644 lines
29 KiB
Python
644 lines
29 KiB
Python
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from collections import defaultdict
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from typing import Dict, List, Optional, Sequence, Tuple, Union
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import torchgen.api.dispatcher as dispatcher
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from torchgen.api.translate import translate
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from torchgen.api.types import Binding, DispatcherSignature, Expr
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from torchgen.context import with_native_function
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from torchgen.model import (
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Annotation,
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Argument,
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BackendIndex,
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BackendMetadata,
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BaseOperatorName,
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BaseTy,
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BaseType,
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DEFAULT_KERNEL_NAMESPACE,
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DeviceCheckType,
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DispatchKey,
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FunctionSchema,
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NativeFunction,
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NativeFunctionsGroup,
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OperatorName,
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Return,
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SchemaKind,
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Variant,
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)
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from torchgen.utils import concatMap
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# See Note: [Out ops with functional variants that don't get grouped properly]
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OUT_OPS_THAT_DONT_GET_GROUPED_PROPERLY = [
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# This has a functional variant, but it's currently marked private.
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# This function should be marked private as well (*_backward ops aren't exposed to python anyway).
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"adaptive_avg_pool3d_backward.grad_input",
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# There's a functional variant, _slow_conv2d_backward.output_mask, that isn't grouped properly.
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# Maybe we can kill this operator in favor of convolution_backward?
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"_slow_conv2d_backward.grad_input",
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]
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# See Note: [Mutable ops that cannot get an out variant]
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MUTABLE_OPS_THAT_CANNOT_GET_AN_OUT_VARIANT = [
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# should be out=?
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"_cummax_helper",
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# should be out=?
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"_cummin_helper",
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]
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# All of these operators don't have any tensor like returns
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FUNCTIONAL_OPS_THAT_CANNOT_GET_AN_OUT_VARIANT = [
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"_assert_async", # no return
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"_assert_async.msg", # no return
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"_cslt_sparse_mm_search", # returns an int
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"_assert_scalar", # no return
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"_dimI", # returns an int
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"_dimV", # returns an int
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"_has_same_storage_numel", # returns a boolean
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"_linalg_check_errors", # no return
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"_local_scalar_dense", # returns a Scalar
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"_nested_tensor_from_mask_left_aligned", # returns a boolean
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"_nnz", # returns an int
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"_use_cudnn_ctc_loss", # returns a boolean
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"_use_cudnn_ctc_loss.Tensor", # returns a boolean
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"_validate_compressed_sparse_indices", # no return
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"allclose", # returns a boolean
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"dense_dim", # returns an int
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"equal", # returns a boolean
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"is_coalesced", # returns an boolean
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"is_pinned", # returns a boolean
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"is_same_size", # returns a boolean
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"is_set_to", # returns a boolean
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"q_per_channel_axis", # returns an int
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"q_scale", # returns a float
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"q_zero_point", # returns an int
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"qscheme", # returns a QScheme
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"record_stream", # no return
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"sparse_dim", # returns an int
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"sym_constrain_range", # no return
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"sym_constrain_range_for_size", # no return
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"_nested_tensor_storage_offsets", # returns a vector of ints
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"_chunk_grad_outputs_efficient_attention", # returns a bool
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"_fused_sdp_choice", # returns an int
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"_print", # no return
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"_nested_get_ragged_idx", # returns an int
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]
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INPLACE_OPS_THAT_DONT_GET_GROUPED_PROPERLY = [
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# polygamma and polygamma.out both exist, but have a
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# pre-self arg (while polygamma_ does not)
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# We should either fix this schema so it can be grouped properly,
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# or allow the codegen to generate new functional/out= NativeFunctions for this op
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# (which would require changing its overload name to prevent overload ambiguity).
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"polygamma_"
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]
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# Groups "similar" NativeFunctions together
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# example add.Tensor, add_.Tensor, add.out
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# "similar" NativeFunctions are all expected to have an identical `signature()`,
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# But have differing SchemaKinds.
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def pre_group_native_functions(
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native_functions: Sequence[NativeFunction],
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) -> Dict[FunctionSchema, Dict[SchemaKind, NativeFunction]]:
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pre_grouped_native_functions: Dict[
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FunctionSchema, Dict[SchemaKind, NativeFunction]
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] = defaultdict(dict)
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for f in native_functions:
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d = pre_grouped_native_functions[f.func.signature()]
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assert f.func.kind() not in d
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d[f.func.kind()] = f
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return pre_grouped_native_functions
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# Returns the out variant overload name given a base function overload name
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def get_expected_out_variant_overload_name(overload_name: Optional[str]) -> str:
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return "out" if not overload_name else f"{overload_name}_out"
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# Helper function: given an inplace FunctionSchema, generate its corresponding out= variant
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# Example before:
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# _add_relu_.Scalar(Tensor(a!) self, Scalar other, Scalar alpha=1) -> Tensor(a!)
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# Example after:
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# _add_relu.Scalar_out(Tensor self, Scalar other, Scalar alpha=1, *, Tensor(a!) out)
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def self_to_out_signature(func: FunctionSchema) -> FunctionSchema:
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# Generating an out= schema from an inplace schema.
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assert func.kind() == SchemaKind.inplace
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assert func.arguments.self_arg is not None
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# The new out= schema has:
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# - a new out argument with the same type as "func" (but with a mutable annotation)
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# - The returns (if any) now alias the out= argument instead of "func"
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# - an "out" overload name
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return FunctionSchema(
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name=func.name.remove_inplace().with_overload(
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get_expected_out_variant_overload_name(func.name.overload_name)
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),
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arguments=func.arguments.remove_self_annotation().with_out_args(
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[
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Argument(
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name="out",
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type=func.arguments.self_arg.argument.type,
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default=None,
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annotation=func.arguments.self_arg.argument.annotation,
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)
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]
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),
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returns=func.returns,
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)
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# Helper function: given a functional FunctionSchema, generate its corresponding out= variant
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# Example before:
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# _to_copy(Tensor self, *, ScalarType? dtype=None, Layout? layout=None, Device? device=None,
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# bool? pin_memory=None, bool non_blocking=False, MemoryFormat? memory_format=None) -> Tensor
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# Example after:
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# _to_copy._out(Tensor self, *, bool non_blocking=False, MemoryFormat? memory_format=None,
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# Tensor(a!) out) -> Tensor(a!)
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def functional_to_out_signature(func: FunctionSchema) -> FunctionSchema:
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# Generating an out= schema from a functional schema.
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assert func.kind() == SchemaKind.functional
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new_returns, new_out_args = generate_out_args_from_schema(func)
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# The new out= schema has:
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# - one or more new out argument(s) with the same type as returns (but with a mutable annotation)
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# - The returns now alias the out= arguments
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# - an "_out" overload name
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return FunctionSchema(
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name=func.name.with_overload(
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get_expected_out_variant_overload_name(func.name.overload_name)
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),
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arguments=func.arguments.signature().with_out_args(
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new_out_args,
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),
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returns=tuple(new_returns),
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)
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# Helper function: given a function schema, generate corresponding out arguments, also the updated return annotations.
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def generate_out_args_from_schema(
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func: FunctionSchema,
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) -> Tuple[List[Return], List[Argument]]:
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# More of a sanity check - our existing restrictions on schemas should enforce that
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# mutable schema kinds never return their mutable arguments.
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assert not any(
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r.annotation is not None and r.annotation.is_write for r in func.returns
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)
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tensorlike_rets = [r for r in func.returns if r.type.is_tensor_like()]
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assert len(tensorlike_rets) > 0
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used_annotations = concatMap(
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lambda a: [] if a.annotation is None else a.annotation.alias_set,
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func.arguments.flat_all,
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)
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valid_annotations = [
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x for x in "abcdefghijklmnopqrstuvwxyz" if x not in used_annotations
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]
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all_rets_are_tensors = all(r.type == BaseType(BaseTy.Tensor) for r in func.returns)
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new_out_args: List[Argument] = []
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# The end result of new_returns is that:
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# - If every return is a plain tensor, then the new returns == the old returns, but with the out= alias annotations added.
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# - Otherwise, none of the out arguments show up in the returns (and we're only left with non-tensor-like returns, if any).
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new_returns: List[Return] = []
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for i, r in enumerate(func.returns):
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if r.type.is_tensor_like():
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new_out = Argument(
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name="out" if len(func.returns) == 1 else f"out{i}",
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type=r.type,
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default=None,
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annotation=Annotation.parse(f"{valid_annotations[i]}!"),
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)
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new_out_args.append(new_out)
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if all_rets_are_tensors:
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# The convention for out= schemas is that they only return their out arguments
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# if the return is a plain Tensor (or if it's a tuple of plain Tensors)
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new_ret = Return(
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name=None, type=new_out.type, annotation=new_out.annotation
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)
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new_returns.append(new_ret)
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else:
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new_returns.append(r)
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return new_returns, new_out_args
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# Helper function: given a mutable FunctionSchema, generate its corresponding out= variant
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# Example before:
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# _fused_moving_avg_obs_fq_helper(Tensor self, Tensor observer_on, Tensor fake_quant_on, Tensor(a!) running_min, Tensor(b!) running_max, Tensor(c!) scale, Tensor(d!) zero_point, float averaging_const, int quant_min, int quant_max, int ch_axis, bool per_row_fake_quant=False, bool symmetric_quant=False) -> (Tensor output, Tensor mask) # noqa: B950
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# Example after:
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# _fused_moving_avg_obs_fq_helper._out(Tensor self, Tensor observer_on, Tensor fake_quant_on, Tensor(a!) running_min, Tensor(b!) running_max, Tensor(c!) scale, Tensor(d!) zero_point, float averaging_const, int quant_min, int quant_max, int ch_axis, bool per_row_fake_quant=False, bool symmetric_quant=False, *, Tensor(e!) out0, Tensor(f!) out1) -> (Tensor(e!), Tensor(f!)) # noqa: B950
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def mutable_to_out_signature(func: FunctionSchema) -> FunctionSchema:
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# Generating an out= schema from a mutable schema.
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assert func.kind() == SchemaKind.mutable
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# The new out= schema has:
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# - Any non-aliased tensor-like returns are converted to mutable, aliased out= arguments
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# (if the argument is a tensor then we also return it for method chaining,
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# otherwise we return nothing)
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# - an "out" overload name
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#
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# Note that:
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# (1) This also means that we can *only* generate an out= variant from a mutable schema
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# if the mutable schema has at least one tensor-like non-aliasing return.
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# (2) The generated out= variant still has mutable positional arguments,
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# but if necessary we could probably add another out= variant that also
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# functionalizes the mutable arguments (a functional_out variant)
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new_returns, new_out_args = generate_out_args_from_schema(func)
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return FunctionSchema(
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name=func.name.remove_inplace().with_overload(
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get_expected_out_variant_overload_name(func.name.overload_name)
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),
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arguments=func.arguments.with_out_args(new_out_args),
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returns=tuple(new_returns),
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)
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# This function, given function of one SchemaKind, as well as a target SchemaKind,
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# generates a new NativeFunction with the same properties, but using the target SchemaKind.
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# We only actually generate functions for either functional or out= SchemaKinds.
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# This function returns a tuple, with:
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# - The generated NativeFunction
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# - a dictionary of `BackendIndex` objects, describing which dispatch keys
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# we will generate kernels for, for the new NativeFunction.
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# Details are in the function, but we only generate composite kernels (in some cases) today.
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def generate_function(
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f: NativeFunction, k: SchemaKind
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) -> Tuple[NativeFunction, Dict[DispatchKey, Dict["OperatorName", "BackendMetadata"]]]:
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from torchgen.api import cpp
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if k == SchemaKind.functional:
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assert f.func.kind() != SchemaKind.functional
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# The new "functional" NativeFunction has:
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# - any mutable arguments have been converted into (immutable) returns.
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# (if a mutable argument was not also a return, it gets converted to one)
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# - "_functional" appended to the base name, ONLY IF this op has a mutable variant.
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# See Note [Overload Ambiguity With Functional Variants]
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# The default grouping logic in signature() actually already does this,
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# so we can piggy-back off it (but we still want return names)
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func = f.func.signature(keep_return_names=True).with_name(
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OperatorName(
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name=BaseOperatorName(
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base=f.func.name.name.base,
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inplace=False,
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dunder_method=f.func.name.name.dunder_method,
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# See Note [Overload Ambiguity With Functional Variants]
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functional_overload=f.func.kind() == SchemaKind.mutable,
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),
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overload_name=f.func.name.overload_name,
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)
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)
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elif k == SchemaKind.out:
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# We generate out= ops mostly just so that we can pair up NativeFunctions into groups easily,
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# but at least today, there is no good reason to actually use them.
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# we'll generate a dispatcher entry for them, but won't actually register any kernels for them.
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if f.func.kind() == SchemaKind.inplace:
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func = self_to_out_signature(f.func)
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elif f.func.kind() == SchemaKind.mutable:
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func = mutable_to_out_signature(f.func)
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elif f.func.kind() == SchemaKind.functional:
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func = functional_to_out_signature(f.func)
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else:
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raise AssertionError(
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"We only bother generating out= functions from either inplace or mutable or functional variants"
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)
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else:
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raise AssertionError(
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"We currently only generate either functional or out= NativeFunctions"
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)
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# Generated kernel naming convention for out: <op_name>_<overload_name>. The reason for this is to
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# disambiguate operator with the same name but different overload name, e.g., `randn.names_out` and
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# `randn.generator_with_names_out`.
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kernel_name = (
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func.name.unambiguous_name()
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if func.kind() == SchemaKind.out
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else cpp.name(func)
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)
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if f.func.has_symint():
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kernel_name += "_symint"
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backend_metadata = {
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DispatchKey.CompositeExplicitAutograd: {
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func.name: BackendMetadata(
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kernel=kernel_name,
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structured=False,
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cpp_namespace=DEFAULT_KERNEL_NAMESPACE,
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)
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}
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}
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tags = {"generated"} | set(
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f.tags & {"nondeterministic_seeded", "view_copy", "pt2_compliant_tag"}
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)
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return (
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NativeFunction(
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func=func,
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use_const_ref_for_mutable_tensors=f.use_const_ref_for_mutable_tensors,
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# These generated fn's aren't meant to be user friendly- don't generate methods.
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variants={Variant.function},
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structured=False,
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structured_delegate=None,
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structured_inherits=None,
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precomputed=None,
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autogen=[],
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ufunc_inner_loop={},
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manual_kernel_registration=False,
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manual_cpp_binding=False,
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python_module=None,
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category_override=None,
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device_guard=False,
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device_check=DeviceCheckType.NoCheck,
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loc=f.loc,
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cpp_no_default_args=set(),
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is_abstract=f.is_abstract,
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has_composite_implicit_autograd_kernel=False,
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has_composite_implicit_autograd_nested_tensor_kernel=False,
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has_composite_explicit_autograd_kernel=True,
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has_composite_explicit_autograd_non_functional_kernel=False,
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# Every generated NativeFunction gets a "generated" tag, so it's easy to tell
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# which NativeFunction objects did not come directly from native_functions.yaml.
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tags=tags,
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namespace=f.namespace,
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),
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backend_metadata,
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)
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# This function is responsible for adding generated NativeFunctions which don't appear
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# explicitly in the codegen.
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# You can inspect the full list of NativeFunctions yourself with the torchgen package, by running
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# torchgen.parse_native_yaml("aten/src/ATen/native/native_functions.yaml", "aten/src/ATen/native/tags.yaml")
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# (Maybe we should make a friendly API for this)
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#
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# Note: this function *mutates* its two inputs,
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# adding the new NativeFunctions / BackendMetadata to them
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def add_generated_native_functions(
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rs: List[NativeFunction],
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indices: Dict[DispatchKey, Dict[OperatorName, BackendMetadata]],
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) -> None:
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# The main code for generating new NativeFunctions
|
||
|
# First we group of NativeFunctions by schema kind,
|
||
|
# then we detect which ones are missing and generate them.
|
||
|
pre_grouped_native_functions = pre_group_native_functions(rs)
|
||
|
for d in pre_grouped_native_functions.values():
|
||
|
has_functional = SchemaKind.functional in d
|
||
|
has_inplace = SchemaKind.inplace in d
|
||
|
has_mutable = SchemaKind.mutable in d
|
||
|
has_out = SchemaKind.out in d
|
||
|
|
||
|
# We automatically generate a few native functions that don't exist in the yaml, for a few reasons:
|
||
|
# (1) If an operator has an inplace/out= variant but no functional variant, we can generate
|
||
|
# a simple functional variant that the functionalization pass can consume.
|
||
|
# (2) If an operator has an inplace or functional but no out= variant, we generate an out=
|
||
|
# variant, mostly so we can easily pair up functions into NativeFunctionsGroup,
|
||
|
# while maintaining the constraint that the out= variant is "required".
|
||
|
if has_mutable or has_inplace or has_out or has_functional:
|
||
|
# Don't bother generating functions trio's for native functions that bypass the dispatcher.
|
||
|
are_manual = all(f.manual_cpp_binding for f in d.values())
|
||
|
# Don't bother generating functional + out= variants for view operators
|
||
|
# set_ is technically an inplace_view, but for now it is treated
|
||
|
# as a normal inplace op in the codegen
|
||
|
has_view_ops = any(
|
||
|
f.is_view_op and str(f.func.name.name) != "set_" for f in d.values()
|
||
|
)
|
||
|
# Don't generate the other variants for CompositeImplicitAutograd operators.
|
||
|
# We could probably do this, but the main benefit of generating the function triplets
|
||
|
# is for transforms that need them, and transforms don't need to act directly
|
||
|
# on CompositeImplicitAutograd operators (since we let them decompose).
|
||
|
are_composite_implicit = all(
|
||
|
f.has_composite_implicit_autograd_kernel for f in d.values()
|
||
|
)
|
||
|
if are_manual or has_view_ops or are_composite_implicit:
|
||
|
continue
|
||
|
if has_out and len(d.values()) == 1:
|
||
|
# Note: [Out ops with functional variants that don't get grouped properly]
|
||
|
# In theory we could validly have an out= operator in native_functions.yaml
|
||
|
# that has no other variants.
|
||
|
# But today, all of the operators where that's the case actually do have
|
||
|
# functional variants, that we are just unable to pair up properly.
|
||
|
# I think banning this all together is probably safer
|
||
|
# (you can always add a functional variant yourself if you want to add a new out= operator).
|
||
|
#
|
||
|
# We should probably fix the existing cases; this check is to prevent us from adding more over time.
|
||
|
if (
|
||
|
str(d[SchemaKind.out].func.name)
|
||
|
not in OUT_OPS_THAT_DONT_GET_GROUPED_PROPERLY
|
||
|
):
|
||
|
raise AssertionError(
|
||
|
f"Found an out= operator that we could not find any other variants of: {str(d[SchemaKind.out].func)}"
|
||
|
)
|
||
|
continue
|
||
|
|
||
|
# Some inplace ops that have problematic schemas (that we should fix), which prevent us
|
||
|
# from generating out= and functional variants
|
||
|
if (
|
||
|
has_inplace
|
||
|
and str(d[SchemaKind.inplace].func.name)
|
||
|
in INPLACE_OPS_THAT_DONT_GET_GROUPED_PROPERLY
|
||
|
):
|
||
|
continue
|
||
|
|
||
|
base_fn = (
|
||
|
d[SchemaKind.inplace]
|
||
|
if has_inplace
|
||
|
else d[SchemaKind.mutable]
|
||
|
if has_mutable
|
||
|
else d[SchemaKind.out]
|
||
|
if has_out
|
||
|
else d[SchemaKind.functional]
|
||
|
)
|
||
|
|
||
|
# Note: [Mutable ops that cannot get an out variant]
|
||
|
# We can only generate an out= variant if either:
|
||
|
# - the original function has tensor-like returns (since we can convert them to out kwargs)
|
||
|
# - or it's inplace (since we can convert `self` to an out kwarg)
|
||
|
# There are only two functions that don't fit this criteria today though,
|
||
|
# and they both look like they should be fixed to be out= variants,
|
||
|
# so if feels safer to ban this schema all-together
|
||
|
base_fn_valid = base_fn.func.kind() == SchemaKind.inplace or any(
|
||
|
r.type.is_tensor_like() for r in base_fn.func.returns
|
||
|
)
|
||
|
# Note: [Loosen the assertion that all functional should have out variant]
|
||
|
# By design all functional operators should have our variants. The needs_out check
|
||
|
# is loosening this requirement, changing it to only generate out variant if there's
|
||
|
# an `autogen` block in the native function, in the long run it should be removed.
|
||
|
# FIXME: Remove this after figuring out CI job failures related to min, max, mean
|
||
|
needs_out = any("out" in str(op_name) for op_name in base_fn.autogen)
|
||
|
gets_out_variant = not has_out and base_fn_valid and needs_out
|
||
|
if not has_out and not base_fn_valid:
|
||
|
if (
|
||
|
str(base_fn.func.name)
|
||
|
not in MUTABLE_OPS_THAT_CANNOT_GET_AN_OUT_VARIANT
|
||
|
and str(base_fn.func.name)
|
||
|
not in FUNCTIONAL_OPS_THAT_CANNOT_GET_AN_OUT_VARIANT
|
||
|
):
|
||
|
raise AssertionError(
|
||
|
f"""Found an operator that we could not generate an out= variant for: {str(base_fn.func)}.
|
||
|
This type of operators don't have tensor-like return, making it difficult to generate a proper out= variant. If
|
||
|
out= variant is not needed, please add the function name into FUNCTIONAL_OPS_THAT_CANNOT_GET_AN_OUT_VARIANT list."""
|
||
|
)
|
||
|
|
||
|
# Generate an out= variant
|
||
|
if gets_out_variant:
|
||
|
fn, metadata = generate_function(base_fn, SchemaKind.out)
|
||
|
d[SchemaKind.out] = fn
|
||
|
BackendIndex.grow_index(indices, metadata)
|
||
|
rs.append(fn)
|
||
|
|
||
|
# Generate a functional variant, but only do it if the operator got an out= variant
|
||
|
# (Functional variants are only useful if we can group up the variants,
|
||
|
# which we can only do if they have an out= variant)
|
||
|
if not has_functional and (has_out or gets_out_variant):
|
||
|
fn, metadata = generate_function(base_fn, SchemaKind.functional)
|
||
|
d[SchemaKind.functional] = fn
|
||
|
BackendIndex.grow_index(indices, metadata)
|
||
|
rs.append(fn)
|
||
|
|
||
|
|
||
|
def return_str(rets: Tuple[Return, ...], names: List[str]) -> str:
|
||
|
assert len(rets) == len(names)
|
||
|
if len(rets) == 0:
|
||
|
return ""
|
||
|
elif len(rets) == 1:
|
||
|
return f"return {names[0]};"
|
||
|
else:
|
||
|
return f"return {dispatcher.returns_type(rets).cpp_type()}({', '.join(names)});"
|
||
|
|
||
|
|
||
|
# Given a function, and the name of a variable corresponding to the output of that function,
|
||
|
# gather up all of the individual returns that are not aliased
|
||
|
def gather_nonaliased_inner_rets(func: FunctionSchema, out_var: str) -> List[str]:
|
||
|
aliased_rets = func.aliased_return_names()
|
||
|
non_aliased_names = []
|
||
|
is_out_var_a_tuple = len(func.returns) > 1
|
||
|
for i, r in enumerate(aliased_rets):
|
||
|
if r is None:
|
||
|
non_aliased_names.append(
|
||
|
f"std::get<{i}>({out_var})" if is_out_var_a_tuple else out_var
|
||
|
)
|
||
|
return non_aliased_names
|
||
|
|
||
|
|
||
|
# Generates functional kernels in terms of their inplace.mutable counterparts.
|
||
|
# We only do this for "generated" NativeFunctions
|
||
|
@with_native_function
|
||
|
def gen_composite_functional_kernel(g: NativeFunctionsGroup) -> Optional[str]:
|
||
|
# We should only be generating these for code-generated NativeFunctions
|
||
|
if "generated" not in g.functional.tags:
|
||
|
return None
|
||
|
# And we always write the kernel for a generated op in terms of a non-generated op.
|
||
|
if g.inplace is not None and "generated" not in g.inplace.tags:
|
||
|
target_f = g.inplace
|
||
|
elif g.mutable is not None and "generated" not in g.mutable.tags:
|
||
|
target_f = g.mutable
|
||
|
else:
|
||
|
# We should be guaranteed to have a valid inplace/mutable variant to call into.
|
||
|
# See Note: [Mutable Ops Not Using Functionalization]
|
||
|
raise AssertionError(str(g.functional.func))
|
||
|
|
||
|
sig = DispatcherSignature(g.functional.func)
|
||
|
target_sig = DispatcherSignature(target_f.func)
|
||
|
|
||
|
context: List[Union[Binding, Expr]] = []
|
||
|
clone_mutable_inputs = []
|
||
|
cloned_return_names = []
|
||
|
# We can't just directly pass all of the arguments from the functional op into the mutating op.
|
||
|
# We need to check for which inputs to the mutating operator are mutable,
|
||
|
# and clone those inputs first.
|
||
|
for a_curr, a_tgt in zip(
|
||
|
dispatcher.jit_arguments(g.functional.func),
|
||
|
dispatcher.jit_arguments(target_f.func),
|
||
|
):
|
||
|
if a_tgt.annotation is not None and a_tgt.annotation.is_write:
|
||
|
clone_mutable_inputs.append(
|
||
|
f"auto {a_curr.name}_clone = clone_arg({a_curr.name});"
|
||
|
)
|
||
|
context.append(
|
||
|
Expr(
|
||
|
expr=f"{a_curr.name}_clone",
|
||
|
type=dispatcher.argument_type(a_curr, binds=a_curr.name),
|
||
|
)
|
||
|
)
|
||
|
# Invariant: mutable arguments on the inner mutable op are always returns on the functional op.
|
||
|
cloned_return_names.append(f"{a_curr.name}_clone")
|
||
|
else:
|
||
|
context.append(dispatcher.argument(a_curr))
|
||
|
exprs = ", ".join([e.expr for e in translate(context, target_sig.arguments())])
|
||
|
|
||
|
out_name = "output"
|
||
|
maybe_assign = f"auto {out_name} = " if len(target_f.func.returns) > 0 else ""
|
||
|
inner_return_names = gather_nonaliased_inner_rets(target_f.func, out_name)
|
||
|
ret_str = return_str(
|
||
|
g.functional.func.returns, inner_return_names + cloned_return_names
|
||
|
)
|
||
|
|
||
|
clone_mutable_inputs_str = "\n".join(clone_mutable_inputs)
|
||
|
return f"""
|
||
|
{sig.defn(name=sig.name() + ("_symint" if g.out.func.has_symint() else ""))} {{
|
||
|
{clone_mutable_inputs_str}
|
||
|
{maybe_assign}at::_ops::{target_f.func.name.unambiguous_name()}::call({exprs});
|
||
|
{ret_str}
|
||
|
}}
|
||
|
"""
|
||
|
|
||
|
|
||
|
# Generates out= kernels in terms of their functional counterparts.
|
||
|
# We only do this for "generated" NativeFunctions
|
||
|
@with_native_function
|
||
|
def gen_composite_out_kernel(g: NativeFunctionsGroup) -> Optional[str]:
|
||
|
# We should only be generating these for code-generated NativeFunctions
|
||
|
if "generated" not in g.out.tags:
|
||
|
return None
|
||
|
# And we always write the kernel for the out= op in terms of the functional.
|
||
|
# Note that the functional op might have also been generated, but we don't have to
|
||
|
# worry about cycles, because the generated functional kernels are always implemented
|
||
|
# in terms of non-generated kernels (see gen_composite_functional_kernel).
|
||
|
|
||
|
sig = DispatcherSignature(g.out.func)
|
||
|
target_sig = DispatcherSignature(g.functional.func)
|
||
|
|
||
|
exprs = ", ".join(
|
||
|
[e.expr for e in translate(sig.arguments(), target_sig.arguments())]
|
||
|
)
|
||
|
|
||
|
copy_outs = []
|
||
|
out_name = "tmp_output"
|
||
|
for i, out_arg in enumerate(g.out.func.arguments.out):
|
||
|
functional_return_name = (
|
||
|
out_name
|
||
|
if len(g.functional.func.returns) == 1
|
||
|
else f"std::get<{i}>({out_name})"
|
||
|
)
|
||
|
copy_outs.append(
|
||
|
f"""\
|
||
|
resize_out_helper({out_arg.name}, {functional_return_name});
|
||
|
copy_arg({out_arg.name}, {functional_return_name});"""
|
||
|
)
|
||
|
|
||
|
rets = []
|
||
|
# For each return arg in the calling (out=) operator,
|
||
|
# If it corresponds to an aliased input, return the input.
|
||
|
# Otherwise, return the corresponding output from calling the functional operator.
|
||
|
for i, ret_name in enumerate(g.out.func.aliased_return_names()):
|
||
|
if ret_name is not None:
|
||
|
rets.append(ret_name)
|
||
|
else:
|
||
|
functional_return_name = (
|
||
|
out_name
|
||
|
if len(g.functional.func.returns) == 1
|
||
|
else f"std::get<{i}>({out_name})"
|
||
|
)
|
||
|
rets.append(functional_return_name)
|
||
|
|
||
|
copy_outs_str = "\n".join(copy_outs)
|
||
|
|
||
|
# Kernel name needs to follow the naming convention defined in `generate_function()`
|
||
|
return f"""
|
||
|
{sig.defn(name=g.out.func.name.unambiguous_name() + ("_symint" if g.out.func.has_symint() else ""))} {{
|
||
|
auto {out_name} = at::_ops::{g.functional.func.name.unambiguous_name()}::call({exprs});
|
||
|
{copy_outs_str}
|
||
|
{return_str(g.out.func.returns, rets)}
|
||
|
}}
|
||
|
"""
|