ai-content-maker/.venv/Lib/site-packages/torchgen/api/python.py

1510 lines
57 KiB
Python

from dataclasses import dataclass
from typing import Dict, List, Optional, Sequence, Set, Tuple, Union
from torchgen.api import cpp
from torchgen.api.types import Binding, CppSignature, CppSignatureGroup
from torchgen.gen import pythonify_default
from torchgen.model import (
Argument,
BaseTy,
BaseType,
FunctionSchema,
ListType,
NativeFunction,
OptionalType,
Return,
Type,
Variant,
)
# ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ #
#
# Data Models
#
# ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ #
#
# [Notes] python binding codegen
#
# The Python binding codegen produces code that takes the input list of
# PyObjects, finds the matching ATen C++ function using PythonArgParser,
# converts the PyObjects into C++ types and calls the ATen C++ function:
#
# +--------+ parsing +------------------------+ binding +-----------------------+
# | PyObjs | ---------> | PythonArgParser Output | ---------> | Cpp Function Dispatch |
# +--------+ +------------------------+ +-----------------------+
#
# The following examples demonstrate the data models the Python binding
# codegen needs to deal with and the tasks it needs to accomplish. It
# helps understand the purpose of the new data types we introduced below.
#
# - Function Schema (source of truth)
#
# aten::empty.names(int[] size, *, Dimname[]? names,
# ScalarType? dtype=None, Layout? layout=None,
# Device? device=None, bool? pin_memory=None,
# MemoryFormat? memory_format=None) -> Tensor
#
# - Python Signature
#
# It's used to generate input schema string for PythonArgParser.
# Note: TensorOptions fields are reordered and the additional
# 'requires_grad' field is added:
#
# empty(IntArrayRef size, *, DimnameList? names,
# MemoryFormat? memory_format=None, ScalarType dtype=None,
# Layout layout=torch.strided, Device device=None,
# bool pin_memory=False, bool requires_grad=False)
#
# - C++ Signature
#
# It's used to generate C++ lambda formals & dispatch call.
# Note: the scattered TensorOptions fields are packed into 'options'.
#
# auto dispatch_empty =
# [](IntArrayRef size, c10::optional<DimnameList> names,
# const TensorOptions & options,
# c10::optional<MemoryFormat> memory_format) -> Tensor {
# pybind11::gil_scoped_release no_gil;
# return torch::empty(size, names, options, memory_format);
# };
#
# - Binding between Python Arguments and C++ Arguments
#
# Given a set of Python Arguments in scope, we need produce the
# binding expressions that translate the Python API into C++ API:
#
# Python Args Cpp Args Binding Exprs
# -----------------------------------------------------------------
# 0: size size '_r.intlist(0)'
# 1: names names 'names' [special init]
# 2: memory_format -------+
# 3: dtype -----+-|--> options 'options' [special packing]
# 4: layout / |
# 5: device / +--> memory_format '_r.memoryformatOptional(2)'
# 6: pin_memory /
# 7: requires_grad -+
#
# So the full dispatch expression would look like:
#
# dispatch_empty(_r.intlist(0), names, options,
# _r.memoryformatOptional(2))
#
# Where does 'names' come from? It involves special local init:
#
# auto __names = _r.toDimnameListOptional(1);
# c10::optional<DimnameList> names =
# __names ? c10::make_optional(DimnameList(__names.value()))
# : c10::nullopt;
#
# Where does 'options' come from? It involves special local init
# for TensorOptions. Note that Python side has the additional
# 'requires_grad' field:
#
# const auto options = TensorOptions()
# .dtype(_r.scalartype(3))
# .device(_r.device(5))
# .layout(_r.layoutOptional(4))
# .requires_grad(_r.toBool(7))
# .pinned_memory(_r.toBool(6));
#
# In some other cases one Python Argument can map to multiple C++
# Arguments. For example:
#
# aten::max.names_dim(Tensor self, Dimname dim, bool keepdim=False)
# -> (Tensor values, Tensor indices)
#
# Python Args Cpp Args Binding Exprs
# ---------------------------------------------------------------------
# +----> max 'out[0]'
# /-----> max_values 'out[1]
# 0: input / self '_r.tensor(0)'
# 1: dim / dim '_r.dimname(1)'
# 2: keepdim / keepdim '_r.toBool(2)'
# 3: out -----+ [local init] out '_r.tensorlist_n<2>(3)'
#
# As demonstrated above, the binding can involve reordering,
# packing, unpacking and special local inits.
#
#
# Let's look at a concrete example:
#
# static PythonArgParser parser({
# "abs(Tensor input, *, Tensor out=None)",
# ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
# ^
# +--- Python Schema, represented by PythonSignature and PythonArgument
#
# }, /*traceable=*/true);
#
# ParsedArgs<2> parsed_args;
# auto _r = parser.parse(nullptr, args, kwargs, parsed_args);
#
# ...
#
# if (_r.isNone(1)) {
# ~~~~~~~~~~~~ <--- Scattered PythonArgParser output (arg name = 'out')
# represented by PythonArgParserOutputExpr
#
# // aten::abs(Tensor self) -> Tensor
# ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
# ^
# +--- NativeFunction schema, base version
#
# auto dispatch_abs = [](const Tensor & self) -> Tensor {
# ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
# ^
# +--- dispatch_lambda_args / dispatch_lambda_return_str
# generated from NativeFunction / CppSignature
# (deprecated PythonSignature is special)
# arguments are represented by DispatchLambdaArgument
#
# pybind11::gil_scoped_release no_gil;
# return self.abs();
# ~~~~~~~~~~~ <--- cpp_dispatch_target / cpp_dispatch_exprs
# generated from NativeFunction / CppSignature
# };
# return wrap(dispatch_abs(_r.tensor(0)));
# ~~~~~~~~~~~~~
# ^
# +--- dispatch_lambda_exprs
# binding PythonArgParserOutputExpr (python args)
# and DispatchLambdaArgument (c++ args)
#
# } else {
# // aten::abs.out(Tensor self, *, Tensor(a!) out) -> Tensor(a!)
# ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
# ^
# +--- NativeFunction schema, out-variant
#
# auto dispatch_abs_out = [](Tensor out, const Tensor & self) -> Tensor {
# pybind11::gil_scoped_release no_gil;
# return at::abs_out(out, self);
# };
# return wrap(dispatch_abs_out(_r.tensor(1), _r.tensor(0)));
# }
#
#
# [Notes] python interface codegen
# The python dataclasses below are used used to generate both python binding code
# and pyi type hint signatures.
# In theory these two should look very similar, but there are number of differences
# in how pyi signatures vs. python_arg_parser signatures are generated.
# These differences have been encapsulated in signature_str() vs. signature_str_pyi()
# to display the full signatures, and argument_str() vs argument_str_pyi() to display arguments.
# For examples, only pyi signatures include return types.
@dataclass(frozen=True)
class PythonReturns:
returns: Tuple[Return, ...]
@dataclass(frozen=True)
class PythonArgument:
name: str
type: Type
default: Optional[str]
# Used to generate the default init expr for some PythonArgParser outputs, e.g.:
#
# _r.layoutWithDefault(3, layout_from_backend(self.options().backend())))
# ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
# ^
# +--- default_init str
default_init: Optional[str]
# Compute argument formal for python argument parsing.
# Needs to be consistent with torch/csrc/utils/python_arg_parser.h.
def argument_str(self, *, method: bool = False, symint: bool = True) -> str:
type_str = (
argument_type_str(self.type, symint=symint)
.replace("const ", "")
.replace(" &", "")
)
name = self.name
# s/self/input/ outside method bindings
# [old codegen] TODO: remove this? doesn't rename in codegen, it's just
# for the parse string
if name == "self" and type_str in ["Tensor", "Number"] and not method:
name = "input"
# add default
if self.default is not None:
default = {
"nullptr": "None",
"c10::nullopt": "None",
"{}": "None",
}.get(self.default, self.default)
return f"{type_str} {name}={default}"
else:
return f"{type_str} {name}"
def argument_str_pyi(
self, *, method: bool = False, deprecated: bool = False
) -> str:
type_str = argument_type_str_pyi(self.type)
name = self.name
# s/self/input/ outside method bindings
# [old codegen] TODO: remove this? doesn't rename in codegen, it's just
# for the parse string
if name == "self" and type_str == "Tensor" and not method and not deprecated:
name = "input"
if name == "from": # from is a Python keyword...
name += "_"
# pyi merges the _out and functional variants into the same signature, with an optional out arg
if name == "out" and type_str == "Tensor" and not deprecated:
type_str = "Optional[" + type_str + "]"
# pyi deprecated signatures don't get defaults for their out arg
treat_as_no_default = (
deprecated
and isinstance(self, PythonOutArgument)
and self.default == "None"
)
# add default
if self.default is not None and not treat_as_no_default:
if (
isinstance(self.type, ListType)
and self.type.elem == BaseType(BaseTy.int)
and self.default.startswith("{")
and self.default.endswith("}")
):
default = "(" + self.default[1:-1] + ")"
else:
default = {
"nullptr": "None",
"c10::nullopt": "None",
"{}": "None",
"MemoryFormat::Contiguous": "contiguous_format",
"QScheme::PER_TENSOR_AFFINE": "per_tensor_affine",
}.get(self.default, self.default)
return f"{name}: {type_str} = {default}"
else:
return f"{name}: {type_str}"
@dataclass(frozen=True)
class PythonOutArgument(PythonArgument):
# In Python signature multiple output fields are packed into one 'out' argument.
# When binding to C++, it's first binded to a local 'out' variable:
# 'auto out = _r.tensorlist_n<2>(2);',
# then binded to scattered C++ output arguments as 'out[0]', 'out[1]', and etc.
# TODO: maybe don't need keep scattered out fields for python signature?
outputs: Tuple[PythonArgument, ...]
@staticmethod
def from_outputs(
outputs: Tuple[PythonArgument, ...]
) -> Optional["PythonOutArgument"]:
if not outputs:
return None
size = len(outputs)
if size == 1:
return PythonOutArgument(
name=outputs[0].name,
type=outputs[0].type,
default="None",
default_init=None,
outputs=outputs,
)
elif size > 1:
if any(not a.type.is_tensor_like() for a in outputs):
raise RuntimeError(f"Unsupported output type: {outputs}")
return PythonOutArgument(
name="out",
# TODO: shouldn't this be OptionalType[ListType[...]], since it defaults to None?
type=ListType(BaseType(BaseTy.Tensor), size),
default="None",
default_init=None,
outputs=outputs,
)
raise AssertionError(r"Unexpected PythonOutArgument size")
@dataclass(frozen=True)
class PythonSignature:
# Base operator name, without inplace/outplace suffix.
name: str
# Positional arguments.
# TODO: create a dedicated SelfArgument type for 'self'?
input_args: Tuple[PythonArgument, ...]
# Keyword arguments excluding the 'out' argument and scattered kwargs belonging
# to TensorOptions (dtype, layout, device, pin_memory, requires_grad, etc).
input_kwargs: Tuple[PythonArgument, ...]
output_args: Optional[PythonOutArgument]
# Return types, which are only used by pyi
returns: PythonReturns
# These are scattered kwargs arguments belonging to TensorOptions.
# When binding to C++, they are packed into a TensorOptions object 'options'.
# It's possible that the C++ signature doesn't take TensorOptions object (e.g.
# for out variant), in which case they will be used as scattered fields without
# being packed into 'options'.
# TODO: maybe create a PythonTensorOptionsArgument?
tensor_options_args: Tuple[PythonArgument, ...]
# method or function signature?
method: bool
@property
def deprecated(self) -> bool:
return False
def arguments(
self, *, skip_outputs: bool = False, skip_tensor_options: bool = False
) -> Tuple[Union[PythonArgument, PythonOutArgument], ...]:
result: List[Union[PythonArgument, PythonOutArgument]] = []
result.extend(self.input_args)
result.extend(self.input_kwargs)
if self.output_args is not None and not skip_outputs:
result.append(self.output_args)
if not skip_tensor_options:
result.extend(self.tensor_options_args)
return tuple(result)
def arguments_count(self) -> int:
return len(self.arguments())
def output_idx(self) -> int:
return len(self.input_args) + len(self.input_kwargs)
# [old codegen] Compute the Python function signature for argument parsing,
# as specified in torch/csrc/utils/python_arg_parser.h. WARNING:
# this is NOT the same type signature as specified by PEP 484
# as understood by mypy; our format was independently developed
# and has some quirks to make it more suitable specifically
# for error parsing.
#
# For a translation to mypy-valid type signatures, see
# signature_str_pyi().
def signature_str(self, *, skip_outputs: bool = False, symint: bool = True) -> str:
args = self.arguments(skip_outputs=skip_outputs)
schema_formals: List[str] = [
a.argument_str(method=self.method, symint=symint) for a in args
]
positional_argc = len(self.input_args)
if len(schema_formals) > positional_argc:
schema_formals.insert(positional_argc, "*")
return f'{self.name}({", ".join(schema_formals)})'
def signature_str_pyi(self, *, skip_outputs: bool = False) -> str:
args = self.arguments(skip_outputs=skip_outputs)
schema_formals: List[str] = [
a.argument_str_pyi(method=self.method) for a in args
]
positional_argc = len(self.input_args)
if len(schema_formals) > positional_argc:
schema_formals.insert(positional_argc, "*")
# only pyi signatures include returns
returns_str = returns_str_pyi(self)
# pyi also includes self (with no typing/defaults) for methods
if self.method:
schema_formals.insert(0, "self")
return f'def {self.name}({", ".join(schema_formals)}) -> {returns_str}: ...'
def signature_str_pyi_vararg(self, *, skip_outputs: bool = False) -> Optional[str]:
# only pyi uses vararg signatures
args = self.arguments(skip_outputs=skip_outputs)
schema_formals: List[str] = [
a.argument_str_pyi(method=self.method) for a in args
]
# vararg only applies to pyi signatures. vararg variants are not generated for all signatures
num_args = self.arguments_count()
num_positionalargs = len(self.input_args)
have_vararg_version = False
if num_args > 0:
vararg_type = args[0].type
if (
isinstance(vararg_type, ListType)
and str(vararg_type.elem) in ["int", "SymInt"]
and num_positionalargs == 1
):
have_vararg_version = True
if not have_vararg_version:
return None
# Below are the major changes in vararg vs. regular pyi signatures
# vararg signatures also omit the asterix
schema_formals[0] = "*" + args[0].name + ": _int"
returns_str = returns_str_pyi(self)
# pyi also includes self (with no typing/defaults) for methods
if self.method:
schema_formals.insert(0, "self")
return f'def {self.name}({", ".join(schema_formals)}) -> {returns_str}: ...'
# The deprecated python signature involves some special logic, so create a
# dedicated data model to store these extra properties.
@dataclass(frozen=True)
class PythonSignatureDeprecated(PythonSignature):
# Schema for the deprecated function
deprecated_schema: FunctionSchema
# The deprecated signature might miss some arguments that the corresponding
# C++ signature expects. We need store the constant default values to pass in.
# For example:
# [deprecate signature]: addmm(Scalar beta, Tensor self, Tensor mat1, Tensor mat2)
# [func schema]: aten::addmm(Tensor self, Tensor mat1, Tensor mat2, *, Scalar beta=1, Scalar alpha=1) -> Tensor
# [func call]: self.addmm(mat1, mat2, beta, 1)
# We store ['self', 'mat1', 'mat2', 'beta', '1'] in this case.
deprecated_args_exprs: Tuple[str, ...]
@property
def deprecated(self) -> bool:
return True
def signature_str(self, *, skip_outputs: bool = False, symint: bool = True) -> str:
return (
PythonSignature.signature_str(
self, skip_outputs=skip_outputs, symint=symint
)
+ "|deprecated"
)
def signature_str_pyi(self, *, skip_outputs: bool = False) -> str:
args = self.arguments(skip_outputs=skip_outputs)
schema_formals: List[str] = [
a.argument_str_pyi(method=self.method, deprecated=True) for a in args
]
positional_argc = len(self.input_args)
if len(schema_formals) > positional_argc:
schema_formals.insert(positional_argc, "*")
returns_str = returns_str_pyi(self)
return f'def {self.name}({", ".join(schema_formals)}) -> {returns_str}: ...'
def signature_str_pyi_vararg(self, *, skip_outputs: bool = False) -> Optional[str]:
# the codegen doesn't include vararg variants for deprecated signatures
return None
# This struct is used to hold the PythonSignature and its corresponding
# NativeFunction BEFORE grouping base and out-variant functions.
# Why not store NativeFunction in PythonSignature or construct PythonSignature
# from NativeFunction? Because they are not 1-1 mapped.
# One native function could have both deprecated and non-deprecated python
# signatures - NativeFunction doesn't contain information to construct the
# deprecated python signature.
# One python signature is used to handle both the base and the out-variant
# function - see 'PythonSignatureGroup'.
@dataclass(frozen=True)
class PythonSignatureNativeFunctionPair:
signature: PythonSignature
function: NativeFunction
# We merge pairs of functions with signatures that are equivalent mod
# output arguments, and use a single entry in the python_arg_parser sig
# list for both (output arguments become optional).
@dataclass(frozen=True)
class PythonSignatureGroup:
# The signature used for Python argument parsing. The outplace signature
# is preferred if exists, because it can be used to parse inputs for both
# the out-place variant and the base version (with output omitted).
signature: PythonSignature
# The regular ATen declaration (e.g. conv2d)
base: NativeFunction
# The out variant (e.g. conv2d_out)
outplace: Optional[NativeFunction]
@classmethod
def from_pairs(
cls,
functional: PythonSignatureNativeFunctionPair,
out: Optional[PythonSignatureNativeFunctionPair],
) -> "PythonSignatureGroup":
if out is None:
return PythonSignatureGroup(
signature=functional.signature,
base=functional.function,
outplace=None,
)
# prefer the signature with optional out=... arguments because it's the
# superset that can be used to parse input for both base and outplace.
signature_kwargs = out.signature.__dict__.copy()
# Out overloads in C++ don't have TensorOptions arguments,
# so take these from the functional variant
signature_kwargs[
"tensor_options_args"
] = functional.signature.tensor_options_args
return PythonSignatureGroup(
signature=type(out.signature)(**signature_kwargs),
base=functional.function,
outplace=out.function,
)
# C++ function dispatch is wrapped in a lambda function. The lambda function
# has almost the same signature as the C++ function, only with some small
# variants - see details below.
# This data model is used to represent arguments of the lambda function
# signature.
@dataclass(frozen=True)
class DispatchLambdaArgument:
name: str
type_str: str
is_out_arg: bool
# To pass PyObjects arguments to C++ function (via the lambda wrapper),
# we need first convert PyObjects into simple C++ objects. This work
# is done by PythonArgParser.
# This data model is used to represent the output of PythonArgParser.
# It has 1-1 mapping with PythonArgument in PythonSignature.
@dataclass(frozen=True)
class PythonArgParserOutputExpr:
# argument name
name: str
# RHS expression to reference PythonArgParser output.
expr: str
# In some special cases we need create different expr, e.g.:
# '_r.isNone(1)' instead of '_r.tensor(1)'.
index: int
# The python argument it maps to.
argument: PythonArgument
@property
def is_none_expr(self) -> str:
return f"_r.isNone({self.index})"
# To pass PythonArgParser output to the lambda wrapper, we need bind
# PythonArgParserOutputExpr to DispatchLambdaArgument.
# They are not always 1-1 mapped, e.g. scattered TensorOptions fields
# need be packed into a TensorOptions object, which is the argument
# that the lambda function wrapper takes.
@dataclass(frozen=True)
class DispatchLambdaArgumentExprs:
# The exprs that provide the binding for lambda arguments, e.g.:
#
# 'self' -> '_r.tensor(0)'
# 'min' -> 'out[0]' / 'min_indices' -> 'out[1]'
# 'options' -> 'options'
#
# It has 1-1 mapping with DispatchLambdaArgument.
exprs: Sequence[str]
# Special local inits, which might introduce new variables that
# the 'exprs' above reference, e.g.:
#
# 'auto out = _r.tensorlist_n<2>(2);'
#
inits: Sequence[str]
# ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ #
#
# Helper Functions
#
# ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ #
def _cpp_signature(f: NativeFunction, *, method: bool = False) -> CppSignature:
return CppSignatureGroup.from_native_function(f, method=method).signature
def has_tensor_options(f: NativeFunction) -> bool:
return f.func.arguments.tensor_options is not None
# ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ #
#
# Python Signature
#
# ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ #
# 'simple_type' was introduced by the old codegen, which is slightly
# different from the python schema type, e.g.: doesn't have '?' suffix
# for optional Tensor/TensorList; doesn't have '[size]' suffix for list type.
def argument_type_str(
t: Type, *, simple_type: bool = False, symint: bool = True
) -> str:
if isinstance(t, BaseType):
if t.name == BaseTy.Tensor:
return "Tensor"
elif t.name == BaseTy.int:
return "int64_t"
elif t.name == BaseTy.float:
return "double"
elif t.name == BaseTy.str:
return "c10::string_view"
elif t.name in [
BaseTy.bool,
BaseTy.QScheme,
BaseTy.Scalar,
BaseTy.ScalarType,
BaseTy.Generator,
BaseTy.Storage,
BaseTy.Layout,
BaseTy.Device,
BaseTy.DeviceIndex,
BaseTy.MemoryFormat,
BaseTy.Dimname,
BaseTy.Stream,
BaseTy.ConstQuantizerPtr,
BaseTy.SymInt,
]:
# These python schema type names line up with their function schema names
return t.name.name
elif isinstance(t, OptionalType):
if str(t.elem) == "Tensor":
# Is it desired to keep '?' for simple_type with new style dispatcher?
return "Tensor?"
elem = argument_type_str(t.elem, simple_type=simple_type, symint=symint)
return f"{elem}?"
elif isinstance(t, ListType):
size = t.size if not simple_type else None
if str(t.elem) == "bool":
assert t.size is not None
return f"::std::array<bool,{t.size}>"
elif str(t.elem) == "int":
return f"IntArrayRef[{size}]" if size is not None else "IntArrayRef"
elif str(t.elem) == "SymInt":
if symint:
return (
f"SymIntArrayRef[{size}]" if size is not None else "SymIntArrayRef"
)
else:
return f"IntArrayRef[{size}]" if size is not None else "IntArrayRef"
elif str(t.elem) == "Tensor":
return f"TensorList[{size}]" if size is not None else "TensorList"
elif str(t.elem) == "Scalar":
return f"ScalarList[{size}]" if size is not None else "ScalarList"
elif str(t.elem) == "Tensor?":
if simple_type:
return "c10::List<c10::optional<Tensor>>"
else:
return "const c10::List<c10::optional<Tensor>> &"
elif str(t.elem) == "Dimname":
return f"DimnameList[{size}]" if size is not None else "DimnameList"
elem = argument_type_str(t.elem, simple_type=simple_type, symint=symint)
return f"ArrayRef<{elem}>"
raise RuntimeError(f"unrecognized type {repr(t)}")
def argument_type_size(t: Type) -> Optional[int]:
l = t.is_list_like()
if l is not None and str(l.elem) != "bool":
return l.size
else:
return None
def argument(a: Argument) -> PythonArgument:
return PythonArgument(
name=a.name,
type=a.type,
# TODO: directly translate a.default to python default
default=str(
pythonify_default(cpp.default_expr(a.default, a.type, symint=False))
)
if a.default is not None
else None,
default_init=None,
)
# Generates a PythonSignature that can be used for either .pyi or PythonArgParser codegen
def signature(
f: NativeFunction, *, method: bool = False, pyi: bool = False
) -> PythonSignature:
return signature_from_schema(
f.func, category_override=f.category_override, method=method, pyi=pyi
)
def signature_from_schema(
func: FunctionSchema,
*,
category_override: Optional[str],
method: bool = False,
pyi: bool = False,
) -> PythonSignature:
args: List[Argument] = []
args.extend(func.arguments.pre_self_positional)
# Skip SelfArgument if this is method.
if not method and func.arguments.self_arg is not None:
args.append(func.arguments.self_arg.argument)
args.extend(func.arguments.post_self_positional)
args.extend(func.arguments.pre_tensor_options_kwarg_only)
# Skip TensorOptionsArguments. Python side TensorOptions
# arguments are created based on different rules - see below.
args.extend(func.arguments.post_tensor_options_kwarg_only)
args.extend(func.arguments.out)
input_arg_set = {a.name for a in func.arguments.flat_positional}
kwarg_only_set = {a.name for a in func.arguments.flat_kwarg_only}
out_arg_set = {a.name for a in func.arguments.out}
input_args = tuple(map(argument, filter(lambda a: a.name in input_arg_set, args)))
input_kwargs = tuple(
map(argument, filter(lambda a: a.name in kwarg_only_set, args))
)
outputs = tuple(map(argument, filter(lambda a: a.name in out_arg_set, args)))
# Reintroduce the scattered fields of TensorOptions for Python.
# Compared to the cpp counterpart, the python arguments have new property
# (default_init) and a new argument 'requires_grad', which require some
# special handlings.
# [old codegen] TODO: because these aren't guaranteed to be 100% faithful
# to the original versions in the yaml, this recreation is a potential
# source of drift between eager and JIT. Pull this logic out to a shared place.
has_tensor_input_arg = any(
a.type.is_tensor_like() for a in func.arguments.flat_non_out
)
if any(a.name == "requires_grad" for a in func.schema_order_arguments()):
raise ValueError(
"argument named requires_grad is reserved, should not explicitly add it in the schema"
)
# [old codegen] this probably won't work if one of the returns is not a tensor,
# but it will produce a compile-time error that is obvious.
has_tensor_return = any(r.type.is_tensor_like() for r in func.returns)
name: str = cpp.name(func)
is_factory_function = category_override == "factory" or (
has_tensor_return and not has_tensor_input_arg
)
is_like_or_new_function = (
category_override in ("new", "like")
or name.startswith("new_")
or name.endswith("_like")
)
is_dummy_function = category_override == "dummy"
tensor_options_args: List[PythonArgument] = []
if (is_factory_function or is_like_or_new_function) and not is_dummy_function:
def topt_default_init(name: str) -> Optional[str]:
topt_args = func.arguments.tensor_options
if topt_args is None:
return None
a = getattr(topt_args, name)
if a.default is None or a.default == "None":
return None
return cpp.default_expr(a.default, a.type, symint=False)
tensor_options_args.append(
PythonArgument(
name="dtype",
type=OptionalType(BaseType(BaseTy.ScalarType)),
default="None",
default_init=(
None if is_like_or_new_function else topt_default_init("dtype")
),
)
)
tensor_options_args.append(
PythonArgument(
name="layout",
type=OptionalType(BaseType(BaseTy.Layout)),
default="None",
default_init=(
None if is_like_or_new_function else topt_default_init("layout")
),
)
)
tensor_options_args.append(
PythonArgument(
name="device",
type=OptionalType(BaseType(BaseTy.Device)),
default="None",
default_init=(
None
if is_like_or_new_function
else (
topt_default_init("device")
or "torch::tensors::get_default_device()"
)
),
)
)
tensor_options_args.append(
PythonArgument(
name="pin_memory",
type=OptionalType(BaseType(BaseTy.bool)),
default="False",
default_init=None,
)
)
tensor_options_args.append(
PythonArgument(
name="requires_grad",
type=OptionalType(BaseType(BaseTy.bool)),
default="False",
default_init=None,
)
)
returns = PythonReturns(returns=func.returns)
return PythonSignature(
name=str(func.name.name),
input_args=input_args,
input_kwargs=input_kwargs,
output_args=PythonOutArgument.from_outputs(outputs),
tensor_options_args=tuple(tensor_options_args),
returns=returns,
method=method,
)
# ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ #
#
# Python Interface
#
# ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ #
def structseq_fieldnames(returns: Tuple[Return, ...]) -> List[str]:
if len(returns) <= 1 or all(r.name is None for r in returns):
return []
else:
if any(r.name is None for r in returns):
# When building on Windows, `PyStructSequence_UnnamedField` could not be
# resolved by the linker for some reason, which cause error in building:
#
# python_nn_functions.cpp.obj : error LNK2001: unresolved external symbol
# PyStructSequence_UnnamedField
#
# Thus, at this point in time, we do not support unnamed
# fields in structseq; you must either name all fields,
# or none of them.
raise ValueError("Unnamed field is not supported by codegen")
return [str(r.name) for r in returns]
def argument_type_str_pyi(t: Type) -> str:
add_optional = False
if isinstance(t, OptionalType):
t = t.elem
add_optional = True
if isinstance(t, BaseType):
if t.name in [BaseTy.int, BaseTy.DeviceIndex]:
ret = "_int"
if t.name == BaseTy.SymInt:
ret = "Union[_int, SymInt]"
elif t.name == BaseTy.float:
ret = "_float"
elif t.name == BaseTy.str:
ret = "str"
elif t.name == BaseTy.Scalar:
ret = "Union[Number, _complex]"
elif t.name == BaseTy.ScalarType:
ret = "_dtype"
elif t.name == BaseTy.bool:
ret = "_bool"
elif t.name == BaseTy.QScheme:
ret = "_qscheme"
elif t.name == BaseTy.Layout:
ret = "_layout"
elif t.name == BaseTy.Device:
ret = "Optional[DeviceLikeType]"
elif t.name == BaseTy.MemoryFormat:
ret = "memory_format"
elif t.name == BaseTy.Dimname:
ret = "Union[str, ellipsis, None]"
elif t.name == BaseTy.Storage:
ret = "Union[Storage, UntypedStorage]"
elif t.name in [BaseTy.Tensor, BaseTy.Generator, BaseTy.Stream]:
# These python schema type names line up with their function schema names
ret = t.name.name
elif isinstance(t, ListType):
if str(t.elem) == "int":
ret = "Union[_int, _size]" if t.size is not None else "_size"
elif t.is_tensor_like():
# TODO: this doesn't seem right...
# Tensor?[] currently translates to Optional[Union[Tuple[Tensor, ...], List[Tensor]]]
# It should probably translate to Union[Tuple[Optional[Tensor], ...], List[Optional[Tensor]]]
if isinstance(t.elem, OptionalType):
add_optional = True
ret = (
"Union[Tensor, Tuple[Tensor, ...], List[Tensor]]"
if t.size is not None
else "Union[Tuple[Tensor, ...], List[Tensor]]"
)
elif str(t.elem) == "float":
ret = "Sequence[_float]"
elif str(t.elem) == "SymInt" and t.size is not None:
elem = argument_type_str_pyi(t.elem)
ret = f"Union[{elem}, Sequence[{elem}]]"
else:
elem = argument_type_str_pyi(t.elem)
ret = f"Sequence[{elem}]"
else:
raise RuntimeError(f"unrecognized type {repr(t)}")
if add_optional:
ret = "Optional[" + ret + "]"
return ret
def return_type_str_pyi(t: Type) -> str:
# Where arguments are open to accepting Union, return types should return
# concrete types
if isinstance(t, OptionalType):
inner = return_type_str_pyi(t.elem)
return f"Optional[{inner}]"
if isinstance(t, BaseType):
if t.name == BaseTy.Device:
return "_device"
elif t.name == BaseTy.Dimname:
ret = "Optional[str]"
else:
return argument_type_str_pyi(t)
if isinstance(t, ListType):
inner = return_type_str_pyi(t.elem)
return f"Tuple[{inner}, ...]"
return argument_type_str_pyi(t)
def returns_structseq_pyi(signature: PythonSignature) -> Optional[Tuple[str, str]]:
python_returns = [return_type_str_pyi(r.type) for r in signature.returns.returns]
structseq_name = signature.name
field_names = structseq_fieldnames(signature.returns.returns)
if field_names:
# These types are structseq objects which act like named NamedTuples, but
# the constructor acts like the constructor of tuple. Using typing.NamedTuple
# does not allow us to override __init__.
field_names_str = ", ".join(repr(name) for name in field_names)
seq_type = f"Tuple[{', '.join(python_returns)}]"
structseq_def_lines = [
f"class {structseq_name}({seq_type}):",
]
for name, typ in zip(field_names, python_returns):
structseq_def_lines.extend(
[
" @property",
f" def {name}(self) -> {typ}: ...",
]
)
structseq_def_lines.extend(
[
f" def __new__(cls, sequence: {seq_type}): ...",
f" n_fields: _int = {len(field_names)}",
f" n_sequeunce_fields: _int = {len(field_names)}",
" n_unnamed_fields: _int = 0",
" def __init_subclass__(cls) -> NoReturn: ... # prohibit subclassing",
"", # add an extra newline
]
)
structseq_def = "\n".join(structseq_def_lines)
# Example:
# structseq_def = (
# "class max(Tuple[Tensor, Tensor]):\n"
# " @property\n"
# " def values(self) -> Tensor: ...\n"
# " @property\n"
# " def indices(self) -> Tensor: ...\n"
# " def __new__(cls, sequence: Tuple[Tensor, Tensor]): ...\n"
# " n_fields: _int = 2",
# " n_sequeunce_fields: _int = 2",
# " n_unnamed_fields: _int = 0",
# " def __init_subclass__(cls) -> NoReturn: ... # prohibit subclassing",
# )
return structseq_name, structseq_def
return None
def returns_str_pyi(signature: PythonSignature) -> str:
field_names = structseq_fieldnames(signature.returns.returns)
if field_names:
return f"torch.return_types.{signature.name}"
python_returns = [return_type_str_pyi(r.type) for r in signature.returns.returns]
if len(python_returns) > 1:
return "Tuple[" + ", ".join(python_returns) + "]"
if len(python_returns) == 1:
return python_returns[0]
return "None"
# ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ #
#
# C++ Function Dispatch
#
# ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ #
# This section provides APIs to generate the code that does C++ function
# dispatch. The C++ function call is wrapped by a lambda function.
# For example:
#
# // aten::selu_(Tensor(a!) self) -> Tensor(a!)
# auto dispatch_selu_ = [](Tensor self) -> Tensor {
# pybind11::gil_scoped_release no_gil;
# return at::selu_(self);
# };
#
# The lambda function's signature follows the C++ signature in common
# cases, e.g.:
#
# // aten::add.Tensor(Tensor self, Tensor other, *, Scalar alpha=1) -> Tensor
# [](const Tensor & self, const Tensor & other, Scalar alpha) -> Tensor
#
# For out variant the 'out' argument's type is changed from 'Tensor &'
# to 'Tensor'. It's because when calling the lambda it passes in the
# PythonArgParser output '_r.tensor(3)', which is stack allocated object
# and needs to pass by value. Also see comments in 'dispatch_lambda_return_str()'.
#
# // aten::add.out(Tensor self, Tensor other, *, Scalar alpha=1, Tensor(a!) out) -> Tensor(a!)
# [](Tensor out, const Tensor & self, const Tensor & other, Scalar alpha) -> Tensor
#
# For multi-output case it can keep using reference type because the
# PythonArgParser output has been unpacked to local variables, e.g.:
#
# // aten::max.names_dim_max(Tensor self, Dimname dim, bool keepdim=False, *,
# // Tensor(a!) max, Tensor(b!) max_values) -> (Tensor(a!) values, Tensor(b!) indices)
# [](Tensor & max, Tensor & max_values, const Tensor & self, Dimname dim, bool keepdim) -> std::tuple<Tensor,Tensor>
#
# For deprecated python signature, it should follow deprecated python arg order.
# TODO: This is to keep same byte-for-byte result as the old codegen - maybe unnecessary?
def dispatch_lambda_args(
ps: PythonSignature, f: NativeFunction, symint: bool = True
) -> Tuple[DispatchLambdaArgument, ...]:
if isinstance(ps, PythonSignatureDeprecated):
schema = ps.deprecated_schema
else:
schema = f.func
# Start with cpp arguments - dispatch lambda signature always include 'self'
cpp_args = cpp.arguments(
arguments=schema.arguments,
faithful=False,
symint=symint,
method=False,
cpp_no_default_args=f.cpp_no_default_args,
)
out_args: Set[str] = {a.name for a in schema.arguments.out}
# Convert from cpp argument to lambda argument
def dispatch_lambda_arg(cpp_arg: Binding) -> DispatchLambdaArgument:
type_str = cpp_arg.type
is_out_arg = cpp_arg.name in out_args
if ps.method and cpp_arg.name == "self":
# For method's 'self', we can use 'const Tensor &' and simply ignore mutability!
type_str = "const at::Tensor &"
else:
# For other cases we need prevent dangling refs to temps (unless it's
# unpacked scattered output)
# The reason is explained in the comments above and in 'dispatch_lambda_return_str()'.
# TODO: avoid this special handling?
ensure_temp_safe = len(out_args) <= 1 or not is_out_arg
if ensure_temp_safe:
type_str = {
"at::Tensor &": "at::Tensor",
}.get(type_str, type_str)
return DispatchLambdaArgument(
name=cpp_arg.name,
type_str=type_str,
is_out_arg=is_out_arg,
)
return tuple(map(dispatch_lambda_arg, cpp_args))
# [old codegen] XXX: if you got here because of an assertion failure, it doesn't mean
# it's enough to just extend the list here. Before you do this, make sure
# to add an appropriate wrap() overload in torch/csrc/autograd/utils/wrap_outputs.h.
SUPPORTED_RETURN_TYPES = {
"at::Tensor",
"::std::tuple<at::Tensor,at::Tensor>",
"::std::tuple<at::Tensor,at::Tensor,at::Tensor>",
"::std::tuple<at::Tensor,at::Tensor,at::Tensor,at::Tensor>",
"::std::tuple<at::Tensor,at::Tensor,at::Tensor,at::Tensor,at::Tensor>",
"::std::tuple<at::Tensor,at::Tensor,at::Tensor,at::Tensor,at::Tensor,at::Tensor>",
"::std::tuple<at::Tensor,at::Tensor,at::Tensor,int64_t>",
"::std::tuple<at::Tensor,at::Tensor,double,int64_t>",
"::std::tuple<at::Tensor,at::Tensor,at::Tensor,at::Tensor,int64_t>",
"::std::tuple<at::Tensor,at::Tensor,double,at::Tensor,int64_t>",
"::std::tuple<double,int64_t>",
"::std::tuple<at::Tensor,::std::vector<at::Tensor>>",
"::std::vector<at::Tensor>",
# Needed for flash attention forw/backward
"::std::tuple<at::Tensor,at::Tensor,at::Tensor,at::Tensor,c10::SymInt,c10::SymInt,at::Tensor,at::Tensor,at::Tensor>",
"at::Scalar",
"bool",
"int64_t",
"void*",
"void",
"at::QScheme",
"double",
"at::IntArrayRef",
"at::ScalarType",
"at::Stream",
}
def dispatch_lambda_return_str(f: NativeFunction) -> str:
# [old codegen] Remove type annotation (e.g. 'Tensor' rather than 'Tensor &')
# because the dispatch lambdas take mutable arguments *by value*, not
# by reference. If you then return a reference to such an argument, you
# will now have a pointer to a dangling stack entry. Not good.
#
# You want:
#
# auto dispatch_selu_ = [](Tensor self) -> Tensor { ...; return at::selu_(self); };
# ^^^^^^
#
# *not*
#
# auto dispatch_selu_ = [](Tensor self) -> Tensor& { ...; return at::selu_(self); };
# ^^^^^^^
#
# (NB: We can't make dispatch_selu_ take Tensor&, because the enclosing
# codegen looks like dispatch_selu_(_r.tensor(0)), and you can't take a
# mutable reference to temporary. Maybe we could assign it to a
# variable itself.)
returns_without_annotation = tuple(
Return(r.name, r.type, None) for r in f.func.returns
)
return_str = cpp.returns_type(returns_without_annotation, symint=True).cpp_type()
if return_str not in SUPPORTED_RETURN_TYPES:
raise RuntimeError(f"{f.func.name} returns unsupported type {return_str}")
return return_str
def cpp_dispatch_target(f: NativeFunction) -> str:
symint = f.func.has_symint()
name = cpp.name(f.func, symint_overload=symint)
if Variant.method in f.variants:
return f"self.{name}"
if Variant.function in f.variants:
if has_tensor_options(f) or f.func.name.name.base.endswith("_like"):
namespace = "torch"
else:
namespace = "at"
return f"{namespace}::{name}"
raise RuntimeError(f"could not dispatch, neither function nor method: {f.func}")
def cpp_dispatch_exprs(
f: NativeFunction,
*,
python_signature: Optional[PythonSignature] = None,
) -> Tuple[str, ...]:
cpp_args: Sequence[Binding] = _cpp_signature(f, method=False).arguments()
exprs: Tuple[str, ...] = tuple()
if not isinstance(python_signature, PythonSignatureDeprecated):
# By default the exprs are consistent with the C++ signature.
exprs = tuple(a.name for a in cpp_args)
else:
# For deprecated python signature we may need fill in some constants.
exprs = tuple(
filter(
lambda n: n != "out" or f.func.is_out_fn(),
python_signature.deprecated_args_exprs,
)
)
if Variant.method in f.variants:
exprs = tuple(filter("self".__ne__, exprs))
return exprs
# ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ #
#
# Python / C++ Args Binding
#
# ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ #
# We explicitly enumerate the PythonArgParser unpacking methods for all
# supported types. This might be more verbose than necessary, partially
# because of the irregularity of unpacking method naming, partially
# because we want to mimic the old codegen behavior - to reject
# unexpected and/or unsupported cases which the old codegen rejects.
# For certain cases it is intentionally more restrictive than necessary,
# e.g.: it doesn't accepts doublelist with definite size.
def arg_parser_unpack_method(
t: Type, default: Optional[str], default_init: Optional[str], *, symint: bool = True
) -> str:
has_default_init = default_init is not None
if has_default_init and str(t) not in (
"ScalarType?",
"ScalarType",
"Device",
"Device?",
"Layout",
"Layout?",
"bool",
"bool?",
):
raise RuntimeError(f"type '{t}' does not supported unpacking with default")
if isinstance(t, BaseType):
if t.name in [
BaseTy.Tensor,
BaseTy.Stream,
BaseTy.Storage,
BaseTy.Scalar,
BaseTy.Dimname,
]:
# These unpack methods line up with their schema names
return t.name.name.lower()
elif t.name == BaseTy.ScalarType:
return "scalartypeWithDefault" if has_default_init else "scalartype"
elif t.name == BaseTy.Device:
return "deviceWithDefault" if has_default_init else "device"
elif t.name == BaseTy.DeviceIndex:
return "toInt64"
elif t.name == BaseTy.int:
return "toInt64"
elif t.name == BaseTy.SymInt:
return "toSymInt" if symint else "toInt64"
elif t.name == BaseTy.bool:
return "toBoolWithDefault" if has_default_init else "toBool"
elif t.name == BaseTy.float:
return "toDouble"
elif t.name == BaseTy.str:
return "stringView"
elif t.name == BaseTy.Layout:
return "layoutWithDefault" if has_default_init else "layout"
elif t.name == BaseTy.MemoryFormat:
return "memoryformat"
elif isinstance(t, OptionalType):
if str(t.elem) == "Tensor":
return "optionalTensor"
elif str(t.elem) == "Generator":
return "generator"
elif str(t.elem) == "Dimname[]":
return "toDimnameListOptional"
elif not has_default_init and default in (None, "None", "c10::nullopt"):
# If default is None: append 'Optional' to elem's unpacking method
return (
arg_parser_unpack_method(t.elem, None, None, symint=symint) + "Optional"
)
else:
# Otherwise, load as underlying type with default
return arg_parser_unpack_method(
t.elem, default, default_init, symint=symint
)
elif isinstance(t, ListType):
if str(t.elem) == "Tensor":
# accept and use definite size
return f"tensorlist_n<{t.size}>" if t.size is not None else "tensorlist"
elif str(t.elem) == "Tensor?":
return "list_of_optional_tensors"
elif str(t.elem) == "Dimname":
# accept definite size
return "dimnamelist"
elif str(t.elem) == "int":
# accept definite size
return "intlist"
elif str(t.elem) == "float":
return "doublelist"
elif str(t.elem) == "SymInt":
# accept definite size
return "symintlist" if symint else "intlist"
elif str(t.elem) == "Scalar":
return "scalarlist"
raise RuntimeError(f"type '{t}' is not supported by PythonArgParser")
# Return RHS expression for python argument using PythonArgParser output.
# e.g. for arg name 'foo', arg type 'bool', arg_index = 2, returns '_r.toBool(2)'
def arg_parser_output_expr(
arg_index: int, a: PythonArgument, *, symint: bool = True
) -> PythonArgParserOutputExpr:
has_default = a.default_init is not None
unpack_method = arg_parser_unpack_method(
t=a.type, default=a.default, default_init=a.default_init, symint=symint
)
default = f", {a.default_init}" if has_default else ""
expr = f"_r.{unpack_method}({arg_index}{default})"
return PythonArgParserOutputExpr(
name=a.name,
expr=expr,
index=arg_index,
argument=a,
)
# Returns a map with key = arg_name and value = PythonArgParserOutputExpr.
def arg_parser_output_exprs(
ps: PythonSignature, f: NativeFunction, *, symint: bool = True
) -> Dict[str, PythonArgParserOutputExpr]:
return {
e.name: e
for i, a in enumerate(ps.arguments())
for e in (arg_parser_output_expr(i, a, symint=symint),)
}
# argument name to type for scattered tensor options fields
TENSOR_OPTIONS_FIELDS = {
"dtype": "ScalarType?",
"device": "Device?",
"layout": "Layout?",
"pin_memory": "bool?",
"requires_grad": "bool?",
}
# bind arg parser outputs (python args) with dispatch lambda arguments (c++ args).
def dispatch_lambda_exprs(
ps: PythonSignature, f: NativeFunction, *, symint: bool = True
) -> DispatchLambdaArgumentExprs:
# This method is to bind 'arg_parser_outputs' and 'lambda_args' by producing
# 'inits' and 'lambda_args_exprs' for each lambda argument using arg parser
# outputs.
arg_parser_outputs = arg_parser_output_exprs(ps, f, symint=symint)
lambda_args = dispatch_lambda_args(ps, f, symint=symint)
inits: List[str] = []
lambda_args_exprs: Dict[str, str] = {}
has_toptions = has_tensor_options(f)
# 1. special inits/unpacking to provide binding exprs for lambda arguments.
for a in ps.arguments(skip_tensor_options=True):
name = a.name
arg_parser_expr = arg_parser_outputs[a.name].expr
if has_toptions and name == "self":
# TODO: why this needs to be special case?
inits.extend(
[
f"auto self = {arg_parser_expr};",
]
)
lambda_args_exprs[name] = name
elif (
isinstance(a, PythonOutArgument)
and len(a.outputs) > 1
and f.func.is_out_fn()
):
inits.extend(
[
f"auto out = {arg_parser_expr};",
]
)
for i, out_arg in enumerate(a.outputs):
lambda_args_exprs[out_arg.name] = f"out[{i}]"
elif str(a.type) == "Dimname[]?":
# [old codegen]
# TODO: make this part of something more general, or get rid of it.
# optional<ArrayRef<T>> are special. The PythonArgParser returns an
# optional<vector<T>>, which cannot be implicitly converted to
# optional<ArrayRef<T>>. One needs to unwrap the optional and rewrap.
inits.extend(
[
f"auto __{name} = {arg_parser_expr};",
f"c10::optional<DimnameList> {name} = __{name} ? c10::make_optional(DimnameList(__{name}.value())) : c10::nullopt;", # noqa: B950
]
)
lambda_args_exprs[name] = name
else:
# default case - directly using PythonArgParser output expr
lambda_args_exprs[name] = arg_parser_expr
# method's self is passed directly to python binding, rather than parsed
if ps.method:
lambda_args_exprs["self"] = "self"
# 2. special packing/checking for TensorOptions.
tensor_options_args_names = [a.name for a in ps.tensor_options_args]
if has_toptions:
if f.func.is_out_fn():
raise RuntimeError(f"{f.func}: tensor options with output arg")
for a in ps.tensor_options_args:
if a.name not in TENSOR_OPTIONS_FIELDS:
raise RuntimeError(
f"{f.func}: unrecognized tensor options field '{a.name}' in python binding arguments"
)
if str(a.type) != TENSOR_OPTIONS_FIELDS.get(a.name):
raise RuntimeError(
f"{f.func}: unrecognized type '{str(a.type)}' for tensor options field '{a.name}'"
)
if not all(
a in tensor_options_args_names for a in TENSOR_OPTIONS_FIELDS.keys()
):
raise RuntimeError(
f"{f.func}: incomplete tensor options args: {tensor_options_args_names}"
)
inits.append(
f"""\
const auto options = TensorOptions()
.dtype({arg_parser_outputs['dtype'].expr})
.device({arg_parser_outputs['device'].expr})
.layout({arg_parser_outputs['layout'].expr})
.requires_grad({arg_parser_outputs['requires_grad'].expr})
.pinned_memory({arg_parser_outputs['pin_memory'].expr});
torch::utils::maybe_initialize_device(options);
"""
)
lambda_args_exprs["options"] = "options"
# 3. special case - access scattered TensorOptions fields without packing
# TODO: maybe move to the generator side as it's not related to binding.
if not has_toptions and tensor_options_args_names:
if "dtype" in tensor_options_args_names:
# we're an output-arg variant, check these args against output tensor
if not f.func.is_out_fn():
raise RuntimeError(
f"{f.func}: dtype in tensor_options_args without output arg"
)
if not all(a in tensor_options_args_names for a in ("layout", "device")):
raise RuntimeError(
f"{f.func}: incomplete tensor options for output check"
)
inits.append(
f"""\
check_out_type_matches({arg_parser_outputs['out'].expr}, {arg_parser_outputs['dtype'].expr},
{arg_parser_outputs['dtype'].is_none_expr}, {arg_parser_outputs['layout'].expr},
{arg_parser_outputs['device'].expr}, {arg_parser_outputs['device'].is_none_expr});
"""
)
# we'll set requires_grad on outgoing tensor
if "requires_grad" not in tensor_options_args_names:
raise RuntimeError(
f'{f.func}: expected "requires_grad" in tensor_options_args absent, but found [{tensor_options_args_names}]'
)
return DispatchLambdaArgumentExprs(
exprs=tuple(lambda_args_exprs[a.name] for a in lambda_args),
inits=inits,
)