerCamelCase , __lowerCamelCase , __lowerCamelCase , __lowerCamelCase )
intro_sort(__lowerCamelCase , __lowerCamelCase , __lowerCamelCase , __lowerCamelCase , __lowerCamelCase )
snake_case : Optional[Any] = p
return insertion_sort(__lowerCamelCase , __lowerCamelCase , __lowerCamelCase )
if __name__ == "__main__":
import doctest
doctest.testmod()
__lowerCamelCase = input("""Enter numbers separated by a comma : """).strip()
__lowerCamelCase = [float(item) for item in user_input.split(""",""")]
print(sort(unsorted))
| 59
|
import argparse
import json
from dataclasses import dataclass, field
from functools import partial
from pathlib import Path
from typing import Callable, Dict, List, Tuple
import timm
import torch
import torch.nn as nn
from classy_vision.models.regnet import RegNet, RegNetParams, RegNetYaagf, RegNetYaagf, RegNetYaaagf
from huggingface_hub import cached_download, hf_hub_url
from torch import Tensor
from vissl.models.model_helpers import get_trunk_forward_outputs
from transformers import AutoImageProcessor, RegNetConfig, RegNetForImageClassification, RegNetModel
from transformers.utils import logging
logging.set_verbosity_info()
__lowerCamelCase = logging.get_logger()
@dataclass
class UpperCAmelCase :
A__ : nn.Module
A__ : List[nn.Module] = field(default_factory=A_ )
A__ : list = field(default_factory=A_ )
def _SCREAMING_SNAKE_CASE (self : Optional[Any] , snake_case__ : Optional[Any] , snake_case__ : Tensor , snake_case__ : Tensor ) -> Optional[Any]:
'''simple docstring'''
snake_case : List[str] = len(list(m.modules() ) ) == 1 or isinstance(snake_case__ , nn.Convad ) or isinstance(snake_case__ , nn.BatchNormad )
if has_not_submodules:
self.traced.append(snake_case__ )
def __call__(self : List[Any] , snake_case__ : Tensor ) -> List[Any]:
'''simple docstring'''
for m in self.module.modules():
self.handles.append(m.register_forward_hook(self._forward_hook ) )
self.module(snake_case__ )
[x.remove() for x in self.handles]
return self
@property
def _SCREAMING_SNAKE_CASE (self : int ) -> Optional[int]:
'''simple docstring'''
return list(filter(lambda snake_case__ : len(list(x.state_dict().keys() ) ) > 0 , self.traced ) )
@dataclass
class UpperCAmelCase :
A__ : nn.Module
A__ : nn.Module
A__ : int = 1
A__ : List = field(default_factory=A_ )
A__ : List = field(default_factory=A_ )
A__ : bool = True
def __call__(self : List[Any] , snake_case__ : Tensor ) -> Any:
'''simple docstring'''
snake_case : str = Tracker(self.dest )(snake_case__ ).parametrized
snake_case : Optional[int] = Tracker(self.src )(snake_case__ ).parametrized
snake_case : List[str] = list(filter(lambda snake_case__ : type(snake_case__ ) not in self.src_skip , snake_case__ ) )
snake_case : Optional[Any] = list(filter(lambda snake_case__ : type(snake_case__ ) not in self.dest_skip , snake_case__ ) )
if len(snake_case__ ) != len(snake_case__ ) and self.raise_if_mismatch:
raise Exception(
f"""Numbers of operations are different. Source module has {len(snake_case__ )} operations while"""
f""" destination module has {len(snake_case__ )}.""" )
for dest_m, src_m in zip(snake_case__ , snake_case__ ):
dest_m.load_state_dict(src_m.state_dict() )
if self.verbose == 1:
print(f"""Transfered from={src_m} to={dest_m}""" )
class UpperCAmelCase ( nn.Module ):
def __init__(self : Tuple , snake_case__ : nn.Module ) -> Optional[Any]:
'''simple docstring'''
super().__init__()
snake_case : List[Tuple[str, nn.Module]] = []
# - get the stem
feature_blocks.append(("conv1", model.stem) )
# - get all the feature blocks
for k, v in model.trunk_output.named_children():
assert k.startswith("block" ), f"""Unexpected layer name {k}"""
snake_case : Union[str, Any] = len(snake_case__ ) + 1
feature_blocks.append((f"""res{block_index}""", v) )
snake_case : Optional[Any] = nn.ModuleDict(snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Tuple , snake_case__ : Tensor ) -> Dict:
'''simple docstring'''
return get_trunk_forward_outputs(
snake_case__ , out_feat_keys=snake_case__ , feature_blocks=self._feature_blocks , )
class UpperCAmelCase ( A_ ):
def _SCREAMING_SNAKE_CASE (self : Any , snake_case__ : str ) -> str:
'''simple docstring'''
snake_case : List[Any] = x.split("-" )
return x_split[0] + x_split[1] + "_" + "".join(x_split[2:] )
def __getitem__(self : Optional[int] , snake_case__ : str ) -> Callable[[], Tuple[nn.Module, Dict]]:
'''simple docstring'''
if x not in self:
snake_case : Dict = self.convert_name_to_timm(snake_case__ )
snake_case : Union[str, Any] = partial(lambda: (timm.create_model(snake_case__ , pretrained=snake_case__ ).eval(), None) )
else:
snake_case : List[str] = super().__getitem__(snake_case__ )
return val
class UpperCAmelCase ( A_ ):
def __getitem__(self : Dict , snake_case__ : str ) -> Callable[[], nn.Module]:
'''simple docstring'''
if "seer" in x and "in1k" not in x:
snake_case : str = RegNetModel
else:
snake_case : Optional[Any] = RegNetForImageClassification
return val
def UpperCamelCase ( __lowerCamelCase : Union[str, Any] , __lowerCamelCase : Union[str, Any] , __lowerCamelCase : List[Tuple[str, str]] ):
for from_key, to_key in keys:
snake_case : str = from_state_dict[from_key].clone()
print(f"""Copied key={from_key} to={to_key}""" )
return to_state_dict
def UpperCamelCase ( __lowerCamelCase : str , __lowerCamelCase : Callable[[], nn.Module] , __lowerCamelCase : Callable[[], nn.Module] , __lowerCamelCase : RegNetConfig , __lowerCamelCase : Path , __lowerCamelCase : bool = True , ):
print(f"""Converting {name}...""" )
with torch.no_grad():
snake_case , snake_case : int = from_model_func()
snake_case : str = our_model_func(__lowerCamelCase ).eval()
snake_case : int = ModuleTransfer(src=__lowerCamelCase , dest=__lowerCamelCase , raise_if_mismatch=__lowerCamelCase )
snake_case : Dict = torch.randn((1, 3, 224, 224) )
module_transfer(__lowerCamelCase )
if from_state_dict is not None:
snake_case : str = []
# for seer - in1k finetuned we have to manually copy the head
if "seer" in name and "in1k" in name:
snake_case : Tuple = [("0.clf.0.weight", "classifier.1.weight"), ("0.clf.0.bias", "classifier.1.bias")]
snake_case : Optional[Any] = manually_copy_vissl_head(__lowerCamelCase , our_model.state_dict() , __lowerCamelCase )
our_model.load_state_dict(__lowerCamelCase )
snake_case : Any = our_model(__lowerCamelCase , output_hidden_states=__lowerCamelCase )
snake_case : Union[str, Any] = (
our_outputs.logits if isinstance(__lowerCamelCase , __lowerCamelCase ) else our_outputs.last_hidden_state
)
snake_case : Union[str, Any] = from_model(__lowerCamelCase )
snake_case : Dict = from_output[-1] if type(__lowerCamelCase ) is list else from_output
# now since I don't want to use any config files, vissl seer model doesn't actually have an head, so let's just check the last hidden state
if "seer" in name and "in1k" in name:
snake_case : Any = our_outputs.hidden_states[-1]
assert torch.allclose(__lowerCamelCase , __lowerCamelCase ), "The model logits don't match the original one."
if push_to_hub:
our_model.push_to_hub(
repo_path_or_name=save_directory / name , commit_message="Add model" , use_temp_dir=__lowerCamelCase , )
snake_case : List[str] = 224 if "seer" not in name else 384
# we can use the convnext one
snake_case : int = AutoImageProcessor.from_pretrained("facebook/convnext-base-224-22k-1k" , size=__lowerCamelCase )
image_processor.push_to_hub(
repo_path_or_name=save_directory / name , commit_message="Add image processor" , use_temp_dir=__lowerCamelCase , )
print(f"""Pushed {name}""" )
def UpperCamelCase ( __lowerCamelCase : Path , __lowerCamelCase : str = None , __lowerCamelCase : bool = True ):
snake_case : Union[str, Any] = "imagenet-1k-id2label.json"
snake_case : List[str] = 1000
snake_case : List[str] = (1, num_labels)
snake_case : Any = "huggingface/label-files"
snake_case : List[str] = num_labels
snake_case : Optional[Any] = json.load(open(cached_download(hf_hub_url(__lowerCamelCase , __lowerCamelCase , repo_type="dataset" ) ) , "r" ) )
snake_case : List[Any] = {int(__lowerCamelCase ): v for k, v in idalabel.items()}
snake_case : str = idalabel
snake_case : List[Any] = {v: k for k, v in idalabel.items()}
snake_case : Dict = partial(__lowerCamelCase , num_labels=__lowerCamelCase , idalabel=__lowerCamelCase , labelaid=__lowerCamelCase )
snake_case : Optional[Any] = {
"regnet-x-002": ImageNetPreTrainedConfig(
depths=[1, 1, 4, 7] , hidden_sizes=[24, 56, 152, 368] , groups_width=8 , layer_type="x" ),
"regnet-x-004": ImageNetPreTrainedConfig(
depths=[1, 2, 7, 12] , hidden_sizes=[32, 64, 160, 384] , groups_width=16 , layer_type="x" ),
"regnet-x-006": ImageNetPreTrainedConfig(
depths=[1, 3, 5, 7] , hidden_sizes=[48, 96, 240, 528] , groups_width=24 , layer_type="x" ),
"regnet-x-008": ImageNetPreTrainedConfig(
depths=[1, 3, 7, 5] , hidden_sizes=[64, 128, 288, 672] , groups_width=16 , layer_type="x" ),
"regnet-x-016": ImageNetPreTrainedConfig(
depths=[2, 4, 10, 2] , hidden_sizes=[72, 168, 408, 912] , groups_width=24 , layer_type="x" ),
"regnet-x-032": ImageNetPreTrainedConfig(
depths=[2, 6, 15, 2] , hidden_sizes=[96, 192, 432, 1008] , groups_width=48 , layer_type="x" ),
"regnet-x-040": ImageNetPreTrainedConfig(
depths=[2, 5, 14, 2] , hidden_sizes=[80, 240, 560, 1360] , groups_width=40 , layer_type="x" ),
"regnet-x-064": ImageNetPreTrainedConfig(
depths=[2, 4, 10, 1] , hidden_sizes=[168, 392, 784, 1624] , groups_width=56 , layer_type="x" ),
"regnet-x-080": ImageNetPreTrainedConfig(
depths=[2, 5, 15, 1] , hidden_sizes=[80, 240, 720, 1920] , groups_width=120 , layer_type="x" ),
"regnet-x-120": ImageNetPreTrainedConfig(
depths=[2, 5, 11, 1] , hidden_sizes=[224, 448, 896, 2240] , groups_width=112 , layer_type="x" ),
"regnet-x-160": ImageNetPreTrainedConfig(
depths=[2, 6, 13, 1] , hidden_sizes=[256, 512, 896, 2048] , groups_width=128 , layer_type="x" ),
"regnet-x-320": ImageNetPreTrainedConfig(
depths=[2, 7, 13, 1] , hidden_sizes=[336, 672, 1344, 2520] , groups_width=168 , layer_type="x" ),
# y variant
"regnet-y-002": ImageNetPreTrainedConfig(depths=[1, 1, 4, 7] , hidden_sizes=[24, 56, 152, 368] , groups_width=8 ),
"regnet-y-004": ImageNetPreTrainedConfig(
depths=[1, 3, 6, 6] , hidden_sizes=[48, 104, 208, 440] , groups_width=8 ),
"regnet-y-006": ImageNetPreTrainedConfig(
depths=[1, 3, 7, 4] , hidden_sizes=[48, 112, 256, 608] , groups_width=16 ),
"regnet-y-008": ImageNetPreTrainedConfig(
depths=[1, 3, 8, 2] , hidden_sizes=[64, 128, 320, 768] , groups_width=16 ),
"regnet-y-016": ImageNetPreTrainedConfig(
depths=[2, 6, 17, 2] , hidden_sizes=[48, 120, 336, 888] , groups_width=24 ),
"regnet-y-032": ImageNetPreTrainedConfig(
depths=[2, 5, 13, 1] , hidden_sizes=[72, 216, 576, 1512] , groups_width=24 ),
"regnet-y-040": ImageNetPreTrainedConfig(
depths=[2, 6, 12, 2] , hidden_sizes=[128, 192, 512, 1088] , groups_width=64 ),
"regnet-y-064": ImageNetPreTrainedConfig(
depths=[2, 7, 14, 2] , hidden_sizes=[144, 288, 576, 1296] , groups_width=72 ),
"regnet-y-080": ImageNetPreTrainedConfig(
depths=[2, 4, 10, 1] , hidden_sizes=[168, 448, 896, 2016] , groups_width=56 ),
"regnet-y-120": ImageNetPreTrainedConfig(
depths=[2, 5, 11, 1] , hidden_sizes=[224, 448, 896, 2240] , groups_width=112 ),
"regnet-y-160": ImageNetPreTrainedConfig(
depths=[2, 4, 11, 1] , hidden_sizes=[224, 448, 1232, 3024] , groups_width=112 ),
"regnet-y-320": ImageNetPreTrainedConfig(
depths=[2, 5, 12, 1] , hidden_sizes=[232, 696, 1392, 3712] , groups_width=232 ),
# models created by SEER -> https://arxiv.org/abs/2202.08360
"regnet-y-320-seer": RegNetConfig(depths=[2, 5, 12, 1] , hidden_sizes=[232, 696, 1392, 3712] , groups_width=232 ),
"regnet-y-640-seer": RegNetConfig(depths=[2, 5, 12, 1] , hidden_sizes=[328, 984, 1968, 4920] , groups_width=328 ),
"regnet-y-1280-seer": RegNetConfig(
depths=[2, 7, 17, 1] , hidden_sizes=[528, 1056, 2904, 7392] , groups_width=264 ),
"regnet-y-2560-seer": RegNetConfig(
depths=[3, 7, 16, 1] , hidden_sizes=[640, 1696, 2544, 5088] , groups_width=640 ),
"regnet-y-10b-seer": ImageNetPreTrainedConfig(
depths=[2, 7, 17, 1] , hidden_sizes=[2020, 4040, 11110, 28280] , groups_width=1010 ),
# finetuned on imagenet
"regnet-y-320-seer-in1k": ImageNetPreTrainedConfig(
depths=[2, 5, 12, 1] , hidden_sizes=[232, 696, 1392, 3712] , groups_width=232 ),
"regnet-y-640-seer-in1k": ImageNetPreTrainedConfig(
depths=[2, 5, 12, 1] , hidden_sizes=[328, 984, 1968, 4920] , groups_width=328 ),
"regnet-y-1280-seer-in1k": ImageNetPreTrainedConfig(
depths=[2, 7, 17, 1] , hidden_sizes=[528, 1056, 2904, 7392] , groups_width=264 ),
"regnet-y-2560-seer-in1k": ImageNetPreTrainedConfig(
depths=[3, 7, 16, 1] , hidden_sizes=[640, 1696, 2544, 5088] , groups_width=640 ),
"regnet-y-10b-seer-in1k": ImageNetPreTrainedConfig(
depths=[2, 7, 17, 1] , hidden_sizes=[2020, 4040, 11110, 28280] , groups_width=1010 ),
}
snake_case : Union[str, Any] = NameToOurModelFuncMap()
snake_case : str = NameToFromModelFuncMap()
# add seer weights logic
def load_using_classy_vision(__lowerCamelCase : str , __lowerCamelCase : Callable[[], nn.Module] ) -> Tuple[nn.Module, Dict]:
snake_case : List[Any] = torch.hub.load_state_dict_from_url(__lowerCamelCase , model_dir=str(__lowerCamelCase ) , map_location="cpu" )
snake_case : Dict = model_func()
# check if we have a head, if yes add it
snake_case : str = files["classy_state_dict"]["base_model"]["model"]
snake_case : Dict = model_state_dict["trunk"]
model.load_state_dict(__lowerCamelCase )
return model.eval(), model_state_dict["heads"]
# pretrained
snake_case : List[Any] = partial(
__lowerCamelCase , "https://dl.fbaipublicfiles.com/vissl/model_zoo/seer_regnet32d/seer_regnet32gf_model_iteration244000.torch" , lambda: FakeRegNetVisslWrapper(RegNetYaagf() ) , )
snake_case : Optional[int] = partial(
__lowerCamelCase , "https://dl.fbaipublicfiles.com/vissl/model_zoo/seer_regnet64/seer_regnet64gf_model_final_checkpoint_phase0.torch" , lambda: FakeRegNetVisslWrapper(RegNetYaagf() ) , )
snake_case : List[str] = partial(
__lowerCamelCase , "https://dl.fbaipublicfiles.com/vissl/model_zoo/swav_ig1b_regnet128Gf_cnstant_bs32_node16_sinkhorn10_proto16k_syncBN64_warmup8k/model_final_checkpoint_phase0.torch" , lambda: FakeRegNetVisslWrapper(RegNetYaaagf() ) , )
snake_case : Tuple = partial(
__lowerCamelCase , "https://dl.fbaipublicfiles.com/vissl/model_zoo/seer_regnet10B/model_iteration124500_conso.torch" , lambda: FakeRegNetVisslWrapper(
RegNet(RegNetParams(depth=27 , group_width=1010 , w_a=1744 , w_a=620.83 , w_m=2.52 ) ) ) , )
# IN1K finetuned
snake_case : List[Any] = partial(
__lowerCamelCase , "https://dl.fbaipublicfiles.com/vissl/model_zoo/seer_finetuned/seer_regnet32_finetuned_in1k_model_final_checkpoint_phase78.torch" , lambda: FakeRegNetVisslWrapper(RegNetYaagf() ) , )
snake_case : Tuple = partial(
__lowerCamelCase , "https://dl.fbaipublicfiles.com/vissl/model_zoo/seer_finetuned/seer_regnet64_finetuned_in1k_model_final_checkpoint_phase78.torch" , lambda: FakeRegNetVisslWrapper(RegNetYaagf() ) , )
snake_case : str = partial(
__lowerCamelCase , "https://dl.fbaipublicfiles.com/vissl/model_zoo/seer_finetuned/seer_regnet128_finetuned_in1k_model_final_checkpoint_phase78.torch" , lambda: FakeRegNetVisslWrapper(RegNetYaaagf() ) , )
snake_case : Dict = partial(
__lowerCamelCase , "https://dl.fbaipublicfiles.com/vissl/model_zoo/seer_finetuned/seer_10b_finetuned_in1k_model_phase28_conso.torch" , lambda: FakeRegNetVisslWrapper(
RegNet(RegNetParams(depth=27 , group_width=1010 , w_a=1744 , w_a=620.83 , w_m=2.52 ) ) ) , )
if model_name:
convert_weight_and_push(
__lowerCamelCase , names_to_from_model_map[model_name] , names_to_ours_model_map[model_name] , names_to_config[model_name] , __lowerCamelCase , __lowerCamelCase , )
else:
for model_name, config in names_to_config.items():
convert_weight_and_push(
__lowerCamelCase , names_to_from_model_map[model_name] , names_to_ours_model_map[model_name] , __lowerCamelCase , __lowerCamelCase , __lowerCamelCase , )
return config, expected_shape
if __name__ == "__main__":
__lowerCamelCase = argparse.ArgumentParser()
# Required parameters
parser.add_argument(
"""--model_name""",
default=None,
type=str,
help=(
"""The name of the model you wish to convert, it must be one of the supported regnet* architecture,"""
""" currently: regnetx-*, regnety-*. If `None`, all of them will the converted."""
),
)
parser.add_argument(
"""--pytorch_dump_folder_path""",
default=None,
type=Path,
required=True,
help="""Path to the output PyTorch model directory.""",
)
parser.add_argument(
"""--push_to_hub""",
default=True,
type=bool,
required=False,
help="""If True, push model and image processor to the hub.""",
)
__lowerCamelCase = parser.parse_args()
__lowerCamelCase = args.pytorch_dump_folder_path
pytorch_dump_folder_path.mkdir(exist_ok=True, parents=True)
convert_weights_and_push(pytorch_dump_folder_path, args.model_name, args.push_to_hub)
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import logging
import os
from dataclasses import dataclass, field
from typing import Dict, Optional
import datasets
import numpy as np
import tensorflow as tf
from transformers import (
AutoConfig,
AutoTokenizer,
EvalPrediction,
HfArgumentParser,
PreTrainedTokenizer,
TFAutoModelForSequenceClassification,
TFTrainer,
TFTrainingArguments,
)
from transformers.utils import logging as hf_logging
hf_logging.set_verbosity_info()
hf_logging.enable_default_handler()
hf_logging.enable_explicit_format()
def UpperCamelCase ( __lowerCamelCase : str , __lowerCamelCase : str , __lowerCamelCase : str , __lowerCamelCase : PreTrainedTokenizer , __lowerCamelCase : int , __lowerCamelCase : Optional[int] = None , ):
snake_case : int = {}
if train_file is not None:
snake_case : List[Any] = [train_file]
if eval_file is not None:
snake_case : Optional[int] = [eval_file]
if test_file is not None:
snake_case : Any = [test_file]
snake_case : int = datasets.load_dataset("csv" , data_files=__lowerCamelCase )
snake_case : str = list(ds[list(files.keys() )[0]].features.keys() )
snake_case : int = features_name.pop(__lowerCamelCase )
snake_case : str = list(set(ds[list(files.keys() )[0]][label_name] ) )
snake_case : str = {label: i for i, label in enumerate(__lowerCamelCase )}
snake_case : List[Any] = tokenizer.model_input_names
snake_case : List[Any] = {}
if len(__lowerCamelCase ) == 1:
for k in files.keys():
snake_case : Tuple = ds[k].map(
lambda __lowerCamelCase : tokenizer.batch_encode_plus(
example[features_name[0]] , truncation=__lowerCamelCase , max_length=__lowerCamelCase , padding="max_length" ) , batched=__lowerCamelCase , )
elif len(__lowerCamelCase ) == 2:
for k in files.keys():
snake_case : List[Any] = ds[k].map(
lambda __lowerCamelCase : tokenizer.batch_encode_plus(
(example[features_name[0]], example[features_name[1]]) , truncation=__lowerCamelCase , max_length=__lowerCamelCase , padding="max_length" , ) , batched=__lowerCamelCase , )
def gen_train():
for ex in transformed_ds[datasets.Split.TRAIN]:
snake_case : Dict = {k: v for k, v in ex.items() if k in input_names}
snake_case : Union[str, Any] = labelaid[ex[label_name]]
yield (d, label)
def gen_val():
for ex in transformed_ds[datasets.Split.VALIDATION]:
snake_case : str = {k: v for k, v in ex.items() if k in input_names}
snake_case : Any = labelaid[ex[label_name]]
yield (d, label)
def gen_test():
for ex in transformed_ds[datasets.Split.TEST]:
snake_case : str = {k: v for k, v in ex.items() if k in input_names}
snake_case : List[str] = labelaid[ex[label_name]]
yield (d, label)
snake_case : int = (
tf.data.Dataset.from_generator(
__lowerCamelCase , ({k: tf.intaa for k in input_names}, tf.intaa) , ({k: tf.TensorShape([None] ) for k in input_names}, tf.TensorShape([] )) , )
if datasets.Split.TRAIN in transformed_ds
else None
)
if train_ds is not None:
snake_case : Optional[Any] = train_ds.apply(tf.data.experimental.assert_cardinality(len(ds[datasets.Split.TRAIN] ) ) )
snake_case : Tuple = (
tf.data.Dataset.from_generator(
__lowerCamelCase , ({k: tf.intaa for k in input_names}, tf.intaa) , ({k: tf.TensorShape([None] ) for k in input_names}, tf.TensorShape([] )) , )
if datasets.Split.VALIDATION in transformed_ds
else None
)
if val_ds is not None:
snake_case : List[str] = val_ds.apply(tf.data.experimental.assert_cardinality(len(ds[datasets.Split.VALIDATION] ) ) )
snake_case : Optional[int] = (
tf.data.Dataset.from_generator(
__lowerCamelCase , ({k: tf.intaa for k in input_names}, tf.intaa) , ({k: tf.TensorShape([None] ) for k in input_names}, tf.TensorShape([] )) , )
if datasets.Split.TEST in transformed_ds
else None
)
if test_ds is not None:
snake_case : str = test_ds.apply(tf.data.experimental.assert_cardinality(len(ds[datasets.Split.TEST] ) ) )
return train_ds, val_ds, test_ds, labelaid
__lowerCamelCase = logging.getLogger(__name__)
@dataclass
class UpperCAmelCase :
A__ : int = field(metadata={"help": "Which column contains the label"} )
A__ : str = field(default=A_ ,metadata={"help": "The path of the training file"} )
A__ : Optional[str] = field(default=A_ ,metadata={"help": "The path of the development file"} )
A__ : Optional[str] = field(default=A_ ,metadata={"help": "The path of the test file"} )
A__ : int = field(
default=1_28 ,metadata={
"help": (
"The maximum total input sequence length after tokenization. Sequences longer "
"than this will be truncated, sequences shorter will be padded."
)
} ,)
A__ : bool = field(
default=A_ ,metadata={"help": "Overwrite the cached training and evaluation sets"} )
@dataclass
class UpperCAmelCase :
A__ : str = field(
metadata={"help": "Path to pretrained model or model identifier from huggingface.co/models"} )
A__ : Optional[str] = field(
default=A_ ,metadata={"help": "Pretrained config name or path if not the same as model_name"} )
A__ : Optional[str] = field(
default=A_ ,metadata={"help": "Pretrained tokenizer name or path if not the same as model_name"} )
A__ : bool = 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.
A__ : Optional[str] = field(
default=A_ ,metadata={"help": "Where do you want to store the pretrained models downloaded from huggingface.co"} ,)
def UpperCamelCase ( ):
# See all possible arguments in src/transformers/training_args.py
# or by passing the --help flag to this script.
# We now keep distinct sets of args, for a cleaner separation of concerns.
snake_case : List[Any] = HfArgumentParser((ModelArguments, DataTrainingArguments, TFTrainingArguments) )
snake_case , snake_case , snake_case : int = parser.parse_args_into_dataclasses()
if (
os.path.exists(training_args.output_dir )
and os.listdir(training_args.output_dir )
and training_args.do_train
and not training_args.overwrite_output_dir
):
raise ValueError(
f"""Output directory ({training_args.output_dir}) already exists and is not empty. Use"""
" --overwrite_output_dir to overcome." )
# Setup logging
logging.basicConfig(
format="%(asctime)s - %(levelname)s - %(name)s - %(message)s" , datefmt="%m/%d/%Y %H:%M:%S" , level=logging.INFO , )
logger.info(
f"""n_replicas: {training_args.n_replicas}, distributed training: {bool(training_args.n_replicas > 1 )}, """
f"""16-bits training: {training_args.fpaa}""" )
logger.info(f"""Training/evaluation parameters {training_args}""" )
# Load pretrained model and tokenizer
#
# Distributed training:
# The .from_pretrained methods guarantee that only one local process can concurrently
# download model & vocab.
snake_case : Tuple = AutoTokenizer.from_pretrained(
model_args.tokenizer_name if model_args.tokenizer_name else model_args.model_name_or_path , cache_dir=model_args.cache_dir , )
snake_case , snake_case , snake_case , snake_case : Tuple = get_tfds(
train_file=data_args.train_file , eval_file=data_args.dev_file , test_file=data_args.test_file , tokenizer=__lowerCamelCase , label_column_id=data_args.label_column_id , max_seq_length=data_args.max_seq_length , )
snake_case : Optional[Any] = AutoConfig.from_pretrained(
model_args.config_name if model_args.config_name else model_args.model_name_or_path , num_labels=len(__lowerCamelCase ) , labelaid=__lowerCamelCase , idalabel={id: label for label, id in labelaid.items()} , finetuning_task="text-classification" , cache_dir=model_args.cache_dir , )
with training_args.strategy.scope():
snake_case : int = TFAutoModelForSequenceClassification.from_pretrained(
model_args.model_name_or_path , from_pt=bool(".bin" in model_args.model_name_or_path ) , config=__lowerCamelCase , cache_dir=model_args.cache_dir , )
def compute_metrics(__lowerCamelCase : EvalPrediction ) -> Dict:
snake_case : Optional[int] = np.argmax(p.predictions , axis=1 )
return {"acc": (preds == p.label_ids).mean()}
# Initialize our Trainer
snake_case : int = TFTrainer(
model=__lowerCamelCase , args=__lowerCamelCase , train_dataset=__lowerCamelCase , eval_dataset=__lowerCamelCase , compute_metrics=__lowerCamelCase , )
# Training
if training_args.do_train:
trainer.train()
trainer.save_model()
tokenizer.save_pretrained(training_args.output_dir )
# Evaluation
snake_case : int = {}
if training_args.do_eval:
logger.info("*** Evaluate ***" )
snake_case : Any = trainer.evaluate()
snake_case : List[Any] = os.path.join(training_args.output_dir , "eval_results.txt" )
with open(__lowerCamelCase , "w" ) as writer:
logger.info("***** Eval results *****" )
for key, value in result.items():
logger.info(f""" {key} = {value}""" )
writer.write(f"""{key} = {value}\n""" )
results.update(__lowerCamelCase )
return results
if __name__ == "__main__":
main()
| 59
|
import warnings
from typing import Dict
import numpy as np
from ..utils import ExplicitEnum, add_end_docstrings, is_tf_available, is_torch_available
from .base import PIPELINE_INIT_ARGS, GenericTensor, Pipeline
if is_tf_available():
from ..models.auto.modeling_tf_auto import TF_MODEL_FOR_SEQUENCE_CLASSIFICATION_MAPPING
if is_torch_available():
from ..models.auto.modeling_auto import MODEL_FOR_SEQUENCE_CLASSIFICATION_MAPPING
def UpperCamelCase ( __lowerCamelCase : List[Any] ):
return 1.0 / (1.0 + np.exp(-_outputs ))
def UpperCamelCase ( __lowerCamelCase : int ):
snake_case : Tuple = np.max(_outputs , axis=-1 , keepdims=__lowerCamelCase )
snake_case : int = np.exp(_outputs - maxes )
return shifted_exp / shifted_exp.sum(axis=-1 , keepdims=__lowerCamelCase )
class UpperCAmelCase ( A_ ):
A__ : Any = "sigmoid"
A__ : str = "softmax"
A__ : int = "none"
@add_end_docstrings(
A_ ,r"\n return_all_scores (`bool`, *optional*, defaults to `False`):\n Whether to return all prediction scores or just the one of the predicted class.\n function_to_apply (`str`, *optional*, defaults to `\"default\"`):\n The function to apply to the model outputs in order to retrieve the scores. Accepts four different values:\n\n - `\"default\"`: if the model has a single label, will apply the sigmoid function on the output. If the model\n has several labels, will apply the softmax function on the output.\n - `\"sigmoid\"`: Applies the sigmoid function on the output.\n - `\"softmax\"`: Applies the softmax function on the output.\n - `\"none\"`: Does not apply any function on the output.\n " ,)
class UpperCAmelCase ( A_ ):
A__ : int = False
A__ : Union[str, Any] = ClassificationFunction.NONE
def __init__(self : List[str] , **snake_case__ : int ) -> str:
'''simple docstring'''
super().__init__(**snake_case__ )
self.check_model_type(
TF_MODEL_FOR_SEQUENCE_CLASSIFICATION_MAPPING
if self.framework == "tf"
else MODEL_FOR_SEQUENCE_CLASSIFICATION_MAPPING )
def _SCREAMING_SNAKE_CASE (self : List[Any] , snake_case__ : List[str]=None , snake_case__ : Optional[Any]=None , snake_case__ : Union[str, Any]="" , **snake_case__ : List[str] ) -> Union[str, Any]:
'''simple docstring'''
snake_case : Dict = tokenizer_kwargs
snake_case : List[Any] = {}
if hasattr(self.model.config , "return_all_scores" ) and return_all_scores is None:
snake_case : Optional[int] = self.model.config.return_all_scores
if isinstance(snake_case__ , snake_case__ ) or top_k is None:
snake_case : List[Any] = top_k
snake_case : str = False
elif return_all_scores is not None:
warnings.warn(
"`return_all_scores` is now deprecated, if want a similar functionality use `top_k=None` instead of"
" `return_all_scores=True` or `top_k=1` instead of `return_all_scores=False`." , snake_case__ , )
if return_all_scores:
snake_case : List[str] = None
else:
snake_case : Optional[int] = 1
if isinstance(snake_case__ , snake_case__ ):
snake_case : Dict = ClassificationFunction[function_to_apply.upper()]
if function_to_apply is not None:
snake_case : Optional[int] = function_to_apply
return preprocess_params, {}, postprocess_params
def __call__(self : Dict , *snake_case__ : List[str] , **snake_case__ : int ) -> Optional[int]:
'''simple docstring'''
snake_case : Optional[int] = super().__call__(*snake_case__ , **snake_case__ )
# TODO try and retrieve it in a nicer way from _sanitize_parameters.
snake_case : Tuple = "top_k" not in kwargs
if isinstance(args[0] , snake_case__ ) and _legacy:
# This pipeline is odd, and return a list when single item is run
return [result]
else:
return result
def _SCREAMING_SNAKE_CASE (self : Dict , snake_case__ : Tuple , **snake_case__ : Union[str, Any] ) -> Dict[str, GenericTensor]:
'''simple docstring'''
snake_case : int = self.framework
if isinstance(snake_case__ , snake_case__ ):
return self.tokenizer(**snake_case__ , return_tensors=snake_case__ , **snake_case__ )
elif isinstance(snake_case__ , snake_case__ ) and len(snake_case__ ) == 1 and isinstance(inputs[0] , snake_case__ ) and len(inputs[0] ) == 2:
# It used to be valid to use a list of list of list for text pairs, keeping this path for BC
return self.tokenizer(
text=inputs[0][0] , text_pair=inputs[0][1] , return_tensors=snake_case__ , **snake_case__ )
elif isinstance(snake_case__ , snake_case__ ):
# This is likely an invalid usage of the pipeline attempting to pass text pairs.
raise ValueError(
"The pipeline received invalid inputs, if you are trying to send text pairs, you can try to send a"
" dictionary `{\"text\": \"My text\", \"text_pair\": \"My pair\"}` in order to send a text pair." )
return self.tokenizer(snake_case__ , return_tensors=snake_case__ , **snake_case__ )
def _SCREAMING_SNAKE_CASE (self : int , snake_case__ : Union[str, Any] ) -> int:
'''simple docstring'''
return self.model(**snake_case__ )
def _SCREAMING_SNAKE_CASE (self : List[str] , snake_case__ : Optional[Any] , snake_case__ : List[str]=None , snake_case__ : Dict=1 , snake_case__ : Tuple=True ) -> str:
'''simple docstring'''
if function_to_apply is None:
if self.model.config.problem_type == "multi_label_classification" or self.model.config.num_labels == 1:
snake_case : Tuple = ClassificationFunction.SIGMOID
elif self.model.config.problem_type == "single_label_classification" or self.model.config.num_labels > 1:
snake_case : Tuple = ClassificationFunction.SOFTMAX
elif hasattr(self.model.config , "function_to_apply" ) and function_to_apply is None:
snake_case : Tuple = self.model.config.function_to_apply
else:
snake_case : int = ClassificationFunction.NONE
snake_case : Any = model_outputs["logits"][0]
snake_case : List[str] = outputs.numpy()
if function_to_apply == ClassificationFunction.SIGMOID:
snake_case : Optional[Any] = sigmoid(snake_case__ )
elif function_to_apply == ClassificationFunction.SOFTMAX:
snake_case : Union[str, Any] = softmax(snake_case__ )
elif function_to_apply == ClassificationFunction.NONE:
snake_case : Optional[Any] = outputs
else:
raise ValueError(f"""Unrecognized `function_to_apply` argument: {function_to_apply}""" )
if top_k == 1 and _legacy:
return {"label": self.model.config.idalabel[scores.argmax().item()], "score": scores.max().item()}
snake_case : Optional[int] = [
{"label": self.model.config.idalabel[i], "score": score.item()} for i, score in enumerate(snake_case__ )
]
if not _legacy:
dict_scores.sort(key=lambda snake_case__ : x["score"] , reverse=snake_case__ )
if top_k is not None:
snake_case : Optional[int] = dict_scores[:top_k]
return dict_scores
| 59
| 1
|
class UpperCAmelCase :
def __init__(self : Optional[int] , snake_case__ : list[int] ) -> None:
'''simple docstring'''
snake_case : str = len(snake_case__ )
snake_case : int = [0] * len_array
if len_array > 0:
snake_case : List[str] = array[0]
for i in range(1 , snake_case__ ):
snake_case : str = self.prefix_sum[i - 1] + array[i]
def _SCREAMING_SNAKE_CASE (self : Tuple , snake_case__ : int , snake_case__ : int ) -> int:
'''simple docstring'''
if start == 0:
return self.prefix_sum[end]
return self.prefix_sum[end] - self.prefix_sum[start - 1]
def _SCREAMING_SNAKE_CASE (self : Union[str, Any] , snake_case__ : int ) -> bool:
'''simple docstring'''
snake_case : Dict = {0}
for sum_item in self.prefix_sum:
if sum_item - target_sum in sums:
return True
sums.add(snake_case__ )
return False
if __name__ == "__main__":
import doctest
doctest.testmod()
| 59
|
from __future__ import annotations
__lowerCamelCase = list[list[int]]
# assigning initial values to the grid
__lowerCamelCase = [
[3, 0, 6, 5, 0, 8, 4, 0, 0],
[5, 2, 0, 0, 0, 0, 0, 0, 0],
[0, 8, 7, 0, 0, 0, 0, 3, 1],
[0, 0, 3, 0, 1, 0, 0, 8, 0],
[9, 0, 0, 8, 6, 3, 0, 0, 5],
[0, 5, 0, 0, 9, 0, 6, 0, 0],
[1, 3, 0, 0, 0, 0, 2, 5, 0],
[0, 0, 0, 0, 0, 0, 0, 7, 4],
[0, 0, 5, 2, 0, 6, 3, 0, 0],
]
# a grid with no solution
__lowerCamelCase = [
[5, 0, 6, 5, 0, 8, 4, 0, 3],
[5, 2, 0, 0, 0, 0, 0, 0, 2],
[1, 8, 7, 0, 0, 0, 0, 3, 1],
[0, 0, 3, 0, 1, 0, 0, 8, 0],
[9, 0, 0, 8, 6, 3, 0, 0, 5],
[0, 5, 0, 0, 9, 0, 6, 0, 0],
[1, 3, 0, 0, 0, 0, 2, 5, 0],
[0, 0, 0, 0, 0, 0, 0, 7, 4],
[0, 0, 5, 2, 0, 6, 3, 0, 0],
]
def UpperCamelCase ( __lowerCamelCase : Matrix , __lowerCamelCase : int , __lowerCamelCase : int , __lowerCamelCase : int ):
for i in range(9 ):
if grid[row][i] == n or grid[i][column] == n:
return False
for i in range(3 ):
for j in range(3 ):
if grid[(row - row % 3) + i][(column - column % 3) + j] == n:
return False
return True
def UpperCamelCase ( __lowerCamelCase : Matrix ):
for i in range(9 ):
for j in range(9 ):
if grid[i][j] == 0:
return i, j
return None
def UpperCamelCase ( __lowerCamelCase : Matrix ):
if location := find_empty_location(__lowerCamelCase ):
snake_case , snake_case : Union[str, Any] = location
else:
# If the location is ``None``, then the grid is solved.
return grid
for digit in range(1 , 10 ):
if is_safe(__lowerCamelCase , __lowerCamelCase , __lowerCamelCase , __lowerCamelCase ):
snake_case : List[Any] = digit
if sudoku(__lowerCamelCase ) is not None:
return grid
snake_case : Union[str, Any] = 0
return None
def UpperCamelCase ( __lowerCamelCase : Matrix ):
for row in grid:
for cell in row:
print(__lowerCamelCase , end=" " )
print()
if __name__ == "__main__":
# make a copy of grid so that you can compare with the unmodified grid
for example_grid in (initial_grid, no_solution):
print("""\nExample grid:\n""" + """=""" * 20)
print_solution(example_grid)
print("""\nExample grid solution:""")
__lowerCamelCase = sudoku(example_grid)
if solution is not None:
print_solution(solution)
else:
print("""Cannot find a solution.""")
| 59
| 1
|
def UpperCamelCase ( __lowerCamelCase : int ):
if a < 0:
raise ValueError("Input value must be a positive integer" )
elif isinstance(__lowerCamelCase , __lowerCamelCase ):
raise TypeError("Input value must be a 'int' type" )
return bin(__lowerCamelCase ).count("1" )
if __name__ == "__main__":
import doctest
doctest.testmod()
| 59
|
import logging
import numpy as np
import pytest
from scipy.linalg import eigh
logging.basicConfig(level=logging.INFO, format="""%(message)s""")
def UpperCamelCase ( __lowerCamelCase : np.ndarray ):
return input_array.reshape((input_array.size, 1) )
def UpperCamelCase ( __lowerCamelCase : np.ndarray , __lowerCamelCase : np.ndarray , __lowerCamelCase : int ):
snake_case : Any = np.nan
for i in range(__lowerCamelCase ):
snake_case : List[str] = features[:, labels == i]
snake_case : Dict = data.mean(1 )
# Centralize the data of class i
snake_case : Optional[Any] = data - column_reshape(__lowerCamelCase )
if i > 0:
# If covariance_sum is not None
covariance_sum += np.dot(__lowerCamelCase , centered_data.T )
else:
# If covariance_sum is np.nan (i.e. first loop)
snake_case : Optional[Any] = np.dot(__lowerCamelCase , centered_data.T )
return covariance_sum / features.shape[1]
def UpperCamelCase ( __lowerCamelCase : np.ndarray , __lowerCamelCase : np.ndarray , __lowerCamelCase : int ):
snake_case : Optional[Any] = features.mean(1 )
snake_case : Tuple = np.nan
for i in range(__lowerCamelCase ):
snake_case : Tuple = features[:, labels == i]
snake_case : Tuple = data.shape[1]
snake_case : List[str] = data.mean(1 )
if i > 0:
# If covariance_sum is not None
covariance_sum += device_data * np.dot(
column_reshape(__lowerCamelCase ) - column_reshape(__lowerCamelCase ) , (column_reshape(__lowerCamelCase ) - column_reshape(__lowerCamelCase )).T , )
else:
# If covariance_sum is np.nan (i.e. first loop)
snake_case : Optional[int] = device_data * np.dot(
column_reshape(__lowerCamelCase ) - column_reshape(__lowerCamelCase ) , (column_reshape(__lowerCamelCase ) - column_reshape(__lowerCamelCase )).T , )
return covariance_sum / features.shape[1]
def UpperCamelCase ( __lowerCamelCase : np.ndarray , __lowerCamelCase : int ):
# Check if the features have been loaded
if features.any():
snake_case : Tuple = features.mean(1 )
# Center the dataset
snake_case : List[str] = features - np.reshape(__lowerCamelCase , (data_mean.size, 1) )
snake_case : Optional[Any] = np.dot(__lowerCamelCase , centered_data.T ) / features.shape[1]
snake_case , snake_case : Dict = np.linalg.eigh(__lowerCamelCase )
# Take all the columns in the reverse order (-1), and then takes only the first
snake_case : Optional[Any] = eigenvectors[:, ::-1][:, 0:dimensions]
# Project the database on the new space
snake_case : Union[str, Any] = np.dot(filtered_eigenvectors.T , __lowerCamelCase )
logging.info("Principal Component Analysis computed" )
return projected_data
else:
logging.basicConfig(level=logging.ERROR , format="%(message)s" , force=__lowerCamelCase )
logging.error("Dataset empty" )
raise AssertionError
def UpperCamelCase ( __lowerCamelCase : np.ndarray , __lowerCamelCase : np.ndarray , __lowerCamelCase : int , __lowerCamelCase : int ):
assert classes > dimensions
# Check if features have been already loaded
if features.any:
snake_case , snake_case : str = eigh(
covariance_between_classes(__lowerCamelCase , __lowerCamelCase , __lowerCamelCase ) , covariance_within_classes(__lowerCamelCase , __lowerCamelCase , __lowerCamelCase ) , )
snake_case : str = eigenvectors[:, ::-1][:, :dimensions]
snake_case , snake_case , snake_case : int = np.linalg.svd(__lowerCamelCase )
snake_case : List[Any] = svd_matrix[:, 0:dimensions]
snake_case : Optional[Any] = np.dot(filtered_svd_matrix.T , __lowerCamelCase )
logging.info("Linear Discriminant Analysis computed" )
return projected_data
else:
logging.basicConfig(level=logging.ERROR , format="%(message)s" , force=__lowerCamelCase )
logging.error("Dataset empty" )
raise AssertionError
def UpperCamelCase ( ):
# Create dummy dataset with 2 classes and 3 features
snake_case : str = np.array([[1, 2, 3, 4, 5], [2, 3, 4, 5, 6], [3, 4, 5, 6, 7]] )
snake_case : Union[str, Any] = np.array([0, 0, 0, 1, 1] )
snake_case : List[Any] = 2
snake_case : Any = 2
# Assert that the function raises an AssertionError if dimensions > classes
with pytest.raises(__lowerCamelCase ) as error_info:
snake_case : str = linear_discriminant_analysis(
__lowerCamelCase , __lowerCamelCase , __lowerCamelCase , __lowerCamelCase )
if isinstance(__lowerCamelCase , np.ndarray ):
raise AssertionError(
"Did not raise AssertionError for dimensions > classes" )
assert error_info.type is AssertionError
def UpperCamelCase ( ):
snake_case : List[str] = np.array([[1, 2, 3], [4, 5, 6], [7, 8, 9]] )
snake_case : List[str] = 2
snake_case : int = np.array([[6.9282_0323, 8.6602_5404, 10.3923_0485], [3.0, 3.0, 3.0]] )
with pytest.raises(__lowerCamelCase ) as error_info:
snake_case : Union[str, Any] = principal_component_analysis(__lowerCamelCase , __lowerCamelCase )
if not np.allclose(__lowerCamelCase , __lowerCamelCase ):
raise AssertionError
assert error_info.type is AssertionError
if __name__ == "__main__":
import doctest
doctest.testmod()
| 59
| 1
|
import gc
import unittest
from parameterized import parameterized
from diffusers import FlaxUNetaDConditionModel
from diffusers.utils import is_flax_available
from diffusers.utils.testing_utils import load_hf_numpy, require_flax, slow
if is_flax_available():
import jax
import jax.numpy as jnp
@slow
@require_flax
class UpperCAmelCase ( unittest.TestCase ):
def _SCREAMING_SNAKE_CASE (self : str , snake_case__ : Union[str, Any] , snake_case__ : List[str] ) -> List[str]:
'''simple docstring'''
return f"""gaussian_noise_s={seed}_shape={'_'.join([str(snake_case__ ) for s in shape] )}.npy"""
def _SCREAMING_SNAKE_CASE (self : Tuple ) -> int:
'''simple docstring'''
super().tearDown()
gc.collect()
def _SCREAMING_SNAKE_CASE (self : str , snake_case__ : Optional[Any]=0 , snake_case__ : Any=(4, 4, 64, 64) , snake_case__ : List[Any]=False ) -> int:
'''simple docstring'''
snake_case : Optional[Any] = jnp.bfloataa if fpaa else jnp.floataa
snake_case : Optional[int] = jnp.array(load_hf_numpy(self.get_file_format(snake_case__ , snake_case__ ) ) , dtype=snake_case__ )
return image
def _SCREAMING_SNAKE_CASE (self : Optional[int] , snake_case__ : Tuple=False , snake_case__ : List[Any]="CompVis/stable-diffusion-v1-4" ) -> List[Any]:
'''simple docstring'''
snake_case : List[str] = jnp.bfloataa if fpaa else jnp.floataa
snake_case : str = "bf16" if fpaa else None
snake_case , snake_case : Optional[int] = FlaxUNetaDConditionModel.from_pretrained(
snake_case__ , subfolder="unet" , dtype=snake_case__ , revision=snake_case__ )
return model, params
def _SCREAMING_SNAKE_CASE (self : List[str] , snake_case__ : Union[str, Any]=0 , snake_case__ : Union[str, Any]=(4, 77, 7_68) , snake_case__ : Dict=False ) -> List[str]:
'''simple docstring'''
snake_case : Any = jnp.bfloataa if fpaa else jnp.floataa
snake_case : Any = jnp.array(load_hf_numpy(self.get_file_format(snake_case__ , snake_case__ ) ) , dtype=snake_case__ )
return hidden_states
@parameterized.expand(
[
# fmt: off
[83, 4, [-0.2323, -0.1304, 0.0813, -0.3093, -0.0919, -0.1571, -0.1125, -0.5806]],
[17, 0.55, [-0.0831, -0.2443, 0.0901, -0.0919, 0.3396, 0.0103, -0.3743, 0.0701]],
[8, 0.89, [-0.4863, 0.0859, 0.0875, -0.1658, 0.9199, -0.0114, 0.4839, 0.4639]],
[3, 10_00, [-0.5649, 0.2402, -0.5518, 0.1248, 1.1328, -0.2443, -0.0325, -1.0078]],
# fmt: on
] )
def _SCREAMING_SNAKE_CASE (self : Optional[int] , snake_case__ : int , snake_case__ : Optional[int] , snake_case__ : Dict ) -> List[str]:
'''simple docstring'''
snake_case , snake_case : List[str] = self.get_unet_model(model_id="CompVis/stable-diffusion-v1-4" , fpaa=snake_case__ )
snake_case : Union[str, Any] = self.get_latents(snake_case__ , fpaa=snake_case__ )
snake_case : List[str] = self.get_encoder_hidden_states(snake_case__ , fpaa=snake_case__ )
snake_case : Dict = model.apply(
{"params": params} , snake_case__ , jnp.array(snake_case__ , dtype=jnp.intaa ) , encoder_hidden_states=snake_case__ , ).sample
assert sample.shape == latents.shape
snake_case : Optional[Any] = jnp.asarray(jax.device_get((sample[-1, -2:, -2:, :2].flatten()) ) , dtype=jnp.floataa )
snake_case : Optional[int] = jnp.array(snake_case__ , dtype=jnp.floataa )
# Found torch (float16) and flax (bfloat16) outputs to be within this tolerance, in the same hardware
assert jnp.allclose(snake_case__ , snake_case__ , atol=1e-2 )
@parameterized.expand(
[
# fmt: off
[83, 4, [0.1514, 0.0807, 0.1624, 0.1016, -0.1896, 0.0263, 0.0677, 0.2310]],
[17, 0.55, [0.1164, -0.0216, 0.0170, 0.1589, -0.3120, 0.1005, -0.0581, -0.1458]],
[8, 0.89, [-0.1758, -0.0169, 0.1004, -0.1411, 0.1312, 0.1103, -0.1996, 0.2139]],
[3, 10_00, [0.1214, 0.0352, -0.0731, -0.1562, -0.0994, -0.0906, -0.2340, -0.0539]],
# fmt: on
] )
def _SCREAMING_SNAKE_CASE (self : Optional[int] , snake_case__ : Optional[int] , snake_case__ : str , snake_case__ : Tuple ) -> str:
'''simple docstring'''
snake_case , snake_case : List[Any] = self.get_unet_model(model_id="stabilityai/stable-diffusion-2" , fpaa=snake_case__ )
snake_case : List[str] = self.get_latents(snake_case__ , shape=(4, 4, 96, 96) , fpaa=snake_case__ )
snake_case : Union[str, Any] = self.get_encoder_hidden_states(snake_case__ , shape=(4, 77, 10_24) , fpaa=snake_case__ )
snake_case : Optional[int] = model.apply(
{"params": params} , snake_case__ , jnp.array(snake_case__ , dtype=jnp.intaa ) , encoder_hidden_states=snake_case__ , ).sample
assert sample.shape == latents.shape
snake_case : int = jnp.asarray(jax.device_get((sample[-1, -2:, -2:, :2].flatten()) ) , dtype=jnp.floataa )
snake_case : Dict = jnp.array(snake_case__ , dtype=jnp.floataa )
# Found torch (float16) and flax (bfloat16) outputs to be within this tolerance, on the same hardware
assert jnp.allclose(snake_case__ , snake_case__ , atol=1e-2 )
| 59
|
import pytest
from datasets import inspect_metric, list_metrics, load_metric
@pytest.fixture
def UpperCamelCase ( __lowerCamelCase : Optional[int] ):
monkeypatch.setattr("datasets.utils.deprecation_utils._emitted_deprecation_warnings" , set() )
@pytest.fixture
def UpperCamelCase ( __lowerCamelCase : str ):
class UpperCAmelCase :
def __init__(self : Optional[int] , snake_case__ : str ) -> Any:
'''simple docstring'''
snake_case : List[str] = metric_id
class UpperCAmelCase :
A__ : List[str] = [MetricMock(A_ ) for metric_id in ["accuracy", "mse", "precision", "codeparrot/apps_metric"]]
def _SCREAMING_SNAKE_CASE (self : int ) -> List[str]:
'''simple docstring'''
return self._metrics
monkeypatch.setattr("datasets.inspect.huggingface_hub" , HfhMock() )
@pytest.mark.parametrize(
"func, args" , [(load_metric, ("metrics/mse",)), (list_metrics, ()), (inspect_metric, ("metrics/mse", "tmp_path"))] )
def UpperCamelCase ( __lowerCamelCase : Optional[int] , __lowerCamelCase : Any , __lowerCamelCase : Any , __lowerCamelCase : int , __lowerCamelCase : Any ):
if "tmp_path" in args:
snake_case : str = tuple(arg if arg != "tmp_path" else tmp_path for arg in args )
with pytest.warns(__lowerCamelCase , match="https://huggingface.co/docs/evaluate" ):
func(*__lowerCamelCase )
| 59
| 1
|
import argparse
import dataclasses
import json
import logging
import os
import shutil
from typing import List, Optional
import datasets
from accelerate import Accelerator
from datasets import load_dataset
from finetuning import finetune
from tqdm.auto import tqdm
import transformers
from transformers import AutoConfig, set_seed
from transformers.trainer_utils import IntervalStrategy
__lowerCamelCase = logging.getLogger(__name__)
__lowerCamelCase = """pytorch_model.bin"""
@dataclasses.dataclass
class UpperCAmelCase :
A__ : str = dataclasses.field(
metadata={"help": "Path to pretrained model or model identifier from huggingface.co/models."} )
A__ : Optional[str] = dataclasses.field(
default=A_ ,metadata={"help": "Where do you want to store the pretrained models downloaded from huggingface.co."} ,)
@dataclasses.dataclass
class UpperCAmelCase :
A__ : str = dataclasses.field(metadata={"help": "A csv or a json file containing the training data."} )
A__ : str = dataclasses.field(metadata={"help": "A csv or a json file containing the data to predict on."} )
A__ : Optional[str] = dataclasses.field(
default=A_ ,metadata={"help": "A csv or a json file containing the validation data."} )
A__ : Optional[str] = dataclasses.field(
default=A_ ,metadata={"help": "The name of the task to train on."} ,)
A__ : Optional[List[str]] = dataclasses.field(
default=A_ ,metadata={"help": "The list of labels for the task."} )
@dataclasses.dataclass
class UpperCAmelCase :
A__ : str = dataclasses.field(
metadata={"help": "The output directory where the model predictions and checkpoints will be written."} )
A__ : Optional[str] = dataclasses.field(
default="accuracy" ,metadata={"help": "The evaluation metric used for the task."} )
A__ : Optional[str] = dataclasses.field(
default="no" ,metadata={
"help": "The evaluation strategy to adopt during training. Possible values are: [\"no\", \"step\", \"epoch]"
} ,)
A__ : Optional[int] = dataclasses.field(
default=10 ,metadata={"help": "Number of evaluation calls with no improvement after which training will be stopped."} ,)
A__ : Optional[float] = dataclasses.field(
default=0.0 ,metadata={
"help": "How much the specified evaluation metric must improve to satisfy early stopping conditions."
} ,)
A__ : Optional[bool] = dataclasses.field(
default=A_ ,metadata={"help": "Whether to filter the pseudo-labeled data based on the confidence score."} ,)
A__ : Optional[bool] = dataclasses.field(
default=A_ ,metadata={"help": "Whether to filter the pseudo-labeled data based on the validation performance."} ,)
A__ : Optional[bool] = dataclasses.field(
default=A_ ,metadata={"help": "Whether to fine-tune on labeled data after pseudo training."} ,)
A__ : Optional[float] = dataclasses.field(
default=0.0 ,metadata={"help": "Confidence threshold for pseudo-labeled data filtering."} ,)
A__ : Optional[int] = dataclasses.field(
default=1_00 ,metadata={"help": "Number of evaluation calls with no improvement after which training will be stopped."} ,)
A__ : Optional[int] = dataclasses.field(
default=A_ ,metadata={"help": "Random seed for initialization."} ,)
def UpperCamelCase ( __lowerCamelCase : int , __lowerCamelCase : Tuple , __lowerCamelCase : Union[str, Any] , __lowerCamelCase : Tuple , __lowerCamelCase : Dict , __lowerCamelCase : Optional[int] ):
snake_case : Tuple = datasets.concatenate_datasets([infer_input, infer_output] , axis=1 )
if args.do_filter_by_confidence:
snake_case : Optional[int] = dataset.filter(lambda __lowerCamelCase : example["probability"] > args.confidence_threshold )
if args.do_filter_by_val_performance:
assert eval_result >= 0.0 and eval_result <= 1.0
snake_case : int = int(eval_result * len(__lowerCamelCase ) )
print(__lowerCamelCase )
snake_case : List[str] = dataset.sort("probability" , reverse=__lowerCamelCase )
snake_case : Tuple = dataset.select(range(__lowerCamelCase ) )
snake_case : List[Any] = dataset.remove_columns(["label", "probability"] )
snake_case : Any = dataset.rename_column("prediction" , "label" )
snake_case : str = dataset.map(lambda __lowerCamelCase : {"label": idalabel[example["label"]]} )
snake_case : List[str] = dataset.shuffle(seed=args.seed )
snake_case : int = os.path.join(__lowerCamelCase , f"""train_pseudo.{args.data_file_extension}""" )
if args.data_file_extension == "csv":
dataset.to_csv(__lowerCamelCase , index=__lowerCamelCase )
else:
dataset.to_json(__lowerCamelCase )
def UpperCamelCase ( __lowerCamelCase : Optional[int] , __lowerCamelCase : str , __lowerCamelCase : Optional[int] , __lowerCamelCase : Tuple , **__lowerCamelCase : List[Any] ):
snake_case : int = Accelerator()
# Make one log on every process with the configuration for debugging.
logging.basicConfig(
format="%(asctime)s - %(levelname)s - %(name)s - %(message)s" , datefmt="%m/%d/%Y %H:%M:%S" , level=logging.INFO , )
logger.info(accelerator.state )
# Setup logging, we only want one process per machine to log things on the
# screen. accelerator.is_local_main_process is only True for one process per
# machine.
logger.setLevel(logging.INFO if accelerator.is_local_main_process else logging.ERROR )
if accelerator.is_local_main_process:
datasets.utils.logging.set_verbosity_warning()
transformers.utils.logging.set_verbosity_info()
else:
datasets.utils.logging.set_verbosity_error()
transformers.utils.logging.set_verbosity_error()
snake_case : Dict = STModelArguments(model_name_or_path=__lowerCamelCase )
snake_case : Tuple = STDataArguments(train_file=__lowerCamelCase , infer_file=__lowerCamelCase )
snake_case : str = STTrainingArguments(output_dir=__lowerCamelCase )
snake_case : int = argparse.Namespace()
for arg_class in (model_args, data_args, training_args):
for key, value in vars(__lowerCamelCase ).items():
setattr(__lowerCamelCase , __lowerCamelCase , __lowerCamelCase )
for key, value in kwargs.items():
if hasattr(__lowerCamelCase , __lowerCamelCase ):
setattr(__lowerCamelCase , __lowerCamelCase , __lowerCamelCase )
# Sanity checks
snake_case : List[str] = {}
snake_case : Optional[int] = None
# You need to provide the training data and the data to predict on
assert args.train_file is not None
assert args.infer_file is not None
snake_case : str = args.train_file
snake_case : Tuple = args.infer_file
if args.evaluation_strategy != IntervalStrategy.NO.value:
assert args.eval_file is not None
snake_case : Tuple = args.eval_file
for key in data_files:
snake_case : List[Any] = data_files[key].split("." )[-1]
assert extension in ["csv", "json"], f"""`{key}_file` should be a csv or a json file."""
if args.data_file_extension is None:
snake_case : Union[str, Any] = extension
else:
assert extension == args.data_file_extension, f"""`{key}_file` should be a {args.data_file_extension} file`."""
assert (
args.eval_metric in datasets.list_metrics()
), f"""{args.eval_metric} not in the list of supported metrics {datasets.list_metrics()}."""
# If passed along, set the training seed now.
if args.seed is not None:
set_seed(args.seed )
logger.info("Creating the initial data directory for self-training..." )
snake_case : List[Any] = f"""{args.output_dir}/self-train_iter-{{}}""".format
snake_case : Optional[int] = data_dir_format(0 )
if accelerator.is_main_process:
if args.output_dir is not None:
os.makedirs(args.output_dir , exist_ok=__lowerCamelCase )
os.makedirs(__lowerCamelCase , exist_ok=__lowerCamelCase )
accelerator.wait_for_everyone()
snake_case : Dict = None
snake_case : Union[str, Any] = None
snake_case : Tuple = 0
snake_case : List[Any] = False
# Show the progress bar
snake_case : List[Any] = tqdm(range(args.max_selftrain_iterations ) , disable=not accelerator.is_local_main_process )
# Self-train
for iteration in range(0 , int(args.max_selftrain_iterations ) ):
snake_case : str = data_dir_format(__lowerCamelCase )
assert os.path.exists(__lowerCamelCase )
# Stage 1: initial fine-tuning for iteration = 0 or pseudo-training for
# iteration > 0
snake_case : Dict = os.path.join(__lowerCamelCase , "stage-1" )
snake_case : Optional[Any] = {
"accelerator": accelerator,
"model_name_or_path": args.model_name_or_path,
"cache_dir": args.cache_dir,
"do_train": True,
"train_file": data_files["train"] if iteration == 0 else data_files["train_pseudo"],
"do_eval": True if args.eval_file is not None else False,
"eval_file": data_files["eval"],
"do_predict": True,
"infer_file": data_files["infer"],
"task_name": args.task_name,
"label_list": args.label_list,
"output_dir": current_output_dir,
"eval_metric": args.eval_metric,
"evaluation_strategy": args.evaluation_strategy,
"early_stopping_patience": args.early_stopping_patience,
"early_stopping_threshold": args.early_stopping_threshold,
"seed": args.seed,
}
# Add additional training arguments
for key, value in kwargs.items():
if key not in arguments_dict and not hasattr(__lowerCamelCase , __lowerCamelCase ):
arguments_dict.update({key: value} )
snake_case : int = os.path.join(__lowerCamelCase , "best-checkpoint" , __lowerCamelCase )
if os.path.exists(__lowerCamelCase ):
logger.info(
"Found existing model checkpoint at %s. Skipping self-training: iteration: %d, stage: 1." , __lowerCamelCase , __lowerCamelCase , )
else:
logger.info("***** Running self-training: iteration: %d, stage: 1 *****" , __lowerCamelCase )
finetune(**__lowerCamelCase )
accelerator.wait_for_everyone()
assert os.path.exists(__lowerCamelCase )
logger.info("Self-training job completed: iteration: %d, stage: 1." , __lowerCamelCase )
if iteration > 0 and args.finetune_on_labeled_data:
# Stage 2 (optional): fine-tuning on the original labeled data
snake_case : str = os.path.join(__lowerCamelCase , "best-checkpoint" )
snake_case : Dict = os.path.join(__lowerCamelCase , "stage-2" )
# Update arguments_dict
snake_case : List[str] = model_path
snake_case : Optional[Any] = data_files["train"]
snake_case : Optional[Any] = current_output_dir
snake_case : Union[str, Any] = os.path.join(__lowerCamelCase , "best-checkpoint" , __lowerCamelCase )
if os.path.exists(__lowerCamelCase ):
logger.info(
"Found existing model checkpoint at %s. Skipping self-training: iteration: %d, stage: 2." , __lowerCamelCase , __lowerCamelCase , )
else:
logger.info("***** Running self-training: iteration: %d, stage: 2 *****" , __lowerCamelCase )
finetune(**__lowerCamelCase )
accelerator.wait_for_everyone()
assert os.path.exists(__lowerCamelCase )
logger.info("Self-training job completed: iteration: %d, stage: 2." , __lowerCamelCase )
snake_case : int = iteration
snake_case : Tuple = data_dir_format(iteration + 1 )
snake_case : Tuple = AutoConfig.from_pretrained(os.path.join(__lowerCamelCase , "best-checkpoint" ) )
snake_case : Optional[int] = config.idalabel
snake_case : List[Any] = os.path.join(__lowerCamelCase , "eval_results_best-checkpoint.json" )
snake_case : Union[str, Any] = os.path.join(__lowerCamelCase , "test_results_best-checkpoint.json" )
assert os.path.exists(__lowerCamelCase )
with open(__lowerCamelCase , "r" ) as f:
snake_case : Dict = float(json.load(__lowerCamelCase )[args.eval_metric] )
snake_case : Optional[int] = os.path.join(__lowerCamelCase , "infer_output_best-checkpoint.csv" )
assert os.path.exists(__lowerCamelCase )
# Loading the dataset from local csv or json files.
snake_case : Optional[Any] = load_dataset(args.data_file_extension , data_files={"data": data_files["infer"]} )["data"]
snake_case : Dict = load_dataset("csv" , data_files={"data": infer_output_file} )["data"]
if accelerator.is_main_process:
os.makedirs(__lowerCamelCase , exist_ok=__lowerCamelCase )
shutil.copy(__lowerCamelCase , os.path.join(__lowerCamelCase , f"""eval_results_iter-{iteration}.json""" ) )
if os.path.exists(__lowerCamelCase ):
shutil.copy(__lowerCamelCase , os.path.join(__lowerCamelCase , f"""test_results_iter-{iteration}.json""" ) )
create_pseudo_labeled_data(__lowerCamelCase , __lowerCamelCase , __lowerCamelCase , __lowerCamelCase , __lowerCamelCase , __lowerCamelCase )
accelerator.wait_for_everyone()
snake_case : str = os.path.join(__lowerCamelCase , f"""train_pseudo.{args.data_file_extension}""" )
if args.evaluation_strategy != IntervalStrategy.NO.value:
snake_case : List[Any] = eval_result
if best_iteration is None:
snake_case : List[Any] = new_iteration
snake_case : int = new_eval_result
else:
if new_eval_result - best_eval_result > args.early_stopping_threshold:
snake_case : int = new_iteration
snake_case : Union[str, Any] = new_eval_result
snake_case : str = 0
else:
if new_eval_result == best_eval_result:
snake_case : Any = new_iteration
snake_case : Union[str, Any] = new_eval_result
early_stopping_patience_counter += 1
if early_stopping_patience_counter >= args.early_stopping_patience:
snake_case : Tuple = True
progress_bar.update(1 )
if should_training_stop:
break
if best_iteration is not None:
# Save the best iteration
logger.info("Best iteration: %d" , __lowerCamelCase )
logger.info("Best evaluation result: %s = %f" , args.eval_metric , __lowerCamelCase )
accelerator.wait_for_everyone()
if accelerator.is_main_process:
shutil.copy(
os.path.join(__lowerCamelCase , f"""eval_results_iter-{iteration}.json""" ) , os.path.join(__lowerCamelCase , "eval_results_best-iteration.json" ) , )
else:
# Assume that the last iteration is the best
logger.info("Best iteration: %d" , args.max_selftrain_iterations - 1 )
logger.info("Best evaluation result: %s = %f" , args.eval_metric , __lowerCamelCase )
accelerator.wait_for_everyone()
if accelerator.is_main_process:
shutil.copy(
os.path.join(__lowerCamelCase , f"""eval_results_iter-{args.max_selftrain_iterations - 1}.json""" ) , os.path.join(__lowerCamelCase , "eval_results_best-iteration.json" ) , )
| 59
|
import argparse
import dataclasses
import json
import logging
import os
import shutil
from typing import List, Optional
import datasets
from accelerate import Accelerator
from datasets import load_dataset
from finetuning import finetune
from tqdm.auto import tqdm
import transformers
from transformers import AutoConfig, set_seed
from transformers.trainer_utils import IntervalStrategy
__lowerCamelCase = logging.getLogger(__name__)
__lowerCamelCase = """pytorch_model.bin"""
@dataclasses.dataclass
class UpperCAmelCase :
A__ : str = dataclasses.field(
metadata={"help": "Path to pretrained model or model identifier from huggingface.co/models."} )
A__ : Optional[str] = dataclasses.field(
default=A_ ,metadata={"help": "Where do you want to store the pretrained models downloaded from huggingface.co."} ,)
@dataclasses.dataclass
class UpperCAmelCase :
A__ : str = dataclasses.field(metadata={"help": "A csv or a json file containing the training data."} )
A__ : str = dataclasses.field(metadata={"help": "A csv or a json file containing the data to predict on."} )
A__ : Optional[str] = dataclasses.field(
default=A_ ,metadata={"help": "A csv or a json file containing the validation data."} )
A__ : Optional[str] = dataclasses.field(
default=A_ ,metadata={"help": "The name of the task to train on."} ,)
A__ : Optional[List[str]] = dataclasses.field(
default=A_ ,metadata={"help": "The list of labels for the task."} )
@dataclasses.dataclass
class UpperCAmelCase :
A__ : str = dataclasses.field(
metadata={"help": "The output directory where the model predictions and checkpoints will be written."} )
A__ : Optional[str] = dataclasses.field(
default="accuracy" ,metadata={"help": "The evaluation metric used for the task."} )
A__ : Optional[str] = dataclasses.field(
default="no" ,metadata={
"help": "The evaluation strategy to adopt during training. Possible values are: [\"no\", \"step\", \"epoch]"
} ,)
A__ : Optional[int] = dataclasses.field(
default=10 ,metadata={"help": "Number of evaluation calls with no improvement after which training will be stopped."} ,)
A__ : Optional[float] = dataclasses.field(
default=0.0 ,metadata={
"help": "How much the specified evaluation metric must improve to satisfy early stopping conditions."
} ,)
A__ : Optional[bool] = dataclasses.field(
default=A_ ,metadata={"help": "Whether to filter the pseudo-labeled data based on the confidence score."} ,)
A__ : Optional[bool] = dataclasses.field(
default=A_ ,metadata={"help": "Whether to filter the pseudo-labeled data based on the validation performance."} ,)
A__ : Optional[bool] = dataclasses.field(
default=A_ ,metadata={"help": "Whether to fine-tune on labeled data after pseudo training."} ,)
A__ : Optional[float] = dataclasses.field(
default=0.0 ,metadata={"help": "Confidence threshold for pseudo-labeled data filtering."} ,)
A__ : Optional[int] = dataclasses.field(
default=1_00 ,metadata={"help": "Number of evaluation calls with no improvement after which training will be stopped."} ,)
A__ : Optional[int] = dataclasses.field(
default=A_ ,metadata={"help": "Random seed for initialization."} ,)
def UpperCamelCase ( __lowerCamelCase : int , __lowerCamelCase : Tuple , __lowerCamelCase : Union[str, Any] , __lowerCamelCase : Tuple , __lowerCamelCase : Dict , __lowerCamelCase : Optional[int] ):
snake_case : Tuple = datasets.concatenate_datasets([infer_input, infer_output] , axis=1 )
if args.do_filter_by_confidence:
snake_case : Optional[int] = dataset.filter(lambda __lowerCamelCase : example["probability"] > args.confidence_threshold )
if args.do_filter_by_val_performance:
assert eval_result >= 0.0 and eval_result <= 1.0
snake_case : int = int(eval_result * len(__lowerCamelCase ) )
print(__lowerCamelCase )
snake_case : List[str] = dataset.sort("probability" , reverse=__lowerCamelCase )
snake_case : Tuple = dataset.select(range(__lowerCamelCase ) )
snake_case : List[Any] = dataset.remove_columns(["label", "probability"] )
snake_case : Any = dataset.rename_column("prediction" , "label" )
snake_case : str = dataset.map(lambda __lowerCamelCase : {"label": idalabel[example["label"]]} )
snake_case : List[str] = dataset.shuffle(seed=args.seed )
snake_case : int = os.path.join(__lowerCamelCase , f"""train_pseudo.{args.data_file_extension}""" )
if args.data_file_extension == "csv":
dataset.to_csv(__lowerCamelCase , index=__lowerCamelCase )
else:
dataset.to_json(__lowerCamelCase )
def UpperCamelCase ( __lowerCamelCase : Optional[int] , __lowerCamelCase : str , __lowerCamelCase : Optional[int] , __lowerCamelCase : Tuple , **__lowerCamelCase : List[Any] ):
snake_case : int = Accelerator()
# Make one log on every process with the configuration for debugging.
logging.basicConfig(
format="%(asctime)s - %(levelname)s - %(name)s - %(message)s" , datefmt="%m/%d/%Y %H:%M:%S" , level=logging.INFO , )
logger.info(accelerator.state )
# Setup logging, we only want one process per machine to log things on the
# screen. accelerator.is_local_main_process is only True for one process per
# machine.
logger.setLevel(logging.INFO if accelerator.is_local_main_process else logging.ERROR )
if accelerator.is_local_main_process:
datasets.utils.logging.set_verbosity_warning()
transformers.utils.logging.set_verbosity_info()
else:
datasets.utils.logging.set_verbosity_error()
transformers.utils.logging.set_verbosity_error()
snake_case : Dict = STModelArguments(model_name_or_path=__lowerCamelCase )
snake_case : Tuple = STDataArguments(train_file=__lowerCamelCase , infer_file=__lowerCamelCase )
snake_case : str = STTrainingArguments(output_dir=__lowerCamelCase )
snake_case : int = argparse.Namespace()
for arg_class in (model_args, data_args, training_args):
for key, value in vars(__lowerCamelCase ).items():
setattr(__lowerCamelCase , __lowerCamelCase , __lowerCamelCase )
for key, value in kwargs.items():
if hasattr(__lowerCamelCase , __lowerCamelCase ):
setattr(__lowerCamelCase , __lowerCamelCase , __lowerCamelCase )
# Sanity checks
snake_case : List[str] = {}
snake_case : Optional[int] = None
# You need to provide the training data and the data to predict on
assert args.train_file is not None
assert args.infer_file is not None
snake_case : str = args.train_file
snake_case : Tuple = args.infer_file
if args.evaluation_strategy != IntervalStrategy.NO.value:
assert args.eval_file is not None
snake_case : Tuple = args.eval_file
for key in data_files:
snake_case : List[Any] = data_files[key].split("." )[-1]
assert extension in ["csv", "json"], f"""`{key}_file` should be a csv or a json file."""
if args.data_file_extension is None:
snake_case : Union[str, Any] = extension
else:
assert extension == args.data_file_extension, f"""`{key}_file` should be a {args.data_file_extension} file`."""
assert (
args.eval_metric in datasets.list_metrics()
), f"""{args.eval_metric} not in the list of supported metrics {datasets.list_metrics()}."""
# If passed along, set the training seed now.
if args.seed is not None:
set_seed(args.seed )
logger.info("Creating the initial data directory for self-training..." )
snake_case : List[Any] = f"""{args.output_dir}/self-train_iter-{{}}""".format
snake_case : Optional[int] = data_dir_format(0 )
if accelerator.is_main_process:
if args.output_dir is not None:
os.makedirs(args.output_dir , exist_ok=__lowerCamelCase )
os.makedirs(__lowerCamelCase , exist_ok=__lowerCamelCase )
accelerator.wait_for_everyone()
snake_case : Dict = None
snake_case : Union[str, Any] = None
snake_case : Tuple = 0
snake_case : List[Any] = False
# Show the progress bar
snake_case : List[Any] = tqdm(range(args.max_selftrain_iterations ) , disable=not accelerator.is_local_main_process )
# Self-train
for iteration in range(0 , int(args.max_selftrain_iterations ) ):
snake_case : str = data_dir_format(__lowerCamelCase )
assert os.path.exists(__lowerCamelCase )
# Stage 1: initial fine-tuning for iteration = 0 or pseudo-training for
# iteration > 0
snake_case : Dict = os.path.join(__lowerCamelCase , "stage-1" )
snake_case : Optional[Any] = {
"accelerator": accelerator,
"model_name_or_path": args.model_name_or_path,
"cache_dir": args.cache_dir,
"do_train": True,
"train_file": data_files["train"] if iteration == 0 else data_files["train_pseudo"],
"do_eval": True if args.eval_file is not None else False,
"eval_file": data_files["eval"],
"do_predict": True,
"infer_file": data_files["infer"],
"task_name": args.task_name,
"label_list": args.label_list,
"output_dir": current_output_dir,
"eval_metric": args.eval_metric,
"evaluation_strategy": args.evaluation_strategy,
"early_stopping_patience": args.early_stopping_patience,
"early_stopping_threshold": args.early_stopping_threshold,
"seed": args.seed,
}
# Add additional training arguments
for key, value in kwargs.items():
if key not in arguments_dict and not hasattr(__lowerCamelCase , __lowerCamelCase ):
arguments_dict.update({key: value} )
snake_case : int = os.path.join(__lowerCamelCase , "best-checkpoint" , __lowerCamelCase )
if os.path.exists(__lowerCamelCase ):
logger.info(
"Found existing model checkpoint at %s. Skipping self-training: iteration: %d, stage: 1." , __lowerCamelCase , __lowerCamelCase , )
else:
logger.info("***** Running self-training: iteration: %d, stage: 1 *****" , __lowerCamelCase )
finetune(**__lowerCamelCase )
accelerator.wait_for_everyone()
assert os.path.exists(__lowerCamelCase )
logger.info("Self-training job completed: iteration: %d, stage: 1." , __lowerCamelCase )
if iteration > 0 and args.finetune_on_labeled_data:
# Stage 2 (optional): fine-tuning on the original labeled data
snake_case : str = os.path.join(__lowerCamelCase , "best-checkpoint" )
snake_case : Dict = os.path.join(__lowerCamelCase , "stage-2" )
# Update arguments_dict
snake_case : List[str] = model_path
snake_case : Optional[Any] = data_files["train"]
snake_case : Optional[Any] = current_output_dir
snake_case : Union[str, Any] = os.path.join(__lowerCamelCase , "best-checkpoint" , __lowerCamelCase )
if os.path.exists(__lowerCamelCase ):
logger.info(
"Found existing model checkpoint at %s. Skipping self-training: iteration: %d, stage: 2." , __lowerCamelCase , __lowerCamelCase , )
else:
logger.info("***** Running self-training: iteration: %d, stage: 2 *****" , __lowerCamelCase )
finetune(**__lowerCamelCase )
accelerator.wait_for_everyone()
assert os.path.exists(__lowerCamelCase )
logger.info("Self-training job completed: iteration: %d, stage: 2." , __lowerCamelCase )
snake_case : int = iteration
snake_case : Tuple = data_dir_format(iteration + 1 )
snake_case : Tuple = AutoConfig.from_pretrained(os.path.join(__lowerCamelCase , "best-checkpoint" ) )
snake_case : Optional[int] = config.idalabel
snake_case : List[Any] = os.path.join(__lowerCamelCase , "eval_results_best-checkpoint.json" )
snake_case : Union[str, Any] = os.path.join(__lowerCamelCase , "test_results_best-checkpoint.json" )
assert os.path.exists(__lowerCamelCase )
with open(__lowerCamelCase , "r" ) as f:
snake_case : Dict = float(json.load(__lowerCamelCase )[args.eval_metric] )
snake_case : Optional[int] = os.path.join(__lowerCamelCase , "infer_output_best-checkpoint.csv" )
assert os.path.exists(__lowerCamelCase )
# Loading the dataset from local csv or json files.
snake_case : Optional[Any] = load_dataset(args.data_file_extension , data_files={"data": data_files["infer"]} )["data"]
snake_case : Dict = load_dataset("csv" , data_files={"data": infer_output_file} )["data"]
if accelerator.is_main_process:
os.makedirs(__lowerCamelCase , exist_ok=__lowerCamelCase )
shutil.copy(__lowerCamelCase , os.path.join(__lowerCamelCase , f"""eval_results_iter-{iteration}.json""" ) )
if os.path.exists(__lowerCamelCase ):
shutil.copy(__lowerCamelCase , os.path.join(__lowerCamelCase , f"""test_results_iter-{iteration}.json""" ) )
create_pseudo_labeled_data(__lowerCamelCase , __lowerCamelCase , __lowerCamelCase , __lowerCamelCase , __lowerCamelCase , __lowerCamelCase )
accelerator.wait_for_everyone()
snake_case : str = os.path.join(__lowerCamelCase , f"""train_pseudo.{args.data_file_extension}""" )
if args.evaluation_strategy != IntervalStrategy.NO.value:
snake_case : List[Any] = eval_result
if best_iteration is None:
snake_case : List[Any] = new_iteration
snake_case : int = new_eval_result
else:
if new_eval_result - best_eval_result > args.early_stopping_threshold:
snake_case : int = new_iteration
snake_case : Union[str, Any] = new_eval_result
snake_case : str = 0
else:
if new_eval_result == best_eval_result:
snake_case : Any = new_iteration
snake_case : Union[str, Any] = new_eval_result
early_stopping_patience_counter += 1
if early_stopping_patience_counter >= args.early_stopping_patience:
snake_case : Tuple = True
progress_bar.update(1 )
if should_training_stop:
break
if best_iteration is not None:
# Save the best iteration
logger.info("Best iteration: %d" , __lowerCamelCase )
logger.info("Best evaluation result: %s = %f" , args.eval_metric , __lowerCamelCase )
accelerator.wait_for_everyone()
if accelerator.is_main_process:
shutil.copy(
os.path.join(__lowerCamelCase , f"""eval_results_iter-{iteration}.json""" ) , os.path.join(__lowerCamelCase , "eval_results_best-iteration.json" ) , )
else:
# Assume that the last iteration is the best
logger.info("Best iteration: %d" , args.max_selftrain_iterations - 1 )
logger.info("Best evaluation result: %s = %f" , args.eval_metric , __lowerCamelCase )
accelerator.wait_for_everyone()
if accelerator.is_main_process:
shutil.copy(
os.path.join(__lowerCamelCase , f"""eval_results_iter-{args.max_selftrain_iterations - 1}.json""" ) , os.path.join(__lowerCamelCase , "eval_results_best-iteration.json" ) , )
| 59
| 1
|
import os
import unittest
from huggingface_hub.utils import are_progress_bars_disabled
import transformers.models.bart.tokenization_bart
from transformers import logging
from transformers.testing_utils import CaptureLogger, mockenv, mockenv_context
from transformers.utils.logging import disable_progress_bar, enable_progress_bar
class UpperCAmelCase ( unittest.TestCase ):
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> Tuple:
'''simple docstring'''
snake_case : Tuple = logging.get_logger()
# the current default level is logging.WARNING
snake_case : Optional[int] = logging.get_verbosity()
logging.set_verbosity_error()
self.assertEqual(logger.getEffectiveLevel() , logging.get_verbosity() )
logging.set_verbosity_warning()
self.assertEqual(logger.getEffectiveLevel() , logging.get_verbosity() )
logging.set_verbosity_info()
self.assertEqual(logger.getEffectiveLevel() , logging.get_verbosity() )
logging.set_verbosity_debug()
self.assertEqual(logger.getEffectiveLevel() , logging.get_verbosity() )
# restore to the original level
logging.set_verbosity(snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Tuple ) -> Optional[Any]:
'''simple docstring'''
snake_case : List[Any] = logging.get_verbosity()
snake_case : Union[str, Any] = logging.get_logger("transformers.models.bart.tokenization_bart" )
snake_case : List[Any] = "Testing 1, 2, 3"
# should be able to log warnings (if default settings weren't overridden by `pytest --log-level-all`)
if level_origin <= logging.WARNING:
with CaptureLogger(snake_case__ ) as cl:
logger.warning(snake_case__ )
self.assertEqual(cl.out , msg + "\n" )
# this is setting the level for all of `transformers.*` loggers
logging.set_verbosity_error()
# should not be able to log warnings
with CaptureLogger(snake_case__ ) as cl:
logger.warning(snake_case__ )
self.assertEqual(cl.out , "" )
# should be able to log warnings again
logging.set_verbosity_warning()
with CaptureLogger(snake_case__ ) as cl:
logger.warning(snake_case__ )
self.assertEqual(cl.out , msg + "\n" )
# restore to the original level
logging.set_verbosity(snake_case__ )
@mockenv(TRANSFORMERS_VERBOSITY="error" )
def _SCREAMING_SNAKE_CASE (self : Dict ) -> Dict:
'''simple docstring'''
transformers.utils.logging._reset_library_root_logger()
# this action activates the env var
snake_case : List[Any] = logging.get_logger("transformers.models.bart.tokenization_bart" )
snake_case : Dict = os.getenv("TRANSFORMERS_VERBOSITY" , snake_case__ )
snake_case : Any = logging.log_levels[env_level_str]
snake_case : List[str] = logging.get_verbosity()
self.assertEqual(
snake_case__ , snake_case__ , f"""TRANSFORMERS_VERBOSITY={env_level_str}/{env_level}, but internal verbosity is {current_level}""" , )
# restore to the original level
snake_case : Union[str, Any] = ""
transformers.utils.logging._reset_library_root_logger()
@mockenv(TRANSFORMERS_VERBOSITY="super-error" )
def _SCREAMING_SNAKE_CASE (self : Dict ) -> Tuple:
'''simple docstring'''
transformers.utils.logging._reset_library_root_logger()
snake_case : Union[str, Any] = logging.logging.getLogger()
with CaptureLogger(snake_case__ ) as cl:
# this action activates the env var
logging.get_logger("transformers.models.bart.tokenization_bart" )
self.assertIn("Unknown option TRANSFORMERS_VERBOSITY=super-error" , cl.out )
# no need to restore as nothing was changed
def _SCREAMING_SNAKE_CASE (self : Union[str, Any] ) -> Optional[int]:
'''simple docstring'''
transformers.utils.logging._reset_library_root_logger()
snake_case : Union[str, Any] = logging.get_logger("transformers.models.bart.tokenization_bart" )
snake_case : str = "Testing 1, 2, 3"
with mockenv_context(TRANSFORMERS_NO_ADVISORY_WARNINGS="1" ):
# nothing should be logged as env var disables this method
with CaptureLogger(snake_case__ ) as cl:
logger.warning_advice(snake_case__ )
self.assertEqual(cl.out , "" )
with mockenv_context(TRANSFORMERS_NO_ADVISORY_WARNINGS="" ):
# should log normally as TRANSFORMERS_NO_ADVISORY_WARNINGS is unset
with CaptureLogger(snake_case__ ) as cl:
logger.warning_advice(snake_case__ )
self.assertEqual(cl.out , msg + "\n" )
def UpperCamelCase ( ):
disable_progress_bar()
assert are_progress_bars_disabled()
enable_progress_bar()
assert not are_progress_bars_disabled()
| 59
|
from typing import TYPE_CHECKING
from ...utils import (
OptionalDependencyNotAvailable,
_LazyModule,
is_flax_available,
is_sentencepiece_available,
is_tf_available,
is_tokenizers_available,
is_torch_available,
)
__lowerCamelCase = {"""configuration_xglm""": ["""XGLM_PRETRAINED_CONFIG_ARCHIVE_MAP""", """XGLMConfig"""]}
try:
if not is_sentencepiece_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = ["""XGLMTokenizer"""]
try:
if not is_tokenizers_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = ["""XGLMTokenizerFast"""]
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = [
"""XGLM_PRETRAINED_MODEL_ARCHIVE_LIST""",
"""XGLMForCausalLM""",
"""XGLMModel""",
"""XGLMPreTrainedModel""",
]
try:
if not is_flax_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = [
"""FlaxXGLMForCausalLM""",
"""FlaxXGLMModel""",
"""FlaxXGLMPreTrainedModel""",
]
try:
if not is_tf_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = [
"""TF_XGLM_PRETRAINED_MODEL_ARCHIVE_LIST""",
"""TFXGLMForCausalLM""",
"""TFXGLMModel""",
"""TFXGLMPreTrainedModel""",
]
if TYPE_CHECKING:
from .configuration_xglm import XGLM_PRETRAINED_CONFIG_ARCHIVE_MAP, XGLMConfig
try:
if not is_sentencepiece_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .tokenization_xglm import XGLMTokenizer
try:
if not is_tokenizers_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .tokenization_xglm_fast import XGLMTokenizerFast
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_xglm import XGLM_PRETRAINED_MODEL_ARCHIVE_LIST, XGLMForCausalLM, XGLMModel, XGLMPreTrainedModel
try:
if not is_flax_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_flax_xglm import FlaxXGLMForCausalLM, FlaxXGLMModel, FlaxXGLMPreTrainedModel
try:
if not is_tf_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_tf_xglm import (
TF_XGLM_PRETRAINED_MODEL_ARCHIVE_LIST,
TFXGLMForCausalLM,
TFXGLMModel,
TFXGLMPreTrainedModel,
)
else:
import sys
__lowerCamelCase = _LazyModule(__name__, globals()["""__file__"""], _import_structure)
| 59
| 1
|
def UpperCamelCase ( __lowerCamelCase : int = 50 ):
snake_case : str = [1] * (length + 1)
for row_length in range(length + 1 ):
for tile_length in range(2 , 5 ):
for tile_start in range(row_length - tile_length + 1 ):
ways_number[row_length] += ways_number[
row_length - tile_start - tile_length
]
return ways_number[length]
if __name__ == "__main__":
print(F'{solution() = }')
| 59
|
from ...configuration_utils import PretrainedConfig
from ...utils import logging
__lowerCamelCase = logging.get_logger(__name__)
__lowerCamelCase = {
# See all MEGATRON_BERT models at https://huggingface.co/models?filter=bert
}
class UpperCAmelCase ( A_ ):
A__ : List[str] = "megatron-bert"
def __init__(self : Optional[int] , snake_case__ : List[str]=2_90_56 , snake_case__ : List[Any]=10_24 , snake_case__ : str=24 , snake_case__ : Tuple=16 , snake_case__ : Union[str, Any]=40_96 , snake_case__ : str="gelu" , snake_case__ : str=0.1 , snake_case__ : Optional[int]=0.1 , snake_case__ : Tuple=5_12 , snake_case__ : Union[str, Any]=2 , snake_case__ : Dict=0.02 , snake_case__ : List[Any]=1e-12 , snake_case__ : int=0 , snake_case__ : Tuple="absolute" , snake_case__ : Any=True , **snake_case__ : Union[str, Any] , ) -> Optional[Any]:
'''simple docstring'''
super().__init__(pad_token_id=snake_case__ , **snake_case__ )
snake_case : Tuple = vocab_size
snake_case : str = hidden_size
snake_case : str = num_hidden_layers
snake_case : str = num_attention_heads
snake_case : Optional[int] = hidden_act
snake_case : int = intermediate_size
snake_case : List[str] = hidden_dropout_prob
snake_case : Union[str, Any] = attention_probs_dropout_prob
snake_case : Dict = max_position_embeddings
snake_case : List[str] = type_vocab_size
snake_case : List[str] = initializer_range
snake_case : Tuple = layer_norm_eps
snake_case : int = position_embedding_type
snake_case : str = use_cache
| 59
| 1
|
from typing import TYPE_CHECKING
from ...utils import OptionalDependencyNotAvailable, _LazyModule, is_tokenizers_available, is_torch_available
__lowerCamelCase = {
"""configuration_m2m_100""": ["""M2M_100_PRETRAINED_CONFIG_ARCHIVE_MAP""", """M2M100Config""", """M2M100OnnxConfig"""],
"""tokenization_m2m_100""": ["""M2M100Tokenizer"""],
}
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = [
"""M2M_100_PRETRAINED_MODEL_ARCHIVE_LIST""",
"""M2M100ForConditionalGeneration""",
"""M2M100Model""",
"""M2M100PreTrainedModel""",
]
if TYPE_CHECKING:
from .configuration_mam_aaa import M2M_100_PRETRAINED_CONFIG_ARCHIVE_MAP, MaMaaaConfig, MaMaaaOnnxConfig
from .tokenization_mam_aaa import MaMaaaTokenizer
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_mam_aaa import (
M2M_100_PRETRAINED_MODEL_ARCHIVE_LIST,
MaMaaaForConditionalGeneration,
MaMaaaModel,
MaMaaaPreTrainedModel,
)
else:
import sys
__lowerCamelCase = _LazyModule(__name__, globals()["""__file__"""], _import_structure, module_spec=__spec__)
| 59
|
import gc
import unittest
from parameterized import parameterized
from diffusers import FlaxUNetaDConditionModel
from diffusers.utils import is_flax_available
from diffusers.utils.testing_utils import load_hf_numpy, require_flax, slow
if is_flax_available():
import jax
import jax.numpy as jnp
@slow
@require_flax
class UpperCAmelCase ( unittest.TestCase ):
def _SCREAMING_SNAKE_CASE (self : str , snake_case__ : Union[str, Any] , snake_case__ : List[str] ) -> List[str]:
'''simple docstring'''
return f"""gaussian_noise_s={seed}_shape={'_'.join([str(snake_case__ ) for s in shape] )}.npy"""
def _SCREAMING_SNAKE_CASE (self : Tuple ) -> int:
'''simple docstring'''
super().tearDown()
gc.collect()
def _SCREAMING_SNAKE_CASE (self : str , snake_case__ : Optional[Any]=0 , snake_case__ : Any=(4, 4, 64, 64) , snake_case__ : List[Any]=False ) -> int:
'''simple docstring'''
snake_case : Optional[Any] = jnp.bfloataa if fpaa else jnp.floataa
snake_case : Optional[int] = jnp.array(load_hf_numpy(self.get_file_format(snake_case__ , snake_case__ ) ) , dtype=snake_case__ )
return image
def _SCREAMING_SNAKE_CASE (self : Optional[int] , snake_case__ : Tuple=False , snake_case__ : List[Any]="CompVis/stable-diffusion-v1-4" ) -> List[Any]:
'''simple docstring'''
snake_case : List[str] = jnp.bfloataa if fpaa else jnp.floataa
snake_case : str = "bf16" if fpaa else None
snake_case , snake_case : Optional[int] = FlaxUNetaDConditionModel.from_pretrained(
snake_case__ , subfolder="unet" , dtype=snake_case__ , revision=snake_case__ )
return model, params
def _SCREAMING_SNAKE_CASE (self : List[str] , snake_case__ : Union[str, Any]=0 , snake_case__ : Union[str, Any]=(4, 77, 7_68) , snake_case__ : Dict=False ) -> List[str]:
'''simple docstring'''
snake_case : Any = jnp.bfloataa if fpaa else jnp.floataa
snake_case : Any = jnp.array(load_hf_numpy(self.get_file_format(snake_case__ , snake_case__ ) ) , dtype=snake_case__ )
return hidden_states
@parameterized.expand(
[
# fmt: off
[83, 4, [-0.2323, -0.1304, 0.0813, -0.3093, -0.0919, -0.1571, -0.1125, -0.5806]],
[17, 0.55, [-0.0831, -0.2443, 0.0901, -0.0919, 0.3396, 0.0103, -0.3743, 0.0701]],
[8, 0.89, [-0.4863, 0.0859, 0.0875, -0.1658, 0.9199, -0.0114, 0.4839, 0.4639]],
[3, 10_00, [-0.5649, 0.2402, -0.5518, 0.1248, 1.1328, -0.2443, -0.0325, -1.0078]],
# fmt: on
] )
def _SCREAMING_SNAKE_CASE (self : Optional[int] , snake_case__ : int , snake_case__ : Optional[int] , snake_case__ : Dict ) -> List[str]:
'''simple docstring'''
snake_case , snake_case : List[str] = self.get_unet_model(model_id="CompVis/stable-diffusion-v1-4" , fpaa=snake_case__ )
snake_case : Union[str, Any] = self.get_latents(snake_case__ , fpaa=snake_case__ )
snake_case : List[str] = self.get_encoder_hidden_states(snake_case__ , fpaa=snake_case__ )
snake_case : Dict = model.apply(
{"params": params} , snake_case__ , jnp.array(snake_case__ , dtype=jnp.intaa ) , encoder_hidden_states=snake_case__ , ).sample
assert sample.shape == latents.shape
snake_case : Optional[Any] = jnp.asarray(jax.device_get((sample[-1, -2:, -2:, :2].flatten()) ) , dtype=jnp.floataa )
snake_case : Optional[int] = jnp.array(snake_case__ , dtype=jnp.floataa )
# Found torch (float16) and flax (bfloat16) outputs to be within this tolerance, in the same hardware
assert jnp.allclose(snake_case__ , snake_case__ , atol=1e-2 )
@parameterized.expand(
[
# fmt: off
[83, 4, [0.1514, 0.0807, 0.1624, 0.1016, -0.1896, 0.0263, 0.0677, 0.2310]],
[17, 0.55, [0.1164, -0.0216, 0.0170, 0.1589, -0.3120, 0.1005, -0.0581, -0.1458]],
[8, 0.89, [-0.1758, -0.0169, 0.1004, -0.1411, 0.1312, 0.1103, -0.1996, 0.2139]],
[3, 10_00, [0.1214, 0.0352, -0.0731, -0.1562, -0.0994, -0.0906, -0.2340, -0.0539]],
# fmt: on
] )
def _SCREAMING_SNAKE_CASE (self : Optional[int] , snake_case__ : Optional[int] , snake_case__ : str , snake_case__ : Tuple ) -> str:
'''simple docstring'''
snake_case , snake_case : List[Any] = self.get_unet_model(model_id="stabilityai/stable-diffusion-2" , fpaa=snake_case__ )
snake_case : List[str] = self.get_latents(snake_case__ , shape=(4, 4, 96, 96) , fpaa=snake_case__ )
snake_case : Union[str, Any] = self.get_encoder_hidden_states(snake_case__ , shape=(4, 77, 10_24) , fpaa=snake_case__ )
snake_case : Optional[int] = model.apply(
{"params": params} , snake_case__ , jnp.array(snake_case__ , dtype=jnp.intaa ) , encoder_hidden_states=snake_case__ , ).sample
assert sample.shape == latents.shape
snake_case : int = jnp.asarray(jax.device_get((sample[-1, -2:, -2:, :2].flatten()) ) , dtype=jnp.floataa )
snake_case : Dict = jnp.array(snake_case__ , dtype=jnp.floataa )
# Found torch (float16) and flax (bfloat16) outputs to be within this tolerance, on the same hardware
assert jnp.allclose(snake_case__ , snake_case__ , atol=1e-2 )
| 59
| 1
|
from pathlib import Path
import fire
from tqdm import tqdm
def UpperCamelCase ( __lowerCamelCase : str="ro" , __lowerCamelCase : int="en" , __lowerCamelCase : Optional[Any]="wmt16" , __lowerCamelCase : List[Any]=None ):
try:
import datasets
except (ModuleNotFoundError, ImportError):
raise ImportError("run pip install datasets" )
snake_case : str = f"""{src_lang}-{tgt_lang}"""
print(f"""Converting {dataset}-{pair}""" )
snake_case : str = datasets.load_dataset(__lowerCamelCase , __lowerCamelCase )
if save_dir is None:
snake_case : List[str] = f"""{dataset}-{pair}"""
snake_case : Any = Path(__lowerCamelCase )
save_dir.mkdir(exist_ok=__lowerCamelCase )
for split in ds.keys():
print(f"""Splitting {split} with {ds[split].num_rows} records""" )
# to save to val.source, val.target like summary datasets
snake_case : int = "val" if split == "validation" else split
snake_case : Optional[Any] = save_dir.joinpath(f"""{fn}.source""" )
snake_case : Union[str, Any] = save_dir.joinpath(f"""{fn}.target""" )
snake_case : List[Any] = src_path.open("w+" )
snake_case : List[str] = tgt_path.open("w+" )
# reader is the bottleneck so writing one record at a time doesn't slow things down
for x in tqdm(ds[split] ):
snake_case : Tuple = x["translation"]
src_fp.write(ex[src_lang] + "\n" )
tgt_fp.write(ex[tgt_lang] + "\n" )
print(f"""Saved {dataset} dataset to {save_dir}""" )
if __name__ == "__main__":
fire.Fire(download_wmt_dataset)
| 59
|
import argparse
import re
from typing import Dict
import torch
from datasets import Audio, Dataset, load_dataset, load_metric
from transformers import AutoFeatureExtractor, pipeline
def UpperCamelCase ( __lowerCamelCase : Dataset , __lowerCamelCase : Dict[str, str] ):
snake_case : int = args.log_outputs
snake_case : Dict = "_".join(args.dataset.split("/" ) + [args.config, args.split] )
# load metric
snake_case : List[str] = load_metric("wer" )
snake_case : Tuple = load_metric("cer" )
# compute metrics
snake_case : List[Any] = wer.compute(references=result["target"] , predictions=result["prediction"] )
snake_case : int = cer.compute(references=result["target"] , predictions=result["prediction"] )
# print & log results
snake_case : int = f"""WER: {wer_result}\nCER: {cer_result}"""
print(__lowerCamelCase )
with open(f"""{dataset_id}_eval_results.txt""" , "w" ) as f:
f.write(__lowerCamelCase )
# log all results in text file. Possibly interesting for analysis
if log_outputs is not None:
snake_case : int = f"""log_{dataset_id}_predictions.txt"""
snake_case : List[Any] = f"""log_{dataset_id}_targets.txt"""
with open(__lowerCamelCase , "w" ) as p, open(__lowerCamelCase , "w" ) as t:
# mapping function to write output
def write_to_file(__lowerCamelCase : str , __lowerCamelCase : Optional[int] ):
p.write(f"""{i}""" + "\n" )
p.write(batch["prediction"] + "\n" )
t.write(f"""{i}""" + "\n" )
t.write(batch["target"] + "\n" )
result.map(__lowerCamelCase , with_indices=__lowerCamelCase )
def UpperCamelCase ( __lowerCamelCase : str ):
snake_case : List[Any] = "[,?.!\-\;\:\"“%‘”�—’…–]" # noqa: W605 IMPORTANT: this should correspond to the chars that were ignored during training
snake_case : List[Any] = re.sub(__lowerCamelCase , "" , text.lower() )
# In addition, we can normalize the target text, e.g. removing new lines characters etc...
# note that order is important here!
snake_case : Optional[Any] = ["\n\n", "\n", " ", " "]
for t in token_sequences_to_ignore:
snake_case : Dict = " ".join(text.split(__lowerCamelCase ) )
return text
def UpperCamelCase ( __lowerCamelCase : int ):
# load dataset
snake_case : str = load_dataset(args.dataset , args.config , split=args.split , use_auth_token=__lowerCamelCase )
# for testing: only process the first two examples as a test
# dataset = dataset.select(range(10))
# load processor
snake_case : List[Any] = AutoFeatureExtractor.from_pretrained(args.model_id )
snake_case : Union[str, Any] = feature_extractor.sampling_rate
# resample audio
snake_case : Union[str, Any] = dataset.cast_column("audio" , Audio(sampling_rate=__lowerCamelCase ) )
# load eval pipeline
if args.device is None:
snake_case : List[str] = 0 if torch.cuda.is_available() else -1
snake_case : str = pipeline("automatic-speech-recognition" , model=args.model_id , device=args.device )
# map function to decode audio
def map_to_pred(__lowerCamelCase : int ):
snake_case : Dict = asr(
batch["audio"]["array"] , chunk_length_s=args.chunk_length_s , stride_length_s=args.stride_length_s )
snake_case : str = prediction["text"]
snake_case : Tuple = normalize_text(batch["sentence"] )
return batch
# run inference on all examples
snake_case : Dict = dataset.map(__lowerCamelCase , remove_columns=dataset.column_names )
# compute and log_results
# do not change function below
log_results(__lowerCamelCase , __lowerCamelCase )
if __name__ == "__main__":
__lowerCamelCase = argparse.ArgumentParser()
parser.add_argument(
"""--model_id""", type=str, required=True, help="""Model identifier. Should be loadable with 🤗 Transformers"""
)
parser.add_argument(
"""--dataset""",
type=str,
required=True,
help="""Dataset name to evaluate the `model_id`. Should be loadable with 🤗 Datasets""",
)
parser.add_argument(
"""--config""", type=str, required=True, help="""Config of the dataset. *E.g.* `'en'` for Common Voice"""
)
parser.add_argument("""--split""", type=str, required=True, help="""Split of the dataset. *E.g.* `'test'`""")
parser.add_argument(
"""--chunk_length_s""", type=float, default=None, help="""Chunk length in seconds. Defaults to 5 seconds."""
)
parser.add_argument(
"""--stride_length_s""", type=float, default=None, help="""Stride of the audio chunks. Defaults to 1 second."""
)
parser.add_argument(
"""--log_outputs""", action="""store_true""", help="""If defined, write outputs to log file for analysis."""
)
parser.add_argument(
"""--device""",
type=int,
default=None,
help="""The device to run the pipeline on. -1 for CPU (default), 0 for the first GPU and so on.""",
)
__lowerCamelCase = parser.parse_args()
main(args)
| 59
| 1
|
from ...utils import (
OptionalDependencyNotAvailable,
is_torch_available,
is_transformers_available,
is_transformers_version,
)
try:
if not (is_transformers_available() and is_torch_available() and is_transformers_version(""">=""", """4.25.0""")):
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
from ...utils.dummy_torch_and_transformers_objects import UnCLIPImageVariationPipeline, UnCLIPPipeline
else:
from .pipeline_unclip import UnCLIPPipeline
from .pipeline_unclip_image_variation import UnCLIPImageVariationPipeline
from .text_proj import UnCLIPTextProjModel
| 59
|
from typing import Optional, Tuple, Union
import flax
import flax.linen as nn
import jax
import jax.numpy as jnp
from flax.core.frozen_dict import FrozenDict
from ..configuration_utils import ConfigMixin, flax_register_to_config
from ..utils import BaseOutput
from .embeddings_flax import FlaxTimestepEmbedding, FlaxTimesteps
from .modeling_flax_utils import FlaxModelMixin
from .unet_ad_blocks_flax import (
FlaxCrossAttnDownBlockaD,
FlaxCrossAttnUpBlockaD,
FlaxDownBlockaD,
FlaxUNetMidBlockaDCrossAttn,
FlaxUpBlockaD,
)
@flax.struct.dataclass
class UpperCAmelCase ( A_ ):
A__ : jnp.ndarray
@flax_register_to_config
class UpperCAmelCase ( nn.Module ,A_ ,A_ ):
A__ : int = 32
A__ : int = 4
A__ : int = 4
A__ : Tuple[str] = (
"CrossAttnDownBlock2D",
"CrossAttnDownBlock2D",
"CrossAttnDownBlock2D",
"DownBlock2D",
)
A__ : Tuple[str] = ("UpBlock2D", "CrossAttnUpBlock2D", "CrossAttnUpBlock2D", "CrossAttnUpBlock2D")
A__ : Union[bool, Tuple[bool]] = False
A__ : Tuple[int] = (3_20, 6_40, 12_80, 12_80)
A__ : int = 2
A__ : Union[int, Tuple[int]] = 8
A__ : Optional[Union[int, Tuple[int]]] = None
A__ : int = 12_80
A__ : float = 0.0
A__ : bool = False
A__ : jnp.dtype = jnp.floataa
A__ : bool = True
A__ : int = 0
A__ : bool = False
def _SCREAMING_SNAKE_CASE (self : Optional[int] , snake_case__ : jax.random.KeyArray ) -> FrozenDict:
'''simple docstring'''
snake_case : Dict = (1, self.in_channels, self.sample_size, self.sample_size)
snake_case : Any = jnp.zeros(snake_case__ , dtype=jnp.floataa )
snake_case : List[str] = jnp.ones((1,) , dtype=jnp.intaa )
snake_case : str = jnp.zeros((1, 1, self.cross_attention_dim) , dtype=jnp.floataa )
snake_case , snake_case : Optional[int] = jax.random.split(snake_case__ )
snake_case : Union[str, Any] = {"params": params_rng, "dropout": dropout_rng}
return self.init(snake_case__ , snake_case__ , snake_case__ , snake_case__ )["params"]
def _SCREAMING_SNAKE_CASE (self : str ) -> Tuple:
'''simple docstring'''
snake_case : str = self.block_out_channels
snake_case : Optional[Any] = block_out_channels[0] * 4
if self.num_attention_heads is not None:
raise ValueError(
"At the moment it is not possible to define the number of attention heads via `num_attention_heads` because of a naming issue as described in https://github.com/huggingface/diffusers/issues/2011#issuecomment-1547958131. Passing `num_attention_heads` will only be supported in diffusers v0.19." )
# If `num_attention_heads` is not defined (which is the case for most models)
# it will default to `attention_head_dim`. This looks weird upon first reading it and it is.
# The reason for this behavior is to correct for incorrectly named variables that were introduced
# when this library was created. The incorrect naming was only discovered much later in https://github.com/huggingface/diffusers/issues/2011#issuecomment-1547958131
# Changing `attention_head_dim` to `num_attention_heads` for 40,000+ configurations is too backwards breaking
# which is why we correct for the naming here.
snake_case : Tuple = self.num_attention_heads or self.attention_head_dim
# input
snake_case : Tuple = nn.Conv(
block_out_channels[0] , kernel_size=(3, 3) , strides=(1, 1) , padding=((1, 1), (1, 1)) , dtype=self.dtype , )
# time
snake_case : Union[str, Any] = FlaxTimesteps(
block_out_channels[0] , flip_sin_to_cos=self.flip_sin_to_cos , freq_shift=self.config.freq_shift )
snake_case : Dict = FlaxTimestepEmbedding(snake_case__ , dtype=self.dtype )
snake_case : List[str] = self.only_cross_attention
if isinstance(snake_case__ , snake_case__ ):
snake_case : List[Any] = (only_cross_attention,) * len(self.down_block_types )
if isinstance(snake_case__ , snake_case__ ):
snake_case : List[Any] = (num_attention_heads,) * len(self.down_block_types )
# down
snake_case : List[Any] = []
snake_case : Optional[int] = block_out_channels[0]
for i, down_block_type in enumerate(self.down_block_types ):
snake_case : List[Any] = output_channel
snake_case : Dict = block_out_channels[i]
snake_case : Optional[Any] = i == len(snake_case__ ) - 1
if down_block_type == "CrossAttnDownBlock2D":
snake_case : List[Any] = FlaxCrossAttnDownBlockaD(
in_channels=snake_case__ , out_channels=snake_case__ , dropout=self.dropout , num_layers=self.layers_per_block , num_attention_heads=num_attention_heads[i] , add_downsample=not is_final_block , use_linear_projection=self.use_linear_projection , only_cross_attention=only_cross_attention[i] , use_memory_efficient_attention=self.use_memory_efficient_attention , dtype=self.dtype , )
else:
snake_case : Union[str, Any] = FlaxDownBlockaD(
in_channels=snake_case__ , out_channels=snake_case__ , dropout=self.dropout , num_layers=self.layers_per_block , add_downsample=not is_final_block , dtype=self.dtype , )
down_blocks.append(snake_case__ )
snake_case : Dict = down_blocks
# mid
snake_case : Optional[int] = FlaxUNetMidBlockaDCrossAttn(
in_channels=block_out_channels[-1] , dropout=self.dropout , num_attention_heads=num_attention_heads[-1] , use_linear_projection=self.use_linear_projection , use_memory_efficient_attention=self.use_memory_efficient_attention , dtype=self.dtype , )
# up
snake_case : Optional[Any] = []
snake_case : Optional[int] = list(reversed(snake_case__ ) )
snake_case : Dict = list(reversed(snake_case__ ) )
snake_case : Tuple = list(reversed(snake_case__ ) )
snake_case : Optional[Any] = reversed_block_out_channels[0]
for i, up_block_type in enumerate(self.up_block_types ):
snake_case : Optional[int] = output_channel
snake_case : List[Any] = reversed_block_out_channels[i]
snake_case : Union[str, Any] = reversed_block_out_channels[min(i + 1 , len(snake_case__ ) - 1 )]
snake_case : int = i == len(snake_case__ ) - 1
if up_block_type == "CrossAttnUpBlock2D":
snake_case : Any = FlaxCrossAttnUpBlockaD(
in_channels=snake_case__ , out_channels=snake_case__ , prev_output_channel=snake_case__ , num_layers=self.layers_per_block + 1 , num_attention_heads=reversed_num_attention_heads[i] , add_upsample=not is_final_block , dropout=self.dropout , use_linear_projection=self.use_linear_projection , only_cross_attention=only_cross_attention[i] , use_memory_efficient_attention=self.use_memory_efficient_attention , dtype=self.dtype , )
else:
snake_case : Optional[int] = FlaxUpBlockaD(
in_channels=snake_case__ , out_channels=snake_case__ , prev_output_channel=snake_case__ , num_layers=self.layers_per_block + 1 , add_upsample=not is_final_block , dropout=self.dropout , dtype=self.dtype , )
up_blocks.append(snake_case__ )
snake_case : Optional[int] = output_channel
snake_case : Tuple = up_blocks
# out
snake_case : Optional[int] = nn.GroupNorm(num_groups=32 , epsilon=1e-5 )
snake_case : List[str] = nn.Conv(
self.out_channels , kernel_size=(3, 3) , strides=(1, 1) , padding=((1, 1), (1, 1)) , dtype=self.dtype , )
def __call__(self : Dict , snake_case__ : Dict , snake_case__ : Dict , snake_case__ : Optional[int] , snake_case__ : Tuple=None , snake_case__ : Union[str, Any]=None , snake_case__ : bool = True , snake_case__ : bool = False , ) -> Union[FlaxUNetaDConditionOutput, Tuple]:
'''simple docstring'''
if not isinstance(snake_case__ , jnp.ndarray ):
snake_case : List[Any] = jnp.array([timesteps] , dtype=jnp.intaa )
elif isinstance(snake_case__ , jnp.ndarray ) and len(timesteps.shape ) == 0:
snake_case : Any = timesteps.astype(dtype=jnp.floataa )
snake_case : int = jnp.expand_dims(snake_case__ , 0 )
snake_case : str = self.time_proj(snake_case__ )
snake_case : str = self.time_embedding(snake_case__ )
# 2. pre-process
snake_case : int = jnp.transpose(snake_case__ , (0, 2, 3, 1) )
snake_case : List[Any] = self.conv_in(snake_case__ )
# 3. down
snake_case : Optional[int] = (sample,)
for down_block in self.down_blocks:
if isinstance(snake_case__ , snake_case__ ):
snake_case , snake_case : List[Any] = down_block(snake_case__ , snake_case__ , snake_case__ , deterministic=not train )
else:
snake_case , snake_case : str = down_block(snake_case__ , snake_case__ , deterministic=not train )
down_block_res_samples += res_samples
if down_block_additional_residuals is not None:
snake_case : Tuple = ()
for down_block_res_sample, down_block_additional_residual in zip(
snake_case__ , snake_case__ ):
down_block_res_sample += down_block_additional_residual
new_down_block_res_samples += (down_block_res_sample,)
snake_case : Optional[int] = new_down_block_res_samples
# 4. mid
snake_case : Optional[int] = self.mid_block(snake_case__ , snake_case__ , snake_case__ , deterministic=not train )
if mid_block_additional_residual is not None:
sample += mid_block_additional_residual
# 5. up
for up_block in self.up_blocks:
snake_case : int = down_block_res_samples[-(self.layers_per_block + 1) :]
snake_case : Optional[Any] = down_block_res_samples[: -(self.layers_per_block + 1)]
if isinstance(snake_case__ , snake_case__ ):
snake_case : Optional[Any] = up_block(
snake_case__ , temb=snake_case__ , encoder_hidden_states=snake_case__ , res_hidden_states_tuple=snake_case__ , deterministic=not train , )
else:
snake_case : Dict = up_block(snake_case__ , temb=snake_case__ , res_hidden_states_tuple=snake_case__ , deterministic=not train )
# 6. post-process
snake_case : List[str] = self.conv_norm_out(snake_case__ )
snake_case : Any = nn.silu(snake_case__ )
snake_case : Optional[int] = self.conv_out(snake_case__ )
snake_case : Union[str, Any] = jnp.transpose(snake_case__ , (0, 3, 1, 2) )
if not return_dict:
return (sample,)
return FlaxUNetaDConditionOutput(sample=snake_case__ )
| 59
| 1
|
import json
import os
import sys
import tempfile
import unittest
from pathlib import Path
from shutil import copyfile
from huggingface_hub import HfFolder, Repository, create_repo, delete_repo
from requests.exceptions import HTTPError
import transformers
from transformers import (
CONFIG_MAPPING,
FEATURE_EXTRACTOR_MAPPING,
PROCESSOR_MAPPING,
TOKENIZER_MAPPING,
AutoConfig,
AutoFeatureExtractor,
AutoProcessor,
AutoTokenizer,
BertTokenizer,
ProcessorMixin,
WavaVecaConfig,
WavaVecaFeatureExtractor,
WavaVecaProcessor,
)
from transformers.testing_utils import TOKEN, USER, get_tests_dir, is_staging_test
from transformers.tokenization_utils import TOKENIZER_CONFIG_FILE
from transformers.utils import FEATURE_EXTRACTOR_NAME, is_tokenizers_available
sys.path.append(str(Path(__file__).parent.parent.parent.parent / """utils"""))
from test_module.custom_configuration import CustomConfig # noqa E402
from test_module.custom_feature_extraction import CustomFeatureExtractor # noqa E402
from test_module.custom_processing import CustomProcessor # noqa E402
from test_module.custom_tokenization import CustomTokenizer # noqa E402
__lowerCamelCase = get_tests_dir("""fixtures/dummy_feature_extractor_config.json""")
__lowerCamelCase = get_tests_dir("""fixtures/vocab.json""")
__lowerCamelCase = get_tests_dir("""fixtures""")
class UpperCAmelCase ( unittest.TestCase ):
A__ : List[str] = ["[UNK]", "[CLS]", "[SEP]", "[PAD]", "[MASK]", "bla", "blou"]
def _SCREAMING_SNAKE_CASE (self : Union[str, Any] ) -> List[Any]:
'''simple docstring'''
snake_case : str = 0
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> Any:
'''simple docstring'''
snake_case : Optional[int] = AutoProcessor.from_pretrained("facebook/wav2vec2-base-960h" )
self.assertIsInstance(snake_case__ , snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> Optional[int]:
'''simple docstring'''
with tempfile.TemporaryDirectory() as tmpdirname:
snake_case : List[Any] = WavaVecaConfig()
snake_case : Any = AutoProcessor.from_pretrained("facebook/wav2vec2-base-960h" )
# save in new folder
model_config.save_pretrained(snake_case__ )
processor.save_pretrained(snake_case__ )
snake_case : Any = AutoProcessor.from_pretrained(snake_case__ )
self.assertIsInstance(snake_case__ , snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> Optional[Any]:
'''simple docstring'''
with tempfile.TemporaryDirectory() as tmpdirname:
# copy relevant files
copyfile(snake_case__ , os.path.join(snake_case__ , snake_case__ ) )
copyfile(snake_case__ , os.path.join(snake_case__ , "vocab.json" ) )
snake_case : List[str] = AutoProcessor.from_pretrained(snake_case__ )
self.assertIsInstance(snake_case__ , snake_case__ )
def _SCREAMING_SNAKE_CASE (self : List[str] ) -> Optional[Any]:
'''simple docstring'''
with tempfile.TemporaryDirectory() as tmpdirname:
snake_case : int = WavaVecaFeatureExtractor()
snake_case : Any = AutoTokenizer.from_pretrained("facebook/wav2vec2-base-960h" )
snake_case : List[str] = WavaVecaProcessor(snake_case__ , snake_case__ )
# save in new folder
processor.save_pretrained(snake_case__ )
# drop `processor_class` in tokenizer
with open(os.path.join(snake_case__ , snake_case__ ) , "r" ) as f:
snake_case : int = json.load(snake_case__ )
config_dict.pop("processor_class" )
with open(os.path.join(snake_case__ , snake_case__ ) , "w" ) as f:
f.write(json.dumps(snake_case__ ) )
snake_case : Tuple = AutoProcessor.from_pretrained(snake_case__ )
self.assertIsInstance(snake_case__ , snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> Tuple:
'''simple docstring'''
with tempfile.TemporaryDirectory() as tmpdirname:
snake_case : int = WavaVecaFeatureExtractor()
snake_case : Tuple = AutoTokenizer.from_pretrained("facebook/wav2vec2-base-960h" )
snake_case : Dict = WavaVecaProcessor(snake_case__ , snake_case__ )
# save in new folder
processor.save_pretrained(snake_case__ )
# drop `processor_class` in feature extractor
with open(os.path.join(snake_case__ , snake_case__ ) , "r" ) as f:
snake_case : List[str] = json.load(snake_case__ )
config_dict.pop("processor_class" )
with open(os.path.join(snake_case__ , snake_case__ ) , "w" ) as f:
f.write(json.dumps(snake_case__ ) )
snake_case : Union[str, Any] = AutoProcessor.from_pretrained(snake_case__ )
self.assertIsInstance(snake_case__ , snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Dict ) -> Tuple:
'''simple docstring'''
with tempfile.TemporaryDirectory() as tmpdirname:
snake_case : Tuple = WavaVecaConfig(processor_class="Wav2Vec2Processor" )
model_config.save_pretrained(snake_case__ )
# copy relevant files
copyfile(snake_case__ , os.path.join(snake_case__ , "vocab.json" ) )
# create emtpy sample processor
with open(os.path.join(snake_case__ , snake_case__ ) , "w" ) as f:
f.write("{}" )
snake_case : Union[str, Any] = AutoProcessor.from_pretrained(snake_case__ )
self.assertIsInstance(snake_case__ , snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Tuple ) -> Optional[int]:
'''simple docstring'''
with self.assertRaises(snake_case__ ):
snake_case : Optional[int] = AutoProcessor.from_pretrained("hf-internal-testing/test_dynamic_processor" )
# If remote code is disabled, we can't load this config.
with self.assertRaises(snake_case__ ):
snake_case : List[Any] = AutoProcessor.from_pretrained(
"hf-internal-testing/test_dynamic_processor" , trust_remote_code=snake_case__ )
snake_case : Optional[int] = AutoProcessor.from_pretrained("hf-internal-testing/test_dynamic_processor" , trust_remote_code=snake_case__ )
self.assertTrue(processor.special_attribute_present )
self.assertEqual(processor.__class__.__name__ , "NewProcessor" )
snake_case : List[Any] = processor.feature_extractor
self.assertTrue(feature_extractor.special_attribute_present )
self.assertEqual(feature_extractor.__class__.__name__ , "NewFeatureExtractor" )
snake_case : str = processor.tokenizer
self.assertTrue(tokenizer.special_attribute_present )
if is_tokenizers_available():
self.assertEqual(tokenizer.__class__.__name__ , "NewTokenizerFast" )
# Test we can also load the slow version
snake_case : int = AutoProcessor.from_pretrained(
"hf-internal-testing/test_dynamic_processor" , trust_remote_code=snake_case__ , use_fast=snake_case__ )
snake_case : Dict = new_processor.tokenizer
self.assertTrue(new_tokenizer.special_attribute_present )
self.assertEqual(new_tokenizer.__class__.__name__ , "NewTokenizer" )
else:
self.assertEqual(tokenizer.__class__.__name__ , "NewTokenizer" )
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> Optional[Any]:
'''simple docstring'''
try:
AutoConfig.register("custom" , snake_case__ )
AutoFeatureExtractor.register(snake_case__ , snake_case__ )
AutoTokenizer.register(snake_case__ , slow_tokenizer_class=snake_case__ )
AutoProcessor.register(snake_case__ , snake_case__ )
# Trying to register something existing in the Transformers library will raise an error
with self.assertRaises(snake_case__ ):
AutoProcessor.register(snake_case__ , snake_case__ )
# Now that the config is registered, it can be used as any other config with the auto-API
snake_case : List[Any] = CustomFeatureExtractor.from_pretrained(snake_case__ )
with tempfile.TemporaryDirectory() as tmp_dir:
snake_case : List[str] = os.path.join(snake_case__ , "vocab.txt" )
with open(snake_case__ , "w" , encoding="utf-8" ) as vocab_writer:
vocab_writer.write("".join([x + "\n" for x in self.vocab_tokens] ) )
snake_case : Optional[int] = CustomTokenizer(snake_case__ )
snake_case : List[Any] = CustomProcessor(snake_case__ , snake_case__ )
with tempfile.TemporaryDirectory() as tmp_dir:
processor.save_pretrained(snake_case__ )
snake_case : str = AutoProcessor.from_pretrained(snake_case__ )
self.assertIsInstance(snake_case__ , snake_case__ )
finally:
if "custom" in CONFIG_MAPPING._extra_content:
del CONFIG_MAPPING._extra_content["custom"]
if CustomConfig in FEATURE_EXTRACTOR_MAPPING._extra_content:
del FEATURE_EXTRACTOR_MAPPING._extra_content[CustomConfig]
if CustomConfig in TOKENIZER_MAPPING._extra_content:
del TOKENIZER_MAPPING._extra_content[CustomConfig]
if CustomConfig in PROCESSOR_MAPPING._extra_content:
del PROCESSOR_MAPPING._extra_content[CustomConfig]
def _SCREAMING_SNAKE_CASE (self : int ) -> Union[str, Any]:
'''simple docstring'''
class UpperCAmelCase ( A_ ):
A__ : Tuple = False
class UpperCAmelCase ( A_ ):
A__ : Tuple = False
class UpperCAmelCase ( A_ ):
A__ : Dict = "AutoFeatureExtractor"
A__ : str = "AutoTokenizer"
A__ : Dict = False
try:
AutoConfig.register("custom" , snake_case__ )
AutoFeatureExtractor.register(snake_case__ , snake_case__ )
AutoTokenizer.register(snake_case__ , slow_tokenizer_class=snake_case__ )
AutoProcessor.register(snake_case__ , snake_case__ )
# If remote code is not set, the default is to use local classes.
snake_case : Optional[Any] = AutoProcessor.from_pretrained("hf-internal-testing/test_dynamic_processor" )
self.assertEqual(processor.__class__.__name__ , "NewProcessor" )
self.assertFalse(processor.special_attribute_present )
self.assertFalse(processor.feature_extractor.special_attribute_present )
self.assertFalse(processor.tokenizer.special_attribute_present )
# If remote code is disabled, we load the local ones.
snake_case : Optional[int] = AutoProcessor.from_pretrained(
"hf-internal-testing/test_dynamic_processor" , trust_remote_code=snake_case__ )
self.assertEqual(processor.__class__.__name__ , "NewProcessor" )
self.assertFalse(processor.special_attribute_present )
self.assertFalse(processor.feature_extractor.special_attribute_present )
self.assertFalse(processor.tokenizer.special_attribute_present )
# If remote is enabled, we load from the Hub.
snake_case : Optional[int] = AutoProcessor.from_pretrained(
"hf-internal-testing/test_dynamic_processor" , trust_remote_code=snake_case__ )
self.assertEqual(processor.__class__.__name__ , "NewProcessor" )
self.assertTrue(processor.special_attribute_present )
self.assertTrue(processor.feature_extractor.special_attribute_present )
self.assertTrue(processor.tokenizer.special_attribute_present )
finally:
if "custom" in CONFIG_MAPPING._extra_content:
del CONFIG_MAPPING._extra_content["custom"]
if CustomConfig in FEATURE_EXTRACTOR_MAPPING._extra_content:
del FEATURE_EXTRACTOR_MAPPING._extra_content[CustomConfig]
if CustomConfig in TOKENIZER_MAPPING._extra_content:
del TOKENIZER_MAPPING._extra_content[CustomConfig]
if CustomConfig in PROCESSOR_MAPPING._extra_content:
del PROCESSOR_MAPPING._extra_content[CustomConfig]
def _SCREAMING_SNAKE_CASE (self : Dict ) -> Any:
'''simple docstring'''
snake_case : str = AutoProcessor.from_pretrained("hf-internal-testing/tiny-random-bert" )
self.assertEqual(processor.__class__.__name__ , "BertTokenizerFast" )
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> Tuple:
'''simple docstring'''
snake_case : Dict = AutoProcessor.from_pretrained("hf-internal-testing/tiny-random-convnext" )
self.assertEqual(processor.__class__.__name__ , "ConvNextImageProcessor" )
@is_staging_test
class UpperCAmelCase ( unittest.TestCase ):
A__ : Dict = ["[UNK]", "[CLS]", "[SEP]", "[PAD]", "[MASK]", "bla", "blou"]
@classmethod
def _SCREAMING_SNAKE_CASE (cls : Dict ) -> List[Any]:
'''simple docstring'''
snake_case : Any = TOKEN
HfFolder.save_token(snake_case__ )
@classmethod
def _SCREAMING_SNAKE_CASE (cls : Optional[Any] ) -> Tuple:
'''simple docstring'''
try:
delete_repo(token=cls._token , repo_id="test-processor" )
except HTTPError:
pass
try:
delete_repo(token=cls._token , repo_id="valid_org/test-processor-org" )
except HTTPError:
pass
try:
delete_repo(token=cls._token , repo_id="test-dynamic-processor" )
except HTTPError:
pass
def _SCREAMING_SNAKE_CASE (self : Union[str, Any] ) -> Tuple:
'''simple docstring'''
snake_case : Dict = WavaVecaProcessor.from_pretrained(snake_case__ )
with tempfile.TemporaryDirectory() as tmp_dir:
processor.save_pretrained(
os.path.join(snake_case__ , "test-processor" ) , push_to_hub=snake_case__ , use_auth_token=self._token )
snake_case : Tuple = WavaVecaProcessor.from_pretrained(f"""{USER}/test-processor""" )
for k, v in processor.feature_extractor.__dict__.items():
self.assertEqual(snake_case__ , getattr(new_processor.feature_extractor , snake_case__ ) )
self.assertDictEqual(new_processor.tokenizer.get_vocab() , processor.tokenizer.get_vocab() )
def _SCREAMING_SNAKE_CASE (self : List[str] ) -> Optional[Any]:
'''simple docstring'''
snake_case : int = WavaVecaProcessor.from_pretrained(snake_case__ )
with tempfile.TemporaryDirectory() as tmp_dir:
processor.save_pretrained(
os.path.join(snake_case__ , "test-processor-org" ) , push_to_hub=snake_case__ , use_auth_token=self._token , organization="valid_org" , )
snake_case : Dict = WavaVecaProcessor.from_pretrained("valid_org/test-processor-org" )
for k, v in processor.feature_extractor.__dict__.items():
self.assertEqual(snake_case__ , getattr(new_processor.feature_extractor , snake_case__ ) )
self.assertDictEqual(new_processor.tokenizer.get_vocab() , processor.tokenizer.get_vocab() )
def _SCREAMING_SNAKE_CASE (self : int ) -> int:
'''simple docstring'''
CustomFeatureExtractor.register_for_auto_class()
CustomTokenizer.register_for_auto_class()
CustomProcessor.register_for_auto_class()
snake_case : List[Any] = CustomFeatureExtractor.from_pretrained(snake_case__ )
with tempfile.TemporaryDirectory() as tmp_dir:
snake_case : Any = os.path.join(snake_case__ , "vocab.txt" )
with open(snake_case__ , "w" , encoding="utf-8" ) as vocab_writer:
vocab_writer.write("".join([x + "\n" for x in self.vocab_tokens] ) )
snake_case : str = CustomTokenizer(snake_case__ )
snake_case : Tuple = CustomProcessor(snake_case__ , snake_case__ )
with tempfile.TemporaryDirectory() as tmp_dir:
create_repo(f"""{USER}/test-dynamic-processor""" , token=self._token )
snake_case : Optional[Any] = Repository(snake_case__ , clone_from=f"""{USER}/test-dynamic-processor""" , token=self._token )
processor.save_pretrained(snake_case__ )
# This has added the proper auto_map field to the feature extractor config
self.assertDictEqual(
processor.feature_extractor.auto_map , {
"AutoFeatureExtractor": "custom_feature_extraction.CustomFeatureExtractor",
"AutoProcessor": "custom_processing.CustomProcessor",
} , )
# This has added the proper auto_map field to the tokenizer config
with open(os.path.join(snake_case__ , "tokenizer_config.json" ) ) as f:
snake_case : List[str] = json.load(snake_case__ )
self.assertDictEqual(
tokenizer_config["auto_map"] , {
"AutoTokenizer": ["custom_tokenization.CustomTokenizer", None],
"AutoProcessor": "custom_processing.CustomProcessor",
} , )
# The code has been copied from fixtures
self.assertTrue(os.path.isfile(os.path.join(snake_case__ , "custom_feature_extraction.py" ) ) )
self.assertTrue(os.path.isfile(os.path.join(snake_case__ , "custom_tokenization.py" ) ) )
self.assertTrue(os.path.isfile(os.path.join(snake_case__ , "custom_processing.py" ) ) )
repo.push_to_hub()
snake_case : int = AutoProcessor.from_pretrained(f"""{USER}/test-dynamic-processor""" , trust_remote_code=snake_case__ )
# Can't make an isinstance check because the new_processor is from the CustomProcessor class of a dynamic module
self.assertEqual(new_processor.__class__.__name__ , "CustomProcessor" )
| 59
|
__lowerCamelCase = {
"joule": 1.0,
"kilojoule": 10_00,
"megajoule": 1_00_00_00,
"gigajoule": 10_00_00_00_00,
"wattsecond": 1.0,
"watthour": 36_00,
"kilowatthour": 3_60_00_00,
"newtonmeter": 1.0,
"calorie_nutr": 41_86.8,
"kilocalorie_nutr": 4_18_68_00.00,
"electronvolt": 1.602_176_634e-19,
"britishthermalunit_it": 10_55.0_55_85,
"footpound": 1.35_5818,
}
def UpperCamelCase ( __lowerCamelCase : str , __lowerCamelCase : str , __lowerCamelCase : float ):
if to_type not in ENERGY_CONVERSION or from_type not in ENERGY_CONVERSION:
snake_case : List[Any] = (
f"""Incorrect 'from_type' or 'to_type' value: {from_type!r}, {to_type!r}\n"""
f"""Valid values are: {', '.join(__lowerCamelCase )}"""
)
raise ValueError(__lowerCamelCase )
return value * ENERGY_CONVERSION[from_type] / ENERGY_CONVERSION[to_type]
if __name__ == "__main__":
import doctest
doctest.testmod()
| 59
| 1
|
import unittest
import numpy as np
from transformers.testing_utils import require_torch, require_vision
from transformers.utils import is_torch_available, is_vision_available
from ...test_image_processing_common import ImageProcessingSavingTestMixin, prepare_image_inputs
if is_torch_available():
import torch
if is_vision_available():
from PIL import Image
from transformers import MobileNetVaImageProcessor
class UpperCAmelCase ( unittest.TestCase ):
def __init__(self : int , snake_case__ : Union[str, Any] , snake_case__ : Dict=7 , snake_case__ : Optional[Any]=3 , snake_case__ : Optional[Any]=18 , snake_case__ : str=30 , snake_case__ : Optional[Any]=4_00 , snake_case__ : List[str]=True , snake_case__ : Any=None , snake_case__ : str=True , snake_case__ : Dict=None , ) -> int:
'''simple docstring'''
snake_case : Any = size if size is not None else {"shortest_edge": 20}
snake_case : Union[str, Any] = crop_size if crop_size is not None else {"height": 18, "width": 18}
snake_case : Optional[Any] = parent
snake_case : Optional[Any] = batch_size
snake_case : List[Any] = num_channels
snake_case : List[Any] = image_size
snake_case : Optional[int] = min_resolution
snake_case : Optional[int] = max_resolution
snake_case : Optional[int] = do_resize
snake_case : Optional[int] = size
snake_case : Optional[int] = do_center_crop
snake_case : Dict = crop_size
def _SCREAMING_SNAKE_CASE (self : Any ) -> Optional[Any]:
'''simple docstring'''
return {
"do_resize": self.do_resize,
"size": self.size,
"do_center_crop": self.do_center_crop,
"crop_size": self.crop_size,
}
@require_torch
@require_vision
class UpperCAmelCase ( A_ ,unittest.TestCase ):
A__ : Optional[Any] = MobileNetVaImageProcessor if is_vision_available() else None
def _SCREAMING_SNAKE_CASE (self : Any ) -> List[Any]:
'''simple docstring'''
snake_case : Optional[Any] = MobileNetVaImageProcessingTester(self )
@property
def _SCREAMING_SNAKE_CASE (self : Any ) -> Union[str, Any]:
'''simple docstring'''
return self.image_processor_tester.prepare_image_processor_dict()
def _SCREAMING_SNAKE_CASE (self : Union[str, Any] ) -> Optional[Any]:
'''simple docstring'''
snake_case : str = self.image_processing_class(**self.image_processor_dict )
self.assertTrue(hasattr(snake_case__ , "do_resize" ) )
self.assertTrue(hasattr(snake_case__ , "size" ) )
self.assertTrue(hasattr(snake_case__ , "do_center_crop" ) )
self.assertTrue(hasattr(snake_case__ , "crop_size" ) )
def _SCREAMING_SNAKE_CASE (self : str ) -> Optional[Any]:
'''simple docstring'''
snake_case : Optional[Any] = self.image_processing_class.from_dict(self.image_processor_dict )
self.assertEqual(image_processor.size , {"shortest_edge": 20} )
self.assertEqual(image_processor.crop_size , {"height": 18, "width": 18} )
snake_case : str = self.image_processing_class.from_dict(self.image_processor_dict , size=42 , crop_size=84 )
self.assertEqual(image_processor.size , {"shortest_edge": 42} )
self.assertEqual(image_processor.crop_size , {"height": 84, "width": 84} )
def _SCREAMING_SNAKE_CASE (self : Tuple ) -> Optional[int]:
'''simple docstring'''
pass
def _SCREAMING_SNAKE_CASE (self : List[Any] ) -> int:
'''simple docstring'''
snake_case : Union[str, Any] = self.image_processing_class(**self.image_processor_dict )
# create random PIL images
snake_case : Optional[int] = prepare_image_inputs(self.image_processor_tester , equal_resolution=snake_case__ )
for image in image_inputs:
self.assertIsInstance(snake_case__ , Image.Image )
# Test not batched input
snake_case : int = image_processing(image_inputs[0] , return_tensors="pt" ).pixel_values
self.assertEqual(
encoded_images.shape , (
1,
self.image_processor_tester.num_channels,
self.image_processor_tester.crop_size["height"],
self.image_processor_tester.crop_size["width"],
) , )
# Test batched
snake_case : Tuple = image_processing(snake_case__ , return_tensors="pt" ).pixel_values
self.assertEqual(
encoded_images.shape , (
self.image_processor_tester.batch_size,
self.image_processor_tester.num_channels,
self.image_processor_tester.crop_size["height"],
self.image_processor_tester.crop_size["width"],
) , )
def _SCREAMING_SNAKE_CASE (self : Dict ) -> Optional[int]:
'''simple docstring'''
snake_case : Optional[int] = self.image_processing_class(**self.image_processor_dict )
# create random numpy tensors
snake_case : Union[str, Any] = prepare_image_inputs(self.image_processor_tester , equal_resolution=snake_case__ , numpify=snake_case__ )
for image in image_inputs:
self.assertIsInstance(snake_case__ , np.ndarray )
# Test not batched input
snake_case : List[Any] = image_processing(image_inputs[0] , return_tensors="pt" ).pixel_values
self.assertEqual(
encoded_images.shape , (
1,
self.image_processor_tester.num_channels,
self.image_processor_tester.crop_size["height"],
self.image_processor_tester.crop_size["width"],
) , )
# Test batched
snake_case : Optional[int] = image_processing(snake_case__ , return_tensors="pt" ).pixel_values
self.assertEqual(
encoded_images.shape , (
self.image_processor_tester.batch_size,
self.image_processor_tester.num_channels,
self.image_processor_tester.crop_size["height"],
self.image_processor_tester.crop_size["width"],
) , )
def _SCREAMING_SNAKE_CASE (self : str ) -> Optional[int]:
'''simple docstring'''
snake_case : str = self.image_processing_class(**self.image_processor_dict )
# create random PyTorch tensors
snake_case : Dict = prepare_image_inputs(self.image_processor_tester , equal_resolution=snake_case__ , torchify=snake_case__ )
for image in image_inputs:
self.assertIsInstance(snake_case__ , torch.Tensor )
# Test not batched input
snake_case : List[str] = image_processing(image_inputs[0] , return_tensors="pt" ).pixel_values
self.assertEqual(
encoded_images.shape , (
1,
self.image_processor_tester.num_channels,
self.image_processor_tester.crop_size["height"],
self.image_processor_tester.crop_size["width"],
) , )
# Test batched
snake_case : Tuple = image_processing(snake_case__ , return_tensors="pt" ).pixel_values
self.assertEqual(
encoded_images.shape , (
self.image_processor_tester.batch_size,
self.image_processor_tester.num_channels,
self.image_processor_tester.crop_size["height"],
self.image_processor_tester.crop_size["width"],
) , )
| 59
|
import logging
import os
from dataclasses import dataclass, field
from typing import Dict, Optional
import datasets
import numpy as np
import tensorflow as tf
from transformers import (
AutoConfig,
AutoTokenizer,
EvalPrediction,
HfArgumentParser,
PreTrainedTokenizer,
TFAutoModelForSequenceClassification,
TFTrainer,
TFTrainingArguments,
)
from transformers.utils import logging as hf_logging
hf_logging.set_verbosity_info()
hf_logging.enable_default_handler()
hf_logging.enable_explicit_format()
def UpperCamelCase ( __lowerCamelCase : str , __lowerCamelCase : str , __lowerCamelCase : str , __lowerCamelCase : PreTrainedTokenizer , __lowerCamelCase : int , __lowerCamelCase : Optional[int] = None , ):
snake_case : int = {}
if train_file is not None:
snake_case : List[Any] = [train_file]
if eval_file is not None:
snake_case : Optional[int] = [eval_file]
if test_file is not None:
snake_case : Any = [test_file]
snake_case : int = datasets.load_dataset("csv" , data_files=__lowerCamelCase )
snake_case : str = list(ds[list(files.keys() )[0]].features.keys() )
snake_case : int = features_name.pop(__lowerCamelCase )
snake_case : str = list(set(ds[list(files.keys() )[0]][label_name] ) )
snake_case : str = {label: i for i, label in enumerate(__lowerCamelCase )}
snake_case : List[Any] = tokenizer.model_input_names
snake_case : List[Any] = {}
if len(__lowerCamelCase ) == 1:
for k in files.keys():
snake_case : Tuple = ds[k].map(
lambda __lowerCamelCase : tokenizer.batch_encode_plus(
example[features_name[0]] , truncation=__lowerCamelCase , max_length=__lowerCamelCase , padding="max_length" ) , batched=__lowerCamelCase , )
elif len(__lowerCamelCase ) == 2:
for k in files.keys():
snake_case : List[Any] = ds[k].map(
lambda __lowerCamelCase : tokenizer.batch_encode_plus(
(example[features_name[0]], example[features_name[1]]) , truncation=__lowerCamelCase , max_length=__lowerCamelCase , padding="max_length" , ) , batched=__lowerCamelCase , )
def gen_train():
for ex in transformed_ds[datasets.Split.TRAIN]:
snake_case : Dict = {k: v for k, v in ex.items() if k in input_names}
snake_case : Union[str, Any] = labelaid[ex[label_name]]
yield (d, label)
def gen_val():
for ex in transformed_ds[datasets.Split.VALIDATION]:
snake_case : str = {k: v for k, v in ex.items() if k in input_names}
snake_case : Any = labelaid[ex[label_name]]
yield (d, label)
def gen_test():
for ex in transformed_ds[datasets.Split.TEST]:
snake_case : str = {k: v for k, v in ex.items() if k in input_names}
snake_case : List[str] = labelaid[ex[label_name]]
yield (d, label)
snake_case : int = (
tf.data.Dataset.from_generator(
__lowerCamelCase , ({k: tf.intaa for k in input_names}, tf.intaa) , ({k: tf.TensorShape([None] ) for k in input_names}, tf.TensorShape([] )) , )
if datasets.Split.TRAIN in transformed_ds
else None
)
if train_ds is not None:
snake_case : Optional[Any] = train_ds.apply(tf.data.experimental.assert_cardinality(len(ds[datasets.Split.TRAIN] ) ) )
snake_case : Tuple = (
tf.data.Dataset.from_generator(
__lowerCamelCase , ({k: tf.intaa for k in input_names}, tf.intaa) , ({k: tf.TensorShape([None] ) for k in input_names}, tf.TensorShape([] )) , )
if datasets.Split.VALIDATION in transformed_ds
else None
)
if val_ds is not None:
snake_case : List[str] = val_ds.apply(tf.data.experimental.assert_cardinality(len(ds[datasets.Split.VALIDATION] ) ) )
snake_case : Optional[int] = (
tf.data.Dataset.from_generator(
__lowerCamelCase , ({k: tf.intaa for k in input_names}, tf.intaa) , ({k: tf.TensorShape([None] ) for k in input_names}, tf.TensorShape([] )) , )
if datasets.Split.TEST in transformed_ds
else None
)
if test_ds is not None:
snake_case : str = test_ds.apply(tf.data.experimental.assert_cardinality(len(ds[datasets.Split.TEST] ) ) )
return train_ds, val_ds, test_ds, labelaid
__lowerCamelCase = logging.getLogger(__name__)
@dataclass
class UpperCAmelCase :
A__ : int = field(metadata={"help": "Which column contains the label"} )
A__ : str = field(default=A_ ,metadata={"help": "The path of the training file"} )
A__ : Optional[str] = field(default=A_ ,metadata={"help": "The path of the development file"} )
A__ : Optional[str] = field(default=A_ ,metadata={"help": "The path of the test file"} )
A__ : int = field(
default=1_28 ,metadata={
"help": (
"The maximum total input sequence length after tokenization. Sequences longer "
"than this will be truncated, sequences shorter will be padded."
)
} ,)
A__ : bool = field(
default=A_ ,metadata={"help": "Overwrite the cached training and evaluation sets"} )
@dataclass
class UpperCAmelCase :
A__ : str = field(
metadata={"help": "Path to pretrained model or model identifier from huggingface.co/models"} )
A__ : Optional[str] = field(
default=A_ ,metadata={"help": "Pretrained config name or path if not the same as model_name"} )
A__ : Optional[str] = field(
default=A_ ,metadata={"help": "Pretrained tokenizer name or path if not the same as model_name"} )
A__ : bool = 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.
A__ : Optional[str] = field(
default=A_ ,metadata={"help": "Where do you want to store the pretrained models downloaded from huggingface.co"} ,)
def UpperCamelCase ( ):
# See all possible arguments in src/transformers/training_args.py
# or by passing the --help flag to this script.
# We now keep distinct sets of args, for a cleaner separation of concerns.
snake_case : List[Any] = HfArgumentParser((ModelArguments, DataTrainingArguments, TFTrainingArguments) )
snake_case , snake_case , snake_case : int = parser.parse_args_into_dataclasses()
if (
os.path.exists(training_args.output_dir )
and os.listdir(training_args.output_dir )
and training_args.do_train
and not training_args.overwrite_output_dir
):
raise ValueError(
f"""Output directory ({training_args.output_dir}) already exists and is not empty. Use"""
" --overwrite_output_dir to overcome." )
# Setup logging
logging.basicConfig(
format="%(asctime)s - %(levelname)s - %(name)s - %(message)s" , datefmt="%m/%d/%Y %H:%M:%S" , level=logging.INFO , )
logger.info(
f"""n_replicas: {training_args.n_replicas}, distributed training: {bool(training_args.n_replicas > 1 )}, """
f"""16-bits training: {training_args.fpaa}""" )
logger.info(f"""Training/evaluation parameters {training_args}""" )
# Load pretrained model and tokenizer
#
# Distributed training:
# The .from_pretrained methods guarantee that only one local process can concurrently
# download model & vocab.
snake_case : Tuple = AutoTokenizer.from_pretrained(
model_args.tokenizer_name if model_args.tokenizer_name else model_args.model_name_or_path , cache_dir=model_args.cache_dir , )
snake_case , snake_case , snake_case , snake_case : Tuple = get_tfds(
train_file=data_args.train_file , eval_file=data_args.dev_file , test_file=data_args.test_file , tokenizer=__lowerCamelCase , label_column_id=data_args.label_column_id , max_seq_length=data_args.max_seq_length , )
snake_case : Optional[Any] = AutoConfig.from_pretrained(
model_args.config_name if model_args.config_name else model_args.model_name_or_path , num_labels=len(__lowerCamelCase ) , labelaid=__lowerCamelCase , idalabel={id: label for label, id in labelaid.items()} , finetuning_task="text-classification" , cache_dir=model_args.cache_dir , )
with training_args.strategy.scope():
snake_case : int = TFAutoModelForSequenceClassification.from_pretrained(
model_args.model_name_or_path , from_pt=bool(".bin" in model_args.model_name_or_path ) , config=__lowerCamelCase , cache_dir=model_args.cache_dir , )
def compute_metrics(__lowerCamelCase : EvalPrediction ) -> Dict:
snake_case : Optional[int] = np.argmax(p.predictions , axis=1 )
return {"acc": (preds == p.label_ids).mean()}
# Initialize our Trainer
snake_case : int = TFTrainer(
model=__lowerCamelCase , args=__lowerCamelCase , train_dataset=__lowerCamelCase , eval_dataset=__lowerCamelCase , compute_metrics=__lowerCamelCase , )
# Training
if training_args.do_train:
trainer.train()
trainer.save_model()
tokenizer.save_pretrained(training_args.output_dir )
# Evaluation
snake_case : int = {}
if training_args.do_eval:
logger.info("*** Evaluate ***" )
snake_case : Any = trainer.evaluate()
snake_case : List[Any] = os.path.join(training_args.output_dir , "eval_results.txt" )
with open(__lowerCamelCase , "w" ) as writer:
logger.info("***** Eval results *****" )
for key, value in result.items():
logger.info(f""" {key} = {value}""" )
writer.write(f"""{key} = {value}\n""" )
results.update(__lowerCamelCase )
return results
if __name__ == "__main__":
main()
| 59
| 1
|
from typing import Optional, Union
import numpy as np
from ...image_processing_utils import BaseImageProcessor, BatchFeature
from ...image_transforms import get_image_size, pad, rescale, to_channel_dimension_format
from ...image_utils import ChannelDimension, ImageInput, make_list_of_images, to_numpy_array, valid_images
from ...utils import TensorType, logging
__lowerCamelCase = logging.get_logger(__name__)
class UpperCAmelCase ( A_ ):
A__ : Any = ["pixel_values"]
def __init__(self : str , snake_case__ : bool = True , snake_case__ : Union[int, float] = 1 / 2_55 , snake_case__ : bool = True , snake_case__ : int = 8 , **snake_case__ : str , ) -> None:
'''simple docstring'''
super().__init__(**snake_case__ )
snake_case : Optional[Any] = do_rescale
snake_case : Union[str, Any] = rescale_factor
snake_case : str = do_pad
snake_case : Union[str, Any] = pad_size
def _SCREAMING_SNAKE_CASE (self : int , snake_case__ : np.ndarray , snake_case__ : float , snake_case__ : Optional[Union[str, ChannelDimension]] = None , **snake_case__ : Union[str, Any] ) -> np.ndarray:
'''simple docstring'''
return rescale(snake_case__ , scale=snake_case__ , data_format=snake_case__ , **snake_case__ )
def _SCREAMING_SNAKE_CASE (self : List[str] , snake_case__ : np.ndarray , snake_case__ : int , snake_case__ : Optional[Union[str, ChannelDimension]] = None ) -> Optional[int]:
'''simple docstring'''
snake_case , snake_case : Tuple = get_image_size(snake_case__ )
snake_case : List[Any] = (old_height // size + 1) * size - old_height
snake_case : int = (old_width // size + 1) * size - old_width
return pad(snake_case__ , ((0, pad_height), (0, pad_width)) , mode="symmetric" , data_format=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Any , snake_case__ : ImageInput , snake_case__ : Optional[bool] = None , snake_case__ : Optional[float] = None , snake_case__ : Optional[bool] = None , snake_case__ : Optional[int] = None , snake_case__ : Optional[Union[str, TensorType]] = None , snake_case__ : Union[str, ChannelDimension] = ChannelDimension.FIRST , **snake_case__ : Tuple , ) -> List[str]:
'''simple docstring'''
snake_case : Optional[int] = do_rescale if do_rescale is not None else self.do_rescale
snake_case : Tuple = rescale_factor if rescale_factor is not None else self.rescale_factor
snake_case : int = do_pad if do_pad is not None else self.do_pad
snake_case : Tuple = pad_size if pad_size is not None else self.pad_size
snake_case : Tuple = make_list_of_images(snake_case__ )
if not valid_images(snake_case__ ):
raise ValueError(
"Invalid image type. Must be of type PIL.Image.Image, numpy.ndarray, "
"torch.Tensor, tf.Tensor or jax.ndarray." )
if do_rescale and rescale_factor is None:
raise ValueError("Rescale factor must be specified if do_rescale is True." )
# All transformations expect numpy arrays.
snake_case : List[str] = [to_numpy_array(snake_case__ ) for image in images]
if do_rescale:
snake_case : Optional[Any] = [self.rescale(image=snake_case__ , scale=snake_case__ ) for image in images]
if do_pad:
snake_case : List[str] = [self.pad(snake_case__ , size=snake_case__ ) for image in images]
snake_case : Any = [to_channel_dimension_format(snake_case__ , snake_case__ ) for image in images]
snake_case : Tuple = {"pixel_values": images}
return BatchFeature(data=snake_case__ , tensor_type=snake_case__ )
| 59
|
import json
import os
import shutil
import tempfile
import unittest
import numpy as np
from transformers import BertTokenizerFast
from transformers.models.bert.tokenization_bert import VOCAB_FILES_NAMES, BertTokenizer
from transformers.testing_utils import require_tokenizers, require_vision
from transformers.utils import IMAGE_PROCESSOR_NAME, is_vision_available
if is_vision_available():
from PIL import Image
from transformers import VisionTextDualEncoderProcessor, ViTImageProcessor
@require_tokenizers
@require_vision
class UpperCAmelCase ( unittest.TestCase ):
def _SCREAMING_SNAKE_CASE (self : Any ) -> List[str]:
'''simple docstring'''
snake_case : int = tempfile.mkdtemp()
# fmt: off
snake_case : Optional[int] = ["[UNK]", "[CLS]", "[SEP]", "[PAD]", "[MASK]", "want", "##want", "##ed", "wa", "un", "runn", "##ing", ",", "low", "lowest"]
# fmt: on
snake_case : List[str] = os.path.join(self.tmpdirname , VOCAB_FILES_NAMES["vocab_file"] )
with open(self.vocab_file , "w" , encoding="utf-8" ) as vocab_writer:
vocab_writer.write("".join([x + "\n" for x in vocab_tokens] ) )
snake_case : int = {
"do_resize": True,
"size": {"height": 18, "width": 18},
"do_normalize": True,
"image_mean": [0.5, 0.5, 0.5],
"image_std": [0.5, 0.5, 0.5],
}
snake_case : Optional[Any] = os.path.join(self.tmpdirname , snake_case__ )
with open(self.image_processor_file , "w" , encoding="utf-8" ) as fp:
json.dump(snake_case__ , snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Optional[Any] , **snake_case__ : str ) -> Optional[int]:
'''simple docstring'''
return BertTokenizer.from_pretrained(self.tmpdirname , **snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Optional[Any] , **snake_case__ : List[str] ) -> int:
'''simple docstring'''
return ViTImageProcessor.from_pretrained(self.tmpdirname , **snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> Dict:
'''simple docstring'''
shutil.rmtree(self.tmpdirname )
def _SCREAMING_SNAKE_CASE (self : Dict ) -> str:
'''simple docstring'''
snake_case : List[Any] = [np.random.randint(2_55 , size=(3, 30, 4_00) , dtype=np.uinta )]
snake_case : Optional[int] = [Image.fromarray(np.moveaxis(snake_case__ , 0 , -1 ) ) for x in image_inputs]
return image_inputs
def _SCREAMING_SNAKE_CASE (self : Union[str, Any] ) -> Union[str, Any]:
'''simple docstring'''
snake_case : Dict = self.get_tokenizer()
snake_case : Optional[Any] = self.get_image_processor()
snake_case : Optional[Any] = VisionTextDualEncoderProcessor(tokenizer=snake_case__ , image_processor=snake_case__ )
processor.save_pretrained(self.tmpdirname )
snake_case : Any = VisionTextDualEncoderProcessor.from_pretrained(self.tmpdirname )
self.assertEqual(processor.tokenizer.get_vocab() , tokenizer.get_vocab() )
self.assertIsInstance(processor.tokenizer , (BertTokenizer, BertTokenizerFast) )
self.assertEqual(processor.image_processor.to_json_string() , image_processor.to_json_string() )
self.assertIsInstance(processor.image_processor , snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Any ) -> Optional[Any]:
'''simple docstring'''
snake_case : str = VisionTextDualEncoderProcessor(
tokenizer=self.get_tokenizer() , image_processor=self.get_image_processor() )
processor.save_pretrained(self.tmpdirname )
snake_case : Optional[int] = self.get_tokenizer(bos_token="(BOS)" , eos_token="(EOS)" )
snake_case : Tuple = self.get_image_processor(do_normalize=snake_case__ , padding_value=1.0 )
snake_case : List[str] = VisionTextDualEncoderProcessor.from_pretrained(
self.tmpdirname , bos_token="(BOS)" , eos_token="(EOS)" , do_normalize=snake_case__ , padding_value=1.0 )
self.assertEqual(processor.tokenizer.get_vocab() , tokenizer_add_kwargs.get_vocab() )
self.assertIsInstance(processor.tokenizer , (BertTokenizer, BertTokenizerFast) )
self.assertEqual(processor.image_processor.to_json_string() , image_processor_add_kwargs.to_json_string() )
self.assertIsInstance(processor.image_processor , snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Union[str, Any] ) -> int:
'''simple docstring'''
snake_case : str = self.get_image_processor()
snake_case : Optional[int] = self.get_tokenizer()
snake_case : List[Any] = VisionTextDualEncoderProcessor(tokenizer=snake_case__ , image_processor=snake_case__ )
snake_case : Optional[Any] = self.prepare_image_inputs()
snake_case : str = image_processor(snake_case__ , return_tensors="np" )
snake_case : Any = processor(images=snake_case__ , return_tensors="np" )
for key in input_feat_extract.keys():
self.assertAlmostEqual(input_feat_extract[key].sum() , input_processor[key].sum() , delta=1e-2 )
def _SCREAMING_SNAKE_CASE (self : Tuple ) -> Optional[Any]:
'''simple docstring'''
snake_case : Dict = self.get_image_processor()
snake_case : int = self.get_tokenizer()
snake_case : Any = VisionTextDualEncoderProcessor(tokenizer=snake_case__ , image_processor=snake_case__ )
snake_case : Tuple = "lower newer"
snake_case : Tuple = processor(text=snake_case__ )
snake_case : Union[str, Any] = tokenizer(snake_case__ )
for key in encoded_tok.keys():
self.assertListEqual(encoded_tok[key] , encoded_processor[key] )
def _SCREAMING_SNAKE_CASE (self : Dict ) -> Optional[int]:
'''simple docstring'''
snake_case : List[Any] = self.get_image_processor()
snake_case : Dict = self.get_tokenizer()
snake_case : Dict = VisionTextDualEncoderProcessor(tokenizer=snake_case__ , image_processor=snake_case__ )
snake_case : int = "lower newer"
snake_case : Dict = self.prepare_image_inputs()
snake_case : Union[str, Any] = processor(text=snake_case__ , images=snake_case__ )
self.assertListEqual(list(inputs.keys() ) , ["input_ids", "token_type_ids", "attention_mask", "pixel_values"] )
# test if it raises when no input is passed
with self.assertRaises(snake_case__ ):
processor()
def _SCREAMING_SNAKE_CASE (self : str ) -> Tuple:
'''simple docstring'''
snake_case : Tuple = self.get_image_processor()
snake_case : Optional[Any] = self.get_tokenizer()
snake_case : Tuple = VisionTextDualEncoderProcessor(tokenizer=snake_case__ , image_processor=snake_case__ )
snake_case : List[str] = [[1, 4, 5, 8, 1, 0, 8], [3, 4, 3, 1, 1, 8, 9]]
snake_case : List[Any] = processor.batch_decode(snake_case__ )
snake_case : Union[str, Any] = tokenizer.batch_decode(snake_case__ )
self.assertListEqual(snake_case__ , snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> List[str]:
'''simple docstring'''
snake_case : str = self.get_image_processor()
snake_case : Union[str, Any] = self.get_tokenizer()
snake_case : Any = VisionTextDualEncoderProcessor(tokenizer=snake_case__ , image_processor=snake_case__ )
snake_case : Optional[Any] = "lower newer"
snake_case : List[Any] = self.prepare_image_inputs()
snake_case : Tuple = processor(text=snake_case__ , images=snake_case__ )
self.assertListEqual(list(inputs.keys() ) , processor.model_input_names )
| 59
| 1
|
import os
import textwrap
import pyarrow as pa
import pytest
from datasets import ClassLabel, Features, Image
from datasets.packaged_modules.csv.csv import Csv
from ..utils import require_pil
@pytest.fixture
def UpperCamelCase ( __lowerCamelCase : List[Any] ):
snake_case : Dict = tmp_path / "file.csv"
snake_case : List[str] = textwrap.dedent(
"\\n header1,header2\n 1,2\n 10,20\n " )
with open(__lowerCamelCase , "w" ) as f:
f.write(__lowerCamelCase )
return str(__lowerCamelCase )
@pytest.fixture
def UpperCamelCase ( __lowerCamelCase : Optional[int] ):
snake_case : Optional[int] = tmp_path / "malformed_file.csv"
snake_case : Union[str, Any] = textwrap.dedent(
"\\n header1,header2\n 1,2\n 10,20,\n " )
with open(__lowerCamelCase , "w" ) as f:
f.write(__lowerCamelCase )
return str(__lowerCamelCase )
@pytest.fixture
def UpperCamelCase ( __lowerCamelCase : Union[str, Any] , __lowerCamelCase : Union[str, Any] ):
snake_case : Any = tmp_path / "csv_with_image.csv"
snake_case : Union[str, Any] = textwrap.dedent(
f"""\
image
{image_file}
""" )
with open(__lowerCamelCase , "w" ) as f:
f.write(__lowerCamelCase )
return str(__lowerCamelCase )
@pytest.fixture
def UpperCamelCase ( __lowerCamelCase : Dict ):
snake_case : Dict = tmp_path / "csv_with_label.csv"
snake_case : int = textwrap.dedent(
"\\n label\n good\n bad\n good\n " )
with open(__lowerCamelCase , "w" ) as f:
f.write(__lowerCamelCase )
return str(__lowerCamelCase )
@pytest.fixture
def UpperCamelCase ( __lowerCamelCase : int ):
snake_case : str = tmp_path / "csv_with_int_list.csv"
snake_case : Dict = textwrap.dedent(
"\\n int_list\n 1 2 3\n 4 5 6\n 7 8 9\n " )
with open(__lowerCamelCase , "w" ) as f:
f.write(__lowerCamelCase )
return str(__lowerCamelCase )
def UpperCamelCase ( __lowerCamelCase : Union[str, Any] , __lowerCamelCase : List[Any] , __lowerCamelCase : str ):
snake_case : Dict = Csv()
snake_case : str = csv._generate_tables([[csv_file, malformed_csv_file]] )
with pytest.raises(__lowerCamelCase , match="Error tokenizing data" ):
for _ in generator:
pass
assert any(
record.levelname == "ERROR"
and "Failed to read file" in record.message
and os.path.basename(__lowerCamelCase ) in record.message
for record in caplog.records )
@require_pil
def UpperCamelCase ( __lowerCamelCase : Union[str, Any] ):
with open(__lowerCamelCase , encoding="utf-8" ) as f:
snake_case : Optional[Any] = f.read().splitlines()[1]
snake_case : Union[str, Any] = Csv(encoding="utf-8" , features=Features({"image": Image()} ) )
snake_case : Optional[Any] = csv._generate_tables([[csv_file_with_image]] )
snake_case : str = pa.concat_tables([table for _, table in generator] )
assert pa_table.schema.field("image" ).type == Image()()
snake_case : Union[str, Any] = pa_table.to_pydict()["image"]
assert generated_content == [{"path": image_file, "bytes": None}]
def UpperCamelCase ( __lowerCamelCase : Any ):
with open(__lowerCamelCase , encoding="utf-8" ) as f:
snake_case : List[str] = f.read().splitlines()[1:]
snake_case : str = Csv(encoding="utf-8" , features=Features({"label": ClassLabel(names=["good", "bad"] )} ) )
snake_case : Dict = csv._generate_tables([[csv_file_with_label]] )
snake_case : Union[str, Any] = pa.concat_tables([table for _, table in generator] )
assert pa_table.schema.field("label" ).type == ClassLabel(names=["good", "bad"] )()
snake_case : Union[str, Any] = pa_table.to_pydict()["label"]
assert generated_content == [ClassLabel(names=["good", "bad"] ).straint(__lowerCamelCase ) for label in labels]
def UpperCamelCase ( __lowerCamelCase : List[Any] ):
snake_case : Union[str, Any] = Csv(encoding="utf-8" , sep="," , converters={"int_list": lambda __lowerCamelCase : [int(__lowerCamelCase ) for i in x.split()]} )
snake_case : Any = csv._generate_tables([[csv_file_with_int_list]] )
snake_case : Optional[Any] = pa.concat_tables([table for _, table in generator] )
assert pa.types.is_list(pa_table.schema.field("int_list" ).type )
snake_case : List[Any] = pa_table.to_pydict()["int_list"]
assert generated_content == [[1, 2, 3], [4, 5, 6], [7, 8, 9]]
| 59
|
from typing import TYPE_CHECKING
from ...utils import OptionalDependencyNotAvailable, _LazyModule, is_tokenizers_available, is_torch_available
__lowerCamelCase = {
"""configuration_biogpt""": ["""BIOGPT_PRETRAINED_CONFIG_ARCHIVE_MAP""", """BioGptConfig"""],
"""tokenization_biogpt""": ["""BioGptTokenizer"""],
}
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = [
"""BIOGPT_PRETRAINED_MODEL_ARCHIVE_LIST""",
"""BioGptForCausalLM""",
"""BioGptForTokenClassification""",
"""BioGptForSequenceClassification""",
"""BioGptModel""",
"""BioGptPreTrainedModel""",
]
if TYPE_CHECKING:
from .configuration_biogpt import BIOGPT_PRETRAINED_CONFIG_ARCHIVE_MAP, BioGptConfig
from .tokenization_biogpt import BioGptTokenizer
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_biogpt import (
BIOGPT_PRETRAINED_MODEL_ARCHIVE_LIST,
BioGptForCausalLM,
BioGptForSequenceClassification,
BioGptForTokenClassification,
BioGptModel,
BioGptPreTrainedModel,
)
else:
import sys
__lowerCamelCase = _LazyModule(__name__, globals()["""__file__"""], _import_structure, module_spec=__spec__)
| 59
| 1
|
def UpperCamelCase ( __lowerCamelCase : str , __lowerCamelCase : str ):
def get_matched_characters(__lowerCamelCase : str , __lowerCamelCase : str ) -> str:
snake_case : Tuple = []
snake_case : Union[str, Any] = min(len(_stra ) , len(_stra ) ) // 2
for i, l in enumerate(_stra ):
snake_case : Any = int(max(0 , i - limit ) )
snake_case : Any = int(min(i + limit + 1 , len(_stra ) ) )
if l in _stra[left:right]:
matched.append(__lowerCamelCase )
snake_case : Dict = f"""{_stra[0:_stra.index(__lowerCamelCase )]} {_stra[_stra.index(__lowerCamelCase ) + 1:]}"""
return "".join(__lowerCamelCase )
# matching characters
snake_case : List[str] = get_matched_characters(__lowerCamelCase , __lowerCamelCase )
snake_case : Union[str, Any] = get_matched_characters(__lowerCamelCase , __lowerCamelCase )
snake_case : List[str] = len(__lowerCamelCase )
# transposition
snake_case : List[Any] = (
len([(ca, ca) for ca, ca in zip(__lowerCamelCase , __lowerCamelCase ) if ca != ca] ) // 2
)
if not match_count:
snake_case : Dict = 0.0
else:
snake_case : int = (
1
/ 3
* (
match_count / len(__lowerCamelCase )
+ match_count / len(__lowerCamelCase )
+ (match_count - transpositions) / match_count
)
)
# common prefix up to 4 characters
snake_case : Any = 0
for ca, ca in zip(stra[:4] , stra[:4] ):
if ca == ca:
prefix_len += 1
else:
break
return jaro + 0.1 * prefix_len * (1 - jaro)
if __name__ == "__main__":
import doctest
doctest.testmod()
print(jaro_winkler("""hello""", """world"""))
| 59
|
import collections
import inspect
import unittest
from typing import Dict, List, Tuple
from transformers import MaskFormerSwinConfig
from transformers.testing_utils import require_torch, require_torch_multi_gpu, torch_device
from transformers.utils import is_torch_available
from ...test_backbone_common import BackboneTesterMixin
from ...test_configuration_common import ConfigTester
from ...test_modeling_common import ModelTesterMixin, floats_tensor, ids_tensor
from ...test_pipeline_mixin import PipelineTesterMixin
if is_torch_available():
import torch
from torch import nn
from transformers import MaskFormerSwinBackbone
from transformers.models.maskformer import MaskFormerSwinModel
class UpperCAmelCase :
def __init__(self : Dict , snake_case__ : Dict , snake_case__ : Any=13 , snake_case__ : Any=32 , snake_case__ : Optional[Any]=2 , snake_case__ : Union[str, Any]=3 , snake_case__ : List[Any]=16 , snake_case__ : int=[1, 2, 1] , snake_case__ : Dict=[2, 2, 4] , snake_case__ : Dict=2 , snake_case__ : Tuple=2.0 , snake_case__ : Optional[int]=True , snake_case__ : Union[str, Any]=0.0 , snake_case__ : Any=0.0 , snake_case__ : Union[str, Any]=0.1 , snake_case__ : int="gelu" , snake_case__ : Optional[int]=False , snake_case__ : List[Any]=True , snake_case__ : List[str]=0.02 , snake_case__ : int=1e-5 , snake_case__ : List[str]=True , snake_case__ : Union[str, Any]=None , snake_case__ : List[Any]=True , snake_case__ : Optional[Any]=10 , snake_case__ : Optional[Any]=8 , snake_case__ : Any=["stage1", "stage2", "stage3"] , snake_case__ : Tuple=[1, 2, 3] , ) -> Union[str, Any]:
'''simple docstring'''
snake_case : Any = parent
snake_case : Optional[int] = batch_size
snake_case : Union[str, Any] = image_size
snake_case : Dict = patch_size
snake_case : Optional[Any] = num_channels
snake_case : Union[str, Any] = embed_dim
snake_case : int = depths
snake_case : List[str] = num_heads
snake_case : Union[str, Any] = window_size
snake_case : Union[str, Any] = mlp_ratio
snake_case : List[Any] = qkv_bias
snake_case : List[Any] = hidden_dropout_prob
snake_case : Union[str, Any] = attention_probs_dropout_prob
snake_case : Union[str, Any] = drop_path_rate
snake_case : int = hidden_act
snake_case : Optional[int] = use_absolute_embeddings
snake_case : int = patch_norm
snake_case : Union[str, Any] = layer_norm_eps
snake_case : Any = initializer_range
snake_case : Optional[Any] = is_training
snake_case : Tuple = scope
snake_case : Optional[int] = use_labels
snake_case : Optional[Any] = type_sequence_label_size
snake_case : Union[str, Any] = encoder_stride
snake_case : Any = out_features
snake_case : Tuple = out_indices
def _SCREAMING_SNAKE_CASE (self : Optional[Any] ) -> Dict:
'''simple docstring'''
snake_case : Optional[Any] = floats_tensor([self.batch_size, self.num_channels, self.image_size, self.image_size] )
snake_case : int = None
if self.use_labels:
snake_case : Tuple = ids_tensor([self.batch_size] , self.type_sequence_label_size )
snake_case : Dict = self.get_config()
return config, pixel_values, labels
def _SCREAMING_SNAKE_CASE (self : List[str] ) -> int:
'''simple docstring'''
return MaskFormerSwinConfig(
image_size=self.image_size , patch_size=self.patch_size , num_channels=self.num_channels , embed_dim=self.embed_dim , depths=self.depths , num_heads=self.num_heads , window_size=self.window_size , mlp_ratio=self.mlp_ratio , qkv_bias=self.qkv_bias , hidden_dropout_prob=self.hidden_dropout_prob , attention_probs_dropout_prob=self.attention_probs_dropout_prob , drop_path_rate=self.drop_path_rate , hidden_act=self.hidden_act , use_absolute_embeddings=self.use_absolute_embeddings , path_norm=self.patch_norm , layer_norm_eps=self.layer_norm_eps , initializer_range=self.initializer_range , encoder_stride=self.encoder_stride , out_features=self.out_features , out_indices=self.out_indices , )
def _SCREAMING_SNAKE_CASE (self : Tuple , snake_case__ : List[Any] , snake_case__ : List[str] , snake_case__ : Tuple ) -> Optional[Any]:
'''simple docstring'''
snake_case : Union[str, Any] = MaskFormerSwinModel(config=snake_case__ )
model.to(snake_case__ )
model.eval()
snake_case : List[Any] = model(snake_case__ )
snake_case : Dict = ((config.image_size // config.patch_size) ** 2) // (4 ** (len(config.depths ) - 1))
snake_case : int = int(config.embed_dim * 2 ** (len(config.depths ) - 1) )
self.parent.assertEqual(result.last_hidden_state.shape , (self.batch_size, expected_seq_len, expected_dim) )
def _SCREAMING_SNAKE_CASE (self : List[str] , snake_case__ : Union[str, Any] , snake_case__ : List[Any] , snake_case__ : Union[str, Any] ) -> str:
'''simple docstring'''
snake_case : Optional[int] = MaskFormerSwinBackbone(config=snake_case__ )
model.to(snake_case__ )
model.eval()
snake_case : List[Any] = model(snake_case__ )
# verify feature maps
self.parent.assertEqual(len(result.feature_maps ) , len(config.out_features ) )
self.parent.assertListEqual(list(result.feature_maps[0].shape ) , [13, 16, 16, 16] )
# verify channels
self.parent.assertEqual(len(model.channels ) , len(config.out_features ) )
self.parent.assertListEqual(model.channels , [16, 32, 64] )
# verify ValueError
with self.parent.assertRaises(snake_case__ ):
snake_case : Tuple = ["stem"]
snake_case : List[Any] = MaskFormerSwinBackbone(config=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : List[Any] ) -> List[Any]:
'''simple docstring'''
snake_case : Union[str, Any] = self.prepare_config_and_inputs()
snake_case , snake_case , snake_case : List[Any] = config_and_inputs
snake_case : int = {"pixel_values": pixel_values}
return config, inputs_dict
@require_torch
class UpperCAmelCase ( A_ ,A_ ,unittest.TestCase ):
A__ : List[str] = (
(
MaskFormerSwinModel,
MaskFormerSwinBackbone,
)
if is_torch_available()
else ()
)
A__ : str = {"feature-extraction": MaskFormerSwinModel} if is_torch_available() else {}
A__ : Optional[Any] = False
A__ : List[Any] = False
A__ : List[str] = False
A__ : List[str] = False
A__ : Union[str, Any] = False
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> List[str]:
'''simple docstring'''
snake_case : str = MaskFormerSwinModelTester(self )
snake_case : Optional[int] = ConfigTester(self , config_class=snake_case__ , embed_dim=37 )
@require_torch_multi_gpu
@unittest.skip(
reason=(
"`MaskFormerSwinModel` outputs `hidden_states_spatial_dimensions` which doesn't work well with"
" `nn.DataParallel`"
) )
def _SCREAMING_SNAKE_CASE (self : str ) -> Optional[Any]:
'''simple docstring'''
pass
def _SCREAMING_SNAKE_CASE (self : str ) -> List[str]:
'''simple docstring'''
self.create_and_test_config_common_properties()
self.config_tester.create_and_test_config_to_json_string()
self.config_tester.create_and_test_config_to_json_file()
self.config_tester.create_and_test_config_from_and_save_pretrained()
self.config_tester.create_and_test_config_with_num_labels()
self.config_tester.check_config_can_be_init_without_params()
self.config_tester.check_config_arguments_init()
def _SCREAMING_SNAKE_CASE (self : Tuple ) -> List[Any]:
'''simple docstring'''
return
def _SCREAMING_SNAKE_CASE (self : Dict ) -> str:
'''simple docstring'''
snake_case : str = self.model_tester.prepare_config_and_inputs()
self.model_tester.create_and_check_model(*snake_case__ )
def _SCREAMING_SNAKE_CASE (self : int ) -> Dict:
'''simple docstring'''
snake_case : Any = self.model_tester.prepare_config_and_inputs()
self.model_tester.create_and_check_backbone(*snake_case__ )
@unittest.skip("Swin does not use inputs_embeds" )
def _SCREAMING_SNAKE_CASE (self : int ) -> Any:
'''simple docstring'''
pass
@unittest.skip("Swin does not support feedforward chunking" )
def _SCREAMING_SNAKE_CASE (self : List[str] ) -> Dict:
'''simple docstring'''
pass
def _SCREAMING_SNAKE_CASE (self : Optional[Any] ) -> List[str]:
'''simple docstring'''
snake_case , snake_case : Any = self.model_tester.prepare_config_and_inputs_for_common()
for model_class in self.all_model_classes:
snake_case : int = model_class(snake_case__ )
self.assertIsInstance(model.get_input_embeddings() , (nn.Module) )
snake_case : List[Any] = model.get_output_embeddings()
self.assertTrue(x is None or isinstance(snake_case__ , nn.Linear ) )
def _SCREAMING_SNAKE_CASE (self : Optional[Any] ) -> Dict:
'''simple docstring'''
snake_case , snake_case : str = self.model_tester.prepare_config_and_inputs_for_common()
for model_class in self.all_model_classes:
snake_case : str = model_class(snake_case__ )
snake_case : Optional[int] = inspect.signature(model.forward )
# signature.parameters is an OrderedDict => so arg_names order is deterministic
snake_case : Optional[Any] = [*signature.parameters.keys()]
snake_case : Tuple = ["pixel_values"]
self.assertListEqual(arg_names[:1] , snake_case__ )
@unittest.skip(reason="MaskFormerSwin is only used as backbone and doesn't support output_attentions" )
def _SCREAMING_SNAKE_CASE (self : List[Any] ) -> str:
'''simple docstring'''
pass
@unittest.skip(reason="MaskFormerSwin is only used as an internal backbone" )
def _SCREAMING_SNAKE_CASE (self : Tuple ) -> Any:
'''simple docstring'''
pass
def _SCREAMING_SNAKE_CASE (self : Optional[Any] , snake_case__ : List[Any] , snake_case__ : str , snake_case__ : List[Any] , snake_case__ : Tuple ) -> Optional[int]:
'''simple docstring'''
snake_case : Tuple = model_class(snake_case__ )
model.to(snake_case__ )
model.eval()
with torch.no_grad():
snake_case : Any = model(**self._prepare_for_class(snake_case__ , snake_case__ ) )
snake_case : int = outputs.hidden_states
snake_case : Union[str, Any] = getattr(
self.model_tester , "expected_num_hidden_layers" , len(self.model_tester.depths ) + 1 )
self.assertEqual(len(snake_case__ ) , snake_case__ )
# Swin has a different seq_length
snake_case : Any = (
config.patch_size
if isinstance(config.patch_size , collections.abc.Iterable )
else (config.patch_size, config.patch_size)
)
snake_case : Tuple = (image_size[1] // patch_size[1]) * (image_size[0] // patch_size[0])
self.assertListEqual(
list(hidden_states[0].shape[-2:] ) , [num_patches, self.model_tester.embed_dim] , )
def _SCREAMING_SNAKE_CASE (self : Dict ) -> Union[str, Any]:
'''simple docstring'''
snake_case , snake_case : List[Any] = self.model_tester.prepare_config_and_inputs_for_common()
snake_case : int = (
self.model_tester.image_size
if isinstance(self.model_tester.image_size , collections.abc.Iterable )
else (self.model_tester.image_size, self.model_tester.image_size)
)
for model_class in self.all_model_classes:
snake_case : int = True
self.check_hidden_states_output(snake_case__ , snake_case__ , snake_case__ , snake_case__ )
# check that output_hidden_states also work using config
del inputs_dict["output_hidden_states"]
snake_case : Dict = True
self.check_hidden_states_output(snake_case__ , snake_case__ , snake_case__ , snake_case__ )
def _SCREAMING_SNAKE_CASE (self : int ) -> Any:
'''simple docstring'''
snake_case , snake_case : Union[str, Any] = self.model_tester.prepare_config_and_inputs_for_common()
snake_case : Any = 3
snake_case : List[str] = (
self.model_tester.image_size
if isinstance(self.model_tester.image_size , collections.abc.Iterable )
else (self.model_tester.image_size, self.model_tester.image_size)
)
snake_case : Tuple = (
config.patch_size
if isinstance(config.patch_size , collections.abc.Iterable )
else (config.patch_size, config.patch_size)
)
snake_case : str = image_size[0] + patch_size[0] - (image_size[0] % patch_size[0])
snake_case : str = image_size[1] + patch_size[1] - (image_size[1] % patch_size[1])
for model_class in self.all_model_classes:
snake_case : str = True
self.check_hidden_states_output(snake_case__ , snake_case__ , snake_case__ , (padded_height, padded_width) )
# check that output_hidden_states also work using config
del inputs_dict["output_hidden_states"]
snake_case : Optional[Any] = True
self.check_hidden_states_output(snake_case__ , snake_case__ , snake_case__ , (padded_height, padded_width) )
@unittest.skip(reason="MaskFormerSwin doesn't have pretrained checkpoints" )
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> str:
'''simple docstring'''
pass
@unittest.skip(reason="This will be fixed once MaskFormerSwin is replaced by native Swin" )
def _SCREAMING_SNAKE_CASE (self : str ) -> int:
'''simple docstring'''
pass
@unittest.skip(reason="This will be fixed once MaskFormerSwin is replaced by native Swin" )
def _SCREAMING_SNAKE_CASE (self : int ) -> str:
'''simple docstring'''
pass
def _SCREAMING_SNAKE_CASE (self : Any ) -> Any:
'''simple docstring'''
snake_case , snake_case : List[Any] = self.model_tester.prepare_config_and_inputs_for_common()
def set_nan_tensor_to_zero(snake_case__ : Union[str, Any] ):
snake_case : Any = 0
return t
def check_equivalence(snake_case__ : Union[str, Any] , snake_case__ : int , snake_case__ : List[str] , snake_case__ : Optional[int]={} ):
with torch.no_grad():
snake_case : Optional[Any] = model(**snake_case__ , return_dict=snake_case__ , **snake_case__ )
snake_case : Tuple = model(**snake_case__ , return_dict=snake_case__ , **snake_case__ ).to_tuple()
def recursive_check(snake_case__ : List[str] , snake_case__ : Optional[Any] ):
if isinstance(snake_case__ , (List, Tuple) ):
for tuple_iterable_value, dict_iterable_value in zip(snake_case__ , snake_case__ ):
recursive_check(snake_case__ , snake_case__ )
elif isinstance(snake_case__ , snake_case__ ):
for tuple_iterable_value, dict_iterable_value in zip(
tuple_object.values() , dict_object.values() ):
recursive_check(snake_case__ , snake_case__ )
elif tuple_object is None:
return
else:
self.assertTrue(
torch.allclose(
set_nan_tensor_to_zero(snake_case__ ) , set_nan_tensor_to_zero(snake_case__ ) , atol=1e-5 ) , msg=(
"Tuple and dict output are not equal. Difference:"
f""" {torch.max(torch.abs(tuple_object - dict_object ) )}. Tuple has `nan`:"""
f""" {torch.isnan(snake_case__ ).any()} and `inf`: {torch.isinf(snake_case__ )}. Dict has"""
f""" `nan`: {torch.isnan(snake_case__ ).any()} and `inf`: {torch.isinf(snake_case__ )}."""
) , )
recursive_check(snake_case__ , snake_case__ )
for model_class in self.all_model_classes:
snake_case : Optional[int] = model_class(snake_case__ )
model.to(snake_case__ )
model.eval()
snake_case : Union[str, Any] = self._prepare_for_class(snake_case__ , snake_case__ )
snake_case : Tuple = self._prepare_for_class(snake_case__ , snake_case__ )
check_equivalence(snake_case__ , snake_case__ , snake_case__ )
snake_case : Tuple = self._prepare_for_class(snake_case__ , snake_case__ , return_labels=snake_case__ )
snake_case : Optional[Any] = self._prepare_for_class(snake_case__ , snake_case__ , return_labels=snake_case__ )
check_equivalence(snake_case__ , snake_case__ , snake_case__ )
snake_case : Dict = self._prepare_for_class(snake_case__ , snake_case__ )
snake_case : List[Any] = self._prepare_for_class(snake_case__ , snake_case__ )
check_equivalence(snake_case__ , snake_case__ , snake_case__ , {"output_hidden_states": True} )
snake_case : Any = self._prepare_for_class(snake_case__ , snake_case__ , return_labels=snake_case__ )
snake_case : List[str] = self._prepare_for_class(snake_case__ , snake_case__ , return_labels=snake_case__ )
check_equivalence(snake_case__ , snake_case__ , snake_case__ , {"output_hidden_states": True} )
@require_torch
class UpperCAmelCase ( unittest.TestCase ,A_ ):
A__ : int = (MaskFormerSwinBackbone,) if is_torch_available() else ()
A__ : int = MaskFormerSwinConfig
def _SCREAMING_SNAKE_CASE (self : List[Any] ) -> Any:
'''simple docstring'''
snake_case : Union[str, Any] = MaskFormerSwinModelTester(self )
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> Optional[Any]:
'''simple docstring'''
snake_case , snake_case : Dict = self.model_tester.prepare_config_and_inputs_for_common()
snake_case : Optional[int] = inputs_dict["pixel_values"].shape[0]
for backbone_class in self.all_model_classes:
snake_case : Optional[int] = backbone_class(snake_case__ )
backbone.to(snake_case__ )
backbone.eval()
snake_case : Union[str, Any] = backbone(**snake_case__ )
# Test default outputs and verify feature maps
self.assertIsInstance(outputs.feature_maps , snake_case__ )
self.assertTrue(len(outputs.feature_maps ) == len(backbone.channels ) )
for feature_map, n_channels in zip(outputs.feature_maps , backbone.channels ):
self.assertTrue(feature_map.shape[:2] , (batch_size, n_channels) )
self.assertIsNone(outputs.hidden_states )
self.assertIsNone(outputs.attentions )
# Test output_hidden_states=True
snake_case : Optional[int] = backbone(**snake_case__ , output_hidden_states=snake_case__ )
self.assertIsNotNone(outputs.hidden_states )
self.assertTrue(len(outputs.hidden_states ) , len(backbone.stage_names ) )
# We skip the stem layer
for hidden_states, n_channels in zip(outputs.hidden_states[1:] , backbone.channels ):
for hidden_state in hidden_states:
# Hidden states are in the format (batch_size, (height * width), n_channels)
snake_case , snake_case , snake_case : Dict = hidden_state.shape
self.assertTrue((h_batch_size, h_n_channels) , (batch_size, n_channels) )
# Test output_attentions=True
if self.has_attentions:
snake_case : Optional[Any] = backbone(**snake_case__ , output_attentions=snake_case__ )
self.assertIsNotNone(outputs.attentions )
| 59
| 1
|
from __future__ import annotations
__lowerCamelCase = list[list[int]]
# assigning initial values to the grid
__lowerCamelCase = [
[3, 0, 6, 5, 0, 8, 4, 0, 0],
[5, 2, 0, 0, 0, 0, 0, 0, 0],
[0, 8, 7, 0, 0, 0, 0, 3, 1],
[0, 0, 3, 0, 1, 0, 0, 8, 0],
[9, 0, 0, 8, 6, 3, 0, 0, 5],
[0, 5, 0, 0, 9, 0, 6, 0, 0],
[1, 3, 0, 0, 0, 0, 2, 5, 0],
[0, 0, 0, 0, 0, 0, 0, 7, 4],
[0, 0, 5, 2, 0, 6, 3, 0, 0],
]
# a grid with no solution
__lowerCamelCase = [
[5, 0, 6, 5, 0, 8, 4, 0, 3],
[5, 2, 0, 0, 0, 0, 0, 0, 2],
[1, 8, 7, 0, 0, 0, 0, 3, 1],
[0, 0, 3, 0, 1, 0, 0, 8, 0],
[9, 0, 0, 8, 6, 3, 0, 0, 5],
[0, 5, 0, 0, 9, 0, 6, 0, 0],
[1, 3, 0, 0, 0, 0, 2, 5, 0],
[0, 0, 0, 0, 0, 0, 0, 7, 4],
[0, 0, 5, 2, 0, 6, 3, 0, 0],
]
def UpperCamelCase ( __lowerCamelCase : Matrix , __lowerCamelCase : int , __lowerCamelCase : int , __lowerCamelCase : int ):
for i in range(9 ):
if grid[row][i] == n or grid[i][column] == n:
return False
for i in range(3 ):
for j in range(3 ):
if grid[(row - row % 3) + i][(column - column % 3) + j] == n:
return False
return True
def UpperCamelCase ( __lowerCamelCase : Matrix ):
for i in range(9 ):
for j in range(9 ):
if grid[i][j] == 0:
return i, j
return None
def UpperCamelCase ( __lowerCamelCase : Matrix ):
if location := find_empty_location(__lowerCamelCase ):
snake_case , snake_case : Union[str, Any] = location
else:
# If the location is ``None``, then the grid is solved.
return grid
for digit in range(1 , 10 ):
if is_safe(__lowerCamelCase , __lowerCamelCase , __lowerCamelCase , __lowerCamelCase ):
snake_case : List[Any] = digit
if sudoku(__lowerCamelCase ) is not None:
return grid
snake_case : Union[str, Any] = 0
return None
def UpperCamelCase ( __lowerCamelCase : Matrix ):
for row in grid:
for cell in row:
print(__lowerCamelCase , end=" " )
print()
if __name__ == "__main__":
# make a copy of grid so that you can compare with the unmodified grid
for example_grid in (initial_grid, no_solution):
print("""\nExample grid:\n""" + """=""" * 20)
print_solution(example_grid)
print("""\nExample grid solution:""")
__lowerCamelCase = sudoku(example_grid)
if solution is not None:
print_solution(solution)
else:
print("""Cannot find a solution.""")
| 59
|
from typing import Dict
import numpy as np
import torch
from . import residue_constants as rc
from .tensor_utils import tensor_tree_map, tree_map
def UpperCamelCase ( __lowerCamelCase : Dict[str, torch.Tensor] ):
snake_case : List[str] = []
snake_case : Optional[int] = []
snake_case : Any = []
for rt in rc.restypes:
snake_case : List[Any] = rc.restype_name_to_atomaa_names[rc.restype_atoa[rt]]
restype_atomaa_to_atomaa_list.append([(rc.atom_order[name] if name else 0) for name in atom_names] )
snake_case : str = {name: i for i, name in enumerate(__lowerCamelCase )}
restype_atomaa_to_atomaa_list.append(
[(atom_name_to_idxaa[name] if name in atom_name_to_idxaa else 0) for name in rc.atom_types] )
restype_atomaa_mask_list.append([(1.0 if name else 0.0) for name in atom_names] )
# Add dummy mapping for restype 'UNK'
restype_atomaa_to_atomaa_list.append([0] * 14 )
restype_atomaa_to_atomaa_list.append([0] * 37 )
restype_atomaa_mask_list.append([0.0] * 14 )
snake_case : Optional[Any] = torch.tensor(
__lowerCamelCase , dtype=torch.intaa , device=protein["aatype"].device , )
snake_case : List[Any] = torch.tensor(
__lowerCamelCase , dtype=torch.intaa , device=protein["aatype"].device , )
snake_case : int = torch.tensor(
__lowerCamelCase , dtype=torch.floataa , device=protein["aatype"].device , )
snake_case : int = protein["aatype"].to(torch.long )
# create the mapping for (residx, atom14) --> atom37, i.e. an array
# with shape (num_res, 14) containing the atom37 indices for this protein
snake_case : List[Any] = restype_atomaa_to_atomaa[protein_aatype]
snake_case : str = restype_atomaa_mask[protein_aatype]
snake_case : str = residx_atomaa_mask
snake_case : Any = residx_atomaa_to_atomaa.long()
# create the gather indices for mapping back
snake_case : List[str] = restype_atomaa_to_atomaa[protein_aatype]
snake_case : List[Any] = residx_atomaa_to_atomaa.long()
# create the corresponding mask
snake_case : Union[str, Any] = torch.zeros([21, 37] , dtype=torch.floataa , device=protein["aatype"].device )
for restype, restype_letter in enumerate(rc.restypes ):
snake_case : Optional[int] = rc.restype_atoa[restype_letter]
snake_case : Any = rc.residue_atoms[restype_name]
for atom_name in atom_names:
snake_case : List[Any] = rc.atom_order[atom_name]
snake_case : Optional[Any] = 1
snake_case : List[Any] = restype_atomaa_mask[protein_aatype]
snake_case : int = residx_atomaa_mask
return protein
def UpperCamelCase ( __lowerCamelCase : Dict[str, torch.Tensor] ):
snake_case : Dict = tree_map(lambda __lowerCamelCase : torch.tensor(__lowerCamelCase , device=batch["aatype"].device ) , __lowerCamelCase , np.ndarray )
snake_case : List[str] = tensor_tree_map(lambda __lowerCamelCase : np.array(__lowerCamelCase ) , make_atomaa_masks(__lowerCamelCase ) )
return out
| 59
| 1
|
from typing import Dict
import numpy as np
import torch
from . import residue_constants as rc
from .tensor_utils import tensor_tree_map, tree_map
def UpperCamelCase ( __lowerCamelCase : Dict[str, torch.Tensor] ):
snake_case : List[str] = []
snake_case : Optional[int] = []
snake_case : Any = []
for rt in rc.restypes:
snake_case : List[Any] = rc.restype_name_to_atomaa_names[rc.restype_atoa[rt]]
restype_atomaa_to_atomaa_list.append([(rc.atom_order[name] if name else 0) for name in atom_names] )
snake_case : str = {name: i for i, name in enumerate(__lowerCamelCase )}
restype_atomaa_to_atomaa_list.append(
[(atom_name_to_idxaa[name] if name in atom_name_to_idxaa else 0) for name in rc.atom_types] )
restype_atomaa_mask_list.append([(1.0 if name else 0.0) for name in atom_names] )
# Add dummy mapping for restype 'UNK'
restype_atomaa_to_atomaa_list.append([0] * 14 )
restype_atomaa_to_atomaa_list.append([0] * 37 )
restype_atomaa_mask_list.append([0.0] * 14 )
snake_case : Optional[Any] = torch.tensor(
__lowerCamelCase , dtype=torch.intaa , device=protein["aatype"].device , )
snake_case : List[Any] = torch.tensor(
__lowerCamelCase , dtype=torch.intaa , device=protein["aatype"].device , )
snake_case : int = torch.tensor(
__lowerCamelCase , dtype=torch.floataa , device=protein["aatype"].device , )
snake_case : int = protein["aatype"].to(torch.long )
# create the mapping for (residx, atom14) --> atom37, i.e. an array
# with shape (num_res, 14) containing the atom37 indices for this protein
snake_case : List[Any] = restype_atomaa_to_atomaa[protein_aatype]
snake_case : str = restype_atomaa_mask[protein_aatype]
snake_case : str = residx_atomaa_mask
snake_case : Any = residx_atomaa_to_atomaa.long()
# create the gather indices for mapping back
snake_case : List[str] = restype_atomaa_to_atomaa[protein_aatype]
snake_case : List[Any] = residx_atomaa_to_atomaa.long()
# create the corresponding mask
snake_case : Union[str, Any] = torch.zeros([21, 37] , dtype=torch.floataa , device=protein["aatype"].device )
for restype, restype_letter in enumerate(rc.restypes ):
snake_case : Optional[int] = rc.restype_atoa[restype_letter]
snake_case : Any = rc.residue_atoms[restype_name]
for atom_name in atom_names:
snake_case : List[Any] = rc.atom_order[atom_name]
snake_case : Optional[Any] = 1
snake_case : List[Any] = restype_atomaa_mask[protein_aatype]
snake_case : int = residx_atomaa_mask
return protein
def UpperCamelCase ( __lowerCamelCase : Dict[str, torch.Tensor] ):
snake_case : Dict = tree_map(lambda __lowerCamelCase : torch.tensor(__lowerCamelCase , device=batch["aatype"].device ) , __lowerCamelCase , np.ndarray )
snake_case : List[str] = tensor_tree_map(lambda __lowerCamelCase : np.array(__lowerCamelCase ) , make_atomaa_masks(__lowerCamelCase ) )
return out
| 59
|
import json
from typing import List, Optional, Tuple
from tokenizers import normalizers
from ...tokenization_utils_fast import PreTrainedTokenizerFast
from .tokenization_lxmert import LxmertTokenizer
__lowerCamelCase = {"""vocab_file""": """vocab.txt""", """tokenizer_file""": """tokenizer.json"""}
__lowerCamelCase = {
"""vocab_file""": {
"""unc-nlp/lxmert-base-uncased""": """https://huggingface.co/unc-nlp/lxmert-base-uncased/resolve/main/vocab.txt""",
},
"""tokenizer_file""": {
"""unc-nlp/lxmert-base-uncased""": (
"""https://huggingface.co/unc-nlp/lxmert-base-uncased/resolve/main/tokenizer.json"""
),
},
}
__lowerCamelCase = {
"""unc-nlp/lxmert-base-uncased""": 5_12,
}
__lowerCamelCase = {
"""unc-nlp/lxmert-base-uncased""": {"""do_lower_case""": True},
}
class UpperCAmelCase ( A_ ):
A__ : Any = VOCAB_FILES_NAMES
A__ : Optional[int] = PRETRAINED_VOCAB_FILES_MAP
A__ : Tuple = PRETRAINED_INIT_CONFIGURATION
A__ : Tuple = PRETRAINED_POSITIONAL_EMBEDDINGS_SIZES
A__ : List[Any] = LxmertTokenizer
def __init__(self : Dict , snake_case__ : Tuple=None , snake_case__ : Optional[Any]=None , snake_case__ : Optional[Any]=True , snake_case__ : Tuple="[UNK]" , snake_case__ : Optional[Any]="[SEP]" , snake_case__ : Optional[Any]="[PAD]" , snake_case__ : List[Any]="[CLS]" , snake_case__ : Tuple="[MASK]" , snake_case__ : Dict=True , snake_case__ : Union[str, Any]=None , **snake_case__ : Dict , ) -> Optional[int]:
'''simple docstring'''
super().__init__(
snake_case__ , tokenizer_file=snake_case__ , do_lower_case=snake_case__ , unk_token=snake_case__ , sep_token=snake_case__ , pad_token=snake_case__ , cls_token=snake_case__ , mask_token=snake_case__ , tokenize_chinese_chars=snake_case__ , strip_accents=snake_case__ , **snake_case__ , )
snake_case : int = json.loads(self.backend_tokenizer.normalizer.__getstate__() )
if (
normalizer_state.get("lowercase" , snake_case__ ) != do_lower_case
or normalizer_state.get("strip_accents" , snake_case__ ) != strip_accents
or normalizer_state.get("handle_chinese_chars" , snake_case__ ) != tokenize_chinese_chars
):
snake_case : Union[str, Any] = getattr(snake_case__ , normalizer_state.pop("type" ) )
snake_case : str = do_lower_case
snake_case : List[Any] = strip_accents
snake_case : Optional[int] = tokenize_chinese_chars
snake_case : int = normalizer_class(**snake_case__ )
snake_case : Optional[Any] = do_lower_case
def _SCREAMING_SNAKE_CASE (self : Union[str, Any] , snake_case__ : Optional[Any] , snake_case__ : Dict=None ) -> Any:
'''simple docstring'''
snake_case : Optional[int] = [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 _SCREAMING_SNAKE_CASE (self : Optional[int] , snake_case__ : List[int] , snake_case__ : Optional[List[int]] = None ) -> List[int]:
'''simple docstring'''
snake_case : Optional[Any] = [self.sep_token_id]
snake_case : Optional[Any] = [self.cls_token_id]
if token_ids_a is None:
return len(cls + token_ids_a + sep ) * [0]
return len(cls + token_ids_a + sep ) * [0] + len(token_ids_a + sep ) * [1]
def _SCREAMING_SNAKE_CASE (self : Any , snake_case__ : str , snake_case__ : Optional[str] = None ) -> Tuple[str]:
'''simple docstring'''
snake_case : List[Any] = self._tokenizer.model.save(snake_case__ , name=snake_case__ )
return tuple(snake_case__ )
| 59
| 1
|
import unicodedata
from dataclasses import dataclass
from typing import Optional, Union
import numpy as np
from transformers.data.data_collator import DataCollatorMixin
from transformers.file_utils import PaddingStrategy
from transformers.tokenization_utils_base import PreTrainedTokenizerBase
def UpperCamelCase ( __lowerCamelCase : Dict , __lowerCamelCase : int , __lowerCamelCase : Dict , __lowerCamelCase : Any ):
if isinstance(__lowerCamelCase , __lowerCamelCase ):
snake_case : int = np.full((len(__lowerCamelCase ), sequence_length, 2) , __lowerCamelCase )
else:
snake_case : List[Any] = np.full((len(__lowerCamelCase ), sequence_length) , __lowerCamelCase )
for i, tensor in enumerate(__lowerCamelCase ):
if padding_side == "right":
if isinstance(__lowerCamelCase , __lowerCamelCase ):
snake_case : Dict = tensor[:sequence_length]
else:
snake_case : Tuple = tensor[:sequence_length]
else:
if isinstance(__lowerCamelCase , __lowerCamelCase ):
snake_case : str = tensor[:sequence_length]
else:
snake_case : Optional[int] = tensor[:sequence_length]
return out_tensor.tolist()
def UpperCamelCase ( __lowerCamelCase : List[Any] ):
snake_case : Any = ord(__lowerCamelCase )
if (cp >= 33 and cp <= 47) or (cp >= 58 and cp <= 64) or (cp >= 91 and cp <= 96) or (cp >= 123 and cp <= 126):
return True
snake_case : List[str] = unicodedata.category(__lowerCamelCase )
if cat.startswith("P" ):
return True
return False
@dataclass
class UpperCAmelCase ( A_ ):
A__ : PreTrainedTokenizerBase
A__ : Union[bool, str, PaddingStrategy] = True
A__ : Optional[int] = None
A__ : Optional[int] = None
A__ : int = -1_00
A__ : str = "pt"
def _SCREAMING_SNAKE_CASE (self : Tuple , snake_case__ : Tuple ) -> int:
'''simple docstring'''
import torch
snake_case : Optional[Any] = "label" if "label" in features[0].keys() else "labels"
snake_case : str = [feature[label_name] for feature in features] if label_name in features[0].keys() else None
snake_case : List[Any] = self.tokenizer.pad(
snake_case__ , padding=self.padding , max_length=self.max_length , pad_to_multiple_of=self.pad_to_multiple_of , return_tensors="pt" if labels is None else None , )
if labels is None:
return batch
snake_case : int = torch.tensor(batch["entity_ids"] ).shape[1]
snake_case : List[Any] = self.tokenizer.padding_side
if padding_side == "right":
snake_case : Tuple = [
list(snake_case__ ) + [self.label_pad_token_id] * (sequence_length - len(snake_case__ )) for label in labels
]
else:
snake_case : str = [
[self.label_pad_token_id] * (sequence_length - len(snake_case__ )) + list(snake_case__ ) for label in labels
]
snake_case : int = [feature["ner_tags"] for feature in features]
snake_case : int = padding_tensor(snake_case__ , -1 , snake_case__ , snake_case__ )
snake_case : str = [feature["original_entity_spans"] for feature in features]
snake_case : Dict = padding_tensor(snake_case__ , (-1, -1) , snake_case__ , snake_case__ )
snake_case : Dict = {k: torch.tensor(snake_case__ , dtype=torch.intaa ) for k, v in batch.items()}
return batch
| 59
|
import torch
from diffusers import DDIMParallelScheduler
from .test_schedulers import SchedulerCommonTest
class UpperCAmelCase ( A_ ):
A__ : Dict = (DDIMParallelScheduler,)
A__ : Tuple = (("eta", 0.0), ("num_inference_steps", 50))
def _SCREAMING_SNAKE_CASE (self : Tuple , **snake_case__ : Optional[int] ) -> Optional[Any]:
'''simple docstring'''
snake_case : Any = {
"num_train_timesteps": 10_00,
"beta_start": 0.0001,
"beta_end": 0.02,
"beta_schedule": "linear",
"clip_sample": True,
}
config.update(**snake_case__ )
return config
def _SCREAMING_SNAKE_CASE (self : Dict , **snake_case__ : Optional[int] ) -> Any:
'''simple docstring'''
snake_case : List[Any] = self.scheduler_classes[0]
snake_case : Any = self.get_scheduler_config(**snake_case__ )
snake_case : Any = scheduler_class(**snake_case__ )
snake_case , snake_case : Union[str, Any] = 10, 0.0
snake_case : List[Any] = self.dummy_model()
snake_case : Any = self.dummy_sample_deter
scheduler.set_timesteps(snake_case__ )
for t in scheduler.timesteps:
snake_case : Optional[int] = model(snake_case__ , snake_case__ )
snake_case : List[str] = scheduler.step(snake_case__ , snake_case__ , snake_case__ , snake_case__ ).prev_sample
return sample
def _SCREAMING_SNAKE_CASE (self : Union[str, Any] ) -> str:
'''simple docstring'''
for timesteps in [1_00, 5_00, 10_00]:
self.check_over_configs(num_train_timesteps=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : str ) -> int:
'''simple docstring'''
for steps_offset in [0, 1]:
self.check_over_configs(steps_offset=snake_case__ )
snake_case : Optional[int] = self.scheduler_classes[0]
snake_case : Optional[int] = self.get_scheduler_config(steps_offset=1 )
snake_case : Union[str, Any] = scheduler_class(**snake_case__ )
scheduler.set_timesteps(5 )
assert torch.equal(scheduler.timesteps , torch.LongTensor([8_01, 6_01, 4_01, 2_01, 1] ) )
def _SCREAMING_SNAKE_CASE (self : int ) -> Tuple:
'''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=snake_case__ , beta_end=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Union[str, Any] ) -> Union[str, Any]:
'''simple docstring'''
for schedule in ["linear", "squaredcos_cap_v2"]:
self.check_over_configs(beta_schedule=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : str ) -> Dict:
'''simple docstring'''
for prediction_type in ["epsilon", "v_prediction"]:
self.check_over_configs(prediction_type=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Optional[Any] ) -> List[str]:
'''simple docstring'''
for clip_sample in [True, False]:
self.check_over_configs(clip_sample=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : List[Any] ) -> List[Any]:
'''simple docstring'''
for timestep_spacing in ["trailing", "leading"]:
self.check_over_configs(timestep_spacing=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> List[Any]:
'''simple docstring'''
for rescale_betas_zero_snr in [True, False]:
self.check_over_configs(rescale_betas_zero_snr=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Optional[Any] ) -> Optional[Any]:
'''simple docstring'''
self.check_over_configs(thresholding=snake_case__ )
for threshold in [0.5, 1.0, 2.0]:
for prediction_type in ["epsilon", "v_prediction"]:
self.check_over_configs(
thresholding=snake_case__ , prediction_type=snake_case__ , sample_max_value=snake_case__ , )
def _SCREAMING_SNAKE_CASE (self : Any ) -> Any:
'''simple docstring'''
for t in [1, 10, 49]:
self.check_over_forward(time_step=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> Any:
'''simple docstring'''
for t, num_inference_steps in zip([1, 10, 50] , [10, 50, 5_00] ):
self.check_over_forward(time_step=snake_case__ , num_inference_steps=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : List[str] ) -> Optional[Any]:
'''simple docstring'''
for t, eta in zip([1, 10, 49] , [0.0, 0.5, 1.0] ):
self.check_over_forward(time_step=snake_case__ , eta=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Optional[Any] ) -> Optional[int]:
'''simple docstring'''
snake_case : Dict = self.scheduler_classes[0]
snake_case : Tuple = self.get_scheduler_config()
snake_case : Dict = scheduler_class(**snake_case__ )
assert torch.sum(torch.abs(scheduler._get_variance(0 , 0 ) - 0.0 ) ) < 1e-5
assert torch.sum(torch.abs(scheduler._get_variance(4_20 , 4_00 ) - 0.14771 ) ) < 1e-5
assert torch.sum(torch.abs(scheduler._get_variance(9_80 , 9_60 ) - 0.32460 ) ) < 1e-5
assert torch.sum(torch.abs(scheduler._get_variance(0 , 0 ) - 0.0 ) ) < 1e-5
assert torch.sum(torch.abs(scheduler._get_variance(4_87 , 4_86 ) - 0.00979 ) ) < 1e-5
assert torch.sum(torch.abs(scheduler._get_variance(9_99 , 9_98 ) - 0.02 ) ) < 1e-5
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> Dict:
'''simple docstring'''
snake_case : Union[str, Any] = self.scheduler_classes[0]
snake_case : List[Any] = self.get_scheduler_config()
snake_case : int = scheduler_class(**snake_case__ )
snake_case , snake_case : Any = 10, 0.0
scheduler.set_timesteps(snake_case__ )
snake_case : Optional[Any] = self.dummy_model()
snake_case : str = self.dummy_sample_deter
snake_case : Dict = self.dummy_sample_deter + 0.1
snake_case : Dict = self.dummy_sample_deter - 0.1
snake_case : Optional[Any] = samplea.shape[0]
snake_case : str = torch.stack([samplea, samplea, samplea] , dim=0 )
snake_case : Tuple = torch.arange(snake_case__ )[0:3, None].repeat(1 , snake_case__ )
snake_case : Tuple = model(samples.flatten(0 , 1 ) , timesteps.flatten(0 , 1 ) )
snake_case : List[str] = scheduler.batch_step_no_noise(snake_case__ , timesteps.flatten(0 , 1 ) , samples.flatten(0 , 1 ) , snake_case__ )
snake_case : Dict = torch.sum(torch.abs(snake_case__ ) )
snake_case : List[Any] = torch.mean(torch.abs(snake_case__ ) )
assert abs(result_sum.item() - 1147.7904 ) < 1e-2
assert abs(result_mean.item() - 0.4982 ) < 1e-3
def _SCREAMING_SNAKE_CASE (self : Optional[Any] ) -> Optional[Any]:
'''simple docstring'''
snake_case : List[Any] = self.full_loop()
snake_case : Optional[Any] = torch.sum(torch.abs(snake_case__ ) )
snake_case : List[Any] = torch.mean(torch.abs(snake_case__ ) )
assert abs(result_sum.item() - 172.0067 ) < 1e-2
assert abs(result_mean.item() - 0.223967 ) < 1e-3
def _SCREAMING_SNAKE_CASE (self : str ) -> Union[str, Any]:
'''simple docstring'''
snake_case : Dict = self.full_loop(prediction_type="v_prediction" )
snake_case : int = torch.sum(torch.abs(snake_case__ ) )
snake_case : Optional[int] = torch.mean(torch.abs(snake_case__ ) )
assert abs(result_sum.item() - 52.5302 ) < 1e-2
assert abs(result_mean.item() - 0.0684 ) < 1e-3
def _SCREAMING_SNAKE_CASE (self : Any ) -> Optional[Any]:
'''simple docstring'''
snake_case : Dict = self.full_loop(set_alpha_to_one=snake_case__ , beta_start=0.01 )
snake_case : str = torch.sum(torch.abs(snake_case__ ) )
snake_case : Optional[Any] = torch.mean(torch.abs(snake_case__ ) )
assert abs(result_sum.item() - 149.8295 ) < 1e-2
assert abs(result_mean.item() - 0.1951 ) < 1e-3
def _SCREAMING_SNAKE_CASE (self : int ) -> Optional[Any]:
'''simple docstring'''
snake_case : int = self.full_loop(set_alpha_to_one=snake_case__ , beta_start=0.01 )
snake_case : Tuple = torch.sum(torch.abs(snake_case__ ) )
snake_case : List[Any] = torch.mean(torch.abs(snake_case__ ) )
assert abs(result_sum.item() - 149.0784 ) < 1e-2
assert abs(result_mean.item() - 0.1941 ) < 1e-3
| 59
| 1
|
# DISCLAIMER: This code is strongly influenced by https://github.com/pesser/pytorch_diffusion
# and https://github.com/hojonathanho/diffusion
import math
from dataclasses import dataclass
from typing import List, Optional, Tuple, Union
import numpy as np
import torch
from diffusers.configuration_utils import ConfigMixin, register_to_config
from diffusers.schedulers.scheduling_utils import SchedulerMixin
from diffusers.utils import BaseOutput, deprecate
@dataclass
# Copied from diffusers.schedulers.scheduling_ddpm.DDPMSchedulerOutput with DDPM->DDIM
class UpperCAmelCase ( A_ ):
A__ : torch.FloatTensor
A__ : Optional[torch.FloatTensor] = None
def UpperCamelCase ( __lowerCamelCase : Union[str, Any] , __lowerCamelCase : Any=0.999 , __lowerCamelCase : Optional[Any]="cosine" , ):
if alpha_transform_type == "cosine":
def alpha_bar_fn(__lowerCamelCase : List[str] ):
return math.cos((t + 0.008) / 1.008 * math.pi / 2 ) ** 2
elif alpha_transform_type == "exp":
def alpha_bar_fn(__lowerCamelCase : List[str] ):
return math.exp(t * -12.0 )
else:
raise ValueError(f"""Unsupported alpha_tranform_type: {alpha_transform_type}""" )
snake_case : Optional[int] = []
for i in range(__lowerCamelCase ):
snake_case : Optional[int] = i / num_diffusion_timesteps
snake_case : Tuple = (i + 1) / num_diffusion_timesteps
betas.append(min(1 - alpha_bar_fn(__lowerCamelCase ) / alpha_bar_fn(__lowerCamelCase ) , __lowerCamelCase ) )
return torch.tensor(__lowerCamelCase , dtype=torch.floataa )
class UpperCAmelCase ( A_ ,A_ ):
A__ : Union[str, Any] = 1
@register_to_config
def __init__(self : Optional[int] , snake_case__ : int = 10_00 , snake_case__ : float = 0.0001 , snake_case__ : float = 0.02 , snake_case__ : str = "linear" , snake_case__ : Optional[Union[np.ndarray, List[float]]] = None , snake_case__ : bool = True , snake_case__ : bool = True , snake_case__ : int = 0 , snake_case__ : str = "epsilon" , snake_case__ : float = 1.0 , **snake_case__ : Union[str, Any] , ) -> Optional[Any]:
'''simple docstring'''
if kwargs.get("set_alpha_to_one" , snake_case__ ) is not None:
snake_case : Dict = (
"The `set_alpha_to_one` argument is deprecated. Please use `set_alpha_to_zero` instead."
)
deprecate("set_alpha_to_one" , "1.0.0" , snake_case__ , standard_warn=snake_case__ )
snake_case : Optional[Any] = kwargs["set_alpha_to_one"]
if trained_betas is not None:
snake_case : Optional[Any] = torch.tensor(snake_case__ , dtype=torch.floataa )
elif beta_schedule == "linear":
snake_case : List[str] = torch.linspace(snake_case__ , snake_case__ , snake_case__ , dtype=torch.floataa )
elif beta_schedule == "scaled_linear":
# this schedule is very specific to the latent diffusion model.
snake_case : Tuple = (
torch.linspace(beta_start**0.5 , beta_end**0.5 , snake_case__ , dtype=torch.floataa ) ** 2
)
elif beta_schedule == "squaredcos_cap_v2":
# Glide cosine schedule
snake_case : Tuple = betas_for_alpha_bar(snake_case__ )
else:
raise NotImplementedError(f"""{beta_schedule} does is not implemented for {self.__class__}""" )
snake_case : Tuple = 1.0 - self.betas
snake_case : int = torch.cumprod(self.alphas , dim=0 )
# At every step in inverted ddim, we are looking into the next alphas_cumprod
# For the final step, there is no next alphas_cumprod, and the index is out of bounds
# `set_alpha_to_zero` decides whether we set this parameter simply to zero
# in this case, self.step() just output the predicted noise
# or whether we use the final alpha of the "non-previous" one.
snake_case : Any = torch.tensor(0.0 ) if set_alpha_to_zero else self.alphas_cumprod[-1]
# standard deviation of the initial noise distribution
snake_case : List[Any] = 1.0
# setable values
snake_case : Optional[int] = None
snake_case : List[Any] = torch.from_numpy(np.arange(0 , snake_case__ ).copy().astype(np.intaa ) )
def _SCREAMING_SNAKE_CASE (self : int , snake_case__ : torch.FloatTensor , snake_case__ : Optional[int] = None ) -> torch.FloatTensor:
'''simple docstring'''
return sample
def _SCREAMING_SNAKE_CASE (self : List[str] , snake_case__ : int , snake_case__ : Union[str, torch.device] = None ) -> Any:
'''simple docstring'''
if num_inference_steps > self.config.num_train_timesteps:
raise ValueError(
f"""`num_inference_steps`: {num_inference_steps} cannot be larger than `self.config.train_timesteps`:"""
f""" {self.config.num_train_timesteps} as the unet model trained with this scheduler can only handle"""
f""" maximal {self.config.num_train_timesteps} timesteps.""" )
snake_case : Union[str, Any] = num_inference_steps
snake_case : Union[str, Any] = self.config.num_train_timesteps // self.num_inference_steps
# creates integer timesteps by multiplying by ratio
# casting to int to avoid issues when num_inference_step is power of 3
snake_case : Optional[Any] = (np.arange(0 , snake_case__ ) * step_ratio).round().copy().astype(np.intaa )
snake_case : Optional[Any] = torch.from_numpy(snake_case__ ).to(snake_case__ )
self.timesteps += self.config.steps_offset
def _SCREAMING_SNAKE_CASE (self : Optional[int] , snake_case__ : torch.FloatTensor , snake_case__ : int , snake_case__ : torch.FloatTensor , snake_case__ : float = 0.0 , snake_case__ : bool = False , snake_case__ : Optional[torch.FloatTensor] = None , snake_case__ : bool = True , ) -> Union[DDIMSchedulerOutput, Tuple]:
'''simple docstring'''
snake_case : Tuple = timestep + self.config.num_train_timesteps // self.num_inference_steps
# 2. compute alphas, betas
# change original implementation to exactly match noise levels for analogous forward process
snake_case : str = self.alphas_cumprod[timestep]
snake_case : Union[str, Any] = (
self.alphas_cumprod[prev_timestep]
if prev_timestep < self.config.num_train_timesteps
else self.final_alpha_cumprod
)
snake_case : Optional[int] = 1 - alpha_prod_t
# 3. compute predicted original sample from predicted noise also called
# "predicted x_0" of formula (12) from https://arxiv.org/pdf/2010.02502.pdf
if self.config.prediction_type == "epsilon":
snake_case : List[str] = (sample - beta_prod_t ** 0.5 * model_output) / alpha_prod_t ** 0.5
snake_case : Optional[int] = model_output
elif self.config.prediction_type == "sample":
snake_case : Optional[Any] = model_output
snake_case : Optional[Any] = (sample - alpha_prod_t ** 0.5 * pred_original_sample) / beta_prod_t ** 0.5
elif self.config.prediction_type == "v_prediction":
snake_case : Dict = (alpha_prod_t**0.5) * sample - (beta_prod_t**0.5) * model_output
snake_case : str = (alpha_prod_t**0.5) * model_output + (beta_prod_t**0.5) * sample
else:
raise ValueError(
f"""prediction_type given as {self.config.prediction_type} must be one of `epsilon`, `sample`, or"""
" `v_prediction`" )
# 4. Clip or threshold "predicted x_0"
if self.config.clip_sample:
snake_case : Tuple = pred_original_sample.clamp(
-self.config.clip_sample_range , self.config.clip_sample_range )
# 5. compute "direction pointing to x_t" of formula (12) from https://arxiv.org/pdf/2010.02502.pdf
snake_case : Any = (1 - alpha_prod_t_prev) ** 0.5 * pred_epsilon
# 6. compute x_t without "random noise" of formula (12) from https://arxiv.org/pdf/2010.02502.pdf
snake_case : str = alpha_prod_t_prev ** 0.5 * pred_original_sample + pred_sample_direction
if not return_dict:
return (prev_sample, pred_original_sample)
return DDIMSchedulerOutput(prev_sample=snake_case__ , pred_original_sample=snake_case__ )
def __len__(self : Dict ) -> Optional[Any]:
'''simple docstring'''
return self.config.num_train_timesteps
| 59
|
def UpperCamelCase ( __lowerCamelCase : str , __lowerCamelCase : int ):
snake_case : list[list[str]] = [[] for _ in range(__lowerCamelCase )]
snake_case : int = key - 1
if key <= 0:
raise ValueError("Height of grid can't be 0 or negative" )
if key == 1 or len(__lowerCamelCase ) <= key:
return input_string
for position, character in enumerate(__lowerCamelCase ):
snake_case : Any = position % (lowest * 2) # puts it in bounds
snake_case : Optional[int] = min(__lowerCamelCase , lowest * 2 - num ) # creates zigzag pattern
temp_grid[num].append(__lowerCamelCase )
snake_case : List[str] = ["".join(__lowerCamelCase ) for row in temp_grid]
snake_case : Tuple = "".join(__lowerCamelCase )
return output_string
def UpperCamelCase ( __lowerCamelCase : str , __lowerCamelCase : int ):
snake_case : Dict = []
snake_case : Union[str, Any] = key - 1
if key <= 0:
raise ValueError("Height of grid can't be 0 or negative" )
if key == 1:
return input_string
snake_case : list[list[str]] = [[] for _ in range(__lowerCamelCase )] # generates template
for position in range(len(__lowerCamelCase ) ):
snake_case : List[str] = position % (lowest * 2) # puts it in bounds
snake_case : Optional[int] = min(__lowerCamelCase , lowest * 2 - num ) # creates zigzag pattern
temp_grid[num].append("*" )
snake_case : Tuple = 0
for row in temp_grid: # fills in the characters
snake_case : Union[str, Any] = input_string[counter : counter + len(__lowerCamelCase )]
grid.append(list(__lowerCamelCase ) )
counter += len(__lowerCamelCase )
snake_case : str = "" # reads as zigzag
for position in range(len(__lowerCamelCase ) ):
snake_case : Optional[int] = position % (lowest * 2) # puts it in bounds
snake_case : Tuple = min(__lowerCamelCase , lowest * 2 - num ) # creates zigzag pattern
output_string += grid[num][0]
grid[num].pop(0 )
return output_string
def UpperCamelCase ( __lowerCamelCase : str ):
snake_case : Tuple = {}
for key_guess in range(1 , len(__lowerCamelCase ) ): # tries every key
snake_case : Any = decrypt(__lowerCamelCase , __lowerCamelCase )
return results
if __name__ == "__main__":
import doctest
doctest.testmod()
| 59
| 1
|
from typing import Any
import numpy as np
def UpperCamelCase ( __lowerCamelCase : np.ndarray ):
return np.array_equal(__lowerCamelCase , matrix.conjugate().T )
def UpperCamelCase ( __lowerCamelCase : np.ndarray , __lowerCamelCase : np.ndarray ):
snake_case : Tuple = v.conjugate().T
snake_case : Tuple = v_star.dot(__lowerCamelCase )
assert isinstance(__lowerCamelCase , np.ndarray )
return (v_star_dot.dot(__lowerCamelCase )) / (v_star.dot(__lowerCamelCase ))
def UpperCamelCase ( ):
snake_case : int = np.array([[2, 2 + 1j, 4], [2 - 1j, 3, 1j], [4, -1j, 1]] )
snake_case : int = np.array([[1], [2], [3]] )
assert is_hermitian(__lowerCamelCase ), f"""{a} is not hermitian."""
print(rayleigh_quotient(__lowerCamelCase , __lowerCamelCase ) )
snake_case : Dict = np.array([[1, 2, 4], [2, 3, -1], [4, -1, 1]] )
assert is_hermitian(__lowerCamelCase ), f"""{a} is not hermitian."""
assert rayleigh_quotient(__lowerCamelCase , __lowerCamelCase ) == float(3 )
if __name__ == "__main__":
import doctest
doctest.testmod()
tests()
| 59
|
from typing import TYPE_CHECKING
from ...utils import (
OptionalDependencyNotAvailable,
_LazyModule,
is_flax_available,
is_sentencepiece_available,
is_tf_available,
is_tokenizers_available,
is_torch_available,
)
if is_sentencepiece_available():
from ..ta.tokenization_ta import TaTokenizer
else:
from ...utils.dummy_sentencepiece_objects import TaTokenizer
__lowerCamelCase = TaTokenizer
if is_tokenizers_available():
from ..ta.tokenization_ta_fast import TaTokenizerFast
else:
from ...utils.dummy_tokenizers_objects import TaTokenizerFast
__lowerCamelCase = TaTokenizerFast
__lowerCamelCase = {"""configuration_mt5""": ["""MT5Config""", """MT5OnnxConfig"""]}
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = [
"""MT5EncoderModel""",
"""MT5ForConditionalGeneration""",
"""MT5ForQuestionAnswering""",
"""MT5Model""",
"""MT5PreTrainedModel""",
"""MT5Stack""",
]
try:
if not is_tf_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = ["""TFMT5EncoderModel""", """TFMT5ForConditionalGeneration""", """TFMT5Model"""]
try:
if not is_flax_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = ["""FlaxMT5EncoderModel""", """FlaxMT5ForConditionalGeneration""", """FlaxMT5Model"""]
if TYPE_CHECKING:
from .configuration_mta import MTaConfig, MTaOnnxConfig
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_mta import (
MTaEncoderModel,
MTaForConditionalGeneration,
MTaForQuestionAnswering,
MTaModel,
MTaPreTrainedModel,
MTaStack,
)
try:
if not is_tf_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_tf_mta import TFMTaEncoderModel, TFMTaForConditionalGeneration, TFMTaModel
try:
if not is_flax_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_flax_mta import FlaxMTaEncoderModel, FlaxMTaForConditionalGeneration, FlaxMTaModel
else:
import sys
__lowerCamelCase = _LazyModule(
__name__,
globals()["""__file__"""],
_import_structure,
extra_objects={"""MT5Tokenizer""": MTaTokenizer, """MT5TokenizerFast""": MTaTokenizerFast},
module_spec=__spec__,
)
| 59
| 1
|
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 UpperCAmelCase ( unittest.TestCase ):
def _SCREAMING_SNAKE_CASE (self : int ) -> str:
'''simple docstring'''
super().tearDown()
gc.collect()
def _SCREAMING_SNAKE_CASE (self : List[Any] ) -> List[Any]:
'''simple docstring'''
snake_case , snake_case : Union[str, Any] = FlaxStableDiffusionPipeline.from_pretrained(
"stabilityai/stable-diffusion-2" , revision="bf16" , dtype=jnp.bfloataa , )
snake_case : List[str] = "A painting of a squirrel eating a burger"
snake_case : Any = jax.device_count()
snake_case : Tuple = num_samples * [prompt]
snake_case : Tuple = sd_pipe.prepare_inputs(snake_case__ )
snake_case : Optional[Any] = replicate(snake_case__ )
snake_case : Any = shard(snake_case__ )
snake_case : Any = jax.random.PRNGKey(0 )
snake_case : str = jax.random.split(snake_case__ , jax.device_count() )
snake_case : Dict = sd_pipe(snake_case__ , snake_case__ , snake_case__ , num_inference_steps=25 , jit=snake_case__ )[0]
assert images.shape == (jax.device_count(), 1, 7_68, 7_68, 3)
snake_case : Dict = images.reshape((images.shape[0] * images.shape[1],) + images.shape[-3:] )
snake_case : Optional[int] = images[0, 2_53:2_56, 2_53:2_56, -1]
snake_case : Union[str, Any] = jnp.asarray(jax.device_get(image_slice.flatten() ) )
snake_case : str = jnp.array([0.4238, 0.4414, 0.4395, 0.4453, 0.4629, 0.4590, 0.4531, 0.45508, 0.4512] )
print(f"""output_slice: {output_slice}""" )
assert jnp.abs(output_slice - expected_slice ).max() < 1e-2
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> Optional[int]:
'''simple docstring'''
snake_case : Dict = "stabilityai/stable-diffusion-2"
snake_case , snake_case : str = FlaxDPMSolverMultistepScheduler.from_pretrained(snake_case__ , subfolder="scheduler" )
snake_case , snake_case : Any = FlaxStableDiffusionPipeline.from_pretrained(
snake_case__ , scheduler=snake_case__ , revision="bf16" , dtype=jnp.bfloataa , )
snake_case : int = scheduler_params
snake_case : Optional[int] = "A painting of a squirrel eating a burger"
snake_case : Any = jax.device_count()
snake_case : str = num_samples * [prompt]
snake_case : List[Any] = sd_pipe.prepare_inputs(snake_case__ )
snake_case : Union[str, Any] = replicate(snake_case__ )
snake_case : str = shard(snake_case__ )
snake_case : Dict = jax.random.PRNGKey(0 )
snake_case : Union[str, Any] = jax.random.split(snake_case__ , jax.device_count() )
snake_case : Union[str, Any] = sd_pipe(snake_case__ , snake_case__ , snake_case__ , num_inference_steps=25 , jit=snake_case__ )[0]
assert images.shape == (jax.device_count(), 1, 7_68, 7_68, 3)
snake_case : Optional[Any] = images.reshape((images.shape[0] * images.shape[1],) + images.shape[-3:] )
snake_case : Dict = images[0, 2_53:2_56, 2_53:2_56, -1]
snake_case : Union[str, Any] = jnp.asarray(jax.device_get(image_slice.flatten() ) )
snake_case : str = jnp.array([0.4336, 0.42969, 0.4453, 0.4199, 0.4297, 0.4531, 0.4434, 0.4434, 0.4297] )
print(f"""output_slice: {output_slice}""" )
assert jnp.abs(output_slice - expected_slice ).max() < 1e-2
| 59
|
import os
import shutil
from pathlib import Path
from typing import Optional, Union
import numpy as np
from huggingface_hub import hf_hub_download
from ..utils import ONNX_EXTERNAL_WEIGHTS_NAME, ONNX_WEIGHTS_NAME, is_onnx_available, logging
if is_onnx_available():
import onnxruntime as ort
__lowerCamelCase = logging.get_logger(__name__)
__lowerCamelCase = {
"""tensor(bool)""": np.bool_,
"""tensor(int8)""": np.inta,
"""tensor(uint8)""": np.uinta,
"""tensor(int16)""": np.intaa,
"""tensor(uint16)""": np.uintaa,
"""tensor(int32)""": np.intaa,
"""tensor(uint32)""": np.uintaa,
"""tensor(int64)""": np.intaa,
"""tensor(uint64)""": np.uintaa,
"""tensor(float16)""": np.floataa,
"""tensor(float)""": np.floataa,
"""tensor(double)""": np.floataa,
}
class UpperCAmelCase :
def __init__(self : Optional[Any] , snake_case__ : Optional[Any]=None , **snake_case__ : Optional[Any] ) -> List[str]:
'''simple docstring'''
logger.info("`diffusers.OnnxRuntimeModel` is experimental and might change in the future." )
snake_case : Optional[Any] = model
snake_case : Dict = kwargs.get("model_save_dir" , snake_case__ )
snake_case : int = kwargs.get("latest_model_name" , snake_case__ )
def __call__(self : Tuple , **snake_case__ : str ) -> List[str]:
'''simple docstring'''
snake_case : Union[str, Any] = {k: np.array(snake_case__ ) for k, v in kwargs.items()}
return self.model.run(snake_case__ , snake_case__ )
@staticmethod
def _SCREAMING_SNAKE_CASE (snake_case__ : Union[str, Path] , snake_case__ : Optional[int]=None , snake_case__ : Optional[int]=None ) -> Any:
'''simple docstring'''
if provider is None:
logger.info("No onnxruntime provider specified, using CPUExecutionProvider" )
snake_case : Optional[int] = "CPUExecutionProvider"
return ort.InferenceSession(snake_case__ , providers=[provider] , sess_options=snake_case__ )
def _SCREAMING_SNAKE_CASE (self : List[Any] , snake_case__ : Union[str, Path] , snake_case__ : Optional[str] = None , **snake_case__ : Any ) -> List[Any]:
'''simple docstring'''
snake_case : Tuple = file_name if file_name is not None else ONNX_WEIGHTS_NAME
snake_case : Any = self.model_save_dir.joinpath(self.latest_model_name )
snake_case : str = Path(snake_case__ ).joinpath(snake_case__ )
try:
shutil.copyfile(snake_case__ , snake_case__ )
except shutil.SameFileError:
pass
# copy external weights (for models >2GB)
snake_case : List[str] = self.model_save_dir.joinpath(snake_case__ )
if src_path.exists():
snake_case : Tuple = Path(snake_case__ ).joinpath(snake_case__ )
try:
shutil.copyfile(snake_case__ , snake_case__ )
except shutil.SameFileError:
pass
def _SCREAMING_SNAKE_CASE (self : str , snake_case__ : Union[str, os.PathLike] , **snake_case__ : Optional[int] , ) -> str:
'''simple docstring'''
if os.path.isfile(snake_case__ ):
logger.error(f"""Provided path ({save_directory}) should be a directory, not a file""" )
return
os.makedirs(snake_case__ , exist_ok=snake_case__ )
# saving model weights/files
self._save_pretrained(snake_case__ , **snake_case__ )
@classmethod
def _SCREAMING_SNAKE_CASE (cls : Tuple , snake_case__ : Union[str, Path] , snake_case__ : Optional[Union[bool, str, None]] = None , snake_case__ : Optional[Union[str, None]] = None , snake_case__ : bool = False , snake_case__ : Optional[str] = None , snake_case__ : Optional[str] = None , snake_case__ : Optional[str] = None , snake_case__ : Optional["ort.SessionOptions"] = None , **snake_case__ : Tuple , ) -> Tuple:
'''simple docstring'''
snake_case : List[str] = file_name if file_name is not None else ONNX_WEIGHTS_NAME
# load model from local directory
if os.path.isdir(snake_case__ ):
snake_case : Any = OnnxRuntimeModel.load_model(
os.path.join(snake_case__ , snake_case__ ) , provider=snake_case__ , sess_options=snake_case__ )
snake_case : Union[str, Any] = Path(snake_case__ )
# load model from hub
else:
# download model
snake_case : Dict = hf_hub_download(
repo_id=snake_case__ , filename=snake_case__ , use_auth_token=snake_case__ , revision=snake_case__ , cache_dir=snake_case__ , force_download=snake_case__ , )
snake_case : List[Any] = Path(snake_case__ ).parent
snake_case : Union[str, Any] = Path(snake_case__ ).name
snake_case : Dict = OnnxRuntimeModel.load_model(snake_case__ , provider=snake_case__ , sess_options=snake_case__ )
return cls(model=snake_case__ , **snake_case__ )
@classmethod
def _SCREAMING_SNAKE_CASE (cls : Optional[Any] , snake_case__ : Union[str, Path] , snake_case__ : bool = True , snake_case__ : Optional[str] = None , snake_case__ : Optional[str] = None , **snake_case__ : Dict , ) -> Union[str, Any]:
'''simple docstring'''
snake_case : Dict = None
if len(str(snake_case__ ).split("@" ) ) == 2:
snake_case , snake_case : int = model_id.split("@" )
return cls._from_pretrained(
model_id=snake_case__ , revision=snake_case__ , cache_dir=snake_case__ , force_download=snake_case__ , use_auth_token=snake_case__ , **snake_case__ , )
| 59
| 1
|
from typing import TYPE_CHECKING
from ...utils import (
OptionalDependencyNotAvailable,
_LazyModule,
is_flax_available,
is_tf_available,
is_tokenizers_available,
is_torch_available,
)
__lowerCamelCase = {
"""configuration_blenderbot_small""": [
"""BLENDERBOT_SMALL_PRETRAINED_CONFIG_ARCHIVE_MAP""",
"""BlenderbotSmallConfig""",
"""BlenderbotSmallOnnxConfig""",
],
"""tokenization_blenderbot_small""": ["""BlenderbotSmallTokenizer"""],
}
try:
if not is_tokenizers_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = ["""BlenderbotSmallTokenizerFast"""]
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = [
"""BLENDERBOT_SMALL_PRETRAINED_MODEL_ARCHIVE_LIST""",
"""BlenderbotSmallForCausalLM""",
"""BlenderbotSmallForConditionalGeneration""",
"""BlenderbotSmallModel""",
"""BlenderbotSmallPreTrainedModel""",
]
try:
if not is_tf_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = [
"""TFBlenderbotSmallForConditionalGeneration""",
"""TFBlenderbotSmallModel""",
"""TFBlenderbotSmallPreTrainedModel""",
]
try:
if not is_flax_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = [
"""FlaxBlenderbotSmallForConditionalGeneration""",
"""FlaxBlenderbotSmallModel""",
"""FlaxBlenderbotSmallPreTrainedModel""",
]
if TYPE_CHECKING:
from .configuration_blenderbot_small import (
BLENDERBOT_SMALL_PRETRAINED_CONFIG_ARCHIVE_MAP,
BlenderbotSmallConfig,
BlenderbotSmallOnnxConfig,
)
from .tokenization_blenderbot_small import BlenderbotSmallTokenizer
try:
if not is_tokenizers_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .tokenization_blenderbot_small_fast import BlenderbotSmallTokenizerFast
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_blenderbot_small import (
BLENDERBOT_SMALL_PRETRAINED_MODEL_ARCHIVE_LIST,
BlenderbotSmallForCausalLM,
BlenderbotSmallForConditionalGeneration,
BlenderbotSmallModel,
BlenderbotSmallPreTrainedModel,
)
try:
if not is_tf_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_tf_blenderbot_small import (
TFBlenderbotSmallForConditionalGeneration,
TFBlenderbotSmallModel,
TFBlenderbotSmallPreTrainedModel,
)
try:
if not is_flax_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_flax_blenderbot_small import (
FlaxBlenderbotSmallForConditionalGeneration,
FlaxBlenderbotSmallModel,
FlaxBlenderbotSmallPreTrainedModel,
)
else:
import sys
__lowerCamelCase = _LazyModule(__name__, globals()["""__file__"""], _import_structure, module_spec=__spec__)
| 59
|
import argparse
import json
from dataclasses import dataclass, field
from functools import partial
from pathlib import Path
from typing import Callable, Dict, List, Tuple
import timm
import torch
import torch.nn as nn
from classy_vision.models.regnet import RegNet, RegNetParams, RegNetYaagf, RegNetYaagf, RegNetYaaagf
from huggingface_hub import cached_download, hf_hub_url
from torch import Tensor
from vissl.models.model_helpers import get_trunk_forward_outputs
from transformers import AutoImageProcessor, RegNetConfig, RegNetForImageClassification, RegNetModel
from transformers.utils import logging
logging.set_verbosity_info()
__lowerCamelCase = logging.get_logger()
@dataclass
class UpperCAmelCase :
A__ : nn.Module
A__ : List[nn.Module] = field(default_factory=A_ )
A__ : list = field(default_factory=A_ )
def _SCREAMING_SNAKE_CASE (self : Optional[Any] , snake_case__ : Optional[Any] , snake_case__ : Tensor , snake_case__ : Tensor ) -> Optional[Any]:
'''simple docstring'''
snake_case : List[str] = len(list(m.modules() ) ) == 1 or isinstance(snake_case__ , nn.Convad ) or isinstance(snake_case__ , nn.BatchNormad )
if has_not_submodules:
self.traced.append(snake_case__ )
def __call__(self : List[Any] , snake_case__ : Tensor ) -> List[Any]:
'''simple docstring'''
for m in self.module.modules():
self.handles.append(m.register_forward_hook(self._forward_hook ) )
self.module(snake_case__ )
[x.remove() for x in self.handles]
return self
@property
def _SCREAMING_SNAKE_CASE (self : int ) -> Optional[int]:
'''simple docstring'''
return list(filter(lambda snake_case__ : len(list(x.state_dict().keys() ) ) > 0 , self.traced ) )
@dataclass
class UpperCAmelCase :
A__ : nn.Module
A__ : nn.Module
A__ : int = 1
A__ : List = field(default_factory=A_ )
A__ : List = field(default_factory=A_ )
A__ : bool = True
def __call__(self : List[Any] , snake_case__ : Tensor ) -> Any:
'''simple docstring'''
snake_case : str = Tracker(self.dest )(snake_case__ ).parametrized
snake_case : Optional[int] = Tracker(self.src )(snake_case__ ).parametrized
snake_case : List[str] = list(filter(lambda snake_case__ : type(snake_case__ ) not in self.src_skip , snake_case__ ) )
snake_case : Optional[Any] = list(filter(lambda snake_case__ : type(snake_case__ ) not in self.dest_skip , snake_case__ ) )
if len(snake_case__ ) != len(snake_case__ ) and self.raise_if_mismatch:
raise Exception(
f"""Numbers of operations are different. Source module has {len(snake_case__ )} operations while"""
f""" destination module has {len(snake_case__ )}.""" )
for dest_m, src_m in zip(snake_case__ , snake_case__ ):
dest_m.load_state_dict(src_m.state_dict() )
if self.verbose == 1:
print(f"""Transfered from={src_m} to={dest_m}""" )
class UpperCAmelCase ( nn.Module ):
def __init__(self : Tuple , snake_case__ : nn.Module ) -> Optional[Any]:
'''simple docstring'''
super().__init__()
snake_case : List[Tuple[str, nn.Module]] = []
# - get the stem
feature_blocks.append(("conv1", model.stem) )
# - get all the feature blocks
for k, v in model.trunk_output.named_children():
assert k.startswith("block" ), f"""Unexpected layer name {k}"""
snake_case : Union[str, Any] = len(snake_case__ ) + 1
feature_blocks.append((f"""res{block_index}""", v) )
snake_case : Optional[Any] = nn.ModuleDict(snake_case__ )
def _SCREAMING_SNAKE_CASE (self : Tuple , snake_case__ : Tensor ) -> Dict:
'''simple docstring'''
return get_trunk_forward_outputs(
snake_case__ , out_feat_keys=snake_case__ , feature_blocks=self._feature_blocks , )
class UpperCAmelCase ( A_ ):
def _SCREAMING_SNAKE_CASE (self : Any , snake_case__ : str ) -> str:
'''simple docstring'''
snake_case : List[Any] = x.split("-" )
return x_split[0] + x_split[1] + "_" + "".join(x_split[2:] )
def __getitem__(self : Optional[int] , snake_case__ : str ) -> Callable[[], Tuple[nn.Module, Dict]]:
'''simple docstring'''
if x not in self:
snake_case : Dict = self.convert_name_to_timm(snake_case__ )
snake_case : Union[str, Any] = partial(lambda: (timm.create_model(snake_case__ , pretrained=snake_case__ ).eval(), None) )
else:
snake_case : List[str] = super().__getitem__(snake_case__ )
return val
class UpperCAmelCase ( A_ ):
def __getitem__(self : Dict , snake_case__ : str ) -> Callable[[], nn.Module]:
'''simple docstring'''
if "seer" in x and "in1k" not in x:
snake_case : str = RegNetModel
else:
snake_case : Optional[Any] = RegNetForImageClassification
return val
def UpperCamelCase ( __lowerCamelCase : Union[str, Any] , __lowerCamelCase : Union[str, Any] , __lowerCamelCase : List[Tuple[str, str]] ):
for from_key, to_key in keys:
snake_case : str = from_state_dict[from_key].clone()
print(f"""Copied key={from_key} to={to_key}""" )
return to_state_dict
def UpperCamelCase ( __lowerCamelCase : str , __lowerCamelCase : Callable[[], nn.Module] , __lowerCamelCase : Callable[[], nn.Module] , __lowerCamelCase : RegNetConfig , __lowerCamelCase : Path , __lowerCamelCase : bool = True , ):
print(f"""Converting {name}...""" )
with torch.no_grad():
snake_case , snake_case : int = from_model_func()
snake_case : str = our_model_func(__lowerCamelCase ).eval()
snake_case : int = ModuleTransfer(src=__lowerCamelCase , dest=__lowerCamelCase , raise_if_mismatch=__lowerCamelCase )
snake_case : Dict = torch.randn((1, 3, 224, 224) )
module_transfer(__lowerCamelCase )
if from_state_dict is not None:
snake_case : str = []
# for seer - in1k finetuned we have to manually copy the head
if "seer" in name and "in1k" in name:
snake_case : Tuple = [("0.clf.0.weight", "classifier.1.weight"), ("0.clf.0.bias", "classifier.1.bias")]
snake_case : Optional[Any] = manually_copy_vissl_head(__lowerCamelCase , our_model.state_dict() , __lowerCamelCase )
our_model.load_state_dict(__lowerCamelCase )
snake_case : Any = our_model(__lowerCamelCase , output_hidden_states=__lowerCamelCase )
snake_case : Union[str, Any] = (
our_outputs.logits if isinstance(__lowerCamelCase , __lowerCamelCase ) else our_outputs.last_hidden_state
)
snake_case : Union[str, Any] = from_model(__lowerCamelCase )
snake_case : Dict = from_output[-1] if type(__lowerCamelCase ) is list else from_output
# now since I don't want to use any config files, vissl seer model doesn't actually have an head, so let's just check the last hidden state
if "seer" in name and "in1k" in name:
snake_case : Any = our_outputs.hidden_states[-1]
assert torch.allclose(__lowerCamelCase , __lowerCamelCase ), "The model logits don't match the original one."
if push_to_hub:
our_model.push_to_hub(
repo_path_or_name=save_directory / name , commit_message="Add model" , use_temp_dir=__lowerCamelCase , )
snake_case : List[str] = 224 if "seer" not in name else 384
# we can use the convnext one
snake_case : int = AutoImageProcessor.from_pretrained("facebook/convnext-base-224-22k-1k" , size=__lowerCamelCase )
image_processor.push_to_hub(
repo_path_or_name=save_directory / name , commit_message="Add image processor" , use_temp_dir=__lowerCamelCase , )
print(f"""Pushed {name}""" )
def UpperCamelCase ( __lowerCamelCase : Path , __lowerCamelCase : str = None , __lowerCamelCase : bool = True ):
snake_case : Union[str, Any] = "imagenet-1k-id2label.json"
snake_case : List[str] = 1000
snake_case : List[str] = (1, num_labels)
snake_case : Any = "huggingface/label-files"
snake_case : List[str] = num_labels
snake_case : Optional[Any] = json.load(open(cached_download(hf_hub_url(__lowerCamelCase , __lowerCamelCase , repo_type="dataset" ) ) , "r" ) )
snake_case : List[Any] = {int(__lowerCamelCase ): v for k, v in idalabel.items()}
snake_case : str = idalabel
snake_case : List[Any] = {v: k for k, v in idalabel.items()}
snake_case : Dict = partial(__lowerCamelCase , num_labels=__lowerCamelCase , idalabel=__lowerCamelCase , labelaid=__lowerCamelCase )
snake_case : Optional[Any] = {
"regnet-x-002": ImageNetPreTrainedConfig(
depths=[1, 1, 4, 7] , hidden_sizes=[24, 56, 152, 368] , groups_width=8 , layer_type="x" ),
"regnet-x-004": ImageNetPreTrainedConfig(
depths=[1, 2, 7, 12] , hidden_sizes=[32, 64, 160, 384] , groups_width=16 , layer_type="x" ),
"regnet-x-006": ImageNetPreTrainedConfig(
depths=[1, 3, 5, 7] , hidden_sizes=[48, 96, 240, 528] , groups_width=24 , layer_type="x" ),
"regnet-x-008": ImageNetPreTrainedConfig(
depths=[1, 3, 7, 5] , hidden_sizes=[64, 128, 288, 672] , groups_width=16 , layer_type="x" ),
"regnet-x-016": ImageNetPreTrainedConfig(
depths=[2, 4, 10, 2] , hidden_sizes=[72, 168, 408, 912] , groups_width=24 , layer_type="x" ),
"regnet-x-032": ImageNetPreTrainedConfig(
depths=[2, 6, 15, 2] , hidden_sizes=[96, 192, 432, 1008] , groups_width=48 , layer_type="x" ),
"regnet-x-040": ImageNetPreTrainedConfig(
depths=[2, 5, 14, 2] , hidden_sizes=[80, 240, 560, 1360] , groups_width=40 , layer_type="x" ),
"regnet-x-064": ImageNetPreTrainedConfig(
depths=[2, 4, 10, 1] , hidden_sizes=[168, 392, 784, 1624] , groups_width=56 , layer_type="x" ),
"regnet-x-080": ImageNetPreTrainedConfig(
depths=[2, 5, 15, 1] , hidden_sizes=[80, 240, 720, 1920] , groups_width=120 , layer_type="x" ),
"regnet-x-120": ImageNetPreTrainedConfig(
depths=[2, 5, 11, 1] , hidden_sizes=[224, 448, 896, 2240] , groups_width=112 , layer_type="x" ),
"regnet-x-160": ImageNetPreTrainedConfig(
depths=[2, 6, 13, 1] , hidden_sizes=[256, 512, 896, 2048] , groups_width=128 , layer_type="x" ),
"regnet-x-320": ImageNetPreTrainedConfig(
depths=[2, 7, 13, 1] , hidden_sizes=[336, 672, 1344, 2520] , groups_width=168 , layer_type="x" ),
# y variant
"regnet-y-002": ImageNetPreTrainedConfig(depths=[1, 1, 4, 7] , hidden_sizes=[24, 56, 152, 368] , groups_width=8 ),
"regnet-y-004": ImageNetPreTrainedConfig(
depths=[1, 3, 6, 6] , hidden_sizes=[48, 104, 208, 440] , groups_width=8 ),
"regnet-y-006": ImageNetPreTrainedConfig(
depths=[1, 3, 7, 4] , hidden_sizes=[48, 112, 256, 608] , groups_width=16 ),
"regnet-y-008": ImageNetPreTrainedConfig(
depths=[1, 3, 8, 2] , hidden_sizes=[64, 128, 320, 768] , groups_width=16 ),
"regnet-y-016": ImageNetPreTrainedConfig(
depths=[2, 6, 17, 2] , hidden_sizes=[48, 120, 336, 888] , groups_width=24 ),
"regnet-y-032": ImageNetPreTrainedConfig(
depths=[2, 5, 13, 1] , hidden_sizes=[72, 216, 576, 1512] , groups_width=24 ),
"regnet-y-040": ImageNetPreTrainedConfig(
depths=[2, 6, 12, 2] , hidden_sizes=[128, 192, 512, 1088] , groups_width=64 ),
"regnet-y-064": ImageNetPreTrainedConfig(
depths=[2, 7, 14, 2] , hidden_sizes=[144, 288, 576, 1296] , groups_width=72 ),
"regnet-y-080": ImageNetPreTrainedConfig(
depths=[2, 4, 10, 1] , hidden_sizes=[168, 448, 896, 2016] , groups_width=56 ),
"regnet-y-120": ImageNetPreTrainedConfig(
depths=[2, 5, 11, 1] , hidden_sizes=[224, 448, 896, 2240] , groups_width=112 ),
"regnet-y-160": ImageNetPreTrainedConfig(
depths=[2, 4, 11, 1] , hidden_sizes=[224, 448, 1232, 3024] , groups_width=112 ),
"regnet-y-320": ImageNetPreTrainedConfig(
depths=[2, 5, 12, 1] , hidden_sizes=[232, 696, 1392, 3712] , groups_width=232 ),
# models created by SEER -> https://arxiv.org/abs/2202.08360
"regnet-y-320-seer": RegNetConfig(depths=[2, 5, 12, 1] , hidden_sizes=[232, 696, 1392, 3712] , groups_width=232 ),
"regnet-y-640-seer": RegNetConfig(depths=[2, 5, 12, 1] , hidden_sizes=[328, 984, 1968, 4920] , groups_width=328 ),
"regnet-y-1280-seer": RegNetConfig(
depths=[2, 7, 17, 1] , hidden_sizes=[528, 1056, 2904, 7392] , groups_width=264 ),
"regnet-y-2560-seer": RegNetConfig(
depths=[3, 7, 16, 1] , hidden_sizes=[640, 1696, 2544, 5088] , groups_width=640 ),
"regnet-y-10b-seer": ImageNetPreTrainedConfig(
depths=[2, 7, 17, 1] , hidden_sizes=[2020, 4040, 11110, 28280] , groups_width=1010 ),
# finetuned on imagenet
"regnet-y-320-seer-in1k": ImageNetPreTrainedConfig(
depths=[2, 5, 12, 1] , hidden_sizes=[232, 696, 1392, 3712] , groups_width=232 ),
"regnet-y-640-seer-in1k": ImageNetPreTrainedConfig(
depths=[2, 5, 12, 1] , hidden_sizes=[328, 984, 1968, 4920] , groups_width=328 ),
"regnet-y-1280-seer-in1k": ImageNetPreTrainedConfig(
depths=[2, 7, 17, 1] , hidden_sizes=[528, 1056, 2904, 7392] , groups_width=264 ),
"regnet-y-2560-seer-in1k": ImageNetPreTrainedConfig(
depths=[3, 7, 16, 1] , hidden_sizes=[640, 1696, 2544, 5088] , groups_width=640 ),
"regnet-y-10b-seer-in1k": ImageNetPreTrainedConfig(
depths=[2, 7, 17, 1] , hidden_sizes=[2020, 4040, 11110, 28280] , groups_width=1010 ),
}
snake_case : Union[str, Any] = NameToOurModelFuncMap()
snake_case : str = NameToFromModelFuncMap()
# add seer weights logic
def load_using_classy_vision(__lowerCamelCase : str , __lowerCamelCase : Callable[[], nn.Module] ) -> Tuple[nn.Module, Dict]:
snake_case : List[Any] = torch.hub.load_state_dict_from_url(__lowerCamelCase , model_dir=str(__lowerCamelCase ) , map_location="cpu" )
snake_case : Dict = model_func()
# check if we have a head, if yes add it
snake_case : str = files["classy_state_dict"]["base_model"]["model"]
snake_case : Dict = model_state_dict["trunk"]
model.load_state_dict(__lowerCamelCase )
return model.eval(), model_state_dict["heads"]
# pretrained
snake_case : List[Any] = partial(
__lowerCamelCase , "https://dl.fbaipublicfiles.com/vissl/model_zoo/seer_regnet32d/seer_regnet32gf_model_iteration244000.torch" , lambda: FakeRegNetVisslWrapper(RegNetYaagf() ) , )
snake_case : Optional[int] = partial(
__lowerCamelCase , "https://dl.fbaipublicfiles.com/vissl/model_zoo/seer_regnet64/seer_regnet64gf_model_final_checkpoint_phase0.torch" , lambda: FakeRegNetVisslWrapper(RegNetYaagf() ) , )
snake_case : List[str] = partial(
__lowerCamelCase , "https://dl.fbaipublicfiles.com/vissl/model_zoo/swav_ig1b_regnet128Gf_cnstant_bs32_node16_sinkhorn10_proto16k_syncBN64_warmup8k/model_final_checkpoint_phase0.torch" , lambda: FakeRegNetVisslWrapper(RegNetYaaagf() ) , )
snake_case : Tuple = partial(
__lowerCamelCase , "https://dl.fbaipublicfiles.com/vissl/model_zoo/seer_regnet10B/model_iteration124500_conso.torch" , lambda: FakeRegNetVisslWrapper(
RegNet(RegNetParams(depth=27 , group_width=1010 , w_a=1744 , w_a=620.83 , w_m=2.52 ) ) ) , )
# IN1K finetuned
snake_case : List[Any] = partial(
__lowerCamelCase , "https://dl.fbaipublicfiles.com/vissl/model_zoo/seer_finetuned/seer_regnet32_finetuned_in1k_model_final_checkpoint_phase78.torch" , lambda: FakeRegNetVisslWrapper(RegNetYaagf() ) , )
snake_case : Tuple = partial(
__lowerCamelCase , "https://dl.fbaipublicfiles.com/vissl/model_zoo/seer_finetuned/seer_regnet64_finetuned_in1k_model_final_checkpoint_phase78.torch" , lambda: FakeRegNetVisslWrapper(RegNetYaagf() ) , )
snake_case : str = partial(
__lowerCamelCase , "https://dl.fbaipublicfiles.com/vissl/model_zoo/seer_finetuned/seer_regnet128_finetuned_in1k_model_final_checkpoint_phase78.torch" , lambda: FakeRegNetVisslWrapper(RegNetYaaagf() ) , )
snake_case : Dict = partial(
__lowerCamelCase , "https://dl.fbaipublicfiles.com/vissl/model_zoo/seer_finetuned/seer_10b_finetuned_in1k_model_phase28_conso.torch" , lambda: FakeRegNetVisslWrapper(
RegNet(RegNetParams(depth=27 , group_width=1010 , w_a=1744 , w_a=620.83 , w_m=2.52 ) ) ) , )
if model_name:
convert_weight_and_push(
__lowerCamelCase , names_to_from_model_map[model_name] , names_to_ours_model_map[model_name] , names_to_config[model_name] , __lowerCamelCase , __lowerCamelCase , )
else:
for model_name, config in names_to_config.items():
convert_weight_and_push(
__lowerCamelCase , names_to_from_model_map[model_name] , names_to_ours_model_map[model_name] , __lowerCamelCase , __lowerCamelCase , __lowerCamelCase , )
return config, expected_shape
if __name__ == "__main__":
__lowerCamelCase = argparse.ArgumentParser()
# Required parameters
parser.add_argument(
"""--model_name""",
default=None,
type=str,
help=(
"""The name of the model you wish to convert, it must be one of the supported regnet* architecture,"""
""" currently: regnetx-*, regnety-*. If `None`, all of them will the converted."""
),
)
parser.add_argument(
"""--pytorch_dump_folder_path""",
default=None,
type=Path,
required=True,
help="""Path to the output PyTorch model directory.""",
)
parser.add_argument(
"""--push_to_hub""",
default=True,
type=bool,
required=False,
help="""If True, push model and image processor to the hub.""",
)
__lowerCamelCase = parser.parse_args()
__lowerCamelCase = args.pytorch_dump_folder_path
pytorch_dump_folder_path.mkdir(exist_ok=True, parents=True)
convert_weights_and_push(pytorch_dump_folder_path, args.model_name, args.push_to_hub)
| 59
| 1
|
from typing import TYPE_CHECKING
from ...utils import OptionalDependencyNotAvailable, _LazyModule, is_torch_available, is_vision_available
__lowerCamelCase = {
"""configuration_pix2struct""": [
"""PIX2STRUCT_PRETRAINED_CONFIG_ARCHIVE_MAP""",
"""Pix2StructConfig""",
"""Pix2StructTextConfig""",
"""Pix2StructVisionConfig""",
],
"""processing_pix2struct""": ["""Pix2StructProcessor"""],
}
try:
if not is_vision_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = ["""Pix2StructImageProcessor"""]
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = [
"""PIX2STRUCT_PRETRAINED_MODEL_ARCHIVE_LIST""",
"""Pix2StructPreTrainedModel""",
"""Pix2StructForConditionalGeneration""",
"""Pix2StructVisionModel""",
"""Pix2StructTextModel""",
]
if TYPE_CHECKING:
from .configuration_pixastruct import (
PIX2STRUCT_PRETRAINED_CONFIG_ARCHIVE_MAP,
PixaStructConfig,
PixaStructTextConfig,
PixaStructVisionConfig,
)
from .processing_pixastruct import PixaStructProcessor
try:
if not is_vision_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .image_processing_pixastruct import PixaStructImageProcessor
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_pixastruct import (
PIX2STRUCT_PRETRAINED_MODEL_ARCHIVE_LIST,
PixaStructForConditionalGeneration,
PixaStructPreTrainedModel,
PixaStructTextModel,
PixaStructVisionModel,
)
else:
import sys
__lowerCamelCase = _LazyModule(__name__, globals()["""__file__"""], _import_structure, module_spec=__spec__)
| 59
|
import warnings
from typing import Dict
import numpy as np
from ..utils import ExplicitEnum, add_end_docstrings, is_tf_available, is_torch_available
from .base import PIPELINE_INIT_ARGS, GenericTensor, Pipeline
if is_tf_available():
from ..models.auto.modeling_tf_auto import TF_MODEL_FOR_SEQUENCE_CLASSIFICATION_MAPPING
if is_torch_available():
from ..models.auto.modeling_auto import MODEL_FOR_SEQUENCE_CLASSIFICATION_MAPPING
def UpperCamelCase ( __lowerCamelCase : List[Any] ):
return 1.0 / (1.0 + np.exp(-_outputs ))
def UpperCamelCase ( __lowerCamelCase : int ):
snake_case : Tuple = np.max(_outputs , axis=-1 , keepdims=__lowerCamelCase )
snake_case : int = np.exp(_outputs - maxes )
return shifted_exp / shifted_exp.sum(axis=-1 , keepdims=__lowerCamelCase )
class UpperCAmelCase ( A_ ):
A__ : Any = "sigmoid"
A__ : str = "softmax"
A__ : int = "none"
@add_end_docstrings(
A_ ,r"\n return_all_scores (`bool`, *optional*, defaults to `False`):\n Whether to return all prediction scores or just the one of the predicted class.\n function_to_apply (`str`, *optional*, defaults to `\"default\"`):\n The function to apply to the model outputs in order to retrieve the scores. Accepts four different values:\n\n - `\"default\"`: if the model has a single label, will apply the sigmoid function on the output. If the model\n has several labels, will apply the softmax function on the output.\n - `\"sigmoid\"`: Applies the sigmoid function on the output.\n - `\"softmax\"`: Applies the softmax function on the output.\n - `\"none\"`: Does not apply any function on the output.\n " ,)
class UpperCAmelCase ( A_ ):
A__ : int = False
A__ : Union[str, Any] = ClassificationFunction.NONE
def __init__(self : List[str] , **snake_case__ : int ) -> str:
'''simple docstring'''
super().__init__(**snake_case__ )
self.check_model_type(
TF_MODEL_FOR_SEQUENCE_CLASSIFICATION_MAPPING
if self.framework == "tf"
else MODEL_FOR_SEQUENCE_CLASSIFICATION_MAPPING )
def _SCREAMING_SNAKE_CASE (self : List[Any] , snake_case__ : List[str]=None , snake_case__ : Optional[Any]=None , snake_case__ : Union[str, Any]="" , **snake_case__ : List[str] ) -> Union[str, Any]:
'''simple docstring'''
snake_case : Dict = tokenizer_kwargs
snake_case : List[Any] = {}
if hasattr(self.model.config , "return_all_scores" ) and return_all_scores is None:
snake_case : Optional[int] = self.model.config.return_all_scores
if isinstance(snake_case__ , snake_case__ ) or top_k is None:
snake_case : List[Any] = top_k
snake_case : str = False
elif return_all_scores is not None:
warnings.warn(
"`return_all_scores` is now deprecated, if want a similar functionality use `top_k=None` instead of"
" `return_all_scores=True` or `top_k=1` instead of `return_all_scores=False`." , snake_case__ , )
if return_all_scores:
snake_case : List[str] = None
else:
snake_case : Optional[int] = 1
if isinstance(snake_case__ , snake_case__ ):
snake_case : Dict = ClassificationFunction[function_to_apply.upper()]
if function_to_apply is not None:
snake_case : Optional[int] = function_to_apply
return preprocess_params, {}, postprocess_params
def __call__(self : Dict , *snake_case__ : List[str] , **snake_case__ : int ) -> Optional[int]:
'''simple docstring'''
snake_case : Optional[int] = super().__call__(*snake_case__ , **snake_case__ )
# TODO try and retrieve it in a nicer way from _sanitize_parameters.
snake_case : Tuple = "top_k" not in kwargs
if isinstance(args[0] , snake_case__ ) and _legacy:
# This pipeline is odd, and return a list when single item is run
return [result]
else:
return result
def _SCREAMING_SNAKE_CASE (self : Dict , snake_case__ : Tuple , **snake_case__ : Union[str, Any] ) -> Dict[str, GenericTensor]:
'''simple docstring'''
snake_case : int = self.framework
if isinstance(snake_case__ , snake_case__ ):
return self.tokenizer(**snake_case__ , return_tensors=snake_case__ , **snake_case__ )
elif isinstance(snake_case__ , snake_case__ ) and len(snake_case__ ) == 1 and isinstance(inputs[0] , snake_case__ ) and len(inputs[0] ) == 2:
# It used to be valid to use a list of list of list for text pairs, keeping this path for BC
return self.tokenizer(
text=inputs[0][0] , text_pair=inputs[0][1] , return_tensors=snake_case__ , **snake_case__ )
elif isinstance(snake_case__ , snake_case__ ):
# This is likely an invalid usage of the pipeline attempting to pass text pairs.
raise ValueError(
"The pipeline received invalid inputs, if you are trying to send text pairs, you can try to send a"
" dictionary `{\"text\": \"My text\", \"text_pair\": \"My pair\"}` in order to send a text pair." )
return self.tokenizer(snake_case__ , return_tensors=snake_case__ , **snake_case__ )
def _SCREAMING_SNAKE_CASE (self : int , snake_case__ : Union[str, Any] ) -> int:
'''simple docstring'''
return self.model(**snake_case__ )
def _SCREAMING_SNAKE_CASE (self : List[str] , snake_case__ : Optional[Any] , snake_case__ : List[str]=None , snake_case__ : Dict=1 , snake_case__ : Tuple=True ) -> str:
'''simple docstring'''
if function_to_apply is None:
if self.model.config.problem_type == "multi_label_classification" or self.model.config.num_labels == 1:
snake_case : Tuple = ClassificationFunction.SIGMOID
elif self.model.config.problem_type == "single_label_classification" or self.model.config.num_labels > 1:
snake_case : Tuple = ClassificationFunction.SOFTMAX
elif hasattr(self.model.config , "function_to_apply" ) and function_to_apply is None:
snake_case : Tuple = self.model.config.function_to_apply
else:
snake_case : int = ClassificationFunction.NONE
snake_case : Any = model_outputs["logits"][0]
snake_case : List[str] = outputs.numpy()
if function_to_apply == ClassificationFunction.SIGMOID:
snake_case : Optional[Any] = sigmoid(snake_case__ )
elif function_to_apply == ClassificationFunction.SOFTMAX:
snake_case : Union[str, Any] = softmax(snake_case__ )
elif function_to_apply == ClassificationFunction.NONE:
snake_case : Optional[Any] = outputs
else:
raise ValueError(f"""Unrecognized `function_to_apply` argument: {function_to_apply}""" )
if top_k == 1 and _legacy:
return {"label": self.model.config.idalabel[scores.argmax().item()], "score": scores.max().item()}
snake_case : Optional[int] = [
{"label": self.model.config.idalabel[i], "score": score.item()} for i, score in enumerate(snake_case__ )
]
if not _legacy:
dict_scores.sort(key=lambda snake_case__ : x["score"] , reverse=snake_case__ )
if top_k is not None:
snake_case : Optional[int] = dict_scores[:top_k]
return dict_scores
| 59
| 1
|
import numpy as np
from PIL import Image
def UpperCamelCase ( __lowerCamelCase : np.ndarray , __lowerCamelCase : int , __lowerCamelCase : int ):
snake_case : List[str] = np.array(__lowerCamelCase )
if arr.shape[0] != arr.shape[1]:
raise ValueError("The input array is not a square matrix" )
snake_case : int = 0
snake_case : Optional[int] = 0
snake_case : Tuple = 0
snake_case : int = 0
# compute the shape of the output matrix
snake_case : Optional[int] = (arr.shape[0] - size) // stride + 1
# initialize the output matrix with zeros of shape maxpool_shape
snake_case : Any = np.zeros((maxpool_shape, maxpool_shape) )
while i < arr.shape[0]:
if i + size > arr.shape[0]:
# if the end of the matrix is reached, break
break
while j < arr.shape[1]:
# if the end of the matrix is reached, break
if j + size > arr.shape[1]:
break
# compute the maximum of the pooling matrix
snake_case : List[str] = np.max(arr[i : i + size, j : j + size] )
# shift the pooling matrix by stride of column pixels
j += stride
mat_j += 1
# shift the pooling matrix by stride of row pixels
i += stride
mat_i += 1
# reset the column index to 0
snake_case : Optional[Any] = 0
snake_case : List[Any] = 0
return updated_arr
def UpperCamelCase ( __lowerCamelCase : np.ndarray , __lowerCamelCase : int , __lowerCamelCase : int ):
snake_case : List[str] = np.array(__lowerCamelCase )
if arr.shape[0] != arr.shape[1]:
raise ValueError("The input array is not a square matrix" )
snake_case : Optional[int] = 0
snake_case : List[str] = 0
snake_case : Dict = 0
snake_case : str = 0
# compute the shape of the output matrix
snake_case : List[Any] = (arr.shape[0] - size) // stride + 1
# initialize the output matrix with zeros of shape avgpool_shape
snake_case : int = np.zeros((avgpool_shape, avgpool_shape) )
while i < arr.shape[0]:
# if the end of the matrix is reached, break
if i + size > arr.shape[0]:
break
while j < arr.shape[1]:
# if the end of the matrix is reached, break
if j + size > arr.shape[1]:
break
# compute the average of the pooling matrix
snake_case : Optional[int] = int(np.average(arr[i : i + size, j : j + size] ) )
# shift the pooling matrix by stride of column pixels
j += stride
mat_j += 1
# shift the pooling matrix by stride of row pixels
i += stride
mat_i += 1
# reset the column index to 0
snake_case : int = 0
snake_case : Any = 0
return updated_arr
# Main Function
if __name__ == "__main__":
from doctest import testmod
testmod(name="""avgpooling""", verbose=True)
# Loading the image
__lowerCamelCase = Image.open("""path_to_image""")
# Converting the image to numpy array and maxpooling, displaying the result
# Ensure that the image is a square matrix
Image.fromarray(maxpooling(np.array(image), size=3, stride=2)).show()
# Converting the image to numpy array and averagepooling, displaying the result
# Ensure that the image is a square matrix
Image.fromarray(avgpooling(np.array(image), size=3, stride=2)).show()
| 59
|
from __future__ import annotations
__lowerCamelCase = list[list[int]]
# assigning initial values to the grid
__lowerCamelCase = [
[3, 0, 6, 5, 0, 8, 4, 0, 0],
[5, 2, 0, 0, 0, 0, 0, 0, 0],
[0, 8, 7, 0, 0, 0, 0, 3, 1],
[0, 0, 3, 0, 1, 0, 0, 8, 0],
[9, 0, 0, 8, 6, 3, 0, 0, 5],
[0, 5, 0, 0, 9, 0, 6, 0, 0],
[1, 3, 0, 0, 0, 0, 2, 5, 0],
[0, 0, 0, 0, 0, 0, 0, 7, 4],
[0, 0, 5, 2, 0, 6, 3, 0, 0],
]
# a grid with no solution
__lowerCamelCase = [
[5, 0, 6, 5, 0, 8, 4, 0, 3],
[5, 2, 0, 0, 0, 0, 0, 0, 2],
[1, 8, 7, 0, 0, 0, 0, 3, 1],
[0, 0, 3, 0, 1, 0, 0, 8, 0],
[9, 0, 0, 8, 6, 3, 0, 0, 5],
[0, 5, 0, 0, 9, 0, 6, 0, 0],
[1, 3, 0, 0, 0, 0, 2, 5, 0],
[0, 0, 0, 0, 0, 0, 0, 7, 4],
[0, 0, 5, 2, 0, 6, 3, 0, 0],
]
def UpperCamelCase ( __lowerCamelCase : Matrix , __lowerCamelCase : int , __lowerCamelCase : int , __lowerCamelCase : int ):
for i in range(9 ):
if grid[row][i] == n or grid[i][column] == n:
return False
for i in range(3 ):
for j in range(3 ):
if grid[(row - row % 3) + i][(column - column % 3) + j] == n:
return False
return True
def UpperCamelCase ( __lowerCamelCase : Matrix ):
for i in range(9 ):
for j in range(9 ):
if grid[i][j] == 0:
return i, j
return None
def UpperCamelCase ( __lowerCamelCase : Matrix ):
if location := find_empty_location(__lowerCamelCase ):
snake_case , snake_case : Union[str, Any] = location
else:
# If the location is ``None``, then the grid is solved.
return grid
for digit in range(1 , 10 ):
if is_safe(__lowerCamelCase , __lowerCamelCase , __lowerCamelCase , __lowerCamelCase ):
snake_case : List[Any] = digit
if sudoku(__lowerCamelCase ) is not None:
return grid
snake_case : Union[str, Any] = 0
return None
def UpperCamelCase ( __lowerCamelCase : Matrix ):
for row in grid:
for cell in row:
print(__lowerCamelCase , end=" " )
print()
if __name__ == "__main__":
# make a copy of grid so that you can compare with the unmodified grid
for example_grid in (initial_grid, no_solution):
print("""\nExample grid:\n""" + """=""" * 20)
print_solution(example_grid)
print("""\nExample grid solution:""")
__lowerCamelCase = sudoku(example_grid)
if solution is not None:
print_solution(solution)
else:
print("""Cannot find a solution.""")
| 59
| 1
|
import pytest
from datasets.splits import SplitDict, SplitInfo
from datasets.utils.py_utils import asdict
@pytest.mark.parametrize(
"split_dict" , [
SplitDict(),
SplitDict({"train": SplitInfo(name="train" , num_bytes=1337 , num_examples=42 , dataset_name="my_dataset" )} ),
SplitDict({"train": SplitInfo(name="train" , num_bytes=1337 , num_examples=42 )} ),
SplitDict({"train": SplitInfo()} ),
] , )
def UpperCamelCase ( __lowerCamelCase : SplitDict ):
snake_case : List[Any] = split_dict._to_yaml_list()
assert len(__lowerCamelCase ) == len(__lowerCamelCase )
snake_case : List[Any] = SplitDict._from_yaml_list(__lowerCamelCase )
for split_name, split_info in split_dict.items():
# dataset_name field is deprecated, and is therefore not part of the YAML dump
snake_case : Tuple = None
# the split name of split_dict takes over the name of the split info object
snake_case : str = split_name
assert split_dict == reloaded
@pytest.mark.parametrize(
"split_info" , [SplitInfo(), SplitInfo(dataset_name=__lowerCamelCase ), SplitInfo(dataset_name="my_dataset" )] )
def UpperCamelCase ( __lowerCamelCase : Dict ):
# For backward compatibility, we need asdict(split_dict) to return split info dictrionaries with the "dataset_name"
# field even if it's deprecated. This way old versionso of `datasets` can still reload dataset_infos.json files
snake_case : Tuple = asdict(SplitDict({"train": split_info} ) )
assert "dataset_name" in split_dict_asdict["train"]
assert split_dict_asdict["train"]["dataset_name"] == split_info.dataset_name
| 59
|
import logging
import numpy as np
import pytest
from scipy.linalg import eigh
logging.basicConfig(level=logging.INFO, format="""%(message)s""")
def UpperCamelCase ( __lowerCamelCase : np.ndarray ):
return input_array.reshape((input_array.size, 1) )
def UpperCamelCase ( __lowerCamelCase : np.ndarray , __lowerCamelCase : np.ndarray , __lowerCamelCase : int ):
snake_case : Any = np.nan
for i in range(__lowerCamelCase ):
snake_case : List[str] = features[:, labels == i]
snake_case : Dict = data.mean(1 )
# Centralize the data of class i
snake_case : Optional[Any] = data - column_reshape(__lowerCamelCase )
if i > 0:
# If covariance_sum is not None
covariance_sum += np.dot(__lowerCamelCase , centered_data.T )
else:
# If covariance_sum is np.nan (i.e. first loop)
snake_case : Optional[Any] = np.dot(__lowerCamelCase , centered_data.T )
return covariance_sum / features.shape[1]
def UpperCamelCase ( __lowerCamelCase : np.ndarray , __lowerCamelCase : np.ndarray , __lowerCamelCase : int ):
snake_case : Optional[Any] = features.mean(1 )
snake_case : Tuple = np.nan
for i in range(__lowerCamelCase ):
snake_case : Tuple = features[:, labels == i]
snake_case : Tuple = data.shape[1]
snake_case : List[str] = data.mean(1 )
if i > 0:
# If covariance_sum is not None
covariance_sum += device_data * np.dot(
column_reshape(__lowerCamelCase ) - column_reshape(__lowerCamelCase ) , (column_reshape(__lowerCamelCase ) - column_reshape(__lowerCamelCase )).T , )
else:
# If covariance_sum is np.nan (i.e. first loop)
snake_case : Optional[int] = device_data * np.dot(
column_reshape(__lowerCamelCase ) - column_reshape(__lowerCamelCase ) , (column_reshape(__lowerCamelCase ) - column_reshape(__lowerCamelCase )).T , )
return covariance_sum / features.shape[1]
def UpperCamelCase ( __lowerCamelCase : np.ndarray , __lowerCamelCase : int ):
# Check if the features have been loaded
if features.any():
snake_case : Tuple = features.mean(1 )
# Center the dataset
snake_case : List[str] = features - np.reshape(__lowerCamelCase , (data_mean.size, 1) )
snake_case : Optional[Any] = np.dot(__lowerCamelCase , centered_data.T ) / features.shape[1]
snake_case , snake_case : Dict = np.linalg.eigh(__lowerCamelCase )
# Take all the columns in the reverse order (-1), and then takes only the first
snake_case : Optional[Any] = eigenvectors[:, ::-1][:, 0:dimensions]
# Project the database on the new space
snake_case : Union[str, Any] = np.dot(filtered_eigenvectors.T , __lowerCamelCase )
logging.info("Principal Component Analysis computed" )
return projected_data
else:
logging.basicConfig(level=logging.ERROR , format="%(message)s" , force=__lowerCamelCase )
logging.error("Dataset empty" )
raise AssertionError
def UpperCamelCase ( __lowerCamelCase : np.ndarray , __lowerCamelCase : np.ndarray , __lowerCamelCase : int , __lowerCamelCase : int ):
assert classes > dimensions
# Check if features have been already loaded
if features.any:
snake_case , snake_case : str = eigh(
covariance_between_classes(__lowerCamelCase , __lowerCamelCase , __lowerCamelCase ) , covariance_within_classes(__lowerCamelCase , __lowerCamelCase , __lowerCamelCase ) , )
snake_case : str = eigenvectors[:, ::-1][:, :dimensions]
snake_case , snake_case , snake_case : int = np.linalg.svd(__lowerCamelCase )
snake_case : List[Any] = svd_matrix[:, 0:dimensions]
snake_case : Optional[Any] = np.dot(filtered_svd_matrix.T , __lowerCamelCase )
logging.info("Linear Discriminant Analysis computed" )
return projected_data
else:
logging.basicConfig(level=logging.ERROR , format="%(message)s" , force=__lowerCamelCase )
logging.error("Dataset empty" )
raise AssertionError
def UpperCamelCase ( ):
# Create dummy dataset with 2 classes and 3 features
snake_case : str = np.array([[1, 2, 3, 4, 5], [2, 3, 4, 5, 6], [3, 4, 5, 6, 7]] )
snake_case : Union[str, Any] = np.array([0, 0, 0, 1, 1] )
snake_case : List[Any] = 2
snake_case : Any = 2
# Assert that the function raises an AssertionError if dimensions > classes
with pytest.raises(__lowerCamelCase ) as error_info:
snake_case : str = linear_discriminant_analysis(
__lowerCamelCase , __lowerCamelCase , __lowerCamelCase , __lowerCamelCase )
if isinstance(__lowerCamelCase , np.ndarray ):
raise AssertionError(
"Did not raise AssertionError for dimensions > classes" )
assert error_info.type is AssertionError
def UpperCamelCase ( ):
snake_case : List[str] = np.array([[1, 2, 3], [4, 5, 6], [7, 8, 9]] )
snake_case : List[str] = 2
snake_case : int = np.array([[6.9282_0323, 8.6602_5404, 10.3923_0485], [3.0, 3.0, 3.0]] )
with pytest.raises(__lowerCamelCase ) as error_info:
snake_case : Union[str, Any] = principal_component_analysis(__lowerCamelCase , __lowerCamelCase )
if not np.allclose(__lowerCamelCase , __lowerCamelCase ):
raise AssertionError
assert error_info.type is AssertionError
if __name__ == "__main__":
import doctest
doctest.testmod()
| 59
| 1
|
from typing import TYPE_CHECKING
from ...utils import (
OptionalDependencyNotAvailable,
_LazyModule,
is_torch_available,
)
__lowerCamelCase = {
"""configuration_falcon""": ["""FALCON_PRETRAINED_CONFIG_ARCHIVE_MAP""", """FalconConfig"""],
}
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = [
"""FALCON_PRETRAINED_MODEL_ARCHIVE_LIST""",
"""FalconForCausalLM""",
"""FalconModel""",
"""FalconPreTrainedModel""",
"""FalconForSequenceClassification""",
"""FalconForTokenClassification""",
"""FalconForQuestionAnswering""",
]
if TYPE_CHECKING:
from .configuration_falcon import FALCON_PRETRAINED_CONFIG_ARCHIVE_MAP, FalconConfig
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_falcon import (
FALCON_PRETRAINED_MODEL_ARCHIVE_LIST,
FalconForCausalLM,
FalconForQuestionAnswering,
FalconForSequenceClassification,
FalconForTokenClassification,
FalconModel,
FalconPreTrainedModel,
)
else:
import sys
__lowerCamelCase = _LazyModule(__name__, globals()["""__file__"""], _import_structure, module_spec=__spec__)
| 59
|
import pytest
from datasets import inspect_metric, list_metrics, load_metric
@pytest.fixture
def UpperCamelCase ( __lowerCamelCase : Optional[int] ):
monkeypatch.setattr("datasets.utils.deprecation_utils._emitted_deprecation_warnings" , set() )
@pytest.fixture
def UpperCamelCase ( __lowerCamelCase : str ):
class UpperCAmelCase :
def __init__(self : Optional[int] , snake_case__ : str ) -> Any:
'''simple docstring'''
snake_case : List[str] = metric_id
class UpperCAmelCase :
A__ : List[str] = [MetricMock(A_ ) for metric_id in ["accuracy", "mse", "precision", "codeparrot/apps_metric"]]
def _SCREAMING_SNAKE_CASE (self : int ) -> List[str]:
'''simple docstring'''
return self._metrics
monkeypatch.setattr("datasets.inspect.huggingface_hub" , HfhMock() )
@pytest.mark.parametrize(
"func, args" , [(load_metric, ("metrics/mse",)), (list_metrics, ()), (inspect_metric, ("metrics/mse", "tmp_path"))] )
def UpperCamelCase ( __lowerCamelCase : Optional[int] , __lowerCamelCase : Any , __lowerCamelCase : Any , __lowerCamelCase : int , __lowerCamelCase : Any ):
if "tmp_path" in args:
snake_case : str = tuple(arg if arg != "tmp_path" else tmp_path for arg in args )
with pytest.warns(__lowerCamelCase , match="https://huggingface.co/docs/evaluate" ):
func(*__lowerCamelCase )
| 59
| 1
|
import argparse
import json
from tqdm import tqdm
def UpperCamelCase ( ):
snake_case : List[Any] = argparse.ArgumentParser()
# Required parameters
parser.add_argument(
"--src_path" , type=__lowerCamelCase , default="biencoder-nq-dev.json" , help="Path to raw DPR training data" , )
parser.add_argument(
"--evaluation_set" , type=__lowerCamelCase , help="where to store parsed evaluation_set file" , )
parser.add_argument(
"--gold_data_path" , type=__lowerCamelCase , help="where to store parsed gold_data_path file" , )
snake_case : Tuple = 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:
snake_case : Tuple = json.load(__lowerCamelCase )
for dpr_record in tqdm(__lowerCamelCase ):
snake_case : Dict = dpr_record["question"]
snake_case : Dict = [context["title"] for context in dpr_record["positive_ctxs"]]
eval_file.write(question + "\n" )
gold_file.write("\t".join(__lowerCamelCase ) + "\n" )
if __name__ == "__main__":
main()
| 59
|
import argparse
import dataclasses
import json
import logging
import os
import shutil
from typing import List, Optional
import datasets
from accelerate import Accelerator
from datasets import load_dataset
from finetuning import finetune
from tqdm.auto import tqdm
import transformers
from transformers import AutoConfig, set_seed
from transformers.trainer_utils import IntervalStrategy
__lowerCamelCase = logging.getLogger(__name__)
__lowerCamelCase = """pytorch_model.bin"""
@dataclasses.dataclass
class UpperCAmelCase :
A__ : str = dataclasses.field(
metadata={"help": "Path to pretrained model or model identifier from huggingface.co/models."} )
A__ : Optional[str] = dataclasses.field(
default=A_ ,metadata={"help": "Where do you want to store the pretrained models downloaded from huggingface.co."} ,)
@dataclasses.dataclass
class UpperCAmelCase :
A__ : str = dataclasses.field(metadata={"help": "A csv or a json file containing the training data."} )
A__ : str = dataclasses.field(metadata={"help": "A csv or a json file containing the data to predict on."} )
A__ : Optional[str] = dataclasses.field(
default=A_ ,metadata={"help": "A csv or a json file containing the validation data."} )
A__ : Optional[str] = dataclasses.field(
default=A_ ,metadata={"help": "The name of the task to train on."} ,)
A__ : Optional[List[str]] = dataclasses.field(
default=A_ ,metadata={"help": "The list of labels for the task."} )
@dataclasses.dataclass
class UpperCAmelCase :
A__ : str = dataclasses.field(
metadata={"help": "The output directory where the model predictions and checkpoints will be written."} )
A__ : Optional[str] = dataclasses.field(
default="accuracy" ,metadata={"help": "The evaluation metric used for the task."} )
A__ : Optional[str] = dataclasses.field(
default="no" ,metadata={
"help": "The evaluation strategy to adopt during training. Possible values are: [\"no\", \"step\", \"epoch]"
} ,)
A__ : Optional[int] = dataclasses.field(
default=10 ,metadata={"help": "Number of evaluation calls with no improvement after which training will be stopped."} ,)
A__ : Optional[float] = dataclasses.field(
default=0.0 ,metadata={
"help": "How much the specified evaluation metric must improve to satisfy early stopping conditions."
} ,)
A__ : Optional[bool] = dataclasses.field(
default=A_ ,metadata={"help": "Whether to filter the pseudo-labeled data based on the confidence score."} ,)
A__ : Optional[bool] = dataclasses.field(
default=A_ ,metadata={"help": "Whether to filter the pseudo-labeled data based on the validation performance."} ,)
A__ : Optional[bool] = dataclasses.field(
default=A_ ,metadata={"help": "Whether to fine-tune on labeled data after pseudo training."} ,)
A__ : Optional[float] = dataclasses.field(
default=0.0 ,metadata={"help": "Confidence threshold for pseudo-labeled data filtering."} ,)
A__ : Optional[int] = dataclasses.field(
default=1_00 ,metadata={"help": "Number of evaluation calls with no improvement after which training will be stopped."} ,)
A__ : Optional[int] = dataclasses.field(
default=A_ ,metadata={"help": "Random seed for initialization."} ,)
def UpperCamelCase ( __lowerCamelCase : int , __lowerCamelCase : Tuple , __lowerCamelCase : Union[str, Any] , __lowerCamelCase : Tuple , __lowerCamelCase : Dict , __lowerCamelCase : Optional[int] ):
snake_case : Tuple = datasets.concatenate_datasets([infer_input, infer_output] , axis=1 )
if args.do_filter_by_confidence:
snake_case : Optional[int] = dataset.filter(lambda __lowerCamelCase : example["probability"] > args.confidence_threshold )
if args.do_filter_by_val_performance:
assert eval_result >= 0.0 and eval_result <= 1.0
snake_case : int = int(eval_result * len(__lowerCamelCase ) )
print(__lowerCamelCase )
snake_case : List[str] = dataset.sort("probability" , reverse=__lowerCamelCase )
snake_case : Tuple = dataset.select(range(__lowerCamelCase ) )
snake_case : List[Any] = dataset.remove_columns(["label", "probability"] )
snake_case : Any = dataset.rename_column("prediction" , "label" )
snake_case : str = dataset.map(lambda __lowerCamelCase : {"label": idalabel[example["label"]]} )
snake_case : List[str] = dataset.shuffle(seed=args.seed )
snake_case : int = os.path.join(__lowerCamelCase , f"""train_pseudo.{args.data_file_extension}""" )
if args.data_file_extension == "csv":
dataset.to_csv(__lowerCamelCase , index=__lowerCamelCase )
else:
dataset.to_json(__lowerCamelCase )
def UpperCamelCase ( __lowerCamelCase : Optional[int] , __lowerCamelCase : str , __lowerCamelCase : Optional[int] , __lowerCamelCase : Tuple , **__lowerCamelCase : List[Any] ):
snake_case : int = Accelerator()
# Make one log on every process with the configuration for debugging.
logging.basicConfig(
format="%(asctime)s - %(levelname)s - %(name)s - %(message)s" , datefmt="%m/%d/%Y %H:%M:%S" , level=logging.INFO , )
logger.info(accelerator.state )
# Setup logging, we only want one process per machine to log things on the
# screen. accelerator.is_local_main_process is only True for one process per
# machine.
logger.setLevel(logging.INFO if accelerator.is_local_main_process else logging.ERROR )
if accelerator.is_local_main_process:
datasets.utils.logging.set_verbosity_warning()
transformers.utils.logging.set_verbosity_info()
else:
datasets.utils.logging.set_verbosity_error()
transformers.utils.logging.set_verbosity_error()
snake_case : Dict = STModelArguments(model_name_or_path=__lowerCamelCase )
snake_case : Tuple = STDataArguments(train_file=__lowerCamelCase , infer_file=__lowerCamelCase )
snake_case : str = STTrainingArguments(output_dir=__lowerCamelCase )
snake_case : int = argparse.Namespace()
for arg_class in (model_args, data_args, training_args):
for key, value in vars(__lowerCamelCase ).items():
setattr(__lowerCamelCase , __lowerCamelCase , __lowerCamelCase )
for key, value in kwargs.items():
if hasattr(__lowerCamelCase , __lowerCamelCase ):
setattr(__lowerCamelCase , __lowerCamelCase , __lowerCamelCase )
# Sanity checks
snake_case : List[str] = {}
snake_case : Optional[int] = None
# You need to provide the training data and the data to predict on
assert args.train_file is not None
assert args.infer_file is not None
snake_case : str = args.train_file
snake_case : Tuple = args.infer_file
if args.evaluation_strategy != IntervalStrategy.NO.value:
assert args.eval_file is not None
snake_case : Tuple = args.eval_file
for key in data_files:
snake_case : List[Any] = data_files[key].split("." )[-1]
assert extension in ["csv", "json"], f"""`{key}_file` should be a csv or a json file."""
if args.data_file_extension is None:
snake_case : Union[str, Any] = extension
else:
assert extension == args.data_file_extension, f"""`{key}_file` should be a {args.data_file_extension} file`."""
assert (
args.eval_metric in datasets.list_metrics()
), f"""{args.eval_metric} not in the list of supported metrics {datasets.list_metrics()}."""
# If passed along, set the training seed now.
if args.seed is not None:
set_seed(args.seed )
logger.info("Creating the initial data directory for self-training..." )
snake_case : List[Any] = f"""{args.output_dir}/self-train_iter-{{}}""".format
snake_case : Optional[int] = data_dir_format(0 )
if accelerator.is_main_process:
if args.output_dir is not None:
os.makedirs(args.output_dir , exist_ok=__lowerCamelCase )
os.makedirs(__lowerCamelCase , exist_ok=__lowerCamelCase )
accelerator.wait_for_everyone()
snake_case : Dict = None
snake_case : Union[str, Any] = None
snake_case : Tuple = 0
snake_case : List[Any] = False
# Show the progress bar
snake_case : List[Any] = tqdm(range(args.max_selftrain_iterations ) , disable=not accelerator.is_local_main_process )
# Self-train
for iteration in range(0 , int(args.max_selftrain_iterations ) ):
snake_case : str = data_dir_format(__lowerCamelCase )
assert os.path.exists(__lowerCamelCase )
# Stage 1: initial fine-tuning for iteration = 0 or pseudo-training for
# iteration > 0
snake_case : Dict = os.path.join(__lowerCamelCase , "stage-1" )
snake_case : Optional[Any] = {
"accelerator": accelerator,
"model_name_or_path": args.model_name_or_path,
"cache_dir": args.cache_dir,
"do_train": True,
"train_file": data_files["train"] if iteration == 0 else data_files["train_pseudo"],
"do_eval": True if args.eval_file is not None else False,
"eval_file": data_files["eval"],
"do_predict": True,
"infer_file": data_files["infer"],
"task_name": args.task_name,
"label_list": args.label_list,
"output_dir": current_output_dir,
"eval_metric": args.eval_metric,
"evaluation_strategy": args.evaluation_strategy,
"early_stopping_patience": args.early_stopping_patience,
"early_stopping_threshold": args.early_stopping_threshold,
"seed": args.seed,
}
# Add additional training arguments
for key, value in kwargs.items():
if key not in arguments_dict and not hasattr(__lowerCamelCase , __lowerCamelCase ):
arguments_dict.update({key: value} )
snake_case : int = os.path.join(__lowerCamelCase , "best-checkpoint" , __lowerCamelCase )
if os.path.exists(__lowerCamelCase ):
logger.info(
"Found existing model checkpoint at %s. Skipping self-training: iteration: %d, stage: 1." , __lowerCamelCase , __lowerCamelCase , )
else:
logger.info("***** Running self-training: iteration: %d, stage: 1 *****" , __lowerCamelCase )
finetune(**__lowerCamelCase )
accelerator.wait_for_everyone()
assert os.path.exists(__lowerCamelCase )
logger.info("Self-training job completed: iteration: %d, stage: 1." , __lowerCamelCase )
if iteration > 0 and args.finetune_on_labeled_data:
# Stage 2 (optional): fine-tuning on the original labeled data
snake_case : str = os.path.join(__lowerCamelCase , "best-checkpoint" )
snake_case : Dict = os.path.join(__lowerCamelCase , "stage-2" )
# Update arguments_dict
snake_case : List[str] = model_path
snake_case : Optional[Any] = data_files["train"]
snake_case : Optional[Any] = current_output_dir
snake_case : Union[str, Any] = os.path.join(__lowerCamelCase , "best-checkpoint" , __lowerCamelCase )
if os.path.exists(__lowerCamelCase ):
logger.info(
"Found existing model checkpoint at %s. Skipping self-training: iteration: %d, stage: 2." , __lowerCamelCase , __lowerCamelCase , )
else:
logger.info("***** Running self-training: iteration: %d, stage: 2 *****" , __lowerCamelCase )
finetune(**__lowerCamelCase )
accelerator.wait_for_everyone()
assert os.path.exists(__lowerCamelCase )
logger.info("Self-training job completed: iteration: %d, stage: 2." , __lowerCamelCase )
snake_case : int = iteration
snake_case : Tuple = data_dir_format(iteration + 1 )
snake_case : Tuple = AutoConfig.from_pretrained(os.path.join(__lowerCamelCase , "best-checkpoint" ) )
snake_case : Optional[int] = config.idalabel
snake_case : List[Any] = os.path.join(__lowerCamelCase , "eval_results_best-checkpoint.json" )
snake_case : Union[str, Any] = os.path.join(__lowerCamelCase , "test_results_best-checkpoint.json" )
assert os.path.exists(__lowerCamelCase )
with open(__lowerCamelCase , "r" ) as f:
snake_case : Dict = float(json.load(__lowerCamelCase )[args.eval_metric] )
snake_case : Optional[int] = os.path.join(__lowerCamelCase , "infer_output_best-checkpoint.csv" )
assert os.path.exists(__lowerCamelCase )
# Loading the dataset from local csv or json files.
snake_case : Optional[Any] = load_dataset(args.data_file_extension , data_files={"data": data_files["infer"]} )["data"]
snake_case : Dict = load_dataset("csv" , data_files={"data": infer_output_file} )["data"]
if accelerator.is_main_process:
os.makedirs(__lowerCamelCase , exist_ok=__lowerCamelCase )
shutil.copy(__lowerCamelCase , os.path.join(__lowerCamelCase , f"""eval_results_iter-{iteration}.json""" ) )
if os.path.exists(__lowerCamelCase ):
shutil.copy(__lowerCamelCase , os.path.join(__lowerCamelCase , f"""test_results_iter-{iteration}.json""" ) )
create_pseudo_labeled_data(__lowerCamelCase , __lowerCamelCase , __lowerCamelCase , __lowerCamelCase , __lowerCamelCase , __lowerCamelCase )
accelerator.wait_for_everyone()
snake_case : str = os.path.join(__lowerCamelCase , f"""train_pseudo.{args.data_file_extension}""" )
if args.evaluation_strategy != IntervalStrategy.NO.value:
snake_case : List[Any] = eval_result
if best_iteration is None:
snake_case : List[Any] = new_iteration
snake_case : int = new_eval_result
else:
if new_eval_result - best_eval_result > args.early_stopping_threshold:
snake_case : int = new_iteration
snake_case : Union[str, Any] = new_eval_result
snake_case : str = 0
else:
if new_eval_result == best_eval_result:
snake_case : Any = new_iteration
snake_case : Union[str, Any] = new_eval_result
early_stopping_patience_counter += 1
if early_stopping_patience_counter >= args.early_stopping_patience:
snake_case : Tuple = True
progress_bar.update(1 )
if should_training_stop:
break
if best_iteration is not None:
# Save the best iteration
logger.info("Best iteration: %d" , __lowerCamelCase )
logger.info("Best evaluation result: %s = %f" , args.eval_metric , __lowerCamelCase )
accelerator.wait_for_everyone()
if accelerator.is_main_process:
shutil.copy(
os.path.join(__lowerCamelCase , f"""eval_results_iter-{iteration}.json""" ) , os.path.join(__lowerCamelCase , "eval_results_best-iteration.json" ) , )
else:
# Assume that the last iteration is the best
logger.info("Best iteration: %d" , args.max_selftrain_iterations - 1 )
logger.info("Best evaluation result: %s = %f" , args.eval_metric , __lowerCamelCase )
accelerator.wait_for_everyone()
if accelerator.is_main_process:
shutil.copy(
os.path.join(__lowerCamelCase , f"""eval_results_iter-{args.max_selftrain_iterations - 1}.json""" ) , os.path.join(__lowerCamelCase , "eval_results_best-iteration.json" ) , )
| 59
| 1
|
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 = {
"""junnyu/roformer_chinese_small""": """https://huggingface.co/junnyu/roformer_chinese_small/resolve/main/config.json""",
"""junnyu/roformer_chinese_base""": """https://huggingface.co/junnyu/roformer_chinese_base/resolve/main/config.json""",
"""junnyu/roformer_chinese_char_small""": (
"""https://huggingface.co/junnyu/roformer_chinese_char_small/resolve/main/config.json"""
),
"""junnyu/roformer_chinese_char_base""": (
"""https://huggingface.co/junnyu/roformer_chinese_char_base/resolve/main/config.json"""
),
"""junnyu/roformer_small_discriminator""": (
"""https://huggingface.co/junnyu/roformer_small_discriminator/resolve/main/config.json"""
),
"""junnyu/roformer_small_generator""": (
"""https://huggingface.co/junnyu/roformer_small_generator/resolve/main/config.json"""
),
# See all RoFormer models at https://huggingface.co/models?filter=roformer
}
class UpperCAmelCase ( A_ ):
A__ : Tuple = "roformer"
def __init__(self : int , snake_case__ : Optional[Any]=5_00_00 , snake_case__ : Optional[int]=None , snake_case__ : Any=7_68 , snake_case__ : Optional[int]=12 , snake_case__ : Optional[int]=12 , snake_case__ : Union[str, Any]=30_72 , snake_case__ : Optional[int]="gelu" , snake_case__ : int=0.1 , snake_case__ : Dict=0.1 , snake_case__ : Tuple=15_36 , snake_case__ : List[str]=2 , snake_case__ : str=0.02 , snake_case__ : Dict=1e-12 , snake_case__ : Any=0 , snake_case__ : str=False , snake_case__ : Dict=True , **snake_case__ : Optional[Any] , ) -> Dict:
'''simple docstring'''
super().__init__(pad_token_id=snake_case__ , **snake_case__ )
snake_case : List[Any] = vocab_size
snake_case : Any = hidden_size if embedding_size is None else embedding_size
snake_case : Tuple = hidden_size
snake_case : str = num_hidden_layers
snake_case : int = num_attention_heads
snake_case : Optional[int] = hidden_act
snake_case : Optional[int] = intermediate_size
snake_case : int = hidden_dropout_prob
snake_case : List[str] = attention_probs_dropout_prob
snake_case : str = max_position_embeddings
snake_case : Union[str, Any] = type_vocab_size
snake_case : List[Any] = initializer_range
snake_case : Optional[int] = layer_norm_eps
snake_case : Optional[Any] = rotary_value
snake_case : Union[str, Any] = use_cache
class UpperCAmelCase ( A_ ):
@property
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> Mapping[str, Mapping[int, str]]:
'''simple docstring'''
if self.task == "multiple-choice":
snake_case : Any = {0: "batch", 1: "choice", 2: "sequence"}
else:
snake_case : Tuple = {0: "batch", 1: "sequence"}
snake_case : str = {0: "batch", 1: "sequence"}
return OrderedDict(
[
("input_ids", dynamic_axis),
("attention_mask", dynamic_axis),
("token_type_ids", dynamic_axis),
] )
| 59
|
from typing import TYPE_CHECKING
from ...utils import (
OptionalDependencyNotAvailable,
_LazyModule,
is_flax_available,
is_sentencepiece_available,
is_tf_available,
is_tokenizers_available,
is_torch_available,
)
__lowerCamelCase = {"""configuration_xglm""": ["""XGLM_PRETRAINED_CONFIG_ARCHIVE_MAP""", """XGLMConfig"""]}
try:
if not is_sentencepiece_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = ["""XGLMTokenizer"""]
try:
if not is_tokenizers_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = ["""XGLMTokenizerFast"""]
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = [
"""XGLM_PRETRAINED_MODEL_ARCHIVE_LIST""",
"""XGLMForCausalLM""",
"""XGLMModel""",
"""XGLMPreTrainedModel""",
]
try:
if not is_flax_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = [
"""FlaxXGLMForCausalLM""",
"""FlaxXGLMModel""",
"""FlaxXGLMPreTrainedModel""",
]
try:
if not is_tf_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = [
"""TF_XGLM_PRETRAINED_MODEL_ARCHIVE_LIST""",
"""TFXGLMForCausalLM""",
"""TFXGLMModel""",
"""TFXGLMPreTrainedModel""",
]
if TYPE_CHECKING:
from .configuration_xglm import XGLM_PRETRAINED_CONFIG_ARCHIVE_MAP, XGLMConfig
try:
if not is_sentencepiece_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .tokenization_xglm import XGLMTokenizer
try:
if not is_tokenizers_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .tokenization_xglm_fast import XGLMTokenizerFast
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_xglm import XGLM_PRETRAINED_MODEL_ARCHIVE_LIST, XGLMForCausalLM, XGLMModel, XGLMPreTrainedModel
try:
if not is_flax_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_flax_xglm import FlaxXGLMForCausalLM, FlaxXGLMModel, FlaxXGLMPreTrainedModel
try:
if not is_tf_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_tf_xglm import (
TF_XGLM_PRETRAINED_MODEL_ARCHIVE_LIST,
TFXGLMForCausalLM,
TFXGLMModel,
TFXGLMPreTrainedModel,
)
else:
import sys
__lowerCamelCase = _LazyModule(__name__, globals()["""__file__"""], _import_structure)
| 59
| 1
|
from __future__ import annotations
from decimal import Decimal
from math import * # noqa: F403
from sympy import diff
def UpperCamelCase ( __lowerCamelCase : str , __lowerCamelCase : float | Decimal , __lowerCamelCase : float = 10**-10 ):
snake_case : List[Any] = a
while True:
snake_case : List[Any] = Decimal(__lowerCamelCase ) - (
Decimal(eval(__lowerCamelCase ) ) / Decimal(eval(str(diff(__lowerCamelCase ) ) ) ) # noqa: S307
)
# This number dictates the accuracy of the answer
if abs(eval(__lowerCamelCase ) ) < precision: # noqa: S307
return float(__lowerCamelCase )
# Let's Execute
if __name__ == "__main__":
# Find root of trigonometric function
# Find value of pi
print(F'The root of sin(x) = 0 is {newton_raphson("sin(x)", 2)}')
# Find root of polynomial
print(F'The root of x**2 - 5*x + 2 = 0 is {newton_raphson("x**2 - 5*x + 2", 0.4)}')
# Find Square Root of 5
print(F'The root of log(x) - 1 = 0 is {newton_raphson("log(x) - 1", 2)}')
# Exponential Roots
print(F'The root of exp(x) - 1 = 0 is {newton_raphson("exp(x) - 1", 0)}')
| 59
|
from ...configuration_utils import PretrainedConfig
from ...utils import logging
__lowerCamelCase = logging.get_logger(__name__)
__lowerCamelCase = {
# See all MEGATRON_BERT models at https://huggingface.co/models?filter=bert
}
class UpperCAmelCase ( A_ ):
A__ : List[str] = "megatron-bert"
def __init__(self : Optional[int] , snake_case__ : List[str]=2_90_56 , snake_case__ : List[Any]=10_24 , snake_case__ : str=24 , snake_case__ : Tuple=16 , snake_case__ : Union[str, Any]=40_96 , snake_case__ : str="gelu" , snake_case__ : str=0.1 , snake_case__ : Optional[int]=0.1 , snake_case__ : Tuple=5_12 , snake_case__ : Union[str, Any]=2 , snake_case__ : Dict=0.02 , snake_case__ : List[Any]=1e-12 , snake_case__ : int=0 , snake_case__ : Tuple="absolute" , snake_case__ : Any=True , **snake_case__ : Union[str, Any] , ) -> Optional[Any]:
'''simple docstring'''
super().__init__(pad_token_id=snake_case__ , **snake_case__ )
snake_case : Tuple = vocab_size
snake_case : str = hidden_size
snake_case : str = num_hidden_layers
snake_case : str = num_attention_heads
snake_case : Optional[int] = hidden_act
snake_case : int = intermediate_size
snake_case : List[str] = hidden_dropout_prob
snake_case : Union[str, Any] = attention_probs_dropout_prob
snake_case : Dict = max_position_embeddings
snake_case : List[str] = type_vocab_size
snake_case : List[str] = initializer_range
snake_case : Tuple = layer_norm_eps
snake_case : int = position_embedding_type
snake_case : str = use_cache
| 59
| 1
|
import requests
__lowerCamelCase = """YOUR API KEY"""
def UpperCamelCase ( __lowerCamelCase : str , __lowerCamelCase : str = giphy_api_key ):
snake_case : Tuple = "+".join(query.split() )
snake_case : Union[str, Any] = f"""https://api.giphy.com/v1/gifs/search?q={formatted_query}&api_key={api_key}"""
snake_case : Optional[Any] = requests.get(__lowerCamelCase ).json()["data"]
return [gif["url"] for gif in gifs]
if __name__ == "__main__":
print("""\n""".join(get_gifs("""space ship""")))
| 59
|
import gc
import unittest
from parameterized import parameterized
from diffusers import FlaxUNetaDConditionModel
from diffusers.utils import is_flax_available
from diffusers.utils.testing_utils import load_hf_numpy, require_flax, slow
if is_flax_available():
import jax
import jax.numpy as jnp
@slow
@require_flax
class UpperCAmelCase ( unittest.TestCase ):
def _SCREAMING_SNAKE_CASE (self : str , snake_case__ : Union[str, Any] , snake_case__ : List[str] ) -> List[str]:
'''simple docstring'''
return f"""gaussian_noise_s={seed}_shape={'_'.join([str(snake_case__ ) for s in shape] )}.npy"""
def _SCREAMING_SNAKE_CASE (self : Tuple ) -> int:
'''simple docstring'''
super().tearDown()
gc.collect()
def _SCREAMING_SNAKE_CASE (self : str , snake_case__ : Optional[Any]=0 , snake_case__ : Any=(4, 4, 64, 64) , snake_case__ : List[Any]=False ) -> int:
'''simple docstring'''
snake_case : Optional[Any] = jnp.bfloataa if fpaa else jnp.floataa
snake_case : Optional[int] = jnp.array(load_hf_numpy(self.get_file_format(snake_case__ , snake_case__ ) ) , dtype=snake_case__ )
return image
def _SCREAMING_SNAKE_CASE (self : Optional[int] , snake_case__ : Tuple=False , snake_case__ : List[Any]="CompVis/stable-diffusion-v1-4" ) -> List[Any]:
'''simple docstring'''
snake_case : List[str] = jnp.bfloataa if fpaa else jnp.floataa
snake_case : str = "bf16" if fpaa else None
snake_case , snake_case : Optional[int] = FlaxUNetaDConditionModel.from_pretrained(
snake_case__ , subfolder="unet" , dtype=snake_case__ , revision=snake_case__ )
return model, params
def _SCREAMING_SNAKE_CASE (self : List[str] , snake_case__ : Union[str, Any]=0 , snake_case__ : Union[str, Any]=(4, 77, 7_68) , snake_case__ : Dict=False ) -> List[str]:
'''simple docstring'''
snake_case : Any = jnp.bfloataa if fpaa else jnp.floataa
snake_case : Any = jnp.array(load_hf_numpy(self.get_file_format(snake_case__ , snake_case__ ) ) , dtype=snake_case__ )
return hidden_states
@parameterized.expand(
[
# fmt: off
[83, 4, [-0.2323, -0.1304, 0.0813, -0.3093, -0.0919, -0.1571, -0.1125, -0.5806]],
[17, 0.55, [-0.0831, -0.2443, 0.0901, -0.0919, 0.3396, 0.0103, -0.3743, 0.0701]],
[8, 0.89, [-0.4863, 0.0859, 0.0875, -0.1658, 0.9199, -0.0114, 0.4839, 0.4639]],
[3, 10_00, [-0.5649, 0.2402, -0.5518, 0.1248, 1.1328, -0.2443, -0.0325, -1.0078]],
# fmt: on
] )
def _SCREAMING_SNAKE_CASE (self : Optional[int] , snake_case__ : int , snake_case__ : Optional[int] , snake_case__ : Dict ) -> List[str]:
'''simple docstring'''
snake_case , snake_case : List[str] = self.get_unet_model(model_id="CompVis/stable-diffusion-v1-4" , fpaa=snake_case__ )
snake_case : Union[str, Any] = self.get_latents(snake_case__ , fpaa=snake_case__ )
snake_case : List[str] = self.get_encoder_hidden_states(snake_case__ , fpaa=snake_case__ )
snake_case : Dict = model.apply(
{"params": params} , snake_case__ , jnp.array(snake_case__ , dtype=jnp.intaa ) , encoder_hidden_states=snake_case__ , ).sample
assert sample.shape == latents.shape
snake_case : Optional[Any] = jnp.asarray(jax.device_get((sample[-1, -2:, -2:, :2].flatten()) ) , dtype=jnp.floataa )
snake_case : Optional[int] = jnp.array(snake_case__ , dtype=jnp.floataa )
# Found torch (float16) and flax (bfloat16) outputs to be within this tolerance, in the same hardware
assert jnp.allclose(snake_case__ , snake_case__ , atol=1e-2 )
@parameterized.expand(
[
# fmt: off
[83, 4, [0.1514, 0.0807, 0.1624, 0.1016, -0.1896, 0.0263, 0.0677, 0.2310]],
[17, 0.55, [0.1164, -0.0216, 0.0170, 0.1589, -0.3120, 0.1005, -0.0581, -0.1458]],
[8, 0.89, [-0.1758, -0.0169, 0.1004, -0.1411, 0.1312, 0.1103, -0.1996, 0.2139]],
[3, 10_00, [0.1214, 0.0352, -0.0731, -0.1562, -0.0994, -0.0906, -0.2340, -0.0539]],
# fmt: on
] )
def _SCREAMING_SNAKE_CASE (self : Optional[int] , snake_case__ : Optional[int] , snake_case__ : str , snake_case__ : Tuple ) -> str:
'''simple docstring'''
snake_case , snake_case : List[Any] = self.get_unet_model(model_id="stabilityai/stable-diffusion-2" , fpaa=snake_case__ )
snake_case : List[str] = self.get_latents(snake_case__ , shape=(4, 4, 96, 96) , fpaa=snake_case__ )
snake_case : Union[str, Any] = self.get_encoder_hidden_states(snake_case__ , shape=(4, 77, 10_24) , fpaa=snake_case__ )
snake_case : Optional[int] = model.apply(
{"params": params} , snake_case__ , jnp.array(snake_case__ , dtype=jnp.intaa ) , encoder_hidden_states=snake_case__ , ).sample
assert sample.shape == latents.shape
snake_case : int = jnp.asarray(jax.device_get((sample[-1, -2:, -2:, :2].flatten()) ) , dtype=jnp.floataa )
snake_case : Dict = jnp.array(snake_case__ , dtype=jnp.floataa )
# Found torch (float16) and flax (bfloat16) outputs to be within this tolerance, on the same hardware
assert jnp.allclose(snake_case__ , snake_case__ , atol=1e-2 )
| 59
| 1
|
import time
import warnings
from abc import ABC
from copy import deepcopy
from typing import Optional
import torch
from ..utils import add_start_docstrings, logging
__lowerCamelCase = logging.get_logger(__name__)
__lowerCamelCase = R"""
Args:
input_ids (`torch.LongTensor` of shape `(batch_size, sequence_length)`):
Indices of input sequence tokens in the vocabulary.
Indices can be obtained using [`AutoTokenizer`]. See [`PreTrainedTokenizer.encode`] and
[`PreTrainedTokenizer.__call__`] for details.
[What are input IDs?](../glossary#input-ids)
scores (`torch.FloatTensor` of shape `(batch_size, config.vocab_size)`):
Prediction scores of a language modeling head. These can be scores for each vocabulary token before SoftMax
or scores for each vocabulary token after SoftMax.
kwargs (`Dict[str, Any]`, *optional*):
Additional stopping criteria specific kwargs.
Return:
`bool`. `False` indicates we should continue, `True` indicates we should stop.
"""
class UpperCAmelCase ( A_ ):
@add_start_docstrings(snake_case__ )
def __call__(self : Union[str, Any] , snake_case__ : torch.LongTensor , snake_case__ : torch.FloatTensor , **snake_case__ : Optional[int] ) -> bool:
'''simple docstring'''
raise NotImplementedError("StoppingCriteria needs to be subclassed" )
class UpperCAmelCase ( A_ ):
def __init__(self : Union[str, Any] , snake_case__ : int , snake_case__ : Optional[int] = None ) -> Any:
'''simple docstring'''
snake_case : List[str] = max_length
snake_case : Dict = max_position_embeddings
@add_start_docstrings(snake_case__ )
def __call__(self : str , snake_case__ : torch.LongTensor , snake_case__ : torch.FloatTensor , **snake_case__ : int ) -> bool:
'''simple docstring'''
snake_case : Optional[Any] = input_ids.shape[-1]
snake_case : Union[str, Any] = cur_len >= self.max_length
if self.max_position_embeddings is not None and not is_done and cur_len >= self.max_position_embeddings:
logger.warning_once(
"This is a friendly reminder - the current text generation call will exceed the model's predefined "
f"""maximum length ({self.max_position_embeddings}). Depending on the model, you may observe """
"exceptions, performance degradation, or nothing at all." )
return is_done
class UpperCAmelCase ( A_ ):
def __init__(self : List[Any] , snake_case__ : int , snake_case__ : int ) -> Union[str, Any]:
'''simple docstring'''
warnings.warn(
"The class `MaxNewTokensCriteria` is deprecated. "
f"""Please use `MaxLengthCriteria(max_length={start_length + max_new_tokens})` """
"with `max_length = start_length + max_new_tokens` instead." , snake_case__ , )
snake_case : Union[str, Any] = start_length
snake_case : Union[str, Any] = max_new_tokens
snake_case : Union[str, Any] = start_length + max_new_tokens
@add_start_docstrings(snake_case__ )
def __call__(self : Optional[Any] , snake_case__ : torch.LongTensor , snake_case__ : torch.FloatTensor , **snake_case__ : Any ) -> bool:
'''simple docstring'''
return input_ids.shape[-1] >= self.max_length
class UpperCAmelCase ( A_ ):
def __init__(self : List[str] , snake_case__ : float , snake_case__ : Optional[float] = None ) -> Any:
'''simple docstring'''
snake_case : Tuple = max_time
snake_case : List[str] = time.time() if initial_timestamp is None else initial_timestamp
@add_start_docstrings(snake_case__ )
def __call__(self : Dict , snake_case__ : torch.LongTensor , snake_case__ : torch.FloatTensor , **snake_case__ : str ) -> bool:
'''simple docstring'''
return time.time() - self.initial_timestamp > self.max_time
class UpperCAmelCase ( A_ ):
@add_start_docstrings(snake_case__ )
def __call__(self : Any , snake_case__ : torch.LongTensor , snake_case__ : torch.FloatTensor , **snake_case__ : List[str] ) -> bool:
'''simple docstring'''
return any(criteria(snake_case__ , snake_case__ ) for criteria in self )
@property
def _SCREAMING_SNAKE_CASE (self : Optional[int] ) -> Optional[int]:
'''simple docstring'''
for stopping_criterium in self:
if isinstance(snake_case__ , snake_case__ ):
return stopping_criterium.max_length
elif isinstance(snake_case__ , snake_case__ ):
return stopping_criterium.max_length
return None
def UpperCamelCase ( __lowerCamelCase : StoppingCriteriaList , __lowerCamelCase : int ):
snake_case : Any = stopping_criteria.max_length
snake_case : Tuple = deepcopy(__lowerCamelCase )
if stopping_max_length is not None and stopping_max_length != max_length:
warnings.warn("You set different `max_length` for stopping criteria and `max_length` parameter" , __lowerCamelCase )
elif stopping_max_length is None:
new_stopping_criteria.append(MaxLengthCriteria(max_length=__lowerCamelCase ) )
return new_stopping_criteria
| 59
|
import argparse
import re
from typing import Dict
import torch
from datasets import Audio, Dataset, load_dataset, load_metric
from transformers import AutoFeatureExtractor, pipeline
def UpperCamelCase ( __lowerCamelCase : Dataset , __lowerCamelCase : Dict[str, str] ):
snake_case : int = args.log_outputs
snake_case : Dict = "_".join(args.dataset.split("/" ) + [args.config, args.split] )
# load metric
snake_case : List[str] = load_metric("wer" )
snake_case : Tuple = load_metric("cer" )
# compute metrics
snake_case : List[Any] = wer.compute(references=result["target"] , predictions=result["prediction"] )
snake_case : int = cer.compute(references=result["target"] , predictions=result["prediction"] )
# print & log results
snake_case : int = f"""WER: {wer_result}\nCER: {cer_result}"""
print(__lowerCamelCase )
with open(f"""{dataset_id}_eval_results.txt""" , "w" ) as f:
f.write(__lowerCamelCase )
# log all results in text file. Possibly interesting for analysis
if log_outputs is not None:
snake_case : int = f"""log_{dataset_id}_predictions.txt"""
snake_case : List[Any] = f"""log_{dataset_id}_targets.txt"""
with open(__lowerCamelCase , "w" ) as p, open(__lowerCamelCase , "w" ) as t:
# mapping function to write output
def write_to_file(__lowerCamelCase : str , __lowerCamelCase : Optional[int] ):
p.write(f"""{i}""" + "\n" )
p.write(batch["prediction"] + "\n" )
t.write(f"""{i}""" + "\n" )
t.write(batch["target"] + "\n" )
result.map(__lowerCamelCase , with_indices=__lowerCamelCase )
def UpperCamelCase ( __lowerCamelCase : str ):
snake_case : List[Any] = "[,?.!\-\;\:\"“%‘”�—’…–]" # noqa: W605 IMPORTANT: this should correspond to the chars that were ignored during training
snake_case : List[Any] = re.sub(__lowerCamelCase , "" , text.lower() )
# In addition, we can normalize the target text, e.g. removing new lines characters etc...
# note that order is important here!
snake_case : Optional[Any] = ["\n\n", "\n", " ", " "]
for t in token_sequences_to_ignore:
snake_case : Dict = " ".join(text.split(__lowerCamelCase ) )
return text
def UpperCamelCase ( __lowerCamelCase : int ):
# load dataset
snake_case : str = load_dataset(args.dataset , args.config , split=args.split , use_auth_token=__lowerCamelCase )
# for testing: only process the first two examples as a test
# dataset = dataset.select(range(10))
# load processor
snake_case : List[Any] = AutoFeatureExtractor.from_pretrained(args.model_id )
snake_case : Union[str, Any] = feature_extractor.sampling_rate
# resample audio
snake_case : Union[str, Any] = dataset.cast_column("audio" , Audio(sampling_rate=__lowerCamelCase ) )
# load eval pipeline
if args.device is None:
snake_case : List[str] = 0 if torch.cuda.is_available() else -1
snake_case : str = pipeline("automatic-speech-recognition" , model=args.model_id , device=args.device )
# map function to decode audio
def map_to_pred(__lowerCamelCase : int ):
snake_case : Dict = asr(
batch["audio"]["array"] , chunk_length_s=args.chunk_length_s , stride_length_s=args.stride_length_s )
snake_case : str = prediction["text"]
snake_case : Tuple = normalize_text(batch["sentence"] )
return batch
# run inference on all examples
snake_case : Dict = dataset.map(__lowerCamelCase , remove_columns=dataset.column_names )
# compute and log_results
# do not change function below
log_results(__lowerCamelCase , __lowerCamelCase )
if __name__ == "__main__":
__lowerCamelCase = argparse.ArgumentParser()
parser.add_argument(
"""--model_id""", type=str, required=True, help="""Model identifier. Should be loadable with 🤗 Transformers"""
)
parser.add_argument(
"""--dataset""",
type=str,
required=True,
help="""Dataset name to evaluate the `model_id`. Should be loadable with 🤗 Datasets""",
)
parser.add_argument(
"""--config""", type=str, required=True, help="""Config of the dataset. *E.g.* `'en'` for Common Voice"""
)
parser.add_argument("""--split""", type=str, required=True, help="""Split of the dataset. *E.g.* `'test'`""")
parser.add_argument(
"""--chunk_length_s""", type=float, default=None, help="""Chunk length in seconds. Defaults to 5 seconds."""
)
parser.add_argument(
"""--stride_length_s""", type=float, default=None, help="""Stride of the audio chunks. Defaults to 1 second."""
)
parser.add_argument(
"""--log_outputs""", action="""store_true""", help="""If defined, write outputs to log file for analysis."""
)
parser.add_argument(
"""--device""",
type=int,
default=None,
help="""The device to run the pipeline on. -1 for CPU (default), 0 for the first GPU and so on.""",
)
__lowerCamelCase = parser.parse_args()
main(args)
| 59
| 1
|
from typing import TYPE_CHECKING
from ...utils import OptionalDependencyNotAvailable, _LazyModule, is_tokenizers_available, is_torch_available
__lowerCamelCase = {
"""configuration_altclip""": [
"""ALTCLIP_PRETRAINED_CONFIG_ARCHIVE_MAP""",
"""AltCLIPConfig""",
"""AltCLIPTextConfig""",
"""AltCLIPVisionConfig""",
],
"""processing_altclip""": ["""AltCLIPProcessor"""],
}
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
__lowerCamelCase = [
"""ALTCLIP_PRETRAINED_MODEL_ARCHIVE_LIST""",
"""AltCLIPPreTrainedModel""",
"""AltCLIPModel""",
"""AltCLIPTextModel""",
"""AltCLIPVisionModel""",
]
if TYPE_CHECKING:
from .configuration_altclip import (
ALTCLIP_PRETRAINED_CONFIG_ARCHIVE_MAP,
AltCLIPConfig,
AltCLIPTextConfig,
AltCLIPVisionConfig,
)
from .processing_altclip import AltCLIPProcessor
try:
if not is_torch_available():
raise OptionalDependencyNotAvailable()
except OptionalDependencyNotAvailable:
pass
else:
from .modeling_altclip import (
ALTCLIP_PRETRAINED_MODEL_ARCHIVE_LIST,
AltCLIPModel,
AltCLIPPreTrainedModel,
AltCLIPTextModel,
AltCLIPVisionModel,
)
else:
import sys
__lowerCamelCase = _LazyModule(__name__, globals()["""__file__"""], _import_structure, module_spec=__spec__)
| 59
|
from typing import Optional, Tuple, Union
import flax
import flax.linen as nn
import jax
import jax.numpy as jnp
from flax.core.frozen_dict import FrozenDict
from ..configuration_utils import ConfigMixin, flax_register_to_config
from ..utils import BaseOutput
from .embeddings_flax import FlaxTimestepEmbedding, FlaxTimesteps
from .modeling_flax_utils import FlaxModelMixin
from .unet_ad_blocks_flax import (
FlaxCrossAttnDownBlockaD,
FlaxCrossAttnUpBlockaD,
FlaxDownBlockaD,
FlaxUNetMidBlockaDCrossAttn,
FlaxUpBlockaD,
)
@flax.struct.dataclass
class UpperCAmelCase ( A_ ):
A__ : jnp.ndarray
@flax_register_to_config
class UpperCAmelCase ( nn.Module ,A_ ,A_ ):
A__ : int = 32
A__ : int = 4
A__ : int = 4
A__ : Tuple[str] = (
"CrossAttnDownBlock2D",
"CrossAttnDownBlock2D",
"CrossAttnDownBlock2D",
"DownBlock2D",
)
A__ : Tuple[str] = ("UpBlock2D", "CrossAttnUpBlock2D", "CrossAttnUpBlock2D", "CrossAttnUpBlock2D")
A__ : Union[bool, Tuple[bool]] = False
A__ : Tuple[int] = (3_20, 6_40, 12_80, 12_80)
A__ : int = 2
A__ : Union[int, Tuple[int]] = 8
A__ : Optional[Union[int, Tuple[int]]] = None
A__ : int = 12_80
A__ : float = 0.0
A__ : bool = False
A__ : jnp.dtype = jnp.floataa
A__ : bool = True
A__ : int = 0
A__ : bool = False
def _SCREAMING_SNAKE_CASE (self : Optional[int] , snake_case__ : jax.random.KeyArray ) -> FrozenDict:
'''simple docstring'''
snake_case : Dict = (1, self.in_channels, self.sample_size, self.sample_size)
snake_case : Any = jnp.zeros(snake_case__ , dtype=jnp.floataa )
snake_case : List[str] = jnp.ones((1,) , dtype=jnp.intaa )
snake_case : str = jnp.zeros((1, 1, self.cross_attention_dim) , dtype=jnp.floataa )
snake_case , snake_case : Optional[int] = jax.random.split(snake_case__ )
snake_case : Union[str, Any] = {"params": params_rng, "dropout": dropout_rng}
return self.init(snake_case__ , snake_case__ , snake_case__ , snake_case__ )["params"]
def _SCREAMING_SNAKE_CASE (self : str ) -> Tuple:
'''simple docstring'''
snake_case : str = self.block_out_channels
snake_case : Optional[Any] = block_out_channels[0] * 4
if self.num_attention_heads is not None:
raise ValueError(
"At the moment it is not possible to define the number of attention heads via `num_attention_heads` because of a naming issue as described in https://github.com/huggingface/diffusers/issues/2011#issuecomment-1547958131. Passing `num_attention_heads` will only be supported in diffusers v0.19." )
# If `num_attention_heads` is not defined (which is the case for most models)
# it will default to `attention_head_dim`. This looks weird upon first reading it and it is.
# The reason for this behavior is to correct for incorrectly named variables that were introduced
# when this library was created. The incorrect naming was only discovered much later in https://github.com/huggingface/diffusers/issues/2011#issuecomment-1547958131
# Changing `attention_head_dim` to `num_attention_heads` for 40,000+ configurations is too backwards breaking
# which is why we correct for the naming here.
snake_case : Tuple = self.num_attention_heads or self.attention_head_dim
# input
snake_case : Tuple = nn.Conv(
block_out_channels[0] , kernel_size=(3, 3) , strides=(1, 1) , padding=((1, 1), (1, 1)) , dtype=self.dtype , )
# time
snake_case : Union[str, Any] = FlaxTimesteps(
block_out_channels[0] , flip_sin_to_cos=self.flip_sin_to_cos , freq_shift=self.config.freq_shift )
snake_case : Dict = FlaxTimestepEmbedding(snake_case__ , dtype=self.dtype )
snake_case : List[str] = self.only_cross_attention
if isinstance(snake_case__ , snake_case__ ):
snake_case : List[Any] = (only_cross_attention,) * len(self.down_block_types )
if isinstance(snake_case__ , snake_case__ ):
snake_case : List[Any] = (num_attention_heads,) * len(self.down_block_types )
# down
snake_case : List[Any] = []
snake_case : Optional[int] = block_out_channels[0]
for i, down_block_type in enumerate(self.down_block_types ):
snake_case : List[Any] = output_channel
snake_case : Dict = block_out_channels[i]
snake_case : Optional[Any] = i == len(snake_case__ ) - 1
if down_block_type == "CrossAttnDownBlock2D":
snake_case : List[Any] = FlaxCrossAttnDownBlockaD(
in_channels=snake_case__ , out_channels=snake_case__ , dropout=self.dropout , num_layers=self.layers_per_block , num_attention_heads=num_attention_heads[i] , add_downsample=not is_final_block , use_linear_projection=self.use_linear_projection , only_cross_attention=only_cross_attention[i] , use_memory_efficient_attention=self.use_memory_efficient_attention , dtype=self.dtype , )
else:
snake_case : Union[str, Any] = FlaxDownBlockaD(
in_channels=snake_case__ , out_channels=snake_case__ , dropout=self.dropout , num_layers=self.layers_per_block , add_downsample=not is_final_block , dtype=self.dtype , )
down_blocks.append(snake_case__ )
snake_case : Dict = down_blocks
# mid
snake_case : Optional[int] = FlaxUNetMidBlockaDCrossAttn(
in_channels=block_out_channels[-1] , dropout=self.dropout , num_attention_heads=num_attention_heads[-1] , use_linear_projection=self.use_linear_projection , use_memory_efficient_attention=self.use_memory_efficient_attention , dtype=self.dtype , )
# up
snake_case : Optional[Any] = []
snake_case : Optional[int] = list(reversed(snake_case__ ) )
snake_case : Dict = list(reversed(snake_case__ ) )
snake_case : Tuple = list(reversed(snake_case__ ) )
snake_case : Optional[Any] = reversed_block_out_channels[0]
for i, up_block_type in enumerate(self.up_block_types ):
snake_case : Optional[int] = output_channel
snake_case : List[Any] = reversed_block_out_channels[i]
snake_case : Union[str, Any] = reversed_block_out_channels[min(i + 1 , len(snake_case__ ) - 1 )]
snake_case : int = i == len(snake_case__ ) - 1
if up_block_type == "CrossAttnUpBlock2D":
snake_case : Any = FlaxCrossAttnUpBlockaD(
in_channels=snake_case__ , out_channels=snake_case__ , prev_output_channel=snake_case__ , num_layers=self.layers_per_block + 1 , num_attention_heads=reversed_num_attention_heads[i] , add_upsample=not is_final_block , dropout=self.dropout , use_linear_projection=self.use_linear_projection , only_cross_attention=only_cross_attention[i] , use_memory_efficient_attention=self.use_memory_efficient_attention , dtype=self.dtype , )
else:
snake_case : Optional[int] = FlaxUpBlockaD(
in_channels=snake_case__ , out_channels=snake_case__ , prev_output_channel=snake_case__ , num_layers=self.layers_per_block + 1 , add_upsample=not is_final_block , dropout=self.dropout , dtype=self.dtype , )
up_blocks.append(snake_case__ )
snake_case : Optional[int] = output_channel
snake_case : Tuple = up_blocks
# out
snake_case : Optional[int] = nn.GroupNorm(num_groups=32 , epsilon=1e-5 )
snake_case : List[str] = nn.Conv(
self.out_channels , kernel_size=(3, 3) , strides=(1, 1) , padding=((1, 1), (1, 1)) , dtype=self.dtype , )
def __call__(self : Dict , snake_case__ : Dict , snake_case__ : Dict , snake_case__ : Optional[int] , snake_case__ : Tuple=None , snake_case__ : Union[str, Any]=None , snake_case__ : bool = True , snake_case__ : bool = False , ) -> Union[FlaxUNetaDConditionOutput, Tuple]:
'''simple docstring'''
if not isinstance(snake_case__ , jnp.ndarray ):
snake_case : List[Any] = jnp.array([timesteps] , dtype=jnp.intaa )
elif isinstance(snake_case__ , jnp.ndarray ) and len(timesteps.shape ) == 0:
snake_case : Any = timesteps.astype(dtype=jnp.floataa )
snake_case : int = jnp.expand_dims(snake_case__ , 0 )
snake_case : str = self.time_proj(snake_case__ )
snake_case : str = self.time_embedding(snake_case__ )
# 2. pre-process
snake_case : int = jnp.transpose(snake_case__ , (0, 2, 3, 1) )
snake_case : List[Any] = self.conv_in(snake_case__ )
# 3. down
snake_case : Optional[int] = (sample,)
for down_block in self.down_blocks:
if isinstance(snake_case__ , snake_case__ ):
snake_case , snake_case : List[Any] = down_block(snake_case__ , snake_case__ , snake_case__ , deterministic=not train )
else:
snake_case , snake_case : str = down_block(snake_case__ , snake_case__ , deterministic=not train )
down_block_res_samples += res_samples
if down_block_additional_residuals is not None:
snake_case : Tuple = ()
for down_block_res_sample, down_block_additional_residual in zip(
snake_case__ , snake_case__ ):
down_block_res_sample += down_block_additional_residual
new_down_block_res_samples += (down_block_res_sample,)
snake_case : Optional[int] = new_down_block_res_samples
# 4. mid
snake_case : Optional[int] = self.mid_block(snake_case__ , snake_case__ , snake_case__ , deterministic=not train )
if mid_block_additional_residual is not None:
sample += mid_block_additional_residual
# 5. up
for up_block in self.up_blocks:
snake_case : int = down_block_res_samples[-(self.layers_per_block + 1) :]
snake_case : Optional[Any] = down_block_res_samples[: -(self.layers_per_block + 1)]
if isinstance(snake_case__ , snake_case__ ):
snake_case : Optional[Any] = up_block(
snake_case__ , temb=snake_case__ , encoder_hidden_states=snake_case__ , res_hidden_states_tuple=snake_case__ , deterministic=not train , )
else:
snake_case : Dict = up_block(snake_case__ , temb=snake_case__ , res_hidden_states_tuple=snake_case__ , deterministic=not train )
# 6. post-process
snake_case : List[str] = self.conv_norm_out(snake_case__ )
snake_case : Any = nn.silu(snake_case__ )
snake_case : Optional[int] = self.conv_out(snake_case__ )
snake_case : Union[str, Any] = jnp.transpose(snake_case__ , (0, 3, 1, 2) )
if not return_dict:
return (sample,)
return FlaxUNetaDConditionOutput(sample=snake_case__ )
| 59
| 1
|
import os
import sys
import warnings
from dataclasses import dataclass, field
from io import BytesIO
from typing import TYPE_CHECKING, Any, ClassVar, Dict, List, Optional, Union
import numpy as np
import pyarrow as pa
from .. import config
from ..download.streaming_download_manager import xopen
from ..table import array_cast
from ..utils.file_utils import is_local_path
from ..utils.py_utils import first_non_null_value, no_op_if_value_is_null, string_to_dict
if TYPE_CHECKING:
import PIL.Image
from .features import FeatureType
__lowerCamelCase = None
__lowerCamelCase = """<""" if sys.byteorder == """little""" else """>"""
# Origin: https://github.com/python-pillow/Pillow/blob/698951e19e19972aeed56df686868f1329981c12/src/PIL/Image.py#L3126 minus "|i1" which values are not preserved correctly when saving and loading an image
__lowerCamelCase = [
np.dtype("""|b1"""),
np.dtype("""|u1"""),
np.dtype("""<u2"""),
np.dtype(""">u2"""),
np.dtype("""<i2"""),
np.dtype(""">i2"""),
np.dtype("""<u4"""),
np.dtype(""">u4"""),
np.dtype("""<i4"""),
np.dtype(""">i4"""),
np.dtype("""<f4"""),
np.dtype(""">f4"""),
np.dtype("""<f8"""),
np.dtype(""">f8"""),
]
@dataclass
class UpperCAmelCase :
A__ : bool = True
A__ : Optional[str] = None
# Automatically constructed
A__ : ClassVar[str] = "PIL.Image.Image"
A__ : ClassVar[Any] = pa.struct({"bytes": pa.binary(), "path": pa.string()} )
A__ : str = field(default="Image" ,init=A_ ,repr=A_ )
def __call__(self : Any ) -> List[str]:
'''simple docstring'''
return self.pa_type
def _SCREAMING_SNAKE_CASE (self : str , snake_case__ : Union[str, bytes, dict, np.ndarray, "PIL.Image.Image"] ) -> dict:
'''simple docstring'''
if config.PIL_AVAILABLE:
import PIL.Image
else:
raise ImportError("To support encoding images, please install 'Pillow'." )
if isinstance(snake_case__ , snake_case__ ):
snake_case : Optional[Any] = np.array(snake_case__ )
if isinstance(snake_case__ , snake_case__ ):
return {"path": value, "bytes": None}
elif isinstance(snake_case__ , snake_case__ ):
return {"path": None, "bytes": value}
elif isinstance(snake_case__ , np.ndarray ):
# convert the image array to PNG/TIFF bytes
return encode_np_array(snake_case__ )
elif isinstance(snake_case__ , PIL.Image.Image ):
# convert the PIL image to bytes (default format is PNG/TIFF)
return encode_pil_image(snake_case__ )
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
return {"bytes": None, "path": value.get("path" )}
elif value.get("bytes" ) is not None or value.get("path" ) is not None:
# store the image bytes, and path is used to infer the image format using the file extension
return {"bytes": value.get("bytes" ), "path": value.get("path" )}
else:
raise ValueError(
f"""An image sample should have one of 'path' or 'bytes' but they are missing or None in {value}.""" )
def _SCREAMING_SNAKE_CASE (self : Union[str, Any] , snake_case__ : dict , snake_case__ : Any=None ) -> "PIL.Image.Image":
'''simple docstring'''
if not self.decode:
raise RuntimeError("Decoding is disabled for this feature. Please use Image(decode=True) instead." )
if config.PIL_AVAILABLE:
import PIL.Image
else:
raise ImportError("To support decoding images, please install 'Pillow'." )
if token_per_repo_id is None:
snake_case : List[Any] = {}
snake_case , snake_case : List[Any] = value["path"], value["bytes"]
if bytes_ is None:
if path is None:
raise ValueError(f"""An image should have one of 'path' or 'bytes' but both are None in {value}.""" )
else:
if is_local_path(snake_case__ ):
snake_case : Optional[Any] = PIL.Image.open(snake_case__ )
else:
snake_case : Any = path.split("::" )[-1]
try:
snake_case : int = string_to_dict(snake_case__ , config.HUB_DATASETS_URL )["repo_id"]
snake_case : Optional[int] = token_per_repo_id.get(snake_case__ )
except ValueError:
snake_case : Dict = None
with xopen(snake_case__ , "rb" , use_auth_token=snake_case__ ) as f:
snake_case : Union[str, Any] = BytesIO(f.read() )
snake_case : Tuple = PIL.Image.open(bytes_ )
else:
snake_case : int = PIL.Image.open(BytesIO(bytes_ ) )
image.load() # to avoid "Too many open files" errors
return image
def _SCREAMING_SNAKE_CASE (self : Union[str, Any] ) -> Union["FeatureType", Dict[str, "FeatureType"]]:
'''simple docstring'''
from .features import Value
return (
self
if self.decode
else {
"bytes": Value("binary" ),
"path": Value("string" ),
}
)
def _SCREAMING_SNAKE_CASE (self : Dict , snake_case__ : Union[pa.StringArray, pa.StructArray, pa.ListArray] ) -> pa.StructArray:
'''simple docstring'''
if pa.types.is_string(storage.type ):
snake_case : str = pa.array([None] * len(snake_case__ ) , type=pa.binary() )
snake_case : Tuple = pa.StructArray.from_arrays([bytes_array, storage] , ["bytes", "path"] , mask=storage.is_null() )
elif pa.types.is_binary(storage.type ):
snake_case : Dict = pa.array([None] * len(snake_case__ ) , type=pa.string() )
snake_case : Tuple = pa.StructArray.from_arrays([storage, path_array] , ["bytes", "path"] , mask=storage.is_null() )
elif pa.types.is_struct(storage.type ):
if storage.type.get_field_index("bytes" ) >= 0:
snake_case : str = storage.field("bytes" )
else:
snake_case : Union[str, Any] = pa.array([None] * len(snake_case__ ) , type=pa.binary() )
if storage.type.get_field_index("path" ) >= 0:
snake_case : str = storage.field("path" )
else:
snake_case : int = pa.array([None] * len(snake_case__ ) , type=pa.string() )
snake_case : int = pa.StructArray.from_arrays([bytes_array, path_array] , ["bytes", "path"] , mask=storage.is_null() )
elif pa.types.is_list(storage.type ):
snake_case : Optional[Any] = pa.array(
[encode_np_array(np.array(snake_case__ ) )["bytes"] if arr is not None else None for arr in storage.to_pylist()] , type=pa.binary() , )
snake_case : str = pa.array([None] * len(snake_case__ ) , type=pa.string() )
snake_case : Any = pa.StructArray.from_arrays(
[bytes_array, path_array] , ["bytes", "path"] , mask=bytes_array.is_null() )
return array_cast(snake_case__ , self.pa_type )
def _SCREAMING_SNAKE_CASE (self : int , snake_case__ : pa.StructArray ) -> pa.StructArray:
'''simple docstring'''
@no_op_if_value_is_null
def path_to_bytes(snake_case__ : List[str] ):
with xopen(snake_case__ , "rb" ) as f:
snake_case : int = f.read()
return bytes_
snake_case : Tuple = 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() , )
snake_case : Dict = pa.array(
[os.path.basename(snake_case__ ) if path is not None else None for path in storage.field("path" ).to_pylist()] , type=pa.string() , )
snake_case : int = pa.StructArray.from_arrays([bytes_array, path_array] , ["bytes", "path"] , mask=bytes_array.is_null() )
return array_cast(snake_case__ , self.pa_type )
def UpperCamelCase ( ):
if config.PIL_AVAILABLE:
import PIL.Image
else:
raise ImportError("To support encoding images, please install 'Pillow'." )
global _IMAGE_COMPRESSION_FORMATS
if _IMAGE_COMPRESSION_FORMATS is None:
PIL.Image.init()
snake_case : Tuple = list(set(PIL.Image.OPEN.keys() ) & set(PIL.Image.SAVE.keys() ) )
return _IMAGE_COMPRESSION_FORMATS
def UpperCamelCase ( __lowerCamelCase : "PIL.Image.Image" ):
snake_case : Dict = BytesIO()
if image.format in list_image_compression_formats():
snake_case : Optional[Any] = image.format
else:
snake_case : List[Any] = "PNG" if image.mode in ["1", "L", "LA", "RGB", "RGBA"] else "TIFF"
image.save(__lowerCamelCase , format=__lowerCamelCase )
return buffer.getvalue()
def UpperCamelCase ( __lowerCamelCase : "PIL.Image.Image" ):
if hasattr(__lowerCamelCase , "filename" ) and image.filename != "":
return {"path": image.filename, "bytes": None}
else:
return {"path": None, "bytes": image_to_bytes(__lowerCamelCase )}
def UpperCamelCase ( __lowerCamelCase : np.ndarray ):
if config.PIL_AVAILABLE:
import PIL.Image
else:
raise ImportError("To support encoding images, please install 'Pillow'." )
snake_case : List[str] = array.dtype
snake_case : Dict = dtype.byteorder if dtype.byteorder != "=" else _NATIVE_BYTEORDER
snake_case : Dict = dtype.kind
snake_case : int = dtype.itemsize
snake_case : Tuple = None
# Multi-channel array case (only np.dtype("|u1") is allowed)
if array.shape[2:]:
snake_case : Any = np.dtype("|u1" )
if dtype_kind not in ["u", "i"]:
raise TypeError(
f"""Unsupported array dtype {dtype} for image encoding. Only {dest_dtype} is supported for multi-channel arrays.""" )
if dtype is not dest_dtype:
warnings.warn(f"""Downcasting array dtype {dtype} to {dest_dtype} to be compatible with 'Pillow'""" )
# Exact match
elif dtype in _VALID_IMAGE_ARRAY_DTPYES:
snake_case : Optional[int] = dtype
else: # Downcast the type within the kind (np.can_cast(from_type, to_type, casting="same_kind") doesn't behave as expected, so do it manually)
while dtype_itemsize >= 1:
snake_case : List[str] = dtype_byteorder + dtype_kind + str(__lowerCamelCase )
snake_case : Dict = np.dtype(__lowerCamelCase )
if dest_dtype in _VALID_IMAGE_ARRAY_DTPYES:
warnings.warn(f"""Downcasting array dtype {dtype} to {dest_dtype} to be compatible with 'Pillow'""" )
break
else:
dtype_itemsize //= 2
if dest_dtype is None:
raise TypeError(
f"""Cannot convert dtype {dtype} to a valid image dtype. Valid image dtypes: {_VALID_IMAGE_ARRAY_DTPYES}""" )
snake_case : List[str] = PIL.Image.fromarray(array.astype(__lowerCamelCase ) )
return {"path": None, "bytes": image_to_bytes(__lowerCamelCase )}
def UpperCamelCase ( __lowerCamelCase : Union[List[str], List[dict], List[np.ndarray], List["PIL.Image.Image"]] ):
if config.PIL_AVAILABLE:
import PIL.Image
else:
raise ImportError("To support encoding images, please install 'Pillow'." )
if objs:
snake_case , snake_case : str = first_non_null_value(__lowerCamelCase )
if isinstance(__lowerCamelCase , __lowerCamelCase ):
return [{"path": obj, "bytes": None} if obj is not None else None for obj in objs]
if isinstance(__lowerCamelCase , np.ndarray ):
snake_case : Any = no_op_if_value_is_null(__lowerCamelCase )
return [obj_to_image_dict_func(__lowerCamelCase ) for obj in objs]
elif isinstance(__lowerCamelCase , PIL.Image.Image ):
snake_case : Optional[int] = no_op_if_value_is_null(__lowerCamelCase )
return [obj_to_image_dict_func(__lowerCamelCase ) for obj in objs]
else:
return objs
else:
return objs
| 59
|
__lowerCamelCase = {
"joule": 1.0,
"kilojoule": 10_00,
"megajoule": 1_00_00_00,
"gigajoule": 10_00_00_00_00,
"wattsecond": 1.0,
"watthour": 36_00,
"kilowatthour": 3_60_00_00,
"newtonmeter": 1.0,
"calorie_nutr": 41_86.8,
"kilocalorie_nutr": 4_18_68_00.00,
"electronvolt": 1.602_176_634e-19,
"britishthermalunit_it": 10_55.0_55_85,
"footpound": 1.35_5818,
}
def UpperCamelCase ( __lowerCamelCase : str , __lowerCamelCase : str , __lowerCamelCase : float ):
if to_type not in ENERGY_CONVERSION or from_type not in ENERGY_CONVERSION:
snake_case : List[Any] = (
f"""Incorrect 'from_type' or 'to_type' value: {from_type!r}, {to_type!r}\n"""
f"""Valid values are: {', '.join(__lowerCamelCase )}"""
)
raise ValueError(__lowerCamelCase )
return value * ENERGY_CONVERSION[from_type] / ENERGY_CONVERSION[to_type]
if __name__ == "__main__":
import doctest
doctest.testmod()
| 59
| 1
|
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