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llvm / llvm-project / 0c1b18f0f3e526da7dcbbd5a9e363dca85a90c95 / . / polly / lib / Transform / MatmulOptimizer.cpp
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//===- MatmulOptimizer.cpp -----------------------------------------------===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
#include "polly/MatmulOptimizer.h"
#include "polly/DependenceInfo.h"
#include "polly/Options.h"
#include "polly/ScheduleTreeTransform.h"
#include "polly/ScopInfo.h"
#include "polly/ScopPass.h"
#include "polly/Simplify.h"
#include "polly/Support/ISLTools.h"
#include "llvm/ADT/ArrayRef.h"
#include "llvm/ADT/Optional.h"
#include "llvm/ADT/Sequence.h"
#include "llvm/ADT/SmallVector.h"
#include "llvm/ADT/StringRef.h"
#include "llvm/ADT/iterator_range.h"
#include "llvm/Analysis/TargetTransformInfo.h"
#include "llvm/IR/DataLayout.h"
#include "llvm/IR/Function.h"
#include "llvm/IR/Module.h"
#include "llvm/Support/CommandLine.h"
#include "llvm/Support/Debug.h"
#include "llvm/Support/TypeSize.h"
#include "llvm/Support/raw_ostream.h"
#include "isl/ctx.h"
#include "isl/schedule_node.h"
#include "isl/schedule_type.h"
#include "isl/union_map.h"
#include "isl/union_set.h"
#include <algorithm>
#include <cassert>
#include <cmath>
#include <cstdint>
#include <string>
#include <vector>
#define DEBUG_TYPE "polly-opt-isl"
using namespace llvm;
using namespace polly;
namespace llvm {
class Value;
}
static cl::opt<int> LatencyVectorFma(
"polly-target-latency-vector-fma",
cl::desc("The minimal number of cycles between issuing two "
"dependent consecutive vector fused multiply-add "
"instructions."),
cl::Hidden, cl::init(8), cl::ZeroOrMore, cl::cat(PollyCategory));
static cl::opt<int> ThroughputVectorFma(
"polly-target-throughput-vector-fma",
cl::desc("A throughput of the processor floating-point arithmetic units "
"expressed in the number of vector fused multiply-add "
"instructions per clock cycle."),
cl::Hidden, cl::init(1), cl::ZeroOrMore, cl::cat(PollyCategory));
static cl::opt<int> FirstCacheLevelSize(
"polly-target-1st-cache-level-size",
cl::desc("The size of the first cache level specified in bytes."),
cl::Hidden, cl::init(-1), cl::ZeroOrMore, cl::cat(PollyCategory));
static cl::opt<int> FirstCacheLevelDefaultSize(
"polly-target-1st-cache-level-default-size",
cl::desc("The default size of the first cache level specified in bytes"
" (if not enough were provided by the TargetTransformInfo)."),
cl::Hidden, cl::init(32768), cl::ZeroOrMore, cl::cat(PollyCategory));
static cl::opt<int> SecondCacheLevelSize(
"polly-target-2nd-cache-level-size",
cl::desc("The size of the second level specified in bytes."), cl::Hidden,
cl::init(-1), cl::ZeroOrMore, cl::cat(PollyCategory));
static cl::opt<int> SecondCacheLevelDefaultSize(
"polly-target-2nd-cache-level-default-size",
cl::desc("The default size of the second cache level specified in bytes"
" (if not enough were provided by the TargetTransformInfo)."),
cl::Hidden, cl::init(262144), cl::ZeroOrMore, cl::cat(PollyCategory));
// This option, along with --polly-target-2nd-cache-level-associativity,
// --polly-target-1st-cache-level-size, and --polly-target-2st-cache-level-size
// represent the parameters of the target cache, which do not have typical
// values that can be used by default. However, to apply the pattern matching
// optimizations, we use the values of the parameters of Intel Core i7-3820
// SandyBridge in case the parameters are not specified or not provided by the
// TargetTransformInfo.
static cl::opt<int> FirstCacheLevelAssociativity(
"polly-target-1st-cache-level-associativity",
cl::desc("The associativity of the first cache level."), cl::Hidden,
cl::init(-1), cl::ZeroOrMore, cl::cat(PollyCategory));
static cl::opt<int> FirstCacheLevelDefaultAssociativity(
"polly-target-1st-cache-level-default-associativity",
cl::desc("The default associativity of the first cache level"
" (if not enough were provided by the TargetTransformInfo)."),
cl::Hidden, cl::init(8), cl::ZeroOrMore, cl::cat(PollyCategory));
static cl::opt<int> SecondCacheLevelAssociativity(
"polly-target-2nd-cache-level-associativity",
cl::desc("The associativity of the second cache level."), cl::Hidden,
cl::init(-1), cl::ZeroOrMore, cl::cat(PollyCategory));
static cl::opt<int> SecondCacheLevelDefaultAssociativity(
"polly-target-2nd-cache-level-default-associativity",
cl::desc("The default associativity of the second cache level"
" (if not enough were provided by the TargetTransformInfo)."),
cl::Hidden, cl::init(8), cl::ZeroOrMore, cl::cat(PollyCategory));
static cl::opt<int> VectorRegisterBitwidth(
"polly-target-vector-register-bitwidth",
cl::desc("The size in bits of a vector register (if not set, this "
"information is taken from LLVM's target information."),
cl::Hidden, cl::init(-1), cl::ZeroOrMore, cl::cat(PollyCategory));
static cl::opt<int> PollyPatternMatchingNcQuotient(
"polly-pattern-matching-nc-quotient",
cl::desc("Quotient that is obtained by dividing Nc, the parameter of the"
"macro-kernel, by Nr, the parameter of the micro-kernel"),
cl::Hidden, cl::init(256), cl::ZeroOrMore, cl::cat(PollyCategory));
namespace {
/// Parameters of the micro kernel.
///
/// Parameters, which determine sizes of rank-1 (i.e., outer product) update
/// used in the optimized matrix multiplication.
struct MicroKernelParamsTy {
int Mr;
int Nr;
};
/// Parameters of the macro kernel.
///
/// Parameters, which determine sizes of blocks of partitioned matrices
/// used in the optimized matrix multiplication.
struct MacroKernelParamsTy {
int Mc;
int Nc;
int Kc;
};
/// Parameters of the matrix multiplication operands.
///
/// Parameters, which describe access relations that represent operands of the
/// matrix multiplication.
struct MatMulInfoTy {
MemoryAccess *A = nullptr;
MemoryAccess *B = nullptr;
MemoryAccess *ReadFromC = nullptr;
MemoryAccess *WriteToC = nullptr;
int i = -1;
int j = -1;
int k = -1;
};
/// Create an isl::union_set, which describes the option of the form
/// [isolate[] -> unroll[x]].
///
/// @param Ctx An isl::ctx, which is used to create the isl::union_set.
static isl::union_set getUnrollIsolatedSetOptions(isl::ctx Ctx) {
isl::space Space = isl::space(Ctx, 0, 0, 1);
isl::map UnrollIsolatedSetOption = isl::map::universe(Space);
isl::id DimInId = isl::id::alloc(Ctx, "isolate", nullptr);
isl::id DimOutId = isl::id::alloc(Ctx, "unroll", nullptr);
UnrollIsolatedSetOption =
UnrollIsolatedSetOption.set_tuple_id(isl::dim::in, DimInId);
UnrollIsolatedSetOption =
UnrollIsolatedSetOption.set_tuple_id(isl::dim::out, DimOutId);
return UnrollIsolatedSetOption.wrap();
}
/// Permute the two dimensions of the isl map.
///
/// Permute @p DstPos and @p SrcPos dimensions of the isl map @p Map that
/// have type @p DimType.
///
/// @param Map The isl map to be modified.
/// @param DimType The type of the dimensions.
/// @param DstPos The first dimension.
/// @param SrcPos The second dimension.
/// @return The modified map.
static isl::map permuteDimensions(isl::map Map, isl::dim DimType,
unsigned DstPos, unsigned SrcPos) {
assert(DstPos < unsignedFromIslSize(Map.dim(DimType)) &&
SrcPos < unsignedFromIslSize(Map.dim(DimType)));
if (DstPos == SrcPos)
return Map;
isl::id DimId;
if (Map.has_tuple_id(DimType))
DimId = Map.get_tuple_id(DimType);
auto FreeDim = DimType == isl::dim::in ? isl::dim::out : isl::dim::in;
isl::id FreeDimId;
if (Map.has_tuple_id(FreeDim))
FreeDimId = Map.get_tuple_id(FreeDim);
auto MaxDim = std::max(DstPos, SrcPos);
auto MinDim = std::min(DstPos, SrcPos);
Map = Map.move_dims(FreeDim, 0, DimType, MaxDim, 1);
Map = Map.move_dims(FreeDim, 0, DimType, MinDim, 1);
Map = Map.move_dims(DimType, MinDim, FreeDim, 1, 1);
Map = Map.move_dims(DimType, MaxDim, FreeDim, 0, 1);
if (!DimId.is_null())
Map = Map.set_tuple_id(DimType, DimId);
if (!FreeDimId.is_null())
Map = Map.set_tuple_id(FreeDim, FreeDimId);
return Map;
}
/// Check the form of the access relation.
///
/// Check that the access relation @p AccMap has the form M[i][j], where i
/// is a @p FirstPos and j is a @p SecondPos.
///
/// @param AccMap The access relation to be checked.
/// @param FirstPos The index of the input dimension that is mapped to
/// the first output dimension.
/// @param SecondPos The index of the input dimension that is mapped to the
/// second output dimension.
/// @return True in case @p AccMap has the expected form and false,
/// otherwise.
static bool isMatMulOperandAcc(isl::set Domain, isl::map AccMap, int &FirstPos,
int &SecondPos) {
isl::space Space = AccMap.get_space();
isl::map Universe = isl::map::universe(Space);
if (unsignedFromIslSize(Space.dim(isl::dim::out)) != 2)
return false;
// MatMul has the form:
// for (i = 0; i < N; i++)
// for (j = 0; j < M; j++)
// for (k = 0; k < P; k++)
// C[i, j] += A[i, k] * B[k, j]
//
// Permutation of three outer loops: 3! = 6 possibilities.
int FirstDims[] = {0, 0, 1, 1, 2, 2};
int SecondDims[] = {1, 2, 2, 0, 0, 1};
for (int i = 0; i < 6; i += 1) {
auto PossibleMatMul =
Universe.equate(isl::dim::in, FirstDims[i], isl::dim::out, 0)
.equate(isl::dim::in, SecondDims[i], isl::dim::out, 1);
AccMap = AccMap.intersect_domain(Domain);
PossibleMatMul = PossibleMatMul.intersect_domain(Domain);
// If AccMap spans entire domain (Non-partial write),
// compute FirstPos and SecondPos.
// If AccMap != PossibleMatMul here (the two maps have been gisted at
// this point), it means that the writes are not complete, or in other
// words, it is a Partial write and Partial writes must be rejected.
if (AccMap.is_equal(PossibleMatMul)) {
if (FirstPos != -1 && FirstPos != FirstDims[i])
continue;
FirstPos = FirstDims[i];
if (SecondPos != -1 && SecondPos != SecondDims[i])
continue;
SecondPos = SecondDims[i];
return true;
}
}
return false;
}
/// Does the memory access represent a non-scalar operand of the matrix
/// multiplication.
///
/// Check that the memory access @p MemAccess is the read access to a non-scalar
/// operand of the matrix multiplication or its result.
///
/// @param MemAccess The memory access to be checked.
/// @param MMI Parameters of the matrix multiplication operands.
/// @return True in case the memory access represents the read access
/// to a non-scalar operand of the matrix multiplication and
/// false, otherwise.
static bool isMatMulNonScalarReadAccess(MemoryAccess *MemAccess,
MatMulInfoTy &MMI) {
if (!MemAccess->isLatestArrayKind() || !MemAccess->isRead())
return false;
auto AccMap = MemAccess->getLatestAccessRelation();
isl::set StmtDomain = MemAccess->getStatement()->getDomain();
if (isMatMulOperandAcc(StmtDomain, AccMap, MMI.i, MMI.j) && !MMI.ReadFromC) {
MMI.ReadFromC = MemAccess;
return true;
}
if (isMatMulOperandAcc(StmtDomain, AccMap, MMI.i, MMI.k) && !MMI.A) {
MMI.A = MemAccess;
return true;
}
if (isMatMulOperandAcc(StmtDomain, AccMap, MMI.k, MMI.j) && !MMI.B) {
MMI.B = MemAccess;
return true;
}
return false;
}
/// Check accesses to operands of the matrix multiplication.
///
/// Check that accesses of the SCoP statement, which corresponds to
/// the partial schedule @p PartialSchedule, are scalar in terms of loops
/// containing the matrix multiplication, in case they do not represent
/// accesses to the non-scalar operands of the matrix multiplication or
/// its result.
///
/// @param PartialSchedule The partial schedule of the SCoP statement.
/// @param MMI Parameters of the matrix multiplication operands.
/// @return True in case the corresponding SCoP statement
/// represents matrix multiplication and false,
/// otherwise.
static bool containsOnlyMatrMultAcc(isl::map PartialSchedule,
MatMulInfoTy &MMI) {
auto InputDimId = PartialSchedule.get_tuple_id(isl::dim::in);
auto *Stmt = static_cast<ScopStmt *>(InputDimId.get_user());
unsigned OutDimNum = unsignedFromIslSize(PartialSchedule.range_tuple_dim());
assert(OutDimNum > 2 && "In case of the matrix multiplication the loop nest "
"and, consequently, the corresponding scheduling "
"functions have at least three dimensions.");
auto MapI =
permuteDimensions(PartialSchedule, isl::dim::out, MMI.i, OutDimNum - 1);
auto MapJ =
permuteDimensions(PartialSchedule, isl::dim::out, MMI.j, OutDimNum - 1);
auto MapK =
permuteDimensions(PartialSchedule, isl::dim::out, MMI.k, OutDimNum - 1);
auto Accesses = getAccessesInOrder(*Stmt);
for (auto *MemA = Accesses.begin(); MemA != Accesses.end() - 1; MemA++) {
auto *MemAccessPtr = *MemA;
if (MemAccessPtr->isLatestArrayKind() && MemAccessPtr != MMI.WriteToC &&
!isMatMulNonScalarReadAccess(MemAccessPtr, MMI) &&
!(MemAccessPtr->isStrideZero(MapI) &&
MemAccessPtr->isStrideZero(MapJ) && MemAccessPtr->isStrideZero(MapK)))
return false;
}
return true;
}
/// Check for dependencies corresponding to the matrix multiplication.
///
/// Check that there is only true dependence of the form
/// S(..., k, ...) -> S(..., k + 1, …), where S is the SCoP statement
/// represented by @p Schedule and k is @p Pos. Such a dependence corresponds
/// to the dependency produced by the matrix multiplication.
///
/// @param Schedule The schedule of the SCoP statement.
/// @param D The SCoP dependencies.
/// @param Pos The parameter to describe an acceptable true dependence.
/// In case it has a negative value, try to determine its
/// acceptable value.
/// @return True in case dependencies correspond to the matrix multiplication
/// and false, otherwise.
static bool containsOnlyMatMulDep(isl::map Schedule, const Dependences *D,
int &Pos) {
isl::union_map Dep = D->getDependences(Dependences::TYPE_RAW);
isl::union_map Red = D->getDependences(Dependences::TYPE_RED);
if (!Red.is_null())
Dep = Dep.unite(Red);
auto DomainSpace = Schedule.get_space().domain();
auto Space = DomainSpace.map_from_domain_and_range(DomainSpace);
auto Deltas = Dep.extract_map(Space).deltas();
int DeltasDimNum = unsignedFromIslSize(Deltas.dim(isl::dim::set));
for (int i = 0; i < DeltasDimNum; i++) {
auto Val = Deltas.plain_get_val_if_fixed(isl::dim::set, i);
Pos = Pos < 0 && Val.is_one() ? i : Pos;
if (Val.is_nan() || !(Val.is_zero() || (i == Pos && Val.is_one())))
return false;
}
if (DeltasDimNum == 0 || Pos < 0)
return false;
return true;
}
/// Check if the SCoP statement could probably be optimized with analytical
/// modeling.
///
/// containsMatrMult tries to determine whether the following conditions
/// are true:
/// 1. The last memory access modeling an array, MA1, represents writing to
/// memory and has the form S(..., i1, ..., i2, ...) -> M(i1, i2) or
/// S(..., i2, ..., i1, ...) -> M(i1, i2), where S is the SCoP statement
/// under consideration.
/// 2. There is only one loop-carried true dependency, and it has the
/// form S(..., i3, ...) -> S(..., i3 + 1, ...), and there are no
/// loop-carried or anti dependencies.
/// 3. SCoP contains three access relations, MA2, MA3, and MA4 that represent
/// reading from memory and have the form S(..., i3, ...) -> M(i1, i3),
/// S(..., i3, ...) -> M(i3, i2), S(...) -> M(i1, i2), respectively,
/// and all memory accesses of the SCoP that are different from MA1, MA2,
/// MA3, and MA4 have stride 0, if the innermost loop is exchanged with any
/// of loops i1, i2 and i3.
///
/// @param PartialSchedule The PartialSchedule that contains a SCoP statement
/// to check.
/// @D The SCoP dependencies.
/// @MMI Parameters of the matrix multiplication operands.
static bool containsMatrMult(isl::map PartialSchedule, const Dependences *D,
MatMulInfoTy &MMI) {
auto InputDimsId = PartialSchedule.get_tuple_id(isl::dim::in);
auto *Stmt = static_cast<ScopStmt *>(InputDimsId.get_user());
if (Stmt->size() <= 1)
return false;
auto Accesses = getAccessesInOrder(*Stmt);
for (auto *MemA = Accesses.end() - 1; MemA != Accesses.begin(); MemA--) {
auto *MemAccessPtr = *MemA;
if (!MemAccessPtr->isLatestArrayKind())
continue;
if (!MemAccessPtr->isWrite())
return false;
auto AccMap = MemAccessPtr->getLatestAccessRelation();
if (!isMatMulOperandAcc(Stmt->getDomain(), AccMap, MMI.i, MMI.j))
return false;
MMI.WriteToC = MemAccessPtr;
break;
}
if (!containsOnlyMatMulDep(PartialSchedule, D, MMI.k))
return false;
if (!MMI.WriteToC || !containsOnlyMatrMultAcc(PartialSchedule, MMI))
return false;
if (!MMI.A || !MMI.B || !MMI.ReadFromC)
return false;
return true;
}
/// Permute two dimensions of the band node.
///
/// Permute FirstDim and SecondDim dimensions of the Node.
///
/// @param Node The band node to be modified.
/// @param FirstDim The first dimension to be permuted.
/// @param SecondDim The second dimension to be permuted.
static isl::schedule_node permuteBandNodeDimensions(isl::schedule_node Node,
unsigned FirstDim,
unsigned SecondDim) {
assert(isl_schedule_node_get_type(Node.get()) == isl_schedule_node_band &&
(unsigned)isl_schedule_node_band_n_member(Node.get()) >
std::max(FirstDim, SecondDim));
auto PartialSchedule =
isl::manage(isl_schedule_node_band_get_partial_schedule(Node.get()));
auto PartialScheduleFirstDim = PartialSchedule.at(FirstDim);
auto PartialScheduleSecondDim = PartialSchedule.at(SecondDim);
PartialSchedule =
PartialSchedule.set_union_pw_aff(SecondDim, PartialScheduleFirstDim);
PartialSchedule =
PartialSchedule.set_union_pw_aff(FirstDim, PartialScheduleSecondDim);
Node = isl::manage(isl_schedule_node_delete(Node.release()));
return Node.insert_partial_schedule(PartialSchedule);
}
static isl::schedule_node
createMicroKernel(isl::schedule_node Node,
MicroKernelParamsTy MicroKernelParams) {
Node = applyRegisterTiling(Node, {MicroKernelParams.Mr, MicroKernelParams.Nr},
1);
Node = Node.parent().parent();
return permuteBandNodeDimensions(Node, 0, 1).child(0).child(0);
}
/// Create the BLIS macro-kernel.
///
/// We create the BLIS macro-kernel by applying a combination of tiling
/// of dimensions of the band node and interchanging of two innermost
/// modified dimensions. The values of of MacroKernelParams's fields are used
/// as tile sizes.
///
/// @param Node The schedule node to be modified.
/// @param MacroKernelParams Parameters of the macro kernel
/// to be used as tile sizes.
static isl::schedule_node
createMacroKernel(isl::schedule_node Node,
MacroKernelParamsTy MacroKernelParams) {
assert(isl_schedule_node_get_type(Node.get()) == isl_schedule_node_band);
if (MacroKernelParams.Mc == 1 && MacroKernelParams.Nc == 1 &&
MacroKernelParams.Kc == 1)
return Node;
int DimOutNum = isl_schedule_node_band_n_member(Node.get());
std::vector<int> TileSizes(DimOutNum, 1);
TileSizes[DimOutNum - 3] = MacroKernelParams.Mc;
TileSizes[DimOutNum - 2] = MacroKernelParams.Nc;
TileSizes[DimOutNum - 1] = MacroKernelParams.Kc;
Node = tileNode(Node, "1st level tiling", TileSizes, 1);
Node = Node.parent().parent();
Node = permuteBandNodeDimensions(Node, DimOutNum - 2, DimOutNum - 1);
Node = permuteBandNodeDimensions(Node, DimOutNum - 3, DimOutNum - 1);
// Mark the outermost loop as parallelizable.
Node = Node.as<isl::schedule_node_band>().member_set_coincident(0, true);
return Node.child(0).child(0);
}
/// Get the size of the widest type of the matrix multiplication operands
/// in bytes, including alignment padding.
///
/// @param MMI Parameters of the matrix multiplication operands.
/// @return The size of the widest type of the matrix multiplication operands
/// in bytes, including alignment padding.
static uint64_t getMatMulAlignTypeSize(MatMulInfoTy MMI) {
auto *S = MMI.A->getStatement()->getParent();
auto &DL = S->getFunction().getParent()->getDataLayout();
auto ElementSizeA = DL.getTypeAllocSize(MMI.A->getElementType());
auto ElementSizeB = DL.getTypeAllocSize(MMI.B->getElementType());
auto ElementSizeC = DL.getTypeAllocSize(MMI.WriteToC->getElementType());
return std::max({ElementSizeA, ElementSizeB, ElementSizeC});
}
/// Get the size of the widest type of the matrix multiplication operands
/// in bits.
///
/// @param MMI Parameters of the matrix multiplication operands.
/// @return The size of the widest type of the matrix multiplication operands
/// in bits.
static uint64_t getMatMulTypeSize(MatMulInfoTy MMI) {
auto *S = MMI.A->getStatement()->getParent();
auto &DL = S->getFunction().getParent()->getDataLayout();
auto ElementSizeA = DL.getTypeSizeInBits(MMI.A->getElementType());
auto ElementSizeB = DL.getTypeSizeInBits(MMI.B->getElementType());
auto ElementSizeC = DL.getTypeSizeInBits(MMI.WriteToC->getElementType());
return std::max({ElementSizeA, ElementSizeB, ElementSizeC});
}
/// Get parameters of the BLIS micro kernel.
///
/// We choose the Mr and Nr parameters of the micro kernel to be large enough
/// such that no stalls caused by the combination of latencies and dependencies
/// are introduced during the updates of the resulting matrix of the matrix
/// multiplication. However, they should also be as small as possible to
/// release more registers for entries of multiplied matrices.
///
/// @param TTI Target Transform Info.
/// @param MMI Parameters of the matrix multiplication operands.
/// @return The structure of type MicroKernelParamsTy.
/// @see MicroKernelParamsTy
static struct MicroKernelParamsTy
getMicroKernelParams(const TargetTransformInfo *TTI, MatMulInfoTy MMI) {
assert(TTI && "The target transform info should be provided.");
// Nvec - Number of double-precision floating-point numbers that can be hold
// by a vector register. Use 2 by default.
long RegisterBitwidth = VectorRegisterBitwidth;
if (RegisterBitwidth == -1)
RegisterBitwidth =
TTI->getRegisterBitWidth(TargetTransformInfo::RGK_FixedWidthVector);
auto ElementSize = getMatMulTypeSize(MMI);
assert(ElementSize > 0 && "The element size of the matrix multiplication "
"operands should be greater than zero.");
auto Nvec = RegisterBitwidth / ElementSize;
if (Nvec == 0)
Nvec = 2;
int Nr = ceil(sqrt((double)(Nvec * LatencyVectorFma * ThroughputVectorFma)) /
Nvec) *
Nvec;
int Mr = ceil((double)(Nvec * LatencyVectorFma * ThroughputVectorFma / Nr));
return {Mr, Nr};
}
/// Determine parameters of the target cache.
///
/// @param TTI Target Transform Info.
static void getTargetCacheParameters(const llvm::TargetTransformInfo *TTI) {
auto L1DCache = llvm::TargetTransformInfo::CacheLevel::L1D;
auto L2DCache = llvm::TargetTransformInfo::CacheLevel::L2D;
if (FirstCacheLevelSize == -1) {
if (TTI->getCacheSize(L1DCache).hasValue())
FirstCacheLevelSize = TTI->getCacheSize(L1DCache).getValue();
else
FirstCacheLevelSize = static_cast<int>(FirstCacheLevelDefaultSize);
}
if (SecondCacheLevelSize == -1) {
if (TTI->getCacheSize(L2DCache).hasValue())
SecondCacheLevelSize = TTI->getCacheSize(L2DCache).getValue();
else
SecondCacheLevelSize = static_cast<int>(SecondCacheLevelDefaultSize);
}
if (FirstCacheLevelAssociativity == -1) {
if (TTI->getCacheAssociativity(L1DCache).hasValue())
FirstCacheLevelAssociativity =
TTI->getCacheAssociativity(L1DCache).getValue();
else
FirstCacheLevelAssociativity =
static_cast<int>(FirstCacheLevelDefaultAssociativity);
}
if (SecondCacheLevelAssociativity == -1) {
if (TTI->getCacheAssociativity(L2DCache).hasValue())
SecondCacheLevelAssociativity =
TTI->getCacheAssociativity(L2DCache).getValue();
else
SecondCacheLevelAssociativity =
static_cast<int>(SecondCacheLevelDefaultAssociativity);
}
}
/// Get parameters of the BLIS macro kernel.
///
/// During the computation of matrix multiplication, blocks of partitioned
/// matrices are mapped to different layers of the memory hierarchy.
/// To optimize data reuse, blocks should be ideally kept in cache between
/// iterations. Since parameters of the macro kernel determine sizes of these
/// blocks, there are upper and lower bounds on these parameters.
///
/// @param TTI Target Transform Info.
/// @param MicroKernelParams Parameters of the micro-kernel
/// to be taken into account.
/// @param MMI Parameters of the matrix multiplication operands.
/// @return The structure of type MacroKernelParamsTy.
/// @see MacroKernelParamsTy
/// @see MicroKernelParamsTy
static struct MacroKernelParamsTy
getMacroKernelParams(const llvm::TargetTransformInfo *TTI,
const MicroKernelParamsTy &MicroKernelParams,
MatMulInfoTy MMI) {
getTargetCacheParameters(TTI);
// According to www.cs.utexas.edu/users/flame/pubs/TOMS-BLIS-Analytical.pdf,
// it requires information about the first two levels of a cache to determine
// all the parameters of a macro-kernel. It also checks that an associativity
// degree of a cache level is greater than two. Otherwise, another algorithm
// for determination of the parameters should be used.
if (!(MicroKernelParams.Mr > 0 && MicroKernelParams.Nr > 0 &&
FirstCacheLevelSize > 0 && SecondCacheLevelSize > 0 &&
FirstCacheLevelAssociativity > 2 && SecondCacheLevelAssociativity > 2))
return {1, 1, 1};
// The quotient should be greater than zero.
if (PollyPatternMatchingNcQuotient <= 0)
return {1, 1, 1};
int Car = floor(
(FirstCacheLevelAssociativity - 1) /
(1 + static_cast<double>(MicroKernelParams.Nr) / MicroKernelParams.Mr));
// Car can be computed to be zero since it is floor to int.
// On Mac OS, division by 0 does not raise a signal. This causes negative
// tile sizes to be computed. Prevent division by Cac==0 by early returning
// if this happens.
if (Car == 0)
return {1, 1, 1};
auto ElementSize = getMatMulAlignTypeSize(MMI);
assert(ElementSize > 0 && "The element size of the matrix multiplication "
"operands should be greater than zero.");
int Kc = (Car * FirstCacheLevelSize) /
(MicroKernelParams.Mr * FirstCacheLevelAssociativity * ElementSize);
double Cac =
static_cast<double>(Kc * ElementSize * SecondCacheLevelAssociativity) /
SecondCacheLevelSize;
int Mc = floor((SecondCacheLevelAssociativity - 2) / Cac);
int Nc = PollyPatternMatchingNcQuotient * MicroKernelParams.Nr;
assert(Mc > 0 && Nc > 0 && Kc > 0 &&
"Matrix block sizes should be greater than zero");
return {Mc, Nc, Kc};
}
/// Create an access relation that is specific to
/// the matrix multiplication pattern.
///
/// Create an access relation of the following form:
/// [O0, O1, O2, O3, O4, O5, O6, O7, O8] -> [OI, O5, OJ]
/// where I is @p FirstDim, J is @p SecondDim.
///
/// It can be used, for example, to create relations that helps to consequently
/// access elements of operands of a matrix multiplication after creation of
/// the BLIS micro and macro kernels.
///
/// @see ScheduleTreeOptimizer::createMicroKernel
/// @see ScheduleTreeOptimizer::createMacroKernel
///
/// Subsequently, the described access relation is applied to the range of
/// @p MapOldIndVar, that is used to map original induction variables to
/// the ones, which are produced by schedule transformations. It helps to
/// define relations using a new space and, at the same time, keep them
/// in the original one.
///
/// @param MapOldIndVar The relation, which maps original induction variables
/// to the ones, which are produced by schedule
/// transformations.
/// @param FirstDim, SecondDim The input dimensions that are used to define
/// the specified access relation.
/// @return The specified access relation.
static isl::map getMatMulAccRel(isl::map MapOldIndVar, unsigned FirstDim,
unsigned SecondDim) {
auto AccessRelSpace = isl::space(MapOldIndVar.ctx(), 0, 9, 3);
auto AccessRel = isl::map::universe(AccessRelSpace);
AccessRel = AccessRel.equate(isl::dim::in, FirstDim, isl::dim::out, 0);
AccessRel = AccessRel.equate(isl::dim::in, 5, isl::dim::out, 1);
AccessRel = AccessRel.equate(isl::dim::in, SecondDim, isl::dim::out, 2);
return MapOldIndVar.apply_range(AccessRel);
}
static isl::schedule_node createExtensionNode(isl::schedule_node Node,
isl::map ExtensionMap) {
auto Extension = isl::union_map(ExtensionMap);
auto NewNode = isl::schedule_node::from_extension(Extension);
return Node.graft_before(NewNode);
}
static isl::schedule_node optimizePackedB(isl::schedule_node Node,
ScopStmt *Stmt, isl::map MapOldIndVar,
MicroKernelParamsTy MicroParams,
MacroKernelParamsTy MacroParams,
MatMulInfoTy &MMI) {
Scop *S = Stmt->getParent();
isl::set Domain = Stmt->getDomain();
// Create packed array.
unsigned FirstDimSize = MacroParams.Nc / MicroParams.Nr;
unsigned SecondDimSize = MacroParams.Kc;
unsigned ThirdDimSize = MicroParams.Nr;
ScopArrayInfo *PackedB =
S->createScopArrayInfo(MMI.B->getElementType(), "Packed_B",
{FirstDimSize, SecondDimSize, ThirdDimSize});
// Compute the access relation for copying from B to PackedB.
isl::map AccRelB = MMI.B->getLatestAccessRelation();
isl::map AccRelPackedB = getMatMulAccRel(MapOldIndVar, 3, 7);
AccRelPackedB =
AccRelPackedB.set_tuple_id(isl::dim::out, PackedB->getBasePtrId());
// Create the copy statement and redirect access.
ScopStmt *CopyStmt = S->addScopStmt(AccRelB, AccRelPackedB, Domain);
MMI.B->setNewAccessRelation(AccRelPackedB);
unsigned Dim = unsignedFromIslSize(MapOldIndVar.range_tuple_dim());
assert(Dim >= 2);
// Insert into the schedule tree.
isl::map ExtMap = MapOldIndVar.project_out(isl::dim::out, 2, Dim - 2);
ExtMap = ExtMap.reverse();
ExtMap = ExtMap.fix_si(isl::dim::out, MMI.i, 0);
ExtMap = ExtMap.intersect_range(Domain);
ExtMap = ExtMap.set_tuple_id(isl::dim::out, CopyStmt->getDomainId());
return createExtensionNode(Node, ExtMap);
}
static isl::schedule_node optimizePackedA(isl::schedule_node Node, ScopStmt *,
isl::map MapOldIndVar,
MicroKernelParamsTy MicroParams,
MacroKernelParamsTy MacroParams,
MatMulInfoTy &MMI) {
isl::id InputDimsId = MapOldIndVar.get_tuple_id(isl::dim::in);
ScopStmt *Stmt = static_cast<ScopStmt *>(InputDimsId.get_user());
isl::set Domain = Stmt->getDomain();
isl::id DomainId = Domain.get_tuple_id();
// Create the packed array.
unsigned FirstDimSize = MacroParams.Mc / MicroParams.Mr;
unsigned SecondDimSize = MacroParams.Kc;
unsigned ThirdDimSize = MicroParams.Mr;
ScopArrayInfo *PackedA = Stmt->getParent()->createScopArrayInfo(
MMI.A->getElementType(), "Packed_A",
{FirstDimSize, SecondDimSize, ThirdDimSize});
// Compute the access relation for copying from A to PackedA.
isl::map AccRelA = MMI.A->getLatestAccessRelation();
isl::map AccRelPackedA = getMatMulAccRel(MapOldIndVar, 4, 6);
AccRelPackedA =
AccRelPackedA.set_tuple_id(isl::dim::out, PackedA->getBasePtrId());
// { MemrefA[] -> PackedA[] }
isl::map PackedATranslator = AccRelPackedA.apply_domain(AccRelA);
// Compute the domain for the copy statement.
// Construct the copy statement domain out of the 3 outermost scatter
// dimensions (to match the 3 band nodes surrounding the extension node) and
// the array elements to copy (one statement instance per array element).
// { Scatter[] }
isl::set ScatterDomain = MapOldIndVar.intersect_domain(Domain).range();
// { Scatter[] -> OutermostScatter[] }
isl::map OuterDomainMap =
makeIdentityMap(ScatterDomain, true).project_out(isl::dim::out, 3, 6);
// { Scatter[] -> MemrefA[] }
isl::map CopyFrom = MapOldIndVar.reverse().apply_range(AccRelA);
// { Scatter[] -> CopyStmt[] }
isl::map DomainTranslator = OuterDomainMap.range_product(CopyFrom);
// { CopyStmt[] }
isl::set CopyDomain = DomainTranslator.range();
// Translate the access relations to the new domain.
// { CopyStmt[] -> MemrefA[] }
CopyFrom = CopyFrom.apply_domain(DomainTranslator);
// { CopyStmt[] -> PackedA[] }
isl::map CopyTo = CopyFrom.apply_range(PackedATranslator);
// Create the copy statement and redirect access.
ScopStmt *CopyStmt =
Stmt->getParent()->addScopStmt(CopyFrom, CopyTo, CopyDomain);
MMI.A->setNewAccessRelation(AccRelPackedA);
// Insert into the schedule tree.
// { Scatter[] -> CopyStmt[] }
isl::map ExtScatterCopy = makeIdentityMap(CopyStmt->getDomain(), true);
ExtScatterCopy = ExtScatterCopy.project_out(isl::dim::in, 3, 2);
return createExtensionNode(Node, ExtScatterCopy);
}
/// Apply the packing transformation.
///
/// The packing transformation can be described as a data-layout
/// transformation that requires to introduce a new array, copy data
/// to the array, and change memory access locations to reference the array.
/// It can be used to ensure that elements of the new array are read in-stride
/// access, aligned to cache lines boundaries, and preloaded into certain cache
/// levels.
///
/// As an example let us consider the packing of the array A that would help
/// to read its elements with in-stride access. An access to the array A
/// is represented by an access relation that has the form
/// S[i, j, k] -> A[i, k]. The scheduling function of the SCoP statement S has
/// the form S[i,j, k] -> [floor((j mod Nc) / Nr), floor((i mod Mc) / Mr),
/// k mod Kc, j mod Nr, i mod Mr].
///
/// To ensure that elements of the array A are read in-stride access, we add
/// a new array Packed_A[Mc/Mr][Kc][Mr] to the SCoP, using
/// Scop::createScopArrayInfo, change the access relation
/// S[i, j, k] -> A[i, k] to
/// S[i, j, k] -> Packed_A[floor((i mod Mc) / Mr), k mod Kc, i mod Mr], using
/// MemoryAccess::setNewAccessRelation, and copy the data to the array, using
/// the copy statement created by Scop::addScopStmt.
///
/// @param Node The schedule node to be optimized.
/// @param MapOldIndVar The relation, which maps original induction variables
/// to the ones, which are produced by schedule
/// transformations.
/// @param MicroParams, MacroParams Parameters of the BLIS kernel
/// to be taken into account.
/// @param MMI Parameters of the matrix multiplication operands.
/// @return The optimized schedule node.
static isl::schedule_node
optimizeDataLayoutMatrMulPattern(isl::schedule_node Node, isl::map MapOldIndVar,
MicroKernelParamsTy MicroParams,
MacroKernelParamsTy MacroParams,
MatMulInfoTy &MMI) {
isl::id InputDimsId = MapOldIndVar.get_tuple_id(isl::dim::in);
ScopStmt *Stmt = static_cast<ScopStmt *>(InputDimsId.get_user());
Node = Node.parent().parent().parent().parent().parent().parent();
Node = isl::manage(isl_schedule_node_band_split(Node.release(), 2));
Node = Node.child(0);
Node =
optimizePackedB(Node, Stmt, MapOldIndVar, MicroParams, MacroParams, MMI);
Node = Node.child(0);
Node =
optimizePackedA(Node, Stmt, MapOldIndVar, MicroParams, MacroParams, MMI);
return Node.child(0).child(0).child(0).child(0).child(0);
}
/// Get a relation mapping induction variables produced by schedule
/// transformations to the original ones.
///
/// @param Node The schedule node produced as the result of creation
/// of the BLIS kernels.
/// @param MicroKernelParams, MacroKernelParams Parameters of the BLIS kernel
/// to be taken into account.
/// @return The relation mapping original induction variables to the ones
/// produced by schedule transformation.
/// @see ScheduleTreeOptimizer::createMicroKernel
/// @see ScheduleTreeOptimizer::createMacroKernel
/// @see getMacroKernelParams
static isl::map
getInductionVariablesSubstitution(isl::schedule_node Node,
MicroKernelParamsTy MicroKernelParams,
MacroKernelParamsTy MacroKernelParams) {
auto Child = Node.child(0);
auto UnMapOldIndVar = Child.get_prefix_schedule_union_map();
auto MapOldIndVar = isl::map::from_union_map(UnMapOldIndVar);
unsigned Dim = unsignedFromIslSize(MapOldIndVar.range_tuple_dim());
if (Dim > 9u)
return MapOldIndVar.project_out(isl::dim::out, 0, Dim - 9);
return MapOldIndVar;
}
/// Isolate a set of partial tile prefixes and unroll the isolated part.
///
/// The set should ensure that it contains only partial tile prefixes that have
/// exactly Mr x Nr iterations of the two innermost loops produced by
/// the optimization of the matrix multiplication. Mr and Nr are parameters of
/// the micro-kernel.
///
/// In case of parametric bounds, this helps to auto-vectorize the unrolled
/// innermost loops, using the SLP vectorizer.
///
/// @param Node The schedule node to be modified.
/// @param MicroKernelParams Parameters of the micro-kernel
/// to be taken into account.
/// @return The modified isl_schedule_node.
static isl::schedule_node
isolateAndUnrollMatMulInnerLoops(isl::schedule_node Node,
struct MicroKernelParamsTy MicroKernelParams) {
isl::schedule_node Child = Node.child(0);
isl::union_map UnMapOldIndVar = Child.get_prefix_schedule_relation();
isl::set Prefix = isl::map::from_union_map(UnMapOldIndVar).range();
unsigned Dims = unsignedFromIslSize(Prefix.tuple_dim());
assert(Dims >= 1);
Prefix = Prefix.project_out(isl::dim::set, Dims - 1, 1);
Prefix = getPartialTilePrefixes(Prefix, MicroKernelParams.Nr);
Prefix = getPartialTilePrefixes(Prefix, MicroKernelParams.Mr);
isl::union_set IsolateOption =
getIsolateOptions(Prefix.add_dims(isl::dim::set, 3), 3);
isl::ctx Ctx = Node.ctx();
auto Options = IsolateOption.unite(getDimOptions(Ctx, "unroll"));
Options = Options.unite(getUnrollIsolatedSetOptions(Ctx));
Node = Node.as<isl::schedule_node_band>().set_ast_build_options(Options);
Node = Node.parent().parent().parent();
IsolateOption = getIsolateOptions(Prefix, 3);
Options = IsolateOption.unite(getDimOptions(Ctx, "separate"));
Node = Node.as<isl::schedule_node_band>().set_ast_build_options(Options);
Node = Node.child(0).child(0).child(0);
return Node;
}
/// Insert "Loop Vectorizer Disabled" mark node.
///
/// @param Node The child of the mark node to be inserted.
/// @return The modified isl_schedule_node.
static isl::schedule_node markLoopVectorizerDisabled(isl::schedule_node Node) {
auto Id = isl::id::alloc(Node.ctx(), "Loop Vectorizer Disabled", nullptr);
return Node.insert_mark(Id).child(0);
}
/// Restore the initial ordering of dimensions of the band node
///
/// In case the band node represents all the dimensions of the iteration
/// domain, recreate the band node to restore the initial ordering of the
/// dimensions.
///
/// @param Node The band node to be modified.
/// @return The modified schedule node.
static isl::schedule_node
getBandNodeWithOriginDimOrder(isl::schedule_node Node) {
assert(isl_schedule_node_get_type(Node.get()) == isl_schedule_node_band);
if (isl_schedule_node_get_type(Node.child(0).get()) != isl_schedule_node_leaf)
return Node;
auto Domain = Node.get_universe_domain();
assert(isl_union_set_n_set(Domain.get()) == 1);
if (Node.get_schedule_depth().release() != 0 ||
(unsignedFromIslSize(isl::set(Domain).tuple_dim()) !=
unsignedFromIslSize(Node.as<isl::schedule_node_band>().n_member())))
return Node;
Node = isl::manage(isl_schedule_node_delete(Node.copy()));
auto PartialSchedulePwAff = Domain.identity_union_pw_multi_aff();
auto PartialScheduleMultiPwAff =
isl::multi_union_pw_aff(PartialSchedulePwAff);
PartialScheduleMultiPwAff =
PartialScheduleMultiPwAff.reset_tuple_id(isl::dim::set);
return Node.insert_partial_schedule(PartialScheduleMultiPwAff);
}
static isl::schedule_node optimizeMatMulPattern(isl::schedule_node Node,
const TargetTransformInfo *TTI,
MatMulInfoTy &MMI) {
assert(TTI && "The target transform info should be provided.");
int DimOutNum = isl_schedule_node_band_n_member(Node.get());
assert(DimOutNum > 2 && "In case of the matrix multiplication the loop nest "
"and, consequently, the corresponding scheduling "
"functions have at least three dimensions.");
Node = getBandNodeWithOriginDimOrder(Node);
Node = permuteBandNodeDimensions(Node, MMI.i, DimOutNum - 3);
int NewJ = MMI.j == DimOutNum - 3 ? MMI.i : MMI.j;
int NewK = MMI.k == DimOutNum - 3 ? MMI.i : MMI.k;
Node = permuteBandNodeDimensions(Node, NewJ, DimOutNum - 2);
NewK = NewK == DimOutNum - 2 ? NewJ : NewK;
Node = permuteBandNodeDimensions(Node, NewK, DimOutNum - 1);
auto MicroKernelParams = getMicroKernelParams(TTI, MMI);
auto MacroKernelParams = getMacroKernelParams(TTI, MicroKernelParams, MMI);
Node = createMacroKernel(Node, MacroKernelParams);
Node = createMicroKernel(Node, MicroKernelParams);
if (MacroKernelParams.Mc == 1 || MacroKernelParams.Nc == 1 ||
MacroKernelParams.Kc == 1)
return Node;
auto MapOldIndVar = getInductionVariablesSubstitution(Node, MicroKernelParams,
MacroKernelParams);
if (MapOldIndVar.is_null())
return Node;
Node = markLoopVectorizerDisabled(Node.parent()).child(0);
Node = isolateAndUnrollMatMulInnerLoops(Node, MicroKernelParams);
return optimizeDataLayoutMatrMulPattern(Node, MapOldIndVar, MicroKernelParams,
MacroKernelParams, MMI);
}
/// Check if this node contains a partial schedule that could
/// probably be optimized with analytical modeling.
///
/// isMatrMultPattern tries to determine whether the following conditions
/// are true:
/// 1. the partial schedule contains only one statement.
/// 2. there are exactly three input dimensions.
/// 3. all memory accesses of the statement will have stride 0 or 1, if we
/// interchange loops (switch the variable used in the inner loop to
/// the outer loop).
/// 4. all memory accesses of the statement except from the last one, are
/// read memory access and the last one is write memory access.
/// 5. all subscripts of the last memory access of the statement don't
/// contain the variable used in the inner loop.
/// If this is the case, we could try to use an approach that is similar to
/// the one used to get close-to-peak performance of matrix multiplications.
///
/// @param Node The node to check.
/// @param D The SCoP dependencies.
/// @param MMI Parameters of the matrix multiplication operands.
static bool isMatrMultPattern(isl::schedule_node Node, const Dependences *D,
MatMulInfoTy &MMI) {
auto PartialSchedule = isl::manage(
isl_schedule_node_band_get_partial_schedule_union_map(Node.get()));
Node = Node.child(0);
auto LeafType = isl_schedule_node_get_type(Node.get());
Node = Node.parent();
if (LeafType != isl_schedule_node_leaf ||
isl_schedule_node_band_n_member(Node.get()) < 3 ||
Node.get_schedule_depth().release() != 0 ||
isl_union_map_n_map(PartialSchedule.get()) != 1)
return false;
auto NewPartialSchedule = isl::map::from_union_map(PartialSchedule);
if (containsMatrMult(NewPartialSchedule, D, MMI))
return true;
return false;
}
} // namespace
isl::schedule_node
polly::tryOptimizeMatMulPattern(isl::schedule_node Node,
const llvm::TargetTransformInfo *TTI,
const Dependences *D) {
MatMulInfoTy MMI;
if (isMatrMultPattern(Node, D, MMI)) {
LLVM_DEBUG(dbgs() << "The matrix multiplication pattern was detected\n");
return optimizeMatMulPattern(Node, TTI, MMI);
}
return {};
}