//===- MachineOperandTest.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 "llvm/CodeGen/MachineOperand.h" #include "llvm/ADT/ilist_node.h" #include "llvm/IR/Constants.h" #include "llvm/IR/InstrTypes.h" #include "llvm/IR/LLVMContext.h" #include "llvm/IR/Module.h" #include "llvm/IR/ModuleSlotTracker.h" #include "llvm/MC/MCContext.h" #include "llvm/MC/MCAsmInfo.h" #include "llvm/Support/raw_ostream.h" #include "gtest/gtest.h" using namespace llvm; namespace { TEST(MachineOperandTest, ChangeToTargetIndexTest) { // Creating a MachineOperand to change it to TargetIndex MachineOperand MO = MachineOperand::CreateImm(50); // Checking some precondition on the newly created // MachineOperand. ASSERT_TRUE(MO.isImm()); ASSERT_TRUE(MO.getImm() == 50); ASSERT_FALSE(MO.isTargetIndex()); // Changing to TargetIndex with some arbitrary values // for index, offset and flags. MO.ChangeToTargetIndex(74, 57, 12); // Checking that the mutation to TargetIndex happened // correctly. ASSERT_TRUE(MO.isTargetIndex()); ASSERT_TRUE(MO.getIndex() == 74); ASSERT_TRUE(MO.getOffset() == 57); ASSERT_TRUE(MO.getTargetFlags() == 12); } TEST(MachineOperandTest, PrintRegisterMask) { uint32_t Dummy; MachineOperand MO = MachineOperand::CreateRegMask(&Dummy); // Checking some preconditions on the newly created // MachineOperand. ASSERT_TRUE(MO.isRegMask()); ASSERT_TRUE(MO.getRegMask() == &Dummy); // Print a MachineOperand containing a RegMask. Here we check that without a // TRI and IntrinsicInfo we still print a less detailed regmask. std::string str; raw_string_ostream OS(str); MO.print(OS, /*TRI=*/nullptr, /*IntrinsicInfo=*/nullptr); ASSERT_TRUE(OS.str() == ""); } TEST(MachineOperandTest, PrintSubReg) { // Create a MachineOperand with RegNum=1 and SubReg=5. MachineOperand MO = MachineOperand::CreateReg( /*Reg=*/1, /*isDef=*/false, /*isImp=*/false, /*isKill=*/false, /*isDead=*/false, /*isUndef=*/false, /*isEarlyClobber=*/false, /*SubReg=*/5, /*isDebug=*/false, /*isInternalRead=*/false); // Checking some preconditions on the newly created // MachineOperand. ASSERT_TRUE(MO.isReg()); ASSERT_TRUE(MO.getReg() == 1); ASSERT_TRUE(MO.getSubReg() == 5); // Print a MachineOperand containing a SubReg. Here we check that without a // TRI and IntrinsicInfo we can still print the subreg index. std::string str; raw_string_ostream OS(str); MO.print(OS, /*TRI=*/nullptr, /*IntrinsicInfo=*/nullptr); ASSERT_TRUE(OS.str() == "$physreg1.subreg5"); } TEST(MachineOperandTest, PrintCImm) { LLVMContext Context; APInt Int(128, UINT64_MAX); ++Int; ConstantInt *CImm = ConstantInt::get(Context, Int); // Create a MachineOperand with an Imm=(UINT64_MAX + 1) MachineOperand MO = MachineOperand::CreateCImm(CImm); // Checking some preconditions on the newly created // MachineOperand. ASSERT_TRUE(MO.isCImm()); ASSERT_TRUE(MO.getCImm() == CImm); ASSERT_TRUE(MO.getCImm()->getValue() == Int); // Print a MachineOperand containing a SubReg. Here we check that without a // TRI and IntrinsicInfo we can still print the subreg index. std::string str; raw_string_ostream OS(str); MO.print(OS, /*TRI=*/nullptr, /*IntrinsicInfo=*/nullptr); ASSERT_TRUE(OS.str() == "i128 18446744073709551616"); } TEST(MachineOperandTest, PrintSubRegIndex) { // Create a MachineOperand with an immediate and print it as a subreg index. MachineOperand MO = MachineOperand::CreateImm(3); // Checking some preconditions on the newly created // MachineOperand. ASSERT_TRUE(MO.isImm()); ASSERT_TRUE(MO.getImm() == 3); // Print a MachineOperand containing a SubRegIdx. Here we check that without a // TRI and IntrinsicInfo we can print the operand as a subreg index. std::string str; raw_string_ostream OS(str); MachineOperand::printSubRegIdx(OS, MO.getImm(), nullptr); ASSERT_TRUE(OS.str() == "%subreg.3"); } TEST(MachineOperandTest, PrintCPI) { // Create a MachineOperand with a constant pool index and print it. MachineOperand MO = MachineOperand::CreateCPI(0, 8); // Checking some preconditions on the newly created // MachineOperand. ASSERT_TRUE(MO.isCPI()); ASSERT_TRUE(MO.getIndex() == 0); ASSERT_TRUE(MO.getOffset() == 8); // Print a MachineOperand containing a constant pool index and a positive // offset. std::string str; { raw_string_ostream OS(str); MO.print(OS, /*TRI=*/nullptr, /*IntrinsicInfo=*/nullptr); ASSERT_TRUE(OS.str() == "%const.0 + 8"); } str.clear(); MO.setOffset(-12); // Print a MachineOperand containing a constant pool index and a negative // offset. { raw_string_ostream OS(str); MO.print(OS, /*TRI=*/nullptr, /*IntrinsicInfo=*/nullptr); ASSERT_TRUE(OS.str() == "%const.0 - 12"); } } TEST(MachineOperandTest, PrintTargetIndexName) { // Create a MachineOperand with a target index and print it. MachineOperand MO = MachineOperand::CreateTargetIndex(0, 8); // Checking some preconditions on the newly created // MachineOperand. ASSERT_TRUE(MO.isTargetIndex()); ASSERT_TRUE(MO.getIndex() == 0); ASSERT_TRUE(MO.getOffset() == 8); // Print a MachineOperand containing a target index and a positive offset. std::string str; { raw_string_ostream OS(str); MO.print(OS, /*TRI=*/nullptr, /*IntrinsicInfo=*/nullptr); ASSERT_TRUE(OS.str() == "target-index() + 8"); } str.clear(); MO.setOffset(-12); // Print a MachineOperand containing a target index and a negative offset. { raw_string_ostream OS(str); MO.print(OS, /*TRI=*/nullptr, /*IntrinsicInfo=*/nullptr); ASSERT_TRUE(OS.str() == "target-index() - 12"); } } TEST(MachineOperandTest, PrintJumpTableIndex) { // Create a MachineOperand with a jump-table index and print it. MachineOperand MO = MachineOperand::CreateJTI(3); // Checking some preconditions on the newly created // MachineOperand. ASSERT_TRUE(MO.isJTI()); ASSERT_TRUE(MO.getIndex() == 3); // Print a MachineOperand containing a jump-table index. std::string str; raw_string_ostream OS(str); MO.print(OS, /*TRI=*/nullptr, /*IntrinsicInfo=*/nullptr); ASSERT_TRUE(OS.str() == "%jump-table.3"); } TEST(MachineOperandTest, PrintExternalSymbol) { // Create a MachineOperand with an external symbol and print it. MachineOperand MO = MachineOperand::CreateES("foo"); // Checking some preconditions on the newly created // MachineOperand. ASSERT_TRUE(MO.isSymbol()); ASSERT_TRUE(MO.getSymbolName() == StringRef("foo")); // Print a MachineOperand containing an external symbol and no offset. std::string str; { raw_string_ostream OS(str); MO.print(OS, /*TRI=*/nullptr, /*IntrinsicInfo=*/nullptr); ASSERT_TRUE(OS.str() == "&foo"); } str.clear(); MO.setOffset(12); // Print a MachineOperand containing an external symbol and a positive offset. { raw_string_ostream OS(str); MO.print(OS, /*TRI=*/nullptr, /*IntrinsicInfo=*/nullptr); ASSERT_TRUE(OS.str() == "&foo + 12"); } str.clear(); MO.setOffset(-12); // Print a MachineOperand containing an external symbol and a negative offset. { raw_string_ostream OS(str); MO.print(OS, /*TRI=*/nullptr, /*IntrinsicInfo=*/nullptr); ASSERT_TRUE(OS.str() == "&foo - 12"); } } TEST(MachineOperandTest, PrintGlobalAddress) { LLVMContext Ctx; Module M("MachineOperandGVTest", Ctx); M.getOrInsertGlobal("foo", Type::getInt32Ty(Ctx)); GlobalValue *GV = M.getNamedValue("foo"); // Create a MachineOperand with a global address and a positive offset and // print it. MachineOperand MO = MachineOperand::CreateGA(GV, 12); // Checking some preconditions on the newly created // MachineOperand. ASSERT_TRUE(MO.isGlobal()); ASSERT_TRUE(MO.getGlobal() == GV); ASSERT_TRUE(MO.getOffset() == 12); std::string str; // Print a MachineOperand containing a global address and a positive offset. { raw_string_ostream OS(str); MO.print(OS, /*TRI=*/nullptr, /*IntrinsicInfo=*/nullptr); ASSERT_TRUE(OS.str() == "@foo + 12"); } str.clear(); MO.setOffset(-12); // Print a MachineOperand containing a global address and a negative offset. { raw_string_ostream OS(str); MO.print(OS, /*TRI=*/nullptr, /*IntrinsicInfo=*/nullptr); ASSERT_TRUE(OS.str() == "@foo - 12"); } } TEST(MachineOperandTest, PrintRegisterLiveOut) { // Create a MachineOperand with a register live out list and print it. uint32_t Mask = 0; MachineOperand MO = MachineOperand::CreateRegLiveOut(&Mask); // Checking some preconditions on the newly created // MachineOperand. ASSERT_TRUE(MO.isRegLiveOut()); ASSERT_TRUE(MO.getRegLiveOut() == &Mask); std::string str; // Print a MachineOperand containing a register live out list without a TRI. raw_string_ostream OS(str); MO.print(OS, /*TRI=*/nullptr, /*IntrinsicInfo=*/nullptr); ASSERT_TRUE(OS.str() == "liveout()"); } TEST(MachineOperandTest, PrintMetadata) { LLVMContext Ctx; Module M("MachineOperandMDNodeTest", Ctx); NamedMDNode *MD = M.getOrInsertNamedMetadata("namedmd"); ModuleSlotTracker MST(&M); Metadata *MDS = MDString::get(Ctx, "foo"); MDNode *Node = MDNode::get(Ctx, MDS); MD->addOperand(Node); // Create a MachineOperand with a metadata and print it. MachineOperand MO = MachineOperand::CreateMetadata(Node); // Checking some preconditions on the newly created // MachineOperand. ASSERT_TRUE(MO.isMetadata()); ASSERT_TRUE(MO.getMetadata() == Node); std::string str; // Print a MachineOperand containing a metadata node. raw_string_ostream OS(str); MO.print(OS, MST, LLT{}, /*OpIdx*/~0U, /*PrintDef=*/false, /*IsStandalone=*/false, /*ShouldPrintRegisterTies=*/false, 0, /*TRI=*/nullptr, /*IntrinsicInfo=*/nullptr); ASSERT_TRUE(OS.str() == "!0"); } TEST(MachineOperandTest, PrintMCSymbol) { MCAsmInfo MAI; MCContext Ctx(&MAI, /*MRI=*/nullptr, /*MOFI=*/nullptr); MCSymbol *Sym = Ctx.getOrCreateSymbol("foo"); // Create a MachineOperand with a metadata and print it. MachineOperand MO = MachineOperand::CreateMCSymbol(Sym); // Checking some preconditions on the newly created // MachineOperand. ASSERT_TRUE(MO.isMCSymbol()); ASSERT_TRUE(MO.getMCSymbol() == Sym); std::string str; // Print a MachineOperand containing a metadata node. raw_string_ostream OS(str); MO.print(OS, /*TRI=*/nullptr, /*IntrinsicInfo=*/nullptr); ASSERT_TRUE(OS.str() == ""); } TEST(MachineOperandTest, PrintCFI) { // Create a MachineOperand with a CFI index but no function and print it. MachineOperand MO = MachineOperand::CreateCFIIndex(8); // Checking some preconditions on the newly created // MachineOperand. ASSERT_TRUE(MO.isCFIIndex()); ASSERT_TRUE(MO.getCFIIndex() == 8); std::string str; // Print a MachineOperand containing a CFI Index node but no machine function // attached to it. raw_string_ostream OS(str); MO.print(OS, /*TRI=*/nullptr, /*IntrinsicInfo=*/nullptr); ASSERT_TRUE(OS.str() == ""); } TEST(MachineOperandTest, PrintIntrinsicID) { // Create a MachineOperand with a generic intrinsic ID. MachineOperand MO = MachineOperand::CreateIntrinsicID(Intrinsic::bswap); // Checking some preconditions on the newly created // MachineOperand. ASSERT_TRUE(MO.isIntrinsicID()); ASSERT_TRUE(MO.getIntrinsicID() == Intrinsic::bswap); std::string str; { // Print a MachineOperand containing a generic intrinsic ID. raw_string_ostream OS(str); MO.print(OS, /*TRI=*/nullptr, /*IntrinsicInfo=*/nullptr); ASSERT_TRUE(OS.str() == "intrinsic(@llvm.bswap)"); } str.clear(); // Set a target-specific intrinsic. MO = MachineOperand::CreateIntrinsicID((Intrinsic::ID)-1); { // Print a MachineOperand containing a target-specific intrinsic ID but not // IntrinsicInfo. raw_string_ostream OS(str); MO.print(OS, /*TRI=*/nullptr, /*IntrinsicInfo=*/nullptr); ASSERT_TRUE(OS.str() == "intrinsic(4294967295)"); } } TEST(MachineOperandTest, PrintPredicate) { // Create a MachineOperand with a generic intrinsic ID. MachineOperand MO = MachineOperand::CreatePredicate(CmpInst::ICMP_EQ); // Checking some preconditions on the newly created // MachineOperand. ASSERT_TRUE(MO.isPredicate()); ASSERT_TRUE(MO.getPredicate() == CmpInst::ICMP_EQ); std::string str; // Print a MachineOperand containing a int predicate ICMP_EQ. raw_string_ostream OS(str); MO.print(OS, /*TRI=*/nullptr, /*IntrinsicInfo=*/nullptr); ASSERT_TRUE(OS.str() == "intpred(eq)"); } TEST(MachineOperandTest, HashValue) { char SymName1[] = "test"; char SymName2[] = "test"; MachineOperand MO1 = MachineOperand::CreateES(SymName1); MachineOperand MO2 = MachineOperand::CreateES(SymName2); ASSERT_NE(SymName1, SymName2); ASSERT_EQ(hash_value(MO1), hash_value(MO2)); ASSERT_TRUE(MO1.isIdenticalTo(MO2)); } } // end namespace