//===- llvm/MC/MCTargetAsmParser.h - Target Assembly Parser -----*- C++ -*-===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// #ifndef LLVM_MC_MCPARSER_MCTARGETASMPARSER_H #define LLVM_MC_MCPARSER_MCTARGETASMPARSER_H #include "llvm/ADT/StringRef.h" #include "llvm/MC/MCExpr.h" #include "llvm/MC/MCInstrInfo.h" #include "llvm/MC/MCParser/MCAsmLexer.h" #include "llvm/MC/MCParser/MCAsmParserExtension.h" #include "llvm/MC/MCTargetOptions.h" #include "llvm/Support/SMLoc.h" #include #include namespace llvm { class MCInst; class MCParsedAsmOperand; class MCStreamer; class MCSubtargetInfo; template class SmallVectorImpl; using OperandVector = SmallVectorImpl>; enum AsmRewriteKind { AOK_Align, // Rewrite align as .align. AOK_EVEN, // Rewrite even as .even. AOK_Emit, // Rewrite _emit as .byte. AOK_Input, // Rewrite in terms of $N. AOK_Output, // Rewrite in terms of $N. AOK_SizeDirective, // Add a sizing directive (e.g., dword ptr). AOK_Label, // Rewrite local labels. AOK_EndOfStatement, // Add EndOfStatement (e.g., "\n\t"). AOK_Skip, // Skip emission (e.g., offset/type operators). AOK_IntelExpr // SizeDirective SymDisp [BaseReg + IndexReg * Scale + ImmDisp] }; const char AsmRewritePrecedence [] = { 2, // AOK_Align 2, // AOK_EVEN 2, // AOK_Emit 3, // AOK_Input 3, // AOK_Output 5, // AOK_SizeDirective 1, // AOK_Label 5, // AOK_EndOfStatement 2, // AOK_Skip 2 // AOK_IntelExpr }; // Represnt the various parts which makes up an intel expression, // used for emitting compound intel expressions struct IntelExpr { bool NeedBracs; int64_t Imm; StringRef BaseReg; StringRef IndexReg; unsigned Scale; IntelExpr(bool needBracs = false) : NeedBracs(needBracs), Imm(0), BaseReg(StringRef()), IndexReg(StringRef()), Scale(1) {} // Compund immediate expression IntelExpr(int64_t imm, bool needBracs) : IntelExpr(needBracs) { Imm = imm; } // [Reg + ImmediateExpression] // We don't bother to emit an immediate expression evaluated to zero IntelExpr(StringRef reg, int64_t imm = 0, unsigned scale = 0, bool needBracs = true) : IntelExpr(imm, needBracs) { IndexReg = reg; if (scale) Scale = scale; } // [BaseReg + IndexReg * ScaleExpression + ImmediateExpression] IntelExpr(StringRef baseReg, StringRef indexReg, unsigned scale = 0, int64_t imm = 0, bool needBracs = true) : IntelExpr(indexReg, imm, scale, needBracs) { BaseReg = baseReg; } bool hasBaseReg() const { return BaseReg.size(); } bool hasIndexReg() const { return IndexReg.size(); } bool hasRegs() const { return hasBaseReg() || hasIndexReg(); } bool isValid() const { return (Scale == 1) || (hasIndexReg() && (Scale == 2 || Scale == 4 || Scale == 8)); } }; struct AsmRewrite { AsmRewriteKind Kind; SMLoc Loc; unsigned Len; int64_t Val; StringRef Label; IntelExpr IntelExp; public: AsmRewrite(AsmRewriteKind kind, SMLoc loc, unsigned len = 0, int64_t val = 0) : Kind(kind), Loc(loc), Len(len), Val(val) {} AsmRewrite(AsmRewriteKind kind, SMLoc loc, unsigned len, StringRef label) : AsmRewrite(kind, loc, len) { Label = label; } AsmRewrite(SMLoc loc, unsigned len, IntelExpr exp) : AsmRewrite(AOK_IntelExpr, loc, len) { IntelExp = exp; } }; struct ParseInstructionInfo { SmallVectorImpl *AsmRewrites = nullptr; ParseInstructionInfo() = default; ParseInstructionInfo(SmallVectorImpl *rewrites) : AsmRewrites(rewrites) {} }; enum OperandMatchResultTy { MatchOperand_Success, // operand matched successfully MatchOperand_NoMatch, // operand did not match MatchOperand_ParseFail // operand matched but had errors }; // When matching of an assembly instruction fails, there may be multiple // encodings that are close to being a match. It's often ambiguous which one // the programmer intended to use, so we want to report an error which mentions // each of these "near-miss" encodings. This struct contains information about // one such encoding, and why it did not match the parsed instruction. class NearMissInfo { public: enum NearMissKind { NoNearMiss, NearMissOperand, NearMissFeature, NearMissPredicate, NearMissTooFewOperands, }; // The encoding is valid for the parsed assembly string. This is only used // internally to the table-generated assembly matcher. static NearMissInfo getSuccess() { return NearMissInfo(); } // The instruction encoding is not valid because it requires some target // features that are not currently enabled. MissingFeatures has a bit set for // each feature that the encoding needs but which is not enabled. static NearMissInfo getMissedFeature(uint64_t MissingFeatures) { NearMissInfo Result; Result.Kind = NearMissFeature; Result.Features = MissingFeatures; return Result; } // The instruction encoding is not valid because the target-specific // predicate function returned an error code. FailureCode is the // target-specific error code returned by the predicate. static NearMissInfo getMissedPredicate(unsigned FailureCode) { NearMissInfo Result; Result.Kind = NearMissPredicate; Result.PredicateError = FailureCode; return Result; } // The instruction encoding is not valid because one (and only one) parsed // operand is not of the correct type. OperandError is the error code // relating to the operand class expected by the encoding. OperandClass is // the type of the expected operand. Opcode is the opcode of the encoding. // OperandIndex is the index into the parsed operand list. static NearMissInfo getMissedOperand(unsigned OperandError, unsigned OperandClass, unsigned Opcode, unsigned OperandIndex) { NearMissInfo Result; Result.Kind = NearMissOperand; Result.MissedOperand.Error = OperandError; Result.MissedOperand.Class = OperandClass; Result.MissedOperand.Opcode = Opcode; Result.MissedOperand.Index = OperandIndex; return Result; } // The instruction encoding is not valid because it expects more operands // than were parsed. OperandClass is the class of the expected operand that // was not provided. Opcode is the instruction encoding. static NearMissInfo getTooFewOperands(unsigned OperandClass, unsigned Opcode) { NearMissInfo Result; Result.Kind = NearMissTooFewOperands; Result.TooFewOperands.Class = OperandClass; Result.TooFewOperands.Opcode = Opcode; return Result; } operator bool() const { return Kind != NoNearMiss; } NearMissKind getKind() const { return Kind; } // Feature flags required by the instruction, that the current target does // not have. uint64_t getFeatures() const { assert(Kind == NearMissFeature); return Features; } // Error code returned by the target predicate when validating this // instruction encoding. unsigned getPredicateError() const { assert(Kind == NearMissPredicate); return PredicateError; } // MatchClassKind of the operand that we expected to see. unsigned getOperandClass() const { assert(Kind == NearMissOperand || Kind == NearMissTooFewOperands); return MissedOperand.Class; } // Opcode of the encoding we were trying to match. unsigned getOpcode() const { assert(Kind == NearMissOperand || Kind == NearMissTooFewOperands); return MissedOperand.Opcode; } // Error code returned when validating the operand. unsigned getOperandError() const { assert(Kind == NearMissOperand); return MissedOperand.Error; } // Index of the actual operand we were trying to match in the list of parsed // operands. unsigned getOperandIndex() const { assert(Kind == NearMissOperand); return MissedOperand.Index; } private: NearMissKind Kind; // These two structs share a common prefix, so we can safely rely on the fact // that they overlap in the union. struct MissedOpInfo { unsigned Class; unsigned Opcode; unsigned Error; unsigned Index; }; struct TooFewOperandsInfo { unsigned Class; unsigned Opcode; }; union { uint64_t Features; unsigned PredicateError; MissedOpInfo MissedOperand; TooFewOperandsInfo TooFewOperands; }; NearMissInfo() : Kind(NoNearMiss) {} }; /// MCTargetAsmParser - Generic interface to target specific assembly parsers. class MCTargetAsmParser : public MCAsmParserExtension { public: enum MatchResultTy { Match_InvalidOperand, Match_MissingFeature, Match_MnemonicFail, Match_Success, Match_NearMisses, FIRST_TARGET_MATCH_RESULT_TY }; protected: // Can only create subclasses. MCTargetAsmParser(MCTargetOptions const &, const MCSubtargetInfo &STI, const MCInstrInfo &MII); /// Create a copy of STI and return a non-const reference to it. MCSubtargetInfo ©STI(); /// AvailableFeatures - The current set of available features. uint64_t AvailableFeatures = 0; /// ParsingInlineAsm - Are we parsing ms-style inline assembly? bool ParsingInlineAsm = false; /// SemaCallback - The Sema callback implementation. Must be set when parsing /// ms-style inline assembly. MCAsmParserSemaCallback *SemaCallback; /// Set of options which affects instrumentation of inline assembly. MCTargetOptions MCOptions; /// Current STI. const MCSubtargetInfo *STI; const MCInstrInfo &MII; public: MCTargetAsmParser(const MCTargetAsmParser &) = delete; MCTargetAsmParser &operator=(const MCTargetAsmParser &) = delete; ~MCTargetAsmParser() override; const MCSubtargetInfo &getSTI() const; uint64_t getAvailableFeatures() const { return AvailableFeatures; } void setAvailableFeatures(uint64_t Value) { AvailableFeatures = Value; } bool isParsingInlineAsm () { return ParsingInlineAsm; } void setParsingInlineAsm (bool Value) { ParsingInlineAsm = Value; } MCTargetOptions getTargetOptions() const { return MCOptions; } void setSemaCallback(MCAsmParserSemaCallback *Callback) { SemaCallback = Callback; } virtual bool ParseRegister(unsigned &RegNo, SMLoc &StartLoc, SMLoc &EndLoc) = 0; /// Sets frame register corresponding to the current MachineFunction. virtual void SetFrameRegister(unsigned RegNo) {} /// ParseInstruction - Parse one assembly instruction. /// /// The parser is positioned following the instruction name. The target /// specific instruction parser should parse the entire instruction and /// construct the appropriate MCInst, or emit an error. On success, the entire /// line should be parsed up to and including the end-of-statement token. On /// failure, the parser is not required to read to the end of the line. // /// \param Name - The instruction name. /// \param NameLoc - The source location of the name. /// \param Operands [out] - The list of parsed operands, this returns /// ownership of them to the caller. /// \return True on failure. virtual bool ParseInstruction(ParseInstructionInfo &Info, StringRef Name, SMLoc NameLoc, OperandVector &Operands) = 0; virtual bool ParseInstruction(ParseInstructionInfo &Info, StringRef Name, AsmToken Token, OperandVector &Operands) { return ParseInstruction(Info, Name, Token.getLoc(), Operands); } /// ParseDirective - Parse a target specific assembler directive /// /// The parser is positioned following the directive name. The target /// specific directive parser should parse the entire directive doing or /// recording any target specific work, or return true and do nothing if the /// directive is not target specific. If the directive is specific for /// the target, the entire line is parsed up to and including the /// end-of-statement token and false is returned. /// /// \param DirectiveID - the identifier token of the directive. virtual bool ParseDirective(AsmToken DirectiveID) = 0; /// MatchAndEmitInstruction - Recognize a series of operands of a parsed /// instruction as an actual MCInst and emit it to the specified MCStreamer. /// This returns false on success and returns true on failure to match. /// /// On failure, the target parser is responsible for emitting a diagnostic /// explaining the match failure. virtual bool MatchAndEmitInstruction(SMLoc IDLoc, unsigned &Opcode, OperandVector &Operands, MCStreamer &Out, uint64_t &ErrorInfo, bool MatchingInlineAsm) = 0; /// Allows targets to let registers opt out of clobber lists. virtual bool OmitRegisterFromClobberLists(unsigned RegNo) { return false; } /// Allow a target to add special case operand matching for things that /// tblgen doesn't/can't handle effectively. For example, literal /// immediates on ARM. TableGen expects a token operand, but the parser /// will recognize them as immediates. virtual unsigned validateTargetOperandClass(MCParsedAsmOperand &Op, unsigned Kind) { return Match_InvalidOperand; } /// Validate the instruction match against any complex target predicates /// before rendering any operands to it. virtual unsigned checkEarlyTargetMatchPredicate(MCInst &Inst, const OperandVector &Operands) { return Match_Success; } /// checkTargetMatchPredicate - Validate the instruction match against /// any complex target predicates not expressible via match classes. virtual unsigned checkTargetMatchPredicate(MCInst &Inst) { return Match_Success; } virtual void convertToMapAndConstraints(unsigned Kind, const OperandVector &Operands) = 0; // Return whether this parser uses assignment statements with equals tokens virtual bool equalIsAsmAssignment() { return true; }; // Return whether this start of statement identifier is a label virtual bool isLabel(AsmToken &Token) { return true; }; // Return whether this parser accept star as start of statement virtual bool starIsStartOfStatement() { return false; }; virtual const MCExpr *applyModifierToExpr(const MCExpr *E, MCSymbolRefExpr::VariantKind, MCContext &Ctx) { return nullptr; } virtual void onLabelParsed(MCSymbol *Symbol) {} /// Ensure that all previously parsed instructions have been emitted to the /// output streamer, if the target does not emit them immediately. virtual void flushPendingInstructions(MCStreamer &Out) {} virtual const MCExpr *createTargetUnaryExpr(const MCExpr *E, AsmToken::TokenKind OperatorToken, MCContext &Ctx) { return nullptr; } }; } // end namespace llvm #endif // LLVM_MC_MCPARSER_MCTARGETASMPARSER_H