//===- MIParser.cpp - Machine instructions parser implementation ----------===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // This file implements the parsing of machine instructions. // //===----------------------------------------------------------------------===// #include "MIParser.h" #include "MILexer.h" #include "llvm/ADT/StringMap.h" #include "llvm/AsmParser/SlotMapping.h" #include "llvm/CodeGen/MachineBasicBlock.h" #include "llvm/CodeGen/MachineFunction.h" #include "llvm/CodeGen/MachineInstr.h" #include "llvm/CodeGen/MachineInstrBuilder.h" #include "llvm/IR/Module.h" #include "llvm/Support/raw_ostream.h" #include "llvm/Support/SourceMgr.h" #include "llvm/Target/TargetSubtargetInfo.h" #include "llvm/Target/TargetInstrInfo.h" using namespace llvm; namespace { /// A wrapper struct around the 'MachineOperand' struct that includes a source /// range. struct MachineOperandWithLocation { MachineOperand Operand; StringRef::iterator Begin; StringRef::iterator End; MachineOperandWithLocation(const MachineOperand &Operand, StringRef::iterator Begin, StringRef::iterator End) : Operand(Operand), Begin(Begin), End(End) {} }; class MIParser { SourceMgr &SM; MachineFunction &MF; SMDiagnostic &Error; StringRef Source, CurrentSource; MIToken Token; const PerFunctionMIParsingState &PFS; /// Maps from indices to unnamed global values and metadata nodes. const SlotMapping &IRSlots; /// Maps from instruction names to op codes. StringMap Names2InstrOpCodes; /// Maps from register names to registers. StringMap Names2Regs; /// Maps from register mask names to register masks. StringMap Names2RegMasks; /// Maps from subregister names to subregister indices. StringMap Names2SubRegIndices; public: MIParser(SourceMgr &SM, MachineFunction &MF, SMDiagnostic &Error, StringRef Source, const PerFunctionMIParsingState &PFS, const SlotMapping &IRSlots); void lex(); /// Report an error at the current location with the given message. /// /// This function always return true. bool error(const Twine &Msg); /// Report an error at the given location with the given message. /// /// This function always return true. bool error(StringRef::iterator Loc, const Twine &Msg); bool parse(MachineInstr *&MI); bool parseMBB(MachineBasicBlock *&MBB); bool parseNamedRegister(unsigned &Reg); bool parseRegister(unsigned &Reg); bool parseRegisterFlag(unsigned &Flags); bool parseSubRegisterIndex(unsigned &SubReg); bool parseRegisterOperand(MachineOperand &Dest, bool IsDef = false); bool parseImmediateOperand(MachineOperand &Dest); bool parseMBBReference(MachineBasicBlock *&MBB); bool parseMBBOperand(MachineOperand &Dest); bool parseGlobalAddressOperand(MachineOperand &Dest); bool parseMachineOperand(MachineOperand &Dest); private: /// Convert the integer literal in the current token into an unsigned integer. /// /// Return true if an error occurred. bool getUnsigned(unsigned &Result); void initNames2InstrOpCodes(); /// Try to convert an instruction name to an opcode. Return true if the /// instruction name is invalid. bool parseInstrName(StringRef InstrName, unsigned &OpCode); bool parseInstruction(unsigned &OpCode); bool verifyImplicitOperands(ArrayRef Operands, const MCInstrDesc &MCID); void initNames2Regs(); /// Try to convert a register name to a register number. Return true if the /// register name is invalid. bool getRegisterByName(StringRef RegName, unsigned &Reg); void initNames2RegMasks(); /// Check if the given identifier is a name of a register mask. /// /// Return null if the identifier isn't a register mask. const uint32_t *getRegMask(StringRef Identifier); void initNames2SubRegIndices(); /// Check if the given identifier is a name of a subregister index. /// /// Return 0 if the name isn't a subregister index class. unsigned getSubRegIndex(StringRef Name); }; } // end anonymous namespace MIParser::MIParser(SourceMgr &SM, MachineFunction &MF, SMDiagnostic &Error, StringRef Source, const PerFunctionMIParsingState &PFS, const SlotMapping &IRSlots) : SM(SM), MF(MF), Error(Error), Source(Source), CurrentSource(Source), Token(MIToken::Error, StringRef()), PFS(PFS), IRSlots(IRSlots) {} void MIParser::lex() { CurrentSource = lexMIToken( CurrentSource, Token, [this](StringRef::iterator Loc, const Twine &Msg) { error(Loc, Msg); }); } bool MIParser::error(const Twine &Msg) { return error(Token.location(), Msg); } bool MIParser::error(StringRef::iterator Loc, const Twine &Msg) { assert(Loc >= Source.data() && Loc <= (Source.data() + Source.size())); Error = SMDiagnostic( SM, SMLoc(), SM.getMemoryBuffer(SM.getMainFileID())->getBufferIdentifier(), 1, Loc - Source.data(), SourceMgr::DK_Error, Msg.str(), Source, None, None); return true; } bool MIParser::parse(MachineInstr *&MI) { lex(); // Parse any register operands before '=' // TODO: Allow parsing of multiple operands before '=' MachineOperand MO = MachineOperand::CreateImm(0); SmallVector Operands; if (Token.isRegister() || Token.isRegisterFlag()) { auto Loc = Token.location(); if (parseRegisterOperand(MO, /*IsDef=*/true)) return true; Operands.push_back(MachineOperandWithLocation(MO, Loc, Token.location())); if (Token.isNot(MIToken::equal)) return error("expected '='"); lex(); } unsigned OpCode; if (Token.isError() || parseInstruction(OpCode)) return true; // TODO: Parse the instruction flags and memory operands. // Parse the remaining machine operands. while (Token.isNot(MIToken::Eof)) { auto Loc = Token.location(); if (parseMachineOperand(MO)) return true; Operands.push_back(MachineOperandWithLocation(MO, Loc, Token.location())); if (Token.is(MIToken::Eof)) break; if (Token.isNot(MIToken::comma)) return error("expected ',' before the next machine operand"); lex(); } const auto &MCID = MF.getSubtarget().getInstrInfo()->get(OpCode); if (!MCID.isVariadic()) { // FIXME: Move the implicit operand verification to the machine verifier. if (verifyImplicitOperands(Operands, MCID)) return true; } // TODO: Check for extraneous machine operands. MI = MF.CreateMachineInstr(MCID, DebugLoc(), /*NoImplicit=*/true); for (const auto &Operand : Operands) MI->addOperand(MF, Operand.Operand); return false; } bool MIParser::parseMBB(MachineBasicBlock *&MBB) { lex(); if (Token.isNot(MIToken::MachineBasicBlock)) return error("expected a machine basic block reference"); if (parseMBBReference(MBB)) return true; lex(); if (Token.isNot(MIToken::Eof)) return error( "expected end of string after the machine basic block reference"); return false; } bool MIParser::parseNamedRegister(unsigned &Reg) { lex(); if (Token.isNot(MIToken::NamedRegister)) return error("expected a named register"); if (parseRegister(Reg)) return 0; lex(); if (Token.isNot(MIToken::Eof)) return error("expected end of string after the register reference"); return false; } static const char *printImplicitRegisterFlag(const MachineOperand &MO) { assert(MO.isImplicit()); return MO.isDef() ? "implicit-def" : "implicit"; } static std::string getRegisterName(const TargetRegisterInfo *TRI, unsigned Reg) { assert(TargetRegisterInfo::isPhysicalRegister(Reg) && "expected phys reg"); return StringRef(TRI->getName(Reg)).lower(); } bool MIParser::verifyImplicitOperands( ArrayRef Operands, const MCInstrDesc &MCID) { if (MCID.isCall()) // We can't verify call instructions as they can contain arbitrary implicit // register and register mask operands. return false; // Gather all the expected implicit operands. SmallVector ImplicitOperands; if (MCID.ImplicitDefs) for (const uint16_t *ImpDefs = MCID.getImplicitDefs(); *ImpDefs; ++ImpDefs) ImplicitOperands.push_back( MachineOperand::CreateReg(*ImpDefs, true, true)); if (MCID.ImplicitUses) for (const uint16_t *ImpUses = MCID.getImplicitUses(); *ImpUses; ++ImpUses) ImplicitOperands.push_back( MachineOperand::CreateReg(*ImpUses, false, true)); const auto *TRI = MF.getSubtarget().getRegisterInfo(); assert(TRI && "Expected target register info"); size_t I = ImplicitOperands.size(), J = Operands.size(); while (I) { --I; if (J) { --J; const auto &ImplicitOperand = ImplicitOperands[I]; const auto &Operand = Operands[J].Operand; if (ImplicitOperand.isIdenticalTo(Operand)) continue; if (Operand.isReg() && Operand.isImplicit()) { return error(Operands[J].Begin, Twine("expected an implicit register operand '") + printImplicitRegisterFlag(ImplicitOperand) + " %" + getRegisterName(TRI, ImplicitOperand.getReg()) + "'"); } } // TODO: Fix source location when Operands[J].end is right before '=', i.e: // insead of reporting an error at this location: // %eax = MOV32r0 // ^ // report the error at the following location: // %eax = MOV32r0 // ^ return error(J < Operands.size() ? Operands[J].End : Token.location(), Twine("missing implicit register operand '") + printImplicitRegisterFlag(ImplicitOperands[I]) + " %" + getRegisterName(TRI, ImplicitOperands[I].getReg()) + "'"); } return false; } bool MIParser::parseInstruction(unsigned &OpCode) { if (Token.isNot(MIToken::Identifier)) return error("expected a machine instruction"); StringRef InstrName = Token.stringValue(); if (parseInstrName(InstrName, OpCode)) return error(Twine("unknown machine instruction name '") + InstrName + "'"); lex(); return false; } bool MIParser::parseRegister(unsigned &Reg) { switch (Token.kind()) { case MIToken::underscore: Reg = 0; break; case MIToken::NamedRegister: { StringRef Name = Token.stringValue(); if (getRegisterByName(Name, Reg)) return error(Twine("unknown register name '") + Name + "'"); break; } case MIToken::VirtualRegister: { unsigned ID; if (getUnsigned(ID)) return true; const auto RegInfo = PFS.VirtualRegisterSlots.find(ID); if (RegInfo == PFS.VirtualRegisterSlots.end()) return error(Twine("use of undefined virtual register '%") + Twine(ID) + "'"); Reg = RegInfo->second; break; } // TODO: Parse other register kinds. default: llvm_unreachable("The current token should be a register"); } return false; } bool MIParser::parseRegisterFlag(unsigned &Flags) { switch (Token.kind()) { case MIToken::kw_implicit: Flags |= RegState::Implicit; break; case MIToken::kw_implicit_define: Flags |= RegState::ImplicitDefine; break; case MIToken::kw_dead: Flags |= RegState::Dead; break; case MIToken::kw_killed: Flags |= RegState::Kill; break; case MIToken::kw_undef: Flags |= RegState::Undef; break; // TODO: report an error when we specify the same flag more than once. // TODO: parse the other register flags. default: llvm_unreachable("The current token should be a register flag"); } lex(); return false; } bool MIParser::parseSubRegisterIndex(unsigned &SubReg) { assert(Token.is(MIToken::colon)); lex(); if (Token.isNot(MIToken::Identifier)) return error("expected a subregister index after ':'"); auto Name = Token.stringValue(); SubReg = getSubRegIndex(Name); if (!SubReg) return error(Twine("use of unknown subregister index '") + Name + "'"); lex(); return false; } bool MIParser::parseRegisterOperand(MachineOperand &Dest, bool IsDef) { unsigned Reg; unsigned Flags = IsDef ? RegState::Define : 0; while (Token.isRegisterFlag()) { if (parseRegisterFlag(Flags)) return true; } if (!Token.isRegister()) return error("expected a register after register flags"); if (parseRegister(Reg)) return true; lex(); unsigned SubReg = 0; if (Token.is(MIToken::colon)) { if (parseSubRegisterIndex(SubReg)) return true; } Dest = MachineOperand::CreateReg( Reg, Flags & RegState::Define, Flags & RegState::Implicit, Flags & RegState::Kill, Flags & RegState::Dead, Flags & RegState::Undef, /*isEarlyClobber=*/false, SubReg); return false; } bool MIParser::parseImmediateOperand(MachineOperand &Dest) { assert(Token.is(MIToken::IntegerLiteral)); const APSInt &Int = Token.integerValue(); if (Int.getMinSignedBits() > 64) // TODO: Replace this with an error when we can parse CIMM Machine Operands. llvm_unreachable("Can't parse large integer literals yet!"); Dest = MachineOperand::CreateImm(Int.getExtValue()); lex(); return false; } bool MIParser::getUnsigned(unsigned &Result) { assert(Token.hasIntegerValue() && "Expected a token with an integer value"); const uint64_t Limit = uint64_t(std::numeric_limits::max()) + 1; uint64_t Val64 = Token.integerValue().getLimitedValue(Limit); if (Val64 == Limit) return error("expected 32-bit integer (too large)"); Result = Val64; return false; } bool MIParser::parseMBBReference(MachineBasicBlock *&MBB) { assert(Token.is(MIToken::MachineBasicBlock)); unsigned Number; if (getUnsigned(Number)) return true; auto MBBInfo = PFS.MBBSlots.find(Number); if (MBBInfo == PFS.MBBSlots.end()) return error(Twine("use of undefined machine basic block #") + Twine(Number)); MBB = MBBInfo->second; if (!Token.stringValue().empty() && Token.stringValue() != MBB->getName()) return error(Twine("the name of machine basic block #") + Twine(Number) + " isn't '" + Token.stringValue() + "'"); return false; } bool MIParser::parseMBBOperand(MachineOperand &Dest) { MachineBasicBlock *MBB; if (parseMBBReference(MBB)) return true; Dest = MachineOperand::CreateMBB(MBB); lex(); return false; } bool MIParser::parseGlobalAddressOperand(MachineOperand &Dest) { switch (Token.kind()) { case MIToken::NamedGlobalValue: { auto Name = Token.stringValue(); const Module *M = MF.getFunction()->getParent(); if (const auto *GV = M->getNamedValue(Name)) { Dest = MachineOperand::CreateGA(GV, /*Offset=*/0); break; } return error(Twine("use of undefined global value '@") + Name + "'"); } case MIToken::GlobalValue: { unsigned GVIdx; if (getUnsigned(GVIdx)) return true; if (GVIdx >= IRSlots.GlobalValues.size()) return error(Twine("use of undefined global value '@") + Twine(GVIdx) + "'"); Dest = MachineOperand::CreateGA(IRSlots.GlobalValues[GVIdx], /*Offset=*/0); break; } default: llvm_unreachable("The current token should be a global value"); } // TODO: Parse offset and target flags. lex(); return false; } bool MIParser::parseMachineOperand(MachineOperand &Dest) { switch (Token.kind()) { case MIToken::kw_implicit: case MIToken::kw_implicit_define: case MIToken::kw_dead: case MIToken::kw_killed: case MIToken::kw_undef: case MIToken::underscore: case MIToken::NamedRegister: case MIToken::VirtualRegister: return parseRegisterOperand(Dest); case MIToken::IntegerLiteral: return parseImmediateOperand(Dest); case MIToken::MachineBasicBlock: return parseMBBOperand(Dest); case MIToken::GlobalValue: case MIToken::NamedGlobalValue: return parseGlobalAddressOperand(Dest); case MIToken::Error: return true; case MIToken::Identifier: if (const auto *RegMask = getRegMask(Token.stringValue())) { Dest = MachineOperand::CreateRegMask(RegMask); lex(); break; } // fallthrough default: // TODO: parse the other machine operands. return error("expected a machine operand"); } return false; } void MIParser::initNames2InstrOpCodes() { if (!Names2InstrOpCodes.empty()) return; const auto *TII = MF.getSubtarget().getInstrInfo(); assert(TII && "Expected target instruction info"); for (unsigned I = 0, E = TII->getNumOpcodes(); I < E; ++I) Names2InstrOpCodes.insert(std::make_pair(StringRef(TII->getName(I)), I)); } bool MIParser::parseInstrName(StringRef InstrName, unsigned &OpCode) { initNames2InstrOpCodes(); auto InstrInfo = Names2InstrOpCodes.find(InstrName); if (InstrInfo == Names2InstrOpCodes.end()) return true; OpCode = InstrInfo->getValue(); return false; } void MIParser::initNames2Regs() { if (!Names2Regs.empty()) return; // The '%noreg' register is the register 0. Names2Regs.insert(std::make_pair("noreg", 0)); const auto *TRI = MF.getSubtarget().getRegisterInfo(); assert(TRI && "Expected target register info"); for (unsigned I = 0, E = TRI->getNumRegs(); I < E; ++I) { bool WasInserted = Names2Regs.insert(std::make_pair(StringRef(TRI->getName(I)).lower(), I)) .second; (void)WasInserted; assert(WasInserted && "Expected registers to be unique case-insensitively"); } } bool MIParser::getRegisterByName(StringRef RegName, unsigned &Reg) { initNames2Regs(); auto RegInfo = Names2Regs.find(RegName); if (RegInfo == Names2Regs.end()) return true; Reg = RegInfo->getValue(); return false; } void MIParser::initNames2RegMasks() { if (!Names2RegMasks.empty()) return; const auto *TRI = MF.getSubtarget().getRegisterInfo(); assert(TRI && "Expected target register info"); ArrayRef RegMasks = TRI->getRegMasks(); ArrayRef RegMaskNames = TRI->getRegMaskNames(); assert(RegMasks.size() == RegMaskNames.size()); for (size_t I = 0, E = RegMasks.size(); I < E; ++I) Names2RegMasks.insert( std::make_pair(StringRef(RegMaskNames[I]).lower(), RegMasks[I])); } const uint32_t *MIParser::getRegMask(StringRef Identifier) { initNames2RegMasks(); auto RegMaskInfo = Names2RegMasks.find(Identifier); if (RegMaskInfo == Names2RegMasks.end()) return nullptr; return RegMaskInfo->getValue(); } void MIParser::initNames2SubRegIndices() { if (!Names2SubRegIndices.empty()) return; const TargetRegisterInfo *TRI = MF.getSubtarget().getRegisterInfo(); for (unsigned I = 1, E = TRI->getNumSubRegIndices(); I < E; ++I) Names2SubRegIndices.insert( std::make_pair(StringRef(TRI->getSubRegIndexName(I)).lower(), I)); } unsigned MIParser::getSubRegIndex(StringRef Name) { initNames2SubRegIndices(); auto SubRegInfo = Names2SubRegIndices.find(Name); if (SubRegInfo == Names2SubRegIndices.end()) return 0; return SubRegInfo->getValue(); } bool llvm::parseMachineInstr(MachineInstr *&MI, SourceMgr &SM, MachineFunction &MF, StringRef Src, const PerFunctionMIParsingState &PFS, const SlotMapping &IRSlots, SMDiagnostic &Error) { return MIParser(SM, MF, Error, Src, PFS, IRSlots).parse(MI); } bool llvm::parseMBBReference(MachineBasicBlock *&MBB, SourceMgr &SM, MachineFunction &MF, StringRef Src, const PerFunctionMIParsingState &PFS, const SlotMapping &IRSlots, SMDiagnostic &Error) { return MIParser(SM, MF, Error, Src, PFS, IRSlots).parseMBB(MBB); } bool llvm::parseNamedRegisterReference(unsigned &Reg, SourceMgr &SM, MachineFunction &MF, StringRef Src, const PerFunctionMIParsingState &PFS, const SlotMapping &IRSlots, SMDiagnostic &Error) { return MIParser(SM, MF, Error, Src, PFS, IRSlots).parseNamedRegister(Reg); }