from __future__ import annotations import collections import contextlib import dataclasses import functools import itertools import logging import math import operator import os from typing import Any, Counter, Dict, Iterable, List, Optional, Set, Tuple import sympy import torch import torch._logging from torch._prims_common import is_integer_dtype from torch.utils._sympy.functions import FloorDiv, ModularIndexing from torch.utils._sympy.value_ranges import ValueRanges from ..._dynamo.utils import counters from .. import config, ir, scheduler from ..codecache import code_hash, get_path, PyCodeCache from ..dependencies import MemoryDep, StarDep from ..ir import IRNode, ReductionHint, TritonTemplateBuffer from ..optimize_indexing import indexing_dtype_strength_reduction from ..scheduler import BaseScheduling from ..triton_heuristics import AutotuneHint from ..utils import ( do_bench, get_fused_kernel_name, get_kernel_metadata, green_text, is_welford_reduction, next_power_of_2, Placeholder, sympy_product, sympy_subs, sympy_symbol, unique, yellow_text, ) from ..virtualized import ops, V from ..wrapper_benchmark import get_kernel_category_by_source_code from .common import ( CSEVariable, DeferredLine, free_symbol_startswith, IndentedBuffer, index_prevent_reordering, Kernel, OpOverrides, PythonPrinter, SizeArg, TensorArg, ) from .triton_utils import config_of, signature_of, signature_to_meta log = logging.getLogger(__name__) perf_hint_log = torch._logging.getArtifactLogger(__name__, "perf_hints") schedule_log = torch._logging.getArtifactLogger(__name__, "schedule") fusion_log = torch._logging.getArtifactLogger(__name__, "fusion") class TritonPrinter(PythonPrinter): def _print_floor(self, expr): assert len(expr.args) == 1 return f"tl.math.floor({self.paren(self._print(expr.args[0]))})" def _helper_sqrt(self, expr): return f"tl.math.sqrt({self.paren(self._print(expr))}.to(tl.float32))" def _print_Where(self, expr): c = self.doprint(expr.args[0]) p = self.doprint(expr.args[1]) q = self.doprint(expr.args[2]) return f"tl.where({c}, {p}, {q})" def _print_Min(self, expr): nargs = len(expr.args) if len(expr.args) == 1: return self._print(expr.args[0]) mid = len(expr.args) // 2 a = self._print(sympy.Min(*expr.args[:mid])) b = self._print(sympy.Min(*expr.args[mid:])) return f"tl.math.min({a}, {b})" def _print_Max(self, expr): nargs = len(expr.args) if len(expr.args) == 1: return self._print(expr.args[0]) mid = len(expr.args) // 2 a = self._print(sympy.Max(*expr.args[:mid])) b = self._print(sympy.Max(*expr.args[mid:])) return f"tl.math.max({a}, {b})" def _print_Abs(self, expr): assert len(expr.args) == 1 return f"tl.abs({self._print(expr.args[0])})" texpr = TritonPrinter().doprint pexpr = PythonPrinter().doprint def triton_compute_type(dtype): triton_type_name = str(dtype).split(".")[-1] if triton_type_name == "bool": triton_type_name = "int1" elif triton_type_name in ("float16", "bfloat16"): # float16 math is done in float32 inside the kernel triton_type_name = "float32" elif triton_type_name == "float8_e4m3fn": triton_type_name = "float8e4nv" elif triton_type_name == "float8_e5m2": triton_type_name = "float8e5" return f"tl.{triton_type_name}" def triton_acc_type(dtype): if is_integer_dtype(dtype) and dtype.is_signed: nbits = 64 if dtype == torch.int64 else 32 return f"tl.int{nbits}" return triton_compute_type(dtype) def triton_constant(value): if value == float("inf"): return 'float("inf")' elif value == float("-inf"): return 'float("-inf")' elif math.isnan(value): return 'float("nan")' return repr(value) class TritonCSEVariable(CSEVariable): def __init__(self, name, bounds: ValueRanges): super().__init__(name, bounds) # We'll use this to track which masks the variable needs when used for indirect indexing self.mask_vars: Set[str] = set() def update_on_args(self, name, args, kwargs): # When making a variable that is going to be used in indirect indexing # if a where clause is used it should mean that the result is always a # valid index, so you shouldn't include any of the dependent variables # in the resulting load mask if name == "where": return for arg in args: if isinstance(arg, TritonCSEVariable): self.mask_vars.update(arg.mask_vars) elif isinstance(arg, sympy.Symbol) and arg.name[0] in "xyr": # most of the time index vars don't need masks associated with them # however, when index vars are used to compute indices for indirect reads # those reads should subsequently be masked, self.mask_vars.update({f"{arg.name[0]}mask"}) class TritonOverrides(OpOverrides): """Map element-wise ops to Triton""" @staticmethod def to_dtype(x, dtype: torch.dtype, src_dtype: Optional[torch.dtype] = None): def _get_min_elements_per_thread( src_dtype: torch.dtype, dst_dtype: torch.dtype ) -> int: if src_dtype == dst_dtype: # No data type conversion is needed. No requirements on min_elem_per_thread. return 0 # fp8 data type conversions has min_elem_per_thread requirements. # Refer to Triton implementations here: # https://github.com/openai/triton/blob/10f59d8ce04052521c1bc0cb3a3f8b98918fc7e3/lib/Conversion/TritonGPUToLLVM/ElementwiseOpToLLVM.cpp#L10. fp8_dtypes = { torch.float8_e4m3fn, torch.float8_e5m2, } # Triton doesn't support type conversions between fp8_e4m3 and fp8_e5m2. assert not ( src_dtype in fp8_dtypes and dst_dtype in fp8_dtypes and src_dtype != dst_dtype ), "Conversions between float8_e5m2 and float8_e4m3fn is not supported!" if src_dtype == torch.float8_e5m2 or dst_dtype == torch.float8_e5m2: return 4 if src_dtype == torch.float8_e4m3fn or dst_dtype == torch.float8_e4m3fn: return 2 # No requirements on min_elem_per_thread. return 0 if src_dtype is not None: # Both dtype and src_dtype are set. This is used by torch to(dtype=dtype). # It takes the maximum min_elem_per_thread if there are multiple fp8 conversions # in the same kernel. V.kernel.min_elem_per_thread = max( _get_min_elements_per_thread(src_dtype, dtype), V.kernel.min_elem_per_thread, ) if dtype == torch.bool: return f"({x} != 0)" elif dtype == torch.uint8: # to work around llvm uint conversion semantics # that produces 0's for negative values return f"{x}.to(tl.int8).to(tl.uint8)" return f"{x}.to({triton_compute_type(dtype)})" @staticmethod def to_dtype_bitcast(x, dtype: torch.dtype): return f"{x}.to({triton_compute_type(dtype)}, bitcast=True)" @classmethod def constant(cls, value, dtype): if dtype == torch.uint8: # tl.full is broken for uint8, remove once triton is fixed. # See openai/triton#1919 tmp = cls.constant(value, torch.int16) return cls.to_dtype(tmp, dtype) type_ = torch._prims_common.dtype_to_type(dtype) triton_val = triton_constant(type_(value)) triton_type = triton_compute_type(dtype) if triton_type == "tl.float32": # Float constants are always f32 in triton return triton_val # NOTE: We use a tensor here in order to get the expected type. # Otherwise, e.g. float64 constants would be trunctated to float32. # Also, we could just use shape=[1] here but starting with the correct # ndim avoids extra `tt.expand_dim` ops appearing in the triton IR. ndim = V.kernel.triton_tensor_ndim() shape = [1] * ndim return f"tl.full({shape}, {triton_val}, {triton_type})" @staticmethod def abs(x): return f"tl.abs({x})" @staticmethod def libdevice_abs(x): return f"tl.math.abs({x})" @staticmethod def exp(x): return f"tl.exp({x})" @staticmethod def libdevice_exp(x): return f"tl.math.exp({x})" @staticmethod def exp2(x): return f"tl.math.exp2({x})" @staticmethod def expm1(x): return f"tl.math.expm1({x})" @staticmethod def sqrt(x): return f"tl.sqrt({x})" @staticmethod def libdevice_sqrt(x): return f"tl.math.sqrt({x})" @staticmethod def relu(x): bug = config.triton.inject_relu_bug_TESTING_ONLY if bug == "compile_error": return "compile error!" elif bug == "runtime_error": # NB: this only triggers runtime error as long as input # is not all zero return f'triton_helpers.device_assert_then({x} == 0, "injected assert fail", {x})' elif bug == "accuracy": return f"{x} + 1" elif bug is None: return ops.maximum("0", x) else: raise AssertionError( f"unrecognized config triton.inject_relu_bug_TESTING_ONLY = {bug!r}" ) @staticmethod def minimum(a, b): return f"triton_helpers.minimum({a}, {b})" @staticmethod def maximum(a, b): return f"triton_helpers.maximum({a}, {b})" @staticmethod def where(a, b, c): return f"tl.where({a}, {b}, {c})" @staticmethod def cos(x): return f"tl.cos({x})" @staticmethod def libdevice_cos(x): return f"tl.math.cos({x})" @staticmethod def sin(x): return f"tl.sin({x})" @staticmethod def libdevice_sin(x): return f"tl.math.sin({x})" @classmethod def index_expr(cls, expr, dtype): index_str, mask_vars, mask, expand_str = V.kernel.indexing(expr) # This is called from CSEProxy.__getattr__, so we'll set the bounds there var = V.kernel.cse.generate(V.kernel.compute, index_str) if dtype not in {torch.int32, torch.int64}: var = V.kernel.cse.generate(V.kernel.compute, cls.to_dtype(var, dtype)) var.mask_vars = mask_vars return var @staticmethod def masked(mask, body, other): with V.kernel.mask_loads(mask) as new_mask: result = body() # Take dtype from result to prevent accidental promotion other = V.kernel.cse.generate( V.kernel.compute, f"tl.full({result}.shape, {triton_constant(other)}, {result}.dtype)", ) return ops.where(new_mask, result, other) @staticmethod def lgamma(x): return f"tl.math.lgamma({x})" @staticmethod def erf(x): return f"tl.math.erf({x})" @staticmethod def cosh(x): return f"tl.math.cosh({x})" @staticmethod def sinh(x): return f"tl.math.sinh({x})" @staticmethod def acos(x): return f"tl.math.acos({x})" @staticmethod def acosh(x): return f"tl.math.acosh({x})" @staticmethod def asin(x): return f"tl.math.asin({x})" @staticmethod def asinh(x): return f"tl.math.asinh({x})" @staticmethod def atan2(x, y): return f"tl.math.atan2({x}, {y})" @staticmethod def atan(x): return f"tl.math.atan({x})" @staticmethod def atanh(x): return f"tl.math.atanh({x})" @staticmethod def copysign(x, y): return f"tl.math.copysign({x}, {y})" @staticmethod def erfc(x): return f"tl.math.erfc({x})" @staticmethod def erfinv(x): return f"tl.math.erfinv({x})" @staticmethod def hypot(x, y): return f"tl.math.hypot({x}, {y})" @staticmethod def log10(x): return f"tl.math.log10({x})" @staticmethod def nextafter(x, y): return f"tl.math.nextafter({x}, {y})" @staticmethod def logical_and(a, b): return f"{a} & {b}" @staticmethod def logical_not(a): return f"{a} == 0" @staticmethod def logical_or(a, b): return f"{a} | {b}" @staticmethod def logical_xor(a, b): return f"({a} ^ {b})" @staticmethod def bitwise_and(a, b): return f"{a} & {b}" @staticmethod def bitwise_not(a): return f"~{a}" @staticmethod def bitwise_or(a, b): return f"{a} | {b}" @staticmethod def bitwise_xor(a, b): return f"{a} ^ {b}" @staticmethod def bitwise_left_shift(a, b): return f"{a} << {b}" @staticmethod def bitwise_right_shift(a, b): return f"{a} >> {b}" @staticmethod def rand(seed, offset): offset = f"({offset}).to(tl.uint32)" return f"tl.rand({seed}, {offset})" @staticmethod def randn(seed, offset): offset = f"({offset}).to(tl.uint32)" return f"tl.randn({seed}, {offset})" @staticmethod def randint64(seed, offset, low, high): offset = f"({offset}).to(tl.uint32)" return f"triton_helpers.randint64({seed}, {offset}, {low}, {high})" @staticmethod def load_seed(name, offset): var = V.kernel.args.input(name) return ( f"tl.load({var} + {V.kernel.args.seed_offset('load_seed_offset', offset)})" ) @staticmethod def rsqrt(x): return f"tl.math.rsqrt({x})" @staticmethod def log1p(x): return f"tl.math.log1p({x})" @staticmethod def tan(x): return f"tl.math.tan({x})" @staticmethod def tanh(x): return f"tl.math.tanh({x})" @staticmethod def sigmoid(x): return f"tl.sigmoid({x})" @staticmethod def libdevice_sigmoid(x): return f"1/(1 + tl.math.exp(-({x})))" @staticmethod def signbit(x): # XX: This is wrong for the value -0.0 in floating point return f"tl.math.signbit({x}) if ({x}).dtype is tl.float32 else {x} < 0" @staticmethod def fmod(a, b): return f"tl.math.fmod({a}, {b})" @staticmethod def pow(a, b): return f"tl.math.pow({a}, {b})" @staticmethod def log(x): return f"tl.log({x})" @staticmethod def libdevice_log(x): return f"tl.math.log({x})" @staticmethod def isinf(x): return f"tl.math.isinf({x}).to(tl.int1)" @staticmethod def isnan(x): return f"tl.math.isnan({x}).to(tl.int1)" @staticmethod def round(x): return f"tl.math.nearbyint({x})" @staticmethod def floor(x): return f"tl.math.floor({x})" @staticmethod def floordiv(a, b): # See the comment in lowering.div_mode. a and b are integer type. # Similar to div_floor_kernel_cuda in pytorch core. # Notice that // in triton behaves as truncdiv instead of floordiv quot = f"{a} // {b}" rem = f"{a} % {b}" return f"tl.where(({a} < 0) != ({b} < 0), tl.where({rem} != 0, {quot} - 1, {quot}), {quot})" @staticmethod def sign(x): def to_int(s): return f"{s}.to(tl.int8)" left = to_int(ops.lt("0", x)) right = to_int(ops.lt(x, "0")) sub = ops.sub(left, right) return f"{sub}.to({x}.dtype)" @staticmethod def trunc(x): return f"tl.math.trunc({x})" @staticmethod def truncdiv(a, b): # See the comment in lowering.div_mode. a and b are integer type. # Notice that // in triton behaves as truncdiv instead of floordiv return f"{a} // {b}" @staticmethod def ceil(x): return f"tl.math.ceil({x})" @dataclasses.dataclass class IterationRanges: """ Each range tree represents multiple sets of iteration indexing in a single tiled dimension in the output kernel. If you have two loops ranges one (4, 3, 2) and another (4, 6), then the range tree will be: 4 (i0) 3 (i1) 6 (i3) 2 (i2) Where i0 is shared between both loops, but then the split into different indexing vars. All loop ranges must iterate over the same number of elements. """ def __init__( self, name: str, var_list: List[sympy.Symbol], var_ranges: Dict[sympy.Symbol, sympy.Expr], numel: sympy.Expr, prefix: str, *, kernel: TritonKernel, divisor=sympy.Integer(1), length=sympy.Integer(1), ): super().__init__() self.name = name self.var_list = var_list self.var_ranges = var_ranges self.numel = numel self.prefix = prefix self.divisor = divisor self.length = length self.kernel = kernel def is_loop(self): return self.prefix == "r" and not self.kernel.persistent_reduction class IterationRangesRoot(IterationRanges): def __init__( self, name: str, numel: sympy.Expr, prefix: str, index: int, kernel: TritonKernel, pid_cache=None, ): if pid_cache is None: pid_cache = {} super().__init__( name=name, var_list=[], var_ranges={}, numel=numel, prefix=prefix, kernel=kernel, ) self.index = index # Store all the nodes in one flat list self.nodes: Dict[sympy.Expr, IterationRangesEntry] = {} # This is for re-ordering program ID in triton mm template # pid_cache["tl.program_id(0)"] = pid_m self.pid_cache: Dict[str, str] = pid_cache def cache_clear(self): for node in self.nodes.values(): node.cache_clear() def lookup(self, divisor, length): """ Lookup a given RangeTreeEntry, creating it if needed """ if V.graph.sizevars.statically_known_equals(divisor * length, self.numel): expr = FloorDiv(sympy_symbol(f"{self.prefix}index"), divisor) else: expr = ModularIndexing(sympy_symbol(f"{self.prefix}index"), divisor, length) if expr not in self.nodes: node = IterationRangesEntry( f"{self.prefix}{next(V.kernel.iter_vars_count)}", divisor, length, expr, self, ) V.kernel.range_tree_nodes[node.symbol()] = node self.var_list.append(node.symbol()) self.var_ranges[node.symbol()] = length self.nodes[expr] = node return self.nodes[expr] def construct_entries(self, lengths: List[sympy.Expr]): divisor = sympy.Integer(1) itervars = [] for length in reversed(lengths): itervars.append(self.lookup(divisor, length)) divisor = divisor * length return list(reversed(itervars)) def construct(self, lengths: List[sympy.Expr]): return [e.symbol() for e in self.construct_entries(lengths)] def vars_and_sizes(self, index: sympy.Expr): """Figure out vars from this tree used in index""" nodes = [V.kernel.range_tree_nodes.get(s) for s in index.free_symbols] nodes = [n for n in nodes if n and n.prefix == self.prefix] nodes.sort(key=lambda x: V.graph.sizevars.size_hint(x.divisor)) divisor = sympy.Integer(1) index_vars = [] sizes = [] def add(node): nonlocal divisor index_vars.append(node.symbol()) sizes.append(node.length) divisor = divisor * node.length for node in nodes: if not V.graph.sizevars.statically_known_equals(node.divisor, divisor): # fill in unused index var add(self.lookup(divisor, FloorDiv(node.divisor, divisor))) divisor = node.divisor add(node) if not V.graph.sizevars.statically_known_equals(self.numel, divisor): # fill in unused index var add(self.lookup(divisor, FloorDiv(self.numel, divisor))) return list(reversed(index_vars)), list(reversed(sizes)) def ranges_code(self): size = self.kernel.indexing_size_str(self.index, self.prefix) index_dtype = self.kernel.index_dtype convert = f".to({index_dtype})" if index_dtype != "tl.int32" else "" return f"tl.arange(0, {self.prefix.upper()}BLOCK){size}{convert}" def scalar_code(self, value): index_dtype = self.kernel.index_dtype ndim = self.kernel.triton_tensor_ndim() size = [1] * ndim return f"tl.full({size}, {value}, {index_dtype})" def get_pid(self): key = f"tl.program_id({self.index})" pid = self.pid_cache.get(key, key) if self.kernel.index_dtype != "tl.int32": return f"{pid}.to({self.kernel.index_dtype})" return pid def codegen_header(self, code, no_x_dim=False): x = self.prefix if self.is_loop(): code.writeline(f"{self.name} = {x}offset + {x}base") elif x == "r" and self.kernel.persistent_reduction: # no need to "roffset = " code.writeline( f"{self.name} = {self.ranges_code()}", ) else: if not no_x_dim: line = f"{x}offset + {self.ranges_code()}" else: line = self.scalar_code(f"{x}offset") code.writelines( [ f"{x}offset = {self.get_pid()} * {x.upper()}BLOCK", f"{self.name} = {line}", ] ) code.writeline(f"{x}mask = {self.name} < {x}numel") class IterationRangesEntry(IterationRanges): def __init__( self, name: str, divisor: sympy.Expr, length: sympy.Expr, expr: sympy.Expr, parent: IterationRanges, ): super().__init__( name=name, numel=parent.numel / length, var_list=parent.var_list, var_ranges=parent.var_ranges, prefix=parent.prefix, divisor=divisor, length=length, kernel=parent.kernel, ) self.parent = parent self.codegen = functools.lru_cache(None)(self._codegen) self.expr = expr def set_name(self, name): self.codegen = lambda: name # type: ignore[assignment] self.codegen.cache_clear = lambda: None # type: ignore[method-assign] self.name = name def cache_clear(self): self.codegen.cache_clear() def writeline(self, line): if self.is_loop(): V.kernel.indexing_code.writeline(line) else: # lift non-reduction stores outside loop V.kernel.body.writeline(line) def _codegen(self): self.writeline(f"{self.name} = " + texpr(V.kernel.rename_indexing(self.expr))) return self.name def precomputed_args(self): # for dynamic shapes, find parts of indexing expressions that have to be precomputed precomputed_args: List[sympy.Expr] = [] if isinstance(self.expr, sympy.Symbol): return precomputed_args assert isinstance(self.expr, (FloorDiv, ModularIndexing)), type(self.expr) for arg in self.expr.args[1:]: if not isinstance(arg, (sympy.Integer, sympy.Symbol)): symbols = arg.free_symbols if len(symbols) > 0 and all(s.name.startswith("s") for s in symbols): precomputed_args.append(arg) return precomputed_args def symbol(self): return sympy_symbol(self.name) def __hash__(self): return hash(self.name) def __eq__(self, other): return self.name == other.name class TritonKernel(Kernel): overrides = TritonOverrides # type: ignore[assignment] sexpr = pexpr def __init__( self, *groups, index_dtype, mutations=None, pid_cache=None, reduction_hint=ReductionHint.DEFAULT, min_elem_per_thread=0, ): if pid_cache is None: pid_cache = {} super().__init__() self.numels = [V.graph.sizevars.simplify(s) for s in groups] self.mutations = mutations self.range_trees: List[IterationRangesRoot] = [] self.range_tree_nodes = {} self.iter_vars_count = itertools.count() self.inside_reduction = self.numels[-1] != 1 self.body = IndentedBuffer() self.indexing_code = IndentedBuffer() self.suffix: IndentedBuffer = IndentedBuffer() # type: ignore[assignment] self.outside_loop_vars = set() self.reduction_hint = reduction_hint self.index_dtype = index_dtype self.min_elem_per_thread = min_elem_per_thread self.last_usage = set() self.persistent_reduction = self.should_use_persistent_reduction() self.no_x_dim = ( self.reduction_hint == ReductionHint.INNER and self.persistent_reduction and len(self.numels) == 2 and self.numels[-1] >= 256 ) self.initialize_range_tree(pid_cache) # A set of autotuning hints to pass as part of triton_meta self.autotune_hints: Set[AutotuneHint] = set() # define this in a closure to make cache local to object @functools.lru_cache(None) def simplify_indexing(index: sympy.Expr): index = V.graph.sizevars.simplify_with_ranges(index, self.var_ranges()) for tree in self.range_trees: index = self.combine_contiguous_dims(index, tree) return index self.simplify_indexing = simplify_indexing def should_use_persistent_reduction(self): """ Heuristic to set self.persistent_reduction and add guards if needed. """ if not (self.inside_reduction and config.triton.persistent_reductions): return False threshold = { ReductionHint.INNER: 1024, }.get(self.reduction_hint, 64) last_numel = self.numels[-1] if not isinstance(last_numel, (int, sympy.Integer)): # Not static return False hint = V.graph.sizevars.size_hint(last_numel) if hint > threshold: return False # will need to recompile if we cross a larger power of 2 boundary V.graph.sizevars.guard_leq(self.numels[-1], next_power_of_2(hint)) return True def set_last_usage(self, nodes): if not self.inside_reduction or self.persistent_reduction: return self.last_usage = set( itertools.chain.from_iterable( n.last_usage for n in nodes if n is not EnableReduction ) ) def initialize_range_tree(self, pid_cache): names = list( reversed(["xindex", "yindex", "zindex"][: len(self.numels) - 1]) ) + ["rindex"] for i in range(len(self.numels)): pid_idx = i if names[i][0] == "r" else "xyz".find(names[i][0]) self.range_trees.append( IterationRangesRoot( names[i], self.numels[i], names[i][0], pid_idx, self, pid_cache ) ) for tree in self.range_trees: # reduction indexing goes inside a loop if not tree.is_loop(): tree.codegen_header(self.body, self.no_x_dim) if self.inside_reduction and self.range_trees[-1].is_loop(): # workaround for this issue: # https://gist.github.com/jansel/6527126f781559095c5531f98a4235a7 self.body.writeline(f"rbase = {self.range_trees[-1].ranges_code()}") def disable_reduction(self): @contextlib.contextmanager def ctx(): if self.numels[-1] == 1: assert not self.inside_reduction yield return if not self.persistent_reduction: # calling codegen_body() will flush all the pending buffers # and write out a reduction loop self.codegen_body() self.inside_reduction = False try: yield if not self.persistent_reduction: # flush out any code before opening the next loop self.codegen_body() finally: self.inside_reduction = True return ctx() def set_ranges(self, *lengths): assert len(lengths) == len(self.range_trees) return [ ranges.construct(length) for length, ranges in zip(lengths, self.range_trees) ] @staticmethod def _split_iteration_ranges( groups: Iterable[sympy.Expr], lengths: List[List[sympy.Expr]] ): sv = V.graph.sizevars new_ranges: List[List[sympy.Expr]] = [[] for _ in groups] remaining = [sv.simplify(g) for g in groups] var_count = itertools.count() def add_range(i, expr): expr = sv.simplify(expr) if not sv.statically_known_multiple_of(remaining[i], expr): raise CantSplit() # guard on the last item out remaining[i] = FloorDiv(remaining[i], expr) new_ranges[i].append(expr) return next(var_count) def make_combined(size, idx1, idx2): def getter(flat_vars): return size * flat_vars[idx1] + flat_vars[idx2] return getter return_getters_groups = [] current_group = 0 for length_group in lengths: return_getters = [] for size in length_group: if sv.statically_known_equals(size, 1): return_getters.append(lambda _: sympy.Integer(0)) continue while ( current_group < len(remaining) and sv.size_hint(remaining[current_group]) == 1 ): # scroll to next group with remaining elements current_group += 1 if sv.size_hint(size) > sv.size_hint(remaining[current_group]): # need to break size in two if not sv.statically_known_multiple_of( size, remaining[current_group] ): raise CantSplit() size1 = remaining[current_group] size2 = FloorDiv(size, remaining[current_group]) return_getters.append( make_combined( size2, add_range(current_group, size1), add_range(current_group + 1, size2), ) ) else: return_getters.append( operator.itemgetter(add_range(current_group, size)) ) return_getters_groups.append(return_getters) assert all( V.graph.sizevars.size_hint(s) == 1 for s in remaining ), f"failed to set ranges {remaining} {lengths}" return new_ranges, return_getters_groups @classmethod def is_compatible( cls, groups: Iterable[sympy.Expr], lengths: List[List[sympy.Expr]] ): try: cls._split_iteration_ranges(groups, lengths) return True except CantSplit: return False def split_and_set_ranges(self, lengths: List[List[sympy.Expr]]): """ We may want to fuse `for i0 in s0*s1` into a tiled kernel with groups (s0, s1). To do this we need to split up the iteration space of i0 into something like: for i1 in s0: for i2 in s1: i0 = i1*s1 + i2 .... This function matches and resplits lengths to the groups of this kernel to enable tiled + non-tiled fusions. """ groups = [rt.numel for rt in self.range_trees] if not self.inside_reduction: groups[-1] = sympy.Integer(1) if len(lengths) == len(self.range_trees) and all( V.graph.sizevars.simplify(sympy_product(x) - g) == 0 for x, g in zip(lengths, groups) ): return self.set_ranges(*lengths) new_ranges, return_getters_groups = self._split_iteration_ranges( groups, lengths ) itervars = list(itertools.chain(*self.set_ranges(*new_ranges))) return [[fn(itervars) for fn in fns] for fns in return_getters_groups] def is_indirect_indexing(self, index: sympy.Expr): # tmpX means indirect indexing return free_symbol_startswith(index, "tmp") def is_broadcasted(self, index: sympy.Expr): # Note. This may not be correct when there is indirect indexing if self.is_indirect_indexing(index): return False index_numels = [1] * len(self.numels) for symbol in index.free_symbols: if symbol not in self.range_tree_nodes: # Non-iterated variables, e.g. strides continue entry = self.range_tree_nodes[symbol] index_numels[entry.parent.index] *= entry.length # If the index variables only iterate over a subset of the kernel # numels, then it must be broadcasted. simplify = V.graph.sizevars.simplify return any( simplify(idx_range) != simplify(iter_range) for idx_range, iter_range in zip(index_numels, self.numels) ) def combine_contiguous_dims(self, index: sympy.Expr, tree: IterationRangesRoot): """ More aggressive simplification to merge contiguous dims """ if isinstance(index, (sympy.Integer, sympy.Symbol)): return index index_vars, sizes = tree.vars_and_sizes(index) if len(sizes) <= 1: return index new_sizes, reindex, prune = V.graph.sizevars._simplify_loops( index_vars, sizes, index_prevent_reordering([index], index_vars, sizes) ) if new_sizes == sizes: return index new_index_vars = tree.construct(new_sizes) new_index = sympy_subs(index, dict(zip(index_vars, reindex(new_index_vars)))) return new_index def index_to_str(self, index: sympy.Expr) -> str: """ Convert an index expr to a string that can be used in triton code. e.g. a sympy expression "s2" may actually appear as "ks1" in the triton kernel. Index expressions often need to be passed in as arguments to the triton kernel. Rename_indexing and codegen_indexing keep track of the needed indices and add new parameters to the function signature. """ return texpr(self.rename_indexing(self.codegen_indexing(index))) def indexing( self, index: sympy.Expr, *, copy_shape=None, dense_indexing=False, override_mask=None, ): """ Compute the index and mask to pass to tl.load() or tl.store() """ index = self.simplify_indexing(index) index = sympy_subs(index, V.graph.sizevars.precomputed_replacements) # if simple replacements didn't get rid of floor/ceil, try full subs if len(index.atoms(sympy.floor)) or len(index.atoms(sympy.ceiling)): index = index.subs(V.graph.sizevars.precomputed_replacements) # last resort, if no range vars are in the expr, hoist it # TODO instead of trying to blindly find complicated exprs, we should hoist the # inputs/outputs sizes and strides, but at the time indexing is generated # kernel inputs and outputs are not set yet, we'd need a deeper refactor # to do it this way if len(index.atoms(sympy.ceiling)): for a in index.atoms(sympy.ceiling): # for nested exprs, atoms yields top level first (?) # so if everything goes fine, lower level replacements will come up empty symbols = a.free_symbols if len(symbols) > 0 and all( s.name.startswith("s") or s.name.startswith("ps") for s in symbols ): replacements = {a: V.graph.sizevars.lookup_precomputed_size(a)} index = sympy_subs(index, replacements) index_vars = index.free_symbols index = self.simplify_indexing(index) index_str = self.index_to_str(index) mask_vars: Set[str] = set() for var in index_vars: assert isinstance(var, sympy.Symbol) if override_mask: pass elif var.name.startswith("tmp"): # indirect indexing cse_var = self.cse.varname_map[var.name] mask_vars.update(cse_var.mask_vars) elif var.name.startswith(("s", "ps")): pass else: # var is one of xN, yN or rN assert var.name[0] in "xyr", var.name mask_vars.add(f"{var.name[0]}mask") need_dense = ( config.triton.dense_indexing or dense_indexing or self._load_mask is not None ) and index != 0 have_dense = True have_loop_vars = False dense_mask_vars = set() for tree in self.range_trees: if tree.prefix == "r" and not self.inside_reduction: continue if index_vars.intersection(tree.var_list): have_loop_vars = True else: have_dense = False dense_mask_vars.add(f"{tree.prefix}mask") expand_str = None if isinstance(index, sympy.Integer): expand_str = f"{copy_shape}.shape" if copy_shape else self.dense_size_str() index_str = f"tl.full({expand_str}, {index_str}, tl.int32)" return index_str, set(), "None", expand_str if need_dense and not have_dense: expand_str = f"{copy_shape}.shape" if copy_shape else self.dense_size_str() index_str = f"tl.broadcast_to({index_str}, {expand_str})" mask_vars = dense_mask_vars elif not have_loop_vars and copy_shape: index_str = f"tl.broadcast_to({index_str}, {copy_shape}.shape)" mask_vars = dense_mask_vars if override_mask: mask_vars = {override_mask} if self._load_mask: mask_vars.add(self._load_mask) self.filter_masks(mask_vars) mask_str = " & ".join(sorted(map(str, mask_vars))) if mask_vars else "None" return index_str, mask_vars, mask_str, expand_str def filter_masks(self, mask_vars): for tree in self.range_trees: # Masks are superfluous if we only have one element if V.graph.sizevars.statically_known_equals(tree.numel, 1): mask_vars.discard(f"{tree.prefix}mask") continue # Masks are superfluous if numel is a multiple of BLOCK # (We use the fact that BLOCK is required by triton to be a power of 2) if tree.prefix.upper() not in config.triton.max_block: continue max_block = config.triton.max_block[tree.prefix.upper()] # Optional optimization: if block divides numel exactly, we will # never need to do a masked load to handle stragglers at the end. # It's faster to avoid masking at all. But it is sound to always # mask. if V.graph.sizevars.statically_known_multiple_of(tree.numel, max_block): mask_vars.discard(f"{tree.prefix}mask") def var_ranges(self): return dict( itertools.chain.from_iterable( tree.var_ranges.items() for tree in self.range_trees ) ) def codegen_indexing(self, expr: sympy.Expr): expr = V.graph.sizevars.simplify_with_ranges(expr, self.var_ranges()) for sym in sorted(expr.free_symbols, key=str): if sym in self.range_tree_nodes: # if indexing expression is complicated, we precompute it on the host side # and send the result as a kernel argument replacements = {} for ps in self.range_tree_nodes[sym].precomputed_args(): replacements[ps] = V.graph.sizevars.lookup_precomputed_size(ps) if len(replacements) > 0: self.range_tree_nodes[sym].expr = sympy_subs( self.range_tree_nodes[sym].expr, replacements ) self.range_tree_nodes[sym].codegen() return expr @contextlib.contextmanager def mask_loads(self, mask): """Context manager to add an additional mask to tl.load/store""" prior = self._load_mask if prior: mask = self.cse.generate(self.compute, f"{mask} & {prior}") self._load_mask = mask try: # TODO(jansel): do we need a reshape here? yield mask finally: self._load_mask = prior def generate_assert(self, check): return torch.version.hip is None and super().generate_assert(check) def load_mask(self, var): mask = "" mask_vars = set(var.mask_vars) if self._load_mask: mask_vars.add(self._load_mask) if mask_vars: mask = ( f"{list(mask_vars)[0]}" if len(mask_vars) == 1 else f"({' & '.join(str(v) for v in mask_vars)})" ) return mask @property def assert_function(self): return "tl.device_assert" def get_strides_of_load(self, index: sympy.Expr): """ This gets the stride of the index for each of the tiling variables (technically, it does it at index 0) For example, if xindex = x0 + 512*x1 + 1024*r0 x0 = (xindex//512) x1 = (xindex % 512) r0 = rindex // 1024 this function would return {xindex: 512, rindex: 1024} """ index_to_tile_indexes = {k: v.expr for k, v in self.range_tree_nodes.items()} index_in_tile_vars = sympy_subs(index, index_to_tile_indexes) strides = {} for range_tree in self.range_trees: s = sympy_symbol(range_tree.name) strides[s] = sympy_subs(index_in_tile_vars, {s: 1}) - sympy_subs( index_in_tile_vars, {s: 0} ) return strides def load(self, name: str, index: sympy.Expr): var = self.args.input(name) indirect_indexing = self.is_indirect_indexing(index) original_index = index index, mask_vars, mask, expand_str = self.indexing(index) # Keep the variable in cache if were going to reuse it. Equiv., if any of the following hold # 1) We are doing broadcasting # 2) It is a non-coalesced load. The intuition is that if it's # non-coalesced, we will likely load each element multiple times in # practice. # 3) It will be used later and it won't be CSE'd. Equiv., if all the following hold # 3.1) We are in a reduction loop # 3.2) Its not its last use # 3.3) This load will not be lifted to the body # is_coalesced = any( i == 1 for i in self.get_strides_of_load(original_index).values() ) if self.is_broadcasted(original_index): ep = ", eviction_policy='evict_last'" elif not is_coalesced: ep = ", eviction_policy='evict_last'" elif self.inside_reduction and not self.persistent_reduction: if name in self.args.inplace_buffers: names = set(self.args.inplace_buffers[name].other_names) else: names = {name} last_use = len(names & self.last_usage) > 0 evict_last = not last_use and ("rmask" in mask or indirect_indexing) if evict_last: ep = ", eviction_policy='evict_last'" else: ep = ", eviction_policy='evict_first'" else: ep = "" # "other" below is a workaround for https://github.com/openai/triton/issues/737 # for bool, even though it's likely subject to the same bug, setting `other` leads # to LLVM errors so we are skipping it for now if ("tmp" in mask or "rmask" in mask) and V.graph.get_dtype(name) != torch.bool: other = ", other=0" else: other = "" append_broadcast = None if V.graph.is_unspec_arg(name): line = var else: if isinstance(original_index, sympy.Integer): line = f"tl.load({var} + ({original_index}))" append_broadcast = expand_str else: line = f"tl.load({var} + ({index}), {mask}{ep}{other})" dtype = V.graph.get_dtype(name) if dtype in (torch.float16, torch.bfloat16): line += ".to(tl.float32)" if dtype == torch.bool and torch.version.hip is None: # Workaround for https://github.com/openai/triton/issues/2151 # tl.load returns int8 when loading from pointer to int1 # NOTE: Currently causes hangs on bool UTs for ROCm line += ".to(tl.int1)" if "tmp" in mask: # Masked loads must come after the mask is computed load_buffer = self.compute elif ( self.inside_reduction and not self.persistent_reduction and "rmask" not in mask and not indirect_indexing ): # can lift a common load outside of reduction loop # One exception is when this is an indirect_load. load_buffer = self.body else: load_buffer = self.loads result_var = self.cse.generate(load_buffer, line) assert isinstance(result_var, TritonCSEVariable) result_var.mask_vars = mask_vars if append_broadcast: line = f"tl.broadcast_to({result_var}, {append_broadcast})" result_var = self.cse.generate(load_buffer, line) if not self.inside_reduction or "rmask" not in mask: self.outside_loop_vars.add(result_var) return result_var def store(self, name, index, value, mode=None): var = self.args.output(name) indirect_indexing = self.is_indirect_indexing(index) original_index = index index, mask_vars, mask, expand_str = self.indexing(index, dense_indexing=True) # Guard against write-after-read corruption in triton. # See # https://github.com/openai/triton/issues/1615 # This triton bug means that a load which is broadcasted over multiple # warps may see the result of a store that happens later in the triton # program. The workaround is to add a barrier before storing, which # enforces that all warps have already read the data. is_inplace = name in self.args.inplace_buffers is_broadcasted = self.is_broadcasted(original_index) if is_inplace and is_broadcasted: self.stores.writeline(DeferredLine(name, "tl.debug_barrier()")) if mode is None: line = f"tl.store({var} + ({index}), {value}, {mask})" elif mode == "atomic_add": line = f"tl.atomic_add({var} + ({index}), {value}, {mask})" else: raise NotImplementedError(f"store mode={mode}") self.stores.writeline(DeferredLine(name, line)) if not self.inside_reduction: self.outside_loop_vars.add(value) def bucketize( self, values: CSEVariable, offsets_name: str, offsets_size: sympy.Expr, indexing_dtype: torch.dtype, right: bool, ): """ See [Note: Inductor bucketize op] """ # Triton performance for bucketize_binary_search is much better when the number # of threads equals the number of elements. # If we're trying to use a bucketize kernel, we should make sure that an # autotuning config with num_elements_per_warp=32 exists. self.autotune_hints.add(AutotuneHint.ELEMENTS_PER_WARP_32) offsets_ptr = self.args.input(offsets_name) block_size = self.dense_size_str() offsets_size_str = self.index_to_str(offsets_size) if indexing_dtype == torch.int32: triton_dtype = "tl.int32" elif indexing_dtype == torch.int64: triton_dtype = "tl.int64" else: raise NotImplementedError( "Bucketize only supports indexing with int32 and int64" ) result = self.cse.generate( self.compute, f"triton_helpers.bucketize_binary_search({values}, {offsets_ptr}, {triton_dtype}, {right}, {offsets_size_str}, {block_size})", # noqa: B950 line too long ) return result def reduction_resize(self, value): ndims = self.triton_tensor_ndim() if ndims == 1: return f"triton_helpers.promote_to_tensor({value})" sizes = [":"] * ndims sizes[-1] = "None" return f"{value}[{', '.join(sizes)}]" @staticmethod def _map_tuple_or_scalar(fn, value): if isinstance(value, tuple): return tuple(map(fn, value)) return fn(value) def reduction(self, dtype, src_dtype, reduction_type, value): assert self.inside_reduction masks = {f"{tree.prefix}mask" for tree in self.range_trees} self.filter_masks(masks) masks = sorted(masks) if self._load_mask: masks.append(self._load_mask) reduction_range_prefix = self.range_trees[-1].prefix reduction_sizes = ["None" for _ in self.range_trees] reduction_sizes[-1] = ":" # Say we have # tmp0 = ops.constant(1, torch.int64) # tmp1 = ops.reduction(torch.int64, torch.int64, "sum", tmp0) # tmp0 in the triton code is either a scalar, or single-element tensor # so if we emit tl.sum directly, it will only give 1 instead of RBLOCK * 1 # To avoid this, we broadcast to the expected shape first. dense_size_str = self.dense_size_str() value = self._map_tuple_or_scalar( lambda v: self.cse.generate( self.compute, f"tl.broadcast_to({v}, {dense_size_str})" ), value, ) def final_reduction(value): use_helper = reduction_type in {"any", "max", "min", "prod"} module = "triton_helpers" if use_helper else "tl" if reduction_type in {"max", "min"}: return self.reduction_resize( f"{module}.{reduction_type}2({value}, {dim})" ) return self.reduction_resize(f"{module}.{reduction_type}({value}, {dim})") def final_argreduce(buffer, result_var, value, index): buffer.splice( f"""\ _, {result_var}_tmp = triton_helpers.{root_op}_with_index({value}, {index}, {dim}) {result_var} = {self.reduction_resize(f'{result_var}_tmp')} """ ) cache_key = (src_dtype, reduction_type, value) if cache_key in self.cse.reduction_cache: return self.cse.reduction_cache[cache_key] dim = len(self.range_trees) - 1 - int(bool(self.no_x_dim)) acc_type = triton_acc_type(src_dtype) result_var: Any = self.cse.newvar() result_var.mask_vars = {var for var in masks if var[0] != "r"} cond = " & ".join(masks) if self.persistent_reduction: default = ir.Reduction.default_value(reduction_type, src_dtype) default = self._map_tuple_or_scalar(triton_constant, default) def _mask_value(value, default): return self.cse.generate( self.compute, f"tl.where({cond}, {value}, {default})" ) if isinstance(value, tuple): masked_value = [_mask_value(v, d) for v, d in zip(value, default)] else: masked_value = _mask_value(value, default) if reduction_type in {"argmax", "argmin"}: accumulator_index = self.cse.generate( self.compute, f"tl.broadcast_to({reduction_range_prefix}index, {masked_value}.shape)", ) root_op = {"argmax": "max", "argmin": "min"}[reduction_type] final_argreduce( self.compute, result_var, masked_value, accumulator_index ) elif reduction_type == "welford_reduce": # For persistent reductions, don't bother with # welford's algorithm since it uses more registers, and # taking two reductions doesn't increase memory usage. sum_ = ops.reduction(dtype, dtype, "sum", value) self.inside_reduction = False rnumel = ops.index_expr(self.numels[-1], dtype) mean = ops.truediv(sum_, rnumel) self.inside_reduction = True dx = ops.sub(value, mean) dx2 = ops.mul(dx, dx) m2 = ops.reduction(dtype, dtype, "sum", dx2) result_var = (mean, m2, rnumel) elif reduction_type == "welford_combine": mean, m2, weight = masked_value welford = f"triton_helpers.welford({mean}, {m2}, {weight}, {dim})" mean, m2, weight = (self.cse.newvar() for _ in range(3)) self.compute.writeline(f"{mean}, {m2}, {weight} = {welford}") result_var = tuple( self.cse.generate(self.compute, self.reduction_resize(var_name)) for var_name in (mean, m2, weight) ) else: result_var = self.cse.generate( self.compute, final_reduction(masked_value) ) else: accumulator = f"_{result_var}" default = ir.Reduction.default_accumulator(reduction_type, src_dtype) default = self._map_tuple_or_scalar(triton_constant, default) if not isinstance(default, tuple): self.body.writeline( f"{accumulator} = tl.full({self.dense_size_str()}, {default}, {acc_type})" ) if reduction_type in {"argmax", "argmin"}: accumulator_index = f"_{result_var}_index" # type: ignore[assignment] long_max = torch.iinfo(torch.int64).max self.body.writeline( f"{accumulator_index} = tl.full({self.dense_size_str()}, {long_max}, tl.int64)" ) root_op = {"argmax": "max", "argmin": "min"}[reduction_type] self.compute.splice( f"""\ {accumulator}_next, {accumulator_index}_next = triton_helpers.{root_op}imum_with_index( {accumulator}, {accumulator_index}, {value}, {reduction_range_prefix}index ) {accumulator} = tl.where({cond}, {accumulator}_next, {accumulator}) {accumulator_index} = tl.where({cond}, {accumulator_index}_next, {accumulator_index}) """ ) final_argreduce(self.suffix, result_var, accumulator, accumulator_index) elif is_welford_reduction(reduction_type): accumulator = f"{result_var}_mean" accumulator_m2 = f"{result_var}_m2" accumulator_weight = f"{result_var}_weight" self.body.writeline( f"{accumulator} = tl.zeros({self.dense_size_str()}, {acc_type})" ) self.body.writeline( f"{accumulator_m2} = tl.zeros({self.dense_size_str()}, {acc_type})" ) self.body.writeline( f"{accumulator_weight} = tl.zeros({self.dense_size_str()}, {acc_type})" ) if reduction_type == "welford_combine": mean, m2, weight = value self.compute.splice( f"""\ {accumulator}_next, {accumulator_m2}_next, {accumulator_weight}_next = triton_helpers.welford_combine( {accumulator}, {accumulator_m2}, {accumulator_weight}, {mean}, {m2}, {weight} ) """ ) else: assert reduction_type == "welford_reduce" self.compute.splice( f"""\ {accumulator}_next, {accumulator_m2}_next, {accumulator_weight}_next = triton_helpers.welford_reduce( {value}, {accumulator}, {accumulator_m2}, {accumulator_weight}, ) """ ) self.compute.splice( f"""\ {accumulator} = tl.where({cond}, {accumulator}_next, {accumulator}) {accumulator_m2} = tl.where({cond}, {accumulator_m2}_next, {accumulator_m2}) {accumulator_weight} = tl.where({cond}, {accumulator_weight}_next, {accumulator_weight}) """ ) result_mean = result_var result_m2 = self.cse.newvar() result_weight = self.cse.newvar() self.suffix.splice( f"""\ {result_mean}_tmp, {result_m2}_tmp, {result_weight}_tmp = triton_helpers.welford( {accumulator}, {accumulator_m2}, {accumulator_weight}, {dim} ) {result_mean} = {self.reduction_resize(f'{result_mean}_tmp')} {result_m2} = {self.reduction_resize(f'{result_m2}_tmp')} {result_weight} = {self.reduction_resize(f'{result_weight}_tmp')} """ ) result_var = result_mean, result_m2, result_weight else: combine_fn = ir.get_reduction_combine_fn(reduction_type, src_dtype) updated = combine_fn(accumulator, value) self.compute.writeline( f"{accumulator} = tl.where({cond}, {updated}, {accumulator})" ) if src_dtype == torch.bool: # This is only really used for aten.any. It changes the # final reduction of a non-persistent reduction from # tmp5 = triton_helpers.max(_tmp5, 1)[:, None] # to # tmp5 = triton_helpers.max(_tmp5.to(tl.int8), 1)[:, None].to(tl.int1) # which is needed because tl.reduce doesn't support tl.int1 accumulator = f"{accumulator}.to(tl.int8)" result_type = triton_compute_type(dtype) self.suffix.writeline( f"{result_var} = {final_reduction(accumulator)}.to({result_type})" ) else: self.suffix.writeline( f"{result_var} = {final_reduction(accumulator)}" ) self.cse.reduction_cache[cache_key] = result_var if isinstance(result_var, tuple): self.outside_loop_vars |= set(result_var) else: self.outside_loop_vars.add(result_var) return result_var def store_reduction(self, name, index, value): assert self.inside_reduction self.inside_reduction = False index, mask_vars, mask, _ = self.indexing(index) assert "rmask" not in index self.inside_reduction = True var = self.args.output(name) self.suffix.writeline( DeferredLine(name, f"tl.store({var} + ({index}), {value}, {mask})") ) def codegen_body(self): """ Concat output code from index_code, loads, compute, stores, suffix into self.body. For pointwise kernels, this is called just once at the end. For reduction kernels, this generates a loop over the reduction axis. """ if not ( self.indexing_code or self.loads or self.stores or self.compute or self.suffix ): return if self.inside_reduction and not self.persistent_reduction: self.body.writeline("for roffset in range(0, rnumel, RBLOCK):") with self.body.indent(): # last range tree is always reduction self.range_trees[-1].codegen_header(self.body) self.body.splice(self.indexing_code) self.body.splice(self.loads) self.body.splice(self.compute) self.body.splice(self.stores) # invalidate any caches that came from inside the reduction loop self.cse.invalidate(self.outside_loop_vars) self.range_trees[-1].cache_clear() else: self.body.splice(self.indexing_code) self.body.splice(self.loads) self.body.splice(self.compute) self.body.splice(self.stores) self.body.splice(self.suffix) self.indexing_code.clear() self.loads.clear() self.compute.clear() self.stores.clear() self.suffix.clear() def codegen_kernel_benchmark(self): result = IndentedBuffer() argdefs, call_args, signature = self.args.python_argdefs() result.writelines(["", "", "def get_args():"]) with result.indent(): name_cnt = itertools.count() var_names = [] for arg_name, arg_sig in zip(call_args, signature): var_name = f"arg_{next(name_cnt)}" buf = V.graph.get_buffer(arg_name) if buf: result.writeline( f"{var_name} = rand_strided({V.graph.sizevars.size_hints(buf.get_size())}, {V.graph.sizevars.size_hints(buf.get_stride())}, device='{buf.get_device()}', dtype={buf.get_dtype()})" # noqa: B950 line too long ) elif arg_name in V.graph.constants: # note that random seed is put in V.graph.constants const_tensor = V.graph.constants[arg_name] result.writeline( f"{var_name} = rand_strided({V.graph.sizevars.size_hints(const_tensor.size())}, {V.graph.sizevars.size_hints(const_tensor.stride())}, device='{const_tensor.device}', dtype={const_tensor.dtype})" # noqa: B950 line too long ) elif isinstance(arg_sig, SizeArg): symval_hint = V.graph.sizevars.size_hint(arg_sig.expr) # Force the seed_offset to be 0 so calls to the same kernel # using different seed offset will have the same benchmark harness. # We can dedup kernel definitions in this case. if "seed_offset" in arg_sig.name: symval_hint = 0 result.writeline(f"{var_name} = {symval_hint}") else: raise KeyError( f"Don't find the buffer or const tensor for {arg_name}" ) var_names.append(var_name) result.writeline(f"return {', '.join(var_names)},") result.writelines(["\n", "\n", "def call(args):"]) grid = [] extra_args = [] extra_args_str = None index = V.graph.scheduler.current_device.index with result.indent(): result.writeline(f"with torch.cuda._DeviceGuard({index}):") with result.indent(): result.writeline( f"torch.cuda.set_device({index})" ) # no-op to ensure context for tree in self.range_trees: expr = pexpr(V.graph.sizevars.size_hint(tree.numel)) if tree.prefix != "r" or self.inside_reduction: extra_args.append(expr) if tree.prefix != "r": grid.append(expr) stream_name = f"stream{index}" result.writeline(f"{stream_name} = get_cuda_stream({index})") extra_args_str = ", ".join(map(str, extra_args)) + ", " result.writeline( f"{str(Placeholder.KERNEL_NAME)}.run(*args, {extra_args_str}grid=grid({', '.join(grid)}), stream={stream_name})" ) # benchmark all configs result.writelines(["\n", "\n", "def benchmark_all_configs(args):"]) with result.indent(): result.writeline(f"with torch.cuda._DeviceGuard({index}):") with result.indent(): result.writeline( f"torch.cuda.set_device({index})" ) # no-op to ensure context result.writeline( f"return {str(Placeholder.KERNEL_NAME)}.benchmark_all_configs(*args, {extra_args_str}grid=grid({', '.join(grid)}))" # noqa: B950 line too long ) ninplace_args = len(unique(self.args.inplace_buffers.values())) result.writelines(["\n", "\n", "if __name__ == '__main__':"]) with result.indent(): result.writeline("from torch._inductor.utils import get_num_bytes") result.writeline("from triton.testing import do_bench") result.writeline("") result.writeline("args = get_args()") result.writeline( "ms = do_bench(lambda: call(args), rep=40, fast_flush=True)" ) result.writeline( f"num_gb = get_num_bytes(*args, num_in_out_args={ninplace_args}) / 1e9" ) result.writeline("gb_per_s = num_gb / (ms / 1e3)") result.writeline( 'print(f"{ms:.3f}ms {num_gb:.3f}GB {gb_per_s:.2f}GB/s")' ) return result def codegen_kernel(self, name=None): from triton import next_power_of_2 code = IndentedBuffer() size_hints = [] for numel in self.numels: numel_hint = V.graph.sizevars.symbolic_hint(numel) if not isinstance(numel_hint, (int, sympy.Integer)): # This default heuristic hint was picked carefully: it is # large, to ensure that we don't shrink the block size (since # if you don't have many elements, it'd be wasteful to pick a # large block size). Since we don't know how many elements we # might have, we should be OK with some inefficiency to make # sure we handle the large case well. 8192 is the largest # block size we support, so we pick that. # # If we have a better hint for unbacked SymInts (e.g., because # a user told us, or we are tracking upper bounds) we could # use that here. size_hint = 8192 else: size_hint = next_power_of_2(int(numel_hint)) size_hints.append(size_hint) if self.persistent_reduction: assert self.inside_reduction heuristics = "persistent_reduction" elif self.inside_reduction: heuristics = "reduction" else: size_hints.pop() heuristics = "pointwise" if name is None: code.splice( f""" import triton import triton.language as tl from torch._inductor.ir import ReductionHint from torch._inductor.ir import TileHint from torch._inductor.triton_heuristics import AutotuneHint, {heuristics} from torch._inductor.utils import instance_descriptor from torch._inductor import triton_helpers """ ) if config.benchmark_kernel: code.splice( """ from torch._dynamo.testing import rand_strided from torch._C import _cuda_getCurrentRawStream as get_cuda_stream import torch from torch._inductor.triton_heuristics import grid """ ) argdefs, _, signature = self.args.python_argdefs() # maps actual expression to SizeArg if its in sizevars replacements for i, arg in enumerate(signature): if ( isinstance(arg, SizeArg) and arg.expr in V.graph.sizevars.inv_precomputed_replacements ): signature[i] = SizeArg( arg.name, V.graph.sizevars.inv_precomputed_replacements[arg.expr] ) mutated_args = set() for mutation in self.mutations: if mutation in self.args.input_buffers: mutated_args.add(self.args.input_buffers[mutation]) if ( mutation in self.args.inplace_buffers and mutation not in V.graph.removed_buffers and mutation not in self.removed_buffers ): mutated_args.add(self.args.inplace_buffers[mutation].inner_name) if mutation in self.args.output_buffers: mutated_args.add(self.args.output_buffers[mutation]) mutated_args = sorted(mutated_args) triton_meta = { "signature": signature_to_meta(signature, size_dtype=self.index_dtype), "device": V.graph.scheduler.current_device.index, "device_type": V.graph.scheduler.current_device.type, "constants": {}, } inductor_meta = { "autotune_hints": set(self.autotune_hints), "kernel_name": str(Placeholder.DESCRIPTIVE_NAME), "mutated_arg_names": mutated_args, } for tree in self.range_trees: if tree.prefix != "r" or self.inside_reduction: sizearg = SizeArg(f"{tree.prefix}numel", tree.numel) signature.append(sizearg) triton_meta["signature"][len(argdefs)] = signature_of( sizearg, size_dtype=self.index_dtype ) argdefs.append(f"{tree.prefix}numel") # constexpr version causes issues, see # https://github.com/pytorch/torchdynamo/pull/1362 # triton_meta["constants"][len(argdefs)] = V.graph.sizevars.size_hint( # tree.numel # ) # argdefs.append(f"{tree.prefix}numel: tl.constexpr") triton_meta["configs"] = [config_of(signature)] for tree in self.range_trees: if tree.prefix == "r" and ( not self.inside_reduction or self.persistent_reduction ): continue if tree.prefix == "x" and self.no_x_dim: continue argdefs.append(f"{tree.prefix.upper()}BLOCK : tl.constexpr") if self.inside_reduction: reduction_hint = self.reduction_hint heuristics_line = f""" @{heuristics}( size_hints={size_hints!r}, reduction_hint={reduction_hint}, filename=__file__, triton_meta={triton_meta!r}, inductor_meta={inductor_meta!r} ) @triton.jit """ else: tile_hint = "" if len(size_hints) == 2: if len(signature) == 4: # input, output and 2 args tile_hint = "tile_hint=TileHint.SQUARE," else: tile_hint = "tile_hint=TileHint.DEFAULT," heuristics_line = f""" @{heuristics}( size_hints={size_hints!r}, {tile_hint} filename=__file__, triton_meta={triton_meta!r}, inductor_meta={inductor_meta!r}, min_elem_per_thread={self.min_elem_per_thread} ) @triton.jit """ code.splice(heuristics_line) code.writeline( f"def {name or str(Placeholder.KERNEL_NAME)}({', '.join(argdefs)}):" ) self.codegen_body() with code.indent(): self.codegen_static_numels(code) for old, new in self.args.aliases(): code.writeline(f"{old} = {new}") code.splice(self.body) if config.benchmark_kernel: code.splice(self.codegen_kernel_benchmark()) return code.getvalue() def codegen_static_numels(self, code): """ We get a small speedup from hard coding numels if they are static. This code stomps on the passed-in values by writing an constant to the top of the kernel. In a kernel like: def KERNEL_NAME(in_ptr0, in_ptr1, out_ptr2, xnumel, rnumel, XBLOCK : tl.constexpr, RBLOCK : tl.constexpr): We would add xnumel = 4096 rnumel = 768 After the signature, before the kernel code, if we decided to make these static. As its hardcoded, it becomes a better signal to triton on how to unroll and do some static indexing. So, it's not so much that downstream knows that its a static numel, as that you just plop a constant into the kernel. """ for tree in self.range_trees: if tree.prefix != "r" or self.inside_reduction: simplified_tree_numel = V.graph.sizevars.simplify(tree.numel) if isinstance(simplified_tree_numel, (sympy.Integer, int)): code.writeline(f"{tree.prefix}numel = {int(simplified_tree_numel)}") if tree.prefix == "r" and self.persistent_reduction: simplified_tree_numel = V.graph.sizevars.simplify(tree.numel) if isinstance(simplified_tree_numel, (sympy.Integer, int)): val = int(simplified_tree_numel) else: continue val = next_power_of_2(val) code.writeline(f"RBLOCK: tl.constexpr = {val}") if tree.prefix == "x" and self.no_x_dim: code.writeline("XBLOCK: tl.constexpr = 1") def triton_tensor_ndim(self): no_x_dim = int(bool(self.no_x_dim)) no_r_dim = self.numels[-1] == 1 return len(self.range_trees) - no_x_dim - no_r_dim def indexing_size_str(self, i=None, x=None): # no_x_dim is sympy.logic.boolalg.BooleanTrue no_x_dim = int(bool(self.no_x_dim)) sizes = ["None"] * self.triton_tensor_ndim() if i is not None: idx = i - no_x_dim sizes[idx] = ":" return f"[{', '.join(sizes)}]" def dense_size_str(self): sizes = [] for tree in self.range_trees: if self.no_x_dim and tree.prefix == "x": continue if tree.prefix != "r" or self.inside_reduction: sizes.append(f"{tree.prefix.upper()}BLOCK") elif tree.prefix == "r" and tree.numel != 1: sizes.append("1") if sizes[0:3] == ["ZBLOCK", "YBLOCK", "XBLOCK"]: sizes[0:3] = reversed(sizes[0:3]) if sizes[0:2] == ["YBLOCK", "XBLOCK"]: sizes[0:2] = reversed(sizes[0:2]) return f"[{', '.join(sizes)}]" def call_kernel(self, name: str, node: Optional[IRNode] = None): wrapper = V.graph.wrapper_code _, call_args, _ = self.args.python_argdefs() # dynamo wraps unspec variable as 0d CPU tensor, need convert to scalar for i in range(len(call_args)): if V.graph.is_unspec_arg(call_args[i]): call_args[i] = call_args[i] + ".item()" grid = [] # TODO(jansel): if there are constants, we shouldn't bother passing them as args for tree in self.range_trees: if isinstance(tree.numel, (sympy.Integer, sympy.Symbol)): expr = tree.numel else: expr = wrapper.generate_numel_expr(name, tree) if tree.prefix != "r" or self.inside_reduction: call_args.append(expr) if tree.prefix != "r": grid.append(expr) grid = wrapper.generate_default_grid(name, grid) wrapper.generate_kernel_call( name, call_args, grid, V.graph.scheduler.current_device.index, cuda=True, triton=True, ) def codegen_nan_check(self): if not config.nan_asserts: return wrapper = V.graph.wrapper_code _, call_args, arg_types = self.args.python_argdefs() for arg, arg_type in zip(call_args, arg_types): if isinstance(arg_type, TensorArg): line = f"assert not {arg}.isnan().any().item()" wrapper.writeline(line) line = f"assert not {arg}.isinf().any().item()" wrapper.writeline(line) def warn_mix_layout(self, kernel_name): """ Print message if the kernel have mixed layout inputs. Only care about 4D tensor for now. """ if ( len(self.args.input_buffers) == 1 and len(self.args.output_buffers) == 1 and len(self.args.inplace_buffers) == 0 ): # even if input buffer and output buffer have different layout, # this can be a layout conversion kernel. No need to warn for # the mix layouts. return argdefs, call_args, signature = self.args.python_argdefs() uniform_stride_order = None for arg_name in call_args: buf = V.graph.get_buffer(arg_name) if buf and len(buf.layout.size) == 4: # ignore the tensor if only 1 dimension is non-zero if len([x for x in buf.layout.size if x == 1]) == 3: continue stride_order = ir.get_stride_order(buf.layout.stride) if uniform_stride_order is None: uniform_stride_order = stride_order elif uniform_stride_order != stride_order: msg = yellow_text( f"Expected stride order {uniform_stride_order}, but found stride order" + f" {stride_order} for kernel {kernel_name}" ) log.warning(msg) stride_order_list = [ ir.get_stride_order(V.graph.get_buffer(name).layout.stride) if V.graph.get_buffer(name) else None for name in call_args ] size_list = [ V.graph.get_buffer(name).layout.size if V.graph.get_buffer(name) else None for name in call_args ] source_list = [ "GraphInput" if name in V.graph.graph_inputs else "IntermediateBuffer" if name in V.graph.name_to_buffer else None for name in call_args ] msg = yellow_text( f" param names {argdefs}\n buf names {call_args}\n strides {stride_order_list}" + f"\n sizes {size_list}\n sources {source_list}\n" ) log.warning(msg) return msg = green_text( f"All the inputs for the triton kernel {kernel_name} have uniform layout" ) log.warning(msg) def create_cse_var(self, *args, **kwargs): return TritonCSEVariable(*args, **kwargs) class TritonScheduling(BaseScheduling): def __init__(self, scheduler): self.scheduler = scheduler def group_fn(self, sizes): return tuple(V.graph.sizevars.simplify(sympy_product(s)) for s in sizes) def can_fuse(self, node1, node2): """ Hook called by Scheduler to determine if the Triton backend can fuse node1 and node2. These nodes might already be FusedSchedulerNodes. """ if isinstance(node1, scheduler.ForeachKernelSchedulerNode) or isinstance( node2, scheduler.ForeachKernelSchedulerNode ): return scheduler.ForeachKernelSchedulerNode.can_fuse(node1, node2) _, (numel1, rnumel1) = node1.group _, (numel2, rnumel2) = node2.group if node1.is_reduction() and node2.is_reduction(): reduction_can_fuse = numel1 == numel2 and rnumel1 == rnumel2 if not reduction_can_fuse: fusion_log.debug( "cannot fuse (triton:1): numel/rnumel mismatch (reduce) (%d, %d), (%d, %d)", numel1, numel2, rnumel1, rnumel2, ) return reduction_can_fuse if not node1.is_reduction() and not node2.is_reduction(): if not (numel1 == numel2 and rnumel1 == rnumel2): fusion_log.debug( "cannot fuse (triton:2): numel/rnumel mismatch (non-reduce) (%d, %d), (%d, %d)", numel1, numel2, rnumel1, rnumel2, ) return False if node1.is_template(): # Only allow fusion for TritonTemplates for now. # Fusion for CUDATemplates are not supported. is_triton_template = isinstance(node1.node, TritonTemplateBuffer) if not is_triton_template: fusion_log.debug( "cannot fuse (triton:3): is not TritonTemplateBuffer %s", node1, ) return is_triton_template # check for a bad combined tiling tiling1 = self.select_tiling(node1.get_nodes(), numel1, rnumel1) tiling2 = self.select_tiling(node2.get_nodes(), numel1, rnumel1) tiling3 = self.select_tiling( node1.get_nodes() + node2.get_nodes(), numel1, rnumel1 ) if config.triton.tiling_prevents_pointwise_fusion: cond = True if len(tiling1) > 2: if len(tiling2) > 2: cond = tiling1 == tiling2 == tiling3 else: cond = tiling1 == tiling3 elif len(tiling2) > 2: cond = tiling2 == tiling3 if not cond: fusion_log.debug( "cannot fuse (triton:4): tiling mismatch (%s, %s, %s)", tiling1, tiling2, tiling3, ) return cond return True if not node1.is_reduction() and node2.is_reduction(): assert rnumel1 == 1 and rnumel2 != 1 if numel1 == numel2 * rnumel2: if not all( TritonKernel.is_compatible((numel2, rnumel2), n.get_ranges()) for n in node1.get_nodes() ): fusion_log.debug( "cannot fuse (triton:5): nodes numel/rnumel incompatibility" ) return False if ( config.triton.tiling_prevents_reduction_fusion and not node1.is_template() ): is_reduction_tiling_valid = self.select_tiling( node1.get_nodes(), numel1 ) in ( (numel1, 1), (numel2, rnumel2, 1), ) if not is_reduction_tiling_valid: fusion_log.debug( "cannot fuse (triton:6): invalid tiling for reduction" ) return is_reduction_tiling_valid return True return numel1 == numel2 assert node1.is_reduction() and not node2.is_reduction() # swap args to hit the case above return self.can_fuse_horizontal(node2, node1) can_fuse_vertical = can_fuse can_fuse_horizontal = can_fuse def generate_node_schedule(self, nodes, numel, rnumel): node_schedule: List[Any] = [] current_loop_writes: Set[str] = set() is_current_reductions = set() done = set() def fits_in_main_body(n): _, (node_numel, node_rnumel) = n.group return (node_numel == numel and node_rnumel == rnumel) or ( node_numel == numel * rnumel and node_rnumel == 1 ) def fits_outside_reduction(n): _, (node_numel, node_rnumel) = n.group return node_numel == numel and node_rnumel == 1 and rnumel != 1 @contextlib.contextmanager def end_current_reduction_loop(): if current_loop_writes: # flush out any other runnable nodes to reduce number of loops for other_node in nodes[index + 1 :]: if ( node not in done and fits_in_main_body(other_node) and not (current_loop_writes & other_node.ancestors) ): done.add(node) current_loop_writes.add(node.get_name()) is_current_reductions.add(node.is_reduction()) node_schedule.append(node) if node_schedule and node_schedule[-1] is EnableReduction: node_schedule.pop() else: node_schedule.append(DisableReduction) yield node_schedule.append(EnableReduction) current_loop_writes.clear() is_current_reductions.clear() for index, node in enumerate(nodes): if node in done: continue done.add(node) def requires_closing_previous_reduction(node, node_schedule): if rnumel == 1: return False if not current_loop_writes & node.ancestors: return False assert node_schedule and not isinstance( node_schedule[-1], (EnableReduction, DisableReduction) ) return True in is_current_reductions if fits_in_main_body(node): if requires_closing_previous_reduction(node, node_schedule): with end_current_reduction_loop(): pass # need to start a new reduction loop current_loop_writes.add(node.get_name()) is_current_reductions.add(node.is_reduction()) node_schedule.append(node) elif fits_outside_reduction(node): with end_current_reduction_loop(): node_schedule.append(node) else: raise NotImplementedError( f"unexpected group: ({numel}, {rnumel}) != {node.group[1]}" ) return node_schedule def codegen_nodes(self, nodes): """ Given a set of pre-fused nodes, generate a Triton kernel. """ _, (numel, rnumel) = max(nodes, key=lambda x: int(x.is_reduction())).group node_schedule = self.generate_node_schedule(nodes, numel, rnumel) schedule_log.debug("Schedule:\n %s", node_schedule) return self.codegen_node_schedule(node_schedule, numel, rnumel) @staticmethod def reduction_hint(node): assert node.is_reduction() if all( dep.is_contiguous() for dep in itertools.chain(node.read_writes.reads, node.read_writes.writes) ): return ReductionHint.INNER else: return node.node.data.reduction_hint @staticmethod def can_use_32bit_indexing(numel: sympy.Expr, buffers: Iterable[ir.Buffer]) -> bool: int_max = torch.iinfo(torch.int32).max size_hint = V.graph.sizevars.size_hint has_hint = V.graph.sizevars.shape_env.has_hint def within_32bit(e): # Allow for unhinted e as long as we can still statically prove # (e.g., via ValueRanges) that it is still in bounds if V.graph.sizevars.is_expr_static_and_true(e <= int_max): return True # Otherwise, the hint MUST exist and be in range return has_hint(e) and size_hint(e) <= int_max if not within_32bit(numel): return False # Any use of a MultiOutputLayout will create a buffer with a # Layout whose sizes are accounted for buf_sizes = [ buf.get_layout().storage_size() for buf in buffers if not isinstance(buf.get_layout(), ir.MultiOutputLayout) ] if not all(within_32bit(size) for size in buf_sizes): return False # Only install guards for 32-bit indexing as there is no correctness # issue with using 64-bit for everything V.graph.sizevars.guard_leq(numel, int_max) for size in buf_sizes: V.graph.sizevars.guard_leq(size, int_max) return True @staticmethod def select_index_dtype(node_schedule, numel, reduction_numel): # Gather all used buffer names buffer_names = set() for node in node_schedule: if not isinstance(node, scheduler.BaseSchedulerNode): continue buffer_names.update(node.get_names()) buffer_names.update(node.used_buffer_names()) # Get buffers objects def _get_buffer(name: str) -> ir.Buffer: if name in V.graph.name_to_buffer: return V.graph.name_to_buffer[name] elif name in V.graph.graph_inputs: return V.graph.graph_inputs[name] elif name in V.graph.constants: data = V.graph.constants[name] return ir.ConstantBuffer( name, ir.FixedLayout( data.device, data.dtype, *V.graph.static_sizes_strides(data) ), ) raise RuntimeError(f"Failed to find buffer matching name {name}") buffers = [_get_buffer(name) for name in buffer_names] # In theory we can separately check xnumel and rnumel are <= int_max # but some indexers do use the full linear index so we need to be # conservative here. total_numel = numel * reduction_numel if TritonScheduling.can_use_32bit_indexing(total_numel, buffers): return "tl.int32" return "tl.int64" def get_kernel_args(self, node_schedule, numel, reduction_numel): reductions = list( filter( lambda n: n not in (EnableReduction, DisableReduction) and n.is_reduction(), node_schedule, ) ) if len(reductions) > 0: hints = [self.reduction_hint(n) for n in reductions] if hints.count(hints[0]) == len(hints): reduction_hint_val = hints[0] else: reduction_hint_val = ReductionHint.DEFAULT else: reduction_hint_val = ReductionHint.DEFAULT mutations = set() for node in node_schedule: if hasattr(node, "get_mutations"): mutations.update(node.get_mutations()) index_dtype = self.select_index_dtype(node_schedule, numel, reduction_numel) return reduction_hint_val, mutations, index_dtype def codegen_comment(self, node_schedule): wrapper = V.graph.wrapper_code origins, detailed_origins = get_kernel_metadata(node_schedule, wrapper) if origins: wrapper.writeline(origins) if config.debug_fusion: from torch._inductor.scheduler import ( BaseSchedulerNode, ForeachKernelSchedulerNode, ) if not any( isinstance(n, ForeachKernelSchedulerNode) for n in node_schedule ): # We probably should look what are the nodes inside a foreach # schedule node node_names = [ n.get_name() for n in node_schedule if isinstance(n, BaseSchedulerNode) ] wrapper.writeline( f"{wrapper.comment} Fused node name list: {', '.join(node_names)}" ) def codegen_node_schedule(self, node_schedule, numel, reduction_numel): tiled_groups = self.select_tiling(node_schedule, numel, reduction_numel) reduction_hint_val, mutations, index_dtype = self.get_kernel_args( node_schedule, numel, reduction_numel ) kernel = TritonKernel( *tiled_groups, reduction_hint=reduction_hint_val, mutations=mutations, index_dtype=index_dtype, ) self.codegen_node_schedule_with_kernel(node_schedule, kernel) with V.set_kernel_handler(kernel): # type: ignore[call-arg] src_code = kernel.codegen_kernel() for node in node_schedule: if node not in (EnableReduction, DisableReduction): node.mark_run() kernel_name = self.define_kernel(src_code, node_schedule) log.debug("Generating kernel code with kernel_name: %s", kernel_name) self.codegen_comment(node_schedule) kernel.call_kernel(kernel_name) kernel.codegen_nan_check() V.graph.removed_buffers |= kernel.removed_buffers V.graph.inplaced_to_remove |= kernel.inplaced_to_remove if config.warn_mix_layout: kernel.warn_mix_layout(kernel_name) if ( V.graph.wrapper_code.supports_intermediate_hooks and config.generate_intermediate_hooks ): # Not every node in the schedule will actually be live on output; # we can't check dead buffers. live_outs = kernel.args.live_output_buffers() for node in node_schedule: if not isinstance(node, scheduler.BaseSchedulerNode): continue name = node.get_name() if name not in live_outs: continue origin_node = node.node.get_origin_node() if origin_node is not None: counters["inductor"]["intermediate_hooks"] += 1 V.graph.wrapper_code.writeline( f"run_intermediate_hooks({origin_node.name!r}, {name})" ) self.scheduler.free_buffers() def codegen_node_schedule_with_kernel(self, node_schedule, kernel): def current_reduction_nodes(nodes): return itertools.takewhile(lambda n: n is not DisableReduction, nodes) with kernel: stack = contextlib.ExitStack() kernel.set_last_usage(current_reduction_nodes(node_schedule)) for node in node_schedule: if node not in (EnableReduction, DisableReduction): node.decide_inplace_update() for i, node in enumerate(node_schedule): if node is DisableReduction: stack.enter_context(kernel.disable_reduction()) elif node is EnableReduction: stack.close() kernel.set_last_usage(current_reduction_nodes(node_schedule[i:])) else: # TODO - use split ranges ? indexing_dtype_strength_reduction(node._body) index_vars = kernel.split_and_set_ranges(node.get_ranges()) node.codegen(index_vars) def define_kernel(self, src_code, node_schedule): wrapper = V.graph.wrapper_code if src_code in wrapper.src_to_kernel: kernel_name = wrapper.src_to_kernel[src_code] else: fused_name = ( get_fused_kernel_name(node_schedule, config.triton.descriptive_names) if config.triton.descriptive_names else "" ) kernel_category = get_kernel_category_by_source_code(src_code)[:3] kernel_name = "_".join( ["triton", kernel_category, fused_name, wrapper.next_kernel_suffix()] ) # use the original src_code as the key wrapper.src_to_kernel[src_code] = kernel_name subs_name = kernel_name if config.triton.unique_kernel_names else "triton_" # DESCRIPTIVE_NAME is used for profiling purposes; it shows the full kernel name # even when unique_kernel_names is turned off. Meanwhile, KERNEL_NAME is sometimes set # to "triton_" to maximize caching opportunities (when unique_kernel_names = False). src_code = src_code.replace(str(Placeholder.DESCRIPTIVE_NAME), kernel_name) src_code = src_code.replace(str(Placeholder.KERNEL_NAME), subs_name) # TODO(voz): Ostensibly, we should not need this. But there are cases where C++ codegen does # not use BracesBuffer, so we have no good indicator of a C++ buffer atm. src_code = src_code.replace("#pragma CMT", "#") basename, _, kernel_path = get_path(code_hash(src_code), "py") compile_wrapper = IndentedBuffer() compile_wrapper.writeline(f"async_compile.triton({subs_name!r}, '''") compile_wrapper.splice(src_code, strip=True) compile_wrapper.writeline("''')") metadata_comment = f"# kernel path: {kernel_path}" origins, detailed_origins = get_kernel_metadata(node_schedule, wrapper) metadata_comment += "\n" + origins + "\n" + detailed_origins wrapper.define_kernel( kernel_name, compile_wrapper.getvalue(), metadata_comment ) return kernel_name def codegen_template(self, template_node, epilogue_nodes): """ Codegen a triton template """ _, (numel, rnumel) = template_node.group assert rnumel == 1 kernel, render = template_node.node.make_kernel_render(template_node.node) with kernel: for node in [template_node, *epilogue_nodes]: node.mark_run() partial_code = render() for node in epilogue_nodes: node.codegen(kernel.split_and_set_ranges(node.get_ranges())) # finalize must be called after adding epilogue above with V.set_kernel_handler(kernel): # type: ignore[call-arg] # TODO: Maybe unify CUDATemplateKernel to also use PartialRender for flexible epilogue fusion. src_code = ( partial_code if isinstance(partial_code, str) else partial_code.finalize() ) node_schedule = [template_node, *epilogue_nodes] kernel_name = self.define_kernel(src_code, node_schedule) self.codegen_comment(node_schedule) kernel.call_kernel(kernel_name, template_node.node) V.graph.removed_buffers |= kernel.removed_buffers V.graph.inplaced_to_remove |= kernel.inplaced_to_remove self.scheduler.free_buffers() def codegen_sync(self): V.graph.wrapper_code.writeline("torch.cuda.synchronize()") def codegen_foreach(self, foreach_node): from .triton_foreach import ForeachKernel for partitions_with_metadata in ForeachKernel.horizontal_partition( foreach_node.get_subkernel_nodes(), self ): kernel = ForeachKernel() for nodes, tiled_groups, numel, rnumel in partitions_with_metadata: node_schedule = self.generate_node_schedule(nodes, numel, rnumel) ( reduction_hint_val, mutations, index_dtype, ) = self.get_kernel_args(node_schedule, numel, rnumel) subkernel = kernel.create_sub_kernel( *tiled_groups, reduction_hint=reduction_hint_val, mutations=mutations, index_dtype=index_dtype, ) self.codegen_node_schedule_with_kernel( node_schedule, subkernel, ) with V.set_kernel_handler(subkernel): # type: ignore[call-arg] for node in node_schedule: if node not in (EnableReduction, DisableReduction): node.mark_run() V.graph.removed_buffers |= subkernel.removed_buffers V.graph.inplaced_to_remove |= subkernel.inplaced_to_remove src_code = kernel.codegen_kernel() kernel_name = self.define_kernel(src_code, [foreach_node]) self.codegen_comment([foreach_node]) kernel.call_kernel(V.graph.wrapper_code, kernel_name) self.scheduler.free_buffers() @staticmethod @functools.lru_cache(32) def candidate_tilings(node): ranges, reduction_ranges = node.get_ranges() if len(ranges) <= 1: return () rw = node.pointwise_read_writes() assert len(rw.range_vars) == len(ranges) # isinstance(dep, MemoryDep): this filters out StarDeps. StarDeps refer to reads # that need to access the entire tensor; they don't contribute read indexing # information (and practically, they don't have dep.index so they can't be used # for stride_hints below dep_sources = [rw.reads, rw.writes] assert all( isinstance(dep, (MemoryDep, StarDep)) for dep in itertools.chain(*dep_sources) ) deps = [ dep for dep in itertools.chain(*dep_sources) if dep.name not in V.graph.removed_buffers and isinstance(dep, MemoryDep) ] write_names = {dep.name for dep in rw.writes} tilings: List[CandidateTiling] = [] for dep in deps: strides = V.graph.sizevars.stride_hints(dep.index, rw.range_vars) assert len(strides) == len(ranges) try: split = strides.index(1) + 1 if split == len(ranges): continue if all(s == 0 for s in strides[split:]): # if this is a broadcasted tensor and all dimensions after split are broadcast, # this is not a real split continue except ValueError: continue tiled_groups = ( V.graph.sizevars.simplify(sympy_product(ranges[:split])), V.graph.sizevars.simplify(sympy_product(ranges[split:])), ) # score by number of elements score = V.graph.sizevars.size_hint( sympy_product( size for size, stride in zip(ranges, strides) if stride != 0 ) ) if dep.name in write_names: # ngimel said contiguous writes is more important than reads score *= 2 if CandidateTiling.is_good_size(tiled_groups[0]): score *= 2 if CandidateTiling.is_good_size(tiled_groups[1]): score *= 2 if ( V.graph.sizevars.size_hint( score - sympy_product(itertools.chain(ranges, reduction_ranges)) ) >= 0 ): tilings.append(CandidateTiling(tiled_groups, score, dep.name)) return tilings @classmethod def select_tiling(cls, node_schedule, numel, reduction_numel=sympy.Integer(1)): """ Heuristics to decide how to tile kernels. Currently, we tile based on stride-1 dimensions. Returns: `(tile1, tile2, reduction_numel)` s.t. `tile1 * tile2 == numel` """ if reduction_numel != 1 or config.triton.max_tiles <= 1: # TODO(jansel): should we tile reductions? # do perf hint here if stride-1 dim is not being reduced if perf_hint_log.level <= logging.WARNING: for node in EnableReduction.filter(node_schedule): if len(cls.candidate_tilings(node)) > 0: perf_hint_log.info("reduction over non-contiguous dims") break return (numel, reduction_numel) seen_names = set() candidate_tiles: Counter[Any] = collections.Counter() for node in EnableReduction.filter(node_schedule): for tiling in cls.candidate_tilings(node): if tiling.name in seen_names: continue seen_names.add(tiling.name) candidate_tiles[tiling.tiling] += tiling.score ranked_tilings = [tiling for tiling, score in candidate_tiles.most_common()] if config.triton.max_tiles >= 3: # Consider adding a third dimension of tiling, but only # when a1 is a multiple of b1; otherwise, you have a lot # of stragglers which is annoying to generate code for. # # NB: More than three max tiles is not enabled by default. # Add one 3D tiling choice for i in range(1, len(ranked_tilings)): a0, a1 = ranked_tilings[0] b0, b1 = ranked_tilings[i] if V.graph.sizevars.size_hint(a1 - b1) == 0: continue if V.graph.sizevars.size_hint(a1 - b1) < 0: # swap so a0 is bigger a0, a1 = ranked_tilings[i] b0, b1 = ranked_tilings[0] assert V.graph.sizevars.size_hint(a1 - b1) > 0 if V.graph.sizevars.statically_known_multiple_of(a1, b1): tiling = (a0, FloorDiv(a1, b1), b1) ranked_tilings = [tiling] + ranked_tilings break # only 1 choice for now if len(ranked_tilings) > 1: perf_hint_log.info("possibly bad tiling: %s", ranked_tilings) for tiled_groups in ranked_tilings: new_groups = (*tiled_groups, reduction_numel) if all( TritonKernel.is_compatible(new_groups, node.get_ranges()) for node in node_schedule if isinstance(node, scheduler.SchedulerNode) ): return new_groups return (numel, reduction_numel) def flush(self): pass def benchmark_fused_nodes(self, nodes): _, (numel, rnumel) = max(nodes, key=lambda x: int(x.is_reduction())).group node_schedule = self.generate_node_schedule(nodes, numel, rnumel) tiled_groups = self.select_tiling(node_schedule, numel, rnumel) reduction_hint_val, mutations, index_dtype = self.get_kernel_args( node_schedule, numel, rnumel ) kernel = TritonKernel( *tiled_groups, reduction_hint=reduction_hint_val, mutations=mutations, index_dtype=index_dtype, ) # empty last_usage. May cause more aggressive 'evict_last'. Should be fine. for n in nodes: n.last_usage = set() self.codegen_node_schedule_with_kernel(node_schedule, kernel) with config.patch("benchmark_kernel", True), V.set_kernel_handler(kernel): # type: ignore[attr-defined] src_code = kernel.codegen_kernel() src_code = src_code.replace(str(Placeholder.KERNEL_NAME), "triton_") mod = PyCodeCache.load(src_code) def cache_file_path(): return os.path.splitext(mod.__file__)[0] + ".kernel_perf" # type: ignore[type-var,operator] def load_cache(): path = cache_file_path() if os.path.exists(path): with open(path) as fd: return float(fd.read()) return None def store_cache(): path = cache_file_path() with open(path, "w") as fd: fd.write(str(ms)) log.debug( "kernel src code for %s written to: %s", {n.get_name() for n in nodes}, mod.__file__, ) ms = load_cache() if ms is not None: return ms, mod.__file__ args = mod.get_args() call = mod.call wrapped_jit_function = mod.triton_ # call once to trigger the compilation call(wrapped_jit_function.clone_args(*args)[0]) launchers = wrapped_jit_function.launchers assert len(launchers) == 1 if launchers[0].n_spills > 0: # skip benchmarking the kernel if there are register spills ms = float("inf") else: # We have to clone the inplace updated arguments to avoid earlier calls # generating out of range indices for later calls. ms = do_bench(lambda: call(wrapped_jit_function.clone_args(*args)[0])) log.debug( "The fused kernel for %s took %.3f ms to run", {n.get_name() for n in nodes}, ms, ) store_cache() return ms, mod.__file__ @dataclasses.dataclass class CandidateTiling: tiling: Tuple[sympy.Expr, sympy.Expr] score: int # higher is better name: Optional[str] = None @staticmethod def is_good_size(s): """Somewhat arbitrary heuristic used to boost scores for some sizes""" s = V.graph.sizevars.size_hint(s) return s >= 32 and (s % 32 == 0) class DisableReduction: """ Marker to invoke `kernel.disable_reduction()`. This closes a reduction loop and allows for pointwise ops to occur on the output of a reduction. """ class EnableReduction: """ Marker to end a DisableReduction block. """ @staticmethod def filter(node_schedule): """ Get the nodes from node_schedule skipping those in a DisableReduction block. """ disabled = False for node in node_schedule: if node in (EnableReduction, DisableReduction): # Don't tile stuff outside the main reduction loop disabled = node is DisableReduction elif disabled: pass else: yield node class CantSplit(Exception): pass