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      1 //===- MIParser.cpp - Machine instructions parser implementation ----------===//
      2 //
      3 //                     The LLVM Compiler Infrastructure
      4 //
      5 // This file is distributed under the University of Illinois Open Source
      6 // License. See LICENSE.TXT for details.
      7 //
      8 //===----------------------------------------------------------------------===//
      9 //
     10 // This file implements the parsing of machine instructions.
     11 //
     12 //===----------------------------------------------------------------------===//
     13 
     14 #include "MIParser.h"
     15 #include "MILexer.h"
     16 #include "llvm/ADT/StringMap.h"
     17 #include "llvm/AsmParser/Parser.h"
     18 #include "llvm/AsmParser/SlotMapping.h"
     19 #include "llvm/CodeGen/MachineBasicBlock.h"
     20 #include "llvm/CodeGen/MachineFunction.h"
     21 #include "llvm/CodeGen/MachineFrameInfo.h"
     22 #include "llvm/CodeGen/MachineInstr.h"
     23 #include "llvm/CodeGen/MachineInstrBuilder.h"
     24 #include "llvm/CodeGen/MachineMemOperand.h"
     25 #include "llvm/CodeGen/MachineModuleInfo.h"
     26 #include "llvm/IR/Instructions.h"
     27 #include "llvm/IR/Constants.h"
     28 #include "llvm/IR/Module.h"
     29 #include "llvm/IR/ModuleSlotTracker.h"
     30 #include "llvm/IR/ValueSymbolTable.h"
     31 #include "llvm/Support/raw_ostream.h"
     32 #include "llvm/Support/SourceMgr.h"
     33 #include "llvm/Target/TargetSubtargetInfo.h"
     34 #include "llvm/Target/TargetInstrInfo.h"
     35 
     36 using namespace llvm;
     37 
     38 namespace {
     39 
     40 /// A wrapper struct around the 'MachineOperand' struct that includes a source
     41 /// range and other attributes.
     42 struct ParsedMachineOperand {
     43   MachineOperand Operand;
     44   StringRef::iterator Begin;
     45   StringRef::iterator End;
     46   Optional<unsigned> TiedDefIdx;
     47 
     48   ParsedMachineOperand(const MachineOperand &Operand, StringRef::iterator Begin,
     49                        StringRef::iterator End, Optional<unsigned> &TiedDefIdx)
     50       : Operand(Operand), Begin(Begin), End(End), TiedDefIdx(TiedDefIdx) {
     51     if (TiedDefIdx)
     52       assert(Operand.isReg() && Operand.isUse() &&
     53              "Only used register operands can be tied");
     54   }
     55 };
     56 
     57 class MIParser {
     58   SourceMgr &SM;
     59   MachineFunction &MF;
     60   SMDiagnostic &Error;
     61   StringRef Source, CurrentSource;
     62   MIToken Token;
     63   const PerFunctionMIParsingState &PFS;
     64   /// Maps from indices to unnamed global values and metadata nodes.
     65   const SlotMapping &IRSlots;
     66   /// Maps from instruction names to op codes.
     67   StringMap<unsigned> Names2InstrOpCodes;
     68   /// Maps from register names to registers.
     69   StringMap<unsigned> Names2Regs;
     70   /// Maps from register mask names to register masks.
     71   StringMap<const uint32_t *> Names2RegMasks;
     72   /// Maps from subregister names to subregister indices.
     73   StringMap<unsigned> Names2SubRegIndices;
     74   /// Maps from slot numbers to function's unnamed basic blocks.
     75   DenseMap<unsigned, const BasicBlock *> Slots2BasicBlocks;
     76   /// Maps from slot numbers to function's unnamed values.
     77   DenseMap<unsigned, const Value *> Slots2Values;
     78   /// Maps from target index names to target indices.
     79   StringMap<int> Names2TargetIndices;
     80   /// Maps from direct target flag names to the direct target flag values.
     81   StringMap<unsigned> Names2DirectTargetFlags;
     82   /// Maps from direct target flag names to the bitmask target flag values.
     83   StringMap<unsigned> Names2BitmaskTargetFlags;
     84 
     85 public:
     86   MIParser(SourceMgr &SM, MachineFunction &MF, SMDiagnostic &Error,
     87            StringRef Source, const PerFunctionMIParsingState &PFS,
     88            const SlotMapping &IRSlots);
     89 
     90   void lex();
     91 
     92   /// Report an error at the current location with the given message.
     93   ///
     94   /// This function always return true.
     95   bool error(const Twine &Msg);
     96 
     97   /// Report an error at the given location with the given message.
     98   ///
     99   /// This function always return true.
    100   bool error(StringRef::iterator Loc, const Twine &Msg);
    101 
    102   bool
    103   parseBasicBlockDefinitions(DenseMap<unsigned, MachineBasicBlock *> &MBBSlots);
    104   bool parseBasicBlocks();
    105   bool parse(MachineInstr *&MI);
    106   bool parseStandaloneMBB(MachineBasicBlock *&MBB);
    107   bool parseStandaloneNamedRegister(unsigned &Reg);
    108   bool parseStandaloneVirtualRegister(unsigned &Reg);
    109   bool parseStandaloneStackObject(int &FI);
    110   bool parseStandaloneMDNode(MDNode *&Node);
    111 
    112   bool
    113   parseBasicBlockDefinition(DenseMap<unsigned, MachineBasicBlock *> &MBBSlots);
    114   bool parseBasicBlock(MachineBasicBlock &MBB);
    115   bool parseBasicBlockLiveins(MachineBasicBlock &MBB);
    116   bool parseBasicBlockSuccessors(MachineBasicBlock &MBB);
    117 
    118   bool parseRegister(unsigned &Reg);
    119   bool parseRegisterFlag(unsigned &Flags);
    120   bool parseSubRegisterIndex(unsigned &SubReg);
    121   bool parseRegisterTiedDefIndex(unsigned &TiedDefIdx);
    122   bool parseRegisterOperand(MachineOperand &Dest,
    123                             Optional<unsigned> &TiedDefIdx, bool IsDef = false);
    124   bool parseImmediateOperand(MachineOperand &Dest);
    125   bool parseIRConstant(StringRef::iterator Loc, StringRef Source,
    126                        const Constant *&C);
    127   bool parseIRConstant(StringRef::iterator Loc, const Constant *&C);
    128   bool parseTypedImmediateOperand(MachineOperand &Dest);
    129   bool parseFPImmediateOperand(MachineOperand &Dest);
    130   bool parseMBBReference(MachineBasicBlock *&MBB);
    131   bool parseMBBOperand(MachineOperand &Dest);
    132   bool parseStackFrameIndex(int &FI);
    133   bool parseStackObjectOperand(MachineOperand &Dest);
    134   bool parseFixedStackFrameIndex(int &FI);
    135   bool parseFixedStackObjectOperand(MachineOperand &Dest);
    136   bool parseGlobalValue(GlobalValue *&GV);
    137   bool parseGlobalAddressOperand(MachineOperand &Dest);
    138   bool parseConstantPoolIndexOperand(MachineOperand &Dest);
    139   bool parseJumpTableIndexOperand(MachineOperand &Dest);
    140   bool parseExternalSymbolOperand(MachineOperand &Dest);
    141   bool parseMDNode(MDNode *&Node);
    142   bool parseMetadataOperand(MachineOperand &Dest);
    143   bool parseCFIOffset(int &Offset);
    144   bool parseCFIRegister(unsigned &Reg);
    145   bool parseCFIOperand(MachineOperand &Dest);
    146   bool parseIRBlock(BasicBlock *&BB, const Function &F);
    147   bool parseBlockAddressOperand(MachineOperand &Dest);
    148   bool parseTargetIndexOperand(MachineOperand &Dest);
    149   bool parseLiveoutRegisterMaskOperand(MachineOperand &Dest);
    150   bool parseMachineOperand(MachineOperand &Dest,
    151                            Optional<unsigned> &TiedDefIdx);
    152   bool parseMachineOperandAndTargetFlags(MachineOperand &Dest,
    153                                          Optional<unsigned> &TiedDefIdx);
    154   bool parseOffset(int64_t &Offset);
    155   bool parseAlignment(unsigned &Alignment);
    156   bool parseOperandsOffset(MachineOperand &Op);
    157   bool parseIRValue(const Value *&V);
    158   bool parseMemoryOperandFlag(unsigned &Flags);
    159   bool parseMemoryPseudoSourceValue(const PseudoSourceValue *&PSV);
    160   bool parseMachinePointerInfo(MachinePointerInfo &Dest);
    161   bool parseMachineMemoryOperand(MachineMemOperand *&Dest);
    162 
    163 private:
    164   /// Convert the integer literal in the current token into an unsigned integer.
    165   ///
    166   /// Return true if an error occurred.
    167   bool getUnsigned(unsigned &Result);
    168 
    169   /// Convert the integer literal in the current token into an uint64.
    170   ///
    171   /// Return true if an error occurred.
    172   bool getUint64(uint64_t &Result);
    173 
    174   /// If the current token is of the given kind, consume it and return false.
    175   /// Otherwise report an error and return true.
    176   bool expectAndConsume(MIToken::TokenKind TokenKind);
    177 
    178   /// If the current token is of the given kind, consume it and return true.
    179   /// Otherwise return false.
    180   bool consumeIfPresent(MIToken::TokenKind TokenKind);
    181 
    182   void initNames2InstrOpCodes();
    183 
    184   /// Try to convert an instruction name to an opcode. Return true if the
    185   /// instruction name is invalid.
    186   bool parseInstrName(StringRef InstrName, unsigned &OpCode);
    187 
    188   bool parseInstruction(unsigned &OpCode, unsigned &Flags);
    189 
    190   bool assignRegisterTies(MachineInstr &MI,
    191                           ArrayRef<ParsedMachineOperand> Operands);
    192 
    193   bool verifyImplicitOperands(ArrayRef<ParsedMachineOperand> Operands,
    194                               const MCInstrDesc &MCID);
    195 
    196   void initNames2Regs();
    197 
    198   /// Try to convert a register name to a register number. Return true if the
    199   /// register name is invalid.
    200   bool getRegisterByName(StringRef RegName, unsigned &Reg);
    201 
    202   void initNames2RegMasks();
    203 
    204   /// Check if the given identifier is a name of a register mask.
    205   ///
    206   /// Return null if the identifier isn't a register mask.
    207   const uint32_t *getRegMask(StringRef Identifier);
    208 
    209   void initNames2SubRegIndices();
    210 
    211   /// Check if the given identifier is a name of a subregister index.
    212   ///
    213   /// Return 0 if the name isn't a subregister index class.
    214   unsigned getSubRegIndex(StringRef Name);
    215 
    216   const BasicBlock *getIRBlock(unsigned Slot);
    217   const BasicBlock *getIRBlock(unsigned Slot, const Function &F);
    218 
    219   const Value *getIRValue(unsigned Slot);
    220 
    221   void initNames2TargetIndices();
    222 
    223   /// Try to convert a name of target index to the corresponding target index.
    224   ///
    225   /// Return true if the name isn't a name of a target index.
    226   bool getTargetIndex(StringRef Name, int &Index);
    227 
    228   void initNames2DirectTargetFlags();
    229 
    230   /// Try to convert a name of a direct target flag to the corresponding
    231   /// target flag.
    232   ///
    233   /// Return true if the name isn't a name of a direct flag.
    234   bool getDirectTargetFlag(StringRef Name, unsigned &Flag);
    235 
    236   void initNames2BitmaskTargetFlags();
    237 
    238   /// Try to convert a name of a bitmask target flag to the corresponding
    239   /// target flag.
    240   ///
    241   /// Return true if the name isn't a name of a bitmask target flag.
    242   bool getBitmaskTargetFlag(StringRef Name, unsigned &Flag);
    243 };
    244 
    245 } // end anonymous namespace
    246 
    247 MIParser::MIParser(SourceMgr &SM, MachineFunction &MF, SMDiagnostic &Error,
    248                    StringRef Source, const PerFunctionMIParsingState &PFS,
    249                    const SlotMapping &IRSlots)
    250     : SM(SM), MF(MF), Error(Error), Source(Source), CurrentSource(Source),
    251       PFS(PFS), IRSlots(IRSlots) {}
    252 
    253 void MIParser::lex() {
    254   CurrentSource = lexMIToken(
    255       CurrentSource, Token,
    256       [this](StringRef::iterator Loc, const Twine &Msg) { error(Loc, Msg); });
    257 }
    258 
    259 bool MIParser::error(const Twine &Msg) { return error(Token.location(), Msg); }
    260 
    261 bool MIParser::error(StringRef::iterator Loc, const Twine &Msg) {
    262   assert(Loc >= Source.data() && Loc <= (Source.data() + Source.size()));
    263   const MemoryBuffer &Buffer = *SM.getMemoryBuffer(SM.getMainFileID());
    264   if (Loc >= Buffer.getBufferStart() && Loc <= Buffer.getBufferEnd()) {
    265     // Create an ordinary diagnostic when the source manager's buffer is the
    266     // source string.
    267     Error = SM.GetMessage(SMLoc::getFromPointer(Loc), SourceMgr::DK_Error, Msg);
    268     return true;
    269   }
    270   // Create a diagnostic for a YAML string literal.
    271   Error = SMDiagnostic(SM, SMLoc(), Buffer.getBufferIdentifier(), 1,
    272                        Loc - Source.data(), SourceMgr::DK_Error, Msg.str(),
    273                        Source, None, None);
    274   return true;
    275 }
    276 
    277 static const char *toString(MIToken::TokenKind TokenKind) {
    278   switch (TokenKind) {
    279   case MIToken::comma:
    280     return "','";
    281   case MIToken::equal:
    282     return "'='";
    283   case MIToken::colon:
    284     return "':'";
    285   case MIToken::lparen:
    286     return "'('";
    287   case MIToken::rparen:
    288     return "')'";
    289   default:
    290     return "<unknown token>";
    291   }
    292 }
    293 
    294 bool MIParser::expectAndConsume(MIToken::TokenKind TokenKind) {
    295   if (Token.isNot(TokenKind))
    296     return error(Twine("expected ") + toString(TokenKind));
    297   lex();
    298   return false;
    299 }
    300 
    301 bool MIParser::consumeIfPresent(MIToken::TokenKind TokenKind) {
    302   if (Token.isNot(TokenKind))
    303     return false;
    304   lex();
    305   return true;
    306 }
    307 
    308 bool MIParser::parseBasicBlockDefinition(
    309     DenseMap<unsigned, MachineBasicBlock *> &MBBSlots) {
    310   assert(Token.is(MIToken::MachineBasicBlockLabel));
    311   unsigned ID = 0;
    312   if (getUnsigned(ID))
    313     return true;
    314   auto Loc = Token.location();
    315   auto Name = Token.stringValue();
    316   lex();
    317   bool HasAddressTaken = false;
    318   bool IsLandingPad = false;
    319   unsigned Alignment = 0;
    320   BasicBlock *BB = nullptr;
    321   if (consumeIfPresent(MIToken::lparen)) {
    322     do {
    323       // TODO: Report an error when multiple same attributes are specified.
    324       switch (Token.kind()) {
    325       case MIToken::kw_address_taken:
    326         HasAddressTaken = true;
    327         lex();
    328         break;
    329       case MIToken::kw_landing_pad:
    330         IsLandingPad = true;
    331         lex();
    332         break;
    333       case MIToken::kw_align:
    334         if (parseAlignment(Alignment))
    335           return true;
    336         break;
    337       case MIToken::IRBlock:
    338         // TODO: Report an error when both name and ir block are specified.
    339         if (parseIRBlock(BB, *MF.getFunction()))
    340           return true;
    341         lex();
    342         break;
    343       default:
    344         break;
    345       }
    346     } while (consumeIfPresent(MIToken::comma));
    347     if (expectAndConsume(MIToken::rparen))
    348       return true;
    349   }
    350   if (expectAndConsume(MIToken::colon))
    351     return true;
    352 
    353   if (!Name.empty()) {
    354     BB = dyn_cast_or_null<BasicBlock>(
    355         MF.getFunction()->getValueSymbolTable().lookup(Name));
    356     if (!BB)
    357       return error(Loc, Twine("basic block '") + Name +
    358                             "' is not defined in the function '" +
    359                             MF.getName() + "'");
    360   }
    361   auto *MBB = MF.CreateMachineBasicBlock(BB);
    362   MF.insert(MF.end(), MBB);
    363   bool WasInserted = MBBSlots.insert(std::make_pair(ID, MBB)).second;
    364   if (!WasInserted)
    365     return error(Loc, Twine("redefinition of machine basic block with id #") +
    366                           Twine(ID));
    367   if (Alignment)
    368     MBB->setAlignment(Alignment);
    369   if (HasAddressTaken)
    370     MBB->setHasAddressTaken();
    371   MBB->setIsEHPad(IsLandingPad);
    372   return false;
    373 }
    374 
    375 bool MIParser::parseBasicBlockDefinitions(
    376     DenseMap<unsigned, MachineBasicBlock *> &MBBSlots) {
    377   lex();
    378   // Skip until the first machine basic block.
    379   while (Token.is(MIToken::Newline))
    380     lex();
    381   if (Token.isErrorOrEOF())
    382     return Token.isError();
    383   if (Token.isNot(MIToken::MachineBasicBlockLabel))
    384     return error("expected a basic block definition before instructions");
    385   unsigned BraceDepth = 0;
    386   do {
    387     if (parseBasicBlockDefinition(MBBSlots))
    388       return true;
    389     bool IsAfterNewline = false;
    390     // Skip until the next machine basic block.
    391     while (true) {
    392       if ((Token.is(MIToken::MachineBasicBlockLabel) && IsAfterNewline) ||
    393           Token.isErrorOrEOF())
    394         break;
    395       else if (Token.is(MIToken::MachineBasicBlockLabel))
    396         return error("basic block definition should be located at the start of "
    397                      "the line");
    398       else if (consumeIfPresent(MIToken::Newline)) {
    399         IsAfterNewline = true;
    400         continue;
    401       }
    402       IsAfterNewline = false;
    403       if (Token.is(MIToken::lbrace))
    404         ++BraceDepth;
    405       if (Token.is(MIToken::rbrace)) {
    406         if (!BraceDepth)
    407           return error("extraneous closing brace ('}')");
    408         --BraceDepth;
    409       }
    410       lex();
    411     }
    412     // Verify that we closed all of the '{' at the end of a file or a block.
    413     if (!Token.isError() && BraceDepth)
    414       return error("expected '}'"); // FIXME: Report a note that shows '{'.
    415   } while (!Token.isErrorOrEOF());
    416   return Token.isError();
    417 }
    418 
    419 bool MIParser::parseBasicBlockLiveins(MachineBasicBlock &MBB) {
    420   assert(Token.is(MIToken::kw_liveins));
    421   lex();
    422   if (expectAndConsume(MIToken::colon))
    423     return true;
    424   if (Token.isNewlineOrEOF()) // Allow an empty list of liveins.
    425     return false;
    426   do {
    427     if (Token.isNot(MIToken::NamedRegister))
    428       return error("expected a named register");
    429     unsigned Reg = 0;
    430     if (parseRegister(Reg))
    431       return true;
    432     MBB.addLiveIn(Reg);
    433     lex();
    434   } while (consumeIfPresent(MIToken::comma));
    435   return false;
    436 }
    437 
    438 bool MIParser::parseBasicBlockSuccessors(MachineBasicBlock &MBB) {
    439   assert(Token.is(MIToken::kw_successors));
    440   lex();
    441   if (expectAndConsume(MIToken::colon))
    442     return true;
    443   if (Token.isNewlineOrEOF()) // Allow an empty list of successors.
    444     return false;
    445   do {
    446     if (Token.isNot(MIToken::MachineBasicBlock))
    447       return error("expected a machine basic block reference");
    448     MachineBasicBlock *SuccMBB = nullptr;
    449     if (parseMBBReference(SuccMBB))
    450       return true;
    451     lex();
    452     unsigned Weight = 0;
    453     if (consumeIfPresent(MIToken::lparen)) {
    454       if (Token.isNot(MIToken::IntegerLiteral))
    455         return error("expected an integer literal after '('");
    456       if (getUnsigned(Weight))
    457         return true;
    458       lex();
    459       if (expectAndConsume(MIToken::rparen))
    460         return true;
    461     }
    462     MBB.addSuccessor(SuccMBB, BranchProbability::getRaw(Weight));
    463   } while (consumeIfPresent(MIToken::comma));
    464   MBB.normalizeSuccProbs();
    465   return false;
    466 }
    467 
    468 bool MIParser::parseBasicBlock(MachineBasicBlock &MBB) {
    469   // Skip the definition.
    470   assert(Token.is(MIToken::MachineBasicBlockLabel));
    471   lex();
    472   if (consumeIfPresent(MIToken::lparen)) {
    473     while (Token.isNot(MIToken::rparen) && !Token.isErrorOrEOF())
    474       lex();
    475     consumeIfPresent(MIToken::rparen);
    476   }
    477   consumeIfPresent(MIToken::colon);
    478 
    479   // Parse the liveins and successors.
    480   // N.B: Multiple lists of successors and liveins are allowed and they're
    481   // merged into one.
    482   // Example:
    483   //   liveins: %edi
    484   //   liveins: %esi
    485   //
    486   // is equivalent to
    487   //   liveins: %edi, %esi
    488   while (true) {
    489     if (Token.is(MIToken::kw_successors)) {
    490       if (parseBasicBlockSuccessors(MBB))
    491         return true;
    492     } else if (Token.is(MIToken::kw_liveins)) {
    493       if (parseBasicBlockLiveins(MBB))
    494         return true;
    495     } else if (consumeIfPresent(MIToken::Newline)) {
    496       continue;
    497     } else
    498       break;
    499     if (!Token.isNewlineOrEOF())
    500       return error("expected line break at the end of a list");
    501     lex();
    502   }
    503 
    504   // Parse the instructions.
    505   bool IsInBundle = false;
    506   MachineInstr *PrevMI = nullptr;
    507   while (true) {
    508     if (Token.is(MIToken::MachineBasicBlockLabel) || Token.is(MIToken::Eof))
    509       return false;
    510     else if (consumeIfPresent(MIToken::Newline))
    511       continue;
    512     if (consumeIfPresent(MIToken::rbrace)) {
    513       // The first parsing pass should verify that all closing '}' have an
    514       // opening '{'.
    515       assert(IsInBundle);
    516       IsInBundle = false;
    517       continue;
    518     }
    519     MachineInstr *MI = nullptr;
    520     if (parse(MI))
    521       return true;
    522     MBB.insert(MBB.end(), MI);
    523     if (IsInBundle) {
    524       PrevMI->setFlag(MachineInstr::BundledSucc);
    525       MI->setFlag(MachineInstr::BundledPred);
    526     }
    527     PrevMI = MI;
    528     if (Token.is(MIToken::lbrace)) {
    529       if (IsInBundle)
    530         return error("nested instruction bundles are not allowed");
    531       lex();
    532       // This instruction is the start of the bundle.
    533       MI->setFlag(MachineInstr::BundledSucc);
    534       IsInBundle = true;
    535       if (!Token.is(MIToken::Newline))
    536         // The next instruction can be on the same line.
    537         continue;
    538     }
    539     assert(Token.isNewlineOrEOF() && "MI is not fully parsed");
    540     lex();
    541   }
    542   return false;
    543 }
    544 
    545 bool MIParser::parseBasicBlocks() {
    546   lex();
    547   // Skip until the first machine basic block.
    548   while (Token.is(MIToken::Newline))
    549     lex();
    550   if (Token.isErrorOrEOF())
    551     return Token.isError();
    552   // The first parsing pass should have verified that this token is a MBB label
    553   // in the 'parseBasicBlockDefinitions' method.
    554   assert(Token.is(MIToken::MachineBasicBlockLabel));
    555   do {
    556     MachineBasicBlock *MBB = nullptr;
    557     if (parseMBBReference(MBB))
    558       return true;
    559     if (parseBasicBlock(*MBB))
    560       return true;
    561     // The method 'parseBasicBlock' should parse the whole block until the next
    562     // block or the end of file.
    563     assert(Token.is(MIToken::MachineBasicBlockLabel) || Token.is(MIToken::Eof));
    564   } while (Token.isNot(MIToken::Eof));
    565   return false;
    566 }
    567 
    568 bool MIParser::parse(MachineInstr *&MI) {
    569   // Parse any register operands before '='
    570   MachineOperand MO = MachineOperand::CreateImm(0);
    571   SmallVector<ParsedMachineOperand, 8> Operands;
    572   while (Token.isRegister() || Token.isRegisterFlag()) {
    573     auto Loc = Token.location();
    574     Optional<unsigned> TiedDefIdx;
    575     if (parseRegisterOperand(MO, TiedDefIdx, /*IsDef=*/true))
    576       return true;
    577     Operands.push_back(
    578         ParsedMachineOperand(MO, Loc, Token.location(), TiedDefIdx));
    579     if (Token.isNot(MIToken::comma))
    580       break;
    581     lex();
    582   }
    583   if (!Operands.empty() && expectAndConsume(MIToken::equal))
    584     return true;
    585 
    586   unsigned OpCode, Flags = 0;
    587   if (Token.isError() || parseInstruction(OpCode, Flags))
    588     return true;
    589 
    590   // Parse the remaining machine operands.
    591   while (!Token.isNewlineOrEOF() && Token.isNot(MIToken::kw_debug_location) &&
    592          Token.isNot(MIToken::coloncolon) && Token.isNot(MIToken::lbrace)) {
    593     auto Loc = Token.location();
    594     Optional<unsigned> TiedDefIdx;
    595     if (parseMachineOperandAndTargetFlags(MO, TiedDefIdx))
    596       return true;
    597     Operands.push_back(
    598         ParsedMachineOperand(MO, Loc, Token.location(), TiedDefIdx));
    599     if (Token.isNewlineOrEOF() || Token.is(MIToken::coloncolon) ||
    600         Token.is(MIToken::lbrace))
    601       break;
    602     if (Token.isNot(MIToken::comma))
    603       return error("expected ',' before the next machine operand");
    604     lex();
    605   }
    606 
    607   DebugLoc DebugLocation;
    608   if (Token.is(MIToken::kw_debug_location)) {
    609     lex();
    610     if (Token.isNot(MIToken::exclaim))
    611       return error("expected a metadata node after 'debug-location'");
    612     MDNode *Node = nullptr;
    613     if (parseMDNode(Node))
    614       return true;
    615     DebugLocation = DebugLoc(Node);
    616   }
    617 
    618   // Parse the machine memory operands.
    619   SmallVector<MachineMemOperand *, 2> MemOperands;
    620   if (Token.is(MIToken::coloncolon)) {
    621     lex();
    622     while (!Token.isNewlineOrEOF()) {
    623       MachineMemOperand *MemOp = nullptr;
    624       if (parseMachineMemoryOperand(MemOp))
    625         return true;
    626       MemOperands.push_back(MemOp);
    627       if (Token.isNewlineOrEOF())
    628         break;
    629       if (Token.isNot(MIToken::comma))
    630         return error("expected ',' before the next machine memory operand");
    631       lex();
    632     }
    633   }
    634 
    635   const auto &MCID = MF.getSubtarget().getInstrInfo()->get(OpCode);
    636   if (!MCID.isVariadic()) {
    637     // FIXME: Move the implicit operand verification to the machine verifier.
    638     if (verifyImplicitOperands(Operands, MCID))
    639       return true;
    640   }
    641 
    642   // TODO: Check for extraneous machine operands.
    643   MI = MF.CreateMachineInstr(MCID, DebugLocation, /*NoImplicit=*/true);
    644   MI->setFlags(Flags);
    645   for (const auto &Operand : Operands)
    646     MI->addOperand(MF, Operand.Operand);
    647   if (assignRegisterTies(*MI, Operands))
    648     return true;
    649   if (MemOperands.empty())
    650     return false;
    651   MachineInstr::mmo_iterator MemRefs =
    652       MF.allocateMemRefsArray(MemOperands.size());
    653   std::copy(MemOperands.begin(), MemOperands.end(), MemRefs);
    654   MI->setMemRefs(MemRefs, MemRefs + MemOperands.size());
    655   return false;
    656 }
    657 
    658 bool MIParser::parseStandaloneMBB(MachineBasicBlock *&MBB) {
    659   lex();
    660   if (Token.isNot(MIToken::MachineBasicBlock))
    661     return error("expected a machine basic block reference");
    662   if (parseMBBReference(MBB))
    663     return true;
    664   lex();
    665   if (Token.isNot(MIToken::Eof))
    666     return error(
    667         "expected end of string after the machine basic block reference");
    668   return false;
    669 }
    670 
    671 bool MIParser::parseStandaloneNamedRegister(unsigned &Reg) {
    672   lex();
    673   if (Token.isNot(MIToken::NamedRegister))
    674     return error("expected a named register");
    675   if (parseRegister(Reg))
    676     return true;
    677   lex();
    678   if (Token.isNot(MIToken::Eof))
    679     return error("expected end of string after the register reference");
    680   return false;
    681 }
    682 
    683 bool MIParser::parseStandaloneVirtualRegister(unsigned &Reg) {
    684   lex();
    685   if (Token.isNot(MIToken::VirtualRegister))
    686     return error("expected a virtual register");
    687   if (parseRegister(Reg))
    688     return true;
    689   lex();
    690   if (Token.isNot(MIToken::Eof))
    691     return error("expected end of string after the register reference");
    692   return false;
    693 }
    694 
    695 bool MIParser::parseStandaloneStackObject(int &FI) {
    696   lex();
    697   if (Token.isNot(MIToken::StackObject))
    698     return error("expected a stack object");
    699   if (parseStackFrameIndex(FI))
    700     return true;
    701   if (Token.isNot(MIToken::Eof))
    702     return error("expected end of string after the stack object reference");
    703   return false;
    704 }
    705 
    706 bool MIParser::parseStandaloneMDNode(MDNode *&Node) {
    707   lex();
    708   if (Token.isNot(MIToken::exclaim))
    709     return error("expected a metadata node");
    710   if (parseMDNode(Node))
    711     return true;
    712   if (Token.isNot(MIToken::Eof))
    713     return error("expected end of string after the metadata node");
    714   return false;
    715 }
    716 
    717 static const char *printImplicitRegisterFlag(const MachineOperand &MO) {
    718   assert(MO.isImplicit());
    719   return MO.isDef() ? "implicit-def" : "implicit";
    720 }
    721 
    722 static std::string getRegisterName(const TargetRegisterInfo *TRI,
    723                                    unsigned Reg) {
    724   assert(TargetRegisterInfo::isPhysicalRegister(Reg) && "expected phys reg");
    725   return StringRef(TRI->getName(Reg)).lower();
    726 }
    727 
    728 /// Return true if the parsed machine operands contain a given machine operand.
    729 static bool isImplicitOperandIn(const MachineOperand &ImplicitOperand,
    730                                 ArrayRef<ParsedMachineOperand> Operands) {
    731   for (const auto &I : Operands) {
    732     if (ImplicitOperand.isIdenticalTo(I.Operand))
    733       return true;
    734   }
    735   return false;
    736 }
    737 
    738 bool MIParser::verifyImplicitOperands(ArrayRef<ParsedMachineOperand> Operands,
    739                                       const MCInstrDesc &MCID) {
    740   if (MCID.isCall())
    741     // We can't verify call instructions as they can contain arbitrary implicit
    742     // register and register mask operands.
    743     return false;
    744 
    745   // Gather all the expected implicit operands.
    746   SmallVector<MachineOperand, 4> ImplicitOperands;
    747   if (MCID.ImplicitDefs)
    748     for (const MCPhysReg *ImpDefs = MCID.getImplicitDefs(); *ImpDefs; ++ImpDefs)
    749       ImplicitOperands.push_back(
    750           MachineOperand::CreateReg(*ImpDefs, true, true));
    751   if (MCID.ImplicitUses)
    752     for (const MCPhysReg *ImpUses = MCID.getImplicitUses(); *ImpUses; ++ImpUses)
    753       ImplicitOperands.push_back(
    754           MachineOperand::CreateReg(*ImpUses, false, true));
    755 
    756   const auto *TRI = MF.getSubtarget().getRegisterInfo();
    757   assert(TRI && "Expected target register info");
    758   for (const auto &I : ImplicitOperands) {
    759     if (isImplicitOperandIn(I, Operands))
    760       continue;
    761     return error(Operands.empty() ? Token.location() : Operands.back().End,
    762                  Twine("missing implicit register operand '") +
    763                      printImplicitRegisterFlag(I) + " %" +
    764                      getRegisterName(TRI, I.getReg()) + "'");
    765   }
    766   return false;
    767 }
    768 
    769 bool MIParser::parseInstruction(unsigned &OpCode, unsigned &Flags) {
    770   if (Token.is(MIToken::kw_frame_setup)) {
    771     Flags |= MachineInstr::FrameSetup;
    772     lex();
    773   }
    774   if (Token.isNot(MIToken::Identifier))
    775     return error("expected a machine instruction");
    776   StringRef InstrName = Token.stringValue();
    777   if (parseInstrName(InstrName, OpCode))
    778     return error(Twine("unknown machine instruction name '") + InstrName + "'");
    779   lex();
    780   return false;
    781 }
    782 
    783 bool MIParser::parseRegister(unsigned &Reg) {
    784   switch (Token.kind()) {
    785   case MIToken::underscore:
    786     Reg = 0;
    787     break;
    788   case MIToken::NamedRegister: {
    789     StringRef Name = Token.stringValue();
    790     if (getRegisterByName(Name, Reg))
    791       return error(Twine("unknown register name '") + Name + "'");
    792     break;
    793   }
    794   case MIToken::VirtualRegister: {
    795     unsigned ID;
    796     if (getUnsigned(ID))
    797       return true;
    798     const auto RegInfo = PFS.VirtualRegisterSlots.find(ID);
    799     if (RegInfo == PFS.VirtualRegisterSlots.end())
    800       return error(Twine("use of undefined virtual register '%") + Twine(ID) +
    801                    "'");
    802     Reg = RegInfo->second;
    803     break;
    804   }
    805   // TODO: Parse other register kinds.
    806   default:
    807     llvm_unreachable("The current token should be a register");
    808   }
    809   return false;
    810 }
    811 
    812 bool MIParser::parseRegisterFlag(unsigned &Flags) {
    813   const unsigned OldFlags = Flags;
    814   switch (Token.kind()) {
    815   case MIToken::kw_implicit:
    816     Flags |= RegState::Implicit;
    817     break;
    818   case MIToken::kw_implicit_define:
    819     Flags |= RegState::ImplicitDefine;
    820     break;
    821   case MIToken::kw_def:
    822     Flags |= RegState::Define;
    823     break;
    824   case MIToken::kw_dead:
    825     Flags |= RegState::Dead;
    826     break;
    827   case MIToken::kw_killed:
    828     Flags |= RegState::Kill;
    829     break;
    830   case MIToken::kw_undef:
    831     Flags |= RegState::Undef;
    832     break;
    833   case MIToken::kw_internal:
    834     Flags |= RegState::InternalRead;
    835     break;
    836   case MIToken::kw_early_clobber:
    837     Flags |= RegState::EarlyClobber;
    838     break;
    839   case MIToken::kw_debug_use:
    840     Flags |= RegState::Debug;
    841     break;
    842   default:
    843     llvm_unreachable("The current token should be a register flag");
    844   }
    845   if (OldFlags == Flags)
    846     // We know that the same flag is specified more than once when the flags
    847     // weren't modified.
    848     return error("duplicate '" + Token.stringValue() + "' register flag");
    849   lex();
    850   return false;
    851 }
    852 
    853 bool MIParser::parseSubRegisterIndex(unsigned &SubReg) {
    854   assert(Token.is(MIToken::colon));
    855   lex();
    856   if (Token.isNot(MIToken::Identifier))
    857     return error("expected a subregister index after ':'");
    858   auto Name = Token.stringValue();
    859   SubReg = getSubRegIndex(Name);
    860   if (!SubReg)
    861     return error(Twine("use of unknown subregister index '") + Name + "'");
    862   lex();
    863   return false;
    864 }
    865 
    866 bool MIParser::parseRegisterTiedDefIndex(unsigned &TiedDefIdx) {
    867   if (!consumeIfPresent(MIToken::kw_tied_def))
    868     return error("expected 'tied-def' after '('");
    869   if (Token.isNot(MIToken::IntegerLiteral))
    870     return error("expected an integer literal after 'tied-def'");
    871   if (getUnsigned(TiedDefIdx))
    872     return true;
    873   lex();
    874   if (expectAndConsume(MIToken::rparen))
    875     return true;
    876   return false;
    877 }
    878 
    879 bool MIParser::assignRegisterTies(MachineInstr &MI,
    880                                   ArrayRef<ParsedMachineOperand> Operands) {
    881   SmallVector<std::pair<unsigned, unsigned>, 4> TiedRegisterPairs;
    882   for (unsigned I = 0, E = Operands.size(); I != E; ++I) {
    883     if (!Operands[I].TiedDefIdx)
    884       continue;
    885     // The parser ensures that this operand is a register use, so we just have
    886     // to check the tied-def operand.
    887     unsigned DefIdx = Operands[I].TiedDefIdx.getValue();
    888     if (DefIdx >= E)
    889       return error(Operands[I].Begin,
    890                    Twine("use of invalid tied-def operand index '" +
    891                          Twine(DefIdx) + "'; instruction has only ") +
    892                        Twine(E) + " operands");
    893     const auto &DefOperand = Operands[DefIdx].Operand;
    894     if (!DefOperand.isReg() || !DefOperand.isDef())
    895       // FIXME: add note with the def operand.
    896       return error(Operands[I].Begin,
    897                    Twine("use of invalid tied-def operand index '") +
    898                        Twine(DefIdx) + "'; the operand #" + Twine(DefIdx) +
    899                        " isn't a defined register");
    900     // Check that the tied-def operand wasn't tied elsewhere.
    901     for (const auto &TiedPair : TiedRegisterPairs) {
    902       if (TiedPair.first == DefIdx)
    903         return error(Operands[I].Begin,
    904                      Twine("the tied-def operand #") + Twine(DefIdx) +
    905                          " is already tied with another register operand");
    906     }
    907     TiedRegisterPairs.push_back(std::make_pair(DefIdx, I));
    908   }
    909   // FIXME: Verify that for non INLINEASM instructions, the def and use tied
    910   // indices must be less than tied max.
    911   for (const auto &TiedPair : TiedRegisterPairs)
    912     MI.tieOperands(TiedPair.first, TiedPair.second);
    913   return false;
    914 }
    915 
    916 bool MIParser::parseRegisterOperand(MachineOperand &Dest,
    917                                     Optional<unsigned> &TiedDefIdx,
    918                                     bool IsDef) {
    919   unsigned Reg;
    920   unsigned Flags = IsDef ? RegState::Define : 0;
    921   while (Token.isRegisterFlag()) {
    922     if (parseRegisterFlag(Flags))
    923       return true;
    924   }
    925   if (!Token.isRegister())
    926     return error("expected a register after register flags");
    927   if (parseRegister(Reg))
    928     return true;
    929   lex();
    930   unsigned SubReg = 0;
    931   if (Token.is(MIToken::colon)) {
    932     if (parseSubRegisterIndex(SubReg))
    933       return true;
    934   }
    935   if ((Flags & RegState::Define) == 0 && consumeIfPresent(MIToken::lparen)) {
    936     unsigned Idx;
    937     if (parseRegisterTiedDefIndex(Idx))
    938       return true;
    939     TiedDefIdx = Idx;
    940   }
    941   Dest = MachineOperand::CreateReg(
    942       Reg, Flags & RegState::Define, Flags & RegState::Implicit,
    943       Flags & RegState::Kill, Flags & RegState::Dead, Flags & RegState::Undef,
    944       Flags & RegState::EarlyClobber, SubReg, Flags & RegState::Debug,
    945       Flags & RegState::InternalRead);
    946   return false;
    947 }
    948 
    949 bool MIParser::parseImmediateOperand(MachineOperand &Dest) {
    950   assert(Token.is(MIToken::IntegerLiteral));
    951   const APSInt &Int = Token.integerValue();
    952   if (Int.getMinSignedBits() > 64)
    953     return error("integer literal is too large to be an immediate operand");
    954   Dest = MachineOperand::CreateImm(Int.getExtValue());
    955   lex();
    956   return false;
    957 }
    958 
    959 bool MIParser::parseIRConstant(StringRef::iterator Loc, StringRef StringValue,
    960                                const Constant *&C) {
    961   auto Source = StringValue.str(); // The source has to be null terminated.
    962   SMDiagnostic Err;
    963   C = parseConstantValue(Source.c_str(), Err, *MF.getFunction()->getParent(),
    964                          &IRSlots);
    965   if (!C)
    966     return error(Loc + Err.getColumnNo(), Err.getMessage());
    967   return false;
    968 }
    969 
    970 bool MIParser::parseIRConstant(StringRef::iterator Loc, const Constant *&C) {
    971   if (parseIRConstant(Loc, StringRef(Loc, Token.range().end() - Loc), C))
    972     return true;
    973   lex();
    974   return false;
    975 }
    976 
    977 bool MIParser::parseTypedImmediateOperand(MachineOperand &Dest) {
    978   assert(Token.is(MIToken::IntegerType));
    979   auto Loc = Token.location();
    980   lex();
    981   if (Token.isNot(MIToken::IntegerLiteral))
    982     return error("expected an integer literal");
    983   const Constant *C = nullptr;
    984   if (parseIRConstant(Loc, C))
    985     return true;
    986   Dest = MachineOperand::CreateCImm(cast<ConstantInt>(C));
    987   return false;
    988 }
    989 
    990 bool MIParser::parseFPImmediateOperand(MachineOperand &Dest) {
    991   auto Loc = Token.location();
    992   lex();
    993   if (Token.isNot(MIToken::FloatingPointLiteral))
    994     return error("expected a floating point literal");
    995   const Constant *C = nullptr;
    996   if (parseIRConstant(Loc, C))
    997     return true;
    998   Dest = MachineOperand::CreateFPImm(cast<ConstantFP>(C));
    999   return false;
   1000 }
   1001 
   1002 bool MIParser::getUnsigned(unsigned &Result) {
   1003   assert(Token.hasIntegerValue() && "Expected a token with an integer value");
   1004   const uint64_t Limit = uint64_t(std::numeric_limits<unsigned>::max()) + 1;
   1005   uint64_t Val64 = Token.integerValue().getLimitedValue(Limit);
   1006   if (Val64 == Limit)
   1007     return error("expected 32-bit integer (too large)");
   1008   Result = Val64;
   1009   return false;
   1010 }
   1011 
   1012 bool MIParser::parseMBBReference(MachineBasicBlock *&MBB) {
   1013   assert(Token.is(MIToken::MachineBasicBlock) ||
   1014          Token.is(MIToken::MachineBasicBlockLabel));
   1015   unsigned Number;
   1016   if (getUnsigned(Number))
   1017     return true;
   1018   auto MBBInfo = PFS.MBBSlots.find(Number);
   1019   if (MBBInfo == PFS.MBBSlots.end())
   1020     return error(Twine("use of undefined machine basic block #") +
   1021                  Twine(Number));
   1022   MBB = MBBInfo->second;
   1023   if (!Token.stringValue().empty() && Token.stringValue() != MBB->getName())
   1024     return error(Twine("the name of machine basic block #") + Twine(Number) +
   1025                  " isn't '" + Token.stringValue() + "'");
   1026   return false;
   1027 }
   1028 
   1029 bool MIParser::parseMBBOperand(MachineOperand &Dest) {
   1030   MachineBasicBlock *MBB;
   1031   if (parseMBBReference(MBB))
   1032     return true;
   1033   Dest = MachineOperand::CreateMBB(MBB);
   1034   lex();
   1035   return false;
   1036 }
   1037 
   1038 bool MIParser::parseStackFrameIndex(int &FI) {
   1039   assert(Token.is(MIToken::StackObject));
   1040   unsigned ID;
   1041   if (getUnsigned(ID))
   1042     return true;
   1043   auto ObjectInfo = PFS.StackObjectSlots.find(ID);
   1044   if (ObjectInfo == PFS.StackObjectSlots.end())
   1045     return error(Twine("use of undefined stack object '%stack.") + Twine(ID) +
   1046                  "'");
   1047   StringRef Name;
   1048   if (const auto *Alloca =
   1049           MF.getFrameInfo()->getObjectAllocation(ObjectInfo->second))
   1050     Name = Alloca->getName();
   1051   if (!Token.stringValue().empty() && Token.stringValue() != Name)
   1052     return error(Twine("the name of the stack object '%stack.") + Twine(ID) +
   1053                  "' isn't '" + Token.stringValue() + "'");
   1054   lex();
   1055   FI = ObjectInfo->second;
   1056   return false;
   1057 }
   1058 
   1059 bool MIParser::parseStackObjectOperand(MachineOperand &Dest) {
   1060   int FI;
   1061   if (parseStackFrameIndex(FI))
   1062     return true;
   1063   Dest = MachineOperand::CreateFI(FI);
   1064   return false;
   1065 }
   1066 
   1067 bool MIParser::parseFixedStackFrameIndex(int &FI) {
   1068   assert(Token.is(MIToken::FixedStackObject));
   1069   unsigned ID;
   1070   if (getUnsigned(ID))
   1071     return true;
   1072   auto ObjectInfo = PFS.FixedStackObjectSlots.find(ID);
   1073   if (ObjectInfo == PFS.FixedStackObjectSlots.end())
   1074     return error(Twine("use of undefined fixed stack object '%fixed-stack.") +
   1075                  Twine(ID) + "'");
   1076   lex();
   1077   FI = ObjectInfo->second;
   1078   return false;
   1079 }
   1080 
   1081 bool MIParser::parseFixedStackObjectOperand(MachineOperand &Dest) {
   1082   int FI;
   1083   if (parseFixedStackFrameIndex(FI))
   1084     return true;
   1085   Dest = MachineOperand::CreateFI(FI);
   1086   return false;
   1087 }
   1088 
   1089 bool MIParser::parseGlobalValue(GlobalValue *&GV) {
   1090   switch (Token.kind()) {
   1091   case MIToken::NamedGlobalValue: {
   1092     const Module *M = MF.getFunction()->getParent();
   1093     GV = M->getNamedValue(Token.stringValue());
   1094     if (!GV)
   1095       return error(Twine("use of undefined global value '") + Token.range() +
   1096                    "'");
   1097     break;
   1098   }
   1099   case MIToken::GlobalValue: {
   1100     unsigned GVIdx;
   1101     if (getUnsigned(GVIdx))
   1102       return true;
   1103     if (GVIdx >= IRSlots.GlobalValues.size())
   1104       return error(Twine("use of undefined global value '@") + Twine(GVIdx) +
   1105                    "'");
   1106     GV = IRSlots.GlobalValues[GVIdx];
   1107     break;
   1108   }
   1109   default:
   1110     llvm_unreachable("The current token should be a global value");
   1111   }
   1112   return false;
   1113 }
   1114 
   1115 bool MIParser::parseGlobalAddressOperand(MachineOperand &Dest) {
   1116   GlobalValue *GV = nullptr;
   1117   if (parseGlobalValue(GV))
   1118     return true;
   1119   lex();
   1120   Dest = MachineOperand::CreateGA(GV, /*Offset=*/0);
   1121   if (parseOperandsOffset(Dest))
   1122     return true;
   1123   return false;
   1124 }
   1125 
   1126 bool MIParser::parseConstantPoolIndexOperand(MachineOperand &Dest) {
   1127   assert(Token.is(MIToken::ConstantPoolItem));
   1128   unsigned ID;
   1129   if (getUnsigned(ID))
   1130     return true;
   1131   auto ConstantInfo = PFS.ConstantPoolSlots.find(ID);
   1132   if (ConstantInfo == PFS.ConstantPoolSlots.end())
   1133     return error("use of undefined constant '%const." + Twine(ID) + "'");
   1134   lex();
   1135   Dest = MachineOperand::CreateCPI(ID, /*Offset=*/0);
   1136   if (parseOperandsOffset(Dest))
   1137     return true;
   1138   return false;
   1139 }
   1140 
   1141 bool MIParser::parseJumpTableIndexOperand(MachineOperand &Dest) {
   1142   assert(Token.is(MIToken::JumpTableIndex));
   1143   unsigned ID;
   1144   if (getUnsigned(ID))
   1145     return true;
   1146   auto JumpTableEntryInfo = PFS.JumpTableSlots.find(ID);
   1147   if (JumpTableEntryInfo == PFS.JumpTableSlots.end())
   1148     return error("use of undefined jump table '%jump-table." + Twine(ID) + "'");
   1149   lex();
   1150   Dest = MachineOperand::CreateJTI(JumpTableEntryInfo->second);
   1151   return false;
   1152 }
   1153 
   1154 bool MIParser::parseExternalSymbolOperand(MachineOperand &Dest) {
   1155   assert(Token.is(MIToken::ExternalSymbol));
   1156   const char *Symbol = MF.createExternalSymbolName(Token.stringValue());
   1157   lex();
   1158   Dest = MachineOperand::CreateES(Symbol);
   1159   if (parseOperandsOffset(Dest))
   1160     return true;
   1161   return false;
   1162 }
   1163 
   1164 bool MIParser::parseMDNode(MDNode *&Node) {
   1165   assert(Token.is(MIToken::exclaim));
   1166   auto Loc = Token.location();
   1167   lex();
   1168   if (Token.isNot(MIToken::IntegerLiteral) || Token.integerValue().isSigned())
   1169     return error("expected metadata id after '!'");
   1170   unsigned ID;
   1171   if (getUnsigned(ID))
   1172     return true;
   1173   auto NodeInfo = IRSlots.MetadataNodes.find(ID);
   1174   if (NodeInfo == IRSlots.MetadataNodes.end())
   1175     return error(Loc, "use of undefined metadata '!" + Twine(ID) + "'");
   1176   lex();
   1177   Node = NodeInfo->second.get();
   1178   return false;
   1179 }
   1180 
   1181 bool MIParser::parseMetadataOperand(MachineOperand &Dest) {
   1182   MDNode *Node = nullptr;
   1183   if (parseMDNode(Node))
   1184     return true;
   1185   Dest = MachineOperand::CreateMetadata(Node);
   1186   return false;
   1187 }
   1188 
   1189 bool MIParser::parseCFIOffset(int &Offset) {
   1190   if (Token.isNot(MIToken::IntegerLiteral))
   1191     return error("expected a cfi offset");
   1192   if (Token.integerValue().getMinSignedBits() > 32)
   1193     return error("expected a 32 bit integer (the cfi offset is too large)");
   1194   Offset = (int)Token.integerValue().getExtValue();
   1195   lex();
   1196   return false;
   1197 }
   1198 
   1199 bool MIParser::parseCFIRegister(unsigned &Reg) {
   1200   if (Token.isNot(MIToken::NamedRegister))
   1201     return error("expected a cfi register");
   1202   unsigned LLVMReg;
   1203   if (parseRegister(LLVMReg))
   1204     return true;
   1205   const auto *TRI = MF.getSubtarget().getRegisterInfo();
   1206   assert(TRI && "Expected target register info");
   1207   int DwarfReg = TRI->getDwarfRegNum(LLVMReg, true);
   1208   if (DwarfReg < 0)
   1209     return error("invalid DWARF register");
   1210   Reg = (unsigned)DwarfReg;
   1211   lex();
   1212   return false;
   1213 }
   1214 
   1215 bool MIParser::parseCFIOperand(MachineOperand &Dest) {
   1216   auto Kind = Token.kind();
   1217   lex();
   1218   auto &MMI = MF.getMMI();
   1219   int Offset;
   1220   unsigned Reg;
   1221   unsigned CFIIndex;
   1222   switch (Kind) {
   1223   case MIToken::kw_cfi_same_value:
   1224     if (parseCFIRegister(Reg))
   1225       return true;
   1226     CFIIndex =
   1227         MMI.addFrameInst(MCCFIInstruction::createSameValue(nullptr, Reg));
   1228     break;
   1229   case MIToken::kw_cfi_offset:
   1230     if (parseCFIRegister(Reg) || expectAndConsume(MIToken::comma) ||
   1231         parseCFIOffset(Offset))
   1232       return true;
   1233     CFIIndex =
   1234         MMI.addFrameInst(MCCFIInstruction::createOffset(nullptr, Reg, Offset));
   1235     break;
   1236   case MIToken::kw_cfi_def_cfa_register:
   1237     if (parseCFIRegister(Reg))
   1238       return true;
   1239     CFIIndex =
   1240         MMI.addFrameInst(MCCFIInstruction::createDefCfaRegister(nullptr, Reg));
   1241     break;
   1242   case MIToken::kw_cfi_def_cfa_offset:
   1243     if (parseCFIOffset(Offset))
   1244       return true;
   1245     // NB: MCCFIInstruction::createDefCfaOffset negates the offset.
   1246     CFIIndex = MMI.addFrameInst(
   1247         MCCFIInstruction::createDefCfaOffset(nullptr, -Offset));
   1248     break;
   1249   case MIToken::kw_cfi_def_cfa:
   1250     if (parseCFIRegister(Reg) || expectAndConsume(MIToken::comma) ||
   1251         parseCFIOffset(Offset))
   1252       return true;
   1253     // NB: MCCFIInstruction::createDefCfa negates the offset.
   1254     CFIIndex =
   1255         MMI.addFrameInst(MCCFIInstruction::createDefCfa(nullptr, Reg, -Offset));
   1256     break;
   1257   default:
   1258     // TODO: Parse the other CFI operands.
   1259     llvm_unreachable("The current token should be a cfi operand");
   1260   }
   1261   Dest = MachineOperand::CreateCFIIndex(CFIIndex);
   1262   return false;
   1263 }
   1264 
   1265 bool MIParser::parseIRBlock(BasicBlock *&BB, const Function &F) {
   1266   switch (Token.kind()) {
   1267   case MIToken::NamedIRBlock: {
   1268     BB = dyn_cast_or_null<BasicBlock>(
   1269         F.getValueSymbolTable().lookup(Token.stringValue()));
   1270     if (!BB)
   1271       return error(Twine("use of undefined IR block '") + Token.range() + "'");
   1272     break;
   1273   }
   1274   case MIToken::IRBlock: {
   1275     unsigned SlotNumber = 0;
   1276     if (getUnsigned(SlotNumber))
   1277       return true;
   1278     BB = const_cast<BasicBlock *>(getIRBlock(SlotNumber, F));
   1279     if (!BB)
   1280       return error(Twine("use of undefined IR block '%ir-block.") +
   1281                    Twine(SlotNumber) + "'");
   1282     break;
   1283   }
   1284   default:
   1285     llvm_unreachable("The current token should be an IR block reference");
   1286   }
   1287   return false;
   1288 }
   1289 
   1290 bool MIParser::parseBlockAddressOperand(MachineOperand &Dest) {
   1291   assert(Token.is(MIToken::kw_blockaddress));
   1292   lex();
   1293   if (expectAndConsume(MIToken::lparen))
   1294     return true;
   1295   if (Token.isNot(MIToken::GlobalValue) &&
   1296       Token.isNot(MIToken::NamedGlobalValue))
   1297     return error("expected a global value");
   1298   GlobalValue *GV = nullptr;
   1299   if (parseGlobalValue(GV))
   1300     return true;
   1301   auto *F = dyn_cast<Function>(GV);
   1302   if (!F)
   1303     return error("expected an IR function reference");
   1304   lex();
   1305   if (expectAndConsume(MIToken::comma))
   1306     return true;
   1307   BasicBlock *BB = nullptr;
   1308   if (Token.isNot(MIToken::IRBlock) && Token.isNot(MIToken::NamedIRBlock))
   1309     return error("expected an IR block reference");
   1310   if (parseIRBlock(BB, *F))
   1311     return true;
   1312   lex();
   1313   if (expectAndConsume(MIToken::rparen))
   1314     return true;
   1315   Dest = MachineOperand::CreateBA(BlockAddress::get(F, BB), /*Offset=*/0);
   1316   if (parseOperandsOffset(Dest))
   1317     return true;
   1318   return false;
   1319 }
   1320 
   1321 bool MIParser::parseTargetIndexOperand(MachineOperand &Dest) {
   1322   assert(Token.is(MIToken::kw_target_index));
   1323   lex();
   1324   if (expectAndConsume(MIToken::lparen))
   1325     return true;
   1326   if (Token.isNot(MIToken::Identifier))
   1327     return error("expected the name of the target index");
   1328   int Index = 0;
   1329   if (getTargetIndex(Token.stringValue(), Index))
   1330     return error("use of undefined target index '" + Token.stringValue() + "'");
   1331   lex();
   1332   if (expectAndConsume(MIToken::rparen))
   1333     return true;
   1334   Dest = MachineOperand::CreateTargetIndex(unsigned(Index), /*Offset=*/0);
   1335   if (parseOperandsOffset(Dest))
   1336     return true;
   1337   return false;
   1338 }
   1339 
   1340 bool MIParser::parseLiveoutRegisterMaskOperand(MachineOperand &Dest) {
   1341   assert(Token.is(MIToken::kw_liveout));
   1342   const auto *TRI = MF.getSubtarget().getRegisterInfo();
   1343   assert(TRI && "Expected target register info");
   1344   uint32_t *Mask = MF.allocateRegisterMask(TRI->getNumRegs());
   1345   lex();
   1346   if (expectAndConsume(MIToken::lparen))
   1347     return true;
   1348   while (true) {
   1349     if (Token.isNot(MIToken::NamedRegister))
   1350       return error("expected a named register");
   1351     unsigned Reg = 0;
   1352     if (parseRegister(Reg))
   1353       return true;
   1354     lex();
   1355     Mask[Reg / 32] |= 1U << (Reg % 32);
   1356     // TODO: Report an error if the same register is used more than once.
   1357     if (Token.isNot(MIToken::comma))
   1358       break;
   1359     lex();
   1360   }
   1361   if (expectAndConsume(MIToken::rparen))
   1362     return true;
   1363   Dest = MachineOperand::CreateRegLiveOut(Mask);
   1364   return false;
   1365 }
   1366 
   1367 bool MIParser::parseMachineOperand(MachineOperand &Dest,
   1368                                    Optional<unsigned> &TiedDefIdx) {
   1369   switch (Token.kind()) {
   1370   case MIToken::kw_implicit:
   1371   case MIToken::kw_implicit_define:
   1372   case MIToken::kw_def:
   1373   case MIToken::kw_dead:
   1374   case MIToken::kw_killed:
   1375   case MIToken::kw_undef:
   1376   case MIToken::kw_internal:
   1377   case MIToken::kw_early_clobber:
   1378   case MIToken::kw_debug_use:
   1379   case MIToken::underscore:
   1380   case MIToken::NamedRegister:
   1381   case MIToken::VirtualRegister:
   1382     return parseRegisterOperand(Dest, TiedDefIdx);
   1383   case MIToken::IntegerLiteral:
   1384     return parseImmediateOperand(Dest);
   1385   case MIToken::IntegerType:
   1386     return parseTypedImmediateOperand(Dest);
   1387   case MIToken::kw_half:
   1388   case MIToken::kw_float:
   1389   case MIToken::kw_double:
   1390   case MIToken::kw_x86_fp80:
   1391   case MIToken::kw_fp128:
   1392   case MIToken::kw_ppc_fp128:
   1393     return parseFPImmediateOperand(Dest);
   1394   case MIToken::MachineBasicBlock:
   1395     return parseMBBOperand(Dest);
   1396   case MIToken::StackObject:
   1397     return parseStackObjectOperand(Dest);
   1398   case MIToken::FixedStackObject:
   1399     return parseFixedStackObjectOperand(Dest);
   1400   case MIToken::GlobalValue:
   1401   case MIToken::NamedGlobalValue:
   1402     return parseGlobalAddressOperand(Dest);
   1403   case MIToken::ConstantPoolItem:
   1404     return parseConstantPoolIndexOperand(Dest);
   1405   case MIToken::JumpTableIndex:
   1406     return parseJumpTableIndexOperand(Dest);
   1407   case MIToken::ExternalSymbol:
   1408     return parseExternalSymbolOperand(Dest);
   1409   case MIToken::exclaim:
   1410     return parseMetadataOperand(Dest);
   1411   case MIToken::kw_cfi_same_value:
   1412   case MIToken::kw_cfi_offset:
   1413   case MIToken::kw_cfi_def_cfa_register:
   1414   case MIToken::kw_cfi_def_cfa_offset:
   1415   case MIToken::kw_cfi_def_cfa:
   1416     return parseCFIOperand(Dest);
   1417   case MIToken::kw_blockaddress:
   1418     return parseBlockAddressOperand(Dest);
   1419   case MIToken::kw_target_index:
   1420     return parseTargetIndexOperand(Dest);
   1421   case MIToken::kw_liveout:
   1422     return parseLiveoutRegisterMaskOperand(Dest);
   1423   case MIToken::Error:
   1424     return true;
   1425   case MIToken::Identifier:
   1426     if (const auto *RegMask = getRegMask(Token.stringValue())) {
   1427       Dest = MachineOperand::CreateRegMask(RegMask);
   1428       lex();
   1429       break;
   1430     }
   1431   // fallthrough
   1432   default:
   1433     // FIXME: Parse the MCSymbol machine operand.
   1434     return error("expected a machine operand");
   1435   }
   1436   return false;
   1437 }
   1438 
   1439 bool MIParser::parseMachineOperandAndTargetFlags(
   1440     MachineOperand &Dest, Optional<unsigned> &TiedDefIdx) {
   1441   unsigned TF = 0;
   1442   bool HasTargetFlags = false;
   1443   if (Token.is(MIToken::kw_target_flags)) {
   1444     HasTargetFlags = true;
   1445     lex();
   1446     if (expectAndConsume(MIToken::lparen))
   1447       return true;
   1448     if (Token.isNot(MIToken::Identifier))
   1449       return error("expected the name of the target flag");
   1450     if (getDirectTargetFlag(Token.stringValue(), TF)) {
   1451       if (getBitmaskTargetFlag(Token.stringValue(), TF))
   1452         return error("use of undefined target flag '" + Token.stringValue() +
   1453                      "'");
   1454     }
   1455     lex();
   1456     while (Token.is(MIToken::comma)) {
   1457       lex();
   1458       if (Token.isNot(MIToken::Identifier))
   1459         return error("expected the name of the target flag");
   1460       unsigned BitFlag = 0;
   1461       if (getBitmaskTargetFlag(Token.stringValue(), BitFlag))
   1462         return error("use of undefined target flag '" + Token.stringValue() +
   1463                      "'");
   1464       // TODO: Report an error when using a duplicate bit target flag.
   1465       TF |= BitFlag;
   1466       lex();
   1467     }
   1468     if (expectAndConsume(MIToken::rparen))
   1469       return true;
   1470   }
   1471   auto Loc = Token.location();
   1472   if (parseMachineOperand(Dest, TiedDefIdx))
   1473     return true;
   1474   if (!HasTargetFlags)
   1475     return false;
   1476   if (Dest.isReg())
   1477     return error(Loc, "register operands can't have target flags");
   1478   Dest.setTargetFlags(TF);
   1479   return false;
   1480 }
   1481 
   1482 bool MIParser::parseOffset(int64_t &Offset) {
   1483   if (Token.isNot(MIToken::plus) && Token.isNot(MIToken::minus))
   1484     return false;
   1485   StringRef Sign = Token.range();
   1486   bool IsNegative = Token.is(MIToken::minus);
   1487   lex();
   1488   if (Token.isNot(MIToken::IntegerLiteral))
   1489     return error("expected an integer literal after '" + Sign + "'");
   1490   if (Token.integerValue().getMinSignedBits() > 64)
   1491     return error("expected 64-bit integer (too large)");
   1492   Offset = Token.integerValue().getExtValue();
   1493   if (IsNegative)
   1494     Offset = -Offset;
   1495   lex();
   1496   return false;
   1497 }
   1498 
   1499 bool MIParser::parseAlignment(unsigned &Alignment) {
   1500   assert(Token.is(MIToken::kw_align));
   1501   lex();
   1502   if (Token.isNot(MIToken::IntegerLiteral) || Token.integerValue().isSigned())
   1503     return error("expected an integer literal after 'align'");
   1504   if (getUnsigned(Alignment))
   1505     return true;
   1506   lex();
   1507   return false;
   1508 }
   1509 
   1510 bool MIParser::parseOperandsOffset(MachineOperand &Op) {
   1511   int64_t Offset = 0;
   1512   if (parseOffset(Offset))
   1513     return true;
   1514   Op.setOffset(Offset);
   1515   return false;
   1516 }
   1517 
   1518 bool MIParser::parseIRValue(const Value *&V) {
   1519   switch (Token.kind()) {
   1520   case MIToken::NamedIRValue: {
   1521     V = MF.getFunction()->getValueSymbolTable().lookup(Token.stringValue());
   1522     break;
   1523   }
   1524   case MIToken::IRValue: {
   1525     unsigned SlotNumber = 0;
   1526     if (getUnsigned(SlotNumber))
   1527       return true;
   1528     V = getIRValue(SlotNumber);
   1529     break;
   1530   }
   1531   case MIToken::NamedGlobalValue:
   1532   case MIToken::GlobalValue: {
   1533     GlobalValue *GV = nullptr;
   1534     if (parseGlobalValue(GV))
   1535       return true;
   1536     V = GV;
   1537     break;
   1538   }
   1539   case MIToken::QuotedIRValue: {
   1540     const Constant *C = nullptr;
   1541     if (parseIRConstant(Token.location(), Token.stringValue(), C))
   1542       return true;
   1543     V = C;
   1544     break;
   1545   }
   1546   default:
   1547     llvm_unreachable("The current token should be an IR block reference");
   1548   }
   1549   if (!V)
   1550     return error(Twine("use of undefined IR value '") + Token.range() + "'");
   1551   return false;
   1552 }
   1553 
   1554 bool MIParser::getUint64(uint64_t &Result) {
   1555   assert(Token.hasIntegerValue());
   1556   if (Token.integerValue().getActiveBits() > 64)
   1557     return error("expected 64-bit integer (too large)");
   1558   Result = Token.integerValue().getZExtValue();
   1559   return false;
   1560 }
   1561 
   1562 bool MIParser::parseMemoryOperandFlag(unsigned &Flags) {
   1563   const unsigned OldFlags = Flags;
   1564   switch (Token.kind()) {
   1565   case MIToken::kw_volatile:
   1566     Flags |= MachineMemOperand::MOVolatile;
   1567     break;
   1568   case MIToken::kw_non_temporal:
   1569     Flags |= MachineMemOperand::MONonTemporal;
   1570     break;
   1571   case MIToken::kw_invariant:
   1572     Flags |= MachineMemOperand::MOInvariant;
   1573     break;
   1574   // TODO: parse the target specific memory operand flags.
   1575   default:
   1576     llvm_unreachable("The current token should be a memory operand flag");
   1577   }
   1578   if (OldFlags == Flags)
   1579     // We know that the same flag is specified more than once when the flags
   1580     // weren't modified.
   1581     return error("duplicate '" + Token.stringValue() + "' memory operand flag");
   1582   lex();
   1583   return false;
   1584 }
   1585 
   1586 bool MIParser::parseMemoryPseudoSourceValue(const PseudoSourceValue *&PSV) {
   1587   switch (Token.kind()) {
   1588   case MIToken::kw_stack:
   1589     PSV = MF.getPSVManager().getStack();
   1590     break;
   1591   case MIToken::kw_got:
   1592     PSV = MF.getPSVManager().getGOT();
   1593     break;
   1594   case MIToken::kw_jump_table:
   1595     PSV = MF.getPSVManager().getJumpTable();
   1596     break;
   1597   case MIToken::kw_constant_pool:
   1598     PSV = MF.getPSVManager().getConstantPool();
   1599     break;
   1600   case MIToken::FixedStackObject: {
   1601     int FI;
   1602     if (parseFixedStackFrameIndex(FI))
   1603       return true;
   1604     PSV = MF.getPSVManager().getFixedStack(FI);
   1605     // The token was already consumed, so use return here instead of break.
   1606     return false;
   1607   }
   1608   case MIToken::kw_call_entry: {
   1609     lex();
   1610     switch (Token.kind()) {
   1611     case MIToken::GlobalValue:
   1612     case MIToken::NamedGlobalValue: {
   1613       GlobalValue *GV = nullptr;
   1614       if (parseGlobalValue(GV))
   1615         return true;
   1616       PSV = MF.getPSVManager().getGlobalValueCallEntry(GV);
   1617       break;
   1618     }
   1619     case MIToken::ExternalSymbol:
   1620       PSV = MF.getPSVManager().getExternalSymbolCallEntry(
   1621           MF.createExternalSymbolName(Token.stringValue()));
   1622       break;
   1623     default:
   1624       return error(
   1625           "expected a global value or an external symbol after 'call-entry'");
   1626     }
   1627     break;
   1628   }
   1629   default:
   1630     llvm_unreachable("The current token should be pseudo source value");
   1631   }
   1632   lex();
   1633   return false;
   1634 }
   1635 
   1636 bool MIParser::parseMachinePointerInfo(MachinePointerInfo &Dest) {
   1637   if (Token.is(MIToken::kw_constant_pool) || Token.is(MIToken::kw_stack) ||
   1638       Token.is(MIToken::kw_got) || Token.is(MIToken::kw_jump_table) ||
   1639       Token.is(MIToken::FixedStackObject) || Token.is(MIToken::kw_call_entry)) {
   1640     const PseudoSourceValue *PSV = nullptr;
   1641     if (parseMemoryPseudoSourceValue(PSV))
   1642       return true;
   1643     int64_t Offset = 0;
   1644     if (parseOffset(Offset))
   1645       return true;
   1646     Dest = MachinePointerInfo(PSV, Offset);
   1647     return false;
   1648   }
   1649   if (Token.isNot(MIToken::NamedIRValue) && Token.isNot(MIToken::IRValue) &&
   1650       Token.isNot(MIToken::GlobalValue) &&
   1651       Token.isNot(MIToken::NamedGlobalValue) &&
   1652       Token.isNot(MIToken::QuotedIRValue))
   1653     return error("expected an IR value reference");
   1654   const Value *V = nullptr;
   1655   if (parseIRValue(V))
   1656     return true;
   1657   if (!V->getType()->isPointerTy())
   1658     return error("expected a pointer IR value");
   1659   lex();
   1660   int64_t Offset = 0;
   1661   if (parseOffset(Offset))
   1662     return true;
   1663   Dest = MachinePointerInfo(V, Offset);
   1664   return false;
   1665 }
   1666 
   1667 bool MIParser::parseMachineMemoryOperand(MachineMemOperand *&Dest) {
   1668   if (expectAndConsume(MIToken::lparen))
   1669     return true;
   1670   unsigned Flags = 0;
   1671   while (Token.isMemoryOperandFlag()) {
   1672     if (parseMemoryOperandFlag(Flags))
   1673       return true;
   1674   }
   1675   if (Token.isNot(MIToken::Identifier) ||
   1676       (Token.stringValue() != "load" && Token.stringValue() != "store"))
   1677     return error("expected 'load' or 'store' memory operation");
   1678   if (Token.stringValue() == "load")
   1679     Flags |= MachineMemOperand::MOLoad;
   1680   else
   1681     Flags |= MachineMemOperand::MOStore;
   1682   lex();
   1683 
   1684   if (Token.isNot(MIToken::IntegerLiteral))
   1685     return error("expected the size integer literal after memory operation");
   1686   uint64_t Size;
   1687   if (getUint64(Size))
   1688     return true;
   1689   lex();
   1690 
   1691   const char *Word = Flags & MachineMemOperand::MOLoad ? "from" : "into";
   1692   if (Token.isNot(MIToken::Identifier) || Token.stringValue() != Word)
   1693     return error(Twine("expected '") + Word + "'");
   1694   lex();
   1695 
   1696   MachinePointerInfo Ptr = MachinePointerInfo();
   1697   if (parseMachinePointerInfo(Ptr))
   1698     return true;
   1699   unsigned BaseAlignment = Size;
   1700   AAMDNodes AAInfo;
   1701   MDNode *Range = nullptr;
   1702   while (consumeIfPresent(MIToken::comma)) {
   1703     switch (Token.kind()) {
   1704     case MIToken::kw_align:
   1705       if (parseAlignment(BaseAlignment))
   1706         return true;
   1707       break;
   1708     case MIToken::md_tbaa:
   1709       lex();
   1710       if (parseMDNode(AAInfo.TBAA))
   1711         return true;
   1712       break;
   1713     case MIToken::md_alias_scope:
   1714       lex();
   1715       if (parseMDNode(AAInfo.Scope))
   1716         return true;
   1717       break;
   1718     case MIToken::md_noalias:
   1719       lex();
   1720       if (parseMDNode(AAInfo.NoAlias))
   1721         return true;
   1722       break;
   1723     case MIToken::md_range:
   1724       lex();
   1725       if (parseMDNode(Range))
   1726         return true;
   1727       break;
   1728     // TODO: Report an error on duplicate metadata nodes.
   1729     default:
   1730       return error("expected 'align' or '!tbaa' or '!alias.scope' or "
   1731                    "'!noalias' or '!range'");
   1732     }
   1733   }
   1734   if (expectAndConsume(MIToken::rparen))
   1735     return true;
   1736   Dest =
   1737       MF.getMachineMemOperand(Ptr, Flags, Size, BaseAlignment, AAInfo, Range);
   1738   return false;
   1739 }
   1740 
   1741 void MIParser::initNames2InstrOpCodes() {
   1742   if (!Names2InstrOpCodes.empty())
   1743     return;
   1744   const auto *TII = MF.getSubtarget().getInstrInfo();
   1745   assert(TII && "Expected target instruction info");
   1746   for (unsigned I = 0, E = TII->getNumOpcodes(); I < E; ++I)
   1747     Names2InstrOpCodes.insert(std::make_pair(StringRef(TII->getName(I)), I));
   1748 }
   1749 
   1750 bool MIParser::parseInstrName(StringRef InstrName, unsigned &OpCode) {
   1751   initNames2InstrOpCodes();
   1752   auto InstrInfo = Names2InstrOpCodes.find(InstrName);
   1753   if (InstrInfo == Names2InstrOpCodes.end())
   1754     return true;
   1755   OpCode = InstrInfo->getValue();
   1756   return false;
   1757 }
   1758 
   1759 void MIParser::initNames2Regs() {
   1760   if (!Names2Regs.empty())
   1761     return;
   1762   // The '%noreg' register is the register 0.
   1763   Names2Regs.insert(std::make_pair("noreg", 0));
   1764   const auto *TRI = MF.getSubtarget().getRegisterInfo();
   1765   assert(TRI && "Expected target register info");
   1766   for (unsigned I = 0, E = TRI->getNumRegs(); I < E; ++I) {
   1767     bool WasInserted =
   1768         Names2Regs.insert(std::make_pair(StringRef(TRI->getName(I)).lower(), I))
   1769             .second;
   1770     (void)WasInserted;
   1771     assert(WasInserted && "Expected registers to be unique case-insensitively");
   1772   }
   1773 }
   1774 
   1775 bool MIParser::getRegisterByName(StringRef RegName, unsigned &Reg) {
   1776   initNames2Regs();
   1777   auto RegInfo = Names2Regs.find(RegName);
   1778   if (RegInfo == Names2Regs.end())
   1779     return true;
   1780   Reg = RegInfo->getValue();
   1781   return false;
   1782 }
   1783 
   1784 void MIParser::initNames2RegMasks() {
   1785   if (!Names2RegMasks.empty())
   1786     return;
   1787   const auto *TRI = MF.getSubtarget().getRegisterInfo();
   1788   assert(TRI && "Expected target register info");
   1789   ArrayRef<const uint32_t *> RegMasks = TRI->getRegMasks();
   1790   ArrayRef<const char *> RegMaskNames = TRI->getRegMaskNames();
   1791   assert(RegMasks.size() == RegMaskNames.size());
   1792   for (size_t I = 0, E = RegMasks.size(); I < E; ++I)
   1793     Names2RegMasks.insert(
   1794         std::make_pair(StringRef(RegMaskNames[I]).lower(), RegMasks[I]));
   1795 }
   1796 
   1797 const uint32_t *MIParser::getRegMask(StringRef Identifier) {
   1798   initNames2RegMasks();
   1799   auto RegMaskInfo = Names2RegMasks.find(Identifier);
   1800   if (RegMaskInfo == Names2RegMasks.end())
   1801     return nullptr;
   1802   return RegMaskInfo->getValue();
   1803 }
   1804 
   1805 void MIParser::initNames2SubRegIndices() {
   1806   if (!Names2SubRegIndices.empty())
   1807     return;
   1808   const TargetRegisterInfo *TRI = MF.getSubtarget().getRegisterInfo();
   1809   for (unsigned I = 1, E = TRI->getNumSubRegIndices(); I < E; ++I)
   1810     Names2SubRegIndices.insert(
   1811         std::make_pair(StringRef(TRI->getSubRegIndexName(I)).lower(), I));
   1812 }
   1813 
   1814 unsigned MIParser::getSubRegIndex(StringRef Name) {
   1815   initNames2SubRegIndices();
   1816   auto SubRegInfo = Names2SubRegIndices.find(Name);
   1817   if (SubRegInfo == Names2SubRegIndices.end())
   1818     return 0;
   1819   return SubRegInfo->getValue();
   1820 }
   1821 
   1822 static void initSlots2BasicBlocks(
   1823     const Function &F,
   1824     DenseMap<unsigned, const BasicBlock *> &Slots2BasicBlocks) {
   1825   ModuleSlotTracker MST(F.getParent(), /*ShouldInitializeAllMetadata=*/false);
   1826   MST.incorporateFunction(F);
   1827   for (auto &BB : F) {
   1828     if (BB.hasName())
   1829       continue;
   1830     int Slot = MST.getLocalSlot(&BB);
   1831     if (Slot == -1)
   1832       continue;
   1833     Slots2BasicBlocks.insert(std::make_pair(unsigned(Slot), &BB));
   1834   }
   1835 }
   1836 
   1837 static const BasicBlock *getIRBlockFromSlot(
   1838     unsigned Slot,
   1839     const DenseMap<unsigned, const BasicBlock *> &Slots2BasicBlocks) {
   1840   auto BlockInfo = Slots2BasicBlocks.find(Slot);
   1841   if (BlockInfo == Slots2BasicBlocks.end())
   1842     return nullptr;
   1843   return BlockInfo->second;
   1844 }
   1845 
   1846 const BasicBlock *MIParser::getIRBlock(unsigned Slot) {
   1847   if (Slots2BasicBlocks.empty())
   1848     initSlots2BasicBlocks(*MF.getFunction(), Slots2BasicBlocks);
   1849   return getIRBlockFromSlot(Slot, Slots2BasicBlocks);
   1850 }
   1851 
   1852 const BasicBlock *MIParser::getIRBlock(unsigned Slot, const Function &F) {
   1853   if (&F == MF.getFunction())
   1854     return getIRBlock(Slot);
   1855   DenseMap<unsigned, const BasicBlock *> CustomSlots2BasicBlocks;
   1856   initSlots2BasicBlocks(F, CustomSlots2BasicBlocks);
   1857   return getIRBlockFromSlot(Slot, CustomSlots2BasicBlocks);
   1858 }
   1859 
   1860 static void mapValueToSlot(const Value *V, ModuleSlotTracker &MST,
   1861                            DenseMap<unsigned, const Value *> &Slots2Values) {
   1862   int Slot = MST.getLocalSlot(V);
   1863   if (Slot == -1)
   1864     return;
   1865   Slots2Values.insert(std::make_pair(unsigned(Slot), V));
   1866 }
   1867 
   1868 /// Creates the mapping from slot numbers to function's unnamed IR values.
   1869 static void initSlots2Values(const Function &F,
   1870                              DenseMap<unsigned, const Value *> &Slots2Values) {
   1871   ModuleSlotTracker MST(F.getParent(), /*ShouldInitializeAllMetadata=*/false);
   1872   MST.incorporateFunction(F);
   1873   for (const auto &Arg : F.args())
   1874     mapValueToSlot(&Arg, MST, Slots2Values);
   1875   for (const auto &BB : F) {
   1876     mapValueToSlot(&BB, MST, Slots2Values);
   1877     for (const auto &I : BB)
   1878       mapValueToSlot(&I, MST, Slots2Values);
   1879   }
   1880 }
   1881 
   1882 const Value *MIParser::getIRValue(unsigned Slot) {
   1883   if (Slots2Values.empty())
   1884     initSlots2Values(*MF.getFunction(), Slots2Values);
   1885   auto ValueInfo = Slots2Values.find(Slot);
   1886   if (ValueInfo == Slots2Values.end())
   1887     return nullptr;
   1888   return ValueInfo->second;
   1889 }
   1890 
   1891 void MIParser::initNames2TargetIndices() {
   1892   if (!Names2TargetIndices.empty())
   1893     return;
   1894   const auto *TII = MF.getSubtarget().getInstrInfo();
   1895   assert(TII && "Expected target instruction info");
   1896   auto Indices = TII->getSerializableTargetIndices();
   1897   for (const auto &I : Indices)
   1898     Names2TargetIndices.insert(std::make_pair(StringRef(I.second), I.first));
   1899 }
   1900 
   1901 bool MIParser::getTargetIndex(StringRef Name, int &Index) {
   1902   initNames2TargetIndices();
   1903   auto IndexInfo = Names2TargetIndices.find(Name);
   1904   if (IndexInfo == Names2TargetIndices.end())
   1905     return true;
   1906   Index = IndexInfo->second;
   1907   return false;
   1908 }
   1909 
   1910 void MIParser::initNames2DirectTargetFlags() {
   1911   if (!Names2DirectTargetFlags.empty())
   1912     return;
   1913   const auto *TII = MF.getSubtarget().getInstrInfo();
   1914   assert(TII && "Expected target instruction info");
   1915   auto Flags = TII->getSerializableDirectMachineOperandTargetFlags();
   1916   for (const auto &I : Flags)
   1917     Names2DirectTargetFlags.insert(
   1918         std::make_pair(StringRef(I.second), I.first));
   1919 }
   1920 
   1921 bool MIParser::getDirectTargetFlag(StringRef Name, unsigned &Flag) {
   1922   initNames2DirectTargetFlags();
   1923   auto FlagInfo = Names2DirectTargetFlags.find(Name);
   1924   if (FlagInfo == Names2DirectTargetFlags.end())
   1925     return true;
   1926   Flag = FlagInfo->second;
   1927   return false;
   1928 }
   1929 
   1930 void MIParser::initNames2BitmaskTargetFlags() {
   1931   if (!Names2BitmaskTargetFlags.empty())
   1932     return;
   1933   const auto *TII = MF.getSubtarget().getInstrInfo();
   1934   assert(TII && "Expected target instruction info");
   1935   auto Flags = TII->getSerializableBitmaskMachineOperandTargetFlags();
   1936   for (const auto &I : Flags)
   1937     Names2BitmaskTargetFlags.insert(
   1938         std::make_pair(StringRef(I.second), I.first));
   1939 }
   1940 
   1941 bool MIParser::getBitmaskTargetFlag(StringRef Name, unsigned &Flag) {
   1942   initNames2BitmaskTargetFlags();
   1943   auto FlagInfo = Names2BitmaskTargetFlags.find(Name);
   1944   if (FlagInfo == Names2BitmaskTargetFlags.end())
   1945     return true;
   1946   Flag = FlagInfo->second;
   1947   return false;
   1948 }
   1949 
   1950 bool llvm::parseMachineBasicBlockDefinitions(MachineFunction &MF, StringRef Src,
   1951                                              PerFunctionMIParsingState &PFS,
   1952                                              const SlotMapping &IRSlots,
   1953                                              SMDiagnostic &Error) {
   1954   SourceMgr SM;
   1955   SM.AddNewSourceBuffer(
   1956       MemoryBuffer::getMemBuffer(Src, "", /*RequiresNullTerminator=*/false),
   1957       SMLoc());
   1958   return MIParser(SM, MF, Error, Src, PFS, IRSlots)
   1959       .parseBasicBlockDefinitions(PFS.MBBSlots);
   1960 }
   1961 
   1962 bool llvm::parseMachineInstructions(MachineFunction &MF, StringRef Src,
   1963                                     const PerFunctionMIParsingState &PFS,
   1964                                     const SlotMapping &IRSlots,
   1965                                     SMDiagnostic &Error) {
   1966   SourceMgr SM;
   1967   SM.AddNewSourceBuffer(
   1968       MemoryBuffer::getMemBuffer(Src, "", /*RequiresNullTerminator=*/false),
   1969       SMLoc());
   1970   return MIParser(SM, MF, Error, Src, PFS, IRSlots).parseBasicBlocks();
   1971 }
   1972 
   1973 bool llvm::parseMBBReference(MachineBasicBlock *&MBB, SourceMgr &SM,
   1974                              MachineFunction &MF, StringRef Src,
   1975                              const PerFunctionMIParsingState &PFS,
   1976                              const SlotMapping &IRSlots, SMDiagnostic &Error) {
   1977   return MIParser(SM, MF, Error, Src, PFS, IRSlots).parseStandaloneMBB(MBB);
   1978 }
   1979 
   1980 bool llvm::parseNamedRegisterReference(unsigned &Reg, SourceMgr &SM,
   1981                                        MachineFunction &MF, StringRef Src,
   1982                                        const PerFunctionMIParsingState &PFS,
   1983                                        const SlotMapping &IRSlots,
   1984                                        SMDiagnostic &Error) {
   1985   return MIParser(SM, MF, Error, Src, PFS, IRSlots)
   1986       .parseStandaloneNamedRegister(Reg);
   1987 }
   1988 
   1989 bool llvm::parseVirtualRegisterReference(unsigned &Reg, SourceMgr &SM,
   1990                                          MachineFunction &MF, StringRef Src,
   1991                                          const PerFunctionMIParsingState &PFS,
   1992                                          const SlotMapping &IRSlots,
   1993                                          SMDiagnostic &Error) {
   1994   return MIParser(SM, MF, Error, Src, PFS, IRSlots)
   1995       .parseStandaloneVirtualRegister(Reg);
   1996 }
   1997 
   1998 bool llvm::parseStackObjectReference(int &FI, SourceMgr &SM,
   1999                                      MachineFunction &MF, StringRef Src,
   2000                                      const PerFunctionMIParsingState &PFS,
   2001                                      const SlotMapping &IRSlots,
   2002                                      SMDiagnostic &Error) {
   2003   return MIParser(SM, MF, Error, Src, PFS, IRSlots)
   2004       .parseStandaloneStackObject(FI);
   2005 }
   2006 
   2007 bool llvm::parseMDNode(MDNode *&Node, SourceMgr &SM, MachineFunction &MF,
   2008                        StringRef Src, const PerFunctionMIParsingState &PFS,
   2009                        const SlotMapping &IRSlots, SMDiagnostic &Error) {
   2010   return MIParser(SM, MF, Error, Src, PFS, IRSlots).parseStandaloneMDNode(Node);
   2011 }
   2012