blob: 4fa6faa8585bf4bdb5d933433f18637ac9498353 [file] [log] [blame]
//===- lib/FileFormat/MachO/ArchHandler.h ---------------------------------===//
//
// The LLVM Linker
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
#ifndef LLD_READER_WRITER_MACHO_ARCH_HANDLER_H
#define LLD_READER_WRITER_MACHO_ARCH_HANDLER_H
#include "Atoms.h"
#include "File.h"
#include "MachONormalizedFile.h"
#include "lld/Core/LLVM.h"
#include "lld/Core/Reference.h"
#include "lld/Core/Simple.h"
#include "lld/ReaderWriter/MachOLinkingContext.h"
#include "llvm/ADT/Triple.h"
namespace lld {
namespace mach_o {
///
/// The ArchHandler class handles all architecture specific aspects of
/// mach-o linking.
///
class ArchHandler {
public:
virtual ~ArchHandler();
/// There is no public interface to subclasses of ArchHandler, so this
/// is the only way to instantiate an ArchHandler.
static std::unique_ptr<ArchHandler> create(MachOLinkingContext::Arch arch);
/// Get (arch specific) kind strings used by Registry.
virtual const Registry::KindStrings *kindStrings() = 0;
/// Convert mach-o Arch to Reference::KindArch.
virtual Reference::KindArch kindArch() = 0;
/// Used by StubPass to update References to shared library functions
/// to be references to a stub.
virtual bool isCallSite(const Reference &) = 0;
/// Used by GOTPass to locate GOT References
virtual bool isGOTAccess(const Reference &, bool &canBypassGOT) {
return false;
}
/// Used by TLVPass to locate TLV References.
virtual bool isTLVAccess(const Reference &) const { return false; }
/// Used by the TLVPass to update TLV References.
virtual void updateReferenceToTLV(const Reference *) {}
/// Used by ShimPass to insert shims in branches that switch mode.
virtual bool isNonCallBranch(const Reference &) = 0;
/// Used by GOTPass to update GOT References
virtual void updateReferenceToGOT(const Reference *, bool targetIsNowGOT) {}
/// Does this architecture make use of __unwind_info sections for exception
/// handling? If so, it will need a separate pass to create them.
virtual bool needsCompactUnwind() = 0;
/// Returns the kind of reference to use to synthesize a 32-bit image-offset
/// value, used in the __unwind_info section.
virtual Reference::KindValue imageOffsetKind() = 0;
/// Returns the kind of reference to use to synthesize a 32-bit image-offset
/// indirect value. Used for personality functions in the __unwind_info
/// section.
virtual Reference::KindValue imageOffsetKindIndirect() = 0;
/// Architecture specific compact unwind type that signals __eh_frame should
/// actually be used.
virtual uint32_t dwarfCompactUnwindType() = 0;
/// Reference from an __eh_frame CIE atom to its personality function it's
/// describing. Usually pointer-sized and PC-relative, but differs in whether
/// it needs to be in relocatable objects.
virtual Reference::KindValue unwindRefToPersonalityFunctionKind() = 0;
/// Reference from an __eh_frame FDE to the CIE it's based on.
virtual Reference::KindValue unwindRefToCIEKind() = 0;
/// Reference from an __eh_frame FDE atom to the function it's
/// describing. Usually pointer-sized and PC-relative, but differs in whether
/// it needs to be in relocatable objects.
virtual Reference::KindValue unwindRefToFunctionKind() = 0;
/// Reference from an __unwind_info entry of dwarfCompactUnwindType to the
/// required __eh_frame entry. On current architectures, the low 24 bits
/// represent the offset of the function's FDE entry from the start of
/// __eh_frame.
virtual Reference::KindValue unwindRefToEhFrameKind() = 0;
/// Returns a pointer sized reference kind. On 64-bit targets this will
/// likely be something like pointer64, and pointer32 on 32-bit targets.
virtual Reference::KindValue pointerKind() = 0;
virtual const Atom *fdeTargetFunction(const DefinedAtom *fde);
/// Used by normalizedFromAtoms() to know where to generated rebasing and
/// binding info in final executables.
virtual bool isPointer(const Reference &) = 0;
/// Used by normalizedFromAtoms() to know where to generated lazy binding
/// info in final executables.
virtual bool isLazyPointer(const Reference &);
/// Returns true if the specified relocation is paired to the next relocation.
virtual bool isPairedReloc(const normalized::Relocation &) = 0;
/// Prototype for a helper function. Given a sectionIndex and address,
/// finds the atom and offset with that atom of that address.
typedef std::function<std::error_code (uint32_t sectionIndex, uint64_t addr,
const lld::Atom **, Reference::Addend *)>
FindAtomBySectionAndAddress;
/// Prototype for a helper function. Given a symbolIndex, finds the atom
/// representing that symbol.
typedef std::function<std::error_code (uint32_t symbolIndex,
const lld::Atom **)> FindAtomBySymbolIndex;
/// Analyzes a relocation from a .o file and returns the info
/// (kind, target, addend) needed to instantiate a Reference.
/// Two helper functions are passed as parameters to find the target atom
/// given a symbol index or address.
virtual std::error_code
getReferenceInfo(const normalized::Relocation &reloc,
const DefinedAtom *inAtom,
uint32_t offsetInAtom,
uint64_t fixupAddress, bool isBigEndian,
FindAtomBySectionAndAddress atomFromAddress,
FindAtomBySymbolIndex atomFromSymbolIndex,
Reference::KindValue *kind,
const lld::Atom **target,
Reference::Addend *addend) = 0;
/// Analyzes a pair of relocations from a .o file and returns the info
/// (kind, target, addend) needed to instantiate a Reference.
/// Two helper functions are passed as parameters to find the target atom
/// given a symbol index or address.
virtual std::error_code
getPairReferenceInfo(const normalized::Relocation &reloc1,
const normalized::Relocation &reloc2,
const DefinedAtom *inAtom,
uint32_t offsetInAtom,
uint64_t fixupAddress, bool isBig, bool scatterable,
FindAtomBySectionAndAddress atomFromAddress,
FindAtomBySymbolIndex atomFromSymbolIndex,
Reference::KindValue *kind,
const lld::Atom **target,
Reference::Addend *addend) = 0;
/// Prototype for a helper function. Given an atom, finds the symbol table
/// index for it in the output file.
typedef std::function<uint32_t (const Atom &atom)> FindSymbolIndexForAtom;
/// Prototype for a helper function. Given an atom, finds the index
/// of the section that will contain the atom.
typedef std::function<uint32_t (const Atom &atom)> FindSectionIndexForAtom;
/// Prototype for a helper function. Given an atom, finds the address
/// assigned to it in the output file.
typedef std::function<uint64_t (const Atom &atom)> FindAddressForAtom;
/// Some architectures require local symbols on anonymous atoms.
virtual bool needsLocalSymbolInRelocatableFile(const DefinedAtom *atom) {
return false;
}
/// Copy raw content then apply all fixup References on an Atom.
virtual void generateAtomContent(const DefinedAtom &atom, bool relocatable,
FindAddressForAtom findAddress,
FindAddressForAtom findSectionAddress,
uint64_t imageBaseAddress,
uint8_t *atomContentBuffer) = 0;
/// Used in -r mode to convert a Reference to a mach-o relocation.
virtual void appendSectionRelocations(const DefinedAtom &atom,
uint64_t atomSectionOffset,
const Reference &ref,
FindSymbolIndexForAtom,
FindSectionIndexForAtom,
FindAddressForAtom,
normalized::Relocations&) = 0;
/// Add arch-specific References.
virtual void addAdditionalReferences(MachODefinedAtom &atom) { }
// Add Reference for data-in-code marker.
virtual void addDataInCodeReference(MachODefinedAtom &atom, uint32_t atomOff,
uint16_t length, uint16_t kind) { }
/// Returns true if the specificed Reference value marks the start or end
/// of a data-in-code range in an atom.
virtual bool isDataInCodeTransition(Reference::KindValue refKind) {
return false;
}
/// Returns the Reference value for a Reference that marks that start of
/// a data-in-code range.
virtual Reference::KindValue dataInCodeTransitionStart(
const MachODefinedAtom &atom) {
return 0;
}
/// Returns the Reference value for a Reference that marks that end of
/// a data-in-code range.
virtual Reference::KindValue dataInCodeTransitionEnd(
const MachODefinedAtom &atom) {
return 0;
}
/// Only relevant for 32-bit arm archs.
virtual bool isThumbFunction(const DefinedAtom &atom) { return false; }
/// Only relevant for 32-bit arm archs.
virtual const DefinedAtom *createShim(MachOFile &file, bool thumbToArm,
const DefinedAtom &) {
llvm_unreachable("shims only support on arm");
}
/// Does a given unwind-cfi atom represent a CIE (as opposed to an FDE).
static bool isDwarfCIE(bool isBig, const DefinedAtom *atom);
struct ReferenceInfo {
Reference::KindArch arch;
uint16_t kind;
uint32_t offset;
int32_t addend;
};
struct OptionalRefInfo {
bool used;
uint16_t kind;
uint32_t offset;
int32_t addend;
};
/// Table of architecture specific information for creating stubs.
struct StubInfo {
const char* binderSymbolName;
ReferenceInfo lazyPointerReferenceToHelper;
ReferenceInfo lazyPointerReferenceToFinal;
ReferenceInfo nonLazyPointerReferenceToBinder;
uint8_t codeAlignment;
uint32_t stubSize;
uint8_t stubBytes[16];
ReferenceInfo stubReferenceToLP;
OptionalRefInfo optStubReferenceToLP;
uint32_t stubHelperSize;
uint8_t stubHelperBytes[16];
ReferenceInfo stubHelperReferenceToImm;
ReferenceInfo stubHelperReferenceToHelperCommon;
DefinedAtom::ContentType stubHelperImageCacheContentType;
uint32_t stubHelperCommonSize;
uint8_t stubHelperCommonAlignment;
uint8_t stubHelperCommonBytes[36];
ReferenceInfo stubHelperCommonReferenceToCache;
OptionalRefInfo optStubHelperCommonReferenceToCache;
ReferenceInfo stubHelperCommonReferenceToBinder;
OptionalRefInfo optStubHelperCommonReferenceToBinder;
};
virtual const StubInfo &stubInfo() = 0;
protected:
ArchHandler();
static std::unique_ptr<mach_o::ArchHandler> create_x86_64();
static std::unique_ptr<mach_o::ArchHandler> create_x86();
static std::unique_ptr<mach_o::ArchHandler> create_arm();
static std::unique_ptr<mach_o::ArchHandler> create_arm64();
// Handy way to pack mach-o r_type and other bit fields into one 16-bit value.
typedef uint16_t RelocPattern;
enum {
rScattered = 0x8000,
rPcRel = 0x4000,
rExtern = 0x2000,
rLength1 = 0x0000,
rLength2 = 0x0100,
rLength4 = 0x0200,
rLength8 = 0x0300,
rLenArmLo = rLength1,
rLenArmHi = rLength2,
rLenThmbLo = rLength4,
rLenThmbHi = rLength8
};
/// Extract RelocPattern from normalized mach-o relocation.
static RelocPattern relocPattern(const normalized::Relocation &reloc);
/// Create normalized Relocation initialized from pattern.
static normalized::Relocation relocFromPattern(RelocPattern pattern);
/// One liner to add a relocation.
static void appendReloc(normalized::Relocations &relocs, uint32_t offset,
uint32_t symbol, uint32_t value,
RelocPattern pattern);
static int16_t readS16(const uint8_t *addr, bool isBig);
static int32_t readS32(const uint8_t *addr, bool isBig);
static uint32_t readU32(const uint8_t *addr, bool isBig);
static int64_t readS64(const uint8_t *addr, bool isBig);
};
} // namespace mach_o
} // namespace lld
#endif // LLD_READER_WRITER_MACHO_ARCH_HANDLER_H