# mypy: allow-untyped-defs from __future__ import annotations import collections import contextlib import dataclasses import dis import functools import inspect import logging import operator import random import re import tempfile from itertools import chain, count from typing import Any, Callable, Optional, TYPE_CHECKING, Union import sympy from sympy import Expr import torch import torch._ops import torch.utils._pytree as pytree from torch import dtype as torch_dtype from torch._dynamo.utils import counters, dynamo_timed from torch._inductor.codegen.debug_utils import DebugPrinterManager from torch._inductor.codegen.multi_kernel import MultiKernelState from torch._inductor.runtime.runtime_utils import cache_dir from torch.fx.experimental.symbolic_shapes import ( CallMethodKey, ConvertIntKey, DivideByKey, resolve_unbacked_bindings, SymTypes, ) from torch.fx.node import _get_qualified_name from torch.utils._ordered_set import OrderedSet from torch.utils._sympy.singleton_int import SingletonInt from torch.utils._sympy.symbol import symbol_is_type, SymT from .. import async_compile, config, ir from ..codecache import output_code_log from ..ir import IRNode, ReinterpretView from ..runtime import triton_heuristics from ..runtime.hints import DeviceProperties from ..utils import ( cache_on_self, DelayReplaceLine, get_benchmark_name, IndentedBuffer, is_codegen_graph_partition_subgraph, LineContext, set_kernel_post_grad_provenance_tracing, sympy_product, sympy_str, sympy_subs, triton_version_uses_attrs_dict, ) from ..virtualized import V from .common import ( ArgName, CodeGen, DeferredLine, PythonPrinter, WorkspaceArg, WorkspaceZeroMode, ) from .cpp_utils import cexpr from .triton_utils import config_of, should_unwrap_unspec_arg, signature_to_meta if TYPE_CHECKING: from collections.abc import Iterator, Sequence import triton from ..graph import GraphLowering from .wrapper_fxir import FxConverter log = logging.getLogger(__name__) pexpr = PythonPrinter().doprint ReuseKey = tuple[torch.device, torch.dtype, str, bool] BufferLike = Union[ir.Buffer, WorkspaceArg] FxConversionFunc = Callable[["WrapperLine"], None] def buffer_reuse_key(node: BufferLike) -> ReuseKey: storage_size = V.graph.get_allocation_storage_size(node) alignment = node.get_name() not in V.graph.unaligned_buffers return ( node.get_device_or_error(), node.get_dtype(), # NB: this is symbolic so that we don't try to reuse a buffer # for s0 for s1, just because they happen to share the same # size hint sympy_str(V.graph.sizevars.simplify(storage_size)), alignment, ) def can_match_buffer_size(input_buf: BufferLike, output_buf: BufferLike): # Return True if input_buf can be re-inplaced for output_buf. # This differs from `buffer_reuse_key` for general buffer reuse. if input_buf.get_device_or_error() != output_buf.get_device_or_error(): return False if input_buf.get_dtype() != output_buf.get_dtype(): return False input_size = V.graph.sizevars.simplify( V.graph.get_allocation_storage_size(input_buf) ) output_size = V.graph.sizevars.simplify( V.graph.get_allocation_storage_size(output_buf) ) if ( # NB: this is symbolic so that we don't try to reuse a buffer # for s0 for s1, just because they happen to share the same # size hint sympy_str(input_size) == sympy_str(output_size) ) or ( # statically known that 0.95 * input_size <= output_size <= input_size V.graph.sizevars.statically_known_geq(output_size, 0.95 * input_size) and V.graph.sizevars.statically_known_leq(output_size, input_size) ): return True return False # TODO: Move to a well known place TritonMetaParams = dict[str, int] TritonGrid = Union[ tuple[Union[int, sympy.Expr], ...], Callable[[TritonMetaParams], tuple[int, ...]] ] def user_defined_kernel_grid_fn_code( name: str, configs: list[triton.Config], # type: ignore[name-defined] grids: list[TritonGrid], wrapper: Optional[PythonWrapperCodegen] = None, original_fxnode_name: Optional[str] = None, ) -> tuple[str, str]: output = IndentedBuffer() def _convert_to_sympy_expr(item: Union[int, sympy.Expr]) -> sympy.Expr: return item if isinstance(item, sympy.Expr) else sympy.Integer(item) def determine_grid( grid: TritonGrid, example_grid: Optional[TritonGrid] = None, ): """ This function return a tuple of two values: the first one is for the real grid which is used in the generated code; the second one is an example grid with concreate values which is used in the autotune block to run the generated kernels at compile time. """ if wrapper is None or callable(grid): # return as-is when used in eager mode or when grid is callable return grid, grid # Grid contains ints/Expr, so utilize wrapper's expr printer for codegen sympy_grid = tuple(_convert_to_sympy_expr(g) for g in grid) if not example_grid: example_grid = sympy_grid return ( wrapper.codegen_python_shape_tuple(sympy_grid), ( wrapper.codegen_python_shape_tuple( tuple( wrapper.generate_example_arg_value(g, type(g)) for g in example_grid # type: ignore[union-attr] ) ) if config.triton.autotune_at_compile_time else None ), ) def writeline(line: str, example_grid: Optional[str] = None): output.writeline(line) if ( wrapper and config.triton.autotune_at_compile_time and name not in wrapper.kernel_autotune_names ): wrapper.kernel_autotune_calls.writeline(example_grid or line) fn_name = f"grid_wrapper_for_{name}" writeline(f"def {fn_name}(meta):") kernel_autotune_calls_indent = ( wrapper.kernel_autotune_calls.indent() if wrapper and config.triton.autotune_at_compile_time else contextlib.nullcontext() ) with output.indent(), kernel_autotune_calls_indent: if ( config.triton.autotune_at_compile_time and original_fxnode_name and V.graph.autotuning_grids and original_fxnode_name in V.graph.autotuning_grids ): example_grids = V.graph.autotuning_grids[original_fxnode_name] else: example_grids = [None] * len(grids) if len(grids) == 1: grid, example_grid = determine_grid(grids[0], example_grids[0]) writeline(f"return {grid}", f"return {example_grid}") else: assert len(grids) > 1 assert len(grids) == len(configs) seen: OrderedSet[str] = OrderedSet() # sort the configs from the largest # of kwargs to the smallest to # emit the grids in the order of (approximately) decreasing specificity # TODO(aakhundov): the sorting below is generally not sufficient, so # maybe we'll need to restrict the supported cases to identical kwarg # names in all autotuning configs. for grid, c, example_grid in sorted( zip(grids, configs, example_grids), key=lambda x: len(x[1].kwargs), reverse=True, ): if c.kwargs: guards = [ f"meta['{name}'] == {val}" for name, val in c.kwargs.items() ] guards = " and ".join(guards) else: guards = "True" # for configs with empty kwargs grid, example_grid = determine_grid(grid, example_grid) statement = f"if {guards}: return {grid}" if statement in seen: continue seen.add(statement) writeline(statement, f"if {guards}: return {example_grid}") return fn_name, output.getvalue() def user_defined_triton_kernel_transitive_closure_source_code(kernel) -> str: """ Given a triton kernel function pointer collect the transitive closure of its dependencies """ compile_wrapper = IndentedBuffer() compile_wrapper.splice(kernel.src, strip=True) # Also include any possible kernel being called indirectly from triton import JITFunction # type: ignore[name-defined, attr-defined] from triton.language import constexpr # type: ignore[name-defined] # global constexpr vars handled above symbols_included = OrderedSet([kernel.__name__]) def traverse(cur_kernel): # here we extract the unqualified names (i.e., not attributes and # without prepended module name) loaded in the kernel code, which # are matched with the co_names and __globals__ below to codegen # the respective imports necessary for the kernel compilation unqualified_loads = OrderedSet( inst.argval for inst in dis.Bytecode(cur_kernel.fn) if inst.opname == "LOAD_GLOBAL" ) global_annotations = cur_kernel.fn.__globals__.get("__annotations__", {}) for symbol_name in cur_kernel.fn.__code__.co_names: if symbol_name in symbols_included: continue if symbol_name in cur_kernel.fn.__globals__: symbol = cur_kernel.fn.__globals__[symbol_name] if isinstance(symbol, JITFunction): compile_wrapper.newline() compile_wrapper.writeline("@triton.jit") compile_wrapper.splice(symbol.src, strip=True) symbols_included.add(symbol_name) traverse(symbol) elif isinstance(symbol, (int, str, bool, constexpr)): compile_wrapper.newline() if isinstance(symbol, constexpr): symbol_str = f"tl.constexpr({symbol.value!r})" else: symbol_str = f"{symbol!r}" if annotation := global_annotations.get(symbol_name): if isinstance(annotation, type): annotation_code = ( f": {annotation.__module__}.{annotation.__name__}" ) else: annotation_code = f": {annotation!r}" compile_wrapper.writeline( f"{symbol_name}{annotation_code} = {symbol_str}" ) else: compile_wrapper.writeline(f"{symbol_name} = {symbol_str}") symbols_included.add(symbol_name) elif ( symbol_name in unqualified_loads and symbol_name != "tl" # already imported and hasattr(symbol, "__module__") # only codegen imports from triton; JITFunctions # imported from other modules will be codegened # in the separate branch above and symbol.__module__.startswith("triton") ): # a global symbol imported from triton is referenced # without module qualification (i.e., `store` instead # of `tl.store`): need to codegen an import compile_wrapper.writeline( f"from {symbol.__module__} import {symbol.__name__} as {symbol_name}" ) symbols_included.add(symbol_name) traverse(kernel) return compile_wrapper.getvalue() @dataclasses.dataclass class SymbolicCallArg: inner: str # the original symbolic expression represented by inner inner_expr: sympy.Expr def __str__(self): return str(self.inner) class MemoryPlanningState: def __init__(self): super().__init__() self.reuse_pool: dict[ReuseKey, list[FreeIfNotReusedLine]] = ( collections.defaultdict(list) ) self.total_allocated_buffer_size: int = 0 def __contains__(self, key: ReuseKey) -> bool: return bool(self.reuse_pool.get(key, None)) def pop(self, key: ReuseKey) -> FreeIfNotReusedLine: item = self.reuse_pool[key].pop() assert not item.is_reused return item def push(self, key: ReuseKey, item: FreeIfNotReusedLine) -> None: assert not item.is_reused self.reuse_pool[key].append(item) class WrapperLine: def codegen_fx(self, converter: FxConverter) -> FxConversionFunc: raise NotImplementedError("FX codegen not yet supported for type {type(self)}") @dataclasses.dataclass class EnterSubgraphLine(WrapperLine): wrapper: PythonWrapperCodegen graph: GraphLowering def __post_init__(self) -> None: self.wrapper.push_computed_sizes(self.wrapper.computed_sizes) def codegen(self, code: IndentedBuffer) -> None: self.wrapper.push_codegened_graph(self.graph) code.do_indent() def codegen_fx(self, converter: FxConverter) -> FxConversionFunc: return converter._generate_enter_subgraph @dataclasses.dataclass class CommentLine(WrapperLine): line: LineContext def codegen(self, code: IndentedBuffer) -> None: code.writeline(self.line) @staticmethod def codegen_fx(converter: FxConverter) -> FxConversionFunc: return converter._generate_comment @dataclasses.dataclass class ExitSubgraphLine(WrapperLine): wrapper: PythonWrapperCodegen def __post_init__(self) -> None: self.wrapper.computed_sizes = self.wrapper.pop_computed_sizes() def codegen(self, code: IndentedBuffer) -> None: self.wrapper.pop_codegened_graph() code.do_unindent() def codegen_fx(self, converter: FxConverter) -> FxConversionFunc: return converter._generate_exit_subgraph @dataclasses.dataclass class EnterDeviceContextManagerLine(WrapperLine): device_idx: int last_seen_device_guard_index: Optional[int] def codegen(self, code: IndentedBuffer) -> None: if V.graph.cpp_wrapper: code.writeline("\n") if V.graph.aot_mode: # In AOT mode, we have a stream provided as a param. A stream is # associated with a device, so we never expect the device to change. # CUDAStreamGuard sets the stream and the device. if self.last_seen_device_guard_index is None: code.writeline( f"{V.graph.device_ops.cpp_aoti_stream_guard()} stream_guard(stream, this->device_idx_);" ) else: assert self.last_seen_device_guard_index == self.device_idx, ( "AOTInductor only supports running on one CUDA device" ) else: if self.last_seen_device_guard_index is None: code.writeline( f"{V.graph.device_ops.cpp_aoti_device_guard()} device_guard({self.device_idx});" ) else: code.writeline(f"device_guard.set_index({self.device_idx});") else: # Note _DeviceGuard has less overhead than device, but only accepts # integers code.writeline(f"with {V.graph.device_ops.device_guard(self.device_idx)}:") code.do_indent() code.writeline(V.graph.device_ops.set_device(self.device_idx)) def codegen_fx(self, converter: FxConverter) -> FxConversionFunc: return converter._generate_enter_device_context_manager class ExitDeviceContextManagerLine(WrapperLine): def codegen(self, code: IndentedBuffer) -> None: if not V.graph.cpp_wrapper: code.do_unindent() def codegen_fx(self, converter: FxConverter) -> FxConversionFunc: return converter._generate_exit_device_context_manager @dataclasses.dataclass class ExternKernelAllocLine(WrapperLine): wrapper: PythonWrapperCodegen node: ir.ExternKernelAlloc def codegen(self, code: IndentedBuffer) -> None: node = self.node args = [*node.codegen_args(), *node.codegen_kwargs()] self.wrapper._generate_extern_kernel_alloc_helper(self.node, args) def codegen_fx(self, converter: FxConverter) -> FxConversionFunc: return converter._generate_extern_kernel_alloc @dataclasses.dataclass class ExternKernelOutLine(WrapperLine): wrapper: PythonWrapperCodegen node: ir.ExternKernelOut def codegen(self, code: IndentedBuffer) -> None: node = self.node args = [*node.codegen_args(), *node.codegen_kwargs(skip_out=True)] kernel_name = node.get_kernel_name() if ( V.graph.cpp_wrapper and node.cpp_kernel_name == "torch::inductor::_mm_plus_mm" ): # For https://github.com/pytorch/pytorch/issues/128474 kernel_name = "aoti_torch__mm_plus_mm_out" else: kernel_name = node.get_kernel_name() device = d.type if (d := node.get_device()) else V.graph.device_type # set provenance tracing kernel mapping for ExternKernel types if config.trace.enabled: set_kernel_post_grad_provenance_tracing(node, kernel_name, is_extern=True) self.wrapper._generate_extern_kernel_out_helper( kernel_name, node.codegen_reference(), node.output_view.codegen_reference() if node.output_view else None, args, device, ) def codegen_fx(self, converter: FxConverter) -> FxConversionFunc: return converter._generate_extern_kernel_out @dataclasses.dataclass class FreeLine(WrapperLine): wrapper: PythonWrapperCodegen node: Union[BufferLike, ir.TorchBindObject] def codegen(self, code: IndentedBuffer) -> None: assert self.node.get_name() not in V.graph.removed_buffers code.writeline(self.wrapper.make_buffer_free(self.node)) def codegen_fx(self, converter: FxConverter) -> FxConversionFunc: return converter._generate_free @dataclasses.dataclass class KernelCallLine(WrapperLine): wrapper: PythonWrapperCodegen kernel_name: str call_args: tuple[Any, ...] raw_keys: tuple[Any, ...] raw_args: tuple[Any, ...] arg_types: list[str] triton: bool triton_meta: dict[str, Any] device: torch.device graph_name: str original_fxnode_name: str def codegen(self, code: IndentedBuffer) -> None: self.wrapper._generate_kernel_call_helper( self.kernel_name, self.call_args, triton=self.triton, arg_types=self.arg_types, raw_keys=self.raw_keys, raw_args=self.raw_args, triton_meta=self.triton_meta, device=self.device, graph_name=self.graph_name, original_fxnode_name=self.original_fxnode_name, ) def codegen_fx(self, converter: FxConverter) -> FxConversionFunc: return converter._generate_kernel_call @dataclasses.dataclass class KernelDefinitionLine(WrapperLine): wrapper: PythonWrapperCodegen kernel_name: str kernel_body: str metadata: Optional[str] = None gpu: bool = True cpp_definition: Optional[str] = None def codegen(self, code: IndentedBuffer) -> None: self.wrapper._define_kernel_helper( self.kernel_name, self.kernel_body, metadata=self.metadata, gpu=self.gpu, cpp_definition=self.cpp_definition, ) def codegen_fx(self, converter: FxConverter) -> FxConversionFunc: return converter._generate_kernel_definition @dataclasses.dataclass class MemoryPlanningLine(WrapperLine): wrapper: PythonWrapperCodegen def plan(self, state: MemoryPlanningState) -> MemoryPlanningLine: """First pass to find reuse""" return self def codegen(self, code: IndentedBuffer) -> None: """Second pass to output code""" def __str__(self) -> str: """ Emits a string representation that fits on one line. """ args: list[str] = [] for field in dataclasses.fields(self): if field.name == "wrapper": continue val = getattr(self, field.name) args.append( f"{field.name}={val.get_name() if field.type is ir.Buffer else val}" ) return f"{type(self).__name__}({', '.join(args)})" @dataclasses.dataclass class AllocateLine(MemoryPlanningLine): node: BufferLike def plan(self, state: MemoryPlanningState) -> MemoryPlanningLine: if self.node.get_name() in V.graph.removed_buffers: return NullLine(self.wrapper) # try to reuse a recently freed buffer key = buffer_reuse_key(self.node) if config.allow_buffer_reuse and key in state: free_line = state.pop(key) free_line.is_reused = True return ReuseLine(self.wrapper, free_line.node, self.node) if self.node.get_device_or_error().type == "cpu": static_shape = self.wrapper.static_shape_for_buffer_or_none(self.node) if static_shape is not None: state.total_allocated_buffer_size += int( functools.reduce(operator.mul, static_shape, 1) ) return self def codegen(self, code: IndentedBuffer) -> None: assert self.node.get_name() not in V.graph.removed_buffers line = self.wrapper.make_buffer_allocation(self.node) code.writeline(line) def codegen_fx(self, converter: FxConverter) -> FxConversionFunc: return converter._generate_allocate @dataclasses.dataclass class FreeIfNotReusedLine(MemoryPlanningLine): node: BufferLike is_reused: bool = False def plan(self, state: MemoryPlanningState) -> MemoryPlanningLine: if len(self.node.get_inputs_that_alias_output()) > 0: return self if isinstance(self.node.layout, ir.MultiOutputLayout): return self assert not self.is_reused if self.node.get_name() in V.graph.removed_buffers: return NullLine(self.wrapper) if config.allow_buffer_reuse: state.push(buffer_reuse_key(self.node), self) return self def codegen(self, code: IndentedBuffer) -> None: assert self.node.get_name() not in V.graph.removed_buffers if not self.is_reused: code.writeline(self.wrapper.make_buffer_free(self.node)) def codegen_fx(self, converter: FxConverter) -> FxConversionFunc: return converter._generate_free_if_not_reused @dataclasses.dataclass class ReinterpretLine(MemoryPlanningLine): node: BufferLike reused_as: BufferLike layout: ir.Layout def plan(self, state: MemoryPlanningState) -> MemoryPlanningLine: return self def codegen(self, code: IndentedBuffer) -> None: assert isinstance(self.layout, ir.NonOwningLayout) assert isinstance(self.layout.view, ir.ReinterpretView) self.wrapper.codegen_deferred_allocation( self.reused_as.get_name(), self.layout.view ) def codegen_fx(self, converter: FxConverter) -> FxConversionFunc: return converter._generate_reinterpret @dataclasses.dataclass class ReuseLine(MemoryPlanningLine): node: BufferLike reused_as: BufferLike delete_old: bool = True def plan(self, state: MemoryPlanningState) -> MemoryPlanningLine: if self.node.get_name() in V.graph.removed_buffers: assert self.reused_as.get_name() in V.graph.removed_buffers return NullLine(self.wrapper) assert self.reused_as.get_name() not in V.graph.removed_buffers return self def codegen(self, code: IndentedBuffer) -> None: assert self.node.get_name() not in V.graph.removed_buffers assert self.reused_as.get_name() not in V.graph.removed_buffers code.writeline( self.wrapper.make_buffer_reuse(self.node, self.reused_as, self.delete_old) ) def codegen_fx(self, converter: FxConverter) -> FxConversionFunc: return converter._generate_reuse class NullLine(MemoryPlanningLine): def codegen_fx(self, converter: FxConverter) -> FxConversionFunc: return converter._generate_null @dataclasses.dataclass class CommBufferLine(WrapperLine): wrapper: PythonWrapperCodegen # type: ignore[name-defined] # noqa: F821 node: ir.Buffer @property def size(self) -> int: from torch._inductor.utils import is_symbolic numel = self.node.get_numel() dtype = self.node.get_dtype() if is_symbolic(numel): raise AssertionError( f"The size of a comm buffer can't be symbolic: {self.node}" ) return int(numel) * dtype.itemsize @property def comm_buffer_type(self) -> ir.CommBufferType: layout = self.node.get_output_spec() assert isinstance(layout, ir.CommBufferLayout) return layout.comm_buffer_type @property def group_name(self) -> str: layout = self.node.get_output_spec() assert isinstance(layout, ir.CommBufferLayout) return layout.group_name @dataclasses.dataclass class CommBufferAllocateLine(CommBufferLine): def codegen(self, code: IndentedBuffer) -> None: assert self.node.get_name() not in V.graph.removed_buffers name = self.node.get_name() device = self.node.get_device() dtype = self.node.get_dtype() shape = tuple(self.node.get_size()) stride = tuple(self.node.get_stride()) code.writeline( self.make_allocation_line( self.comm_buffer_type, self.group_name, self.wrapper, name, device, dtype, shape, stride, ) ) @staticmethod def make_allocation_line( comm_buffer_type, group_name, wrapper, name, device, dtype, shape, stride ): if comm_buffer_type == ir.CommBufferType.SYMM_MEM: return ( f"{name} = empty_strided_p2p(" f"{wrapper.codegen_shape_tuple(shape)}, " f"{wrapper.codegen_shape_tuple(stride)}, " f"{dtype}, " f'torch.device("cuda:{device.index}"), ' f'group_name="{group_name}", ' f"alloc_id={random.randint(0, 2**64 - 1)})" ) else: raise NotImplementedError( f"Unsupported comm buffer type: {comm_buffer_type}" ) def codegen_fx(self, converter: FxConverter) -> FxConversionFunc: return converter._generate_comm_buffer_allocate @dataclasses.dataclass class CommBufferFreeLine(CommBufferLine): def codegen(self, code: IndentedBuffer) -> None: line = self.wrapper.make_buffer_free(self.node) code.writeline(f"{line} # {self.comm_buffer_type.value} buffer free") def codegen_fx(self, converter: FxConverter) -> FxConversionFunc: return converter._generate_comm_buffer_free @dataclasses.dataclass class MultiOutputLine(WrapperLine): """ Given a MultiOutputLayout buffer, indexes actual buffer(s) from the result. """ wrapper: PythonWrapperCodegen result_name: str arg_name: str indices: Sequence[Any] def codegen(self, code: IndentedBuffer) -> None: def codegen_list_tuple_access(basename, indices): # type: ignore[no-untyped-def] if len(indices) > 0: itype, i = indices[0] if issubclass(itype, list): return codegen_list_tuple_access(f"{basename}[{i}]", indices[1:]) elif issubclass(itype, tuple): # cpp wrapper code needs to use std::get<> to access a tuple tuple_access = self.wrapper.codegen_tuple_access( basename, self.result_name, str(i) ) return codegen_list_tuple_access(tuple_access, indices[1:]) elif issubclass(itype, dict): return codegen_list_tuple_access(f"{basename}['{i}']", indices[1:]) else: raise AssertionError("non supported index type: ", itype) else: return basename value = codegen_list_tuple_access(self.arg_name, self.indices) code.writeline( f"{self.wrapper.declare}{self.result_name} = {value}{self.wrapper.ending}" ) def codegen_fx(self, converter: FxConverter) -> FxConversionFunc: return converter._generate_multi_output @dataclasses.dataclass class SymbolicCallArgLine(WrapperLine): wrapper: PythonWrapperCodegen arg: SymbolicCallArg graph: GraphLowering def codegen(self, code: IndentedBuffer) -> None: self.wrapper._generate_symbolic_call_arg_helper(self.arg, self.graph) def codegen_fx(self, converter: FxConverter) -> FxConversionFunc: return converter._generate_symbolic_call_arg BufferName = str Line = Union[MemoryPlanningLine, LineContext] class PythonWrapperCodegen(CodeGen): """ Generate outer wrapper in Python that calls the kernels. """ supports_caching = True # Whether the output code is cacheable. def __init__(self): super().__init__() self._names_iter: Iterator[int] = count() self.args_to_buffers: dict[ str, Union[None, ir.TensorBox, ir.Buffer, ir.TorchBindObject] ] = {} self.imports = IndentedBuffer() self.header = IndentedBuffer() self.prefix = IndentedBuffer() self.suffix = IndentedBuffer() self.kernel_declarations = IndentedBuffer() self.wrapper_call = IndentedBuffer() self.kernel_autotune_defs = IndentedBuffer() self.kernel_autotune_calls = IndentedBuffer() self.subgraph_definitions = IndentedBuffer() self.kernel_autotune_names: OrderedSet[str] = OrderedSet() # Map key is the kernel argument name; value is a tuple of the resulting example # tensor name with the kernel where that tensor was most recently used. self.kernel_autotune_example_args: dict[str, tuple[str, str]] = {} self.kernel_autotune_tmp_arg_idx: int = 0 # If the generated source code is exactly the same, reuse the # pre-existing kernel for it self.src_to_kernel: dict[str, str] = {} self.kernel_numel_expr: OrderedSet[tuple[str, GraphLowering]] = OrderedSet() self.lines: list[Line] = [] self.declare = "" self.declare_maybe_reference = "" self.ending = "" self.comment = "#" self.none_str = "None" self.move_begin = "std::move(" if V.graph.cpp_wrapper else "" self.move_end = ")" if V.graph.cpp_wrapper else "" self.last_seen_device_guard_index: Optional[int] = None self.supports_intermediate_hooks = True self.user_defined_kernel_cache: dict[tuple[Any, ...], tuple[str, Any]] = {} self.unbacked_symbol_decls: OrderedSet[str] = ( OrderedSet() ) # str of sympy.Symbol self.computed_sizes: OrderedSet[sympy.Symbol] = OrderedSet() self.launcher_fn_name = None # This function can be overridden to change the launcher name self.set_launcher_fn_name() # this is used for tracking which GraphLowering instance---parent graph # or (nested) subgraph---is currently codegened; the primary use case is # including the graph instance into a cache key to avoid cross-graph # caching during lowering of nested subgraphs self.codegened_graph_stack = [] self.computed_sizes_stack = [] self.write_header() if not is_codegen_graph_partition_subgraph(self): # See [Note: Removed Graph Partition Arguments] self.write_prefix() self.write_kernel_autotune_defs_header() if not V.graph.aot_mode: for name, hashed in V.graph.constant_reprs.items(): # include a hash so our code cache puts different constants into different files self.write_constant(name, hashed) self.allocated = OrderedSet[BufferName]() self.freed = OrderedSet[BufferName]() # maps from reusing buffer to reused buffer self.reuses: dict[BufferName, BufferName] = {} self.write_get_raw_stream = functools.lru_cache(None)( # type: ignore[assignment] self.write_get_raw_stream ) @functools.cache def add_import_once(line: str) -> None: self.imports.writeline(line) if config.triton.autotune_at_compile_time: self.kernel_autotune_calls.writeline(line) self.add_import_once = add_import_once self._metas: dict[str, str] = {} self._meta_vars: OrderedSet[str] = OrderedSet() self.multi_kernel_state = MultiKernelState() self.already_codegened_subgraphs: OrderedSet[str] = OrderedSet() self.allocated_workspaces: dict[str, Any] = {} # intermediate tensor value printing utility self.debug_printer = DebugPrinterManager( debug_printer_level=config.aot_inductor.debug_intermediate_value_printer, use_array_ref=config.aot_inductor.allow_stack_allocation, ) # Additional files that are dependent to the wrapper (ex. cubin files) self.additional_files = [] @staticmethod def create( is_subgraph: bool, subgraph_name: Optional[str], parent_wrapper: Optional[PythonWrapperCodegen], partition_signatures: Optional[ir.GraphPartitionSignature] = None, ): if is_subgraph: assert subgraph_name is not None assert parent_wrapper is not None return SubgraphPythonWrapperCodegen( subgraph_name, parent_wrapper, partition_signatures ) return PythonWrapperCodegen() def set_launcher_fn_name(self) -> None: self.launcher_fn_name = "call" def write_constant(self, name: str, hashed: str) -> None: self.header.writeline(f"{name} = None # {hashed}") def write_header(self) -> None: context = torch._guards.TracingContext.try_get() aot_config_comment = "" if context is not None and context.aot_graph_name is not None: aot_config_comment = f"# AOT ID: {context.aot_graph_name}" aot_inductor_debug_utils = "" if int(config.aot_inductor.debug_intermediate_value_printer) > 0: aot_inductor_debug_utils = "from torch._inductor.codegen.debug_utils import _print_debugging_tensor_value_info" self.imports.splice( f""" {aot_config_comment} from ctypes import c_void_p, c_long, c_int import torch import math import random import os import tempfile from math import inf, nan from cmath import nanj from torch._inductor.hooks import run_intermediate_hooks from torch._inductor.utils import maybe_profile from torch._inductor.codegen.memory_planning import _align as align from torch import device, empty_strided from {async_compile.__name__} import AsyncCompile from torch._inductor.select_algorithm import extern_kernels {aot_inductor_debug_utils} """, strip=True, ) self.header.splice( """ aten = torch.ops.aten inductor_ops = torch.ops.inductor _quantized = torch.ops._quantized assert_size_stride = torch._C._dynamo.guards.assert_size_stride assert_alignment = torch._C._dynamo.guards.assert_alignment empty_strided_cpu = torch._C._dynamo.guards._empty_strided_cpu empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda empty_strided_xpu = torch._C._dynamo.guards._empty_strided_xpu reinterpret_tensor = torch._C._dynamo.guards._reinterpret_tensor alloc_from_pool = torch.ops.inductor._alloc_from_pool async_compile = AsyncCompile() """, strip=True, ) try: # Only add empty_strided_p2p() if distributed and SymmetricMemory # is available from torch._C._distributed_c10d import _SymmetricMemory # noqa: F401 self.header.splice( """ empty_strided_p2p = torch._C._distributed_c10d._SymmetricMemory.empty_strided_p2p """, strip=True, ) except (AttributeError, ImportError): pass if config.annotate_training: self.header.writeline("from torch.cuda import nvtx") def include_extra_header(self, header: str): pass def write_kernel_autotune_defs_header(self) -> None: self.kernel_autotune_defs.splice( f""" import torch from torch._dynamo.testing import rand_strided from torch._dynamo.utils import preserve_rng_state from torch._inductor.select_algorithm import AlgorithmSelectorCache from {async_compile.__name__} import AsyncCompile async_compile = AsyncCompile() generate_example_value = AlgorithmSelectorCache.generate_example_value empty_strided_cuda = torch._C._dynamo.guards._empty_strided_cuda empty_strided_xpu = torch._C._dynamo.guards._empty_strided_xpu """ ) @cache_on_self def write_triton_header_once(self) -> None: import_str = f""" import triton import triton.language as tl from {triton_heuristics.__name__} import start_graph, end_graph """ if config.triton.autotune_at_compile_time: self.kernel_autotune_calls.splice(import_str) self.kernel_autotune_calls.writeline( V.graph.device_ops.import_get_raw_stream_as("get_raw_stream") ) if not V.graph.cpp_wrapper: self.imports.splice(import_str, strip=True) self.imports.writeline( V.graph.device_ops.import_get_raw_stream_as("get_raw_stream") ) def write_get_raw_stream_header(self) -> None: if config.triton.autotune_at_compile_time: self.kernel_autotune_calls.writeline( V.graph.device_ops.import_get_raw_stream_as("get_raw_stream") ) if not V.graph.cpp_wrapper: self.imports.writeline( V.graph.device_ops.import_get_raw_stream_as("get_raw_stream") ) @cache_on_self def write_get_raw_stream_header_once(self) -> None: self.write_get_raw_stream_header() def add_meta_once(self, meta: TritonMetaParams) -> str: meta = repr(meta) if meta not in self._metas: var = f"meta{len(self._metas)}" self._metas[meta] = var self.header.writeline(f"{var} = {meta}") if config.triton.autotune_at_compile_time: self.kernel_autotune_calls.writeline(f"{var} = {meta}") self._meta_vars.add(var) return self._metas[meta] @cache_on_self def get_output_refs(self) -> list[str]: return [ x.codegen_reference(self.wrapper_call) for x in self.get_graph_outputs() ] def mark_output_type(self) -> None: return def get_graph_inputs( self, ) -> dict[str, Union[ir.TensorBox, ir.TorchBindObject, sympy.Expr]]: return V.graph.graph_inputs def get_graph_outputs(self) -> list[IRNode]: return V.graph.graph_outputs def codegen_input_size_asserts(self) -> None: for name, buf in self.get_graph_inputs().items(): if isinstance(buf, (sympy.Expr, ir.TorchBindObject)): continue # a graph partition may take an IRNode output from a previous partition if name not in V.graph.graph_input_names or isinstance( buf, ir.GeneratorState ): continue # comparing strides for 0 size tensor is tricky. Ignore them for now. if sympy_product(buf.get_size()) == 0: continue size = self.codegen_python_shape_tuple(buf.get_size()) stride = self.codegen_python_shape_tuple(buf.get_stride()) self.prefix.writeline(f"assert_size_stride({name}, {size}, {stride})") def codegen_input_nan_asserts(self) -> None: self.prefix.writeline("# make sure graph inputs are not nan/inf") for name, buf in self.get_graph_inputs().items(): if isinstance(buf, (sympy.Expr, ir.TorchBindObject)): continue line = f"assert not {name}.isnan().any().item()" self.prefix.writeline(line) line = f"assert not {name}.isinf().any().item()" self.prefix.writeline(line) def write_async_compile_wait(self) -> None: self.prefix.splice( """ async_compile.wait(globals()) del async_compile """ ) def write_args(self, input_names: list[str]): lhs = ", ".join(input_names) if len(input_names) == 1: lhs += "," self.prefix.writeline(f"{lhs} = args") self.prefix.writeline("args.clear()") def write_launcher_fn_call_get_indent(self) -> int: if config.graph_partition: self.prefix.splice( """ class Runner: def __init__(self, partitions): self.partitions = partitions def recursively_apply_fns(self, fns): new_callables = [] for fn, c in zip(fns, self.partitions): new_callables.append(fn(c)) self.partitions = new_callables def call(self, args): """ ) prefix_indent = 2 else: self.prefix.splice( f""" def {self.launcher_fn_name}(args): """ ) prefix_indent = 1 return prefix_indent def get_graph_input_names(self) -> list[str]: return V.graph.graph_input_names def write_prefix(self) -> None: assert self.launcher_fn_name is not None self.write_async_compile_wait() prefix_indent = self.write_launcher_fn_call_get_indent() with self.prefix.indent(prefix_indent): if config.triton.debug_sync_graph: self.prefix.writeline(V.graph.device_ops.synchronize()) phase = V.graph.get_training_phase() if config.annotate_training: self.prefix.writeline( f"training_annotation = nvtx._device_range_start('{phase}')" ) if graph_input_names := self.get_graph_input_names(): self.write_args(graph_input_names) self.codegen_inputs() self.codegen_input_size_and_nan_asserts() def codegen_input_size_and_nan_asserts(self) -> None: if config.size_asserts: self.codegen_input_size_asserts() if config.nan_asserts: self.codegen_input_nan_asserts() # this function (and below) takes the graph name as input so # that stream caching happens per graph instance. this # is important for nested subgraph codegening. def write_get_raw_stream(self, device_idx: int, graph_name: str) -> str: self.write_get_raw_stream_header_once() name = f"stream{device_idx}" if config.triton.autotune_at_compile_time: self.kernel_autotune_calls.writeline( f"{name} = get_raw_stream({device_idx})" ) if V.graph.cpp_wrapper: # For cpp wrapper, no need to continue codegen for the main body return name self.writeline(f"{name} = get_raw_stream({device_idx})") return name def get_codegened_graph(self): return self.codegened_graph_stack[-1] def push_codegened_graph(self, graph): self.codegened_graph_stack.append(graph) def pop_codegened_graph(self): return self.codegened_graph_stack.pop() def push_computed_sizes(self, computed_sizes): from copy import deepcopy return self.computed_sizes_stack.append(deepcopy(computed_sizes)) def pop_computed_sizes(self): return self.computed_sizes_stack.pop() def next_kernel_suffix(self) -> str: return f"{next(self._names_iter)}" def codegen_device_guard_enter(self, device_idx: int) -> None: self.writeline( EnterDeviceContextManagerLine(device_idx, self.last_seen_device_guard_index) ) if config.triton.autotune_at_compile_time: # mimic logic of EnterDeviceContextManagerLine.codegen for the autotune code block self.write_triton_header_once() self.kernel_autotune_calls.writeline( f"with {V.graph.device_ops.device_guard(device_idx)}:" ) self.kernel_autotune_calls.do_indent() self.kernel_autotune_calls.writeline( V.graph.device_ops.set_device(device_idx) ) if is_codegen_graph_partition_subgraph(self): # Need get_raw_stream for subgraph self.write_get_raw_stream_header() self.kernel_autotune_calls.writeline( f"stream{device_idx} = get_raw_stream({device_idx})" ) self.last_seen_device_guard_index = device_idx def codegen_device_guard_exit(self) -> None: self.writeline(ExitDeviceContextManagerLine()) if config.triton.autotune_at_compile_time: self.kernel_autotune_calls.do_unindent() def generate_return(self, output_refs: list[str]) -> None: if output_refs: if config.nan_asserts: self.wrapper_call.writeline( "return_vars = (" + ", ".join(output_refs) + ", )" ) self.wrapper_call.writeline("for var in return_vars:") self.wrapper_call.do_indent() self.wrapper_call.writeline("if isinstance(var, torch.Tensor):") self.wrapper_call.do_indent() self.wrapper_call.writeline("assert not var.isnan().any().item()") self.wrapper_call.writeline("assert not var.isinf().any().item()") self.wrapper_call.do_unindent(2) self.wrapper_call.writeline("return (" + ", ".join(output_refs) + ", )") else: self.wrapper_call.writeline("return ()") def generate_before_suffix(self, result: IndentedBuffer) -> None: return def generate_after_suffix(self, result: IndentedBuffer) -> None: if config.graph_partition: all_partition_name_list = ", ".join(self.all_partition_names) + ( "," if len(self.all_partition_names) == 1 else "" ) result.splice( f""" runner = Runner(partitions=[{all_partition_name_list}]) call = runner.call recursively_apply_fns = runner.recursively_apply_fns """ ) def generate_end(self, result: IndentedBuffer) -> None: return def generate_fallback_kernel(self, node: ir.FallbackKernel) -> None: self.writeline(ExternKernelAllocLine(self, node)) def generate_extern_kernel_alloc(self, node: ir.ExternKernelAlloc): node.codegen_comment(self) self.writeline(ExternKernelAllocLine(self, node)) if isinstance(node.layout, ir.Layout): node.codegen_size_asserts(self) def _generate_extern_kernel_alloc_helper(self, extern_kernel, args): # If it's a NoneLayout then the extern_kernel should essentially be # treated as if it doesn't return anything no_return = isinstance(extern_kernel.layout, ir.NoneLayout) output_name = extern_kernel.get_name() origin_node = extern_kernel.get_origin_node() kernel_name = extern_kernel.get_kernel_name() ending = self.ending if config.memory_planning and "view_as_complex" in kernel_name: # view operation fallbacks cause issues since inductor # doesn't know the memory is still needed and might reuse it. ending = f".clone(){ending}" if no_return: self.writeline(f"{self.declare}{kernel_name}({', '.join(args)}){ending}") else: self.writeline( f"{self.declare}{output_name} = {kernel_name}({', '.join(args)}){ending}" ) if ( self.supports_intermediate_hooks and config.generate_intermediate_hooks and origin_node is not None ): counters["inductor"]["intermediate_hooks"] += 1 self.writeline( f"run_intermediate_hooks({origin_node.name!r}, {output_name})" ) def generate_extern_kernel_out( self, node: ir.ExternKernelOut, ) -> None: node.codegen_comment(self) self.writeline(ExternKernelOutLine(self, node)) def _generate_extern_kernel_out_helper( self, kernel: str, out: str, out_view: Optional[str], args: list[str], device: str, ) -> None: # add debug printer code for triton kernel calls at (jit) inductor level debug_printer_manager = V.graph.wrapper_code.debug_printer debug_printer_manager.set_printer_args(args, kernel, None, None, "extern") args.append(f"out={out_view if out_view else out}") with debug_printer_manager: self.writeline(f"{kernel}({', '.join(args)})") def _generate_tma_descriptor_call_experimental(self, desc, apply_size_hints=False): dims = desc.dims block_dims = desc.block_dims if apply_size_hints: dims = tuple(V.graph.sizevars.atomically_apply_size_hint(d) for d in dims) block_dims = tuple( V.graph.sizevars.atomically_apply_size_hint(d) for d in block_dims ) ptr = f"{desc.tensor.codegen_reference()}.data_ptr()" # Explicitly call the Python version of val_to_arg_str dims = ", ".join(PythonWrapperCodegen.val_to_arg_str(self, dim) for dim in dims) block_dims = ", ".join( PythonWrapperCodegen.val_to_arg_str(self, dim) for dim in block_dims ) element_size = PythonWrapperCodegen.val_to_arg_str(self, desc.element_size) prefix = "triton.tools.experimental_descriptor" fn = f"{prefix}.create_{desc.rank}d_tma_descriptor" args = f"{ptr}, {dims}, {block_dims}, {element_size}" call = f"{fn}({args})" return call def _generate_tma_descriptor_call_stable(self, desc, apply_size_hints=False): block_shape = desc.block_shape if apply_size_hints: block_shape = tuple( V.graph.sizevars.atomically_apply_size_hint(d) for d in block_shape ) prefix = "triton.tools.tensor_descriptor.TensorDescriptor" fn = f"{prefix}.from_tensor" args = f"{desc.tensor.codegen_reference()}, {block_shape}" call = f"{fn}({args})" return call def _generate_tma_descriptor_call(self, desc, apply_size_hints=False): if isinstance(desc, ir.TMADescriptorExperimental): return self._generate_tma_descriptor_call_experimental( desc, apply_size_hints ) else: assert isinstance(desc, ir.TMADescriptorStable) return self._generate_tma_descriptor_call_stable(desc, apply_size_hints) def generate_tma_descriptor(self, desc): call = self._generate_tma_descriptor_call(desc) line = f"{desc.name} = {call}{self.ending}" self.writeline(line) def generate_scatter_fallback( self, output, inputs, cpp_kernel_name, python_kernel_name, src_is_tensor, reduce, kwargs, ): line = f"{python_kernel_name}({','.join(map(str, inputs))}" if python_kernel_name.startswith("aten.scatter_reduce"): line += ", ".join([""] + kwargs) else: if reduce: line += f", reduce={repr(reduce)}" line += ")" self.writeline(line) def generate_index_put_fallback(self, kernel, x, indices, values, accumulate): indices_str = f"[{', '.join(indices)}]" args = [x, indices_str, values, accumulate] self.writeline(self.wrap_kernel_call(kernel, args)) def generate_fallback_kernel_with_runtime_lookup( self, buf_name: str, python_kernel_name: str, get_args: Callable[[], Sequence[str]], op_overload: Union[torch._ops.OpOverload, torch._ops.HigherOrderOperator], raw_args: Sequence[Any], outputs: Sequence[ir.Buffer], ) -> None: self.writeline(f"{buf_name} = {python_kernel_name}({', '.join(get_args())})") def generate(self, is_inference): with dynamo_timed("PythonWrapperCodegen.generate"): return self._generate(is_inference) def get_wrapper_call_indent(self) -> int: if config.graph_partition: return 2 else: return 1 @contextlib.contextmanager def set_writeline(self, new: Callable[..., None]) -> Iterator[Callable[..., None]]: old = self.writeline try: self.writeline = new # type: ignore[method-assign] yield new finally: self.writeline = old # type: ignore[method-assign] def _write_multi_kernel_defs(self) -> None: kernel_defs = self.multi_kernel_state.kernel_defs if config.triton.autotune_at_compile_time: self.kernel_autotune_defs.splice(kernel_defs) else: self.header.splice(kernel_defs) def _generate(self, is_inference): if config.profile_bandwidth: self.write_triton_header_once() with contextlib.ExitStack() as stack: stack.enter_context(self.wrapper_call.indent()) if config.profiler_mark_wrapper_call: self.generate_profiler_mark_wrapper_call(stack) if config.profile_bandwidth: self.generate_start_graph() self.run_wrapper_ir_passes(is_inference) if config.triton.store_cubin and not config.triton.autotune_at_compile_time: self.generate_reset_kernel_saved_flags() # At this point, we shouldn't generate any new memory planning lines. # Override writeline to point at the wrapper call, in case it gets called. with self.set_writeline(self.wrapper_call.writeline): for line in self.lines: if isinstance(line, WrapperLine): line.codegen(self.wrapper_call) else: self.wrapper_call.writeline(line) self._write_multi_kernel_defs() output_refs = self.get_output_refs() self.mark_output_type() if config.triton.debug_sync_graph: self.wrapper_call.writeline(V.graph.device_ops.synchronize()) if config.profile_bandwidth: self.generate_end_graph() if config.triton.store_cubin and not config.triton.autotune_at_compile_time: self.generate_save_uncompiled_kernels() if config.triton.autotune_at_compile_time: self.generate_and_run_autotune_block() # cpp_wrapper currently doesn't support nvtx if config.annotate_training and not config.cpp_wrapper: self.wrapper_call.writeline( "nvtx._device_range_end(training_annotation)" ) self.generate_return(output_refs) # Assemble the final code from sections. result = IndentedBuffer() result.splice(self.imports) result.writeline("") result.splice(self.header) # We do not want the cpp header for intermediate const graph. Headers would be # rendered by the main module instead. if V.graph.aot_mode and V.graph.cpp_wrapper and V.graph.is_const_graph: result = IndentedBuffer() # Add subgraph definitions to the result result.splice(self.subgraph_definitions) self.finalize_prefix() result.splice(self.prefix) wrapper_call_indent = self.get_wrapper_call_indent() with result.indent(wrapper_call_indent): result.splice(self.wrapper_call) self.generate_before_suffix(result) result.splice(self.suffix) self.generate_after_suffix(result) self.generate_end(result) self.add_benchmark_harness(result) return ( result.getvaluewithlinemap(), self.kernel_declarations.getvaluewithlinemap(), ) def generate_and_run_autotune_block(self): """ Compose self.kernel_autotune_defs and self.kernel_autotune_calls into a single block of code and execute it to trigger Triton kernel compilation and auto-tuning """ self.kernel_autotune_defs.splice( """ async_compile.wait(globals()) del async_compile """ ) scope = {} # type: ignore[var-annotated] if config.triton.autotune_at_compile_time and V.graph.autotuning_inputs: scope = { self.get_autotuning_input_name(idx): v # type: ignore[attr-defined] for idx, v in enumerate(V.graph.autotuning_inputs) } tuning_code = ( self.kernel_autotune_defs.getvalue() + "\n" + self.kernel_autotune_calls.getvalue() ) if output_code_log.level == logging.DEBUG: # Save the autotuning code block into a file # Create a temporary file with tempfile.NamedTemporaryFile( dir=cache_dir(), suffix=".py", delete=False ) as f: f.write(tuning_code.encode("utf-8")) file_path = f.name output_code_log.debug( "Auto-tuning code written to %s", file_path, ) # Execute the code to autotune kernels try: exec(tuning_code, scope) except Exception as e: raise RuntimeError(f"Failed to run autotuning code block: {e}") from e def memory_plan(self): from .memory_planning import MemoryPlanner self.lines = MemoryPlanner(self).plan(self.lines) def memory_plan_reuse(self): out_names = V.graph.get_output_names() while ( self.lines and isinstance(self.lines[-1], MemoryPlanningLine) # TODO: this seems legit, NullLine has no node and self.lines[-1].node.name not in out_names # type: ignore[attr-defined] ): # these lines will be pointless self.lines.pop() # codegen allocations in two passes planning_states = [MemoryPlanningState()] past_planning_states = [] for i in range(len(self.lines)): line = self.lines[i] if isinstance(line, MemoryPlanningLine): self.lines[i] = line.plan(planning_states[-1]) elif isinstance(line, EnterSubgraphLine): planning_states.append(MemoryPlanningState()) elif isinstance(line, ExitSubgraphLine): past_planning_states.append(planning_states.pop()) past_planning_states.append(planning_states.pop()) assert len(planning_states) == 0 # conservatively use the sum of all allocated buffer sizes # in potentially nested scopes as the total allocated size # FIXME(rec): not used _total_allocated_buffer_size = sum( s.total_allocated_buffer_size for s in past_planning_states ) def run_wrapper_ir_passes(self, is_inference: bool): # We disable planning during training because it presently increases peak memory consumption. if is_inference and config.memory_planning: self.memory_plan() else: self.memory_plan_reuse() def codegen_input_symbol_assignment( self, name: str, value: ir.TensorBox, bound_vars: OrderedSet[sympy.Symbol], ): code = self.prefix @functools.cache def sizeof(name): code.writeline(f"{name}_size = {name}.size()") return f"{name}_size" @functools.cache def strideof(name): code.writeline(f"{name}_stride = {name}.stride()") return f"{name}_stride" if isinstance(value, sympy.Expr): if not isinstance(value, sympy.Symbol) or value in bound_vars: return code.writeline(f"{value} = {name}") bound_vars.add(value) elif isinstance(value, ir.TensorBox): for dim, size in enumerate(value.get_size()): if isinstance(size, sympy.Symbol) and size not in bound_vars: code.writeline(f"{size} = {sizeof(name)}[{dim}]") bound_vars.add(size) for dim, stride in enumerate(value.get_stride()): if isinstance(stride, sympy.Symbol) and stride not in bound_vars: code.writeline(f"{stride} = {strideof(name)}[{dim}]") bound_vars.add(stride) elif isinstance(value, ir.TorchBindObject): return elif isinstance(value, ir.GeneratorState): return else: if torch._inductor.config.graph_partition: pass else: raise AssertionError(f"Unknown value type: {type(value)}") def codegen_inputs(self): """Assign all symbolic shapes to locals""" bound_vars = OrderedSet[sympy.Symbol]() # There is a subtle case in the cpp wrapper codegen which requires generating # symbol inputs first followed by non-symbol ones. # # When a dynamic size constraint specified at the Export time is an expression, # we need to solve that expression to proper define a symbol in cpp. Thus we # are enforcing this iterating order here to make sure all plain size symbols # are defined first. graph_inputs = self.get_graph_inputs() inputs = [ (k, v) for k, v in graph_inputs.items() if isinstance(v, sympy.Symbol) ] + [(k, v) for k, v in graph_inputs.items() if not isinstance(v, sympy.Symbol)] for name, value in inputs: self.codegen_input_symbol_assignment(name, value, bound_vars) def _verify_input_symbol_assignment( value: ir.TensorBox, bound_vars: OrderedSet[sympy.Symbol], ): for expr in chain.from_iterable([value.get_size(), value.get_stride()]): if not isinstance(expr, Expr) or isinstance(expr, sympy.Symbol): continue undefined_symbols = [ sym for sym in expr.free_symbols if sym not in bound_vars ] if len(undefined_symbols) > 0: raise AssertionError( f"For {expr}, expected {undefined_symbols} to have been codegen-ed." ) # For inputs with size/strides which contain sympy expressions, we can # encounter symbols that weren't defined yet. Now, let's check each # symbol is defined. for _, value in inputs: if not isinstance(value, ir.TensorBox): continue _verify_input_symbol_assignment(value, bound_vars) def ensure_size_computed(self, sym: sympy.Symbol): if isinstance(sym, sympy.Symbol) and symbol_is_type(sym, SymT.PRECOMPUTED_SIZE): if sym in self.computed_sizes: return self.computed_sizes.add(sym) expr = V.graph.sizevars.inv_precomputed_replacements[sym] self.writeline(f"{sym} = {pexpr(expr)}") def finalize_prefix(self): pass def codegen_cpp_sizevar(self, x: Expr, *, simplify: bool = True) -> str: raise RuntimeError("codegen_cpp_sizevar is only implemented for cpp_wrapper!") def codegen_python_sizevar(self, x: Expr, *, simplify: bool = True) -> str: return pexpr(x, simplify=simplify) def codegen_sizevar(self, x: Expr) -> str: return self.codegen_python_sizevar(x) def codegen_tuple_access(self, basename: str, name: str, index: str) -> str: return f"{basename}[{index}]" def codegen_python_shape_tuple(self, shape: Sequence[Expr]) -> str: parts = [*map(self.codegen_python_sizevar, shape)] if len(parts) == 0: return "()" if len(parts) == 1: return f"({parts[0]}, )" return f"({', '.join(parts)})" def codegen_shape_tuple(self, shape: Sequence[Expr]) -> str: return self.codegen_python_shape_tuple(shape) def codegen_alloc_from_pool(self, name, offset, dtype, shape, stride) -> str: return "alloc_from_pool({})".format( ", ".join( [ name, pexpr(offset), # bytes not numel str(dtype), self.codegen_python_shape_tuple(shape), self.codegen_python_shape_tuple(stride), ] ) ) def codegen_reinterpret_view( self, data, size, stride, offset, writeline: Callable[..., None], dtype=None, ) -> str: if ( size == data.layout.size and stride == data.layout.stride and offset == data.layout.offset ): if dtype is not None and dtype != data.dtype: return f"aten.view.dtype({data.get_name()}, {dtype})" else: return f"{data.get_name()}" else: size = self.codegen_python_shape_tuple(size) stride = self.codegen_python_shape_tuple(stride) offset = self.codegen_sizevar(offset) if dtype is not None and dtype != data.dtype: return f"aten.view.dtype(reinterpret_tensor({data.get_name()}, {size}, {stride}, {offset}), {dtype})" else: return ( f"reinterpret_tensor({data.get_name()}, {size}, {stride}, {offset})" ) def codegen_device_copy(self, src, dst, non_blocking: bool): self.writeline(f"{dst}.copy_({src}, {non_blocking})") def codegen_multi_output(self, node: ir.MultiOutput): result_name = node.get_name() arg_name = node.inputs[0].get_name() self.writeline(MultiOutputLine(self, result_name, arg_name, node.indices)) def codegen_dynamic_scalar(self, node): (data,) = (t.codegen_reference() for t in node.inputs) if len(node.keypath) == 0: self.writeline(f"{node.sym} = {data}.item()") elif len(node.keypath) == 1 and isinstance(node.keypath[0], ConvertIntKey): self.writeline(f"{node.sym} = 1 if {data}.item() else 0") elif len(node.keypath) == 1 and isinstance(node.keypath[0], DivideByKey): self.writeline(f"{node.sym}_undivided = {data}.item()") self.writeline( f"assert {node.sym}_undivided % {node.keypath[0].divisor} == 0, " f"f'{{{node.sym}_undivided}} not divisible by {node.keypath[0].divisor}'" ) self.writeline( f"{node.sym} = {node.sym}_undivided // {node.keypath[0].divisor}" ) else: raise AssertionError(f"unrecognized keypath {node.keypath}") # No one should ever use this buffer, but for uniformity # define the variable and assign it None self.writeline(f"{node.get_name()} = None") def benchmark_compiled_module(self, output): def add_fake_input(name, shape, stride, device, dtype): output.writeline( f"{name} = rand_strided(" f"{self.codegen_python_shape_tuple(shape)}, " f"{self.codegen_python_shape_tuple(stride)}, " f"device='{device}', dtype={dtype})" ) def add_expr_input(name, val): output.writeline(f"{name} = {val}") def add_torchbind_input(name, value): import pickle assert isinstance(value, torch.ScriptObject) output.writeline(f"{name} = pickle.loads({pickle.dumps(value)!r})") output.writelines( ["", "", "def benchmark_compiled_module(times=10, repeat=10):"] ) with output.indent(): output.splice( """ from torch._dynamo.testing import rand_strided from torch._inductor.utils import print_performance """, strip=True, ) for name, value in V.graph.constants.items(): # all the constants are global variables, that's why we need # these 'global var_name' lines output.writeline(f"global {name}") add_fake_input( name, value.size(), value.stride(), value.device, value.dtype ) if len(V.graph.torchbind_constants) > 0: output.writeline("import pickle") for name, torchbind_obj in V.graph.torchbind_constants.items(): # all the constants are global variables, that's why we need # these 'global var_name' lines output.writeline(f"global {name}") add_torchbind_input(name, torchbind_obj) for name, value in V.graph.graph_inputs.items(): if isinstance(value, sympy.Symbol) and isinstance( V.graph.sizevars.var_to_val.get(value, None), SingletonInt ): # Inductor should only work with dense -> dense graph, and # SingletonInts belong to metadata that should only live on # the subclass. continue if isinstance(value, ir.TorchBindObject): if len(V.graph.torchbind_constants) == 0: # otherwise we have already imported the pickle package output.writeline("import pickle") output.writeline(f"global {name}") add_torchbind_input(name, value.get_real_obj()) elif isinstance(value, sympy.Expr): # Don't need to add symbolic # TODO: this fallback and those below actually will generate possibly # invalid benchmark code, because it's not guaranteed 42 # is actually a valid value for the kernel in question. # See https://github.com/pytorch/pytorch/issues/124686 add_expr_input(name, V.graph.sizevars.size_hint(value, fallback=42)) elif isinstance(value, ir.GeneratorState): add_expr_input( name, f"torch.cuda.default_generators[{value.device.index}].graphsafe_get_state()", ) else: shape = [ V.graph.sizevars.size_hint(x, fallback=42) for x in value.get_size() ] stride = [ V.graph.sizevars.size_hint(x, fallback=42) for x in value.get_stride() ] add_fake_input( name, shape, stride, value.get_device(), value.get_dtype(), ) call_str = f"call([{', '.join(V.graph.graph_inputs.keys())}])" output.writeline(f"fn = lambda: {call_str}") output.writeline("return print_performance(fn, times=times, repeat=repeat)") def add_benchmark_harness(self, output): """ Append a benchmark harness to generated code for debugging """ if not config.benchmark_harness: return self.benchmark_compiled_module(output) output.writelines(["", "", 'if __name__ == "__main__":']) with output.indent(): output.writelines( [ "from torch._inductor.wrapper_benchmark import compiled_module_main", f"compiled_module_main('{get_benchmark_name()}', benchmark_compiled_module)", ] ) def define_kernel( self, kernel_name: str, kernel_body: str, metadata: Optional[str] = None, gpu: bool = True, cpp_definition: Optional[str] = None, ): self.writeline( KernelDefinitionLine( self, kernel_name, kernel_body, metadata=metadata, gpu=gpu, cpp_definition=cpp_definition, ) ) @staticmethod def _format_kernel_definition( kernel_name: str, kernel_body: str, metadata: Optional[str] = None ): metadata_comment = f"{metadata}\n" if metadata else "" body = f"\n\n{metadata_comment}{kernel_name} = {kernel_body}" return body def _define_kernel_helper( self, kernel_name: str, kernel_body: str, metadata: Optional[str] = None, gpu: bool = True, cpp_definition: Optional[str] = None, ): if config.triton.autotune_at_compile_time: # Skip inserting comments for the autotune block as they may contain cpp style comments body = self._format_kernel_definition( kernel_name, kernel_body, metadata=None ) self.kernel_autotune_defs.splice(body) if V.graph.cpp_wrapper: # For cpp wrapper, no need to continue codegen for the main body return body = self._format_kernel_definition( kernel_name, kernel_body, metadata=metadata ) self.header.splice(body) def define_subgraph_launcher_fn(self, fn_code: str): self.subgraph_definitions.splice(fn_code) def define_user_defined_triton_kernel( self, kernel, configs, kwargs, restore_value_args, reset_to_zero_args, grids: list[list[Union[int, sympy.Expr]]], ): from ..runtime.triton_heuristics import ( config_to_dict, FixedGrid, PrecomputedGrid, ) from .common import ( ConstexprArg, KernelArgType, SizeArg, TensorArg, TMADescriptorArg, ) from .triton import gen_common_triton_imports, TritonKernel original_name = kernel.__name__ signature: list[KernelArgType] = [] constants: dict[str, Any] = {} arg_indices: list[int] = [] equal_to_1_args: list[str] = [] def add_to_signature(idx, arg): signature.append(arg) arg_indices.append(idx) def add_arg(idx, arg, is_constexpr=False, equals_1=False, equals_none=False): if is_constexpr: if triton_version_uses_attrs_dict(): # tl.constexpr args appear in the signature in new versions of triton, # but not in old versions of triton. add_to_signature(idx, arg) if arg.name in kwargs: # the arg may not appear in kwargs if it is an autotuned arg. # in this case, it will be added in triton_heuristics after autotuning. constants[arg.name] = kwargs[arg.name] else: # the only case where arg name isn't in kwargs, should be # when the arg is a constexpr. assert arg.name in kwargs if equals_1: if triton_version_uses_attrs_dict(): # new versions of triton: add the equal-to-1 arg in the signature (labeled as "constexpr"), # and add the arg as a constant. # new versions of triton: add the equal-to-1 arg in the signature (labeled as, e.g., "i32"), # and add the arg as a constant. add_to_signature(idx, ConstexprArg(name=arg.name)) else: add_to_signature(idx, arg) constants[arg.name] = 1 elif equals_none: if triton_version_uses_attrs_dict(): # new versions of triton: add the none arg in the signature (as a constexpr arg) and as a constant # old versions of triton: include the none arg as a constant (but not in the signature) add_to_signature(idx, ConstexprArg(name=arg.name)) constants[arg.name] = None else: add_to_signature(idx, arg) for idx, key in enumerate(kernel.arg_names): if idx in kernel.constexprs: add_arg(idx, ConstexprArg(name=key), is_constexpr=True) continue if key not in kwargs: continue arg = kwargs[key] if kwargs[key] is None: add_arg(idx, ConstexprArg(name=key), equals_none=True) else: if isinstance(arg, ir.TMADescriptor): api_type, block_shape, dtype = ( ("stable", arg.block_shape, arg.tensor.get_dtype()) if isinstance(arg, ir.TMADescriptorStable) else ("experimental", None, None) ) add_arg( idx, TMADescriptorArg( name=key, api_type=api_type, block_shape=block_shape, dtype=dtype, ), ) elif isinstance(arg, ir.Buffer): add_arg( idx, TensorArg( name=key, buffer=arg.get_name(), dtype=arg.get_dtype(), ), ) elif isinstance(arg, ir.ReinterpretView): # for ReinterpretView we use the underlying # buffer name and note the (possibly non-zero) # offset relative to the underlying buffer add_arg( idx, TensorArg( name=key, buffer=arg.data.get_name(), dtype=arg.get_dtype(), offset=arg.layout.offset, ), ) else: equals_1 = isinstance( arg, (int, sympy.Integer) ) and V.graph.sizevars.statically_known_equals( arg, 1, # type: ignore[arg-type] ) add_arg(idx, SizeArg(key, arg), equals_1=equals_1) triton_signature = signature_to_meta( signature, size_dtype=None, # try to infer based on symints indices=arg_indices, argdefs=[ArgName(x) for x in kernel.arg_names], ) triton_meta: dict[str, Any] = { "signature": triton_signature, "device": DeviceProperties.create(V.graph.get_current_device_or_throw()), # Triton compiler includes equal_to_1 args into constants even # when they are not constexpr. otherwise there may be a segfault # during launching the Inductor-compiled Triton kernel. # TODO(aakhundov): add None args to constants, too. currently, this # causes CUDA errors in test_aot_inductor.test_triton_kernel_with_none_input. # https://github.com/pytorch/pytorch/issues/120478#issuecomment-1962822307 # https://github.com/triton-lang/triton/blob/231efe9ed2d200be0f69a07c298e4342b08efe3d/python/triton/runtime/jit.py#L384 "constants": { **constants, **dict.fromkeys(equal_to_1_args, 1), }, "configs": [ config_of( signature, indices=arg_indices, ) ], } if restore_value_args: triton_meta["restore_value"] = tuple(restore_value_args) if reset_to_zero_args: triton_meta["reset_to_zero"] = tuple(reset_to_zero_args) if len(grids) == 1: # compute the grid in the wrapper and pass it in as an arg inductor_meta: dict[str, Any] = FixedGrid.setup_grid_as_args() extra_launcher_call_args = [*map(sympy.sympify, grids[0])] else: def rename_sizes_for_launcher(expr: Union[int, sympy.Expr]) -> sympy.Expr: if isinstance(expr, sympy.Expr): symbols = [*expr.free_symbols] if not symbols: return expr symbols.sort(key=str) for sym in symbols: if sym in extra_launcher_args: continue extra_launcher_args[sym] = sympy.Symbol( f"_launcher_s{len(extra_launcher_args)}" ) return sympy_subs(expr, extra_launcher_args) assert isinstance(expr, int) return sympy.Integer(expr) extra_launcher_args: dict[sympy.Symbol, sympy.Symbol] = {} grids = [[*map(rename_sizes_for_launcher, grid)] for grid in grids] assert grids and len(grids) == len(configs) precomputed_grids = [] for grid, cfg in sorted( zip(grids, configs), key=lambda x: len(x[1].kwargs), reverse=True ): precomputed_grids.append( { "config": config_to_dict(cfg), "python": [*map(pexpr, grid)], "cpp": [*map(cexpr, grid)], } ) inductor_meta = { "grid_type": PrecomputedGrid.__name__, "precomputed_grids": precomputed_grids, "extra_launcher_args": [*map(str, extra_launcher_args.values())], } extra_launcher_call_args = [*extra_launcher_args.keys()] # Distinguish between different functions using function id cache_key: Any = [id(kernel.fn)] if len(configs) > 0: for arg in kwargs.values(): # We need to key on non tensor arg only in autotune mode if not isinstance(arg, (ir.Buffer, ir.ReinterpretView)): cache_key.append(arg) cache_key.append(str(triton_meta)) cache_key.extend(str(inductor_meta)) cache_key = tuple(cache_key) if cache_key in self.user_defined_kernel_cache: return ( *self.user_defined_kernel_cache[cache_key], extra_launcher_call_args, ) name = f"{original_name}_{len(self.user_defined_kernel_cache)}" compile_wrapper = IndentedBuffer() if config.triton.unique_user_kernel_names: compile_wrapper.writeline(f"async_compile.triton({name!r}, '''") else: compile_wrapper.writeline(f"async_compile.triton({original_name!r}, '''") inductor_meta["kernel_name"] = name inductor_meta.update(TritonKernel.inductor_meta_common()) compile_wrapper.splice(gen_common_triton_imports()) compile_wrapper.splice( f""" @triton_heuristics.user_autotune( configs={[*map(config_to_dict, configs)]!r}, inductor_meta={inductor_meta!r}, triton_meta={triton_meta!r}, filename=__file__, custom_kernel=True, ) @triton.jit """ ) kernel_src = user_defined_triton_kernel_transitive_closure_source_code(kernel) if config.triton.unique_user_kernel_names: # We replace the original_name with the unique name. kernel_src = kernel_src.replace(f"def {original_name}(", f"def {name}(") kernel_src = kernel_src.replace("'''", "\\'\\'\\'") compile_wrapper.splice(kernel_src) current_device = V.graph.get_current_device_or_throw() compile_wrapper.writeline(f"''', device_str='{current_device.type}')") _, lineno = inspect.getsourcelines(kernel.fn) srcfile = inspect.getsourcefile(kernel.fn) metadata = f"# Original path: {srcfile}:{lineno}" self.define_kernel( name, compile_wrapper.getvalue(), metadata, ) # Add to the cache for the next use self.user_defined_kernel_cache[cache_key] = (name, triton_meta) return name, triton_meta, extra_launcher_call_args def generate_numel_expr(self, kernel_name: str, tree, suffix: Optional[str] = None): expr = f"{kernel_name}_{tree.prefix}numel" if suffix is not None: expr += f"_{suffix}" # We can get symbolic expressions here, like s0*64 # It is fine to have them here, but we need to handle them correctly as their own type # This is tricky to do, so we wrap in a custom type, distinct from scalars, but also from sympy* # scalars as well. # This is handled in `generate_args_decl` which has a correct comment of: TODO: only works for # constant now, need type info. I agree, this needs type info, and while this is not true type info # it suffices as a type hint for the purposes of producing the correct code for this type. arg = SymbolicCallArg(expr, tree.numel) self.writeline(SymbolicCallArgLine(self, arg, V.graph)) return arg def _generate_symbolic_call_arg_helper( self, arg: SymbolicCallArg, graph: GraphLowering ) -> None: self.writeline(f"{arg.inner} = {pexpr(arg.inner_expr)}") def generate_workspace_allocation(self, ws: WorkspaceArg): name = ws.get_name() line = AllocateLine(self, ws) if ws.zero_mode == WorkspaceZeroMode.UNINITIALIZED: self.writeline(line) elif ws.zero_mode == WorkspaceZeroMode.ZERO_ON_CALL: self.writeline(line) self.writeline(self.make_zero_buffer(name)) elif ws.zero_mode == WorkspaceZeroMode.ZERO_PER_GRAPH: prior = self.allocated_workspaces.get(name) if prior: assert isinstance(prior, AllocateLine) and isinstance( prior.node, WorkspaceArg ) # expand existing allocation prior.node = WorkspaceArg.maximum(prior.node, ws) else: self.writeline(line) self.writeline(self.make_zero_buffer(name)) self.allocated_workspaces[name] = line else: raise AssertionError(ws.zero_mode) if config.triton.autotune_at_compile_time: self.kernel_autotune_calls.writeline( PythonWrapperCodegen.make_allocation( self, name, ws.device, ws.dtype, shape=(V.graph.sizevars.size_hint(ws.count),), stride=(1,), ) ) if ws.zero_mode != WorkspaceZeroMode.UNINITIALIZED: self.kernel_autotune_calls.writeline( PythonWrapperCodegen.make_zero_buffer(self, name) ) def generate_workspace_deallocation(self, ws: WorkspaceArg): if ws.zero_mode != WorkspaceZeroMode.ZERO_PER_GRAPH: self.writeline(FreeIfNotReusedLine(self, ws)) def make_zero_buffer(self, name): return f"{name}.zero_(){self.ending}" def wrap_kernel_call(self, name, call_args): return f"{name}({', '.join(call_args)}){self.ending}" def generate_profiler_mark_wrapper_call(self, stack): self.wrapper_call.writeline("from torch.profiler import record_function") self.wrapper_call.writeline( f"with record_function('graph_{V.graph.graph_id}_inductor_wrapper_call'):" ) stack.enter_context(self.wrapper_call.indent()) def generate_start_graph(self): self.wrapper_call.writeline("start_graph()") def generate_end_graph(self): self.wrapper_call.writeline(f"end_graph({config.profile_bandwidth_output!r})") def generate_reset_kernel_saved_flags(self): self.wrapper_call.splice( f""" for kernel in globals().values(): if isinstance(kernel, {triton_heuristics.__name__}.CachingAutotuner): kernel.cuda_kernel_saved = False """ ) def generate_save_uncompiled_kernels(self): """ Precompile and save the CUBINs of the Triton kernels that haven't been precompiled and saved as a side effect of running the generated JIT model (Python wrapper). This can happen when the model contains control flow: only one pass through the control flow operators covers the kernels that are saved, the remaining kernels are not launched, hence not saved. The main purpose of this codegen is to compile and save the Triton kernels outside the active control flow path for subsequent AOTInductor code generation and compilation. """ self.wrapper_call.splice( f""" for kernel in globals().values(): if isinstance(kernel, {triton_heuristics.__name__}.CachingAutotuner): if not kernel.cuda_kernel_saved: if len(kernel.launchers) == 0: kernel.precompile() kernel.save_gpu_kernel( grid=(0, 0, 0), # use dummy grid stream="stream", # use dummy stream launcher=kernel.launchers[0], ) """ ) def prepare_triton_kernel_call(self, call_args): def wrap_arg(arg): if isinstance(arg, str): # dynamo wraps unspec variable as 0d CPU tensor, need convert to scalar return arg + ".item()" if should_unwrap_unspec_arg(arg) else arg elif isinstance(arg, (int, float, bool, SymbolicCallArg)): return str(arg) else: return pexpr(V.graph.sizevars.simplify(arg)) return [wrap_arg(arg) for arg in call_args] def generate_example_arg_value(self, arg, arg_type, raw_arg=None): if isinstance(arg_type, torch_dtype): if isinstance(raw_arg, ir.TMADescriptor): # first we generate the underlying buffer buf_name = raw_arg.get_tensor().get_name() buf = self.args_to_buffers[arg] elif self.args_to_buffers.get(arg): buf_name = arg buf = self.args_to_buffers[arg] else: assert raw_arg is not None, ( "V.graph.get_buffer(arg) and raw_arg can't be None at the same time" ) buf_name = f"tmp_arg_{self.kernel_autotune_tmp_arg_idx}" buf = raw_arg self.kernel_autotune_tmp_arg_idx += 1 assert buf is not None, f"Failed to find a buffer for arg {arg}" size = tuple( V.graph.sizevars.atomically_apply_size_hint( e, fallback=config.unbacked_symint_fallback, ) for e in buf.get_size() ) allocation_size = tuple( V.graph.sizevars.atomically_apply_size_hint( e, fallback=config.unbacked_symint_fallback, ) for e in V.graph.get_allocation_size(buf) ) stride = tuple( V.graph.sizevars.atomically_apply_size_hint( e, fallback=config.unbacked_symint_fallback, ) for e in buf.get_stride() ) device = buf.get_device() dtype = buf.get_dtype() offset = V.graph.sizevars.size_hint( buf.get_layout().offset, fallback=config.unbacked_symint_fallback, ) value = f"generate_example_value({size}, {stride}, '{device}', {dtype}, {offset}, {allocation_size})" self.kernel_autotune_calls.writeline(f"{buf_name} = {value}") if isinstance(raw_arg, ir.TMADescriptor): # generate another line initializing a host-side TMA # descriptor from the underlying buffer created above value = self._generate_tma_descriptor_call( desc=raw_arg, apply_size_hints=True, ) buf_name = arg self.kernel_autotune_calls.writeline(f"{buf_name} = {value}") return buf_name elif issubclass(arg_type, sympy.Basic) or isinstance(arg, SymbolicCallArg): # arg is a symbol or symbolic expression if isinstance(arg, str): if arg in self._meta_vars: return arg if raw_arg is None: return "None" arg = raw_arg if isinstance(arg, SymbolicCallArg): arg = arg.inner_expr if arg in V.graph.sizevars.inv_precomputed_replacements: arg = V.graph.sizevars.inv_precomputed_replacements[arg] return str( V.graph.sizevars.atomically_apply_size_hint( arg, fallback=config.unbacked_symint_fallback ) ) elif isinstance(arg, (str, int, float, bool)): return str(arg) elif isinstance(arg, list): return f"[{', '.join(self.generate_example_arg_value(a, type(a)) for a in arg)}]" else: raise NotImplementedError(f"Unsupported type {type(arg)}") def _grid_dim_str(self, grid_per_dim): if isinstance(grid_per_dim, list): return ( "[" + ", ".join(self._grid_dim_str(item) for item in grid_per_dim) + "]" ) else: return pexpr(grid_per_dim) def generate_kernel_call( self, kernel_name: str, call_args, *, device=None, triton=True, arg_types=None, raw_keys=None, raw_args=None, triton_meta=None, original_fxnode_name=None, ): """ Generates kernel call code. triton: Defines whether the backend uses Triton for codegen. Otherwise it uses the CUDA language when gpu=True, and C++ when gpu=False. """ # Store buffers corresponding to each call arg. # This is used to generate example args for autotuning later on. self.args_to_buffers.update( { arg: V.graph.try_get_buffer(arg) for arg in call_args if isinstance(arg, str) } ) device = device or V.graph.get_current_device_or_throw() self.writeline( KernelCallLine( self, kernel_name=kernel_name, call_args=call_args, raw_keys=raw_keys, raw_args=raw_args, arg_types=arg_types, triton=triton, triton_meta=triton_meta, device=device, graph_name=V.graph.name, original_fxnode_name=original_fxnode_name, ) ) def _generate_kernel_call_helper( self, kernel_name: str, call_args, *, device=None, triton=True, arg_types=None, raw_keys=None, raw_args=None, triton_meta=None, graph_name="", original_fxnode_name=None, ): device = device or V.graph.get_current_device_or_throw() if not (triton or device.type != "cpu"): self.writeline(self.wrap_kernel_call(kernel_name, call_args)) return call_args_str = self.prepare_triton_kernel_call(call_args) call_args_str = ", ".join(call_args_str) stream_name = PythonWrapperCodegen.write_get_raw_stream( self, device.index, graph_name ) if not triton: stream_ptr = f"c_void_p({stream_name})" self.writeline( f"{kernel_name}.{kernel_name}({call_args_str}, {stream_ptr})" ) return self.write_triton_header_once() if ( config.triton.autotune_at_compile_time and kernel_name not in self.kernel_autotune_names ): # Create example args for autotune in a separate epilogue assert arg_types is not None and len(call_args) == len(arg_types), ( "call_args and arg_types do not match" ) autotune_args = None if original_fxnode_name and V.graph.autotuning_mapping: autotune_args = V.graph.autotuning_mapping.get( original_fxnode_name, None ) def get_autotune_deletion_call() -> str: """After all the autotune kernel calls have been written (i.e. self.kernel_autotune_example_args is complete), returns a deletion call for all autotune example tensors that are unnecessary after kernel_name is called.""" tensors_to_delete = [ tensor for tensor, kn in self.kernel_autotune_example_args.values() if kn == kernel_name ] if tensors_to_delete: return f"del {', '.join(tensors_to_delete)}\n" return "" def infer_arg_by_inputs(raw_keys, raw_args, idx, reused_args): """We try to infer raw_arg (i.e. raw_args[idx]) from remaining raw_args. This is particularly useful for jagged cases, where the dimension is often being passed in as an input.""" target_arg = raw_args[idx] if target_arg in reused_args: return True for i, (raw_key, raw_arg) in enumerate(zip(raw_keys, raw_args)): if i == idx or not isinstance(raw_arg, IRNode): continue triton_input = "" if autotune_args and raw_key in autotune_args: triton_input = self.get_autotuning_input_name( # type: ignore[attr-defined] autotune_args[raw_key] ) if triton_input == "": continue try: layout = raw_arg.get_layout() for dim, s in enumerate(layout.size): if s == target_arg: reused_args[target_arg] = f"{triton_input}.shape[{dim}]" return True except NotImplementedError: # If layout for this IRNode is not implemented, we could just skip. # Only raise for other Error cases. continue return False all_args = [] if raw_args is None: # create a dummy raw_args for uniform behavior in the following loop assert raw_keys is None, "keys are not None but args are" raw_keys = [None] * len(call_args) raw_args = [None] * len(call_args) else: assert len(raw_args) == len(call_args), ( "call_args and raw_args do not match" ) reused_args = {} for i, (arg, arg_type, raw_key, raw_arg) in enumerate( zip(call_args, arg_types, raw_keys, raw_args) ): key = None if isinstance(arg, str) and "=" in str(arg): # arg may be passed in a kwarg style, and then we need to extract its value key, arg = arg.split("=") triton_input: Optional[str] = None if autotune_args and raw_key in autotune_args: triton_input = self.get_autotuning_input_name( # type: ignore[attr-defined] autotune_args[raw_key] ) if triton_input: arg_str = triton_input if not isinstance(arg_type, torch_dtype) and ( issubclass(arg_type, sympy.Basic) or isinstance(arg, SymbolicCallArg) ): reused_args[raw_arg] = arg_str elif raw_key == "" and infer_arg_by_inputs( raw_keys, raw_args, i, reused_args ): # Empty raw_key means this is a arg that's not native to the triton kernel, # and is being added by inductor. arg_str = reused_args[raw_arg] elif isinstance(arg_type, torch_dtype): # workspace allocation is already generated by `generate_workspace_allocation()` # in `TritonKernel.call_kernel()`. if re.match(r"^(workspace|semaphore)", arg): arg_str = arg elif arg not in self.kernel_autotune_example_args: arg_str = self.generate_example_arg_value( arg, arg_type, raw_arg ) else: arg_str = self.kernel_autotune_example_args[arg][0] self.kernel_autotune_example_args[arg] = (arg_str, kernel_name) else: arg_str = self.generate_example_arg_value(arg, arg_type, raw_arg) all_args.append(arg_str if key is None else f"{key}={arg_str}") self.kernel_autotune_calls.writeline( f"{kernel_name}.run({', '.join(all_args)}, stream={stream_name})" ) self.kernel_autotune_calls.writeline( DelayReplaceLine("", get_autotune_deletion_call, "") ) self.kernel_autotune_names.add(kernel_name) if V.graph.cpp_wrapper: # For cpp wrapper, no need to continue codegen for the main body return # add debug printer code for triton kernel calls at (jit) inductor level debug_printer_manager = V.graph.wrapper_code.debug_printer debug_printer_manager.set_printer_args(call_args, kernel_name, arg_types, None) with debug_printer_manager: self.writeline(f"{kernel_name}.run({call_args_str}, stream={stream_name})") self.write_triton_header_once() def writeline(self, line): self.lines.append(line) def writelines(self, lines): for line in lines: self.writeline(line) def enter_context(self, ctx): self.lines.append(LineContext(ctx)) def val_to_arg_str(self, s, type_=None): from torch.utils._triton import has_triton_package if has_triton_package(): import triton if isinstance(s, SymTypes): return pexpr(s.node.expr) elif isinstance(s, sympy.Expr): return pexpr(s) elif isinstance(s, (tuple, list)): @dataclasses.dataclass class Shim: ref: Any def __repr__(self): return self.ref # Explicitly call the Python version of val_to_arg_str return repr( type(s)(Shim(PythonWrapperCodegen.val_to_arg_str(self, a)) for a in s) ) elif isinstance(s, torch._ops.OpOverload): return _get_qualified_name(s) elif isinstance(s, (ir.Buffer, ir.MutableBox, ReinterpretView)): return s.codegen_reference() elif has_triton_package() and isinstance(s, triton.language.dtype): # type: ignore[possibly-undefined] return repr(s) elif isinstance(s, ir.GeneratorState): return s.codegen_reference() else: return repr(s) # The following methods are for memory management def make_buffer_allocation(self, buffer: BufferLike): device = buffer.get_device() dtype = buffer.get_dtype() shape = tuple(buffer.get_size()) allocation_shape = tuple(V.graph.get_allocation_size(buffer)) stride = tuple(buffer.get_stride()) return self.make_allocation( buffer.get_name(), device, dtype, shape, stride, allocation_shape ) def make_allocation( self, name, device, dtype, shape, stride, allocation_shape=None ): if allocation_shape is None: allocation_shape = shape codegen_shape_tuple = self.codegen_python_shape_tuple(shape) codegen_allocation_shape_tuple = self.codegen_python_shape_tuple( allocation_shape ) codegen_stride_tuple = self.codegen_python_shape_tuple(stride) if device.type in ("cpu", "cuda", "xpu"): # optimized path for faster allocations, saving ~2us versus the stuff below out = ( f"{name} = empty_strided_{device.type}(" f"{codegen_allocation_shape_tuple}, " f"{codegen_stride_tuple}, " f"{dtype})" ) # all other devices: else: out = ( f"{name} = empty_strided(" f"{codegen_allocation_shape_tuple}, " f"{codegen_stride_tuple}, " f"device='{device.type}', dtype={dtype})" ) if codegen_shape_tuple != codegen_allocation_shape_tuple: # need an extra as_strided call out = out + f".as_strided({codegen_shape_tuple}, {codegen_stride_tuple})" return out def make_comment(self, line): self.writeline(CommentLine(line)) def make_tensor_alias(self, new_name, old_name, comment=""): return f"{self.declare}{new_name} = {old_name}{self.ending} {self.comment} {comment}" def make_buffer_free(self, buffer: Union[BufferLike, ir.TorchBindObject]): return f"del {buffer.get_name()}" def make_free_by_names(self, names_to_del: list[str]): return f"del {', '.join(name for name in names_to_del)}" def codegen_exact_buffer_reuse(self, old_name: str, new_name: str, del_line: str): return f"{self.declare_maybe_reference}{new_name} = {old_name}{del_line}{self.ending} {self.comment} reuse" def make_buffer_reuse(self, old: BufferLike, new: BufferLike, delete_old: bool): assert old.get_dtype() == new.get_dtype() old_name = old.get_name() new_name = new.get_name() del_line = ";" if old_name not in V.graph.get_output_names() and delete_old: del_line = f"; {self.make_buffer_free(old)}" if old.get_size() == new.get_size() and old.get_stride() == new.get_stride(): return self.codegen_exact_buffer_reuse(old_name, new_name, del_line) reinterpret_view = self.codegen_reinterpret_view( old, new.get_size(), new.get_stride(), 0, self.wrapper_call.writeline ) return f"{self.declare}{new_name} = {reinterpret_view}{del_line} {self.comment} reuse" def codegen_deferred_allocation(self, name: str, view: ir.ReinterpretView) -> None: self.writeline( DeferredLine( name, f"{self.declare}{name} = {view.codegen_reference()}{self.ending} {self.comment} alias", ) ) def codegen_allocation(self, buffer: ir.Buffer): name = buffer.get_name() if ( name in V.graph.removed_buffers or name in self.allocated or isinstance(buffer, (ir.DonatedBuffer, ir.SubgraphBuffer)) ): return self.allocated.add(name) if ( isinstance( buffer.get_defining_op(), (ir.ExternKernelAlloc, ir.MultiOutput), ) and not buffer.should_allocate() ): return layout = buffer.get_output_spec() if isinstance(layout, ir.MutationLayoutSHOULDREMOVE): return if isinstance(layout, ir.NoneLayout): return if isinstance(layout, ir.NonOwningLayout): assert isinstance(layout.view, ir.ReinterpretView), ( f"unexpected {type(layout.view)}: {layout.view}" ) box = layout.view.data assert isinstance(box, ir.StorageBox), type(box) input_buffer = box.data assert isinstance(input_buffer, ir.Buffer), type(box) self.codegen_allocation(input_buffer) self.writeline(ReinterpretLine(self, input_buffer, buffer, layout)) return if isinstance(layout, ir.CommBufferLayout): self.writeline(CommBufferAllocateLine(self, buffer)) return self.writeline(AllocateLine(self, buffer)) def codegen_free(self, buffer): name = buffer.get_name() # can be freed but not reused if isinstance(buffer, (ir.InputBuffer, ir.TorchBindObject)): self.writeline(FreeLine(self, buffer)) return if isinstance(buffer.get_output_spec(), ir.CommBufferLayout): # Comm buffers are not eligible for in-place reuse. Their reuse is # achieved exclusively via buffer planning. self.writeline(CommBufferFreeLine(self, buffer)) return if not self.can_reuse(buffer): return self.freed.add(name) self.writeline(FreeIfNotReusedLine(self, buffer)) def can_reuse(self, input_buffer, output_buffer=None): name = input_buffer.get_name() return not ( name in V.graph.removed_buffers or ( name in V.graph.graph_inputs and not isinstance( V.graph.graph_inputs_original[name], ir.DonatedBuffer ) ) or name in V.graph.constants or name in V.graph.torchbind_constants or name in V.graph.never_reuse_buffers or name in self.freed ) def did_reuse(self, buffer, reused_buffer): # Check whether a given buffer was reused by a possible reuser in the wrapper codegen # Can be consulted from inside ir codegen, e.g. to determine whether a copy is needed return ( buffer.get_name() in self.reuses and self.reuses[buffer.get_name()] == reused_buffer.get_name() ) def codegen_inplace_reuse(self, input_buffer: ir.Buffer, output_buffer: ir.Buffer): assert can_match_buffer_size(input_buffer, output_buffer) self.codegen_allocation(input_buffer) self.freed.add(input_buffer.get_name()) self.allocated.add(output_buffer.get_name()) self.reuses[output_buffer.get_name()] = input_buffer.get_name() self.writeline(ReuseLine(self, input_buffer, output_buffer)) def codegen_unbacked_symbol_decl(self, symbol): name = str(symbol) if name in self.unbacked_symbol_decls: return name else: # When in CppWrapperCpu, we should only generate the declaration once self.unbacked_symbol_decls.add(name) return self.declare + name def codegen_unbacked_symbol_defs_for_outputs( self, output_name: str, outputs: Any, unbacked_bindings: Optional[dict[sympy.Symbol, pytree.KeyPath]], ) -> None: unbacked_bindings = resolve_unbacked_bindings( V.graph.sizevars.shape_env, unbacked_bindings ) if not unbacked_bindings: return # This code is designed to generate code expressions from symbolic paths (keypaths) # associated with certain symbols (unbacked bindings). These keypaths describe how # to access the unbacked symbol in a structured way. # For example, we might want to generate "u0 = outs[0].stride(1)"", where s = u0, and the keypath # describes the structure of "outs[0].stride(1)", like [SequenceKey(0), CallMethodKey("stride"), SequenceKey[1]]. for s, keypath in unbacked_bindings.items(): # `go` recursively constructs a code expression by processing each element of # the keypath and construct the expression incrementally. # For example, given output name outs and keypath [SequenceKey(0), CallMethodKey("stride", 1)], # it generates "outs[0]" based on SequenceKey(0), then recursively go("outs[0]", [CallMethodKey("stride"), ...]) def go(expr: str, keypath: pytree.KeyPath): if keypath == (): return expr if ( len(keypath) >= 2 and isinstance(keypath[0], CallMethodKey) and isinstance(keypath[1], pytree.SequenceKey) ): return go( f"{expr}.{keypath[0].name}({keypath[1].idx})", keypath[2:] ) elif isinstance(keypath[0], CallMethodKey): return go(f"{expr}.{keypath[0].name}()", keypath[1:]) elif isinstance(keypath[0], pytree.SequenceKey): return ( go(f"std::get<{keypath[0].idx}>({expr})", keypath[1:]) if V.graph.cpp_wrapper else go(f"{expr}[{keypath[0].idx}]", keypath[1:]) ) elif isinstance(keypath[0], DivideByKey): # TODO: need to assert divisibility # TODO: this is invalid C++ codegen return go(f"{expr}.__floordiv__({keypath[0].divisor})", keypath[1:]) else: raise AssertionError(f"unrecognized keypath {keypath}") # `go_outer` manages the top-level logic for generating the final expression. # It handles special cases for C++ code generation and adjusts # the keypath based on the context (e.g., single vs. multiple outputs). def go_outer(): # type: ignore[no-untyped-def] if V.graph.cpp_wrapper: # Special handling for the top level buffer access, # because self.get_name() is actually never bound; the # individual output arguments are bound by # generate_c_shim_fallback_kernel if len(outputs) == 1: out = outputs[0] # When fallback kernel returns a list consisting of a single tensor, # the output is represented as a MultiOutput with non empty indices. # In this case, we strip the first key path away. return go( outputs[0].get_name(), keypath[1:] if isinstance(out, ir.MultiOutput) and len(out.indices) != 0 else keypath, ) else: assert isinstance(keypath[0], pytree.SequenceKey) return go(outputs[keypath[0].idx].get_name(), keypath[1:]) else: return go(output_name, keypath) self.writeline( f"{self.codegen_unbacked_symbol_decl(s)} = {go_outer()}{self.ending}" ) def codegen_subgraph_by_inlining(self, subgraph, outer_inputs, outer_outputs): # TODO (desertfire) - This function is the old way of supporting # subgraph codegen by inlining subgraphs in the output code. For python # wrapper, we have moved to lifting subgraphs as functions, supported by # `codegen_subgraph` function. # # However this does not work with cpp wrapper. With cpp wrapper, we make # two passes and the kernels are shared from the first pass to the next. # Therefore, both the Python and CppWrapper need to share the some # codegen infra. For now, CppWrapperCpu has not been updated to lift the # subgraph as functions. Therefore for cpp_wrapper first pass with # PythonWrapper, we still fallback to the old way of inlining subgraphs # in the output code. Once we update CppWrapperCpu, we can remove this # function. def _codegen_subgraph_prefix(): assert len(subgraph.graph.graph_inputs) == len(outer_inputs) for inner_input, outer_input in zip( subgraph.graph.graph_inputs, outer_inputs ): self.writeline( f"{self.declare}{inner_input} = {outer_input}{self.ending}" ) def _codegen_subgraph_suffix(): assert len(subgraph.graph.graph_outputs) == len(outer_outputs) for inner_output, outer_output in zip( subgraph.graph.graph_outputs, outer_outputs ): self.writeline( f"{outer_output} = {inner_output.codegen_reference()}{self.ending}" ) try: self.push_codegened_graph(subgraph.graph) self.writeline(f"{self.comment} subgraph: {subgraph.name}") _codegen_subgraph_prefix() parent_graph = V.graph with V.set_graph_handler(subgraph.graph): subgraph.graph.codegen_subgraph( parent_graph=parent_graph, ) _codegen_subgraph_suffix() finally: self.pop_codegened_graph() def codegen_partition_call( self, partition_id: int, partition_signatures: ir.GraphPartitionSignature, ): """Generate code to call a graph partition""" input_deallocation = partition_signatures.input_deallocation output_nodes = partition_signatures.output_nodes input_names = list(input_deallocation.keys()) + [ symbol_input.name for symbol_input in partition_signatures.symbol_inputs ] inputs = ", ".join(input_names) + ("," if len(input_names) == 1 else "") output_names = [node.get_name() for node in output_nodes] outputs = ", ".join(output_names) + ("," if len(output_nodes) == 1 else "") # Create a list of inputs for the subgraph call self.writeline(f"partition{partition_id}_args = [{inputs}]") names_to_del = [ name for name, deallocate in input_deallocation.items() if deallocate ] if names_to_del: self.writeline(f"del {', '.join(names_to_del)}") # Call the subgraph launcher function self.writeline( f"({outputs}) = self.partitions[{partition_id}](partition{partition_id}_args)" ) self.writeline(f"del partition{partition_id}_args") def set_all_partition_names(self, num_partitions: int): self.all_partition_names = [f"partition_{idx}" for idx in range(num_partitions)] def codegen_subgraph_call_with_flattened_outputs( self, subgraph, outer_inputs, outer_flattened_outputs ): # Get the input and output names of the subgraph outer_output_names = ", ".join(outer_flattened_outputs) + ( "," if len(outer_flattened_outputs) == 1 else "" ) outer_input_names = ", ".join(outer_inputs) + ( "," if len(outer_inputs) == 1 else "" ) self.writeline(f"{subgraph.graph.name}_args = [{outer_input_names}]") # Call the subgraph launcher function self.writeline( f"({outer_output_names}) = {subgraph.graph.name}({subgraph.graph.name}_args)" ) def codegen_subgraph_call(self, subgraph, outer_inputs, outer_buffer_name): # Get the input and output names of the subgraph outer_input_names = ", ".join(outer_inputs) + ( "," if len(outer_inputs) == 1 else "" ) self.writeline(f"{subgraph.graph.name}_args = [{outer_input_names}]") # Since the buffers are already put into the args list, we can free the # buffers here. V.graph.scheduler.free_buffers() # Call the subgraph launcher function self.writeline( f"{outer_buffer_name} = {subgraph.graph.name}({subgraph.graph.name}_args)" ) def codegen_subgraph_common(self, subgraph): self.push_codegened_graph(subgraph.graph) self.writeline("") self.writeline(f"{self.comment} subgraph: {subgraph.name}") parent_graph = V.graph subgraph.graph.cpp_wrapper = parent_graph.cpp_wrapper if subgraph.graph.name not in self.already_codegened_subgraphs: # If it is already codegened, the parent wrapper already has # subgraph fn by name subgraph.graph.name with V.set_graph_handler(subgraph.graph): # do not graph partition for subgraph with config.patch("graph_partition", False): # Call the codegen of subgraph recursively subgraph_code, _ = subgraph.graph.codegen() self.already_codegened_subgraphs.add(subgraph.graph.name) self.define_subgraph_launcher_fn(subgraph_code.value) def codegen_subgraph_with_flattened_outputs( self, subgraph, outer_inputs, outer_flattened_outputs ): self.codegen_subgraph_common(subgraph) self.codegen_subgraph_call_with_flattened_outputs( subgraph, outer_inputs, outer_flattened_outputs ) def codegen_subgraph(self, subgraph, outer_inputs, outer_buffer_name): # Codegen subgraph by recursively calling the codegen for the subgraph. # This lifts the subgraph as a function in the output code. self.codegen_subgraph_common(subgraph) self.codegen_subgraph_call(subgraph, outer_inputs, outer_buffer_name) def codegen_invoke_subgraph(self, invoke_subgraph): name = invoke_subgraph.get_name() self.writeline(f"{name} = [None] * {len(invoke_subgraph.outputs)}") outer_inputs = [buf.codegen_reference() for buf in invoke_subgraph.inputs] if V.graph.aot_mode: outer_outputs = [ f"{name}[{i}]" for i in range(len(invoke_subgraph.outputs)) ] self.codegen_subgraph_by_inlining( invoke_subgraph.subgraph, outer_inputs, outer_outputs ) else: self.codegen_subgraph(invoke_subgraph.subgraph, outer_inputs, name) def codegen_conditional(self, conditional): name = conditional.get_name() outer_inputs = [buf.codegen_reference() for buf in conditional.operands] predicate = conditional.predicate.codegen_reference() if not isinstance(conditional.predicate, ir.ShapeAsConstantBuffer): # move the Tensor predicate to host predicate = f"{predicate}.item()" self.writeline(f"{name} = [None] * {len(conditional.outputs)}") self.writeline(f"if {predicate}:") self.writeline(EnterSubgraphLine(self, conditional.true_subgraph.graph)) if V.graph.aot_mode: outer_outputs = [f"{name}[{i}]" for i in range(len(conditional.outputs))] self.codegen_subgraph_by_inlining( conditional.true_subgraph, outer_inputs, outer_outputs ) else: self.codegen_subgraph(conditional.true_subgraph, outer_inputs, name) self.writeline(ExitSubgraphLine(self)) self.writeline("else:") self.writeline(EnterSubgraphLine(self, conditional.false_subgraph.graph)) if V.graph.aot_mode: outer_outputs = [f"{name}[{i}]" for i in range(len(conditional.outputs))] self.codegen_subgraph_by_inlining( conditional.false_subgraph, outer_inputs, outer_outputs ) else: self.codegen_subgraph(conditional.false_subgraph, outer_inputs, name) self.writeline(ExitSubgraphLine(self)) def codegen_while_loop(self, while_loop): name = while_loop.get_name() outer_carried_inputs = [ buf.codegen_reference() for buf in while_loop.carried_inputs ] outer_additional_inputs = [ buf.codegen_reference() for buf in while_loop.additional_inputs ] self.writeline(f"{name} = [None] * {len(outer_carried_inputs)}") for i, inp in enumerate(outer_carried_inputs): # set the initial state before the loop self.writeline(f"{name}[{i}] = {inp}") cond_outer_inputs = [ *[f"{name}[{i}]" for i in range(len(outer_carried_inputs))], *outer_additional_inputs, ] cond_outer_outputs = [f"{name}_cond_result"] body_outer_inputs = list( cond_outer_inputs ) # same inputs for cond_fn and body_fn # Carry over the state from body_fn. Note: We only carry over # the carried_inputs part of the inputs, the additional ones # are passed in as they're before. body_outer_outputs = body_outer_inputs[: len(outer_carried_inputs)] self.writeline("while True:") self.writeline(EnterSubgraphLine(self, while_loop.cond_subgraph.graph)) if V.graph.aot_mode: self.codegen_subgraph_by_inlining( while_loop.cond_subgraph, cond_outer_inputs, cond_outer_outputs ) else: self.codegen_subgraph_with_flattened_outputs( while_loop.cond_subgraph, cond_outer_inputs, cond_outer_outputs ) self.writeline( f"if not {cond_outer_outputs[0]}: break" ) # condition doesn't hold self.writeline(ExitSubgraphLine(self)) self.writeline(EnterSubgraphLine(self, while_loop.body_subgraph.graph)) if V.graph.aot_mode: self.codegen_subgraph_by_inlining( while_loop.body_subgraph, body_outer_inputs, body_outer_outputs ) else: self.codegen_subgraph_with_flattened_outputs( while_loop.body_subgraph, body_outer_inputs, body_outer_outputs ) self.writeline(ExitSubgraphLine(self)) @staticmethod def statically_known_int_or_none(x): try: if getattr(x, "free_symbols", None): # _maybe_evaluate_static will return (s0 // (2 // s0)) as 2, but # the actual codegen will still generate the full expression here. return None if isinstance(x, int): return x val = V.graph._shape_env._maybe_evaluate_static(x) if val is None: return val return int(val) # type: ignore[call-overload] except Exception: return None @staticmethod def statically_known_list_of_ints_or_none(lst): result = [] for x in lst: num = PythonWrapperCodegen.statically_known_int_or_none(x) if num is None: return None result.append(num) return result @staticmethod def is_statically_known_list_of_ints(lst): return ( PythonWrapperCodegen.statically_known_list_of_ints_or_none(lst) is not None ) @staticmethod def static_shape_for_buffer_or_none(buffer): return PythonWrapperCodegen.statically_known_list_of_ints_or_none( buffer.get_size() ) @staticmethod def can_prove_buffer_has_static_shape(buffer): return PythonWrapperCodegen.static_shape_for_buffer_or_none(buffer) is not None class SubgraphPythonWrapperCodegen(PythonWrapperCodegen): """ A wrapper codegen that generates code for a subgraph. For most of the methods, we rely on the implementation in the PythonWrapperCodegen. But we override a few functions to produce cleaner code (like avoiding writing imports twice in the output code) """ def __init__( self, subgraph_name: str, parent_wrapper: PythonWrapperCodegen, partition_signatures: Optional[ir.GraphPartitionSignature] = None, ): # It is necessary to set the subgraph_name before calling super __init__ # because __init__ calls set_launcher_fn_name self.subgraph_name = subgraph_name self.parent_wrapper = parent_wrapper self.partition_signatures = partition_signatures super().__init__() def set_launcher_fn_name(self) -> None: # This sets up the name of the function containing the launcher code of # the subgraph. self.launcher_fn_name = self.subgraph_name def write_header(self) -> None: pass def add_benchmark_harness(self, output): pass def benchmark_compiled_module(self, output): pass def write_async_compile_wait(self): pass def next_kernel_suffix(self) -> str: # Ensures that subgraphs kernels do not clash with each other return self.parent_wrapper.next_kernel_suffix() def generate_after_suffix(self, result: IndentedBuffer) -> None: return def write_launcher_fn_call_get_indent(self) -> int: self.prefix.splice( f""" def {self.launcher_fn_name}(args): """ ) prefix_indent = 1 return prefix_indent def get_wrapper_call_indent(self) -> int: return 1 def get_graph_inputs( self, ) -> dict[str, Union[ir.TensorBox, ir.TorchBindObject, sympy.Expr]]: if signature := self.partition_signatures: inputs = signature.input_nodes | { str(s): s for s in signature.symbol_inputs } else: inputs = V.graph.graph_inputs return inputs def get_graph_input_names(self) -> list[str]: if signature := self.partition_signatures: names = list(signature.input_nodes.keys()) + [ symbol_input.name for symbol_input in signature.symbol_inputs ] else: names = V.graph.graph_input_names return names def get_graph_outputs(self) -> list[IRNode]: if signature := self.partition_signatures: outputs = signature.output_nodes else: outputs = V.graph.graph_outputs return outputs def codegen_allocation(self, buffer: ir.Buffer): name = buffer.get_name() if (signature := self.partition_signatures) and name in signature.input_nodes: # skip allocation if buffer is a subgraph input. # This allows reusing an input buffer in graph partition, # although this is not allowed in general. return super().codegen_allocation(buffer) @cache_on_self def write_triton_header_once(self) -> None: # TODO: Uncomment in future. This will be needed to support subgraph # codegen for cpp wrapper. # if config.triton.autotune_at_compile_time: # import_str = self.triton_header_str() # self.kernel_autotune_calls.splice(import_str) self.parent_wrapper.write_triton_header_once() @cache_on_self def write_get_raw_stream_header_once(self) -> None: # TODO: Uncomment in future. This will be needed to support subgraph # codegen for cpp wrapper. # if config.triton.autotune_at_compile_time: # self.kernel_autotune_calls.writeline( # V.graph.device_ops.import_get_raw_stream_as("get_raw_stream") # ) self.parent_wrapper.write_get_raw_stream_header_once()