//===- MachineIRBuilderTest.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 "GISelMITest.h" #include "llvm/CodeGen/GlobalISel/MachineIRBuilder.h" TEST_F(AArch64GISelMITest, TestBuildConstantFConstant) { setUp(); if (!TM) return; B.buildConstant(LLT::scalar(32), 42); B.buildFConstant(LLT::scalar(32), 1.0); B.buildConstant(LLT::vector(2, 32), 99); B.buildFConstant(LLT::vector(2, 32), 2.0); // Test APFloat overload. APFloat KVal(APFloat::IEEEdouble(), "4.0"); B.buildFConstant(LLT::scalar(64), KVal); auto CheckStr = R"( CHECK: [[CONST0:%[0-9]+]]:_(s32) = G_CONSTANT i32 42 CHECK: [[FCONST0:%[0-9]+]]:_(s32) = G_FCONSTANT float 1.000000e+00 CHECK: [[CONST1:%[0-9]+]]:_(s32) = G_CONSTANT i32 99 CHECK: [[VEC0:%[0-9]+]]:_(<2 x s32>) = G_BUILD_VECTOR [[CONST1]]:_(s32), [[CONST1]]:_(s32) CHECK: [[FCONST1:%[0-9]+]]:_(s32) = G_FCONSTANT float 2.000000e+00 CHECK: [[VEC1:%[0-9]+]]:_(<2 x s32>) = G_BUILD_VECTOR [[FCONST1]]:_(s32), [[FCONST1]]:_(s32) CHECK: [[FCONST2:%[0-9]+]]:_(s64) = G_FCONSTANT double 4.000000e+00 )"; EXPECT_TRUE(CheckMachineFunction(*MF, CheckStr)) << *MF; } #ifdef GTEST_HAS_DEATH_TEST #ifndef NDEBUG TEST_F(AArch64GISelMITest, TestBuildConstantFConstantDeath) { setUp(); if (!TM) return; LLVMContext &Ctx = MF->getFunction().getContext(); APInt APV32(32, 12345); // Test APInt version breaks EXPECT_DEATH(B.buildConstant(LLT::scalar(16), APV32), "creating constant with the wrong size"); EXPECT_DEATH(B.buildConstant(LLT::vector(2, 16), APV32), "creating constant with the wrong size"); // Test ConstantInt version breaks ConstantInt *CI = ConstantInt::get(Ctx, APV32); EXPECT_DEATH(B.buildConstant(LLT::scalar(16), *CI), "creating constant with the wrong size"); EXPECT_DEATH(B.buildConstant(LLT::vector(2, 16), *CI), "creating constant with the wrong size"); APFloat DoubleVal(APFloat::IEEEdouble()); ConstantFP *CF = ConstantFP::get(Ctx, DoubleVal); EXPECT_DEATH(B.buildFConstant(LLT::scalar(16), *CF), "creating fconstant with the wrong size"); EXPECT_DEATH(B.buildFConstant(LLT::vector(2, 16), *CF), "creating fconstant with the wrong size"); } #endif #endif TEST_F(AArch64GISelMITest, DstOpSrcOp) { setUp(); if (!TM) return; SmallVector Copies; collectCopies(Copies, MF); LLT s64 = LLT::scalar(64); auto MIBAdd = B.buildAdd(s64, Copies[0], Copies[1]); // Test SrcOp and DstOp can be constructed directly from MachineOperand by // copying the instruction B.buildAdd(MIBAdd->getOperand(0), MIBAdd->getOperand(1), MIBAdd->getOperand(2)); auto CheckStr = R"( ; CHECK: [[COPY0:%[0-9]+]]:_(s64) = COPY $x0 ; CHECK: [[COPY1:%[0-9]+]]:_(s64) = COPY $x1 ; CHECK: [[ADD:%[0-9]+]]:_(s64) = G_ADD [[COPY0]]:_, [[COPY1]]:_ ; CHECK: [[ADD]]:_(s64) = G_ADD [[COPY0]]:_, [[COPY1]]:_ )"; EXPECT_TRUE(CheckMachineFunction(*MF, CheckStr)) << *MF; } TEST_F(AArch64GISelMITest, BuildUnmerge) { setUp(); if (!TM) return; SmallVector Copies; collectCopies(Copies, MF); B.buildUnmerge(LLT::scalar(32), Copies[0]); B.buildUnmerge(LLT::scalar(16), Copies[1]); auto CheckStr = R"( ; CHECK: [[COPY0:%[0-9]+]]:_(s64) = COPY $x0 ; CHECK: [[COPY1:%[0-9]+]]:_(s64) = COPY $x1 ; CHECK: [[UNMERGE32_0:%[0-9]+]]:_(s32), [[UNMERGE32_1:%[0-9]+]]:_(s32) = G_UNMERGE_VALUES [[COPY0]] ; CHECK: [[UNMERGE16_0:%[0-9]+]]:_(s16), [[UNMERGE16_1:%[0-9]+]]:_(s16), [[UNMERGE16_2:%[0-9]+]]:_(s16), [[UNMERGE16_3:%[0-9]+]]:_(s16) = G_UNMERGE_VALUES [[COPY1]] )"; EXPECT_TRUE(CheckMachineFunction(*MF, CheckStr)) << *MF; } TEST_F(AArch64GISelMITest, TestBuildFPInsts) { setUp(); if (!TM) return; SmallVector Copies; collectCopies(Copies, MF); LLT S64 = LLT::scalar(64); B.buildFAdd(S64, Copies[0], Copies[1]); B.buildFSub(S64, Copies[0], Copies[1]); B.buildFMA(S64, Copies[0], Copies[1], Copies[2]); B.buildFMAD(S64, Copies[0], Copies[1], Copies[2]); B.buildFMAD(S64, Copies[0], Copies[1], Copies[2], MachineInstr::FmNoNans); B.buildFNeg(S64, Copies[0]); B.buildFAbs(S64, Copies[0]); B.buildFCopysign(S64, Copies[0], Copies[1]); auto CheckStr = R"( ; CHECK: [[COPY0:%[0-9]+]]:_(s64) = COPY $x0 ; CHECK: [[COPY1:%[0-9]+]]:_(s64) = COPY $x1 ; CHECK: [[COPY2:%[0-9]+]]:_(s64) = COPY $x2 ; CHECK: [[FADD:%[0-9]+]]:_(s64) = G_FADD [[COPY0]]:_, [[COPY1]]:_ ; CHECK: [[FSUB:%[0-9]+]]:_(s64) = G_FSUB [[COPY0]]:_, [[COPY1]]:_ ; CHECK: [[FMA:%[0-9]+]]:_(s64) = G_FMA [[COPY0]]:_, [[COPY1]]:_, [[COPY2]]:_ ; CHECK: [[FMAD0:%[0-9]+]]:_(s64) = G_FMAD [[COPY0]]:_, [[COPY1]]:_, [[COPY2]]:_ ; CHECK: [[FMAD1:%[0-9]+]]:_(s64) = nnan G_FMAD [[COPY0]]:_, [[COPY1]]:_, [[COPY2]]:_ ; CHECK: [[FNEG:%[0-9]+]]:_(s64) = G_FNEG [[COPY0]]:_ ; CHECK: [[FABS:%[0-9]+]]:_(s64) = G_FABS [[COPY0]]:_ ; CHECK: [[FCOPYSIGN:%[0-9]+]]:_(s64) = G_FCOPYSIGN [[COPY0]]:_, [[COPY1]]:_ )"; EXPECT_TRUE(CheckMachineFunction(*MF, CheckStr)) << *MF; } TEST_F(AArch64GISelMITest, BuildIntrinsic) { setUp(); if (!TM) return; LLT S64 = LLT::scalar(64); SmallVector Copies; collectCopies(Copies, MF); // Make sure DstOp version works. sqrt is just a placeholder intrinsic. B.buildIntrinsic(Intrinsic::sqrt, {S64}, false) .addUse(Copies[0]); // Make sure register version works SmallVector Results; Results.push_back(MRI->createGenericVirtualRegister(S64)); B.buildIntrinsic(Intrinsic::sqrt, Results, false) .addUse(Copies[1]); auto CheckStr = R"( ; CHECK: [[COPY0:%[0-9]+]]:_(s64) = COPY $x0 ; CHECK: [[COPY1:%[0-9]+]]:_(s64) = COPY $x1 ; CHECK: [[SQRT0:%[0-9]+]]:_(s64) = G_INTRINSIC intrinsic(@llvm.sqrt), [[COPY0]]:_ ; CHECK: [[SQRT1:%[0-9]+]]:_(s64) = G_INTRINSIC intrinsic(@llvm.sqrt), [[COPY1]]:_ )"; EXPECT_TRUE(CheckMachineFunction(*MF, CheckStr)) << *MF; } TEST_F(AArch64GISelMITest, BuildXor) { setUp(); if (!TM) return; LLT S64 = LLT::scalar(64); LLT S128 = LLT::scalar(128); SmallVector Copies; collectCopies(Copies, MF); B.buildXor(S64, Copies[0], Copies[1]); B.buildNot(S64, Copies[0]); // Make sure this works with > 64-bit types auto Merge = B.buildMerge(S128, {Copies[0], Copies[1]}); B.buildNot(S128, Merge); auto CheckStr = R"( ; CHECK: [[COPY0:%[0-9]+]]:_(s64) = COPY $x0 ; CHECK: [[COPY1:%[0-9]+]]:_(s64) = COPY $x1 ; CHECK: [[XOR0:%[0-9]+]]:_(s64) = G_XOR [[COPY0]]:_, [[COPY1]]:_ ; CHECK: [[NEGONE64:%[0-9]+]]:_(s64) = G_CONSTANT i64 -1 ; CHECK: [[XOR1:%[0-9]+]]:_(s64) = G_XOR [[COPY0]]:_, [[NEGONE64]]:_ ; CHECK: [[MERGE:%[0-9]+]]:_(s128) = G_MERGE_VALUES [[COPY0]]:_(s64), [[COPY1]]:_(s64) ; CHECK: [[NEGONE128:%[0-9]+]]:_(s128) = G_CONSTANT i128 -1 ; CHECK: [[XOR2:%[0-9]+]]:_(s128) = G_XOR [[MERGE]]:_, [[NEGONE128]]:_ )"; EXPECT_TRUE(CheckMachineFunction(*MF, CheckStr)) << *MF; } TEST_F(AArch64GISelMITest, BuildBitCounts) { setUp(); if (!TM) return; LLT S32 = LLT::scalar(32); SmallVector Copies; collectCopies(Copies, MF); B.buildCTPOP(S32, Copies[0]); B.buildCTLZ(S32, Copies[0]); B.buildCTLZ_ZERO_UNDEF(S32, Copies[1]); B.buildCTTZ(S32, Copies[0]); B.buildCTTZ_ZERO_UNDEF(S32, Copies[1]); auto CheckStr = R"( ; CHECK: [[COPY0:%[0-9]+]]:_(s64) = COPY $x0 ; CHECK: [[COPY1:%[0-9]+]]:_(s64) = COPY $x1 ; CHECK: [[CTPOP:%[0-9]+]]:_(s32) = G_CTPOP [[COPY0]]:_ ; CHECK: [[CTLZ0:%[0-9]+]]:_(s32) = G_CTLZ [[COPY0]]:_ ; CHECK: [[CTLZ_UNDEF0:%[0-9]+]]:_(s32) = G_CTLZ_ZERO_UNDEF [[COPY1]]:_ ; CHECK: [[CTTZ:%[0-9]+]]:_(s32) = G_CTTZ [[COPY0]]:_ ; CHECK: [[CTTZ_UNDEF0:%[0-9]+]]:_(s32) = G_CTTZ_ZERO_UNDEF [[COPY1]]:_ )"; EXPECT_TRUE(CheckMachineFunction(*MF, CheckStr)) << *MF; } TEST_F(AArch64GISelMITest, BuildCasts) { setUp(); if (!TM) return; LLT S32 = LLT::scalar(32); SmallVector Copies; collectCopies(Copies, MF); B.buildUITOFP(S32, Copies[0]); B.buildSITOFP(S32, Copies[0]); B.buildFPTOUI(S32, Copies[0]); B.buildFPTOSI(S32, Copies[0]); auto CheckStr = R"( ; CHECK: [[COPY0:%[0-9]+]]:_(s64) = COPY $x0 ; CHECK: [[UITOFP:%[0-9]+]]:_(s32) = G_UITOFP [[COPY0]]:_ ; CHECK: [[SITOFP:%[0-9]+]]:_(s32) = G_SITOFP [[COPY0]]:_ ; CHECK: [[FPTOUI:%[0-9]+]]:_(s32) = G_FPTOUI [[COPY0]]:_ ; CHECK: [[FPTOSI:%[0-9]+]]:_(s32) = G_FPTOSI [[COPY0]]:_ )"; EXPECT_TRUE(CheckMachineFunction(*MF, CheckStr)) << *MF; } TEST_F(AArch64GISelMITest, BuildMinMaxAbs) { setUp(); if (!TM) return; LLT S64 = LLT::scalar(64); SmallVector Copies; collectCopies(Copies, MF); B.buildSMin(S64, Copies[0], Copies[1]); B.buildSMax(S64, Copies[0], Copies[1]); B.buildUMin(S64, Copies[0], Copies[1]); B.buildUMax(S64, Copies[0], Copies[1]); B.buildAbs(S64, Copies[0]); auto CheckStr = R"( ; CHECK: [[COPY0:%[0-9]+]]:_(s64) = COPY $x0 ; CHECK: [[COPY1:%[0-9]+]]:_(s64) = COPY $x1 ; CHECK: [[SMIN0:%[0-9]+]]:_(s64) = G_SMIN [[COPY0]]:_, [[COPY1]]:_ ; CHECK: [[SMAX0:%[0-9]+]]:_(s64) = G_SMAX [[COPY0]]:_, [[COPY1]]:_ ; CHECK: [[UMIN0:%[0-9]+]]:_(s64) = G_UMIN [[COPY0]]:_, [[COPY1]]:_ ; CHECK: [[UMAX0:%[0-9]+]]:_(s64) = G_UMAX [[COPY0]]:_, [[COPY1]]:_ ; CHECK: [[UABS0:%[0-9]+]]:_(s64) = G_ABS [[COPY0]]:_ )"; EXPECT_TRUE(CheckMachineFunction(*MF, CheckStr)) << *MF; } TEST_F(AArch64GISelMITest, BuildAtomicRMW) { setUp(); if (!TM) return; LLT S64 = LLT::scalar(64); LLT P0 = LLT::pointer(0, 64); SmallVector Copies; collectCopies(Copies, MF); MachineMemOperand *MMO = MF->getMachineMemOperand( MachinePointerInfo(), MachineMemOperand::MOLoad | MachineMemOperand::MOStore, 8, Align(8), AAMDNodes(), nullptr, SyncScope::System, AtomicOrdering::Unordered); auto Ptr = B.buildUndef(P0); B.buildAtomicRMWFAdd(S64, Ptr, Copies[0], *MMO); B.buildAtomicRMWFSub(S64, Ptr, Copies[0], *MMO); auto CheckStr = R"( ; CHECK: [[COPY0:%[0-9]+]]:_(s64) = COPY $x0 ; CHECK: [[COPY1:%[0-9]+]]:_(s64) = COPY $x1 ; CHECK: [[PTR:%[0-9]+]]:_(p0) = G_IMPLICIT_DEF ; CHECK: [[FADD:%[0-9]+]]:_(s64) = G_ATOMICRMW_FADD [[PTR]]:_(p0), [[COPY0]]:_ :: (load store unordered 8) ; CHECK: [[FSUB:%[0-9]+]]:_(s64) = G_ATOMICRMW_FSUB [[PTR]]:_(p0), [[COPY0]]:_ :: (load store unordered 8) )"; EXPECT_TRUE(CheckMachineFunction(*MF, CheckStr)) << *MF; } TEST_F(AArch64GISelMITest, BuildMerge) { setUp(); if (!TM) return; LLT S32 = LLT::scalar(32); Register RegC0 = B.buildConstant(S32, 0).getReg(0); Register RegC1 = B.buildConstant(S32, 1).getReg(0); Register RegC2 = B.buildConstant(S32, 2).getReg(0); Register RegC3 = B.buildConstant(S32, 3).getReg(0); // Merging plain constants as one big blob of bit should produce a // G_MERGE_VALUES. B.buildMerge(LLT::scalar(128), {RegC0, RegC1, RegC2, RegC3}); // Merging plain constants to a vector should produce a G_BUILD_VECTOR. LLT V2x32 = LLT::vector(2, 32); Register RegC0C1 = B.buildMerge(V2x32, {RegC0, RegC1}).getReg(0); Register RegC2C3 = B.buildMerge(V2x32, {RegC2, RegC3}).getReg(0); // Merging vector constants to a vector should produce a G_CONCAT_VECTORS. B.buildMerge(LLT::vector(4, 32), {RegC0C1, RegC2C3}); // Merging vector constants to a plain type is not allowed. // Nothing else to test. auto CheckStr = R"( ; CHECK: [[C0:%[0-9]+]]:_(s32) = G_CONSTANT i32 0 ; CHECK: [[C1:%[0-9]+]]:_(s32) = G_CONSTANT i32 1 ; CHECK: [[C2:%[0-9]+]]:_(s32) = G_CONSTANT i32 2 ; CHECK: [[C3:%[0-9]+]]:_(s32) = G_CONSTANT i32 3 ; CHECK: {{%[0-9]+}}:_(s128) = G_MERGE_VALUES [[C0]]:_(s32), [[C1]]:_(s32), [[C2]]:_(s32), [[C3]]:_(s32) ; CHECK: [[LOW2x32:%[0-9]+]]:_(<2 x s32>) = G_BUILD_VECTOR [[C0]]:_(s32), [[C1]]:_(s32) ; CHECK: [[HIGH2x32:%[0-9]+]]:_(<2 x s32>) = G_BUILD_VECTOR [[C2]]:_(s32), [[C3]]:_(s32) ; CHECK: {{%[0-9]+}}:_(<4 x s32>) = G_CONCAT_VECTORS [[LOW2x32]]:_(<2 x s32>), [[HIGH2x32]]:_(<2 x s32>) )"; EXPECT_TRUE(CheckMachineFunction(*MF, CheckStr)) << *MF; } TEST_F(AArch64GISelMITest, BuildAddoSubo) { setUp(); if (!TM) return; LLT S1 = LLT::scalar(1); LLT S64 = LLT::scalar(64); SmallVector Copies; collectCopies(Copies, MF); auto UAddo = B.buildUAddo(S64, S1, Copies[0], Copies[1]); auto USubo = B.buildUSubo(S64, S1, Copies[0], Copies[1]); auto SAddo = B.buildSAddo(S64, S1, Copies[0], Copies[1]); auto SSubo = B.buildSSubo(S64, S1, Copies[0], Copies[1]); B.buildUAdde(S64, S1, Copies[0], Copies[1], UAddo.getReg(1)); B.buildUSube(S64, S1, Copies[0], Copies[1], USubo.getReg(1)); B.buildSAdde(S64, S1, Copies[0], Copies[1], SAddo.getReg(1)); B.buildSSube(S64, S1, Copies[0], Copies[1], SSubo.getReg(1)); auto CheckStr = R"( ; CHECK: [[COPY0:%[0-9]+]]:_(s64) = COPY $x0 ; CHECK: [[COPY1:%[0-9]+]]:_(s64) = COPY $x1 ; CHECK: [[UADDO:%[0-9]+]]:_(s64), [[UADDO_FLAG:%[0-9]+]]:_(s1) = G_UADDO [[COPY0]]:_, [[COPY1]]:_ ; CHECK: [[USUBO:%[0-9]+]]:_(s64), [[USUBO_FLAG:%[0-9]+]]:_(s1) = G_USUBO [[COPY0]]:_, [[COPY1]]:_ ; CHECK: [[SADDO:%[0-9]+]]:_(s64), [[SADDO_FLAG:%[0-9]+]]:_(s1) = G_SADDO [[COPY0]]:_, [[COPY1]]:_ ; CHECK: [[SSUBO:%[0-9]+]]:_(s64), [[SSUBO_FLAG:%[0-9]+]]:_(s1) = G_SSUBO [[COPY0]]:_, [[COPY1]]:_ ; CHECK: [[UADDE:%[0-9]+]]:_(s64), [[UADDE_FLAG:%[0-9]+]]:_(s1) = G_UADDE [[COPY0]]:_, [[COPY1]]:_, [[UADDO_FLAG]] ; CHECK: [[USUBE:%[0-9]+]]:_(s64), [[USUBE_FLAG:%[0-9]+]]:_(s1) = G_USUBE [[COPY0]]:_, [[COPY1]]:_, [[USUBO_FLAG]] ; CHECK: [[SADDE:%[0-9]+]]:_(s64), [[SADDE_FLAG:%[0-9]+]]:_(s1) = G_SADDE [[COPY0]]:_, [[COPY1]]:_, [[SADDO_FLAG]] ; CHECK: [[SSUBE:%[0-9]+]]:_(s64), [[SSUBE_FLAG:%[0-9]+]]:_(s1) = G_SSUBE [[COPY0]]:_, [[COPY1]]:_, [[SSUBO_FLAG]] )"; EXPECT_TRUE(CheckMachineFunction(*MF, CheckStr)) << *MF; }