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# coding=utf-8 | |
# Copyright 2021 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. | |
import builtins | |
import collections | |
import functools | |
import inspect | |
import math | |
import operator | |
import os | |
import random | |
import warnings | |
from typing import Any, Callable, Dict, List, Optional, Type, Union | |
import torch | |
from torch import nn | |
from torch.fx import Graph, GraphModule, Proxy, Tracer | |
from torch.fx._compatibility import compatibility | |
from torch.fx.proxy import ParameterProxy | |
from .. import PretrainedConfig, PreTrainedModel, logging | |
from ..models.auto import get_values | |
from ..models.auto.modeling_auto import ( | |
MODEL_FOR_AUDIO_CLASSIFICATION_MAPPING_NAMES, | |
MODEL_FOR_BACKBONE_MAPPING_NAMES, | |
MODEL_FOR_CAUSAL_LM_MAPPING_NAMES, | |
MODEL_FOR_CTC_MAPPING_NAMES, | |
MODEL_FOR_DOCUMENT_QUESTION_ANSWERING_MAPPING_NAMES, | |
MODEL_FOR_IMAGE_CLASSIFICATION_MAPPING_NAMES, | |
MODEL_FOR_MASKED_IMAGE_MODELING_MAPPING_NAMES, | |
MODEL_FOR_MASKED_LM_MAPPING_NAMES, | |
MODEL_FOR_MULTIPLE_CHOICE_MAPPING_NAMES, | |
MODEL_FOR_NEXT_SENTENCE_PREDICTION_MAPPING_NAMES, | |
MODEL_FOR_PRETRAINING_MAPPING_NAMES, | |
MODEL_FOR_QUESTION_ANSWERING_MAPPING_NAMES, | |
MODEL_FOR_SEMANTIC_SEGMENTATION_MAPPING_NAMES, | |
MODEL_FOR_SEQ_TO_SEQ_CAUSAL_LM_MAPPING_NAMES, | |
MODEL_FOR_SEQUENCE_CLASSIFICATION_MAPPING_NAMES, | |
MODEL_FOR_SPEECH_SEQ_2_SEQ_MAPPING_NAMES, | |
MODEL_FOR_TOKEN_CLASSIFICATION_MAPPING_NAMES, | |
MODEL_FOR_ZERO_SHOT_IMAGE_CLASSIFICATION_MAPPING_NAMES, | |
MODEL_MAPPING_NAMES, | |
) | |
from ..utils import ( | |
ENV_VARS_TRUE_VALUES, | |
TORCH_FX_REQUIRED_VERSION, | |
get_torch_version, | |
is_peft_available, | |
is_torch_fx_available, | |
) | |
if is_peft_available(): | |
from peft import PeftModel | |
logger = logging.get_logger(__name__) | |
_IS_IN_DEBUG_MODE = os.environ.get("FX_DEBUG_MODE", "").upper() in ENV_VARS_TRUE_VALUES | |
def _generate_supported_model_class_names( | |
model_name: Type[PretrainedConfig], | |
supported_tasks: Optional[Union[str, List[str]]] = None, | |
) -> List[str]: | |
task_mapping = { | |
"default": MODEL_MAPPING_NAMES, | |
"pretraining": MODEL_FOR_PRETRAINING_MAPPING_NAMES, | |
"next-sentence-prediction": MODEL_FOR_NEXT_SENTENCE_PREDICTION_MAPPING_NAMES, | |
"masked-lm": MODEL_FOR_MASKED_LM_MAPPING_NAMES, | |
"causal-lm": MODEL_FOR_CAUSAL_LM_MAPPING_NAMES, | |
"seq2seq-lm": MODEL_FOR_SEQ_TO_SEQ_CAUSAL_LM_MAPPING_NAMES, | |
"speech-seq2seq": MODEL_FOR_SPEECH_SEQ_2_SEQ_MAPPING_NAMES, | |
"multiple-choice": MODEL_FOR_MULTIPLE_CHOICE_MAPPING_NAMES, | |
"document-question-answering": MODEL_FOR_DOCUMENT_QUESTION_ANSWERING_MAPPING_NAMES, | |
"question-answering": MODEL_FOR_QUESTION_ANSWERING_MAPPING_NAMES, | |
"sequence-classification": MODEL_FOR_SEQUENCE_CLASSIFICATION_MAPPING_NAMES, | |
"token-classification": MODEL_FOR_TOKEN_CLASSIFICATION_MAPPING_NAMES, | |
"masked-image-modeling": MODEL_FOR_MASKED_IMAGE_MODELING_MAPPING_NAMES, | |
"image-classification": MODEL_FOR_IMAGE_CLASSIFICATION_MAPPING_NAMES, | |
"zero-shot-image-classification": MODEL_FOR_ZERO_SHOT_IMAGE_CLASSIFICATION_MAPPING_NAMES, | |
"ctc": MODEL_FOR_CTC_MAPPING_NAMES, | |
"audio-classification": MODEL_FOR_AUDIO_CLASSIFICATION_MAPPING_NAMES, | |
"semantic-segmentation": MODEL_FOR_SEMANTIC_SEGMENTATION_MAPPING_NAMES, | |
"backbone": MODEL_FOR_BACKBONE_MAPPING_NAMES, | |
} | |
if supported_tasks is None: | |
supported_tasks = task_mapping.keys() | |
if isinstance(supported_tasks, str): | |
supported_tasks = [supported_tasks] | |
model_class_names = [] | |
for task in supported_tasks: | |
class_name = task_mapping[task].get(model_name, None) | |
if class_name: | |
model_class_names.append(class_name) | |
return model_class_names | |
_REGULAR_SUPPORTED_MODEL_NAMES_AND_TASKS = [ | |
"altclip", | |
"albert", | |
"bart", | |
"bert", | |
"blenderbot", | |
"blenderbot-small", | |
"bloom", | |
"clip", | |
"convnext", | |
"deberta", | |
"deberta-v2", | |
"dinov2", | |
"distilbert", | |
"donut-swin", | |
"electra", | |
"gpt2", | |
"gpt_neo", | |
"gptj", | |
"hubert", | |
"layoutlm", | |
"lxmert", | |
"m2m_100", | |
"marian", | |
"mbart", | |
"megatron-bert", | |
"mobilebert", | |
"mt5", | |
"nezha", | |
"opt", | |
"pegasus", | |
"plbart", | |
"resnet", | |
"roberta", | |
"segformer", | |
"speech_to_text", | |
"speech_to_text_2", | |
"swin", | |
"t5", | |
"trocr", | |
"vit", | |
"xglm", | |
"wav2vec2", | |
# "xlnet", | |
] | |
_REGULAR_SUPPORTED_MODELS = [] | |
for item in _REGULAR_SUPPORTED_MODEL_NAMES_AND_TASKS: | |
if isinstance(item, dict): | |
_REGULAR_SUPPORTED_MODELS.extend(_generate_supported_model_class_names(**item)) | |
else: | |
_REGULAR_SUPPORTED_MODELS.extend(_generate_supported_model_class_names(item)) | |
_SPECIAL_SUPPORTED_MODELS = [ | |
"CLIPTextModel", | |
"CLIPTextModelWithProjection", | |
"CLIPVisionModel", | |
"CLIPVisionModelWithProjection", | |
"AltCLIPTextModel", | |
"AltCLIPVisionModel", | |
"GitVisionModel", | |
"GPT2DoubleHeadsModel", | |
"Speech2Text2Decoder", | |
"TrOCRDecoder", | |
"PeftModelForCausalLM", | |
"PeftModelForSeq2SeqLM", | |
# TODO: add support for them as it should be quite easy to do so (small blocking issues). | |
# XLNetForQuestionAnswering, | |
] | |
_SUPPORTED_MODELS = tuple(sorted(set(_REGULAR_SUPPORTED_MODELS + _SPECIAL_SUPPORTED_MODELS))) | |
def torch_nn_embedding(self, input): | |
return torch.empty(*input.shape, self.weight.shape[-1], device="meta", dtype=self.weight.dtype) | |
def torch_nn_functional_embedding( | |
input, weight, padding_idx=None, max_norm=None, norm_type=2.0, scale_grad_by_freq=False, sparse=False | |
): | |
return torch.empty(*input.shape, weight.shape[-1], device="meta", dtype=weight.dtype) | |
def torch_nn_layernorm(self, input): | |
return input | |
def torch_nn_groupnorm(self, input): | |
return input | |
def torch_nn_linear(self, input): | |
return torch.empty(input.shape[:-1] + (self.out_features,), device="meta") | |
def torch_relu(x): | |
return x | |
def torch_nn_relu(self, x): | |
return x | |
def torch_nn_functional_relu(x, inplace=False): | |
if not inplace: | |
raise ValueError("Don't support in-place functional.relu for MetaTensor analysis") | |
return x | |
def torch_where(condition, x, y): | |
# torch.where returns the broadcasted tensor of condition, x, and y, | |
# so hack it by using addition | |
return condition.to(device="meta") + x.to(device="meta") + y.to(device="meta") | |
def torch_abs(input, *, out=None): | |
if out is not None: | |
raise ValueError("Don't support in-place abs for MetaTensor analysis") | |
return input | |
def torch_arange(*args, **kwargs): | |
n = len(args) | |
step = 1 | |
if n == 1: | |
start = 0 | |
end = args[0] | |
elif n == 2: | |
start, end = args | |
else: | |
start, end, step = args | |
if isinstance(start, float): | |
start = int(start) | |
if isinstance(end, float): | |
start = int(end) | |
if isinstance(step, float): | |
step = int(step) | |
step = kwargs.get("step", step) | |
dtype = kwargs.get("dtype") | |
return torch.empty((end - start) // step, dtype=dtype, device="meta") | |
def torch_full(*args, **kwargs): | |
args = list(args) | |
if isinstance(args[1], torch.Tensor) and args[1].device == torch.device("meta"): | |
args[1] = 1 # Any value. | |
kwargs_without_device = dict(kwargs) | |
kwargs_without_device.pop("device", None) | |
return torch.full(*args, **kwargs_without_device) | |
def torch_cat(tensors, dim=None, axis=None, *, out=None): | |
if dim is None and axis is None: | |
dim = 0 | |
if dim is None and axis is not None: | |
dim = axis | |
if dim < 0: | |
dim = tensors[0].dim() + dim | |
shapes = [t.shape for t in tensors] | |
shape = list(shapes[0]) | |
concatenated_dim = sum(shape[dim] for shape in shapes) | |
final_shape = shape[:dim] + [concatenated_dim] + shape[dim + 1 :] | |
return torch.empty(final_shape, device="meta") | |
def torch_stack(tensors, dim=None, axis=None, *, out=None): | |
if dim is None and axis is None: | |
dim = 0 | |
if dim is None and axis is not None: | |
dim = axis | |
if dim < 0: | |
dim = tensors[0].dim() + 1 + dim | |
shape = list(tensors[0].shape) | |
shape.insert(dim, len(tensors)) | |
return torch.empty(shape, device="meta") | |
def torch_add(input, other, *, alpha=1, out=None): | |
if not isinstance(input, torch.Tensor): | |
return torch.empty_like(other, device="meta") | |
if not isinstance(other, torch.Tensor): | |
return torch.empty_like(input, device="meta") | |
max_length = max(input.dim(), other.dim()) | |
input_shape = list(input.shape) + [1] * (max_length - input.dim()) | |
other_shape = list(other.shape) + [1] * (max_length - other.dim()) | |
shape = [] | |
for i in range(max_length): | |
shape.append(max(input_shape[i], other_shape[i])) | |
return torch.empty(shape, device="meta") | |
def torch_mul(input, other, *, out=None): | |
return torch_add(input, other, out=out) | |
def torch_tensor_mul(self, other): | |
return torch_mul(self, other) | |
def torch_matmul(input, other, *, out=None): | |
d1 = input.dim() | |
d2 = other.dim() | |
shape = None | |
if d1 == 1 and d2 == 1: | |
shape = None | |
elif d1 == 2 and d2 == 2: | |
shape = (input.size(0), other.size(1)) | |
elif d1 == 1 and d2 == 2: | |
shape = (other.size(1),) | |
elif d1 == 2 and d1 == 1: | |
shape = (input.size(0),) | |
else: | |
max_length = max(input.dim(), other.dim()) | |
shape1 = list(input.shape) | |
shape2 = list(other.shape) | |
if d1 == 1: | |
shape1 = [1] + shape1 | |
if d2 == 1: | |
shape2.append(1) | |
shape1 = [-1] * (max_length - d1) + list(input.shape) | |
shape2 = [-1] * (max_length - d2) + list(other.shape) | |
shape = [] | |
for i in range(max_length): | |
shape.append(max(shape1[i], shape2[i])) | |
shape[-2] = shape1[-2] | |
shape[-1] = shape2[-1] | |
if d1 == 1: | |
shape.pop(-2) | |
if d2 == 1: | |
shape.pop(-1) | |
if shape is None: | |
return torch.tensor(0.0, device="meta") | |
return torch.empty(*shape, device="meta") | |
def torch_bmm(input, mat2, *, out=None): | |
if out is not None: | |
raise ValueError("Don't support in-place bmm for MetaTensor analysis") | |
batch_size, n, m = input.shape | |
_, _, p = mat2.shape | |
return torch.empty(batch_size, n, p, device="meta") | |
def torch_baddbmm(input, batch1, batch2, *, beta=1, alpha=1, out=None): | |
if out is not None: | |
raise ValueError("Don't support in-place baddbmm for MetaTensor analysis") | |
return torch_bmm(batch1, batch2) | |
def torch_tensor_baddbmm(self, batch1, batch2, *, beta=1, alpha=1, out=None): | |
return torch_baddbmm(self, batch1, batch2, beta=beta, alpha=alpha, out=out) | |
def torch_einsum(equation, *operands): | |
# TODO: infer shape without performing the computation, this might be quite hard. | |
concrete_operands = (torch.empty_like(operand, device="cpu") for operand in operands) | |
return torch.einsum(equation, *concrete_operands).to("meta") | |
def torch_tensor_repeat(self, *sizes): | |
shape = list(self.shape) | |
for i, x in enumerate(sizes): | |
shape[i] *= x | |
return torch.empty(shape, device="meta") | |
def torch_repeat_interleave(*args, dim=None, output_size=None): | |
num_args = len(args) | |
if num_args == 1: | |
shape = [output_size if output_size is not None else args[0].sum()] | |
else: | |
shape = list(args[0].shape) | |
if dim is None: | |
if num_args > 2: | |
dim = args[2] | |
else: | |
shape = [sum(shape)] | |
dim = 0 | |
repeats = args[1] | |
if isinstance(repeats, int) or torch.numel(repeats) == 1: | |
shape[dim] *= int(repeats) | |
else: | |
shape[dim] = output_size if output_size is not None else repeats.sum() | |
return torch.empty(*shape, device="meta") | |
def torch_index_select(input, dim, index, *, out=None): | |
shape = list(input.shape) | |
shape[dim] = len(index) | |
return torch.empty(*shape, device="meta") | |
def torch_tensor_index_select(self, dim, index): | |
return torch_index_select(self, dim, index) | |
def torch_gather(input, dim, index, *, sparse_grad=False, out=None): | |
shape = list(input.shape) | |
shape[dim] = index.shape[dim] | |
return torch.empty(*shape, device="meta") | |
def torch_tensor_gather(self, dim, index): | |
return torch_gather(self, dim, index) | |
def torch_roll(input, shifts, dims=None): | |
return input | |
def torch_flip(input, dims): | |
return input | |
def torch_tensor_flip(self, dims): | |
return self | |
def torch_nn_conv1d(self, input): | |
l_in = input.shape[-1] | |
shape = None | |
padding = self.padding | |
if padding == "valid": | |
padding = (0, 0) | |
if padding == "same": | |
shape = list(input.shape) | |
if shape is None: | |
shape = list(input.shape) | |
l_out = math.floor( | |
(l_in + 2 * padding[0] - self.dilation[0] * (self.kernel_size[0] - 1) - 1) / self.stride[0] + 1 | |
) | |
shape[-1] = l_out | |
shape[-2] = self.out_channels | |
return torch.empty(shape, device="meta") | |
def torch_nn_conv2d(self, input): | |
h_in, w_in = input.shape[-2:] | |
shape = None | |
padding = self.padding | |
if padding == "valid": | |
padding = (0, 0) | |
if padding == "same": | |
shape = list(input.shape) | |
if shape is None: | |
shape = list(input.shape) | |
h_out = math.floor( | |
(h_in + 2 * padding[0] - self.dilation[0] * (self.kernel_size[0] - 1) - 1) / self.stride[0] + 1 | |
) | |
w_out = math.floor( | |
(w_in + 2 * padding[1] - self.dilation[1] * (self.kernel_size[1] - 1) - 1) / self.stride[1] + 1 | |
) | |
shape[-2:] = [h_out, w_out] | |
shape[-3] = self.out_channels | |
return torch.empty(shape, device="meta") | |
def torch_squeeze(input, dim=None): | |
shape = list(input.shape) | |
if dim is not None: | |
if dim < 0: | |
dim = input.dim() + dim | |
if shape[dim] == 1: | |
shape.pop(dim) | |
else: | |
new_shape = [] | |
for dim_value in shape: | |
if dim_value == 1: | |
continue | |
new_shape.append(dim_value) | |
shape = new_shape | |
return torch.empty(shape, device="meta") | |
def torch_tensor_squeeze(self, dim=None): | |
return torch_squeeze(self, dim) | |
def torch_unsqueeze(input, dim): | |
shape = list(input.shape) | |
if dim < 0: | |
dim = input.dim() + 1 + dim | |
shape.insert(dim, 1) | |
return torch.empty(shape, device="meta") | |
def torch_tensor_unsqueeze(self, dim): | |
return torch_unsqueeze(self, dim) | |
def torch_unique_consecutive(input, **kwargs): | |
output = torch.unique_consecutive(torch.zeros_like(input, device="cpu"), **kwargs) | |
if isinstance(output, torch.Tensor): | |
return output.to("meta") | |
else: | |
return tuple(map(output, lambda x: x.to("meta"))) | |
def torch_nn_functional_one_hot(tensor, num_classes=-1): | |
if num_classes < 0: | |
raise ValueError("Don't support automatic num_classes inference for MetaTensor analysis") | |
shape = list(tensor.shape) + [num_classes] | |
return torch.empty(shape, device="meta") | |
def torch_nn_mseloss(self, input, target): | |
if self.reduction == "none": | |
shape = target.shape | |
else: | |
shape = (1,) | |
return torch.empty(shape, device="meta") | |
def torch_nn_crossentropyloss(self, input, target): | |
if self.reduction == "none": | |
shape = target.shape | |
else: | |
shape = (1,) | |
return torch.empty(shape, device="meta") | |
def torch_nn_bcewithlogitsloss(self, input, target): | |
if self.reduction == "none": | |
shape = target.shape | |
else: | |
shape = (1,) | |
return torch.empty(shape, device="meta") | |
def operator_getitem(a, b): | |
def to_concrete(t): | |
if isinstance(t, torch.Tensor): | |
concrete = torch.ones_like(t, device="cpu") | |
if concrete.dtype in [torch.float16, torch.float32, torch.float64, torch.int32]: | |
concrete = concrete.to(torch.int64) | |
return concrete | |
return t | |
if isinstance(a, torch.Tensor): | |
# TODO: infer shape without performing the computation. | |
if isinstance(b, tuple): | |
b = tuple(map(to_concrete, b)) | |
else: | |
b = to_concrete(b) | |
return operator.getitem(torch.empty_like(a, device="cpu"), b).to("meta") | |
return operator.getitem(a, b) | |
_MANUAL_META_OVERRIDES: Dict[Callable, Callable] = { | |
torch.nn.Embedding: torch_nn_embedding, | |
torch.nn.functional.embedding: torch_nn_functional_embedding, | |
torch.nn.LayerNorm: torch_nn_layernorm, | |
torch.nn.GroupNorm: torch_nn_groupnorm, | |
torch.nn.Linear: torch_nn_linear, | |
torch.relu: torch_relu, | |
torch.nn.functional.relu: torch_nn_functional_relu, | |
torch.nn.ReLU: torch_nn_relu, | |
torch.where: torch_where, | |
torch.abs: torch_abs, | |
torch.arange: torch_arange, | |
torch.full: torch_full, | |
torch.cat: torch_cat, | |
torch.stack: torch_stack, | |
torch.add: torch_add, | |
torch.mul: torch_mul, | |
torch.Tensor.mul: torch_tensor_mul, | |
torch.matmul: torch_matmul, | |
torch.bmm: torch_bmm, | |
torch.baddbmm: torch_baddbmm, | |
torch.Tensor.baddbmm: torch_tensor_baddbmm, | |
torch.einsum: torch_einsum, | |
torch.Tensor.repeat: torch_tensor_repeat, | |
torch.repeat_interleave: torch_repeat_interleave, | |
torch.roll: torch_roll, | |
torch.flip: torch_flip, | |
torch.Tensor.flip: torch_tensor_flip, | |
torch.index_select: torch_index_select, | |
torch.Tensor.index_select: torch_tensor_index_select, | |
torch.gather: torch_gather, | |
torch.Tensor.gather: torch_tensor_gather, | |
torch.nn.Conv1d: torch_nn_conv1d, | |
torch.nn.Conv2d: torch_nn_conv2d, | |
torch.squeeze: torch_squeeze, | |
torch.Tensor.squeeze: torch_tensor_squeeze, | |
torch.unsqueeze: torch_unsqueeze, | |
torch.Tensor.unsqueeze: torch_tensor_unsqueeze, | |
torch.unique_consecutive: torch_unique_consecutive, | |
torch.nn.functional.one_hot: torch_nn_functional_one_hot, | |
torch.nn.MSELoss: torch_nn_mseloss, | |
torch.nn.CrossEntropyLoss: torch_nn_crossentropyloss, | |
torch.nn.BCEWithLogitsLoss: torch_nn_bcewithlogitsloss, | |
operator.getitem: operator_getitem, | |
} | |
class HFProxy(Proxy): | |
""" | |
Proxy that uses metadata to handle data-dependent control-flow. | |
""" | |
def install_metadata(self, metadata): | |
self._metadata = metadata | |
def shape(self): | |
return self.tracer.create_proxy("call_method", "size", (self,), {}) | |
def device(self): | |
# Hack so we can track when devices are used. During meta-tensor propagation, | |
# replace these values with a constant 'meta' | |
return MetaDeviceAttribute(self, "device") | |
def __len__(self): | |
if hasattr(self, "_metadata") and self._metadata is not None: | |
return len(self._metadata) | |
return super().__len__() | |
def __bool__(self): | |
if hasattr(self, "_metadata") and self._metadata is not None: | |
return self._metadata | |
return super().__bool__() | |
def __getattr__(self, k): | |
if k == "_metadata": | |
return self.__getattribute__(k) | |
# note: not added to the graph yet, if this is a method call | |
# we peephole optimize to the method invocation | |
return HFAttribute(self, k) | |
def __setitem__(self, indices, values): | |
return self.tracer.create_proxy("call_function", operator.setitem, (self, indices, values), {}) | |
def __contains__(self, key): | |
if hasattr(self, "_metadata") and self._metadata is not None: | |
return key in self._metadata | |
return super().__contains__(key) | |
class HFAttribute(HFProxy): | |
def __init__(self, root, attr: str): | |
self.root = root | |
self.attr = attr | |
self.tracer = root.tracer | |
self._node = None | |
if hasattr(self.root, "_metadata"): | |
self.install_metadata(getattr(self.root._metadata, attr)) | |
def node(self): | |
# the node for attributes is added lazily, since most will just be method calls | |
# which do not rely on the getitem call | |
if self._node is None: | |
self._node = self.tracer.create_proxy("call_function", builtins.getattr, (self.root, self.attr), {}).node | |
return self._node | |
def __call__(self, *args, **kwargs): | |
return self.tracer.create_proxy("call_method", self.attr, (self.root,) + args, kwargs) | |
class MetaDeviceAttribute(HFAttribute): | |
pass | |
def _proxies_to_metas(v): | |
"""Returns the underlying metadata for HFProxies, and behaves like the identity for the others.""" | |
if isinstance(v, MetaDeviceAttribute): | |
return "meta" | |
if isinstance(v, torch.fx.Proxy): | |
if not (isinstance(v, HFProxy) and hasattr(v, "_metadata")): | |
raise RuntimeError(f"No metadata was found for {v}") | |
return v._metadata | |
return v | |
def _gen_constructor_wrapper(target): | |
def wrapper(*args, **kwargs): | |
proxy = None | |
def check_has_proxy(v): | |
if isinstance(v, Proxy): | |
nonlocal proxy | |
proxy = v | |
torch.fx.node.map_aggregate(args, check_has_proxy) | |
torch.fx.node.map_aggregate(kwargs, check_has_proxy) | |
if proxy is not None: | |
return proxy.tracer.create_proxy("call_function", target, args, kwargs) | |
else: | |
return target(*args, **kwargs) | |
return wrapper, target | |
def _generate_random_int(low: int = 10, high: int = 20, forbidden_values: Optional[List[int]] = None): | |
if forbidden_values is None: | |
forbidden_values = [] | |
value = random.randint(low, high) | |
while value in forbidden_values: | |
value = random.randint(low, high) | |
return value | |
class HFTracer(Tracer): | |
""" | |
Tracer that is able to symbolically trace models from the library. To do that, it uses the HFProxy instead of the | |
regular PyTorch torch.fx.Proxy. | |
""" | |
# Feature flag for proxying accesses to buffer values | |
proxy_buffer_attributes: bool = True | |
allow_insert_stateless_mods: bool = True | |
_TORCH_METHODS_TO_PATCH = [ | |
"arange", | |
"zeros", | |
"ones", | |
"full", | |
"full_like", | |
"eye", | |
"empty", | |
"tensor", | |
"clamp", | |
"finfo", | |
] | |
supported_archs = (PreTrainedModel,) if not is_peft_available() else (PreTrainedModel, PeftModel) | |
def __init__(self, autowrap_modules=(math,), autowrap_functions=()): | |
super().__init__(autowrap_modules=autowrap_modules, autowrap_functions=autowrap_functions) | |
if not is_torch_fx_available(): | |
raise ImportError( | |
f"Found an incompatible version of torch. Found version {get_torch_version()}, but only version " | |
f"{TORCH_FX_REQUIRED_VERSION} is supported." | |
) | |
def _generate_dummy_input( | |
self, model: PreTrainedModel, input_name: str, shape: List[int] | |
) -> Dict[str, torch.Tensor]: | |
"""Generates dummy input for model inference recording.""" | |
# Retrieving the model class, either from the "class_for_deserialization" attribute if the model was restored | |
# from pickle, or from the "__class__" attribute in the general case. | |
model_class_name = getattr(model, "class_for_deserialization", model.__class__).__name__ | |
device = model.device | |
inputs_dict = {} | |
if input_name in ["labels", "start_positions", "end_positions"]: | |
batch_size = shape[0] | |
if model_class_name in [ | |
*get_values(MODEL_FOR_NEXT_SENTENCE_PREDICTION_MAPPING_NAMES), | |
*get_values(MODEL_FOR_MULTIPLE_CHOICE_MAPPING_NAMES), | |
*get_values(MODEL_FOR_IMAGE_CLASSIFICATION_MAPPING_NAMES), | |
*get_values(MODEL_FOR_BACKBONE_MAPPING_NAMES), | |
*get_values(MODEL_FOR_AUDIO_CLASSIFICATION_MAPPING_NAMES), | |
]: | |
inputs_dict["labels"] = torch.zeros(batch_size, dtype=torch.long, device=device) | |
elif model_class_name in [ | |
*get_values(MODEL_FOR_QUESTION_ANSWERING_MAPPING_NAMES), | |
*get_values(MODEL_FOR_DOCUMENT_QUESTION_ANSWERING_MAPPING_NAMES), | |
"XLNetForQuestionAnswering", | |
]: | |
inputs_dict["start_positions"] = torch.zeros(batch_size, dtype=torch.long, device=device) | |
inputs_dict["end_positions"] = torch.zeros(batch_size, dtype=torch.long, device=device) | |
elif model_class_name in get_values(MODEL_FOR_SEQUENCE_CLASSIFICATION_MAPPING_NAMES): | |
if not hasattr(model.config, "problem_type") or model.config.problem_type is None: | |
raise ValueError( | |
"Could not retrieve the problem type for the sequence classification task, please set " | |
'model.config.problem_type to one of the following values: "regression", ' | |
'"single_label_classification", or "multi_label_classification".' | |
) | |
if model.config.problem_type == "regression": | |
labels_shape = (batch_size, model.config.num_labels) | |
labels_dtype = torch.float32 | |
elif model.config.problem_type == "single_label_classification": | |
labels_shape = (batch_size,) | |
labels_dtype = torch.long | |
elif model.config.problem_type == "multi_label_classification": | |
labels_shape = (batch_size, model.config.num_labels) | |
labels_dtype = torch.float32 | |
else: | |
raise ValueError( | |
'Expected model.config.problem_type to be either: "regression", "single_label_classification"' | |
f', or "multi_label_classification", but "{model.config.problem_type}" was provided.' | |
) | |
inputs_dict["labels"] = torch.zeros(*labels_shape, dtype=labels_dtype, device=device) | |
elif model_class_name in [ | |
*get_values(MODEL_FOR_PRETRAINING_MAPPING_NAMES), | |
*get_values(MODEL_FOR_TOKEN_CLASSIFICATION_MAPPING_NAMES), | |
*get_values(MODEL_FOR_CAUSAL_LM_MAPPING_NAMES), | |
*get_values(MODEL_FOR_MASKED_LM_MAPPING_NAMES), | |
*get_values(MODEL_FOR_SEQ_TO_SEQ_CAUSAL_LM_MAPPING_NAMES), | |
*get_values(MODEL_FOR_SEMANTIC_SEGMENTATION_MAPPING_NAMES), | |
"GPT2DoubleHeadsModel", | |
"PeftModelForCausalLM", | |
"PeftModelForSeq2SeqLM", | |
]: | |
inputs_dict["labels"] = torch.zeros(shape, dtype=torch.long, device=device) | |
elif model_class_name in [*get_values(MODEL_FOR_CTC_MAPPING_NAMES)]: | |
inputs_dict["labels"] = torch.zeros(shape, dtype=torch.float32, device=device) | |
else: | |
raise NotImplementedError( | |
f"Generating the dummy input named {input_name} for {model_class_name} is not supported yet." | |
) | |
elif "pixel_values" in input_name: | |
batch_size = shape[0] | |
image_size = getattr(model.config, "image_size", None) | |
if image_size is None: | |
if hasattr(model.config, "vision_config"): | |
image_size = model.config.vision_config.image_size | |
elif hasattr(model.config, "encoder"): | |
image_size = model.config.encoder.image_size | |
else: | |
image_size = (_generate_random_int(), _generate_random_int()) | |
# If no num_channels is in the config, use some arbitrary value. | |
num_channels = getattr(model.config, "num_channels", 3) | |
if not isinstance(image_size, collections.abc.Iterable): | |
image_size = (image_size, image_size) | |
height, width = image_size | |
inputs_dict[input_name] = torch.zeros( | |
batch_size, num_channels, height, width, dtype=torch.float32, device=device | |
) | |
elif "bbox" in input_name: | |
inputs_dict[input_name] = torch.zeros(*shape, 4, dtype=torch.float, device=device) | |
elif "input_features" in input_name: | |
inputs_dict[input_name] = torch.zeros( | |
*shape, model.config.input_feat_per_channel, dtype=torch.float, device=device | |
) | |
elif "visual_feats" in input_name: | |
inputs_dict[input_name] = torch.zeros( | |
shape | |
+ [ | |
model.config.visual_feat_dim, | |
], | |
dtype=torch.float, | |
device=device, | |
) | |
elif "visual_pos" in input_name: | |
inputs_dict[input_name] = torch.zeros( | |
shape | |
+ [ | |
model.config.visual_pos_dim, | |
], | |
dtype=torch.float, | |
device=device, | |
) | |
elif "inputs" in input_name: | |
inputs_dict[input_name] = torch.zeros(*shape, dtype=torch.float, device=device) | |
elif "input_values" in input_name: | |
batch_size, _ = shape | |
# Generating big sequence length for audio inputs. | |
seq_length = _generate_random_int(low=10000, high=20000) | |
inputs_dict[input_name] = torch.zeros(batch_size, seq_length, dtype=torch.float, device=device) | |
elif "mask" in input_name or "ids" in input_name: | |
inputs_dict[input_name] = torch.zeros(shape, dtype=torch.long, device=device) | |
else: | |
shape_with_hidden_size = shape + [model.config.hidden_size] | |
inputs_dict[input_name] = torch.zeros(shape_with_hidden_size, dtype=torch.float, device=device) | |
return inputs_dict | |
def create_proxy(self, kind, target, args, kwargs, name=None, type_expr=None, proxy_factory_fn=None): | |
rv = super().create_proxy(kind, target, args, kwargs, name, type_expr, proxy_factory_fn) | |
if kind == "placeholder" and target in self.meta_args: | |
rv.install_metadata(self.meta_args[target]) | |
return rv | |
if target in self.orig_fns: | |
# NOTE: tensor constructors in PyTorch define the `device` argument as | |
# *kwargs-only*. That is why this works. If you add methods to | |
# _TORCH_METHODS_TO_PATCH that do not define `device` as kwarg-only, | |
# this will break and you will likely see issues where we cannot infer | |
# the size of the output. | |
if "device" in kwargs: | |
kwargs["device"] = "meta" | |
try: | |
args_metas = torch.fx.node.map_aggregate(args, _proxies_to_metas) | |
kwargs_metas = torch.fx.node.map_aggregate(kwargs, _proxies_to_metas) | |
if kind == "call_function": | |
meta_target = _MANUAL_META_OVERRIDES.get(target, target) | |
meta_out = meta_target(*args_metas, **kwargs_metas) | |
if isinstance(meta_out, torch.Tensor): | |
meta_out = meta_out.to(device="meta") | |
elif kind == "call_method": | |
method = getattr(args_metas[0].__class__, target) | |
meta_target = _MANUAL_META_OVERRIDES.get(method, method) | |
meta_out = meta_target(*args_metas, **kwargs_metas) | |
elif kind == "call_module": | |
if not hasattr(self, "orig_forward"): | |
raise AttributeError(f"{self} does not have an attribute called orig_forward") | |
self._disable_module_getattr = True | |
try: | |
mod = self.root.get_submodule(target) | |
mod_type = type(mod) | |
if mod_type in _MANUAL_META_OVERRIDES: | |
meta_out = _MANUAL_META_OVERRIDES[mod_type](mod, *args_metas, **kwargs_metas) | |
else: | |
meta_out = self.orig_forward(*args_metas, **kwargs_metas) | |
finally: | |
self._disable_module_getattr = False | |
elif kind == "get_attr": | |
self._disable_module_getattr = True | |
try: | |
attr_itr = self.root | |
atoms = target.split(".") | |
for atom in atoms: | |
attr_itr = getattr(attr_itr, atom) | |
if isinstance(attr_itr, torch.Tensor): | |
meta_out = attr_itr.to(device="meta") | |
else: | |
meta_out = attr_itr | |
finally: | |
self._disable_module_getattr = False | |
else: | |
return rv | |
if not isinstance(rv, Proxy): | |
raise ValueError("Don't support composite output yet") | |
rv.install_metadata(meta_out) | |
except Exception as e: | |
if _IS_IN_DEBUG_MODE: | |
warnings.warn(f"Could not compute metadata for {kind} target {target}: {e}") | |
return rv | |
# Replaced by .getattr from PyTorch 1.13 | |
def _module_getattr(self, attr, attr_val, parameter_proxy_cache): | |
if getattr(self, "_disable_module_getattr", False): | |
return attr_val | |
else: | |
def maybe_get_proxy_for_attr(attr_val, collection_to_search, parameter_proxy_cache): | |
for n, p in collection_to_search: | |
if attr_val is p: | |
if n not in parameter_proxy_cache: | |
kwargs = {} | |
if "proxy_factory_fn" in inspect.signature(self.create_proxy).parameters: | |
kwargs["proxy_factory_fn"] = ( | |
None | |
if not self.param_shapes_constant | |
else lambda node: ParameterProxy(self, node, n, attr_val) | |
) | |
val_proxy = self.create_proxy("get_attr", n, (), {}, **kwargs) # type: ignore[arg-type] | |
parameter_proxy_cache[n] = val_proxy | |
return parameter_proxy_cache[n] | |
return None | |
if isinstance(attr_val, torch.nn.Parameter): | |
maybe_parameter_proxy = maybe_get_proxy_for_attr( | |
attr_val, self.root.named_parameters(), parameter_proxy_cache | |
) | |
if maybe_parameter_proxy is not None: | |
return maybe_parameter_proxy | |
if self.proxy_buffer_attributes and isinstance(attr_val, torch.Tensor): | |
maybe_buffer_proxy = maybe_get_proxy_for_attr( | |
attr_val, self.root.named_buffers(), parameter_proxy_cache | |
) | |
if maybe_buffer_proxy is not None: | |
return maybe_buffer_proxy | |
return attr_val | |
# Needed for PyTorch 1.13+ | |
def getattr(self, attr: str, attr_val: Any, parameter_proxy_cache: Dict[str, Any]): | |
return self._module_getattr(attr, attr_val, parameter_proxy_cache) | |
def call_module(self, m, forward, args, kwargs): | |
self.orig_forward = forward | |
return super().call_module(m, forward, args, kwargs) | |
def proxy(self, node): | |
return HFProxy(node, self) | |
def trace( | |
self, | |
root: Union[torch.nn.Module, Callable[..., Any]], | |
concrete_args: Optional[Dict[str, Any]] = None, | |
dummy_inputs: Optional[Dict[str, Any]] = None, | |
complete_concrete_args_with_inputs_not_in_dummy_inputs: bool = True, | |
) -> Graph: | |
""" | |
Traces `root` and returns the corresponding FX `torch.fx.Graph` representation. `root` can either be a | |
`torch.nn.Module` instance or a Python callable. Note that after this call, `self.root` may be different from | |
the `root` passed in here. For example, when a free function is passed to `trace()`, we will create a | |
`torch.nn.Module` instance to use as the root and add embedded constants to. | |
Args: | |
root (`torch.nn.Module` or `Callable`): | |
Either a `torch.nn.Module`` or a function to be traced through. If root is not a | |
[`~transformers.PreTrainedModel`], then `dummy_inputs` must be passed, otherwise tracing will fail. | |
concrete_args (`Dict[str, Any], *optional*): | |
Concrete arguments that should not be treated as Proxies | |
dummy_inputs (`Dict[str, Any]`, *optional*): | |
The dummy inputs needed to handle data-dependent control-flow if `root` is not a | |
[`~transformers.PreTrainedModel`]. It can also be used when `root` is a | |
[`~transformers.PreTrainedModel`] to specify custom dummy inputs for a subset or all the model inputs. | |
complete_concrete_args_with_inputs_not_in_dummy_inputs (`bool`, *optional*, defaults to `True`): | |
If `True`, and `dummy_inputs` is specified, every argument that `root` can take that is not in | |
`dummy_inputs` and not in `concrete_args` will be added to `concrete_args`, otherwise does nothing. | |
Returns: | |
`torch.fx.Graph`: | |
A FX `torch.fx.Graph` representing the semantics of the passed-in `root`. | |
""" | |
sig = inspect.signature(root.forward if isinstance(root, torch.nn.Module) else root) | |
if concrete_args is None: | |
concrete_args = {} | |
if dummy_inputs is not None and complete_concrete_args_with_inputs_not_in_dummy_inputs: | |
for param in sig.parameters.values(): | |
if param.name in dummy_inputs: | |
continue | |
if param.default is inspect.Parameter.empty: | |
raise ValueError(f"You need to specify a default value for the parameter {param.name}.") | |
concrete_args.update( | |
{ | |
p.name: p.default | |
for p in sig.parameters.values() | |
if (p.name not in dummy_inputs and p.name not in concrete_args) | |
} | |
) | |
input_names = sig.parameters.keys() - concrete_args.keys() | |
# Creating a random input shape to generate dummy inputs. | |
batch_size = _generate_random_int() | |
sequence_length = _generate_random_int() | |
shape = [batch_size, sequence_length] | |
if root.__class__.__name__ in get_values(MODEL_FOR_MULTIPLE_CHOICE_MAPPING_NAMES): | |
num_choices = _generate_random_int(low=2, high=5) | |
shape.insert(1, num_choices) | |
inputs = dict(dummy_inputs) if dummy_inputs is not None else {} | |
for input_name in input_names: | |
if input_name in inputs: | |
continue | |
# We enforce that root must either be a PreTrainedModel or deserialized from a serialized traced model to | |
# be able to use HFTracer._generate_dummy_input. | |
if isinstance(root, self.supported_archs) or type(root).__qualname__.startswith( | |
("_deserialize_graph_module", "_CodeOnlyModule") | |
): | |
inputs.update(self._generate_dummy_input(root, input_name, shape)) | |
else: | |
raise RuntimeError( | |
f"Could not generate input named {input_name} for because root is not a" | |
" transformers.PreTrainedModel." | |
) | |
concrete_metas = { | |
input_name: input_.to("meta") if isinstance(input_, torch.Tensor) else input_ | |
for input_name, input_ in inputs.items() | |
} | |
for param in sig.parameters.values(): | |
if param.kind == inspect.Parameter.VAR_KEYWORD and param.name not in input_names: | |
concrete_metas[f"**{param.name}"] = {} | |
self.meta_args = concrete_metas | |
self.patched_torch_methods = { | |
target: _gen_constructor_wrapper(getattr(torch, target)) for target in self._TORCH_METHODS_TO_PATCH | |
} | |
self.orig_fns = set() | |
for name, (wrapper, orig) in self.patched_torch_methods.items(): | |
setattr(torch, name, wrapper) | |
self.orig_fns.add(orig) | |
try: | |
self.graph = super().trace(root, concrete_args=concrete_args) | |
finally: | |
for name, (_, orig) in self.patched_torch_methods.items(): | |
setattr(torch, name, orig) | |
# This is necessary because concrete args are added as input to the traced module since | |
# https://github.com/pytorch/pytorch/pull/55888. | |
for node in self.graph.nodes: | |
if node.op == "placeholder": | |
# Removing default values for inputs as the forward pass will fail with them. | |
if node.target in input_names: | |
node.args = () | |
# Without this, torch.jit.script fails because the inputs type is Optional[torch.Tensor]. | |
# It cannot infer on the attributes and methods the input should have, and fails. | |
node.type = torch.Tensor | |
# It is a concrete arg so it is not used and should be removed. | |
else: | |
to_visit = [node] | |
to_delete = collections.OrderedDict() | |
while to_visit: | |
n = to_visit.pop(0) | |
to_delete[n] = None | |
to_visit += list(n.users.keys()) | |
for user in reversed(to_delete.keys()): | |
self.graph.erase_node(user) | |
# TODO: solves GraphModule creation. | |
# Without this, return type annotation "Tuple" is causing code execution failure. | |
if node.op == "output": | |
node.type = None | |
return self.graph | |
def _stateless_mod_instanciation_depends_on_proxies(self, mod: nn.Module) -> bool: | |
""" | |
Whether the module was instantiated with Proxies. If that is the case, such module cannot be a leaf module | |
because its attributes are input-dependent. | |
""" | |
return any(isinstance(attr, Proxy) for attr in mod.__dict__.values()) | |
def _insert_module_as_submodule(self, mod: nn.Module) -> str: | |
""" | |
Helper method which tries to insert a module that was not declared as submodule. | |
""" | |
# If one of the module attributes is a Proxy, it means that its instantiation is input-dependent. | |
# It is not possible to insert such modules, those should be traced through. | |
if self._stateless_mod_instanciation_depends_on_proxies(mod): | |
return "" | |
idx = 0 | |
mod_name = mod.__class__.__name__.lower() | |
path = f"{mod_name}_{idx}" | |
already_inserted = False | |
while hasattr(self.root, path): | |
if getattr(self.root, path) is mod: | |
already_inserted = True | |
break | |
path = f"{mod_name}_{idx}" | |
idx += 1 | |
# No need to add multiple instances of the same module. | |
if not already_inserted: | |
self.root.add_module(path, mod) | |
return path | |
def path_of_module(self, mod: nn.Module) -> str: | |
""" | |
Helper method to find the qualified name of `mod` in the Module hierarchy of `root`. For example, if `root` has | |
a submodule named `foo`, which has a submodule named `bar`, passing `bar` into this function will return the | |
string "foo.bar". | |
Args: | |
mod (str): The `Module` to retrieve the qualified name for. | |
""" | |
try: | |
return super().path_of_module(mod) | |
except NameError as e: | |
if self.allow_insert_stateless_mods and len(list(mod.parameters())) == 0 and len(list(mod.buffers())) == 0: | |
path = self._insert_module_as_submodule(mod) | |
return path | |
raise e | |
def is_leaf_module(self, m: torch.nn.Module, module_qualified_name: str) -> bool: | |
return (not self._stateless_mod_instanciation_depends_on_proxies(m)) and super().is_leaf_module( | |
m, module_qualified_name | |
) | |
def keys(self, obj: "Proxy") -> Any: | |
"""Called when a proxy object is has the keys() method called. | |
This is what happens when ** is called on a proxy. This should return an iterator if ** is supposed to work in | |
your custom tracer. | |
""" | |
attribute = HFAttribute(obj, "keys")() | |
if obj.node.target == "**kwargs": | |
return attribute._metadata | |
return attribute | |
def get_concrete_args(model: nn.Module, input_names: List[str]): | |
sig = inspect.signature(model.forward) | |
if not (set(input_names) <= set(sig.parameters.keys())): | |
formatted_input_names = input_names[0] if len(input_names) == 1 else ", ".join(input_names) | |
formatted_allowed_input_names = ", ".join(sig.parameters.keys()) | |
raise ValueError( | |
f"The model does not have input(s) named: {formatted_input_names}, expected a subset of the following:" | |
f" {formatted_allowed_input_names}" | |
) | |
return {p.name: p.default for p in sig.parameters.values() if p.name not in input_names} | |
def check_if_model_is_supported(model: PreTrainedModel): | |
if model.__class__.__name__ not in _SUPPORTED_MODELS: | |
supported_model_names = ", ".join(_SUPPORTED_MODELS) | |
raise NotImplementedError( | |
f"Model {model.__class__.__name__} is not supported yet, supported models: {supported_model_names}" | |
) | |
def symbolic_trace( | |
model: PreTrainedModel, | |
input_names: Optional[List[str]] = None, | |
disable_check: bool = False, | |
tracer_cls: Type[HFTracer] = HFTracer, | |
) -> GraphModule: | |
""" | |
Performs symbolic tracing on the model. | |
Args: | |
model ([`PretrainedModel`]): | |
The model to trace. | |
input_names (`List[str]`, *optional*): | |
The names of the inputs of the traced model. If unset, model.dummy_inputs.keys() are used instead. | |
disable_check (`bool`, *optional*, defaults to `False`): | |
If `True`, no check is done before trying to trace the model, this is mostly usesul for debugging purposes. | |
tracer_cls (`Type[HFTracer]`, *optional*, defaults to `HFTracer`): | |
The tracer class to use for instantiating the tracer. If unset, `HFTracer` is used instead. | |
Returns: | |
`torch.fx.GraphModule`: A GraphModule constructed by recording operations seen while tracing the model. | |
Example: | |
```python | |
from transformers.utils.fx import symbolic_trace | |
traced_model = symbolic_trace(model, input_names=["input_ids", "attention_mask", "token_type_ids"]) | |
``` | |
""" | |
if input_names is None: | |
input_names = model.dummy_inputs.keys() | |
input_names = list(input_names) | |
concrete_args = get_concrete_args(model, input_names) | |
if not disable_check: | |
check_if_model_is_supported(model) | |
# Tracing. | |
tracer = tracer_cls() | |
traced_graph = tracer.trace(model, concrete_args=concrete_args) | |
traced = torch.fx.GraphModule(model, traced_graph) | |
traced.config = model.config | |
# The model class must be stored as an attribute to allow model deserialization, which uses trace, and thus | |
# _generate_dummy_input, where the model class is needed. | |
traced.class_for_deserialization = model.__class__ | |
traced.device = model.device | |
return traced | |