llvm-project/llvm/unittests/IR/PatternMatch.cpp

565 lines
21 KiB
C++

//===---- llvm/unittest/IR/PatternMatch.cpp - PatternMatch unit tests ----===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
#include "llvm/IR/PatternMatch.h"
#include "llvm/ADT/STLExtras.h"
#include "llvm/Analysis/ValueTracking.h"
#include "llvm/IR/BasicBlock.h"
#include "llvm/IR/Constants.h"
#include "llvm/IR/DataLayout.h"
#include "llvm/IR/DerivedTypes.h"
#include "llvm/IR/Function.h"
#include "llvm/IR/IRBuilder.h"
#include "llvm/IR/Instructions.h"
#include "llvm/IR/LLVMContext.h"
#include "llvm/IR/MDBuilder.h"
#include "llvm/IR/Module.h"
#include "llvm/IR/NoFolder.h"
#include "llvm/IR/Operator.h"
#include "llvm/IR/Type.h"
#include "gtest/gtest.h"
using namespace llvm;
using namespace llvm::PatternMatch;
namespace {
struct PatternMatchTest : ::testing::Test {
LLVMContext Ctx;
std::unique_ptr<Module> M;
Function *F;
BasicBlock *BB;
IRBuilder<NoFolder> IRB;
PatternMatchTest()
: M(new Module("PatternMatchTestModule", Ctx)),
F(Function::Create(
FunctionType::get(Type::getVoidTy(Ctx), /* IsVarArg */ false),
Function::ExternalLinkage, "f", M.get())),
BB(BasicBlock::Create(Ctx, "entry", F)), IRB(BB) {}
};
TEST_F(PatternMatchTest, OneUse) {
// Build up a little tree of values:
//
// One = (1 + 2) + 42
// Two = One + 42
// Leaf = (Two + 8) + (Two + 13)
Value *One = IRB.CreateAdd(IRB.CreateAdd(IRB.getInt32(1), IRB.getInt32(2)),
IRB.getInt32(42));
Value *Two = IRB.CreateAdd(One, IRB.getInt32(42));
Value *Leaf = IRB.CreateAdd(IRB.CreateAdd(Two, IRB.getInt32(8)),
IRB.CreateAdd(Two, IRB.getInt32(13)));
Value *V;
EXPECT_TRUE(m_OneUse(m_Value(V)).match(One));
EXPECT_EQ(One, V);
EXPECT_FALSE(m_OneUse(m_Value()).match(Two));
EXPECT_FALSE(m_OneUse(m_Value()).match(Leaf));
}
TEST_F(PatternMatchTest, CommutativeDeferredValue) {
Value *X = IRB.getInt32(1);
Value *Y = IRB.getInt32(2);
{
Value *tX = X;
EXPECT_TRUE(match(X, m_Deferred(tX)));
EXPECT_FALSE(match(Y, m_Deferred(tX)));
}
{
const Value *tX = X;
EXPECT_TRUE(match(X, m_Deferred(tX)));
EXPECT_FALSE(match(Y, m_Deferred(tX)));
}
{
Value *const tX = X;
EXPECT_TRUE(match(X, m_Deferred(tX)));
EXPECT_FALSE(match(Y, m_Deferred(tX)));
}
{
const Value *const tX = X;
EXPECT_TRUE(match(X, m_Deferred(tX)));
EXPECT_FALSE(match(Y, m_Deferred(tX)));
}
{
Value *tX = nullptr;
EXPECT_TRUE(match(IRB.CreateAnd(X, X), m_And(m_Value(tX), m_Deferred(tX))));
EXPECT_EQ(tX, X);
}
{
Value *tX = nullptr;
EXPECT_FALSE(
match(IRB.CreateAnd(X, Y), m_c_And(m_Value(tX), m_Deferred(tX))));
}
auto checkMatch = [X, Y](Value *Pattern) {
Value *tX = nullptr, *tY = nullptr;
EXPECT_TRUE(match(
Pattern, m_c_And(m_Value(tX), m_c_And(m_Deferred(tX), m_Value(tY)))));
EXPECT_EQ(tX, X);
EXPECT_EQ(tY, Y);
};
checkMatch(IRB.CreateAnd(X, IRB.CreateAnd(X, Y)));
checkMatch(IRB.CreateAnd(X, IRB.CreateAnd(Y, X)));
checkMatch(IRB.CreateAnd(IRB.CreateAnd(X, Y), X));
checkMatch(IRB.CreateAnd(IRB.CreateAnd(Y, X), X));
}
TEST_F(PatternMatchTest, FloatingPointOrderedMin) {
Type *FltTy = IRB.getFloatTy();
Value *L = ConstantFP::get(FltTy, 1.0);
Value *R = ConstantFP::get(FltTy, 2.0);
Value *MatchL, *MatchR;
// Test OLT.
EXPECT_TRUE(m_OrdFMin(m_Value(MatchL), m_Value(MatchR))
.match(IRB.CreateSelect(IRB.CreateFCmpOLT(L, R), L, R)));
EXPECT_EQ(L, MatchL);
EXPECT_EQ(R, MatchR);
// Test OLE.
EXPECT_TRUE(m_OrdFMin(m_Value(MatchL), m_Value(MatchR))
.match(IRB.CreateSelect(IRB.CreateFCmpOLE(L, R), L, R)));
EXPECT_EQ(L, MatchL);
EXPECT_EQ(R, MatchR);
// Test no match on OGE.
EXPECT_FALSE(m_OrdFMin(m_Value(MatchL), m_Value(MatchR))
.match(IRB.CreateSelect(IRB.CreateFCmpOGE(L, R), L, R)));
// Test no match on OGT.
EXPECT_FALSE(m_OrdFMin(m_Value(MatchL), m_Value(MatchR))
.match(IRB.CreateSelect(IRB.CreateFCmpOGT(L, R), L, R)));
// Test inverted selects. Note, that this "inverts" the ordering, e.g.:
// %cmp = fcmp oge L, R
// %min = select %cmp R, L
// Given L == NaN
// the above is expanded to %cmp == false ==> %min = L
// which is true for UnordFMin, not OrdFMin, so test that:
// [OU]GE with inverted select.
EXPECT_FALSE(m_OrdFMin(m_Value(MatchL), m_Value(MatchR))
.match(IRB.CreateSelect(IRB.CreateFCmpOGE(L, R), R, L)));
EXPECT_TRUE(m_OrdFMin(m_Value(MatchL), m_Value(MatchR))
.match(IRB.CreateSelect(IRB.CreateFCmpUGE(L, R), R, L)));
EXPECT_EQ(L, MatchL);
EXPECT_EQ(R, MatchR);
// [OU]GT with inverted select.
EXPECT_FALSE(m_OrdFMin(m_Value(MatchL), m_Value(MatchR))
.match(IRB.CreateSelect(IRB.CreateFCmpOGT(L, R), R, L)));
EXPECT_TRUE(m_OrdFMin(m_Value(MatchL), m_Value(MatchR))
.match(IRB.CreateSelect(IRB.CreateFCmpUGT(L, R), R, L)));
EXPECT_EQ(L, MatchL);
EXPECT_EQ(R, MatchR);
}
TEST_F(PatternMatchTest, FloatingPointOrderedMax) {
Type *FltTy = IRB.getFloatTy();
Value *L = ConstantFP::get(FltTy, 1.0);
Value *R = ConstantFP::get(FltTy, 2.0);
Value *MatchL, *MatchR;
// Test OGT.
EXPECT_TRUE(m_OrdFMax(m_Value(MatchL), m_Value(MatchR))
.match(IRB.CreateSelect(IRB.CreateFCmpOGT(L, R), L, R)));
EXPECT_EQ(L, MatchL);
EXPECT_EQ(R, MatchR);
// Test OGE.
EXPECT_TRUE(m_OrdFMax(m_Value(MatchL), m_Value(MatchR))
.match(IRB.CreateSelect(IRB.CreateFCmpOGE(L, R), L, R)));
EXPECT_EQ(L, MatchL);
EXPECT_EQ(R, MatchR);
// Test no match on OLE.
EXPECT_FALSE(m_OrdFMax(m_Value(MatchL), m_Value(MatchR))
.match(IRB.CreateSelect(IRB.CreateFCmpOLE(L, R), L, R)));
// Test no match on OLT.
EXPECT_FALSE(m_OrdFMax(m_Value(MatchL), m_Value(MatchR))
.match(IRB.CreateSelect(IRB.CreateFCmpOLT(L, R), L, R)));
// Test inverted selects. Note, that this "inverts" the ordering, e.g.:
// %cmp = fcmp ole L, R
// %max = select %cmp, R, L
// Given L == NaN,
// the above is expanded to %cmp == false ==> %max == L
// which is true for UnordFMax, not OrdFMax, so test that:
// [OU]LE with inverted select.
EXPECT_FALSE(m_OrdFMax(m_Value(MatchL), m_Value(MatchR))
.match(IRB.CreateSelect(IRB.CreateFCmpOLE(L, R), R, L)));
EXPECT_TRUE(m_OrdFMax(m_Value(MatchL), m_Value(MatchR))
.match(IRB.CreateSelect(IRB.CreateFCmpULE(L, R), R, L)));
EXPECT_EQ(L, MatchL);
EXPECT_EQ(R, MatchR);
// [OUT]LT with inverted select.
EXPECT_FALSE(m_OrdFMax(m_Value(MatchL), m_Value(MatchR))
.match(IRB.CreateSelect(IRB.CreateFCmpOLT(L, R), R, L)));
EXPECT_TRUE(m_OrdFMax(m_Value(MatchL), m_Value(MatchR))
.match(IRB.CreateSelect(IRB.CreateFCmpULT(L, R), R, L)));
EXPECT_EQ(L, MatchL);
EXPECT_EQ(R, MatchR);
}
TEST_F(PatternMatchTest, FloatingPointUnorderedMin) {
Type *FltTy = IRB.getFloatTy();
Value *L = ConstantFP::get(FltTy, 1.0);
Value *R = ConstantFP::get(FltTy, 2.0);
Value *MatchL, *MatchR;
// Test ULT.
EXPECT_TRUE(m_UnordFMin(m_Value(MatchL), m_Value(MatchR))
.match(IRB.CreateSelect(IRB.CreateFCmpULT(L, R), L, R)));
EXPECT_EQ(L, MatchL);
EXPECT_EQ(R, MatchR);
// Test ULE.
EXPECT_TRUE(m_UnordFMin(m_Value(MatchL), m_Value(MatchR))
.match(IRB.CreateSelect(IRB.CreateFCmpULE(L, R), L, R)));
EXPECT_EQ(L, MatchL);
EXPECT_EQ(R, MatchR);
// Test no match on UGE.
EXPECT_FALSE(m_UnordFMin(m_Value(MatchL), m_Value(MatchR))
.match(IRB.CreateSelect(IRB.CreateFCmpUGE(L, R), L, R)));
// Test no match on UGT.
EXPECT_FALSE(m_UnordFMin(m_Value(MatchL), m_Value(MatchR))
.match(IRB.CreateSelect(IRB.CreateFCmpUGT(L, R), L, R)));
// Test inverted selects. Note, that this "inverts" the ordering, e.g.:
// %cmp = fcmp uge L, R
// %min = select %cmp R, L
// Given L == NaN
// the above is expanded to %cmp == true ==> %min = R
// which is true for OrdFMin, not UnordFMin, so test that:
// [UO]GE with inverted select.
EXPECT_FALSE(m_UnordFMin(m_Value(MatchL), m_Value(MatchR))
.match(IRB.CreateSelect(IRB.CreateFCmpUGE(L, R), R, L)));
EXPECT_TRUE(m_UnordFMin(m_Value(MatchL), m_Value(MatchR))
.match(IRB.CreateSelect(IRB.CreateFCmpOGE(L, R), R, L)));
EXPECT_EQ(L, MatchL);
EXPECT_EQ(R, MatchR);
// [UO]GT with inverted select.
EXPECT_FALSE(m_UnordFMin(m_Value(MatchL), m_Value(MatchR))
.match(IRB.CreateSelect(IRB.CreateFCmpUGT(L, R), R, L)));
EXPECT_TRUE(m_UnordFMin(m_Value(MatchL), m_Value(MatchR))
.match(IRB.CreateSelect(IRB.CreateFCmpOGT(L, R), R, L)));
EXPECT_EQ(L, MatchL);
EXPECT_EQ(R, MatchR);
}
TEST_F(PatternMatchTest, FloatingPointUnorderedMax) {
Type *FltTy = IRB.getFloatTy();
Value *L = ConstantFP::get(FltTy, 1.0);
Value *R = ConstantFP::get(FltTy, 2.0);
Value *MatchL, *MatchR;
// Test UGT.
EXPECT_TRUE(m_UnordFMax(m_Value(MatchL), m_Value(MatchR))
.match(IRB.CreateSelect(IRB.CreateFCmpUGT(L, R), L, R)));
EXPECT_EQ(L, MatchL);
EXPECT_EQ(R, MatchR);
// Test UGE.
EXPECT_TRUE(m_UnordFMax(m_Value(MatchL), m_Value(MatchR))
.match(IRB.CreateSelect(IRB.CreateFCmpUGE(L, R), L, R)));
EXPECT_EQ(L, MatchL);
EXPECT_EQ(R, MatchR);
// Test no match on ULE.
EXPECT_FALSE(m_UnordFMax(m_Value(MatchL), m_Value(MatchR))
.match(IRB.CreateSelect(IRB.CreateFCmpULE(L, R), L, R)));
// Test no match on ULT.
EXPECT_FALSE(m_UnordFMax(m_Value(MatchL), m_Value(MatchR))
.match(IRB.CreateSelect(IRB.CreateFCmpULT(L, R), L, R)));
// Test inverted selects. Note, that this "inverts" the ordering, e.g.:
// %cmp = fcmp ule L, R
// %max = select %cmp R, L
// Given L == NaN
// the above is expanded to %cmp == true ==> %max = R
// which is true for OrdFMax, not UnordFMax, so test that:
// [UO]LE with inverted select.
EXPECT_FALSE(m_UnordFMax(m_Value(MatchL), m_Value(MatchR))
.match(IRB.CreateSelect(IRB.CreateFCmpULE(L, R), R, L)));
EXPECT_TRUE(m_UnordFMax(m_Value(MatchL), m_Value(MatchR))
.match(IRB.CreateSelect(IRB.CreateFCmpOLE(L, R), R, L)));
EXPECT_EQ(L, MatchL);
EXPECT_EQ(R, MatchR);
// [UO]LT with inverted select.
EXPECT_FALSE(m_UnordFMax(m_Value(MatchL), m_Value(MatchR))
.match(IRB.CreateSelect(IRB.CreateFCmpULT(L, R), R, L)));
EXPECT_TRUE(m_UnordFMax(m_Value(MatchL), m_Value(MatchR))
.match(IRB.CreateSelect(IRB.CreateFCmpOLT(L, R), R, L)));
EXPECT_EQ(L, MatchL);
EXPECT_EQ(R, MatchR);
}
TEST_F(PatternMatchTest, OverflowingBinOps) {
Value *L = IRB.getInt32(1);
Value *R = IRB.getInt32(2);
Value *MatchL, *MatchR;
EXPECT_TRUE(
m_NSWAdd(m_Value(MatchL), m_Value(MatchR)).match(IRB.CreateNSWAdd(L, R)));
EXPECT_EQ(L, MatchL);
EXPECT_EQ(R, MatchR);
MatchL = MatchR = nullptr;
EXPECT_TRUE(
m_NSWSub(m_Value(MatchL), m_Value(MatchR)).match(IRB.CreateNSWSub(L, R)));
EXPECT_EQ(L, MatchL);
EXPECT_EQ(R, MatchR);
MatchL = MatchR = nullptr;
EXPECT_TRUE(
m_NSWMul(m_Value(MatchL), m_Value(MatchR)).match(IRB.CreateNSWMul(L, R)));
EXPECT_EQ(L, MatchL);
EXPECT_EQ(R, MatchR);
MatchL = MatchR = nullptr;
EXPECT_TRUE(m_NSWShl(m_Value(MatchL), m_Value(MatchR)).match(
IRB.CreateShl(L, R, "", /* NUW */ false, /* NSW */ true)));
EXPECT_EQ(L, MatchL);
EXPECT_EQ(R, MatchR);
EXPECT_TRUE(
m_NUWAdd(m_Value(MatchL), m_Value(MatchR)).match(IRB.CreateNUWAdd(L, R)));
EXPECT_EQ(L, MatchL);
EXPECT_EQ(R, MatchR);
MatchL = MatchR = nullptr;
EXPECT_TRUE(
m_NUWSub(m_Value(MatchL), m_Value(MatchR)).match(IRB.CreateNUWSub(L, R)));
EXPECT_EQ(L, MatchL);
EXPECT_EQ(R, MatchR);
MatchL = MatchR = nullptr;
EXPECT_TRUE(
m_NUWMul(m_Value(MatchL), m_Value(MatchR)).match(IRB.CreateNUWMul(L, R)));
EXPECT_EQ(L, MatchL);
EXPECT_EQ(R, MatchR);
MatchL = MatchR = nullptr;
EXPECT_TRUE(m_NUWShl(m_Value(MatchL), m_Value(MatchR)).match(
IRB.CreateShl(L, R, "", /* NUW */ true, /* NSW */ false)));
EXPECT_EQ(L, MatchL);
EXPECT_EQ(R, MatchR);
EXPECT_FALSE(m_NSWAdd(m_Value(), m_Value()).match(IRB.CreateAdd(L, R)));
EXPECT_FALSE(m_NSWAdd(m_Value(), m_Value()).match(IRB.CreateNUWAdd(L, R)));
EXPECT_FALSE(m_NSWAdd(m_Value(), m_Value()).match(IRB.CreateNSWSub(L, R)));
EXPECT_FALSE(m_NSWSub(m_Value(), m_Value()).match(IRB.CreateSub(L, R)));
EXPECT_FALSE(m_NSWSub(m_Value(), m_Value()).match(IRB.CreateNUWSub(L, R)));
EXPECT_FALSE(m_NSWSub(m_Value(), m_Value()).match(IRB.CreateNSWAdd(L, R)));
EXPECT_FALSE(m_NSWMul(m_Value(), m_Value()).match(IRB.CreateMul(L, R)));
EXPECT_FALSE(m_NSWMul(m_Value(), m_Value()).match(IRB.CreateNUWMul(L, R)));
EXPECT_FALSE(m_NSWMul(m_Value(), m_Value()).match(IRB.CreateNSWAdd(L, R)));
EXPECT_FALSE(m_NSWShl(m_Value(), m_Value()).match(IRB.CreateShl(L, R)));
EXPECT_FALSE(m_NSWShl(m_Value(), m_Value()).match(
IRB.CreateShl(L, R, "", /* NUW */ true, /* NSW */ false)));
EXPECT_FALSE(m_NSWShl(m_Value(), m_Value()).match(IRB.CreateNSWAdd(L, R)));
EXPECT_FALSE(m_NUWAdd(m_Value(), m_Value()).match(IRB.CreateAdd(L, R)));
EXPECT_FALSE(m_NUWAdd(m_Value(), m_Value()).match(IRB.CreateNSWAdd(L, R)));
EXPECT_FALSE(m_NUWAdd(m_Value(), m_Value()).match(IRB.CreateNUWSub(L, R)));
EXPECT_FALSE(m_NUWSub(m_Value(), m_Value()).match(IRB.CreateSub(L, R)));
EXPECT_FALSE(m_NUWSub(m_Value(), m_Value()).match(IRB.CreateNSWSub(L, R)));
EXPECT_FALSE(m_NUWSub(m_Value(), m_Value()).match(IRB.CreateNUWAdd(L, R)));
EXPECT_FALSE(m_NUWMul(m_Value(), m_Value()).match(IRB.CreateMul(L, R)));
EXPECT_FALSE(m_NUWMul(m_Value(), m_Value()).match(IRB.CreateNSWMul(L, R)));
EXPECT_FALSE(m_NUWMul(m_Value(), m_Value()).match(IRB.CreateNUWAdd(L, R)));
EXPECT_FALSE(m_NUWShl(m_Value(), m_Value()).match(IRB.CreateShl(L, R)));
EXPECT_FALSE(m_NUWShl(m_Value(), m_Value()).match(
IRB.CreateShl(L, R, "", /* NUW */ false, /* NSW */ true)));
EXPECT_FALSE(m_NUWShl(m_Value(), m_Value()).match(IRB.CreateNUWAdd(L, R)));
}
TEST_F(PatternMatchTest, LoadStoreOps) {
// Create this load/store sequence:
//
// %p = alloca i32*
// %0 = load i32*, i32** %p
// store i32 42, i32* %0
Value *Alloca = IRB.CreateAlloca(IRB.getInt32Ty());
Value *LoadInst = IRB.CreateLoad(Alloca);
Value *FourtyTwo = IRB.getInt32(42);
Value *StoreInst = IRB.CreateStore(FourtyTwo, Alloca);
Value *MatchLoad, *MatchStoreVal, *MatchStorePointer;
EXPECT_TRUE(m_Load(m_Value(MatchLoad)).match(LoadInst));
EXPECT_EQ(Alloca, MatchLoad);
EXPECT_TRUE(m_Load(m_Specific(Alloca)).match(LoadInst));
EXPECT_FALSE(m_Load(m_Value(MatchLoad)).match(Alloca));
EXPECT_TRUE(m_Store(m_Value(MatchStoreVal), m_Value(MatchStorePointer))
.match(StoreInst));
EXPECT_EQ(FourtyTwo, MatchStoreVal);
EXPECT_EQ(Alloca, MatchStorePointer);
EXPECT_FALSE(m_Store(m_Value(MatchStoreVal), m_Value(MatchStorePointer))
.match(Alloca));
EXPECT_TRUE(m_Store(m_SpecificInt(42), m_Specific(Alloca))
.match(StoreInst));
EXPECT_FALSE(m_Store(m_SpecificInt(42), m_Specific(FourtyTwo))
.match(StoreInst));
EXPECT_FALSE(m_Store(m_SpecificInt(43), m_Specific(Alloca))
.match(StoreInst));
}
TEST_F(PatternMatchTest, VectorOps) {
// Build up small tree of vector operations
//
// Val = 0 + 1
// Val2 = Val + 3
// VI1 = insertelement <2 x i8> undef, i8 1, i32 0 = <1, undef>
// VI2 = insertelement <2 x i8> %VI1, i8 %Val2, i8 %Val = <1, 4>
// VI3 = insertelement <2 x i8> %VI1, i8 %Val2, i32 1 = <1, 4>
// VI4 = insertelement <2 x i8> %VI1, i8 2, i8 %Val = <1, 2>
//
// SI1 = shufflevector <2 x i8> %VI1, <2 x i8> undef, zeroinitializer
// SI2 = shufflevector <2 x i8> %VI3, <2 x i8> %VI4, <2 x i8> <i8 0, i8 2>
// SI3 = shufflevector <2 x i8> %VI3, <2 x i8> undef, zeroinitializer
// SI4 = shufflevector <2 x i8> %VI4, <2 x i8> undef, zeroinitializer
//
// SP1 = VectorSplat(2, i8 2)
// SP2 = VectorSplat(2, i8 %Val)
Type *VecTy = VectorType::get(IRB.getInt8Ty(), 2);
Type *i32 = IRB.getInt32Ty();
Type *i32VecTy = VectorType::get(i32, 2);
Value *Val = IRB.CreateAdd(IRB.getInt8(0), IRB.getInt8(1));
Value *Val2 = IRB.CreateAdd(Val, IRB.getInt8(3));
SmallVector<Constant *, 2> VecElemIdxs;
VecElemIdxs.push_back(ConstantInt::get(i32, 0));
VecElemIdxs.push_back(ConstantInt::get(i32, 2));
auto *IdxVec = ConstantVector::get(VecElemIdxs);
Value *UndefVec = UndefValue::get(VecTy);
Value *VI1 = IRB.CreateInsertElement(UndefVec, IRB.getInt8(1), (uint64_t)0);
Value *VI2 = IRB.CreateInsertElement(VI1, Val2, Val);
Value *VI3 = IRB.CreateInsertElement(VI1, Val2, (uint64_t)1);
Value *VI4 = IRB.CreateInsertElement(VI1, IRB.getInt8(2), Val);
Value *EX1 = IRB.CreateExtractElement(VI4, Val);
Value *EX2 = IRB.CreateExtractElement(VI4, (uint64_t)0);
Value *EX3 = IRB.CreateExtractElement(IdxVec, (uint64_t)1);
Value *Zero = ConstantAggregateZero::get(i32VecTy);
Value *SI1 = IRB.CreateShuffleVector(VI1, UndefVec, Zero);
Value *SI2 = IRB.CreateShuffleVector(VI3, VI4, IdxVec);
Value *SI3 = IRB.CreateShuffleVector(VI3, UndefVec, Zero);
Value *SI4 = IRB.CreateShuffleVector(VI4, UndefVec, Zero);
Value *SP1 = IRB.CreateVectorSplat(2, IRB.getInt8(2));
Value *SP2 = IRB.CreateVectorSplat(2, Val);
Value *A = nullptr, *B = nullptr, *C = nullptr;
// Test matching insertelement
EXPECT_TRUE(match(VI1, m_InsertElement(m_Value(), m_Value(), m_Value())));
EXPECT_TRUE(
match(VI1, m_InsertElement(m_Undef(), m_ConstantInt(), m_ConstantInt())));
EXPECT_TRUE(
match(VI1, m_InsertElement(m_Undef(), m_ConstantInt(), m_Zero())));
EXPECT_TRUE(
match(VI1, m_InsertElement(m_Undef(), m_SpecificInt(1), m_Zero())));
EXPECT_TRUE(match(VI2, m_InsertElement(m_Value(), m_Value(), m_Value())));
EXPECT_FALSE(
match(VI2, m_InsertElement(m_Value(), m_Value(), m_ConstantInt())));
EXPECT_FALSE(
match(VI2, m_InsertElement(m_Value(), m_ConstantInt(), m_Value())));
EXPECT_FALSE(match(VI2, m_InsertElement(m_Constant(), m_Value(), m_Value())));
EXPECT_TRUE(match(VI3, m_InsertElement(m_Value(A), m_Value(B), m_Value(C))));
EXPECT_TRUE(A == VI1);
EXPECT_TRUE(B == Val2);
EXPECT_TRUE(isa<ConstantInt>(C));
A = B = C = nullptr; // reset
// Test matching extractelement
EXPECT_TRUE(match(EX1, m_ExtractElement(m_Value(A), m_Value(B))));
EXPECT_TRUE(A == VI4);
EXPECT_TRUE(B == Val);
A = B = C = nullptr; // reset
EXPECT_FALSE(match(EX1, m_ExtractElement(m_Value(), m_ConstantInt())));
EXPECT_TRUE(match(EX2, m_ExtractElement(m_Value(), m_ConstantInt())));
EXPECT_TRUE(match(EX3, m_ExtractElement(m_Constant(), m_ConstantInt())));
// Test matching shufflevector
EXPECT_TRUE(match(SI1, m_ShuffleVector(m_Value(), m_Undef(), m_Zero())));
EXPECT_TRUE(match(SI2, m_ShuffleVector(m_Value(A), m_Value(B), m_Value(C))));
EXPECT_TRUE(A == VI3);
EXPECT_TRUE(B == VI4);
EXPECT_TRUE(C == IdxVec);
A = B = C = nullptr; // reset
// Test matching the vector splat pattern
EXPECT_TRUE(match(
SI1,
m_ShuffleVector(m_InsertElement(m_Undef(), m_SpecificInt(1), m_Zero()),
m_Undef(), m_Zero())));
EXPECT_FALSE(match(
SI3, m_ShuffleVector(m_InsertElement(m_Undef(), m_Value(), m_Zero()),
m_Undef(), m_Zero())));
EXPECT_FALSE(match(
SI4, m_ShuffleVector(m_InsertElement(m_Undef(), m_Value(), m_Zero()),
m_Undef(), m_Zero())));
EXPECT_TRUE(match(
SP1,
m_ShuffleVector(m_InsertElement(m_Undef(), m_SpecificInt(2), m_Zero()),
m_Undef(), m_Zero())));
EXPECT_TRUE(match(
SP2, m_ShuffleVector(m_InsertElement(m_Undef(), m_Value(A), m_Zero()),
m_Undef(), m_Zero())));
EXPECT_TRUE(A == Val);
}
template <typename T> struct MutableConstTest : PatternMatchTest { };
typedef ::testing::Types<std::tuple<Value*, Instruction*>,
std::tuple<const Value*, const Instruction *>>
MutableConstTestTypes;
TYPED_TEST_CASE(MutableConstTest, MutableConstTestTypes);
TYPED_TEST(MutableConstTest, ICmp) {
auto &IRB = PatternMatchTest::IRB;
typedef typename std::tuple_element<0, TypeParam>::type ValueType;
typedef typename std::tuple_element<1, TypeParam>::type InstructionType;
Value *L = IRB.getInt32(1);
Value *R = IRB.getInt32(2);
ICmpInst::Predicate Pred = ICmpInst::ICMP_UGT;
ValueType MatchL;
ValueType MatchR;
ICmpInst::Predicate MatchPred;
EXPECT_TRUE(m_ICmp(MatchPred, m_Value(MatchL), m_Value(MatchR))
.match((InstructionType)IRB.CreateICmp(Pred, L, R)));
EXPECT_EQ(L, MatchL);
EXPECT_EQ(R, MatchR);
}
} // anonymous namespace.