//===-- llvm/Target/TargetAsmInfo.h - Asm info ------------------*- C++ -*-===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // This file contains a class to be used as the basis for target specific // asm writers. This class primarily takes care of global printing constants, // which are used in very similar ways across all targets. // //===----------------------------------------------------------------------===// #ifndef LLVM_TARGET_ASM_INFO_H #define LLVM_TARGET_ASM_INFO_H #include "llvm/ADT/StringMap.h" #include "llvm/Support/DataTypes.h" #include namespace llvm { template class SmallVectorImpl; // DWARF encoding query type namespace DwarfEncoding { enum Target { Data = 0, CodeLabels = 1, Functions = 2 }; } /// SectionKind - This is a simple POD value that classifies the properties of /// a section. A global variable is classified into the deepest possible /// classification, and then the target maps them onto their sections based on /// what capabilities they have. /// /// The comments below describe these as if they were an inheritance hierarchy /// in order to explain the predicates below. struct SectionKind { enum Kind { /// Text - Text section, used for functions and other executable code. Text, /// ReadOnly - Data that is never written to at program runtime by the /// program or the dynamic linker. Things in the top-level readonly /// SectionKind are not mergeable. ReadOnly, /// MergeableCString - This is a special section for nul-terminated /// strings. The linker can unique the C strings, knowing their /// semantics. Because it uniques based on the nul terminators, the /// compiler can't put strings in this section that have embeded nuls /// in them. MergeableCString, /// MergeableConst - These are sections for merging fixed-length /// constants together. For example, this can be used to unique /// constant pool entries etc. MergeableConst, /// MergeableConst4 - This is a section used by 4-byte constants, /// for example, floats. MergeableConst4, /// MergeableConst8 - This is a section used by 8-byte constants, /// for example, doubles. MergeableConst8, /// MergeableConst16 - This is a section used by 16-byte constants, /// for example, vectors. MergeableConst16, /// Writeable - This is the base of all segments that need to be written /// to during program runtime. /// ThreadLocal - This is the base of all TLS segments. All TLS /// objects must be writeable, otherwise there is no reason for them to /// be thread local! /// ThreadBSS - Zero-initialized TLS data objects. ThreadBSS, /// ThreadData - Initialized TLS data objects. ThreadData, /// GlobalWriteableData - Writeable data that is global (not thread /// local). /// BSS - Zero initialized writeable data. BSS, /// DataRel - This is the most general form of data that is written /// to by the program, it can have random relocations to arbitrary /// globals. DataRel, /// DataRelLocal - This is writeable data that has a non-zero /// initializer and has relocations in it, but all of the /// relocations are known to be within the final linked image /// the global is linked into. DataRelLocal, /// DataNoRel - This is writeable data that has a non-zero /// initializer, but whose initializer is known to have no /// relocations. DataNoRel, /// ReadOnlyWithRel - These are global variables that are never /// written to by the program, but that have relocations, so they /// must be stuck in a writeable section so that the dynamic linker /// can write to them. If it chooses to, the dynamic linker can /// mark the pages these globals end up on as read-only after it is /// done with its relocation phase. ReadOnlyWithRel, /// ReadOnlyWithRelLocal - This is data that is readonly by the /// program, but must be writeable so that the dynamic linker /// can perform relocations in it. This is used when we know /// that all the relocations are to globals in this final /// linked image. ReadOnlyWithRelLocal }; private: Kind K : 6; /// Weak - This is true if the referenced symbol is weak (i.e. linkonce, /// weak, weak_odr, etc). This is orthogonal from the categorization. bool Weak : 1; /// ExplicitSection - This is true if the global had a section explicitly /// specified on it. bool ExplicitSection : 1; public: bool isWeak() const { return Weak; } bool hasExplicitSection() const { return ExplicitSection; } bool isText() const { return K == Text; } bool isReadOnly() const { return K == ReadOnly || K == MergeableCString || isMergeableConst(); } bool isMergeableCString() const { return K == MergeableCString; } bool isMergeableConst() const { return K == MergeableConst || K == MergeableConst4 || K == MergeableConst8 || K == MergeableConst16; } bool isMergeableConst4() const { return K == MergeableConst4; } bool isMergeableConst8() const { return K == MergeableConst8; } bool isMergeableConst16() const { return K == MergeableConst16; } bool isWriteable() const { return isThreadLocal() || isGlobalWriteableData(); } bool isThreadLocal() const { return K == ThreadData || K == ThreadBSS; } bool isThreadBSS() const { return K == ThreadBSS; } bool isThreadData() const { return K == ThreadData; } bool isGlobalWriteableData() const { return isBSS() || isDataRel() || isReadOnlyWithRel(); } bool isBSS() const { return K == BSS; } bool isDataRel() const { return K == DataRel || K == DataRelLocal || K == DataNoRel; } bool isDataRelLocal() const { return K == DataRelLocal || K == DataNoRel; } bool isDataNoRel() const { return K == DataNoRel; } bool isReadOnlyWithRel() const { return K == ReadOnlyWithRel || K == ReadOnlyWithRelLocal; } bool isReadOnlyWithRelLocal() const { return K == ReadOnlyWithRelLocal; } static SectionKind get(Kind K, bool isWeak, bool hasExplicitSection = false) { SectionKind Res; Res.K = K; Res.Weak = isWeak; Res.ExplicitSection = hasExplicitSection; return Res; } }; namespace SectionFlags { const unsigned Invalid = -1U; const unsigned None = 0; const unsigned Code = 1 << 0; ///< Section contains code const unsigned Writable = 1 << 1; ///< Section is writeable const unsigned BSS = 1 << 2; ///< Section contains only zeroes const unsigned Mergeable = 1 << 3; ///< Section contains mergeable data const unsigned Strings = 1 << 4; ///< Section contains C-type strings const unsigned TLS = 1 << 5; ///< Section contains thread-local data const unsigned Debug = 1 << 6; ///< Section contains debug data const unsigned Linkonce = 1 << 7; ///< Section is linkonce const unsigned TypeFlags = 0xFF; // Some gap for future flags /// Named - True if this section should be printed with ".section ", /// false if the section name is something like ".const". const unsigned Named = 1 << 23; ///< Section is named const unsigned EntitySize = 0xFF << 24; ///< Entity size for mergeable stuff static inline unsigned getEntitySize(unsigned Flags) { return (Flags >> 24) & 0xFF; } // FIXME: Why does this return a value? static inline unsigned setEntitySize(unsigned Flags, unsigned Size) { return (Flags & ~EntitySize) | ((Size & 0xFF) << 24); } struct KeyInfo { static inline unsigned getEmptyKey() { return Invalid; } static inline unsigned getTombstoneKey() { return Invalid - 1; } static unsigned getHashValue(const unsigned &Key) { return Key; } static bool isEqual(unsigned LHS, unsigned RHS) { return LHS == RHS; } static bool isPod() { return true; } }; } class TargetMachine; class CallInst; class GlobalValue; class Type; class Mangler; class Section { friend class TargetAsmInfo; friend class StringMapEntry
; friend class StringMap
; std::string Name; unsigned Flags; explicit Section(unsigned F = SectionFlags::Invalid) : Flags(F) { } public: unsigned getEntitySize() const { return (Flags >> 24) & 0xFF; } const std::string &getName() const { return Name; } unsigned getFlags() const { return Flags; } bool hasFlag(unsigned F) const { return (Flags & F) != 0; } }; /// TargetAsmInfo - This class is intended to be used as a base class for asm /// properties and features specific to the target. class TargetAsmInfo { private: mutable StringMap
Sections; protected: /// TM - The current TargetMachine. const TargetMachine &TM; //===------------------------------------------------------------------===// // Properties to be set by the target writer, used to configure asm printer. // /// TextSection - Section directive for standard text. /// const Section *TextSection; // Defaults to ".text". /// DataSection - Section directive for standard data. /// const Section *DataSection; // Defaults to ".data". /// BSSSection - Section directive for uninitialized data. Null if this /// target doesn't support a BSS section. /// const char *BSSSection; // Default to ".bss". const Section *BSSSection_; /// ReadOnlySection - This is the directive that is emitted to switch to a /// read-only section for constant data (e.g. data declared const, /// jump tables). const Section *ReadOnlySection; // Defaults to NULL /// TLSDataSection - Section directive for Thread Local data. /// const Section *TLSDataSection; // Defaults to ".tdata". /// TLSBSSSection - Section directive for Thread Local uninitialized data. /// Null if this target doesn't support a BSS section. /// const Section *TLSBSSSection; // Defaults to ".tbss". /// ZeroFillDirective - Directive for emitting a global to the ZeroFill /// section on this target. Null if this target doesn't support zerofill. const char *ZeroFillDirective; // Default is null. /// NonexecutableStackDirective - Directive for declaring to the /// linker and beyond that the emitted code does not require stack /// memory to be executable. const char *NonexecutableStackDirective; // Default is null. /// NeedsSet - True if target asm treats expressions in data directives /// as linktime-relocatable. For assembly-time computation, we need to /// use a .set. Thus: /// .set w, x-y /// .long w /// is computed at assembly time, while /// .long x-y /// is relocated if the relative locations of x and y change at linktime. /// We want both these things in different places. bool NeedsSet; // Defaults to false. /// MaxInstLength - This is the maximum possible length of an instruction, /// which is needed to compute the size of an inline asm. unsigned MaxInstLength; // Defaults to 4. /// PCSymbol - The symbol used to represent the current PC. Used in PC /// relative expressions. const char *PCSymbol; // Defaults to "$". /// SeparatorChar - This character, if specified, is used to separate /// instructions from each other when on the same line. This is used to /// measure inline asm instructions. char SeparatorChar; // Defaults to ';' /// CommentColumn - This indicates the comment num (zero-based) at /// which asm comments should be printed. unsigned CommentColumn; // Defaults to 60 /// CommentString - This indicates the comment character used by the /// assembler. const char *CommentString; // Defaults to "#" /// FirstOperandColumn - The output column where the first operand /// should be printed unsigned FirstOperandColumn; // Defaults to 0 (ignored) /// MaxOperandLength - The maximum length of any printed asm /// operand unsigned MaxOperandLength; // Defaults to 0 (ignored) /// GlobalPrefix - If this is set to a non-empty string, it is prepended /// onto all global symbols. This is often used for "_" or ".". const char *GlobalPrefix; // Defaults to "" /// PrivateGlobalPrefix - This prefix is used for globals like constant /// pool entries that are completely private to the .s file and should not /// have names in the .o file. This is often "." or "L". const char *PrivateGlobalPrefix; // Defaults to "." /// LinkerPrivateGlobalPrefix - This prefix is used for symbols that should /// be passed through the assembler but be removed by the linker. This /// is "l" on Darwin, currently used for some ObjC metadata. const char *LinkerPrivateGlobalPrefix; // Defaults to "" /// JumpTableSpecialLabelPrefix - If not null, a extra (dead) label is /// emitted before jump tables with the specified prefix. const char *JumpTableSpecialLabelPrefix; // Default to null. /// GlobalVarAddrPrefix/Suffix - If these are nonempty, these strings /// will enclose any GlobalVariable (that isn't a function) /// const char *GlobalVarAddrPrefix; // Defaults to "" const char *GlobalVarAddrSuffix; // Defaults to "" /// FunctionAddrPrefix/Suffix - If these are nonempty, these strings /// will enclose any GlobalVariable that points to a function. /// const char *FunctionAddrPrefix; // Defaults to "" const char *FunctionAddrSuffix; // Defaults to "" /// PersonalityPrefix/Suffix - If these are nonempty, these strings will /// enclose any personality function in the common frame section. /// const char *PersonalityPrefix; // Defaults to "" const char *PersonalitySuffix; // Defaults to "" /// NeedsIndirectEncoding - If set, we need to set the indirect encoding bit /// for EH in Dwarf. /// bool NeedsIndirectEncoding; // Defaults to false /// InlineAsmStart/End - If these are nonempty, they contain a directive to /// emit before and after an inline assembly statement. const char *InlineAsmStart; // Defaults to "#APP\n" const char *InlineAsmEnd; // Defaults to "#NO_APP\n" /// AssemblerDialect - Which dialect of an assembler variant to use. unsigned AssemblerDialect; // Defaults to 0 /// AllowQuotesInName - This is true if the assembler allows for complex /// symbol names to be surrounded in quotes. This defaults to false. bool AllowQuotesInName; //===--- Data Emission Directives -------------------------------------===// /// ZeroDirective - this should be set to the directive used to get some /// number of zero bytes emitted to the current section. Common cases are /// "\t.zero\t" and "\t.space\t". If this is set to null, the /// Data*bitsDirective's will be used to emit zero bytes. const char *ZeroDirective; // Defaults to "\t.zero\t" const char *ZeroDirectiveSuffix; // Defaults to "" /// AsciiDirective - This directive allows emission of an ascii string with /// the standard C escape characters embedded into it. const char *AsciiDirective; // Defaults to "\t.ascii\t" /// AscizDirective - If not null, this allows for special handling of /// zero terminated strings on this target. This is commonly supported as /// ".asciz". If a target doesn't support this, it can be set to null. const char *AscizDirective; // Defaults to "\t.asciz\t" /// DataDirectives - These directives are used to output some unit of /// integer data to the current section. If a data directive is set to /// null, smaller data directives will be used to emit the large sizes. const char *Data8bitsDirective; // Defaults to "\t.byte\t" const char *Data16bitsDirective; // Defaults to "\t.short\t" const char *Data32bitsDirective; // Defaults to "\t.long\t" const char *Data64bitsDirective; // Defaults to "\t.quad\t" /// getDataASDirective - Return the directive that should be used to emit /// data of the specified size to the specified numeric address space. virtual const char *getDataASDirective(unsigned Size, unsigned AS) const { assert(AS != 0 && "Don't know the directives for default addr space"); return NULL; } //===--- Alignment Information ----------------------------------------===// /// AlignDirective - The directive used to emit round up to an alignment /// boundary. /// const char *AlignDirective; // Defaults to "\t.align\t" /// AlignmentIsInBytes - If this is true (the default) then the asmprinter /// emits ".align N" directives, where N is the number of bytes to align to. /// Otherwise, it emits ".align log2(N)", e.g. 3 to align to an 8 byte /// boundary. bool AlignmentIsInBytes; // Defaults to true /// TextAlignFillValue - If non-zero, this is used to fill the executable /// space created as the result of a alignment directive. unsigned TextAlignFillValue; //===--- Section Switching Directives ---------------------------------===// /// SwitchToSectionDirective - This is the directive used when we want to /// emit a global to an arbitrary section. The section name is emited after /// this. const char *SwitchToSectionDirective; // Defaults to "\t.section\t" /// TextSectionStartSuffix - This is printed after each start of section /// directive for text sections. const char *TextSectionStartSuffix; // Defaults to "". /// DataSectionStartSuffix - This is printed after each start of section /// directive for data sections. const char *DataSectionStartSuffix; // Defaults to "". /// SectionEndDirectiveSuffix - If non-null, the asm printer will close each /// section with the section name and this suffix printed. const char *SectionEndDirectiveSuffix;// Defaults to null. /// ConstantPoolSection - This is the section that we SwitchToSection right /// before emitting the constant pool for a function. const char *ConstantPoolSection; // Defaults to "\t.section .rodata" /// JumpTableDataSection - This is the section that we SwitchToSection right /// before emitting the jump tables for a function when the relocation model /// is not PIC. const char *JumpTableDataSection; // Defaults to "\t.section .rodata" /// JumpTableDirective - if non-null, the directive to emit before a jump /// table. const char *JumpTableDirective; /// CStringSection - If not null, this allows for special handling of /// cstring constants (null terminated string that does not contain any /// other null bytes) on this target. This is commonly supported as /// ".cstring". const char *CStringSection; // Defaults to NULL const Section *CStringSection_; /// StaticCtorsSection - This is the directive that is emitted to switch to /// a section to emit the static constructor list. /// Defaults to "\t.section .ctors,\"aw\",@progbits". const char *StaticCtorsSection; /// StaticDtorsSection - This is the directive that is emitted to switch to /// a section to emit the static destructor list. /// Defaults to "\t.section .dtors,\"aw\",@progbits". const char *StaticDtorsSection; //===--- Global Variable Emission Directives --------------------------===// /// GlobalDirective - This is the directive used to declare a global entity. /// const char *GlobalDirective; // Defaults to NULL. /// ExternDirective - This is the directive used to declare external /// globals. /// const char *ExternDirective; // Defaults to NULL. /// SetDirective - This is the name of a directive that can be used to tell /// the assembler to set the value of a variable to some expression. const char *SetDirective; // Defaults to null. /// LCOMMDirective - This is the name of a directive (if supported) that can /// be used to efficiently declare a local (internal) block of zero /// initialized data in the .bss/.data section. The syntax expected is: /// @verbatim SYMBOLNAME LENGTHINBYTES, ALIGNMENT /// @endverbatim const char *LCOMMDirective; // Defaults to null. const char *COMMDirective; // Defaults to "\t.comm\t". /// COMMDirectiveTakesAlignment - True if COMMDirective take a third /// argument that specifies the alignment of the declaration. bool COMMDirectiveTakesAlignment; // Defaults to true. /// HasDotTypeDotSizeDirective - True if the target has .type and .size /// directives, this is true for most ELF targets. bool HasDotTypeDotSizeDirective; // Defaults to true. /// HasSingleParameterDotFile - True if the target has a single parameter /// .file directive, this is true for ELF targets. bool HasSingleParameterDotFile; // Defaults to true. /// UsedDirective - This directive, if non-null, is used to declare a global /// as being used somehow that the assembler can't see. This prevents dead /// code elimination on some targets. const char *UsedDirective; // Defaults to null. /// WeakRefDirective - This directive, if non-null, is used to declare a /// global as being a weak undefined symbol. const char *WeakRefDirective; // Defaults to null. /// WeakDefDirective - This directive, if non-null, is used to declare a /// global as being a weak defined symbol. const char *WeakDefDirective; // Defaults to null. /// HiddenDirective - This directive, if non-null, is used to declare a /// global or function as having hidden visibility. const char *HiddenDirective; // Defaults to "\t.hidden\t". /// ProtectedDirective - This directive, if non-null, is used to declare a /// global or function as having protected visibility. const char *ProtectedDirective; // Defaults to "\t.protected\t". //===--- Dwarf Emission Directives -----------------------------------===// /// AbsoluteDebugSectionOffsets - True if we should emit abolute section /// offsets for debug information. Defaults to false. bool AbsoluteDebugSectionOffsets; /// AbsoluteEHSectionOffsets - True if we should emit abolute section /// offsets for EH information. Defaults to false. bool AbsoluteEHSectionOffsets; /// HasLEB128 - True if target asm supports leb128 directives. /// bool HasLEB128; // Defaults to false. /// hasDotLocAndDotFile - True if target asm supports .loc and .file /// directives for emitting debugging information. /// bool HasDotLocAndDotFile; // Defaults to false. /// SupportsDebugInformation - True if target supports emission of debugging /// information. bool SupportsDebugInformation; /// SupportsExceptionHandling - True if target supports /// exception handling. /// bool SupportsExceptionHandling; // Defaults to false. /// RequiresFrameSection - true if the Dwarf2 output needs a frame section /// bool DwarfRequiresFrameSection; // Defaults to true. /// DwarfUsesInlineInfoSection - True if DwarfDebugInlineSection is used to /// encode inline subroutine information. bool DwarfUsesInlineInfoSection; // Defaults to false. /// Is_EHSymbolPrivate - If set, the "_foo.eh" is made private so that it /// doesn't show up in the symbol table of the object file. bool Is_EHSymbolPrivate; // Defaults to true. /// GlobalEHDirective - This is the directive used to make exception frame /// tables globally visible. /// const char *GlobalEHDirective; // Defaults to NULL. /// SupportsWeakEmptyEHFrame - True if target assembler and linker will /// handle a weak_definition of constant 0 for an omitted EH frame. bool SupportsWeakOmittedEHFrame; // Defaults to true. /// DwarfSectionOffsetDirective - Special section offset directive. const char* DwarfSectionOffsetDirective; // Defaults to NULL /// DwarfAbbrevSection - Section directive for Dwarf abbrev. /// const char *DwarfAbbrevSection; // Defaults to ".debug_abbrev". /// DwarfInfoSection - Section directive for Dwarf info. /// const char *DwarfInfoSection; // Defaults to ".debug_info". /// DwarfLineSection - Section directive for Dwarf info. /// const char *DwarfLineSection; // Defaults to ".debug_line". /// DwarfFrameSection - Section directive for Dwarf info. /// const char *DwarfFrameSection; // Defaults to ".debug_frame". /// DwarfPubNamesSection - Section directive for Dwarf info. /// const char *DwarfPubNamesSection; // Defaults to ".debug_pubnames". /// DwarfPubTypesSection - Section directive for Dwarf info. /// const char *DwarfPubTypesSection; // Defaults to ".debug_pubtypes". /// DwarfDebugInlineSection - Section directive for inline info. /// const char *DwarfDebugInlineSection; // Defaults to ".debug_inlined" /// DwarfStrSection - Section directive for Dwarf info. /// const char *DwarfStrSection; // Defaults to ".debug_str". /// DwarfLocSection - Section directive for Dwarf info. /// const char *DwarfLocSection; // Defaults to ".debug_loc". /// DwarfARangesSection - Section directive for Dwarf info. /// const char *DwarfARangesSection; // Defaults to ".debug_aranges". /// DwarfRangesSection - Section directive for Dwarf info. /// const char *DwarfRangesSection; // Defaults to ".debug_ranges". /// DwarfMacroInfoSection - Section directive for DWARF macro info. /// const char *DwarfMacroInfoSection; // Defaults to ".debug_macinfo". /// DwarfEHFrameSection - Section directive for Exception frames. /// const char *DwarfEHFrameSection; // Defaults to ".eh_frame". /// DwarfExceptionSection - Section directive for Exception table. /// const char *DwarfExceptionSection; // Defaults to ".gcc_except_table". //===--- CBE Asm Translation Table -----------------------------------===// const char *const *AsmTransCBE; // Defaults to empty public: explicit TargetAsmInfo(const TargetMachine &TM); virtual ~TargetAsmInfo(); const Section* getNamedSection(const char *Name, unsigned Flags = SectionFlags::None) const; const Section* getUnnamedSection(const char *Directive, unsigned Flags = SectionFlags::None) const; /// Measure the specified inline asm to determine an approximation of its /// length. virtual unsigned getInlineAsmLength(const char *Str) const; /// emitUsedDirectiveFor - This hook allows targets to selectively decide /// not to emit the UsedDirective for some symbols in llvm.used. // FIXME: REMOVE this (rdar://7071300) virtual bool emitUsedDirectiveFor(const GlobalValue *GV, Mangler *Mang) const { return (GV!=0); } /// PreferredEHDataFormat - This hook allows the target to select data /// format used for encoding pointers in exception handling data. Reason is /// 0 for data, 1 for code labels, 2 for function pointers. Global is true /// if the symbol can be relocated. virtual unsigned PreferredEHDataFormat(DwarfEncoding::Target Reason, bool Global) const; /// getSectionForMergeableConstant - Given a Mergeable constant with the /// specified size and relocation information, return a section that it /// should be placed in. virtual const Section *getSectionForMergeableConstant(SectionKind Kind)const; /// getSectionPrefixForUniqueGlobal - Return a string that we should prepend /// onto a global's name in order to get the unique section name for the /// global. This is important for globals that need to be merged across /// translation units. virtual const char * getSectionPrefixForUniqueGlobal(SectionKind Kind) const { return 0; } /// getFlagsForNamedSection - If this target wants to be able to infer /// section flags based on the name of the section specified for a global /// variable, it can implement this. This is used on ELF systems so that /// ".tbss" gets the TLS bit set etc. virtual unsigned getFlagsForNamedSection(const char *Section) const { return 0; } /// SectionForGlobal - This method computes the appropriate section to emit /// the specified global variable or function definition. This should not /// be passed external (or available externally) globals. // FIXME: MOVE TO ASMPRINTER. const Section* SectionForGlobal(const GlobalValue *GV) const; /// getSpecialCasedSectionGlobals - Allow the target to completely override /// section assignment of a global. /// FIXME: ELIMINATE this by making PIC16 implement ADDRESS with /// getFlagsForNamedSection. virtual const Section * getSpecialCasedSectionGlobals(const GlobalValue *GV, SectionKind Kind) const { return 0; } /// Turn the specified flags into a string that can be printed to the /// assembly file. virtual void getSectionFlags(unsigned Flags, SmallVectorImpl &Str) const { } // FIXME: Eliminate this. virtual const Section* SelectSectionForGlobal(const GlobalValue *GV, SectionKind Kind) const; /// getSLEB128Size - Compute the number of bytes required for a signed /// leb128 value. static unsigned getSLEB128Size(int Value); /// getULEB128Size - Compute the number of bytes required for an unsigned /// leb128 value. static unsigned getULEB128Size(unsigned Value); // Data directive accessors. // const char *getData8bitsDirective(unsigned AS = 0) const { return AS == 0 ? Data8bitsDirective : getDataASDirective(8, AS); } const char *getData16bitsDirective(unsigned AS = 0) const { return AS == 0 ? Data16bitsDirective : getDataASDirective(16, AS); } const char *getData32bitsDirective(unsigned AS = 0) const { return AS == 0 ? Data32bitsDirective : getDataASDirective(32, AS); } const char *getData64bitsDirective(unsigned AS = 0) const { return AS == 0 ? Data64bitsDirective : getDataASDirective(64, AS); } // Accessors. // const Section *getTextSection() const { return TextSection; } const Section *getDataSection() const { return DataSection; } const char *getBSSSection() const { return BSSSection; } const Section *getBSSSection_() const { return BSSSection_; } const Section *getReadOnlySection() const { return ReadOnlySection; } const Section *getTLSDataSection() const { return TLSDataSection; } const Section *getTLSBSSSection() const { return TLSBSSSection; } const char *getZeroFillDirective() const { return ZeroFillDirective; } const char *getNonexecutableStackDirective() const { return NonexecutableStackDirective; } bool needsSet() const { return NeedsSet; } const char *getPCSymbol() const { return PCSymbol; } char getSeparatorChar() const { return SeparatorChar; } unsigned getCommentColumn() const { return CommentColumn; } const char *getCommentString() const { return CommentString; } unsigned getOperandColumn(int operand) const { return FirstOperandColumn + (MaxOperandLength+1)*(operand-1); } const char *getGlobalPrefix() const { return GlobalPrefix; } const char *getPrivateGlobalPrefix() const { return PrivateGlobalPrefix; } const char *getLinkerPrivateGlobalPrefix() const { return LinkerPrivateGlobalPrefix; } const char *getJumpTableSpecialLabelPrefix() const { return JumpTableSpecialLabelPrefix; } const char *getGlobalVarAddrPrefix() const { return GlobalVarAddrPrefix; } const char *getGlobalVarAddrSuffix() const { return GlobalVarAddrSuffix; } const char *getFunctionAddrPrefix() const { return FunctionAddrPrefix; } const char *getFunctionAddrSuffix() const { return FunctionAddrSuffix; } const char *getPersonalityPrefix() const { return PersonalityPrefix; } const char *getPersonalitySuffix() const { return PersonalitySuffix; } bool getNeedsIndirectEncoding() const { return NeedsIndirectEncoding; } const char *getInlineAsmStart() const { return InlineAsmStart; } const char *getInlineAsmEnd() const { return InlineAsmEnd; } unsigned getAssemblerDialect() const { return AssemblerDialect; } bool doesAllowQuotesInName() const { return AllowQuotesInName; } const char *getZeroDirective() const { return ZeroDirective; } const char *getZeroDirectiveSuffix() const { return ZeroDirectiveSuffix; } const char *getAsciiDirective() const { return AsciiDirective; } const char *getAscizDirective() const { return AscizDirective; } const char *getJumpTableDirective() const { return JumpTableDirective; } const char *getAlignDirective() const { return AlignDirective; } bool getAlignmentIsInBytes() const { return AlignmentIsInBytes; } unsigned getTextAlignFillValue() const { return TextAlignFillValue; } const char *getSwitchToSectionDirective() const { return SwitchToSectionDirective; } const char *getTextSectionStartSuffix() const { return TextSectionStartSuffix; } const char *getDataSectionStartSuffix() const { return DataSectionStartSuffix; } const char *getSectionEndDirectiveSuffix() const { return SectionEndDirectiveSuffix; } const char *getConstantPoolSection() const { return ConstantPoolSection; } const char *getJumpTableDataSection() const { return JumpTableDataSection; } const char *getCStringSection() const { return CStringSection; } const Section *getCStringSection_() const { return CStringSection_; } const char *getStaticCtorsSection() const { return StaticCtorsSection; } const char *getStaticDtorsSection() const { return StaticDtorsSection; } const char *getGlobalDirective() const { return GlobalDirective; } const char *getExternDirective() const { return ExternDirective; } const char *getSetDirective() const { return SetDirective; } const char *getLCOMMDirective() const { return LCOMMDirective; } const char *getCOMMDirective() const { return COMMDirective; } bool getCOMMDirectiveTakesAlignment() const { return COMMDirectiveTakesAlignment; } bool hasDotTypeDotSizeDirective() const { return HasDotTypeDotSizeDirective; } bool hasSingleParameterDotFile() const { return HasSingleParameterDotFile; } const char *getUsedDirective() const { return UsedDirective; } const char *getWeakRefDirective() const { return WeakRefDirective; } const char *getWeakDefDirective() const { return WeakDefDirective; } const char *getHiddenDirective() const { return HiddenDirective; } const char *getProtectedDirective() const { return ProtectedDirective; } bool isAbsoluteDebugSectionOffsets() const { return AbsoluteDebugSectionOffsets; } bool isAbsoluteEHSectionOffsets() const { return AbsoluteEHSectionOffsets; } bool hasLEB128() const { return HasLEB128; } bool hasDotLocAndDotFile() const { return HasDotLocAndDotFile; } bool doesSupportDebugInformation() const { return SupportsDebugInformation; } bool doesSupportExceptionHandling() const { return SupportsExceptionHandling; } bool doesDwarfRequireFrameSection() const { return DwarfRequiresFrameSection; } bool doesDwarfUsesInlineInfoSection() const { return DwarfUsesInlineInfoSection; } bool is_EHSymbolPrivate() const { return Is_EHSymbolPrivate; } const char *getGlobalEHDirective() const { return GlobalEHDirective; } bool getSupportsWeakOmittedEHFrame() const { return SupportsWeakOmittedEHFrame; } const char *getDwarfSectionOffsetDirective() const { return DwarfSectionOffsetDirective; } const char *getDwarfAbbrevSection() const { return DwarfAbbrevSection; } const char *getDwarfInfoSection() const { return DwarfInfoSection; } const char *getDwarfLineSection() const { return DwarfLineSection; } const char *getDwarfFrameSection() const { return DwarfFrameSection; } const char *getDwarfPubNamesSection() const { return DwarfPubNamesSection; } const char *getDwarfPubTypesSection() const { return DwarfPubTypesSection; } const char *getDwarfDebugInlineSection() const { return DwarfDebugInlineSection; } const char *getDwarfStrSection() const { return DwarfStrSection; } const char *getDwarfLocSection() const { return DwarfLocSection; } const char *getDwarfARangesSection() const { return DwarfARangesSection; } const char *getDwarfRangesSection() const { return DwarfRangesSection; } const char *getDwarfMacroInfoSection() const { return DwarfMacroInfoSection; } const char *getDwarfEHFrameSection() const { return DwarfEHFrameSection; } const char *getDwarfExceptionSection() const { return DwarfExceptionSection; } const char *const *getAsmCBE() const { return AsmTransCBE; } }; } #endif