//===- ValueTrackingTest.cpp - ValueTracking tests ------------------------===// // // 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 "llvm/Analysis/ValueTracking.h" #include "llvm/AsmParser/Parser.h" #include "llvm/IR/Function.h" #include "llvm/IR/InstIterator.h" #include "llvm/IR/LLVMContext.h" #include "llvm/IR/Module.h" #include "llvm/Support/ErrorHandling.h" #include "llvm/Support/KnownBits.h" #include "llvm/Support/SourceMgr.h" #include "gtest/gtest.h" using namespace llvm; namespace { class ValueTrackingTest : public testing::Test { protected: std::unique_ptr parseModule(StringRef Assembly) { SMDiagnostic Error; std::unique_ptr M = parseAssemblyString(Assembly, Error, Context); std::string errMsg; raw_string_ostream os(errMsg); Error.print("", os); EXPECT_TRUE(M) << os.str(); return M; } void parseAssembly(StringRef Assembly) { M = parseModule(Assembly); ASSERT_TRUE(M); Function *F = M->getFunction("test"); ASSERT_TRUE(F) << "Test must have a function @test"; if (!F) return; A = nullptr; for (inst_iterator I = inst_begin(F), E = inst_end(F); I != E; ++I) { if (I->hasName()) { if (I->getName() == "A") A = &*I; } } ASSERT_TRUE(A) << "@test must have an instruction %A"; } LLVMContext Context; std::unique_ptr M; Instruction *A = nullptr; }; class MatchSelectPatternTest : public ValueTrackingTest { protected: void expectPattern(const SelectPatternResult &P) { Value *LHS, *RHS; Instruction::CastOps CastOp; SelectPatternResult R = matchSelectPattern(A, LHS, RHS, &CastOp); EXPECT_EQ(P.Flavor, R.Flavor); EXPECT_EQ(P.NaNBehavior, R.NaNBehavior); EXPECT_EQ(P.Ordered, R.Ordered); } }; class ComputeKnownBitsTest : public ValueTrackingTest { protected: void expectKnownBits(uint64_t Zero, uint64_t One) { auto Known = computeKnownBits(A, M->getDataLayout()); ASSERT_FALSE(Known.hasConflict()); EXPECT_EQ(Known.One.getZExtValue(), One); EXPECT_EQ(Known.Zero.getZExtValue(), Zero); } }; } TEST_F(MatchSelectPatternTest, SimpleFMin) { parseAssembly( "define float @test(float %a) {\n" " %1 = fcmp ult float %a, 5.0\n" " %A = select i1 %1, float %a, float 5.0\n" " ret float %A\n" "}\n"); expectPattern({SPF_FMINNUM, SPNB_RETURNS_NAN, false}); } TEST_F(MatchSelectPatternTest, SimpleFMax) { parseAssembly( "define float @test(float %a) {\n" " %1 = fcmp ogt float %a, 5.0\n" " %A = select i1 %1, float %a, float 5.0\n" " ret float %A\n" "}\n"); expectPattern({SPF_FMAXNUM, SPNB_RETURNS_OTHER, true}); } TEST_F(MatchSelectPatternTest, SwappedFMax) { parseAssembly( "define float @test(float %a) {\n" " %1 = fcmp olt float 5.0, %a\n" " %A = select i1 %1, float %a, float 5.0\n" " ret float %A\n" "}\n"); expectPattern({SPF_FMAXNUM, SPNB_RETURNS_OTHER, false}); } TEST_F(MatchSelectPatternTest, SwappedFMax2) { parseAssembly( "define float @test(float %a) {\n" " %1 = fcmp olt float %a, 5.0\n" " %A = select i1 %1, float 5.0, float %a\n" " ret float %A\n" "}\n"); expectPattern({SPF_FMAXNUM, SPNB_RETURNS_NAN, false}); } TEST_F(MatchSelectPatternTest, SwappedFMax3) { parseAssembly( "define float @test(float %a) {\n" " %1 = fcmp ult float %a, 5.0\n" " %A = select i1 %1, float 5.0, float %a\n" " ret float %A\n" "}\n"); expectPattern({SPF_FMAXNUM, SPNB_RETURNS_OTHER, true}); } TEST_F(MatchSelectPatternTest, FastFMin) { parseAssembly( "define float @test(float %a) {\n" " %1 = fcmp nnan olt float %a, 5.0\n" " %A = select i1 %1, float %a, float 5.0\n" " ret float %A\n" "}\n"); expectPattern({SPF_FMINNUM, SPNB_RETURNS_ANY, false}); } TEST_F(MatchSelectPatternTest, FMinConstantZero) { parseAssembly( "define float @test(float %a) {\n" " %1 = fcmp ole float %a, 0.0\n" " %A = select i1 %1, float %a, float 0.0\n" " ret float %A\n" "}\n"); // This shouldn't be matched, as %a could be -0.0. expectPattern({SPF_UNKNOWN, SPNB_NA, false}); } TEST_F(MatchSelectPatternTest, FMinConstantZeroNsz) { parseAssembly( "define float @test(float %a) {\n" " %1 = fcmp nsz ole float %a, 0.0\n" " %A = select i1 %1, float %a, float 0.0\n" " ret float %A\n" "}\n"); // But this should be, because we've ignored signed zeroes. expectPattern({SPF_FMINNUM, SPNB_RETURNS_OTHER, true}); } TEST_F(MatchSelectPatternTest, FMinMismatchConstantZero1) { parseAssembly( "define float @test(float %a) {\n" " %1 = fcmp olt float -0.0, %a\n" " %A = select i1 %1, float 0.0, float %a\n" " ret float %A\n" "}\n"); // The sign of zero doesn't matter in fcmp. expectPattern({SPF_FMINNUM, SPNB_RETURNS_NAN, true}); } TEST_F(MatchSelectPatternTest, FMinMismatchConstantZero2) { parseAssembly( "define float @test(float %a) {\n" " %1 = fcmp ogt float %a, -0.0\n" " %A = select i1 %1, float 0.0, float %a\n" " ret float %A\n" "}\n"); // The sign of zero doesn't matter in fcmp. expectPattern({SPF_FMINNUM, SPNB_RETURNS_NAN, false}); } TEST_F(MatchSelectPatternTest, FMinMismatchConstantZero3) { parseAssembly( "define float @test(float %a) {\n" " %1 = fcmp olt float 0.0, %a\n" " %A = select i1 %1, float -0.0, float %a\n" " ret float %A\n" "}\n"); // The sign of zero doesn't matter in fcmp. expectPattern({SPF_FMINNUM, SPNB_RETURNS_NAN, true}); } TEST_F(MatchSelectPatternTest, FMinMismatchConstantZero4) { parseAssembly( "define float @test(float %a) {\n" " %1 = fcmp ogt float %a, 0.0\n" " %A = select i1 %1, float -0.0, float %a\n" " ret float %A\n" "}\n"); // The sign of zero doesn't matter in fcmp. expectPattern({SPF_FMINNUM, SPNB_RETURNS_NAN, false}); } TEST_F(MatchSelectPatternTest, FMinMismatchConstantZero5) { parseAssembly( "define float @test(float %a) {\n" " %1 = fcmp ogt float -0.0, %a\n" " %A = select i1 %1, float %a, float 0.0\n" " ret float %A\n" "}\n"); // The sign of zero doesn't matter in fcmp. expectPattern({SPF_FMINNUM, SPNB_RETURNS_OTHER, false}); } TEST_F(MatchSelectPatternTest, FMinMismatchConstantZero6) { parseAssembly( "define float @test(float %a) {\n" " %1 = fcmp olt float %a, -0.0\n" " %A = select i1 %1, float %a, float 0.0\n" " ret float %A\n" "}\n"); // The sign of zero doesn't matter in fcmp. expectPattern({SPF_FMINNUM, SPNB_RETURNS_OTHER, true}); } TEST_F(MatchSelectPatternTest, FMinMismatchConstantZero7) { parseAssembly( "define float @test(float %a) {\n" " %1 = fcmp ogt float 0.0, %a\n" " %A = select i1 %1, float %a, float -0.0\n" " ret float %A\n" "}\n"); // The sign of zero doesn't matter in fcmp. expectPattern({SPF_FMINNUM, SPNB_RETURNS_OTHER, false}); } TEST_F(MatchSelectPatternTest, FMinMismatchConstantZero8) { parseAssembly( "define float @test(float %a) {\n" " %1 = fcmp olt float %a, 0.0\n" " %A = select i1 %1, float %a, float -0.0\n" " ret float %A\n" "}\n"); // The sign of zero doesn't matter in fcmp. expectPattern({SPF_FMINNUM, SPNB_RETURNS_OTHER, true}); } TEST_F(MatchSelectPatternTest, FMaxMismatchConstantZero1) { parseAssembly( "define float @test(float %a) {\n" " %1 = fcmp ogt float -0.0, %a\n" " %A = select i1 %1, float 0.0, float %a\n" " ret float %A\n" "}\n"); // The sign of zero doesn't matter in fcmp. expectPattern({SPF_FMAXNUM, SPNB_RETURNS_NAN, true}); } TEST_F(MatchSelectPatternTest, FMaxMismatchConstantZero2) { parseAssembly( "define float @test(float %a) {\n" " %1 = fcmp olt float %a, -0.0\n" " %A = select i1 %1, float 0.0, float %a\n" " ret float %A\n" "}\n"); // The sign of zero doesn't matter in fcmp. expectPattern({SPF_FMAXNUM, SPNB_RETURNS_NAN, false}); } TEST_F(MatchSelectPatternTest, FMaxMismatchConstantZero3) { parseAssembly( "define float @test(float %a) {\n" " %1 = fcmp ogt float 0.0, %a\n" " %A = select i1 %1, float -0.0, float %a\n" " ret float %A\n" "}\n"); // The sign of zero doesn't matter in fcmp. expectPattern({SPF_FMAXNUM, SPNB_RETURNS_NAN, true}); } TEST_F(MatchSelectPatternTest, FMaxMismatchConstantZero4) { parseAssembly( "define float @test(float %a) {\n" " %1 = fcmp olt float %a, 0.0\n" " %A = select i1 %1, float -0.0, float %a\n" " ret float %A\n" "}\n"); // The sign of zero doesn't matter in fcmp. expectPattern({SPF_FMAXNUM, SPNB_RETURNS_NAN, false}); } TEST_F(MatchSelectPatternTest, FMaxMismatchConstantZero5) { parseAssembly( "define float @test(float %a) {\n" " %1 = fcmp olt float -0.0, %a\n" " %A = select i1 %1, float %a, float 0.0\n" " ret float %A\n" "}\n"); // The sign of zero doesn't matter in fcmp. expectPattern({SPF_FMAXNUM, SPNB_RETURNS_OTHER, false}); } TEST_F(MatchSelectPatternTest, FMaxMismatchConstantZero6) { parseAssembly( "define float @test(float %a) {\n" " %1 = fcmp ogt float %a, -0.0\n" " %A = select i1 %1, float %a, float 0.0\n" " ret float %A\n" "}\n"); // The sign of zero doesn't matter in fcmp. expectPattern({SPF_FMAXNUM, SPNB_RETURNS_OTHER, true}); } TEST_F(MatchSelectPatternTest, FMaxMismatchConstantZero7) { parseAssembly( "define float @test(float %a) {\n" " %1 = fcmp olt float 0.0, %a\n" " %A = select i1 %1, float %a, float -0.0\n" " ret float %A\n" "}\n"); // The sign of zero doesn't matter in fcmp. expectPattern({SPF_FMAXNUM, SPNB_RETURNS_OTHER, false}); } TEST_F(MatchSelectPatternTest, FMaxMismatchConstantZero8) { parseAssembly( "define float @test(float %a) {\n" " %1 = fcmp ogt float %a, 0.0\n" " %A = select i1 %1, float %a, float -0.0\n" " ret float %A\n" "}\n"); // The sign of zero doesn't matter in fcmp. expectPattern({SPF_FMAXNUM, SPNB_RETURNS_OTHER, true}); } TEST_F(MatchSelectPatternTest, FMinMismatchConstantZeroVecUndef) { parseAssembly( "define <2 x float> @test(<2 x float> %a) {\n" " %1 = fcmp ogt <2 x float> %a, \n" " %A = select <2 x i1> %1, <2 x float> , <2 x float> %a\n" " ret <2 x float> %A\n" "}\n"); // An undef in a vector constant can not be back-propagated for this analysis. expectPattern({SPF_UNKNOWN, SPNB_NA, false}); } TEST_F(MatchSelectPatternTest, FMaxMismatchConstantZeroVecUndef) { parseAssembly( "define <2 x float> @test(<2 x float> %a) {\n" " %1 = fcmp ogt <2 x float> %a, zeroinitializer\n" " %A = select <2 x i1> %1, <2 x float> %a, <2 x float> \n" " ret <2 x float> %A\n" "}\n"); // An undef in a vector constant can not be back-propagated for this analysis. expectPattern({SPF_UNKNOWN, SPNB_NA, false}); } TEST_F(MatchSelectPatternTest, VectorFMinimum) { parseAssembly( "define <4 x float> @test(<4 x float> %a) {\n" " %1 = fcmp ule <4 x float> %a, \n" " \n" " %A = select <4 x i1> %1, <4 x float> %a,\n" " <4 x float> \n" " ret <4 x float> %A\n" "}\n"); // Check that pattern matching works on vectors where each lane has the same // unordered pattern. expectPattern({SPF_FMINNUM, SPNB_RETURNS_NAN, false}); } TEST_F(MatchSelectPatternTest, VectorFMinOtherOrdered) { parseAssembly( "define <4 x float> @test(<4 x float> %a) {\n" " %1 = fcmp ole <4 x float> %a, \n" " \n" " %A = select <4 x i1> %1, <4 x float> %a,\n" " <4 x float> \n" " ret <4 x float> %A\n" "}\n"); // Check that pattern matching works on vectors where each lane has the same // ordered pattern. expectPattern({SPF_FMINNUM, SPNB_RETURNS_OTHER, true}); } TEST_F(MatchSelectPatternTest, VectorNotFMinimum) { parseAssembly( "define <4 x float> @test(<4 x float> %a) {\n" " %1 = fcmp ule <4 x float> %a, \n" " \n" " %A = select <4 x i1> %1, <4 x float> %a,\n" " <4 x float> \n" " ret <4 x float> %A\n" "}\n"); // The lane that contains a NaN (0x7ff80...) behaves like a // non-NaN-propagating min and the other lines behave like a NaN-propagating // min, so check that neither is returned. expectPattern({SPF_UNKNOWN, SPNB_NA, false}); } TEST_F(MatchSelectPatternTest, VectorNotFMinZero) { parseAssembly( "define <4 x float> @test(<4 x float> %a) {\n" " %1 = fcmp ule <4 x float> %a, \n" " \n" " %A = select <4 x i1> %1, <4 x float> %a,\n" " <4 x float> \n" " ret <4 x float> %A\n" "}\n"); // Always selects the second lane of %a if it is positive or negative zero, so // this is stricter than a min. expectPattern({SPF_UNKNOWN, SPNB_NA, false}); } TEST_F(MatchSelectPatternTest, DoubleCastU) { parseAssembly( "define i32 @test(i8 %a, i8 %b) {\n" " %1 = icmp ult i8 %a, %b\n" " %2 = zext i8 %a to i32\n" " %3 = zext i8 %b to i32\n" " %A = select i1 %1, i32 %2, i32 %3\n" " ret i32 %A\n" "}\n"); // We should be able to look through the situation where we cast both operands // to the select. expectPattern({SPF_UMIN, SPNB_NA, false}); } TEST_F(MatchSelectPatternTest, DoubleCastS) { parseAssembly( "define i32 @test(i8 %a, i8 %b) {\n" " %1 = icmp slt i8 %a, %b\n" " %2 = sext i8 %a to i32\n" " %3 = sext i8 %b to i32\n" " %A = select i1 %1, i32 %2, i32 %3\n" " ret i32 %A\n" "}\n"); // We should be able to look through the situation where we cast both operands // to the select. expectPattern({SPF_SMIN, SPNB_NA, false}); } TEST_F(MatchSelectPatternTest, DoubleCastBad) { parseAssembly( "define i32 @test(i8 %a, i8 %b) {\n" " %1 = icmp ult i8 %a, %b\n" " %2 = zext i8 %a to i32\n" " %3 = sext i8 %b to i32\n" " %A = select i1 %1, i32 %2, i32 %3\n" " ret i32 %A\n" "}\n"); // The cast types here aren't the same, so we cannot match an UMIN. expectPattern({SPF_UNKNOWN, SPNB_NA, false}); } TEST(ValueTracking, GuaranteedToTransferExecutionToSuccessor) { StringRef Assembly = "declare void @nounwind_readonly(i32*) nounwind readonly " "declare void @nounwind_argmemonly(i32*) nounwind argmemonly " "declare void @throws_but_readonly(i32*) readonly " "declare void @throws_but_argmemonly(i32*) argmemonly " "declare void @nounwind_willreturn(i32*) nounwind willreturn" " " "declare void @unknown(i32*) " " " "define void @f(i32* %p) { " " call void @nounwind_readonly(i32* %p) " " call void @nounwind_argmemonly(i32* %p) " " call void @throws_but_readonly(i32* %p) " " call void @throws_but_argmemonly(i32* %p) " " call void @unknown(i32* %p) nounwind readonly " " call void @unknown(i32* %p) nounwind argmemonly " " call void @unknown(i32* %p) readonly " " call void @unknown(i32* %p) argmemonly " " call void @nounwind_willreturn(i32* %p)" " ret void " "} "; LLVMContext Context; SMDiagnostic Error; auto M = parseAssemblyString(Assembly, Error, Context); assert(M && "Bad assembly?"); auto *F = M->getFunction("f"); assert(F && "Bad assembly?"); auto &BB = F->getEntryBlock(); bool ExpectedAnswers[] = { true, // call void @nounwind_readonly(i32* %p) true, // call void @nounwind_argmemonly(i32* %p) false, // call void @throws_but_readonly(i32* %p) false, // call void @throws_but_argmemonly(i32* %p) true, // call void @unknown(i32* %p) nounwind readonly true, // call void @unknown(i32* %p) nounwind argmemonly false, // call void @unknown(i32* %p) readonly false, // call void @unknown(i32* %p) argmemonly true, // call void @nounwind_willreturn(i32* %p) false, // ret void }; int Index = 0; for (auto &I : BB) { EXPECT_EQ(isGuaranteedToTransferExecutionToSuccessor(&I), ExpectedAnswers[Index]) << "Incorrect answer at instruction " << Index << " = " << I; Index++; } } TEST_F(ValueTrackingTest, ComputeNumSignBits_PR32045) { parseAssembly( "define i32 @test(i32 %a) {\n" " %A = ashr i32 %a, -1\n" " ret i32 %A\n" "}\n"); EXPECT_EQ(ComputeNumSignBits(A, M->getDataLayout()), 1u); } // No guarantees for canonical IR in this analysis, so this just bails out. TEST_F(ValueTrackingTest, ComputeNumSignBits_Shuffle) { parseAssembly( "define <2 x i32> @test() {\n" " %A = shufflevector <2 x i32> undef, <2 x i32> undef, <2 x i32> \n" " ret <2 x i32> %A\n" "}\n"); EXPECT_EQ(ComputeNumSignBits(A, M->getDataLayout()), 1u); } // No guarantees for canonical IR in this analysis, so a shuffle element that // references an undef value means this can't return any extra information. TEST_F(ValueTrackingTest, ComputeNumSignBits_Shuffle2) { parseAssembly( "define <2 x i32> @test(<2 x i1> %x) {\n" " %sext = sext <2 x i1> %x to <2 x i32>\n" " %A = shufflevector <2 x i32> %sext, <2 x i32> undef, <2 x i32> \n" " ret <2 x i32> %A\n" "}\n"); EXPECT_EQ(ComputeNumSignBits(A, M->getDataLayout()), 1u); } TEST_F(ComputeKnownBitsTest, ComputeKnownBits) { parseAssembly( "define i32 @test(i32 %a, i32 %b) {\n" " %ash = mul i32 %a, 8\n" " %aad = add i32 %ash, 7\n" " %aan = and i32 %aad, 4095\n" " %bsh = shl i32 %b, 4\n" " %bad = or i32 %bsh, 6\n" " %ban = and i32 %bad, 4095\n" " %A = mul i32 %aan, %ban\n" " ret i32 %A\n" "}\n"); expectKnownBits(/*zero*/ 4278190085u, /*one*/ 10u); } TEST_F(ComputeKnownBitsTest, ComputeKnownMulBits) { parseAssembly( "define i32 @test(i32 %a, i32 %b) {\n" " %aa = shl i32 %a, 5\n" " %bb = shl i32 %b, 5\n" " %aaa = or i32 %aa, 24\n" " %bbb = or i32 %bb, 28\n" " %A = mul i32 %aaa, %bbb\n" " ret i32 %A\n" "}\n"); expectKnownBits(/*zero*/ 95u, /*one*/ 32u); } TEST_F(ComputeKnownBitsTest, ComputeKnownFshl) { // fshl(....1111....0000, 00..1111........, 6) // = 11....000000..11 parseAssembly( "define i16 @test(i16 %a, i16 %b) {\n" " %aa = shl i16 %a, 4\n" " %bb = lshr i16 %b, 2\n" " %aaa = or i16 %aa, 3840\n" " %bbb = or i16 %bb, 3840\n" " %A = call i16 @llvm.fshl.i16(i16 %aaa, i16 %bbb, i16 6)\n" " ret i16 %A\n" "}\n" "declare i16 @llvm.fshl.i16(i16, i16, i16)\n"); expectKnownBits(/*zero*/ 1008u, /*one*/ 49155u); } TEST_F(ComputeKnownBitsTest, ComputeKnownFshr) { // fshr(....1111....0000, 00..1111........, 26) // = 11....000000..11 parseAssembly( "define i16 @test(i16 %a, i16 %b) {\n" " %aa = shl i16 %a, 4\n" " %bb = lshr i16 %b, 2\n" " %aaa = or i16 %aa, 3840\n" " %bbb = or i16 %bb, 3840\n" " %A = call i16 @llvm.fshr.i16(i16 %aaa, i16 %bbb, i16 26)\n" " ret i16 %A\n" "}\n" "declare i16 @llvm.fshr.i16(i16, i16, i16)\n"); expectKnownBits(/*zero*/ 1008u, /*one*/ 49155u); } TEST_F(ComputeKnownBitsTest, ComputeKnownFshlZero) { // fshl(....1111....0000, 00..1111........, 0) // = ....1111....0000 parseAssembly( "define i16 @test(i16 %a, i16 %b) {\n" " %aa = shl i16 %a, 4\n" " %bb = lshr i16 %b, 2\n" " %aaa = or i16 %aa, 3840\n" " %bbb = or i16 %bb, 3840\n" " %A = call i16 @llvm.fshl.i16(i16 %aaa, i16 %bbb, i16 0)\n" " ret i16 %A\n" "}\n" "declare i16 @llvm.fshl.i16(i16, i16, i16)\n"); expectKnownBits(/*zero*/ 15u, /*one*/ 3840u); } TEST_F(ComputeKnownBitsTest, ComputeKnownUAddSatLeadingOnes) { // uadd.sat(1111...1, ........) // = 1111.... parseAssembly( "define i8 @test(i8 %a, i8 %b) {\n" " %aa = or i8 %a, 241\n" " %A = call i8 @llvm.uadd.sat.i8(i8 %aa, i8 %b)\n" " ret i8 %A\n" "}\n" "declare i8 @llvm.uadd.sat.i8(i8, i8)\n"); expectKnownBits(/*zero*/ 0u, /*one*/ 240u); } TEST_F(ComputeKnownBitsTest, ComputeKnownUAddSatOnesPreserved) { // uadd.sat(00...011, .1...110) // = .......1 parseAssembly( "define i8 @test(i8 %a, i8 %b) {\n" " %aa = or i8 %a, 3\n" " %aaa = and i8 %aa, 59\n" " %bb = or i8 %b, 70\n" " %bbb = and i8 %bb, 254\n" " %A = call i8 @llvm.uadd.sat.i8(i8 %aaa, i8 %bbb)\n" " ret i8 %A\n" "}\n" "declare i8 @llvm.uadd.sat.i8(i8, i8)\n"); expectKnownBits(/*zero*/ 0u, /*one*/ 1u); } TEST_F(ComputeKnownBitsTest, ComputeKnownUSubSatLHSLeadingZeros) { // usub.sat(0000...0, ........) // = 0000.... parseAssembly( "define i8 @test(i8 %a, i8 %b) {\n" " %aa = and i8 %a, 14\n" " %A = call i8 @llvm.usub.sat.i8(i8 %aa, i8 %b)\n" " ret i8 %A\n" "}\n" "declare i8 @llvm.usub.sat.i8(i8, i8)\n"); expectKnownBits(/*zero*/ 240u, /*one*/ 0u); } TEST_F(ComputeKnownBitsTest, ComputeKnownUSubSatRHSLeadingOnes) { // usub.sat(........, 1111...1) // = 0000.... parseAssembly( "define i8 @test(i8 %a, i8 %b) {\n" " %bb = or i8 %a, 241\n" " %A = call i8 @llvm.usub.sat.i8(i8 %a, i8 %bb)\n" " ret i8 %A\n" "}\n" "declare i8 @llvm.usub.sat.i8(i8, i8)\n"); expectKnownBits(/*zero*/ 240u, /*one*/ 0u); } TEST_F(ComputeKnownBitsTest, ComputeKnownUSubSatZerosPreserved) { // usub.sat(11...011, .1...110) // = ......0. parseAssembly( "define i8 @test(i8 %a, i8 %b) {\n" " %aa = or i8 %a, 195\n" " %aaa = and i8 %aa, 251\n" " %bb = or i8 %b, 70\n" " %bbb = and i8 %bb, 254\n" " %A = call i8 @llvm.usub.sat.i8(i8 %aaa, i8 %bbb)\n" " ret i8 %A\n" "}\n" "declare i8 @llvm.usub.sat.i8(i8, i8)\n"); expectKnownBits(/*zero*/ 2u, /*one*/ 0u); } class IsBytewiseValueTest : public ValueTrackingTest, public ::testing::WithParamInterface< std::pair> { protected: }; const std::pair IsBytewiseValueTests[] = { { "i8 0", "i48* null", }, { "i8 undef", "i48* undef", }, { "i8 0", "i8 zeroinitializer", }, { "i8 0", "i8 0", }, { "i8 -86", "i8 -86", }, { "i8 -1", "i8 -1", }, { "i8 undef", "i16 undef", }, { "i8 0", "i16 0", }, { "", "i16 7", }, { "i8 -86", "i16 -21846", }, { "i8 -1", "i16 -1", }, { "i8 0", "i48 0", }, { "i8 -1", "i48 -1", }, { "i8 0", "i49 0", }, { "", "i49 -1", }, { "i8 0", "half 0xH0000", }, { "i8 -85", "half 0xHABAB", }, { "i8 0", "float 0.0", }, { "i8 -1", "float 0xFFFFFFFFE0000000", }, { "i8 0", "double 0.0", }, { "i8 -15", "double 0xF1F1F1F1F1F1F1F1", }, { "i8 undef", "i16* undef", }, { "i8 0", "i16* inttoptr (i64 0 to i16*)", }, { "i8 -1", "i16* inttoptr (i64 -1 to i16*)", }, { "i8 -86", "i16* inttoptr (i64 -6148914691236517206 to i16*)", }, { "", "i16* inttoptr (i48 -1 to i16*)", }, { "i8 -1", "i16* inttoptr (i96 -1 to i16*)", }, { "i8 undef", "[0 x i8] zeroinitializer", }, { "i8 undef", "[0 x i8] undef", }, { "i8 undef", "[5 x [0 x i8]] zeroinitializer", }, { "i8 undef", "[5 x [0 x i8]] undef", }, { "i8 0", "[6 x i8] zeroinitializer", }, { "i8 undef", "[6 x i8] undef", }, { "i8 1", "[5 x i8] [i8 1, i8 1, i8 1, i8 1, i8 1]", }, { "", "[5 x i64] [i64 1, i64 1, i64 1, i64 1, i64 1]", }, { "i8 -1", "[5 x i64] [i64 -1, i64 -1, i64 -1, i64 -1, i64 -1]", }, { "", "[4 x i8] [i8 1, i8 2, i8 1, i8 1]", }, { "i8 1", "[4 x i8] [i8 1, i8 undef, i8 1, i8 1]", }, { "i8 0", "<6 x i8> zeroinitializer", }, { "i8 undef", "<6 x i8> undef", }, { "i8 1", "<5 x i8> ", }, { "", "<5 x i64> ", }, { "i8 -1", "<5 x i64> ", }, { "", "<4 x i8> ", }, { "i8 5", "<2 x i8> < i8 5, i8 undef >", }, { "i8 0", "[2 x [2 x i16]] zeroinitializer", }, { "i8 undef", "[2 x [2 x i16]] undef", }, { "i8 -86", "[2 x [2 x i16]] [[2 x i16] [i16 -21846, i16 -21846], " "[2 x i16] [i16 -21846, i16 -21846]]", }, { "", "[2 x [2 x i16]] [[2 x i16] [i16 -21846, i16 -21846], " "[2 x i16] [i16 -21836, i16 -21846]]", }, { "i8 undef", "{ } zeroinitializer", }, { "i8 undef", "{ } undef", }, { "i8 undef", "{ {}, {} } zeroinitializer", }, { "i8 undef", "{ {}, {} } undef", }, { "i8 0", "{i8, i64, i16*} zeroinitializer", }, { "i8 undef", "{i8, i64, i16*} undef", }, { "i8 -86", "{i8, i64, i16*} {i8 -86, i64 -6148914691236517206, i16* undef}", }, { "", "{i8, i64, i16*} {i8 86, i64 -6148914691236517206, i16* undef}", }, }; INSTANTIATE_TEST_CASE_P(IsBytewiseValueParamTests, IsBytewiseValueTest, ::testing::ValuesIn(IsBytewiseValueTests),); TEST_P(IsBytewiseValueTest, IsBytewiseValue) { auto M = parseModule(std::string("@test = global ") + GetParam().second); GlobalVariable *GV = dyn_cast(M->getNamedValue("test")); Value *Actual = isBytewiseValue(GV->getInitializer(), M->getDataLayout()); std::string Buff; raw_string_ostream S(Buff); if (Actual) S << *Actual; EXPECT_EQ(GetParam().first, S.str()); }