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Source code for torch.compiler

# mypy: allow-untyped-defs
from typing import Any, Callable, List, TypeVar

import torch


__all__ = [
    "compile",
    "assume_constant_result",
    "reset",
    "allow_in_graph",
    "substitute_in_graph",
    "list_backends",
    "disable",
    "cudagraph_mark_step_begin",
    "wrap_numpy",
    "is_compiling",
    "is_dynamo_compiling",
]


_F = TypeVar("_F", bound=Callable[..., Any])


[docs]def compile(*args, **kwargs): """ See :func:`torch.compile` for details on the arguments for this function. """ return torch.compile(*args, **kwargs)
[docs]def reset() -> None: """ This function clears all compilation caches and restores the system to its initial state. It is recommended to call this function, especially after using operations like `torch.compile(...)` to ensure a clean state before another unrelated compilation """ import torch._dynamo torch._dynamo.reset()
[docs]def allow_in_graph(fn): """ Tells the compiler frontend (Dynamo) to skip symbolic introspection of the function and instead directly write it to the graph when encountered. If you are using :func:`torch.compile` (with backend="inductor" (the default)), or :func:`torch.export.export`, and trying to black-box a Python function throughout all tracing, do not use this API. Instead, please create a custom operator (see :ref:`custom-ops-landing-page`) .. warning:: If you're a typical torch.compile user (e.g. you're applying torch.compile to a model to make it run faster), you probably don't want to use this function. :func:`allow_in_graph` is a footgun because it skips the compiler frontend (Dynamo) that is responsible for doing safety checks (graph breaks, handling closures, etc). Incorrect usage will lead to difficult-to-debug silent incorrectness issues. Given a Python function with no allow_in_graph decorator, regular execution of torch.compile traces through the function. :func:`allow_in_graph` changes it so that the frontend does not trace inside the function, but the compiler backend still traces through it. Compare this to custom operators, which treats a function as a black box throughout the torch.compile stack. The following table compares these mechanisms. +------------------------+-----------------------+--------------------------------+ | Mechanism | Frontend (Dynamo) | Backend (AOTAutograd+Inductor) | +========================+=======================+================================+ | no decorator | trace inside | trace inside | +------------------------+-----------------------+--------------------------------+ | allow_in_graph | opaque callable | trace inside | +------------------------+-----------------------+--------------------------------+ | custom op | opaque callable | opaque callable | +------------------------+-----------------------+--------------------------------+ One common use case for :func:`allow_in_graph()` is as an escape hatch for the compiler frontend: if you know the function works w.r.t. to the downstream components of the compilation stack (AOTAutograd and Inductor) but there is a Dynamo bug that prevents it from symbolically introspecting the function properly (or if your code is in C/C++ and therefore cannot be introspected with Dynamo), then one can decorate said function with :func:`allow_in_graph` to bypass Dynamo. We require that ``fn`` adhere to the following restrictions. Failure to adhere results in undefined behavior: - The inputs to ``fn`` must be Proxy-able types in the FX graph. Valid types include: Tensor/int/bool/float/None/List[Tensor?]/List[int?]/List[float?] Tuple[Tensor?, ...]/Tuple[int?, ...]/Tuple[float?, ...]/torch.dtype/torch.device - The outputs to ``fn`` must be Proxy-able types in the FX graph (see previous bullet) - all Tensors used inside of ``fn`` must be passed directly as inputs to ``fn`` (as opposed to being captured variables). Args: fn: A callable representing the function to be included in the graph. If ``fn`` is a list or tuple of callables it recursively applies :func:`allow_in_graph()` to each function and returns a new list or tuple containing the modified functions. Example:: torch.compiler.allow_in_graph(my_custom_function) @torch.compile(...) def fn(a): x = torch.add(x, 1) x = my_custom_function(x) x = torch.add(x, 1) return x fn(...) Will capture a single graph containing ``my_custom_function()``. """ import torch._dynamo return torch._dynamo.allow_in_graph(fn)
[docs]def substitute_in_graph( original_fn: _F, *, can_constant_fold_through: bool = False, skip_signature_check: bool = False, ) -> Callable[[_F], _F]: """ Register a polyfill handler for a function, usually a C function from the C extension, to be used in place of the original function when inlining the original function in the graph. .. note:: The polyfill handler is only used when inlining the original function. It is not used when the original function is called directly. In the eager mode, the decorated function calls the performant C function rather than the polyfill handler. The polyfill handler is a function that will be called in place of the original function when inlining the original function. The polyfill handler should have the same signature and the same behavior as the original function. Args: original_fn (callable): The original function, usually a C function, to register a polyfill handler for. can_constant_fold_through (bool, optional): Whether the polyfill handler can be constant folded through. That is, if the polyfill handler is a pure function and its arguments are constant, the result of the polyfill handler can be constant folded during the compilation. Defaults to ``False``. skip_signature_check (bool, optional): Whether to skip the signature check between the original function and the polyfill handler. Defaults to ``False``. Returns: A decorator that registers the polyfill handler for the original function. Example:: >>> import operator >>> operator.indexOf([1, 2, 3, 4, 5], 3) 2 >>> torch.compile(operator.indexOf, fullgraph=True)([1, 2, 3, 4, 5], 3) ... # xdoctest: +SKIP("Long tracebacks") Traceback (most recent call last): ... torch._dynamo.exc.Unsupported: ... >>> @torch.compiler.substitute_in_graph(operator.indexOf) ... def indexOf(a, b, /): ... for i, item in enumerate(a): ... if item is b or item == b: ... return i ... raise ValueError("sequence.index(x): x not in sequence") >>> >>> torch.compile(operator.indexOf, fullgraph=True)([1, 2, 3, 4, 5], 3) 2 """ import torch._dynamo return torch._dynamo.substitute_in_graph( original_fn, can_constant_fold_through=can_constant_fold_through, skip_signature_check=skip_signature_check, )
[docs]def list_backends(exclude_tags=("debug", "experimental")) -> List[str]: """ Return valid strings that can be passed to `torch.compile(..., backend="name")`. Args: exclude_tags(optional): A tuple of strings representing tags to exclude. """ import torch._dynamo return torch._dynamo.list_backends(exclude_tags)
[docs]def assume_constant_result(fn): """ This function is used to mark a function `fn` as having a constant result. This allows the compiler to optimize away your function Returns The same function `fn` Args: fn: The function to be marked as having a constant result. .. warning:: `assume_constant_result` can if invalid cause safety and soundness issues, :func:`torch.compile` will not attempt to validate whether the constant assumption is true or not """ import torch._dynamo return torch._dynamo.assume_constant_result(fn)
[docs]def disable(fn=None, recursive=True): """ This function provides both a decorator and a context manager to disable compilation on a function It also provides the option of recursively disabling called functions Args: fn (optional): The function to disable recursive (optional): A boolean value indicating whether the disabling should be recursive. """ import torch._dynamo return torch._dynamo.disable(fn, recursive)
[docs]def cudagraph_mark_step_begin(): """ Indicates that a new iteration of inference or training is about to begin. CUDA Graphs will free tensors of a prior iteration. A new iteration is started on each invocation of torch.compile, so long as there is not a pending backward that has not been called. If that heuristic is wrong, such as in the following example, manually mark it with this api. .. code-block:: python @torch.compile(mode="reduce-overhead") def rand_foo(): return torch.rand([4], device="cuda") for _ in range(5): torch.compiler.cudagraph_mark_step_begin() rand_foo() + rand_foo() For more details, see `torch.compiler_cudagraph_trees <https://pytorch.org/docs/main/torch.compiler_cudagraph_trees.html>`__ """ from torch._inductor import cudagraph_trees cudagraph_trees.mark_step_begin()
def wrap_numpy(fn): r"""Decorator that turns a function from ``np.ndarray``s to ``np.ndarray``s into a function from ``torch.Tensor``s to ``torch.Tensor``s. It is designed to be used with :func:`torch.compile` with ``fullgraph=True``. It allows to compile a NumPy function as if it were a PyTorch function. This allows you to run NumPy code on CUDA or compute its gradients. .. note:: This decorator does not work without :func:`torch.compile`. Example:: >>> # xdoctest: +REQUIRES(env:TORCH_DOCTEST_CUDA) >>> # Compile a NumPy function as a Tensor -> Tensor function >>> @torch.compile(fullgraph=True) >>> @torch.compiler.wrap_numpy >>> def fn(a: np.ndarray): >>> return np.sum(a * a) >>> # Execute the NumPy function using Tensors on CUDA and compute the gradients >>> x = torch.arange(6, dtype=torch.float32, device="cuda", requires_grad=True) >>> out = fn(x) >>> out.backward() >>> print(x.grad) tensor([ 0., 2., 4., 6., 8., 10.], device='cuda:0') """ from torch._dynamo.external_utils import wrap_numpy as wrap return wrap(fn) _is_compiling_flag: bool = False
[docs]def is_compiling() -> bool: """ Indicates whether a graph is executed/traced as part of torch.compile() or torch.export(). Note that there are 2 other related flags that should deprecated eventually: * torch._dynamo.external_utils.is_compiling() * torch._utils.is_compiling() Example:: >>> def forward(self, x): >>> if not torch.compiler.is_compiling(): >>> pass # ...logic that is not needed in a compiled/traced graph... >>> >>> # ...rest of the function... """ if torch.jit.is_scripting(): return False else: return _is_compiling_flag
[docs]def is_dynamo_compiling() -> bool: """ Indicates whether a graph is traced via TorchDynamo. It's stricter than is_compiling() flag, as it would only be set to True when TorchDynamo is used. Example:: >>> def forward(self, x): >>> if not torch.compiler.is_dynamo_compiling(): >>> pass # ...logic that is not needed in a TorchDynamo-traced graph... >>> >>> # ...rest of the function... """ return False

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