torch-mlir/projects/pt1/python/torch_mlir/torchscript.py

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# Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
# See https://llvm.org/LICENSE.txt for license information.
# SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
# Also available under a BSD-style license. See LICENSE.
from typing import Optional, Sequence, Union, List, Dict, Tuple, Callable, Iterable
from enum import Enum
import sys
from io import StringIO
import tempfile
import os
from torch._functorch.compile_utils import strip_overloads
import torch
import torch.fx
from torch_mlir.dynamo import _get_decomposition_table
from torch.fx.experimental.proxy_tensor import make_fx
from torch_mlir.compiler_utils import (
run_pipeline_with_repro_report,
OutputType,
lower_mlir_module,
)
from torch_mlir.jit_ir_importer import ClassAnnotator, ImportOptions, ModuleBuilder
from torch_mlir.jit_ir_importer.build_tools.library_generator import generate_library
class TensorPlaceholder:
"""A class that represents a formal parameter of a given shape and dtype.
This class can be constructed explicitly from a shape and dtype:
```python
placeholder = TensorPlaceholder([3, 4], torch.float32)
```
This class can also be constructed from a `torch.Tensor` which is already
known to be a valid input to the function. In this case, a set of
dynamic axes are allowed to be specified.
```python
placeholder = TensorPlaceholder.like(torch.ones(3, 4), dynamic_axes=[1])
# Equivalent to `TensorPlaceholder([3, -1], torch.float32)`
```
"""
def __init__(self, shape: List[int], dtype: torch.dtype):
"""Create a tensor with shape `shape` and dtype `dtype`.
Args:
shape: The shape of the tensor. A size of `-1` indicates that the
dimension has an unknown size.
dtype: The dtype of the tensor.
"""
self.shape = shape
self.dtype = dtype
@staticmethod
def like(tensor: torch.Tensor, dynamic_axes: List[int] = None):
"""Create a tensor placeholder that is like the given tensor.
Args:
tensor: The tensor to create a placeholder for.
dynamic_axes: A list of dynamic axes. If specified, the compiled
module will allow those axes to be any size at runtime.
"""
if dynamic_axes is None:
dynamic_axes = []
shape = []
for i, dim in enumerate(tensor.shape):
if i in dynamic_axes:
shape.append(-1)
else:
shape.append(dim)
return TensorPlaceholder(shape, tensor.dtype)
_example_arg = Union[TensorPlaceholder, torch.Tensor]
_example_args_for_one_method = Union[_example_arg, Sequence[_example_arg]]
_example_args = Union[_example_args_for_one_method, "ExampleArgs"]
class ExampleArgs:
"""A class representing the example arguments to an nn.Module.
In general, an nn.Module may have multiple methods that need to be compiled.
This requires example args for each method. This class is a lightweight
wrapper around a dictionary that maps method names to example arguments.
In user-facing API's, this type can always be passed interchangeably with a
single arg or list of args, which normalizes to an ExampleArgs for just
the `forward` method via the `ExampleArgs.get` static method.
"""
def __init__(self):
self._example_args = {}
def add_method(self, method_name: str, example_args: _example_args_for_one_method):
"""Adds example args for a method.
Args:
method_name: The name of the method. Must have not already been
added previously as a method.
example_args: The example args for the method.
Returns:
self, for chaining.
"""
assert method_name not in self._example_args
self._example_args[method_name] = ExampleArgs._canonicalize_args(example_args)
return self
@staticmethod
def get(example_args: _example_args) -> "ExampleArgs":
"""Gets an ExampleArgs from one of the permissible ways to specify one.
Args:
example_args: An ExampleArgs instance or a single arg or list of args.
Returns:
An ExampleArgs instance.
"""
if isinstance(example_args, ExampleArgs):
return example_args
return ExampleArgs().add_method("forward", example_args)
@staticmethod
def _canonicalize_args(example_args: _example_args_for_one_method):
"""Canonicalize the args for one method into a tuple."""
if not isinstance(example_args, Sequence):
example_args = [example_args]
for arg in example_args:
if not isinstance(arg, (TensorPlaceholder, torch.Tensor)):
raise Exception(
f"Only Tensor's, TensorPlaceholder's, or sequences of "
f"Tensor's and TensorPlaceholder's are supported as "
f"example args for method inputs. "
f"Got '{arg}'."
)
return tuple(example_args)
def _get_methods(self):
return self._example_args.keys()
def _get_for_annotation(self):
result = {}
for method_name, example_args in self._example_args.items():
placeholders = []
for arg in example_args:
if isinstance(arg, TensorPlaceholder):
placeholders.append(arg)
else:
assert isinstance(arg, torch.Tensor)
placeholders.append(TensorPlaceholder.like(arg))
result[method_name] = placeholders
return result
def _get_for_tracing(
self,
use_tracing: bool,
ignore_traced_shapes: bool,
) -> Dict[str, Tuple[_example_arg, ...]]:
result = {}
for method_name, example_args in self._example_args.items():
# If we are tracing, then we need to convert any placeholders into
# concrete values.
if use_tracing:
example_args_for_trace = []
for arg in example_args:
if isinstance(arg, TensorPlaceholder):
if not ignore_traced_shapes:
# To avoid accidental footguns, we require
# `ignore_traced_shapes` to be true if we're using
# TensorPlaceholder's, as it falls into the same
# "hopefully the trace works for different inputs"
# bucket of concerns.
raise Exception(
"TensorPlaceholder can only be used with tracing when `ignore_traced_shapes=True`"
)
# For any dynamic dimensions, replace them with "7"
# arbitrarily. If a user is using dynamic dimensions with
# tracing, they are walking on thin ice already -- assume
# they know what they are doing and that their trace is
# correct for any specific concrete size.
shape = [s if s != -1 else 7 for s in arg.shape]
if len(shape) == 0:
example_args_for_trace.append(torch.tensor(1))
else:
example_args_for_trace.append(
torch.ones(*shape, dtype=arg.dtype)
)
else:
assert isinstance(arg, torch.Tensor)
example_args_for_trace.append(arg)
example_args = tuple(example_args_for_trace)
result[method_name] = example_args
return result
# The set of ops that are considered legal for each backend.
# These are currently quite load-bearing, since different backends might be
# missing patterns for decomposed forms of certain ops.
# TODO: Tighten up the definition of these "conditionally legal for backends"
# ops in the backend contract, and move these lists somewhere deeper in the
# compiler where each backend can "own" its set of legal ops.
BACKEND_LEGAL_OPS = {
OutputType.TOSA: [
"aten.flatten.using_ints",
"aten.native_layer_norm",
"aten.linear",
],
OutputType.LINALG_ON_TENSORS: [
"aten.flatten.using_ints",
"aten.adaptive_avg_pool1d",
"aten.adaptive_avg_pool2d",
"aten.unflatten.int",
],
OutputType.STABLEHLO: [
"aten.amax",
"aten.amin",
"aten.randn.generator",
"aten.normal_functional",
],
}
def _canon_extra_library(
extra_library, extra_library_file_name="custom_op_extra_library.mlir"
):
if len(extra_library) != 0:
extra_library_dict = {}
for library_func in extra_library:
extra_library_dict[library_func.__name__] = library_func
mlir_library = generate_library(extra_library_dict)
extra_library_file = os.path.join(
tempfile.gettempdir(), extra_library_file_name
)
with open(extra_library_file, "w") as f:
f.write(mlir_library)
return extra_library_file
else:
return ""
def compile(
model: torch.nn.Module,
example_args: _example_args,
output_type: Union[str, "OutputType"] = OutputType.TORCH,
use_tracing: bool = False,
ignore_traced_shapes=False,
backend_legal_ops: Optional[Sequence[str]] = None,
extra_library: Iterable[Callable] = [],
verbose: bool = False,
use_make_fx: bool = False,
enable_ir_printing: bool = False,
):
"""Convert a PyTorch model to MLIR.
Args:
model: The PyTorch model to convert.
example_args: A list of example arguments to use when inferring the
shapes of the arguments to `forward` method of the model.
A single tensor is treated as a list of a single tensor.
A TensorPlaceholder object is also allowed in the place of any
Tensor. For models with multiple methods, an `ExampleArgs` object
can be passed.
output_type: The kind of output to produce. See `OutputType` for more
details.
use_tracing: If True, use `torch.jit.trace` to convert the model to
JIT IR rather than `torch.jit.script`.
ignore_traced_shapes: If True, ignore the shapes that were observed
during tracing. This should only be used if one knows that the
original traced program would result in the same trace (modulo
shapes) for all shape combinations implied by any
`TensorPlaceholder`'s used as `example_args`. Also,
strictly-speaking, this option covers dtypes too, but we just say
"shapes" to be succinct.
backend_legal_ops: A list of ops that should be considered legal for
the backend. An op that is considered legal will not be decomposed.
This option is only valid with the `"torch"` output type.
extra_library: List of abstract interpretation functions to splice
into the abstract interpretation library. See
`docs/adding_abstract_interpretation_functions.md` for more info
on the format the functions should have.
verbose: If true, print extra information about the conversion to
stdout.
enable_ir_printing: If true, print the IR before and after each pass to
stderr. This is equivalent to setting MLIR's `-print-ir-after-all`
flag. Note that this can easily generate many gigabytes of text,
so make sure to pipe stderr to a file (for example, run
`python tinymodel.py 2> tinymodel.stderr` on Linux).
Returns:
An MLIR module that contains the converted model in the specified
output type.
"""
extra_library_file_name = _canon_extra_library(extra_library)
output_type = OutputType.get(output_type)
example_args = ExampleArgs.get(example_args)
if ignore_traced_shapes and not use_tracing:
raise Exception("`ignore_traced_shapes` requires `use_tracing`")
# We only allow `backend_legal_ops` to be specified for the `"torch"`
# output type because the other output types actually invoke their
# respective backends (Linalg, TOSA, or STABLEHLO), and those backends have
# very specific requirements about the ops which are legal.
# See `BACKEND_LEGAL_OPS` for more details.
if backend_legal_ops is not None:
if output_type != OutputType.TORCH:
raise Exception(
"`backend_legal_ops` is only valid with the " "`torch` output type"
)
backend_legal_ops = list(sorted(set(backend_legal_ops)))
else:
backend_legal_ops = BACKEND_LEGAL_OPS.get(output_type, [])
if use_make_fx:
args = example_args._get_for_tracing(
use_tracing=True, ignore_traced_shapes=True
)["forward"]
model = make_fx(model, decomposition_table=_get_decomposition_table())(*args)
# For FX-based models, automatically strip overloads.
if isinstance(model, torch.fx.GraphModule):
strip_overloads(model)
# Get the model as JIT IR (TorchScript) for import.
# TODO: Longer-term, we probably need to split `torchscript.compile`.
# There should be an "acquisition" step that does
# tracing/scripting/importing from FX/using torchdynamo.export/etc.
# + any lowering to the backend contract. Then there should be a
# "backend lowering" step that does the actual lowering to each
# backend. This separation should be visible at the Python API level, and
# we can implement a deliberately simplified API like `torchscript.compile`
# on top of those building blocks.
if isinstance(model, torch.jit.ScriptModule):
# If the user already converted the model to JIT IR themselves, just
# do some basic error checking, but take the model as-is.
for method_name in example_args._get_methods():
if not hasattr(model, method_name):
raise Exception(
f"Model does not have exported method '{method_name}', "
f"requested in `example_args`. Consider adding "
f"`@torch.jit.export` to the method definition."
)
scripted = model
elif use_tracing:
scripted = torch.jit.trace_module(
model, example_args._get_for_tracing(use_tracing, ignore_traced_shapes)
)
else:
# Make sure that all the methods that the user requested get scripted.
# By default, PyTorch only scripts the `forward` method and transitive
# callees.
for method_name in example_args._get_methods():
torch.jit.export(getattr(model, method_name).__func__)
scripted = torch.jit.script(model)
class_annotator = ClassAnnotator()
class_annotator.exportNone(scripted._c._type())
for method_name, example_args in example_args._get_for_annotation().items():
class_annotator.exportPath(scripted._c._type(), [method_name])
annotation = [None] # `None` is always the annotation for "self".
for arg in example_args:
annotation.append((arg.shape, arg.dtype, True))
class_annotator.annotateArgs(scripted._c._type(), [method_name], annotation)
mb = ModuleBuilder()
import_options = ImportOptions()
import_options.ignoreExistingTensorShapesAndDtypes = ignore_traced_shapes
try:
original_stderr = sys.stderr
sys.stderr = StringIO()
# Import the TorchScript module to MLIR
mb.import_module(scripted._c, class_annotator, import_options)
except Exception as e:
raise Exception(
f"""
PyTorch TorchScript module -> torch-mlir Object Graph IR import failed with:
### Importer C++ Exception:
{e}
### Importer Diagnostics:
{sys.stderr.getvalue()}
"""
) from None
finally:
sys.stderr = original_stderr
if verbose:
print("\n====================")
print("TorchScript RAW IR")
print(mb.module)
if output_type == OutputType.RAW:
return mb.module
option_string = (
"{backend-legal-ops="
+ ",".join(backend_legal_ops)
+ " extra-library="
+ extra_library_file_name
+ "}"
)
run_pipeline_with_repro_report(
mb.module,
f"builtin.module(torchscript-module-to-torch-backend-pipeline{option_string})",
"Lowering TorchScript IR -> Torch Backend IR",
enable_ir_printing=enable_ir_printing,
)
return lower_mlir_module(verbose, output_type, mb.module)