# Copyright 2022 The HuggingFace Team. All rights reserved. # # Licensed under the Apache License, Version 2.0 (the "License"); # you may not use this file except in compliance with the License. # You may obtain a copy of the License at # # http://www.apache.org/licenses/LICENSE-2.0 # # Unless required by applicable law or agreed to in writing, software # distributed under the License is distributed on an "AS IS" BASIS, # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. # See the License for the specific language governing permissions and # limitations under the License. """ Generic utilities """ import inspect import json import os import tempfile import warnings from collections import OrderedDict, UserDict, defaultdict from collections.abc import Iterable, MutableMapping from contextlib import ExitStack, contextmanager from dataclasses import dataclass, fields, is_dataclass from enum import Enum from functools import partial, wraps from typing import Any, Callable, ContextManager, Optional, TypedDict import numpy as np from packaging import version from ..utils import logging from .import_utils import ( get_torch_version, is_flax_available, is_mlx_available, is_tf_available, is_torch_available, is_torch_fx_proxy, requires, ) _CAN_RECORD_REGISTRY = {} logger = logging.get_logger(__name__) if is_torch_available(): # required for @can_return_tuple decorator to work with torchdynamo import torch # noqa: F401 class cached_property(property): """ Descriptor that mimics @property but caches output in member variable. From tensorflow_datasets Built-in in functools from Python 3.8. """ def __get__(self, obj, objtype=None): # See docs.python.org/3/howto/descriptor.html#properties if obj is None: return self if self.fget is None: raise AttributeError("unreadable attribute") attr = "__cached_" + self.fget.__name__ cached = getattr(obj, attr, None) if cached is None: cached = self.fget(obj) setattr(obj, attr, cached) return cached # vendored from distutils.util def strtobool(val): """Convert a string representation of truth to true (1) or false (0). True values are 'y', 'yes', 't', 'true', 'on', and '1'; false values are 'n', 'no', 'f', 'false', 'off', and '0'. Raises ValueError if 'val' is anything else. """ val = val.lower() if val in {"y", "yes", "t", "true", "on", "1"}: return 1 if val in {"n", "no", "f", "false", "off", "0"}: return 0 raise ValueError(f"invalid truth value {val!r}") def infer_framework_from_repr(x): """ Tries to guess the framework of an object `x` from its repr (brittle but will help in `is_tensor` to try the frameworks in a smart order, without the need to import the frameworks). """ representation = str(type(x)) if representation.startswith(" You can't unpack a `ModelOutput` directly. Use the [`~utils.ModelOutput.to_tuple`] method to convert it to a tuple before. """ def __init_subclass__(cls) -> None: """Register subclasses as pytree nodes. This is necessary to synchronize gradients when using `torch.nn.parallel.DistributedDataParallel` with `static_graph=True` with modules that output `ModelOutput` subclasses. """ if is_torch_available(): if version.parse(get_torch_version()) >= version.parse("2.2"): from torch.utils._pytree import register_pytree_node register_pytree_node( cls, _model_output_flatten, partial(_model_output_unflatten, output_type=cls), serialized_type_name=f"{cls.__module__}.{cls.__name__}", ) else: from torch.utils._pytree import _register_pytree_node _register_pytree_node( cls, _model_output_flatten, partial(_model_output_unflatten, output_type=cls), ) def __init__(self, *args, **kwargs): super().__init__(*args, **kwargs) # Subclasses of ModelOutput must use the @dataclass decorator # This check is done in __init__ because the @dataclass decorator operates after __init_subclass__ # issubclass() would return True for issubclass(ModelOutput, ModelOutput) when False is needed # Just need to check that the current class is not ModelOutput is_modeloutput_subclass = self.__class__ != ModelOutput if is_modeloutput_subclass and not is_dataclass(self): raise TypeError( f"{self.__module__}.{self.__class__.__name__} is not a dataclass." " This is a subclass of ModelOutput and so must use the @dataclass decorator." ) def __post_init__(self): """Check the ModelOutput dataclass. Only occurs if @dataclass decorator has been used. """ class_fields = fields(self) # Safety and consistency checks if not len(class_fields): raise ValueError(f"{self.__class__.__name__} has no fields.") if not all(field.default is None for field in class_fields[1:]): raise ValueError(f"{self.__class__.__name__} should not have more than one required field.") first_field = getattr(self, class_fields[0].name) other_fields_are_none = all(getattr(self, field.name) is None for field in class_fields[1:]) if other_fields_are_none and not is_tensor(first_field): if isinstance(first_field, dict): iterator = first_field.items() first_field_iterator = True else: try: iterator = iter(first_field) first_field_iterator = True except TypeError: first_field_iterator = False # if we provided an iterator as first field and the iterator is a (key, value) iterator # set the associated fields if first_field_iterator: for idx, element in enumerate(iterator): if ( not isinstance(element, (list, tuple)) or not len(element) == 2 or not isinstance(element[0], str) ): if idx == 0: # If we do not have an iterator of key/values, set it as attribute self[class_fields[0].name] = first_field else: # If we have a mixed iterator, raise an error raise ValueError( f"Cannot set key/value for {element}. It needs to be a tuple (key, value)." ) break setattr(self, element[0], element[1]) if element[1] is not None: self[element[0]] = element[1] elif first_field is not None: self[class_fields[0].name] = first_field else: for field in class_fields: v = getattr(self, field.name) if v is not None: self[field.name] = v def __delitem__(self, *args, **kwargs): raise Exception(f"You cannot use ``__delitem__`` on a {self.__class__.__name__} instance.") def setdefault(self, *args, **kwargs): raise Exception(f"You cannot use ``setdefault`` on a {self.__class__.__name__} instance.") def pop(self, *args, **kwargs): raise Exception(f"You cannot use ``pop`` on a {self.__class__.__name__} instance.") def update(self, *args, **kwargs): raise Exception(f"You cannot use ``update`` on a {self.__class__.__name__} instance.") def __getitem__(self, k): if isinstance(k, str): inner_dict = dict(self.items()) return inner_dict[k] else: return self.to_tuple()[k] def __setattr__(self, name, value): if name in self.keys() and value is not None: # Don't call self.__setitem__ to avoid recursion errors super().__setitem__(name, value) super().__setattr__(name, value) def __setitem__(self, key, value): # Will raise a KeyException if needed super().__setitem__(key, value) # Don't call self.__setattr__ to avoid recursion errors super().__setattr__(key, value) def __reduce__(self): if not is_dataclass(self): return super().__reduce__() callable, _args, *remaining = super().__reduce__() args = tuple(getattr(self, field.name) for field in fields(self)) return callable, args, *remaining def to_tuple(self) -> tuple[Any]: """ Convert self to a tuple containing all the attributes/keys that are not `None`. """ return tuple(self[k] for k in self.keys()) if is_torch_available(): import torch.utils._pytree as _torch_pytree def _model_output_flatten(output: ModelOutput) -> tuple[list[Any], "_torch_pytree.Context"]: return list(output.values()), list(output.keys()) def _model_output_unflatten( values: Iterable[Any], context: "_torch_pytree.Context", output_type=None, ) -> ModelOutput: return output_type(**dict(zip(context, values))) if version.parse(get_torch_version()) >= version.parse("2.2"): _torch_pytree.register_pytree_node( ModelOutput, _model_output_flatten, partial(_model_output_unflatten, output_type=ModelOutput), serialized_type_name=f"{ModelOutput.__module__}.{ModelOutput.__name__}", ) else: _torch_pytree._register_pytree_node( ModelOutput, _model_output_flatten, partial(_model_output_unflatten, output_type=ModelOutput), ) class ExplicitEnum(str, Enum): """ Enum with more explicit error message for missing values. """ @classmethod def _missing_(cls, value): raise ValueError( f"{value} is not a valid {cls.__name__}, please select one of {list(cls._value2member_map_.keys())}" ) class PaddingStrategy(ExplicitEnum): """ Possible values for the `padding` argument in [`PreTrainedTokenizerBase.__call__`]. Useful for tab-completion in an IDE. """ LONGEST = "longest" MAX_LENGTH = "max_length" DO_NOT_PAD = "do_not_pad" class TensorType(ExplicitEnum): """ Possible values for the `return_tensors` argument in [`PreTrainedTokenizerBase.__call__`]. Useful for tab-completion in an IDE. """ PYTORCH = "pt" TENSORFLOW = "tf" NUMPY = "np" JAX = "jax" MLX = "mlx" class ContextManagers: """ Wrapper for `contextlib.ExitStack` which enters a collection of context managers. Adaptation of `ContextManagers` in the `fastcore` library. """ def __init__(self, context_managers: list[ContextManager]): self.context_managers = context_managers self.stack = ExitStack() def __enter__(self): for context_manager in self.context_managers: self.stack.enter_context(context_manager) def __exit__(self, *args, **kwargs): self.stack.__exit__(*args, **kwargs) def can_return_loss(model_class): """ Check if a given model can return loss. Args: model_class (`type`): The class of the model. """ framework = infer_framework(model_class) if framework == "tf": signature = inspect.signature(model_class.call) # TensorFlow models elif framework == "pt": signature = inspect.signature(model_class.forward) # PyTorch models else: signature = inspect.signature(model_class.__call__) # Flax models for p in signature.parameters: if p == "return_loss" and signature.parameters[p].default is True: return True return False def find_labels(model_class): """ Find the labels used by a given model. Args: model_class (`type`): The class of the model. """ model_name = model_class.__name__ framework = infer_framework(model_class) if framework == "tf": signature = inspect.signature(model_class.call) # TensorFlow models elif framework == "pt": signature = inspect.signature(model_class.forward) # PyTorch models else: signature = inspect.signature(model_class.__call__) # Flax models if "QuestionAnswering" in model_name: return [p for p in signature.parameters if "label" in p or p in ("start_positions", "end_positions")] else: return [p for p in signature.parameters if "label" in p] def flatten_dict(d: MutableMapping, parent_key: str = "", delimiter: str = "."): """Flatten a nested dict into a single level dict.""" def _flatten_dict(d, parent_key="", delimiter="."): for k, v in d.items(): key = str(parent_key) + delimiter + str(k) if parent_key else k if v and isinstance(v, MutableMapping): yield from flatten_dict(v, key, delimiter=delimiter).items() else: yield key, v return dict(_flatten_dict(d, parent_key, delimiter)) @contextmanager def working_or_temp_dir(working_dir, use_temp_dir: bool = False): if use_temp_dir: with tempfile.TemporaryDirectory() as tmp_dir: yield tmp_dir else: yield working_dir def transpose(array, axes=None): """ Framework-agnostic version of `numpy.transpose` that will work on torch/TensorFlow/Jax tensors as well as NumPy arrays. """ if is_numpy_array(array): return np.transpose(array, axes=axes) elif is_torch_tensor(array): return array.T if axes is None else array.permute(*axes) elif is_tf_tensor(array): import tensorflow as tf return tf.transpose(array, perm=axes) elif is_jax_tensor(array): import jax.numpy as jnp return jnp.transpose(array, axes=axes) else: raise ValueError(f"Type not supported for transpose: {type(array)}.") def reshape(array, newshape): """ Framework-agnostic version of `numpy.reshape` that will work on torch/TensorFlow/Jax tensors as well as NumPy arrays. """ if is_numpy_array(array): return np.reshape(array, newshape) elif is_torch_tensor(array): return array.reshape(*newshape) elif is_tf_tensor(array): import tensorflow as tf return tf.reshape(array, newshape) elif is_jax_tensor(array): import jax.numpy as jnp return jnp.reshape(array, newshape) else: raise ValueError(f"Type not supported for reshape: {type(array)}.") def squeeze(array, axis=None): """ Framework-agnostic version of `numpy.squeeze` that will work on torch/TensorFlow/Jax tensors as well as NumPy arrays. """ if is_numpy_array(array): return np.squeeze(array, axis=axis) elif is_torch_tensor(array): return array.squeeze() if axis is None else array.squeeze(dim=axis) elif is_tf_tensor(array): import tensorflow as tf return tf.squeeze(array, axis=axis) elif is_jax_tensor(array): import jax.numpy as jnp return jnp.squeeze(array, axis=axis) else: raise ValueError(f"Type not supported for squeeze: {type(array)}.") def expand_dims(array, axis): """ Framework-agnostic version of `numpy.expand_dims` that will work on torch/TensorFlow/Jax tensors as well as NumPy arrays. """ if is_numpy_array(array): return np.expand_dims(array, axis) elif is_torch_tensor(array): return array.unsqueeze(dim=axis) elif is_tf_tensor(array): import tensorflow as tf return tf.expand_dims(array, axis=axis) elif is_jax_tensor(array): import jax.numpy as jnp return jnp.expand_dims(array, axis=axis) else: raise ValueError(f"Type not supported for expand_dims: {type(array)}.") def tensor_size(array): """ Framework-agnostic version of `numpy.size` that will work on torch/TensorFlow/Jax tensors as well as NumPy arrays. """ if is_numpy_array(array): return np.size(array) elif is_torch_tensor(array): return array.numel() elif is_tf_tensor(array): import tensorflow as tf return tf.size(array) elif is_jax_tensor(array): return array.size else: raise ValueError(f"Type not supported for tensor_size: {type(array)}.") def infer_framework(model_class): """ Infers the framework of a given model without using isinstance(), because we cannot guarantee that the relevant classes are imported or available. """ for base_class in inspect.getmro(model_class): module = base_class.__module__ name = base_class.__name__ if module.startswith("tensorflow") or module.startswith("keras") or name == "TFPreTrainedModel": return "tf" elif module.startswith("torch") or name == "PreTrainedModel": return "pt" elif module.startswith("flax") or module.startswith("jax") or name == "FlaxPreTrainedModel": return "flax" else: raise TypeError(f"Could not infer framework from class {model_class}.") def torch_int(x): """ Casts an input to a torch int64 tensor if we are in a tracing context, otherwise to a Python int. """ if not is_torch_available(): return int(x) import torch return x.to(torch.int64) if torch.jit.is_tracing() and isinstance(x, torch.Tensor) else int(x) def torch_float(x): """ Casts an input to a torch float32 tensor if we are in a tracing context, otherwise to a Python float. """ if not is_torch_available(): return int(x) import torch return x.to(torch.float32) if torch.jit.is_tracing() and isinstance(x, torch.Tensor) else int(x) def filter_out_non_signature_kwargs(extra: Optional[list] = None): """ Decorator to filter out named arguments that are not in the function signature. This decorator ensures that only the keyword arguments that match the function's signature, or are specified in the `extra` list, are passed to the function. Any additional keyword arguments are filtered out and a warning is issued. Parameters: extra (`Optional[list]`, *optional*): A list of extra keyword argument names that are allowed even if they are not in the function's signature. Returns: Callable: A decorator that wraps the function and filters out invalid keyword arguments. Example usage: ```python @filter_out_non_signature_kwargs(extra=["allowed_extra_arg"]) def my_function(arg1, arg2, **kwargs): print(arg1, arg2, kwargs) my_function(arg1=1, arg2=2, allowed_extra_arg=3, invalid_arg=4) # This will print: 1 2 {"allowed_extra_arg": 3} # And issue a warning: "The following named arguments are not valid for `my_function` and were ignored: 'invalid_arg'" ``` """ extra = extra or [] extra_params_to_pass = set(extra) def decorator(func): sig = inspect.signature(func) function_named_args = set(sig.parameters.keys()) valid_kwargs_to_pass = function_named_args.union(extra_params_to_pass) # Required for better warning message is_instance_method = "self" in function_named_args is_class_method = "cls" in function_named_args # Mark function as decorated func._filter_out_non_signature_kwargs = True @wraps(func) def wrapper(*args, **kwargs): valid_kwargs = {} invalid_kwargs = {} for k, v in kwargs.items(): if k in valid_kwargs_to_pass: valid_kwargs[k] = v else: invalid_kwargs[k] = v if invalid_kwargs: invalid_kwargs_names = [f"'{k}'" for k in invalid_kwargs.keys()] invalid_kwargs_names = ", ".join(invalid_kwargs_names) # Get the class name for better warning message if is_instance_method: cls_prefix = args[0].__class__.__name__ + "." elif is_class_method: cls_prefix = args[0].__name__ + "." else: cls_prefix = "" warnings.warn( f"The following named arguments are not valid for `{cls_prefix}{func.__name__}`" f" and were ignored: {invalid_kwargs_names}", UserWarning, stacklevel=2, ) return func(*args, **valid_kwargs) return wrapper return decorator class TransformersKwargs(TypedDict, total=False): """ Keyword arguments to be passed to the loss function Attributes: num_items_in_batch (`Optional[torch.Tensor]`, *optional*): Number of items in the batch. It is recommended to pass it when you are doing gradient accumulation. output_hidden_states (`Optional[bool]`, *optional*): Most of the models support outputing all hidden states computed during the forward pass. output_attentions (`Optional[bool]`, *optional*): Turn this on to return the intermediary attention scores. output_router_logits (`Optional[bool]`, *optional*): For MoE models, this allows returning the router logits to compute the loss. cumulative_seqlens_q (`torch.LongTensor`, *optional*) Gets cumulative sequence length for query state. cumulative_seqlens_k (`torch.LongTensor`, *optional*) Gets cumulative sequence length for key state. max_length_q (`int`, *optional*): Maximum sequence length for query state. max_length_k (`int`, *optional*): Maximum sequence length for key state. """ num_items_in_batch: Optional["torch.Tensor"] output_hidden_states: Optional[bool] output_attentions: Optional[bool] output_router_logits: Optional[bool] cumulative_seqlens_q: Optional["torch.LongTensor"] cumulative_seqlens_k: Optional["torch.LongTensor"] max_length_q: Optional[int] max_length_k: Optional[int] def is_timm_config_dict(config_dict: dict[str, Any]) -> bool: """Checks whether a config dict is a timm config dict.""" return "pretrained_cfg" in config_dict def is_timm_local_checkpoint(pretrained_model_path: str) -> bool: """ Checks whether a checkpoint is a timm model checkpoint. """ if pretrained_model_path is None: return False # in case it's Path, not str pretrained_model_path = str(pretrained_model_path) is_file = os.path.isfile(pretrained_model_path) is_dir = os.path.isdir(pretrained_model_path) # pretrained_model_path is a file if is_file and pretrained_model_path.endswith(".json"): with open(pretrained_model_path) as f: config_dict = json.load(f) return is_timm_config_dict(config_dict) # pretrained_model_path is a directory with a config.json if is_dir and os.path.exists(os.path.join(pretrained_model_path, "config.json")): with open(os.path.join(pretrained_model_path, "config.json")) as f: config_dict = json.load(f) return is_timm_config_dict(config_dict) return False def set_attribute_for_modules(module: "torch.nn.Module", key: str, value: Any): """ Set a value to a module and all submodules. """ setattr(module, key, value) for submodule in module.children(): set_attribute_for_modules(submodule, key, value) def del_attribute_from_modules(module: "torch.nn.Module", key: str): """ Delete a value from a module and all submodules. """ # because we might remove it previously in case it's a shared module, e.g. activation function if hasattr(module, key): delattr(module, key) for submodule in module.children(): del_attribute_from_modules(submodule, key) def can_return_tuple(func): """ Decorator to wrap model method, to call output.to_tuple() if return_dict=False passed as a kwarg or use_return_dict=False is set in the config. Note: output.to_tuple() convert output to tuple skipping all `None` values. """ @wraps(func) def wrapper(self, *args, **kwargs): return_dict = self.config.return_dict if hasattr(self, "config") else True return_dict_passed = kwargs.pop("return_dict", return_dict) if return_dict_passed is not None: return_dict = return_dict_passed output = func(self, *args, **kwargs) if not return_dict and not isinstance(output, tuple): output = output.to_tuple() return output return wrapper # if is_torch_available(): # @torch._dynamo.disable @dataclass @requires(backends=("torch",)) class OutputRecorder: """ Configuration for recording outputs from a model via hooks. Attributes: target_class (Type): The class (e.g., nn.Module) to which the hook will be attached. index (Optional[int]): If the output is a tuple/list, optionally record only at a specific index. layer_name (Optional[str]): Name of the submodule to target (if needed), e.g., "transformer.layer.3.attn". """ target_class: "type[torch.nn.Module]" index: Optional[int] = 0 layer_name: Optional[str] = None def check_model_inputs(func): """ Decorator to intercept specific layer outputs without using hooks. Compatible with torch.compile (Dynamo tracing). """ @wraps(func) def wrapper(self, *args, **kwargs): use_cache = kwargs.get("use_cache", None) if use_cache is None: use_cache = getattr(self.config, "use_cache", False) return_dict = kwargs.pop("return_dict", None) if return_dict is None: return_dict = getattr(self.config, "return_dict", True) if getattr(self, "gradient_checkpointing", False) and self.training and use_cache: logger.warning_once( "`use_cache=True` is incompatible with gradient checkpointing. Setting `use_cache=False`." ) use_cache = False kwargs["use_cache"] = use_cache all_args = kwargs.copy() if "kwargs" in all_args: for k, v in all_args["kwargs"].items(): all_args[k] = v capture_flags = _CAN_RECORD_REGISTRY.get(str(self.__class__), {}) # there is a weak ref for executorch recordable_keys = { f"output_{k}": all_args.get( f"output_{k}", getattr( self.config, f"output_{k}", all_args.get("output_attentions", getattr(self.config, "output_attentions", False)), ), ) for k in capture_flags } collected_outputs = defaultdict(tuple) monkey_patched_layers = [] def make_capture_wrapper(module, orig_forward, key, index): @wraps(orig_forward) def wrapped_forward(*args, **kwargs): if key == "hidden_states" and len(collected_outputs[key]) == 0: collected_outputs[key] += (args[0],) output = orig_forward(*args, **kwargs) if not isinstance(output, tuple): collected_outputs[key] += (output,) elif output[index] is not None: collected_outputs[key] += (output[index],) return output return wrapped_forward if any(recordable_keys.values()): capture_tasks = [] for key, layer_specs in capture_flags.items(): if not recordable_keys.get(f"output_{key}", False): continue if not isinstance(layer_specs, list): layer_specs = [layer_specs] for specs in layer_specs: if not isinstance(specs, OutputRecorder): index = 0 if "hidden_states" in key else 1 specs = OutputRecorder(target_class=specs, index=index) capture_tasks.append((key, specs)) for name, module in self.named_modules(): for key, specs in capture_tasks: if isinstance(module, specs.target_class): if specs.layer_name is not None and specs.layer_name not in name: continue # Monkey patch forward original_forward = module.forward module.forward = make_capture_wrapper(module, original_forward, key, specs.index) monkey_patched_layers.append((module, original_forward)) outputs = func(self, *args, **kwargs) # Restore original forward methods for module, original_forward in monkey_patched_layers: module.forward = original_forward # Inject collected outputs into model output for key in collected_outputs: if key == "hidden_states": collected_outputs[key] = collected_outputs[key][:-1] if hasattr(outputs, "vision_hidden_states"): collected_outputs[key] += (outputs.vision_hidden_states,) elif hasattr(outputs, "last_hidden_state"): collected_outputs[key] += (outputs.last_hidden_state,) outputs[key] = collected_outputs[key] elif key == "attentions": if isinstance(capture_flags[key], list) and len(capture_flags[key]) == 2: outputs[key] = collected_outputs[key][0::2] outputs["cross_" + key] = collected_outputs[key][1::2] else: outputs[key] = collected_outputs[key] else: outputs[key] = collected_outputs[key] if return_dict is False: outputs = outputs.to_tuple() return outputs return wrapper class GeneralInterface(MutableMapping): """ Dict-like object keeping track of a class-wide mapping, as well as a local one. Allows to have library-wide modifications though the class mapping, as well as local modifications in a single file with the local mapping. """ # Class instance object, so that a call to `register` can be reflected into all other files correctly, even if # a new instance is created (in order to locally override a given function) _global_mapping = {} def __init__(self): self._local_mapping = {} def __getitem__(self, key): # First check if instance has a local override if key in self._local_mapping: return self._local_mapping[key] return self._global_mapping[key] def __setitem__(self, key, value): # Allow local update of the default functions without impacting other instances self._local_mapping.update({key: value}) def __delitem__(self, key): del self._local_mapping[key] def __iter__(self): # Ensure we use all keys, with the overwritten ones on top return iter({**self._global_mapping, **self._local_mapping}) def __len__(self): return len(self._global_mapping.keys() | self._local_mapping.keys()) @classmethod def register(cls, key: str, value: Callable): cls._global_mapping.update({key: value}) def valid_keys(self) -> list[str]: return list(self.keys())