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//===- MCStreamer.h - High-level Streaming Machine Code Output --*- C++ -*-===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // This file declares the MCStreamer class. // //===----------------------------------------------------------------------===// #ifndef LLVM_MC_MCSTREAMER_H #define LLVM_MC_MCSTREAMER_H #include "llvm/Support/DataTypes.h" #include "llvm/MC/MCDirectives.h" #include "llvm/MC/MCDwarf.h" #include "llvm/MC/MCWin64EH.h" #include "llvm/ADT/ArrayRef.h" #include "llvm/ADT/SmallVector.h" namespace llvm { class MCAsmBackend; class MCCodeEmitter; class MCContext; class MCExpr; class MCInst; class MCInstPrinter; class MCSection; class MCSymbol; class StringRef; class Twine; class raw_ostream; class formatted_raw_ostream; /// MCStreamer - Streaming machine code generation interface. This interface /// is intended to provide a programatic interface that is very similar to the /// level that an assembler .s file provides. It has callbacks to emit bytes, /// handle directives, etc. The implementation of this interface retains /// state to know what the current section is etc. /// /// There are multiple implementations of this interface: one for writing out /// a .s file, and implementations that write out .o files of various formats. /// class MCStreamer { MCContext &Context; MCStreamer(const MCStreamer&); // DO NOT IMPLEMENT MCStreamer &operator=(const MCStreamer&); // DO NOT IMPLEMENT bool EmitEHFrame; bool EmitDebugFrame; std::vector<MCDwarfFrameInfo> FrameInfos; MCDwarfFrameInfo *getCurrentFrameInfo(); void EnsureValidFrame(); std::vector<MCWin64EHUnwindInfo *> W64UnwindInfos; MCWin64EHUnwindInfo *CurrentW64UnwindInfo; void setCurrentW64UnwindInfo(MCWin64EHUnwindInfo *Frame); void EnsureValidW64UnwindInfo(); MCSymbol* LastSymbol; /// SectionStack - This is stack of current and previous section /// values saved by PushSection. SmallVector<std::pair<const MCSection *, const MCSection *>, 4> SectionStack; unsigned UniqueCodeBeginSuffix; unsigned UniqueDataBeginSuffix; protected: /// Indicator of whether the previous data-or-code indicator was for /// code or not. Used to determine when we need to emit a new indicator. enum DataType { Data, Code, JumpTable8, JumpTable16, JumpTable32 }; DataType RegionIndicator; MCStreamer(MCContext &Ctx); const MCExpr *BuildSymbolDiff(MCContext &Context, const MCSymbol *A, const MCSymbol *B); const MCExpr *ForceExpAbs(const MCExpr* Expr); void RecordProcStart(MCDwarfFrameInfo &Frame); virtual void EmitCFIStartProcImpl(MCDwarfFrameInfo &Frame); void RecordProcEnd(MCDwarfFrameInfo &Frame); virtual void EmitCFIEndProcImpl(MCDwarfFrameInfo &CurFrame); void EmitFrames(bool usingCFI); MCWin64EHUnwindInfo *getCurrentW64UnwindInfo(){return CurrentW64UnwindInfo;} void EmitW64Tables(); public: virtual ~MCStreamer(); MCContext &getContext() const { return Context; } unsigned getNumFrameInfos() { return FrameInfos.size(); } const MCDwarfFrameInfo &getFrameInfo(unsigned i) { return FrameInfos[i]; } ArrayRef<MCDwarfFrameInfo> getFrameInfos() { return FrameInfos; } unsigned getNumW64UnwindInfos() { return W64UnwindInfos.size(); } MCWin64EHUnwindInfo &getW64UnwindInfo(unsigned i) { return *W64UnwindInfos[i]; } /// @name Assembly File Formatting. /// @{ /// isVerboseAsm - Return true if this streamer supports verbose assembly /// and if it is enabled. virtual bool isVerboseAsm() const { return false; } /// hasRawTextSupport - Return true if this asm streamer supports emitting /// unformatted text to the .s file with EmitRawText. virtual bool hasRawTextSupport() const { return false; } /// AddComment - Add a comment that can be emitted to the generated .s /// file if applicable as a QoI issue to make the output of the compiler /// more readable. This only affects the MCAsmStreamer, and only when /// verbose assembly output is enabled. /// /// If the comment includes embedded \n's, they will each get the comment /// prefix as appropriate. The added comment should not end with a \n. virtual void AddComment(const Twine &T) {} /// GetCommentOS - Return a raw_ostream that comments can be written to. /// Unlike AddComment, you are required to terminate comments with \n if you /// use this method. virtual raw_ostream &GetCommentOS(); /// AddBlankLine - Emit a blank line to a .s file to pretty it up. virtual void AddBlankLine() {} /// @} /// @name Symbol & Section Management /// @{ /// getCurrentSection - Return the current section that the streamer is /// emitting code to. const MCSection *getCurrentSection() const { if (!SectionStack.empty()) return SectionStack.back().first; return NULL; } /// getPreviousSection - Return the previous section that the streamer is /// emitting code to. const MCSection *getPreviousSection() const { if (!SectionStack.empty()) return SectionStack.back().second; return NULL; } /// ChangeSection - Update streamer for a new active section. /// /// This is called by PopSection and SwitchSection, if the current /// section changes. virtual void ChangeSection(const MCSection *) = 0; /// pushSection - Save the current and previous section on the /// section stack. void PushSection() { SectionStack.push_back(std::make_pair(getCurrentSection(), getPreviousSection())); } /// popSection - Restore the current and previous section from /// the section stack. Calls ChangeSection as needed. /// /// Returns false if the stack was empty. bool PopSection() { if (SectionStack.size() <= 1) return false; const MCSection *oldSection = SectionStack.pop_back_val().first; const MCSection *curSection = SectionStack.back().first; if (oldSection != curSection) ChangeSection(curSection); return true; } /// SwitchSection - Set the current section where code is being emitted to /// @p Section. This is required to update CurSection. /// /// This corresponds to assembler directives like .section, .text, etc. void SwitchSection(const MCSection *Section) { assert(Section && "Cannot switch to a null section!"); const MCSection *curSection = SectionStack.back().first; SectionStack.back().second = curSection; if (Section != curSection) { SectionStack.back().first = Section; ChangeSection(Section); } } /// SwitchSectionNoChange - Set the current section where code is being /// emitted to @p Section. This is required to update CurSection. This /// version does not call ChangeSection. void SwitchSectionNoChange(const MCSection *Section) { assert(Section && "Cannot switch to a null section!"); const MCSection *curSection = SectionStack.back().first; SectionStack.back().second = curSection; if (Section != curSection) SectionStack.back().first = Section; } /// InitSections - Create the default sections and set the initial one. virtual void InitSections() = 0; /// EmitLabel - Emit a label for @p Symbol into the current section. /// /// This corresponds to an assembler statement such as: /// foo: /// /// @param Symbol - The symbol to emit. A given symbol should only be /// emitted as a label once, and symbols emitted as a label should never be /// used in an assignment. virtual void EmitLabel(MCSymbol *Symbol); /// EmitDataRegion - Emit a label that marks the beginning of a data /// region. /// On ELF targets, this corresponds to an assembler statement such as: /// $d.1: virtual void EmitDataRegion(); /// EmitJumpTable8Region - Emit a label that marks the beginning of a /// jump table composed of 8-bit offsets. /// On ELF targets, this corresponds to an assembler statement such as: /// $d.1: virtual void EmitJumpTable8Region(); /// EmitJumpTable16Region - Emit a label that marks the beginning of a /// jump table composed of 16-bit offsets. /// On ELF targets, this corresponds to an assembler statement such as: /// $d.1: virtual void EmitJumpTable16Region(); /// EmitJumpTable32Region - Emit a label that marks the beginning of a /// jump table composed of 32-bit offsets. /// On ELF targets, this corresponds to an assembler statement such as: /// $d.1: virtual void EmitJumpTable32Region(); /// EmitCodeRegion - Emit a label that marks the beginning of a code /// region. /// On ELF targets, this corresponds to an assembler statement such as: /// $a.1: virtual void EmitCodeRegion(); /// ForceCodeRegion - Forcibly sets the current region mode to code. Used /// at function entry points. void ForceCodeRegion() { RegionIndicator = Code; } virtual void EmitEHSymAttributes(const MCSymbol *Symbol, MCSymbol *EHSymbol); /// EmitAssemblerFlag - Note in the output the specified @p Flag virtual void EmitAssemblerFlag(MCAssemblerFlag Flag) = 0; /// EmitThumbFunc - Note in the output that the specified @p Func is /// a Thumb mode function (ARM target only). virtual void EmitThumbFunc(MCSymbol *Func) = 0; /// EmitAssignment - Emit an assignment of @p Value to @p Symbol. /// /// This corresponds to an assembler statement such as: /// symbol = value /// /// The assignment generates no code, but has the side effect of binding the /// value in the current context. For the assembly streamer, this prints the /// binding into the .s file. /// /// @param Symbol - The symbol being assigned to. /// @param Value - The value for the symbol. virtual void EmitAssignment(MCSymbol *Symbol, const MCExpr *Value) = 0; /// EmitWeakReference - Emit an weak reference from @p Alias to @p Symbol. /// /// This corresponds to an assembler statement such as: /// .weakref alias, symbol /// /// @param Alias - The alias that is being created. /// @param Symbol - The symbol being aliased. virtual void EmitWeakReference(MCSymbol *Alias, const MCSymbol *Symbol) = 0; /// EmitSymbolAttribute - Add the given @p Attribute to @p Symbol. virtual void EmitSymbolAttribute(MCSymbol *Symbol, MCSymbolAttr Attribute) = 0; /// EmitSymbolDesc - Set the @p DescValue for the @p Symbol. /// /// @param Symbol - The symbol to have its n_desc field set. /// @param DescValue - The value to set into the n_desc field. virtual void EmitSymbolDesc(MCSymbol *Symbol, unsigned DescValue) = 0; /// BeginCOFFSymbolDef - Start emitting COFF symbol definition /// /// @param Symbol - The symbol to have its External & Type fields set. virtual void BeginCOFFSymbolDef(const MCSymbol *Symbol) = 0; /// EmitCOFFSymbolStorageClass - Emit the storage class of the symbol. /// /// @param StorageClass - The storage class the symbol should have. virtual void EmitCOFFSymbolStorageClass(int StorageClass) = 0; /// EmitCOFFSymbolType - Emit the type of the symbol. /// /// @param Type - A COFF type identifier (see COFF::SymbolType in X86COFF.h) virtual void EmitCOFFSymbolType(int Type) = 0; /// EndCOFFSymbolDef - Marks the end of the symbol definition. virtual void EndCOFFSymbolDef() = 0; /// EmitCOFFSecRel32 - Emits a COFF section relative relocation. /// /// @param Symbol - Symbol the section relative realocation should point to. virtual void EmitCOFFSecRel32(MCSymbol const *Symbol); /// EmitELFSize - Emit an ELF .size directive. /// /// This corresponds to an assembler statement such as: /// .size symbol, expression /// virtual void EmitELFSize(MCSymbol *Symbol, const MCExpr *Value) = 0; /// EmitCommonSymbol - Emit a common symbol. /// /// @param Symbol - The common symbol to emit. /// @param Size - The size of the common symbol. /// @param ByteAlignment - The alignment of the symbol if /// non-zero. This must be a power of 2. virtual void EmitCommonSymbol(MCSymbol *Symbol, uint64_t Size, unsigned ByteAlignment) = 0; /// EmitLocalCommonSymbol - Emit a local common (.lcomm) symbol. /// /// @param Symbol - The common symbol to emit. /// @param Size - The size of the common symbol. /// @param ByteAlignment - The alignment of the common symbol in bytes. virtual void EmitLocalCommonSymbol(MCSymbol *Symbol, uint64_t Size, unsigned ByteAlignment) = 0; /// EmitZerofill - Emit the zerofill section and an optional symbol. /// /// @param Section - The zerofill section to create and or to put the symbol /// @param Symbol - The zerofill symbol to emit, if non-NULL. /// @param Size - The size of the zerofill symbol. /// @param ByteAlignment - The alignment of the zerofill symbol if /// non-zero. This must be a power of 2 on some targets. virtual void EmitZerofill(const MCSection *Section, MCSymbol *Symbol = 0, unsigned Size = 0,unsigned ByteAlignment = 0) = 0; /// EmitTBSSSymbol - Emit a thread local bss (.tbss) symbol. /// /// @param Section - The thread local common section. /// @param Symbol - The thread local common symbol to emit. /// @param Size - The size of the symbol. /// @param ByteAlignment - The alignment of the thread local common symbol /// if non-zero. This must be a power of 2 on some targets. virtual void EmitTBSSSymbol(const MCSection *Section, MCSymbol *Symbol, uint64_t Size, unsigned ByteAlignment = 0) = 0; /// @} /// @name Generating Data /// @{ /// EmitBytes - Emit the bytes in \arg Data into the output. /// /// This is used to implement assembler directives such as .byte, .ascii, /// etc. virtual void EmitBytes(StringRef Data, unsigned AddrSpace) = 0; /// EmitValue - Emit the expression @p Value into the output as a native /// integer of the given @p Size bytes. /// /// This is used to implement assembler directives such as .word, .quad, /// etc. /// /// @param Value - The value to emit. /// @param Size - The size of the integer (in bytes) to emit. This must /// match a native machine width. virtual void EmitValueImpl(const MCExpr *Value, unsigned Size, unsigned AddrSpace) = 0; void EmitValue(const MCExpr *Value, unsigned Size, unsigned AddrSpace = 0); /// EmitIntValue - Special case of EmitValue that avoids the client having /// to pass in a MCExpr for constant integers. virtual void EmitIntValue(uint64_t Value, unsigned Size, unsigned AddrSpace = 0); /// EmitAbsValue - Emit the Value, but try to avoid relocations. On MachO /// this is done by producing /// foo = value /// .long foo void EmitAbsValue(const MCExpr *Value, unsigned Size, unsigned AddrSpace = 0); virtual void EmitULEB128Value(const MCExpr *Value) = 0; virtual void EmitSLEB128Value(const MCExpr *Value) = 0; /// EmitULEB128Value - Special case of EmitULEB128Value that avoids the /// client having to pass in a MCExpr for constant integers. void EmitULEB128IntValue(uint64_t Value, unsigned AddrSpace = 0, unsigned Padding = 0); /// EmitSLEB128Value - Special case of EmitSLEB128Value that avoids the /// client having to pass in a MCExpr for constant integers. void EmitSLEB128IntValue(int64_t Value, unsigned AddrSpace = 0); /// EmitSymbolValue - Special case of EmitValue that avoids the client /// having to pass in a MCExpr for MCSymbols. void EmitSymbolValue(const MCSymbol *Sym, unsigned Size, unsigned AddrSpace = 0); /// EmitGPRel64Value - Emit the expression @p Value into the output as a /// gprel64 (64-bit GP relative) value. /// /// This is used to implement assembler directives such as .gpdword on /// targets that support them. virtual void EmitGPRel64Value(const MCExpr *Value); /// EmitGPRel32Value - Emit the expression @p Value into the output as a /// gprel32 (32-bit GP relative) value. /// /// This is used to implement assembler directives such as .gprel32 on /// targets that support them. virtual void EmitGPRel32Value(const MCExpr *Value); /// EmitFill - Emit NumBytes bytes worth of the value specified by /// FillValue. This implements directives such as '.space'. virtual void EmitFill(uint64_t NumBytes, uint8_t FillValue, unsigned AddrSpace); /// EmitZeros - Emit NumBytes worth of zeros. This is a convenience /// function that just wraps EmitFill. void EmitZeros(uint64_t NumBytes, unsigned AddrSpace) { EmitFill(NumBytes, 0, AddrSpace); } /// EmitValueToAlignment - Emit some number of copies of @p Value until /// the byte alignment @p ByteAlignment is reached. /// /// If the number of bytes need to emit for the alignment is not a multiple /// of @p ValueSize, then the contents of the emitted fill bytes is /// undefined. /// /// This used to implement the .align assembler directive. /// /// @param ByteAlignment - The alignment to reach. This must be a power of /// two on some targets. /// @param Value - The value to use when filling bytes. /// @param ValueSize - The size of the integer (in bytes) to emit for /// @p Value. This must match a native machine width. /// @param MaxBytesToEmit - The maximum numbers of bytes to emit, or 0. If /// the alignment cannot be reached in this many bytes, no bytes are /// emitted. virtual void EmitValueToAlignment(unsigned ByteAlignment, int64_t Value = 0, unsigned ValueSize = 1, unsigned MaxBytesToEmit = 0) = 0; /// EmitCodeAlignment - Emit nops until the byte alignment @p ByteAlignment /// is reached. /// /// This used to align code where the alignment bytes may be executed. This /// can emit different bytes for different sizes to optimize execution. /// /// @param ByteAlignment - The alignment to reach. This must be a power of /// two on some targets. /// @param MaxBytesToEmit - The maximum numbers of bytes to emit, or 0. If /// the alignment cannot be reached in this many bytes, no bytes are /// emitted. virtual void EmitCodeAlignment(unsigned ByteAlignment, unsigned MaxBytesToEmit = 0) = 0; /// EmitValueToOffset - Emit some number of copies of @p Value until the /// byte offset @p Offset is reached. /// /// This is used to implement assembler directives such as .org. /// /// @param Offset - The offset to reach. This may be an expression, but the /// expression must be associated with the current section. /// @param Value - The value to use when filling bytes. /// @return false on success, true if the offset was invalid. virtual bool EmitValueToOffset(const MCExpr *Offset, unsigned char Value = 0) = 0; /// @} /// EmitFileDirective - Switch to a new logical file. This is used to /// implement the '.file "foo.c"' assembler directive. virtual void EmitFileDirective(StringRef Filename) = 0; /// EmitDwarfFileDirective - Associate a filename with a specified logical /// file number. This implements the DWARF2 '.file 4 "foo.c"' assembler /// directive. virtual bool EmitDwarfFileDirective(unsigned FileNo, StringRef Directory, StringRef Filename); /// EmitDwarfLocDirective - This implements the DWARF2 // '.loc fileno lineno ...' assembler directive. virtual void EmitDwarfLocDirective(unsigned FileNo, unsigned Line, unsigned Column, unsigned Flags, unsigned Isa, unsigned Discriminator, StringRef FileName); virtual void EmitDwarfAdvanceLineAddr(int64_t LineDelta, const MCSymbol *LastLabel, const MCSymbol *Label, unsigned PointerSize) = 0; virtual void EmitDwarfAdvanceFrameAddr(const MCSymbol *LastLabel, const MCSymbol *Label) { } void EmitDwarfSetLineAddr(int64_t LineDelta, const MCSymbol *Label, int PointerSize); virtual void EmitCompactUnwindEncoding(uint32_t CompactUnwindEncoding); virtual void EmitCFISections(bool EH, bool Debug); void EmitCFIStartProc(); void EmitCFIEndProc(); virtual void EmitCFIDefCfa(int64_t Register, int64_t Offset); virtual void EmitCFIDefCfaOffset(int64_t Offset); virtual void EmitCFIDefCfaRegister(int64_t Register); virtual void EmitCFIOffset(int64_t Register, int64_t Offset); virtual void EmitCFIPersonality(const MCSymbol *Sym, unsigned Encoding); virtual void EmitCFILsda(const MCSymbol *Sym, unsigned Encoding); virtual void EmitCFIRememberState(); virtual void EmitCFIRestoreState(); virtual void EmitCFISameValue(int64_t Register); virtual void EmitCFIRestore(int64_t Register); virtual void EmitCFIRelOffset(int64_t Register, int64_t Offset); virtual void EmitCFIAdjustCfaOffset(int64_t Adjustment); virtual void EmitCFIEscape(StringRef Values); virtual void EmitCFISignalFrame(); virtual void EmitWin64EHStartProc(const MCSymbol *Symbol); virtual void EmitWin64EHEndProc(); virtual void EmitWin64EHStartChained(); virtual void EmitWin64EHEndChained(); virtual void EmitWin64EHHandler(const MCSymbol *Sym, bool Unwind, bool Except); virtual void EmitWin64EHHandlerData(); virtual void EmitWin64EHPushReg(unsigned Register); virtual void EmitWin64EHSetFrame(unsigned Register, unsigned Offset); virtual void EmitWin64EHAllocStack(unsigned Size); virtual void EmitWin64EHSaveReg(unsigned Register, unsigned Offset); virtual void EmitWin64EHSaveXMM(unsigned Register, unsigned Offset); virtual void EmitWin64EHPushFrame(bool Code); virtual void EmitWin64EHEndProlog(); /// EmitInstruction - Emit the given @p Instruction into the current /// section. virtual void EmitInstruction(const MCInst &Inst) = 0; /// EmitRawText - If this file is backed by a assembly streamer, this dumps /// the specified string in the output .s file. This capability is /// indicated by the hasRawTextSupport() predicate. By default this aborts. virtual void EmitRawText(StringRef String); void EmitRawText(const Twine &String); /// ARM-related methods. /// FIXME: Eventually we should have some "target MC streamer" and move /// these methods there. virtual void EmitFnStart(); virtual void EmitFnEnd(); virtual void EmitCantUnwind(); virtual void EmitPersonality(const MCSymbol *Personality); virtual void EmitHandlerData(); virtual void EmitSetFP(unsigned FpReg, unsigned SpReg, int64_t Offset = 0); virtual void EmitPad(int64_t Offset); virtual void EmitRegSave(const SmallVectorImpl<unsigned> &RegList, bool isVector); /// FinishImpl - Streamer specific finalization. virtual void FinishImpl() = 0; /// Finish - Finish emission of machine code. void Finish(); }; /// createNullStreamer - Create a dummy machine code streamer, which does /// nothing. This is useful for timing the assembler front end. MCStreamer *createNullStreamer(MCContext &Ctx); /// createAsmStreamer - Create a machine code streamer which will print out /// assembly for the native target, suitable for compiling with a native /// assembler. /// /// \param InstPrint - If given, the instruction printer to use. If not given /// the MCInst representation will be printed. This method takes ownership of /// InstPrint. /// /// \param CE - If given, a code emitter to use to show the instruction /// encoding inline with the assembly. This method takes ownership of \arg CE. /// /// \param TAB - If given, a target asm backend to use to show the fixup /// information in conjunction with encoding information. This method takes /// ownership of \arg TAB. /// /// \param ShowInst - Whether to show the MCInst representation inline with /// the assembly. /// /// \param DecodeLSDA - If true, emit comments that translates the LSDA into a /// human readable format. Only usable with CFI. MCStreamer *createAsmStreamer(MCContext &Ctx, formatted_raw_ostream &OS, bool isVerboseAsm, bool useLoc, bool useCFI, bool useDwarfDirectory, MCInstPrinter *InstPrint = 0, MCCodeEmitter *CE = 0, MCAsmBackend *TAB = 0, bool ShowInst = false); /// createMachOStreamer - Create a machine code streamer which will generate /// Mach-O format object files. /// /// Takes ownership of \arg TAB and \arg CE. MCStreamer *createMachOStreamer(MCContext &Ctx, MCAsmBackend &TAB, raw_ostream &OS, MCCodeEmitter *CE, bool RelaxAll = false); /// createWinCOFFStreamer - Create a machine code streamer which will /// generate Microsoft COFF format object files. /// /// Takes ownership of \arg TAB and \arg CE. MCStreamer *createWinCOFFStreamer(MCContext &Ctx, MCAsmBackend &TAB, MCCodeEmitter &CE, raw_ostream &OS, bool RelaxAll = false); /// createELFStreamer - Create a machine code streamer which will generate /// ELF format object files. MCStreamer *createELFStreamer(MCContext &Ctx, MCAsmBackend &TAB, raw_ostream &OS, MCCodeEmitter *CE, bool RelaxAll, bool NoExecStack); /// createPureStreamer - Create a machine code streamer which will generate /// "pure" MC object files, for use with MC-JIT and testing tools. /// /// Takes ownership of \arg TAB and \arg CE. MCStreamer *createPureStreamer(MCContext &Ctx, MCAsmBackend &TAB, raw_ostream &OS, MCCodeEmitter *CE); } // end namespace llvm #endif