708 lines
28 KiB
Python
708 lines
28 KiB
Python
import itertools
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from abc import ABC
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from dataclasses import dataclass
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from typing import Any, Dict, List, Optional, Tuple, Union
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import torchgen.api.dispatcher as dispatcher
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from torchgen.api.lazy import (
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getValueT,
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isValueType,
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LazyArgument,
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LazyIrProperties,
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LazyIrSchema,
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tensorListValueT,
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)
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from torchgen.api.translate import translate
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from torchgen.api.types import (
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BaseCType,
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Binding,
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deviceT,
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DispatcherSignature,
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kernel_signature,
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NativeSignature,
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OptionalCType,
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VectorCType,
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)
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from torchgen.context import method_with_native_function
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from torchgen.dest.lazy_ts_lowering import ts_lowering_body
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from torchgen.model import (
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Argument,
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BackendIndex,
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BackendMetadata,
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BaseTy,
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BaseType,
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FunctionSchema,
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ListType,
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NativeFunction,
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NativeFunctionsGroup,
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)
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def node_ctor_arg_rvalue_string(arg: LazyArgument) -> str:
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"""
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Given a LazyArgument,
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generate a c++ string for materializing an rvalue of that arg for passing into
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a lazy Node constructor.
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"""
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# TODO: Matching on CType seems wrong; should be matching on Type
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if isValueType(arg.lazy_type):
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if isinstance(arg.lazy_type, BaseCType):
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if arg.is_wrapped_scalar:
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return f"node_{arg.name}"
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elif arg.lazy_type.type is tensorListValueT:
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return f"lazy_{arg.name}_tensorlist"
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elif arg.is_symint_or_list:
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return f"GetSymIntValue({arg.name})"
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return f"lazy_{arg.name}->GetIrValue()"
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elif isinstance(arg.lazy_type, OptionalCType):
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if arg.is_symint_or_list:
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# TODO: I don't understand when you should put lazy_ in the name
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# or not
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return f"{arg.name} ? c10::make_optional(GetSymIntValue(*{arg.name})) : c10::nullopt"
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elif arg.is_wrapped_scalar:
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return f"node_{arg.name}"
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return (
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f"lazy_{arg.name} ? "
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f"c10::make_optional(lazy_{arg.name}->GetIrValue()) : "
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"c10::nullopt"
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)
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else:
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raise AssertionError(
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f"TODO not sure if there are other valid types to handle here ({arg.lazy_type})"
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)
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else:
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# NB: this is here because right now we aren't treating SymInt[] as a
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# value type; when we do this needs to move above
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# NB: we cannot test arg.lazy_type as we've already specified it is an
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# int64_t and so we cannot distinguish between SymInt and int64_t
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if isinstance(arg.orig_type, ListType) and arg.orig_type.elem == BaseType(
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BaseTy.SymInt
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):
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if arg.symint:
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return f"GetSymIntArrayRefValue({arg.name})"
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else:
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return f"std::vector<int64_t>({arg.name}.begin(), {arg.name}.end())"
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elif isinstance(arg.lazy_type, VectorCType) and isinstance(
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arg.lazy_type.elem, BaseCType
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):
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return f"std::vector<{arg.lazy_type.elem.type}>({arg.name}.begin(), {arg.name}.end())"
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elif (
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isinstance(arg.lazy_type, OptionalCType)
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and isinstance(arg.lazy_type.elem, VectorCType)
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and isinstance(arg.lazy_type.elem.elem, BaseCType)
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):
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return f"torch::lazy::ToOptionalVector<{arg.lazy_type.elem.elem.type}>({arg.name})"
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else:
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return f"{arg.name}"
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def node_ctor_inputs(schema: LazyIrSchema) -> str:
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"""
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Produce a formatted string with the arguments as passed into the constructor of a node class.
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"""
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node_ctor_values = [
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node_ctor_arg_rvalue_string(arg) for arg in schema.filtered_args()
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]
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return ", ".join(node_ctor_values)
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def gen_fallback_code(
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schema: LazyIrSchema,
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sig: Union[DispatcherSignature, NativeSignature],
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overload_name: str,
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) -> str:
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"""
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Generate code that falls back to eager conditioned on a predicate
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"""
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dispatcher_sig = DispatcherSignature.from_schema(schema.func)
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exprs = translate(sig.arguments(), dispatcher_sig.arguments())
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fallback_args = ",\n ".join([a.expr for a in exprs])
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if len(overload_name):
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aten_op_str = f"ATEN_OP2({schema.aten_name}, {overload_name})"
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else:
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aten_op_str = f"ATEN_OP({schema.aten_name})"
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return f"""
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if (force_eager_fallback({aten_symbol(schema)})) {{
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return at::native::call_fallback_fn_symint<<c_eager_fallback, {aten_op_str}>::call(
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{fallback_args}
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);
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}}
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"""
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def aten_symbol(schema: LazyIrSchema) -> str:
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missing_interned_strings = {
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"sigmoid_backward",
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}
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if schema.aten_name in missing_interned_strings:
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return f'c10::Symbol::fromQualString("aten::{schema.aten_name}")'
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if not schema.aten_name.startswith("at::"):
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return f"at::aten::{schema.aten_name}"
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else:
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return schema.aten_name
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# converts all tensor-like arguments to meta tensors. Returns:
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# (1) a string containing all of the logic that does the conversions.
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# (2) a context, to be used by translate(), with all of the relevant bindings.
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def convert_to_meta_tensors(sig: DispatcherSignature) -> Tuple[str, List[Binding]]:
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context: List[Binding] = []
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unwrapped_tensor_args: List[str] = []
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for arg in sig.arguments():
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if isinstance(arg.argument, Argument) and arg.argument.type.is_tensor_like():
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unwrapped_name = f"{arg.name}_meta"
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unwrapped_tensor_args.append(
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f"auto {unwrapped_name} = to_meta({arg.name});"
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)
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context.append(arg.with_name(unwrapped_name))
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else:
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context.append(arg)
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unwrap_tensor_args_str = "\n ".join(unwrapped_tensor_args)
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return unwrap_tensor_args_str, context
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@dataclass(frozen=True)
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class GenLazyIR(ABC):
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backend_index: BackendIndex
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backend_name: str
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node_base: str
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use_lazy_shape: bool
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@method_with_native_function
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def __call__(self, f: Union[NativeFunctionsGroup, NativeFunction]) -> List[str]:
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func = f.functional.func if isinstance(f, NativeFunctionsGroup) else f.func
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metadata = self.backend_index.get_kernel(
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f.functional if isinstance(f, NativeFunctionsGroup) else f
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)
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schema = LazyIrSchema(
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func, symint=metadata is not None and metadata.supports_symint()
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)
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return self.gen(schema)
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# there is no lowering functionality generated unless this IR base class is subclassed and
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# implemented as a backend-specific node
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def lowering_function(self, schema: LazyIrSchema) -> str:
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return ""
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def create_function(self, schema: LazyIrSchema, node_ctor_args: str) -> str:
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return ""
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def can_be_reused_function(self, schema: LazyIrSchema, node_ctor_args: str) -> str:
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return f"""bool CanBeReused({node_ctor_args}) const {{
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return false;
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}}"""
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def node_base_ctor_call(self, schema: LazyIrSchema) -> str:
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value_args = schema.filtered_args(values=True, scalars=False)
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# backends can customize the way the node base class constructor is called,
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# as long as all of its arguments can be generated from information available from the schema
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base_ctor_value_args_list = []
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for arg in value_args:
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if isinstance(arg.lazy_type, (BaseCType, VectorCType)):
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base_ctor_value_args_list.append(f"{arg.name}")
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elif isinstance(arg.lazy_type, OptionalCType):
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base_ctor_value_args_list.append(f"{arg.name}.value_or(kNullValue)")
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else:
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raise AssertionError(
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f"Unsupported type ({arg.lazy_type}) - add support if necessary"
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)
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base_ctor_value_args = ", ".join(base_ctor_value_args_list)
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scalar_args = schema.filtered_args(values=False, scalars=True)
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# Shape construction.
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# Conditionally build shape depending on specified shape property
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if schema.properties.ShapePrecompute:
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shape_ctor_arg = "std::move(shapes),"
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elif schema.properties.ShapeCompute:
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shape_args = [a.name for a in value_args]
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shape_args.extend(a.name for a in scalar_args)
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shape_ctor_arg = f"compute_shape_{schema.name}({', '.join(shape_args)}),"
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elif schema.properties.ShapeCache:
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shape_args = [f"operand({i})" for i in range(len(value_args))]
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shape_args.extend(a.name for a in scalar_args)
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shape_ctor_arg = f"[&](){{ return compute_shape_{schema.name}({', '.join(shape_args)})[0]; }},"
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else:
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shape_ctor_arg = ""
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scalar_hashes = ", ".join(f"{a.name}" for a in scalar_args)
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return f"""{self.node_base}(
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{schema.node_name}::ClassOpKind(),
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OpList{{{base_ctor_value_args}}},
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{shape_ctor_arg}
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/* num_outputs */ {len(schema.returns)},
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torch::lazy::MHash({scalar_hashes}))"""
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def gen(self, schema: LazyIrSchema) -> List[str]:
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opkind = schema.opkind or aten_symbol(schema)
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# for now, we just want one IR class decl and soon after also the method defs
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# and we use the functional version not out/inplace.
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all_args = schema.filtered_args()
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value_args = schema.filtered_args(values=True, scalars=False)
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scalar_args = schema.filtered_args(values=False, scalars=True)
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ctor_args = [f"const {i.lazy_type.cpp_type()}& {i.name}" for i in all_args]
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reuse_ctor_args = ", ".join(ctor_args)
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if self.use_lazy_shape and schema.properties.ShapePrecompute:
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ctor_args.append("std::vector<torch::lazy::Shape>&& shapes")
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node_ctor_args = ", ".join(ctor_args)
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scalar_initializers = ",\n ".join(
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[
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# This code is just special casing the mapping from string_view -> strings
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f"{a.name}({a.name}.has_value() ? c10::make_optional(std::string(*{a.name})) : c10::nullopt)"
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if a.lazy_type.cpp_type() == "c10::optional<c10::string_view>"
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else f"{a.name}({a.name})"
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for a in scalar_args
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]
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)
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if len(scalar_initializers):
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scalar_initializers = f",\n {scalar_initializers}"
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scalar_decls = "\n ".join(
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[
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f"std::string {a.name};"
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if a.lazy_type.cpp_type() == "c10::string_view"
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else f"c10::optional<std::string> {a.name};"
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if a.lazy_type.cpp_type() == "c10::optional<c10::string_view>"
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else f"{a.lazy_type.cpp_type()} {a.name};"
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for a in scalar_args
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]
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)
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optional_values = [
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arg.name
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for arg in schema.filtered_args(values=True, scalars=False)
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if isinstance(arg.lazy_type, OptionalCType)
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]
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has_optional_decls = "\n ".join(
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[f"bool has_{value}: 1;" for value in optional_values]
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)
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has_optional_defs = "\n ".join(
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[f"has_{value} = !!{value};" for value in optional_values]
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)
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members_to_string = []
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for arg in scalar_args:
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if isinstance(arg.lazy_type, OptionalCType):
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value = f"{arg.name}.value()"
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if arg.is_generator:
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value = '"torch.Generator()"'
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members_to_string.append(
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f"""if ({arg.name}.has_value()) {{
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ss << ", {arg.name}=" << {value};
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}} else {{
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ss << ", {arg.name}=null";
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}}"""
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)
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else:
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members_to_string.append(f'ss << ", {arg.name}=" << {arg.name};')
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members_to_string_str = "\n ".join(members_to_string)
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return [
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f"""\
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class {schema.node_name} : public {self.node_base} {{
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public:
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static torch::lazy::OpKind ClassOpKind() {{
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return torch::lazy::OpKind({opkind});
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}}
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{schema.node_name}({node_ctor_args})
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: {self.node_base_ctor_call(schema)}{scalar_initializers}
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{{
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{has_optional_defs}
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}}
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std::string ToString() const override {{
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std::stringstream ss;
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ss << {self.node_base}::ToString();
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{members_to_string_str}
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return ss.str();
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}}
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{self.create_function(schema, reuse_ctor_args)}
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{self.can_be_reused_function(schema, reuse_ctor_args)}
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{self.lowering_function(schema)}
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{scalar_decls}
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{has_optional_decls}
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}};
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""",
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]
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@dataclass(frozen=True)
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class GenTSLazyIR(GenLazyIR):
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def lowering_function(self, schema: LazyIrSchema) -> str:
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signature = """
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torch::lazy::TSOpVector Lower(
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std::shared_ptr<torch::jit::GraphFunction> function,
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torch::lazy::TSLoweringContext* loctx) const override"""
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if schema.properties.LowerDeclOnly:
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return f"{signature};"
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elif schema.properties.Lower:
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return f"""{signature} {{
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{ts_lowering_body(schema)}
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}}
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"""
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else:
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return ""
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def create_function(self, schema: LazyIrSchema, node_ctor_args: str) -> str:
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signature = f"static NodePtr Create({node_ctor_args})"
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if schema.properties.CreateFnDeclOnly:
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return f"{signature};"
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elif not schema.properties.CreateFn:
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return ""
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return f"""{signature} {{
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return ReuseOrMakeNode<{schema.node_name}>(data);
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}}"""
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def can_be_reused_function(self, schema: LazyIrSchema, node_ctor_args: str) -> str:
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signature = f"bool CanBeReused({node_ctor_args}) const"
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if schema.properties.CanBeReusedDeclOnly:
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return f"{signature};"
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elif not schema.properties.CanBeReused:
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return ""
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value_comparison = []
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for arg in itertools.chain(schema.positional_values, schema.keyword_values):
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if isinstance(arg.lazy_type, OptionalCType):
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value_comparison.append(
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f"nullable_operand(i++) == {arg.name}.value_or(kNullValue)"
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)
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else:
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value_comparison.append(f"operand(i++) == {arg.name}")
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for arg in itertools.chain(schema.positional_scalars, schema.keyword_scalars):
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if isinstance(arg.lazy_type, OptionalCType):
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value_comparison.append(
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f"((!this->{arg.name}&&!{arg.name}) || (this->{arg.name}&&{arg.name} && *(this->{arg.name}) == *{arg.name}))"
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)
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else:
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value_comparison.append(f"this->{arg.name} == {arg.name}")
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value_comparison_str = " &&\n ".join(value_comparison)
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return f"""{signature} {{
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size_t i = 0;
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return ({value_comparison_str});
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}}"""
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@dataclass(frozen=True)
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class GenLazyNativeFuncDefinition:
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class_method_name: str
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backend_index: BackendIndex
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tensor_class: str
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gen_forced_fallback_code: bool
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backend_namespace: str
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get_tensorlist: str
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get_tensor_or_wrap_number: str
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try_get_tensor: str
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metrics_counter: str
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create_tensor: str
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create_from_first_tensor: bool
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create_aten_from_ltc_tensor: str
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tuple_aten_from_ltc_tensors: str
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lazy_tensor_ptr: str
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get_device_fn: str
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def lazy_tensor_decls(self, func: NativeFunction, schema: LazyIrSchema) -> str:
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value_args = schema.filtered_args(values=True, scalars=False)
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# Generates lazy_{name} variables for LazyTensors wrapping input tensors
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lazy_tensor_decls: List[str] = []
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for arg in value_args:
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if arg.is_wrapped_scalar:
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if isinstance(arg.lazy_type, OptionalCType):
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lazy_tensor_decls.append(
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f"""auto node_{arg.name} = {arg.name} ?
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c10::make_optional(torch::lazy::LazyGraphExecutor::Get()->
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GetIrValueForScalarFromCodegen(*{arg.name}, *common_device)):
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c10::nullopt;"""
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)
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else:
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lazy_tensor_decls.append(
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f"""auto node_{arg.name} = torch::lazy::LazyGraphExecutor::Get()->
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GetIrValueForScalarFromCodegen({arg.name}, *common_device);"""
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)
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elif arg.is_symint_or_list:
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continue # values are extracted in isValueType
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elif isinstance(arg.lazy_type, BaseCType):
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if arg.lazy_type.type is tensorListValueT:
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lazy_tensor_decls.append(
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f"auto lazy_{arg.name}_tensorlist = "
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f"{self.backend_namespace}::{self.get_tensorlist}({arg.name});"
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)
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else:
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lazy_tensor_decls.append(
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f"{self.lazy_tensor_ptr} lazy_{arg.name} = "
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f"{self.backend_namespace}::{self.get_tensor_or_wrap_number}({arg.name}, *common_device);"
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)
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elif isinstance(arg.lazy_type, OptionalCType):
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assert arg.lazy_type.elem == BaseCType(getValueT()), arg.lazy_type.elem
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# TODO(alanwaketan): Maybe we want to apply GetLtcTensorOrCreateForWrappedNumber here, but hold it
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# until we encounter a real world example.
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lazy_tensor_decls.append(
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f"{self.lazy_tensor_ptr} lazy_{arg.name} = "
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f"{self.backend_namespace}::{self.try_get_tensor}({arg.name}.value_or(at::Tensor()));"
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)
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else:
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raise AssertionError(
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f"TODO not sure if there are other valid types to handle here ({arg.lazy_type})"
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)
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return ("\n ").join(lazy_tensor_decls)
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def force_eager_fallback(
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self,
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func: NativeFunction,
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schema: LazyIrSchema,
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metadata: BackendMetadata,
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sig: Union[DispatcherSignature, NativeSignature],
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) -> str:
|
|
if self.gen_forced_fallback_code:
|
|
return gen_fallback_code(
|
|
schema, sig, overload_name=func.func.name.overload_name
|
|
)
|
|
return ""
|
|
|
|
def metrics(self, func: NativeFunction, schema: LazyIrSchema) -> str:
|
|
return f"{self.metrics_counter};"
|
|
|
|
def get_device(self, func: NativeFunction, schema: LazyIrSchema) -> str:
|
|
value_args = schema.filtered_args(values=True, scalars=False)
|
|
scalar_args = schema.filtered_args(values=False, scalars=True)
|
|
value_types_names = [f"{a.name}" for a in value_args if not a.is_wrapped_scalar]
|
|
optional_device = OptionalCType(BaseCType(deviceT))
|
|
optional_devices = [
|
|
a.name for a in scalar_args if a.lazy_type == optional_device
|
|
]
|
|
assert (
|
|
len(value_types_names) > 0 or len(optional_devices) > 0
|
|
), "Expected at least one Value or Device type"
|
|
get_device_str = (
|
|
f"{self.get_device_fn}({', '.join(value_types_names + optional_devices)})"
|
|
)
|
|
return f"""auto common_device = {get_device_str};
|
|
TORCH_INTERNAL_ASSERT(common_device);
|
|
"""
|
|
|
|
def shape_inference(self, func: NativeFunction, schema: LazyIrSchema) -> str:
|
|
metadata = self.backend_index.get_kernel(func)
|
|
assert metadata is not None
|
|
all_args = schema.filtered_args()
|
|
returns_length = len(schema.returns)
|
|
# call the meta kernel if it exists, to compute output shape/dtype for our IR
|
|
# Note [Generated LTC Shape Functions]
|
|
# LTC uses meta tensors from core to do shape inference when possible, and otherwise
|
|
# we generate a shape function declaration that needs to be manually implemented.
|
|
# How do we detect which ops are eligible to use meta tensors?
|
|
# In general we should be able to use meta tensors not just on structured operators,
|
|
# but also on composite operators that are implemented in terms of structured kernels.
|
|
# We don't currently have a way of knowing at codegen time which ops are implemented that way.
|
|
# This is the case for all view and view_copy operators however, so we're going to
|
|
# use them specifically for all of the view_copy ops (instead of manually writing shape rules for all of them).
|
|
is_view_copy_op = "view_copy" in func.tags
|
|
is_structured = func.structured or func.structured_delegate is not None
|
|
if is_structured or is_view_copy_op:
|
|
meta_out = """
|
|
std::vector<torch::lazy::Shape> shapes{torch::lazy::Shape(out_meta.scalar_type(), out_meta.sizes().vec())};"""
|
|
if returns_length > 1:
|
|
|
|
def this_shape(i: int) -> str:
|
|
return f"torch::lazy::Shape(std::get<{i}>(out_meta).scalar_type(), std::get<{i}>(out_meta).sizes().vec())"
|
|
|
|
shapes_str = ",".join([this_shape(i) for i in range(returns_length)])
|
|
meta_out = "std::vector<torch::lazy::Shape> shapes{" + shapes_str + "};"
|
|
|
|
# Convert tensor args to the meta device and call it.
|
|
# (We can't pass in the input tensors directly, because they are "functional wrappers".
|
|
# If any of the meta kernels call a tensor op and redispatch, we don't want to hit the functionalize kernels.)
|
|
# Even at::meta:: functions might redispatch, e.g. if they call into view ops.
|
|
dispatcher_sig = DispatcherSignature.from_schema(func.func)
|
|
meta_conversion_str, meta_call_ctx = convert_to_meta_tensors(dispatcher_sig)
|
|
meta_call_args = [
|
|
e.expr
|
|
for e in translate(
|
|
meta_call_ctx, dispatcher_sig.arguments(), method=False
|
|
)
|
|
]
|
|
if is_view_copy_op:
|
|
# view_copy ops always have a CompositeExplicitAutogradNonFunctional kernel
|
|
assert func.has_composite_explicit_autograd_non_functional_kernel
|
|
dispatch_ns = "compositeexplicitautogradnonfunctional"
|
|
else:
|
|
dispatch_ns = "meta"
|
|
aten_name = schema.aten_name
|
|
# TODO: this is trolling
|
|
if func.func.has_symint() and metadata.supports_symint():
|
|
aten_name += "_symint"
|
|
shape_str = f"""\
|
|
{meta_conversion_str}
|
|
auto out_meta = at::{dispatch_ns}::{aten_name}({', '.join(meta_call_args)});
|
|
{meta_out}"""
|
|
else:
|
|
shape_sig = ComputeShapeSignature(
|
|
metadata.kernel, func, symint=metadata.supports_symint()
|
|
)
|
|
shape_str = f"""
|
|
auto shapes = {shape_sig.shape_call};"""
|
|
|
|
shape_str += f"""
|
|
TORCH_INTERNAL_ASSERT(shapes.size() == {returns_length});"""
|
|
|
|
# Calculating which dimensions are symbolic
|
|
func_schema_str = "aten::" + str(func.func)
|
|
shape_str += f"""
|
|
if(torch::lazy::symbolicShapeEnabled()){{
|
|
std::vector<torch::jit::IValue> inputs = {{ {', '.join(str(a.name) for a in all_args)} }};
|
|
const char* schema_str = "{func_schema_str}";
|
|
applySymbolicShapesOnLT(schema_str, inputs, shapes);
|
|
}}
|
|
"""
|
|
return shape_str
|
|
|
|
def build_ir_node(self, func: NativeFunction, schema: LazyIrSchema) -> str:
|
|
node_ctor_input_str = node_ctor_inputs(schema)
|
|
return f"""torch::lazy::NodePtr node = torch::lazy::ReuseNode<{schema.node_name}>({node_ctor_input_str});
|
|
if (!node) {{
|
|
{self.shape_inference(func, schema)}
|
|
node = torch::lazy::MakeNode<{schema.node_name}>({node_ctor_input_str}, std::move(shapes));
|
|
CacheNode(node);
|
|
}}
|
|
"""
|
|
|
|
def create_lazy_tensor(self, first_tensor_name: Optional[str] = None) -> str:
|
|
# xla uses an instance method for tensor creation, for the time being
|
|
if self.create_from_first_tensor:
|
|
# TODO(whc) remove this if XLA switches to using static method for creation
|
|
assert (
|
|
first_tensor_name is not None
|
|
), "Requires first tensor to create lazy tensor"
|
|
return f"{first_tensor_name}.{self.create_tensor}"
|
|
return f"{self.backend_namespace}::{self.create_tensor}"
|
|
|
|
def return_aten_tensor(self, func: NativeFunction, schema: LazyIrSchema) -> str:
|
|
returns_length = len(schema.returns)
|
|
value_args = schema.filtered_args(values=True, scalars=False)
|
|
value_types_names = [f"{a.name}" for a in value_args if not a.is_wrapped_scalar]
|
|
first_tensor_name = value_types_names[0] if len(value_types_names) > 0 else None
|
|
bridge_str = f"""auto result = {self.create_aten_from_ltc_tensor}(
|
|
{self.create_lazy_tensor(first_tensor_name)}(std::move(node), *common_device));"""
|
|
|
|
if returns_length > 1:
|
|
assert (
|
|
len(value_types_names) > 0
|
|
), "Code below assumes there is at least one tensor arg"
|
|
bridge_str = f"""std::vector<{self.lazy_tensor_ptr}> lazy_tensors;
|
|
for (int i = 0; i < {returns_length}; i++) {{
|
|
lazy_tensors.push_back({self.create_lazy_tensor(first_tensor_name)}({getValueT()}(node, i), *common_device));
|
|
}}
|
|
auto result = {self.tuple_aten_from_ltc_tensors}<{returns_length}>(lazy_tensors);"""
|
|
|
|
if schema.name.name.inplace or func.func.is_out_fn():
|
|
assert returns_length == 1, (
|
|
"We assumed there was no such case where an op is an in-place variant "
|
|
f"and has tuple outputs, but got tuple of len {returns_length}."
|
|
)
|
|
bridge_str = f"""lazy_{first_tensor_name}->SetInPlaceIrValue(node);
|
|
auto& result = {first_tensor_name};"""
|
|
|
|
bridge_str += """
|
|
return result;"""
|
|
return bridge_str
|
|
|
|
@method_with_native_function
|
|
def __call__(self, func: NativeFunction) -> List[str]:
|
|
sig = kernel_signature(func, self.backend_index)
|
|
metadata = self.backend_index.get_kernel(func)
|
|
assert metadata is not None
|
|
schema = LazyIrSchema(func.func, symint=metadata.supports_symint())
|
|
return [
|
|
f"""\
|
|
{sig.decl(name=f"{self.class_method_name}::{metadata.kernel}")} {{
|
|
{self.force_eager_fallback(func, schema, metadata, sig)}
|
|
{self.metrics(func, schema)}
|
|
{self.get_device(func, schema)}
|
|
{self.lazy_tensor_decls(func, schema)}
|
|
{self.build_ir_node(func, schema)}
|
|
{self.return_aten_tensor(func, schema)}
|
|
}}\n
|
|
"""
|
|
]
|
|
|
|
|
|
class ComputeShapeSignature:
|
|
"""
|
|
Here we use the base name as the suffix of the signature to avoid generating for in-place variants.
|
|
"""
|
|
|
|
def __init__(self, kernel_name: str, f: NativeFunction, *, symint: bool):
|
|
self.__schema = LazyIrSchema(f.func, symint=symint)
|
|
self.__dispatch_args = ", ".join(
|
|
[a.decl() for a in dispatcher.arguments(f.func, symint=symint)]
|
|
)
|
|
self.__call_args = ", ".join(
|
|
[f"{arg.name}" for arg in self.__schema.filtered_args(generator=True)]
|
|
)
|
|
self.__kernel_name = kernel_name
|
|
|
|
def __decl_suffix(self) -> str:
|
|
return f"{self.__kernel_name}({self.__dispatch_args})"
|
|
|
|
def __call_suffix(self) -> str:
|
|
return f"{self.__kernel_name}({self.__call_args})"
|
|
|
|
@property
|
|
def shape_decl(self) -> str:
|
|
return f"TORCH_API std::vector<torch::lazy::Shape> compute_shape_{self.__decl_suffix()}"
|
|
|
|
@property
|
|
def shape_call(self) -> str:
|
|
return f"torch::lazy::compute_shape_{self.__call_suffix()}"
|
|
|
|
|
|
@dataclass(frozen=True)
|
|
class GenLazyShapeInferenceDefinition:
|
|
backend_index: BackendIndex
|
|
tensor_class: str
|
|
|
|
@method_with_native_function
|
|
def __call__(self, f: NativeFunction) -> List[str]:
|
|
sig = kernel_signature(f, self.backend_index)
|
|
metadata = self.backend_index.get_kernel(f)
|
|
assert metadata is not None
|
|
|
|
# See Note [Generated LTC Shape Functions]
|
|
is_view_copy_op = "view_copy" in f.tags
|
|
is_structured = f.structured or f.structured_delegate is not None
|
|
if is_structured or is_view_copy_op:
|
|
return []
|
|
else:
|
|
shape_sig = ComputeShapeSignature(
|
|
metadata.kernel, f, symint=metadata.supports_symint()
|
|
)
|
|
return ["\n".join([f"{shape_sig.shape_decl};"])]
|
|
|
|
|
|
def generate_non_native_lazy_ir_nodes(
|
|
non_native: List[Dict[str, Any]], gen_lazy_ir: GenLazyIR
|
|
) -> List[str]:
|
|
"""Generate the non-native lazy IR node classes"""
|
|
nodes = []
|
|
for op in non_native:
|
|
# Set default properties for Non-Native IRs
|
|
properties = LazyIrProperties("ShapeCache", "CanBeReused", "LowerDeclOnly")
|
|
for p in op.get("properties", []):
|
|
setattr(properties, p, True)
|
|
|
|
# non-native is assumed to want symint bindings if you wrote symint
|
|
schema = LazyIrSchema(FunctionSchema.parse(op["func"]), properties, symint=True)
|
|
schema.opkind = op.get("opkind")
|
|
nodes.append(gen_lazy_ir.gen(schema)[0])
|
|
|
|
return nodes
|