# mypy: allow-untyped-defs import contextlib import dataclasses import functools import itertools import math import re import sys import warnings from copy import copy, deepcopy from enum import Enum from typing import cast, Dict, List, Optional, Sequence, Set, Tuple, Union import sympy import torch import torch.fx from torch._inductor import dependencies from torch._prims_common import is_float_dtype, is_integer_dtype from torch.utils._sympy.functions import CeilDiv, FloorDiv, ModularIndexing from torch.utils._sympy.symbol import free_symbol_is_type, symbol_is_type, SymT from ..._dynamo.utils import counters from .. import codecache, config, cpp_builder, cpu_vec_isa, ir, metrics from ..loop_body import LoopBody from ..scheduler import ( BaseSchedulerNode, BaseScheduling, ForeachKernelSchedulerNode, FusedSchedulerNode, Scheduler, SchedulerNode, ) from ..utils import ( cache_on_self, get_bounds_index_expr, get_fused_kernel_name, has_free_symbols, is_welford_reduction, parallel_num_threads, Placeholder, sympy_index_symbol, sympy_index_symbol_with_prefix, sympy_product, sympy_subs, ) from ..virtualized import NullKernelHandler, ops, OpsValue, V from .common import ( BackendFeature, BracesBuffer, CppWrapperKernelArgs, CSE, CSEVariable, DataTypePropagation, DeferredLine, DTYPE_TO_COMPUTATION_DTYPE, IndentedBuffer, Kernel, KernelArgs, OpOverrides, OptimizationContext, ) from .cpp_utils import ( _get_dtype_from_loopbodies, _get_loop_body, cexpr, cexpr_index, codegen_rand, CppCSEVariable, DTYPE_TO_CPP, INDEX_TYPE, LocalBufferContext, promote_args, template_fusion_with_epilogues_supported, unify_mask_base_type, value_to_cpp, ) _IS_WINDOWS = sys.platform == "win32" def get_export_declaration(): return "__declspec(dllexport)" if _IS_WINDOWS else "" schedule_log = torch._logging.getArtifactLogger(__name__, "schedule") NATIVE_OMP_RTYPES = {"+", "*", "^", "||", "min", "max"} RTYPE_TO_CPP = { "sum": "+", "prod": "*", "xor_sum": "^", "min": "min", "max": "max", "argmin": "argmin", "argmax": "argmax", "any": "||", "welford_reduce": "welford", "welford_combine": "welford", } VECTORIZABLE_RTYPES = { "max", "min", "sum", "prod", "xor_sum", "welford_reduce", "welford_combine", "argmin", "argmax", "any", } PYTHON_TO_CPP = { "Tensor": "at::Tensor", "int": "long", "float": "double", "bool": "bool", "str": "std::string", "ScalarType": "c10::ScalarType", "MemoryFormat": "at::MemoryFormat", "Layout": "at::Layout", "Device": "at::Device", "number": "at::Scalar", } CONTAINER_PYTHON_TO_CPP = { "List": "std::vector", "Optional": "std::optional", } DTYPE_LOWP_FP = [ torch.bfloat16, torch.float16, ] VECTORIZABLE_DTYPES: List[torch.dtype] = [ torch.float64, torch.float, torch.bfloat16, torch.float16, torch.bool, torch.uint8, torch.int8, torch.int32, torch.int64, ] MASKED_VECTORIZABLE_DTYPES: List[torch.dtype] = [ torch.float, torch.bfloat16, torch.float16, torch.uint8, torch.int8, ] def reduction_init(reduction_type, dtype): if dtype in DTYPE_LOWP_FP: # Since load promotes all half-precision inputs to float, the initial # constant for reduction must be promoted as well dtype = torch.float32 if reduction_type in ("xor_sum", "sum", "any"): return 0 if reduction_type == "prod": return 1 if reduction_type in ("max", "argmax", "min", "argmin"): cdtype = DTYPE_TO_CPP[dtype] min_var = ( f"-std::numeric_limits<{cdtype}>::infinity()" if is_float_dtype(dtype) else f"std::numeric_limits<{cdtype}>::min()" ) max_var = ( f"std::numeric_limits<{cdtype}>::infinity()" if is_float_dtype(dtype) else f"std::numeric_limits<{cdtype}>::max()" ) init_var = min_var if reduction_type in ("max", "argmax") else max_var return ( init_var if reduction_type in ("max", "min") else f"IndexValue<{cdtype}>{{0, {init_var}}}" ) if is_welford_reduction(reduction_type): return f"Welford<{DTYPE_TO_CPP[dtype]}>()" raise AssertionError(reduction_type) def reduction_acc_type(reduction_type, dtype): scalar_type = DTYPE_TO_CPP[DTYPE_TO_COMPUTATION_DTYPE[dtype]] if is_welford_reduction(reduction_type): return f"Welford<{scalar_type}>" if reduction_type in {"argmin", "argmax"}: return f"IndexValue<{scalar_type}>" return scalar_type def reduction_combine( reduction_type, var, next_value, index: Optional[sympy.Symbol] = None, src_dtype=None, ): is_bool = src_dtype == torch.bool if reduction_type == "sum": conjunction = "|" if is_bool else "+" return f"{var} {conjunction} {next_value}" if reduction_type == "prod": return f"{var} * {next_value}" if reduction_type == "xor_sum": return f"{var} ^ {next_value}" if reduction_type == "any": return f"{var} || {next_value}" if reduction_type in ("min", "max"): return f"{reduction_type}_propagate_nan({var}, {next_value})" if reduction_type == "welford_reduce": return f"welford_combine({var}, {next_value})" if reduction_type == "welford_combine": if isinstance(next_value, tuple): mean, m2, weight = next_value else: mean, m2, weight = reduction_project(reduction_type, next_value) return f"welford_combine({var}, {{{mean}, {m2}, {weight}}})" if reduction_type in ("argmin", "argmax"): if index is not None: return f"{reduction_type}_combine({var}, {next_value}, {index})" else: return f"{reduction_type}_combine({var}, {next_value})" raise AssertionError(reduction_type) def reduction_project(reduction_type, acc): if is_welford_reduction(reduction_type): return f"{acc}.mean", f"{acc}.m2", f"{acc}.weight" elif reduction_type in {"argmin", "argmax"}: return f"{acc}.index" return acc @functools.lru_cache def stride_at(index: sympy.Expr, var: sympy.Symbol): if not index.has(var): # see test_torchinductor_dynamic_shapes.py::test_full_boolean_dynamic_shapes_cpu # which has tmp0 = ops.index_expr(s0 >= 1024, torch.bool) and fails below calculation. # in this case, there is no dependencies between index and var. return sympy.Integer(0) replacement = {var: var + 1} new_index = sympy_subs(index, replacement) # type: ignore[arg-type] return sympy.simplify(new_index - index) @functools.lru_cache def simplify_index_in_vec_range(index: sympy.Expr, var: sympy.Expr, vec_length: int): """ Simplifies the index expression within the range of a vectorized loop. Given a vectorized loop variable `var` in the range of a loop with `vec_length`, this function transforms the `index` into an equivalent form. It handles simplifications for cases where `var` can be expressed as `vec_length * a + b`, where `b` ranges from 0 to `vec_length - 1`. The function reduces occurrences of `FloorDiv` and `ModularIndexing` in the `index` with best-effort optimizations. NOTE: The simplified index expression is intended for analysis purposes only, not for code generation. It replaces `FloorDiv` and `ModularIndexing` with free variables which are not dependent on the loop variable `var` in the vectorized range. Check https://github.com/pytorch/pytorch/pull/117221#discussion_r1449746217 for more details. Examples: 1. If `var` is `x3` and `vec_length` is 16, and `x3 = 16*a + b`, then `FloorDiv(x3, div)` or `ModularIndexing(x3, div, mod)` becomes a free variable when `div` is divisible by 16. 2. `ModularIndexing(x3, 1, mod)` can be simplified to `x3 + c` where `c` is a free variable when `mod` is divisible by 16. """ div_freevar_id = 0 mod_freevar_id = 0 def visit_indexing_div(divisor): nonlocal div_freevar_id result = FloorDiv(var, divisor) if sympy.gcd(divisor, vec_length) == vec_length: result = sympy.Symbol(f"{var}_div_c{div_freevar_id}") div_freevar_id += 1 return result def visit_modular_indexing(divisor, modulus): nonlocal mod_freevar_id result = ModularIndexing(var, divisor, modulus) if sympy.gcd(divisor, vec_length) == vec_length: result = sympy.Symbol(f"{var}_mod_c{mod_freevar_id}") mod_freevar_id += 1 elif divisor == 1 and sympy.gcd(modulus, vec_length) == vec_length: result = var + sympy.Symbol(f"{var}_mod_c{mod_freevar_id}") mod_freevar_id += 1 return result original_index = index div = sympy.Wild("divisor", integer=True) if index.has(FloorDiv): index = index.replace(FloorDiv(var, div), visit_indexing_div) mod = sympy.Wild("modulus", integer=True) if index.has(ModularIndexing): index = index.replace(ModularIndexing(var, div, mod), visit_modular_indexing) index = sympy.simplify(index) if index != original_index: return simplify_index_in_vec_range(index, var, vec_length) return index @functools.lru_cache def stride_at_vec_range( index: sympy.Expr, var: sympy.Symbol, vec_length: Optional[int] = None ): if vec_length: index = simplify_index_in_vec_range(index, var, vec_length) return stride_at(index, var) class OuterLoopFusedSchedulerNode(FusedSchedulerNode): @classmethod def fuse( # type: ignore[override] cls, node1: BaseSchedulerNode, node2: BaseSchedulerNode, outer_loop_fusion_depth ): assert node1.scheduler is node2.scheduler assert all( type(node) in ( OuterLoopFusedSchedulerNode, SchedulerNode, FusedSchedulerNode, ) for node in (node1, node2) ) if any(type(node) is OuterLoopFusedSchedulerNode for node in (node1, node2)): return cls( node1.scheduler, ( list(node1.get_outer_nodes()) if type(node1) is OuterLoopFusedSchedulerNode else [ node1, ] ) + ( list(node2.get_outer_nodes()) if type(node2) is OuterLoopFusedSchedulerNode else [ node2, ] ), outer_loop_fusion_depth, ) else: return cls(node1.scheduler, [node1, node2], outer_loop_fusion_depth) # type: ignore[list-item] def __init__( self, scheduler: "Scheduler", outer_fused_nodes: List[Union[FusedSchedulerNode, SchedulerNode]], outer_loop_fusion_depth, ): self.outer_fused_nodes: List[ Union[FusedSchedulerNode, SchedulerNode] ] = outer_fused_nodes self.outer_loop_fusion_depth = outer_loop_fusion_depth flatten_snodes = [] for _node in self.outer_fused_nodes: assert isinstance(_node, (SchedulerNode, FusedSchedulerNode)) flatten_snodes.extend(list(_node.get_nodes())) super().__init__(scheduler, flatten_snodes) # type: ignore[arg-type] def get_outer_nodes(self): return self.outer_fused_nodes def check_outer_fusion_loop_level_attr( self, cpp_kernel_proxy_list, outer_loop_fusion_depth ): # This function ensures that the same tiling split is applied at each loop level within the outer loop fusion depth. # In the fusion stage, we only examine nodes with same vars and reduce. # However, for nodes with same vars and reduce, the loops may still have different tile splits. # For example (test_expr_vec_non_contiguous in test_cpu_repro.py): # * buf0 tiling along the 2nd loop level, buf1 tiling along the 3rd loop level. # If the check failed, we should fall back to standard loop codegen. def _inner( left_loop_level: LoopLevel, right_loop_level: LoopLevel, loop_fusion_depth: int, ) -> bool: # Check if same loop level attr outer_loops_attr_compare_list = [ "var", "size", "offset", "steps", ] if not ( all( getattr(left_loop_level, attr_compare) == getattr(right_loop_level, attr_compare) for attr_compare in outer_loops_attr_compare_list ) ): return False assert loop_fusion_depth >= 1 if (loop_fusion_depth := loop_fusion_depth - 1) > 0: # If the next loop level is expected to undergo outer loop fusion, # there should be no kernel present at the current loop level. assert ( left_loop_level.kernel is None and right_loop_level.kernel is None ) # Check next loop level attr if any( # Assume no main/tail loop split at any outer loop fusion depth # Given no clear performance benefit for this complex case len(loop_level.inner) != 1 for loop_level in [left_loop_level, right_loop_level] ) or not _inner( left_loop_level.inner[0], right_loop_level.inner[0], loop_fusion_depth, ): return False return True for idx in range(len(cpp_kernel_proxy_list) - 1): left_loop_nest = cpp_kernel_proxy_list[idx].loop_nest right_loop_nest = cpp_kernel_proxy_list[idx + 1].loop_nest if any( # Assume no main/tail loop split at any outer loop fusion depth len(loop_nest.root) != 1 for loop_nest in [left_loop_nest, right_loop_nest] ) or not _inner( left_loop_nest.root[0], right_loop_nest.root[0], outer_loop_fusion_depth ): return False return True def merge_outer_fusion_kernels( self, cpp_kernel_proxy_list, ): loop_nest_list: List[LoopNestWithSplit] = [ kernel.loop_nest for kernel in cpp_kernel_proxy_list ] kernel_group = cpp_kernel_proxy_list[0].kernel_group def _merge_outer_fusion_loop_levels( loop_level_nested_list: List[List["LoopLevel"]], outer_loop_fusion_depth, ): assert outer_loop_fusion_depth >= 1 # Assume no main/tail loop split at any outer loop fusion depth assert all( len(loop_level_list) == 1 for loop_level_list in loop_level_nested_list ) if (outer_loop_fusion_depth := outer_loop_fusion_depth - 1) >= 1: # Further merge the next loop level next_loop_level_nested_list = [ loop_level_list[0].inner for loop_level_list in loop_level_nested_list ] _merge_outer_fusion_loop_levels( next_loop_level_nested_list, outer_loop_fusion_depth, ) else: outer_loop_fused_kernel = OuterLoopFusedKernel(kernel_group) loop_level_of_first_kernel = loop_level_nested_list[0][0] for kernel_idx in range(len(loop_level_nested_list)): outer_loop_fused_kernel.inner.append( deepcopy(loop_level_nested_list[kernel_idx][0]), ) loop_level_of_first_kernel.inner = [] loop_level_of_first_kernel.kernel = outer_loop_fused_kernel # Merge the List[LoopNestWithSplit] from cpp_kernel_proxy_list # into cpp_kernel_proxy_list[0].loop_nest _merge_outer_fusion_loop_levels( [_loop_nest.root for _loop_nest in loop_nest_list], # type: ignore[misc] self.outer_loop_fusion_depth, ) return cpp_kernel_proxy_list[0] class RecordOptimizationContext: def __init__(self, func_name: str = ""): self.func_name = func_name self.current_node: Optional[torch.fx.Node] = None self.opt_ctx: Optional[OptimizationContext] = None def __enter__(self): assert V.interpreter assert V.interpreter.current_node self.current_node = V.interpreter.current_node assert self.current_node is not None if OptimizationContext.key in self.current_node.meta: self.opt_ctx = self.current_node.meta[OptimizationContext.key] else: self.opt_ctx = OptimizationContext() assert self.opt_ctx is not None self.opt_ctx.ops_name = self.func_name return self def __exit__(self, exc_type, exc_val, exc_tb): assert self.current_node assert self.opt_ctx self.current_node.meta[OptimizationContext.key] = self.opt_ctx def get_opt_ctx(self): return self.opt_ctx def get_fx_node(self): assert self.current_node return self.current_node class CppOverrides(OpOverrides): """Map element-wise ops to C++""" @staticmethod def add(a, b): return f"decltype({a})({a} + {b})" @staticmethod def sub(a, b): return f"decltype({a})({a} - {b})" @staticmethod def mul(a, b): return f"decltype({a})({a} * {b})" @staticmethod def to_dtype(x, dtype, src_dtype=None, use_compute_types=True): assert isinstance(x, CppCSEVariable) if src_dtype is None: src_dtype = x.dtype expr = V.kernel.get_to_dtype_expr(x, dtype, src_dtype) csevar = V.kernel.cse.generate(V.kernel.compute, expr) csevar.update_on_args("to_dtype", (x, dtype), {"src_dtype": src_dtype}) if dtype in [torch.bfloat16, torch.float16] and src_dtype == torch.float: """ https://github.com/pytorch/pytorch/issues/115260 For FusedSchedulerNode[node1, node2], the node2 loads what node1 stores and the buffer is in low-precision floating point data type. When the output of node1 also serves as the output of the kernel, the result of nodes would be different from the case when output of node1 is not the output of the kernel (where we don't need to insert `to_dtype` for legalization). To address the problem, on storing the lowp node1 output, we also add the inverse dtype conversion to high precision data type to the cse cache. Example (pseudo code): node1_output = ... node1_output_lowp = to_dtype(node1_output, dtype=torch.bfloat16) store(buf, node1_output_lowp) node2_input_lowp = load(buf) node2_input = to_dtype(node2_input_lowp, dtype=torch.float) Without cse cache trick: node1_output = ... node1_output_lowp = to_dtype(node1_output, dtype=torch.bfloat16) store(buf, node1_output_lowp) node2_input_lowp = node_output_lowp # hit store cache node2_input = to_dtype(node2_input_lowp, dtype=torch.float) With cse cache trick: node1_output = ... node1_output_lowp = to_dtype(node1_output, dtype=torch.bfloat16) # also add `to_dtype(node1_input_lowp, dtype=torch.float)` -> `node1_output` to cse cache store(buf, node1_output_lowp) node2_input_lowp = node_output_lowp # hit store cache node2_input = node1_output # hit cse cache """ V.kernel.cache_dtype_convert(x, src_dtype, csevar, dtype) return csevar @staticmethod def to_dtype_bitcast(x, dtype, src_dtype): assert dtype in DTYPE_TO_CPP, f"{dtype} missing from {__name__}.DTYPE_TO_CPP" if src_dtype in (torch.float16, torch.bfloat16): # c10::bit_cast requires the source and target have the bitwidth. # Because the input tensor's dtype could be promoted, e.g. from float16 to # float, we have to cast the tensor to its original source dtype before # invoking bit_cast. We also need to convert the bit-casted tensor # back to float to make sure we keep using higher precision values # for the rest of the computation. cast_x = f"c10::convert<{DTYPE_TO_CPP[src_dtype]}>({x})" cast_x = f"c10::bit_cast<{DTYPE_TO_CPP[dtype]}>({cast_x})" return f"c10::convert<{DTYPE_TO_CPP[torch.float32]}>({cast_x})" else: return f"c10::bit_cast<{DTYPE_TO_CPP[dtype]}>({x})" @staticmethod def abs(x): return f"std::abs({x})" @staticmethod def sin(x): return f"std::sin({x})" @staticmethod def cos(x): return f"std::cos({x})" @staticmethod def neg(x): return f"decltype({x})(-{x})" @staticmethod def exp(x): # return f"Sleef_expf_u10({x})" return f"std::exp({x})" @staticmethod def exp2(x): return f"std::exp2({x})" @staticmethod def expm1(x): return f"std::expm1({x})" @staticmethod def erf(x): return f"std::erf({x})" @staticmethod def erfc(x): return f"std::erfc({x})" @staticmethod def erfinv(x): return f"calc_erfinv({x})" @staticmethod def sqrt(x): return f"std::sqrt({x})" @staticmethod def rsqrt(x): return f"1 / std::sqrt({x})" @staticmethod def log1p(x): bug = config.cpp.inject_log1p_bug_TESTING_ONLY if bug == "accuracy": return f"{x} + decltype({x})(1)" elif bug is None: return f"std::log1p({x})" else: raise AssertionError( f"unrecognized config cpp.inject_log1p_bug_TESTING_ONLY = {bug!r}" ) @staticmethod def tan(x): return f"std::tan({x})" @staticmethod def tanh(x): return f"std::tanh({x})" @staticmethod def signbit(x): """ On windows std::signbit only support float type. Ref: https://learn.microsoft.com/en-us/cpp/c-runtime-library/reference/signbit?view=msvc-170 """ return ( f"std::signbit(static_cast({x}))" if _IS_WINDOWS else f"std::signbit({x})" ) @staticmethod def pow(a, b): return f"std::pow({a}, {b})" @staticmethod def log(x): return f"std::log({x})" @staticmethod def round(x): return f"std::nearbyint({x})" @staticmethod def floor(x): return f"std::floor({x})" @staticmethod def floordiv(a, b): # a and b are integer type quot = f"{a} / {b}" rem = f"{a} % {b}" return f"(({a} < 0) != ({b} < 0) ? ({rem} != 0 ? {quot} - 1 : {quot}) : {quot})" @staticmethod def ceil(x): return f"std::ceil({x})" @staticmethod def trunc(x): return f"std::trunc({x})" @staticmethod def truncdiv(a, b): # a and b are integer type return f"{a} / {b}" @staticmethod def fmod(a, b): return f"std::fmod({a}, {b})" @staticmethod def isinf(x): return f"std::isinf({x})" @staticmethod def isnan(x): return f"std::isnan({x})" @staticmethod def lgamma(x): return f"std::lgamma({x})" @staticmethod def acos(x): return f"std::acos({x})" @staticmethod def acosh(x): return f"std::acosh({x})" @staticmethod def cosh(x): return f"std::cosh({x})" @staticmethod def sinh(x): return f"std::sinh({x})" @staticmethod def asin(x): return f"std::asin({x})" @staticmethod def asinh(x): return f"std::asinh({x})" @staticmethod def atan2(x, y): return f"std::atan2({x}, {y})" @staticmethod def atan(x): return f"std::atan({x})" @staticmethod def atanh(x): return f"std::atanh({x})" @staticmethod def copysign(x, y): return f"std::copysign({x}, {y})" @staticmethod def frexp(x): cache_keys = f"frexp({x})[0]", f"frexp({x})[1]" if all(cache_key in V.kernel.cse.cache for cache_key in cache_keys): return tuple(V.kernel.cse.cache[cache_key] for cache_key in cache_keys) code = BracesBuffer() exponent = V.kernel.cse.newvar() mantissa = V.kernel.cse.newvar() code.writeline(f"int32_t {exponent};") code.writeline(f"auto {mantissa} = std::frexp({x}, &{exponent});") V.kernel.compute.splice(code) cse_vars = (mantissa, exponent) for cache_key, cse_var in zip(cache_keys, cse_vars): V.kernel.cse.cache[cache_key] = cse_var return mantissa, exponent @staticmethod def hypot(x, y): return f"std::hypot({x}, {y})" @staticmethod def log10(x): return f"std::log10({x})" @staticmethod def log2(x): return f"std::log2({x})" @staticmethod def nextafter(x, y): return f"std::nextafter({x}, {y})" @staticmethod def relu(x): bug = config.cpp.inject_relu_bug_TESTING_ONLY if bug == "compile_error": return "compile error!" elif bug == "runtime_error": return f"{x}; throw 1" elif bug == "accuracy": return f"{x} + decltype({x})(1)" elif bug is None: return f"std::max({x}, decltype({x})(0))" else: raise AssertionError( f"unrecognized config cpp.inject_relu_bug_TESTING_ONLY = {bug!r}" ) @staticmethod def minimum(a, b): return f"min_propagate_nan({a}, {b})" @staticmethod def maximum(a, b): return f"max_propagate_nan({a}, {b})" @staticmethod def where(a, b, c): return f"{a} ? {b} : {c}" @staticmethod def mod(a, b): return f"mod({a}, {b})" @staticmethod def constant(val, dtype): if dtype in DTYPE_LOWP_FP: # Since load promotes all half-precision inputs to float, constants # must be promoted as well dtype = torch.float32 return value_to_cpp(val, DTYPE_TO_CPP[dtype]) @staticmethod def index_expr(expr, dtype): idx_str = cexpr(V.kernel.rename_indexing(expr)) var = V.kernel.cse.generate( V.kernel.compute, idx_str, bounds=get_bounds_index_expr(expr) ) return ops.to_dtype(var, dtype) @staticmethod def masked(mask, body, other): code = BracesBuffer() # Write masked operation into a lambda body_var = V.kernel.cse.newvar() code.writeline(f"auto {body_var} = [&]") with V.kernel.swap_buffers(code), code.indent(): result = body() code.writeline(f"return {result};") code.writeline(";") V.kernel.compute.splice(code) # Use the lambda's return type as the type of other other_code = value_to_cpp(other, f"decltype({body_var}())") return f"{mask} ? {body_var}() : {other_code}" @staticmethod def logical_and(a, b): return f"{a} && {b}" @staticmethod def logical_not(a): return f"!{a}" @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"decltype({a})({a} & {b})" @staticmethod def bitwise_not(a): return f"decltype({a})(~{a})" @staticmethod def bitwise_or(a, b): return f"decltype({a})({a} | {b})" @staticmethod def bitwise_xor(a, b): return f"decltype({a})({a} ^ {b})" @staticmethod def bitwise_left_shift(a, b): return f"decltype({a})({a} << {b})" @staticmethod def bitwise_right_shift(a, b): return f"decltype({a})({a} >> {b})" @staticmethod def rand(seed: sympy.Expr, offset: sympy.Expr): return f"normalized_rand_cpu({seed}, {offset})" @staticmethod def randn(seed: sympy.Expr, offset: sympy.Expr): return f"randn_cpu({seed}, {offset})" @staticmethod def randint64(seed: sympy.Expr, offset: sympy.Expr, low, high): return f"randint64_cpu({seed}, {offset}, {low}, {high})" @staticmethod def sigmoid(x): return f"decltype({x})(1) / (decltype({x})(1) + std::exp(-{x}))" @staticmethod def sign(x): code = BracesBuffer() scalar_zero = f"decltype({x})(0)" scalar_one = f"decltype({x})(1)" code.writeline("[&]()") with code.indent(): code.writeline(f"auto left = {x} > 0 ? {scalar_one} : {scalar_zero};") code.writeline(f"auto right = {x} < 0 ? {scalar_one} : {scalar_zero};") code.writeline("return left - right;") code.writeline("()") return code CppOverrides._initialize_pointwise_overrides("cpp") class CppVecOverrides(CppOverrides): """Map element-wise ops to aten vectorization C++""" def __new__(cls, *args, **kargs): self = super().__new__(cls) def wrap(func): # `CppVecKernel` generates both scalar ops and vector ops according to # whether the inputs are scalars or vectors while all ops in `CppVecOverrides` # (except for some ops explained below) assume the inputs are vectors. We wrap the ops in # `CppVecOverrides` to broadcast scalar inputs to vectors if needed or fallback to # `CppOverrides` when all inputs are scalars. # # Notes on ops handled separately in their own functions: # `ops.masked`: # needs recursive handling of masked body. # `ops.index_expr`: # needs to further analyze the dependency of the index expression on # the tiling itervar. def wrapper(*args, **kwargs): scalars = [ arg for arg in args if isinstance(arg, (int, sympy.Expr)) or (isinstance(arg, CppCSEVariable) and not arg.is_vec) ] vectors = [ arg for arg in args if isinstance(arg, CppCSEVariable) and arg.is_vec ] new_args = list(args) if scalars and vectors: new_args = [] for arg in args: if isinstance(arg, (int, sympy.Expr)): if isinstance(arg, sympy.Expr) and not arg.is_number: arg = ops.index_expr(arg, torch.int64) else: arg = ops.constant(arg, torch.int64) arg = arg.value if isinstance(arg, OpsValue) else arg new_args.append(arg) # DType Promotion if vectors: # We have saw several data type mismatch issues related with index_expr in # the lowering phase of torch.int8. torch.int32, torch.int64. # 1. int32 and int64 in test_torchinductor.py::test_max_pool2d_with_indices_backward3_cpu # 2. int8 and int32 in test_torchinductor.py::test_max_pool2d5_cpu # 3. int32 and fp32 in test_torchinductor_dynamic_shapes.py::test_avg_pool2d8_dynamic_shapes_cpu if len(new_args) == 2: new_args = promote_args(new_args) elif func == CppVecOverrides.where: new_args[1:] = promote_args(new_args[1:]) # Broadcast scalar args to vector if scalars and vectors: assert isinstance(V.kernel, CppVecKernel) new_args = [ V.kernel.broadcast(new_arg) if ( isinstance(new_arg, CppCSEVariable) and not new_arg.is_vec and func not in [ CppVecOverrides.rand, CppVecOverrides.randn, CppVecOverrides.randint64, ] ) else new_arg for new_arg in new_args ] if vectors: return func(*new_args, **kwargs) else: # fallback to scalar ops scalar_ops = super(CppVecOverrides, self) scalar_func = getattr( scalar_ops, func.__name__, scalar_ops.__getattr__(func.__name__) # type: ignore[attr-defined] ) assert scalar_func is not None return scalar_func(*args, **kwargs) return wrapper for name, method in vars(CppVecOverrides).items(): if getattr(method, "__class__", None) == staticmethod and name not in [ "masked", "index_expr", ]: setattr(self, name, wrap(method.__func__)) return self @staticmethod def add(a, b): return f"{a} + {b}" @staticmethod def sub(a, b): return f"{a} - {b}" @staticmethod def mul(a, b): return f"{a} * {b}" @staticmethod def truediv(a, b): return f"{a} / {b}" @staticmethod def abs(x): return f"{x}.abs()" @staticmethod def sin(x): return f"{x}.sin()" @staticmethod def cos(x): return f"{x}.cos()" @staticmethod def exp(x): return f"{x}.exp()" @staticmethod def exp2(x): return f"{x}.exp2()" @staticmethod def expm1(x): # decompose for a better performance vec_one = f"decltype({x})(1)" return f"{x}.exp() - {vec_one}" @staticmethod def erf(x): return f"{x}.erf()" @staticmethod def erfc(x): return f"{x}.erfc()" @staticmethod def erfinv(x): return f"{x}.erfinv()" @staticmethod def sqrt(x): return f"{x}.sqrt()" @staticmethod def eq(x, y): assert isinstance(V.kernel, CppVecKernel) assert isinstance(x, CppCSEVariable) assert x.dtype is not None return f"{V.kernel._get_mask_type(x.dtype)}({x} == {y})" @staticmethod def ne(x, y): assert isinstance(V.kernel, CppVecKernel) assert isinstance(x, CppCSEVariable) if x.dtype == torch.bool: assert y.dtype == torch.bool x_cast, y_cast = unify_mask_base_type(V.kernel.compute, (x, y)) return f"{x_cast} != {y_cast}" else: assert x.dtype is not None return f"{V.kernel._get_mask_type(x.dtype)}({x} != {y})" @staticmethod def lt(x, y): assert isinstance(V.kernel, CppVecKernel) assert isinstance(x, CppCSEVariable) assert x.dtype is not None return f"{V.kernel._get_mask_type(x.dtype)}({x} < {y})" @staticmethod def gt(x, y): assert isinstance(V.kernel, CppVecKernel) assert isinstance(x, CppCSEVariable) assert x.dtype is not None return f"{V.kernel._get_mask_type(x.dtype)}({x} > {y})" @staticmethod def le(x, y): assert isinstance(V.kernel, CppVecKernel) assert isinstance(x, CppCSEVariable) assert x.dtype is not None return f"{V.kernel._get_mask_type(x.dtype)}({x} <= {y})" @staticmethod def ge(x, y): assert isinstance(V.kernel, CppVecKernel) assert isinstance(x, CppCSEVariable) assert x.dtype is not None return f"{V.kernel._get_mask_type(x.dtype)}({x} >= {y})" @staticmethod def and_(x, y): return f"{x} & {y}" @staticmethod def rsqrt(x): return f"{x}.rsqrt()" @staticmethod def pow(a, b): return f"{a}.pow({b})" @staticmethod def log(x): return f"{x}.log()" @staticmethod def round(x): return f"{x}.round()" @staticmethod def floor(x): return f"{x}.floor()" @staticmethod def ceil(x): return f"{x}.ceil()" @staticmethod def trunc(x): return f"{x}.trunc()" @staticmethod def fmod(a, b): return f"{a}.fmod({b})" @staticmethod def lgamma(x): return f"{x}.lgamma()" @staticmethod def logical_and(a, b): return f"{a} & {b}" @staticmethod def logical_not(a): return f"~{a}" @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 load_seed(name, offset): assert isinstance(V.kernel, CppVecKernel) return f"{V.kernel.load(name, offset)}" @staticmethod def rand(seed, offset): assert isinstance(V.kernel, CppVecKernel) code = BracesBuffer() rand_function = ( f"result[offset_idx] = normalized_rand_cpu({seed}, offset[offset_idx]);" ) return codegen_rand(offset, code, rand_function) @staticmethod def randn(seed, offset): assert isinstance(V.kernel, CppVecKernel) code = BracesBuffer() rand_function = f"result[offset_idx] = randn_cpu({seed}, offset[offset_idx]);" return codegen_rand(offset, code, rand_function) @staticmethod def randint64(seed, offset, low, high): assert isinstance(V.kernel, CppVecKernel) code = BracesBuffer() rand_function = f"result[offset_idx] = randint64_cpu({seed}, offset[offset_idx], {low}, {high});" return codegen_rand(offset, code, rand_function, torch.int64) @staticmethod def remainder(a, b): assert ( a.dtype == b.dtype ), "remainder vec implementation expect the same inputs' dtype." return f"{a} - ({CppVecOverrides.floordiv(a, b)}) * {b}" @staticmethod def tan(a): return f"{a}.tan()" @staticmethod def tanh(a): vec_one = f"decltype({a})(1)" vec_two = f"decltype({a})(2)" vec_minus_two = f"decltype({a})(-2)" return f"{vec_two} / ({vec_one} + ({vec_minus_two} * {a}).exp()) - {vec_one}" @staticmethod def reciprocal(a): return f"{a}.reciprocal()" @staticmethod def atan(x): return f"{x}.atan()" @staticmethod def acos(x): return f"{x}.acos()" @staticmethod def asin(x): return f"{x}.asin()" @staticmethod def cosh(x): return f"{x}.cosh()" @staticmethod def sinh(x): return f"{x}.sinh()" @staticmethod def log10(x): return f"{x}.log10()" @staticmethod def log2(x): return f"{x}.log2()" @staticmethod def nextafter(x, y): return f"{x}.nextafter({y})" @staticmethod def copysign(a, b): return f"{a}.copysign({b})" @staticmethod def atan2(a, b): return f"{a}.atan2({b})" @staticmethod def hypot(a, b): return f"{a}.hypot({b})" @staticmethod def atanh(x): # For real x, atanh(x) = 1/2 * log((1+x)/(1-x)) vec_one = f"decltype({x})(1)" vec_one_half = f"decltype({x})(0.5)" return f"{vec_one_half} * (({vec_one} + {x})/({vec_one} - {x})).log()" @staticmethod def asinh(x): # For real x, asinh(x) = log(x + sqrt(1 + x**2)) vec_one = f"decltype({x})(1)" return f"({x} + ({vec_one} + {x}*{x}).sqrt()).log()" @staticmethod def acosh(x): return f"{x}.acosh()" @staticmethod def relu(x): bug = config.cpp.inject_relu_bug_TESTING_ONLY if bug == "compile_error": return "compile error!" elif bug == "runtime_error": return f"{x}; throw 1" elif bug == "accuracy": return f"{x} + decltype({x})(1)" elif bug is None: return f"at::vec::clamp_min({x}, decltype({x})(0))" else: raise AssertionError( f"unrecognized config cpp.inject_relu_bug_TESTING_ONLY = {bug!r}" ) # TODO: this seems to be dead @staticmethod def sigmoid(x): return f"decltype({x})(1)/(decltype({x})(1) + {x}.neg().exp())" @staticmethod def neg(x): return f"{x}.neg()" @staticmethod def floordiv(a, b): if is_float_dtype(a.dtype): assert ( a.dtype == b.dtype ), "div_floor_floating_vec implementation expect the same inputs' dtype." return f"div_floor_floating_vec({a}, {b})" else: assert all(is_integer_dtype(item.dtype) for item in [a, b]) # a and b are integer type _t = f"decltype({a})" if V.kernel._get_raw_num_vectors(b.dtype) < 1: # Doing blend to set the remaining bits of b to non-zero b = f"{_t}::blend<{(1 << V.kernel.tiling_factor) - 1}>({_t}(1), {b})" quot = f"{a} / {b}" has_rem = f"({a} % {b} != {_t}(0))" is_neg = f"(({a} < {_t}(0)) != ({b} < {_t}(0)))" return f"{_t}::blendv({quot}, {quot} - {_t}(1), {has_rem} & {is_neg})" @staticmethod def truncdiv(a, b): # a and b are integer type if V.kernel._get_raw_num_vectors(b.dtype) < 1: # Doing blend to set the remaining bits of b to non-zero _t = f"decltype({b})" b = f"{_t}::blend<{(1 << V.kernel.tiling_factor) - 1}>({_t}(1), {b})" return f"{a} / {b}" @staticmethod def minimum(a, b): if a.dtype == torch.bool: assert b.dtype == torch.bool a_cast, b_cast = unify_mask_base_type(V.kernel.compute, (a, b)) return f"{a_cast} & {b_cast}" else: return f"at::vec::minimum({a}, {b})" @staticmethod def maximum(a, b): if a.dtype == torch.bool: assert b.dtype == torch.bool a_cast, b_cast = unify_mask_base_type(V.kernel.compute, (a, b)) return f"{a_cast} | {b_cast}" else: return f"at::vec::maximum({a}, {b})" @staticmethod def square(a): return f"{a} * {a}" @staticmethod def where(a, b, c): assert isinstance(V.kernel, CppVecKernel) if b.dtype == torch.bool: assert c.dtype == torch.bool blendv_a, blendv_b, blendv_c = unify_mask_base_type( V.kernel.compute, (a, b, c) ) return f"decltype({blendv_b})::blendv({blendv_c}, {blendv_b}, {blendv_a})" else: return f"decltype({b})::blendv({c}, {b}, {V.kernel._get_mask_cast(a, b.dtype)})" @staticmethod def sign(x): code = BracesBuffer() vec_zero = f"decltype({x})(0)" vec_one = f"decltype({x})(1)" blendv_l = f"decltype({x})::blendv({vec_zero}, {vec_one}, {vec_zero} < {x})" blendv_r = f"decltype({x})::blendv({vec_zero}, {vec_one}, {x} < {vec_zero})" code.writeline("[&]()") with code.indent(): code.writeline(f"auto left = {blendv_l};") code.writeline(f"auto right = {blendv_r};") code.writeline("return left - right;") code.writeline("()") return code @staticmethod def to_dtype(x, dtype, src_dtype=None, use_compute_dtypes=True): assert dtype in [ torch.bool, torch.float64, torch.float, torch.bfloat16, torch.float16, torch.uint8, torch.int8, torch.int32, torch.int64, ], f"{__name__} does not support {dtype}" assert isinstance(x, CppCSEVariable) src_dtype = x.dtype expr = V.kernel.get_to_dtype_expr(x, dtype, src_dtype) csevar = V.kernel.cse.generate(V.kernel.compute, expr) csevar.update_on_args("to_dtype", (x, dtype), {"src_dtype": src_dtype}) if dtype in [torch.bfloat16, torch.float16] and src_dtype == torch.float: V.kernel.cache_dtype_convert(x, src_dtype, csevar, dtype) return csevar @staticmethod def log1p(x): bug = config.cpp.inject_log1p_bug_TESTING_ONLY if bug == "accuracy": return f"{x} + decltype({x})(1)" elif bug is None: return f"{x}.log1p()" else: raise AssertionError( f"unrecognized config cpp.inject_log1p_bug_TESTING_ONLY = {bug!r}" ) @staticmethod def masked(mask, body, other): assert isinstance(V.kernel, CppVecKernel) code = BracesBuffer() var = V.kernel.cse.newvar() with V.kernel.masked(mask) as new_mask: code.writeline(f"auto {var} = [&]") with V.kernel.swap_buffers(code), code.indent(): result = body() code.writeline(f"return {result};") code.writeline(";") V.kernel.compute.splice(code) dtype = result.dtype body_code = f"{var}()" body_code_vec = ( body_code if result.is_vec else f"{V.kernel._get_vec_type(dtype)}({body_code})" ) other_code = value_to_cpp(other, DTYPE_TO_CPP[dtype]) # loading bool as VecMask other_code_vec = ( f"{V.kernel._get_mask_type()}::from({other_code})" if dtype == torch.bool else f"{V.kernel._get_vec_type(dtype)}({other_code})" ) assert isinstance(new_mask, CppCSEVariable), new_mask if new_mask.is_vec: code = BracesBuffer() code.writeline("[&]") with V.kernel.swap_buffers(code), code.indent(): code.writeline(f"if ({new_mask}.all_zero())") with code.indent(): code.writeline(f"return {other_code_vec};") code.writeline("else") with code.indent(): # Create cse variable to reuse kernel.overrides.where body_vec_var = V.kernel.cse.generate( V.kernel.compute, body_code_vec, ) other_vec_var = V.kernel.cse.generate( V.kernel.compute, other_code_vec, ) assert isinstance(body_vec_var, CppCSEVariable), body_vec_var assert isinstance(other_vec_var, CppCSEVariable), other_vec_var body_vec_var.dtype = dtype other_vec_var.dtype = dtype code.writeline( f"return {V.kernel.overrides.where(new_mask, body_vec_var, other_vec_var)};" ) code.writeline("()") csevar = V.kernel.cse.generate( V.kernel.compute, code, ) elif result.is_vec: csevar = V.kernel.cse.generate( V.kernel.compute, f"{mask} ? {body_code_vec} : {other_code_vec}" ) else: csevar = V.kernel.cse.generate( V.kernel.compute, f"{mask} ? {body_code} : {other_code}" ) # `result` is explicitly added to the args for correct propagation # of relevant itervars and vectorization status. csevar.update_on_args("masked", (mask, body, other, result), {}) return csevar @staticmethod def index_expr(expr, dtype): assert isinstance(V.kernel, CppVecKernel) index = V.kernel.rename_indexing(expr) tiling_var = V.kernel.itervars[V.kernel.tiling_idx] stride = V.kernel._try_get_const_stride(index, tiling_var) if stride == 0: return CppOverrides.index_expr(expr, dtype) elif stride is not None: idx = V.kernel.cse.generate( V.kernel.compute, cexpr(index), bounds=get_bounds_index_expr(expr) ) value = ops.to_dtype(idx, dtype) if isinstance(value, OpsValue): value = value.value csevar = V.kernel.arange(value, stride) else: csevar = V.kernel._load_or_store_non_contiguous( # type: ignore[assignment] None, index, dtype, V.kernel.compute ) csevar.update_on_args("index_expr", (expr, dtype), {}) return csevar @staticmethod def frexp(x): cache_keys = f"frexp({x})[0]", f"frexp({x})[1]" if all(cache_key in V.kernel.cse.cache for cache_key in cache_keys): return tuple(V.kernel.cse.cache[cache_key] for cache_key in cache_keys) cdtype = DTYPE_TO_CPP[x.dtype] size = V.kernel.tail_size if V.kernel.tail_size else V.kernel.tiling_factor code = BracesBuffer() exponent = V.kernel.cse.newvar() mantissa = V.kernel.cse.newvar() exponent.update_on_args("frexp", (x,), kwargs={}) mantissa.update_on_args("frexp", (x,), kwargs={}) n_vec = V.kernel._get_num_vectors(x.dtype) mantissa_t = ( f"at::vec::Vectorized<{cdtype}>" if n_vec == 1 else f"at::vec::VectorizedN<{cdtype}, {n_vec}>" ) code.writeline( f"at::vec::Vectorized {exponent};" if n_vec == 1 else f"at::vec::VectorizedN {exponent};" ) code.writeline(f"{mantissa_t} {mantissa};") code.writeline("[&]()") with code.indent(): code.writeline( f"__at_align__ std::array<{cdtype}, {V.kernel.tiling_factor}> tmpbuf;" ) code.writeline(f"{x}.store(tmpbuf.data(), {cexpr_index(size)});") code.writeline( f"__at_align__ std::array tmpbuf_exponent;" ) code.writeline( f"__at_align__ std::array<{cdtype}, {V.kernel.tiling_factor}> tmpbuf_mantissa;" ) code.writeline(f"for (int i = 0; i < {cexpr_index(size)}; i++)") with code.indent(): code.writeline( "tmpbuf_mantissa[i] = std::frexp(tmpbuf[i], &tmpbuf_exponent[i]);" ) code.writeline( f"{exponent} = at::vec::Vectorized::loadu(tmpbuf_exponent.data(), {cexpr_index(size)});" if n_vec == 1 else f"{exponent} = at::vec::VectorizedN::loadu(tmpbuf_exponent.data(), {cexpr_index(size)});" ) code.writeline( f"{mantissa} = {mantissa_t}::loadu(tmpbuf_mantissa.data(), {cexpr_index(size)});" ) code.writeline("();") V.kernel.compute.splice(code) cse_vars = (mantissa, exponent) for cache_key, cse_var in zip(cache_keys, cse_vars): V.kernel.cse.cache[cache_key] = cse_var return mantissa, exponent @classmethod def scalarize(cls, scalar_func): def inner(*args, **kwargs): assert not kwargs kernel = V.kernel assert isinstance(kernel, CppVecKernel) code = BracesBuffer() code.writeline("[&]()") vec_dtype = args[0].dtype n_vec = kernel._get_num_vectors(vec_dtype) size = kernel.tail_size if kernel.tail_size else kernel.tiling_factor scalar_args = [] cdtype = DTYPE_TO_CPP[vec_dtype] output_mask = scalar_func.__name__ in ( "isinf", "isnan", "signbit", ) octype = "bool" if output_mask else cdtype octype = ( DTYPE_TO_CPP[args[-2]] if (scalar_func.__name__ == "to_dtype_bitcast") else octype ) with code.indent(): for argidx, arg in enumerate(args): if isinstance(arg, CppCSEVariable): assert arg.is_vec assert arg.dtype == vec_dtype code.writeline( f"__at_align__ std::array<{cdtype}, {kernel.tiling_factor}> tmpbuf{argidx};" ) code.writeline( f"{arg}.store(tmpbuf{argidx}.data(), {cexpr_index(size)});" ) scalar_args.append(f"tmpbuf{argidx}[i]") else: scalar_args.append(arg) code.writeline( f"__at_align__ std::array<{octype}, {kernel.tiling_factor}> tmpbuf_out;" ) res = scalar_func(*scalar_args) code.writeline(f"for (int i = 0; i < {cexpr_index(size)}; i++)") with code.indent(): code.writeline(f"tmpbuf_out[i] = {res};") if output_mask: assert not kernel.tail_size load_args = "tmpbuf_out.data()" load_fn = f"at::vec::VecMask<{cdtype},{n_vec}>::from" else: load_args = f"tmpbuf_out.data(), {cexpr_index(size)}" if n_vec == 1: load_fn = f"at::vec::Vectorized<{octype}>::loadu" else: load_fn = f" at::vec::VectorizedN<{octype}, {n_vec}>::loadu" code.writeline(f"return {load_fn}({load_args});") code.writeline("()") return code return inner @classmethod def _initialize_scalarize(cls): for name, method in vars(CppOverrides).items(): if getattr(method, "__class__", None) == staticmethod and name not in vars( CppVecOverrides ): func = cls.scalarize(method.__func__) func.__name__ = name setattr(cls, name, staticmethod(func)) CppVecOverrides._initialize_pointwise_overrides("cppvec") CppVecOverrides._initialize_scalarize() class CppTile2DOverrides(CppVecOverrides): @staticmethod def index_expr(expr, dtype): assert isinstance(V.kernel, CppTile2DKernel) expr = V.kernel.transform_indexing(expr) return CppVecOverrides.index_expr(expr, dtype) class CppKernel(Kernel): overrides = CppOverrides # type: ignore[assignment] sexpr = cexpr newvar_prefix = "auto " suffix = ";" def __init__(self, args, num_threads): super().__init__(args) self.call_ranges: Optional[Tuple[sympy.Expr, ...]] = None self.ranges: List[sympy.Expr] = [] self.itervars: List[sympy.Symbol] = [] self.reduction_depth = None self.reduction_prefix = IndentedBuffer() self.reduction_suffix = IndentedBuffer() self.parallel_reduction_prefix = IndentedBuffer() self.parallel_reduction_suffix = IndentedBuffer() self.local_reduction_init = IndentedBuffer() self.local_reduction_stores = IndentedBuffer() self.is_reduction = False self.non_parallel_reduction_prefix = IndentedBuffer() self.reduction_cse = CSE(self.newvar_prefix, self.suffix, name_prefix="tmp_acc") self.weight_recps_cse = CSE( self.newvar_prefix, self.suffix, name_prefix="wrecps" ) self.preloads = IndentedBuffer() self.poststores = IndentedBuffer() self.num_threads = num_threads # num_threads the kernel specialized for self.reduction_omp_dec: Dict[Tuple[str, str], str] = {} def _gen_parallel_reduction_buffers( self, acc, acc_type, reduction_type, dtype, reduction_combine_fn=reduction_combine, reduction_init_fn=reduction_init, welford_weight_reciprocal_vec_fn=None, ): if config.cpp.dynamic_threads and not self.parallel_reduction_prefix: self.parallel_reduction_prefix.writeline( "int max_threads = omp_get_max_threads();" ) acc_local = f"{acc}_local" num_threads = ( "max_threads" if config.cpp.dynamic_threads else parallel_num_threads() ) acc_per_thread_var_name = f"{acc}_arr" acc_per_thread = f"{acc_per_thread_var_name}[{num_threads}]" """ MSVC don't support dynamic array(VLA). Please use std::unique_ptr to instead of it. Ref: https://stackoverflow.com/questions/56555406/creating-dynamic-sized-array-using-msvc-c-compiler MSVC is the only one compiler, which not support VLA. And MSVC can't get good inductor performance. So, we can use unique_ptr make it works on MSVC. For other compilers, we continue to use VLA to get best performence. """ acc_per_thread_unique_ptr_decl = f"auto {acc_per_thread_var_name} = std::make_unique<{acc_type}[]>({num_threads})" acc_per_thread_vla_decl = f"{acc_per_thread_var_name}[{num_threads}]" acc_local_in_array = acc_per_thread.replace(f"[{num_threads}]", "[tid]") self.local_reduction_init.writeline( f"{acc_type} {acc_local} = {reduction_init_fn(reduction_type, dtype)};" ) self.parallel_reduction_prefix.writeline( f"{acc_per_thread_unique_ptr_decl};" if cpp_builder.is_msvc_cl() else f"{acc_type} {acc_per_thread_vla_decl};" ) self.parallel_reduction_prefix.writelines( [ f"for (int tid = 0; tid < {num_threads}; tid++)", "{", f" {acc_local_in_array} = {reduction_init_fn(reduction_type, dtype)};", "}", ], ) self.local_reduction_stores.writelines( [ f"{acc_local_in_array} = {acc_local};", ] ) self.parallel_reduction_suffix.writelines( [ f"for (int tid = 0; tid < {num_threads}; tid++)", "{", f" {acc} = {reduction_combine_fn(reduction_type, acc, acc_local_in_array, src_dtype=dtype)};", "}", ], ) def get_reduction_var_pattern(self, line: str): return re.search("tmp_acc[0-9]+", line) def update_stores_with_parallel_reduction(self): for i, line in enumerate(self.stores._lines): if isinstance(line, str): m = self.get_reduction_var_pattern(line) if m: var_name = m.group(0) self.stores._lines[i] = line.replace(var_name, f"{var_name}_local") @contextlib.contextmanager def masked(self, mask): """Context manager to add an additional mask to loads and stores.""" prior = self._load_mask if prior: mask = ops.and_(mask, prior) if isinstance(mask, OpsValue): mask = mask.value assert isinstance(mask, CppCSEVariable) # see NOTE [dtype of CppCSEVariable] # mask's dtype should be bool mask.dtype = torch.bool self._load_mask = mask try: yield mask finally: self._load_mask = prior def scale_index_with_offset( self, index: sympy.Expr, scale=1, itervar_idx=-1, offset=0 ): var = self.itervars[itervar_idx] replacement = {var: var * scale + offset} new_index = sympy_subs(index, replacement) return new_index def index_to_str(self, index: sympy.Expr) -> str: """ Convert an index expr to a string that can be used in cpp code. e.g. a sympy expression "s2" may actually appear as "ks1" in the cpp kernel. """ return cexpr(self.rename_indexing(index)) def index_indirect_depends_on(self, index: sympy.Expr, itervar: sympy.Symbol): """ Check if an index has free symbol CppCSEVariable that depends on `itervar`. """ return any( self.cse.varname_map[s.name].depends_on(itervar) # type: ignore[attr-defined] for s in index.free_symbols if s.name in self.cse.varname_map # type: ignore[attr-defined] and isinstance(self.cse.varname_map[s.name], CppCSEVariable) # type: ignore[attr-defined] ) def index_depends_on(self, index: sympy.Expr, itervar: sympy.Symbol): return itervar in index.free_symbols or self.index_indirect_depends_on( index, itervar ) def var_ranges(self): return dict(zip(self.itervars, self.ranges)) def check_bounds( self, expr: sympy.Expr, size: sympy.Expr, lower: bool, upper: bool, ): if not (lower or upper): return indirect = free_symbol_is_type(expr, SymT.TMP) if indirect: # indexing in compute csevar = ops.index_expr(expr, torch.int64).value buffer = V.kernel.compute else: # indexing in loads prior_compute = V.kernel.compute try: V.kernel.compute = self.loads csevar = ops.index_expr(expr, torch.int64).value finally: V.kernel.compute = prior_compute buffer = self.loads size_str = V.kernel.sexpr(self.rename_indexing(size)) if upper else None line = self.indirect_assert( csevar, "0" if lower else None, size_str, self._load_mask ) self.cse.generate(buffer, line, assignment=False) def load(self, name: str, index: sympy.Expr): var = self.args.input(name) index = self.rename_indexing(index) line = f"{var}[{cexpr_index(index)}]" csevar = self.cse.generate(self.loads, line) csevar.update_on_args("load", (self, name, index), {}) return csevar def store(self, name, index, value, mode=None): assert "buf" in name var = self.args.output(name) index = self.rename_indexing(index) if mode is None: line = f"{var}[{cexpr_index(index)}] = {value};" elif mode == "atomic_add": if not config.cpp.dynamic_threads and self.num_threads == 1: line = f"{var}[{cexpr_index(index)}] += {value};" else: dtype = V.graph.get_dtype(name) # mirroring static_cast(...) in load: value = f"static_cast<{DTYPE_TO_CPP[dtype]}>({value})" line = f"atomic_add(&{var}[{cexpr_index(index)}], {value});" else: raise NotImplementedError(f"store mode={mode}") self.stores.writeline(DeferredLine(name, line)) def reduction(self, dtype, src_dtype, reduction_type, value): argmax_or_argmin = reduction_type in {"argmax", "argmin"} reduction_key = src_dtype, reduction_type, value if reduction_key in self.reduction_cse.reduction_cache: return self.reduction_cse.reduction_cache[reduction_key] acc = self.reduction_cse.generate( self.loads, f"reduction {reduction_key}", write=False ) self.is_reduction = True init_dtype = src_dtype if argmax_or_argmin else dtype acc_type = reduction_acc_type(reduction_type, init_dtype) self.reduction_prefix.writeline( f"{acc_type} {acc} = {reduction_init(reduction_type, init_dtype)};" ) assert self.reduction_depth is not None index = self.itervars[self.reduction_depth] for i in range(self.reduction_depth + 1, len(self.itervars)): index = index * self.ranges[i] + self.itervars[i] self.stores.writeline( f"{acc} = {reduction_combine(reduction_type, acc, value, index)};" ) self._gen_parallel_reduction_buffers(acc, acc_type, reduction_type, init_dtype) result = reduction_project(reduction_type, acc) self.reduction_cse.reduction_cache[reduction_key] = result return result def store_reduction(self, name, index, value): index = self.rename_indexing(index) var = self.args.output(name) self.reduction_suffix.writeline( DeferredLine(name, f"{var}[{cexpr_index(index)}] = {value};") ) def set_ranges(self, lengths, reduction_lengths): if self.call_ranges: assert self.call_ranges == tuple(lengths) + tuple( reduction_lengths ), f"{self.call_ranges} == {tuple(lengths)} + {tuple(reduction_lengths)}" assert self.reduction_depth == len(lengths) else: self.call_ranges = tuple(lengths) + tuple(reduction_lengths) self.ranges = [self.rename_indexing(x) for x in self.call_ranges] self.itervars = [ sympy_index_symbol_with_prefix(SymT.XBLOCK, n) for n in range(len(self.ranges)) ] self.reduction_depth = len(lengths) return ( self.itervars[: self.reduction_depth], self.itervars[self.reduction_depth :], ) def size_hint(self): return V.graph.sizevars.size_hint( sympy_product(self.call_ranges), fallback=8192 ) def codegen_loops_impl(self, loop_nest, code, worksharing): threads = parallel_num_threads() assert self.call_ranges is not None kernels = loop_nest.get_kernels() has_outer_loop_kernel = any( isinstance(kernel, OuterLoopFusedKernel) for kernel in kernels ) if has_outer_loop_kernel: assert len(kernels) == 1 assert isinstance(kernels[0], OuterLoopFusedKernel) par_depth = kernels[0].decide_parallel_depth( loop_nest.max_parallel_depth(), threads ) else: par_depth = self.decide_parallel_depth( loop_nest.max_parallel_depth(), threads ) with contextlib.ExitStack() as stack: if par_depth: if loop_nest.is_reduction_only(): # need to close the worksharing scope to define reduction vars outside it worksharing.close() else: worksharing.parallel(threads) loop_nest.mark_parallel(par_depth) elif threads > 1: if worksharing.single(): stack.enter_context(code.indent()) def gen_loop_kernel(loop: LoopLevel): def is_parallel_reduction(loop): root = loop.get_root() return root.is_reduction and root.parallel kernels = loop.get_kernels() assert len(kernels) == 1 if not isinstance( kernels[0], OuterLoopFusedKernel ) and is_parallel_reduction(loop): kernels[0].update_stores_with_parallel_reduction() gen_kernel(kernels[0]) def gen_kernel(kernel): if isinstance(kernel, OuterLoopFusedKernel): for loop in kernel.inner: if loop.inner: gen_loops(loop.inner, loop.is_reduction) else: with contextlib.ExitStack() as stack: # If there is any kernel existing at the final outer loop fusion level, # the kernel code should be placed within its respective indent to prevent # the duplication of variable definitions. stack.enter_context(code.indent()) gen_loop_kernel(loop) else: with contextlib.ExitStack() as stack: assert kernel if hasattr(kernel, "codegen_inner_loops"): code.splice(kernel.preloads) kernel.codegen_inner_loops(code) stack.enter_context(code.indent()) code.splice(kernel.loads) code.splice(kernel.compute) code.splice(kernel.stores) if hasattr(kernel, "codegen_inner_loops"): code.splice(kernel.poststores) def get_reduction_code_buffer(loops, buffer="prefix"): assert buffer in ("prefix", "suffix", "local") for loop in loops: for kernel in loop.get_kernels(): if buffer == "local": return ( kernel.local_reduction_init, kernel.local_reduction_stores, ) elif buffer == "suffix": suffix = kernel.reduction_suffix if loop.parallel: suffix = kernel.parallel_reduction_suffix + suffix return suffix else: prefix = kernel.reduction_prefix if loop.parallel: prefix = prefix + kernel.parallel_reduction_prefix else: prefix = prefix + kernel.non_parallel_reduction_prefix return prefix def gen_loops(loops: List[LoopLevel], in_reduction=False): with contextlib.ExitStack() as stack_outer: local_reduction_init = local_reduction_stores = None if loops: loop = loops[0] if loop.is_reduction and not in_reduction: reduction_prefix = get_reduction_code_buffer(loops) if reduction_prefix: stack_outer.enter_context(code.indent()) code.splice(reduction_prefix) if loop_nest.is_reduction_only() and loop.parallel: ( local_reduction_init, local_reduction_stores, ) = get_reduction_code_buffer(loops, "local") worksharing.parallel(threads) if local_reduction_init: assert local_reduction_stores code.splice(local_reduction_init) for loop in loops: gen_loop(loop) if loops: loop = loops[0] if loop_nest.is_reduction_only() and loop.parallel: if local_reduction_stores: code.splice(local_reduction_stores) worksharing.close() if loop.is_reduction and not in_reduction: code.splice(get_reduction_code_buffer(loops, "suffix")) def gen_loop(loop: LoopLevel): with contextlib.ExitStack() as stack: loop_lines = loop.lines() if loop_lines is None: return code.writelines(loop_lines) stack.enter_context(code.indent()) # generate inner loops or loop body if loop.inner: gen_loops(loop.inner, loop.is_reduction) else: gen_loop_kernel(loop) stack.enter_context(code.indent()) if loop_nest.root: if ( has_outer_loop_kernel and isinstance(V.local_buffer_context, LocalBufferContext) and V.local_buffer_context.local_buffers ): # Allocate local buffer local_buffers = V.local_buffer_context.local_buffers for local_buffer in local_buffers.values(): # For dynamic size, rename s to ks local_buf_size = sympy_product( [ self.rename_indexing(size_val) for size_val in local_buffer.get_layout().size ] ) local_buf_dtype = DTYPE_TO_CPP[local_buffer.get_layout().dtype] allocate = f"std::make_unique<{local_buf_dtype} []>({cexpr(local_buf_size)})" local_buffer_name = local_buffer.get_name() code.splice( f"std::unique_ptr<{local_buf_dtype} []> buf_{local_buffer_name} = {allocate};" ) code.splice( f"{local_buf_dtype}* {local_buffer_name} = buf_{local_buffer_name}.get();" ) gen_loops(loop_nest.root) else: gen_kernel(loop_nest.kernel) def codegen_loops(self, code, worksharing): loop_nest = LoopNestWithSplit.build(self) self.codegen_loops_impl(loop_nest, code, worksharing) @property def assert_function(self) -> str: if config.abi_compatible: return "AOTI_TORCH_CHECK" else: return "TORCH_CHECK" def decide_parallel_depth(self, max_parallel_depth, threads): assert self.call_ranges is not None ranges = self.call_ranges[:max_parallel_depth] seq = self.size_hint() par = 1 depth = 0 for expr in ranges: hint = V.graph.sizevars.size_hint(expr, fallback=8192) if par >= 2 * threads or par == threads: break if seq // threads < config.cpp.min_chunk_size: # not enough work break depth += 1 par *= hint seq /= hint # if we assume thread number is dynamic, make sure we # have at least one parallel scope and let OMP runtime # to manage the serial vs. parallel. if config.cpp.dynamic_threads and depth == 0 and len(ranges) > 0: depth = 1 return depth @contextlib.contextmanager def write_to_suffix(self): prior = (self.loads, self.compute, self.stores, self.cse) self.loads = IndentedBuffer() self.compute = IndentedBuffer() self.stores = IndentedBuffer() self.cse = self.cse.clone() yield self.reduction_suffix.splice(self.loads) self.reduction_suffix.splice(self.compute) self.reduction_suffix.splice(self.stores) (self.loads, self.compute, self.stores, self.cse) = prior def create_cse_var(self, *args, **kwargs): return CppCSEVariable(*args, **kwargs) def get_to_dtype_expr(self, src, dtype, src_dtype): return f"c10::convert<{DTYPE_TO_CPP[dtype]}>({src})" def cache_dtype_convert(self, dst, dst_dtype, src, src_dtype): expr = self.get_to_dtype_expr(src, dst_dtype, src_dtype) self.cse.cache[expr] = dst class CppVecKernel(CppKernel): overrides = CppVecOverrides # type: ignore[assignment] def __init__( self, args, num_threads, tiling_factor, tiling_idx, tail_size=None, ): super().__init__(args, num_threads) self.vec_isa = cpu_vec_isa.pick_vec_isa() assert self.vec_isa assert tiling_factor > 0, "Expect pass in Non-Zero tiling_factor explicitly" self.tiling_factor = tiling_factor self.tiling_idx = tiling_idx self.tail_size = tail_size self.num_elems = tail_size if tail_size else tiling_factor def _try_get_const_stride(self, index: sympy.Expr, itervar: sympy.Symbol): if self.index_indirect_depends_on(index, itervar): return None for indirect_var in ( self.cse.varname_map[s.name] # type: ignore[attr-defined] for s in index.free_symbols if symbol_is_type(s, SymT.TMP) ): assert isinstance(indirect_var, CppCSEVariable) if indirect_var.is_vec: return None stride = stride_at_vec_range(index, itervar, self.tiling_factor) return stride if stride.is_number else None def _get_num_vectors(self, dtype: torch.dtype) -> int: num_vectors = math.ceil( self.tiling_factor * dtype.itemsize * 8 / self.vec_isa.bit_width() ) assert num_vectors >= 1 return num_vectors def _get_raw_num_vectors(self, dtype: torch.dtype) -> float: # This utility function is used to check if the vector lanes has been # fully utilized. For example, uint8 will only use 1/4 of the vector lanes. return self.tiling_factor * dtype.itemsize * 8 / self.vec_isa.bit_width() def _get_vec_type(self, dtype: torch.dtype) -> str: num_vectors = self._get_num_vectors(dtype) if num_vectors == 1: return f"at::vec::Vectorized<{DTYPE_TO_CPP[dtype]}>" else: return f"at::vec::VectorizedN<{DTYPE_TO_CPP[dtype]},{num_vectors}>" def _get_mask_type(self, dtype: torch.dtype = torch.float) -> str: if dtype == torch.bool: return "" num_vectors = self._get_num_vectors(dtype) return f"at::vec::VecMask<{DTYPE_TO_CPP[dtype]},{num_vectors}>" def _get_mask_cast(self, mask: CppCSEVariable, dtype: torch.dtype) -> str: assert mask.dtype == torch.bool, repr(mask) num_vectors = self._get_num_vectors(dtype) return f"{mask}.template cast<{DTYPE_TO_CPP[dtype]},{num_vectors}>()" def get_reduction_var_pattern(self, line: str): return re.search("tmp_acc[0-9]+_vec", line) def _get_vec_load_line( self, var: str, index: sympy.Expr, dtype: torch.dtype, load_mask: Optional[CppCSEVariable] = None, ): """ Get a load line str that loads a vector from `var` at `index` of type `dtype`. If `load_mask` is not None, we do a masked load accordingly. Notes on the `dtype`: 1. We always load `self.tiling_factor` number of elements regardless of the `dtype`. It means we load half of the vector lanes for 16-bit data types and quarter of the vector lanes for 8-bit data types. 2. `torch.bool` and `torch.uint8` could mean masks and we load them as float mask vectors. """ cpp_type = DTYPE_TO_CPP[dtype] num_vectors = self._get_num_vectors(dtype) load_mask_str = None if load_mask: if not load_mask.is_vec: # TODO: avoid hard-code torch.float load_mask_str = f"{self._get_mask_type(torch.float)}::from({load_mask})" else: load_mask_str = f"{self._get_mask_cast(load_mask, torch.float)}" loadbuf = f"{var} + {cexpr_index(index)}" if index != 0 else var if dtype == torch.bool: # TODO: should we consider load mask here? line = f"{self._get_mask_type()}::from({loadbuf})" else: line = ( f"{load_mask_str}.template loadu<{cpp_type},{num_vectors}>({loadbuf})" if load_mask_str else f"{self._get_vec_type(dtype)}::loadu({loadbuf}, {cexpr_index(self.num_elems)})" ) return line def _load_or_store_non_contiguous( self, var: Optional[str], index: sympy.Expr, dtype: torch.dtype, buffer: Optional[IndentedBuffer] = None, store_value: Optional[Union[str, CppCSEVariable]] = None, accu_store: bool = False, ) -> Optional[CppCSEVariable]: """ Load or store a vector in a non-contiguous way. The vector is initialized from an array that is filled in an inner loop over the tiling factor. :param var: buffer to load from or store to, i.e. `var[transformed(index)]`. If None, we load the index as index expression, i.e. `transformed(index)`. :param index: index into the `var` or the index expression by its own if `var` is None. The `index` could contain indirect indexing or the tiling itervar. When used in the inner loop, the index is transformed as follows: 1. the index is linearized along the tiling dim. 2. the indirect indexing vector variables are transformed into arrays over the tiling dim. :param dtype: data type of `var` or `index` if `var` is None. :param buffer: the code buffer to write the generated code to. If None, we write to `self.loads`. :param store_value: the value to store. If None, we load the vector. :param accu_store: whether accumulate the store_value to store_ptr. If True, a store_value should be provided :return: a CppCSEVariable that represents the loaded vector or None if it is a store. """ assert not store_value or var is not None, "store var must be provided" if accu_store: assert store_value if buffer is None: buffer = self.loads def get_result_size(dtype: torch.dtype) -> int: if dtype.itemsize < 4: return self.num_elems * (4 // dtype.itemsize) else: return self.num_elems def get_tiling_size(dtype: torch.dtype) -> int: if dtype.itemsize < 4: return self.tiling_factor * (4 // dtype.itemsize) else: return self.tiling_factor def vec_to_array(vec_var: CppCSEVariable) -> CppCSEVariable: assert vec_var.is_vec code = BracesBuffer() code.writeline("[&]") with code.indent(): vec_dtype = vec_var.dtype assert vec_dtype is not None if vec_dtype == torch.bool: vec_dtype = torch.float result_size = get_result_size(vec_dtype) tiling_size = get_tiling_size(vec_dtype) code.writeline( f"__at_align__ std::array<{DTYPE_TO_CPP[vec_dtype]}, {tiling_size}> tmpbuf;" ) line = f"{vec_var}.store(tmpbuf.data(), {cexpr_index(result_size)});" code.writeline(line) code.writeline("return tmpbuf;") code.writeline("()") csevar = self.cse.generate(buffer, code) assert isinstance(csevar, CppCSEVariable) return csevar code = BracesBuffer() code.writeline("[&]") with code.indent(): result_size = get_result_size(dtype) tiling_size = get_tiling_size(dtype) result_declare = ( f"__at_align__ std::array<{DTYPE_TO_CPP[dtype]}, {tiling_size}> tmpbuf;" ) code.writeline(result_declare) if store_value: code.writeline( f"{store_value}.store(tmpbuf.data(), {cexpr_index(result_size)});" ) itervar_inner = sympy_index_symbol( f"{self.itervars[self.tiling_idx]}_inner" ) replacements = {} for indirect_var in ( self.cse.varname_map[s.name] # type: ignore[attr-defined] for s in index.free_symbols if symbol_is_type(s, SymT.TMP) ): assert isinstance(indirect_var, CppCSEVariable) if indirect_var.is_vec: array_var = vec_to_array(indirect_var) replacements[indirect_var] = f"{array_var}[{itervar_inner}]" index = self.scale_index_with_offset( index, itervar_idx=self.tiling_idx, offset=itervar_inner ) load_mask = None if self._load_mask is not None: assert not store_value, "unexpected store with load mask" assert isinstance(self._load_mask, CppCSEVariable), self._load_mask if self._load_mask.is_vec: load_mask = f"{self._load_mask}.is_masked({itervar_inner})" else: load_mask = f"{self._load_mask} != 0" if cpp_builder.is_gcc(): code.writeline(f"#pragma GCC unroll {self.tiling_factor}") else: code.writeline(f"#pragma unroll {self.tiling_factor}") code.writeline( f"for (long {itervar_inner} = 0; " + f"{itervar_inner} < {cexpr_index(self.num_elems)}; " + f"{itervar_inner}++)" ) with code.indent(), contextlib.ExitStack() as stack: index_c = cexpr_index(index) for indirect_var in replacements: index_c = re.sub( r"\b" + f"{indirect_var}" + r"\b", replacements[indirect_var], index_c, ) rhs = f"{var}[{index_c}]" if var is not None else f"{index_c}" if load_mask: code.writeline(f"if ({load_mask})") stack.enter_context(code.indent()) if store_value: conjunction = "+=" if accu_store else "=" code.writeline(f"{rhs} {conjunction} tmpbuf[{itervar_inner}];") else: code.writeline(f"tmpbuf[{itervar_inner}] = {rhs};") if not store_value: load_line = self._get_vec_load_line("tmpbuf.data()", 0, dtype) # type: ignore[arg-type] code.writeline(f"return {load_line};") code.writeline("()") if store_value: code.writeline(";") buffer.splice(code) return None else: csevar = self.cse.generate(buffer, code) assert isinstance(csevar, CppCSEVariable) csevar.is_vec = True return csevar def load(self, name: str, index: sympy.Expr): var = self.args.input(name) index = self.rename_indexing(index) dtype = V.graph.get_dtype(name) tiling_var = self.itervars[self.tiling_idx] stride = self._try_get_const_stride(index, tiling_var) if stride == 0: # load scalar and lazily broadcast it on demand return super().load(name, index) elif stride == 1: # load contiguously line = self._get_vec_load_line(var, index, dtype, self._load_mask) csevar = self.cse.generate(self.loads, line) # type: ignore[assignment] else: csevar = self._load_or_store_non_contiguous(var, index, dtype) # type: ignore[assignment] assert isinstance(csevar, CppCSEVariable) csevar.update_on_args("load", (self, name, index), {}) csevar.is_vec = True return csevar def _get_store_line( self, value: Union[str, CppCSEVariable], var: str, index: sympy.Expr, dtype: torch.dtype, accu_store: bool = False, ): """ Get a store line buffer that stores `value` into `var` at `index` of `dtype`. It handles both contiguous and non-contiguous store cases. :param value: Vectorized type templaterized on `dtype`. :param var: buffer to store into. :index: index into the `var`. """ # when value's type is str (e.g., welford reduction), caller should make sure # it is a vector assert isinstance(value, str) or ( isinstance(value, CppCSEVariable) and value.is_vec ), value tiling_var = self.itervars[self.tiling_idx] var_expr = f"{var} + {cexpr_index(index)}" stride = self._try_get_const_stride(index, tiling_var) code = IndentedBuffer() if stride == 1: if dtype == torch.float and self.tail_size is None: code.writeline(f"{value}.store({var_expr});") else: code.writeline( f"{value}.store({var_expr}, {cexpr_index(self.num_elems)});" ) else: self._load_or_store_non_contiguous( var, index, dtype, buffer=code, store_value=value, accu_store=accu_store ) return code def store(self, name, index, value, mode=None): assert "buf" in name assert isinstance(value, CppCSEVariable), value if not value.is_vec: # this happens when we store a scalar into a vectorized buffer like "fill" value = self.broadcast(value) var = self.args.output(name) index = self.rename_indexing(index) dtype = V.graph.get_dtype(name) if mode is None: code = self._get_store_line(value, var, index, dtype) self.stores.splice(code.map(lambda x: DeferredLine(name, x))) elif mode == "atomic_add": if not config.cpp.dynamic_threads and self.num_threads == 1: code = self._get_store_line( f"{value}", var, index, dtype, accu_store=True, ) self.stores.splice(code.map(lambda x: DeferredLine(name, x))) else: n_src = self._get_num_vectors(dtype) n_idx = self._get_num_vectors(torch.int64) cdtype = DTYPE_TO_CPP[dtype] index = ops.index_expr(index, torch.int64).value assert isinstance(index, CppCSEVariable) and index.is_vec line = f"atomic_add_vec<{cdtype}, {n_idx}, {n_src}>({var}, {index}, {value});" self.stores.writeline(DeferredLine(name, line)) else: raise NotImplementedError(f"store mode={mode}") def reduction(self, dtype, src_dtype, reduction_type, value): assert reduction_type in VECTORIZABLE_RTYPES argmax_or_argmin = reduction_type in {"argmax", "argmin"} horizontal_reduction = self.tiling_idx >= self.reduction_depth init_dtype = src_dtype if argmax_or_argmin else dtype assert isinstance(value, CppCSEVariable), value if not value.is_vec: value = self.broadcast(value) reduction_key = src_dtype, reduction_type, value if reduction_key in self.reduction_cse.reduction_cache: return self.reduction_cse.reduction_cache[reduction_key] vec_ns = "at::vec" vec = f"{vec_ns}::Vectorized<{DTYPE_TO_CPP[dtype]}>" acc_type = reduction_acc_type(reduction_type, init_dtype) acc_type_vec = self.reduction_acc_type_vec(reduction_type, init_dtype) acc = self.reduction_cse.generate( self.loads, f"reduction {reduction_key}", write=False ) acc_vec = f"{acc}_vec" self.is_reduction = True self.reduction_prefix.writeline( f"{acc_type} {acc} = {reduction_init(reduction_type, init_dtype)};" ) self.reduction_prefix.writeline( f"{acc_type_vec} {acc_vec} = {self.reduction_init_vec(reduction_type, init_dtype)};" ) if reduction_type == "welford_reduce": # save the reciprocal of weights for welford reduce assert self.reduction_depth is not None # use masked acc_vec for tail vec kernel self.reduction_prefix.writeline( f"{acc_type_vec} masked_{acc_vec} = {self.reduction_init_vec(reduction_type, dtype)};" ) reduction_size = functools.reduce( lambda x, y: x * y, self.ranges[self.reduction_depth :] ) reduction_factor = ( self.tiling_factor if self.tiling_idx >= self.reduction_depth else 1 ) self.weight_recp_vec_range = FloorDiv(reduction_size, reduction_factor) if self.weight_recp_vec_range not in self.weight_recps_cse.reduction_cache: self.weight_recps_val = self.weight_recps_cse.generate( self.compute, f"reduction {self.weight_recp_vec_range}", write=False ) self.weight_recps_cse.reduction_cache[ self.weight_recp_vec_range ] = self.weight_recps_val self.non_parallel_reduction_prefix.writeline( self.welford_weight_reciprocal_vec(dtype) ) # generate weight_recps for parallel reduction num_threads = ( "max_threads" if config.cpp.dynamic_threads else parallel_num_threads() ) self.local_reduction_init.writeline( self.welford_weight_reciprocal_vec(dtype, num_threads) ) else: self.weight_recps_val = self.weight_recps_cse.reduction_cache[ self.weight_recp_vec_range ] # use masked acc_vec for tail vec kernel acc_vec_ = f"masked_{acc_vec}" if self.tail_size else acc_vec self.stores.writeline( f"{acc_vec_} = {self.reduction_combine_vec(reduction_type, acc_vec_, value, True)};" ) else: assert self.reduction_depth is not None index = self.itervars[self.reduction_depth] for i in range(self.reduction_depth + 1, len(self.itervars)): index = index * self.ranges[i] + self.itervars[i] combine = self.reduction_combine_vec( reduction_type, acc_vec, value, index=index, horizontal_reduction=horizontal_reduction, src_dtype=src_dtype, ) self.stores.writeline(f"{acc_vec} = {combine};") self._gen_parallel_reduction_buffers( acc, acc_type, reduction_type, init_dtype, ) self._gen_parallel_reduction_buffers( acc_vec, acc_type_vec, reduction_type, init_dtype, reduction_combine_fn=self.reduction_combine_vec, reduction_init_fn=self.reduction_init_vec, ) if reduction_type == "welford_reduce": # use masked acc_vec for tail vec kernel self._gen_parallel_reduction_buffers( f"masked_{acc_vec}", acc_type_vec, reduction_type, dtype, reduction_combine_fn=self.reduction_combine_vec, reduction_init_fn=self.reduction_init_vec, ) tmpvar: Union[str, CSEVariable] is_bool = dtype == torch.bool if horizontal_reduction: # Horizontal reduction if is_welford_reduction(reduction_type): assert self._get_num_vectors(dtype) in [ 1, 2, ], "Welford reduction does not support VectorizedN (N>2)" next_value = f"welford_vec_reduce_all({acc_vec})" masked_next_value = f"welford_vec_reduce_all(masked_{acc_vec})" self.reduction_suffix.writeline( f"{acc} = {reduction_combine(reduction_type, acc, masked_next_value)};" ) elif argmax_or_argmin: next_value = f"{reduction_type}_vec_reduce_all({acc_vec})" elif is_bool: if reduction_type in ( "any", "sum", "max", ): next_value = f"!{acc_vec}.all_zero()" else: assert reduction_type == "min" next_value = f"{acc_vec}.all_masked()" else: reduce_all_body = ( "{ return " + self.reduction_combine_vec(reduction_type, "x", "y") + "; }" ) is_bool = dtype == torch.bool # we are using at::vec::VecMask for bool vec_dtype = torch.float if is_bool else dtype vec = f"at::vec::Vectorized<{DTYPE_TO_CPP[vec_dtype]}>" vec_reduce_all_func = f"at::vec::vec_reduce_all<{DTYPE_TO_CPP[vec_dtype]}, {self._get_num_vectors(vec_dtype)}>" next_value = f"{vec_reduce_all_func}([]({vec}& x, {vec}& y) {reduce_all_body}, {acc_vec})" self.reduction_suffix.writeline( f"{acc} = {reduction_combine(reduction_type, acc, next_value, src_dtype=src_dtype)};" ) tmpvar = acc else: tmpvar = acc_vec if is_welford_reduction(reduction_type): masked_tmpvar = f"masked_{tmpvar}" self.reduction_suffix.writeline( f"{tmpvar} = {reduction_combine(reduction_type, tmpvar, masked_tmpvar)};" ) result = reduction_project(reduction_type, tmpvar) self.reduction_cse.reduction_cache[reduction_key] = result return result def store_reduction(self, name, index, value): index = self.rename_indexing(index) var = self.args.output(name) out_dtype = V.graph.get_dtype(name) dtype = ( (out_dtype if out_dtype == torch.double else torch.float) if out_dtype.is_floating_point else torch.int64 ) out_num_vectors = V.kernel._get_num_vectors(out_dtype) src_num_vectors = V.kernel._get_num_vectors(dtype) code = IndentedBuffer() if self.tiling_idx >= self.reduction_depth: # Horizontal reduction code.writeline( f"{var}[{cexpr_index(index)}] = static_cast<{DTYPE_TO_CPP[out_dtype]}>({value});" ) else: # Vertical reduction if out_dtype != dtype: converted_value = f"{DTYPE_TO_CPP[out_dtype]}_{value}" if out_dtype == torch.bool: convert = f"{value}.template cast()" else: if src_num_vectors == out_num_vectors == 1: convert = ( f"at::vec::convert<{DTYPE_TO_CPP[out_dtype]}>({value})" ) else: convert = ( f"at::vec::convert<{DTYPE_TO_CPP[out_dtype]}," f"{out_num_vectors},{DTYPE_TO_CPP[dtype]},{src_num_vectors}>({value})" ) code.writeline(f"auto {converted_value} = {convert};") value = converted_value code.splice(self._get_store_line(value, var, index, out_dtype)) self.reduction_suffix.splice(code.map(lambda x: DeferredLine(name, x))) def broadcast(self, scalar_var: CppCSEVariable) -> CppCSEVariable: assert not scalar_var.is_vec if scalar_var.dtype == torch.bool: vec_var = self.cse.generate( self.compute, f"{self._get_mask_type()}::from({scalar_var.name})" ) else: assert scalar_var.dtype is not None vec_var = self.cse.generate( self.compute, f"{self._get_vec_type(scalar_var.dtype)}({scalar_var.name})", ) assert isinstance(vec_var, CppCSEVariable) vec_var.dtype = scalar_var.dtype vec_var.dependent_itervars = scalar_var.dependent_itervars vec_var.is_vec = True return vec_var def arange(self, index: CppCSEVariable, stride: sympy.Symbol) -> CppCSEVariable: assert not index.is_vec assert index.dtype is not None csevar = self.cse.generate( self.compute, f"{self._get_vec_type(index.dtype)}::arange({index}, {stride})", ) assert isinstance(csevar, CppCSEVariable) csevar.dtype = index.dtype csevar.is_vec = True return csevar def reduction_init_vec(self, reduction_type, dtype): scalar_type = DTYPE_TO_COMPUTATION_DTYPE[dtype] vec_type = self._get_vec_type(scalar_type) if is_welford_reduction(reduction_type): return f"Welford<{vec_type}>()" if reduction_type in {"argmin", "argmax"}: cdtype = DTYPE_TO_CPP[scalar_type] acc_type = self.reduction_acc_type_vec(reduction_type, dtype) if reduction_type == "argmin": val = ( f"std::numeric_limits<{cdtype}>::infinity()" if is_float_dtype(dtype) else f"std::numeric_limits<{cdtype}>::max()" ) else: val = ( f"-std::numeric_limits<{cdtype}>::infinity()" if is_float_dtype(dtype) else f"std::numeric_limits<{cdtype}>::min()" ) return f"{acc_type}({val})" if reduction_type == "any": return f"{self._get_mask_type()}::from(0)" scalar_init = reduction_init(reduction_type, dtype) vec_init = f"{vec_type}({scalar_init})" if dtype == torch.bool: assert reduction_type in ("min", "max", "sum") return f"{self._get_mask_type()}::from({scalar_init})" return vec_init def reduction_acc_type_vec(self, reduction_type, dtype): scalar_type = DTYPE_TO_COMPUTATION_DTYPE[dtype] vec_type = self._get_vec_type(scalar_type) if is_welford_reduction(reduction_type): return f"Welford<{vec_type}>" if reduction_type in {"argmin", "argmax"}: n_src = self._get_num_vectors(scalar_type) n_idx = self._get_num_vectors(torch.int64) return f"IndexValueVec<{DTYPE_TO_CPP[scalar_type]}, {n_src}, {n_idx}>" if dtype == torch.bool: assert reduction_type in ("min", "max", "any", "sum") return f"{self._get_mask_type()}" return vec_type def welford_weight_reciprocal_vec(self, dtype, num_threads=None): vec_num_range_thread = ( CeilDiv(self.weight_recp_vec_range, num_threads) if num_threads else self.weight_recp_vec_range ) vec_num_range_thread_expr = cexpr_index(vec_num_range_thread) return ( f"static WeightRecp<{self._get_vec_type(dtype)}> {self.weight_recps_val}" f"(" f"{vec_num_range_thread_expr}" f");" ) def reduction_combine_vec( self, reduction_type, var, next_value, use_weight_recps=False, index: Optional[sympy.Symbol] = None, horizontal_reduction: Optional[bool] = None, src_dtype: Optional[torch.dtype] = torch.float32, ): is_bool = src_dtype == torch.bool if reduction_type == "max": if self.tail_size: return f"max_masked_reduce({var}, {next_value}, {cexpr_index(self.tail_size)})" else: return ( f"{var} | {next_value}" if is_bool else f"at::vec::maximum({var}, {next_value})" ) elif reduction_type == "min": if self.tail_size: return f"min_masked_reduce({var}, {next_value}, {cexpr_index(self.tail_size)})" else: return ( f"{var} & {next_value}" if is_bool else f"at::vec::minimum({var}, {next_value})" ) elif reduction_type == "sum": if self.tail_size: return f"sum_masked_reduce({var}, {next_value}, {cexpr_index(self.tail_size)})" else: conjunction = "|" if is_bool else "+" return f"{var} {conjunction} {next_value}" elif reduction_type == "prod": if self.tail_size: return f"prod_masked_reduce({var}, {next_value}, {cexpr_index(self.tail_size)})" else: return f"{var} * {next_value}" elif reduction_type == "xor_sum": if self.tail_size: return f"xor_sum_masked_reduce({var}, {next_value}, {cexpr_index(self.tail_size)})" else: return f"{var} ^ {next_value}" elif reduction_type == "welford_reduce": if use_weight_recps: if self.tail_size: return f"welford_combine({var}, {next_value}, {cexpr_index(self.tail_size)}, &{self.weight_recps_val})" else: return f"welford_combine({var}, {next_value}, &{self.weight_recps_val})" else: if self.tail_size: return f"welford_combine({var}, {next_value}, {cexpr_index(self.tail_size)})" else: return f"welford_combine({var}, {next_value})" elif reduction_type == "welford_combine": if isinstance(next_value, tuple): # When reading a value from Inductor IR we have a tuple of variable names mean, m2, weight = next_value else: # When combining intermediate accumulators we have a Welford struct mean, m2, weight = reduction_project(reduction_type, next_value) if self.tail_size: return f"welford_combine({var}, {{{mean}, {m2}, {weight}}}, {cexpr_index(self.tail_size)})" else: return f"welford_combine({var}, {{{mean}, {m2}, {weight}}})" elif reduction_type in ("argmin", "argmax"): assert src_dtype is not None cdtype = DTYPE_TO_CPP[src_dtype] n_src = self._get_num_vectors(src_dtype) n_idx = self._get_num_vectors(torch.int64) t_extra = "" arg_extra = "" if index is not None: assert horizontal_reduction is not None t_extra = f", {str(horizontal_reduction).lower()}" arg_extra = f", {index}" if self.tail_size: return ( f"{reduction_type}_combine_vec<{cdtype}, {n_src}, {n_idx}{t_extra}>" f"({var}, {next_value}{arg_extra}, {cexpr_index(self.tail_size)})" ) else: return f"{reduction_type}_combine_vec<{cdtype}, {n_src}, {n_idx}{t_extra}>({var}, {next_value}{arg_extra})" elif reduction_type == "any": return f"{var} | {next_value}" else: raise NotImplementedError def indirect_assert(self, var, lower, upper, mask=None): assert isinstance(var, CppCSEVariable) assert var.dtype is not None if not var.is_vec: if isinstance(mask, CppCSEVariable) and mask.is_vec: mask = f"({mask}).all_masked()" return super().indirect_assert(var, lower, upper, mask) lower_scalar = lower upper_scalar = upper if lower: lower = f"{self._get_vec_type(var.dtype)}({lower})" if upper: upper = f"{self._get_vec_type(var.dtype)}({upper})" if lower and upper: cond = f"({lower} <= {var}) & ({var} < {upper})" cond_print = f"{lower_scalar} <= {var} < {upper_scalar}" elif lower: cond = f"{lower} <= {var}" cond_print = f"{lower_scalar} <= {var}" else: assert upper cond = f"{var} < {upper}" cond_print = f"{var} < {upper_scalar}" cond = f"{self._get_mask_type(var.dtype)}({cond})" if mask: if not mask.is_vec: mask = f"{self._get_mask_type(var.dtype)}({mask})" # We need not check when the mask is False cond = f"({cond}) | ~({mask})" if self.tail_size: cond = ( f"{self._get_mask_type(var.dtype)}::set({self._get_mask_type(var.dtype)}::from(1)" f", ({cond}), {cexpr_index(self.tail_size)})" ) cond = f"({cond}).all_masked()" return f'{self.assert_function}({cond}, "index out of bounds: {cond_print}")' def get_to_dtype_expr(self, src, dtype, src_dtype): assert isinstance(src, CppCSEVariable) if not src.is_vec: return super().get_to_dtype_expr(src, dtype, src_dtype) src_cpp_type = DTYPE_TO_CPP[src_dtype] src_num_vectors = self._get_num_vectors(src_dtype) dst_cpp_type = DTYPE_TO_CPP[dtype] dst_num_vectors = self._get_num_vectors(dtype) expr = f"({src})" if src_dtype != torch.bool and dtype == torch.bool: expr = f"{self._get_mask_type(src_dtype)}::from<{src_cpp_type},{src_num_vectors}>({src})" elif src_dtype == torch.bool and dtype != torch.bool: expr = f"{src}.to<{dst_cpp_type},{dst_num_vectors}>()" elif src_dtype != dtype: if src_num_vectors == dst_num_vectors == 1: expr = f"at::vec::convert<{dst_cpp_type}>({src})" else: expr = f"at::vec::convert<{dst_cpp_type},{dst_num_vectors},{src_cpp_type},{src_num_vectors}>({src})" return expr class CppTile2DKernel(CppVecKernel): """ A vector kernel that handles the 2d tiles with the tile size defined in `tiling_factor` on the inner-most loop level and one of the outer loop level (`outer_tiling_idx`). When the data tile is accessed in a contiguous way from the outer loop axis, a transposition is applied on the tile to make the access contiguous from the inner-most loop axis. Then, the same vectorization logic from its parent `CppVecKernel` is leveraged for load/store/compute. The transposed tile load and store are generated into kernel.preloads and kernel.poststores buffers. The loop structure looks like below: for ... for i_outer ... for ... for inner_most ... // generated by CppTile2DKernel float tmp0[16*16]; at::vec::transpose_mxn<...>(tmp0, in_ptr0 + ..., ...); // into kernel.preloads float tmp1[16*16]; // into kernel.preloads for i_inner ... { // the kernel inner loop vectorized loads/compute/stores (e.g., load tmp0, store tmp1) // into kernel.loads/compute/stores } at::vec::transpose_mxn(out_ptr0 + ..., tmp1, ...) // into kernel.poststores for inner_most ... (tail) // generated by CppVecKernel ... for i_outer ... (tail) for ... for ... // generated by CppKernel ... """ overrides = CppTile2DOverrides # type: ignore[assignment] def __init__( self, args, num_threads, tiling_factor, tiling_indices, inner_tail_size=None, outer_tail_size=None, ): super().__init__( args, num_threads, tiling_factor, tiling_indices[1], inner_tail_size, ) self.tiling_indices = tiling_indices self.inner_tail_size = inner_tail_size self.outer_tail_size = outer_tail_size self.inner_num_elems = inner_tail_size if inner_tail_size else tiling_factor self.outer_num_elems = outer_tail_size if outer_tail_size else tiling_factor self.inner_is_tiling_idx = True def inner_itervar(self): return sympy_index_symbol(f"{self.itervars[self.outer_idx]}_inner") def need_vec_transpose(self, index): outer_var = self.itervars[self.outer_idx] inner_var = self.itervars[self.tiling_idx] outer_stride = stride_at_vec_range(index, outer_var, self.tiling_factor) inner_stride = stride_at_vec_range(index, inner_var, self.tiling_factor) return ( self._load_mask is None # TODO: support transposition with mask and outer_stride == 1 and index.has(inner_var) and not inner_stride.has(inner_var) and not inner_stride.has(outer_var) ) def gen_transposed_tile_load_store(self, name, var, index, is_store): # transposed tile load/store outside the kernel inner loop dtype = V.graph.get_dtype(name) factor = self.tiling_factor src = f"{var} + {cexpr_index(index)}" dst = "__place_holder__" ld_src = f"{cexpr_index(stride_at_vec_range(index, self.itervars[self.tiling_idx], self.tiling_factor))}" ld_dst = f"{cexpr_index(self.num_elems)}" if is_store: src, dst = dst, src ld_src, ld_dst = ld_dst, ld_src need_define = True if self.inner_is_tiling_idx ^ is_store: M, N = self.inner_num_elems, self.outer_num_elems else: M, N = ( self.outer_num_elems, self.inner_num_elems, ) if (isinstance(M, sympy.Expr) and not M.is_number) or ( isinstance(N, sympy.Expr) and not N.is_number ): load_or_store = ( f"at::vec::transpose_mxn<{DTYPE_TO_CPP[dtype]}>" f"({src}, {ld_src}, {dst}, {ld_dst}, {cexpr_index(M)}, {cexpr_index(N)});" ) else: load_or_store = ( f"at::vec::transpose_mxn<{DTYPE_TO_CPP[dtype]},{cexpr_index(M)},{cexpr_index(N)}>" f"({src}, {ld_src}, {dst}, {ld_dst});" ) if is_store: tile_var = self.cse.newvar() elif load_or_store not in self.cse.cache: tile_var = self.cse.generate(self.preloads, load_or_store, write=False) else: need_define = False tile_var = self.cse.cache[load_or_store] if need_define: define_line = f"alignas({factor}) {DTYPE_TO_CPP[dtype]} {tile_var}[{factor}*{factor}];" self.preloads.writeline(define_line) load_or_store = load_or_store.replace("__place_holder__", str(tile_var)) if is_store: self.poststores.writeline(DeferredLine(name, load_or_store)) else: self.preloads.writeline(load_or_store) return tile_var def load(self, name: str, index: sympy.Expr): var = self.args.input(name) index = self.rename_indexing(index) inner = self.inner_itervar() if self.need_vec_transpose(index): tile_var = self.gen_transposed_tile_load_store( name, var, index, is_store=False ) # vector load inside the kernel inner loop loadbuf = f"{tile_var} + {cexpr_index(inner * self.num_elems)}" dtype = V.graph.get_dtype(name) line = self._get_vec_load_line(loadbuf, 0, dtype) # type: ignore[arg-type] csevar = self.cse.generate(self.loads, line) csevar.update_on_args("load", (self, name, index), {}) assert isinstance(csevar, CppCSEVariable) csevar.is_vec = True return csevar else: new_index = self.transform_indexing(index) return super().load(name, new_index) def store(self, name, index, value, mode=None): assert "buf" in name var = self.args.output(name) inner = self.inner_itervar() index = self.rename_indexing(index) assert mode is None if self.need_vec_transpose(index): tile_var = self.gen_transposed_tile_load_store( name, var, index, is_store=True ) # vector store inside the kernel inner loop storebuf = f"{tile_var} + {cexpr_index(inner * self.num_elems)}" if self.tail_size or V.graph.get_dtype(name) in DTYPE_LOWP_FP + [ torch.uint8, torch.int8, ]: line = f"{value}.store({storebuf}, {cexpr_index(self.num_elems)});" else: line = f"{value}.store({storebuf});" self.stores.writeline(DeferredLine(name, line)) else: new_index = self.transform_indexing(index) super().store(name, new_index, value, mode) def codegen_inner_loops(self, code): inner = self.inner_itervar() if self.inner_is_tiling_idx: code.writeline( f"for (long {inner} = 0; {inner} < {cexpr_index(self.outer_num_elems)}; {inner}++)" ) else: code.writeline( f"for (long {inner} = 0; {inner} < {cexpr_index(self.inner_num_elems)}; {inner}++)" ) def set_ranges(self, group, reduction_group): vars = super().set_ranges(group, reduction_group) # do vertical reduction as the tail loop self.outer_idx, self.tiling_idx = ( self.tiling_indices if self.tiling_indices[1] < self.reduction_depth else reversed(self.tiling_indices) ) if self.tiling_idx == self.tiling_indices[0]: self.tail_size = self.outer_tail_size self.num_elems = self.outer_num_elems self.inner_is_tiling_idx = False else: self.tail_size = self.inner_tail_size self.num_elems = self.inner_num_elems self.inner_is_tiling_idx = True return vars def transform_indexing(self, index: sympy.Expr) -> sympy.Expr: return self.scale_index_with_offset( index, itervar_idx=self.outer_idx, offset=self.inner_itervar(), ) def get_loop_body_lowp_fp(_body: LoopBody) -> Tuple[Optional[torch.dtype], bool]: """ Returns the low precision data type (torch.float16/torch.bfloat16) contained in the nodes and if all the nodes can codegen with this data type without converting to float. Otherwise returns None and True. """ sub_blocks = [_body.root_block] + list(_body.subblocks.values()) _lowp_fp_type: Optional[torch.dtype] = None _use_fp32 = False for sub_block in sub_blocks: for _node in sub_block.graph.nodes: if _node.op == "placeholder" or _node.target in ( "get_index", "index_expr", ): continue # Fast path if all operations can support bf16/fp16 without converting to fp32 if _node.target not in [ "load", "store", "abs", "neg", "output", ]: _use_fp32 = True if hasattr(_node, "meta") and _node.meta: assert OptimizationContext.key in _node.meta opt_ctx: OptimizationContext = _node.meta[OptimizationContext.key] if not opt_ctx.dtype or opt_ctx.dtype not in DTYPE_LOWP_FP: _use_fp32 = True elif _lowp_fp_type is not None: if _lowp_fp_type != opt_ctx.dtype: warnings.warn("bf16 and fp16 are mixed in the scheduler node.") else: _lowp_fp_type = opt_ctx.dtype else: _use_fp32 = True return _lowp_fp_type, _use_fp32 class TilingSelect: """ Implement the heuristic to select the tiling factors and tiling indices. In the future, we can implement advanced heuristic in a subclass. """ def __init__(self): super().__init__() def select_tiling( self, fn_list, var_sizes_list, ) -> Tuple[List[int], List[int]]: # TODO(jgong5): support alternative tiling factors and data types loop_bodies = _get_loop_body(fn_list) all_dtypes = _get_dtype_from_loopbodies(loop_bodies) assert all_dtypes if any(dtype not in VECTORIZABLE_DTYPES for dtype in all_dtypes): return [], [] dtype = torch.float _lowp_fp_dtype = get_loop_body_lowp_fp(loop_bodies[0])[0] if _lowp_fp_dtype and all( (get_loop_body_lowp_fp(loop_body)[0] == _lowp_fp_dtype) for loop_body in loop_bodies[1:] ): dtype = _lowp_fp_dtype tiling_factor = cpu_vec_isa.pick_vec_isa().nelements(dtype=dtype) tiling_indices = self._select_tiling_indices( fn_list, var_sizes_list, tiling_factor ) if tiling_indices: group, reduction_group = max( var_sizes_list, key=lambda sizes: len(sizes[1]) ) call_ranges = tuple(group) + tuple(reduction_group) if config.cpp.enable_tiling_heuristics: def _try_get_stride( index, itervars, tiling_factor, tiling_indices, ): itervar = itervars[tiling_indices[0]] stride = stride_at_vec_range(index, itervar, tiling_factor) return stride if stride.is_number else None def _update_negative_op_count( node_name, non_contig_indexing_op_counter ): if node_name not in non_contig_indexing_op_counter: non_contig_indexing_op_counter[node_name] = 1 else: non_contig_indexing_op_counter[node_name] += 1 def _is_valid_indices( itervars, tiling_indices, ): return ( len(tiling_indices) == 1 and len(itervars) > 0 and ( tiling_indices[0] if tiling_indices[0] >= 0 else tiling_indices[0] + len(itervars) ) < len(itervars) ) itervars = [ sympy_index_symbol_with_prefix(SymT.XBLOCK, n) for n in range(len(call_ranges)) ] reduction_depth = len(group) vars, reduction_vars = ( itervars[:reduction_depth], itervars[reduction_depth:], ) op_counter: Dict[str, int] = {} # ops may cause overhead with vectorization, like non-contiguous # index_expr, load, store non_contig_indexing_op_counter: Dict[str, int] = {} for _body in loop_bodies: sub_blocks = [_body.root_block] + list(_body.subblocks.values()) for sub_block in sub_blocks: for _node in sub_block.graph.nodes: if _node.target in ["index_expr", "load", "store"]: # get the index and replace prefix from z to x arg_idx = 1 if _node.target == "index_expr" else 2 index = sub_block.body.indexing_from_args( (vars, reduction_vars) )[_node.args[arg_idx].args[0]] if _is_valid_indices(itervars, tiling_indices): stride = _try_get_stride( index, itervars, tiling_factor, tiling_indices ) if ( stride is None if _node.target == "index_expr" else stride not in [0, 1] ): _update_negative_op_count( _node.target, non_contig_indexing_op_counter ) if isinstance(_node.target, str) and not ( _node.target.startswith("masked_subblock") or _node.target in ["ops", "output", "constant", "get_index"] ): if _node.target not in op_counter: op_counter[_node.target] = 1 else: op_counter[_node.target] += 1 op_num = sum(op_counter.values()) non_contig_indexing_op_num = sum( non_contig_indexing_op_counter.values() ) threshold = 0.08 if op_num > 0 and non_contig_indexing_op_num / op_num >= threshold: # Too many non-contiguous load/store/index_expr which hurts the # vectorization performance. Disable vectorization when exceeding # the threshold. return [], [] if ( not reduction_group and group and len(tiling_indices) == 1 and not has_free_symbols( [ group[tiling_indices[0]], ] ) and group[tiling_indices[0]] < tiling_factor / 2 ): # For case of Multi Thread AMP Static shape of pyhpc_isoneutral_mixing, # the inner loop range doesn't have enough elements to do vectorization # explicitly and found that `#pragma GCC ivdep` has better performance than # `#pragma omp simd simdlen(8)`. Disable vectorization for this case. # Leslie: maybe we can always disable vectorization when loop range is less # than tiling factor and enable `#pragma omp simd simdlen(8)` for scalar kernel # when needed. return [], [] if dtype in DTYPE_LOWP_FP: # For lower precision data type, if the call_range is not long enough, # use tiling_factor // 2 for better performance factor_lowp = cpu_vec_isa.pick_vec_isa().nelements(dtype=dtype) for tiling_indice in tiling_indices: if tiling_indice < 0: tiling_indice = tiling_indice + len(call_ranges) if tiling_indice < 0 or tiling_indice >= len(call_ranges): continue if has_free_symbols(call_ranges): call_range = V.graph.sizevars.size_hint( call_ranges[tiling_indice], fallback=0 ) if call_range < factor_lowp: V.graph.sizevars.guard_lt(call_range, factor_lowp) # type: ignore[arg-type] tiling_factor = factor_lowp // 2 break elif call_ranges[tiling_indice] < factor_lowp: tiling_factor = factor_lowp // 2 break if len(tiling_indices) == 1: return [tiling_factor], tiling_indices if len(tiling_indices) == 2: return [tiling_factor, tiling_factor], tiling_indices return [], [] def _select_tiling_indices( self, fn_list, var_sizes_list, tiling_factor, ): all_index = [] for fn, var_sizes in zip(fn_list, var_sizes_list): rw = dependencies.extract_read_writes(fn, *var_sizes) all_index += [dep.index for dep in itertools.chain(rw.reads, rw.writes)] contig_vars = set() contig_vars_list = [] non_contig_stride_const = set() non_contig_stride_other = set() for index in all_index: for var in index.free_symbols: if not re.search(r"^d\d+$", var.name): continue stride = stride_at_vec_range(index, var, tiling_factor) if stride == 0: continue elif stride == 1: contig_vars.add(int(var.name[1:])) contig_vars_list.append(int(var.name[1:])) elif all(symbol_is_type(s, SymT.SIZE) for s in stride.free_symbols): non_contig_stride_const.add(int(var.name[1:])) else: non_contig_stride_other.add(int(var.name[1:])) contig_only = contig_vars - non_contig_stride_const - non_contig_stride_other group, reduction_group = max(var_sizes_list, key=lambda sizes: len(sizes[1])) num_itervars = len(group) + len(reduction_group) if len(contig_vars) == 0: # no contiguous vars return [num_itervars - 1] if contig_only: return sorted(contig_only)[-1:] contig_and_const_stride = ( contig_vars & non_contig_stride_const ) - non_contig_stride_other contig_vars_sorted = sorted(contig_vars) if ( len(contig_vars_sorted) == 2 and contig_vars_sorted[-1] in contig_and_const_stride and contig_vars_sorted[-1] == num_itervars - 1 ): return contig_vars_sorted return sorted(contig_vars_sorted, key=contig_vars_list.count)[-1:] class CppKernelProxy(CppKernel): def __init__(self, kernel_group): super().__init__(kernel_group.args, kernel_group.ws.num_threads) self.kernel_group = kernel_group self.loop_nest = None self.call_ranges = None self.picked_vec_isa: cpu_vec_isa.VecISA = cpu_vec_isa.pick_vec_isa() def data_type_propagation(self, nodes): for _node in nodes: assert isinstance(_node, SchedulerNode) DataTypePropagation.propagate_scheduler_node(_node) # Check if all the nodes of a given fx graph can support BF16/FP16 def is_lowp_fp_scheduler(self, scheduler_node: SchedulerNode): if not isinstance(scheduler_node._body, LoopBody): return True # Propagate the dtype to check if all the fx node is bf16/fp16 DataTypePropagation.propagate_scheduler_node(scheduler_node) return ( get_loop_body_lowp_fp(scheduler_node._body)[0] is not None and not get_loop_body_lowp_fp(scheduler_node._body)[1] ) def legalize_lowp_fp_dtype_loopbody(self, loop_body: LoopBody): def add_to_dtype(sub_graph: torch.fx.Graph): def is_lowp_fp_load(node: torch.fx.Node): if node.target not in ["load"]: return False assert len(node.args) == 3 load_dtype = V.graph.get_dtype(node.args[1]) # type: ignore[arg-type] return load_dtype in DTYPE_LOWP_FP def is_lowp_fp_store(node: torch.fx.Node): if node.target != "store": return False _, store_var, _, _, _ = node.args store_dtype = V.graph.get_dtype(store_var) # type: ignore[arg-type] return store_dtype in DTYPE_LOWP_FP sub_graph_nodes = list(sub_graph.nodes) to_lowp_fp_legalized_nodes = [] for _node in sub_graph_nodes: if is_lowp_fp_load(_node): # No need to promote to float if all users are direct stores if all(user.target == "store" for user in _node.users): continue ops = _node.args[0] with sub_graph.inserting_after(_node): to_type_node = sub_graph.call_method( "to_dtype", args=(ops, _node, torch.float) ) to_type_node_args = to_type_node.args _node.replace_all_uses_with(to_type_node) to_type_node.args = to_type_node_args metrics.cpp_to_dtype_count += 1 elif is_lowp_fp_store(_node): ops, name, _, value_var, _ = _node.args # No need to promote to float if it is a user of a load which are all directly stored if value_var.target == "load" and all( user.target == "store" for user in value_var.users ): continue dtype = V.graph.get_dtype(name) with sub_graph.inserting_before(_node): to_type_node = sub_graph.call_method( "to_dtype", args=(ops, value_var, dtype) ) _node.replace_input_with(value_var, to_type_node) metrics.cpp_to_dtype_count += 1 elif _node.target == "reduction": ( ops, dtype, src_dtype, reduction_type, value, ) = _node.args if src_dtype in DTYPE_LOWP_FP: # Since we always convert the load/store value to float if the tensor is bfloat16/float16. # Therefore, the reduction should never work with bfloat16/float16 value. Hence, we update # the bfloat16/float16 reduction by # 1) updating the src_dtype to float # and 2) updating the dtype to float if it is bfloat16/float16. assert dtype in [ torch.float, torch.bfloat16, torch.float16, torch.int64, ] _node.args = ( ops, torch.float if dtype in DTYPE_LOWP_FP else dtype, torch.float, reduction_type, value, ) elif _node.target == "to_dtype" and _node.args[-1] in DTYPE_LOWP_FP: (ops, x, _) = _node.args # The legalization always loads the BF16/FP16 tensor as FP32 for computation # and converts back to BF16/FP16 after the computation. # Hence, there should be no computation w/ BF16/FP16. # Therefore, we update the to_dtype by replacing the bf16/fp16 dtype with fp32. # Save the legalized to_dtype node for the elimination(eliminate_to_dtype step): # 1) Eliminate the redundant to_dtype node if we have a pattern as follows: # graph(): # %lowp_fp_legalized = call_method[target=to_dtype](args = (%ops, %input, torch.float)) # %to_dtype2 = call_method[target=to_dtype](args = (%ops, %lowp_fp_legalized, torch.bfloat16/float16)) # Regarding the first to_dtype, it is redundant because # the second to_type also converts to the torch.bfloat16/torch.float16. # Hence, we remove the first to_type. to_lowp_fp_legalized_nodes.append(_node) _node.args = (ops, x, torch.float) else: pass def eliminate_to_dtype(sub_graph: torch.fx.Graph): def _eliminate_duplicate_to_node(sub_graph: torch.fx.Graph): # Eliminate the redundant to_dtype node. Let's consider a pattern as follows: # graph(): # %to_dtype1 = call_method[target=to_dtype](args = (%ops, %input, torch.float), kwargs = {}) # %to_dtype2 = call_method[target=to_dtype](args = (%ops, %to_dtype1, torch.float), kwargs = {}) # Regarding the first to_dtype, it is redundant because the second to_type also converts to the # torch.float. Hence, we remove the first to_type def _used_by_to(to_node: torch.fx.Node): return all(usr.target == "to_dtype" for usr in to_node.users) all_to_nodes = [ node for node in sub_graph.nodes if node.target == "to_dtype" ] all_to_nodes_and_users = [ {node: node.users} for node in all_to_nodes if _used_by_to(node) ] for node_users in all_to_nodes_and_users: for node, users in node_users.items(): if node in sub_graph.nodes and ( all(usr.args[-1] == node.args[-1] for usr in users) or ( node in to_lowp_fp_legalized_nodes and all( usr.args[-1] in DTYPE_LOWP_FP for usr in users ) ) ): val_node = node.all_input_nodes[-1] node.replace_all_uses_with(val_node) sub_graph.erase_node(node) # For debug mode, the graph of LoopBody will attach a new GraphModule as # owning_module for debugging while the release mode will not. The lint will # check whether the graph has owning_module to decide if it needs to check # call_module. LoopBody might contain get_index as a module call. But it # is just a function. Hence, it cannot pass the lint check for debug mode. # We bypass the check if the owning_module is None. Eventually, we should call # get_index via call_function but not call_module. if sub_graph.owning_module is None: sub_graph.lint() _eliminate_duplicate_to_node(sub_graph) eliminate_to_dtype(sub_graph) sub_blocks = [loop_body.root_block] + list(loop_body.subblocks.values()) for sub_block in sub_blocks: add_to_dtype(sub_block.graph) def legalize_lowp_fp_dtype(self, nodes): if all( isinstance(_node, SchedulerNode) and self.is_lowp_fp_scheduler(_node) for _node in nodes ): # Mark the load node to load bf16/fp16 for _node in nodes: sub_blocks = [_node._body.root_block] + list( _node._body.subblocks.values() ) for sub_block in sub_blocks: for fx_node in sub_block.graph.nodes: if fx_node.target in ["load", "store"]: assert fx_node.meta assert OptimizationContext.key in fx_node.meta opt_ctx: OptimizationContext = fx_node.meta[ OptimizationContext.key ] assert opt_ctx.dtype in DTYPE_LOWP_FP # Bypass the legalization as the kernel can run with bf16/fp16 directly return for _node in nodes: assert isinstance(_node, SchedulerNode) assert isinstance(_node._body, LoopBody) body: LoopBody = _node._body if not body.is_memory_copy(): self.legalize_lowp_fp_dtype_loopbody(body) def codegen_functions(self, fn_list, var_sizes_list): assert len(fn_list) == len(var_sizes_list) kernel_group = self.kernel_group group, reduction_group = max(var_sizes_list, key=lambda sizes: len(sizes[1])) self.set_ranges(group, reduction_group) def codegen_kernel(cls, *args): with kernel_group.new_kernel(cls, *args) as kernel: # Ugly hack to maintain the metrics kernel count since # we only count in CppKernelProxy, not those contained in it metrics.generated_kernel_count -= 1 run(kernel) return kernel def run(kernel): vars, reduction_vars = kernel.set_ranges(group, reduction_group) in_suffix = False for fn, var_sizes in zip(fn_list, var_sizes_list): if var_sizes in [ (group, reduction_group), (tuple(itertools.chain(group, reduction_group)), ()), ]: assert not in_suffix fn(vars, reduction_vars) else: in_suffix = True assert var_sizes == ( group, (), ), f"unexpected group: {var_sizes} != {group}, {reduction_group}" # we can fuse in some extra pointwise into the suffix with kernel.write_to_suffix(): fn(vars, ()) scalar_kernel = codegen_kernel(CppKernel) V.graph.removed_buffers |= scalar_kernel.removed_buffers V.graph.inplaced_to_remove |= scalar_kernel.inplaced_to_remove self.loop_nest = LoopNestWithSplit.build(scalar_kernel) if not self.picked_vec_isa: return if not self.itervars: # not a loop return # Kernels share the same global contexts like V.graph.wrapper_code, V.kernel.args. # But the generated scalar kernel has updated these global contexts. Hence, the other kernels # should not do this again to avoid context conflict. By now, we only control the # config.inplace_buffers. In the future, we could maintain more contexts. with torch._inductor.config.patch(inplace_buffers=False): tiling_select = TilingSelect() tiling_factors, tiling_indices = tiling_select.select_tiling( fn_list, var_sizes_list ) assert len(tiling_factors) == len(tiling_indices) # This should be removed after full support for vectorization is implemented. could_masked_vec = True all_dtypes = _get_dtype_from_loopbodies(_get_loop_body(fn_list)) if any(dtype not in MASKED_VECTORIZABLE_DTYPES for dtype in all_dtypes): # can be removed after masked vectorizable dtype are same with vectorizable dtype could_masked_vec = False if len(tiling_indices) == 1: vec_kernel = codegen_kernel( CppVecKernel, tiling_factors[0], tiling_indices[0] ) metrics.generated_cpp_vec_kernel_count += 1 main_loop, tail_loop = self.loop_nest.split_with_tiling( tiling_indices[0], factor=tiling_factors[0] ) main_loop.set_kernel(vec_kernel) main_loop.simd_vec = True if config.cpp.enable_loop_tail_vec and could_masked_vec: tail_loop.steps = tail_loop.size - tail_loop.offset masked_vec_kernel = codegen_kernel( CppVecKernel, tiling_factors[0], tiling_indices[0], tail_loop.steps, ) tail_loop.set_kernel(masked_vec_kernel) tail_loop.simd_vec = True else: tail_loop.set_kernel(scalar_kernel) tail_loop.simd_omp = True # We chop the loop into two cubes by the nelements - main loop and tail loop. # Regarding the main loop, it is straightforward that it could be vectorized with # nelements. But for the tail loop, it still could be vectorized. For example, # if the nelements is 8(256bits), then the tail loop still could be vectorized # as 4(128bits). tail_loop.simd_nelements = tiling_factors[0] // 2 elif len(tiling_indices) == 2: assert ( tiling_indices[1] == len(self.itervars) - 1 and tiling_factors[0] == tiling_factors[1] ) metrics.generated_cpp_vec_kernel_count += 2 outer_main_loop, outer_tail_loop = self.loop_nest.split_with_tiling( tiling_indices[0], factor=tiling_factors[0] ) ( inner_main_loop, inner_tail_loop, ) = outer_main_loop.split_with_tiling( tiling_indices[1] - tiling_indices[0], factor=tiling_factors[0] ) tile2d_kernel = codegen_kernel( CppTile2DKernel, tiling_factors[0], tiling_indices ) inner_main_loop.set_kernel(tile2d_kernel) if config.cpp.enable_loop_tail_vec and could_masked_vec: ( inner_main_loop_of_outer_tail_loop, inner_tail_loop_of_outer_tail_loop, ) = outer_tail_loop.split_with_tiling( tiling_indices[1] - tiling_indices[0], factor=tiling_factors[0] ) for tail_loop in ( inner_tail_loop, outer_tail_loop, inner_tail_loop_of_outer_tail_loop, ): tail_loop.steps = tail_loop.size - tail_loop.offset for tail_loop, inner_tail_size, outer_tail_size in ( (inner_tail_loop, inner_tail_loop.steps, None), ( inner_main_loop_of_outer_tail_loop, None, outer_tail_loop.steps, ), ( inner_tail_loop_of_outer_tail_loop, inner_tail_loop_of_outer_tail_loop.steps, outer_tail_loop.steps, ), ): masked_tile2d_kernel = codegen_kernel( CppTile2DKernel, tiling_factors[0], tiling_indices, inner_tail_size, outer_tail_size, ) tail_loop.set_kernel(masked_tile2d_kernel) else: vec_kernel = codegen_kernel( CppVecKernel, tiling_factors[0], tiling_indices[0] ) inner_tail_loop.set_kernel(vec_kernel) outer_tail_loop.set_kernel(scalar_kernel) def codegen_loop_bodies(self, loop_bodies, var_sizes_list): for body in loop_bodies: self.legalize_lowp_fp_dtype_loopbody(body) DataTypePropagation.propagate_loopbody(body) self.codegen_functions(loop_bodies, var_sizes_list) def codegen_nodes(self, nodes: List[SchedulerNode]): # Legalize BF16 node by adding to_dtype explicitly self.legalize_lowp_fp_dtype(nodes) self.data_type_propagation(nodes) assert len(nodes) >= 1 def fn(node, *index_vars): node.decide_inplace_update() node.mark_run() if isinstance(V.kernel, NullKernelHandler): return node._body(*index_vars) else: return node.codegen(index_vars) fn_list = [functools.partial(fn, node) for node in nodes] if ( isinstance(V.local_buffer_context, LocalBufferContext) and V.local_buffer_context.local_buffers ): def wrap_fn(fn): wrapped_fn = V.local_buffer_context.localize_function( fn, ) wrapped_fn.original_fn = fn return wrapped_fn fn_list = [wrap_fn(fn) for fn in fn_list] var_sizes_list = [node.group[1] for node in nodes] self.codegen_functions(fn_list, var_sizes_list) def codegen_loops(self, code, worksharing): self.codegen_loops_impl(self.loop_nest, code, worksharing) class OuterLoopFusedKernel(CppKernel): def __init__(self, kernel_group): super().__init__(kernel_group.args, kernel_group.ws.num_threads) self.inner: List[LoopLevel] = [] def decide_parallel_depth(self, max_parallel_depth, threads) -> int: kernels_parallel_depth = [] nested_kernels: List[List[CppKernel]] = [ loop.get_kernels() for loop in self.inner ] for kernels in nested_kernels: # For any ScalarKernel, VecKernel, or Tile2DKernel, # they should all have the same call_ranges call_ranges = kernels[0].call_ranges assert call_ranges is not None assert all(kernel.call_ranges == call_ranges for kernel in kernels) kernels_parallel_depth.append( kernels[0].decide_parallel_depth(len(call_ranges), threads) ) return min( max_parallel_depth, max(kernels_parallel_depth), ) class ReasonFusedNodes(Enum): SAME_VARS_REDUCE = "same_vars_reduce" COMPATIBLE_REDUCTION = "compatible_reduction" COMPATIBLE_RANGES_NO_REDUCTION = "compatible_ranges_no_reduction" class CppScheduling(BaseScheduling): # ctypes limits the number of args to 1024, refer to: # https://github.com/python/cpython/commit/a285af7e626d1b81cf09f8b2bf7656f100bc1237 # We set a conservative threshold here. MAX_FUSED_KERNEL_ARGS_NUM = 500 backend_features = dict.fromkeys( [ BackendFeature.INPLACE_BUFFERS, BackendFeature.REDUCE_TO_SINGLE_ELEMENT, ] ) @classmethod def get_backend_features(cls, device: torch.device): return cls.backend_features def __init__(self, scheduler): super().__init__() self.scheduler = scheduler if scheduler: self.reset_kernel_group() self._ready_to_flush = False def _set_flush_status(self, status: bool): self._ready_to_flush = status def group_fn(self, sizes): return tuple(tuple(map(V.graph.sizevars.simplify, s)) for s in sizes) def reset_kernel_group(self): from .cpp_wrapper_cpu import CppWrapperCpu self.kernel_group: Union[CppWrapperKernelGroup, KernelGroup] if isinstance(V.graph.wrapper_code, CppWrapperCpu): self.kernel_group = CppWrapperKernelGroup() else: self.kernel_group = KernelGroup() def fuse(self, node1, node2): if node1.is_foreach() or node2.is_foreach(): return ForeachKernelSchedulerNode.fuse(node1, node2) elif node1.is_template(): assert not node2.is_template() return FusedSchedulerNode.fuse(node1, node2) else: if ( self._why_fuse_nodes(node1, node2) == ReasonFusedNodes.COMPATIBLE_RANGES_NO_REDUCTION ): assert isinstance(node1, (SchedulerNode, FusedSchedulerNode)) assert isinstance(node2, (SchedulerNode, FusedSchedulerNode)) _, (vars1, reduce1) = node1.group _, (vars2, reduce2) = node2.group assert reduce1 == () and reduce2 == (), (reduce1, reduce2) def get_indexing_ranges_exprs(node): if isinstance(node, FusedSchedulerNode): assert len(node.snodes) > 0, node.snodes var_ranges = None indexing_exprs = set() for snode in node.snodes: v, exprs = get_indexing_ranges_exprs(snode) if var_ranges is None: var_ranges = v assert var_ranges == v, (var_ranges, v, node.snodes) indexing_exprs.update(exprs) return var_ranges, list(indexing_exprs) else: assert isinstance(node, SchedulerNode) comp_buffer = node.node assert isinstance(comp_buffer, ir.ComputedBuffer) _, body, _ = comp_buffer.get_default_sizes_body() return body.var_ranges, list(body.indexing_exprs.values()) node_to_recomp = node1 if len(vars1) < len(vars2) else node2 assert isinstance(node_to_recomp, SchedulerNode) ref_node = node2 if len(vars1) < len(vars2) else node1 extra_indexing_constraints = get_indexing_ranges_exprs(ref_node) node_to_recomp.recompute_size_and_body( extra_indexing_constraints=extra_indexing_constraints ) _, (vars1, _) = node1.group _, (vars2, _) = node2.group assert vars1 == vars2, (vars1, vars2) return FusedSchedulerNode.fuse(node1, node2) elif self.can_fuse_vertical_outer_loop(node1, node2): return OuterLoopFusedSchedulerNode.fuse( node1, node2, self._get_outer_loop_fusion_depth(node1, node2) ) else: return FusedSchedulerNode.fuse(node1, node2) def _why_fuse_nodes(self, node1, node2) -> Optional[ReasonFusedNodes]: _, (vars1, reduce1) = node1.group _, (vars2, reduce2) = node2.group if vars1 == vars2 and reduce1 == reduce2: return ReasonFusedNodes.SAME_VARS_REDUCE if reduce1 == () and vars1 == vars2 + reduce2: return ReasonFusedNodes.COMPATIBLE_REDUCTION if self._can_fuse_nodes_with_compatible_ranges(node1, node2): return ReasonFusedNodes.COMPATIBLE_RANGES_NO_REDUCTION # TODO(jansel): allow fusion pointwise (vars1, ()) suffix? return None def _can_fuse_nodes_with_compatible_ranges(self, node1, node2): # Here we try to fuse SchedulerNode/FusedSchedulerNode with compatible ranges # e.g. (s0, s1, s2) and (s0 * s1 * s2) _, (vars1, reduce1) = node1.group _, (vars2, reduce2) = node2.group c1 = reduce1 == () and reduce2 == () c2 = math.prod(vars1) == math.prod(vars2) c3 = len(vars1) == 1 or len(vars2) == 1 if not (c1 and c2 and c3): return False node_to_recomp = node1 if len(vars1) < len(vars2) else node2 ref_node = node2 if len(vars1) < len(vars2) else node1 # We can not recompute sizes and body for nodes other than SchedulerNode # TODO: we can extend fusion support with compatible ranges for FusedSchedulerNode if isinstance(node_to_recomp, FusedSchedulerNode): return False # It may happen that node1 and node2 compatible number of elements # but different original ranges, for example: # {d0: s0, d1: s1, d2: s2} vs {d0: s0*s1*s2} # See https://github.com/pytorch/pytorch/pull/120077/files#r1500427848 for more details # TODO: we can fix if it allows us to CSE at least one of the variables assert isinstance(node_to_recomp, SchedulerNode) if isinstance(node_to_recomp.node, ir.TemplateBuffer): return False assert isinstance(node_to_recomp.node, ir.ComputedBuffer) # node.data.get_size() is a cheaper version of node.get_read_writes().var_ranges # but without variable name ranges2 = node_to_recomp.node.data.get_size() ranges1 = None if isinstance(ref_node, FusedSchedulerNode): ranges_set = set() for snode in ref_node.snodes: if isinstance(snode.node, ir.TemplateBuffer): break assert isinstance(snode.node, ir.ComputedBuffer) ranges_set.add(tuple(snode.node.data.get_size())) if len(ranges_set) != 1: return False ranges1 = list(next(iter(ranges_set))) else: assert isinstance(ref_node, SchedulerNode) assert isinstance(ref_node.node, ir.ComputedBuffer) ranges1 = ref_node.node.data.get_size() if ranges1 != ranges2: return False return True def _can_fuse_horizontal_impl(self, node1, node2): assert isinstance(node1, (FusedSchedulerNode, SchedulerNode)) assert isinstance(node2, (FusedSchedulerNode, SchedulerNode)) if any( isinstance(node, OuterLoopFusedSchedulerNode) for node in (node1, node2) ): return False return self._why_fuse_nodes(node1, node2) is not None def can_fuse_horizontal(self, node1, node2): if node1.is_template() or node2.is_template(): return False if ( len(node1.get_nodes()) + len(node2.get_nodes()) > config.cpp.max_horizontal_fusion_size ): return False return self._can_fuse_horizontal_impl(node1, node2) def _get_outer_loop_fusion_depth(self, node1, node2): DISABLE_OUTER_LOOP_FUSION = 0 if not all( type(node) in (OuterLoopFusedSchedulerNode, FusedSchedulerNode, SchedulerNode) for node in (node1, node2) ): return DISABLE_OUTER_LOOP_FUSION _node1 = ( node1.get_outer_nodes()[-1] if isinstance(node1, OuterLoopFusedSchedulerNode) else node1 ) assert isinstance(_node1, (FusedSchedulerNode, SchedulerNode)) _node2 = ( node2.get_outer_nodes()[0] if isinstance(node2, OuterLoopFusedSchedulerNode) else node2 ) assert isinstance(_node2, (FusedSchedulerNode, SchedulerNode)) _, (vars1, reduce1) = _node1.group _, (vars2, reduce2) = _node2.group if vars1 == () and vars2 == () and reduce1 != () and reduce2 != (): # Reduction only return DISABLE_OUTER_LOOP_FUSION if all(type(node) is OuterLoopFusedSchedulerNode for node in (node1, node2)): return ( node1.outer_loop_fusion_depth if node1.outer_loop_fusion_depth == node2.outer_loop_fusion_depth else DISABLE_OUTER_LOOP_FUSION ) outer_loop_fusion_depth = min(len(vars1), len(vars2)) if ( outer_loop_fusion_depth >= 1 and vars1[:outer_loop_fusion_depth] == vars2[:outer_loop_fusion_depth] ): if any( type(node) is OuterLoopFusedSchedulerNode for node in (node1, node2) ): _compare_node = ( node1 if type(node1) is OuterLoopFusedSchedulerNode else node2 ) if _compare_node.outer_loop_fusion_depth == outer_loop_fusion_depth: # Same outer loop fusion depth as prev nodes in OuterLoopFusedSchedulerNode return outer_loop_fusion_depth else: return DISABLE_OUTER_LOOP_FUSION else: # First 2 nodes to generate OuterLoopFusedSchedulerNode return outer_loop_fusion_depth return DISABLE_OUTER_LOOP_FUSION def can_fuse_vertical_outer_loop(self, node1, node2): return ( not node1.is_template() and not node2.is_template() and node1.get_operation_names() & node2.ancestors and not ( self._can_fuse_horizontal_impl(node1, node2) and not node1.is_reduction() ) and self._get_outer_loop_fusion_depth(node1, node2) >= 1 ) def get_fusion_pair_priority(self, node1, node2): if self.can_fuse_vertical_outer_loop(node1, node2): # Outer loop fusion with lower priority return 1 else: return 0 def can_fuse_vertical(self, node1, node2): if node2.is_template(): # TODO(jgong5): support pre-op fusion with template return False if node1.is_template(): template_fusion_supported, _ = template_fusion_with_epilogues_supported( node1, [node2] ) return not node2.is_reduction() and template_fusion_supported return ( self._can_fuse_horizontal_impl(node1, node2) and not node1.is_reduction() ) or self.can_fuse_vertical_outer_loop(node1, node2) def try_loop_split(self, nodes: List[SchedulerNode]): """ Apply loop split optimization. When one of the indexing_exprs contains a division, we eliminate the division by splitting the loop to avoid non-contiguous loads, subject to the following conditions: 1. No reduction and no mudular index for all nodes. 2. The indexing_exprs of all nodes contain only one (or more, but all the same) division, where the divisor is an integer, the dividend is one of the iter_vars, and this var, i.e. the dimension that needs to be split, is contiguous in all other indexing_exprs. For example, if the node's var_ranges: {z0: 2, z1: 9216, z2: 960} and indexing_exprs: {'index0': 8847360*z0 + 960*z1 + z2, 'index1': 32*z0 + (z2//30), 'index2': z2}, we will split z2 -> 30*z2 + z3, then the node's var_ranges will be changed to {z0: 2, z1: 9216, z2: 32, z3: 30} and indexing_exprs will be changed to {'index0': 8847360*z0 + 960*z1 + 30*z2 + z3, 'index1': 32*z0 + z2, 'index2': 30*z2 + z3}. """ # No reduction and no mudular if any( len(node.group[1][1]) != 0 or any( expr.has(ModularIndexing) for expr in node._body.indexing_exprs.values() ) for node in nodes ): return nodes split_var = None split_number = None num_div = 0 div_expr_ = None match_div = False matched_node = None for node in nodes: assert isinstance(node.node, ir.ComputedBuffer) _, original_body, _ = node.node.get_default_sizes_body() for name, expr in original_body.indexing_exprs.items(): for div_expr in expr.find(FloorDiv): if ( any(div_expr.has(var) for var in original_body.iter_vars) and div_expr != div_expr_ ): div_expr_ = div_expr num_div += 1 if num_div > 1: return nodes if ( isinstance(div_expr.args[1], sympy.core.numbers.Integer) and div_expr.args[0] in original_body.iter_vars and name is not None and all( stride_at_vec_range(expr_, div_expr.args[0]) in (0, 1) for name_, expr_ in original_body.indexing_exprs.items() if name_ != name ) ): split_var = div_expr.args[0] split_number = div_expr.args[1] match_div = True matched_node = node # Only one node contains a division, and the split dimension is contiguous in all other indexing_exprs. if not match_div: return nodes extra_indexing_constraints = None def loop_split(sizes, body, vars): index_size, reduce_size = sizes index_vars, reduce_vars = vars split_idx = index_vars.index(split_var) new_index_size = index_size.copy() new_index_size[split_idx] = index_size[split_idx] // split_number new_index_size.insert(split_idx + 1, split_number) (new_index_vars, _), var_ranges = dependencies.index_vars_no_squeeze( new_index_size, reduce_size, prefix="y" ) iter_vars = new_index_vars.copy() divisor_var = iter_vars.pop(split_idx + 1) iter_vars[split_idx] = split_number * iter_vars[split_idx] + divisor_var body = ir.LoopBody( body, [iter_vars, reduce_vars], var_ranges, new_index_vars, reduce_vars ) nonlocal extra_indexing_constraints if not extra_indexing_constraints: extra_indexing_constraints = ( body.var_ranges, list(body.indexing_exprs.values()), ) return ( (new_index_size, reduce_size), body, (new_index_vars, reduce_vars), ) # Here decide the final loop order for node in nodes: if node == matched_node: node.recompute_size_and_body(recompute_sizes_body_func=loop_split) for node in nodes: if node != matched_node: node.recompute_size_and_body( extra_indexing_constraints=extra_indexing_constraints, recompute_sizes_body_func=loop_split, ) return nodes def codegen_outer_loop_node( self, node: OuterLoopFusedSchedulerNode, ): """ Generate the code for the outer loop fused scheduler node. 1. Codegen with fused outer loop: depends on the analysis of the outer loop fused scheduler node, with or without the local buffer. 2. If failed, fallback to standard codegen. """ kernel_group = self.kernel_group generated_cpp_vec_kernel_count = metrics.generated_cpp_vec_kernel_count cpp_kernel_proxy_list: List[CppKernelProxy] = [] nodes_list: List[List[SchedulerNode]] = [] assert isinstance(node, OuterLoopFusedSchedulerNode) def try_outer_loop_fusion_with_local_buf(node: OuterLoopFusedSchedulerNode): """ Codegen code with fused outer loop and local Buffer. """ assert isinstance(node, OuterLoopFusedSchedulerNode) cpp_kernel_proxy_list.clear() nodes_list.clear() def get_call_ranges(node: BaseSchedulerNode): assert isinstance(node, (SchedulerNode, FusedSchedulerNode)) nodes: List[SchedulerNode] = node.get_nodes() # type: ignore[assignment] _, (group, reduction_group) = max( nodes, key=lambda x: int(x.is_reduction()) ).group call_ranges = tuple(group) + tuple(reduction_group) return call_ranges local_buffers: List[ir.Buffer] = [] # Map local buffer name to a list of global buffers local_to_global_buffers: Dict[str, List[ir.Buffer]] = {} if all( len(get_call_ranges(_node)) == node.outer_loop_fusion_depth + 1 for _node in node.get_outer_nodes() ): # Ref to the typical case of local buffer # in https://github.com/pytorch/pytorch/blob/ # 1115a25c36340554442f28f9570abd42f0aface2/aten/src/ATen/native/cpu/SoftMaxKernel.cpp#L159 # where the buffer is with size of last dim and contiguous. # Only support this typical case at first. visited_scheduler_nodes: Set[str] = set() for scheduler_node in node.get_nodes(): # all users inside same OuterLoopFusedSchedulerNode assert isinstance(scheduler_node, SchedulerNode) visited_scheduler_nodes.add(scheduler_node.get_name()) if ( scheduler_node.is_reduction() or len(scheduler_node.get_outputs()) != 1 ): continue scheduler_buffer = scheduler_node.get_outputs()[0] if all( user.node in node.get_nodes() for user in scheduler_buffer.users ): global_buffer = scheduler_buffer.node assert isinstance(global_buffer, ir.ComputedBuffer) global_buffer_layout = global_buffer.get_layout() size_offset = node.outer_loop_fusion_depth - len( get_call_ranges(scheduler_node) ) def is_all_write_read_contiguous(): contiguous_index_expr = 0 stride = 1 for var, range in reversed( scheduler_node._body.var_ranges.items() ): contiguous_index_expr += stride * var stride *= range write_index_expr = scheduler_node._body.get_write_expr( scheduler_buffer.get_name() ) def is_contiguous_index(x): return x == contiguous_index_expr return is_contiguous_index(write_index_expr) and all( isinstance(user.node, SchedulerNode) and is_contiguous_index( user.node._body.get_read_expr( scheduler_buffer.get_name() ), ) for user in scheduler_buffer.users ) if not ( global_buffer_layout.is_contiguous() and is_all_write_read_contiguous() ): continue # Local Buffer is a view of global buffer local_buffer_layout = ir.FixedLayout( global_buffer_layout.device, global_buffer_layout.dtype, global_buffer_layout.size[size_offset:], global_buffer_layout.stride[size_offset:], ) def try_share_local_buffer(local_buffer_layout, local_buffers): for local_buf in local_buffers: if local_buffer_layout == local_buf.layout and all( all( user.node.get_name() in visited_scheduler_nodes for user in V.graph.scheduler.name_to_buf[ global_buffer.name ].users ) for global_buffer in local_to_global_buffers[ local_buf.name ] if global_buffer.name is not None ): return local_buf return None local_buf_prefix = "local_buffer_data" # Share existing local buffer local_buffer_used = try_share_local_buffer( local_buffer_layout, local_buffers ) if not local_buffer_used: # Create new local buffer local_buffer_used = ir.Buffer( f"{local_buf_prefix}_{len(local_buffers)}", local_buffer_layout, ) local_buffers.append(local_buffer_used) local_to_global_buffers[local_buffer_used.name] = [] local_to_global_buffers[local_buffer_used.name].append( global_buffer, ) with LocalBufferContext(kernel_group.args) as scope: if len(local_buffers) > 0: for local_buffer in local_buffers: assert local_buffer.name is not None scope.add_local_buffer( local_buffer, local_to_global_buffers[local_buffer.name] ) for _node in node.get_outer_nodes(): assert isinstance(_node, (FusedSchedulerNode, SchedulerNode)) cpp_kernel_proxy = CppKernelProxy(kernel_group) cpp_kernel_proxy.codegen_nodes(_node.get_nodes()) # type: ignore[arg-type] cpp_kernel_proxy_list.append(cpp_kernel_proxy) nodes_list.append(_node.get_nodes()) # type: ignore[arg-type] if not node.check_outer_fusion_loop_level_attr( cpp_kernel_proxy_list, node.outer_loop_fusion_depth ): return False metrics.cpp_outer_loop_fused_inner_counts.append( metrics.CppOuterLoopFusedCount( len(cpp_kernel_proxy_list), local_buffer_number=len(scope.local_buffers), ) ) outer_fusion_cpp_kernel_proxy = node.merge_outer_fusion_kernels( cpp_kernel_proxy_list, ) kernel_group.finalize_kernel( outer_fusion_cpp_kernel_proxy, [_node for _nodes in nodes_list for _node in _nodes], ) return True if not try_outer_loop_fusion_with_local_buf(node): # Reset generated_cpp_vec_kernel_count to codegen again metrics.generated_cpp_vec_kernel_count = generated_cpp_vec_kernel_count cpp_kernel_proxy_list.clear() nodes_list.clear() # Similar as comment in # https://github.com/pytorch/pytorch/blob/469383755fe416eb1c41fa724762ad3eaecdff07/torch/_inductor/codegen/cpp.py#L3269-L3272 # Kernels share the same global contexts like V.graph.wrapper_code, V.kernel.args. with torch._inductor.config.patch(inplace_buffers=False): for _node in node.get_outer_nodes(): assert isinstance(_node, (FusedSchedulerNode, SchedulerNode)) _nodes: List[SchedulerNode] = _node.get_nodes() # type: ignore[assignment] cpp_kernel_proxy = CppKernelProxy(kernel_group) cpp_kernel_proxy.codegen_nodes(_nodes) kernel_group.finalize_kernel(cpp_kernel_proxy, _nodes) def codegen_node( self, node: Union[OuterLoopFusedSchedulerNode, FusedSchedulerNode, SchedulerNode], ): """ Turn an set of pre-fused nodes into a C++ kernel. """ kernel_group = self.kernel_group if isinstance(node, OuterLoopFusedSchedulerNode): self.codegen_outer_loop_node(node) else: nodes: List[SchedulerNode] = node.get_nodes() # type: ignore[assignment] nodes = self.try_loop_split(nodes) cpp_kernel_proxy = CppKernelProxy(kernel_group) cpp_kernel_proxy.codegen_nodes(nodes) kernel_group.finalize_kernel(cpp_kernel_proxy, nodes) args_num = self._get_scheduled_num_args() if args_num > CppScheduling.MAX_FUSED_KERNEL_ARGS_NUM: self._set_flush_status(True) def is_cpp_template(self, node: BaseSchedulerNode) -> bool: return isinstance(node, SchedulerNode) and isinstance( node.node, ir.CppTemplateBuffer ) def codegen_template( self, template_node: BaseSchedulerNode, epilogue_nodes: Sequence[BaseSchedulerNode], ): """ Codegen a CPP template, possibly with fused epilogues """ counters["inductor"]["cpp_epilogue_fusion_counter"] += len(epilogue_nodes) assert self.is_cpp_template( template_node ), "Template node passed to CppScheduler.codegen_template must be a SchedulerNode that wraps a CppTemplateBuffer" template_node = cast(SchedulerNode, template_node) _, (_, rnumel) = template_node.group assert rnumel == () ctb: ir.CppTemplateBuffer = cast(ir.CppTemplateBuffer, template_node.node) epilogue_ir_nodes: List[Optional[ir.Operation]] = [ n.node for n in epilogue_nodes ] assert all( isinstance(n, ir.ComputedBuffer) for n in epilogue_ir_nodes ), "Epilogue nodes must all be instances of ir.ComputedBuffer" def template_buffer_has_other_users( template_buffer, outputs_by_name, epilogue_nodes ): if not epilogue_nodes: return False assert template_buffer.get_name() in outputs_by_name users = outputs_by_name[template_buffer.get_name()].users return not all( isinstance(user.node, BaseSchedulerNode) and user.node.node in epilogue_nodes for user in users ) flag_template_buffer_has_other_users = template_buffer_has_other_users( ctb, template_node.outputs_by_name, epilogue_ir_nodes ) kernel, render = ctb.make_kernel_render( ctb, flag_template_buffer_has_other_users=flag_template_buffer_has_other_users, epilogue_nodes=epilogue_ir_nodes, ) with kernel: for node in [template_node, *epilogue_nodes]: node.mark_run() # type: ignore[attr-defined] src_code = render() with V.set_kernel_handler(kernel): node_schedule = [template_node, *epilogue_nodes] kernel_name = self.define_kernel(src_code, node_schedule, kernel.args) kernel.call_kernel(kernel_name, ctb) V.graph.removed_buffers |= kernel.removed_buffers self.scheduler.free_buffers() def _get_scheduled_num_args(self): return self.kernel_group.get_num_args() def ready_to_flush(self): return self._ready_to_flush def codegen_sync(self): pass def define_kernel(self, src_code, nodes, kernel_args=None): wrapper = V.graph.wrapper_code fused_name = ( get_fused_kernel_name(nodes, config.cpp.descriptive_names) if config.cpp.descriptive_names else "" ) kernel_name = "_".join(["cpp", fused_name, wrapper.next_kernel_suffix()]) kernel_decl_name = kernel_name if V.graph.cpp_wrapper else "kernel" src_code = src_code.replace(str(Placeholder.KERNEL_NAME), kernel_decl_name) src_code = src_code.replace(str(Placeholder.DESCRIPTIVE_NAME), kernel_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", "//") compile_wrapper = IndentedBuffer() args = self.kernel_group.args if kernel_args is None else kernel_args _, _, arg_types = args.cpp_argdefs() if not V.graph.cpp_wrapper: compile_wrapper.writeline(f"async_compile.cpp_pybinding({arg_types!r}, '''") compile_wrapper.splice(src_code, strip=True) if not V.graph.cpp_wrapper: compile_wrapper.writeline("''')") wrapper.define_kernel(kernel_name, compile_wrapper.getvalue(), gpu=False) return kernel_name def flush(self): src_code = self.kernel_group.codegen_group() if src_code: kernel_name = self.define_kernel( src_code, self.kernel_group.scheduled_nodes ) self.kernel_group.call_kernel(V.graph.wrapper_code, kernel_name) self.reset_kernel_group() self._set_flush_status(False) class KernelGroup: def __init__(self): super().__init__() self.args = KernelArgs() self.loops_code = BracesBuffer() self.ws = WorkSharing(self.loops_code) self.stack = contextlib.ExitStack() self.stack.enter_context(self.ws) self.scheduled_nodes = [] def new_kernel(self, cls, *args): return cls(self.args, parallel_num_threads(), *args) def finalize_kernel(self, new_kernel, nodes): self.scheduled_nodes += nodes code = self.loops_code ws = self.ws new_kernel.codegen_loops(code, ws) def get_num_args(self): arg_defs, call_args, arg_types = self.args.cpp_argdefs() args_num = len(arg_defs) return args_num def codegen_group(self, name=None) -> str: self.stack.close() if not self.scheduled_nodes: return "" code = BracesBuffer() # 1. Include header files # TODO: support kernel profile on other platforms enable_kernel_profile = config.cpp.enable_kernel_profile and sys.platform in [ "linux", "win32", ] if enable_kernel_profile: code.writelines(["#include "]) code.writeline(codecache.cpp_prefix()) # 2. Function definition kernel_decl_name = str(Placeholder.KERNEL_NAME) if name is None else name kernel_name = str(Placeholder.DESCRIPTIVE_NAME) if name is None else name arg_defs, _, _ = self.args.cpp_argdefs() arg_defs = ",\n".ljust(25).join(arg_defs) func_export_decl = get_export_declaration() code.writeline( f'extern "C" {func_export_decl} void {kernel_decl_name}({arg_defs})' ) # 3. Function body with code.indent(): if enable_kernel_profile: graph_id = V.graph.graph_id prefix = "graph_" + str(graph_id) + "_" if graph_id is not None else "" code.writelines( [ f'RECORD_FUNCTION("{prefix + kernel_name}", c10::ArrayRef({{}}));' ] ) for old, new in self.args.aliases(): code.writeline(f"auto {old} = {new};") code.splice(self.loops_code) return code.getvalue() def call_kernel(self, wrapper, kernel_name): _, call_args, arg_types = self.args.cpp_argdefs() wrapper.generate_kernel_call( kernel_name, call_args, gpu=False, triton=False, arg_types=arg_types ) class CppWrapperKernelGroup(KernelGroup): def __init__(self): super().__init__() self.args = CppWrapperKernelArgs() class WorkSharing: def __init__(self, code): self.code = code self.in_parallel = False self.num_threads = None self.stack = contextlib.ExitStack() def parallel(self, threads): if self.in_parallel and threads != self.num_threads: # wrong number of threads self.close() if not self.in_parallel: self.num_threads = threads self.in_parallel = True if config.cpp.dynamic_threads: self.code.writeline("#pragma omp parallel") else: self.code.writeline(f"#pragma omp parallel num_threads({threads})") self.stack.enter_context(self.code.indent()) self.code.writeline( "int tid = omp_get_thread_num();", ) def single(self): if self.in_parallel: self.code.writeline("#pragma omp single") return self.in_parallel def close(self): self.stack.close() self.in_parallel = False def __enter__(self): self.stack.__enter__() return self def __exit__(self, exc_type, exc_val, exc_tb): self.stack.__exit__(exc_type, exc_val, exc_tb) @dataclasses.dataclass class LoopLevel: var: Optional[sympy.Expr] = None size: Optional[sympy.Expr] = None offset: sympy.Expr = sympy.Integer(0) steps: sympy.Expr = sympy.Integer(1) parallel: int = 0 simd_omp: bool = False simd_vec: bool = False collapsed: bool = False is_reduction: bool = False parent: Optional["LoopLevel"] = None # the next inner level of the loop, empty if it is inner-most # contains >1 LoopLevel if the inner level of loop is split inner: List["LoopLevel"] = dataclasses.field(default_factory=list) # kernel assigned to this loop level, only valid when it is a leaf kernel: Optional[CppKernel] = None def __post_init__(self): # Regarding the C++/OpenMP backend, `cpu_vec_isa.pick_vec_isa()` to check # vectorization ISA is a time-consuming and one-shot operation. It leads # to taking a longer time to import `codegen.cpp` package because the # `LoopLevel` of the package is decorated by `@dataclasses.dataclass` while # the decorator will invoke `cpu_vec_isa.pick_vec_isa()` to initialize the # `simd_nelements` of the `LoopLevel`. It might introduce additional compilation # overhead to the Triton backend. Therefore, we moved the `simd_nelements` to # `__post_init__` picked_vec_isa: cpu_vec_isa.VecISA = cpu_vec_isa.pick_vec_isa() self.simd_nelements: int = picked_vec_isa.nelements() if picked_vec_isa else 0 def get_kernels(self) -> List[CppKernel]: """Get all kernel objects under this loop level""" if self.kernel: return [self.kernel] kernels = [] for loop in self.inner: kernels += loop.get_kernels() return kernels def get_root(self): """Get all kernel objects under this loop level""" root = self while root.parent: root = root.parent return root def set_kernel(self, kernel: CppKernel): """ Set the kernel under this loop level. No split is allowed under this loop level. """ if not self.inner: self.kernel = kernel loop: Optional[LoopLevel] = self assert loop is not None return assert len(self.inner) == 1 self.inner[0].set_kernel(kernel) def get_loops_at(self, depth) -> List["LoopLevel"]: if depth == 0: return [self] else: loops = [] for loop in self.inner: loops += loop.get_loops_at(depth - 1) return loops def split_with_tiling(self, depth, factor): def clone_inner(): inner = [] if self.inner: for loop in self.inner: inner.append(loop.clone()) return inner def do_split_with_tiling(): sympy_factor = sympy.Integer(factor) offset = FloorDiv(self.size, sympy_factor) * sympy_factor main_loop = LoopLevel(self.var, offset) main_loop.steps = sympy_factor main_loop.parallel = self.parallel main_loop.collapsed = False main_loop.is_reduction = self.is_reduction main_loop.inner = clone_inner() if main_loop.inner: for loop in main_loop.inner: loop.parent = main_loop tail_loop = LoopLevel(self.var, self.size) tail_loop.offset = offset tail_loop.parallel = self.parallel tail_loop.collapsed = False tail_loop.is_reduction = self.is_reduction tail_loop.inner = clone_inner() if tail_loop.inner: for loop in tail_loop.inner: loop.parent = tail_loop return main_loop, tail_loop if depth == 0: main_loop, tail_loop = do_split_with_tiling() parent = self.parent if parent: parent.inner = [main_loop, tail_loop] main_loop.parent = parent tail_loop.parent = parent return main_loop, tail_loop else: assert len(self.inner) == 1 return self.inner[0].split_with_tiling(depth - 1, factor) def clone(self): loop = copy(self) loop.inner = [] if self.inner: for inner_loop in self.inner: inner_loop_clone = inner_loop.clone() inner_loop_clone.parent = loop loop.inner.append(inner_loop_clone) loop.kernel = deepcopy(self.kernel) return loop def lines(self): offset_expr = cexpr_index(self.offset) size_expr = cexpr_index(self.size) if config.cpp.no_redundant_loops and offset_expr == size_expr: return None simd = ( f"simd simdlen({self.simd_nelements}) " if self.simd_omp and self.simd_nelements > 1 else "" ) if self.parallel: # TODO(jansel): look into chunk size and other schedules line1 = "#pragma omp for" if self.parallel > 1: line1 += f" collapse({self.parallel})" if self.simd_omp: line1 = line1.replace(" for ", f" for {simd}") elif self.simd_vec: line1 = "" elif self.simd_omp: line1 = f"#pragma omp {simd}" elif not self.is_reduction and cpp_builder.is_gcc(): line1 = "#pragma GCC ivdep" else: line1 = "" offset_str = f"{INDEX_TYPE} {self.var}={offset_expr}" size_str = f"{self.var}<{size_expr}" if self.steps.is_number: steps_str = f"{self.var}+={cexpr_index(self.steps)}" else: # If the step size is 0, change it to 1 because a step size of 0 # will cause floating point exception (core dump) during parallelization. steps_str = ( f"{self.var}+=({cexpr_index(self.steps)} == 0 ? " f"1 : {cexpr_index(self.steps)})" ) line2 = f"for({offset_str}; {size_str}; {steps_str})" if self.collapsed or not line1: return [line2] return [line1, line2] @dataclasses.dataclass class LoopNestWithSplit: """ A loop-nest like structure but with some loop level split along the loop range into the main tiling loop and the tail. It is built with the `build` method as a loop nest and then split with `split_with_tiling` at some depth. A typical case is for vectorization where we typically split at the inner-most loop level. A more complicated case is 2D tiling where we split at both inner-most and outer levels. """ root: Optional[List[LoopLevel]] = None kernel: Optional[CppKernel] = None @staticmethod def build(kernel: CppKernel): """Build a LoopNest with the given `kernel` as the leaf""" itervars = kernel.itervars ranges = kernel.ranges reduction_depth = kernel.reduction_depth assert reduction_depth is not None root: List[LoopLevel] = [] levels: List[LoopLevel] = root loop: Optional[LoopLevel] = None for loop_idx, (var, size) in enumerate(zip(itervars, ranges)): loop = LoopLevel(var, size, parent=loop) if loop_idx >= reduction_depth: loop.is_reduction = kernel.is_reduction levels.append(loop) levels = loop.inner loop_nest = LoopNestWithSplit(root) if loop: loop.kernel = kernel else: loop_nest.kernel = kernel return loop_nest def __bool__(self): return bool(self.root) def get_loops_at(self, depth) -> List[LoopLevel]: """Get all the loop levels at the given `depth` (most outer loop has depth 0)""" loops: List[LoopLevel] = [] assert self.root is not None for loop in self.root: loops += loop.get_loops_at(depth) return loops @cache_on_self def max_parallel_depth(self): """ Maximal allowed depth for parallelism: 1) Levels without splitting and 2) All reduction or non-reduction levels When the loop is split at the top level, the max depth is 1. """ max_depth = 0 assert self.root is not None loops = self.root if len(loops) > 1: return 1 is_reduction = loops[0].is_reduction if loops else False while len(loops) == 1 and loops[0].is_reduction == is_reduction: max_depth += 1 loops = loops[0].inner return max_depth def is_reduction_only(self): """ Whether all the loops are for reduction. Reduction loops are always the inner most ones. """ return ( self.root is not None and len(self.root) > 0 and self.root[0].is_reduction ) def mark_parallel(self, par_depth): assert ( par_depth <= self.max_parallel_depth() ), "Parallel depth cannot exceed the maximal allowed parallel depth" assert self.root is not None loops = self.root for loop in loops: loop.parallel = par_depth for i in range(1, par_depth): loops = loops[0].inner loops[0].collapsed = True def split_with_tiling(self, depth, factor): """ Split the loop into main and tail loops at given `depth` so that the range of the main loop has range `floor_div(range, factor) * factor` and the tail loop handles the remainder. The main loop is tiled according to the `factor`. """ loops = self.get_loops_at(depth) assert len(loops) == 1 split_loops = loops[0].split_with_tiling(0, factor) if depth == 0: self.root = split_loops return split_loops def get_kernels(self) -> List[CppKernel]: """Get all kernel objects under this loop nest""" if self.kernel: return [self.kernel] kernels: List[CppKernel] = [] assert self.root is not None for loop in self.root: kernels += loop.get_kernels() return kernels